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657 lines
27 KiB
Plaintext
=============================
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Password management in Django
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=============================
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Password management is something that should generally not be reinvented
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unnecessarily, and Django endeavors to provide a secure and flexible set of
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tools for managing user passwords. This document describes how Django stores
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passwords, how the storage hashing can be configured, and some utilities to
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work with hashed passwords.
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.. seealso::
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Even though users may use strong passwords, attackers might be able to
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eavesdrop on their connections. Use :ref:`HTTPS
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<security-recommendation-ssl>` to avoid sending passwords (or any other
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sensitive data) over plain HTTP connections because they will be vulnerable
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to password sniffing.
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.. _auth_password_storage:
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How Django stores passwords
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===========================
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Django provides a flexible password storage system and uses PBKDF2 by default.
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The :attr:`~django.contrib.auth.models.User.password` attribute of a
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:class:`~django.contrib.auth.models.User` object is a string in this format::
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<algorithm>$<iterations>$<salt>$<hash>
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Those are the components used for storing a User's password, separated by the
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dollar-sign character and consist of: the hashing algorithm, the number of
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algorithm iterations (work factor), the random salt, and the resulting password
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hash. The algorithm is one of a number of one-way hashing or password storage
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algorithms Django can use; see below. Iterations describe the number of times
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the algorithm is run over the hash. Salt is the random seed used and the hash
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is the result of the one-way function.
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By default, Django uses the PBKDF2_ algorithm with a SHA256 hash, a
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password stretching mechanism recommended by NIST_. This should be
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sufficient for most users: it's quite secure, requiring massive
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amounts of computing time to break.
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However, depending on your requirements, you may choose a different
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algorithm, or even use a custom algorithm to match your specific
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security situation. Again, most users shouldn't need to do this -- if
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you're not sure, you probably don't. If you do, please read on:
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Django chooses the algorithm to use by consulting the
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:setting:`PASSWORD_HASHERS` setting. This is a list of hashing algorithm
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classes that this Django installation supports. The first entry in this list
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(that is, ``settings.PASSWORD_HASHERS[0]``) will be used to store passwords,
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and all the other entries are valid hashers that can be used to check existing
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passwords. This means that if you want to use a different algorithm, you'll
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need to modify :setting:`PASSWORD_HASHERS` to list your preferred algorithm
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first in the list.
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The default for :setting:`PASSWORD_HASHERS` is::
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PASSWORD_HASHERS = [
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'django.contrib.auth.hashers.PBKDF2PasswordHasher',
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'django.contrib.auth.hashers.PBKDF2SHA1PasswordHasher',
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'django.contrib.auth.hashers.Argon2PasswordHasher',
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'django.contrib.auth.hashers.BCryptSHA256PasswordHasher',
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]
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This means that Django will use PBKDF2_ to store all passwords but will support
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checking passwords stored with PBKDF2SHA1, argon2_, and bcrypt_.
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The next few sections describe a couple of common ways advanced users may want
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to modify this setting.
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.. _argon2_usage:
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Using Argon2 with Django
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------------------------
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Argon2_ is the winner of the 2015 `Password Hashing Competition`_, a community
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organized open competition to select a next generation hashing algorithm. It's
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designed not to be easier to compute on custom hardware than it is to compute
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on an ordinary CPU.
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Argon2_ is not the default for Django because it requires a third-party
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library. The Password Hashing Competition panel, however, recommends immediate
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use of Argon2 rather than the other algorithms supported by Django.
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To use Argon2 as your default storage algorithm, do the following:
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1. Install the `argon2-cffi library`_. This can be done by running ``pip
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install django[argon2]``, which is equivalent to ``pip install argon2-cffi``
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(along with any version requirement from Django's ``setup.py``).
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2. Modify :setting:`PASSWORD_HASHERS` to list ``Argon2PasswordHasher`` first.
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That is, in your settings file, you'd put::
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PASSWORD_HASHERS = [
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'django.contrib.auth.hashers.Argon2PasswordHasher',
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'django.contrib.auth.hashers.PBKDF2PasswordHasher',
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'django.contrib.auth.hashers.PBKDF2SHA1PasswordHasher',
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'django.contrib.auth.hashers.BCryptSHA256PasswordHasher',
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]
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Keep and/or add any entries in this list if you need Django to :ref:`upgrade
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passwords <password-upgrades>`.
