Postgres-XC 1.0.1 Documentation | ||||
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Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
The pgcrypto module provides cryptographic functions for PostgreSQL.
digest()
digest(data text, type text) returns bytea digest(data bytea, type text) returns bytea
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Computes a binary hash of the given data. type is the algorithm to use. Standard algorithms are md5, sha1, sha224, sha256, sha384 and sha512. If pgcrypto was built with OpenSSL, more algorithms are available, as detailed in Table F-18.
If you want the digest as a hexadecimal string, use
encode()
on the result. For example:
CREATE OR REPLACE FUNCTION sha1(bytea) returns text AS $$ SELECT encode(digest($1, 'sha1'), 'hex') $$ LANGUAGE SQL STRICT IMMUTABLE;
hmac()
hmac(data text, key text, type text) returns bytea hmac(data bytea, key text, type text) returns bytea
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Calculates hashed MAC for data with key key.
type is the same as in digest()
.
This is similar to digest()
but the hash can only be
recalculated knowing the key. This prevents the scenario of someone
altering data and also changing the hash to match.
If the key is larger than the hash block size it will first be hashed and the result will be used as key.
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
The functions crypt()
and gen_salt()
are specifically designed for hashing passwords.
crypt()
does the hashing and gen_salt()
prepares algorithm parameters for it.
The algorithms in crypt()
differ from usual hashing algorithms
like MD5 or SHA1 in the following respects:
They are slow. As the amount of data is so small, this is the only way to make brute-forcing passwords hard.
They use a random value, called the salt, so that users having the same password will have different encrypted passwords. This is also an additional defense against reversing the algorithm.
They include the algorithm type in the result, so passwords hashed with different algorithms can co-exist.
Some of them are adaptive — that means when computers get faster, you can tune the algorithm to be slower, without introducing incompatibility with existing passwords.
Table F-15 lists the algorithms
supported by the crypt()
function.
Table F-15. Supported Algorithms for crypt()
Algorithm | Max Password Length | Adaptive? | Salt Bits | Description |
---|---|---|---|---|
bf | 72 | yes | 128 | Blowfish-based, variant 2a |
md5 | unlimited | no | 48 | MD5-based crypt |
xdes | 8 | yes | 24 | Extended DES |
des | 8 | no | 12 | Original UNIX crypt |
crypt()
crypt(password text, salt text) returns text
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Calculates a crypt(3)-style hash of password.
When storing a new password, you need to use
gen_salt()
to generate a new salt value.
To check a password, pass the stored hash value as salt,
and test whether the result matches the stored value.
Example of setting a new password:
UPDATE ... SET pswhash = crypt('new password', gen_salt('md5'));
Example of authentication:
SELECT pswhash = crypt('entered password', pswhash) FROM ... ;
This returns true if the entered password is correct.
gen_salt()
gen_salt(type text [, iter_count integer ]) returns text
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Generates a new random salt string for use in crypt()
.
The salt string also tells crypt()
which algorithm to use.
The type parameter specifies the hashing algorithm. The accepted types are: des, xdes, md5 and bf.
The iter_count parameter lets the user specify the iteration count, for algorithms that have one. The higher the count, the more time it takes to hash the password and therefore the more time to break it. Although with too high a count the time to calculate a hash may be several years — which is somewhat impractical. If the iter_count parameter is omitted, the default iteration count is used. Allowed values for iter_count depend on the algorithm and are shown in Table F-16.
For xdes there is an additional limitation that the iteration count must be an odd number.
To pick an appropriate iteration count, consider that the original DES crypt was designed to have the speed of 4 hashes per second on the hardware of that time. Slower than 4 hashes per second would probably dampen usability. Faster than 100 hashes per second is probably too fast.
Table F-17 gives an overview of the relative slowness
of different hashing algorithms.
The table shows how much time it would take to try all
combinations of characters in an 8-character password, assuming
that the password contains either only lower case letters, or
upper- and lower-case letters and numbers.
In the crypt-bf entries, the number after a slash is
the iter_count parameter of
gen_salt
.
