1 mod help;
2 mod meta;
3 pub mod parser;
4 mod settings;
5 mod usage;
6 mod validator;
7 
8 // Std
9 use std::env;
10 use std::ffi::{OsStr, OsString};
11 use std::fmt;
12 use std::io::{self, BufRead, BufWriter, Write};
13 use std::path::Path;
14 use std::process;
15 use std::rc::Rc;
16 use std::result::Result as StdResult;
17 
18 // Third Party
19 #[cfg(feature = "yaml")]
20 use yaml_rust::Yaml;
21 
22 // Internal
23 pub use self::settings::AppSettings;
24 use app::help::Help;
25 use app::parser::Parser;
26 use args::{AnyArg, Arg, ArgGroup, ArgMatcher, ArgMatches, ArgSettings};
27 use completions::Shell;
28 use errors::Result as ClapResult;
29 use map::{self, VecMap};
30 
31 /// Used to create a representation of a command line program and all possible command line
32 /// arguments. Application settings are set using the "builder pattern" with the
33 /// [`App::get_matches`] family of methods being the terminal methods that starts the
34 /// runtime-parsing process. These methods then return information about the user supplied
35 /// arguments (or lack there of).
36 ///
37 /// **NOTE:** There aren't any mandatory "options" that one must set. The "options" may
38 /// also appear in any order (so long as one of the [`App::get_matches`] methods is the last method
39 /// called).
40 ///
41 /// # Examples
42 ///
43 /// ```no_run
44 /// # use clap::{App, Arg};
45 /// let m = App::new("My Program")
46 ///     .author("Me, me@mail.com")
47 ///     .version("1.0.2")
48 ///     .about("Explains in brief what the program does")
49 ///     .arg(
50 ///         Arg::with_name("in_file").index(1)
51 ///     )
52 ///     .after_help("Longer explanation to appear after the options when \
53 ///                  displaying the help information from --help or -h")
54 ///     .get_matches();
55 ///
56 /// // Your program logic starts here...
57 /// ```
58 /// [`App::get_matches`]: ./struct.App.html#method.get_matches
59 #[allow(missing_debug_implementations)]
60 pub struct App<'a, 'b>
61 where
62     'a: 'b,
63 {
64     #[doc(hidden)]
65     pub p: Parser<'a, 'b>,
66 }
67 
68 impl<'a, 'b> App<'a, 'b> {
69     /// Creates a new instance of an application requiring a name. The name may be, but doesn't
70     /// have to be same as the binary. The name will be displayed to the user when they request to
71     /// print version or help and usage information.
72     ///
73     /// # Examples
74     ///
75     /// ```no_run
76     /// # use clap::{App, Arg};
77     /// let prog = App::new("My Program")
78     /// # ;
79     /// ```
new<S: Into<String>>(n: S) -> Self80     pub fn new<S: Into<String>>(n: S) -> Self {
81         App {
82             p: Parser::with_name(n.into()),
83         }
84     }
85 
86     /// Get the name of the app
get_name(&self) -> &str87     pub fn get_name(&self) -> &str {
88         &self.p.meta.name
89     }
90 
91     /// Get the name of the binary
get_bin_name(&self) -> Option<&str>92     pub fn get_bin_name(&self) -> Option<&str> {
93         self.p.meta.bin_name.as_ref().map(|s| s.as_str())
94     }
95 
96     /// Creates a new instance of an application requiring a name, but uses the [`crate_authors!`]
97     /// and [`crate_version!`] macros to fill in the [`App::author`] and [`App::version`] fields.
98     ///
99     /// # Examples
100     ///
101     /// ```no_run
102     /// # use clap::{App, Arg};
103     /// let prog = App::with_defaults("My Program")
104     /// # ;
105     /// ```
106     /// [`crate_authors!`]: ./macro.crate_authors!.html
107     /// [`crate_version!`]: ./macro.crate_version!.html
108     /// [`App::author`]: ./struct.App.html#method.author
109     /// [`App::version`]: ./struct.App.html#method.author
110     #[deprecated(
111         since = "2.14.1",
112         note = "Can never work; use explicit App::author() and App::version() calls instead"
113     )]
with_defaults<S: Into<String>>(n: S) -> Self114     pub fn with_defaults<S: Into<String>>(n: S) -> Self {
115         let mut a = App {
116             p: Parser::with_name(n.into()),
117         };
118         a.p.meta.author = Some("Kevin K. <kbknapp@gmail.com>");
119         a.p.meta.version = Some("2.19.2");
120         a
121     }
122 
123     /// Creates a new instance of [`App`] from a .yml (YAML) file. A full example of supported YAML
124     /// objects can be found in [`examples/17_yaml.rs`] and [`examples/17_yaml.yml`]. One great use
125     /// for using YAML is when supporting multiple languages and dialects, as each language could
126     /// be a distinct YAML file and determined at compiletime via `cargo` "features" in your
127     /// `Cargo.toml`
128     ///
129     /// In order to use this function you must compile `clap` with the `features = ["yaml"]` in
130     /// your settings for the `[dependencies.clap]` table of your `Cargo.toml`
131     ///
132     /// **NOTE:** Due to how the YAML objects are built there is a convenience macro for loading
133     /// the YAML file at compile time (relative to the current file, like modules work). That YAML
134     /// object can then be passed to this function.
135     ///
136     /// # Panics
137     ///
138     /// The YAML file must be properly formatted or this function will [`panic!`]. A good way to
139     /// ensure this doesn't happen is to run your program with the `--help` switch. If this passes
140     /// without error, you needn't worry because the YAML is properly formatted.
141     ///
142     /// # Examples
143     ///
144     /// The following example shows how to load a properly formatted YAML file to build an instance
145     /// of an [`App`] struct.
146     ///
147     /// ```ignore
148     /// # #[macro_use]
149     /// # extern crate clap;
150     /// # use clap::App;
151     /// # fn main() {
152     /// let yml = load_yaml!("app.yml");
153     /// let app = App::from_yaml(yml);
154     ///
155     /// // continued logic goes here, such as `app.get_matches()` etc.
156     /// # }
157     /// ```
158     /// [`App`]: ./struct.App.html
159     /// [`examples/17_yaml.rs`]: https://github.com/clap-rs/clap/blob/v2.33.1/examples/17_yaml.rs
160     /// [`examples/17_yaml.yml`]: https://github.com/clap-rs/clap/blob/v2.33.1/examples/17_yaml.yml
161     /// [`panic!`]: https://doc.rust-lang.org/std/macro.panic!.html
162     #[cfg(feature = "yaml")]
from_yaml(yaml: &'a Yaml) -> App<'a, 'a>163     pub fn from_yaml(yaml: &'a Yaml) -> App<'a, 'a> {
164         App::from(yaml)
165     }
166 
167     /// Sets a string of author(s) that will be displayed to the user when they
168     /// request the help information with `--help` or `-h`.
169     ///
170     /// **Pro-tip:** Use `clap`s convenience macro [`crate_authors!`] to automatically set your
171     /// application's author(s) to the same thing as your crate at compile time. See the [`examples/`]
172     /// directory for more information
173     ///
174     /// See the [`examples/`]
175     /// directory for more information
176     ///
177     /// # Examples
178     ///
179     /// ```no_run
180     /// # use clap::{App, Arg};
181     /// App::new("myprog")
182     ///      .author("Me, me@mymain.com")
183     /// # ;
184     /// ```
185     /// [`crate_authors!`]: ./macro.crate_authors!.html
186     /// [`examples/`]: https://github.com/clap-rs/clap/tree/v2.33.1/examples
author<S: Into<&'b str>>(mut self, author: S) -> Self187     pub fn author<S: Into<&'b str>>(mut self, author: S) -> Self {
188         self.p.meta.author = Some(author.into());
189         self
190     }
191 
192     /// Overrides the system-determined binary name. This should only be used when absolutely
193     /// necessary, such as when the binary name for your application is misleading, or perhaps
194     /// *not* how the user should invoke your program.
195     ///
196     /// **Pro-tip:** When building things such as third party `cargo` subcommands, this setting
197     /// **should** be used!
198     ///
199     /// **NOTE:** This command **should not** be used for [`SubCommand`]s.
200     ///
201     /// # Examples
202     ///
203     /// ```no_run
204     /// # use clap::{App, Arg};
205     /// App::new("My Program")
206     ///      .bin_name("my_binary")
207     /// # ;
208     /// ```
209     /// [`SubCommand`]: ./struct.SubCommand.html
bin_name<S: Into<String>>(mut self, name: S) -> Self210     pub fn bin_name<S: Into<String>>(mut self, name: S) -> Self {
211         self.p.meta.bin_name = Some(name.into());
212         self
213     }
214 
215     /// Sets a string describing what the program does. This will be displayed when displaying help
216     /// information with `-h`.
217     ///
218     /// **NOTE:** If only `about` is provided, and not [`App::long_about`] but the user requests
219     /// `--help` clap will still display the contents of `about` appropriately
220     ///
221     /// **NOTE:** Only [`App::about`] is used in completion script generation in order to be
222     /// concise
223     ///
224     /// # Examples
225     ///
226     /// ```no_run
227     /// # use clap::{App, Arg};
228     /// App::new("myprog")
229     ///     .about("Does really amazing things to great people")
230     /// # ;
231     /// ```
232     /// [`App::long_about`]: ./struct.App.html#method.long_about
about<S: Into<&'b str>>(mut self, about: S) -> Self233     pub fn about<S: Into<&'b str>>(mut self, about: S) -> Self {
234         self.p.meta.about = Some(about.into());
235         self
236     }
237 
238     /// Sets a string describing what the program does. This will be displayed when displaying help
239     /// information.
240     ///
241     /// **NOTE:** If only `long_about` is provided, and not [`App::about`] but the user requests
242     /// `-h` clap will still display the contents of `long_about` appropriately
243     ///
244     /// **NOTE:** Only [`App::about`] is used in completion script generation in order to be
245     /// concise
246     ///
247     /// # Examples
248     ///
249     /// ```no_run
250     /// # use clap::{App, Arg};
251     /// App::new("myprog")
252     ///     .long_about(
253     /// "Does really amazing things to great people. Now let's talk a little
254     ///  more in depth about how this subcommand really works. It may take about
255     ///  a few lines of text, but that's ok!")
