vendor/github.com/jcmturner/gokrb5/v8/crypto/rfc3961/nfold.go - voltha-go - Gitiles

 package rfc3961

 // Implementation of the n-fold algorithm as defined in RFC 3961.

 /* Credits
 This golang implementation of nfold used the following project for help with implementation detail.
 Although their source is in java it was helpful as a reference implementation of the RFC.
 You can find the source code of their open source project along with license information below.
 We acknowledge and are grateful to these developers for their contributions to open source

 Project: Apache Directory (http://http://directory.apache.org/)
 https://svn.apache.org/repos/asf/directory/apacheds/tags/1.5.1/kerberos-shared/src/main/java/org/apache/directory/server/kerberos/shared/crypto/encryption/NFold.java
 License: http://www.apache.org/licenses/LICENSE-2.0
 */

 // Nfold expands the key to ensure it is not smaller than one cipher block.
 // Defined in RFC 3961.
 //
 // m input bytes that will be "stretched" to the least common multiple of n bits and the bit length of m.
 func Nfold(m []byte, n int) []byte {
 	k := len(m) * 8

 	//Get the lowest common multiple of the two bit sizes
 	lcm := lcm(n, k)
 	relicate := lcm / k
 	var sumBytes []byte

 	for i := 0; i < relicate; i++ {
 		rotation := 13 * i
 		sumBytes = append(sumBytes, rotateRight(m, rotation)...)
 	}

 	nfold := make([]byte, n/8)
 	sum := make([]byte, n/8)
 	for i := 0; i < lcm/n; i++ {
 		for j := 0; j < n/8; j++ {
 			sum[j] = sumBytes[j+(i*len(sum))]
 		}
 		nfold = onesComplementAddition(nfold, sum)
 	}
 	return nfold
 }

 func onesComplementAddition(n1, n2 []byte) []byte {
 	numBits := len(n1) * 8
 	out := make([]byte, numBits/8)
 	carry := 0
 	for i := numBits - 1; i > -1; i-- {
 		n1b := getBit(&n1, i)
 		n2b := getBit(&n2, i)
 		s := n1b + n2b + carry

 		if s == 0 || s == 1 {
 			setBit(&out, i, s)
 			carry = 0
 		} else if s == 2 {
 			carry = 1
 		} else if s == 3 {
 			setBit(&out, i, 1)
 			carry = 1
 		}
 	}
 	if carry == 1 {
 		carryArray := make([]byte, len(n1))
 		carryArray[len(carryArray)-1] = 1
 		out = onesComplementAddition(out, carryArray)
 	}
 	return out
 }

 func rotateRight(b []byte, step int) []byte {
 	out := make([]byte, len(b))
 	bitLen := len(b) * 8
 	for i := 0; i < bitLen; i++ {
 		v := getBit(&b, i)
 		setBit(&out, (i+step)%bitLen, v)
 	}
 	return out
 }

 func lcm(x, y int) int {
 	return (x * y) / gcd(x, y)
 }

 func gcd(x, y int) int {
 	for y != 0 {
 		x, y = y, x%y
 	}
 	return x
 }

 func getBit(b *[]byte, p int) int {
 	pByte := p / 8
 	pBit := uint(p % 8)
 	vByte := (*b)[pByte]
 	vInt := int(vByte >> (8 - (pBit + 1)) & 0x0001)
 	return vInt
 }

 func setBit(b *[]byte, p, v int) {
 	pByte := p / 8
 	pBit := uint(p % 8)
 	oldByte := (*b)[pByte]
 	var newByte byte
 	newByte = byte(v<<(8-(pBit+1))) | oldByte
 	(*b)[pByte] = newByte
 }
	package rfc3961

	// Implementation of the n-fold algorithm as defined in RFC 3961.

	/* Credits
	This golang implementation of nfold used the following project for help with implementation detail.
	Although their source is in java it was helpful as a reference implementation of the RFC.
	You can find the source code of their open source project along with license information below.
	We acknowledge and are grateful to these developers for their contributions to open source

	Project: Apache Directory (http://http://directory.apache.org/)
	https://svn.apache.org/repos/asf/directory/apacheds/tags/1.5.1/kerberos-shared/src/main/java/org/apache/directory/server/kerberos/shared/crypto/encryption/NFold.java
	License: http://www.apache.org/licenses/LICENSE-2.0
	*/

	// Nfold expands the key to ensure it is not smaller than one cipher block.
	// Defined in RFC 3961.
	//
	// m input bytes that will be "stretched" to the least common multiple of n bits and the bit length of m.
	func Nfold(m []byte, n int) []byte {
	k := len(m) * 8

	//Get the lowest common multiple of the two bit sizes
	lcm := lcm(n, k)
	relicate := lcm / k
	var sumBytes []byte

	for i := 0; i < relicate; i++ {
	rotation := 13 * i
	sumBytes = append(sumBytes, rotateRight(m, rotation)...)
	}

	nfold := make([]byte, n/8)
	sum := make([]byte, n/8)
	for i := 0; i < lcm/n; i++ {
	for j := 0; j < n/8; j++ {
	sum[j] = sumBytes[j+(i*len(sum))]
	}
	nfold = onesComplementAddition(nfold, sum)
	}
	return nfold
	}

	func onesComplementAddition(n1, n2 []byte) []byte {
	numBits := len(n1) * 8
	out := make([]byte, numBits/8)
	carry := 0
	for i := numBits - 1; i > -1; i-- {
	n1b := getBit(&n1, i)
	n2b := getBit(&n2, i)
	s := n1b + n2b + carry

	if s == 0 \|\| s == 1 {
	setBit(&out, i, s)
	carry = 0
	} else if s == 2 {
	carry = 1
	} else if s == 3 {
	setBit(&out, i, 1)
	carry = 1
	}
	}
	if carry == 1 {
	carryArray := make([]byte, len(n1))
	carryArray[len(carryArray)-1] = 1
	out = onesComplementAddition(out, carryArray)
	}
	return out
	}

	func rotateRight(b []byte, step int) []byte {
	out := make([]byte, len(b))
	bitLen := len(b) * 8
	for i := 0; i < bitLen; i++ {
	v := getBit(&b, i)
	setBit(&out, (i+step)%bitLen, v)
	}
	return out
	}

	func lcm(x, y int) int {
	return (x * y) / gcd(x, y)
	}

	func gcd(x, y int) int {
	for y != 0 {
	x, y = y, x%y
	}
	return x
	}

	func getBit(b *[]byte, p int) int {
	pByte := p / 8
	pBit := uint(p % 8)
	vByte := (*b)[pByte]
	vInt := int(vByte >> (8 - (pBit + 1)) & 0x0001)
	return vInt
	}

	func setBit(b *[]byte, p, v int) {
	pByte := p / 8
	pBit := uint(p % 8)
	oldByte := (*b)[pByte]
	var newByte byte
	newByte = byte(v<<(8-(pBit+1))) \| oldByte
	(*b)[pByte] = newByte
	}