# Random string generation with upper case letters and digits

How do I generate a string of size N, made of numbers and uppercase English letters such as:

• 6U1S75
• 4Z4UKK
• U911K4
• This is a very popular question. I wish an expert would add his take on the uniqueness of these random numbers for the top 3 answers i.e. the collision probability for range of string size, say from 6 to 16.
– user
Jun 21, 2014 at 7:06
• @buffer It's easy to calculate the number of possible combinations. 10 numbers + 26 letters = 36 possible characters, to the power of 6 (length of string) is equal to about two billion. My rule of thumb for random values is "if I generated values for every human on Earth, how many values could they have each?". In this case that would be less than one value per person, so if this is to identify users or objects, it's too few characters. One alternative would be to add in lower case letters, which lands you at 62^6 = almost 57 billion unique values. May 17, 2015 at 18:17
• And while it might seem silly to think of the world's population, that's just because you want a huge buffer for potential collisions. See the birthday problem: en.wikipedia.org/wiki/Birthday_problem May 17, 2015 at 18:18
• @buffer, You would be interested in this answer then. Aug 20, 2015 at 2:09
• You could start a vim child, wait till the user exits it, read the file the user left when he tried to close vim and filter numbers and uppercase latin characters from it. Jul 30, 2021 at 16:47

``````''.join(random.choice(string.ascii_uppercase + string.digits) for _ in range(N))
``````

or even shorter starting with Python 3.6 using `random.choices()`:

``````''.join(random.choices(string.ascii_uppercase + string.digits, k=N))
``````

A cryptographically more secure version: see this post

``````''.join(random.SystemRandom().choice(string.ascii_uppercase + string.digits) for _ in range(N))
``````

In details, with a clean function for further reuse:

``````>>> import string
>>> import random
>>> def id_generator(size=6, chars=string.ascii_uppercase + string.digits):
...    return ''.join(random.choice(chars) for _ in range(size))
...
>>> id_generator()
'G5G74W'
>>> id_generator(3, "6793YUIO")
'Y3U'
``````

How does it work ?

We import `string`, a module that contains sequences of common ASCII characters, and `random`, a module that deals with random generation.

`string.ascii_uppercase + string.digits` just concatenates the list of characters representing uppercase ASCII chars and digits:

``````>>> string.ascii_uppercase
'ABCDEFGHIJKLMNOPQRSTUVWXYZ'
>>> string.digits
'0123456789'
>>> string.ascii_uppercase + string.digits
'ABCDEFGHIJKLMNOPQRSTUVWXYZ0123456789'
``````

Then we use a list comprehension to create a list of 'n' elements:

``````>>> range(4) # range create a list of 'n' numbers
[0, 1, 2, 3]
>>> ['elem' for _ in range(4)] # we use range to create 4 times 'elem'
['elem', 'elem', 'elem', 'elem']
``````

In the example above, we use `[` to create the list, but we don't in the `id_generator` function so Python doesn't create the list in memory, but generates the elements on the fly, one by one (more about this here).

Instead of asking to create 'n' times the string `elem`, we will ask Python to create 'n' times a random character, picked from a sequence of characters:

``````>>> random.choice("abcde")
'a'
>>> random.choice("abcde")
'd'
>>> random.choice("abcde")
'b'
``````

Therefore `random.choice(chars) for _ in range(size)` really is creating a sequence of `size` characters. Characters that are randomly picked from `chars`:

``````>>> [random.choice('abcde') for _ in range(3)]
['a', 'b', 'b']
>>> [random.choice('abcde') for _ in range(3)]
['e', 'b', 'e']
>>> [random.choice('abcde') for _ in range(3)]
['d', 'a', 'c']
``````

