Argparse Tutorial¶
- author:
Tshepang Mbambo
This tutorial is intended to be a gentle introduction to argparse
, the
recommended command-line parsing module in the Python standard library.
Note
The standard library includes two other libraries directly related
to command-line parameter processing: the lower level optparse
module (which may require more code to configure for a given application,
but also allows an application to request behaviors that argparse
doesn’t support), and the very low level getopt
(which specifically
serves as an equivalent to the getopt()
family of functions
available to C programmers).
While neither of those modules is covered directly in this guide, many of
the core concepts in argparse
first originated in optparse
, so
some aspects of this tutorial will also be relevant to optparse
users.
Concepts¶
Let’s show the sort of functionality that we are going to explore in this introductory tutorial by making use of the ls command:
$ ls
cpython devguide prog.py pypy rm-unused-function.patch
$ ls pypy
ctypes_configure demo dotviewer include lib_pypy lib-python ...
$ ls -l
total 20
drwxr-xr-x 19 wena wena 4096 Feb 18 18:51 cpython
drwxr-xr-x 4 wena wena 4096 Feb 8 12:04 devguide
-rwxr-xr-x 1 wena wena 535 Feb 19 00:05 prog.py
drwxr-xr-x 14 wena wena 4096 Feb 7 00:59 pypy
-rw-r--r-- 1 wena wena 741 Feb 18 01:01 rm-unused-function.patch
$ ls --help
Usage: ls [OPTION]... [FILE]...
List information about the FILEs (the current directory by default).
Sort entries alphabetically if none of -cftuvSUX nor --sort is specified.
...
A few concepts we can learn from the four commands:
The ls command is useful when run without any options at all. It defaults to displaying the contents of the current directory.
If we want beyond what it provides by default, we tell it a bit more. In this case, we want it to display a different directory,
pypy
. What we did is specify what is known as a positional argument. It’s named so because the program should know what to do with the value, solely based on where it appears on the command line. This concept is more relevant to a command like cp, whose most basic usage iscp SRC DEST
. The first position is what you want copied, and the second position is where you want it copied to.Now, say we want to change behaviour of the program. In our example, we display more info for each file instead of just showing the file names. The
-l
in that case is known as an optional argument.That’s a snippet of the help text. It’s very useful in that you can come across a program you have never used before, and can figure out how it works simply by reading its help text.
The basics¶
Let us start with a very simple example which does (almost) nothing:
import argparse
parser = argparse.ArgumentParser()
parser.parse_args()
Following is a result of running the code:
$ python prog.py
$ python prog.py --help
usage: prog.py [-h]
options:
-h, --help show this help message and exit
$ python prog.py --verbose
usage: prog.py [-h]
prog.py: error: unrecognized arguments: --verbose
$ python prog.py foo
usage: prog.py [-h]
prog.py: error: unrecognized arguments: foo
Here is what is happening:
Running the script without any options results in nothing displayed to stdout. Not so useful.
The second one starts to display the usefulness of the
argparse
module. We have done almost nothing, but already we get a nice help message.The
--help
option, which can also be shortened to-h
, is the only option we get for free (i.e. no need to specify it). Specifying anything else results in an error. But even then, we do get a useful usage message, also for free.
Introducing Positional arguments¶
An example:
import argparse
parser = argparse.ArgumentParser()
parser.add_argument("echo")
args = parser.parse_args()
print(args.echo)
And running the code:
$ python prog.py
usage: prog.py [-h] echo
prog.py: error: the following arguments are required: echo
$ python prog.py --help
usage: prog.py [-h] echo
positional arguments:
echo
options:
-h, --help show this help message and exit
$ python prog.py foo
foo
Here is what’s happening:
We’ve added the
add_argument()
method, which is what we use to specify which command-line options the program is willing to accept. In this case, I’ve named itecho
so that it’s in line with its function.Calling our program now requires us to specify an option.
The
parse_args()
method actually returns some data from the options specified, in this case,echo
.The variable is some form of ‘magic’ that
argparse
performs for free (i.e. no need to specify which variable that value is stored in). You will also notice that its name matches the string argument given to the method,echo
.