256     /// # ;
257     /// ```
258     /// [`App::about`]: ./struct.App.html#method.about
long_about<S: Into<&'b str>>(mut self, about: S) -> Self259     pub fn long_about<S: Into<&'b str>>(mut self, about: S) -> Self {
260         self.p.meta.long_about = Some(about.into());
261         self
262     }
263 
264     /// Sets the program's name. This will be displayed when displaying help information.
265     ///
266     /// **Pro-top:** This function is particularly useful when configuring a program via
267     /// [`App::from_yaml`] in conjunction with the [`crate_name!`] macro to derive the program's
268     /// name from its `Cargo.toml`.
269     ///
270     /// # Examples
271     /// ```ignore
272     /// # #[macro_use]
273     /// # extern crate clap;
274     /// # use clap::App;
275     /// # fn main() {
276     /// let yml = load_yaml!("app.yml");
277     /// let app = App::from_yaml(yml)
278     ///     .name(crate_name!());
279     ///
280     /// // continued logic goes here, such as `app.get_matches()` etc.
281     /// # }
282     /// ```
283     ///
284     /// [`App::from_yaml`]: ./struct.App.html#method.from_yaml
285     /// [`crate_name!`]: ./macro.crate_name.html
name<S: Into<String>>(mut self, name: S) -> Self286     pub fn name<S: Into<String>>(mut self, name: S) -> Self {
287         self.p.meta.name = name.into();
288         self
289     }
290 
291     /// Adds additional help information to be displayed in addition to auto-generated help. This
292     /// information is displayed **after** the auto-generated help information. This is often used
293     /// to describe how to use the arguments, or caveats to be noted.
294     ///
295     /// # Examples
296     ///
297     /// ```no_run
298     /// # use clap::App;
299     /// App::new("myprog")
300     ///     .after_help("Does really amazing things to great people...but be careful with -R")
301     /// # ;
302     /// ```
after_help<S: Into<&'b str>>(mut self, help: S) -> Self303     pub fn after_help<S: Into<&'b str>>(mut self, help: S) -> Self {
304         self.p.meta.more_help = Some(help.into());
305         self
306     }
307 
308     /// Adds additional help information to be displayed in addition to auto-generated help. This
309     /// information is displayed **before** the auto-generated help information. This is often used
310     /// for header information.
311     ///
312     /// # Examples
313     ///
314     /// ```no_run
315     /// # use clap::App;
316     /// App::new("myprog")
317     ///     .before_help("Some info I'd like to appear before the help info")
318     /// # ;
319     /// ```
before_help<S: Into<&'b str>>(mut self, help: S) -> Self320     pub fn before_help<S: Into<&'b str>>(mut self, help: S) -> Self {
321         self.p.meta.pre_help = Some(help.into());
322         self
323     }
324 
325     /// Sets a string of the version number to be displayed when displaying version or help
326     /// information with `-V`.
327     ///
328     /// **NOTE:** If only `version` is provided, and not [`App::long_version`] but the user
329     /// requests `--version` clap will still display the contents of `version` appropriately
330     ///
331     /// **Pro-tip:** Use `clap`s convenience macro [`crate_version!`] to automatically set your
332     /// application's version to the same thing as your crate at compile time. See the [`examples/`]
333     /// directory for more information
334     ///
335     /// # Examples
336     ///
337     /// ```no_run
338     /// # use clap::{App, Arg};
339     /// App::new("myprog")
340     ///     .version("v0.1.24")
341     /// # ;
342     /// ```
343     /// [`crate_version!`]: ./macro.crate_version!.html
344     /// [`examples/`]: https://github.com/clap-rs/clap/tree/v2.33.1/examples
345     /// [`App::long_version`]: ./struct.App.html#method.long_version
version<S: Into<&'b str>>(mut self, ver: S) -> Self346     pub fn version<S: Into<&'b str>>(mut self, ver: S) -> Self {
347         self.p.meta.version = Some(ver.into());
348         self
349     }
350 
351     /// Sets a string of the version number to be displayed when displaying version or help
352     /// information with `--version`.
353     ///
354     /// **NOTE:** If only `long_version` is provided, and not [`App::version`] but the user
355     /// requests `-V` clap will still display the contents of `long_version` appropriately
356     ///
357     /// **Pro-tip:** Use `clap`s convenience macro [`crate_version!`] to automatically set your
358     /// application's version to the same thing as your crate at compile time. See the [`examples/`]
359     /// directory for more information
360     ///
361     /// # Examples
362     ///
363     /// ```no_run
364     /// # use clap::{App, Arg};
365     /// App::new("myprog")
366     ///     .long_version(
367     /// "v0.1.24
368     ///  commit: abcdef89726d
369     ///  revision: 123
370     ///  release: 2
371     ///  binary: myprog")
372     /// # ;
373     /// ```
374     /// [`crate_version!`]: ./macro.crate_version!.html
375     /// [`examples/`]: https://github.com/clap-rs/clap/tree/v2.33.1/examples
376     /// [`App::version`]: ./struct.App.html#method.version
long_version<S: Into<&'b str>>(mut self, ver: S) -> Self377     pub fn long_version<S: Into<&'b str>>(mut self, ver: S) -> Self {
378         self.p.meta.long_version = Some(ver.into());
379         self
380     }
381 
382     /// Sets a custom usage string to override the auto-generated usage string.
383     ///
384     /// This will be displayed to the user when errors are found in argument parsing, or when you
385     /// call [`ArgMatches::usage`]
386     ///
387     /// **CAUTION:** Using this setting disables `clap`s "context-aware" usage strings. After this
388     /// setting is set, this will be the only usage string displayed to the user!
389     ///
390     /// **NOTE:** You do not need to specify the "USAGE: \n\t" portion, as that will
391     /// still be applied by `clap`, you only need to specify the portion starting
392     /// with the binary name.
393     ///
394     /// **NOTE:** This will not replace the entire help message, *only* the portion
395     /// showing the usage.
396     ///
397     /// # Examples
398     ///
399     /// ```no_run
400     /// # use clap::{App, Arg};
401     /// App::new("myprog")
402     ///     .usage("myapp [-clDas] <some_file>")
403     /// # ;
404     /// ```
405     /// [`ArgMatches::usage`]: ./struct.ArgMatches.html#method.usage
usage<S: Into<&'b str>>(mut self, usage: S) -> Self406     pub fn usage<S: Into<&'b str>>(mut self, usage: S) -> Self {
407         self.p.meta.usage_str = Some(usage.into());
408         self
409     }
410 
411     /// Sets a custom help message and overrides the auto-generated one. This should only be used
412     /// when the auto-generated message does not suffice.
413     ///
414     /// This will be displayed to the user when they use `--help` or `-h`
415     ///
416     /// **NOTE:** This replaces the **entire** help message, so nothing will be auto-generated.
417     ///
418     /// **NOTE:** This **only** replaces the help message for the current command, meaning if you
419     /// are using subcommands, those help messages will still be auto-generated unless you
420     /// specify a [`Arg::help`] for them as well.
421     ///
422     /// # Examples
423     ///
424     /// ```no_run
425     /// # use clap::{App, Arg};
426     /// App::new("myapp")
427     ///     .help("myapp v1.0\n\
428     ///            Does awesome things\n\
429     ///            (C) me@mail.com\n\n\
430     ///
431     ///            USAGE: myapp <opts> <command>\n\n\
432     ///
433     ///            Options:\n\
434     ///            -h, --help       Display this message\n\
435     ///            -V, --version    Display version info\n\
436     ///            -s <stuff>       Do something with stuff\n\
437     ///            -v               Be verbose\n\n\
438     ///
439     ///            Commmands:\n\
440     ///            help             Prints this message\n\
441     ///            work             Do some work")
442     /// # ;
443     /// ```
444     /// [`Arg::help`]: ./struct.Arg.html#method.help
help<S: Into<&'b str>>(mut self, help: S) -> Self445     pub fn help<S: Into<&'b str>>(mut self, help: S) -> Self {
446         self.p.meta.help_str = Some(help.into());
447         self
448     }
449 
450     /// Sets the [`short`] for the auto-generated `help` argument.
451     ///
452     /// By default `clap` automatically assigns `h`, but this can be overridden if you have a
453     /// different argument which you'd prefer to use the `-h` short with. This can be done by
454     /// defining your own argument with a lowercase `h` as the [`short`].
455     ///
456     /// `clap` lazily generates these `help` arguments **after** you've defined any arguments of
457     /// your own.
458     ///
459     /// **NOTE:** Any leading `-` characters will be stripped, and only the first
460     /// non `-` character will be used as the [`short`] version
461     ///
462     /// # Examples
463     ///
464     /// ```no_run
465     /// # use clap::{App, Arg};
466     /// App::new("myprog")
467     ///     .help_short("H") // Using an uppercase `H` instead of the default lowercase `h`
468     /// # ;
469     /// ```
470     /// [`short`]: ./struct.Arg.html#method.short
help_short<S: AsRef<str> + 'b>(mut self, s: S) -> Self471     pub fn help_short<S: AsRef<str> + 'b>(mut self, s: S) -> Self {
472         self.p.help_short(s.as_ref());
473         self
474     }
475 
476     /// Sets the [`short`] for the auto-generated `version` argument.
477     ///
478     /// By default `clap` automatically assigns `V`, but this can be overridden if you have a
479     /// different argument which you'd prefer to use the `-V` short with. This can be done by
480     /// defining your own argument with an uppercase `V` as the [`short`].
481     ///
482     /// `clap` lazily generates these `version` arguments **after** you've defined any arguments of
483     /// your own.
484     ///
485     /// **NOTE:** Any leading `-` characters will be stripped, and only the first
486     /// non `-` character will be used as the `short` version
487     ///
488     /// # Examples
489     ///
490     /// ```no_run
491     /// # use clap::{App, Arg};
492     /// App::new("myprog")
493     ///     .version_short("v") // Using a lowercase `v` instead of the default capital `V`
494     /// # ;
495     /// ```
496     /// [`short`]: ./struct.Arg.html#method.short
version_short<S: AsRef<str>>(mut self, s: S) -> Self497     pub fn version_short<S: AsRef<str>>(mut self, s: S) -> Self {
498         self.p.version_short(s.as_ref());
499         self
500     }
501 
502     /// Sets the help text for the auto-generated `help` argument.
503     ///
504     /// By default `clap` sets this to `"Prints help information"`, but if you're using a
505     /// different convention for your help messages and would prefer a different phrasing you can
506     /// override it.