Then we just join them with an empty string so the sequence becomes a string:

``````>>> ''.join(['a', 'b', 'b'])
'abb'
>>> [random.choice('abcde') for _ in range(3)]
['d', 'c', 'b']
>>> ''.join(random.choice('abcde') for _ in range(3))
'dac'
``````
• @jorelli: It's not a list comprehension; it's a generator expression. Jun 9, 2011 at 20:34
• @TKKocheran: Do you mean SystemRandom? If not, please supply URL. Feb 11, 2012 at 7:28
• Very useful. Interestingly, Django is using this piece of code for generating passwords & CSRF tokens. Although you should replace `random` with `random.SystemRandom()` : github.com/django/django/blob/…
– user
Jun 21, 2014 at 7:03
• @Chiel92, `random.sample` creates samples without replacement, in other words, without the possibility to repeat characters, which isn't in the OP's requirements. I don't think that would be desirable for most applications. Aug 12, 2014 at 3:18

This Stack Overflow quesion is the current top Google result for "random string Python". The current top answer is:

``````''.join(random.choice(string.ascii_uppercase + string.digits) for _ in range(N))
``````

This is an excellent method, but the PRNG in random is not cryptographically secure. I assume many people researching this question will want to generate random strings for encryption or passwords. You can do this securely by making a small change in the above code:

``````''.join(random.SystemRandom().choice(string.ascii_uppercase + string.digits) for _ in range(N))
``````

Using `random.SystemRandom()` instead of just random uses /dev/urandom on *nix machines and `CryptGenRandom()` in Windows. These are cryptographically secure PRNGs. Using `random.choice` instead of `random.SystemRandom().choice` in an application that requires a secure PRNG could be potentially devastating, and given the popularity of this question, I bet that mistake has been made many times already.

If you're using python3.6 or above, you can use the new secrets module as mentioned in MSeifert's answer:

``````''.join(secrets.choice(string.ascii_uppercase + string.digits) for _ in range(N))
``````

The module docs also discuss convenient ways to generate secure tokens and best practices.

• Yes, the official standard library for `random` has warn this: "Warning: The pseudo-random generators of this module should not be used for security purposes. Use os.urandom() or SystemRandom if you require a cryptographically secure pseudo-random number generator." Here is the ref: random.SystemRandom and os.urandom May 16, 2015 at 14:30
• Great answer. Small note: You changed it to `string.uppercase` which can lead to unexpected results depending on the locale set. Using `string.ascii_uppercase` (or `string.ascii_letters + string.digits` for base62 instead of base36) is safer in cases where encoding is involved. May 17, 2015 at 18:03
• small note - better to use `xrange` instead of `range` as the latter generates an in-memory list, while the former creates an iterator.
– Guy
Jul 31, 2016 at 11:44
• will the random sting will be alway be unique ? i wanted to use a primary key. Sep 27, 2016 at 8:45
• @shakthydoss: no. It may return "AAA000", which is a random string, and next "AAA000", which is also a random string. You must explicitly add a check for uniqueness. Mar 2, 2018 at 11:15

# Simply use Python's builtin uuid:

If UUIDs are okay for your purposes, use the built-in uuid package.

## One Line Solution:

`import uuid; uuid.uuid4().hex.upper()[0:6]`

## In Depth Version:

Example:

``````import uuid
uuid.uuid4() #uuid4 => full random uuid
# Outputs something like: UUID('0172fc9a-1dac-4414-b88d-6b9a6feb91ea')
``````

