pub struct Arg<'help> { /* private fields */ }
Expand description
The abstract representation of a command line argument. Used to set all the options and relationships that define a valid argument for the program.
There are two methods for constructing Arg
s, using the builder pattern and setting options
manually, or using a usage string which is far less verbose but has fewer options. You can also
use a combination of the two methods to achieve the best of both worlds.
Examples
// Using the traditional builder pattern and setting each option manually
let cfg = Arg::new("config")
.short('c')
.long("config")
.takes_value(true)
.value_name("FILE")
.help("Provides a config file to myprog");
// Using a usage string (setting a similar argument to the one above)
let input = arg!(-i --input <FILE> "Provides an input file to the program");
Implementations
sourceimpl<'help> Arg<'help>
impl<'help> Arg<'help>
sourcepub fn new<S: Into<&'help str>>(n: S) -> Self
pub fn new<S: Into<&'help str>>(n: S) -> Self
Create a new Arg
with a unique name.
The name is used to check whether or not the argument was used at runtime, get values, set relationships with other args, etc..
NOTE: In the case of arguments that take values (i.e. Arg::takes_value(true)
)
and positional arguments (i.e. those without a preceding -
or --
) the name will also
be displayed when the user prints the usage/help information of the program.
Examples
Arg::new("config")
sourcepub fn id<S: Into<&'help str>>(self, n: S) -> Self
pub fn id<S: Into<&'help str>>(self, n: S) -> Self
Set the identifier used for referencing this argument in the clap API.
See Arg::new
for more details.
sourcepub fn short(self, s: char) -> Self
pub fn short(self, s: char) -> Self
Sets the short version of the argument without the preceding -
.
By default V
and h
are used by the auto-generated version
and help
arguments,
respectively. You may use the uppercase V
or lowercase h
for your own arguments, in
which case clap
simply will not assign those to the auto-generated
version
or help
arguments.
Examples
When calling short
, use a single valid UTF-8 character which will allow using the
argument via a single hyphen (-
) such as -c
:
let m = Command::new("prog")
.arg(Arg::new("config")
.short('c')
.takes_value(true))
.get_matches_from(vec![
"prog", "-c", "file.toml"
]);
assert_eq!(m.get_one::<String>("config").map(String::as_str), Some("file.toml"));
sourcepub fn long(self, l: &'help str) -> Self
pub fn long(self, l: &'help str) -> Self
Sets the long version of the argument without the preceding --
.
By default version
and help
are used by the auto-generated version
and help
arguments, respectively. You may use the word version
or help
for the long form of your
own arguments, in which case clap
simply will not assign those to the auto-generated
version
or help
arguments.
NOTE: Any leading -
characters will be stripped
Examples
To set long
use a word containing valid UTF-8. If you supply a double leading
--
such as --config
they will be stripped. Hyphens in the middle of the word, however,
will not be stripped (i.e. config-file
is allowed).
Setting long
allows using the argument via a double hyphen (--
) such as --config
let m = Command::new("prog")
.arg(Arg::new("cfg")
.long("config")
.takes_value(true))
.get_matches_from(vec![
"prog", "--config", "file.toml"
]);
assert_eq!(m.get_one::<String>("cfg").map(String::as_str), Some("file.toml"));
sourcepub fn alias<S: Into<&'help str>>(self, name: S) -> Self
pub fn alias<S: Into<&'help str>>(self, name: S) -> Self
Add an alias, which functions as a hidden long flag.
This is more efficient, and easier than creating multiple hidden arguments as one only needs to check for the existence of this command, and not all variants.
Examples
let m = Command::new("prog")
.arg(Arg::new("test")
.long("test")
.alias("alias")
.takes_value(true))
.get_matches_from(vec![
"prog", "--alias", "cool"
]);
assert!(m.contains_id("test"));
assert_eq!(m.value_of("test"), Some("cool"));
sourcepub fn short_alias(self, name: char) -> Self
pub fn short_alias(self, name: char) -> Self
Add an alias, which functions as a hidden short flag.
This is more efficient, and easier than creating multiple hidden arguments as one only needs to check for the existence of this command, and not all variants.
Examples
let m = Command::new("prog")
.arg(Arg::new("test")
.short('t')
.short_alias('e')
.takes_value(true))
.get_matches_from(vec![
"prog", "-e", "cool"
]);
assert!(m.contains_id("test"));
assert_eq!(m.value_of("test"), Some("cool"));
sourcepub fn aliases(self, names: &[&'help str]) -> Self
pub fn aliases(self, names: &[&'help str]) -> Self
Add aliases, which function as hidden long flags.
This is more efficient, and easier than creating multiple hidden subcommands as one only needs to check for the existence of this command, and not all variants.
Examples
let m = Command::new("prog")
.arg(Arg::new("test")
.long("test")
.aliases(&["do-stuff", "do-tests", "tests"])
.action(ArgAction::SetTrue)
.help("the file to add")
.required(false))
.get_matches_from(vec![
"prog", "--do-tests"
]);
assert_eq!(*m.get_one::<bool>("test").expect("defaulted by clap"), true);
sourcepub fn short_aliases(self, names: &[char]) -> Self
pub fn short_aliases(self, names: &[char]) -> Self
Add aliases, which functions as a hidden short flag.
This is more efficient, and easier than creating multiple hidden subcommands as one only needs to check for the existence of this command, and not all variants.
Examples
let m = Command::new("prog")
.arg(Arg::new("test")
.short('t')
.short_aliases(&['e', 's'])
.action(ArgAction::SetTrue)
.help("the file to add")
.required(false))
.get_matches_from(vec![
"prog", "-s"
]);
assert_eq!(*m.get_one::<bool>("test").expect("defaulted by clap"), true);
sourcepub fn visible_alias<S: Into<&'help str>>(self, name: S) -> Self
pub fn visible_alias<S: Into<&'help str>>(self, name: S) -> Self
Add an alias, which functions as a visible long flag.
Like Arg::alias
, except that they are visible inside the help message.
Examples
let m = Command::new("prog")
.arg(Arg::new("test")
.visible_alias("something-awesome")
.long("test")
.takes_value(true))
.get_matches_from(vec![
"prog", "--something-awesome", "coffee"
]);
assert!(m.contains_id("test"));
assert_eq!(m.value_of("test"), Some("coffee"));
sourcepub fn visible_short_alias(self, name: char) -> Self
pub fn visible_short_alias(self, name: char) -> Self
Add an alias, which functions as a visible short flag.
Like Arg::short_alias
, except that they are visible inside the help message.
Examples
let m = Command::new("prog")
.arg(Arg::new("test")
.long("test")
.visible_short_alias('t')
.takes_value(true))
.get_matches_from(vec![
"prog", "-t", "coffee"
]);
assert!(m.contains_id("test"));
assert_eq!(m.value_of("test"), Some("coffee"));
sourcepub fn visible_aliases(self, names: &[&'help str]) -> Self
pub fn visible_aliases(self, names: &[&'help str]) -> Self
Add aliases, which function as visible long flags.
Like Arg::aliases
, except that they are visible inside the help message.
Examples
let m = Command::new("prog")
.arg(Arg::new("test")
.long("test")
.action(ArgAction::SetTrue)
.visible_aliases(&["something", "awesome", "cool"]))
.get_matches_from(vec![
"prog", "--awesome"
]);
assert_eq!(*m.get_one::<bool>("test").expect("defaulted by clap"), true);
sourcepub fn visible_short_aliases(self, names: &[char]) -> Self
pub fn visible_short_aliases(self, names: &[char]) -> Self
Add aliases, which function as visible short flags.
Like Arg::short_aliases
, except that they are visible inside the help message.
Examples
let m = Command::new("prog")
.arg(Arg::new("test")
.long("test")
.action(ArgAction::SetTrue)
.visible_short_aliases(&['t', 'e']))
.get_matches_from(vec![
"prog", "-t"
]);
assert_eq!(*m.get_one::<bool>("test").expect("defaulted by clap"), true);
sourcepub fn index(self, idx: usize) -> Self
pub fn index(self, idx: usize) -> Self
Specifies the index of a positional argument starting at 1.
NOTE: The index refers to position according to other positional argument. It does not define position in the argument list as a whole.
NOTE: You can optionally leave off the index
method, and the index will be
assigned in order of evaluation. Utilizing the index
method allows for setting
indexes out of order
NOTE: This is only meant to be used for positional arguments and shouldn’t to be used
with Arg::short
or Arg::long
.
NOTE: When utilized with Arg::multiple_values(true)
, only the last positional argument
may be defined as multiple (i.e. with the highest index)
Panics
Command
will panic!
if indexes are skipped (such as defining index(1)
and index(3)
but not index(2)
, or a positional argument is defined as multiple and is not the highest
index
Examples
Arg::new("config")
.index(1)
let m = Command::new("prog")
.arg(Arg::new("mode")
.index(1))
.arg(Arg::new("debug")
.long("debug"))
.get_matches_from(vec![
"prog", "--debug", "fast"
]);
assert!(m.contains_id("mode"));
assert_eq!(m.value_of("mode"), Some("fast")); // notice index(1) means "first positional"
// *not* first argument
sourcepub fn last(self, yes: bool) -> Self
pub fn last(self, yes: bool) -> Self
This arg is the last, or final, positional argument (i.e. has the highest
index) and is only able to be accessed via the --
syntax (i.e. $ prog args -- last_arg
).
Even, if no other arguments are left to parse, if the user omits the --
syntax
they will receive an UnknownArgument
error. Setting an argument to .last(true)
also
allows one to access this arg early using the --
syntax. Accessing an arg early, even with
the --
syntax is otherwise not possible.
NOTE: This will change the usage string to look like $ prog [OPTIONS] [-- <ARG>]
if
ARG
is marked as .last(true)
.
NOTE: This setting will imply crate::Command::dont_collapse_args_in_usage
because failing
to set this can make the usage string very confusing.
NOTE: This setting only applies to positional arguments, and has no effect on OPTIONS
NOTE: Setting this requires Arg::takes_value
CAUTION: Using this setting and having child subcommands is not
recommended with the exception of also using
crate::Command::args_conflicts_with_subcommands
(or crate::Command::subcommand_negates_reqs
if the argument marked Last
is also
marked Arg::required
)
Examples
Arg::new("args")
.takes_value(true)
.last(true)
Setting last
ensures the arg has the highest index of all positional args
and requires that the --
syntax be used to access it early.
let res = Command::new("prog")
.arg(Arg::new("first"))
.arg(Arg::new("second"))
.arg(Arg::new("third")
.takes_value(true)
.last(true))
.try_get_matches_from(vec![
"prog", "one", "--", "three"
]);
assert!(res.is_ok());
let m = res.unwrap();
assert_eq!(m.value_of("third"), Some("three"));
assert!(m.value_of("second").is_none());
Even if the positional argument marked Last
is the only argument left to parse,
failing to use the --
syntax results in an error.
let res = Command::new("prog")
.arg(Arg::new("first"))
.arg(Arg::new("second"))
.arg(Arg::new("third")
.takes_value(true)
.last(true))
.try_get_matches_from(vec![
"prog", "one", "two", "three"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::UnknownArgument);
sourcepub fn required(self, yes: bool) -> Self
pub fn required(self, yes: bool) -> Self
Specifies that the argument must be present.
Required by default means it is required, when no other conflicting rules or overrides have been evaluated. Conflicting rules take precedence over being required.
Pro tip: Flags (i.e. not positional, or arguments that take values) shouldn’t be required by default. This is because if a flag were to be required, it should simply be implied. No additional information is required from user. Flags by their very nature are simply boolean on/off switches. The only time a user should be required to use a flag is if the operation is destructive in nature, and the user is essentially proving to you, “Yes, I know what I’m doing.”