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.. _bcrypt_usage:
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Using ``bcrypt`` with Django
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----------------------------
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Bcrypt_ is a popular password storage algorithm that's specifically designed
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for long-term password storage. It's not the default used by Django since it
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requires the use of third-party libraries, but since many people may want to
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use it Django supports bcrypt with minimal effort.
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To use Bcrypt as your default storage algorithm, do the following:
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1. Install the `bcrypt library`_. This can be done by running ``pip install
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django[bcrypt]``, which is equivalent to ``pip install bcrypt`` (along with
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any version requirement from Django's ``setup.py``).
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2. Modify :setting:`PASSWORD_HASHERS` to list ``BCryptSHA256PasswordHasher``
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first. That is, in your settings file, you'd put::
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PASSWORD_HASHERS = [
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'django.contrib.auth.hashers.BCryptSHA256PasswordHasher',
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'django.contrib.auth.hashers.PBKDF2PasswordHasher',
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'django.contrib.auth.hashers.PBKDF2SHA1PasswordHasher',
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'django.contrib.auth.hashers.Argon2PasswordHasher',
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]
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Keep and/or add any entries in this list if you need Django to :ref:`upgrade
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passwords <password-upgrades>`.
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That's it -- now your Django install will use Bcrypt as the default storage
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algorithm.
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.. _increasing-password-algorithm-work-factor:
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Increasing the work factor
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--------------------------
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PBKDF2 and bcrypt
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~~~~~~~~~~~~~~~~~
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The PBKDF2 and bcrypt algorithms use a number of iterations or rounds of
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hashing. This deliberately slows down attackers, making attacks against hashed
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passwords harder. However, as computing power increases, the number of
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iterations needs to be increased. We've chosen a reasonable default (and will
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increase it with each release of Django), but you may wish to tune it up or
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down, depending on your security needs and available processing power. To do so,
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you'll subclass the appropriate algorithm and override the ``iterations``
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parameters. For example, to increase the number of iterations used by the
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default PBKDF2 algorithm:
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1. Create a subclass of ``django.contrib.auth.hashers.PBKDF2PasswordHasher``::
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from django.contrib.auth.hashers import PBKDF2PasswordHasher
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class MyPBKDF2PasswordHasher(PBKDF2PasswordHasher):
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"""
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A subclass of PBKDF2PasswordHasher that uses 100 times more iterations.
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"""
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iterations = PBKDF2PasswordHasher.iterations * 100
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Save this somewhere in your project. For example, you might put this in
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a file like ``myproject/hashers.py``.
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2. Add your new hasher as the first entry in :setting:`PASSWORD_HASHERS`::
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PASSWORD_HASHERS = [
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'myproject.hashers.MyPBKDF2PasswordHasher',
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'django.contrib.auth.hashers.PBKDF2PasswordHasher',
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'django.contrib.auth.hashers.PBKDF2SHA1PasswordHasher',
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'django.contrib.auth.hashers.Argon2PasswordHasher',
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'django.contrib.auth.hashers.BCryptSHA256PasswordHasher',
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]
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That's it -- now your Django install will use more iterations when it
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stores passwords using PBKDF2.
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Argon2
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~~~~~~
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Argon2 has three attributes that can be customized:
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#. ``time_cost`` controls the number of iterations within the hash.
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#. ``memory_cost`` controls the size of memory that must be used during the
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computation of the hash.
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#. ``parallelism`` controls how many CPUs the computation of the hash can be
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parallelized on.
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The default values of these attributes are probably fine for you. If you
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determine that the password hash is too fast or too slow, you can tweak it as
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follows:
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#. Choose ``parallelism`` to be the number of threads you can
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spare computing the hash.
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#. Choose ``memory_cost`` to be the KiB of memory you can spare.
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#. Adjust ``time_cost`` and measure the time hashing a password takes.
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Pick a ``time_cost`` that takes an acceptable time for you.
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If ``time_cost`` set to 1 is unacceptably slow, lower ``memory_cost``.
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.. admonition:: ``memory_cost`` interpretation
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The argon2 command-line utility and some other libraries interpret the
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``memory_cost`` parameter differently from the value that Django uses. The
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conversion is given by ``memory_cost == 2 ** memory_cost_commandline``.
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.. _password-upgrades:
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Password upgrading
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------------------
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When users log in, if their passwords are stored with anything other than
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the preferred algorithm, Django will automatically upgrade the algorithm
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to the preferred one. This means that old installs of Django will get
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automatically more secure as users log in, and it also means that you
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can switch to new (and better) storage algorithms as they get invented.