If you need exactly your format (for example, "6U1S75"), you can do it like this:

``````import uuid

def my_random_string(string_length=10):
"""Returns a random string of length string_length."""
random = str(uuid.uuid4()) # Convert UUID format to a Python string.
random = random.upper() # Make all characters uppercase.
random = random.replace("-","") # Remove the UUID '-'.
return random[0:string_length] # Return the random string.

print(my_random_string(6)) # For example, D9E50C
``````
• +1 For thinking behind the question. Perhaps you could briefly explain the difference between uuid1 and uuid4. Jan 29, 2014 at 12:36
• uui1: Generate a UUID from a host ID, sequence number, and the current time. uuid4: Generate a random UUID. Mar 14, 2014 at 5:19
• If you want to skip the string casting & hyphen replacing, you can just call my_uuid.get_hex() or uuid.uuid4().get_hex() and it will return a string generated from the uuid that does not have hyphens. Apr 11, 2014 at 0:50
• Is it a good idea to truncate a UUID? Depending on how small `string_length` is, the probability of collision can be a concern.
– user
Jun 21, 2014 at 7:01
• Why limit yourself to just hex characters. Base64 or Base32 (for only uppercase characters and 6 different digits) to encode a random `os.urandom()` bytes sequence. Bypass the `uuid` middleman for more speed! Jan 24, 2018 at 13:39

A simpler, faster but slightly less random way is to use `random.sample` instead of choosing each letter separately, If n-repetitions are allowed, enlarge your random basis by n times e.g.

``````import random
import string

char_set = string.ascii_uppercase + string.digits
print ''.join(random.sample(char_set*6, 6))
``````

Note: random.sample prevents character reuse, multiplying the size of the character set makes multiple repetitions possible, but they are still less likely then they are in a pure random choice. If we go for a string of length 6, and we pick 'X' as the first character, in the choice example, the odds of getting 'X' for the second character are the same as the odds of getting 'X' as the first character. In the random.sample implementation, the odds of getting 'X' as any subsequent character are only 6/7 the chance of getting it as the first character

• This way isn't bad but it's not quite as random as selecting each character separately, as with `sample` you'll never get the same character listed twice. Also of course it'll fail for `N` higher than `36`. Feb 13, 2010 at 12:54
• for the given use case(if no repeat is ok) i will say it is still the best solution. Feb 13, 2010 at 14:30
• One of the examples has a repeat, so I doubt he is looking to disallow repeats. Feb 13, 2010 at 14:34
• If random.sample prevents character reuse, multiplying the size of the character set makes multiple repetitions possible, but they are still less likely then they are in a pure random choice. If we go for a string of length 6, and we pick 'X' as the first character, in the choice example, the odds of getting 'X' for the second character are the same as the odds of getting 'X' as the first character. In the random.sample implementation, the odds of getting 'X' as any subsequent character are only 5/6 the chance of getting it as the first character. Aug 31, 2013 at 19:11
• The chance of getting a particular character repeated drops off as you move through the generated string. Generating a string of 6 characters from the 26 uppercase letters plus 10 digits, randomly choosing each character independently, any particular string occurs with frequency 1/(36^6). The chance of generating 'FU3WYE' and 'XXXXXX' is the same. In the sample implementation, the chance of generating 'XXXXXX' is (1/(36^6)) * ((6/6) * (5/6) * (4/6) * (3/6) * (2/6) * (1/6)) due to the non-replacement feature of random.sample. 'XXXXXX' is 324 times less likely in the sample implementation. Aug 31, 2013 at 19:24
``````import uuid
lowercase_str = uuid.uuid4().hex
``````

`lowercase_str` is a random value like `'cea8b32e00934aaea8c005a35d85a5c0'`

``````uppercase_str = lowercase_str.upper()
``````

`uppercase_str` is `'CEA8B32E00934AAEA8C005A35D85A5C0'`

• `uppercase_str[:N+1]`
– Yajo
May 12, 2016 at 15:51
• @Yajo yeah we can limit using slicing May 13, 2016 at 4:40
• @Yajo: no, you don't want to slice the hex value. You remove entropy compared to a full sequence of uppercase letters and digits. Perhaps base32-encode the value instead (slightly reduced entropy, from 36 ** n to 32 ** n, still better than 16 ** n). Jan 24, 2018 at 13:41
• @Yajo Some bits in the uuid are not random! They are used for indicating which variant and version the uuid is, so they are not random and you get fewer random bits than you expected! Either fully understand how UUIDs work when truncating (read the RFC), or better yet, use the python secrets module (or python2 equivalent random.SystemRandom()), because that gives you security guarantees (in comparison to the uuid module currently). Jan 24, 2022 at 11:12