507     ///
508     /// # Examples
509     ///
510     /// ```no_run
511     /// # use clap::{App, Arg};
512     /// App::new("myprog")
513     ///     .help_message("Print help information") // Perhaps you want imperative help messages
514     ///
515     /// # ;
516     /// ```
help_message<S: Into<&'a str>>(mut self, s: S) -> Self517     pub fn help_message<S: Into<&'a str>>(mut self, s: S) -> Self {
518         self.p.help_message = Some(s.into());
519         self
520     }
521 
522     /// Sets the help text for the auto-generated `version` argument.
523     ///
524     /// By default `clap` sets this to `"Prints version information"`, but if you're using a
525     /// different convention for your help messages and would prefer a different phrasing then you
526     /// can change it.
527     ///
528     /// # Examples
529     /// ```no_run
530     /// # use clap::{App, Arg};
531     /// App::new("myprog")
532     ///     .version_message("Print version information") // Perhaps you want imperative help messages
533     /// # ;
534     /// ```
version_message<S: Into<&'a str>>(mut self, s: S) -> Self535     pub fn version_message<S: Into<&'a str>>(mut self, s: S) -> Self {
536         self.p.version_message = Some(s.into());
537         self
538     }
539 
540     /// Sets the help template to be used, overriding the default format.
541     ///
542     /// Tags arg given inside curly brackets.
543     ///
544     /// Valid tags are:
545     ///
546     ///   * `{bin}`         - Binary name.
547     ///   * `{version}`     - Version number.
548     ///   * `{author}`      - Author information.
549     ///   * `{about}`       - General description (from [`App::about`])
550     ///   * `{usage}`       - Automatically generated or given usage string.
551     ///   * `{all-args}`    - Help for all arguments (options, flags, positionals arguments,
552     ///                       and subcommands) including titles.
553     ///   * `{unified}`     - Unified help for options and flags. Note, you must *also* set
554     ///                       [`AppSettings::UnifiedHelpMessage`] to fully merge both options and
555     ///                       flags, otherwise the ordering is "best effort"
556     ///   * `{flags}`       - Help for flags.
557     ///   * `{options}`     - Help for options.
558     ///   * `{positionals}` - Help for positionals arguments.
559     ///   * `{subcommands}` - Help for subcommands.
560     ///   * `{after-help}`  - Help from [`App::after_help`]
561     ///   * `{before-help}`  - Help from [`App::before_help`]
562     ///
563     /// # Examples
564     ///
565     /// ```no_run
566     /// # use clap::{App, Arg};
567     /// App::new("myprog")
568     ///     .version("1.0")
569     ///     .template("{bin} ({version}) - {usage}")
570     /// # ;
571     /// ```
572     /// **NOTE:** The template system is, on purpose, very simple. Therefore the tags have to be
573     /// written in lowercase and without spacing.
574     ///
575     /// [`App::about`]: ./struct.App.html#method.about
576     /// [`App::after_help`]: ./struct.App.html#method.after_help
577     /// [`App::before_help`]: ./struct.App.html#method.before_help
578     /// [`AppSettings::UnifiedHelpMessage`]: ./enum.AppSettings.html#variant.UnifiedHelpMessage
template<S: Into<&'b str>>(mut self, s: S) -> Self579     pub fn template<S: Into<&'b str>>(mut self, s: S) -> Self {
580         self.p.meta.template = Some(s.into());
581         self
582     }
583 
584     /// Enables a single command, or [`SubCommand`], level settings.
585     ///
586     /// See [`AppSettings`] for a full list of possibilities and examples.
587     ///
588     /// # Examples
589     ///
590     /// ```no_run
591     /// # use clap::{App, Arg, AppSettings};
592     /// App::new("myprog")
593     ///     .setting(AppSettings::SubcommandRequired)
594     ///     .setting(AppSettings::WaitOnError)
595     /// # ;
596     /// ```
597     /// [`SubCommand`]: ./struct.SubCommand.html
598     /// [`AppSettings`]: ./enum.AppSettings.html
setting(mut self, setting: AppSettings) -> Self599     pub fn setting(mut self, setting: AppSettings) -> Self {
600         self.p.set(setting);
601         self
602     }
603 
604     /// Enables multiple command, or [`SubCommand`], level settings
605     ///
606     /// See [`AppSettings`] for a full list of possibilities and examples.
607     ///
608     /// # Examples
609     ///
610     /// ```no_run
611     /// # use clap::{App, Arg, AppSettings};
612     /// App::new("myprog")
613     ///     .settings(&[AppSettings::SubcommandRequired,
614     ///                  AppSettings::WaitOnError])
615     /// # ;
616     /// ```
617     /// [`SubCommand`]: ./struct.SubCommand.html
618     /// [`AppSettings`]: ./enum.AppSettings.html
settings(mut self, settings: &[AppSettings]) -> Self619     pub fn settings(mut self, settings: &[AppSettings]) -> Self {
620         for s in settings {
621             self.p.set(*s);
622         }
623         self
624     }
625 
626     /// Enables a single setting that is propagated down through all child [`SubCommand`]s.
627     ///
628     /// See [`AppSettings`] for a full list of possibilities and examples.
629     ///
630     /// **NOTE**: The setting is *only* propagated *down* and not up through parent commands.
631     ///
632     /// # Examples
633     ///
634     /// ```no_run
635     /// # use clap::{App, Arg, AppSettings};
636     /// App::new("myprog")
637     ///     .global_setting(AppSettings::SubcommandRequired)
638     /// # ;
639     /// ```
640     /// [`SubCommand`]: ./struct.SubCommand.html
641     /// [`AppSettings`]: ./enum.AppSettings.html
global_setting(mut self, setting: AppSettings) -> Self642     pub fn global_setting(mut self, setting: AppSettings) -> Self {
643         self.p.set(setting);
644         self.p.g_settings.set(setting);
645         self
646     }
647 
648     /// Enables multiple settings which are propagated *down* through all child [`SubCommand`]s.
649     ///
650     /// See [`AppSettings`] for a full list of possibilities and examples.
651     ///
652     /// **NOTE**: The setting is *only* propagated *down* and not up through parent commands.
653     ///
654     /// # Examples
655     ///
656     /// ```no_run
657     /// # use clap::{App, Arg, AppSettings};
658     /// App::new("myprog")
659     ///     .global_settings(&[AppSettings::SubcommandRequired,
660     ///                  AppSettings::ColoredHelp])
661     /// # ;
662     /// ```
663     /// [`SubCommand`]: ./struct.SubCommand.html
664     /// [`AppSettings`]: ./enum.AppSettings.html
global_settings(mut self, settings: &[AppSettings]) -> Self665     pub fn global_settings(mut self, settings: &[AppSettings]) -> Self {
666         for s in settings {
667             self.p.set(*s);
668             self.p.g_settings.set(*s)
669         }
670         self
671     }
672 
673     /// Disables a single command, or [`SubCommand`], level setting.
674     ///
675     /// See [`AppSettings`] for a full list of possibilities and examples.
676     ///
677     /// # Examples
678     ///
679     /// ```no_run
680     /// # use clap::{App, AppSettings};
681     /// App::new("myprog")
682     ///     .unset_setting(AppSettings::ColorAuto)
683     /// # ;
684     /// ```
685     /// [`SubCommand`]: ./struct.SubCommand.html
686     /// [`AppSettings`]: ./enum.AppSettings.html
unset_setting(mut self, setting: AppSettings) -> Self687     pub fn unset_setting(mut self, setting: AppSettings) -> Self {
688         self.p.unset(setting);
689         self
690     }
691 
692     /// Disables multiple command, or [`SubCommand`], level settings.
693     ///
694     /// See [`AppSettings`] for a full list of possibilities and examples.
695     ///
696     /// # Examples
697     ///
698     /// ```no_run
699     /// # use clap::{App, AppSettings};
700     /// App::new("myprog")
701     ///     .unset_settings(&[AppSettings::ColorAuto,
702     ///                       AppSettings::AllowInvalidUtf8])
703     /// # ;
704     /// ```
705     /// [`SubCommand`]: ./struct.SubCommand.html
706     /// [`AppSettings`]: ./enum.AppSettings.html
unset_settings(mut self, settings: &[AppSettings]) -> Self707     pub fn unset_settings(mut self, settings: &[AppSettings]) -> Self {
708         for s in settings {
709             self.p.unset(*s);
710         }
711         self
712     }
713 
714     /// Sets the terminal width at which to wrap help messages. Defaults to `120`. Using `0` will
715     /// ignore terminal widths and use source formatting.
716     ///
717     /// `clap` automatically tries to determine the terminal width on Unix, Linux, macOS and Windows
718     /// if the `wrap_help` cargo "feature" has been used while compiling. If the terminal width
719     /// cannot be determined, `clap` defaults to `120`.
720     ///
721     /// **NOTE:** This setting applies globally and *not* on a per-command basis.
722     ///
723     /// **NOTE:** This setting must be set **before** any subcommands are added!
724     ///
725     /// # Platform Specific
726     ///
727     /// Only Unix, Linux, macOS and Windows support automatic determination of terminal width.
728     /// Even on those platforms, this setting is useful if for any reason the terminal width
729     /// cannot be determined.
730     ///
731     /// # Examples
732     ///
733     /// ```no_run
734     /// # use clap::App;
735     /// App::new("myprog")
736     ///     .set_term_width(80)
737     /// # ;
738     /// ```
set_term_width(mut self, width: usize) -> Self739     pub fn set_term_width(mut self, width: usize) -> Self {
740         self.p.meta.term_w = Some(width);
741         self
742     }
743 
744     /// Sets the max terminal width at which to wrap help messages. Using `0` will ignore terminal
745     /// widths and use source formatting.
746     ///
747     /// `clap` automatically tries to determine the terminal width on Unix, Linux, macOS and Windows
748     /// if the `wrap_help` cargo "feature" has been used while compiling, but one might want to
749     /// limit the size (e.g. when the terminal is running fullscreen).
750     ///
751     /// **NOTE:** This setting applies globally and *not* on a per-command basis.
752     ///
753     /// **NOTE:** This setting must be set **before** any subcommands are added!
754     ///
755     /// # Platform Specific
756     ///
757     /// Only Unix, Linux, macOS and Windows support automatic determination of terminal width.
758     ///
759     /// # Examples
760     ///
761     /// ```no_run
762     /// # use clap::App;
763     /// App::new("myprog")
764     ///     .max_term_width(100)
765     /// # ;
766     /// ```
max_term_width(mut self, w: usize) -> Self767     pub fn max_term_width(mut self, w: usize) -> Self {
768         self.p.meta.max_w = Some(w);
769         self
770     }
771 
772     /// Adds an [argument] to the list of valid possibilities.