Note however that, although the help display looks nice and all, it currently
is not as helpful as it can be. For example we see that we got echo
as a
positional argument, but we don’t know what it does, other than by guessing or
by reading the source code. So, let’s make it a bit more useful:
import argparse
parser = argparse.ArgumentParser()
parser.add_argument("echo", help="echo the string you use here")
args = parser.parse_args()
print(args.echo)
And we get:
$ python prog.py -h
usage: prog.py [-h] echo
positional arguments:
echo echo the string you use here
options:
-h, --help show this help message and exit
Now, how about doing something even more useful:
import argparse
parser = argparse.ArgumentParser()
parser.add_argument("square", help="display a square of a given number")
args = parser.parse_args()
print(args.square**2)
Following is a result of running the code:
$ python prog.py 4
Traceback (most recent call last):
File "prog.py", line 5, in <module>
print(args.square**2)
TypeError: unsupported operand type(s) for ** or pow(): 'str' and 'int'
That didn’t go so well. That’s because argparse
treats the options we
give it as strings, unless we tell it otherwise. So, let’s tell
argparse
to treat that input as an integer:
import argparse
parser = argparse.ArgumentParser()
parser.add_argument("square", help="display a square of a given number",
type=int)
args = parser.parse_args()
print(args.square**2)
Following is a result of running the code:
$ python prog.py 4
16
$ python prog.py four
usage: prog.py [-h] square
prog.py: error: argument square: invalid int value: 'four'
That went well. The program now even helpfully quits on bad illegal input before proceeding.
Introducing Optional arguments¶
So far we have been playing with positional arguments. Let us have a look on how to add optional ones:
import argparse
parser = argparse.ArgumentParser()
parser.add_argument("--verbosity", help="increase output verbosity")
args = parser.parse_args()
if args.verbosity:
print("verbosity turned on")
And the output:
$ python prog.py --verbosity 1
verbosity turned on
$ python prog.py
$ python prog.py --help
usage: prog.py [-h] [--verbosity VERBOSITY]
options:
-h, --help show this help message and exit
--verbosity VERBOSITY
increase output verbosity
$ python prog.py --verbosity
usage: prog.py [-h] [--verbosity VERBOSITY]
prog.py: error: argument --verbosity: expected one argument
Here is what is happening:
The program is written so as to display something when
--verbosity
is specified and display nothing when not.To show that the option is actually optional, there is no error when running the program without it. Note that by default, if an optional argument isn’t used, the relevant variable, in this case
args.verbosity
, is givenNone
as a value, which is the reason it fails the truth test of theif
statement.The help message is a bit different.
When using the
--verbosity
option, one must also specify some value, any value.
The above example accepts arbitrary integer values for --verbosity
, but for
our simple program, only two values are actually useful, True
or False
.
Let’s modify the code accordingly:
import argparse
parser = argparse.ArgumentParser()
parser.add_argument("--verbose", help="increase output verbosity",
action="store_true")
args = parser.parse_args()
if args.verbose:
print("verbosity turned on")
And the output:
$ python prog.py --verbose
verbosity turned on
$ python prog.py --verbose 1
usage: prog.py [-h] [--verbose]
prog.py: error: unrecognized arguments: 1
$ python prog.py --help
usage: prog.py [-h] [--verbose]
options:
-h, --help show this help message and exit
--verbose increase output verbosity
Here is what is happening:
The option is now more of a flag than something that requires a value. We even changed the name of the option to match that idea. Note that we now specify a new keyword,
action
, and give it the value"store_true"
. This means that, if the option is specified, assign the valueTrue
toargs.verbose
. Not specifying it impliesFalse
.It complains when you specify a value, in true spirit of what flags actually are.
Notice the different help text.
Short options¶
If you are familiar with command line usage, you will notice that I haven’t yet touched on the topic of short versions of the options. It’s quite simple:
import argparse
parser = argparse.ArgumentParser()
parser.add_argument("-v", "--verbose", help="increase output verbosity",
action="store_true")
args = parser.parse_args()
if args.verbose:
print("verbosity turned on")
And here goes:
$ python prog.py -v
verbosity turned on
$ python prog.py --help
usage: prog.py [-h] [-v]
options:
-h, --help show this help message and exit
-v, --verbose increase output verbosity
Note that the new ability is also reflected in the help text.
Combining Positional and Optional arguments¶
Our program keeps growing in complexity:
import argparse
parser = argparse.ArgumentParser()
parser.add_argument("square", type=int,
help="display a square of a given number")
parser.add_argument("-v", "--verbose", action="store_true",
help="increase output verbosity")
args = parser.parse_args()
answer = args.square**2
if args.verbose:
print(f"the square of {args.square} equals {answer}")
else:
print(answer)
And now the output:
$ python prog.py
usage: prog.py [-h] [-v] square
prog.py: error: the following arguments are required: square
$ python prog.py 4
16
$ python prog.py 4 --verbose
the square of 4 equals 16
$ python prog.py --verbose 4
the square of 4 equals 16
We’ve brought back a positional argument, hence the complaint.
