xs/vendor/blitter.com/go/wanderer/wanderer.go

// WANDERER - a crypto doodle that appears to give adequate
// protection to data in a stream cipher context
//
// Properties visualized using https://github.com/circulosmeos/circle
package wanderer

// TODOs:
// -define s-box rotation/shuffle schema
// -devise p-box schema (? Meh. Need to blockify & re-streamify to do this)
// ...

import (
	"errors"
	"fmt"
	"io"
	"time"

	mtwist "blitter.com/go/mtwist"
)

const (
	keylen    = 512
	sboxCount = keylen / 8
)

// Given input byte x (treated as 2-bit dirs),
// 'walk' box applying XOR of each position (E/S/W/N) given box
// dimensions w,h
// NOTE to ensure reachability of all values within a box, w,h
// should not each exceed 3 and should probably stay at 2, to
// give more even coverage given random input.
func walkingXOR(key, s []byte, w, h int, x byte) (r byte) {
	i := 0
	r = x
	for sidx := range key {
		ktemp := key[sidx]
		r = r ^ (s[i])
		for shift := uint(0); shift < 8; shift += 2 {
			//			fmt.Println("i:", i, "r:", r)
			dir := (ktemp >> shift) & 0x03
			switch dir {
			case 0:
				i = i + 1
				i = i % len(s)
			case 1:
				i = i + w
				i = i % len(s)
			case 2:
				if i%w != 0 {
					i = i - 1
				} else {
					i = i + w - 1
				}
			case 3:
				if i >= w {
					i = i - w
				} else {
					i = len(s) + i - w
				}
			}
			r = r ^ (s[i])
		}
	}
	return
}

func (c *Cipher) genSBoxen(n uint) {
	c.sboxen = make([][]byte, n)
	var idx uint
	for ; idx < n; idx++ {
		c.sboxen[idx] = make([]byte, c.sw*c.sh)
		_, _ = c.prng.Read(c.sboxen[idx])
	}
	//fmt.Fprintf(os.Stderr, "sboxen[0]:%v\n", c.sboxen[0])
}

// Mutate the session key (intended to be called as encryption
// proceeds), so that the 'walk path' through sboxes also does so.
func (c *Cipher) keyUpdate(perturb byte) {
	c.k[c.kidx] = c.k[c.kidx] ^ c.k[(c.kidx+1)%uint(len(c.k))]
	c.k[c.kidx] = c.k[c.kidx] ^ byte((c.prng.Int63()>>4)%256)
	c.kidx = (c.kidx + uint(perturb)) % uint(len(c.k))
}

// slow - perturb a single octet of a single sbox for each octet
// (CV = ~8.725% over 700 MiB of 0-byte pt)
func (c *Cipher) sboxUpdateA(perturb byte) {
	c.sboxen[perturb%sboxCount][int(perturb)%(c.sw+c.sh)] ^=
		perturb
}

// slower - perturb a single sbox for each octet
// (CV = ~?% over 700 MiB of 0-byte pt)
func (c *Cipher) sboxUpdateB(perturb byte) {
	lim := c.sw * c.sh
	for idx := 0; idx < lim; idx++ {
		c.sboxen[perturb%sboxCount][idx] ^= perturb
	}
}

// slowest -- full sbox re-gen after each octet
// (but lowest CV, ~0.05% over 700MiB of 0-byte pt)
func (c *Cipher) sboxUpdateC(perturb byte) {
	c.genSBoxen(sboxCount)
	//c.sboxen[perturb%sboxCount][int(perturb)%(c.sw+c.sh)] ^=
	//	perturb
}

type Cipher struct {
	prng   *mtwist.MT19937_64
	r      io.Reader
	w      io.Writer
	k      []byte
	kidx   uint
	sboxen [][]byte
	sw     int
	sh     int
	sctr   int // TODO: used to count down to re-keying & sbox regen
	mode   int
	n      byte
}

func NewCodec(r io.Reader, w io.Writer, mode int, key []byte, width, height int) (c *Cipher) {
	c = &Cipher{}
	c.prng = mtwist.New()
	if len(key) == 0 {
		c.k = []byte(fmt.Sprintf("%s", time.Now()))
	} else {
		c.k = key
	}
	c.prng.SeedFullState(c.k)

	// Discard first 64 bytes of MT output
	for idx := 0; idx < 64; idx++ {
		_ = c.prng.Int63()
	}
	c.mode = mode
	c.r = r
	c.w = w
	c.sw = width
	c.sh = height
	c.sctr = c.sw // sbox ctr: countdown to regen sboxes
	c.n = 0
	c.genSBoxen(sboxCount)

