Encrypting Data and Database Connections

This topic describes how to encrypt data at rest in the database or in transit over the network, to protect from eavesdroppers or man-in-the-middle attacks.

  • Connections between clients and the master database can be encrypted with SSL. This is enabled with the ssl server configuration parameter, which is off by default. Setting the ssl parameter to on allows client communications with the master to be encrypted. The master database must be set up for SSL. See OpenSSL Configuration for more about encrypting client connections with SSL.
  • Greenplum Database allows SSL encryption of data in transit between the Greenplum parallel file distribution server, gpfdist, and segment hosts. See Encrypting gpfdist Connections for more information.
  • The pgcrypto module of encryption/decryption functions protects data at rest in the database. Encryption at the column level protects sensitive information, such as social security numbers or credit card numbers. See Encrypting Data at Rest with pgcrypto for more information.

Parent topic: Greenplum Database Security Configuration Guide

Encrypting gpfdist Connections

The gpfdists protocol is a secure version of the gpfdist protocol that securely identifies the file server and the Greenplum Database and encrypts the communications between them. Using gpfdists protects against eavesdropping and man-in-the-middle attacks.

The gpfdists protocol implements client/server SSL security with the following notable features:

  • Client certificates are required.
  • Multilingual certificates are not supported.
  • A Certificate Revocation List (CRL) is not supported.
  • A minimum TLS version of 1.2 is required.
  • SSL renegotiation is supported.
  • The SSL ignore host mismatch parameter is set to false.
  • Private keys containing a passphrase are not supported for the gpfdist file server (server.key) or for the Greenplum Database (client.key).
  • It is the user’s responsibility to issue certificates that are appropriate for the operating system in use. Generally, converting certificates to the required format is supported, for example using the SSL Converter at https://www.sslshopper.com/ssl-converter.html.

A gpfdist server started with the --ssl option can only communicate with the gpfdists protocol. A gpfdist server started without the --ssl option can only communicate with the gpfdist protocol. For more detail about gpfdist refer to the Greenplum Database Administrator Guide.

There are two ways to enable the gpfdists protocol:

  • Run gpfdist with the --ssl option and then use the gpfdists protocol in the LOCATION clause of a CREATE EXTERNAL TABLE statement.
  • Use a YAML control file with the SSL option set to true and run gpload. Running gpload starts the gpfdist server with the --ssl option and then uses the gpfdists protocol.

When using gpfdists, the following client certificates must be located in the $PGDATA/gpfdists directory on each segment:

  • The client certificate file, client.crt
  • The client private key file, client.key
  • The trusted certificate authorities, root.crt

Important

Do not protect the private key with a passphrase. The server does not prompt for a passphrase for the private key, and loading data fails with an error if one is required.

When using gpload with SSL you specify the location of the server certificates in the YAML control file. When using gpfdist with SSL, you specify the location of the server certificates with the –ssl option.

The following example shows how to securely load data into an external table. The example creates a readable external table named ext_expenses from all files with the txt extension, using the gpfdists protocol. The files are formatted with a pipe (|) as the column delimiter and an empty space as null.

  1. Run gpfdist with the --ssl option on the segment hosts.
  2. Log into the database and run the following command:

    1. =# CREATE EXTERNAL TABLE ext_expenses
    2. ( name text, date date, amount float4, category text, desc1 text )
    3. LOCATION ('gpfdists://etlhost-1:8081/*.txt', 'gpfdists://etlhost-2:8082/*.txt')
    4. FORMAT 'TEXT' ( DELIMITER '|' NULL ' ') ;

Encrypting Data at Rest with pgcrypto

The pgcrypto module for Greenplum Database provides functions for encrypting data at rest in the database. Administrators can encrypt columns with sensitive information, such as social security numbers or credit card numbers, to provide an extra layer of protection. Database data stored in encrypted form cannot be read by users who do not have the encryption key, and the data cannot be read directly from disk.

pgcrypto is installed by default when you install Greenplum Database. You must explicitly enable pgcrypto in each database in which you want to use the module.

pgcrypto allows PGP encryption using symmetric and asymmetric encryption. Symmetric encryption encrypts and decrypts data using the same key and is faster than asymmetric encryption. It is the preferred method in an environment where exchanging secret keys is not an issue. With asymmetric encryption, a public key is used to encrypt data and a private key is used to decrypt data. This is slower then symmetric encryption and it requires a stronger key.

Using pgcrypto always comes at the cost of performance and maintainability. It is important to use encryption only with the data that requires it. Also, keep in mind that you cannot search encrypted data by indexing the data.

Before you implement in-database encryption, consider the following PGP limitations.

  • No support for signing. That also means that it is not checked whether the encryption sub-key belongs to the master key.
  • No support for encryption key as master key. This practice is generally discouraged, so this limitation 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.

