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authorDaniel Mueller <deso@posteo.net>2019-01-02 21:14:10 -0800
committerDaniel Mueller <deso@posteo.net>2019-01-02 21:14:10 -0800
commitecf3474223ca3d16a10f12dc2272e3b0ed72c1bb (patch)
tree03134a683791176b49ef5c92e8d6acd24c3b5a9b /rand/rand_isaac/src/isaac64.rs
parent686f61b75055ecb02baf9d9449525ae447a3bed1 (diff)
downloadnitrocli-ecf3474223ca3d16a10f12dc2272e3b0ed72c1bb.tar.gz
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Update nitrokey crate to 0.2.3
This change updates the nitrokey crate to version 0.2.3. This version bumps the rand crate used to 0.6.1, which in turn requires an additional set of dependencies. Import subrepo nitrokey/:nitrokey at b3e2adc5bb1300441ca74cc7672617c042f3ea31 Import subrepo rand/:rand at 73613ff903512e9503e41cc8ba9eae76269dc598 Import subrepo rustc_version/:rustc_version at 0294f2ba2018bf7be672abd53db351ce5055fa02 Import subrepo semver-parser/:semver-parser at 750da9b11a04125231b1fb293866ca036845acee Import subrepo semver/:semver at 5eb6db94fa03f4d5c64a625a56188f496be47598
Diffstat (limited to 'rand/rand_isaac/src/isaac64.rs')
-rw-r--r--rand/rand_isaac/src/isaac64.rs481
1 files changed, 481 insertions, 0 deletions
diff --git a/rand/rand_isaac/src/isaac64.rs b/rand/rand_isaac/src/isaac64.rs
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+// Copyright 2018 Developers of the Rand project.
+// Copyright 2013-2018 The Rust Project Developers.
+//
+// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
+// https://www.apache.org/licenses/LICENSE-2.0> or the MIT license
+// <LICENSE-MIT or https://opensource.org/licenses/MIT>, at your
+// option. This file may not be copied, modified, or distributed
+// except according to those terms.
+
+//! The ISAAC-64 random number generator.
+
+use core::{fmt, slice};
+use core::num::Wrapping as w;
+use rand_core::{RngCore, SeedableRng, Error, le};
+use rand_core::block::{BlockRngCore, BlockRng64};
+use isaac_array::IsaacArray;
+
+#[allow(non_camel_case_types)]
+type w64 = w<u64>;
+
+const RAND_SIZE_LEN: usize = 8;
+const RAND_SIZE: usize = 1 << RAND_SIZE_LEN;
+
+/// A random number generator that uses ISAAC-64, the 64-bit variant of the
+/// ISAAC algorithm.
+///
+/// ISAAC stands for "Indirection, Shift, Accumulate, Add, and Count" which are
+/// the principal bitwise operations employed. It is the most advanced of a
+/// series of array based random number generator designed by Robert Jenkins
+/// in 1996[^1].
+///
+/// ISAAC-64 is mostly similar to ISAAC. Because it operates on 64-bit integers
+/// instead of 32-bit, it uses twice as much memory to hold its state and
+/// results. Also it uses different constants for shifts and indirect indexing,
+/// optimized to give good results for 64bit arithmetic.
+///
+/// ISAAC-64 is notably fast and produces excellent quality random numbers for
+/// non-cryptographic applications.
+///
+/// In spite of being designed with cryptographic security in mind, ISAAC hasn't
+/// been stringently cryptanalyzed and thus cryptographers do not not
+/// consensually trust it to be secure. When looking for a secure RNG, prefer
+/// [`Hc128Rng`] instead, which, like ISAAC, is an array-based RNG and one of
+/// the stream-ciphers selected the by eSTREAM contest.