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However, Django can only upgrade passwords that use algorithms mentioned in
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:setting:`PASSWORD_HASHERS`, so as you upgrade to new systems you should make
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sure never to *remove* entries from this list. If you do, users using
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unmentioned algorithms won't be able to upgrade. Hashed passwords will be
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updated when increasing (or decreasing) the number of PBKDF2 iterations or
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bcrypt rounds.
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Be aware that if all the passwords in your database aren't encoded in the
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default hasher's algorithm, you may be vulnerable to a user enumeration timing
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attack due to a difference between the duration of a login request for a user
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with a password encoded in a non-default algorithm and the duration of a login
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request for a nonexistent user (which runs the default hasher). You may be able
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to mitigate this by :ref:`upgrading older password hashes
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<wrapping-password-hashers>`.
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.. _wrapping-password-hashers:
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Password upgrading without requiring a login
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--------------------------------------------
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If you have an existing database with an older, weak hash such as MD5 or SHA1,
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you might want to upgrade those hashes yourself instead of waiting for the
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upgrade to happen when a user logs in (which may never happen if a user doesn't
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return to your site). In this case, you can use a "wrapped" password hasher.
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For this example, we'll migrate a collection of SHA1 hashes to use
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PBKDF2(SHA1(password)) and add the corresponding password hasher for checking
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if a user entered the correct password on login. We assume we're using the
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built-in ``User`` model and that our project has an ``accounts`` app. You can
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modify the pattern to work with any algorithm or with a custom user model.
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First, we'll add the custom hasher:
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.. code-block:: python
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:caption: accounts/hashers.py
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from django.contrib.auth.hashers import (
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PBKDF2PasswordHasher, SHA1PasswordHasher,
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)
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class PBKDF2WrappedSHA1PasswordHasher(PBKDF2PasswordHasher):
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algorithm = 'pbkdf2_wrapped_sha1'
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def encode_sha1_hash(self, sha1_hash, salt, iterations=None):
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return super().encode(sha1_hash, salt, iterations)
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def encode(self, password, salt, iterations=None):
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_, _, sha1_hash = SHA1PasswordHasher().encode(password, salt).split('$', 2)
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return self.encode_sha1_hash(sha1_hash, salt, iterations)
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The data migration might look something like:
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.. code-block:: python
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:caption: accounts/migrations/0002_migrate_sha1_passwords.py
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from django.db import migrations
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from ..hashers import PBKDF2WrappedSHA1PasswordHasher
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def forwards_func(apps, schema_editor):
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User = apps.get_model('auth', 'User')
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users = User.objects.filter(password__startswith='sha1$')
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hasher = PBKDF2WrappedSHA1PasswordHasher()
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for user in users:
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algorithm, salt, sha1_hash = user.password.split('$', 2)
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user.password = hasher.encode_sha1_hash(sha1_hash, salt)
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user.save(update_fields=['password'])
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class Migration(migrations.Migration):
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dependencies = [
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('accounts', '0001_initial'),
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# replace this with the latest migration in contrib.auth
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('auth', '####_migration_name'),
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]
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operations = [
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migrations.RunPython(forwards_func),
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]
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Be aware that this migration will take on the order of several minutes for
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several thousand users, depending on the speed of your hardware.
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Finally, we'll add a :setting:`PASSWORD_HASHERS` setting:
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.. code-block:: python
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:caption: mysite/settings.py
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PASSWORD_HASHERS = [
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'django.contrib.auth.hashers.PBKDF2PasswordHasher',
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'accounts.hashers.PBKDF2WrappedSHA1PasswordHasher',
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]
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Include any other hashers that your site uses in this list.