773     ///
774     /// # Examples
775     ///
776     /// ```no_run
777     /// # use clap::{App, Arg};
778     /// App::new("myprog")
779     ///     // Adding a single "flag" argument with a short and help text, using Arg::with_name()
780     ///     .arg(
781     ///         Arg::with_name("debug")
782     ///            .short("d")
783     ///            .help("turns on debugging mode")
784     ///     )
785     ///     // Adding a single "option" argument with a short, a long, and help text using the less
786     ///     // verbose Arg::from_usage()
787     ///     .arg(
788     ///         Arg::from_usage("-c --config=[CONFIG] 'Optionally sets a config file to use'")
789     ///     )
790     /// # ;
791     /// ```
792     /// [argument]: ./struct.Arg.html
arg<A: Into<Arg<'a, 'b>>>(mut self, a: A) -> Self793     pub fn arg<A: Into<Arg<'a, 'b>>>(mut self, a: A) -> Self {
794         self.p.add_arg(a.into());
795         self
796     }
797 
798     /// Adds multiple [arguments] to the list of valid possibilities
799     ///
800     /// # Examples
801     ///
802     /// ```no_run
803     /// # use clap::{App, Arg};
804     /// App::new("myprog")
805     ///     .args(
806     ///         &[Arg::from_usage("[debug] -d 'turns on debugging info'"),
807     ///          Arg::with_name("input").index(1).help("the input file to use")]
808     ///     )
809     /// # ;
810     /// ```
811     /// [arguments]: ./struct.Arg.html
args(mut self, args: &[Arg<'a, 'b>]) -> Self812     pub fn args(mut self, args: &[Arg<'a, 'b>]) -> Self {
813         for arg in args {
814             self.p.add_arg_ref(arg);
815         }
816         self
817     }
818 
819     /// A convenience method for adding a single [argument] from a usage type string. The string
820     /// used follows the same rules and syntax as [`Arg::from_usage`]
821     ///
822     /// **NOTE:** The downside to using this method is that you can not set any additional
823     /// properties of the [`Arg`] other than what [`Arg::from_usage`] supports.
824     ///
825     /// # Examples
826     ///
827     /// ```no_run
828     /// # use clap::{App, Arg};
829     /// App::new("myprog")
830     ///     .arg_from_usage("-c --config=<FILE> 'Sets a configuration file to use'")
831     /// # ;
832     /// ```
833     /// [argument]: ./struct.Arg.html
834     /// [`Arg`]: ./struct.Arg.html
835     /// [`Arg::from_usage`]: ./struct.Arg.html#method.from_usage
arg_from_usage(mut self, usage: &'a str) -> Self836     pub fn arg_from_usage(mut self, usage: &'a str) -> Self {
837         self.p.add_arg(Arg::from_usage(usage));
838         self
839     }
840 
841     /// Adds multiple [arguments] at once from a usage string, one per line. See
842     /// [`Arg::from_usage`] for details on the syntax and rules supported.
843     ///
844     /// **NOTE:** Like [`App::arg_from_usage`] the downside is you only set properties for the
845     /// [`Arg`]s which [`Arg::from_usage`] supports.
846     ///
847     /// # Examples
848     ///
849     /// ```no_run
850     /// # use clap::{App, Arg};
851     /// App::new("myprog")
852     ///     .args_from_usage(
853     ///         "-c --config=[FILE] 'Sets a configuration file to use'
854     ///          [debug]... -d 'Sets the debugging level'
855     ///          <FILE> 'The input file to use'"
856     ///     )
857     /// # ;
858     /// ```
859     /// [arguments]: ./struct.Arg.html
860     /// [`Arg::from_usage`]: ./struct.Arg.html#method.from_usage
861     /// [`App::arg_from_usage`]: ./struct.App.html#method.arg_from_usage
862     /// [`Arg`]: ./struct.Arg.html
args_from_usage(mut self, usage: &'a str) -> Self863     pub fn args_from_usage(mut self, usage: &'a str) -> Self {
864         for line in usage.lines() {
865             let l = line.trim();
866             if l.is_empty() {
867                 continue;
868             }
869             self.p.add_arg(Arg::from_usage(l));
870         }
871         self
872     }
873 
874     /// Allows adding a [`SubCommand`] alias, which function as "hidden" subcommands that
875     /// automatically dispatch as if this subcommand was used. This is more efficient, and easier
876     /// than creating multiple hidden subcommands as one only needs to check for the existence of
877     /// this command, and not all variants.
878     ///
879     /// # Examples
880     ///
881     /// ```no_run
882     /// # use clap::{App, Arg, SubCommand};
883     /// let m = App::new("myprog")
884     ///             .subcommand(SubCommand::with_name("test")
885     ///                 .alias("do-stuff"))
886     ///             .get_matches_from(vec!["myprog", "do-stuff"]);
887     /// assert_eq!(m.subcommand_name(), Some("test"));
888     /// ```
889     /// [`SubCommand`]: ./struct.SubCommand.html
alias<S: Into<&'b str>>(mut self, name: S) -> Self890     pub fn alias<S: Into<&'b str>>(mut self, name: S) -> Self {
891         if let Some(ref mut als) = self.p.meta.aliases {
892             als.push((name.into(), false));
893         } else {
894             self.p.meta.aliases = Some(vec![(name.into(), false)]);
895         }
896         self
897     }
898 
899     /// Allows adding [`SubCommand`] aliases, which function as "hidden" subcommands that
900     /// automatically dispatch as if this subcommand was used. This is more efficient, and easier
901     /// than creating multiple hidden subcommands as one only needs to check for the existence of
902     /// this command, and not all variants.
903     ///
904     /// # Examples
905     ///
906     /// ```rust
907     /// # use clap::{App, Arg, SubCommand};
908     /// let m = App::new("myprog")
909     ///             .subcommand(SubCommand::with_name("test")
910     ///                 .aliases(&["do-stuff", "do-tests", "tests"]))
911     ///                 .arg(Arg::with_name("input")
912     ///                             .help("the file to add")
913     ///                             .index(1)
914     ///                             .required(false))
915     ///             .get_matches_from(vec!["myprog", "do-tests"]);
916     /// assert_eq!(m.subcommand_name(), Some("test"));
917     /// ```
918     /// [`SubCommand`]: ./struct.SubCommand.html
aliases(mut self, names: &[&'b str]) -> Self919     pub fn aliases(mut self, names: &[&'b str]) -> Self {
920         if let Some(ref mut als) = self.p.meta.aliases {
921             for n in names {
922                 als.push((n, false));
923             }
924         } else {
925             self.p.meta.aliases = Some(names.iter().map(|n| (*n, false)).collect::<Vec<_>>());
926         }
927         self
928     }
929 
930     /// Allows adding a [`SubCommand`] alias that functions exactly like those defined with
931     /// [`App::alias`], except that they are visible inside the help message.
932     ///
933     /// # Examples
934     ///
935     /// ```no_run
936     /// # use clap::{App, Arg, SubCommand};
937     /// let m = App::new("myprog")
938     ///             .subcommand(SubCommand::with_name("test")
939     ///                 .visible_alias("do-stuff"))
940     ///             .get_matches_from(vec!["myprog", "do-stuff"]);
941     /// assert_eq!(m.subcommand_name(), Some("test"));
942     /// ```
943     /// [`SubCommand`]: ./struct.SubCommand.html
944     /// [`App::alias`]: ./struct.App.html#method.alias
visible_alias<S: Into<&'b str>>(mut self, name: S) -> Self945     pub fn visible_alias<S: Into<&'b str>>(mut self, name: S) -> Self {
946         if let Some(ref mut als) = self.p.meta.aliases {
947             als.push((name.into(), true));
948         } else {
949             self.p.meta.aliases = Some(vec![(name.into(), true)]);
950         }
951         self
952     }
953 
954     /// Allows adding multiple [`SubCommand`] aliases that functions exactly like those defined
955     /// with [`App::aliases`], except that they are visible inside the help message.
956     ///
957     /// # Examples
958     ///
959     /// ```no_run
960     /// # use clap::{App, Arg, SubCommand};
961     /// let m = App::new("myprog")
962     ///             .subcommand(SubCommand::with_name("test")
963     ///                 .visible_aliases(&["do-stuff", "tests"]))
964     ///             .get_matches_from(vec!["myprog", "do-stuff"]);
965     /// assert_eq!(m.subcommand_name(), Some("test"));
966     /// ```
967     /// [`SubCommand`]: ./struct.SubCommand.html
968     /// [`App::aliases`]: ./struct.App.html#method.aliases
visible_aliases(mut self, names: &[&'b str]) -> Self969     pub fn visible_aliases(mut self, names: &[&'b str]) -> Self {
970         if let Some(ref mut als) = self.p.meta.aliases {
971             for n in names {
972                 als.push((n, true));
973             }
974         } else {
975             self.p.meta.aliases = Some(names.iter().map(|n| (*n, true)).collect::<Vec<_>>());
976         }
977         self
978     }
979 
980     /// Adds an [`ArgGroup`] to the application. [`ArgGroup`]s are a family of related arguments.
981     /// By placing them in a logical group, you can build easier requirement and exclusion rules.
982     /// For instance, you can make an entire [`ArgGroup`] required, meaning that one (and *only*
983     /// one) argument from that group must be present at runtime.
984     ///
985     /// You can also do things such as name an [`ArgGroup`] as a conflict to another argument.
986     /// Meaning any of the arguments that belong to that group will cause a failure if present with
987     /// the conflicting argument.
988     ///
989     /// Another added benefit of [`ArgGroup`]s is that you can extract a value from a group instead
990     /// of determining exactly which argument was used.
991     ///
992     /// Finally, using [`ArgGroup`]s to ensure exclusion between arguments is another very common
993     /// use
994     ///
995     /// # Examples
996     ///
997     /// The following example demonstrates using an [`ArgGroup`] to ensure that one, and only one,
998     /// of the arguments from the specified group is present at runtime.