	//	fmt.Printf("%+v\n", sboxen)
	//	c.buf = make([]byte, 4)
	return c
}

func (c *Cipher) Read(p []byte) (n int, err error) {
	n, err = c.r.Read(p)
	if err == nil {
		for idx := 0; idx < n; idx++ {
			p[idx] = c.yield(p[idx])
		}
	}
	return n, err
}

func (c *Cipher) Write(p []byte) (n int, err error) {
	n, err = c.w.Write(p)
	return n, err
}

func (c *Cipher) yield(pt byte) (ct byte) {
	ct = walkingXOR(c.k, c.sboxen[c.n], c.sw, c.sh, pt)
	c.n = (c.n + 1) % byte(len(c.sboxen))
	c.keyUpdate(ct ^ pt) // must be equal in either encrypt/decrypt dirs
	switch c.mode {
	case 0:
		// [nothing - varA]
		break
	case 1:
		c.sboxUpdateA(ct ^ pt) // varA
	case 2:
		c.sboxUpdateB(ct ^ pt) // varB
	case 3:
		c.sboxUpdateC(ct ^ pt) // varC
	default:
		// [nothing]
	}
	//	c.sctr = c.sctr - 1
	//	if c.sctr == 0 {
	//		c.genSBoxen(sboxCount)
	//		c.sctr = c.sw
	//	}
	return ct
}

// XORKeyStream XORs each byte in the given slice with a byte from the
// cipher's key stream. Dst and src must overlap entirely or not at all.
//
// If len(dst) < len(src), XORKeyStream should panic. It is acceptable
// to pass a dst bigger than src, and in that case, XORKeyStream will
// only update dst[:len(src)] and will not touch the rest of dst.
//
// Multiple calls to XORKeyStream behave as if the concatenation of
// the src buffers was passed in a single run. That is, Stream
// maintains state and does not reset at each XORKeyStream call.
func (c *Cipher) XORKeyStream(dst, src []byte) {
	//fmt.Printf("len dst:%d len src:%d\n", len(dst), len(src))
	if len(dst) < len(src) {
		panic(errors.New("len(dst) < len(src)"))
	}

	for idx, v := range src {
		dst[idx] = c.yield(v)
	}
}
1/3 Updated Makefile to allow VENDOR flag (adds -vendor to version string) 2/3 Added vendor/ dir to lock down dependent pkg versions. The author of git.schwanenlied.me/yawning/{chacha20,newhope,kyber}.git has copied their repos to gitlab.com/yawning/ but some imports of chacha20 from newhope still inconsistently refer to git.schwanenlied.me/, breaking build. Licenses for chacha20 also changed from CC0 to AGPL, which may or may not be an issue. Until the two aforementioned issues are resolved, locking to last-good versions is probably the best way forward for now. To build with vendored deps, use make VENDOR=1 clean all 3/3 Moved body of CI push script into bacillus/ 2020-01-29 21:25:14 +00:00			`// WANDERER - a crypto doodle that appears to give adequate`
			`// protection to data in a stream cipher context`
			`//`
			`// Properties visualized using https://github.com/circulosmeos/circle`
			`package wanderer`

			`// TODOs:`
			`// -define s-box rotation/shuffle schema`
			`// -devise p-box schema (? Meh. Need to blockify & re-streamify to do this)`
			`// ...`

			`import (`
			`"errors"`
			`"fmt"`
			`"io"`
			`"time"`

			`mtwist "blitter.com/go/mtwist"`
			`)`

			`const (`
			`keylen = 512`
			`sboxCount = keylen / 8`
			`)`

			`// Given input byte x (treated as 2-bit dirs),`
			`// 'walk' box applying XOR of each position (E/S/W/N) given box`
			`// dimensions w,h`
			`// NOTE to ensure reachability of all values within a box, w,h`
			`// should not each exceed 3 and should probably stay at 2, to`
			`// give more even coverage given random input.`
			`func walkingXOR(key, s []byte, w, h int, x byte) (r byte) {`
			`i := 0`
			`r = x`
			`for sidx := range key {`
			`ktemp := key[sidx]`
			`r = r ^ (s[i])`
			`for shift := uint(0); shift < 8; shift += 2 {`
			`// fmt.Println("i:", i, "r:", r)`
			`dir := (ktemp >> shift) & 0x03`
			`switch dir {`
			`case 0:`
			`i = i + 1`
			`i = i % len(s)`
			`case 1:`
			`i = i + w`
			`i = i % len(s)`
			`case 2:`
			`if i%w != 0 {`
			`i = i - 1`
			`} else {`
			`i = i + w - 1`
			`}`
			`case 3:`
			`if i >= w {`
			`i = i - w`
			`} else {`
			`i = len(s) + i - w`
			`}`
			`}`
			`r = r ^ (s[i])`
			`}`
			`}`
			`return`
			`}`

			`func (c *Cipher) genSBoxen(n uint) {`
			`c.sboxen = make([][]byte, n)`
			`var idx uint`
			`for ; idx < n; idx++ {`
			`c.sboxen[idx] = make([]byte, c.sw*c.sh)`
			`_, _ = c.prng.Read(c.sboxen[idx])`
			`}`
			`//fmt.Fprintf(os.Stderr, "sboxen[0]:%v\n", c.sboxen[0])`
			`}`

			`// Mutate the session key (intended to be called as encryption`
			`// proceeds), so that the 'walk path' through sboxes also does so.`
			`func (c *Cipher) keyUpdate(perturb byte) {`
			`c.k[c.kidx] = c.k[c.kidx] ^ c.k[(c.kidx+1)%uint(len(c.k))]`
			`c.k[c.kidx] = c.k[c.kidx] ^ byte((c.prng.Int63()>>4)%256)`
			`c.kidx = (c.kidx + uint(perturb)) % uint(len(c.k))`
			`}`

