Frustration-free command line processing
So many different command line processing libraries out there and none of them just work!
Some bring their whole extended family of related and unrelated external dependencies (yes, I'm looking at you Boost).
Some require quirky syntax and/or very verbose setups that sacrifice simplicity for the generation of a cute usage message and validation. Many come to dominate your main()
file and yet others do not build on multiple plaforms - for some even their own tests and trivial usage cause crashes on some systems. Argh!
If you're writing a highly-sophisticated command line tool, then Boost.Program_options
and its kind might give you many advanced options. However, if you need to get up and running quickly, effectively and with minimal fuss, give the single header-file argh
a try.
TL;DR
It doesn't get much simpler than this:
#include <iostream>
#include "argh.h"
int main(int, char* argv[])
{
argh::parser cmdl(argv);
if (cmdl[{ "-v", "--verbose" }])
std::cout << "Verbose, I am.\n";
return EXIT_SUCCESS;
}
Philosophy
Contrary to many alternatives, argh
takes a minimalist laissez-faire approach, very suitable for fuss-less prototyping with the following rules:
The API is:
- Minimalistic but expressive:
- No getters nor binders
- Just the
[]
and()
operators - Easy iteration (range-
for
too)
- You don't pay for what you don't use
- Conversion to typed variables happens (via
std::istream >>
) on the user side after the parsing phase - No exceptions thrown for failures
- Liberal BSD license
- Single header file
- No non-
std
dependencies
argh
does not care about:
- How many '
-
' preceded your option - Which flags and options you support - that is your responsibility
- Syntax validation: any command line is a valid (not necessarily unique) combination of positional parameters, flags and options
- Automatically producing a usage message
Tutorial
Create parser:
auto cmdl = argh::parser(argc, argv);
In fact, you can even drop argc
. This will also work:
argh::parser cmdl(argv);
Positional argument access by (integer) index with [<size_t>]
:
cout << "Exe name is: " << cmdl[0] << '\n';
^^^
assert(cmdl[10000].empty()); // out-of-bound index returns empty string
^^^^^
Boolean flag argument access by (string) name with [<std::string>]
:
cout << "Verbose mode is " << ( cmdl["verbose"] ? "ON" : "OFF" ) << '\n';
^^^^^^^^^^^
Any dashes are trimmed so are not required.
Your flag can have several alternatives, just list them with [{ "<name-1>", "<name-2>", ... }]
:
cout << "Verbose mode is " << ( cmdl[{ "-v", "--verbose" }] ? "ON" : "OFF" ) << '\n';
^^^^^^^^^^^^^^^^^^^^^^^
Beyond bool
and std::string
access with []
, as shown above, we can also access the argument values as an std::istream
. This is very useful for type conversions.
std::istream
positional argument access by (integer) index with (<size_t>)
:
std::string my_app_name;
cmdl(0) >> my_app_name; // streaming into a string
^^^
cout << "Exe name is: " << my_app_name << '\n';
We can also check if a particular positional arg was given or not (this is like using [<std::string>]
above):
if (!cmdl(10))
cerr << "Must provide at least 10 arguments!" << '\n';
else if (cmdl(11))
cout << "11th argument is: " << cmdl[11] << '\n';
But we can also set default values for positional arguments. These are passed as the second argument:
float scale_factor;
cmdl(2, 1.0f) >> scale_factor;
^^^^^^^
If the position argument was not given or the streaming conversion failed, the default value will be used.
Similarly, parameters can be accessed by name(s) (i.e. by string or list of string literals) with:
(<std::string> [, <default value>])
or ({ "<name-1>", "<name-2>", ... } [, <default value>])
:
float scale_factor;
cmdl("scale", 1.0f) >> scale_factor; // Use 1.0f as default value
^^^^^^^^^^^^^
float threshold;
if (!(cmdl({ "-t", "--threshold"}) >> threshold)) // Check for missing param and/or bad (inconvertible) param value
cerr << "Must provide a valid threshold value! Got '" << cmdl("threshold").str() << "'" << endl;
else ^^^^^^
cout << "Threshold set to: " << threshold << '\n';
As shown above, use std::istream::str()
to get the param value as a std:string
or just stream the value into a variable of a suitable type. Standard stream state indicates failure, including when the argument was not given.