999     ///
1000     /// ```no_run
1001     /// # use clap::{App, ArgGroup};
1002     /// App::new("app")
1003     ///     .args_from_usage(
1004     ///         "--set-ver [ver] 'set the version manually'
1005     ///          --major         'auto increase major'
1006     ///          --minor         'auto increase minor'
1007     ///          --patch         'auto increase patch'")
1008     ///     .group(ArgGroup::with_name("vers")
1009     ///          .args(&["set-ver", "major", "minor","patch"])
1010     ///          .required(true))
1011     /// # ;
1012     /// ```
1013     /// [`ArgGroup`]: ./struct.ArgGroup.html
group(mut self, group: ArgGroup<'a>) -> Self1014     pub fn group(mut self, group: ArgGroup<'a>) -> Self {
1015         self.p.add_group(group);
1016         self
1017     }
1018 
1019     /// Adds multiple [`ArgGroup`]s to the [`App`] at once.
1020     ///
1021     /// # Examples
1022     ///
1023     /// ```no_run
1024     /// # use clap::{App, ArgGroup};
1025     /// App::new("app")
1026     ///     .args_from_usage(
1027     ///         "--set-ver [ver] 'set the version manually'
1028     ///          --major         'auto increase major'
1029     ///          --minor         'auto increase minor'
1030     ///          --patch         'auto increase patch'
1031     ///          -c [FILE]       'a config file'
1032     ///          -i [IFACE]      'an interface'")
1033     ///     .groups(&[
1034     ///         ArgGroup::with_name("vers")
1035     ///             .args(&["set-ver", "major", "minor","patch"])
1036     ///             .required(true),
1037     ///         ArgGroup::with_name("input")
1038     ///             .args(&["c", "i"])
1039     ///     ])
1040     /// # ;
1041     /// ```
1042     /// [`ArgGroup`]: ./struct.ArgGroup.html
1043     /// [`App`]: ./struct.App.html
groups(mut self, groups: &[ArgGroup<'a>]) -> Self1044     pub fn groups(mut self, groups: &[ArgGroup<'a>]) -> Self {
1045         for g in groups {
1046             self = self.group(g.into());
1047         }
1048         self
1049     }
1050 
1051     /// Adds a [`SubCommand`] to the list of valid possibilities. Subcommands are effectively
1052     /// sub-[`App`]s, because they can contain their own arguments, subcommands, version, usage,
1053     /// etc. They also function just like [`App`]s, in that they get their own auto generated help,
1054     /// version, and usage.
1055     ///
1056     /// # Examples
1057     ///
1058     /// ```no_run
1059     /// # use clap::{App, Arg, SubCommand};
1060     /// App::new("myprog")
1061     ///     .subcommand(SubCommand::with_name("config")
1062     ///         .about("Controls configuration features")
1063     ///         .arg_from_usage("<config> 'Required configuration file to use'"))
1064     /// # ;
1065     /// ```
1066     /// [`SubCommand`]: ./struct.SubCommand.html
1067     /// [`App`]: ./struct.App.html
subcommand(mut self, subcmd: App<'a, 'b>) -> Self1068     pub fn subcommand(mut self, subcmd: App<'a, 'b>) -> Self {
1069         self.p.add_subcommand(subcmd);
1070         self
1071     }
1072 
1073     /// Adds multiple subcommands to the list of valid possibilities by iterating over an
1074     /// [`IntoIterator`] of [`SubCommand`]s
1075     ///
1076     /// # Examples
1077     ///
1078     /// ```rust
1079     /// # use clap::{App, Arg, SubCommand};
1080     /// # App::new("myprog")
1081     /// .subcommands( vec![
1082     ///        SubCommand::with_name("config").about("Controls configuration functionality")
1083     ///                                 .arg(Arg::with_name("config_file").index(1)),
1084     ///        SubCommand::with_name("debug").about("Controls debug functionality")])
1085     /// # ;
1086     /// ```
1087     /// [`SubCommand`]: ./struct.SubCommand.html
1088     /// [`IntoIterator`]: https://doc.rust-lang.org/std/iter/trait.IntoIterator.html
subcommands<I>(mut self, subcmds: I) -> Self where I: IntoIterator<Item = App<'a, 'b>>,1089     pub fn subcommands<I>(mut self, subcmds: I) -> Self
1090     where
1091         I: IntoIterator<Item = App<'a, 'b>>,
1092     {
1093         for subcmd in subcmds {
1094             self.p.add_subcommand(subcmd);
1095         }
1096         self
1097     }
1098 
1099     /// Allows custom ordering of [`SubCommand`]s within the help message. Subcommands with a lower
1100     /// value will be displayed first in the help message. This is helpful when one would like to
1101     /// emphasise frequently used subcommands, or prioritize those towards the top of the list.
1102     /// Duplicate values **are** allowed. Subcommands with duplicate display orders will be
1103     /// displayed in alphabetical order.
1104     ///
1105     /// **NOTE:** The default is 999 for all subcommands.
1106     ///
1107     /// # Examples
1108     ///
1109     /// ```rust
1110     /// # use clap::{App, SubCommand};
1111     /// let m = App::new("cust-ord")
1112     ///     .subcommand(SubCommand::with_name("alpha") // typically subcommands are grouped
1113     ///                                                // alphabetically by name. Subcommands
1114     ///                                                // without a display_order have a value of
1115     ///                                                // 999 and are displayed alphabetically with
1116     ///                                                // all other 999 subcommands
1117     ///         .about("Some help and text"))
1118     ///     .subcommand(SubCommand::with_name("beta")
1119     ///         .display_order(1)   // In order to force this subcommand to appear *first*
1120     ///                             // all we have to do is give it a value lower than 999.
1121     ///                             // Any other subcommands with a value of 1 will be displayed
1122     ///                             // alphabetically with this one...then 2 values, then 3, etc.
1123     ///         .about("I should be first!"))
1124     ///     .get_matches_from(vec![
1125     ///         "cust-ord", "--help"
1126     ///     ]);
1127     /// ```
1128     ///
1129     /// The above example displays the following help message
1130     ///
1131     /// ```text
1132     /// cust-ord
1133     ///
1134     /// USAGE:
1135     ///     cust-ord [FLAGS] [OPTIONS]
1136     ///
1137     /// FLAGS:
1138     ///     -h, --help       Prints help information
1139     ///     -V, --version    Prints version information
1140     ///
1141     /// SUBCOMMANDS:
1142     ///     beta    I should be first!
1143     ///     alpha   Some help and text
1144     /// ```
1145     /// [`SubCommand`]: ./struct.SubCommand.html
display_order(mut self, ord: usize) -> Self1146     pub fn display_order(mut self, ord: usize) -> Self {
1147         self.p.meta.disp_ord = ord;
1148         self
1149     }
1150 
1151     /// Prints the full help message to [`io::stdout()`] using a [`BufWriter`] using the same
1152     /// method as if someone ran `-h` to request the help message
1153     ///
1154     /// **NOTE:** clap has the ability to distinguish between "short" and "long" help messages
1155     /// depending on if the user ran [`-h` (short)] or [`--help` (long)]
1156     ///
1157     /// # Examples
1158     ///
1159     /// ```rust
1160     /// # use clap::App;
1161     /// let mut app = App::new("myprog");
1162     /// app.print_help();
1163     /// ```
1164     /// [`io::stdout()`]: https://doc.rust-lang.org/std/io/fn.stdout.html
1165     /// [`BufWriter`]: https://doc.rust-lang.org/std/io/struct.BufWriter.html
1166     /// [`-h` (short)]: ./struct.Arg.html#method.help
1167     /// [`--help` (long)]: ./struct.Arg.html#method.long_help
print_help(&mut self) -> ClapResult<()>1168     pub fn print_help(&mut self) -> ClapResult<()> {
1169         // If there are global arguments, or settings we need to propagate them down to subcommands
1170         // before parsing incase we run into a subcommand
1171         self.p.propagate_globals();
1172         self.p.propagate_settings();
1173         self.p.derive_display_order();
1174 
1175         self.p.create_help_and_version();
1176         let out = io::stdout();
1177         let mut buf_w = BufWriter::new(out.lock());
1178         self.write_help(&mut buf_w)
1179     }
1180 
1181     /// Prints the full help message to [`io::stdout()`] using a [`BufWriter`] using the same
1182     /// method as if someone ran `--help` to request the help message
1183     ///
1184     /// **NOTE:** clap has the ability to distinguish between "short" and "long" help messages
1185     /// depending on if the user ran [`-h` (short)] or [`--help` (long)]
1186     ///
1187     /// # Examples
1188     ///
1189     /// ```rust
1190     /// # use clap::App;
1191     /// let mut app = App::new("myprog");
1192     /// app.print_long_help();
1193     /// ```
1194     /// [`io::stdout()`]: https://doc.rust-lang.org/std/io/fn.stdout.html
1195     /// [`BufWriter`]: https://doc.rust-lang.org/std/io/struct.BufWriter.html
1196     /// [`-h` (short)]: ./struct.Arg.html#method.help
1197     /// [`--help` (long)]: ./struct.Arg.html#method.long_help
print_long_help(&mut self) -> ClapResult<()>1198     pub fn print_long_help(&mut self) -> ClapResult<()> {
1199         let out = io::stdout();
1200         let mut buf_w = BufWriter::new(out.lock());
1201         self.write_long_help(&mut buf_w)
1202     }
1203 
1204     /// Writes the full help message to the user to a [`io::Write`] object in the same method as if
1205     /// the user ran `-h`
1206     ///
1207     /// **NOTE:** clap has the ability to distinguish between "short" and "long" help messages
1208     /// depending on if the user ran [`-h` (short)] or [`--help` (long)]
1209     ///
1210     /// **NOTE:** There is a known bug where this method does not write propagated global arguments
1211     /// or autogenerated arguments (i.e. the default help/version args). Prefer
1212     /// [`App::write_long_help`] instead if possible!
