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clap

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Command Line Argument Parser for Rust

It is a simple-to-use, efficient, and full-featured library for parsing command line arguments and subcommands when writing console/terminal applications.

documentation

website

blog

Table of Contents

Created by gh-md-toc

What's New

Here's the highlights for v2.23.1

  • fixes a missing newline character in the autogenerated help and version messages in some instances
  • allows specifying a short help vs a long help (i.e. varying levels of detail depending on if -h or --help was used)
  • clap_app!: adds support for arg names with hyphens similar to longs with hyphens
  • fixes a bug that wasn't allowing help and version to be properly overridden
    • This may break code that was relying on this bug! If you add a flag with a long of help manually and rely on the help message to be printed automatically your code could break. Please see the commit link in the full CHANGELOG.md
  • App::long_about
  • App::long_version
  • App::print_long_help
  • App::write_long_help
  • App::print_long_version
  • App::write_long_version
  • Arg::long_help
  • clap_app!: documents the --("some-arg") method for using args with hyphens inside them

Here's the highlights for v2.21.0 to v2.22.2

  • fixes the usage string regression when using help templates
  • fixes a big regression with custom usage strings
  • adds the ability to change the name of the App instance after creation
  • adds ability to hide the default value of an argument from the help string
  • fixes support for loading author info from yaml
  • adds fish subcommand help support
  • options that use require_equals(true) now display the equals sign in help messages, usage strings, and errors
  • setting the max term width now correctly propagates down through child subcommands
  • fixes the precedence of this error to prioritize over other error messages
  • fixes some regression bugs resulting from old asserts in debug mode.
  • adds the ability to mark a positional argument as 'last' which means it should be used with -- syntax and can be accessed early to effectivly skip other positional args
  • Some performance improvements by reducing the ammount of duplicate work, cloning, and allocations in all cases.
  • Some massive perfomance gains when using many args (i.e. things like shell glob expansions)
  • adds a setting to allow one to infer shortened subcommands or aliases (i.e. for subcommmand "test", "t", "te", or "tes" would be allowed assuming no other ambiguities)
  • when AppSettings::SubcommandsNegateReqs and ArgsNegateSubcommands are used, a new more accurate double line usage string is shown
  • provides default_value_os and default_value_if[s]_os
  • provides App::help_message and App::version_message which allows one to override the auto-generated help/version flag associated help
  • adds the ability to require the equals syntax with options --opt=val
  • doesn't print the argument sections in the help message if all args in that section are hidden
  • doesn't include the various [ARGS] [FLAGS] or [OPTIONS] if the only ones available are hidden
  • now correctly shows subcommand as required in the usage string when AppSettings::SubcommandRequiredElseHelp is used
  • fixes some "memory leaks" when an error is detected and clap exits
  • fixes a trait that's marked private accidentlly, but should be crate internal public
  • fixes a bug that tried to propogate global args multiple times when generating multiple completion scripts
  • Fixes a critical bug in the clap_app! macro of a missing fragment specifier when using !property style tags.
  • Fix examples link in CONTRIBUTING.md

For full details, see CHANGELOG.md

About

clap is used to parse and validate the string of command line arguments provided by the user at runtime. You provide the list of valid possibilities, and clap handles the rest. This means you focus on your applications functionality, and less on the parsing and validating of arguments.

clap also provides the traditional version and help switches (or flags) 'for free' meaning automatically with no configuration. It does this by checking list of valid possibilities you supplied and adding only the ones you haven't already defined. If you are using subcommands, clap will also auto-generate a help subcommand for you in addition to the traditional flags.

Once clap parses the user provided string of arguments, it returns the matches along with any applicable values. If the user made an error or typo, clap informs them of the mistake and exits gracefully (or returns a Result type and allows you to perform any clean up prior to exit). Because of this, you can make reasonable assumptions in your code about the validity of the arguments.

