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ref: 0843b337e2c2f96bde753090304e1a918b03d73f
dir: /lib/crypto/aes.myr/

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/*
 * Translated to Myrddin by Ori Bernstein
 * Copyright (c) 2016 Thomas Pornin <pornin@bolet.org>
 *
 * Permission is hereby granted, free of charge, to any person obtaining 
 * a copy of this software and associated documentation files (the
 * "Software"), to deal in the Software without restriction, including
 * without limitation the rights to use, copy, modify, merge, publish,
 * distribute, sublicense, and/or sell copies of the Software, and to
 * permit persons to whom the Software is furnished to do so, subject to
 * the following conditions:
 *
 * The above copyright notice and this permission notice shall be 
 * included in all copies or substantial portions of the Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, 
 * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
 * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND 
 * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
 * BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
 * ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
 * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
 * SOFTWARE.
 */


use std

pkg crypto =
	type aesctx = struct
		nrounds	: uint32
		skey	: uint64[30]
		accum	: byte[16]
	;;

	const aeskeysched	: (x : aesctx#, k : byte[:] -> void) 
	const aesencrypt	: (x : aesctx#, m : byte[:], c : byte[:] -> void)
	const aesdecrypt	: (x : aesctx#, c : byte[:], m : byte[:] -> void)
;;

const Rcon = [0x01, 0x02, 0x04, 0x08, 0x10, 0x20, 0x40, 0x80, 0x1B, 0x36]

const aeskeysched = {x, key
	var skey : uint32[60]
	var q : uint64[8]
	var nk, nkf
	var tmp, j, k

	match key.len
	| 16:	x.nrounds = 10
	| 24:	x.nrounds = 12
	| 32:	x.nrounds = 14
	| _:	std.die("invalid key size in aes")
	;;

	nk = key.len >> 2
	nkf = (x.nrounds + 1) << 2
	for var i = 0; i < key.len; i += 4
		skey[i>>2] = std.getle32(key[i:i+4])
	;;
	j = 0
	k = 0
	tmp = skey[(key.len >> 2) - 1];
	for var i = nk; i < nkf; i++
		if j == 0
			tmp = (tmp << 24) | (tmp >> 8)
			tmp = subword(tmp) ^ Rcon[k]
		elif nk > 6 && j == 4
			tmp = subword(tmp)
		;;
		tmp ^= skey[i-nk]
		skey[i] = tmp
		j++
		if j == nk
			j = 0
			k++
		;;
	;;

	j = 0
	for var i = 0; i < nkf; i += 4
		interleavein(&q[0], &q[4], skey[i:i+4])
		q[1] = q[0]
		q[2] = q[0]
		q[3] = q[0]
		q[5] = q[4]
		q[6] = q[4]
		q[7] = q[4]
		ortho(q[:])
		x.skey[j + 0] = \
			  (q[0] & 0x1111111111111111ul) \
			| (q[1] & 0x2222222222222222ul) \
			| (q[2] & 0x4444444444444444ul) \
			| (q[3] & 0x8888888888888888ul)
		x.skey[j + 1] = \
			  (q[4] & 0x1111111111111111ul) \
			| (q[5] & 0x2222222222222222ul) \
			| (q[6] & 0x4444444444444444ul) \
			| (q[7] & 0x8888888888888888ul)
		j += 2
	;;
}

const aesencrypt = {x, m, c
	var q : uint64[8]
	var w : uint32[4]
	var expkey : uint64[240]

	std.assert(m.len % 16 == 0, "mismatched block size in aesencrypt")
	std.assert(m.len == c.len, "ciphertext length does not match plaintext length")

	expand(expkey[:], x.nrounds, x.skey[:])
	while m.len != 0
		w[0] = std.getle32(m[0:4])
		w[1] = std.getle32(m[4:8])
		w[2] = std.getle32(m[8:12])
		w[3] = std.getle32(m[12:16])

		interleavein(&q[0], &q[4], w[:])
		ortho(q[:])
		encrypt64(x.nrounds, expkey[:], q[:])
		ortho(q[:])
		interleaveout(w[:], q[0], q[4])