1213     ///
1214     /// # Examples
1215     ///
1216     /// ```rust
1217     /// # use clap::App;
1218     /// use std::io;
1219     /// let mut app = App::new("myprog");
1220     /// let mut out = io::stdout();
1221     /// app.write_help(&mut out).expect("failed to write to stdout");
1222     /// ```
1223     /// [`io::Write`]: https://doc.rust-lang.org/std/io/trait.Write.html
1224     /// [`-h` (short)]: ./struct.Arg.html#method.help
1225     /// [`--help` (long)]: ./struct.Arg.html#method.long_help
write_help<W: Write>(&self, w: &mut W) -> ClapResult<()>1226     pub fn write_help<W: Write>(&self, w: &mut W) -> ClapResult<()> {
1227         // PENDING ISSUE: 808
1228         //      https://github.com/clap-rs/clap/issues/808
1229         // If there are global arguments, or settings we need to propagate them down to subcommands
1230         // before parsing incase we run into a subcommand
1231         // self.p.propagate_globals();
1232         // self.p.propagate_settings();
1233         // self.p.derive_display_order();
1234         // self.p.create_help_and_version();
1235 
1236         Help::write_app_help(w, self, false)
1237     }
1238 
1239     /// Writes the full help message to the user to a [`io::Write`] object in the same method as if
1240     /// the user ran `--help`
1241     ///
1242     /// **NOTE:** clap has the ability to distinguish between "short" and "long" help messages
1243     /// depending on if the user ran [`-h` (short)] or [`--help` (long)]
1244     ///
1245     /// # Examples
1246     ///
1247     /// ```rust
1248     /// # use clap::App;
1249     /// use std::io;
1250     /// let mut app = App::new("myprog");
1251     /// let mut out = io::stdout();
1252     /// app.write_long_help(&mut out).expect("failed to write to stdout");
1253     /// ```
1254     /// [`io::Write`]: https://doc.rust-lang.org/std/io/trait.Write.html
1255     /// [`-h` (short)]: ./struct.Arg.html#method.help
1256     /// [`--help` (long)]: ./struct.Arg.html#method.long_help
write_long_help<W: Write>(&mut self, w: &mut W) -> ClapResult<()>1257     pub fn write_long_help<W: Write>(&mut self, w: &mut W) -> ClapResult<()> {
1258         // If there are global arguments, or settings we need to propagate them down to subcommands
1259         // before parsing incase we run into a subcommand
1260         self.p.propagate_globals();
1261         self.p.propagate_settings();
1262         self.p.derive_display_order();
1263         self.p.create_help_and_version();
1264 
1265         Help::write_app_help(w, self, true)
1266     }
1267 
1268     /// Writes the version message to the user to a [`io::Write`] object as if the user ran `-V`.
1269     ///
1270     /// **NOTE:** clap has the ability to distinguish between "short" and "long" version messages
1271     /// depending on if the user ran [`-V` (short)] or [`--version` (long)]
1272     ///
1273     /// # Examples
1274     ///
1275     /// ```rust
1276     /// # use clap::App;
1277     /// use std::io;
1278     /// let mut app = App::new("myprog");
1279     /// let mut out = io::stdout();
1280     /// app.write_version(&mut out).expect("failed to write to stdout");
1281     /// ```
1282     /// [`io::Write`]: https://doc.rust-lang.org/std/io/trait.Write.html
1283     /// [`-V` (short)]: ./struct.App.html#method.version
1284     /// [`--version` (long)]: ./struct.App.html#method.long_version
write_version<W: Write>(&self, w: &mut W) -> ClapResult<()>1285     pub fn write_version<W: Write>(&self, w: &mut W) -> ClapResult<()> {
1286         self.p.write_version(w, false).map_err(From::from)
1287     }
1288 
1289     /// Writes the version message to the user to a [`io::Write`] object
1290     ///
1291     /// **NOTE:** clap has the ability to distinguish between "short" and "long" version messages
1292     /// depending on if the user ran [`-V` (short)] or [`--version` (long)]
1293     ///
1294     /// # Examples
1295     ///
1296     /// ```rust
1297     /// # use clap::App;
1298     /// use std::io;
1299     /// let mut app = App::new("myprog");
1300     /// let mut out = io::stdout();
1301     /// app.write_long_version(&mut out).expect("failed to write to stdout");
1302     /// ```
1303     /// [`io::Write`]: https://doc.rust-lang.org/std/io/trait.Write.html
1304     /// [`-V` (short)]: ./struct.App.html#method.version
1305     /// [`--version` (long)]: ./struct.App.html#method.long_version
write_long_version<W: Write>(&self, w: &mut W) -> ClapResult<()>1306     pub fn write_long_version<W: Write>(&self, w: &mut W) -> ClapResult<()> {
1307         self.p.write_version(w, true).map_err(From::from)
1308     }
1309 
1310     /// Generate a completions file for a specified shell at compile time.
1311     ///
1312     /// **NOTE:** to generate the file at compile time you must use a `build.rs` "Build Script"
1313     ///
1314     /// # Examples
1315     ///
1316     /// The following example generates a bash completion script via a `build.rs` script. In this
1317     /// simple example, we'll demo a very small application with only a single subcommand and two
1318     /// args. Real applications could be many multiple levels deep in subcommands, and have tens or
1319     /// potentially hundreds of arguments.
1320     ///
1321     /// First, it helps if we separate out our `App` definition into a separate file. Whether you
1322     /// do this as a function, or bare App definition is a matter of personal preference.
1323     ///
1324     /// ```
1325     /// // src/cli.rs
1326     ///
1327     /// use clap::{App, Arg, SubCommand};
1328     ///
1329     /// pub fn build_cli() -> App<'static, 'static> {
1330     ///     App::new("compl")
1331     ///         .about("Tests completions")
1332     ///         .arg(Arg::with_name("file")
1333     ///             .help("some input file"))
1334     ///         .subcommand(SubCommand::with_name("test")
1335     ///             .about("tests things")
1336     ///             .arg(Arg::with_name("case")
1337     ///                 .long("case")
1338     ///                 .takes_value(true)
1339     ///                 .help("the case to test")))
1340     /// }
1341     /// ```
1342     ///
1343     /// In our regular code, we can simply call this `build_cli()` function, then call
1344     /// `get_matches()`, or any of the other normal methods directly after. For example:
1345     ///
1346     /// ```ignore
1347     /// // src/main.rs
1348     ///
1349     /// mod cli;
1350     ///
1351     /// fn main() {
1352     ///     let m = cli::build_cli().get_matches();
1353     ///
1354     ///     // normal logic continues...
1355     /// }
1356     /// ```
1357     ///
1358     /// Next, we set up our `Cargo.toml` to use a `build.rs` build script.
1359     ///
1360     /// ```toml
1361     /// # Cargo.toml
1362     /// build = "build.rs"
1363     ///
1364     /// [build-dependencies]
1365     /// clap = "2.23"
1366     /// ```
1367     ///
1368     /// Next, we place a `build.rs` in our project root.
1369     ///
1370     /// ```ignore
1371     /// extern crate clap;
1372     ///
1373     /// use clap::Shell;
1374     ///
1375     /// include!("src/cli.rs");
1376     ///
1377     /// fn main() {
1378     ///     let outdir = match env::var_os("OUT_DIR") {
1379     ///         None => return,
1380     ///         Some(outdir) => outdir,
1381     ///     };
1382     ///     let mut app = build_cli();
1383     ///     app.gen_completions("myapp",      // We need to specify the bin name manually
1384     ///                         Shell::Bash,  // Then say which shell to build completions for
1385     ///                         outdir);      // Then say where write the completions to
1386     /// }
1387     /// ```
1388     /// Now, once we compile there will be a `{bin_name}.bash` file in the directory.
1389     /// Assuming we compiled with debug mode, it would be somewhere similar to
1390     /// `<project>/target/debug/build/myapp-<hash>/out/myapp.bash`.
1391     ///
1392     /// Fish shell completions will use the file format `{bin_name}.fish`
gen_completions<T: Into<OsString>, S: Into<String>>( &mut self, bin_name: S, for_shell: Shell, out_dir: T, )1393     pub fn gen_completions<T: Into<OsString>, S: Into<String>>(
1394         &mut self,
1395         bin_name: S,
1396         for_shell: Shell,
1397         out_dir: T,
1398     ) {
1399         self.p.meta.bin_name = Some(bin_name.into());
1400         self.p.gen_completions(for_shell, out_dir.into());
1401     }
1402 
1403     /// Generate a completions file for a specified shell at runtime.  Until `cargo install` can
1404     /// install extra files like a completion script, this may be used e.g. in a command that
1405     /// outputs the contents of the completion script, to be redirected into a file by the user.
1406     ///
1407     /// # Examples
1408     ///
1409     /// Assuming a separate `cli.rs` like the [example above](./struct.App.html#method.gen_completions),
1410     /// we can let users generate a completion script using a command:
1411     ///
1412     /// ```ignore
1413     /// // src/main.rs
1414     ///
1415     /// mod cli;
1416     /// use std::io;
1417     ///
1418     /// fn main() {
1419     ///     let matches = cli::build_cli().get_matches();
1420     ///
1421     ///     if matches.is_present("generate-bash-completions") {
1422     ///         cli::build_cli().gen_completions_to("myapp", Shell::Bash, &mut io::stdout());
1423     ///     }
1424     ///
1425     ///     // normal logic continues...
1426     /// }
1427     ///
1428     /// ```
1429     ///
1430     /// Usage:
1431     ///
1432     /// ```shell
1433     /// $ myapp generate-bash-completions > /usr/share/bash-completion/completions/myapp.bash
1434     /// ```
gen_completions_to<W: Write, S: Into<String>>( &mut self, bin_name: S, for_shell: Shell, buf: &mut W, )1435     pub fn gen_completions_to<W: Write, S: Into<String>>(
1436         &mut self,
1437         bin_name: S,
1438         for_shell: Shell,
1439         buf: &mut W,
1440     ) {
1441         self.p.meta.bin_name = Some(bin_name.into());
1442         self.p.gen_completions_to(for_shell, buf);
1443     }
1444 
1445     /// Starts the parsing process, upon a failed parse an error will be displayed to the user and
1446     /// the process will exit with the appropriate error code. By default this method gets all user
1447     /// provided arguments from [`env::args_os`] in order to allow for invalid UTF-8 code points,
1448     /// which are legal on many platforms.
1449     ///
1450     /// # Examples
1451     ///
1452     /// ```no_run
1453     /// # use clap::{App, Arg};
1454     /// let matches = App::new("myprog")
1455     ///     // Args and options go here...
1456     ///     .get_matches();
1457     /// ```
1458     /// [`env::args_os`]: https://doc.rust-lang.org/std/env/fn.args_os.html
get_matches(self) -> ArgMatches<'a>1459     pub fn get_matches(self) -> ArgMatches<'a> {
1460         self.get_matches_from(&mut env::args_os())
1461     }
1462 
1463     /// Starts the parsing process. This method will return a [`clap::Result`] type instead of exiting
1464     /// the process on failed parse. By default this method gets matches from [`env::args_os`]
1465     ///
1466     /// **NOTE:** This method WILL NOT exit when `--help` or `--version` (or short versions) are
1467     /// used. It will return a [`clap::Error`], where the [`kind`] is a
1468     /// [`ErrorKind::HelpDisplayed`] or [`ErrorKind::VersionDisplayed`] respectively. You must call
1469     /// [`Error::exit`] or perform a [`std::process::exit`].