Greenplum Database is compiled with zlib by default; this allows PGP encryption functions to compress data before encrypting. When compiled with OpenSSL, more algorithms will be available.

Because pgcrypto functions run inside the database server, the data and passwords move between pgcrypto and the client application in clear-text. For optimal security, you should connect locally or use SSL connections and you should trust both the system and database administrators.

pgcrypto configures itself according to the findings of the main PostgreSQL configure script.

When compiled with zlib, pgcrypto encryption functions are able to compress data before encrypting.

Pgcrypto has various levels of encryption ranging from basic to advanced built-in functions. The following table shows the supported encryption algorithms.

Value FunctionalityBuilt-inWith OpenSSL
MD5yesyes
SHA1yesyes
SHA224/256/384/512yesyes 1
Other digest algorithmsnoyes 2
Blowfishyesyes
AESyesyes3
DES/3DES/CAST5noyes
Raw Encryptionyesyes
PGP Symmetric-Keyyesyes
PGP Public Keyyesyes

Creating PGP Keys

To use PGP asymmetric encryption in Greenplum Database, you must first create public and private keys and install them.

This section assumes you are installing Greenplum Database on a Linux machine with the Gnu Privacy Guard (gpg) command line tool. Use the latest version of GPG to create keys. Download and install Gnu Privacy Guard (GPG) for your operating system from https://www.gnupg.org/download/. On the GnuPG website you will find installers for popular Linux distributions and links for Windows and Mac OS X installers.

  1. As root, run the following command and choose option 1 from the menu:

    1. # gpg --gen-key
    2. gpg (GnuPG) 2.0.14; Copyright (C) 2009 Free Software Foundation, Inc.
    3. This is free software: you are free to change and redistribute it.
    4. There is NO WARRANTY, to the extent permitted by law.
    5. gpg: directory '/root/.gnupg' created
    6. gpg: new configuration file '/root/.gnupg/gpg.conf' created
    7. gpg: WARNING: options in '/root/.gnupg/gpg.conf' are not yet active during this run
    8. gpg: keyring '/root/.gnupg/secring.gpg' created
    9. gpg: keyring '/root/.gnupg/pubring.gpg' created
    10. Please select what kind of key you want:
    11. (1) RSA and RSA (default)
    12. (2) DSA and Elgamal
    13. (3) DSA (sign only)
    14. (4) RSA (sign only)
    15. Your selection? **1**
  2. Respond to the prompts and follow the instructions, as shown in this example:

    1. RSA keys may be between 1024 and 4096 bits long.
    2. What keysize do you want? (2048) Press enter to accept default key size
    3. Requested keysize is 2048 bits
    4. Please specify how long the key should be valid.
    5. 0 = key does not expire
    6. <n> = key expires in n days
    7. <n>w = key expires in n weeks
    8. <n>m = key expires in n months
    9. <n>y = key expires in n years
    10. Key is valid for? (0) **365**
    11. Key expires at Wed 13 Jan 2016 10:35:39 AM PST
    12. Is this correct? (y/N) **y**
    13. GnuPG needs to construct a user ID to identify your key.
    14. Real name: **John Doe**
    15. Email address: **jdoe@email.com**
    16. Comment:
    17. You selected this USER-ID:
    18. "John Doe <jdoe@email.com>"
    19. Change (N)ame, (C)omment, (E)mail or (O)kay/(Q)uit? **O**
    20. You need a Passphrase to protect your secret key.
    21. *\(For this demo the passphrase is blank.\)*
    22. can't connect to '/root/.gnupg/S.gpg-agent': No such file or directory
    23. You don't want a passphrase - this is probably a *bad* idea!
    24. I will do it anyway. You can change your passphrase at any time,
    25. using this program with the option "--edit-key".
    26. We need to generate a lot of random bytes. It is a good idea to perform
    27. some other action (type on the keyboard, move the mouse, utilize the
    28. disks) during the prime generation; this gives the random number
    29. generator a better chance to gain enough entropy.
    30. We need to generate a lot of random bytes. It is a good idea to perform
    31. some other action (type on the keyboard, move the mouse, utilize the
    32. disks) during the prime generation; this gives the random number
    33. generator a better chance to gain enough entropy.
    34. gpg: /root/.gnupg/trustdb.gpg: trustdb created
    35. gpg: key 2027CC30 marked as ultimately trusted
    36. public and secret key created and signed.
    37. gpg: checking the trustdbgpg:
    38. 3 marginal(s) needed, 1 complete(s) needed, PGP trust model
    39. gpg: depth: 0 valid: 1 signed: 0 trust: 0-, 0q, 0n, 0m, 0f, 1u
    40. gpg: next trustdb check due at 2016-01-13
    41. pub 2048R/2027CC30 2015-01-13 [expires: 2016-01-13]
    42. Key fingerprint = 7EDA 6AD0 F5E0 400F 4D45 3259 077D 725E 2027 CC30
    43. uid John Doe <jdoe@email.com>
    44. sub 2048R/4FD2EFBB 2015-01-13 [expires: 2016-01-13]
  3. List the PGP keys by entering the following command:

    1. gpg --list-secret-keys
    2. /root/.gnupg/secring.gpg
    3. ------------------------
    4. sec 2048R/2027CC30 2015-01-13 [expires: 2016-01-13]
    5. uid John Doe <jdoe@email.com>
    6. ssb 2048R/4FD2EFBB 2015-01-13

    2027CC30 is the public key and will be used to encrypt data in the database. 4FD2EFBB is the private (secret) key and will be used to decrypt data.