Examples
Arg::new("config")
.required(true)
Setting required requires that the argument be used at runtime.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.required(true)
.takes_value(true)
.long("config"))
.try_get_matches_from(vec![
"prog", "--config", "file.conf",
]);
assert!(res.is_ok());
Setting required and then not supplying that argument at runtime is an error.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.required(true)
.takes_value(true)
.long("config"))
.try_get_matches_from(vec![
"prog"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::MissingRequiredArgument);
sourcepub fn requires<T: Key>(self, arg_id: T) -> Self
pub fn requires<T: Key>(self, arg_id: T) -> Self
Sets an argument that is required when this one is present
i.e. when using this argument, the following argument must be present.
NOTE: Conflicting rules and override rules take precedence over being required
Examples
Arg::new("config")
.requires("input")
Setting Arg::requires(name)
requires that the argument be used at runtime if the
defining argument is used. If the defining argument isn’t used, the other argument isn’t
required
let res = Command::new("prog")
.arg(Arg::new("cfg")
.takes_value(true)
.requires("input")
.long("config"))
.arg(Arg::new("input"))
.try_get_matches_from(vec![
"prog"
]);
assert!(res.is_ok()); // We didn't use cfg, so input wasn't required
Setting Arg::requires(name)
and not supplying that argument is an error.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.takes_value(true)
.requires("input")
.long("config"))
.arg(Arg::new("input"))
.try_get_matches_from(vec![
"prog", "--config", "file.conf"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::MissingRequiredArgument);
sourcepub fn exclusive(self, yes: bool) -> Self
pub fn exclusive(self, yes: bool) -> Self
This argument must be passed alone; it conflicts with all other arguments.
Examples
Arg::new("config")
.exclusive(true)
Setting an exclusive argument and having any other arguments present at runtime is an error.
let res = Command::new("prog")
.arg(Arg::new("exclusive")
.takes_value(true)
.exclusive(true)
.long("exclusive"))
.arg(Arg::new("debug")
.long("debug"))
.arg(Arg::new("input"))
.try_get_matches_from(vec![
"prog", "--exclusive", "file.conf", "file.txt"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::ArgumentConflict);
sourcepub fn global(self, yes: bool) -> Self
pub fn global(self, yes: bool) -> Self
Specifies that an argument can be matched to all child Subcommand
s.
NOTE: Global arguments only propagate down, not up (to parent commands), however their values once a user uses them will be propagated back up to parents. In effect, this means one should define all global arguments at the top level, however it doesn’t matter where the user uses the global argument.
Examples
Assume an application with two subcommands, and you’d like to define a
--verbose
flag that can be called on any of the subcommands and parent, but you don’t
want to clutter the source with three duplicate Arg
definitions.
let m = Command::new("prog")
.arg(Arg::new("verb")
.long("verbose")
.short('v')
.action(ArgAction::SetTrue)
.global(true))
.subcommand(Command::new("test"))
.subcommand(Command::new("do-stuff"))
.get_matches_from(vec![
"prog", "do-stuff", "--verbose"
]);
assert_eq!(m.subcommand_name(), Some("do-stuff"));
let sub_m = m.subcommand_matches("do-stuff").unwrap();
assert_eq!(*sub_m.get_one::<bool>("verb").expect("defaulted by clap"), true);
sourcepub fn multiple_occurrences(self, yes: bool) -> Self
pub fn multiple_occurrences(self, yes: bool) -> Self
Deprecated, replaced with Arg::action
(Issue #3772)
sourcepub fn max_occurrences(self, qty: usize) -> Self
pub fn max_occurrences(self, qty: usize) -> Self
Deprecated, for flags this is replaced with action(ArgAction::Count).value_parser(value_parser!(u8).range(..max))
sourcepub fn is_set(&self, s: ArgSettings) -> bool
pub fn is_set(&self, s: ArgSettings) -> bool
Check if the ArgSettings
variant is currently set on the argument.
sourcepub fn setting<F>(self, setting: F) -> Self where
F: Into<ArgFlags>,
pub fn setting<F>(self, setting: F) -> Self where
F: Into<ArgFlags>,
Apply a setting to the argument.
See ArgSettings
for a full list of possibilities and examples.
Examples
Arg::new("config")
.setting(ArgSettings::Required)
.setting(ArgSettings::TakesValue)
Arg::new("config")
.setting(ArgSettings::Required | ArgSettings::TakesValue)
sourcepub fn unset_setting<F>(self, setting: F) -> Self where
F: Into<ArgFlags>,
pub fn unset_setting<F>(self, setting: F) -> Self where
F: Into<ArgFlags>,
Remove a setting from the argument.
See ArgSettings
for a full list of possibilities and examples.
Examples
Arg::new("config")
.unset_setting(ArgSettings::Required)
.unset_setting(ArgSettings::TakesValue)
Arg::new("config")
.unset_setting(ArgSettings::Required | ArgSettings::TakesValue)
sourceimpl<'help> Arg<'help>
impl<'help> Arg<'help>
sourcepub fn takes_value(self, yes: bool) -> Self
pub fn takes_value(self, yes: bool) -> Self
Specifies that the argument takes a value at run time.
NOTE: values for arguments may be specified in any of the following methods
- Using a space such as
-o value
or--option value
- Using an equals and no space such as
-o=value
or--option=value
- Use a short and no space such as
-ovalue
NOTE: By default, args which allow multiple values are delimited by commas, meaning
--option=val1,val2,val3
is three values for the --option
argument. If you wish to
change the delimiter to another character you can use Arg::value_delimiter(char)
,
alternatively you can turn delimiting values OFF by using
Arg::use_value_delimiter(false)
Examples
let m = Command::new("prog")
.arg(Arg::new("mode")
.long("mode")
.takes_value(true))
.get_matches_from(vec![
"prog", "--mode", "fast"
]);
assert!(m.contains_id("mode"));
assert_eq!(m.value_of("mode"), Some("fast"));
sourcepub fn action(self, action: ArgAction) -> Self
pub fn action(self, action: ArgAction) -> Self
Specify the behavior when parsing an argument
Examples
let cmd = Command::new("mycmd")
.arg(
Arg::new("flag")
.long("flag")
.action(clap::ArgAction::Set)
);
let matches = cmd.try_get_matches_from(["mycmd", "--flag", "value"]).unwrap();
assert!(matches.contains_id("flag"));
assert_eq!(matches.occurrences_of("flag"), 0);
assert_eq!(
matches.get_many::<String>("flag").unwrap_or_default().map(|v| v.as_str()).collect::<Vec<_>>(),
vec!["value"]
);
sourcepub fn value_parser(self, parser: impl Into<ValueParser>) -> Self
pub fn value_parser(self, parser: impl Into<ValueParser>) -> Self
Specify the type of the argument.
This allows parsing and validating a value before storing it into
ArgMatches
.
See also
value_parser!
for auto-selecting a value parser for a given typeBoolishValueParser
, andFalseyValueParser
for alternativebool
implementationsNonEmptyStringValueParser
for basic validation for strings
RangedI64ValueParser
andRangedU64ValueParser
for numeric rangesEnumValueParser
andPossibleValuesParser
for static enumerated values- or any other
TypedValueParser
implementation
let mut cmd = clap::Command::new("raw")
.arg(
clap::Arg::new("color")
.long("color")
.value_parser(["always", "auto", "never"])
.default_value("auto")
)
.arg(
clap::Arg::new("hostname")
.long("hostname")
.value_parser(clap::builder::NonEmptyStringValueParser::new())
.takes_value(true)
.required(true)
)
.arg(
clap::Arg::new("port")
.long("port")
.value_parser(clap::value_parser!(u16).range(3000..))
.takes_value(true)
.required(true)
);
let m = cmd.try_get_matches_from_mut(
["cmd", "--hostname", "rust-lang.org", "--port", "3001"]
).unwrap();
let color: &String = m.get_one("color")
.expect("default");
assert_eq!(color, "auto");
let hostname: &String = m.get_one("hostname")
.expect("required");
assert_eq!(hostname, "rust-lang.org");
let port: u16 = *m.get_one("port")
.expect("required");
assert_eq!(port, 3001);
sourcepub fn multiple_values(self, yes: bool) -> Self
pub fn multiple_values(self, yes: bool) -> Self
Specifies that the argument may have an unknown number of values
Without any other settings, this argument may appear only once.
For example, --opt val1 val2
is allowed, but --opt val1 val2 --opt val3
is not.
NOTE: Setting this requires Arg::takes_value
.
WARNING:
Setting multiple_values
for an argument that takes a value, but with no other details can
be dangerous in some circumstances. Because multiple values are allowed,
--option val1 val2 val3
is perfectly valid. Be careful when designing a CLI where
positional arguments are also expected as clap
will continue parsing values until one
of the following happens:
- It reaches the maximum number of values
- It reaches a specific number of values
- It finds another flag or option (i.e. something that starts with a
-
) - It reaches a value terminator is reached
Alternatively, require a delimiter between values.
WARNING:
When using args with multiple_values
and subcommands
, one needs to consider the
possibility of an argument value being the same as a valid subcommand. By default clap
will
parse the argument in question as a value only if a value is possible at that moment.
Otherwise it will be parsed as a subcommand. In effect, this means using multiple_values
with no
additional parameters and a value that coincides with a subcommand name, the subcommand
cannot be called unless another argument is passed between them.
As an example, consider a CLI with an option --ui-paths=<paths>...
and subcommand signer
The following would be parsed as values to --ui-paths
.
$ program --ui-paths path1 path2 signer
This is because --ui-paths
accepts multiple values. clap
will continue parsing values
until another argument is reached and it knows --ui-paths
is done parsing.
By adding additional parameters to --ui-paths
we can solve this issue. Consider adding
Arg::number_of_values(1)
or using only ArgAction::Append
. The following are all
valid, and signer
is parsed as a subcommand in the first case, but a value in the second
case.
$ program --ui-paths path1 signer
$ program --ui-paths path1 --ui-paths signer signer
Examples
An example with options
let m = Command::new("prog")
.arg(Arg::new("file")
.takes_value(true)
.multiple_values(true)
.short('F'))
.get_matches_from(vec![
"prog", "-F", "file1", "file2", "file3"
]);
assert!(m.contains_id("file"));
let files: Vec<_> = m.values_of("file").unwrap().collect();
assert_eq!(files, ["file1", "file2", "file3"]);
Although multiple_values
has been specified, we cannot use the argument more than once.
let res = Command::new("prog")
.arg(Arg::new("file")
.takes_value(true)
.multiple_values(true)
.short('F'))
.try_get_matches_from(vec![
"prog", "-F", "file1", "-F", "file2", "-F", "file3"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::UnexpectedMultipleUsage)
A common mistake is to define an option which allows multiple values, and a positional argument.
let m = Command::new("prog")
.arg(Arg::new("file")
.takes_value(true)
.multiple_values(true)
.short('F'))
.arg(Arg::new("word"))
.get_matches_from(vec![
"prog", "-F", "file1", "file2", "file3", "word"
]);
assert!(m.contains_id("file"));
let files: Vec<_> = m.values_of("file").unwrap().collect();
assert_eq!(files, ["file1", "file2", "file3", "word"]); // wait...what?!
assert!(!m.contains_id("word")); // but we clearly used word!
The problem is clap
doesn’t know when to stop parsing values for “files”. This is further
compounded by if we’d said word -F file1 file2
it would have worked fine, so it would
appear to only fail sometimes…not good!