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.. _sha1: https://en.wikipedia.org/wiki/SHA1
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.. _pbkdf2: https://en.wikipedia.org/wiki/PBKDF2
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.. _nist: https://dx.doi.org/10.6028/NIST.SP.800-132
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.. _bcrypt: https://en.wikipedia.org/wiki/Bcrypt
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.. _`bcrypt library`: https://pypi.org/project/bcrypt/
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.. _`argon2-cffi library`: https://pypi.org/project/argon2_cffi/
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.. _argon2: https://en.wikipedia.org/wiki/Argon2
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.. _`Password Hashing Competition`: https://password-hashing.net
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.. _auth-included-hashers:
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Included hashers
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----------------
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The full list of hashers included in Django is::
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[
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'django.contrib.auth.hashers.PBKDF2PasswordHasher',
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'django.contrib.auth.hashers.PBKDF2SHA1PasswordHasher',
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'django.contrib.auth.hashers.Argon2PasswordHasher',
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'django.contrib.auth.hashers.BCryptSHA256PasswordHasher',
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'django.contrib.auth.hashers.BCryptPasswordHasher',
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'django.contrib.auth.hashers.SHA1PasswordHasher',
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'django.contrib.auth.hashers.MD5PasswordHasher',
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'django.contrib.auth.hashers.UnsaltedSHA1PasswordHasher',
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'django.contrib.auth.hashers.UnsaltedMD5PasswordHasher',
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'django.contrib.auth.hashers.CryptPasswordHasher',
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]
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The corresponding algorithm names are:
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* ``pbkdf2_sha256``
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* ``pbkdf2_sha1``
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* ``argon2``
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* ``bcrypt_sha256``
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* ``bcrypt``
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* ``sha1``
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* ``md5``
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* ``unsalted_sha1``
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* ``unsalted_md5``
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* ``crypt``
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.. _write-your-own-password-hasher:
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Writing your own hasher
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-----------------------
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If you write your own password hasher that contains a work factor such as a
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number of iterations, you should implement a
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``harden_runtime(self, password, encoded)`` method to bridge the runtime gap
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between the work factor supplied in the ``encoded`` password and the default
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work factor of the hasher. This prevents a user enumeration timing attack due
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to difference between a login request for a user with a password encoded in an
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older number of iterations and a nonexistent user (which runs the default
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hasher's default number of iterations).
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Taking PBKDF2 as example, if ``encoded`` contains 20,000 iterations and the
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hasher's default ``iterations`` is 30,000, the method should run ``password``
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through another 10,000 iterations of PBKDF2.
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If your hasher doesn't have a work factor, implement the method as a no-op
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(``pass``).
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Manually managing a user's password
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===================================
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.. module:: django.contrib.auth.hashers
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The :mod:`django.contrib.auth.hashers` module provides a set of functions
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to create and validate hashed passwords. You can use them independently
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from the ``User`` model.
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.. function:: check_password(password, encoded)
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If you'd like to manually authenticate a user by comparing a plain-text
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password to the hashed password in the database, use the convenience
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function :func:`check_password`. It takes two arguments: the plain-text
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password to check, and the full value of a user's ``password`` field in the
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database to check against, and returns ``True`` if they match, ``False``
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otherwise.
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.. function:: make_password(password, salt=None, hasher='default')
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Creates a hashed password in the format used by this application. It takes
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one mandatory argument: the password in plain-text. Optionally, you can
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provide a salt and a hashing algorithm to use, if you don't want to use the
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defaults (first entry of ``PASSWORD_HASHERS`` setting). See
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:ref:`auth-included-hashers` for the algorithm name of each hasher. If the
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password argument is ``None``, an unusable password is returned (one that
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will never be accepted by :func:`check_password`).
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.. function:: is_password_usable(encoded_password)
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Returns ``False`` if the password is a result of
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:meth:`.User.set_unusable_password`.
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.. versionchanged:: 2.1
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In older versions, this also returns ``False`` if the password is
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``None`` or an empty string, or if the password uses a hasher that's
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not in the :setting:`PASSWORD_HASHERS` setting. That behavior is
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considered a bug as it prevents users with such passwords from
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requesting a password reset.
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.. _password-validation:
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Password validation
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===================
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.. module:: django.contrib.auth.password_validation
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Users often choose poor passwords. To help mitigate this problem, Django
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offers pluggable password validation. You can configure multiple password
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validators at the same time. A few validators are included in Django, but it's
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simple to write your own as well.
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Each password validator must provide a help text to explain the requirements to
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the user, validate a given password and return an error message if it does not
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meet the requirements, and optionally receive passwords that have been set.
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Validators can also have optional settings to fine tune their behavior.
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Validation is controlled by the :setting:`AUTH_PASSWORD_VALIDATORS` setting.
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The default for the setting is an empty list, which means no validators are
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applied. In new projects created with the default :djadmin:`startproject`
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template, a simple set of validators is enabled.
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By default, validators are used in the forms to reset or change passwords and
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in the :djadmin:`createsuperuser` and :djadmin:`changepassword` management
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commands. Validators aren't applied at the model level, for example in
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``User.objects.create_user()`` and ``create_superuser()``, because we assume
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that developers, not users, interact with Django at that level and also because
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model validation doesn't automatically run as part of creating models.