  4. Export the keys using the following commands:

    1. # gpg -a --export 4FD2EFBB > public.key
    2. # gpg -a --export-secret-keys 2027CC30 > secret.key

See the pgcrypto documentation for more information about PGP encryption functions.

Encrypting Data in Tables using PGP

This section shows how to encrypt data inserted into a column using the PGP keys you generated.

  1. Dump the contents of the public.key file and then copy it to the clipboard:

    1. # cat public.key
    2. -----BEGIN PGP PUBLIC KEY BLOCK-----
    3. Version: GnuPG v2.0.14 (GNU/Linux)
    4. mQENBFS1Zf0BCADNw8Qvk1V1C36Kfcwd3Kpm/dijPfRyyEwB6PqKyA05jtWiXZTh
    5. 2His1ojSP6LI0cSkIqMU9LAlncecZhRIhBhuVgKlGSgd9texg2nnSL9Admqik/yX
    6. R5syVKG+qcdWuvyZg9oOOmeyjhc3n+kkbRTEMuM3flbMs8shOwzMvstCUVmuHU/V
    7. vG5rJAe8PuYDSJCJ74I6w7SOH3RiRIc7IfL6xYddV42l3ctd44bl8/i71hq2UyN2
    8. /Hbsjii2ymg7ttw3jsWAx2gP9nssDgoy8QDy/o9nNqC8EGlig96ZFnFnE6Pwbhn+
    9. ic8MD0lK5/GAlR6Hc0ZIHf8KEcavruQlikjnABEBAAG0HHRlc3Qga2V5IDx0ZXN0
    10. a2V5QGVtYWlsLmNvbT6JAT4EEwECACgFAlS1Zf0CGwMFCQHhM4AGCwkIBwMCBhUI
    11. AgkKCwQWAgMBAh4BAheAAAoJEAd9cl4gJ8wwbfwH/3VyVsPkQl1owRJNxvXGt1bY
    12. 7BfrvU52yk+PPZYoes9UpdL3CMRk8gAM9bx5Sk08q2UXSZLC6fFOpEW4uWgmGYf8
    13. JRoC3ooezTkmCBW8I1bU0qGetzVxopdXLuPGCE7hVWQe9HcSntiTLxGov1mJAwO7
    14. TAoccXLbyuZh9Rf5vLoQdKzcCyOHh5IqXaQOT100TeFeEpb9TIiwcntg3WCSU5P0
    15. DGoUAOanjDZ3KE8Qp7V74fhG1EZVzHb8FajR62CXSHFKqpBgiNxnTOk45NbXADn4
    16. eTUXPSnwPi46qoAp9UQogsfGyB1XDOTB2UOqhutAMECaM7VtpePv79i0Z/NfnBe5
    17. AQ0EVLVl/QEIANabFdQ+8QMCADOipM1bF/JrQt3zUoc4BTqICaxdyzAfz0tUSf/7
    18. Zro2us99GlARqLWd8EqJcl/xmfcJiZyUam6ZAzzFXCgnH5Y1sdtMTJZdLp5WeOjw
    19. gCWG/ZLu4wzxOFFzDkiPv9RDw6e5MNLtJrSp4hS5o2apKdbO4Ex83O4mJYnav/rE
    20. iDDCWU4T0lhv3hSKCpke6LcwsX+7liozp+aNmP0Ypwfi4hR3UUMP70+V1beFqW2J
    21. bVLz3lLLouHRgpCzla+PzzbEKs16jq77vG9kqZTCIzXoWaLljuitRlfJkO3vQ9hO
    22. v/8yAnkcAmowZrIBlyFg2KBzhunYmN2YvkUAEQEAAYkBJQQYAQIADwUCVLVl/QIb
    23. DAUJAeEzgAAKCRAHfXJeICfMMOHYCACFhInZA9uAM3TC44l+MrgMUJ3rW9izrO48
    24. WrdTsxR8WkSNbIxJoWnYxYuLyPb/shc9k65huw2SSDkj//0fRrI61FPHQNPSvz62
    25. WH+N2lasoUaoJjb2kQGhLOnFbJuevkyBylRz+hI/+8rJKcZOjQkmmK8Hkk8qb5x/
    26. HMUc55H0g2qQAY0BpnJHgOOQ45Q6pk3G2/7Dbek5WJ6K1wUrFy51sNlGWE8pvgEx
    27. /UUZB+dYqCwtvX0nnBu1KNCmk2AkEcFK3YoliCxomdOxhFOv9AKjjojDyC65KJci
    28. Pv2MikPS2fKOAg1R3LpMa8zDEtl4w3vckPQNrQNnYuUtfj6ZoCxv
    29. =XZ8J
    30. -----END PGP PUBLIC KEY BLOCK-----
  2. Create a table called userssn and insert some sensitive data, social security numbers for Bob and Alice, in this example. Paste the public.key contents after “dearmor(”.