			`// slow - perturb a single octet of a single sbox for each octet`
			`// (CV = ~8.725% over 700 MiB of 0-byte pt)`
			`func (c *Cipher) sboxUpdateA(perturb byte) {`
			`c.sboxen[perturb%sboxCount][int(perturb)%(c.sw+c.sh)] ^=`
			`perturb`
			`}`

			`// slower - perturb a single sbox for each octet`
			`// (CV = ~?% over 700 MiB of 0-byte pt)`
			`func (c *Cipher) sboxUpdateB(perturb byte) {`
			`lim := c.sw * c.sh`
			`for idx := 0; idx < lim; idx++ {`
			`c.sboxen[perturb%sboxCount][idx] ^= perturb`
			`}`
			`}`

			`// slowest -- full sbox re-gen after each octet`
			`// (but lowest CV, ~0.05% over 700MiB of 0-byte pt)`
			`func (c *Cipher) sboxUpdateC(perturb byte) {`
			`c.genSBoxen(sboxCount)`
			`//c.sboxen[perturb%sboxCount][int(perturb)%(c.sw+c.sh)] ^=`
			`// perturb`
			`}`

			`type Cipher struct {`
			`prng *mtwist.MT19937_64`
			`r io.Reader`
			`w io.Writer`
			`k []byte`
			`kidx uint`
			`sboxen [][]byte`
			`sw int`
			`sh int`
			`sctr int // TODO: used to count down to re-keying & sbox regen`
			`mode int`
			`n byte`
			`}`

			`func NewCodec(r io.Reader, w io.Writer, mode int, key []byte, width, height int) (c *Cipher) {`
			`c = &Cipher{}`
			`c.prng = mtwist.New()`
			`if len(key) == 0 {`
			`c.k = []byte(fmt.Sprintf("%s", time.Now()))`
			`} else {`
			`c.k = key`
			`}`
			`c.prng.SeedFullState(c.k)`

			`// Discard first 64 bytes of MT output`
			`for idx := 0; idx < 64; idx++ {`
			`_ = c.prng.Int63()`
			`}`
			`c.mode = mode`
			`c.r = r`
			`c.w = w`
			`c.sw = width`
			`c.sh = height`
			`c.sctr = c.sw // sbox ctr: countdown to regen sboxes`
			`c.n = 0`
			`c.genSBoxen(sboxCount)`

			`// fmt.Printf("%+v\n", sboxen)`
			`// c.buf = make([]byte, 4)`
			`return c`
			`}`

			`func (c *Cipher) Read(p []byte) (n int, err error) {`
			`n, err = c.r.Read(p)`
			`if err == nil {`
			`for idx := 0; idx < n; idx++ {`
			`p[idx] = c.yield(p[idx])`
			`}`
			`}`
			`return n, err`
			`}`

			`func (c *Cipher) Write(p []byte) (n int, err error) {`
			`n, err = c.w.Write(p)`
			`return n, err`
			`}`

			`func (c *Cipher) yield(pt byte) (ct byte) {`
			`ct = walkingXOR(c.k, c.sboxen[c.n], c.sw, c.sh, pt)`
			`c.n = (c.n + 1) % byte(len(c.sboxen))`
			`c.keyUpdate(ct ^ pt) // must be equal in either encrypt/decrypt dirs`
			`switch c.mode {`
			`case 0:`
			`// [nothing - varA]`
			`break`
			`case 1:`
			`c.sboxUpdateA(ct ^ pt) // varA`
			`case 2:`
			`c.sboxUpdateB(ct ^ pt) // varB`
			`case 3:`
			`c.sboxUpdateC(ct ^ pt) // varC`
			`default:`
			`// [nothing]`
			`}`
			`// c.sctr = c.sctr - 1`
			`// if c.sctr == 0 {`
			`// c.genSBoxen(sboxCount)`
			`// c.sctr = c.sw`
			`// }`
			`return ct`
			`}`

			`// XORKeyStream XORs each byte in the given slice with a byte from the`
			`// cipher's key stream. Dst and src must overlap entirely or not at all.`
			`//`
			`// If len(dst) < len(src), XORKeyStream should panic. It is acceptable`
			`// to pass a dst bigger than src, and in that case, XORKeyStream will`
			`// only update dst[:len(src)] and will not touch the rest of dst.`
			`//`
			`// Multiple calls to XORKeyStream behave as if the concatenation of`
			`// the src buffers was passed in a single run. That is, Stream`
			`// maintains state and does not reset at each XORKeyStream call.`
			`func (c *Cipher) XORKeyStream(dst, src []byte) {`
			`//fmt.Printf("len dst:%d len src:%d\n", len(dst), len(src))`
			`if len(dst) < len(src) {`
			`panic(errors.New("len(dst) < len(src)"))`
			`}`

			`for idx, v := range src {`
			`dst[idx] = c.yield(v)`
			`}`
			`}`