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clap/src/app/mod.rs
Kevin K 7d2a2ed413 feat(Subcommands): adds support for custom ordering in help messages 
Allows custom ordering of subcommands within the help message. Subcommands with a lower
value will be displayed first in the help message. This is helpful when one would like to
emphasise frequently used subcommands, or prioritize those towards the top of the list.
Duplicate values **are** allowed. Subcommands with duplicate display orders will be
displayed in alphabetical order.

**NOTE:** The default is 999 for all subcommands.

```rust
use clap::{App, SubCommand};
let m = App::new("cust-ord")
    .subcommand(SubCommand::with_name("alpha") // typically subcommands are grouped
                                               // alphabetically by name. Subcommands
                                               // without a display_order have a value of
                                               // 999 and are displayed alphabetically with
                                               // all other 999 subcommands
        .about("Some help and text"))
    .subcommand(SubCommand::with_name("beta")
        .display_order(1)   // In order to force this subcommand to appear *first*
                            // all we have to do is give it a value lower than 999.
                            // Any other subcommands with a value of 1 will be displayed
                            // alphabetically with this one...then 2 values, then 3, etc.
        .about("I should be first!"))
    .get_matches_from(vec![
        "cust-ord", "--help"
    ]);
```

The above example displays the following help message

```
cust-ord

USAGE:
    cust-ord [FLAGS] [OPTIONS]

FLAGS:
    -h, --help       Prints help information
    -V, --version    Prints version information

SUBCOMMANDS:
    beta    I should be first!
    alpha   Some help and text
```

Closes #442
2016-03-09 19:43:53 -05:00

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#[allow(dead_code)]
mod settings;
#[macro_use]
mod macros;
mod parser;
mod meta;
pub use self::settings::AppSettings;
use std::env;
use std::io::{self, BufRead, BufWriter, Write};
use std::path::Path;
use std::process;
use std::ffi::OsString;
use std::borrow::Borrow;
#[cfg(feature = "yaml")]
use yaml_rust::Yaml;
use args::{Arg, AnyArg, ArgGroup, ArgMatches, ArgMatcher};
use app::parser::Parser;
use errors::Error;
use errors::Result as ClapResult;
/// Used to create a representation of a command line program and all possible command line
/// arguments. Application settings are set using the "builder pattern" with the
/// `.get_matches()` family of methods being the terminal methods that starts the runtime-parsing
/// process. These methods then return information about the user supplied arguments (or lack there
/// of).
///
/// **NOTE:** There aren't any mandatory "options" that one must set. The "options" may
/// also appear in any order (so long as one of the `App::get_matches*` methods is the last method
/// called).
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// let m = App::new("My Program")
/// .author("Me, me@mail.com")
/// .version("1.0.2")
/// .about("Explains in brief what the program does")
/// .arg(
/// Arg::with_name("in_file").index(1)
/// )
/// .after_help("Longer explaination to appear after the options when \
/// displaying the help information from --help or -h")
/// .get_matches();
///
/// // Your program logic starts here...
/// ```
#[allow(missing_debug_implementations)]
pub struct App<'a, 'b> where 'a: 'b {
#[doc(hidden)]
pub p: Parser<'a, 'b>
}
impl<'a, 'b> App<'a, 'b> {
/// Creates a new instance of an application requiring a name. The name may be, but doesn't
/// have to be same as the binary. The name will be displayed to the user when they request to
/// print version or help and usage information.
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// let prog = App::new("My Program")
/// # ;
/// ```
pub fn new<S: Into<String>>(n: S) -> Self { App { p: Parser::with_name(n.into()) } }
/// Creates a new instace of `App` from a .yml (YAML) file. A full example of supported YAML
/// objects can be found in `examples/17_yaml.rs` and `examples/17_yaml.yml`. One great use for
/// using YAML is when supporting multiple languages and dialects, as each language could be a
/// distinct YAML file and determined at compiletime via `cargo` "features" in your
/// `Cargo.toml`
///
/// In order to use this function you must compile `clap` with the `features = ["yaml"]` in
/// your settings for the `[dependencies.clap]` table of your `Cargo.toml`
///
/// **NOTE:** Due to how the YAML objects are built there is a convienience macro for loading
/// the YAML file at compile time (relative to the current file, like modules work). That YAML
/// object can then be passed to this function.