    1. CREATE TABLE userssn( ssn_id SERIAL PRIMARY KEY,
    2. username varchar(100), ssn bytea);
    3. INSERT INTO userssn(username, ssn)
    4. SELECT robotccs.username, pgp_pub_encrypt(robotccs.ssn, keys.pubkey) AS ssn
    5. FROM (
    6. VALUES ('Alice', '123-45-6788'), ('Bob', '123-45-6799'))
    7. AS robotccs(username, ssn)
    8. CROSS JOIN (SELECT dearmor('-----BEGIN PGP PUBLIC KEY BLOCK-----
    9. Version: GnuPG v2.0.14 (GNU/Linux)
    10. mQENBFS1Zf0BCADNw8Qvk1V1C36Kfcwd3Kpm/dijPfRyyEwB6PqKyA05jtWiXZTh
    11. 2His1ojSP6LI0cSkIqMU9LAlncecZhRIhBhuVgKlGSgd9texg2nnSL9Admqik/yX
    12. R5syVKG+qcdWuvyZg9oOOmeyjhc3n+kkbRTEMuM3flbMs8shOwzMvstCUVmuHU/V
    13. vG5rJAe8PuYDSJCJ74I6w7SOH3RiRIc7IfL6xYddV42l3ctd44bl8/i71hq2UyN2
    14. /Hbsjii2ymg7ttw3jsWAx2gP9nssDgoy8QDy/o9nNqC8EGlig96ZFnFnE6Pwbhn+
    15. ic8MD0lK5/GAlR6Hc0ZIHf8KEcavruQlikjnABEBAAG0HHRlc3Qga2V5IDx0ZXN0
    16. a2V5QGVtYWlsLmNvbT6JAT4EEwECACgFAlS1Zf0CGwMFCQHhM4AGCwkIBwMCBhUI
    17. AgkKCwQWAgMBAh4BAheAAAoJEAd9cl4gJ8wwbfwH/3VyVsPkQl1owRJNxvXGt1bY
    18. 7BfrvU52yk+PPZYoes9UpdL3CMRk8gAM9bx5Sk08q2UXSZLC6fFOpEW4uWgmGYf8
    19. JRoC3ooezTkmCBW8I1bU0qGetzVxopdXLuPGCE7hVWQe9HcSntiTLxGov1mJAwO7
    20. TAoccXLbyuZh9Rf5vLoQdKzcCyOHh5IqXaQOT100TeFeEpb9TIiwcntg3WCSU5P0
    21. DGoUAOanjDZ3KE8Qp7V74fhG1EZVzHb8FajR62CXSHFKqpBgiNxnTOk45NbXADn4
    22. eTUXPSnwPi46qoAp9UQogsfGyB1XDOTB2UOqhutAMECaM7VtpePv79i0Z/NfnBe5
    23. AQ0EVLVl/QEIANabFdQ+8QMCADOipM1bF/JrQt3zUoc4BTqICaxdyzAfz0tUSf/7
    24. Zro2us99GlARqLWd8EqJcl/xmfcJiZyUam6ZAzzFXCgnH5Y1sdtMTJZdLp5WeOjw
    25. gCWG/ZLu4wzxOFFzDkiPv9RDw6e5MNLtJrSp4hS5o2apKdbO4Ex83O4mJYnav/rE
    26. iDDCWU4T0lhv3hSKCpke6LcwsX+7liozp+aNmP0Ypwfi4hR3UUMP70+V1beFqW2J
    27. bVLz3lLLouHRgpCzla+PzzbEKs16jq77vG9kqZTCIzXoWaLljuitRlfJkO3vQ9hO
    28. v/8yAnkcAmowZrIBlyFg2KBzhunYmN2YvkUAEQEAAYkBJQQYAQIADwUCVLVl/QIb
    29. DAUJAeEzgAAKCRAHfXJeICfMMOHYCACFhInZA9uAM3TC44l+MrgMUJ3rW9izrO48
    30. WrdTsxR8WkSNbIxJoWnYxYuLyPb/shc9k65huw2SSDkj//0fRrI61FPHQNPSvz62
    31. WH+N2lasoUaoJjb2kQGhLOnFbJuevkyBylRz+hI/+8rJKcZOjQkmmK8Hkk8qb5x/
    32. HMUc55H0g2qQAY0BpnJHgOOQ45Q6pk3G2/7Dbek5WJ6K1wUrFy51sNlGWE8pvgEx
    33. /UUZB+dYqCwtvX0nnBu1KNCmk2AkEcFK3YoliCxomdOxhFOv9AKjjojDyC65KJci
    34. Pv2MikPS2fKOAg1R3LpMa8zDEtl4w3vckPQNrQNnYuUtfj6ZoCxv
    35. =XZ8J
    36. -----END PGP PUBLIC KEY BLOCK-----' AS pubkey) AS keys;
  3. Verify that the ssn column is encrypted.