From Python 3.6 on you should use the secrets module if you need it to be cryptographically secure instead of the `random` module (otherwise this answer is identical to the one of @Ignacio Vazquez-Abrams):

``````from secrets import choice
import string

''.join([choice(string.ascii_uppercase + string.digits) for _ in range(N)])
``````

One additional note: a list-comprehension is faster in the case of `str.join` than using a generator expression!

A faster, easier and more flexible way to do this is to use the `strgen` module (`pip install StringGenerator`).

Generate a 6-character random string with upper case letters and digits:

``````>>> from strgen import StringGenerator as SG
>>> SG("[\u\d]{6}").render()
u'YZI2CI'
``````

Get a unique list:

``````>>> SG("[\l\d]{10}").render_list(5,unique=True)
[u'xqqtmi1pOk', u'zmkWdUr63O', u'PGaGcPHrX2', u'6RZiUbkk2i', u'j9eIeeWgEF']
``````

Guarantee one "special" character in the string:

``````>>> SG("[\l\d]{10}&[\p]").render()
u'jaYI0bcPG*0'
``````

A random HTML color:

``````>>> SG("#[\h]{6}").render()
u'#CEdFCa'
``````

etc.

We need to be aware that this:

``````''.join(random.choice(string.ascii_uppercase + string.digits) for _ in range(N))
``````

might not have a digit (or uppercase character) in it.

`strgen` is faster in developer-time than any of the above solutions. The solution from Ignacio is the fastest run-time performing and is the right answer using the Python Standard Library. But you will hardly ever use it in that form. You will want to use SystemRandom (or fallback if not available), make sure required character sets are represented, use unicode (or not), make sure successive invocations produce a unique string, use a subset of one of the string module character classes, etc. This all requires lots more code than in the answers provided. The various attempts to generalize a solution all have limitations that strgen solves with greater brevity and expressive power using a simple template language.

It's on PyPI:

``````pip install StringGenerator
``````

Disclosure: I'm the author of the strgen module.

• Note this silently falls back to the cryptographically insecure `random.Random` if the secure method is not available! It also uses the fallback when the user is providing a seed value. No general guarantee is made when it uses a cryptographically secure method. Jan 24, 2022 at 11:09

Based on another Stack Overflow answer, Most lightweight way to create a random string and a random hexadecimal number, a better version than the accepted answer would be:

``````('%06x' % random.randrange(16**6)).upper()
``````

much faster.

• This is nice, though it will only use 'A-F' and not 'A-Z'. Also, the code gets a little less nice when parametrize `N`. Jan 29, 2014 at 12:41

I thought no one had answered this yet lol! But hey, here's my own go at it:

``````import random

def random_alphanumeric(limit):
#ascii alphabet of all alphanumerals
r = (range(48, 58) + range(65, 91) + range(97, 123))
random.shuffle(r)
return reduce(lambda i, s: i + chr(s), r[:random.randint(0, len(r))], "")
``````
• I won't vote this down, but I think it's far too complicated for such a simple task. The return expression is a monster. Simple is better than complex. Dec 28, 2012 at 23:14
• @CarlSmith, true my solution seems a bit overkill for the task, but I was aware of the other simpler solutions, and just wished to find an alternative route to a good answer. Without freedom, creativity is in danger, thus I went ahead and posted it.
– JWL
Dec 29, 2012 at 4:40