///
/// # Panics
///
/// The YAML file must be properly formatted or this function will panic!(). A good way to
/// ensure this doesn't happen is to run your program with the `--help` switch. If this passes
/// without error, you needn't worry because the YAML is properly formatted.
///
/// # Examples
///
/// The following example shows how to load a properly formatted YAML file to build an instnace
/// of an `App` struct.
///
/// ```ignore
/// # use clap::App;
/// let yml = load_yaml!("app.yml");
/// let app = App::from_yaml(yml);
///
/// // continued logic goes here, such as `app.get_matches()` etc.
/// ```
#[cfg(feature = "yaml")]
pub fn from_yaml(yaml: &'a Yaml) -> App<'a, 'a> {
App::from(yaml)
}
/// Sets a string of author(s) that will be displayed to the user when they request the help
/// information with `--help` or `-h`.
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// App::new("myprog")
/// .author("Me, me@mymain.com")
/// # ;
/// ```
pub fn author<S: Into<&'b str>>(mut self, author: S) -> Self {
self.p.meta.author = Some(author.into());
self
}
/// Overrides the system-determined binary name. This should only be used when absolutely
/// neccessary, such as when the binary name for your application is misleading, or perhaps
/// *not* how the user should invoke your program.
///
/// **Pro-tip:** When building things such as third party `cargo` subcommands, this setting
/// **should** be used!
///
/// **NOTE:** This command **should not** be used for `SubCommand`s.
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// App::new("My Program")
/// .bin_name("my_binary")
/// # ;
/// ```
pub fn bin_name<S: Into<String>>(mut self, name: S) -> Self {
self.p.meta.bin_name = Some(name.into());
self
}
/// Sets a string describing what the program does. This will be displayed when displaying help
/// information.
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// App::new("myprog")
/// .about("Does really amazing things to great people")
/// # ;
/// ```
pub fn about<S: Into<&'b str>>(mut self, about: S) -> Self {
self.p.meta.about = Some(about.into());
self
}
/// Adds additional help information to be displayed in addition to auto-generated help. This
/// information is displayed **after** the auto-generated help information. This is often used
/// to describe how to use the arguments, or caveats to be noted.
///
/// # Examples
///
/// ```no_run
/// # use clap::App;
/// App::new("myprog")
/// .after_help("Does really amazing things to great people...but be careful with -R")
/// # ;
/// ```
pub fn after_help<S: Into<&'b str>>(mut self, help: S) -> Self {
self.p.meta.more_help = Some(help.into());
self
}
/// Sets a string of the version number to be displayed when displaying version or help
/// information.
///
/// **Pro-tip:** Use `clap`s convienience macro `crate_version!` to automatically set your
/// application's version to the same thing as your crate at compile time. See the `examples/`
/// directory for more information
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// App::new("myprog")
/// .version("v0.1.24")
/// # ;
/// ```
pub fn version<S: Into<&'b str>>(mut self, ver: S) -> Self {
self.p.meta.version = Some(ver.into());
self
}
/// Sets a custom usage string to override the auto-generated usage string.
///
/// This will be displayed to the user when errors are found in argument parsing, or when you
/// call `ArgMatches::usage`
///
/// **CAUTION:** Using this setting disables `clap`s "context-aware" usage strings. After this
/// setting is set, this will be the only usage string displayed to the user!
///
/// **NOTE:** You do not need to specify the "USAGE: \n\t" portion, as that will
/// still be applied by `clap`, you only need to specify the portion starting
/// with the binary name.
///
/// **NOTE:** This will not replace the entire help message, *only* the portion
/// showing the usage.