    1. test_db=# select * from userssn;
    2. ssn_id | 1
    3. username | Alice
    4. ssn | \301\300L\003\235M%_O\322\357\273\001\010\000\272\227\010\341\216\360\217C\020\261)_\367
    5. [\227\034\313:C\354d<\337\006Q\351('\2330\031lX\263Qf\341\262\200\3015\235\036AK\242fL+\315g\322
    6. 7u\270*\304\361\355\220\021\330"\200%\264\274}R\213\377\363\235\366\030\023)\364!\331\303\237t\277=
    7. f \015\004\242\231\263\225%\032\271a\001\035\277\021\375X\232\304\305/\340\334\0131\325\344[~\362\0
    8. 37-\251\336\303\340\377_\011\275\301/MY\334\343\245\244\372y\257S\374\230\346\277\373W\346\230\276\
    9. 017fi\226Q\307\012\326\3646\000\326\005:E\364W\252=zz\010(:\343Y\237\257iqU\0326\350=v0\362\327\350\
    10. 315G^\027:K_9\254\362\354\215<\001\304\357\331\355\323,\302\213Fe\265\315\232\367\254\245%(\\\373
    11. 4\254\230\331\356\006B\257\333\326H\022\013\353\216F?\023\220\370\035vH5/\227\344b\322\227\026\362=\
    12. 42\033\322<\001}\243\224;)\030zqX\214\340\221\035\275U\345\327\214\032\351\223c\2442\345\304K\016\
    13. 011\214\307\227\237\270\026'R\205\205a~1\263\236[\037C\260\031\205\374\245\317\033k|\366\253\037
    14. ---------+--------------------------------------------------------------------------------------------
    15. ------------------------------------------------------------------------------------------------------
    16. ------------------------------------------------------------------------------------------------------
    17. ------------------------------------------------------------------------------------------------------
    18. ------------------------------------------------------------------------------------------------------
    19. ------------------------------------------------------------------------------------------------------
    20. ------------------------------------------------------------------------------------------------------
    21. ------------------------------------------------------------------------------------------------------
    22. ------------------------------------------------------------------------------------------------------
    23. ------------------------------------------------------------------------------
    24. ssn_id | 2
    25. username | Bob
    26. ssn | \301\300L\003\235M%_O\322\357\273\001\007\377t>\345\343,\200\256\272\300\012\033M4\265\032L
    27. L[v\262k\244\2435\264\232B\357\370d9\375\011\002\327\235<\246\210b\030\012\337@\226Z\361\246\032\00
    28. 7'\012c\353]\355d7\360T\335\314\367\370;X\371\350*\231\212\260B\010#RQ0\223\253c7\0132b\355\242\233\34
    29. 1\000\370\370\366\013\022\357\005i\202~\005\\z\301o\012\230Z\014\362\244\324&\243g\351\362\325\375
    30. \213\032\226$\2751\256XR\346k\266\030\234\267\201vUh\004\250\337A\231\223u\247\366/i\022\275\276\350\2
    31. 20\316\306|\203+\010\261;\232\254tp\255\243\261\373Rq;\316w\357\006\207\374U\333\365\365\245hg\031\005
    32. \322\347ea\220\015l\212g\337\264\336b\263\004\311\210.4\340G+\221\274D\035\375\2216\241'\346a0\273wE\2
    33. 12\342y^\202\262|A7\202t\240\333p\345G\373\253\243oCO\011\360\247\211\014\024{\272\271\322<\001\267
    34. \347\240\005\213\0078\036\210\307$\317\322\311\222\035\354\006<\266\264\004\376\251q\256\220(+\030\
    35. 3270\013c\327\272\212%\363\033\252\322\337\354\276\225\232\201\212^\304\210\2269@\3230\370{
  4. Extract the public.key ID from the database:

    1. SELECT pgp_key_id(dearmor('-----BEGIN PGP PUBLIC KEY BLOCK-----
    2. Version: GnuPG v2.0.14 (GNU/Linux)
    3. mQENBFS1Zf0BCADNw8Qvk1V1C36Kfcwd3Kpm/dijPfRyyEwB6PqKyA05jtWiXZTh
    4. 2His1ojSP6LI0cSkIqMU9LAlncecZhRIhBhuVgKlGSgd9texg2nnSL9Admqik/yX
    5. R5syVKG+qcdWuvyZg9oOOmeyjhc3n+kkbRTEMuM3flbMs8shOwzMvstCUVmuHU/V
    6. vG5rJAe8PuYDSJCJ74I6w7SOH3RiRIc7IfL6xYddV42l3ctd44bl8/i71hq2UyN2
    7. /Hbsjii2ymg7ttw3jsWAx2gP9nssDgoy8QDy/o9nNqC8EGlig96ZFnFnE6Pwbhn+
    8. ic8MD0lK5/GAlR6Hc0ZIHf8KEcavruQlikjnABEBAAG0HHRlc3Qga2V5IDx0ZXN0
    9. a2V5QGVtYWlsLmNvbT6JAT4EEwECACgFAlS1Zf0CGwMFCQHhM4AGCwkIBwMCBhUI
    10. AgkKCwQWAgMBAh4BAheAAAoJEAd9cl4gJ8wwbfwH/3VyVsPkQl1owRJNxvXGt1bY
    11. 7BfrvU52yk+PPZYoes9UpdL3CMRk8gAM9bx5Sk08q2UXSZLC6fFOpEW4uWgmGYf8
    12. JRoC3ooezTkmCBW8I1bU0qGetzVxopdXLuPGCE7hVWQe9HcSntiTLxGov1mJAwO7
    13. TAoccXLbyuZh9Rf5vLoQdKzcCyOHh5IqXaQOT100TeFeEpb9TIiwcntg3WCSU5P0
    14. DGoUAOanjDZ3KE8Qp7V74fhG1EZVzHb8FajR62CXSHFKqpBgiNxnTOk45NbXADn4
    15. eTUXPSnwPi46qoAp9UQogsfGyB1XDOTB2UOqhutAMECaM7VtpePv79i0Z/NfnBe5
    16. AQ0EVLVl/QEIANabFdQ+8QMCADOipM1bF/JrQt3zUoc4BTqICaxdyzAfz0tUSf/7
    17. Zro2us99GlARqLWd8EqJcl/xmfcJiZyUam6ZAzzFXCgnH5Y1sdtMTJZdLp5WeOjw
    18. gCWG/ZLu4wzxOFFzDkiPv9RDw6e5MNLtJrSp4hS5o2apKdbO4Ex83O4mJYnav/rE
    19. iDDCWU4T0lhv3hSKCpke6LcwsX+7liozp+aNmP0Ypwfi4hR3UUMP70+V1beFqW2J
    20. bVLz3lLLouHRgpCzla+PzzbEKs16jq77vG9kqZTCIzXoWaLljuitRlfJkO3vQ9hO
    21. v/8yAnkcAmowZrIBlyFg2KBzhunYmN2YvkUAEQEAAYkBJQQYAQIADwUCVLVl/QIb
    22. DAUJAeEzgAAKCRAHfXJeICfMMOHYCACFhInZA9uAM3TC44l+MrgMUJ3rW9izrO48
    23. WrdTsxR8WkSNbIxJoWnYxYuLyPb/shc9k65huw2SSDkj//0fRrI61FPHQNPSvz62
    24. WH+N2lasoUaoJjb2kQGhLOnFbJuevkyBylRz+hI/+8rJKcZOjQkmmK8Hkk8qb5x/
    25. HMUc55H0g2qQAY0BpnJHgOOQ45Q6pk3G2/7Dbek5WJ6K1wUrFy51sNlGWE8pvgEx
    26. /UUZB+dYqCwtvX0nnBu1KNCmk2AkEcFK3YoliCxomdOxhFOv9AKjjojDyC65KJci
    27. Pv2MikPS2fKOAg1R3LpMa8zDEtl4w3vckPQNrQNnYuUtfj6ZoCxv
    28. =XZ8J
    29. -----END PGP PUBLIC KEY BLOCK-----'));
    30. pgp_key_id | 9D4D255F4FD2EFBB

    This shows that the PGP key ID used to encrypt the ssn column is 9D4D255F4FD2EFBB. It is recommended to perform this step whenever a new key is created and then store the ID for tracking.

    You can use this key to see which key pair was used to encrypt the data:

    1. SELECT username, pgp_key_id(ssn) As key_used
    2. FROM userssn;
    3. username | Bob
    4. key_used | 9D4D255F4FD2EFBB
    5. ---------+-----------------
    6. username | Alice
    7. key_used | 9D4D255F4FD2EFBB

    Note

    Different keys may have the same ID. This is rare, but is a normal event. The client application should try to decrypt with each one to see which fits — like handling ANYKEY. See pgp_key_id() in the pgcrypto documentation.