Note that the order does not matter.
How about we give this program of ours back the ability to have multiple verbosity values, and actually get to use them:
import argparse
parser = argparse.ArgumentParser()
parser.add_argument("square", type=int,
help="display a square of a given number")
parser.add_argument("-v", "--verbosity", type=int,
help="increase output verbosity")
args = parser.parse_args()
answer = args.square**2
if args.verbosity == 2:
print(f"the square of {args.square} equals {answer}")
elif args.verbosity == 1:
print(f"{args.square}^2 == {answer}")
else:
print(answer)
And the output:
$ python prog.py 4
16
$ python prog.py 4 -v
usage: prog.py [-h] [-v VERBOSITY] square
prog.py: error: argument -v/--verbosity: expected one argument
$ python prog.py 4 -v 1
4^2 == 16
$ python prog.py 4 -v 2
the square of 4 equals 16
$ python prog.py 4 -v 3
16
These all look good except the last one, which exposes a bug in our program.
Let’s fix it by restricting the values the --verbosity
option can accept:
import argparse
parser = argparse.ArgumentParser()
parser.add_argument("square", type=int,
help="display a square of a given number")
parser.add_argument("-v", "--verbosity", type=int, choices=[0, 1, 2],
help="increase output verbosity")
args = parser.parse_args()
answer = args.square**2
if args.verbosity == 2:
print(f"the square of {args.square} equals {answer}")
elif args.verbosity == 1:
print(f"{args.square}^2 == {answer}")
else:
print(answer)
And the output:
$ python prog.py 4 -v 3
usage: prog.py [-h] [-v {0,1,2}] square
prog.py: error: argument -v/--verbosity: invalid choice: 3 (choose from 0, 1, 2)
$ python prog.py 4 -h
usage: prog.py [-h] [-v {0,1,2}] square
positional arguments:
square display a square of a given number
options:
-h, --help show this help message and exit
-v, --verbosity {0,1,2}
increase output verbosity
Note that the change also reflects both in the error message as well as the help string.
Now, let’s use a different approach of playing with verbosity, which is pretty
common. It also matches the way the CPython executable handles its own
verbosity argument (check the output of python --help
):
import argparse
parser = argparse.ArgumentParser()
parser.add_argument("square", type=int,
help="display the square of a given number")
parser.add_argument("-v", "--verbosity", action="count",
help="increase output verbosity")
args = parser.parse_args()
answer = args.square**2
if args.verbosity == 2:
print(f"the square of {args.square} equals {answer}")
elif args.verbosity == 1:
print(f"{args.square}^2 == {answer}")
else:
print(answer)
We have introduced another action, “count”, to count the number of occurrences of specific options.
$ python prog.py 4
16
$ python prog.py 4 -v
4^2 == 16
$ python prog.py 4 -vv
the square of 4 equals 16
$ python prog.py 4 --verbosity --verbosity
the square of 4 equals 16
$ python prog.py 4 -v 1
usage: prog.py [-h] [-v] square
prog.py: error: unrecognized arguments: 1
$ python prog.py 4 -h
usage: prog.py [-h] [-v] square
positional arguments:
square display a square of a given number
options:
-h, --help show this help message and exit
-v, --verbosity increase output verbosity
$ python prog.py 4 -vvv
16
Yes, it’s now more of a flag (similar to
action="store_true"
) in the previous version of our script. That should explain the complaint.It also behaves similar to “store_true” action.
Now here’s a demonstration of what the “count” action gives. You’ve probably seen this sort of usage before.
And if you don’t specify the
-v
flag, that flag is considered to haveNone
value.As should be expected, specifying the long form of the flag, we should get the same output.
Sadly, our help output isn’t very informative on the new ability our script has acquired, but that can always be fixed by improving the documentation for our script (e.g. via the
help
keyword argument).That last output exposes a bug in our program.
Let’s fix:
import argparse
parser = argparse.ArgumentParser()
parser.add_argument("square", type=int,
help="display a square of a given number")
parser.add_argument("-v", "--verbosity", action="count",
help="increase output verbosity")
args = parser.parse_args()
answer = args.square**2
# bugfix: replace == with >=
if args.verbosity >= 2:
print(f"the square of {args.square} equals {answer}")
elif args.verbosity >= 1:
print(f"{args.square}^2 == {answer}")
else:
print(answer)
And this is what it gives:
$ python prog.py 4 -vvv
the square of 4 equals 16
$ python prog.py 4 -vvvv
the square of 4 equals 16
$ python prog.py 4
Traceback (most recent call last):
File "prog.py", line 11, in <module>
if args.verbosity >= 2:
TypeError: '>=' not supported between instances of 'NoneType' and 'int'
First output went well, and fixes the bug we had before. That is, we want any value >= 2 to be as verbose as possible.