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// App::new("myprog")
/// .usage("myapp [-clDas] <some_file>")
/// # ;
/// ```
pub fn usage<S: Into<&'b str>>(mut self, usage: S) -> Self {
self.p.meta.usage_str = Some(usage.into());
self
}
/// Sets a custom help message and overrides the auto-generated one. This should only be used
/// when the auto-generated message does not suffice.
///
/// This will be displayed to the user when they use `--help` or `-h`
///
/// **NOTE:** This replaces the **entire** help message, so nothing will be auto-generated.
///
/// **NOTE:** This **only** replaces the help message for the current command, meaning if you
/// are using subcommands, those help messages will still be auto-generated unless you
/// specify a `.help()` for them as well.
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// App::new("myapp")
/// .help("myapp v1.0\n\
/// Does awesome things\n\
/// (C) me@mail.com\n\n\
///
/// USAGE: myapp <opts> <comamnd>\n\n\
///
/// Options:\n\
/// -h, --helpe Dispay this message\n\
/// -V, --version Display version info\n\
/// -s <stuff> Do something with stuff\n\
/// -v Be verbose\n\n\
///
/// Commmands:\n\
/// help Prints this message\n\
/// work Do some work")
/// # ;
/// ```
pub fn help<S: Into<&'b str>>(mut self, help: S) -> Self {
self.p.meta.help_str = Some(help.into());
self
}
/// Sets the short version of the `help` argument without the preceding `-`.
///
/// By default `clap` automatically assigns `h`, but this can be overridden by defining your
/// own argument with a lowercase `h` as the `short`. `clap` lazily generates these help
/// arguments **after** you've defined any arguments of your own.
///
/// **NOTE:** Any leading `-` characters will be stripped, and only the first
/// non `-` chacter will be used as the `short` version
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// App::new("myprog")
/// .help_short("H") // Using an uppercase `H` instead of the default lowercase `h`
/// # ;
/// ```
pub fn help_short<S: AsRef<str> + 'b>(mut self, s: S) -> Self {
self.p.help_short(s.as_ref());
self
}
/// Sets the short version of the `version` argument without the preceding `-`.
///
/// By default `clap` automatically assigns `V`, but this can be overridden by defining your
/// own argument with a uppercase `V` as the `short`. `clap` lazily generates these version
/// arguments **after** you've defined any arguments of your own.
///
/// **NOTE:** Any leading `-` characters will be stripped, and only the first
/// non `-` chacter will be used as the `short` version
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// App::new("myprog")
/// .version_short("v") // Using a lowercase `v` instead of the default capital `V`
/// # ;
/// ```
pub fn version_short<S: AsRef<str>>(mut self, s: S) -> Self {
self.p.version_short(s.as_ref());
self
}
/// Enables a single Application level settings.
///
/// See `AppSettings` for a full list of possibilities and examples.
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg, AppSettings};
/// App::new("myprog")
/// .setting(AppSettings::SubcommandRequired)
/// .setting(AppSettings::WaitOnError)
/// # ;
/// ```
pub fn setting(mut self, setting: AppSettings) -> Self {
self.p.set(setting);
self
}
/// Enables multiple Application level settings
///
/// See `AppSettings` for a full list of possibilities and examples.
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg, AppSettings};
/// App::new("myprog")
/// .settings(&[AppSettings::SubcommandRequired,
/// AppSettings::WaitOnError])
/// # ;
/// ```
pub fn settings(mut self, settings: &[AppSettings]) -> Self {
for s in settings {
self.p.set(*s);
}
self
}
/// Adds an argument to the list of valid possibilties.
