@Beta @Immutable public interface HashFunction
Unpacking this definition:
Hasher
), but this is merely a convenience; these are always translated into raw
byte sequences under the covers.
bits()
). For example, Hashing.sha1()
produces a 160-bit number,
while Hashing.murmur3_32()
yields only 32 bits. Because a long
value is
clearly insufficient to hold all hash code values, this API represents a hash code as an
instance of HashCode
.
HashFunction
instances should always be
stateless, and therefore thread-safe.
Summarizing the last two points: "equal yield equal always; unequal yield unequal often." This is the most important characteristic of all hash functions.
A high-quality hash function strives for some subset of the following virtues:
Hashing.sha512()
are designed to
make it as infeasible as possible to reverse-engineer the input that produced a given hash
code, or even to discover any two distinct inputs that yield the same result. These
are called cryptographic hash functions. But, whenever it is learned that either of
these feats has become computationally feasible, the function is deemed "broken" and should
no longer be used for secure purposes. (This is the likely eventual fate of all
cryptographic hashes.)
The primary way to provide the data that your hash function should act on is via a Hasher
. Obtain a new hasher from the hash function using newHasher()
, "push" the relevant
data into it using methods like Hasher.putBytes(byte[])
, and finally ask for the HashCode
when finished using Hasher.hash()
. (See an example of
this.)
If all you want to hash is a single byte array, string or long
value, there are
convenient shortcut methods defined directly on HashFunction
to make this easier.
Hasher accepts primitive data types, but can also accept any Object of type T
provided
that you implement a Funnel
<T>
to specify how to "feed" data from that object
into the function. (See an example of this.)
Compatibility note: Throughout this API, multibyte values are always interpreted in
little-endian order. That is, hashing the byte array {0x01, 0x02, 0x03, 0x04}
is
equivalent to hashing the int
value 0x04030201
. If this isn't what you need,
methods such as Integer.reverseBytes(int)
and Ints.toByteArray(int)
will help.
Object.hashCode()
Java's baked-in concept of hash codes is constrained to 32 bits, and provides no separation
between hash algorithms and the data they act on, so alternate hash algorithms can't be easily
substituted. Also, implementations of hashCode
tend to be poor-quality, in part because
they end up depending on other existing poor-quality hashCode
implementations,
including those in many JDK classes.
Object.hashCode
implementations tend to be very fast, but have weak collision
prevention and no expectation of bit dispersion. This leaves them perfectly suitable for
use in hash tables, because extra collisions cause only a slight performance hit, while poor bit
dispersion is easily corrected using a secondary hash function (which all reasonable hash table
implementations in Java use). For the many uses of hash functions beyond data structures,
however, Object.hashCode
almost always falls short -- hence this library.
Modifier and Type | Method and Description |
---|---|
int |
bits()
Returns the number of bits (a multiple of 32) that each hash code produced by this hash
function has.
|
HashCode |
hashBytes(byte[] input)
Shortcut for
newHasher().putBytes(input).hash() . |
HashCode |
hashBytes(byte[] input,
int off,
int len)
Shortcut for
newHasher().putBytes(input, off, len).hash() . |
HashCode |
hashBytes(ByteBuffer input)
Shortcut for
newHasher().putBytes(input).hash() . |
HashCode |
hashInt(int input)
Shortcut for
newHasher().putInt(input).hash() ; returns the hash code for the given
int value, interpreted in little-endian byte order. |
HashCode |
hashLong(long input)
Shortcut for
newHasher().putLong(input).hash() ; returns the hash code for the given
long value, interpreted in little-endian byte order. |
<T> HashCode |
hashObject(T instance,
Funnel<? super T> funnel)
Shortcut for
newHasher().putObject(instance, funnel).hash() . |
HashCode |
hashString(CharSequence input,
Charset charset)
Shortcut for
newHasher().putString(input, charset).hash() . |
HashCode |
hashUnencodedChars(CharSequence input)
Shortcut for
newHasher().putUnencodedChars(input).hash() . |
Hasher |
newHasher()
Begins a new hash code computation by returning an initialized, stateful
Hasher
instance that is ready to receive data. |
Hasher |
newHasher(int expectedInputSize)
Begins a new hash code computation as
newHasher() , but provides a hint of the expected
size of the input (in bytes). |
Hasher newHasher()
Hasher
instance that is ready to receive data. Example:
HashFunction hf = Hashing.md5();
HashCode hc = hf.newHasher()
.putLong(id)
.putBoolean(isActive)
.hash();
Hasher newHasher(int expectedInputSize)
newHasher()
, but provides a hint of the expected
size of the input (in bytes). This is only important for non-streaming hash functions (hash
functions that need to buffer their whole input before processing any of it).HashCode hashInt(int input)
newHasher().putInt(input).hash()
; returns the hash code for the given
int
value, interpreted in little-endian byte order. The implementation might
perform better than its longhand equivalent, but should not perform worse.HashCode hashLong(long input)
newHasher().putLong(input).hash()
; returns the hash code for the given
long
value, interpreted in little-endian byte order. The implementation might
perform better than its longhand equivalent, but should not perform worse.HashCode hashBytes(byte[] input)
newHasher().putBytes(input).hash()
. The implementation might
perform better than its longhand equivalent, but should not perform worse.HashCode hashBytes(byte[] input, int off, int len)
newHasher().putBytes(input, off, len).hash()
. The implementation
might perform better than its longhand equivalent, but should not perform worse.IndexOutOfBoundsException
- if off < 0
or off + len > bytes.length
or
len < 0
HashCode hashBytes(ByteBuffer input)
newHasher().putBytes(input).hash()
. The implementation might
perform better than its longhand equivalent, but should not perform worse.HashCode hashUnencodedChars(CharSequence input)
newHasher().putUnencodedChars(input).hash()
. The implementation
might perform better than its longhand equivalent, but should not perform worse. Note
that no character encoding is performed; the low byte and high byte of each char
are
hashed directly (in that order).
Warning: This method will produce different output than most other languages do when
running the same hash function on the equivalent input. For cross-language compatibility, use
hashString(java.lang.CharSequence, java.nio.charset.Charset)
, usually with a charset of UTF-8. For other use cases, use hashUnencodedChars
.
HashCode hashString(CharSequence input, Charset charset)
newHasher().putString(input, charset).hash()
. Characters are encoded using
the given Charset
. The implementation might perform better than its longhand
equivalent, but should not perform worse.
Warning: This method, which reencodes the input before hashing it, is useful only for
cross-language compatibility. For other use cases, prefer hashUnencodedChars(java.lang.CharSequence)
, which is
faster, produces the same output across Java releases, and hashes every char
in the
input, even if some are invalid.
<T> HashCode hashObject(T instance, Funnel<? super T> funnel)
newHasher().putObject(instance, funnel).hash()
. The implementation
might perform better than its longhand equivalent, but should not perform worse.int bits()
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