+///
+/// ## Overview of the ISAAC-64 algorithm:
+/// (in pseudo-code)
+///
+/// ```text
+/// Input: a, b, c, s[256] // state
+/// Output: r[256] // results
+///
+/// mix(a,i) = !(a ^ a << 21) if i = 0 mod 4
+/// a ^ a >> 5 if i = 1 mod 4
+/// a ^ a << 12 if i = 2 mod 4
+/// a ^ a >> 33 if i = 3 mod 4
+///
+/// c = c + 1
+/// b = b + c
+///
+/// for i in 0..256 {
+/// x = s_[i]
+/// a = mix(a,i) + s[i+128 mod 256]
+/// y = a + b + s[x>>3 mod 256]
+/// s[i] = y
+/// b = x + s[y>>11 mod 256]
+/// r[i] = b
+/// }
+/// ```
+///
+/// This implementation uses [`BlockRng64`] to implement the [`RngCore`] methods.
+///
+/// See for more information the documentation of [`IsaacRng`].
+///
+/// [^1]: Bob Jenkins, [*ISAAC and RC4*](
+/// http://burtleburtle.net/bob/rand/isaac.html)
+///
+/// [`IsaacRng`]: ../isaac/struct.IsaacRng.html
+/// [`Hc128Rng`]: ../../rand_hc/struct.Hc128Rng.html
+/// [`BlockRng64`]: ../../rand_core/block/struct.BlockRng64.html
+/// [`RngCore`]: ../../rand_core/trait.RngCore.html
+#[derive(Clone, Debug)]
+#[cfg_attr(feature="serde1", derive(Serialize, Deserialize))]
+pub struct Isaac64Rng(BlockRng64<Isaac64Core>);
+
+impl RngCore for Isaac64Rng {
+ #[inline(always)]
+ fn next_u32(&mut self) -> u32 {
+ self.0.next_u32()
+ }
+
+ #[inline(always)]
+ fn next_u64(&mut self) -> u64 {
+ self.0.next_u64()
+ }
+
+ fn fill_bytes(&mut self, dest: &mut [u8]) {
+ self.0.fill_bytes(dest)
+ }
+
+ fn try_fill_bytes(&mut self, dest: &mut [u8]) -> Result<(), Error> {
+ self.0.try_fill_bytes(dest)
+ }
+}
+
+impl SeedableRng for Isaac64Rng {
+ type Seed = <Isaac64Core as SeedableRng>::Seed;
+
+ fn from_seed(seed: Self::Seed) -> Self {
+ Isaac64Rng(BlockRng64::<Isaac64Core>::from_seed(seed))
+ }
+
+ /// Create an ISAAC random number generator using an `u64` as seed.
+ /// If `seed == 0` this will produce the same stream of random numbers as
+ /// the reference implementation when used unseeded.
+ fn seed_from_u64(seed: u64) -> Self {
+ Isaac64Rng(BlockRng64::<Isaac64Core>::seed_from_u64(seed))
+ }
+
+ fn from_rng<S: RngCore>(rng: S) -> Result<Self, Error> {
+ BlockRng64::<Isaac64Core>::from_rng(rng).map(|rng| Isaac64Rng(rng))
+ }
+}
+
+impl Isaac64Rng {
+ /// Create an ISAAC-64 random number generator using an `u64` as seed.
+ /// If `seed == 0` this will produce the same stream of random numbers as
+ /// the reference implementation when used unseeded.
+ #[deprecated(since="0.6.0", note="use SeedableRng::seed_from_u64 instead")]
+ pub fn new_from_u64(seed: u64) -> Self {
+ Self::seed_from_u64(seed)
+ }
+}
+
+/// The core of `Isaac64Rng`, used with `BlockRng`.
+#[derive(Clone)]
+#[cfg_attr(feature="serde1", derive(Serialize, Deserialize))]
+pub struct Isaac64Core {
+ #[cfg_attr(feature="serde1",serde(with="super::isaac_array::isaac_array_serde"))]
+ mem: [w64; RAND_SIZE],
+ a: w64,
+ b: w64,
+ c: w64,
+}
+
+// Custom Debug implementation that does not expose the internal state
+impl fmt::Debug for Isaac64Core {
+ fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
+ write!(f, "Isaac64Core {{}}")
+ }
+}
+
+impl BlockRngCore for Isaac64Core {
+ type Item = u64;
+ type Results = IsaacArray<Self::Item>;
+
+ /// Refills the output buffer, `results`. See also the pseudocode desciption
+ /// of the algorithm in the [`Isaac64Rng`] documentation.