FAQ

For a full FAQ and more in depth details, see the wiki page

Comparisons

First, let me say that these comparisons are highly subjective, and not meant in a critical or harsh manner. All the argument parsing libraries out there (to include clap) have their own strengths and weaknesses. Sometimes it just comes down to personal taste when all other factors are equal. When in doubt, try them all and pick one that you enjoy :) There's plenty of room in the Rust community for multiple implementations!

How does clap compare to getopts?

getopts is a very basic, fairly minimalist argument parsing library. This isn't a bad thing, sometimes you don't need tons of features, you just want to parse some simple arguments, and have some help text generated for you based on valid arguments you specify. The downside to this approach is that you must manually implement most of the common features (such as checking to display help messages, usage strings, etc.). If you want a highly custom argument parser, and don't mind writing the majority of the functionality yourself, getopts is an excellent base.

getopts also doesn't allocate much, or at all. This gives it a very small performance boost. Although, as you start implementing additional features, that boost quickly disappears.

Personally, I find many, many uses of getopts are manually implementing features that clap provides by default. Using clap simplifies your codebase allowing you to focus on your application, and not argument parsing.

How does clap compare to docopt.rs?

I first want to say I'm a big a fan of BurntSushi's work, the creator of Docopt.rs. I aspire to produce the quality of libraries that this man does! When it comes to comparing these two libraries they are very different. docopt tasks you with writing a help message, and then it parsers that message for you to determine all valid arguments and their use. Some people LOVE this approach, others do not. If you're willing to write a detailed help message, it's nice that you can stick that in your program and have docopt do the rest. On the downside, it's far less flexible.

docopt is also excellent at translating arguments into Rust types automatically. There is even a syntax extension which will do all this for you, if you're willing to use a nightly compiler (use of a stable compiler requires you to somewhat manually translate from arguments to Rust types). To use BurntSushi's words, docopt is also a sort of black box. You get what you get, and it's hard to tweak implementation or customize the experience for your use case.

Because docopt is doing a ton of work to parse your help messages and determine what you were trying to communicate as valid arguments, it's also one of the more heavy weight parsers performance-wise. For most applications this isn't a concern and this isn't to say docopt is slow, in fact from it. This is just something to keep in mind while comparing.

All else being equal, what are some reasons to use clap?

clap is as fast, and as lightweight as possible while still giving all the features you'd expect from a modern argument parser. In fact, for the amount and type of features clap offers it remains about as fast as getopts. If you use clap when just need some simple arguments parsed, you'll find it's a walk in the park. clap also makes it possible to represent extremely complex, and advanced requirements, without too much thought. clap aims to be intuitive, easy to use, and fully capable for wide variety use cases and needs.

Features

Below are a few of the features which clap supports, full descriptions and usage can be found in the documentation and examples/ directory