  5. Decrypt the data using the private key.

    ``` SELECT username, pgp_pub_decrypt(ssn, keys.privkey)

    1. AS decrypted_ssn FROM userssn
    2. CROSS JOIN
    3. (SELECT dearmor('-----BEGIN PGP PRIVATE KEY BLOCK-----

    Version: GnuPG v2.0.14 (GNU/Linux)

    lQOYBFS1Zf0BCADNw8Qvk1V1C36Kfcwd3Kpm/dijPfRyyEwB6PqKyA05jtWiXZTh 2His1ojSP6LI0cSkIqMU9LAlncecZhRIhBhuVgKlGSgd9texg2nnSL9Admqik/yX R5syVKG+qcdWuvyZg9oOOmeyjhc3n+kkbRTEMuM3flbMs8shOwzMvstCUVmuHU/V vG5rJAe8PuYDSJCJ74I6w7SOH3RiRIc7IfL6xYddV42l3ctd44bl8/i71hq2UyN2 /Hbsjii2ymg7ttw3jsWAx2gP9nssDgoy8QDy/o9nNqC8EGlig96ZFnFnE6Pwbhn+ ic8MD0lK5/GAlR6Hc0ZIHf8KEcavruQlikjnABEBAAEAB/wNfjjvP1brRfjjIm/j XwUNm+sI4v2Ur7qZC94VTukPGf67lvqcYZJuqXxvZrZ8bl6mvl65xEUiZYy7BNA8 fe0PaM4Wy+Xr94Cz2bPbWgawnRNN3GAQy4rlBTrvqQWy+kmpbd87iTjwZidZNNmx 02iSzraq41Rt0Zx21Jh4rkpF67ftmzOH0vlrS0bWOvHUeMY7tCwmdPe9HbQeDlPr n9CllUqBn4/acTtCClWAjREZn0zXAsNixtTIPC1V+9nO9YmecMkVwNfIPkIhymAM OPFnuZ/Dz1rCRHjNHb5j6ZyUM5zDqUVnnezktxqrOENSxm0gfMGcpxHQogUMzb7c 6UyBBADSCXHPfo/VPVtMm5p1yGrNOR2jR2rUj9+poZzD2gjkt5G/xIKRlkB4uoQl emu27wr9dVEX7ms0nvDq58iutbQ4d0JIDlcHMeSRQZluErblB75Vj3HtImblPjpn 4Jx6SWRXPUJPGXGI87u0UoBH0Lwij7M2PW7l1ao+MLEA9jAjQwQA+sr9BKPL4Ya2 r5nE72gsbCCLowkC0rdldf1RGtobwYDMpmYZhOaRKjkOTMG6rCXJxrf6LqiN8w/L /gNziTmch35MCq/MZzA/bN4VMPyeIlwzxVZkJLsQ7yyqX/A7ac7B7DH0KfXciEXW MSOAJhMmklW1Q1RRNw3cnYi8w3q7X40EAL/w54FVvvPqp3+sCd86SAAapM4UO2R3 tIsuNVemMWdgNXwvK8AJsz7VreVU5yZ4B8hvCuQj1C7geaN/LXhiT8foRsJC5o71 Bf+iHC/VNEv4k4uDb4lOgnHJYYyifB1wC+nn/EnXCZYQINMia1a4M6Vqc/RIfTH4 nwkZt/89LsAiR/20HHRlc3Qga2V5IDx0ZXN0a2V5QGVtYWlsLmNvbT6JAT4EEwEC ACgFAlS1Zf0CGwMFCQHhM4AGCwkIBwMCBhUIAgkKCwQWAgMBAh4BAheAAAoJEAd9 cl4gJ8wwbfwH/3VyVsPkQl1owRJNxvXGt1bY7BfrvU52yk+PPZYoes9UpdL3CMRk 8gAM9bx5Sk08q2UXSZLC6fFOpEW4uWgmGYf8JRoC3ooezTkmCBW8I1bU0qGetzVx opdXLuPGCE7hVWQe9HcSntiTLxGov1mJAwO7TAoccXLbyuZh9Rf5vLoQdKzcCyOH h5IqXaQOT100TeFeEpb9TIiwcntg3WCSU5P0DGoUAOanjDZ3KE8Qp7V74fhG1EZV zHb8FajR62CXSHFKqpBgiNxnTOk45NbXADn4eTUXPSnwPi46qoAp9UQogsfGyB1X DOTB2UOqhutAMECaM7VtpePv79i0Z/NfnBedA5gEVLVl/QEIANabFdQ+8QMCADOi pM1bF/JrQt3zUoc4BTqICaxdyzAfz0tUSf/7Zro2us99GlARqLWd8EqJcl/xmfcJ iZyUam6ZAzzFXCgnH5Y1sdtMTJZdLp5WeOjwgCWG/ZLu4wzxOFFzDkiPv9RDw6e5 MNLtJrSp4hS5o2apKdbO4Ex83O4mJYnav/rEiDDCWU4T0lhv3hSKCpke6LcwsX+7 liozp+aNmP0Ypwfi4hR3UUMP70+V1beFqW2JbVLz3lLLouHRgpCzla+PzzbEKs16 jq77vG9kqZTCIzXoWaLljuitRlfJkO3vQ9hOv/8yAnkcAmowZrIBlyFg2KBzhunY mN2YvkUAEQEAAQAH/A7r4hDrnmzX3QU6FAzePlRB7niJtE2IEN8AufF05Q2PzKU/ c1S72WjtqMAIAgYasDkOhfhcxanTneGuFVYggKT3eSDm1RFKpRjX22m0zKdwy67B