+ ///
+ /// Optimisations used (similar to the reference implementation):
+ ///
+ /// - The loop is unrolled 4 times, once for every constant of mix().
+ /// - The contents of the main loop are moved to a function `rngstep`, to
+ /// reduce code duplication.
+ /// - We use local variables for a and b, which helps with optimisations.
+ /// - We split the main loop in two, one that operates over 0..128 and one
+ /// over 128..256. This way we can optimise out the addition and modulus
+ /// from `s[i+128 mod 256]`.
+ /// - We maintain one index `i` and add `m` or `m2` as base (m2 for the
+ /// `s[i+128 mod 256]`), relying on the optimizer to turn it into pointer
+ /// arithmetic.
+ /// - We fill `results` backwards. The reference implementation reads values
+ /// from `results` in reverse. We read them in the normal direction, to
+ /// make `fill_bytes` a memcopy. To maintain compatibility we fill in
+ /// reverse.
+ ///
+ /// [`Isaac64Rng`]: struct.Isaac64Rng.html
+ fn generate(&mut self, results: &mut IsaacArray<Self::Item>) {
+ self.c += w(1);
+ // abbreviations
+ let mut a = self.a;
+ let mut b = self.b + self.c;
+ const MIDPOINT: usize = RAND_SIZE / 2;
+
+ #[inline]
+ fn ind(mem:&[w64; RAND_SIZE], v: w64, amount: usize) -> w64 {
+ let index = (v >> amount).0 as usize % RAND_SIZE;
+ mem[index]
+ }
+
+ #[inline]
+ fn rngstep(mem: &mut [w64; RAND_SIZE],
+ results: &mut [u64; RAND_SIZE],
+ mix: w64,
+ a: &mut w64,
+ b: &mut w64,
+ base: usize,
+ m: usize,
+ m2: usize) {
+ let x = mem[base + m];
+ *a = mix + mem[base + m2];
+ let y = *a + *b + ind(&mem, x, 3);
+ mem[base + m] = y;
+ *b = x + ind(&mem, y, 3 + RAND_SIZE_LEN);
+ results[RAND_SIZE - 1 - base - m] = (*b).0;
+ }
+
+ let mut m = 0;
+ let mut m2 = MIDPOINT;
+ for i in (0..MIDPOINT/4).map(|i| i * 4) {
+ rngstep(&mut self.mem, results, !(a ^ (a << 21)), &mut a, &mut b, i + 0, m, m2);
+ rngstep(&mut self.mem, results, a ^ (a >> 5 ), &mut a, &mut b, i + 1, m, m2);
+ rngstep(&mut self.mem, results, a ^ (a << 12), &mut a, &mut b, i + 2, m, m2);
+ rngstep(&mut self.mem, results, a ^ (a >> 33), &mut a, &mut b, i + 3, m, m2);
+ }
+
+ m = MIDPOINT;
+ m2 = 0;
+ for i in (0..MIDPOINT/4).map(|i| i * 4) {
+ rngstep(&mut self.mem, results, !(a ^ (a << 21)), &mut a, &mut b, i + 0, m, m2);
+ rngstep(&mut self.mem, results, a ^ (a >> 5 ), &mut a, &mut b, i + 1, m, m2);
+ rngstep(&mut self.mem, results, a ^ (a << 12), &mut a, &mut b, i + 2, m, m2);
+ rngstep(&mut self.mem, results, a ^ (a >> 33), &mut a, &mut b, i + 3, m, m2);
+ }
+
+ self.a = a;
+ self.b = b;
+ }
+}
+
+impl Isaac64Core {
+ /// Create a new ISAAC-64 random number generator.