  • Auto-generated Help, Version, and Usage information
    • Can optionally be fully, or partially overridden if you want a custom help, version, or usage
  • Auto-generated bash completion scripts at compile time
    • Even works through many multiple levels of subcommands
    • Works with options which only accept certain values
    • Works with subcommand aliases
  • Flags / Switches (i.e. bool fields)
    • Both short and long versions supported (i.e. -f and --flag respectively)
    • Supports combining short versions (i.e. -fBgoZ is the same as -f -B -g -o -Z)
    • Supports multiple occurrences (i.e. -vvv or -v -v -v)
  • Positional Arguments (i.e. those which are based off an index from the program name)
    • Supports multiple values (i.e. myprog <file>... such as myprog file1.txt file2.txt being two values for the same "file" argument)
    • Supports Specific Value Sets (See below)
    • Can set value parameters (such as the minimum number of values, the maximum number of values, or the exact number of values)
    • Can set custom validations on values to extend the argument parsing capability to truly custom domains
  • Option Arguments (i.e. those that take values)
    • Both short and long versions supported (i.e. -o value, -ovalue, -o=value and --option value or --option=value respectively)
    • Supports multiple values (i.e. -o <val1> -o <val2> or -o <val1> <val2>)
    • Supports delimited values (i.e. -o=val1,val2,val3, can also change the delimiter)
    • Supports Specific Value Sets (See below)
    • Supports named values so that the usage/help info appears as -o <FILE> <INTERFACE> etc. for when you require specific multiple values
    • Can set value parameters (such as the minimum number of values, the maximum number of values, or the exact number of values)
    • Can set custom validations on values to extend the argument parsing capability to truly custom domains
  • Sub-Commands (i.e. git add <file> where add is a sub-command of git)
    • Support their own sub-arguments, and sub-sub-commands independent of the parent
    • Get their own auto-generated Help, Version, and Usage independent of parent
  • Support for building CLIs from YAML - This keeps your Rust source nice and tidy and makes supporting localized translation very simple!
  • Requirement Rules: Arguments can define the following types of requirement rules
    • Can be required by default
    • Can be required only if certain arguments are present
    • Can require other arguments to be present
  • Confliction Rules: Arguments can optionally define the following types of exclusion rules
    • Can be disallowed when certain arguments are present
    • Can disallow use of other arguments when present
  • Groups: Arguments can be made part of a group
    • Fully compatible with other relational rules (requirements, conflicts, and overrides) which allows things like requiring the use of any arg in a group, or denying the use of an entire group conditionally
  • Specific Value Sets: Positional or Option Arguments can define a specific set of allowed values (i.e. imagine a --mode option which may only have one of two values fast or slow such as --mode fast or --mode slow)
  • Default Values
  • Automatic Version from Cargo.toml: clap is fully compatible with Rust's env!() macro for automatically setting the version of your application to the version in your Cargo.toml. See 09_auto_version example for how to do this (Thanks to jhelwig for pointing this out)
  • Typed Values: You can use several convenience macros provided by clap to get typed values (i.e. i32, u8, etc.) from positional or option arguments so long as the type you request implements std::str::FromStr See the 12_typed_values example. You can also use claps arg_enum! macro to create an enum with variants that automatically implement std::str::FromStr. See 13a_enum_values_automatic example for details
  • Suggestions: Suggests corrections when the user enters a typo. For example, if you defined a --myoption argument, and the user mistakenly typed --moyption (notice y and o transposed), they would receive a Did you mean '--myoption'? error and exit gracefully. This also works for subcommands and flags. (Thanks to Byron for the implementation) (This feature can optionally be disabled, see 'Optional Dependencies / Features')
  • Colorized Errors (Non Windows OS only): Error message are printed in in colored text (this feature can optionally be disabled, see 'Optional Dependencies / Features').
  • Global Arguments: Arguments can optionally be defined once, and be available to all child subcommands.
  • Custom Validations: You can define a function to use as a validator of argument values. Imagine defining a function to validate IP addresses, or fail parsing upon error. This means your application logic can be solely focused on using values.
  • POSIX Compatible Conflicts/Overrides - In POSIX args can be conflicting, but not fail parsing because whichever arg comes last "wins" so to speak. This allows things such as aliases (i.e. alias ls='ls -l' but then using ls -C in your terminal which ends up passing ls -l -C as the final arguments. Since -l and -C aren't compatible, this effectively runs ls -C in clap if you choose...clap also supports hard conflicts that fail parsing). (Thanks to Vinatorul!)
  • Supports the Unix -- meaning, only positional arguments follow

Quick Example

The following examples show a quick example of some of the very basic functionality of clap. For more advanced usage, such as requirements, conflicts, groups, multiple values and occurrences see the documentation, examples/ directory of this repository or the video tutorials.

NOTE: All of these examples are functionally the same, but show different styles in which to use clap

The first example shows a method that allows more advanced configuration options (not shown in this small example), or even dynamically generating arguments when desired. The downside is it's more verbose.