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// App::new("myprog")
/// // Adding a single "flag" argument with a short and help text, using Arg::with_name()
/// .arg(
/// Arg::with_name("debug")
/// .short("d")
/// .help("turns on debugging mode")
/// )
/// // Adding a single "option" argument with a short, a long, and help text using the less
/// // verbose Arg::from_usage()
/// .arg(
/// Arg::from_usage("-c --config=[CONFIG] 'Optionally sets a config file to use'")
/// )
/// # ;
/// ```
pub fn arg<A: Borrow<Arg<'a, 'b>> + 'a>(mut self, a: A) -> Self {
self.p.add_arg(a.borrow());
self
}
/// Adds multiple arguments to the list of valid possibilties
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// App::new("myprog")
/// .args(
/// &[Arg::from_usage("[debug] -d 'turns on debugging info'"),
/// Arg::with_name("input").index(1).help("the input file to use")]
/// )
/// # ;
/// ```
pub fn args(mut self, args: &[Arg<'a, 'b>]) -> Self {
for arg in args {
self.p.add_arg(arg);
}
self
}
/// A convienience method for adding a single argument from a usage type string. The string
/// used follows the same rules and syntax as `Arg::from_usage()`
///
/// **NOTE:** The downside to using this method is that you can not set any additional
/// properties of the `Arg` other than what `Arg::from_usage()` supports.
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// App::new("myprog")
/// .arg_from_usage("-c --config=<FILE> 'Sets a configuration file to use'")
/// # ;
/// ```
pub fn arg_from_usage(mut self, usage: &'a str) -> Self {
self.p.add_arg(&Arg::from_usage(usage));
self
}
/// Adds multiple arguments at once from a usage string, one per line. See `Arg::from_usage()`
/// for details on the syntax and rules supported.
///
/// **NOTE:** Like `App::arg_from_usage()` the downside is you only set properties for the
/// `Arg`s which `Arg::from_usage()` supports.
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// App::new("myprog")
/// .args_from_usage(
/// "-c --config=[FILE] 'Sets a configuration file to use'
/// [debug]... -d 'Sets the debugging level'
/// <FILE> 'The input file to use'"
/// )
/// # ;
/// ```
pub fn args_from_usage(mut self, usage: &'a str) -> Self {
for l in usage.lines() {
if l.len() == 0 { continue; }
self.p.add_arg(&Arg::from_usage(l.trim()));
}
self
}
/// Adds an `ArgGroup` to the application. `ArgGroup`s are a family of related arguments. By
/// placing them in a logical group, you can build easier requirement and exclusion rules. For
/// instance, you can make an entire `ArgGroup` required, meaning that one (and *only* one) argument
/// from that group must be present at runtime.
///
/// You can also do things such as name an `ArgGroup` as a conflict to another argument.
/// Meaning any of the arguments that belong to that group will cause a failure if present with
/// the conflicting argument.
///
/// Another added benfit of `ArgGroup`s is that you can extract a value from a group instead of
/// determining exactly which argument was used.
///
/// Finally, using `ArgGroup`s to ensure exclusion between arguments is another very common use
///
/// # Examples
///
/// The following example demonstrates using an `ArgGroup` to ensure that one, and only one, of
/// the arguments from the specified group is present at runtime.
///
/// ```no_run
/// # use clap::{App, ArgGroup};
/// App::new("app")
/// .args_from_usage(
/// "--set-ver [ver] 'set the version manually'
/// --major 'auto increase major'
/// --minor 'auto increase minor'
/// --patch 'auto increase patch'")
/// .group(ArgGroup::with_name("vers")
/// .args(&["set-ver", "major", "minor","patch"])
/// .required(true))
/// # ;
/// ```
pub fn group(mut self, group: ArgGroup<'a>) -> Self {
self.p.add_group(group);
self
}
/// Adds multiple `ArgGroup`s to the application at once.
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, ArgGroup};
/// App::new("app")
/// .args_from_usage(
/// "--set-ver [ver] 'set the version manually'
/// --major 'auto increase major'
/// --minor 'auto increase minor'
/// --patch 'auto increase patch'
/// -c [FILE] 'a config file'
/// -i [IFACE] 'an interface'")
/// .groups(&[
/// ArgGroup::with_name("vers")
/// .args(&["set-ver", "major", "minor","patch"])
/// .required(true),
/// ArgGroup::with_name("input")
/// .args(&["c", "i"])
/// ])
/// # ;
/// ```
pub fn groups(mut self, groups: &[ArgGroup<'a>]) -> Self {
for g in groups {
self = self.group(g.into());
}
self
}
/// Adds a subcommand to the list of valid possibilties. Subcommands are effectively sub-apps,
/// because they can contain their own arguments, subcommands, version, usage, etc. They also
/// function just like apps, in that they get their own auto generated help, version, and
/// usage.
