Documentation/security/siphash.rst - linux - Git at Google

 ===========================
 SipHash - a short input PRF
 ===========================

 :Author: Written by Jason A. Donenfeld <jason@zx2c4.com>

 SipHash is a cryptographically secure PRF -- a keyed hash function -- that
 performs very well for short inputs, hence the name. It was designed by
 cryptographers Daniel J. Bernstein and Jean-Philippe Aumasson. It is intended
 as a replacement for some uses of: `jhash`, `md5_transform`, `sha1_transform`,
 and so forth.

 SipHash takes a secret key filled with randomly generated numbers and either
 an input buffer or several input integers. It spits out an integer that is
 indistinguishable from random. You may then use that integer as part of secure
 sequence numbers, secure cookies, or mask it off for use in a hash table.

 Generating a key
 ================

 Keys should always be generated from a cryptographically secure source of
 random numbers, either using get_random_bytes or get_random_once::

 	siphash_key_t key;
 	get_random_bytes(&key, sizeof(key));

 If you're not deriving your key from here, you're doing it wrong.

 Using the functions
 ===================

 There are two variants of the function, one that takes a list of integers, and
 one that takes a buffer::

 	u64 siphash(const void *data, size_t len, const siphash_key_t *key);

 And::

 	u64 siphash_1u64(u64, const siphash_key_t *key);
 	u64 siphash_2u64(u64, u64, const siphash_key_t *key);
 	u64 siphash_3u64(u64, u64, u64, const siphash_key_t *key);
 	u64 siphash_4u64(u64, u64, u64, u64, const siphash_key_t *key);
 	u64 siphash_1u32(u32, const siphash_key_t *key);
 	u64 siphash_2u32(u32, u32, const siphash_key_t *key);
 	u64 siphash_3u32(u32, u32, u32, const siphash_key_t *key);
 	u64 siphash_4u32(u32, u32, u32, u32, const siphash_key_t *key);

 If you pass the generic siphash function something of a constant length, it
 will constant fold at compile-time and automatically choose one of the
 optimized functions.

 Hashtable key function usage::

 	struct some_hashtable {
 		DECLARE_HASHTABLE(hashtable, 8);
 		siphash_key_t key;
 	};

 	void init_hashtable(struct some_hashtable *table)
 	{
 		get_random_bytes(&table->key, sizeof(table->key));
 	}

 	static inline hlist_head *some_hashtable_bucket(struct some_hashtable *table, struct interesting_input *input)
 	{
 		return &table->hashtable[siphash(input, sizeof(*input), &table->key) & (HASH_SIZE(table->hashtable) - 1)];
 	}

 You may then iterate like usual over the returned hash bucket.

 Security
 ========

 SipHash has a very high security margin, with its 128-bit key. So long as the
 key is kept secret, it is impossible for an attacker to guess the outputs of
 the function, even if being able to observe many outputs, since 2^128 outputs
 is significant.

 Linux implements the "2-4" variant of SipHash.

 Struct-passing Pitfalls
 =======================

 Often times the XuY functions will not be large enough, and instead you'll
 want to pass a pre-filled struct to siphash. When doing this, it's important
 to always ensure the struct has no padding holes. The easiest way to do this
 is to simply arrange the members of the struct in descending order of size,
 and to use offsetofend() instead of sizeof() for getting the size. For
 performance reasons, if possible, it's probably a good thing to align the
 struct to the right boundary. Here's an example::

 	const struct {
 		struct in6_addr saddr;
 		u32 counter;
 		u16 dport;
 	} __aligned(SIPHASH_ALIGNMENT) combined = {
 		.saddr = *(struct in6_addr *)saddr,
 		.counter = counter,
 		.dport = dport
 	};
 	u64 h = siphash(&combined, offsetofend(typeof(combined), dport), &secret);

 Resources
 =========

 Read the SipHash paper if you're interested in learning more:
 https://131002.net/siphash/siphash.pdf

 -------------------------------------------------------------------------------

 ===============================================
 HalfSipHash - SipHash's insecure younger cousin
 ===============================================

 :Author: Written by Jason A. Donenfeld <jason@zx2c4.com>

 On the off-chance that SipHash is not fast enough for your needs, you might be
 able to justify using HalfSipHash, a terrifying but potentially useful
 possibility. HalfSipHash cuts SipHash's rounds down from "2-4" to "1-3" and,
 even scarier, uses an easily brute-forcable 64-bit key (with a 32-bit output)
 instead of SipHash's 128-bit key. However, this may appeal to some
 high-performance `jhash` users.

 HalfSipHash support is provided through the "hsiphash" family of functions.

 .. warning::
    Do not ever use the hsiphash functions except for as a hashtable key
    function, and only then when you can be absolutely certain that the outputs
    will never be transmitted out of the kernel. This is only remotely useful
    over `jhash` as a means of mitigating hashtable flooding denial of service
    attacks.