A solution for the example above is to limit how many values with a maximum, or specific
number, or to say ArgAction::Append
is ok, but multiple values is not.
let m = Command::new("prog")
.arg(Arg::new("file")
.takes_value(true)
.action(ArgAction::Append)
.short('F'))
.arg(Arg::new("word"))
.get_matches_from(vec![
"prog", "-F", "file1", "-F", "file2", "-F", "file3", "word"
]);
assert!(m.contains_id("file"));
let files: Vec<_> = m.values_of("file").unwrap().collect();
assert_eq!(files, ["file1", "file2", "file3"]);
assert!(m.contains_id("word"));
assert_eq!(m.value_of("word"), Some("word"));
As a final example, let’s fix the above error and get a pretty message to the user :)
let res = Command::new("prog")
.arg(Arg::new("file")
.takes_value(true)
.action(ArgAction::Append)
.short('F'))
.arg(Arg::new("word"))
.try_get_matches_from(vec![
"prog", "-F", "file1", "file2", "file3", "word"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::UnknownArgument);
sourcepub fn number_of_values(self, qty: usize) -> Self
pub fn number_of_values(self, qty: usize) -> Self
The number of values allowed for this argument.
For example, if you had a
-f <file>
argument where you wanted exactly 3 ‘files’ you would set
.number_of_values(3)
, and this argument wouldn’t be satisfied unless the user provided
3 and only 3 values.
NOTE: Does not require Arg::multiple_occurrences(true)
to be set. Setting
Arg::multiple_occurrences(true)
would allow -f <file> <file> <file> -f <file> <file> <file>
where
as not setting it would only allow one occurrence of this argument.
NOTE: implicitly sets [Arg::takes_value(true)
] and [Arg::multiple_values(true)
].
Examples
Arg::new("file")
.short('f')
.number_of_values(3);
Not supplying the correct number of values is an error
let res = Command::new("prog")
.arg(Arg::new("file")
.takes_value(true)
.number_of_values(2)
.short('F'))
.try_get_matches_from(vec![
"prog", "-F", "file1"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::WrongNumberOfValues);
sourcepub fn max_values(self, qty: usize) -> Self
pub fn max_values(self, qty: usize) -> Self
The maximum number of values are for this argument.
For example, if you had a
-f <file>
argument where you wanted up to 3 ‘files’ you would set .max_values(3)
, and
this argument would be satisfied if the user provided, 1, 2, or 3 values.
NOTE: This does not implicitly set Arg::multiple_occurrences(true)
. This is because
-o val -o val
is multiple occurrences but a single value and -o val1 val2
is a single
occurrence with multiple values. For positional arguments this does set
Arg::multiple_occurrences(true)
because there is no way to determine the difference between multiple
occurrences and multiple values.
Examples
Arg::new("file")
.short('f')
.max_values(3);
Supplying less than the maximum number of values is allowed
let res = Command::new("prog")
.arg(Arg::new("file")
.takes_value(true)
.max_values(3)
.short('F'))
.try_get_matches_from(vec![
"prog", "-F", "file1", "file2"
]);
assert!(res.is_ok());
let m = res.unwrap();
let files: Vec<_> = m.values_of("file").unwrap().collect();
assert_eq!(files, ["file1", "file2"]);
Supplying more than the maximum number of values is an error
let res = Command::new("prog")
.arg(Arg::new("file")
.takes_value(true)
.max_values(2)
.short('F'))
.try_get_matches_from(vec![
"prog", "-F", "file1", "file2", "file3"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::UnknownArgument);
sourcepub fn min_values(self, qty: usize) -> Self
pub fn min_values(self, qty: usize) -> Self
The minimum number of values for this argument.
For example, if you had a
-f <file>
argument where you wanted at least 2 ‘files’ you would set
.min_values(2)
, and this argument would be satisfied if the user provided, 2 or more
values.
NOTE: This does not implicitly set Arg::multiple_occurrences(true)
. This is because
-o val -o val
is multiple occurrences but a single value and -o val1 val2
is a single
occurrence with multiple values. For positional arguments this does set
Arg::multiple_occurrences(true)
because there is no way to determine the difference between multiple
occurrences and multiple values.
NOTE: Passing a non-zero value is not the same as specifying Arg::required(true)
.
This is due to min and max validation only being performed for present arguments,
marking them as required will thus perform validation and a min value of 1
is unnecessary, ignored if not required.
Examples
Arg::new("file")
.short('f')
.min_values(3);
Supplying more than the minimum number of values is allowed
let res = Command::new("prog")
.arg(Arg::new("file")
.takes_value(true)
.min_values(2)
.short('F'))
.try_get_matches_from(vec![
"prog", "-F", "file1", "file2", "file3"
]);
assert!(res.is_ok());
let m = res.unwrap();
let files: Vec<_> = m.values_of("file").unwrap().collect();
assert_eq!(files, ["file1", "file2", "file3"]);
Supplying less than the minimum number of values is an error
let res = Command::new("prog")
.arg(Arg::new("file")
.takes_value(true)
.min_values(2)
.short('F'))
.try_get_matches_from(vec![
"prog", "-F", "file1"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::TooFewValues);
sourcepub fn value_name(self, name: &'help str) -> Self
pub fn value_name(self, name: &'help str) -> Self
Placeholder for the argument’s value in the help message / usage.
This name is cosmetic only; the name is not used to access arguments.
This setting can be very helpful when describing the type of input the user should be
using, such as FILE
, INTERFACE
, etc. Although not required, it’s somewhat convention to
use all capital letters for the value name.
NOTE: implicitly sets Arg::takes_value(true)
Examples
Arg::new("cfg")
.long("config")
.value_name("FILE")
let m = Command::new("prog")
.arg(Arg::new("config")
.long("config")
.value_name("FILE")
.help("Some help text"))
.get_matches_from(vec![
"prog", "--help"
]);
Running the above program produces the following output
valnames
USAGE:
valnames [OPTIONS]
OPTIONS:
--config <FILE> Some help text
-h, --help Print help information
-V, --version Print version information
sourcepub fn value_names(self, names: &[&'help str]) -> Self
pub fn value_names(self, names: &[&'help str]) -> Self
Placeholders for the argument’s values in the help message / usage.
These names are cosmetic only, used for help and usage strings only. The names are not
used to access arguments. The values of the arguments are accessed in numeric order (i.e.
if you specify two names one
and two
one
will be the first matched value, two
will
be the second).
This setting can be very helpful when describing the type of input the user should be
using, such as FILE
, INTERFACE
, etc. Although not required, it’s somewhat convention to
use all capital letters for the value name.
Pro Tip: It may help to use Arg::next_line_help(true)
if there are long, or
multiple value names in order to not throw off the help text alignment of all options.
NOTE: implicitly sets Arg::takes_value(true)
and Arg::multiple_values(true)
.
Examples
Arg::new("speed")
.short('s')
.value_names(&["fast", "slow"]);
let m = Command::new("prog")
.arg(Arg::new("io")
.long("io-files")
.value_names(&["INFILE", "OUTFILE"]))
.get_matches_from(vec![
"prog", "--help"
]);
Running the above program produces the following output
valnames
USAGE:
valnames [OPTIONS]
OPTIONS:
-h, --help Print help information
--io-files <INFILE> <OUTFILE> Some help text
-V, --version Print version information
sourcepub fn value_hint(self, value_hint: ValueHint) -> Self
pub fn value_hint(self, value_hint: ValueHint) -> Self
Provide the shell a hint about how to complete this argument.
See ValueHint
for more information.
NOTE: implicitly sets [Arg::takes_value(true)
].
For example, to take a username as argument:
Arg::new("user")
.short('u')
.long("user")
.value_hint(ValueHint::Username);
To take a full command line and its arguments (for example, when writing a command wrapper):
Command::new("prog")
.trailing_var_arg(true)
.arg(
Arg::new("command")
.takes_value(true)
.multiple_values(true)
.value_hint(ValueHint::CommandWithArguments)
);
sourcepub fn validator<F, O, E>(self, f: F) -> Self where
F: FnMut(&str) -> Result<O, E> + Send + 'help,
E: Into<Box<dyn Error + Send + Sync + 'static>>,
pub fn validator<F, O, E>(self, f: F) -> Self where
F: FnMut(&str) -> Result<O, E> + Send + 'help,
E: Into<Box<dyn Error + Send + Sync + 'static>>,
Deprecated, replaced with [Arg::value_parser(...)
]
sourcepub fn validator_os<F, O, E>(self, f: F) -> Self where
F: FnMut(&OsStr) -> Result<O, E> + Send + 'help,
E: Into<Box<dyn Error + Send + Sync + 'static>>,
pub fn validator_os<F, O, E>(self, f: F) -> Self where
F: FnMut(&OsStr) -> Result<O, E> + Send + 'help,
E: Into<Box<dyn Error + Send + Sync + 'static>>,
Deprecated, replaced with [Arg::value_parser(...)
]
sourcepub fn possible_value<T>(self, value: T) -> Self where
T: Into<PossibleValue<'help>>,
pub fn possible_value<T>(self, value: T) -> Self where
T: Into<PossibleValue<'help>>,
Deprecated, replaced with [Arg::value_parser(PossibleValuesParser::new(...))
]
sourcepub fn possible_values<I, T>(self, values: I) -> Self where
I: IntoIterator<Item = T>,
T: Into<PossibleValue<'help>>,
pub fn possible_values<I, T>(self, values: I) -> Self where
I: IntoIterator<Item = T>,
T: Into<PossibleValue<'help>>,
Deprecated, replaced with [Arg::value_parser(PossibleValuesParser::new(...))
]
sourcepub fn ignore_case(self, yes: bool) -> Self
pub fn ignore_case(self, yes: bool) -> Self
Match values against Arg::possible_values
without matching case.
When other arguments are conditionally required based on the
value of a case-insensitive argument, the equality check done
by Arg::required_if_eq
, Arg::required_if_eq_any
, or
Arg::required_if_eq_all
is case-insensitive.
NOTE: Setting this requires Arg::takes_value
NOTE: To do unicode case folding, enable the unicode
feature flag.
Examples
let m = Command::new("pv")
.arg(Arg::new("option")
.long("option")
.takes_value(true)
.ignore_case(true)
.value_parser(["test123"]))
.get_matches_from(vec![
"pv", "--option", "TeSt123",
]);
assert!(m.value_of("option").unwrap().eq_ignore_ascii_case("test123"));
This setting also works when multiple values can be defined:
let m = Command::new("pv")
.arg(Arg::new("option")
.short('o')
.long("option")
.takes_value(true)
.ignore_case(true)
.multiple_values(true)
.value_parser(["test123", "test321"]))
.get_matches_from(vec![
"pv", "--option", "TeSt123", "teST123", "tESt321"
]);
let matched_vals = m.values_of("option").unwrap().collect::<Vec<_>>();
assert_eq!(&*matched_vals, &["TeSt123", "teST123", "tESt321"]);
sourcepub fn allow_hyphen_values(self, yes: bool) -> Self
pub fn allow_hyphen_values(self, yes: bool) -> Self
Allows values which start with a leading hyphen (-
)
NOTE: Setting this requires Arg::takes_value
WARNING: Take caution when using this setting combined with
Arg::multiple_values
, as this becomes ambiguous $ prog --arg -- -- val
. All
three --, --, val
will be values when the user may have thought the second --
would
constitute the normal, “Only positional args follow” idiom. To fix this, consider using
Arg::multiple_occurrences
which only allows a single value at a time.
WARNING: When building your CLIs, consider the effects of allowing leading hyphens and
the user passing in a value that matches a valid short. For example, prog -opt -F
where
-F
is supposed to be a value, yet -F
is also a valid short for another arg.
Care should be taken when designing these args. This is compounded by the ability to “stack”
short args. I.e. if -val
is supposed to be a value, but -v
, -a
, and -l
are all valid
shorts.
Examples
let m = Command::new("prog")
.arg(Arg::new("pat")
.takes_value(true)
.allow_hyphen_values(true)
.long("pattern"))
.get_matches_from(vec![
"prog", "--pattern", "-file"
]);
assert_eq!(m.value_of("pat"), Some("-file"));
Not setting Arg::allow_hyphen_values(true)
and supplying a value which starts with a
hyphen is an error.
let res = Command::new("prog")
.arg(Arg::new("pat")
.takes_value(true)
.long("pattern"))
.try_get_matches_from(vec![
"prog", "--pattern", "-file"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::UnknownArgument);
sourcepub fn allow_invalid_utf8(self, yes: bool) -> Self
pub fn allow_invalid_utf8(self, yes: bool) -> Self
Deprecated, replaced with [Arg::value_parser(...)