// (Full example with detailed comments in examples/01b_quick_example.rs)
//
// This example demonstrates clap's full 'builder pattern' style of creating arguments which is
// more verbose, but allows easier editing, and at times more advanced options, or the possibility
// to generate arguments dynamically.
extern crate clap;
use clap::{Arg, App, SubCommand};

fn main() {
    let matches = App::new("My Super Program")
                          .version("1.0")
                          .author("Kevin K. <kbknapp@gmail.com>")
                          .about("Does awesome things")
                          .arg(Arg::with_name("config")
                               .short("c")
                               .long("config")
                               .value_name("FILE")
                               .help("Sets a custom config file")
                               .takes_value(true))
                          .arg(Arg::with_name("INPUT")
                               .help("Sets the input file to use")
                               .required(true)
                               .index(1))
                          .arg(Arg::with_name("v")
                               .short("v")
                               .multiple(true)
                               .help("Sets the level of verbosity"))
                          .subcommand(SubCommand::with_name("test")
                                      .about("controls testing features")
                                      .version("1.3")
                                      .author("Someone E. <someone_else@other.com>")
                                      .arg(Arg::with_name("debug")
                                          .short("d")
                                          .help("print debug information verbosely")))
                          .get_matches();

    // Gets a value for config if supplied by user, or defaults to "default.conf"
    let config = matches.value_of("config").unwrap_or("default.conf");
    println!("Value for config: {}", config);

    // Calling .unwrap() is safe here because "INPUT" is required (if "INPUT" wasn't
    // required we could have used an 'if let' to conditionally get the value)
    println!("Using input file: {}", matches.value_of("INPUT").unwrap());

    // Vary the output based on how many times the user used the "verbose" flag
    // (i.e. 'myprog -v -v -v' or 'myprog -vvv' vs 'myprog -v'
    match matches.occurrences_of("v") {
        0 => println!("No verbose info"),
        1 => println!("Some verbose info"),
        2 => println!("Tons of verbose info"),
        3 | _ => println!("Don't be crazy"),
    }

    // You can handle information about subcommands by requesting their matches by name
    // (as below), requesting just the name used, or both at the same time
    if let Some(matches) = matches.subcommand_matches("test") {
        if matches.is_present("debug") {
            println!("Printing debug info...");
        } else {
            println!("Printing normally...");
        }
    }

    // more program logic goes here...
}

The next example shows a far less verbose method, but sacrifices some of the advanced configuration options (not shown in this small example). This method also takes a very minor runtime penalty.

// (Full example with detailed comments in examples/01a_quick_example.rs)
//
// This example demonstrates clap's "usage strings" method of creating arguments
// which is less verbose
extern crate clap;
use clap::{Arg, App, SubCommand};

fn main() {
    let matches = App::new("myapp")
                          .version("1.0")
                          .author("Kevin K. <kbknapp@gmail.com>")
                          .about("Does awesome things")
                          .args_from_usage(
                              "-c, --config=[FILE] 'Sets a custom config file'
                              <INPUT>              'Sets the input file to use'
                              -v...                'Sets the level of verbosity'")
                          .subcommand(SubCommand::with_name("test")
                                      .about("controls testing features")
                                      .version("1.3")
                                      .author("Someone E. <someone_else@other.com>")
                                      .arg_from_usage("-d, --debug 'Print debug information'"))
                          .get_matches();

    // Same as previous example...
}

This third method shows how you can use a YAML file to build your CLI and keep your Rust source tidy or support multiple localized translations by having different YAML files for each localization.