When using multiple names, the first value found will be returned.
Positional arguments can be iterated upon directly using range-for:
cout << "Positional args:\n";
for (auto& pos_arg : cmdl)
cout << '\t' << pos_arg << '\n';
Similarly, cmdl.size()
will return the count of positional arguments.
Positional arguments, flags and parameters are accessible as "ranges":
cout << "Positional args:\n";
for (auto& pos_arg : cmdl.pos_args())
cout << '\t' << pos_arg << '\n';
cout << "\nFlags:\n";
for (auto& flag : cmdl.flags())
cout << '\t' << flag << '\n';
cout << "\nParameters:\n";
for (auto& param : cmdl.params())
cout << '\t' << param.first << " : " << param.second << '\n';
By default, options are assumed to be boolean flags. When this is not what you want, there are several ways to specify when an option is a parameter with an associated value.
Specify PREFER_PARAM_FOR_UNREG_OPTION
mode to interpret any <option> <non-option>
as <parameter-name> <parameter-value>
:
using namespace argh;
auto cmdl = parser(argc, argv, parser::PREFER_PARAM_FOR_UNREG_OPTION);
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
cout << cmdl("--threshold").str() << '\n';
Pre-register an expected parameter name with add_param()
(before calling parse()
):
argh::parser cmdl;
cmdl.add_param("threshold"); // pre-register "threshold" as a param: name + value
cmdl.parse(argc, argv);
cout << cmdl("threshold").str() << '\n';
You can also batch pre-register multiple options as parameters with add_params({ ... })
:
argh::parser cmdl;
cmdl.add_params({ "-t", "--threshold", "-s", "--scale" }); // batch pre-register multiple params: name + value
cmdl.parse(argc, argv);
cout << cmdl("threshold").str() << '\n';
Since pre-registration has to be done before parsing, we might as well just use the ctor:
argh::parser cmdl({ "-t", "--threshold", "-s", "--scale" }); // batch pre-register multiple params: name + value
cmdl.parse(argc, argv);
cout << cmdl("threshold").str() << '\n';
Use a =
(with no spaces around it) within the option when calling the app:
>> my_app --threshold=42
42
Tips
- By default, arguments of the form
--<name>=<value>
(with no spaces, one or more dashes), e.g.--answer=42
, will be parsed as<parameter-name> <parameter-value>
. To disable this specify theNO_SPLIT_ON_EQUALSIGN
mode. - Specifying the
SINGLE_DASH_IS_MULTIFLAG
mode will split a single-hyphen argument into multiple single-character flags (as is common in various POSIX tools). - When using
SINGLE_DASH_IS_MULTIFLAG
, you can still pre-register the last character as a param with the value, such that if we pre-registerf
as a param,>> myapp -xvf 42
will be parsed with two boolean flagsx
andv
and a one paramf
=42
. - When parsing parameter values as strings that may contain spaces (e.g.
--config="C:\Folder\With Space\Config.ini"
), prefer using.str()
instead of>>
to avoid the default automatic whitespace input stream tokenization:
cout << cmdl({ "-c", "--config" }).str()
.
Terminology
Any command line is composed of 2 types of Args:
- Positional Args:
Free standing, in-order, values
e.g.config.json
- Options:
Args beginning with-
(and that are not negative numbers).
We identify 2 kinds of Options:- Flags:
Boolean options => (appear ? true : false)
e.g.-v
,--verbose
- Parameters:
A named value followed by a non-option value
e.g.--gamma 2.2
- Flags:
Thus, any command line can always be broken into some combination of (1) positional args (2) flags and (3) parameters.