Table F-17. Hash Algorithm Speeds
Algorithm | Hashes/sec | For [a-z] | For [A-Za-z0-9] |
---|---|---|---|
crypt-bf/8 | 28 | 246 years | 251322 years |
crypt-bf/7 | 57 | 121 years | 123457 years |
crypt-bf/6 | 112 | 62 years | 62831 years |
crypt-bf/5 | 211 | 33 years | 33351 years |
crypt-md5 | 2681 | 2.6 years | 2625 years |
crypt-des | 362837 | 7 days | 19 years |
sha1 | 590223 | 4 days | 12 years |
md5 | 2345086 | 1 day | 3 years |
Notes:
The machine used is a 1.5GHz Pentium 4.
crypt-des and crypt-md5 algorithm numbers are taken from John the Ripper v1.6.38 -test output.
md5 numbers are from mdcrack 1.2.
sha1 numbers are from lcrack-20031130-beta.
crypt-bf numbers are taken using a simple program that loops over 1000 8-character passwords. That way I can show the speed with different numbers of iterations. For reference: john -test shows 213 loops/sec for crypt-bf/5. (The very small difference in results is in accordance with the fact that the crypt-bf implementation in pgcrypto is the same one used in John the Ripper.)
Note that "try all combinations" is not a realistic exercise. Usually password cracking is done with the help of dictionaries, which contain both regular words and various mutations of them. So, even somewhat word-like passwords could be cracked much faster than the above numbers suggest, while a 6-character non-word-like password may escape cracking. Or not.
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
The functions here implement the encryption part of the OpenPGP (RFC 4880) standard. Supported are both symmetric-key and public-key encryption.
An encrypted PGP message consists of 2 parts, or packets:
Packet containing a session key — either symmetric-key or public-key encrypted.
Packet containing data encrypted with the session key.
When encrypting with a symmetric key (i.e., a password):
The given password is hashed using a String2Key (S2K) algorithm. This is
rather similar to crypt()
algorithms — purposefully
slow and with random salt — but it produces a full-length binary
key.
If a separate session key is requested, a new random key will be generated. Otherwise the S2K key will be used directly as the session key.
If the S2K key is to be used directly, then only S2K settings will be put into the session key packet. Otherwise the session key will be encrypted with the S2K key and put into the session key packet.
When encrypting with a public key:
A new random session key is generated.
It is encrypted using the public key and put into the session key packet.
In either case the data to be encrypted is processed as follows:
Optional data-manipulation: compression, conversion to UTF-8, and/or conversion of line-endings.
The data is prefixed with a block of random bytes. This is equivalent to using a random IV.
An SHA1 hash of the random prefix and data is appended.
All this is encrypted with the session key and placed in the data packet.
pgp_sym_encrypt()
pgp_sym_encrypt(data text, psw text [, options text ]) returns bytea pgp_sym_encrypt_bytea(data bytea, psw text [, options text ]) returns bytea
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Encrypt data with a symmetric PGP key psw. The options parameter can contain option settings, as described below.
pgp_sym_decrypt()
pgp_sym_decrypt(msg bytea, psw text [, options text ]) returns text pgp_sym_decrypt_bytea(msg bytea, psw text [, options text ]) returns bytea
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Decrypt a symmetric-key-encrypted PGP message.
Decrypting bytea data with pgp_sym_decrypt
is disallowed.
This is to avoid outputting invalid character data. Decrypting
originally textual data with pgp_sym_decrypt_bytea
is fine.
The options parameter can contain option settings, as described below.
pgp_pub_encrypt()
pgp_pub_encrypt(data text, key bytea [, options text ]) returns bytea pgp_pub_encrypt_bytea(data bytea, key bytea [, options text ]) returns bytea
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Encrypt data with a public PGP key key. Giving this function a secret key will produce a error.
The options parameter can contain option settings, as described below.
pgp_pub_decrypt()
pgp_pub_decrypt(msg bytea, key bytea [, psw text [, options text ]]) returns text pgp_pub_decrypt_bytea(msg bytea, key bytea [, psw text [, options text ]]) returns bytea
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Decrypt a public-key-encrypted message. key must be the secret key corresponding to the public key that was used to encrypt. If the secret key is password-protected, you must give the password in psw. If there is no password, but you want to specify options, you need to give an empty password.
Decrypting bytea data with pgp_pub_decrypt
is disallowed.
This is to avoid outputting invalid character data. Decrypting
originally textual data with pgp_pub_decrypt_bytea
is fine.
The options parameter can contain option settings, as described below.
pgp_key_id()
pgp_key_id(bytea) returns text
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
pgp_key_id
extracts the key ID of a PGP public or secret key.
Or it gives the key ID that was used for encrypting the data, if given
an encrypted message.
It can return 2 special key IDs:
SYMKEY
The message is encrypted with a symmetric key.
ANYKEY
The message is public-key encrypted, but the key ID has been removed. That means you will need to try all your secret keys on it to see which one decrypts it. pgcrypto itself does not produce such messages.
Note that different keys may have the same ID. This is rare but a normal event. The client application should then try to decrypt with each one, to see which fits — like handling ANYKEY.
armor()
, dearmor()
armor(data bytea) returns text dearmor(data text) returns bytea
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
These functions wrap/unwrap binary data into PGP ASCII-armor format, which is basically Base64 with CRC and additional formatting.