] with either ValueParser::os_string()
or ValueParser::path_buf()
sourcepub fn forbid_empty_values(self, yes: bool) -> Self
pub fn forbid_empty_values(self, yes: bool) -> Self
Deprecated, replaced with [Arg::value_parser(NonEmptyStringValueParser::new())
]
sourcepub fn require_equals(self, yes: bool) -> Self
pub fn require_equals(self, yes: bool) -> Self
Requires that options use the --option=val
syntax
i.e. an equals between the option and associated value.
NOTE: Setting this requires Arg::takes_value
Examples
Setting require_equals
requires that the option have an equals sign between
it and the associated value.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.takes_value(true)
.require_equals(true)
.long("config"))
.try_get_matches_from(vec![
"prog", "--config=file.conf"
]);
assert!(res.is_ok());
Setting require_equals
and not supplying the equals will cause an
error.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.takes_value(true)
.require_equals(true)
.long("config"))
.try_get_matches_from(vec![
"prog", "--config", "file.conf"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::NoEquals);
sourcepub fn use_value_delimiter(self, yes: bool) -> Self
pub fn use_value_delimiter(self, yes: bool) -> Self
Specifies that an argument should allow grouping of multiple values via a delimiter.
i.e. should --option=val1,val2,val3
be parsed as three values (val1
, val2
,
and val3
) or as a single value (val1,val2,val3
). Defaults to using ,
(comma) as the
value delimiter for all arguments that accept values (options and positional arguments)
NOTE: When this setting is used, it will default Arg::value_delimiter
to the comma ,
.
NOTE: Implicitly sets Arg::takes_value
Examples
The following example shows the default behavior.
let delims = Command::new("prog")
.arg(Arg::new("option")
.long("option")
.use_value_delimiter(true)
.takes_value(true))
.get_matches_from(vec![
"prog", "--option=val1,val2,val3",
]);
assert!(delims.contains_id("option"));
assert_eq!(delims.values_of("option").unwrap().collect::<Vec<_>>(), ["val1", "val2", "val3"]);
The next example shows the difference when turning delimiters off. This is the default behavior
let nodelims = Command::new("prog")
.arg(Arg::new("option")
.long("option")
.takes_value(true))
.get_matches_from(vec![
"prog", "--option=val1,val2,val3",
]);
assert!(nodelims.contains_id("option"));
assert_eq!(nodelims.value_of("option").unwrap(), "val1,val2,val3");
sourcepub fn use_delimiter(self, yes: bool) -> Self
pub fn use_delimiter(self, yes: bool) -> Self
Deprecated, replaced with Arg::use_value_delimiter
sourcepub fn value_delimiter(self, d: char) -> Self
pub fn value_delimiter(self, d: char) -> Self
Separator between the arguments values, defaults to ,
(comma).
NOTE: implicitly sets Arg::use_value_delimiter(true)
NOTE: implicitly sets Arg::takes_value(true)
Examples
let m = Command::new("prog")
.arg(Arg::new("config")
.short('c')
.long("config")
.value_delimiter(';'))
.get_matches_from(vec![
"prog", "--config=val1;val2;val3"
]);
assert_eq!(m.values_of("config").unwrap().collect::<Vec<_>>(), ["val1", "val2", "val3"])
sourcepub fn require_value_delimiter(self, yes: bool) -> Self
pub fn require_value_delimiter(self, yes: bool) -> Self
Specifies that multiple values may only be set using the delimiter.
This means if an option is encountered, and no delimiter is found, it is assumed that no additional values for that option follow. This is unlike the default, where it is generally assumed that more values will follow regardless of whether or not a delimiter is used.
NOTE: The default is false
.
NOTE: Setting this requires Arg::use_value_delimiter
and
Arg::takes_value
NOTE: It’s a good idea to inform the user that use of a delimiter is required, either through help text or other means.
Examples
These examples demonstrate what happens when require_delimiter(true)
is used. Notice
everything works in this first example, as we use a delimiter, as expected.
let delims = Command::new("prog")
.arg(Arg::new("opt")
.short('o')
.takes_value(true)
.use_value_delimiter(true)
.require_delimiter(true)
.multiple_values(true))
.get_matches_from(vec![
"prog", "-o", "val1,val2,val3",
]);
assert!(delims.contains_id("opt"));
assert_eq!(delims.values_of("opt").unwrap().collect::<Vec<_>>(), ["val1", "val2", "val3"]);
In this next example, we will not use a delimiter. Notice it’s now an error.
let res = Command::new("prog")
.arg(Arg::new("opt")
.short('o')
.takes_value(true)
.use_value_delimiter(true)
.require_delimiter(true))
.try_get_matches_from(vec![
"prog", "-o", "val1", "val2", "val3",
]);
assert!(res.is_err());
let err = res.unwrap_err();
assert_eq!(err.kind(), ErrorKind::UnknownArgument);
What’s happening is -o
is getting val1
, and because delimiters are required yet none
were present, it stops parsing -o
. At this point it reaches val2
and because no
positional arguments have been defined, it’s an error of an unexpected argument.
In this final example, we contrast the above with clap
’s default behavior where the above
is not an error.
let delims = Command::new("prog")
.arg(Arg::new("opt")
.short('o')
.takes_value(true)
.multiple_values(true))
.get_matches_from(vec![
"prog", "-o", "val1", "val2", "val3",
]);
assert!(delims.contains_id("opt"));
assert_eq!(delims.values_of("opt").unwrap().collect::<Vec<_>>(), ["val1", "val2", "val3"]);
sourcepub fn require_delimiter(self, yes: bool) -> Self
pub fn require_delimiter(self, yes: bool) -> Self
Deprecated, replaced with Arg::require_value_delimiter
sourcepub fn value_terminator(self, term: &'help str) -> Self
pub fn value_terminator(self, term: &'help str) -> Self
Sentinel to stop parsing multiple values of a give argument.
By default when
one sets multiple_values(true)
on an argument, clap will continue parsing values for that
argument until it reaches another valid argument, or one of the other more specific settings
for multiple values is used (such as min_values
, max_values
or
number_of_values
).
NOTE: This setting only applies to options and positional arguments
NOTE: When the terminator is passed in on the command line, it is not stored as one of the values
Examples
Arg::new("vals")
.takes_value(true)
.multiple_values(true)
.value_terminator(";")
The following example uses two arguments, a sequence of commands, and the location in which to perform them
let m = Command::new("prog")
.arg(Arg::new("cmds")
.takes_value(true)
.multiple_values(true)
.allow_hyphen_values(true)
.value_terminator(";"))
.arg(Arg::new("location"))
.get_matches_from(vec![
"prog", "find", "-type", "f", "-name", "special", ";", "/home/clap"
]);
let cmds: Vec<_> = m.values_of("cmds").unwrap().collect();
assert_eq!(&cmds, &["find", "-type", "f", "-name", "special"]);
assert_eq!(m.value_of("location"), Some("/home/clap"));
sourcepub fn raw(self, yes: bool) -> Self
pub fn raw(self, yes: bool) -> Self
Consume all following arguments.
Do not be parse them individually, but rather pass them in entirety.
It is worth noting that setting this requires all values to come after a --
to indicate
they should all be captured. For example:
--foo something -- -v -v -v -b -b -b --baz -q -u -x
Will result in everything after --
to be considered one raw argument. This behavior
may not be exactly what you are expecting and using crate::Command::trailing_var_arg
may be more appropriate.
NOTE: Implicitly sets Arg::takes_value(true)
Arg::multiple_values(true)
,
Arg::allow_hyphen_values(true)
, and Arg::last(true)
when set to true
.
sourcepub fn default_value(self, val: &'help str) -> Self
pub fn default_value(self, val: &'help str) -> Self
Value for the argument when not present.
NOTE: If the user does not use this argument at runtime, ArgMatches::occurrences_of
will return 0
even though the ArgMatches::value_of
will return the default specified.
NOTE: If the user does not use this argument at runtime ArgMatches::contains_id
will
still return true
. If you wish to determine whether the argument was used at runtime or
not, consider ArgMatches::value_source
.
NOTE: This setting is perfectly compatible with Arg::default_value_if
but slightly
different. Arg::default_value
only takes effect when the user has not provided this arg
at runtime. Arg::default_value_if
however only takes effect when the user has not provided
a value at runtime and these other conditions are met as well. If you have set
Arg::default_value
and Arg::default_value_if
, and the user did not provide this arg
at runtime, nor were the conditions met for Arg::default_value_if
, the Arg::default_value
will be applied.
NOTE: This implicitly sets Arg::takes_value(true)
.
Examples
First we use the default value without providing any value at runtime.
let m = Command::new("prog")
.arg(Arg::new("opt")
.long("myopt")
.default_value("myval"))
.get_matches_from(vec![
"prog"
]);
assert_eq!(m.value_of("opt"), Some("myval"));
assert!(m.contains_id("opt"));
assert_eq!(m.value_source("opt"), Some(ValueSource::DefaultValue));
Next we provide a value at runtime to override the default.
let m = Command::new("prog")
.arg(Arg::new("opt")
.long("myopt")
.default_value("myval"))
.get_matches_from(vec![
"prog", "--myopt=non_default"
]);
assert_eq!(m.value_of("opt"), Some("non_default"));
assert!(m.contains_id("opt"));
assert_eq!(m.value_source("opt"), Some(ValueSource::CommandLine));
sourcepub fn default_value_os(self, val: &'help OsStr) -> Self
pub fn default_value_os(self, val: &'help OsStr) -> Self
Value for the argument when not present.
See Arg::default_value
.
sourcepub fn default_values(self, vals: &[&'help str]) -> Self
pub fn default_values(self, vals: &[&'help str]) -> Self
Value for the argument when not present.
See Arg::default_value
.
sourcepub fn default_values_os(self, vals: &[&'help OsStr]) -> Self
pub fn default_values_os(self, vals: &[&'help OsStr]) -> Self
Value for the argument when not present.
See Arg::default_values
.
sourcepub fn default_missing_value(self, val: &'help str) -> Self
pub fn default_missing_value(self, val: &'help str) -> Self
Value for the argument when the flag is present but no value is specified.
This configuration option is often used to give the user a shortcut and allow them to
efficiently specify an option argument without requiring an explicitly value. The --color
argument is a common example. By, supplying an default, such as default_missing_value("always")
,
the user can quickly just add --color
to the command line to produce the desired color output.
NOTE: using this configuration option requires the use of the .min_values(0)
and the
.require_equals(true)
configuration option. These are required in order to unambiguously
determine what, if any, value was supplied for the argument.
Examples
For POSIX style --color
:
fn cli() -> Command<'static> {
Command::new("prog")
.arg(Arg::new("color").long("color")
.value_name("WHEN")
.value_parser(["always", "auto", "never"])
.default_value("auto")
.min_values(0)
.require_equals(true)
.default_missing_value("always")
.help("Specify WHEN to colorize output.")
