Difference between revisions of "Cryptographic Storage Cheat Sheet"
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* Key exchange: Diffie–Hellman key exchange with minimum 2048 bits
* Key exchange: Diffie–Hellman key exchange with minimum 2048 bits
* Message Integrity: HMAC-SHA2
* Message Hash: SHA2 256 bits
* Assymetric encryption: RSA 2048 bits
* Symmetric-key algorithm: AES 128 bits
* Password Hashing: PBKDF2, Scrypt, Bcrypt.
= Providing Cryptographic Functionality =
= Providing Cryptographic Functionality =
Revision as of 02:07, 6 March 2017
Last revision (mm/dd/yy): 03/6/2017
This article provides a simple model to follow when implementing solutions to protect data at rest.
An architectural decision must be made to determine the appropriate method to protect data at rest. There are such wide varieties of products, methods and mechanisms for cryptographic storage. This cheat sheet will only focus on low-level guidelines for developers and architects who are implementing cryptographic solutions. We will not address specific vendor solutions, nor will we address the design of cryptographic algorithms.
The general practices and required minimum key length depending on the scenario listed below.
Providing Cryptographic Functionality
Secure Cryptographic Storage Design
Rule - Only store sensitive data that you need
Many eCommerce businesses utilize third party payment providers to store credit card information for recurring billing. This offloads the burden of keeping credit card numbers safe.
Rule - Use strong approved Authenticated Encryption
Rule - Use strong approved cryptographic algorithms
Do not implement an existing cryptographic algorithm on your own, no matter how easy it appears. Instead, use widely accepted algorithms and widely accepted implementations.
Only use approved public algorithms such as AES, RSA public key cryptography, and SHA-256 or better for hashing. Do not use weak algorithms, such as MD5 or SHA1. Avoid hashing for password storage, instead use PBKDF2, bcrypt or scrypt. Note that the classification of a "strong" cryptographic algorithm can change over time. See NIST approved algorithms or ISO TR 14742 “Recommendations on Cryptographic Algorithms and their use” or Algorithms, key size and parameters report – 2014 from European Union Agency for Network and Information Security. E.g. AES 128, RSA 3072, SHA 256.
Ensure that the implementation has (at minimum) had some cryptography experts involved in its creation. If possible, use an implementation that is FIPS 140-2 certified.
See NIST approved algorithms Table 2 “Comparable strengths” for the strength (“security bits”) of different algorithms and key lengths, and how they compare to each other.
If a password is being used to protect keys then the password strengthshould be sufficient for the strength of the keys it is protecting.
When 3DES is used, ensure K1 != K2 != K3, and the minimum key length must be 192 bit.
Rule - Use approved cryptographic modes
In general, you should not use AES, DES or other symmetric cipher primitives directly. NIST approved modes should be used instead.
NOTE: Do not use ECB mode for encrypting lots of data (the other modes are better because they chain the blocks of data together to improve the data security).
Rule - Use strong random numbers
Ensure that all random numbers, especially those used for cryptographic parameters (keys, IV’s, MAC tags), random file names, random GUIDs, and random strings are generated in a cryptographically strong fashion.
Ensure that random algorithms are seeded with sufficient entropy.
Tools like NIST RNG Test tool (as used in PCI PTS Derived Test Requirements) can be used to comprehensively assess the quality of a Random Number Generator by reading e.g. 128MB of data from the RNG source and then assessing its randomness properties with the tool.
The following libraries are considered weak random numbers generator and should not be used.
For secure random number generation, refer to NIST SP 800-90A. CTR-DRBG、HASH-DRBG、HMAC-DRBG are recommended. Refer to NIST SP800-22 A Statistical Test Suite for Random and Pseudorandom Number Generators for Cryptographic Applications, and the testing toolkit.
Rule - Use Authenticated Encryption of data
Use (AE) modes under a uniform API. Recommended modes include CCM, and GCM as these, and only these as of November 2014, are specified in NIST approved modes, ISO IEC 19772 (2009) "Information technology — Security techniques — Authenticated encryption", and IEEE P1619 Standard for Cryptographic Protection of Data on Block-Oriented Storage Devices
If these recommended AE modes are not available
Note: Disk encryption is a special case of data at rest e.g. Encrypted File System on a Hard Disk Drive. XTS-AES mode is optimized for Disk encryption and is one of the NIST approved modes; it provides confidentiality and some protection against data manipulation (but not as strong as the AE NIST approved modes). It is also specified in IEEE P1619 Standard for Cryptographic Protection of Data on Block-Oriented Storage Devices
Rule - Store a one-way and salted value of passwords
Use PBKDF2, bcrypt or scrypt for password storage. For more information on password storage, please see the Password Storage Cheat Sheet.