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Options are named to be similar to GnuPG. An option's value should be given after an equal sign; separate options from each other with commas. For example:
pgp_sym_encrypt(data, psw, 'compress-algo=1, cipher-algo=aes256')
All of the options except convert-crlf apply only to encrypt functions. Decrypt functions get the parameters from the PGP data.
The most interesting options are probably compress-algo and unicode-mode. The rest should have reasonable defaults.
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Which cipher algorithm to use.
Values: bf, aes128, aes192, aes256 (OpenSSL-only: 3des, cast5)
Default: aes128
Applies to: pgp_sym_encrypt, pgp_pub_encrypt
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Which compression algorithm to use. Only available if PostgreSQL was built with zlib.
Values:
0 - no compression
1 - ZIP compression
2 - ZLIB compression (= ZIP plus meta-data and block CRCs)
Default: 0
Applies to: pgp_sym_encrypt, pgp_pub_encrypt
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
How much to compress. Higher levels compress smaller but are slower. 0 disables compression.
Values: 0, 1-9
Default: 6
Applies to: pgp_sym_encrypt, pgp_pub_encrypt
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Whether to convert \n into \r\n when encrypting and \r\n to \n when decrypting. RFC 4880 specifies that text data should be stored using \r\n line-feeds. Use this to get fully RFC-compliant behavior.
Values: 0, 1
Default: 0
Applies to: pgp_sym_encrypt, pgp_pub_encrypt, pgp_sym_decrypt, pgp_pub_decrypt
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Do not protect data with SHA-1. The only good reason to use this option is to achieve compatibility with ancient PGP products, predating the addition of SHA-1 protected packets to RFC 4880. Recent gnupg.org and pgp.com software supports it fine.
Values: 0, 1
Default: 0
Applies to: pgp_sym_encrypt, pgp_pub_encrypt
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Use separate session key. Public-key encryption always uses a separate session key; this is for symmetric-key encryption, which by default uses the S2K key directly.
Values: 0, 1
Default: 0
Applies to: pgp_sym_encrypt
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Which S2K algorithm to use.
Values:
0 - Without salt. Dangerous!
1 - With salt but with fixed iteration count.
3 - Variable iteration count.
Default: 3
Applies to: pgp_sym_encrypt
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Which digest algorithm to use in S2K calculation.
Values: md5, sha1
Default: sha1
Applies to: pgp_sym_encrypt
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Which cipher to use for encrypting separate session key.
Values: bf, aes, aes128, aes192, aes256
Default: use cipher-algo
Applies to: pgp_sym_encrypt
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Whether to convert textual data from database internal encoding to UTF-8 and back. If your database already is UTF-8, no conversion will be done, but the message will be tagged as UTF-8. Without this option it will not be.
Values: 0, 1
Default: 0
Applies to: pgp_sym_encrypt, pgp_pub_encrypt
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
To generate a new key:
gpg --gen-key
The preferred key type is "DSA and Elgamal".
For RSA encryption you must create either DSA or RSA sign-only key as master and then add an RSA encryption subkey with gpg --edit-key.
To list keys:
gpg --list-secret-keys
To export a public key in ASCII-armor format:
gpg -a --export KEYID > public.key
To export a secret key in ASCII-armor format:
gpg -a --export-secret-keys KEYID > secret.key
You need to use dearmor()
on these keys before giving them to
the PGP functions. Or if you can handle binary data, you can drop
-a from the command.
For more details see man gpg, The GNU Privacy Handbook and other documentation on http://www.gnupg.org.
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
No support for signing. That also means that it is not checked whether the encryption subkey belongs to the master key.
No support for encryption key as master key. As such practice is generally discouraged, this should not be a problem.
No support for several subkeys. This may seem like a problem, as this is common practice. On the other hand, you should not use your regular GPG/PGP keys with pgcrypto, but create new ones, as the usage scenario is rather different.
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
These functions only run a cipher over data; they don't have any advanced features of PGP encryption. Therefore they have some major problems:
They use user key directly as cipher key.
They don't provide any integrity checking, to see if the encrypted data was modified.
They expect that users manage all encryption parameters themselves, even IV.
They don't handle text.