 On 64-bit kernels, the hsiphash functions actually implement SipHash-1-3, a
 reduced-round variant of SipHash, instead of HalfSipHash-1-3. This is because in
 64-bit code, SipHash-1-3 is no slower than HalfSipHash-1-3, and can be faster.
 Note, this does *not* mean that in 64-bit kernels the hsiphash functions are the
 same as the siphash ones, or that they are secure; the hsiphash functions still
 use a less secure reduced-round algorithm and truncate their outputs to 32
 bits.

 Generating a hsiphash key
 =========================

 Keys should always be generated from a cryptographically secure source of
 random numbers, either using get_random_bytes or get_random_once::

 	hsiphash_key_t key;
 	get_random_bytes(&key, sizeof(key));

 If you're not deriving your key from here, you're doing it wrong.

 Using the hsiphash functions
 ============================

 There are two variants of the function, one that takes a list of integers, and
 one that takes a buffer::

 	u32 hsiphash(const void *data, size_t len, const hsiphash_key_t *key);

 And::

 	u32 hsiphash_1u32(u32, const hsiphash_key_t *key);
 	u32 hsiphash_2u32(u32, u32, const hsiphash_key_t *key);
 	u32 hsiphash_3u32(u32, u32, u32, const hsiphash_key_t *key);
 	u32 hsiphash_4u32(u32, u32, u32, u32, const hsiphash_key_t *key);

 If you pass the generic hsiphash function something of a constant length, it
 will constant fold at compile-time and automatically choose one of the
 optimized functions.

 Hashtable key function usage
 ============================

 ::

 	struct some_hashtable {
 		DECLARE_HASHTABLE(hashtable, 8);
 		hsiphash_key_t key;
 	};

 	void init_hashtable(struct some_hashtable *table)
 	{
 		get_random_bytes(&table->key, sizeof(table->key));
 	}

 	static inline hlist_head *some_hashtable_bucket(struct some_hashtable *table, struct interesting_input *input)
 	{
 		return &table->hashtable[hsiphash(input, sizeof(*input), &table->key) & (HASH_SIZE(table->hashtable) - 1)];
 	}

 You may then iterate like usual over the returned hash bucket.

 Performance
 ===========

 hsiphash() is roughly 3 times slower than jhash(). For many replacements, this
 will not be a problem, as the hashtable lookup isn't the bottleneck. And in
 general, this is probably a good sacrifice to make for the security and DoS
 resistance of hsiphash().
	===========================
	SipHash - a short input PRF
	===========================

	:Author: Written by Jason A. Donenfeld <jason@zx2c4.com>

	SipHash is a cryptographically secure PRF -- a keyed hash function -- that
	performs very well for short inputs, hence the name. It was designed by
	cryptographers Daniel J. Bernstein and Jean-Philippe Aumasson. It is intended
	as a replacement for some uses of: `jhash`, `md5_transform`, `sha1_transform`,
	and so forth.

	SipHash takes a secret key filled with randomly generated numbers and either
	an input buffer or several input integers. It spits out an integer that is
	indistinguishable from random. You may then use that integer as part of secure
	sequence numbers, secure cookies, or mask it off for use in a hash table.

	Generating a key
	================

	Keys should always be generated from a cryptographically secure source of
	random numbers, either using get_random_bytes or get_random_once::

	siphash_key_t key;
	get_random_bytes(&key, sizeof(key));

	If you're not deriving your key from here, you're doing it wrong.

	Using the functions
	===================

	There are two variants of the function, one that takes a list of integers, and
	one that takes a buffer::

	u64 siphash(const void data, size_t len, const siphash_key_t key);

	And::

	u64 siphash_1u64(u64, const siphash_key_t *key);
	u64 siphash_2u64(u64, u64, const siphash_key_t *key);
	u64 siphash_3u64(u64, u64, u64, const siphash_key_t *key);
	u64 siphash_4u64(u64, u64, u64, u64, const siphash_key_t *key);
	u64 siphash_1u32(u32, const siphash_key_t *key);
	u64 siphash_2u32(u32, u32, const siphash_key_t *key);
	u64 siphash_3u32(u32, u32, u32, const siphash_key_t *key);
	u64 siphash_4u32(u32, u32, u32, u32, const siphash_key_t *key);

	If you pass the generic siphash function something of a constant length, it
	will constant fold at compile-time and automatically choose one of the
	optimized functions.

	Hashtable key function usage::

	struct some_hashtable {
	DECLARE_HASHTABLE(hashtable, 8);
	siphash_key_t key;
	};

	void init_hashtable(struct some_hashtable *table)
	{
	get_random_bytes(&table->key, sizeof(table->key));
	}

	static inline hlist_head some_hashtable_bucket(struct some_hashtable table, struct interesting_input *input)
	{
	return &table->hashtable[siphash(input, sizeof(*input), &table->key) & (HASH_SIZE(table->hashtable) - 1)];
	}

	You may then iterate like usual over the returned hash bucket.