Mu95V2Oklul6OCm8dO6+2fmkGxGqc4ZsKy+jQxtxK3HG9YxMC0dvA2v2C5N4TWi3 Utc7zh//k6IbmaLd7F1d7DXt7Hn2Qsmo8I1rtgPE8grDToomTnRUodToyejEqKyI ORwsp8n8g2CSFaXSrEyU6HbFYXSxZealhQJGYLFOZdR0MzVtZQCn/7n+IHjupndC Nd2a8DVx3yQS3dAmvLzhFacZdjXi31wvj0moFOkEAOCz1E63SKNNksniQ11lRMJp gaov6Ux/zGLMstwTzNouI+Kr8/db0GlSAy1Z3UoAB4tFQXEApoX9A4AJ2KqQjqOX cZVULenfDZaxrbb9Lid7ZnTDXKVyGTWDF7ZHavHJ4981mCW17lU11zHBB9xMlx6p dhFvb0gdy0jSLaFMFr/JBAD0fz3RrhP7e6Xll2zdBqGthjC5S/IoKwwBgw6ri2yx LoxqBr2pl9PotJJ/JUMPhD/LxuTcOZtYjy8PKgm5jhnBDq3Ss0kNKAY1f5EkZG9a 6I4iAX/NekqSyF+OgBfC9aCgS5RG8hYoOCbp8na5R3bgiuS8IzmVmm5OhZ4MDEwg nQP7BzmR0p5BahpZ8r3Ada7FcK+0ZLLRdLmOYF/yUrZ53SoYCZRzU/GmtQ7LkXBh Gjqied9Bs1MHdNUolq7GaexcjZmOWHEf6w9+9M4+vxtQq1nkIWqtaphewEmd5/nf EP3sIY0EAE3mmiLmHLqBju+UJKMNwFNeyMTqgcg50ISH8J9FRIkBJQQYAQIADwUC VLVl/QIbDAUJAeEzgAAKCRAHfXJeICfMMOHYCACFhInZA9uAM3TC44l+MrgMUJ3r W9izrO48WrdTsxR8WkSNbIxJoWnYxYuLyPb/shc9k65huw2SSDkj//0fRrI61FPH QNPSvz62WH+N2lasoUaoJjb2kQGhLOnFbJuevkyBylRz+hI/+8rJKcZOjQkmmK8H kk8qb5x/HMUc55H0g2qQAY0BpnJHgOOQ45Q6pk3G2/7Dbek5WJ6K1wUrFy51sNlG WE8pvgEx/UUZB+dYqCwtvX0nnBu1KNCmk2AkEcFK3YoliCxomdOxhFOv9AKjjojD yC65KJciPv2MikPS2fKOAg1R3LpMa8zDEtl4w3vckPQNrQNnYuUtfj6ZoCxv =fa+6 ——-END PGP PRIVATE KEY BLOCK——-‘) AS privkey) AS keys;

    username | decrypted_ssn —————+———————- Alice | 123-45-6788 Bob | 123-45-6799 (2 rows)

  1. ```
  2. If you created a key with passphrase, you may have to enter it here. However for the purpose of this example, the passphrase is blank.

Key Management

Whether you are using symmetric (single private key) or asymmetric (public and private key) cryptography, it is important to store the master or private key securely. There are many options for storing encryption keys, for example, on a file system, key vault, encrypted USB, trusted platform module (TPM), or hardware security module (HSM).

Consider the following questions when planning for key management:

  • Where will the keys be stored?
  • When should keys expire?
  • How are keys protected?
  • How are keys accessed?
  • How can keys be recovered and revoked?

The Open Web Application Security Project (OWASP) provides a very comprehensive guide to securing encryption keys.

1 SHA2 algorithms were added to OpenSSL in version 0.9.8. For older versions, pgcrypto will use built-in code.
2 Any digest algorithm OpenSSL supports is automatically picked up. This is not possible with ciphers, which need to be supported explicitly.
3 AES is included in OpenSSL since version 0.9.7. For older versions, pgcrypto will use built-in code.