		std.putle32(c[0:4], w[0])
		std.putle32(c[4:8], w[1])
		std.putle32(c[8:12], w[2])
		std.putle32(c[12:16], w[3])

		m = m[16:]
		c = c[16:]
	;;
}

const aesdecrypt = {x, c, m
	var q : uint64[8]
	var w : uint32[4]
	var expkey : uint64[240]

	std.assert(m.len % 16 == 0, "mismatched block size in aesencrypt")
	std.assert(m.len == c.len, "ciphertext length does not match plaintext length")

	expand(expkey[:], x.nrounds, x.skey[:])
	while c.len != 0
		w[0] = std.getle32(c[0:4])
		w[1] = std.getle32(c[4:8])
		w[2] = std.getle32(c[8:12])
		w[3] = std.getle32(c[12:16])

		interleavein(&q[0], &q[4], w[:])
		ortho(q[:])
		decrypt64(x.nrounds, expkey[:], q[:])
		ortho(q[:])
		interleaveout(w[:], q[0], q[4])

		std.putle32(m[0:4], w[0])
		std.putle32(m[4:8], w[1])
		std.putle32(m[8:12], w[2])
		std.putle32(m[12:16], w[3])

		m = m[16:]
		c = c[16:]
	;;
}

const expand = {expkey, nrounds, key
	var x0, x1, x2, x3
	var u, v, n

	n = (nrounds + 1) * 2
	u = 0
	v = 0
	while u < n
		x0 = x1 = x2 = x3 = key[u]
		x0 &= 0x1111111111111111ul
		x1 &= 0x2222222222222222ul
		x2 &= 0x4444444444444444ul
		x3 &= 0x8888888888888888ul
		x1 >>= 1
		x2 >>= 2
		x3 >>= 3
		expkey[v + 0] = (x0 << 4) - x0
		expkey[v + 1] = (x1 << 4) - x1
		expkey[v + 2] = (x2 << 4) - x2
		expkey[v + 3] = (x3 << 4) - x3
		u++
		v += 4
	;;
}

const encrypt64 = {nrounds, skey, q
	var i

	addroundkey(q, skey)
	for i = 1; i < nrounds; i++
		sbox(q)
		shiftrows(q)
		mixcols(q)
		addroundkey(q, skey[i*8:i*8+8])
	;;

	sbox(q)
	shiftrows(q)
	addroundkey(q, skey[8*nrounds:8*nrounds + 8])
}

const decrypt64 = {nrounds, skey, q
	var u

	addroundkey(q, skey[8*nrounds:8*nrounds + 8])
	for u = nrounds - 1; u > 0; u--
		invshiftrows(q)
		invsbox(q)
		addroundkey(q, skey[u*8:u*8+8])
		invmixcols(q)
	;;
	invshiftrows(q)
	invsbox(q)
	addroundkey(q, skey[0:8])
}

const addroundkey = {q, sk
	q[0] ^= sk[0]
	q[1] ^= sk[1]
	q[2] ^= sk[2]
	q[3] ^= sk[3]
	q[4] ^= sk[4]
	q[5] ^= sk[5]
	q[6] ^= sk[6]
	q[7] ^= sk[7]
}

const shiftrows = {q
	var x

	for var i = 0; i < 8; i ++
		x = q[i]
		q[i] = (x & 0x000000000000FFFFul) \
			| ((x & 0x00000000FFF00000ul) >> 4) \
			| ((x & 0x00000000000F0000ul) << 12) \
			| ((x & 0x0000FF0000000000ul) >> 8) \
			| ((x & 0x000000FF00000000ul) << 8) \
			| ((x & 0xF000000000000000ul) >> 12) \
			| ((x & 0x0FFF000000000000ul) << 4)
	;;
}

const invshiftrows = {q
	var x

	for var i = 0; i < 8; i ++
		x = q[i];
		q[i] = (x & 0x000000000000FFFFul) \
			| ((x & 0x000000000FFF0000ul) << 4) \
			| ((x & 0x00000000F0000000ul) >> 12) \
			| ((x & 0x000000FF00000000ul) << 8) \
			| ((x & 0x0000FF0000000000ul) >> 8) \
			| ((x & 0x000F000000000000ul) << 12) \
			| ((x & 0xFFF0000000000000ul) >> 4)
	;;
}