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg, SubCommand};
/// App::new("myprog")
/// .subcommand(SubCommand::with_name("config")
/// .about("Controls configuration features")
/// .arg_from_usage("<config> 'Required configuration file to use'"))
/// # ;
/// ```
pub fn subcommand(mut self, subcmd: App<'a, 'b>) -> Self {
self.p.add_subcommand(subcmd);
self
}
/// Adds multiple subcommands to the list of valid possibilties by iterating over a Vec of
/// `SubCommand`s
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg, SubCommand};
/// # App::new("myprog")
/// .subcommands( vec![
/// SubCommand::with_name("config").about("Controls configuration functionality")
/// .arg(Arg::with_name("config_file").index(1)),
/// SubCommand::with_name("debug").about("Controls debug functionality")])
/// # ;
/// ```
pub fn subcommands<I>(mut self, subcmds: I) -> Self
where I: IntoIterator<Item = App<'a, 'b>>
{
for subcmd in subcmds.into_iter() {
self.p.add_subcommand(subcmd);
}
self
}
/// Allows custom ordering of subcommands within the help message. Subcommands with a lower
/// value will be displayed first in the help message. This is helpful when one would like to
/// emphasise frequently used subcommands, or prioritize those towards the top of the list.
/// Duplicate values **are** allowed. Subcommands with duplicate display orders will be
/// displayed in alphabetical order.
///
/// **NOTE:** The default is 999 for all subcommands.
///
/// # Examples
///
/// ```rust
/// # use clap::{App, SubCommand};
/// let m = App::new("cust-ord")
/// .subcommand(SubCommand::with_name("alpha") // typically subcommands are grouped
/// // alphabetically by name. Subcommands
/// // without a display_order have a value of
/// // 999 and are displayed alphabetically with
/// // all other 999 subcommands
/// .about("Some help and text"))
/// .subcommand(SubCommand::with_name("beta")
/// .display_order(1) // In order to force this subcommand to appear *first*
/// // all we have to do is give it a value lower than 999.
/// // Any other subcommands with a value of 1 will be displayed
/// // alphabetically with this one...then 2 values, then 3, etc.
/// .about("I should be first!"))
/// .get_matches_from(vec![
/// "cust-ord", "--help"
/// ]);
/// ```
///
/// The above example displays the following help message
///
/// ```ignore
/// cust-ord
///
/// USAGE:
/// cust-ord [FLAGS] [OPTIONS]
///
/// FLAGS:
/// -h, --help Prints help information
/// -V, --version Prints version information
///
/// SUBCOMMANDS:
/// beta I should be first!
/// alpha Some help and text
/// ```
pub fn display_order(mut self, ord: usize) -> Self {
self.p.meta.disp_ord = ord;
self
}
/// Prints the full help message to `io::stdout()` using a `BufWriter`
///
/// # Examples
///
/// ```no_run
/// # use clap::App;
/// let app = App::new("myprog");
/// app.print_help();
/// ```
pub fn print_help(&self) -> ClapResult<()> {
let out = io::stdout();
let mut buf_w = BufWriter::new(out.lock());
self.write_help(&mut buf_w)
}
/// Writes the full help message to the user to a `io::Write` object
///
/// # Examples
///
/// ```no_run
/// # use clap::App;
/// use std::io;
/// let mut app = App::new("myprog");
/// let mut out = io::stdout();
/// app.write_help(&mut out).ok().expect("failed to write to stdout");
/// ```
pub fn write_help<W: Write>(&self, w: &mut W) -> ClapResult<()> {
self.p.write_help(w)
}
/// Starts the parsing process, upon a failed parse an error will be displayed to the user and
/// the process with exit with the appropriate error code. By default this method gets matches
/// from `env::args_os`
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// let matches = App::new("myprog")
/// // Args and options go here...