So, with the introduction of PGP encryption, usage of raw encryption functions is discouraged.
encrypt(data bytea, key bytea, type text) returns bytea decrypt(data bytea, key bytea, type text) returns bytea encrypt_iv(data bytea, key bytea, iv bytea, type text) returns bytea decrypt_iv(data bytea, key bytea, iv bytea, type text) returns bytea
Encrypt/decrypt data using the cipher method specified by type. The syntax of the type string is:
algorithm [ - mode ] [ /pad: padding ]
where algorithm is one of:
bf — Blowfish
aes — AES (Rijndael-128)
and mode is one of:
cbc — next block depends on previous (default)
ecb — each block is encrypted separately (for testing only)
and padding is one of:
pkcs — data may be any length (default)
none — data must be multiple of cipher block size
So, for example, these are equivalent:
encrypt(data, 'fooz', 'bf') encrypt(data, 'fooz', 'bf-cbc/pad:pkcs')
In encrypt_iv
and decrypt_iv
, the
iv parameter is the initial value for the CBC mode;
it is ignored for ECB.
It is clipped or padded with zeroes if not exactly block size.
It defaults to all zeroes in the functions without this parameter.
gen_random_bytes(count integer) returns bytea
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Returns count cryptographically strong random bytes. At most 1024 bytes can be extracted at a time. This is to avoid draining the randomness generator pool.
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
pgcrypto configures itself according to the findings of the main PostgreSQL configure script. The options that affect it are --with-zlib and --with-openssl.
When compiled with zlib, PGP encryption functions are able to compress data before encrypting.
When compiled with OpenSSL, there will be more algorithms available. Also public-key encryption functions will be faster as OpenSSL has more optimized BIGNUM functions.
Table F-18. Summary of Functionality with and without OpenSSL
Functionality | Built-in | With OpenSSL |
---|---|---|
MD5 | yes | yes |
SHA1 | yes | yes |
SHA224/256/384/512 | yes | yes (Note 1) |
Other digest algorithms | no | yes (Note 2) |
Blowfish | yes | yes |
AES | yes | yes (Note 3) |
DES/3DES/CAST5 | no | yes |
Raw encryption | yes | yes |
PGP Symmetric encryption | yes | yes |
PGP Public-Key encryption | yes | yes |
Notes:
SHA2 algorithms were added to OpenSSL in version 0.9.8. For older versions, pgcrypto will use built-in code.
Any digest algorithm OpenSSL supports is automatically picked up. This is not possible with ciphers, which need to be supported explicitly.
AES is included in OpenSSL since version 0.9.7. For older versions, pgcrypto will use built-in code.
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
As is standard in SQL, all functions return NULL, if any of the arguments are NULL. This may create security risks on careless usage.
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
All pgcrypto functions run inside the database server. That means that all the data and passwords move between pgcrypto and client applications in clear text. Thus you must:
Connect locally or use SSL connections.
Trust both system and database administrator.
If you cannot, then better do crypto inside client application.
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
http://www.gnupg.org/gph/en/manual.html
The GNU Privacy Handbook.
http://www.openwall.com/crypt/
Describes the crypt-blowfish algorithm.
http://www.stack.nl/~galactus/remailers/passphrase-faq.html
How to choose a good password.
http://world.std.com/~reinhold/diceware.html
Interesting idea for picking passwords.
http://www.interhack.net/people/cmcurtin/snake-oil-faq.html
Describes good and bad cryptography.
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
http://www.ietf.org/rfc/rfc4880.txt
OpenPGP message format.
http://www.ietf.org/rfc/rfc1321.txt
The MD5 Message-Digest Algorithm.
http://www.ietf.org/rfc/rfc2104.txt
HMAC: Keyed-Hashing for Message Authentication.
http://www.usenix.org/events/usenix99/provos.html
Comparison of crypt-des, crypt-md5 and bcrypt algorithms.
http://csrc.nist.gov/cryptval/des.htm
Standards for DES, 3DES and AES.
http://en.wikipedia.org/wiki/Fortuna_(PRNG)
Description of Fortuna CSPRNG.
Jean-Luc Cooke Fortuna-based /dev/random driver for Linux.
http://research.cyber.ee/~lipmaa/crypto/
Collection of cryptology pointers.
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Marko Kreen <markokr@gmail.com>
pgcrypto uses code from the following sources:
Algorithm | Author | Source origin |
---|---|---|
DES crypt | David Burren and others | FreeBSD libcrypt |
MD5 crypt | Poul-Henning Kamp | FreeBSD libcrypt |
Blowfish crypt | Solar Designer | www.openwall.com |
Blowfish cipher | Simon Tatham | PuTTY |
Rijndael cipher | Brian Gladman | OpenBSD sys/crypto |
MD5 and SHA1 | WIDE Project | KAME kame/sys/crypto |
SHA256/384/512 | Aaron D. Gifford | OpenBSD sys/crypto |
BIGNUM math | Michael J. Fromberger | dartmouth.edu/~sting/sw/imath |