Crates.io | fncmd |
lib.rs | fncmd |
version | 2.1.0 |
source | src |
created_at | 2021-11-23 21:33:20.752651 |
updated_at | 2023-04-22 15:45:28.923127 |
description | Command line interface as a function. |
homepage | |
repository | https://github.com/yuhr/fncmd |
max_upload_size | |
id | 486544 |
size | 54,092 |
Command line interface as a function.
#[fncmd::fncmd] pub fn main() { println!("Hello, World!"); }
fncmd
is an opinionated command line parser frontend that wraps around clap
. The functionality is mostly identical to clap
, but provides much more automated and integrated experience.
Imagine a command line program you want to create. Essentially, it can be abstracted as a simple function that takes command line options as arguments. Then there should be nothing to stop you from being able to write it literally as a function, without using structs or builders like today's Rustaceans do.
This concept is tremendously inspired by argopt
, I really appreciate the work. However, it still requires a bit of cumbersome code, especially for handling subcommands. fncmd
has been rewritten from scratch to get rid of all the complexities. Dig into Subcommands section to see how we can handle it.
This crate is nightly-only. Make sure you have set up your toolchain as nightly before using (e.g. having rust-toolchain
file). You might be interested in Why nightly.
To install, run in your project directory:
cargo add fncmd
For those who prefer case studies: see examples
.
This crate exposes just a single attribute macro, [fncmd
], which can only be attached to the main
function:
// main.rs
/// Description of the command line tool
#[fncmd::fncmd]
pub fn main(
/// Argument foo
#[opt(short, long)]
foo: String,
/// Argument bar
#[opt(short, long)]
bar: Option<String>,
) {
println!("{:?} {:?}", foo, bar);
}
That's all, and now you got a command line program with options handled by clap
. With above code, the help message will be like below:
$ crate-name --help
Description of the command line tool
Usage: crate-name[EXE] [OPTIONS] --foo <FOO>
Options:
-f, --foo <FOO> Argument foo
-b, --bar <BAR> Argument bar
-h, --help Print help
-V, --version Print version
The name and the version of your command are automatically inferred from Cargo metadata.
The usage of the opt
attribute is almost exactly the same as the underlying arg
attribute. They're just passed as is, except that (long)
is implied if no configuration was provided, i.e. #[opt]
means #[opt(long)]
. If you want to take the argument foo
without --foo
, just omit #[opt]
.
As you may know, in Cargo project you can put entrypoints for additional binaries into src/bin
. If 1) their names are prefixed by crate-name
and 2) their main
functions are decorated with the #[fncmd]
attribute and 3) exposed as pub
, then those are automatically wrapped up as subcommands of the default binary target crate-name
. Say you have the following directory structure:
src
├── main.rs
└── bin
├── crate-name-subcommand1.rs
└── crate-name-subcommand2.rs
You'll get the following subcommand structure:
crate-name
├── crate-name subcommand1
└── crate-name subcommand2
Actually fncmd
doesn't have any distinction between the “default” binary and “additional” binaries. It determines subcommand structure just based on prefix structure instead. Therefore, configuring binary targets in your Cargo.toml
should work as intended, for example:
[[bin]]
name = "crate-name"
path = "src/clis/crate-name.rs"
[[bin]]
name = "another"
path = "src/clis/another.rs"
[[bin]]
name = "another-sub" # `pub`
path = "src/clis/another-sub.rs"
[[bin]]
name = "another-sub-subsub" # `pub`
path = "src/clis/another-sub-subsub.rs"
[[bin]]
name = "another-orphan" # non-`pub`
path = "src/clis/another-orphan.rs"
[[bin]]
name = "another-orphan-sub" # `pub`
path = "src/clis/another-orphan-sub.rs"
This configuration yields up into these commands:
crate-name
another
└── another sub
└── another sub subsub
another-orphan
└── another-orphan sub
Note that another-orphan
is not contained within another
, because it's not exposed as pub
. As seen here, making the main
non-pub
is only meaningful when you want it to have a common prefix with others but not to be included by another command, so in most cases you can set pub
without thinking.
Of course the same structure can be achieved without manually editing Cargo.toml
, by placing files into the default location:
src
├── main.rs
└── bin
├── another.rs
├── another-sub.rs
├── another-sub-subsub.rs
├── another-orphan.rs
└── another-orphan-sub.rs
Sometimes you may want to transform the main
function with another attribute macro such as #[tokio::main]
and #[async_std::main]
. In such case you have to put #[fncmd]
at the outmost level:
/// Description of the command line tool
#[fncmd]
#[tokio::main]
pub async fn main(hello: String) -> anyhow::Result<()> {
...
}
But not:
/// Description of the command line tool
#[tokio::main]
#[fncmd]
pub async fn main(hello: String) -> anyhow::Result<()> {
...
}
This is because the macros like #[tokio::main]
do some assertions on their own, so we need to feed them a well-mannered version of main
function, e.g. removing parameters.
Position of the doc comment doesn't matter.
fncmd
won't support following features by design. That's why fncmd
states “opinionated”.
Showing authors in the help will simply be a noise from general user's point of view.
Changing metadata such as name
and version
to different values from the ones defined in Cargo.toml
can easily undermine maintainability and consistency of them.
#[fncmd]
to functions other than main
Attaching #[fncmd]
to arbitrary functions can lead to a bloated single file codebase, which should be avoided in general.
The way it automatically determines which targets are subcommands or not requires the #[fncmd]
macro itself to know the name of the attached target, and thus the path of the file at which it has been called. This can be achieved by Span::source_file
, which is behind an unstable feature flag proc_macro_span
.