First, create the cli.yml file to hold your CLI options, but it could be called anything we like:

name: myapp
version: "1.0"
author: Kevin K. <kbknapp@gmail.com>
about: Does awesome things
args:
    - config:
        short: c
        long: config
        value_name: FILE
        help: Sets a custom config file
        takes_value: true
    - INPUT:
        help: Sets the input file to use
        required: true
        index: 1
    - verbose:
        short: v
        multiple: true
        help: Sets the level of verbosity
subcommands:
    - test:
        about: controls testing features
        version: "1.3"
        author: Someone E. <someone_else@other.com>
        args:
            - debug:
                short: d
                help: print debug information

Since this feature requires additional dependencies that not everyone may want, it is not compiled in by default and we need to enable a feature flag in Cargo.toml:

Simply change your clap = "2.19" to clap = {version = "2.19", features = ["yaml"]}.

At last we create our main.rs file just like we would have with the previous two examples:

// (Full example with detailed comments in examples/17_yaml.rs)
//
// This example demonstrates clap's building from YAML style of creating arguments which is far
// more clean, but takes a very small performance hit compared to the other two methods.
#[macro_use]
extern crate clap;
use clap::App;

fn main() {
    // The YAML file is found relative to the current file, similar to how modules are found
    let yaml = load_yaml!("cli.yml");
    let matches = App::from_yaml(yaml).get_matches();

    // Same as previous examples...
}

Finally there is a macro version, which is like a hybrid approach offering the speed of the builder pattern (the first example), but without all the verbosity.

#[macro_use]
extern crate clap;

fn main() {
    let matches = clap_app!(myapp =>
        (version: "1.0")
        (author: "Kevin K. <kbknapp@gmail.com>")
        (about: "Does awesome things")
        (@arg CONFIG: -c --config +takes_value "Sets a custom config file")
        (@arg INPUT: +required "Sets the input file to use")
        (@arg debug: -d ... "Sets the level of debugging information")
        (@subcommand test =>
            (about: "controls testing features")
            (version: "1.3")
            (author: "Someone E. <someone_else@other.com>")
            (@arg verbose: -v --verbose "Print test information verbosely")
        )
    ).get_matches();

    // Same as before...
}

If you were to compile any of the above programs and run them with the flag --help or -h (or help subcommand, since we defined test as a subcommand) the following would be output

$ myprog --help
My Super Program 1.0
Kevin K. <kbknapp@gmail.com>
Does awesome things

USAGE:
    MyApp [FLAGS] [OPTIONS] <INPUT> [SUBCOMMAND]

FLAGS:
    -h, --help       Prints this message
    -v               Sets the level of verbosity
    -V, --version    Prints version information

OPTIONS:
    -c, --config <FILE>    Sets a custom config file

ARGS:
    INPUT    The input file to use

SUBCOMMANDS:
    help    Prints this message
    test    Controls testing features

NOTE: You could also run myapp test --help to see similar output and options for the test subcommand.

Try it!

Pre-Built Test

To try out the pre-built example, use the following steps:

  • Clone the repository $ git clone https://github.com/kbknapp/clap-rs && cd clap-rs/tests
  • Compile the example $ cargo build --release
  • Run the help info $ ./target/release/claptests --help
  • Play with the arguments!

BYOB (Build Your Own Binary)

To test out clap's default auto-generated help/version follow these steps:

  • Create a new cargo project $ cargo new fake --bin && cd fake
  • Add clap to your Cargo.toml
[dependencies]
clap = "2"
  • Add the following to your src/main.rs
extern crate clap;
use clap::App;

fn main() {
  App::new("fake").version("v1.0-beta").get_matches();
}
  • Build your program $ cargo build --release
  • Run with help or version $ ./target/release/fake --help or $ ./target/release/fake --version

Usage

For full usage, add clap as a dependency in your Cargo.toml () to use from crates.io:

[dependencies]
clap = "~2.19.0"

(note: If you are concerned with supporting a minimum version of Rust that is older than the current stable Rust minus 2 stable releases, it's recommended to use the ~major.minor.patch style versions in your Cargo.toml which will only update the patch version automatically. For more information see the Compatibility Policy)

Then add extern crate clap; to your crate root.

