========
Argparse
========
The ``rust-argparse`` is command-line parsing module for rust. It's inspired
by python's ``argparse`` module.
Features:
* Supports standard (GNU) option conventions
* Properly typed values
* Automatically generated help and usage messages
Importing
=========
Edit your Cargo.toml to add ``rust-argparse`` to your project.
.. code-block:: rust
[dependencies]
argparse = "0.2.2"
Example
=======
The following code is a simple Rust program with command-line arguments:
.. code-block:: rust
extern crate argparse;
use argparse::{ArgumentParser, StoreTrue, Store};
fn main() {
let mut verbose = false;
let mut name = "World".to_string();
{ // this block limits scope of borrows by ap.refer() method
let mut ap = ArgumentParser::new();
ap.set_description("Greet somebody.");
ap.refer(&mut verbose)
.add_option(&["-v", "--verbose"], StoreTrue,
"Be verbose");
ap.refer(&mut name)
.add_option(&["--name"], Store,
"Name for the greeting");
ap.parse_args_or_exit();
}
if verbose {
println!("name is {}", name);
}
println!("Hello {}!", name);
}
Assuming the Rust code above is saved into a file ``greeting.rs``, let's see
what we have now::
$ rustc greeting.rs
$ ./greeting -h
Usage:
./greeting [OPTIONS]
Greet somebody.
Optional arguments:
-h, --help Show this help message and exit
-v, --verbose
Be verbose
--name NAME Name for the greeting
$ ./greeting
Hello World!
$ ./greeting --name Bob
Hello Bob!
$ ./greeting -v --name Alice
name is Alice
Hello Alice!
Basic Workflow
==============
Create ArgumentParser
---------------------
The argument parser is created empty and is built incrementally. So we create
a mutable variable::
extern crate argparse;
use argparse::ArgumentParser;
let mut parser = ArgumentParser::new();
Customize
---------
There are optional customization methods. The most important one is::
parser.set_description("My command-line utility")
The descripion is rewrapped to fit 80 column string nicely. Just like option
descriptions.
Add Options
-----------
The ``refer`` method creates a cell variable, which the result will be written
to::
let mut verbose = false;
parser.refer(&mut verbose);
Next we add an options which control the variable:
For example::
parser.refer(&mut verbose)
.add_option(&["-v", "--verbose"], StoreTrue,
"Be verbose");
You may add multiple options for the same variable::
parser.refer(&mut verbose)
.add_option(&["-v", "--verbose"], StoreTrue,
"Be verbose")
.add_option(&["-q", "--quiet"], StoreFalse,
"Be verbose");
Similarly positional arguments are added::
let mut command = String;
parser.refer(&mut command)
.add_argument("command", Store,
"Command to run");
Organizing Options
------------------
It's often useful to organize options into some kind of structure. You can
easily borrow variables from the structure into option parser. For example::
struct Options {
verbose: bool,
}
...
let mut options = Options { verbose: false };
parser.refer(&mut options.verbose)
.add_option(&["-v"], StoreTrue,
"Be verbose");
Parsing Arguments
-----------------
All the complex work is done in ``parser.parse_args()``. But there is
a simpler option::
parser.parse_args_or_exit()
In case you don't want argparse to exit itself, you might use the
``parse_args`` function directly::
use std::process::exit;
match parser.parse_args() {
Ok(()) => {}
Err(x) => {
std::process::exit(x);
}
}
ArgumentParser Methods
======================
``parser.refer<T>(var: &mut T) -> Ref``
Attach the variable to argument parser. The options are added to the
returned ``Ref`` object and modify a variable passed to the method.
``parser.add_option(names: &[&str], action: TypedAction, help: &str)``
Add a single option which has no parameters. Most options must be added
by ``refer(..)`` and methods on ``Ref`` object (see below).
Example::
ap.add_option(&["-V", "--version"],
Print(env!("CARGO_PKG_VERSION").to_string()), "Show version");
``parser.set_description(descr: &str)``
Set description that is at the top of help message.
``parser.stop_on_first_argument(val: bool)``
If called with ``true``, parser will stop searching for options when first
non-option (the one doesn't start with ``-``) argument is encountered. This
is useful if you want to parse following options with another argparser or
external program.
``parser.silence_double_dash(val: bool)``
If called with ``true`` (default), parser will not treat *first* double
dash ``--`` as positional argument. Use ``false`` if you need to add some
meaning to the ``--`` marker.
