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118 lines
4.9 KiB
Plaintext
118 lines
4.9 KiB
Plaintext
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Password Hashing
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========================================
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Storing passwords for user authentication purposes in plaintext is the
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simplest but least secure method; when an attacker compromises the
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database in which the passwords are stored, they immediately gain
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access to all of them. Often passwords are reused among multiple
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services or machines, meaning once a password to a single service is
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known an attacker has a substantial head start on attacking other
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machines.
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The general approach is to store, instead of the password, the output
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of a one way function of the password. Upon receiving an
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authentication request, the authenticator can recompute the one way
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function and compare the value just computed with the one that was
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stored. If they match, then the authentication request succeeds. But
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when an attacker gains access to the database, they only have the
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output of the one way function, not the original password.
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Common hash functions such as SHA-256 are one way, but used alone they
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have problems for this purpose. What an attacker can do, upon gaining
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access to such a stored password database, is hash common dictionary
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words and other possible passwords, storing them in a list. Then he
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can search through his list; if a stored hash and an entry in his list
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match, then he has found the password. Even worse, this can happen
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*offline*: an attacker can begin hashing common passwords days,
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months, or years before ever gaining access to the database. In
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addition, if two users choose the same password, the one way function
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output will be the same for both of them, which will be visible upon
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inspection of the database.
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There are two solutions to these problems: salting and
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iteration. Salting refers to including, along with the password, a
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randomly chosen value which perturbs the one way function. Salting can
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reduce the effectivness of offline dictionary generation (because for
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each potential password, an attacker would have to compute the one way
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function output for all possible salts - with a large enough salt,
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this can make the problem quite difficult). It also prevents the same
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password from producing the same output, as long as the salts do not
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collide. With a large salt (say 80 to 128 bits) this will be quite
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unlikely. Iteration refers to the general technique of forcing
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multiple one way function evaluations when computing the output, to
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slow down the operation. For instance if hashing a single password
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requires running SHA-256 100,000 times instead of just once, that will
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slow down user authentication by a factor of 100,000, but user
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authentication happens quite rarely, and usually there are more
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expensive operations that need to occur anyway (network and database
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I/O, etc). On the other hand, an attacker who is attempting to break a
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database full of stolen password hashes will be seriously
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inconvenienced by a factor of 100,000 slowdown; they will be able to
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only test at a rate of .0001% of what they would without iterations
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(or, equivalently, will require 100,000 times as many zombie botnet
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hosts).
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Botan provides two techniques for password hashing, bcrypt and
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passhash9.
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.. _bcrypt:
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Bcrypt Password Hashing
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----------------------------------------
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Bcrypt is a password hashing scheme originally designed for use in
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OpenBSD, but numerous other implementations exist. It is made
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available by including ``bcrypt.h``. Bcrypt provides outputs that
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look like this::
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"$2a$12$7KIYdyv8Bp32WAvc.7YvI.wvRlyVn0HP/EhPmmOyMQA4YKxINO0p2"
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.. cpp:function:: std::string generate_bcrypt(const std::string& password, \
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RandomNumberGenerator& rng, u16bit work_factor = 10)
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Takes the password to hash, a rng, and a work factor. Higher values
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increase the amount of time the algorithm runs, increasing the cost
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of cracking attempts. The resulting hash is returned as a string.
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.. cpp:function:: bool check_bcrypt(const std::string& password, \
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const std::string& hash)
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Takes a password and a bcrypt output and returns true if the
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password is the same as the one that was used to generate the
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bcrypt hash.
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Here is an example of using bcrypt:
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.. literalinclude:: examples/bcrypt.cpp
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.. _passhash9:
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Passhash9
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----------------------------------------
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Botan also provides a password hashing technique called passhash9, in
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``passhash9.h``, which is based on PBKDF2. Its outputs look like::
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"$9$AAAKxwMGNPSdPkOKJS07Xutm3+1Cr3ytmbnkjO6LjHzCMcMQXvcT"
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.. cpp:function:: std::string generate_passhash9(const std::string& password, \
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RandomNumberGenerator& rng, u16bit work_factor = 10, byte alg_id = 0)
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Functions much like ``generate_bcrypt``. The last parameter,
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``alg_id``, specifies which PRF to use. Currently defined values
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are
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======= ==============
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Value PRF algorithm
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======= ==============
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0 HMAC(SHA-1)
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1 HMAC(SHA-256)
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2 CMAC(Blowfish)
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======= ==============
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.. cpp:function:: bool check_passhash9(const std::string& password, \
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const std::string& hash)
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Functions much like ``check_bcrypt``
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