Third output not so good.
Let’s fix that bug:
import argparse
parser = argparse.ArgumentParser()
parser.add_argument("square", type=int,
help="display a square of a given number")
parser.add_argument("-v", "--verbosity", action="count", default=0,
help="increase output verbosity")
args = parser.parse_args()
answer = args.square**2
if args.verbosity >= 2:
print(f"the square of {args.square} equals {answer}")
elif args.verbosity >= 1:
print(f"{args.square}^2 == {answer}")
else:
print(answer)
We’ve just introduced yet another keyword, default
.
We’ve set it to 0
in order to make it comparable to the other int values.
Remember that by default,
if an optional argument isn’t specified,
it gets the None
value, and that cannot be compared to an int value
(hence the TypeError
exception).
And:
$ python prog.py 4
16
You can go quite far just with what we’ve learned so far,
and we have only scratched the surface.
The argparse
module is very powerful,
and we’ll explore a bit more of it before we end this tutorial.
Getting a little more advanced¶
What if we wanted to expand our tiny program to perform other powers, not just squares:
import argparse
parser = argparse.ArgumentParser()
parser.add_argument("x", type=int, help="the base")
parser.add_argument("y", type=int, help="the exponent")
parser.add_argument("-v", "--verbosity", action="count", default=0)
args = parser.parse_args()
answer = args.x**args.y
if args.verbosity >= 2:
print(f"{args.x} to the power {args.y} equals {answer}")
elif args.verbosity >= 1:
print(f"{args.x}^{args.y} == {answer}")
else:
print(answer)
Output:
$ python prog.py
usage: prog.py [-h] [-v] x y
prog.py: error: the following arguments are required: x, y
$ python prog.py -h
usage: prog.py [-h] [-v] x y
positional arguments:
x the base
y the exponent
options:
-h, --help show this help message and exit
-v, --verbosity
$ python prog.py 4 2 -v
4^2 == 16
Notice that so far we’ve been using verbosity level to change the text that gets displayed. The following example instead uses verbosity level to display more text instead:
import argparse
parser = argparse.ArgumentParser()
parser.add_argument("x", type=int, help="the base")
parser.add_argument("y", type=int, help="the exponent")
parser.add_argument("-v", "--verbosity", action="count", default=0)
args = parser.parse_args()
answer = args.x**args.y
if args.verbosity >= 2:
print(f"Running '{__file__}'")
if args.verbosity >= 1:
print(f"{args.x}^{args.y} == ", end="")
print(answer)
Output:
$ python prog.py 4 2
16
$ python prog.py 4 2 -v
4^2 == 16
$ python prog.py 4 2 -vv
Running 'prog.py'
4^2 == 16
Specifying ambiguous arguments¶
When there is ambiguity in deciding whether an argument is positional or for an
argument, --
can be used to tell parse_args()
that
everything after that is a positional argument:
>>> parser = argparse.ArgumentParser(prog='PROG')
>>> parser.add_argument('-n', nargs='+')
>>> parser.add_argument('args', nargs='*')
>>> # ambiguous, so parse_args assumes it's an option
>>> parser.parse_args(['-f'])
usage: PROG [-h] [-n N [N ...]] [args ...]
PROG: error: unrecognized arguments: -f
>>> parser.parse_args(['--', '-f'])
Namespace(args=['-f'], n=None)
>>> # ambiguous, so the -n option greedily accepts arguments
>>> parser.parse_args(['-n', '1', '2', '3'])
Namespace(args=[], n=['1', '2', '3'])
>>> parser.parse_args(['-n', '1', '--', '2', '3'])
Namespace(args=['2', '3'], n=['1'])
Conflicting options¶
So far, we have been working with two methods of an
argparse.ArgumentParser
instance. Let’s introduce a third one,
add_mutually_exclusive_group()
. It allows for us to specify options that
conflict with each other. Let’s also change the rest of the program so that
the new functionality makes more sense:
we’ll introduce the --quiet
option,
which will be the opposite of the --verbose
one:
import argparse
parser = argparse.ArgumentParser()
group = parser.add_mutually_exclusive_group()
group.add_argument("-v", "--verbose", action="store_true")
group.add_argument("-q", "--quiet", action="store_true")
parser.add_argument("x", type=int, help="the base")
parser.add_argument("y", type=int, help="the exponent")
args = parser.parse_args()
answer = args.x**args.y
if args.quiet:
print(answer)
elif args.verbose:
print(f"{args.x} to the power {args.y} equals {answer}")
else:
print(f"{args.x}^{args.y} == {answer}")
Our program is now simpler, and we’ve lost some functionality for the sake of demonstration. Anyways, here’s the output:
$ python prog.py 4 2
4^2 == 16
$ python prog.py 4 2 -q
16
$ python prog.py 4 2 -v
4 to the power 2 equals 16
$ python prog.py 4 2 -vq
usage: prog.py [-h] [-v | -q] x y
prog.py: error: argument -q/--quiet: not allowed with argument -v/--verbose
$ python prog.py 4 2 -v --quiet
usage: prog.py [-h] [-v | -q] x y
prog.py: error: argument -q/--quiet: not allowed with argument -v/--verbose
That should be easy to follow. I’ve added that last output so you can see the sort of flexibility you get, i.e. mixing long form options with short form ones.