If you need a random string rather than a pseudo random one, you should use `os.urandom` as the source

``````from os import urandom
from itertools import islice, imap, repeat
import string

def rand_string(length=5):
chars = set(string.ascii_uppercase + string.digits)
char_gen = (c for c in imap(urandom, repeat(1)) if c in chars)
return ''.join(islice(char_gen, None, length))
``````
• How is `os.urandom` not pseudo random? It might be using a better algorithm to generate numbers that are more random, but it is still pseudo random. Dec 9, 2012 at 15:00
• @Tyilo, I am aware of the difference between `/dev/random` and `/dev/urandom`. The problem is that `/dev/random` blocks when there is not enough entropy which limits it's usefulness. For a one time pad `/dev/urandom` isn't good enough, but I think it's better than pseudo random here. Dec 9, 2012 at 21:20
• I would say that both `/dev/random` and `/dev/urandom` is pseudo random, but it might depend on your definition. Dec 9, 2012 at 21:27

This method is slightly faster, and slightly more annoying, than the random.choice() method Ignacio posted.

It takes advantage of the nature of pseudo-random algorithms, and banks on bitwise and and shift being faster than generating a new random number for each character.

``````# must be length 32 -- 5 bits -- the question didn't specify using the full set
# of uppercase letters ;)
_ALPHABET = 'ABCDEFGHJKLMNPQRSTUVWXYZ23456789'

def generate_with_randbits(size=32):
def chop(x):
while x:
yield x & 31
x = x >> 5
return  ''.join(_ALPHABET[x] for x in chop(random.getrandbits(size * 5))).ljust(size, 'A')
``````

...create a generator that takes out 5 bit numbers at a time 0..31 until none left

...join() the results of the generator on a random number with the right bits

With Timeit, for 32-character strings, the timing was:

``````[('generate_with_random_choice', 28.92901611328125),
('generate_with_randbits', 20.0293550491333)]
``````

...but for 64 character strings, randbits loses out ;)

I would probably never use this approach in production code unless I really disliked my co-workers.

edit: updated to suit the question (uppercase and digits only), and use bitwise operators & and >> instead of % and //

## Security Oriented Approach

Our recommendation for anything security related is to avoid "rolling you own" and to use the secrets module which is specifically vetted for security.

This is from the best practices section of the docs:

``````import string
import secrets
alphabet = string.ascii_letters + string.digits
password = ''.join(secrets.choice(alphabet) for i in range(8))
``````

Since you specifically asked for uppercase letters, you can either substitute `ascii_uppercase` for `ascii_letters`, or just uppercase the password with:

``````password = password.upper()
``````

## Standard Approach Not Aiming for Security

The canonical approach to this problem (as specified) uses the choices() function in the random module:

``````>>> from random import choices
>>> from string import ascii_uppercase, digits

>>> population = ascii_uppercase + digits
>>> str.join('', choices(population, k=6))
'6JWF1H'
``````

Use Numpy's random.choice() function

``````import numpy as np
import string

if __name__ == '__main__':
length = 16
a = np.random.choice(list(string.ascii_uppercase + string.digits), length)
print(''.join(a))
``````

Documentation is here http://docs.scipy.org/doc/numpy-1.10.0/reference/generated/numpy.random.choice.html

• Why should I use numpy random instead of python stdlib random? Jul 8, 2016 at 13:17
• Because it allows more options in arguments like length, variable probability and selection with replacement. Jul 11, 2016 at 21:17

I'd do it this way:

``````import random
from string import digits, ascii_uppercase

legals = digits + ascii_uppercase

def rand_string(length, char_set=legals):

output = ''
for _ in range(length): output += random.choice(char_set)
return output
``````

Or just:

``````def rand_string(length, char_set=legals):

return ''.join( random.choice(char_set) for _ in range(length) )
``````

Sometimes 0 (zero) & O (letter O) can be confusing. So I use

``````import uuid
uuid.uuid4().hex[:6].upper().replace('0','X').replace('O','Y')
``````
• Some bits in the uuid are not random! They are used for indicating which variant and version the uuid is, so they are not random and you get fewer random bits than you expected if you are truncating it! Either fully understand how UUIDs work when truncating (read the RFC), or better yet, use the python secrets module (or python2 equivalent random.SystemRandom()), because that gives you security guarantees (in comparison to the uuid module currently). Jan 24, 2022 at 11:13
``````>>> import string
>>> import random
``````

the following logic still generates 6 character random sample

``````>>> print ''.join(random.sample((string.ascii_uppercase+string.digits),6))
JT7K3Q
``````