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.. note::
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Password validation can prevent the use of many types of weak passwords.
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However, the fact that a password passes all the validators doesn't
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guarantee that it is a strong password. There are many factors that can
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weaken a password that are not detectable by even the most advanced
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password validators.
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Enabling password validation
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----------------------------
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Password validation is configured in the
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:setting:`AUTH_PASSWORD_VALIDATORS` setting::
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AUTH_PASSWORD_VALIDATORS = [
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{
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'NAME': 'django.contrib.auth.password_validation.UserAttributeSimilarityValidator',
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},
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{
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'NAME': 'django.contrib.auth.password_validation.MinimumLengthValidator',
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'OPTIONS': {
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'min_length': 9,
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}
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},
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{
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'NAME': 'django.contrib.auth.password_validation.CommonPasswordValidator',
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},
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{
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'NAME': 'django.contrib.auth.password_validation.NumericPasswordValidator',
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},
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]
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This example enables all four included validators:
|
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* ``UserAttributeSimilarityValidator``, which checks the similarity between
|
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the password and a set of attributes of the user.
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* ``MinimumLengthValidator``, which simply checks whether the password meets a
|
|
minimum length. This validator is configured with a custom option: it now
|
|
requires the minimum length to be nine characters, instead of the default
|
|
eight.
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* ``CommonPasswordValidator``, which checks whether the password occurs in a
|
|
list of common passwords. By default, it compares to an included list of
|
|
20,000 common passwords.
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|
* ``NumericPasswordValidator``, which checks whether the password isn't
|
|
entirely numeric.
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|
|
|
For ``UserAttributeSimilarityValidator`` and ``CommonPasswordValidator``,
|
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we're simply using the default settings in this example.
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``NumericPasswordValidator`` has no settings.
|
|
|
|
The help texts and any errors from password validators are always returned in
|
|
the order they are listed in :setting:`AUTH_PASSWORD_VALIDATORS`.
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|
|
|
Included validators
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|
-------------------
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|
|
|
Django includes four validators:
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|
|
|
.. class:: MinimumLengthValidator(min_length=8)
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|
|
|
Validates whether the password meets a minimum length.
|
|
The minimum length can be customized with the ``min_length`` parameter.
|
|
|
|
.. class:: UserAttributeSimilarityValidator(user_attributes=DEFAULT_USER_ATTRIBUTES, max_similarity=0.7)
|
|
|
|
Validates whether the password is sufficiently different from certain
|
|
attributes of the user.
|
|
|
|
The ``user_attributes`` parameter should be an iterable of names of user
|
|
attributes to compare to. If this argument is not provided, the default
|
|
is used: ``'username', 'first_name', 'last_name', 'email'``.
|
|
Attributes that don't exist are ignored.
|
|
|
|
The minimum similarity of a rejected password can be set on a scale of 0 to
|
|
1 with the ``max_similarity`` parameter. A setting of 0 rejects all
|
|
passwords, whereas a setting of 1 rejects only passwords that are identical
|
|
to an attribute's value.
|
|
|
|
.. class:: CommonPasswordValidator(password_list_path=DEFAULT_PASSWORD_LIST_PATH)
|
|
|
|
Validates whether the password is not a common password. This converts the
|
|
password to lowercase (to do a case-insensitive comparison) and checks it
|
|
against a list of 20,000 common password created by `Royce Williams
|
|
<https://gist.github.com/roycewilliams/281ce539915a947a23db17137d91aeb7>`_.
|
|
|
|
The ``password_list_path`` can be set to the path of a custom file of
|
|
common passwords. This file should contain one lowercase password per line
|
|
and may be plain text or gzipped.
|
|
|
|
.. versionchanged:: 2.1
|
|
|
|
In older versions, a list of 1,000 common passwords is used.
|
|
|
|
.. class:: NumericPasswordValidator()
|
|
|
|
Validates whether the password is not entirely numeric.
|
|
|
|
Integrating validation
|
|
-----------------------
|
|
|
|
There are a few functions in ``django.contrib.auth.password_validation`` that
|
|
you can call from your own forms or other code to integrate password
|
|
validation. This can be useful if you use custom forms for password setting,
|
|
or if you have API calls that allow passwords to be set, for example.