Rule - Ensure that the cryptographic protection remains secure even if access controls fail
This rule supports the principle of defense in depth. Access controls (usernames, passwords, privileges, etc.) are one layer of protection. Storage encryption should add an additional layer of protection that will continue protecting the data even if an attacker subverts the database access control layer.
Rule - Define a key lifecycle
The key lifecycle details the various states that a key will move through during its life. The lifecycle will specify when a key should no longer be used for encryption, when a key should no longer be used for decryption (these are not necessarily coincident), whether data must be rekeyed when a new key is introduced, and when a key should be removed from use all together.
Rule - Store unencrypted keys away from the encrypted data
If the keys are stored with the data then any compromise of the data will easily compromise the keys as well. Unencrypted keys should never reside on the same machine or cluster as the data.
Rule - Use independent keys when multiple keys are required
Ensure that key material is independent. That is, do not choose a second key which is easily related to the first (or any preceeding) keys.
Rule - Protect keys in a key vault
Keys should remain in a protected key vault at all times. In particular, ensure that there is a gap between the threat vectors that have direct access to the data and the threat vectors that have direct access to the keys. This implies that keys should not be stored on the application or web server (assuming that application attackers are part of the relevant threat model).
Rule - Document concrete procedures for managing keys through the lifecycle
These procedures must be written down and the key custodians must be adequately trained.
Rule - Build support for changing algorithms and keys when needed
If keys are compromised or an external authority expires them, key changes will be needed. Application polices or emergency needs will force application administrators to rotate keys and potentially rekey data at some point. It's best to be prepared to rapidly handle this need when necessary. Including a key version and encryption algorithm version with the encrypted data is a useful, proactive feature. For instance, including a simple prefix string, such as "
Rule - Document concrete procedures to handle a key compromise
Ensure operations staff have the information they need, readily available, when rotation of encryption keys must be performed. Rotating keys should not require changes to source code or other risky deployment measures, since doing this in the middle of an incident will already place a great deal of stress on these staff.
Rule - Limit quantity of data encrypted with one key
If the amount of data encrypted grows beyond a certain threshold, a new key should be used. This certain threshold varies depending on the encryption algorithm used, but is typically 235 bytes (~34 gigabytes) for 64 bit block ciphers (DES, 3DES, Blowfish, RC5, ...) and 268 bytes (~ 295,147,905 terabytes) for 128 bit block ciphers (AES, TwoFish, Serpent). If encrypting with a modern cipher, this threshold is unlikely to be reached, but it should be considered when evaluating algorithms and rotation procedures.
Rule - Follow applicable regulations on use of cryptography
Rule - Under PCI DSS requirement 3, you must protect cardholder data
The Payment Card Industry (PCI) Data Security Standard (DSS) was developed to encourage and enhance cardholder data security and facilitate the broad adoption of consistent data security measures globally. The standard was introduced in 2005 and replaced individual compliance standards from Visa, Mastercard, Amex, JCB and Diners. The current version of the standard is 3.1 and was published in April, 2015.
PCI DSS requirement 3 covers secure storage of credit card data. This requirement covers several aspects of secure storage including the data you must never store but we are covering Cryptographic Storage which is covered in requirements 3.4, 3.5 and 3.6 as you can see below:
3.4 Render PAN (Primary Account Number), at minimum, unreadable anywhere it is stored
Compliance with requirement 3.4 can be met by implementing any of the four types of secure storage described in the standard which includes encrypting and hashing data. These two approaches will often be the most popular choices from the list of options. The standard doesn't refer to any specific algorithms but it mandates the use of Strong Cryptography. The glossary document from the PCI council defines Strong Cryptography as:
Cryptography based on industry-tested and accepted algorithms, along with strong key lengths and proper key-management practices. Cryptography is a method to protect data and includes both encryption (which is reversible) and hashing (which is not reversible, or “one way”). SHA-1 is an example of an industry-tested and accepted hashing algorithm. Examples of industry-tested and accepted standards and algorithms for encryption include AES (128 bits and higher), TDES (minimum double-length keys), RSA (1024 bits and higher), ECC (160 bits and higher), and ElGamal (1024 bits and higher).