+ fn init(mut mem: [w64; RAND_SIZE], rounds: u32) -> Self {
+ fn mix(a: &mut w64, b: &mut w64, c: &mut w64, d: &mut w64,
+ e: &mut w64, f: &mut w64, g: &mut w64, h: &mut w64) {
+ *a -= *e; *f ^= *h >> 9; *h += *a;
+ *b -= *f; *g ^= *a << 9; *a += *b;
+ *c -= *g; *h ^= *b >> 23; *b += *c;
+ *d -= *h; *a ^= *c << 15; *c += *d;
+ *e -= *a; *b ^= *d >> 14; *d += *e;
+ *f -= *b; *c ^= *e << 20; *e += *f;
+ *g -= *c; *d ^= *f >> 17; *f += *g;
+ *h -= *d; *e ^= *g << 14; *g += *h;
+ }
+
+ // These numbers are the result of initializing a...h with the
+ // fractional part of the golden ratio in binary (0x9e3779b97f4a7c13)
+ // and applying mix() 4 times.
+ let mut a = w(0x647c4677a2884b7c);
+ let mut b = w(0xb9f8b322c73ac862);
+ let mut c = w(0x8c0ea5053d4712a0);
+ let mut d = w(0xb29b2e824a595524);
+ let mut e = w(0x82f053db8355e0ce);
+ let mut f = w(0x48fe4a0fa5a09315);
+ let mut g = w(0xae985bf2cbfc89ed);
+ let mut h = w(0x98f5704f6c44c0ab);
+
+ // Normally this should do two passes, to make all of the seed effect
+ // all of `mem`
+ for _ in 0..rounds {
+ for i in (0..RAND_SIZE/8).map(|i| i * 8) {
+ a += mem[i ]; b += mem[i+1];
+ c += mem[i+2]; d += mem[i+3];
+ e += mem[i+4]; f += mem[i+5];
+ g += mem[i+6]; h += mem[i+7];
+ mix(&mut a, &mut b, &mut c, &mut d,
+ &mut e, &mut f, &mut g, &mut h);
+ mem[i ] = a; mem[i+1] = b;
+ mem[i+2] = c; mem[i+3] = d;
+ mem[i+4] = e; mem[i+5] = f;
+ mem[i+6] = g; mem[i+7] = h;
+ }
+ }
+
+ Self { mem, a: w(0), b: w(0), c: w(0) }
+ }
+
+ /// Create an ISAAC-64 random number generator using an `u64` as seed.
+ /// If `seed == 0` this will produce the same stream of random numbers as
+ /// the reference implementation when used unseeded.
+ #[deprecated(since="0.6.0", note="use SeedableRng::seed_from_u64 instead")]
+ pub fn new_from_u64(seed: u64) -> Self {
+ Self::seed_from_u64(seed)
+ }
+}
+
+impl SeedableRng for Isaac64Core {
+ type Seed = [u8; 32];
+
+ fn from_seed(seed: Self::Seed) -> Self {
+ let mut seed_u64 = [0u64; 4];
+ le::read_u64_into(&seed, &mut seed_u64);
+ // Convert the seed to `Wrapping<u64>` and zero-extend to `RAND_SIZE`.
+ let mut seed_extended = [w(0); RAND_SIZE];
+ for (x, y) in seed_extended.iter_mut().zip(seed_u64.iter()) {
+ *x = w(*y);
+ }
+ Self::init(seed_extended, 2)
+ }
+
+ fn seed_from_u64(seed: u64) -> Self {
+ let mut key = [w(0); RAND_SIZE];
+ key[0] = w(seed);
+ // Initialize with only one pass.
+ // A second pass does not improve the quality here, because all of the
+ // seed was already available in the first round.
+ // Not doing the second pass has the small advantage that if
+ // `seed == 0` this method produces exactly the same state as the
+ // reference implementation when used unseeded.
+ Self::init(key, 1)
+ }
+
+ fn from_rng<R: RngCore>(mut rng: R) -> Result<Self, Error> {
+ // Custom `from_rng` implementation that fills a seed with the same size
+ // as the entire state.