Define a list of valid arguments for your program (see the documentation or examples/ directory of this repo)

Then run cargo build or cargo update && cargo build for your project.

Optional Dependencies / Features

Features enabled by default

  • "suggestions": Turns on the Did you mean '--myoption'? feature for when users make typos. (builds dependency strsim)
  • "color": Turns on colored error messages. This feature only works on non-Windows OSs. (builds dependency ansi-term)
  • "wrap_help": Wraps the help at the actual terminal width when available, instead of 120 chracters. (builds dependency term_size)

To disable these, add this to your Cargo.toml:

[dependencies.clap]
version = "2.19"
default-features = false

You can also selectively enable only the features you'd like to include, by adding:

[dependencies.clap]
version = "2.19"
default-features = false

# Cherry-pick the features you'd like to use
features = [ "suggestions", "color" ]

Opt-in features

  • "yaml": Enables building CLIs from YAML documents. (builds dependency yaml-rust)
  • "unstable": Enables unstable clap features that may change from release to release

Dependencies Tree

The following graphic depicts claps dependency graph (generated using cargo-graph).

  • Dashed Line: Optional dependency
  • Red Color: NOT included by default (must use cargo features to enable)
  • Blue Color: Dev dependency, only used while developing.

clap dependencies

More Information

You can find complete documentation on the docs.rs for this project.

You can also find usage examples in the examples/ directory of this repo.

Video Tutorials

There's also the video tutorial series Argument Parsing with Rust v2.

These videos slowly trickle out as I finish them and currently a work in progress.

How to Contribute

Contributions are always welcome! And there is a multitude of ways in which you can help depending on what you like to do, or are good at. Anything from documentation, code cleanup, issue completion, new features, you name it, even filing issues is contributing and greatly appreciated!

Another really great way to help is if you find an interesting, or helpful way in which to use clap. You can either add it to the examples/ directory, or file an issue and tell me. I'm all about giving credit where credit is due :)

Please read CONTRIBUTING.md before you start contributing.

Testing Code

To test with all features both enabled and disabled, you can run theese commands:

$ cargo test --no-default-features
$ cargo test --features "yaml unstable"

Alternatively, if you have just installed you can run the prebuilt recipies. Not using just is prfeclty fine as well, it simply bundles commands automatically.

For example, to test the code, as above simply run:

$ just run-tests

From here on, I will list the appropriate cargo command as well as the just command.

Sometimes it's helpful to only run a subset of the tests, which can be done via:

$ cargo test --test <test_name>

# Or

$ just run-test <test_name>

Linting Code

During the CI process clap runs against many different lints using clippy. In order to check if these lints pass on your own computer prior to submitting a PR you'll need a nightly compiler.

In order to check the code for lints run either:

$ rustup override add nightly
$ cargo build --features lints
$ rustup override remove

# Or

$ just lint

Debugging Code

Another helpful technique is to see the clap debug output while developing features. In order to see the debug output while running the full test suite or individual tests, run:

$ cargo test --features debug

# Or for individual tests
$ cargo test --test <test_name> --features debug

# The corresponding just command for individual debugging tests is:
$ just debug <test_name>

Goals

There are a few goals of clap that I'd like to maintain throughout contributions. If your proposed changes break, or go against any of these goals we'll discuss the changes further before merging (but will not be ignored, all contributes are welcome!). These are by no means hard-and-fast rules, as I'm no expert and break them myself from time to time (even if by mistake or ignorance :P).

  • Remain backwards compatible when possible
    • If backwards compatibility must be broken, use deprecation warnings if at all possible before removing legacy code
    • This does not apply for security concerns
  • Parse arguments quickly
    • Parsing of arguments shouldn't slow down usage of the main program
    • This is also true of generating help and usage information (although slightly less stringent, as the program is about to exit)
  • Try to be cognizant of memory usage
    • Once parsing is complete, the memory footprint of clap should be low since the main program is the star of the show
  • panic! on developer error, exit gracefully on end-user error

Compatibility Policy

Because clap takes SemVer and compatibility seriously, this is the official policy regarding breaking changes and minimum required versions of Rust.

clap will pin the minimum required version of Rust to the CI builds. Bumping the minimum version of Rust is considered a minor breaking change, meaning at a minimum the minor version of clap will be bumped.

