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122 lines
5.7 KiB
Plaintext
122 lines
5.7 KiB
Plaintext
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TL;DR- Copy & paste your crypto code from here instead of Stack Overflow.
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This library demonstrates a suite of basic cryptography from the Go standard
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library. To the extent possible, it tries to hide complexity and help you avoid
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common mistakes. The recommendations were chosen as a compromise between
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cryptographic qualities, the Go standard lib, and my existing use cases.
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Some particular design choices I've made:
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1. SHA-512/256 has been chosen as the default hash for the examples. It's
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faster on 64-bit machines and immune to length extension. If it doesn't work
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in your case, replace instances of it with ordinary SHA-256.
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2. The specific ECDSA parameters were chosen to be compatible with RFC7518[1]
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while using the best implementation of ECDSA available. Go's P-256 is
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constant-time (which prevents certain types of attacks) while its P-384 and
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P-521 are not.
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3. Key parameters are arrays rather than slices so the compiler can help you
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avoid mixing up the arguments. The signing and marshaling functions use the
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crypto/ecdsa key types directly for the same reason.
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4. Public/private keypairs for signing are marshaled into and out of PEM
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format, making them relatively portable to other crypto software you're
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likely to use (openssl, cfssl, etc).
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5. Key generation functions will panic if they can't read enough random bytes
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to generate the key. Key generation is critical, and if crypto/rand fails at
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that stage then you should stop doing cryptography on that machine immediately.
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6. The license is a CC0 public domain dedication, with the intent that you can
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just copy bits of this directly into your code and never be required to
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acknowledge my copyright, provide source code, or do anything else commonly
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associated with open licenses.
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The specific recommendations are:
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Encryption - 256-bit AES-GCM with random 96-bit nonces
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Using AES-GCM (instead of AES-CBC, AES-CFB, or AES-CTR, all of which Go also
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offers) provides authentication in addition to confidentiality. This means that
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the content of your data is hidden and that any modification of the encrypted
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data will result in a failure to decrypt. This rules out entire classes of
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possible attacks. Randomized nonces remove the choices around nonce generation
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and management, which are another common source of error in crypto
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implementations.
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The interfaces in this library allow only the use of 256-bit keys.
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Hashing - HMAC-SHA512/256
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Using hash functions directly is fraught with various perils – it's common for
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developers to accidentally write code that is subject to easy collision or
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length extension attacks. HMAC is a function built on top of hashes and it
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doesn't have those problems. Using SHA-512/256 as the underlying hash function
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means the process will be faster on 64-bit machines, but the output will be the
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same length as the more familiar SHA-256.
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This interface encourages you to scope your hashes with an English-language
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string (a "tag") that describes the purpose of the hash. Tagged hashes are a
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common "security hygiene" measure to ensure that hashing the same data for
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different purposes will produce different outputs.
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Password hashing - bcrypt with work factor 14
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Use this to store users' passwords and check them for login (e.g. in a web
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backend). While they both have "hashing" in the name, password hashing is an
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entirely different situation from ordinary hashing and requires its own
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specialized algorithm. bcrypt is a hash function designed for password storage.
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It can be made selectively slower (based on a "work factor") to increase the
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difficulty of brute-force password cracking attempts.
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As of 2016, a work factor of 14 should be well on the side of future-proofing
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over performance. If it turns out to be too slow for your needs, you can try
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using 13 or even 12. You should not go below work factor 12.
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Symmetric Signatures / Message Authentication - HMAC-SHA512/256
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When two parties share a secret key, they can use message authentication to
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make sure that a piece of data hasn't been altered. You can think of it as a
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"symmetric signature" - it proves both that the data is unchanged and that
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someone who knows the shared secret key generated it. Anyone who does not know
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the secret key can neither validate the data nor make valid alterations.
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This comes up most often in the context of web stuff, such as:
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1. Authenticating requests to your API. The most widely known example is
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probably the Amazon AWS API, which requires you to sign requests with
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HMAC-SHA256. In this type of use, the "secret key" is a token that the API
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provider issues to authorized API users.
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2. Validating authenticated tokens (cookies, JWTs, etc) that are issued by a
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service but are stored by a user. In this case, the service wants to ensure
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that a user doesn't modify the data contained in the token.
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As with encryption, you should always use a 256-bit random key to
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authenticate messages.
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Asymmetric Signatures - ECDSA on P-256 with SHA-256 message digests
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These are the classic public/private keypair signatures that you probably think
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of when you hear the word "signature". The holder of a private key can sign
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data that anyone who has the corresponding public key can verify.
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Go takes very good care of us here. In particular, the Go implementation of
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P-256 is constant time to protect against side-channel attacks, and the Go
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implementation of ECDSA generates safe nonces to protect against the type of
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repeated-nonce attack that broke the PS3.
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In terms of JWTs, this algorithm is called "ES256". The functions
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"EncodeSignatureJWT" and "DecodeSignatureJWT" will convert the basic signature
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format to and from the encoding specified by RFC7515[2]
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[1] https://tools.ietf.org/html/rfc7518#section-3.1
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[2] https://tools.ietf.org/html/rfc7515#appendix-A.3
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