)
}
// first, we'll provide no arguments
let m = cli().get_matches_from(vec![
"prog"
]);
assert_eq!(m.value_of("color"), Some("auto"));
assert_eq!(m.value_source("color"), Some(ValueSource::DefaultValue));
// next, we'll provide a runtime value to override the default (as usually done).
let m = cli().get_matches_from(vec![
"prog", "--color=never"
]);
assert_eq!(m.value_of("color"), Some("never"));
assert_eq!(m.value_source("color"), Some(ValueSource::CommandLine));
// finally, we will use the shortcut and only provide the argument without a value.
let m = cli().get_matches_from(vec![
"prog", "--color"
]);
assert_eq!(m.value_of("color"), Some("always"));
assert_eq!(m.value_source("color"), Some(ValueSource::CommandLine));
For bool literals:
fn cli() -> Command<'static> {
Command::new("prog")
.arg(Arg::new("create").long("create")
.value_name("BOOL")
.value_parser(value_parser!(bool))
.min_values(0)
.require_equals(true)
.default_missing_value("true")
)
}
// first, we'll provide no arguments
let m = cli().get_matches_from(vec![
"prog"
]);
assert_eq!(m.get_one::<bool>("create").copied(), None);
// next, we'll provide a runtime value to override the default (as usually done).
let m = cli().get_matches_from(vec![
"prog", "--create=false"
]);
assert_eq!(m.get_one::<bool>("create").copied(), Some(false));
assert_eq!(m.value_source("create"), Some(ValueSource::CommandLine));
// finally, we will use the shortcut and only provide the argument without a value.
let m = cli().get_matches_from(vec![
"prog", "--create"
]);
assert_eq!(m.get_one::<bool>("create").copied(), Some(true));
assert_eq!(m.value_source("create"), Some(ValueSource::CommandLine));
sourcepub fn default_missing_value_os(self, val: &'help OsStr) -> Self
pub fn default_missing_value_os(self, val: &'help OsStr) -> Self
Value for the argument when the flag is present but no value is specified.
sourcepub fn default_missing_values(self, vals: &[&'help str]) -> Self
pub fn default_missing_values(self, vals: &[&'help str]) -> Self
Value for the argument when the flag is present but no value is specified.
sourcepub fn default_missing_values_os(self, vals: &[&'help OsStr]) -> Self
pub fn default_missing_values_os(self, vals: &[&'help OsStr]) -> Self
Value for the argument when the flag is present but no value is specified.
sourceimpl<'help> Arg<'help>
impl<'help> Arg<'help>
sourcepub fn help(self, h: impl Into<Option<&'help str>>) -> Self
pub fn help(self, h: impl Into<Option<&'help str>>) -> Self
Sets the description of the argument for short help (-h
).
Typically, this is a short (one line) description of the arg.
If Arg::long_help
is not specified, this message will be displayed for --help
.
NOTE: Only Arg::help
is used in completion script generation in order to be concise
Examples
Any valid UTF-8 is allowed in the help text. The one exception is when one wishes to include a newline in the help text and have the following text be properly aligned with all the other help text.
Setting help
displays a short message to the side of the argument when the user passes
-h
or --help
(by default).
let m = Command::new("prog")
.arg(Arg::new("cfg")
.long("config")
.help("Some help text describing the --config arg"))
.get_matches_from(vec![
"prog", "--help"
]);
The above example displays
helptest
USAGE:
helptest [OPTIONS]
OPTIONS:
--config Some help text describing the --config arg
-h, --help Print help information
-V, --version Print version information
sourcepub fn long_help(self, h: impl Into<Option<&'help str>>) -> Self
pub fn long_help(self, h: impl Into<Option<&'help str>>) -> Self
Sets the description of the argument for long help (--help
).
Typically this a more detailed (multi-line) message that describes the arg.
If Arg::help
is not specified, this message will be displayed for -h
.
NOTE: Only Arg::help
is used in completion script generation in order to be concise
Examples
Any valid UTF-8 is allowed in the help text. The one exception is when one wishes to include a newline in the help text and have the following text be properly aligned with all the other help text.
Setting help
displays a short message to the side of the argument when the user passes
-h
or --help
(by default).
let m = Command::new("prog")
.arg(Arg::new("cfg")
.long("config")
.long_help(
"The config file used by the myprog must be in JSON format
with only valid keys and may not contain other nonsense
that cannot be read by this program. Obviously I'm going on
and on, so I'll stop now."))
.get_matches_from(vec![
"prog", "--help"
]);
The above example displays
prog
USAGE:
prog [OPTIONS]
OPTIONS:
--config
The config file used by the myprog must be in JSON format
with only valid keys and may not contain other nonsense
that cannot be read by this program. Obviously I'm going on
and on, so I'll stop now.
-h, --help
Print help information
-V, --version
Print version information
sourcepub fn display_order(self, ord: usize) -> Self
pub fn display_order(self, ord: usize) -> Self
Allows custom ordering of args within the help message.
Args with a lower value will be displayed first in the help message. This is helpful when one would like to emphasise frequently used args, or prioritize those towards the top of the list. Args with duplicate display orders will be displayed in alphabetical order.
NOTE: The default is 999 for all arguments.
NOTE: This setting is ignored for positional arguments which are always displayed in index order.
Examples
let m = Command::new("prog")
.arg(Arg::new("a") // Typically args are grouped alphabetically by name.
// Args without a display_order have a value of 999 and are
// displayed alphabetically with all other 999 valued args.
.long("long-option")
.short('o')
.takes_value(true)
.help("Some help and text"))
.arg(Arg::new("b")
.long("other-option")
.short('O')
.takes_value(true)
.display_order(1) // In order to force this arg to appear *first*
// all we have to do is give it a value lower than 999.
// Any other args with a value of 1 will be displayed
// alphabetically with this one...then 2 values, then 3, etc.
.help("I should be first!"))
.get_matches_from(vec![
"prog", "--help"
]);
The above example displays the following help message
cust-ord
USAGE:
cust-ord [OPTIONS]
OPTIONS:
-h, --help Print help information
-V, --version Print version information
-O, --other-option <b> I should be first!
-o, --long-option <a> Some help and text
sourcepub fn help_heading<O>(self, heading: O) -> Self where
O: Into<Option<&'help str>>,
pub fn help_heading<O>(self, heading: O) -> Self where
O: Into<Option<&'help str>>,
Override the current help section.
sourcepub fn next_line_help(self, yes: bool) -> Self
pub fn next_line_help(self, yes: bool) -> Self
Render the help on the line after the argument.
This can be helpful for arguments with very long or complex help messages. This can also be helpful for arguments with very long flag names, or many/long value names.
NOTE: To apply this setting to all arguments and subcommands, consider using
crate::Command::next_line_help
Examples
let m = Command::new("prog")
.arg(Arg::new("opt")
.long("long-option-flag")
.short('o')
.takes_value(true)
.next_line_help(true)
.value_names(&["value1", "value2"])
.help("Some really long help and complex\n\
help that makes more sense to be\n\
on a line after the option"))
.get_matches_from(vec![
"prog", "--help"
]);
The above example displays the following help message
nlh
USAGE:
nlh [OPTIONS]
OPTIONS:
-h, --help Print help information
-V, --version Print version information
-o, --long-option-flag <value1> <value2>
Some really long help and complex
help that makes more sense to be
on a line after the option
sourcepub fn hide(self, yes: bool) -> Self
pub fn hide(self, yes: bool) -> Self
Do not display the argument in help message.
NOTE: This does not hide the argument from usage strings on error
Examples
Setting Hidden
will hide the argument when displaying help text
let m = Command::new("prog")
.arg(Arg::new("cfg")
.long("config")
.hide(true)
.help("Some help text describing the --config arg"))
.get_matches_from(vec![
"prog", "--help"
]);
The above example displays
helptest
USAGE:
helptest [OPTIONS]
OPTIONS:
-h, --help Print help information
-V, --version Print version information
sourcepub fn hide_possible_values(self, yes: bool) -> Self
pub fn hide_possible_values(self, yes: bool) -> Self
Do not display the possible values in the help message.
This is useful for args with many values, or ones which are explained elsewhere in the help text.
NOTE: Setting this requires Arg::takes_value
To set this for all arguments, see
Command::hide_possible_values
.
Examples
let m = Command::new("prog")
.arg(Arg::new("mode")
.long("mode")
.value_parser(["fast", "slow"])
.takes_value(true)
.hide_possible_values(true));
If we were to run the above program with --help
the [values: fast, slow]
portion of
the help text would be omitted.
sourcepub fn hide_default_value(self, yes: bool) -> Self
pub fn hide_default_value(self, yes: bool) -> Self
Do not display the default value of the argument in the help message.
This is useful when default behavior of an arg is explained elsewhere in the help text.
NOTE: Setting this requires Arg::takes_value
Examples
let m = Command::new("connect")
.arg(Arg::new("host")
.long("host")
.default_value("localhost")
.takes_value(true)
.hide_default_value(true));
If we were to run the above program with --help
the [default: localhost]
portion of
the help text would be omitted.
sourcepub fn hide_short_help(self, yes: bool) -> Self
pub fn hide_short_help(self, yes: bool) -> Self
Hides an argument from short help (-h
).
NOTE: This does not hide the argument from usage strings on error
NOTE: Setting this option will cause next-line-help output style to be used
when long help (--help
) is called.
Examples
Arg::new("debug")
.hide_short_help(true);
Setting hide_short_help(true)
will hide the argument when displaying short help text
let m = Command::new("prog")
.arg(Arg::new("cfg")
.long("config")
.hide_short_help(true)
.help("Some help text describing the --config arg"))
.get_matches_from(vec![
"prog", "-h"
]);
The above example displays
helptest
USAGE:
helptest [OPTIONS]
OPTIONS:
-h, --help Print help information
-V, --version Print version information
However, when –help is called
let m = Command::new("prog")
.arg(Arg::new("cfg")
.long("config")
.hide_short_help(true)
.help("Some help text describing the --config arg"))
.get_matches_from(vec![
"prog", "--help"
]);
Then the following would be displayed
helptest
USAGE:
helptest [OPTIONS]
OPTIONS:
--config Some help text describing the --config arg
-h, --help Print help information
-V, --version Print version information
sourcepub fn hide_long_help(self, yes: bool) -> Self
pub fn hide_long_help(self, yes: bool) -> Self
Hides an argument from long help (--help
).
NOTE: This does not hide the argument from usage strings on error
NOTE: Setting this option will cause next-line-help output style to be used
when long help (--help
) is called.
Examples
Setting hide_long_help(true)
will hide the argument when displaying long help text
let m = Command::new("prog")
.arg(Arg::new("cfg")
.long("config")
.hide_long_help(true)
.help("Some help text describing the --config arg"))
.get_matches_from(vec![
"prog", "--help"
]);
The above example displays
helptest
USAGE:
helptest [OPTIONS]
OPTIONS:
-h, --help Print help information
-V, --version Print version information
However, when -h is called
let m = Command::new("prog")
.arg(Arg::new("cfg")
.long("config")
.hide_long_help(true)
.help("Some help text describing the --config arg"))
.get_matches_from(vec![
"prog", "-h"
]);
Then the following would be displayed
helptest
USAGE:
helptest [OPTIONS]
OPTIONS:
--config Some help text describing the --config arg
-h, --help Print help information
-V, --version Print version information
sourceimpl<'help> Arg<'help>
impl<'help> Arg<'help>
sourcepub fn group<T: Key>(self, group_id: T) -> Self
pub fn group<T: Key>(self, group_id: T) -> Self
The name of the ArgGroup
the argument belongs to.
Examples
Arg::new("debug")
.long("debug")
.group("mode")
Multiple arguments can be a member of a single group and then the group checked as if it was one of said arguments.
let m = Command::new("prog")
.arg(Arg::new("debug")
.long("debug")
.group("mode"))
.arg(Arg::new("verbose")
.long("verbose")
.group("mode"))
.get_matches_from(vec![
"prog", "--debug"
]);
assert!(m.contains_id("mode"));
sourcepub fn groups<T: Key>(self, group_ids: &[T]) -> Self
pub fn groups<T: Key>(self, group_ids: &[T]) -> Self
The names of ArgGroup
’s the argument belongs to.