	Security
	========

	SipHash has a very high security margin, with its 128-bit key. So long as the
	key is kept secret, it is impossible for an attacker to guess the outputs of
	the function, even if being able to observe many outputs, since 2^128 outputs
	is significant.

	Linux implements the "2-4" variant of SipHash.

	Struct-passing Pitfalls
	=======================

	Often times the XuY functions will not be large enough, and instead you'll
	want to pass a pre-filled struct to siphash. When doing this, it's important
	to always ensure the struct has no padding holes. The easiest way to do this
	is to simply arrange the members of the struct in descending order of size,
	and to use offsetofend() instead of sizeof() for getting the size. For
	performance reasons, if possible, it's probably a good thing to align the
	struct to the right boundary. Here's an example::

	const struct {
	struct in6_addr saddr;
	u32 counter;
	u16 dport;
	} __aligned(SIPHASH_ALIGNMENT) combined = {
	.saddr = (struct in6_addr )saddr,
	.counter = counter,
	.dport = dport
	};
	u64 h = siphash(&combined, offsetofend(typeof(combined), dport), &secret);

	Resources
	=========

	Read the SipHash paper if you're interested in learning more:
	https://131002.net/siphash/siphash.pdf

	-------------------------------------------------------------------------------

	===============================================
	HalfSipHash - SipHash's insecure younger cousin
	===============================================

	:Author: Written by Jason A. Donenfeld <jason@zx2c4.com>

	On the off-chance that SipHash is not fast enough for your needs, you might be
	able to justify using HalfSipHash, a terrifying but potentially useful
	possibility. HalfSipHash cuts SipHash's rounds down from "2-4" to "1-3" and,
	even scarier, uses an easily brute-forcable 64-bit key (with a 32-bit output)
	instead of SipHash's 128-bit key. However, this may appeal to some
	high-performance `jhash` users.

	HalfSipHash support is provided through the "hsiphash" family of functions.

	.. warning::
	Do not ever use the hsiphash functions except for as a hashtable key
	function, and only then when you can be absolutely certain that the outputs
	will never be transmitted out of the kernel. This is only remotely useful
	over `jhash` as a means of mitigating hashtable flooding denial of service
	attacks.

	On 64-bit kernels, the hsiphash functions actually implement SipHash-1-3, a
	reduced-round variant of SipHash, instead of HalfSipHash-1-3. This is because in
	64-bit code, SipHash-1-3 is no slower than HalfSipHash-1-3, and can be faster.
	Note, this does not mean that in 64-bit kernels the hsiphash functions are the
	same as the siphash ones, or that they are secure; the hsiphash functions still
	use a less secure reduced-round algorithm and truncate their outputs to 32
	bits.

	Generating a hsiphash key
	=========================

	Keys should always be generated from a cryptographically secure source of
	random numbers, either using get_random_bytes or get_random_once::

	hsiphash_key_t key;
	get_random_bytes(&key, sizeof(key));

	If you're not deriving your key from here, you're doing it wrong.

	Using the hsiphash functions
	============================

	There are two variants of the function, one that takes a list of integers, and
	one that takes a buffer::

	u32 hsiphash(const void data, size_t len, const hsiphash_key_t key);

	And::

	u32 hsiphash_1u32(u32, const hsiphash_key_t *key);
	u32 hsiphash_2u32(u32, u32, const hsiphash_key_t *key);
	u32 hsiphash_3u32(u32, u32, u32, const hsiphash_key_t *key);
	u32 hsiphash_4u32(u32, u32, u32, u32, const hsiphash_key_t *key);

	If you pass the generic hsiphash function something of a constant length, it
	will constant fold at compile-time and automatically choose one of the
	optimized functions.

	Hashtable key function usage
	============================

	::

	struct some_hashtable {
	DECLARE_HASHTABLE(hashtable, 8);
	hsiphash_key_t key;
	};

	void init_hashtable(struct some_hashtable *table)
	{
	get_random_bytes(&table->key, sizeof(table->key));
	}

	static inline hlist_head some_hashtable_bucket(struct some_hashtable table, struct interesting_input *input)
	{
	return &table->hashtable[hsiphash(input, sizeof(*input), &table->key) & (HASH_SIZE(table->hashtable) - 1)];
	}

	You may then iterate like usual over the returned hash bucket.

	Performance
	===========

	hsiphash() is roughly 3 times slower than jhash(). For many replacements, this
	will not be a problem, as the hashtable lookup isn't the bottleneck. And in
	general, this is probably a good sacrifice to make for the security and DoS
	resistance of hsiphash().