Crypt::SaltedHash - Perl interface to functions that assist in working with
salted hashes.
use Crypt::SaltedHash;
my $csh = Crypt::SaltedHash->new(algorithm => 'SHA-1');
$csh->add('secret');
my $salted = $csh->generate;
my $valid = Crypt::SaltedHash->validate($salted, 'secret');
The "Crypt::SaltedHash" module provides an object oriented interface
to create salted (or seeded) hashes of clear text data. The original
formalization of this concept comes from RFC-3112 and is extended by the use
of different digital agorithms.
The process starts with 2 elements of data:
- •
- a clear text string (this could represent a password for
instance).
- •
- the salt, a random seed of data. This is the value used to
augment a hash in order to ensure that 2 hashes of identical data yield
different output.
For the purposes of this abstract we will analyze the steps within code that
perform the necessary actions to achieve the endresult hashes. Cryptographers
call this hash a digest. We will not however go into an explanation of a
one-way encryption scheme. Readers of this abstract are encouraged to get
information on that subject by their own.
Theoretically, an implementation of a one-way function as an algorithm takes
input, and provides output, that are both in binary form; realistically though
digests are typically encoded and stored in a database or in a flat text or
XML file. Take slappasswd5 for instance, it performs the exact functionality
described above. We will use it as a black box compiled piece of code for our
analysis.
In pseudocode we generate a salted hash as follows:
Get the source string and salt as separate binary objects
Concatenate the 2 binary values
Hash the concatenation into SaltedPasswordHash
Base64Encode(concat(SaltedPasswordHash, Salt))
We take a clear text string and hash this into a binary object representing the
hashed value of the clear text string plus the random salt. Then we have the
Salt value, which are typically 4 bytes of purely random binary data
represented as hexadecimal notation (Base16 as 8 bytes).
Using SHA-1 as the hashing algorithm, SaltedPasswordHash is of length 20 (bytes)
in raw binary form (40 bytes if we look at it in hex). Salt is then 4 bytes in
raw binary form. The SHA-1 algorithm generates a 160 bit hash string. Consider
that 8 bits = 1 byte. So 160 bits = 20 bytes, which is exactly what the
algorithm gives us.
The Base64 encoding of the binary result looks like:
{SSHA}B0O0XSYdsk7g9K229ZEr73Lid7HBD9DX
Take note here that the final output is a 32-byte string of data. The Base64
encoding process uses bit shifting, masking, and padding as per RFC-3548.
A couple of examples of salted hashes using on the same exact clear-text string:
slappasswd -s testing123
{SSHA}72uhy5xc1AWOLwmNcXALHBSzp8xt4giL
slappasswd -s testing123
{SSHA}zmIAVaKMmTngrUi4UlS0dzYwVAbfBTl7
slappasswd -s testing123
{SSHA}Be3F12VVvBf9Sy6MSqpOgAdEj6JCZ+0f
slappasswd -s testing123
{SSHA}ncHs4XYmQKJqL+VuyNQzQjwRXfvu6noa
4 runs of slappasswd against the same clear text string each yielded unique
endresult hashes. The random salt is generated silently and never made
visible.
One of the keys to note is that the salt is dealt with twice in the process. It
is used once for the actual application of randomness to the given clear text
string, and then it is stored within the final output as purely Base64 encoded
data. In order to perform an authentication query for instance, we must break
apart the concatenation that was created for storage of the data. We
accomplish this by splitting up the binary data we get after Base64 decoding
the stored hash.