Examples
Arg::new("debug")
.long("debug")
.groups(&["mode", "verbosity"])
Arguments can be members of multiple groups and then the group checked as if it was one of said arguments.
let m = Command::new("prog")
.arg(Arg::new("debug")
.long("debug")
.groups(&["mode", "verbosity"]))
.arg(Arg::new("verbose")
.long("verbose")
.groups(&["mode", "verbosity"]))
.get_matches_from(vec![
"prog", "--debug"
]);
assert!(m.contains_id("mode"));
assert!(m.contains_id("verbosity"));
sourcepub fn default_value_if<T: Key>(
self,
arg_id: T,
val: Option<&'help str>,
default: Option<&'help str>
) -> Self
pub fn default_value_if<T: Key>(
self,
arg_id: T,
val: Option<&'help str>,
default: Option<&'help str>
) -> Self
Specifies the value of the argument if arg
has been used at runtime.
If val
is set to None
, arg
only needs to be present. If val
is set to "some-val"
then arg
must be present at runtime and have the value val
.
If default
is set to None
, default_value
will be removed.
NOTE: This setting is perfectly compatible with Arg::default_value
but slightly
different. Arg::default_value
only takes effect when the user has not provided this arg
at runtime. This setting however only takes effect when the user has not provided a value at
runtime and these other conditions are met as well. If you have set Arg::default_value
and Arg::default_value_if
, and the user did not provide this arg at runtime, nor were
the conditions met for Arg::default_value_if
, the Arg::default_value
will be applied.
NOTE: This implicitly sets Arg::takes_value(true)
.
Examples
First we use the default value only if another arg is present at runtime.
let m = Command::new("prog")
.arg(Arg::new("flag")
.long("flag"))
.arg(Arg::new("other")
.long("other")
.default_value_if("flag", None, Some("default")))
.get_matches_from(vec![
"prog", "--flag"
]);
assert_eq!(m.value_of("other"), Some("default"));
Next we run the same test, but without providing --flag
.
let m = Command::new("prog")
.arg(Arg::new("flag")
.long("flag"))
.arg(Arg::new("other")
.long("other")
.default_value_if("flag", None, Some("default")))
.get_matches_from(vec![
"prog"
]);
assert_eq!(m.value_of("other"), None);
Now lets only use the default value if --opt
contains the value special
.
let m = Command::new("prog")
.arg(Arg::new("opt")
.takes_value(true)
.long("opt"))
.arg(Arg::new("other")
.long("other")
.default_value_if("opt", Some("special"), Some("default")))
.get_matches_from(vec![
"prog", "--opt", "special"
]);
assert_eq!(m.value_of("other"), Some("default"));
We can run the same test and provide any value other than special
and we won’t get a
default value.
let m = Command::new("prog")
.arg(Arg::new("opt")
.takes_value(true)
.long("opt"))
.arg(Arg::new("other")
.long("other")
.default_value_if("opt", Some("special"), Some("default")))
.get_matches_from(vec![
"prog", "--opt", "hahaha"
]);
assert_eq!(m.value_of("other"), None);
If we want to unset the default value for an Arg based on the presence or value of some other Arg.
let m = Command::new("prog")
.arg(Arg::new("flag")
.long("flag"))
.arg(Arg::new("other")
.long("other")
.default_value("default")
.default_value_if("flag", None, None))
.get_matches_from(vec![
"prog", "--flag"
]);
assert_eq!(m.value_of("other"), None);
sourcepub fn default_value_if_os<T: Key>(
self,
arg_id: T,
val: Option<&'help OsStr>,
default: Option<&'help OsStr>
) -> Self
pub fn default_value_if_os<T: Key>(
self,
arg_id: T,
val: Option<&'help OsStr>,
default: Option<&'help OsStr>
) -> Self
Provides a conditional default value in the exact same manner as Arg::default_value_if
only using OsStr
s instead.
sourcepub fn default_value_ifs<T: Key>(
self,
ifs: &[(T, Option<&'help str>, Option<&'help str>)]
) -> Self
pub fn default_value_ifs<T: Key>(
self,
ifs: &[(T, Option<&'help str>, Option<&'help str>)]
) -> Self
Specifies multiple values and conditions in the same manner as Arg::default_value_if
.
The method takes a slice of tuples in the (arg, Option<val>, default)
format.
NOTE: The conditions are stored in order and evaluated in the same order. I.e. the first if multiple conditions are true, the first one found will be applied and the ultimate value.
Examples
First we use the default value only if another arg is present at runtime.
let m = Command::new("prog")
.arg(Arg::new("flag")
.long("flag"))
.arg(Arg::new("opt")
.long("opt")
.takes_value(true))
.arg(Arg::new("other")
.long("other")
.default_value_ifs(&[
("flag", None, Some("default")),
("opt", Some("channal"), Some("chan")),
]))
.get_matches_from(vec![
"prog", "--opt", "channal"
]);
assert_eq!(m.value_of("other"), Some("chan"));
Next we run the same test, but without providing --flag
.
let m = Command::new("prog")
.arg(Arg::new("flag")
.long("flag"))
.arg(Arg::new("other")
.long("other")
.default_value_ifs(&[
("flag", None, Some("default")),
("opt", Some("channal"), Some("chan")),
]))
.get_matches_from(vec![
"prog"
]);
assert_eq!(m.value_of("other"), None);
We can also see that these values are applied in order, and if more than one condition is true, only the first evaluated “wins”
let m = Command::new("prog")
.arg(Arg::new("flag")
.long("flag"))
.arg(Arg::new("opt")
.long("opt")
.takes_value(true))
.arg(Arg::new("other")
.long("other")
.default_value_ifs(&[
("flag", None, Some("default")),
("opt", Some("channal"), Some("chan")),
]))
.get_matches_from(vec![
"prog", "--opt", "channal", "--flag"
]);
assert_eq!(m.value_of("other"), Some("default"));
sourcepub fn default_value_ifs_os<T: Key>(
self,
ifs: &[(T, Option<&'help OsStr>, Option<&'help OsStr>)]
) -> Self
pub fn default_value_ifs_os<T: Key>(
self,
ifs: &[(T, Option<&'help OsStr>, Option<&'help OsStr>)]
) -> Self
Provides multiple conditional default values in the exact same manner as
Arg::default_value_ifs
only using OsStr
s instead.
sourcepub fn required_unless_present<T: Key>(self, arg_id: T) -> Self
pub fn required_unless_present<T: Key>(self, arg_id: T) -> Self
Set this arg as required as long as the specified argument is not present at runtime.
Pro Tip: Using Arg::required_unless_present
implies Arg::required
and is therefore not
mandatory to also set.
Examples
Arg::new("config")
.required_unless_present("debug")
In the following example, the required argument is not provided,
but it’s not an error because the unless
arg has been supplied.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.required_unless_present("dbg")
.takes_value(true)
.long("config"))
.arg(Arg::new("dbg")
.long("debug"))
.try_get_matches_from(vec![
"prog", "--debug"
]);
assert!(res.is_ok());
Setting Arg::required_unless_present(name)
and not supplying name
or this arg is an error.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.required_unless_present("dbg")
.takes_value(true)
.long("config"))
.arg(Arg::new("dbg")
.long("debug"))
.try_get_matches_from(vec![
"prog"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::MissingRequiredArgument);
sourcepub fn required_unless_present_all<T, I>(self, names: I) -> Self where
I: IntoIterator<Item = T>,
T: Key,
pub fn required_unless_present_all<T, I>(self, names: I) -> Self where
I: IntoIterator<Item = T>,
T: Key,
Sets this arg as required unless all of the specified arguments are present at runtime.
In other words, parsing will succeed only if user either
- supplies the
self
arg. - supplies all of the
names
arguments.
NOTE: If you wish for this argument to only be required unless any of these args are
present see Arg::required_unless_present_any
Examples
Arg::new("config")
.required_unless_present_all(&["cfg", "dbg"])
In the following example, the required argument is not provided, but it’s not an error
because all of the names
args have been supplied.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.required_unless_present_all(&["dbg", "infile"])
.takes_value(true)
.long("config"))
.arg(Arg::new("dbg")
.long("debug"))
.arg(Arg::new("infile")
.short('i')
.takes_value(true))
.try_get_matches_from(vec![
"prog", "--debug", "-i", "file"
]);
assert!(res.is_ok());
Setting Arg::required_unless_present_all(names)
and not supplying
either all of unless
args or the self
arg is an error.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.required_unless_present_all(&["dbg", "infile"])
.takes_value(true)
.long("config"))
.arg(Arg::new("dbg")
.long("debug"))
.arg(Arg::new("infile")
.short('i')
.takes_value(true))
.try_get_matches_from(vec![
"prog"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::MissingRequiredArgument);
sourcepub fn required_unless_present_any<T, I>(self, names: I) -> Self where
I: IntoIterator<Item = T>,
T: Key,
pub fn required_unless_present_any<T, I>(self, names: I) -> Self where
I: IntoIterator<Item = T>,
T: Key,
Sets this arg as required unless any of the specified arguments are present at runtime.
In other words, parsing will succeed only if user either
- supplies the
self
arg. - supplies one or more of the
unless
arguments.
NOTE: If you wish for this argument to be required unless all of these args are
present see Arg::required_unless_present_all
Examples
Arg::new("config")
.required_unless_present_any(&["cfg", "dbg"])
Setting Arg::required_unless_present_any(names)
requires that the argument be used at runtime
unless at least one of the args in names
are present. In the following example, the
required argument is not provided, but it’s not an error because one the unless
args
have been supplied.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.required_unless_present_any(&["dbg", "infile"])
.takes_value(true)
.long("config"))
.arg(Arg::new("dbg")
.long("debug"))
.arg(Arg::new("infile")
.short('i')
.takes_value(true))
.try_get_matches_from(vec![
"prog", "--debug"
]);
assert!(res.is_ok());
Setting Arg::required_unless_present_any(names)
and not supplying at least one of names
or this arg is an error.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.required_unless_present_any(&["dbg", "infile"])
.takes_value(true)
.long("config"))
.arg(Arg::new("dbg")
.long("debug"))
.arg(Arg::new("infile")
.short('i')
.takes_value(true))
.try_get_matches_from(vec![
"prog"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::MissingRequiredArgument);
sourcepub fn required_if_eq<T: Key>(self, arg_id: T, val: &'help str) -> Self
pub fn required_if_eq<T: Key>(self, arg_id: T, val: &'help str) -> Self
This argument is required only if the specified arg
is present at runtime and its value
equals val
.
Examples
Arg::new("config")
.required_if_eq("other_arg", "value")
let res = Command::new("prog")
.arg(Arg::new("cfg")
.takes_value(true)
.required_if_eq("other", "special")
.long("config"))
.arg(Arg::new("other")
.long("other")
.takes_value(true))
.try_get_matches_from(vec![
"prog", "--other", "not-special"
]);
assert!(res.is_ok()); // We didn't use --other=special, so "cfg" wasn't required
let res = Command::new("prog")
.arg(Arg::new("cfg")
.takes_value(true)
.required_if_eq("other", "special")
.long("config"))
.arg(Arg::new("other")
.long("other")
.takes_value(true))
.try_get_matches_from(vec![
"prog", "--other", "special"
]);
// We did use --other=special so "cfg" had become required but was missing.
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::MissingRequiredArgument);
let res = Command::new("prog")
.arg(Arg::new("cfg")
.takes_value(true)
.required_if_eq("other", "special")
.long("config"))
.arg(Arg::new("other")
.long("other")
.takes_value(true))
.try_get_matches_from(vec![
"prog", "--other", "SPECIAL"
]);
// By default, the comparison is case-sensitive, so "cfg" wasn't required
assert!(res.is_ok());
let res = Command::new("prog")
.arg(Arg::new("cfg")
.takes_value(true)
.required_if_eq("other", "special")
.long("config"))
.arg(Arg::new("other")
.long("other")
.ignore_case(true)
.takes_value(true))
.try_get_matches_from(vec![
"prog", "--other", "SPECIAL"
]);
// However, case-insensitive comparisons can be enabled. This typically occurs when using Arg::possible_values().
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::MissingRequiredArgument);
sourcepub fn required_if_eq_any<T: Key>(self, ifs: &[(T, &'help str)]) -> Self
pub fn required_if_eq_any<T: Key>(self, ifs: &[(T, &'help str)]) -> Self
Specify this argument is required based on multiple conditions.