Before we conclude, you probably want to tell your users the main purpose of your program, just in case they don’t know:
import argparse
parser = argparse.ArgumentParser(description="calculate X to the power of Y")
group = parser.add_mutually_exclusive_group()
group.add_argument("-v", "--verbose", action="store_true")
group.add_argument("-q", "--quiet", action="store_true")
parser.add_argument("x", type=int, help="the base")
parser.add_argument("y", type=int, help="the exponent")
args = parser.parse_args()
answer = args.x**args.y
if args.quiet:
print(answer)
elif args.verbose:
print(f"{args.x} to the power {args.y} equals {answer}")
else:
print(f"{args.x}^{args.y} == {answer}")
Note that slight difference in the usage text. Note the [-v | -q]
,
which tells us that we can either use -v
or -q
,
but not both at the same time:
$ python prog.py --help
usage: prog.py [-h] [-v | -q] x y
calculate X to the power of Y
positional arguments:
x the base
y the exponent
options:
-h, --help show this help message and exit
-v, --verbose
-q, --quiet
How to translate the argparse output¶
The output of the argparse
module such as its help text and error
messages are all made translatable using the gettext
module. This
allows applications to easily localize messages produced by
argparse
. See also Internationalizing your programs and modules.
For instance, in this argparse
output:
$ python prog.py --help
usage: prog.py [-h] [-v | -q] x y
calculate X to the power of Y
positional arguments:
x the base
y the exponent
options:
-h, --help show this help message and exit
-v, --verbose
-q, --quiet
The strings usage:
, positional arguments:
, options:
and
show this help message and exit
are all translatable.
In order to translate these strings, they must first be extracted
into a .po
file. For example, using Babel,
run this command:
$ pybabel extract -o messages.po /usr/lib/python3.12/argparse.py
This command will extract all translatable strings from the argparse
module and output them into a file named messages.po
. This command assumes
that your Python installation is in /usr/lib
.
You can find out the location of the argparse
module on your system
using this script:
import argparse
print(argparse.__file__)
Once the messages in the .po
file are translated and the translations are
installed using gettext
, argparse
will be able to display the
translated messages.
To translate your own strings in the argparse
output, use gettext
.
Custom type converters¶
The argparse
module allows you to specify custom type converters for
your command-line arguments. This allows you to modify user input before it’s
stored in the argparse.Namespace
. This can be useful when you need to
pre-process the input before it is used in your program.
When using a custom type converter, you can use any callable that takes a single string argument (the argument value) and returns the converted value. However, if you need to handle more complex scenarios, you can use a custom action class with the action parameter instead.
For example, let’s say you want to handle arguments with different prefixes and process them accordingly:
import argparse
parser = argparse.ArgumentParser(prefix_chars='-+')
parser.add_argument('-a', metavar='<value>', action='append',
type=lambda x: ('-', x))
parser.add_argument('+a', metavar='<value>', action='append',
type=lambda x: ('+', x))
args = parser.parse_args()
print(args)
Output:
$ python prog.py -a value1 +a value2
Namespace(a=[('-', 'value1'), ('+', 'value2')])
In this example, we:
Created a parser with custom prefix characters using the
prefix_chars
parameter.Defined two arguments,
-a
and+a
, which used thetype
parameter to create custom type converters to store the value in a tuple with the prefix.
Without the custom type converters, the arguments would have treated the -a
and +a
as the same argument, which would have been undesirable. By using custom
type converters, we were able to differentiate between the two arguments.
Conclusion¶
The argparse
module offers a lot more than shown here.
Its docs are quite detailed and thorough, and full of examples.
Having gone through this tutorial, you should easily digest them
without feeling overwhelmed.