lbcutil/bloom/murmurhash3.go

// Copyright (c) 2013, 2014 The btcsuite developers
// Use of this source code is governed by an ISC
// license that can be found in the LICENSE file.

package bloom

import (
	"encoding/binary"
)

// The following constants are used by the MurmurHash3 algorithm.
const (
	murmurC1 = 0xcc9e2d51
	murmurC2 = 0x1b873593
	murmurR1 = 15
	murmurR2 = 13
	murmurM  = 5
	murmurN  = 0xe6546b64
)

// MurmurHash3 implements a non-cryptographic hash function using the
// MurmurHash3 algorithm.  This implementation yields a 32-bit hash value which
// is suitable for general hash-based lookups.  The seed can be used to
// effectively randomize the hash function.  This makes it ideal for use in
// bloom filters which need multiple independent hash functions.
func MurmurHash3(seed uint32, data []byte) uint32 {
	dataLen := uint32(len(data))
	hash := seed
	k := uint32(0)
	numBlocks := dataLen / 4

	// Calculate the hash in 4-byte chunks.
	for i := uint32(0); i < numBlocks; i++ {
		k = binary.LittleEndian.Uint32(data[i*4:])
		k *= murmurC1
		k = (k << murmurR1) | (k >> (32 - murmurR1))
		k *= murmurC2

		hash ^= k
		hash = (hash << murmurR2) | (hash >> (32 - murmurR2))
		hash = hash*murmurM + murmurN
	}

	// Handle remaining bytes.
	tailIdx := numBlocks * 4
	k = 0

	switch dataLen & 3 {
	case 3:
		k ^= uint32(data[tailIdx+2]) << 16
		fallthrough
	case 2:
		k ^= uint32(data[tailIdx+1]) << 8
		fallthrough
	case 1:
		k ^= uint32(data[tailIdx])
		k *= murmurC1
		k = (k << murmurR1) | (k >> (32 - murmurR1))
		k *= murmurC2
		hash ^= k
	}

	// Finalization.
	hash ^= uint32(dataLen)
	hash ^= hash >> 16
	hash *= 0x85ebca6b
	hash ^= hash >> 13
	hash *= 0xc2b2ae35
	hash ^= hash >> 16

	return hash
}
Relicense to the btcsuite developers. 2015-05-01 19:41:58 +02:00			`// Copyright (c) 2013, 2014 The btcsuite developers`
Add license header to all bloom package files. 2014-07-10 03:01:38 +02:00			`// Use of this source code is governed by an ISC`
			`// license that can be found in the LICENSE file.`

Cleanup and finish BIP0037 bloom filter API. This commit finishes the work started by @dajohi on bloom filters. - Rename the package from bloomfilter to bloom - Rename New function to NewFiler - Rename Load function to LoadFilter - Rename BloomFilter type to Filter - Rename Contains to Matches - Correct tx match handling to match all inputs and outputs instead of only the first one - Optimize murmur hash function by using constants - Optimize the merkle block creation and reduce num of memory allocations required - Make MsgFilterLoad concurrent safe as intended - Update various code consistency issues - Add a lot of comments - Improve tests - Make the code golint clean 2014-07-09 04:59:33 +02:00			`package bloom`

			`import (`
			`"encoding/binary"`
			`)`

			`// The following constants are used by the MurmurHash3 algorithm.`
			`const (`
			`murmurC1 = 0xcc9e2d51`
			`murmurC2 = 0x1b873593`
			`murmurR1 = 15`
			`murmurR2 = 13`
			`murmurM = 5`
			`murmurN = 0xe6546b64`
			`)`

			`// MurmurHash3 implements a non-cryptographic hash function using the`
			`// MurmurHash3 algorithm. This implementation yields a 32-bit hash value which`
			`// is suitable for general hash-based lookups. The seed can be used to`
			`// effectively randomize the hash function. This makes it ideal for use in`
			`// bloom filters which need multiple independent hash functions.`
			`func MurmurHash3(seed uint32, data []byte) uint32 {`
			`dataLen := uint32(len(data))`
			`hash := seed`
			`k := uint32(0)`
			`numBlocks := dataLen / 4`

			`// Calculate the hash in 4-byte chunks.`
			`for i := uint32(0); i < numBlocks; i++ {`
			`k = binary.LittleEndian.Uint32(data[i*4:])`
			`k *= murmurC1`
			`k = (k << murmurR1) \| (k >> (32 - murmurR1))`
			`k *= murmurC2`

			`hash ^= k`
			`hash = (hash << murmurR2) \| (hash >> (32 - murmurR2))`
			`hash = hash*murmurM + murmurN`
			`}`

			`// Handle remaining bytes.`
			`tailIdx := numBlocks * 4`
			`k = 0`

			`switch dataLen & 3 {`
			`case 3:`
			`k ^= uint32(data[tailIdx+2]) << 16`
			`fallthrough`
			`case 2:`
			`k ^= uint32(data[tailIdx+1]) << 8`
			`fallthrough`
			`case 1:`
			`k ^= uint32(data[tailIdx])`
			`k *= murmurC1`
			`k = (k << murmurR1) \| (k >> (32 - murmurR1))`
			`k *= murmurC2`
			`hash ^= k`
			`}`

			`// Finalization.`
			`hash ^= uint32(dataLen)`
			`hash ^= hash >> 16`
			`hash *= 0x85ebca6b`
			`hash ^= hash >> 13`
			`hash *= 0xc2b2ae35`
			`hash ^= hash >> 16`

			`return hash`
			`}`