No need to multiply by 6

``````>>> print ''.join(random.sample((string.ascii_uppercase+string.digits)*6,6))

TK82HK
``````
• But this variant will force all characters to be different. And it will not work if N is larger than len(string.ascii_uppercase + string.digits) Jan 9, 2016 at 9:08

I used this method to generate random string of length n from a -> z

``````import random
s = ''.join(random.choice([chr(i) for i in range(ord('a'),ord('z'))]) for _ in range(10))``````

``````>>> import random
>>> str = []
>>> chars = 'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ1234567890'
>>> num = int(raw_input('How long do you want the string to be?  '))
How long do you want the string to be?  10
>>> for k in range(1, num+1):
...    str.append(random.choice(chars))
...
>>> str = "".join(str)
>>> str
'tm2JUQ04CK'
``````

The `random.choice` function picks a random entry in a list. You also create a list so that you can append the character in the `for` statement. At the end str is ['t', 'm', '2', 'J', 'U', 'Q', '0', '4', 'C', 'K'], but the `str = "".join(str)` takes care of that, leaving you with `'tm2JUQ04CK'`.

Hope this helps!

• Nice, but you could have used `range(num)` instead, and str could have been a string `str += random.choice(chars)`. May 9, 2014 at 16:32

For those of you who enjoy functional python:

``````from itertools import imap, starmap, islice, repeat
from functools import partial
from string import letters, digits, join
from random import choice

join_chars = partial(join, sep='')
identity = lambda o: o

def irand_seqs(symbols=join_chars((letters, digits)), length=6, join=join_chars, select=choice, breakup=islice):
""" Generates an indefinite sequence of joined random symbols each of a specific length
:param symbols: symbols to select,
[defaults to string.letters + string.digits, digits 0 - 9, lower and upper case English letters.]
:param length: the length of each sequence,
[defaults to 6]
:param join: method used to join selected symbol,
[defaults to ''.join generating a string.]
:param select: method used to select a random element from the giving population.
[defaults to random.choice, which selects a single element randomly]
:return: indefinite iterator generating random sequences of giving [:param length]
>>> from tools import irand_seqs
>>> strings = irand_seqs()
>>> a = next(strings)
>>> assert isinstance(a, (str, unicode))
>>> assert len(a) == 6
>>> assert next(strings) != next(strings)
"""
return imap(join, starmap(breakup, repeat((imap(select, repeat(symbols)), None, length))))
``````

It generates an indefinite [infinite] iterator, of joined random sequences, by first generating an indefinite sequence of randomly selected symbol from the giving pool, then breaking this sequence into length parts which is then joined, it should work with any sequence that supports getitem, by default it simply generates a random sequence of alpha numeric letters, though you can easily modify to generate other things:

for example to generate random tuples of digits:

``````>>> irand_tuples = irand_seqs(xrange(10), join=tuple)
>>> next(irand_tuples)
(0, 5, 5, 7, 2, 8)
>>> next(irand_tuples)
(3, 2, 2, 0, 3, 1)
``````

if you don't want to use next for generation you can simply make it callable:

``````>>> irand_tuples = irand_seqs(xrange(10), join=tuple)
>>> make_rand_tuples = partial(next, irand_tuples)
>>> make_rand_tuples()
(1, 6, 2, 8, 1, 9)
``````

if you want to generate the sequence on the fly simply set join to identity.