/// .get_matches();
/// ```
pub fn get_matches(self) -> ArgMatches<'a> {
self.get_matches_from(&mut env::args_os())
}
/// Starts the parsing process. This method will return a `Result` type instead of exiting the
/// the process on failed parse. By default this method gets matches
/// from `env::args_os`
///
/// **NOTE:** This method WILL NOT exit when `--help` or `--version` (or short versions) are
/// used. It will return an error, where the `kind` is a `ErrorKind::HelpDisplayed`
/// or `ErrorKind::VersionDisplayed` respectively. You must call `error.exit()` or
/// perform a `std::process::exit`.
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// let matches = App::new("myprog")
/// // Args and options go here...
/// .get_matches_safe()
/// .unwrap_or_else( |e| e.exit() );
/// ```
pub fn get_matches_safe(self) -> ClapResult<ArgMatches<'a>> {
// Start the parsing
self.get_matches_from_safe(&mut env::args_os())
}
/// Starts the parsing process. Like `App::get_matches` this method does not return a `Result`
/// and will automatically exit with an error message. This method, however, lets you specify
/// what iterator to use when performing matches, such as a `Vec` of your making.
///
/// **NOTE:** The first argument will be parsed as the binary name unless
/// `AppSettings::NoBinaryName` is used
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// let arg_vec = vec!["my_prog", "some", "args", "to", "parse"];
///
/// let matches = App::new("myprog")
/// // Args and options go here...
/// .get_matches_from(arg_vec);
/// ```
pub fn get_matches_from<I, T>(mut self, itr: I) -> ArgMatches<'a>
where I: IntoIterator<Item = T>,
T: Into<OsString>
{
self.get_matches_from_safe_borrow(itr).unwrap_or_else(|e| {
// Otherwise, write to stderr and exit
self.maybe_wait_for_exit(e);
})
}
/// Starts the parsing process. A combination of `App::get_matches_from`, and
/// `App::get_matches_safe`
///
/// **NOTE:** This method WILL NOT exit when `--help` or `--version` (or short versions) are
/// used. It will return an error, where the `kind` is a `ErrorKind::HelpDisplayed`
/// or `ErrorKind::VersionDisplayed` respectively. You must call `error.exit()` or
/// perform a `std::process::exit` yourself.
///
/// **NOTE:** The first argument will be parsed as the binary name unless
/// `AppSettings::NoBinaryName` is used
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// let arg_vec = vec!["my_prog", "some", "args", "to", "parse"];
///
/// let matches = App::new("myprog")
/// // Args and options go here...
/// .get_matches_from_safe(arg_vec)
/// .unwrap_or_else( |e| { panic!("An error occurs: {}", e) });
/// ```
pub fn get_matches_from_safe<I, T>(mut self, itr: I) -> ClapResult<ArgMatches<'a>>
where I: IntoIterator<Item = T>,
T: Into<OsString>
{
self.get_matches_from_safe_borrow(itr)
}
/// Starts the parsing process without consuming the `App` struct `self`. This is normally not
/// the desired functionality, instead prefer `App::get_matches_from_safe` which *does*
/// consume `self`.
///
/// **NOTE:** The first argument will be parsed as the binary name unless
/// `AppSettings::NoBinaryName` is used
///
/// # Examples
///
/// ```no_run
/// # use clap::{App, Arg};
/// let arg_vec = vec!["my_prog", "some", "args", "to", "parse"];
///
/// let mut app = App::new("myprog");
/// // Args and options go here...