``parser.print_usage(name: &str, writer: &mut Write)``
Prints usage string to stderr.
``parser.print_help(name: &str, writer: &mut Write)``
Writes help to ``writer``, used by ``--help`` option internally.
``parser.parse_args()``
Method that does all the dirty work. And returns ``Result``
``parser.parse_args_or_exit()``
Method that does all the dirty work. And in case of failure just ``exit()``
Variable Reference Methods
==========================
The ``argparse::Ref`` object is returned from ``parser.refer()``.
The following methods are used to add and customize arguments:
``option.add_option(names: &[&str], action: TypedAction, help: &str)``
Add an option. All items in names should be either in format ``-X`` or
``--long-option`` (i.e. one dash and one char or two dashes and long name).
How this option will be interpreted and whether it will have an argument
dependes on the action. See below list of actions.
``option.add_argument(name: &str, action: TypedAction, help: &str)``
Add a positional argument
``option.metavar(var: &str)``
A name of the argument in usage messages (for options having argument).
``option.envvar(var: &str)``
A name of the environment variable to get option value from. The value
would be parsed with ``FromStr::from_str``, just like an option having
``Store`` action.
``option.required()``
The option or argument is required (it's optional by default). If multiple
options or multiple arguments are defined for this reference at least one
of them is required.
Actions
=======
The following actions are available out of the box. They may be used in either
``add_option`` or ``add_argument``:
``Store``
An option has single argument. Stores a value from command-line in a
variable. Any type that has the ``FromStr`` and ``Clone`` traits implemented
may be used.
``StoreOption``
As ``Store``, but wrap value with ``Some`` for use with ``Option``. For
example:
let mut x: Option<i32> = None;
ap.refer(&mut x).add_option(&["-x"], StoreOption, "Set var x");
``StoreConst(value)``
An option has no arguments. Store a hard-coded ``value`` into variable,
when specified. Any type with the ``Clone`` trait implemented may be used.
``PushConst(value)``
An option has no arguments. Push a hard-coded ``value`` into variable,
when specified. Any type which has the ``Clone`` type implemented may be
used. Option might used for a list of operations to perform, when ``required``
is set for this variable, at least one operation is required.
``StoreTrue``
Stores boolean ``true`` value in a variable.
(shortcut for ``StoreConst(true)``)
``StoreFalse``
Stores boolean ``false`` value in a variable.
(shortcut for ``StoreConst(false)``)
``IncrBy(num)``
An option has no arguments. Increments the value stored in a variable by a
value ``num``. Any type which has the ``Add`` and ``Clone`` traits may be used.
``DecrBy(nym)``
Decrements the value stored in a variable by a value ``num``. Any type
which has the ``Add`` and ``Clone`` traits may be used.
``Collect``
When used for an ``--option``, requires single argument. When used for a
positional argument consumes all remaining arguments. Parsed options are
added to the list. I.e. a ``Collect`` action requires a
``Vec<int>`` variable. Parses arguments using ``FromStr`` trait.
``List``
When used for positional argument, works the same as ``List``. When used
as an option, consumes all remaining arguments.
Note the usage of ``List`` is strongly discouraged, because of complex
rules below. Use ``Collect`` and positional options if possible. But usage
of ``List`` action may be useful if you need shell expansion of anything
other than last positional argument.
Let's learn rules by example. For the next options::
ap.refer(&mut lst1).add_option(&["-X", "--xx"], List, "List1");
ap.refer(&mut lst2).add_argument("yy", List, "List2");
The following command line::
./run 1 2 3 -X 4 5 6
Will return ``[1, 2, 3]`` in the ``lst1`` and the ``[4,5,6]`` in the
``lst2``.
Note that using when using ``=`` or equivalent short option mode, the
'consume all' mode is not enabled. I.e. in the following command-line::
./run 1 2 -X3 4 --xx=5 6
The ``lst1`` has ``[3, 5]`` and ``lst2`` has ``[1, 2, 4, 6]``.
The argument consuming also stops on ``--`` or the next option::
./run: -X 1 2 3 -- 4 5 6
./run: -X 1 2 --xx=3 4 5 6
Both of the above parse ``[4, 5, 6]`` as ``lst1`` and
the ``[1, 2, 3]`` as the ``lst2``.
``Print(value)``
Print the text and exit (with status ``0``). Useful for ``--version``
option::
ap.add_option(&["-V", "--version"],
Print(env!("CARGO_PKG_VERSION").to_string()), "Show version");