API Summary
Parsing
Parse the command line using either
- The
parse()
method:parser::parse([argc,] argv [, mode])
; or - The shorter form using the ctor directly:
argh::parser([argc,] argv [, mode]);
- The shortest form does not even require
argc
, so in defaultmode
just use:
parser(argv);
Special Parsing Modes
Extra flexibility can be added be specifying parsing modes:
NO_SPLIT_ON_EQUALSIGN
: By default, an option of the form--pi=22/7
will be parsed as a parameterpi
with an associated value"22/7"
. By setting this mode, it will be not be broken at the=
.PREFER_FLAG_FOR_UNREG_OPTION
: Split<option> <non-option>
into<flag>
and<pos_arg>
. e.g.myapp -v config.json
will havev
as a lit flag andconfig.json
as a positional arg. This is the default mode.PREFER_PARAM_FOR_UNREG_OPTION
: Interpret<option> <non-option>
as<parameter-name> <parameter-value>
. e.g.myapp --gamma 2.2
will havegamma
as a parameter with the value "2.2".SINGLE_DASH_IS_MULTIFLAG
: Splits an option with a single dash into separate boolean flags, one for each letter. e.g. in this mode,-xvf
will be parsed as 3 separate flags:x
,v
,f
.
Argument Access
-
Use bracket operators to access flags and positional args:
- Use
operator[index]
to access position arg strings by index:- e.g.
assert(cmdl[0] == argv[0])
, the app name.
- e.g.
- Use
operator[string]
to access boolean flags by name:- e.g.
if (cmdl["v"]) make_verbose();
- e.g.
- Use
operator[{...}]
to access boolean flags by multiple names:- e.g.
if (cmdl[{ "v", "verbose" }]) make_verbose();
- e.g.
- Use
-
Use the parenthesis operators to get an
std::istream
to stream values from parameters and positional args:- Use
operator(index)
to access position argistream
by index:- e.g.
cmdl(0) >> my_app_name
.
- e.g.
- Use
operator(string)
to access parameter values by name:- e.g.
cmdl("scale") >> scale_factor;
- e.g.
- Use
operator({...})
to access parameter values by multiple names:- e.g.
cmdl({ "-s", "--scale" }) >> scale_factor;
- e.g.
- Use
operator(index, <default>)
andoperator(string/{list}, <default>)
to stream a default value if the arg did not appear on the command line:- e.g.
cmdl("scale", 1.0f) >> scale_factor;
- e.g.
- Use
The streaming happens at the user's side, so conversion failure can be checked there: e.g
if (!(cmdl("scale") >> scale_factor))
cerr << "Must provide valid scale factor!" << '\n';
Use the .str()
method to get the parameter value as a string: e.g. cmdl("name").str();
More Methods
- Use
parser::add_param()
,parser::add_params()
or theparser({...})
constructor to optionally pre-register a parameter name when inPREFER_FLAG_FOR_UNREG_OPTION
mode. - Use
parser
,parser::pos_args()
,parser::flags()
andparser::params()
to access and iterate over the Arg containers directly.
Finding Argh!
- copy
argh.h
somewhere into your projects directories - or include the repository as a submodule
- or use CMake!
Finding Argh! - CMake
The provided CMakeLists.txt
generates targets for tests, a demo application and an install target to install argh
system-wide and make it known to CMake. You can control generation of test and example targets using the options BUILD_TESTS
and BUILD_EXAMPLES
. Only argh
alongside its license and readme will be installed - not tests and demo!
Add argh
to your CMake-project by using
find_package(argh)
The package exports argh
INTERFACE library target and argh_INCLUDE_DIR
variable. Make argh.h
known to your compiler by using one of the following methods; both will make the location of argh.h
known to the compiler, not link in a precompiled library - even when using target_link_libraries()
.
target_include_directories(${MY_TARGET_NAME} PRIVATE "${argh_INCLUDE_DIR}")
#OR
target_link_libraries(${MY_TARGET_NAME} argh)
Buck
The Buck build system is also supported.
Run the example:
buck run :example
Run the tests:
buck run :tests
buck run test_package
If you take argh
as a submodule, then the visible target is //:argh
.
Colophon
I ❤ your feedback. If you found Argh! useful - do Tweet about it to let me know. If you found it lacking, please post an issue.