``````>>> irand_tuples = irand_seqs(xrange(10), join=identity)
>>> selections = next(irand_tuples)
>>> next(selections)
8
>>> list(selections)
[6, 3, 8, 2, 2]
``````

As others have mentioned if you need more security then set the appropriate select function:

``````>>> from random import SystemRandom
>>> rand_strs = irand_seqs(select=SystemRandom().choice)
``````

the default selector is `choice` which may select the same symbol multiple times for each chunk, if instead you'd want the same member selected at most once for each chunk then, one possible usage:

``````>>> from random import sample
>>> irand_samples = irand_seqs(xrange(10), length=1, join=next, select=lambda pool: sample(pool, 6))
>>> next(irand_samples)
[0, 9, 2, 3, 1, 6]
``````

we use `sample` as our selector, to do the complete selection, so the chunks are actually length 1, and to join we simply call `next` which fetches the next completely generated chunk, granted this example seems a bit cumbersome and it is ...

(1) This will give you all caps and numbers:

``````import string, random
passkey=''
for x in range(8):
if random.choice([1,2]) == 1:
passkey += passkey.join(random.choice(string.ascii_uppercase))
else:
passkey += passkey.join(random.choice(string.digits))
print passkey
``````

(2) If you later want to include lowercase letters in your key, then this will also work:

``````import string, random
passkey=''
for x in range(8):
if random.choice([1,2]) == 1:
passkey += passkey.join(random.choice(string.ascii_letters))
else:
passkey += passkey.join(random.choice(string.digits))
print passkey
``````

this is a take on Anurag Uniyal 's response and something that i was working on myself.

``````import random
import string

oneFile = open('‪Numbers.txt', 'w')
userInput = 0
key_count = 0
value_count = 0
chars = string.ascii_uppercase + string.digits + string.punctuation

for userInput in range(int(input('How many 12 digit keys do you want?'))):
while key_count <= userInput:
key_count += 1
number = random.randint(1, 999)
key = number

text = str(key) + ": " + str(''.join(random.sample(chars*6, 12)))
oneFile.write(text + "\n")
oneFile.close()
``````

I was looking at the different answers and took time to read the documentation of secrets

The secrets module is used for generating cryptographically strong random numbers suitable for managing data such as passwords, account authentication, security tokens, and related secrets.

In particularly, secrets should be used in preference to the default pseudo-random number generator in the random module, which is designed for modelling and simulation, not security or cryptography.

Looking more into what it has to offer I found a very handy function if you want to mimic an ID like Google Drive IDs:

secrets.token_urlsafe([nbytes=None])
Return a random URL-safe text string, containing nbytes random bytes. The text is Base64 encoded, so on average each byte results in approximately 1.3 characters. If nbytes is None or not supplied, a reasonable default is used.

Use it the following way:

``````import secrets
import math

def id_generator():
id = secrets.token_urlsafe(math.floor(32 / 1.3))
return id

print(id_generator())
``````

Output a 32 characters length id:

``````joXR8dYbBDAHpVs5ci6iD-oIgPhkeQFk
``````

I know this is slightly different from the OP's question but I expect that it would still be helpful to many who were looking for the same use-case that I was looking for.

``````import string
from random import *
characters = string.ascii_letters + string.punctuation  + string.digits
password =  "".join(choice(characters) for x in range(randint(8, 16)))
``````
``````import random
q=2
o=1
list  =[r'a','b','c','d','e','f','g','h','i','j','k','l','m','n','o','p','q','r','s','t','u','v','w','s','0','1','2','3','4','5','6','7','8','9','0']
while(q>o):
print("")

for i in range(1,128):
x=random.choice(list)
print(x,end="")
``````

Here length of string can be changed in for loop i.e for i in range(1,length) It is simple algorithm which is easy to understand. it uses list so you can discard characters that you do not need.

Generate random 16-byte ID containig letters, digits, '_' and '-'

`os.urandom(16).translate((f'{string.ascii_letters}{string.digits}-_'*4).encode('ascii'))`

• When I time this on my machine, this is about x40 faster than solutions involving `random.choices()`, and about x200 faster than solutions using `random.choice()`.
– Carl
Oct 5, 2022 at 21:23

A simple one:

