/* __ *\ ** ________ ___ / / ___ Scala API ** ** / __/ __// _ | / / / _ | (c) 2003-2013, LAMP/EPFL ** ** __\ \/ /__/ __ |/ /__/ __ | http://scala-lang.org/ ** ** /____/\___/_/ |_/____/_/ | | ** ** |/ ** \* */ package scala package util /** An implementation of Austin Appleby's MurmurHash 3.0 algorithm * (32 bit version); reference: https://github.com/aappleby/smhasher * * This is the hash used by collections and case classes (including * tuples). * * @author Rex Kerr * @version 2.9 * @since 2.9 */ import java.lang.Integer.{ rotateLeft => rotl } import scala.collection.Iterator /** A class designed to generate well-distributed non-cryptographic * hashes. It is designed to be passed to a collection's foreach method, * or can take individual hash values with append. Its own hash code is * set equal to the hash code of whatever it is hashing. */ @deprecated("Use the object MurmurHash3 instead.", "2.10.0") class MurmurHash[@specialized(Int,Long,Float,Double) T](seed: Int) extends (T => Unit) { import MurmurHash._ private var h = startHash(seed) private var c = hiddenMagicA private var k = hiddenMagicB private var hashed = false private var hashvalue = h /** Begin a new hash using the same seed. */ def reset() { h = startHash(seed) c = hiddenMagicA k = hiddenMagicB hashed = false } /** Incorporate the hash value of one item. */ def apply(t: T) { h = extendHash(h,t.##,c,k) c = nextMagicA(c) k = nextMagicB(k) hashed = false } /** Incorporate a known hash value. */ def append(i: Int) { h = extendHash(h,i,c,k) c = nextMagicA(c) k = nextMagicB(k) hashed = false } /** Retrieve the hash value */ def hash = { if (!hashed) { hashvalue = finalizeHash(h) hashed = true } hashvalue } override def hashCode = hash } /** An object designed to generate well-distributed non-cryptographic * hashes. It is designed to hash a collection of integers; along with * the integers to hash, it generates two magic streams of integers to * increase the distribution of repetitive input sequences. Thus, * three methods need to be called at each step (to start and to * incorporate a new integer) to update the values. Only one method * needs to be called to finalize the hash. */ @deprecated("Use the object MurmurHash3 instead.", "2.10.0") // NOTE: Used by SBT 0.13.0-M2 and below object MurmurHash { // Magic values used for MurmurHash's 32 bit hash. // Don't change these without consulting a hashing expert! final private val visibleMagic = 0x971e137b final private val hiddenMagicA = 0x95543787 final private val hiddenMagicB = 0x2ad7eb25 final private val visibleMixer = 0x52dce729 final private val hiddenMixerA = 0x7b7d159c final private val hiddenMixerB = 0x6bce6396 final private val finalMixer1 = 0x85ebca6b final private val finalMixer2 = 0xc2b2ae35 // Arbitrary values used for hashing certain classes final private val seedString = 0xf7ca7fd2 final private val seedArray = 0x3c074a61 /** The first 23 magic integers from the first stream are stored here */ val storedMagicA = Iterator.iterate(hiddenMagicA)(nextMagicA).take(23).toArray /** The first 23 magic integers from the second stream are stored here */ val storedMagicB = Iterator.iterate(hiddenMagicB)(nextMagicB).take(23).toArray /** Begin a new hash with a seed value. */ def startHash(seed: Int) = seed ^ visibleMagic /** The initial magic integers in the first stream. */ def startMagicA = hiddenMagicA /** The initial magic integer in the second stream. */ def startMagicB = hiddenMagicB /** Incorporates a new value into an existing hash. * * @param hash the prior hash value * @param value the new value to incorporate * @param magicA a magic integer from the stream * @param magicB a magic integer from a different stream * @return the updated hash value */ def extendHash(hash: Int, value: Int, magicA: Int, magicB: Int) = { (hash ^ rotl(value*magicA,11)*magicB)*3 + visibleMixer } /** Given a magic integer from the first stream, compute the next */ def nextMagicA(magicA: Int) = magicA*5 + hiddenMixerA /** Given a magic integer from the second stream, compute the next */ def nextMagicB(magicB: Int) = magicB*5 + hiddenMixerB /** Once all hashes have been incorporated, this performs a final mixing */ def finalizeHash(hash: Int) = { var i = (hash ^ (hash>>>16)) i *= finalMixer1 i ^= (i >>> 13) i *= finalMixer2 i ^= (i >>> 16) i } /** Compute a high-quality hash of an array */ def arrayHash[@specialized T](a: Array[T]) = { var h = startHash(a.length * seedArray) var c = hiddenMagicA var k = hiddenMagicB var j = 0 while (j < a.length) { h = extendHash(h, a(j).##, c, k) c = nextMagicA(c) k = nextMagicB(k) j += 1 } finalizeHash(h) } /** Compute a high-quality hash of a string */ def stringHash(s: String) = { var h = startHash(s.length * seedString) var c = hiddenMagicA var k = hiddenMagicB var j = 0 while (j+1 < s.length) { val i = (s.charAt(j)<<16) + s.charAt(j+1) h = extendHash(h,i,c,k) c = nextMagicA(c) k = nextMagicB(k) j += 2 } if (j < s.length) h = extendHash(h,s.charAt(j).toInt,c,k) finalizeHash(h) } /** Compute a hash that is symmetric in its arguments--that is, * where the order of appearance of elements does not matter. * This is useful for hashing sets, for example. */ def symmetricHash[T](xs: scala.collection.TraversableOnce[T], seed: Int) = { var a,b,n = 0 var c = 1 xs.seq.foreach(i => { val h = i.## a += h b ^= h if (h != 0) c *= h n += 1 }) var h = startHash(seed * n) h = extendHash(h, a, storedMagicA(0), storedMagicB(0)) h = extendHash(h, b, storedMagicA(1), storedMagicB(1)) h = extendHash(h, c, storedMagicA(2), storedMagicB(2)) finalizeHash(h) } }