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The library implementation of the SHA-1 compression function is confusingly called just "sha_transform()". Alongside it are some "SHA_" constants and "sha_init()". Presumably these are left over from a time when SHA just meant SHA-1. But now there are also SHA-2 and SHA-3, and moreover SHA-1 is now considered insecure and thus shouldn't be used. Therefore, rename these functions and constants to make it very clear that they are for SHA-1. Also add a comment to make it clear that these shouldn't be used. For the extra-misleadingly named "SHA_MESSAGE_BYTES", rename it to SHA1_BLOCK_SIZE and define it to just '64' rather than '(512/8)' so that it matches the same definition in <crypto/sha.h>. This prepares for merging <linux/cryptohash.h> into <crypto/sha.h>. Signed-off-by: Eric Biggers <ebiggers@google.com> Signed-off-by: Herbert Xu <herbert@gondor.apana.org.au>
190 lines
6.4 KiB
ReStructuredText
190 lines
6.4 KiB
ReStructuredText
===========================
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SipHash - a short input PRF
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===========================
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:Author: Written by Jason A. Donenfeld <jason@zx2c4.com>
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SipHash is a cryptographically secure PRF -- a keyed hash function -- that
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performs very well for short inputs, hence the name. It was designed by
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cryptographers Daniel J. Bernstein and Jean-Philippe Aumasson. It is intended
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as a replacement for some uses of: `jhash`, `md5_transform`, `sha1_transform`,
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and so forth.
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SipHash takes a secret key filled with randomly generated numbers and either
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an input buffer or several input integers. It spits out an integer that is
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indistinguishable from random. You may then use that integer as part of secure
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sequence numbers, secure cookies, or mask it off for use in a hash table.
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Generating a key
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================
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Keys should always be generated from a cryptographically secure source of
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random numbers, either using get_random_bytes or get_random_once::
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siphash_key_t key;
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get_random_bytes(&key, sizeof(key));
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If you're not deriving your key from here, you're doing it wrong.
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Using the functions
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===================
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There are two variants of the function, one that takes a list of integers, and
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one that takes a buffer::
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u64 siphash(const void *data, size_t len, const siphash_key_t *key);
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And::
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u64 siphash_1u64(u64, const siphash_key_t *key);
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u64 siphash_2u64(u64, u64, const siphash_key_t *key);
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u64 siphash_3u64(u64, u64, u64, const siphash_key_t *key);
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u64 siphash_4u64(u64, u64, u64, u64, const siphash_key_t *key);
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u64 siphash_1u32(u32, const siphash_key_t *key);
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u64 siphash_2u32(u32, u32, const siphash_key_t *key);
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u64 siphash_3u32(u32, u32, u32, const siphash_key_t *key);
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u64 siphash_4u32(u32, u32, u32, u32, const siphash_key_t *key);
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If you pass the generic siphash function something of a constant length, it
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will constant fold at compile-time and automatically choose one of the
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optimized functions.
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Hashtable key function usage::
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struct some_hashtable {
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DECLARE_HASHTABLE(hashtable, 8);
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siphash_key_t key;
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};
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void init_hashtable(struct some_hashtable *table)
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{
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get_random_bytes(&table->key, sizeof(table->key));
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}
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static inline hlist_head *some_hashtable_bucket(struct some_hashtable *table, struct interesting_input *input)
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{
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return &table->hashtable[siphash(input, sizeof(*input), &table->key) & (HASH_SIZE(table->hashtable) - 1)];
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}
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You may then iterate like usual over the returned hash bucket.
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Security
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========
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SipHash has a very high security margin, with its 128-bit key. So long as the
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key is kept secret, it is impossible for an attacker to guess the outputs of
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the function, even if being able to observe many outputs, since 2^128 outputs
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is significant.
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Linux implements the "2-4" variant of SipHash.
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Struct-passing Pitfalls
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=======================
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Often times the XuY functions will not be large enough, and instead you'll
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want to pass a pre-filled struct to siphash. When doing this, it's important
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to always ensure the struct has no padding holes. The easiest way to do this
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is to simply arrange the members of the struct in descending order of size,
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and to use offsetendof() instead of sizeof() for getting the size. For
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performance reasons, if possible, it's probably a good thing to align the
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struct to the right boundary. Here's an example::
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const struct {
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struct in6_addr saddr;
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u32 counter;
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u16 dport;
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} __aligned(SIPHASH_ALIGNMENT) combined = {
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.saddr = *(struct in6_addr *)saddr,
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.counter = counter,
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.dport = dport
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};
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u64 h = siphash(&combined, offsetofend(typeof(combined), dport), &secret);
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Resources
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=========
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Read the SipHash paper if you're interested in learning more:
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https://131002.net/siphash/siphash.pdf
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-------------------------------------------------------------------------------
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===============================================
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HalfSipHash - SipHash's insecure younger cousin
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===============================================
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:Author: Written by Jason A. Donenfeld <jason@zx2c4.com>
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On the off-chance that SipHash is not fast enough for your needs, you might be
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able to justify using HalfSipHash, a terrifying but potentially useful
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possibility. HalfSipHash cuts SipHash's rounds down from "2-4" to "1-3" and,
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even scarier, uses an easily brute-forcable 64-bit key (with a 32-bit output)
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instead of SipHash's 128-bit key. However, this may appeal to some
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high-performance `jhash` users.
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Danger!
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Do not ever use HalfSipHash except for as a hashtable key function, and only
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then when you can be absolutely certain that the outputs will never be
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transmitted out of the kernel. This is only remotely useful over `jhash` as a
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means of mitigating hashtable flooding denial of service attacks.
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Generating a HalfSipHash key
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============================
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Keys should always be generated from a cryptographically secure source of
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random numbers, either using get_random_bytes or get_random_once:
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hsiphash_key_t key;
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get_random_bytes(&key, sizeof(key));
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If you're not deriving your key from here, you're doing it wrong.
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Using the HalfSipHash functions
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===============================
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There are two variants of the function, one that takes a list of integers, and
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one that takes a buffer::
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u32 hsiphash(const void *data, size_t len, const hsiphash_key_t *key);
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And::
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u32 hsiphash_1u32(u32, const hsiphash_key_t *key);
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u32 hsiphash_2u32(u32, u32, const hsiphash_key_t *key);
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u32 hsiphash_3u32(u32, u32, u32, const hsiphash_key_t *key);
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u32 hsiphash_4u32(u32, u32, u32, u32, const hsiphash_key_t *key);
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If you pass the generic hsiphash function something of a constant length, it
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will constant fold at compile-time and automatically choose one of the
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optimized functions.
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Hashtable key function usage
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============================
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::
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struct some_hashtable {
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DECLARE_HASHTABLE(hashtable, 8);
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hsiphash_key_t key;
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};
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void init_hashtable(struct some_hashtable *table)
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{
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get_random_bytes(&table->key, sizeof(table->key));
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}
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static inline hlist_head *some_hashtable_bucket(struct some_hashtable *table, struct interesting_input *input)
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{
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return &table->hashtable[hsiphash(input, sizeof(*input), &table->key) & (HASH_SIZE(table->hashtable) - 1)];
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}
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You may then iterate like usual over the returned hash bucket.
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Performance
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===========
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HalfSipHash is roughly 3 times slower than JenkinsHash. For many replacements,
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this will not be a problem, as the hashtable lookup isn't the bottleneck. And
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in general, this is probably a good sacrifice to make for the security and DoS
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resistance of HalfSipHash.
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