+ let mut seed = [w(0u64); RAND_SIZE];
+ unsafe {
+ let ptr = seed.as_mut_ptr() as *mut u8;
+ let slice = slice::from_raw_parts_mut(ptr, RAND_SIZE * 8);
+ rng.try_fill_bytes(slice)?;
+ }
+ for i in seed.iter_mut() {
+ *i = w(i.0.to_le());
+ }
+
+ Ok(Self::init(seed, 2))
+ }
+}
+
+#[cfg(test)]
+mod test {
+ use rand_core::{RngCore, SeedableRng};
+ use super::Isaac64Rng;
+
+ #[test]
+ fn test_isaac64_construction() {
+ // Test that various construction techniques produce a working RNG.
+ let seed = [1,0,0,0, 23,0,0,0, 200,1,0,0, 210,30,0,0,
+ 0,0,0,0, 0,0,0,0, 0,0,0,0, 0,0,0,0];
+ let mut rng1 = Isaac64Rng::from_seed(seed);
+ assert_eq!(rng1.next_u64(), 14964555543728284049);
+
+ let mut rng2 = Isaac64Rng::from_rng(rng1).unwrap();
+ assert_eq!(rng2.next_u64(), 919595328260451758);
+ }
+
+ #[test]
+ fn test_isaac64_true_values_64() {
+ let seed = [1,0,0,0, 0,0,0,0, 23,0,0,0, 0,0,0,0,
+ 200,1,0,0, 0,0,0,0, 210,30,0,0, 0,0,0,0];
+ let mut rng1 = Isaac64Rng::from_seed(seed);
+ let mut results = [0u64; 10];
+ for i in results.iter_mut() { *i = rng1.next_u64(); }
+ let expected = [
+ 15071495833797886820, 7720185633435529318,
+ 10836773366498097981, 5414053799617603544,
+ 12890513357046278984, 17001051845652595546,
+ 9240803642279356310, 12558996012687158051,
+ 14673053937227185542, 1677046725350116783];
+ assert_eq!(results, expected);
+
+ let seed = [57,48,0,0, 0,0,0,0, 50,9,1,0, 0,0,0,0,
+ 49,212,0,0, 0,0,0,0, 148,38,0,0, 0,0,0,0];
+ let mut rng2 = Isaac64Rng::from_seed(seed);
+ // skip forward to the 10000th number
+ for _ in 0..10000 { rng2.next_u64(); }
+
+ for i in results.iter_mut() { *i = rng2.next_u64(); }
+ let expected = [
+ 18143823860592706164, 8491801882678285927, 2699425367717515619,
+ 17196852593171130876, 2606123525235546165, 15790932315217671084,
+ 596345674630742204, 9947027391921273664, 11788097613744130851,
+ 10391409374914919106];
+ assert_eq!(results, expected);
+ }
+
+ #[test]
+ fn test_isaac64_true_values_32() {
+ let seed = [1,0,0,0, 0,0,0,0, 23,0,0,0, 0,0,0,0,
+ 200,1,0,0, 0,0,0,0, 210,30,0,0, 0,0,0,0];
+ let mut rng = Isaac64Rng::from_seed(seed);
+ let mut results = [0u32; 12];
+ for i in results.iter_mut() { *i = rng.next_u32(); }
+ // Subset of above values, as an LE u32 sequence
+ let expected = [
+ 3477963620, 3509106075,
+ 687845478, 1797495790,
+ 227048253, 2523132918,
+ 4044335064, 1260557630,
+ 4079741768, 3001306521,
+ 69157722, 3958365844];
+ assert_eq!(results, expected);
+ }
+
+ #[test]
+ fn test_isaac64_true_values_mixed() {
+ let seed = [1,0,0,0, 0,0,0,0, 23,0,0,0, 0,0,0,0,
+ 200,1,0,0, 0,0,0,0, 210,30,0,0, 0,0,0,0];
+ let mut rng = Isaac64Rng::from_seed(seed);
+ // Test alternating between `next_u64` and `next_u32` works as expected.
+ // Values are the same as `test_isaac64_true_values` and
+ // `test_isaac64_true_values_32`.