The conditions are set up in a (arg, val)
style tuple. The requirement will only become
valid if one of the specified arg
’s value equals its corresponding val
.
Examples
Arg::new("config")
.required_if_eq_any(&[
("extra", "val"),
("option", "spec")
])
Setting Arg::required_if_eq_any(&[(arg, val)])
makes this arg required if any of the arg
s
are used at runtime and it’s corresponding value is equal to val
. If the arg
’s value is
anything other than val
, this argument isn’t required.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.required_if_eq_any(&[
("extra", "val"),
("option", "spec")
])
.takes_value(true)
.long("config"))
.arg(Arg::new("extra")
.takes_value(true)
.long("extra"))
.arg(Arg::new("option")
.takes_value(true)
.long("option"))
.try_get_matches_from(vec![
"prog", "--option", "other"
]);
assert!(res.is_ok()); // We didn't use --option=spec, or --extra=val so "cfg" isn't required
Setting Arg::required_if_eq_any(&[(arg, val)])
and having any of the arg
s used with its
value of val
but not using this arg is an error.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.required_if_eq_any(&[
("extra", "val"),
("option", "spec")
])
.takes_value(true)
.long("config"))
.arg(Arg::new("extra")
.takes_value(true)
.long("extra"))
.arg(Arg::new("option")
.takes_value(true)
.long("option"))
.try_get_matches_from(vec![
"prog", "--option", "spec"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::MissingRequiredArgument);
sourcepub fn required_if_eq_all<T: Key>(self, ifs: &[(T, &'help str)]) -> Self
pub fn required_if_eq_all<T: Key>(self, ifs: &[(T, &'help str)]) -> Self
Specify this argument is required based on multiple conditions.
The conditions are set up in a (arg, val)
style tuple. The requirement will only become
valid if every one of the specified arg
’s value equals its corresponding val
.
Examples
Arg::new("config")
.required_if_eq_all(&[
("extra", "val"),
("option", "spec")
])
Setting Arg::required_if_eq_all(&[(arg, val)])
makes this arg required if all of the arg
s
are used at runtime and every value is equal to its corresponding val
. If the arg
’s value is
anything other than val
, this argument isn’t required.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.required_if_eq_all(&[
("extra", "val"),
("option", "spec")
])
.takes_value(true)
.long("config"))
.arg(Arg::new("extra")
.takes_value(true)
.long("extra"))
.arg(Arg::new("option")
.takes_value(true)
.long("option"))
.try_get_matches_from(vec![
"prog", "--option", "spec"
]);
assert!(res.is_ok()); // We didn't use --option=spec --extra=val so "cfg" isn't required
Setting Arg::required_if_eq_all(&[(arg, val)])
and having all of the arg
s used with its
value of val
but not using this arg is an error.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.required_if_eq_all(&[
("extra", "val"),
("option", "spec")
])
.takes_value(true)
.long("config"))
.arg(Arg::new("extra")
.takes_value(true)
.long("extra"))
.arg(Arg::new("option")
.takes_value(true)
.long("option"))
.try_get_matches_from(vec![
"prog", "--extra", "val", "--option", "spec"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::MissingRequiredArgument);
sourcepub fn requires_if<T: Key>(self, val: &'help str, arg_id: T) -> Self
pub fn requires_if<T: Key>(self, val: &'help str, arg_id: T) -> Self
Require another argument if this arg was present at runtime and its value equals to val
.
This method takes value, another_arg
pair. At runtime, clap will check
if this arg (self
) is present and its value equals to val
.
If it does, another_arg
will be marked as required.
Examples
Arg::new("config")
.requires_if("val", "arg")
Setting Arg::requires_if(val, arg)
requires that the arg
be used at runtime if the
defining argument’s value is equal to val
. If the defining argument is anything other than
val
, the other argument isn’t required.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.takes_value(true)
.requires_if("my.cfg", "other")
.long("config"))
.arg(Arg::new("other"))
.try_get_matches_from(vec![
"prog", "--config", "some.cfg"
]);
assert!(res.is_ok()); // We didn't use --config=my.cfg, so other wasn't required
Setting Arg::requires_if(val, arg)
and setting the value to val
but not supplying
arg
is an error.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.takes_value(true)
.requires_if("my.cfg", "input")
.long("config"))
.arg(Arg::new("input"))
.try_get_matches_from(vec![
"prog", "--config", "my.cfg"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::MissingRequiredArgument);
sourcepub fn requires_ifs<T: Key>(self, ifs: &[(&'help str, T)]) -> Self
pub fn requires_ifs<T: Key>(self, ifs: &[(&'help str, T)]) -> Self
Allows multiple conditional requirements.
The requirement will only become valid if this arg’s value equals val
.
Examples
Arg::new("config")
.requires_ifs(&[
("val", "arg"),
("other_val", "arg2"),
])
Setting Arg::requires_ifs(&["val", "arg"])
requires that the arg
be used at runtime if the
defining argument’s value is equal to val
. If the defining argument’s value is anything other
than val
, arg
isn’t required.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.takes_value(true)
.requires_ifs(&[
("special.conf", "opt"),
("other.conf", "other"),
])
.long("config"))
.arg(Arg::new("opt")
.long("option")
.takes_value(true))
.arg(Arg::new("other"))
.try_get_matches_from(vec![
"prog", "--config", "special.conf"
]);
assert!(res.is_err()); // We used --config=special.conf so --option <val> is required
assert_eq!(res.unwrap_err().kind(), ErrorKind::MissingRequiredArgument);
sourcepub fn requires_all<T: Key>(self, names: &[T]) -> Self
pub fn requires_all<T: Key>(self, names: &[T]) -> Self
Require these arguments names when this one is presen
i.e. when using this argument, the following arguments must be present.
NOTE: Conflicting rules and override rules take precedence over being required by default.
Examples
Arg::new("config")
.requires_all(&["input", "output"])
Setting Arg::requires_all(&[arg, arg2])
requires that all the arguments be used at
runtime if the defining argument is used. If the defining argument isn’t used, the other
argument isn’t required
let res = Command::new("prog")
.arg(Arg::new("cfg")
.takes_value(true)
.requires("input")
.long("config"))
.arg(Arg::new("input"))
.arg(Arg::new("output"))
.try_get_matches_from(vec![
"prog"
]);
assert!(res.is_ok()); // We didn't use cfg, so input and output weren't required
Setting Arg::requires_all(&[arg, arg2])
and not supplying all the arguments is an
error.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.takes_value(true)
.requires_all(&["input", "output"])
.long("config"))
.arg(Arg::new("input"))
.arg(Arg::new("output"))
.try_get_matches_from(vec![
"prog", "--config", "file.conf", "in.txt"
]);
assert!(res.is_err());
// We didn't use output
assert_eq!(res.unwrap_err().kind(), ErrorKind::MissingRequiredArgument);
sourcepub fn conflicts_with<T: Key>(self, arg_id: T) -> Self
pub fn conflicts_with<T: Key>(self, arg_id: T) -> Self
This argument is mutually exclusive with the specified argument.
NOTE: Conflicting rules take precedence over being required by default. Conflict rules only need to be set for one of the two arguments, they do not need to be set for each.
NOTE: Defining a conflict is two-way, but does not need to defined for both arguments (i.e. if A conflicts with B, defining A.conflicts_with(B) is sufficient. You do not need to also do B.conflicts_with(A))
NOTE: Arg::conflicts_with_all(names)
allows specifying an argument which conflicts with more than one argument.
NOTE Arg::exclusive(true)
allows specifying an argument which conflicts with every other argument.
Examples
Arg::new("config")
.conflicts_with("debug")
Setting conflicting argument, and having both arguments present at runtime is an error.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.takes_value(true)
.conflicts_with("debug")
.long("config"))
.arg(Arg::new("debug")
.long("debug"))
.try_get_matches_from(vec![
"prog", "--debug", "--config", "file.conf"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::ArgumentConflict);
sourcepub fn conflicts_with_all(self, names: &[&str]) -> Self
pub fn conflicts_with_all(self, names: &[&str]) -> Self
This argument is mutually exclusive with the specified arguments.
See Arg::conflicts_with
.
NOTE: Conflicting rules take precedence over being required by default. Conflict rules only need to be set for one of the two arguments, they do not need to be set for each.
NOTE: Defining a conflict is two-way, but does not need to defined for both arguments (i.e. if A conflicts with B, defining A.conflicts_with(B) is sufficient. You do not need need to also do B.conflicts_with(A))
NOTE: Arg::exclusive(true)
allows specifying an argument which conflicts with every other argument.
Examples
Arg::new("config")
.conflicts_with_all(&["debug", "input"])
Setting conflicting argument, and having any of the arguments present at runtime with a conflicting argument is an error.
let res = Command::new("prog")
.arg(Arg::new("cfg")
.takes_value(true)
.conflicts_with_all(&["debug", "input"])
.long("config"))
.arg(Arg::new("debug")
.long("debug"))
.arg(Arg::new("input"))
.try_get_matches_from(vec![
"prog", "--config", "file.conf", "file.txt"
]);
assert!(res.is_err());
assert_eq!(res.unwrap_err().kind(), ErrorKind::ArgumentConflict);
sourcepub fn overrides_with<T: Key>(self, arg_id: T) -> Self
pub fn overrides_with<T: Key>(self, arg_id: T) -> Self
Sets an overridable argument.
i.e. this argument and the following argument will override each other in POSIX style (whichever argument was specified at runtime last “wins”)
NOTE: When an argument is overridden it is essentially as if it never was used, any conflicts, requirements, etc. are evaluated after all “overrides” have been removed
NOTE: Overriding an argument implies they conflict.
WARNING: Positional arguments and options which accept
Arg::multiple_occurrences
cannot override themselves (or we
would never be able to advance to the next positional). If a positional
argument or option with one of the Arg::multiple_occurrences
settings lists itself as an override, it is simply ignored.
Examples
let m = Command::new("prog")
.arg(arg!(-f --flag "some flag")
.conflicts_with("debug"))
.arg(arg!(-d --debug "other flag"))
.arg(arg!(-c --color "third flag")
.overrides_with("flag"))
.get_matches_from(vec![
"prog", "-f", "-d", "-c"]);
// ^~~~~~~~~~~~^~~~~ flag is overridden by color
assert!(m.is_present("color"));
assert!(m.is_present("debug")); // even though flag conflicts with debug, it's as if flag
// was never used because it was overridden with color
assert!(!m.is_present("flag"));
Care must be taken when using this setting, and having an arg override with itself. This is common practice when supporting things like shell aliases, config files, etc. However, when combined with multiple values, it can get dicy. Here is how clap handles such situations:
When a flag overrides itself, it’s as if the flag was only ever used once (essentially preventing a “Unexpected multiple usage” error):
let m = Command::new("posix")
.arg(arg!(--flag "some flag").overrides_with("flag"))
.get_matches_from(vec!["posix", "--flag", "--flag"]);
assert!(m.is_present("flag"));
Making an arg Arg::multiple_occurrences
and override itself
is essentially meaningless. Therefore clap ignores an override of self
if it’s a flag and it already accepts multiple occurrences.
let m = Command::new("posix")
.arg(arg!(--flag ... "some flag").overrides_with("flag"))
.get_matches_from(vec!["", "--flag", "--flag", "--flag", "--flag"]);
assert!(m.is_present("flag"));
Now notice with options (which do not set
Arg::multiple_occurrences
), it’s as if only the last
occurrence happened.
let m = Command::new("posix")
.arg(arg!(--opt <val> "some option").overrides_with("opt"))
.get_matches_from(vec!["", "--opt=some", "--opt=other"]);
assert!(m.is_present("opt"));
assert_eq!(m.value_of("opt"), Some("other"));
This will also work when Arg::multiple_values
is enabled:
let m = Command::new("posix")
.arg(
Arg::new("opt")
.long("opt")
.takes_value(true)
.multiple_values(true)
.overrides_with("opt")
)
.get_matches_from(vec!["", "--opt", "1", "2", "--opt", "3", "4", "5"]);
assert!(m.is_present("opt"));
assert_eq!(m.values_of("opt").unwrap().collect::<Vec<_>>(), &["3", "4", "5"]);
Just like flags, options with Arg::multiple_occurrences
set
will ignore the “override self” setting.
let m = Command::new("posix")
.arg(arg!(--opt <val> ... "some option")
.multiple_values(true)
.overrides_with("opt"))
.get_matches_from(vec!["", "--opt", "first", "over", "--opt", "other", "val"]);
assert!(m.is_present("opt"));
assert_eq!(m.values_of("opt").unwrap().collect::<Vec<_>>(), &["first", "over", "other", "val"]);
sourcepub fn overrides_with_all<T: Key>(self, names: &[T]) -> Self
pub fn overrides_with_all<T: Key>(self, names: &[T]) -> Self
Sets multiple mutually overridable arguments by name.
i.e. this argument and the following argument will override each other in POSIX style (whichever argument was specified at runtime last “wins”)
NOTE: When an argument is overridden it is essentially as if it never was used, any conflicts, requirements, etc. are evaluated after all “overrides” have been removed
NOTE: Overriding an argument implies they conflict.