1470     ///
1471     /// # Examples
1472     ///
1473     /// ```no_run
1474     /// # use clap::{App, Arg};
1475     /// let matches = App::new("myprog")
1476     ///     // Args and options go here...
1477     ///     .get_matches_safe()
1478     ///     .unwrap_or_else( |e| e.exit() );
1479     /// ```
1480     /// [`env::args_os`]: https://doc.rust-lang.org/std/env/fn.args_os.html
1481     /// [`ErrorKind::HelpDisplayed`]: ./enum.ErrorKind.html#variant.HelpDisplayed
1482     /// [`ErrorKind::VersionDisplayed`]: ./enum.ErrorKind.html#variant.VersionDisplayed
1483     /// [`Error::exit`]: ./struct.Error.html#method.exit
1484     /// [`std::process::exit`]: https://doc.rust-lang.org/std/process/fn.exit.html
1485     /// [`clap::Result`]: ./type.Result.html
1486     /// [`clap::Error`]: ./struct.Error.html
1487     /// [`kind`]: ./struct.Error.html
get_matches_safe(self) -> ClapResult<ArgMatches<'a>>1488     pub fn get_matches_safe(self) -> ClapResult<ArgMatches<'a>> {
1489         // Start the parsing
1490         self.get_matches_from_safe(&mut env::args_os())
1491     }
1492 
1493     /// Starts the parsing process. Like [`App::get_matches`] this method does not return a [`clap::Result`]
1494     /// and will automatically exit with an error message. This method, however, lets you specify
1495     /// what iterator to use when performing matches, such as a [`Vec`] of your making.
1496     ///
1497     /// **NOTE:** The first argument will be parsed as the binary name unless
1498     /// [`AppSettings::NoBinaryName`] is used
1499     ///
1500     /// # Examples
1501     ///
1502     /// ```no_run
1503     /// # use clap::{App, Arg};
1504     /// let arg_vec = vec!["my_prog", "some", "args", "to", "parse"];
1505     ///
1506     /// let matches = App::new("myprog")
1507     ///     // Args and options go here...
1508     ///     .get_matches_from(arg_vec);
1509     /// ```
1510     /// [`App::get_matches`]: ./struct.App.html#method.get_matches
1511     /// [`clap::Result`]: ./type.Result.html
1512     /// [`Vec`]: https://doc.rust-lang.org/std/vec/struct.Vec.html
1513     /// [`AppSettings::NoBinaryName`]: ./enum.AppSettings.html#variant.NoBinaryName
get_matches_from<I, T>(mut self, itr: I) -> ArgMatches<'a> where I: IntoIterator<Item = T>, T: Into<OsString> + Clone,1514     pub fn get_matches_from<I, T>(mut self, itr: I) -> ArgMatches<'a>
1515     where
1516         I: IntoIterator<Item = T>,
1517         T: Into<OsString> + Clone,
1518     {
1519         self.get_matches_from_safe_borrow(itr).unwrap_or_else(|e| {
1520             // Otherwise, write to stderr and exit
1521             if e.use_stderr() {
1522                 wlnerr!("{}", e.message);
1523                 if self.p.is_set(AppSettings::WaitOnError) {
1524                     wlnerr!("\nPress [ENTER] / [RETURN] to continue...");
1525                     let mut s = String::new();
1526                     let i = io::stdin();
1527                     i.lock().read_line(&mut s).unwrap();
1528                 }
1529                 drop(self);
1530                 drop(e);
1531                 process::exit(1);
1532             }
1533 
1534             drop(self);
1535             e.exit()
1536         })
1537     }
1538 
1539     /// Starts the parsing process. A combination of [`App::get_matches_from`], and
1540     /// [`App::get_matches_safe`]
1541     ///
1542     /// **NOTE:** This method WILL NOT exit when `--help` or `--version` (or short versions) are
1543     /// used. It will return a [`clap::Error`], where the [`kind`] is a [`ErrorKind::HelpDisplayed`]
1544     /// or [`ErrorKind::VersionDisplayed`] respectively. You must call [`Error::exit`] or
1545     /// perform a [`std::process::exit`] yourself.
1546     ///
1547     /// **NOTE:** The first argument will be parsed as the binary name unless
1548     /// [`AppSettings::NoBinaryName`] is used
1549     ///
1550     /// # Examples
1551     ///
1552     /// ```no_run
1553     /// # use clap::{App, Arg};
1554     /// let arg_vec = vec!["my_prog", "some", "args", "to", "parse"];
1555     ///
1556     /// let matches = App::new("myprog")
1557     ///     // Args and options go here...
1558     ///     .get_matches_from_safe(arg_vec)
1559     ///     .unwrap_or_else( |e| { panic!("An error occurs: {}", e) });
1560     /// ```
1561     /// [`App::get_matches_from`]: ./struct.App.html#method.get_matches_from
1562     /// [`App::get_matches_safe`]: ./struct.App.html#method.get_matches_safe
1563     /// [`ErrorKind::HelpDisplayed`]: ./enum.ErrorKind.html#variant.HelpDisplayed
1564     /// [`ErrorKind::VersionDisplayed`]: ./enum.ErrorKind.html#variant.VersionDisplayed
1565     /// [`Error::exit`]: ./struct.Error.html#method.exit
1566     /// [`std::process::exit`]: https://doc.rust-lang.org/std/process/fn.exit.html
1567     /// [`clap::Error`]: ./struct.Error.html
1568     /// [`Error::exit`]: ./struct.Error.html#method.exit
1569     /// [`kind`]: ./struct.Error.html
1570     /// [`AppSettings::NoBinaryName`]: ./enum.AppSettings.html#variant.NoBinaryName
get_matches_from_safe<I, T>(mut self, itr: I) -> ClapResult<ArgMatches<'a>> where I: IntoIterator<Item = T>, T: Into<OsString> + Clone,1571     pub fn get_matches_from_safe<I, T>(mut self, itr: I) -> ClapResult<ArgMatches<'a>>
1572     where
1573         I: IntoIterator<Item = T>,
1574         T: Into<OsString> + Clone,
1575     {
1576         self.get_matches_from_safe_borrow(itr)
1577     }
1578 
1579     /// Starts the parsing process without consuming the [`App`] struct `self`. This is normally not
1580     /// the desired functionality, instead prefer [`App::get_matches_from_safe`] which *does*
1581     /// consume `self`.
1582     ///
1583     /// **NOTE:** The first argument will be parsed as the binary name unless
1584     /// [`AppSettings::NoBinaryName`] is used
1585     ///
1586     /// # Examples
1587     ///
1588     /// ```no_run
1589     /// # use clap::{App, Arg};
1590     /// let arg_vec = vec!["my_prog", "some", "args", "to", "parse"];
1591     ///
1592     /// let mut app = App::new("myprog");
1593     ///     // Args and options go here...
1594     /// let matches = app.get_matches_from_safe_borrow(arg_vec)
1595     ///     .unwrap_or_else( |e| { panic!("An error occurs: {}", e) });
1596     /// ```
1597     /// [`App`]: ./struct.App.html
1598     /// [`App::get_matches_from_safe`]: ./struct.App.html#method.get_matches_from_safe
1599     /// [`AppSettings::NoBinaryName`]: ./enum.AppSettings.html#variant.NoBinaryName
get_matches_from_safe_borrow<I, T>(&mut self, itr: I) -> ClapResult<ArgMatches<'a>> where I: IntoIterator<Item = T>, T: Into<OsString> + Clone,1600     pub fn get_matches_from_safe_borrow<I, T>(&mut self, itr: I) -> ClapResult<ArgMatches<'a>>
1601     where
1602         I: IntoIterator<Item = T>,
1603         T: Into<OsString> + Clone,
1604     {
1605         // If there are global arguments, or settings we need to propagate them down to subcommands
1606         // before parsing incase we run into a subcommand
1607         if !self.p.is_set(AppSettings::Propagated) {
1608             self.p.propagate_globals();
1609             self.p.propagate_settings();
1610             self.p.derive_display_order();
1611             self.p.set(AppSettings::Propagated);
1612         }
1613 
1614         let mut matcher = ArgMatcher::new();
1615 
1616         let mut it = itr.into_iter();
1617         // Get the name of the program (argument 1 of env::args()) and determine the
1618         // actual file
1619         // that was used to execute the program. This is because a program called
1620         // ./target/release/my_prog -a
1621         // will have two arguments, './target/release/my_prog', '-a' but we don't want
1622         // to display
1623         // the full path when displaying help messages and such
1624         if !self.p.is_set(AppSettings::NoBinaryName) {
1625             if let Some(name) = it.next() {
1626                 let bn_os = name.into();
1627                 let p = Path::new(&*bn_os);
1628                 if let Some(f) = p.file_name() {
1629                     if let Some(s) = f.to_os_string().to_str() {
1630                         if self.p.meta.bin_name.is_none() {
1631                             self.p.meta.bin_name = Some(s.to_owned());
1632                         }
1633                     }
1634                 }
1635             }
1636         }
1637 
1638         // do the real parsing
1639         if let Err(e) = self.p.get_matches_with(&mut matcher, &mut it.peekable()) {
1640             return Err(e);
1641         }
1642 
1643         let global_arg_vec: Vec<&str> = (&self).p.global_args.iter().map(|ga| ga.b.name).collect();
1644         matcher.propagate_globals(&global_arg_vec);
1645 
1646         Ok(matcher.into())
1647     }
1648 }
1649 
1650 #[cfg(feature = "yaml")]
1651 impl<'a> From<&'a Yaml> for App<'a, 'a> {
from(mut yaml: &'a Yaml) -> Self1652     fn from(mut yaml: &'a Yaml) -> Self {
1653         use args::SubCommand;
1654         // We WANT this to panic on error...so expect() is good.