|
|
|
|
.. function:: validate_password(password, user=None, password_validators=None)
|
|
|
|
Validates a password. If all validators find the password valid, returns
|
|
``None``. If one or more validators reject the password, raises a
|
|
:exc:`~django.core.exceptions.ValidationError` with all the error messages
|
|
from the validators.
|
|
|
|
The ``user`` object is optional: if it's not provided, some validators may
|
|
not be able to perform any validation and will accept any password.
|
|
|
|
.. function:: password_changed(password, user=None, password_validators=None)
|
|
|
|
Informs all validators that the password has been changed. This can be used
|
|
by validators such as one that prevents password reuse. This should be
|
|
called once the password has been successfully changed.
|
|
|
|
For subclasses of :class:`~django.contrib.auth.models.AbstractBaseUser`,
|
|
the password field will be marked as "dirty" when calling
|
|
:meth:`~django.contrib.auth.models.AbstractBaseUser.set_password` which
|
|
triggers a call to ``password_changed()`` after the user is saved.
|
|
|
|
.. function:: password_validators_help_texts(password_validators=None)
|
|
|
|
Returns a list of the help texts of all validators. These explain the
|
|
password requirements to the user.
|
|
|
|
.. function:: password_validators_help_text_html(password_validators=None)
|
|
|
|
Returns an HTML string with all help texts in an ``<ul>``. This is
|
|
helpful when adding password validation to forms, as you can pass the
|
|
output directly to the ``help_text`` parameter of a form field.
|
|
|
|
.. function:: get_password_validators(validator_config)
|
|
|
|
Returns a set of validator objects based on the ``validator_config``
|
|
parameter. By default, all functions use the validators defined in
|
|
:setting:`AUTH_PASSWORD_VALIDATORS`, but by calling this function with an
|
|
alternate set of validators and then passing the result into the
|
|
``password_validators`` parameter of the other functions, your custom set
|
|
of validators will be used instead. This is useful when you have a typical
|
|
set of validators to use for most scenarios, but also have a special
|
|
situation that requires a custom set. If you always use the same set
|
|
of validators, there is no need to use this function, as the configuration
|
|
from :setting:`AUTH_PASSWORD_VALIDATORS` is used by default.
|
|
|
|
The structure of ``validator_config`` is identical to the
|
|
structure of :setting:`AUTH_PASSWORD_VALIDATORS`. The return value of
|
|
this function can be passed into the ``password_validators`` parameter
|
|
of the functions listed above.
|
|
|
|
Note that where the password is passed to one of these functions, this should
|
|
always be the clear text password - not a hashed password.
|
|
|
|
Writing your own validator
|
|
--------------------------
|
|
|
|
If Django's built-in validators are not sufficient, you can write your own
|
|
password validators. Validators are fairly simple classes. They must implement
|
|
two methods:
|
|
|
|
* ``validate(self, password, user=None)``: validate a password. Return
|
|
``None`` if the password is valid, or raise a
|
|
:exc:`~django.core.exceptions.ValidationError` with an error message if the
|
|
password is not valid. You must be able to deal with ``user`` being
|
|
``None`` - if that means your validator can't run, simply return ``None``
|
|
for no error.
|
|
* ``get_help_text()``: provide a help text to explain the requirements to
|
|
the user.
|
|
|
|
Any items in the ``OPTIONS`` in :setting:`AUTH_PASSWORD_VALIDATORS` for your
|
|
validator will be passed to the constructor. All constructor arguments should
|
|
have a default value.
|
|
|
|
Here's a basic example of a validator, with one optional setting::
|
|
|
|
from django.core.exceptions import ValidationError
|
|
from django.utils.translation import gettext as _
|
|
|
|
class MinimumLengthValidator:
|
|
def __init__(self, min_length=8):
|
|
self.min_length = min_length
|
|
|
|
def validate(self, password, user=None):
|
|
if len(password) < self.min_length:
|
|
raise ValidationError(
|
|
_("This password must contain at least %(min_length)d characters."),
|
|
code='password_too_short',
|
|
params={'min_length': self.min_length},
|
|
)
|
|
|
|
def get_help_text(self):
|
|
return _(
|
|
"Your password must contain at least %(min_length)d characters."
|
|
% {'min_length': self.min_length}
|
|
)
|
|
|
|
You can also implement ``password_changed(password, user=None``), which will
|
|
be called after a successful password change. That can be used to prevent
|
|
password reuse, for example. However, if you decide to store a user's previous
|
|
passwords, you should never do so in clear text.
|