Examples
let m = Command::new("prog")
.arg(arg!(-f --flag "some flag")
.conflicts_with("color"))
.arg(arg!(-d --debug "other flag"))
.arg(arg!(-c --color "third flag")
.overrides_with_all(&["flag", "debug"]))
.get_matches_from(vec![
"prog", "-f", "-d", "-c"]);
// ^~~~~~^~~~~~~~~ flag and debug are overridden by color
assert!(m.is_present("color")); // even though flag conflicts with color, it's as if flag
// and debug were never used because they were overridden
// with color
assert!(!m.is_present("debug"));
assert!(!m.is_present("flag"));
sourceimpl<'help> Arg<'help>
impl<'help> Arg<'help>
sourcepub fn get_name(&self) -> &'help str
pub fn get_name(&self) -> &'help str
Deprecated, replaced with Arg::get_id
sourcepub fn get_long_help(&self) -> Option<&'help str>
pub fn get_long_help(&self) -> Option<&'help str>
Get the long help specified for this argument, if any
Examples
let arg = Arg::new("foo").long_help("long help");
assert_eq!(Some("long help"), arg.get_long_help());
sourcepub fn get_help_heading(&self) -> Option<&'help str>
pub fn get_help_heading(&self) -> Option<&'help str>
Get the help heading specified for this argument, if any
sourcepub fn get_visible_short_aliases(&self) -> Option<Vec<char>>
pub fn get_visible_short_aliases(&self) -> Option<Vec<char>>
Get visible short aliases for this argument, if any
sourcepub fn get_all_short_aliases(&self) -> Option<Vec<char>>
pub fn get_all_short_aliases(&self) -> Option<Vec<char>>
Get all short aliases for this argument, if any, both visible and hidden.
sourcepub fn get_short_and_visible_aliases(&self) -> Option<Vec<char>>
pub fn get_short_and_visible_aliases(&self) -> Option<Vec<char>>
Get the short option name and its visible aliases, if any
sourcepub fn get_long(&self) -> Option<&'help str>
pub fn get_long(&self) -> Option<&'help str>
Get the long option name for this argument, if any
sourcepub fn get_visible_aliases(&self) -> Option<Vec<&'help str>>
pub fn get_visible_aliases(&self) -> Option<Vec<&'help str>>
Get visible aliases for this argument, if any
sourcepub fn get_all_aliases(&self) -> Option<Vec<&'help str>>
pub fn get_all_aliases(&self) -> Option<Vec<&'help str>>
Get all aliases for this argument, if any, both visible and hidden.
sourcepub fn get_long_and_visible_aliases(&self) -> Option<Vec<&'help str>>
pub fn get_long_and_visible_aliases(&self) -> Option<Vec<&'help str>>
Get the long option name and its visible aliases, if any
sourcepub fn get_possible_values(&self) -> Option<&[PossibleValue<'help>]>
pub fn get_possible_values(&self) -> Option<&[PossibleValue<'help>]>
Deprecated, replaced with [Arg::get_value_parser().possible_values()
]
sourcepub fn get_value_names(&self) -> Option<&[&'help str]>
pub fn get_value_names(&self) -> Option<&[&'help str]>
Get the names of values for this argument.
sourcepub fn get_num_vals(&self) -> Option<usize>
pub fn get_num_vals(&self) -> Option<usize>
Get the number of values for this argument.
sourcepub fn get_value_delimiter(&self) -> Option<char>
pub fn get_value_delimiter(&self) -> Option<char>
Get the delimiter between multiple values
sourcepub fn get_value_hint(&self) -> ValueHint
pub fn get_value_hint(&self) -> ValueHint
Get the value hint of this argument
sourcepub fn get_global(&self) -> bool
pub fn get_global(&self) -> bool
Deprecated, replaced with Arg::is_global_set
sourcepub fn get_default_values(&self) -> &[&OsStr]
pub fn get_default_values(&self) -> &[&OsStr]
Get the default values specified for this argument, if any
Examples
let arg = Arg::new("foo").default_value("default value");
assert_eq!(&["default value"], arg.get_default_values());
sourcepub fn is_positional(&self) -> bool
pub fn is_positional(&self) -> bool
Checks whether this argument is a positional or not.
Examples
let arg = Arg::new("foo");
assert_eq!(true, arg.is_positional());
let arg = Arg::new("foo").long("foo");
assert_eq!(false, arg.is_positional());
sourcepub fn is_required_set(&self) -> bool
pub fn is_required_set(&self) -> bool
Reports whether Arg::required
is set
sourcepub fn is_multiple_values_set(&self) -> bool
pub fn is_multiple_values_set(&self) -> bool
Report whether Arg::multiple_values
is set
sourcepub fn is_multiple_occurrences_set(&self) -> bool
pub fn is_multiple_occurrences_set(&self) -> bool
Arg::multiple_occurrences
is going away (Issue #3772)
sourcepub fn is_takes_value_set(&self) -> bool
pub fn is_takes_value_set(&self) -> bool
Report whether Arg::is_takes_value_set
is set
sourcepub fn is_allow_hyphen_values_set(&self) -> bool
pub fn is_allow_hyphen_values_set(&self) -> bool
Report whether Arg::allow_hyphen_values
is set
sourcepub fn is_forbid_empty_values_set(&self) -> bool
pub fn is_forbid_empty_values_set(&self) -> bool
Deprecated, replaced with Arg::get_value_parser()
sourcepub fn is_allow_invalid_utf8_set(&self) -> bool
pub fn is_allow_invalid_utf8_set(&self) -> bool
Deprecated, replaced with [Arg::get_value_parser()
sourcepub fn get_action(&self) -> &ArgAction
pub fn get_action(&self) -> &ArgAction
Behavior when parsing the argument
sourcepub fn get_value_parser(&self) -> &ValueParser
pub fn get_value_parser(&self) -> &ValueParser
Configured parser for argument values
Example
let cmd = clap::Command::new("raw")
.arg(
clap::Arg::new("port")
.value_parser(clap::value_parser!(usize))
);
let value_parser = cmd.get_arguments()
.find(|a| a.get_id() == "port").unwrap()
.get_value_parser();
println!("{:?}", value_parser);
sourcepub fn is_global_set(&self) -> bool
pub fn is_global_set(&self) -> bool
Report whether Arg::global
is set
sourcepub fn is_next_line_help_set(&self) -> bool
pub fn is_next_line_help_set(&self) -> bool
Report whether Arg::next_line_help
is set
sourcepub fn is_hide_set(&self) -> bool
pub fn is_hide_set(&self) -> bool
Report whether Arg::hide
is set
sourcepub fn is_hide_default_value_set(&self) -> bool
pub fn is_hide_default_value_set(&self) -> bool
Report whether Arg::hide_default_value
is set
sourcepub fn is_hide_possible_values_set(&self) -> bool
pub fn is_hide_possible_values_set(&self) -> bool
Report whether Arg::hide_possible_values
is set
sourcepub fn is_hide_short_help_set(&self) -> bool
pub fn is_hide_short_help_set(&self) -> bool
Report whether Arg::hide_short_help
is set
sourcepub fn is_hide_long_help_set(&self) -> bool
pub fn is_hide_long_help_set(&self) -> bool
Report whether Arg::hide_long_help
is set
sourcepub fn is_use_value_delimiter_set(&self) -> bool
pub fn is_use_value_delimiter_set(&self) -> bool
Report whether Arg::use_value_delimiter
is set
sourcepub fn is_require_value_delimiter_set(&self) -> bool
pub fn is_require_value_delimiter_set(&self) -> bool
Report whether Arg::require_value_delimiter
is set
sourcepub fn is_require_equals_set(&self) -> bool
pub fn is_require_equals_set(&self) -> bool
Report whether Arg::require_equals
is set
sourcepub fn is_exclusive_set(&self) -> bool
pub fn is_exclusive_set(&self) -> bool
Reports whether Arg::exclusive
is set
sourcepub fn is_last_set(&self) -> bool
pub fn is_last_set(&self) -> bool
Reports whether Arg::last
is set
sourcepub fn is_ignore_case_set(&self) -> bool
pub fn is_ignore_case_set(&self) -> bool
Reports whether Arg::ignore_case
is set
Trait Implementations
sourceimpl<'help> Ord for Arg<'help>
impl<'help> Ord for Arg<'help>
sourceimpl<'help> PartialOrd<Arg<'help>> for Arg<'help>
impl<'help> PartialOrd<Arg<'help>> for Arg<'help>
sourcefn partial_cmp(&self, other: &Self) -> Option<Ordering>
fn partial_cmp(&self, other: &Self) -> Option<Ordering>
This method returns an ordering between self
and other
values if one exists. Read more
1.0.0 · sourcefn lt(&self, other: &Rhs) -> bool
fn lt(&self, other: &Rhs) -> bool
This method tests less than (for self
and other
) and is used by the <
operator. Read more
1.0.0 · sourcefn le(&self, other: &Rhs) -> bool
fn le(&self, other: &Rhs) -> bool
This method tests less than or equal to (for self
and other
) and is used by the <=
operator. Read more
impl<'help> Eq for Arg<'help>
Auto Trait Implementations
impl<'help> !RefUnwindSafe for Arg<'help>
impl<'help> Send for Arg<'help>
impl<'help> Sync for Arg<'help>
impl<'help> Unpin for Arg<'help>
impl<'help> !UnwindSafe for Arg<'help>
Blanket Implementations
sourceimpl<T> BorrowMut<T> for T where
T: ?Sized,
impl<T> BorrowMut<T> for T where
T: ?Sized,
const: unstable · sourcefn borrow_mut(&mut self) -> &mut T
fn borrow_mut(&mut self) -> &mut T
Mutably borrows from an owned value. Read more
sourceimpl<Q, K> Equivalent<K> for Q where
Q: Eq + ?Sized,
K: Borrow<Q> + ?Sized,
impl<Q, K> Equivalent<K> for Q where
Q: Eq + ?Sized,
K: Borrow<Q> + ?Sized,
sourcefn equivalent(&self, key: &K) -> bool
fn equivalent(&self, key: &K) -> bool
Compare self to key
and return true
if they are equal.
sourceimpl<T> ToOwned for T where
T: Clone,
impl<T> ToOwned for T where
T: Clone,
type Owned = T
type Owned = T
The resulting type after obtaining ownership.
sourcefn clone_into(&self, target: &mut T)
fn clone_into(&self, target: &mut T)
toowned_clone_into
)Uses borrowed data to replace owned data, usually by cloning. Read more