1655         let mut is_sc = None;
1656         let mut a = if let Some(name) = yaml["name"].as_str() {
1657             App::new(name)
1658         } else {
1659             let yaml_hash = yaml.as_hash().unwrap();
1660             let sc_key = yaml_hash.keys().nth(0).unwrap();
1661             is_sc = Some(yaml_hash.get(sc_key).unwrap());
1662             App::new(sc_key.as_str().unwrap())
1663         };
1664         yaml = if let Some(sc) = is_sc { sc } else { yaml };
1665 
1666         macro_rules! yaml_str {
1667             ($a:ident, $y:ident, $i:ident) => {
1668                 if let Some(v) = $y[stringify!($i)].as_str() {
1669                     $a = $a.$i(v);
1670                 } else if $y[stringify!($i)] != Yaml::BadValue {
1671                     panic!(
1672                         "Failed to convert YAML value {:?} to a string",
1673                         $y[stringify!($i)]
1674                     );
1675                 }
1676             };
1677         }
1678 
1679         yaml_str!(a, yaml, version);
1680         yaml_str!(a, yaml, long_version);
1681         yaml_str!(a, yaml, author);
1682         yaml_str!(a, yaml, bin_name);
1683         yaml_str!(a, yaml, about);
1684         yaml_str!(a, yaml, long_about);
1685         yaml_str!(a, yaml, before_help);
1686         yaml_str!(a, yaml, after_help);
1687         yaml_str!(a, yaml, template);
1688         yaml_str!(a, yaml, usage);
1689         yaml_str!(a, yaml, help);
1690         yaml_str!(a, yaml, help_short);
1691         yaml_str!(a, yaml, version_short);
1692         yaml_str!(a, yaml, help_message);
1693         yaml_str!(a, yaml, version_message);
1694         yaml_str!(a, yaml, alias);
1695         yaml_str!(a, yaml, visible_alias);
1696 
1697         if let Some(v) = yaml["display_order"].as_i64() {
1698             a = a.display_order(v as usize);
1699         } else if yaml["display_order"] != Yaml::BadValue {
1700             panic!(
1701                 "Failed to convert YAML value {:?} to a u64",
1702                 yaml["display_order"]
1703             );
1704         }
1705         if let Some(v) = yaml["setting"].as_str() {
1706             a = a.setting(v.parse().expect("unknown AppSetting found in YAML file"));
1707         } else if yaml["setting"] != Yaml::BadValue {
1708             panic!(
1709                 "Failed to convert YAML value {:?} to an AppSetting",
1710                 yaml["setting"]
1711             );
1712         }
1713         if let Some(v) = yaml["settings"].as_vec() {
1714             for ys in v {
1715                 if let Some(s) = ys.as_str() {
1716                     a = a.setting(s.parse().expect("unknown AppSetting found in YAML file"));
1717                 }
1718             }
1719         } else if let Some(v) = yaml["settings"].as_str() {
1720             a = a.setting(v.parse().expect("unknown AppSetting found in YAML file"));
1721         } else if yaml["settings"] != Yaml::BadValue {
1722             panic!(
1723                 "Failed to convert YAML value {:?} to a string",
1724                 yaml["settings"]
1725             );
1726         }
1727         if let Some(v) = yaml["global_setting"].as_str() {
1728             a = a.setting(v.parse().expect("unknown AppSetting found in YAML file"));
1729         } else if yaml["global_setting"] != Yaml::BadValue {
1730             panic!(
1731                 "Failed to convert YAML value {:?} to an AppSetting",
1732                 yaml["setting"]
1733             );
1734         }
1735         if let Some(v) = yaml["global_settings"].as_vec() {
1736             for ys in v {
1737                 if let Some(s) = ys.as_str() {
1738                     a = a.global_setting(s.parse().expect("unknown AppSetting found in YAML file"));
1739                 }
1740             }
1741         } else if let Some(v) = yaml["global_settings"].as_str() {
1742             a = a.global_setting(v.parse().expect("unknown AppSetting found in YAML file"));
1743         } else if yaml["global_settings"] != Yaml::BadValue {
1744             panic!(
1745                 "Failed to convert YAML value {:?} to a string",
1746                 yaml["global_settings"]
1747             );
1748         }
1749 
1750         macro_rules! vec_or_str {
1751             ($a:ident, $y:ident, $as_vec:ident, $as_single:ident) => {{
1752                 let maybe_vec = $y[stringify!($as_vec)].as_vec();
1753                 if let Some(vec) = maybe_vec {
1754                     for ys in vec {
1755                         if let Some(s) = ys.as_str() {
1756                             $a = $a.$as_single(s);
1757                         } else {
1758                             panic!("Failed to convert YAML value {:?} to a string", ys);
1759                         }
1760                     }
1761                 } else {
1762                     if let Some(s) = $y[stringify!($as_vec)].as_str() {
1763                         $a = $a.$as_single(s);
1764                     } else if $y[stringify!($as_vec)] != Yaml::BadValue {
1765                         panic!(
1766                             "Failed to convert YAML value {:?} to either a vec or string",
1767                             $y[stringify!($as_vec)]
1768                         );
1769                     }
1770                 }
1771                 $a
1772             }};
1773         }
1774 
1775         a = vec_or_str!(a, yaml, aliases, alias);
1776         a = vec_or_str!(a, yaml, visible_aliases, visible_alias);
1777 
1778         if let Some(v) = yaml["args"].as_vec() {
1779             for arg_yaml in v {
1780                 a = a.arg(Arg::from_yaml(arg_yaml.as_hash().unwrap()));
1781             }
1782         }
1783         if let Some(v) = yaml["subcommands"].as_vec() {
1784             for sc_yaml in v {
1785                 a = a.subcommand(SubCommand::from_yaml(sc_yaml));
1786             }
1787         }
1788         if let Some(v) = yaml["groups"].as_vec() {
1789             for ag_yaml in v {
1790                 a = a.group(ArgGroup::from(ag_yaml.as_hash().unwrap()));
1791             }
1792         }
1793 
1794         a
1795     }
1796 }
1797 
1798 impl<'a, 'b> Clone for App<'a, 'b> {
clone(&self) -> Self1799     fn clone(&self) -> Self {
1800         App { p: self.p.clone() }
1801     }
1802 }
1803 
1804 impl<'n, 'e> AnyArg<'n, 'e> for App<'n, 'e> {
name(&self) -> &'n str1805     fn name(&self) -> &'n str {
1806         ""
1807     }
overrides(&self) -> Option<&[&'e str]>1808     fn overrides(&self) -> Option<&[&'e str]> {
1809         None
1810     }
requires(&self) -> Option<&[(Option<&'e str>, &'n str)]>1811     fn requires(&self) -> Option<&[(Option<&'e str>, &'n str)]> {
1812         None
1813     }
blacklist(&self) -> Option<&[&'e str]>1814     fn blacklist(&self) -> Option<&[&'e str]> {
1815         None
1816     }
required_unless(&self) -> Option<&[&'e str]>1817     fn required_unless(&self) -> Option<&[&'e str]> {
1818         None
1819     }
val_names(&self) -> Option<&VecMap<&'e str>>1820     fn val_names(&self) -> Option<&VecMap<&'e str>> {
1821         None
1822     }
is_set(&self, _: ArgSettings) -> bool1823     fn is_set(&self, _: ArgSettings) -> bool {
1824         false
1825     }
val_terminator(&self) -> Option<&'e str>1826     fn val_terminator(&self) -> Option<&'e str> {
1827         None
1828     }
set(&mut self, _: ArgSettings)1829     fn set(&mut self, _: ArgSettings) {
1830         unreachable!("App struct does not support AnyArg::set, this is a bug!")
1831     }
has_switch(&self) -> bool1832     fn has_switch(&self) -> bool {
1833         false
1834     }
max_vals(&self) -> Option<u64>1835     fn max_vals(&self) -> Option<u64> {
1836         None
1837     }
num_vals(&self) -> Option<u64>1838     fn num_vals(&self) -> Option<u64> {
1839         None
1840     }
possible_vals(&self) -> Option<&[&'e str]>1841     fn possible_vals(&self) -> Option<&[&'e str]> {
1842         None
1843     }
validator(&self) -> Option<&Rc<Fn(String) -> StdResult<(), String>>>1844     fn validator(&self) -> Option<&Rc<Fn(String) -> StdResult<(), String>>> {
1845         None
1846     }
validator_os(&self) -> Option<&Rc<Fn(&OsStr) -> StdResult<(), OsString>>>1847     fn validator_os(&self) -> Option<&Rc<Fn(&OsStr) -> StdResult<(), OsString>>> {
1848         None
1849     }
min_vals(&self) -> Option<u64>1850     fn min_vals(&self) -> Option<u64> {
1851         None
1852     }
short(&self) -> Option<char>1853     fn short(&self) -> Option<char> {
1854         None
1855     }
long(&self) -> Option<&'e str>1856     fn long(&self) -> Option<&'e str> {
1857         None
1858     }
val_delim(&self) -> Option<char>1859     fn val_delim(&self) -> Option<char> {
1860         None
1861     }
takes_value(&self) -> bool1862     fn takes_value(&self) -> bool {
1863         true
1864     }
help(&self) -> Option<&'e str>1865     fn help(&self) -> Option<&'e str> {
1866         self.p.meta.about
1867     }
long_help(&self) -> Option<&'e str>1868     fn long_help(&self) -> Option<&'e str> {
1869         self.p.meta.long_about
1870     }
default_val(&self) -> Option<&'e OsStr>1871     fn default_val(&self) -> Option<&'e OsStr> {
1872         None
1873     }
default_vals_ifs(&self) -> Option<map::Values<(&'n str, Option<&'e OsStr>, &'e OsStr)>>1874     fn default_vals_ifs(&self) -> Option<map::Values<(&'n str, Option<&'e OsStr>, &'e OsStr)>> {
1875         None
1876     }
env<'s>(&'s self) -> Option<(&'n OsStr, Option<&'s OsString>)>1877     fn env<'s>(&'s self) -> Option<(&'n OsStr, Option<&'s OsString>)> {
1878         None
1879     }
longest_filter(&self) -> bool1880     fn longest_filter(&self) -> bool {
1881         true
1882     }
aliases(&self) -> Option<Vec<&'e str>>1883     fn aliases(&self) -> Option<Vec<&'e str>> {
1884         if let Some(ref aliases) = self.p.meta.aliases {
1885             let vis_aliases: Vec<_> = aliases
1886                 .iter()
1887                 .filter_map(|&(n, v)| if v { Some(n) } else { None })
1888                 .collect();
1889             if vis_aliases.is_empty() {
1890                 None
1891             } else {
1892                 Some(vis_aliases)
1893             }
1894         } else {
1895             None
1896         }
1897     }
1898 }
1899 
1900 impl<'n, 'e> fmt::Display for App<'n, 'e> {
fmt(&self, f: &mut fmt::Formatter) -> fmt::Result1901     fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
1902         write!(f, "{}", self.p.meta.name)
1903     }
1904 }
1905