const mixcols = {q
	var q0, q1, q2, q3, q4, q5, q6, q7
	var r0, r1, r2, r3, r4, r5, r6, r7

	q0 = q[0]
	q1 = q[1]
	q2 = q[2]
	q3 = q[3]
	q4 = q[4]
	q5 = q[5]
	q6 = q[6]
	q7 = q[7]
	r0 = (q0 >> 16) | (q0 << 48)
	r1 = (q1 >> 16) | (q1 << 48)
	r2 = (q2 >> 16) | (q2 << 48)
	r3 = (q3 >> 16) | (q3 << 48)
	r4 = (q4 >> 16) | (q4 << 48)
	r5 = (q5 >> 16) | (q5 << 48)
	r6 = (q6 >> 16) | (q6 << 48)
	r7 = (q7 >> 16) | (q7 << 48)

	q[0] = q7 ^ r7 ^ r0 ^ rotr32(q0 ^ r0)
	q[1] = q0 ^ r0 ^ q7 ^ r7 ^ r1 ^ rotr32(q1 ^ r1)
	q[2] = q1 ^ r1 ^ r2 ^ rotr32(q2 ^ r2)
	q[3] = q2 ^ r2 ^ q7 ^ r7 ^ r3 ^ rotr32(q3 ^ r3)
	q[4] = q3 ^ r3 ^ q7 ^ r7 ^ r4 ^ rotr32(q4 ^ r4)
	q[5] = q4 ^ r4 ^ r5 ^ rotr32(q5 ^ r5)
	q[6] = q5 ^ r5 ^ r6 ^ rotr32(q6 ^ r6)
	q[7] = q6 ^ r6 ^ r7 ^ rotr32(q7 ^ r7)
}

const invmixcols = {q
	var q0, q1, q2, q3, q4, q5, q6, q7
	var r0, r1, r2, r3, r4, r5, r6, r7

	q0 = q[0]
	q1 = q[1]
	q2 = q[2]
	q3 = q[3]
	q4 = q[4]
	q5 = q[5]
	q6 = q[6]
	q7 = q[7]
	r0 = (q0 >> 16) | (q0 << 48)
	r1 = (q1 >> 16) | (q1 << 48)
	r2 = (q2 >> 16) | (q2 << 48)
	r3 = (q3 >> 16) | (q3 << 48)
	r4 = (q4 >> 16) | (q4 << 48)
	r5 = (q5 >> 16) | (q5 << 48)
	r6 = (q6 >> 16) | (q6 << 48)
	r7 = (q7 >> 16) | (q7 << 48)

	q[0] = q5 ^ q6 ^ q7 ^ r0 ^ r5 ^ r7 ^ rotr32(q0 ^ q5 ^ q6 ^ r0 ^ r5)
	q[1] = q0 ^ q5 ^ r0 ^ r1 ^ r5 ^ r6 ^ r7 ^ rotr32(q1 ^ q5 ^ q7 ^ r1 ^ r5 ^ r6)
	q[2] = q0 ^ q1 ^ q6 ^ r1 ^ r2 ^ r6 ^ r7 ^ rotr32(q0 ^ q2 ^ q6 ^ r2 ^ r6 ^ r7)
	q[3] = q0 ^ q1 ^ q2 ^ q5 ^ q6 ^ r0 ^ r2 ^ r3 ^ r5 ^ rotr32(q0 ^ q1 ^ q3 ^ q5 ^ q6 ^ q7 ^ r0 ^ r3 ^ r5 ^ r7)
	q[4] = q1 ^ q2 ^ q3 ^ q5 ^ r1 ^ r3 ^ r4 ^ r5 ^ r6 ^ r7 ^ rotr32(q1 ^ q2 ^ q4 ^ q5 ^ q7 ^ r1 ^ r4 ^ r5 ^ r6)
	q[5] = q2 ^ q3 ^ q4 ^ q6 ^ r2 ^ r4 ^ r5 ^ r6 ^ r7 ^ rotr32(q2 ^ q3 ^ q5 ^ q6 ^ r2 ^ r5 ^ r6 ^ r7)
	q[6] = q3 ^ q4 ^ q5 ^ q7 ^ r3 ^ r5 ^ r6 ^ r7 ^ rotr32(q3 ^ q4 ^ q6 ^ q7 ^ r3 ^ r6 ^ r7)
	q[7] = q4 ^ q5 ^ q6 ^ r4 ^ r6 ^ r7 ^ rotr32(q4 ^ q5 ^ q7 ^ r4 ^ r7)
}