In pseudocode we would perform the extraction and verification operations as
such:
Strip the hash identifier from the Digest
Base64Decode(Digest, 20)
Split Digest into 2 byte arrays, one for bytes 0 � 20(pwhash), one for bytes 21 � 32 (salt)
Get the target string and salt as separate binary object
Concatenate the 2 binary values
SHA hash the concatenation into targetPasswordHash
Compare targetPasswordHash with pwhash
Return corresponding Boolean value
Our job is to split the original digest up into 2 distinct byte arrays, one of
the left 20 (0 - 20 including the null terminator) bytes and the other for the
rest of the data. The left 0 � 20 bytes will represent the salted
binary value we will use for a byte-by-byte data match against the new clear
text presented for verification. The string presented for verification will
have to be salted as well. The rest of the bytes (21 � 32) represent
the random salt which when decoded will show the exact hex characters that
make up the once randomly generated seed.
We are now ready to verify some data. Let's start with the 4 hashes presented
earlier. We will run them through our code to extract the random salt and then
using that verify the clear text string hashed by slappasswd. First, let's do
a verification test with an erroneous password; this should fail the matching
test:
{SSHA}72uhy5xc1AWOLwmNcXALHBSzp8xt4giL Test123
Hash extracted (in hex): ef6ba1cb9c5cd4058e2f098d71700b1c14b3a7cc
Salt extracted (in hex): 6de2088b
Hash length is: 20 Salt length is: 4
Hash presented in hex: 256bc48def0ce04b0af90dfd2808c42588bf9542
Hashes DON'T match: Test123
The match failure test was successful as expected. Now let's use known valid
data through the same exact code:
{SSHA}72uhy5xc1AWOLwmNcXALHBSzp8xt4giL testing123
Hash extracted (in hex): ef6ba1cb9c5cd4058e2f098d71700b1c14b3a7cc
Salt extracted (in hex): 6de2088b
Hash length is: 20 Salt length is: 4
Hash presented in hex: ef6ba1cb9c5cd4058e2f098d71700b1c14b3a7cc
Hashes match: testing123
The process used for salted passwords should now be clear. We see that salting
hashed data does indeed add another layer of security to the clear text
one-way hashing process. But we also see that salted hashes should also be
protected just as if the data was in clear text form. Now that we have seen
salted hashes actually work you should also realize that in code it is
possible to extract salt values and use them for various purposes. Obviously
the usage can be on either side of the colored hat line, but the data is
there.
- new( [%options] )
- Returns a new Crypt::SaltedHash object. Possible keys for
%options are:
- •
-
algorithm: It's also possible to use common string
representations of the algorithm (e.g. "sha256",
"SHA-384"). If the argument is missing, SHA-1 will be used by
default.
- •
-
salt: You can specify your on salt. You can either
specify it as a sequence of charactres or as a hex encoded string of the
form "HEX{...}". If the argument is missing, a random seed is
provided for you (recommended).
- •
-
salt_len: By default, the module assumes a salt
length of 4 bytes (or 8, if it is encoded in hex). If you choose a
different length, you have to tell the validate function how long
your seed was.
-
add( $data, ... )
- Logically joins the arguments into a single string, and
uses it to update the current digest state. For more details see
Digest.
-
clear()
- Resets the digest.
-
salt_bin()
- Returns the salt in binary form.
-
salt_hex()
- Returns the salt in hexadecimal form ('HEX{...}')
-
generate()
- Generates the seeded hash. Uses the clone-method of
Digest before actually performing the digest calculation, so adding more
cleardata after a call of generate to an instance of
Crypt::SaltedHash has the same effect as adding the data before the
call of generate.
-
validate( $hasheddata,
$cleardata , [$salt_len] )
- Validates a hasheddata previously generated against
cleardata. $salt_len defaults to 4 if not set.
Returns 1 if the validation is successful, 0 otherwise.
-
obj()
- Returns a handle to Digest object.
none yet.
Digest, MIME::Base64
Sascha Kiefer,
[email protected]
The author is particularly grateful to Andres Andreu for his article: Salted
hashes demystified - A Primer
(<
http://www.securitydocs.com/library/3439>)
Copyright (C) 2010 Sascha Kiefer
This library is free software; you can redistribute it and/or modify it under
the same terms as Perl itself.