In order to keep from being suprised of breaking changes, it is highly recommended to use the ~major.minor.patch style in your Cargo.toml only if you wish to target a version of Rust that is older than current stable minus two releases:

[dependencies]
clap = "~2.19.0"

This will cause only the patch version to be updated upon a cargo update call, and therefore cannot break due to new features, or bumped minimum versions of Rust.

Minimum Version of Rust

clap will officially support current stable Rust, minus two releases, but may work with prior releases as well. For example, current stable Rust at the time of this writing is 1.13.0, meaning clap is guaranteed to compile with 1.11.0 and beyond. At the 1.14.0 release, clap will be guaranteed to compile with 1.12.0 and beyond, etc.

Upon bumping the minimum version of Rust (assuming it's within the stable-2 range), it must be clearly annotated in the CHANGELOG.md

Breaking Changes

clap takes a similar policy to Rust and will bump the major veresion number upon breaking changes with only the following exceptions:

  • The breaking change is to fix a security concern
  • The breaking change is to be fixing a bug (i.e. relying on a bug as a feature)
  • The breaking change is a feature isn't used in the wild, or all users of said feature have given approval prior to the change

License

clap is licensed under the MIT license. Please read the LICENSE-MIT file in this repository for more information.

Recent Breaking Changes

clap follows semantic versioning, so breaking changes should only happen upon major version bumps. The only exception to this rule is breaking changes that happen due to implementation that was deemed to be a bug, security concerns, or it can be reasonably proved to affect no code. For the full details, see CHANGELOG.md.

As of 2.0.0 (From 1.x)

  • Fewer lifetimes! Yay!
  • App<'a, 'b, 'c, 'd, 'e, 'f> => App<'a, 'b>
  • Arg<'a, 'b, 'c, 'd, 'e, 'f> => Arg<'a, 'b>
  • ArgMatches<'a, 'b> => ArgMatches<'a>
  • Simply Renamed
  • App::arg_group => App::group
  • App::arg_groups => App::groups
  • ArgGroup::add => ArgGroup::arg
  • ArgGroup::add_all => ArgGroup::args
  • ClapError => Error
  • struct field ClapError::error_type => Error::kind
  • ClapResult => Result
  • ClapErrorType => ErrorKind
  • Removed Deprecated Functions and Methods
  • App::subcommands_negate_reqs
  • App::subcommand_required
  • App::arg_required_else_help
  • App::global_version(bool)
  • App::versionless_subcommands
  • App::unified_help_messages
  • App::wait_on_error
  • App::subcommand_required_else_help
  • SubCommand::new
  • App::error_on_no_subcommand
  • Arg::new
  • Arg::mutually_excludes
  • Arg::mutually_excludes_all
  • Arg::mutually_overrides_with
  • simple_enum!
  • Renamed Error Variants
  • InvalidUnicode => InvalidUtf8
  • InvalidArgument => UnknownArgument
  • Usage Parser
  • Value names can now be specified inline, i.e. -o, --option <FILE> <FILE2> 'some option which takes two files'
  • There is now a priority of order to determine the name - This is perhaps the biggest breaking change. See the documentation for full details. Prior to this change, the value name took precedence. Ensure your args are using the proper names (i.e. typically the long or short and NOT the value name) throughout the code
  • ArgMatches::values_of returns an Values now which implements Iterator (should not break any code)
  • crate_version! returns &'static str instead of String

Deprecations

Old method names will be left around for several minor version bumps, or one major version bump.

As of 2.19.0:

  • None!