/*
 * Interleave bytes for an AES input block. If input bytes are
 * denoted 0123456789ABCDEF, and have been decoded with little-endian
 * convention (w[0] contains 0123, with '3' being most significant
 * w[1] contains 4567, and so on), then output word q0 will be
 * set to 08192A3B (again little-endian convention) and q1 will
 * be set to 4C5D6E7F.
 */
const interleavein = {q0, q1, w
	var x0, x1, x2, x3

	x0 = (w[0] : uint64)
	x1 = (w[1] : uint64)
	x2 = (w[2] : uint64)
	x3 = (w[3] : uint64)
	x0 |= (x0 << 16)
	x1 |= (x1 << 16)
	x2 |= (x2 << 16)
	x3 |= (x3 << 16)
	x0 &= 0x0000FFFF0000FFFFul
	x1 &= 0x0000FFFF0000FFFFul
	x2 &= 0x0000FFFF0000FFFFul
	x3 &= 0x0000FFFF0000FFFFul
	x0 |= (x0 << 8)
	x1 |= (x1 << 8)
	x2 |= (x2 << 8)
	x3 |= (x3 << 8)
	x0 &= 0x00FF00FF00FF00FFul
	x1 &= 0x00FF00FF00FF00FFul
	x2 &= 0x00FF00FF00FF00FFul
	x3 &= 0x00FF00FF00FF00FFul
	q0# = x0 | (x2 << 8)
	q1# = x1 | (x3 << 8)
}

/* invert interleavein */
const interleaveout = {w, q0, q1
	var x0, x1, x2, x3

	x0 = q0 & 0x00FF00FF00FF00FFul
	x1 = q1 & 0x00FF00FF00FF00FFul
	x2 = (q0 >> 8) & 0x00FF00FF00FF00FFul
	x3 = (q1 >> 8) & 0x00FF00FF00FF00FFul
	x0 |= (x0 >> 8)
	x1 |= (x1 >> 8)
	x2 |= (x2 >> 8)
	x3 |= (x3 >> 8)
	x0 &= 0x0000FFFF0000FFFFul
	x1 &= 0x0000FFFF0000FFFFul
	x2 &= 0x0000FFFF0000FFFFul
	x3 &= 0x0000FFFF0000FFFFul
	w[0] = (x0 : uint32) | (x0 >> 16 : uint32)
	w[1] = (x1 : uint32) | (x1 >> 16 : uint32)
	w[2] = (x2 : uint32) | (x2 >> 16 : uint32)
	w[3] = (x3 : uint32) | (x3 >> 16 : uint32)
}

/*
 * Perform bytewise orthogonalization of eight 64-bit words. Bytes
 * of q0..q7 are spread over all words: for a byte x that occurs
 * at rank i in q[j] (byte x uses bits 8*i to 8*i+7 in q[j]), the bit
 * of rank k in x (0 <= k <= 7) goes to q[k] at rank 8*i+j.
 *
 * This operation is an involution.
 */
const ortho = {q
	swap(Kl2, Kh2, 1, &q[0], &q[1])
	swap(Kl2, Kh2, 1, &q[2], &q[3])
	swap(Kl2, Kh2, 1, &q[4], &q[5])
	swap(Kl2, Kh2, 1, &q[6], &q[7])

	swap(Kl4, Kh4, 2, &q[0], &q[2])
	swap(Kl4, Kh4, 2, &q[1], &q[3])
	swap(Kl4, Kh4, 2, &q[4], &q[6])
	swap(Kl4, Kh4, 2, &q[5], &q[7])

	swap(Kl8, Kh8, 4, &q[0], &q[4])
	swap(Kl8, Kh8, 4, &q[1], &q[5])
	swap(Kl8, Kh8, 4, &q[2], &q[6])
	swap(Kl8, Kh8, 4, &q[3], &q[7])
}