+ assert_eq!(rng.next_u64(), 15071495833797886820);
+ assert_eq!(rng.next_u32(), 687845478);
+ assert_eq!(rng.next_u32(), 1797495790);
+ assert_eq!(rng.next_u64(), 10836773366498097981);
+ assert_eq!(rng.next_u32(), 4044335064);
+ // Skip one u32
+ assert_eq!(rng.next_u64(), 12890513357046278984);
+ assert_eq!(rng.next_u32(), 69157722);
+ }
+
+ #[test]
+ fn test_isaac64_true_bytes() {
+ let seed = [1,0,0,0, 0,0,0,0, 23,0,0,0, 0,0,0,0,
+ 200,1,0,0, 0,0,0,0, 210,30,0,0, 0,0,0,0];
+ let mut rng = Isaac64Rng::from_seed(seed);
+ let mut results = [0u8; 32];
+ rng.fill_bytes(&mut results);
+ // Same as first values in test_isaac64_true_values as bytes in LE order
+ let expected = [100, 131, 77, 207, 155, 181, 40, 209,
+ 102, 176, 255, 40, 238, 155, 35, 107,
+ 61, 123, 136, 13, 246, 243, 99, 150,
+ 216, 167, 15, 241, 62, 149, 34, 75];
+ assert_eq!(results, expected);
+ }
+
+ #[test]
+ fn test_isaac64_new_uninitialized() {
+ // Compare the results from initializing `IsaacRng` with
+ // `seed_from_u64(0)`, to make sure it is the same as the reference
+ // implementation when used uninitialized.
+ // Note: We only test the first 16 integers, not the full 256 of the
+ // first block.
+ let mut rng = Isaac64Rng::seed_from_u64(0);
+ let mut results = [0u64; 16];
+ for i in results.iter_mut() { *i = rng.next_u64(); }
+ let expected: [u64; 16] = [
+ 0xF67DFBA498E4937C, 0x84A5066A9204F380, 0xFEE34BD5F5514DBB,
+ 0x4D1664739B8F80D6, 0x8607459AB52A14AA, 0x0E78BC5A98529E49,
+ 0xFE5332822AD13777, 0x556C27525E33D01A, 0x08643CA615F3149F,
+ 0xD0771FAF3CB04714, 0x30E86F68A37B008D, 0x3074EBC0488A3ADF,
+ 0x270645EA7A2790BC, 0x5601A0A8D3763C6A, 0x2F83071F53F325DD,
+ 0xB9090F3D42D2D2EA];
+ assert_eq!(results, expected);
+ }
+
+ #[test]
+ fn test_isaac64_clone() {
+ let seed = [1,0,0,0, 0,0,0,0, 23,0,0,0, 0,0,0,0,
+ 200,1,0,0, 0,0,0,0, 210,30,0,0, 0,0,0,0];
+ let mut rng1 = Isaac64Rng::from_seed(seed);
+ let mut rng2 = rng1.clone();
+ for _ in 0..16 {
+ assert_eq!(rng1.next_u64(), rng2.next_u64());
+ }
+ }
+
+ #[test]
+ #[cfg(feature="serde1")]
+ fn test_isaac64_serde() {
+ use bincode;
+ use std::io::{BufWriter, BufReader};
+
+ let seed = [1,0,0,0, 23,0,0,0, 200,1,0,0, 210,30,0,0,
+ 57,48,0,0, 0,0,0,0, 0,0,0,0, 0,0,0,0];
+ let mut rng = Isaac64Rng::from_seed(seed);
+
+ let buf: Vec<u8> = Vec::new();
+ let mut buf = BufWriter::new(buf);
+ bincode::serialize_into(&mut buf, &rng).expect("Could not serialize");
+
+ let buf = buf.into_inner().unwrap();
+ let mut read = BufReader::new(&buf[..]);
+ let mut deserialized: Isaac64Rng = bincode::deserialize_from(&mut read).expect("Could not deserialize");
+
+ for _ in 0..300 { // more than the 256 buffered results
+ assert_eq!(rng.next_u64(), deserialized.next_u64());
+ }
+ }
+}