If you have implemented the second rule in this cheat sheet you will have implemented a strong cryptographic algorithm which is compliant with or stronger than the requirements of PCI DSS requirement 3.4. You need to ensure that you identify all locations that card data could be stored including logs and apply the appropriate level of protection. This could range from encrypting the data to replacing the card number in logs.
This requirement can also be met by implementing disk encryption rather than file or column level encryption. The requirements for Strong Cryptography are the same for disk encryption and backup media. The card data should never be stored in the clear and by following the guidance in this cheat sheet you will be able to securely store your data in a manner which is compliant with PCI DSS requirement 3.4
3.5 Protect any keys used to secure cardholder data against disclosure and misuse
As the requirement name above indicates, we are required to securely store the encryption keys themselves. This will mean implementing strong access control, auditing and logging for your keys. The keys must be stored in a location which is both secure and "away" from the encrypted data. This means key data shouldn't be stored on web servers, database servers etc
Access to the keys must be restricted to the smallest amount of users possible. This group of users will ideally be users who are highly trusted and trained to perform Key Custodian duties. There will obviously be a requirement for system/service accounts to access the key data to perform encryption/decryption of data.
The keys themselves shouldn't be stored in the clear but encrypted with a KEK (Key Encrypting Key). The KEK must not be stored in the same location as the encryption keys it is encrypting.
3.6 Fully document and implement all key-management processes and procedures for cryptographic keys used for encryption of cardholder data
Requirement 3.6 mandates that key management processes within a PCI compliant company cover 8 specific key lifecycle steps:
3.6.1 Generation of strong cryptographic keys
As we have previously described in this cheat sheet we need to use algorithms which offer high levels of data security. We must also generate strong keys so that the security of the data isn't undermined by weak cryptographic keys. A strong key is generated by using a key length which is sufficient for your data security requirements and compliant with the PCI DSS. The key size alone isn't a measure of the strength of a key. The data used to generate the key must be sufficiently random ("sufficient" often being determined by your data security requirements) and the entropy of the key data itself must be high.
3.6.2 Secure cryptographic key distribution
The method used to distribute keys must be secure to prevent the theft of keys in transit. The use of a protocol such as Diffie Hellman can help secure the distribution of keys, the use of secure transport such as TLS and SSHv2 can also secure the keys in transit. Older protocols like SSLv3 should not be used.
3.6.3 Secure cryptographic key storage
The secure storage of encryption keys including KEK's has been touched on in our description of requirement 3.5 (see above).
3.6.4 Periodic cryptographic key changes
The PCI DSS standard mandates that keys used for encryption must be rotated at least annually. The key rotation process must remove an old key from the encryption/decryption process and replace it with a new key. All new data entering the system must encrypted with the new key. While it is recommended that existing data be rekeyed with the new key, as per the Rekey data at least every one to three years rule above, it is not clear that the PCI DSS requires this.
3.6.5 Retirement or replacement of keys as deemed necessary when the integrity of the key has been weakened or keys are suspected of being compromised
The key management processes must cater for archived, retired or compromised keys. The process of securely storing and replacing these keys will more than likely be covered by your processes for requirements 3.6.2, 3.6.3 and 3.6.4
3.6.6 Split knowledge and establishment of dual control of cryptographic keys
The requirement for split knowledge and/or dual control for key management prevents an individual user performing key management tasks such as key rotation or deletion. The system should require two individual users to perform an action (i.e. entering a value from their own OTP) which creates to separate values which are concatenated to create the final key data.
3.6.7 Prevention of unauthorized substitution of cryptographic keys
The system put in place to comply with requirement 3.6.6 can go a long way to preventing unauthorised substitution of key data. In addition to the dual control process you should implement strong access control, auditing and logging for key data so that unauthorised access attempts are prevented and logged.
3.6.8 Requirement for cryptographic key custodians to sign a form stating that they understand and accept their key-custodian responsibilities
To perform the strong key management functions we have seen in requirement 3.6 we must have highly trusted and trained key custodians who understand how to perform key management duties. The key custodians must also sign a form stating they understand the responsibilities that come with this role.
Authors and Primary Editors
Kevin Kenan - kevin[at]k2dd.com