const subword = {x
	var q : uint64[8]

	std.slfill(q[:], 0)
	q[0] = (x : uint64)
	ortho(q[:])
	sbox(q[:])
	ortho(q[:])
	-> (q[0] : uint32)
}

const Kl2 = 0x5555555555555555
const Kh2 = 0xAAAAAAAAAAAAAAAA
const Kl4 = 0x3333333333333333
const Kh4 = 0xCCCCCCCCCCCCCCCC
const Kl8 = 0x0F0F0F0F0F0F0F0F
const Kh8 = 0xF0F0F0F0F0F0F0F0
const swap = {kl, kh, s, x, y
	var a, b

	a = x#
	b = y#
	x# = (a & kl) | ((b & kl) << s); \
	y# = ((a & kh) >> s) | (b & kh); \
}

const sbox = {q : uint64[:]
	/*
	* Translated from BearSSL
	*
	* This S-box implementation is a straightforward translation of
	* the circuit described by Boyar and Peralta in "A new
	* combinational logic minimization technique with applications
	* to cryptology" (https://eprint.iacr.org/2009/191.pdf).
	*
	* Note that variables x* (input) and s* (output) are numbered
	* in "reverse" order (x0 is the high bit, x7 is the low bit).
	*/

	var x0, x1, x2, x3, x4, x5, x6, x7
	var y1, y2, y3, y4, y5, y6, y7, y8, y9
	var y10, y11, y12, y13, y14, y15, y16, y17, y18, y19
	var y20, y21
	var z0, z1, z2, z3, z4, z5, z6, z7, z8, z9
	var z10, z11, z12, z13, z14, z15, z16, z17
	var t0, t1, t2, t3, t4, t5, t6, t7, t8, t9
	var t10, t11, t12, t13, t14, t15, t16, t17, t18, t19
	var t20, t21, t22, t23, t24, t25, t26, t27, t28, t29
	var t30, t31, t32, t33, t34, t35, t36, t37, t38, t39
	var t40, t41, t42, t43, t44, t45, t46, t47, t48, t49
	var t50, t51, t52, t53, t54, t55, t56, t57, t58, t59
	var t60, t61, t62, t63, t64, t65, t66, t67
	var s0, s1, s2, s3, s4, s5, s6, s7

	x0 = q[7]
	x1 = q[6]
	x2 = q[5]
	x3 = q[4]
	x4 = q[3]
	x5 = q[2]
	x6 = q[1]
	x7 = q[0]

	/*
	* Top linear transformation.
	*/
	y14 = x3 ^ x5
	y13 = x0 ^ x6
	y9 = x0 ^ x3
	y8 = x0 ^ x5
	t0 = x1 ^ x2
	y1 = t0 ^ x7
	y4 = y1 ^ x3
	y12 = y13 ^ y14
	y2 = y1 ^ x0
	y5 = y1 ^ x6
	y3 = y5 ^ y8
	t1 = x4 ^ y12
	y15 = t1 ^ x5
	y20 = t1 ^ x1
	y6 = y15 ^ x7
	y10 = y15 ^ t0
	y11 = y20 ^ y9
	y7 = x7 ^ y11
	y17 = y10 ^ y11
	y19 = y10 ^ y8
	y16 = t0 ^ y11
	y21 = y13 ^ y16
	y18 = x0 ^ y16

	/*
	* Non-linear section.
	*/
	t2 = y12 & y15
	t3 = y3 & y6
	t4 = t3 ^ t2
	t5 = y4 & x7
	t6 = t5 ^ t2
	t7 = y13 & y16
	t8 = y5 & y1
	t9 = t8 ^ t7
	t10 = y2 & y7
	t11 = t10 ^ t7
	t12 = y9 & y11
	t13 = y14 & y17
	t14 = t13 ^ t12
	t15 = y8 & y10
	t16 = t15 ^ t12
	t17 = t4 ^ t14
	t18 = t6 ^ t16
	t19 = t9 ^ t14
	t20 = t11 ^ t16
	t21 = t17 ^ y20
	t22 = t18 ^ y19
	t23 = t19 ^ y21
	t24 = t20 ^ y18