/// let matches = app.get_matches_from_safe_borrow(arg_vec)
/// .unwrap_or_else( |e| { panic!("An error occurs: {}", e) });
/// ```
pub fn get_matches_from_safe_borrow<I, T>(&mut self, itr: I) -> ClapResult<ArgMatches<'a>>
where I: IntoIterator<Item = T>,
T: Into<OsString>
{
// Verify all positional assertions pass
self.p.verify_positionals();
// If there are global arguments, we need to propgate them down to subcommands
// before parsing incase we run into a subcommand
self.p.propogate_globals();
let mut matcher = ArgMatcher::new();
let mut it = itr.into_iter();
// Get the name of the program (argument 1 of env::args()) and determine the
// actual file
// that was used to execute the program. This is because a program called
// ./target/release/my_prog -a
// will have two arguments, './target/release/my_prog', '-a' but we don't want
// to display
// the full path when displaying help messages and such
if !self.p.is_set(AppSettings::NoBinaryName) {
if let Some(name) = it.next() {
let bn_os = name.into();
let p = Path::new(&*bn_os);
if let Some(f) = p.file_name() {
if let Some(s) = f.to_os_string().to_str() {
if let None = self.p.meta.bin_name {
self.p.meta.bin_name = Some(s.to_owned());
}
}
}
}
}
// do the real parsing
if let Err(e) = self.p.get_matches_with(&mut matcher, &mut it) {
return Err(e);
}
Ok(matcher.into())
}
// Re-implements ClapError::exit except it checks if we should wait for input before exiting
// since ClapError doesn't have that info and the error message must be printed before exiting
fn maybe_wait_for_exit(&self, e: Error) -> ! {
if e.use_stderr() {
wlnerr!("{}", e.message);
if self.p.is_set(AppSettings::WaitOnError) {
wlnerr!("\nPress [ENTER] / [RETURN] to continue...");
let mut s = String::new();
let i = io::stdin();
i.lock().read_line(&mut s).unwrap();
}
process::exit(1);
}
e.exit()
}
}
#[cfg(feature = "yaml")]
impl<'a> From<&'a Yaml> for App<'a, 'a> {
fn from(mut yaml: &'a Yaml) -> Self {
use args::SubCommand;
// We WANT this to panic on error...so expect() is good.
let mut is_sc = None;
let mut a = if let Some(name) = yaml["name"].as_str() {
App::new(name)
} else {
let yaml_hash = yaml.as_hash().unwrap();
let sc_key = yaml_hash.keys().nth(0).unwrap();
is_sc = Some(yaml_hash.get(sc_key).unwrap());
App::new(sc_key.as_str().unwrap())
};
yaml = if let Some(sc) = is_sc {
sc
} else {
yaml
};
if let Some(v) = yaml["version"].as_str() {
a = a.version(v);
}
if let Some(v) = yaml["author"].as_str() {
a = a.author(v);
}
if let Some(v) = yaml["bin_name"].as_str() {
a = a.bin_name(v);
}
if let Some(v) = yaml["about"].as_str() {
a = a.about(v);
}
if let Some(v) = yaml["after_help"].as_str() {
a = a.after_help(v);
}
if let Some(v) = yaml["usage"].as_str() {
a = a.usage(v);
}
if let Some(v) = yaml["help"].as_str() {
a = a.help(v);
}
if let Some(v) = yaml["help_short"].as_str() {
a = a.help_short(v);
}
if let Some(v) = yaml["version_short"].as_str() {
a = a.version_short(v);
}
if let Some(v) = yaml["settings"].as_vec() {
for ys in v {
if let Some(s) = ys.as_str() {
a = a.setting(s.parse().ok().expect("unknown AppSetting found in YAML file"));
}
}
}
if let Some(v) = yaml["args"].as_vec() {
for arg_yaml in v {
a = a.arg(Arg::from_yaml(&arg_yaml.as_hash().unwrap()));
}
}
if let Some(v) = yaml["subcommands"].as_vec() {
for sc_yaml in v {
a = a.subcommand(SubCommand::from_yaml(&sc_yaml));
}
}
if let Some(v) = yaml["groups"].as_vec() {
for ag_yaml in v {
a = a.group(ArgGroup::from(ag_yaml.as_hash().unwrap()));
}
}
a
}
}
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