``````import string
import random
character = string.lowercase + string.uppercase + string.digits + string.punctuation
char_len = len(character)
pass_len = random.randint(10,20)
for x in range(pass_len):
``````

I would like to suggest you next option:

``````import crypt
n = 10
crypt.crypt("any sring").replace('/', '').replace('.', '').upper()[-n:-1]
``````

Paranoic mode:

``````import uuid
import crypt
n = 10
crypt.crypt(str(uuid.uuid4())).replace('/', '').replace('.', '').upper()[-n:-1]
``````

Two methods :

``````import random, math
``````

``````def randStr_1(chars:str, length:int) -> str:
chars *= math.ceil(length / len(chars))
chars = letters[0:length]
chars = list(chars)
random.shuffle(characters)

return ''.join(chars)
``````

``````def randStr_2(chars:str, length:int) -> str:
return ''.join(random.choice(chars) for i in range(chars))
``````

Benchmark :

``````from timeit import timeit

setup = """
import os, subprocess, time, string, random, math

def randStr_1(letters:str, length:int) -> str:
letters *= math.ceil(length / len(letters))
letters = letters[0:length]
letters = list(letters)
random.shuffle(letters)
return ''.join(letters)

def randStr_2(letters:str, length:int) -> str:
return ''.join(random.choice(letters) for i in range(length))
"""

print('Method 1 vs Method 2', ', run 10 times each.')

for length in [100,1000,10000,50000,100000,500000,1000000]:
print(length, 'characters:')

eff1 = timeit("randStr_1(string.ascii_letters, {})".format(length), setup=setup, number=10)
eff2 = timeit("randStr_2(string.ascii_letters, {})".format(length), setup=setup, number=10)
print('\t{}s : {}s'.format(round(eff1, 6), round(eff2, 6)))
print('\tratio = {} : {}\n'.format(eff1/eff1, round(eff2/eff1, 2)))
``````

Output :

``````Method 1 vs Method 2 , run 10 times each.

100 characters:
0.001411s : 0.00179s
ratio = 1.0 : 1.27

1000 characters:
0.013857s : 0.017603s
ratio = 1.0 : 1.27

10000 characters:
0.13426s : 0.151169s
ratio = 1.0 : 1.13

50000 characters:
0.709403s : 0.855136s
ratio = 1.0 : 1.21

100000 characters:
1.360735s : 1.674584s
ratio = 1.0 : 1.23

500000 characters:
6.754923s : 7.160508s
ratio = 1.0 : 1.06

1000000 characters:
11.232965s : 14.223914s
ratio = 1.0 : 1.27
``````

The performance of first method is better.

``````import string, random
lower = string.ascii_lowercase
upper = string.ascii_uppercase
digits = string.digits
special = '!"£\$%^&*.,@#/?'

def rand_pass(l=4, u=4, d=4, s=4):
p = []
[p.append(random.choice(lower)) for x in range(l)]
[p.append(random.choice(upper)) for x in range(u)]
[p.append(random.choice(digits)) for x in range(d)]
[p.append(random.choice(special)) for x in range(s)]
random.shuffle(p)
return "".join(p)

print(rand_pass())
# @5U,@A4yIZvnp%51
``````

If you want an easy-to-use but highly customisable key generator, use `key-generator` pypi package.

Here is the GitHub repo where you can find the complete documentation.

You can customise it to give a string jist like you want with many more options. Here's an example:

``````from key_generator.key_generator import generate

custom_key = generate(2, ['-', ':'], 3, 10, type_of_value = 'char', capital = 'mix', seed = 17).get_key()
print(custom_key)  # ZLFdHXIUe-ekwJCu
``````

Hope this helps :)

Disclaimer: This uses the `key-generator` library which I made.