	t25 = t21 ^ t22
	t26 = t21 & t23
	t27 = t24 ^ t26
	t28 = t25 & t27
	t29 = t28 ^ t22
	t30 = t23 ^ t24
	t31 = t22 ^ t26
	t32 = t31 & t30
	t33 = t32 ^ t24
	t34 = t23 ^ t33
	t35 = t27 ^ t33
	t36 = t24 & t35
	t37 = t36 ^ t34
	t38 = t27 ^ t36
	t39 = t29 & t38
	t40 = t25 ^ t39

	t41 = t40 ^ t37
	t42 = t29 ^ t33
	t43 = t29 ^ t40
	t44 = t33 ^ t37
	t45 = t42 ^ t41
	z0 = t44 & y15
	z1 = t37 & y6
	z2 = t33 & x7
	z3 = t43 & y16
	z4 = t40 & y1
	z5 = t29 & y7
	z6 = t42 & y11
	z7 = t45 & y17
	z8 = t41 & y10
	z9 = t44 & y12
	z10 = t37 & y3
	z11 = t33 & y4
	z12 = t43 & y13
	z13 = t40 & y5
	z14 = t29 & y2
	z15 = t42 & y9
	z16 = t45 & y14
	z17 = t41 & y8

	/*
	* Bottom linear transformation.
	*/
	t46 = z15 ^ z16
	t47 = z10 ^ z11
	t48 = z5 ^ z13
	t49 = z9 ^ z10
	t50 = z2 ^ z12
	t51 = z2 ^ z5
	t52 = z7 ^ z8
	t53 = z0 ^ z3
	t54 = z6 ^ z7
	t55 = z16 ^ z17
	t56 = z12 ^ t48
	t57 = t50 ^ t53
	t58 = z4 ^ t46
	t59 = z3 ^ t54
	t60 = t46 ^ t57
	t61 = z14 ^ t57
	t62 = t52 ^ t58
	t63 = t49 ^ t58
	t64 = z4 ^ t59
	t65 = t61 ^ t62
	t66 = z1 ^ t63
	s0 = t59 ^ t63
	s6 = t56 ^ ~t62
	s7 = t48 ^ ~t60
	t67 = t64 ^ t65
	s3 = t53 ^ t66
	s4 = t51 ^ t66
	s5 = t47 ^ t65
	s1 = t64 ^ ~s3
	s2 = t55 ^ ~t67

	q[7] = s0
	q[6] = s1
	q[5] = s2
	q[4] = s3
	q[3] = s4
	q[2] = s5
	q[1] = s6
	q[0] = s7
}

const invsbox = {q
	var q0, q1, q2, q3, q4, q5, q6, q7

	q0 = ~q[0]
	q1 = ~q[1]
	q2 = q[2]
	q3 = q[3]
	q4 = q[4]
	q5 = ~q[5]
	q6 = ~q[6]
	q7 = q[7]
	q[7] = q1 ^ q4 ^ q6
	q[6] = q0 ^ q3 ^ q5
	q[5] = q7 ^ q2 ^ q4
	q[4] = q6 ^ q1 ^ q3
	q[3] = q5 ^ q0 ^ q2
	q[2] = q4 ^ q7 ^ q1
	q[1] = q3 ^ q6 ^ q0
	q[0] = q2 ^ q5 ^ q7

	sbox(q)

	q0 = ~q[0]
	q1 = ~q[1]
	q2 = q[2]
	q3 = q[3]
	q4 = q[4]
	q5 = ~q[5]
	q6 = ~q[6]
	q7 = q[7]
	q[7] = q1 ^ q4 ^ q6
	q[6] = q0 ^ q3 ^ q5
	q[5] = q7 ^ q2 ^ q4
	q[4] = q6 ^ q1 ^ q3
	q[3] = q5 ^ q0 ^ q2
	q[2] = q4 ^ q7 ^ q1
	q[1] = q3 ^ q6 ^ q0
	q[0] = q2 ^ q5 ^ q7
}


const rotr32 = {x
	-> (x << 32) | (x >> 32)
}