// Copyright 2014 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. //! The ChaCha random number generator. use core::num::Wrapping as w; use {Rng, SeedableRng, Rand}; #[allow(bad_style)] type w32 = w; const KEY_WORDS : usize = 8; // 8 words for the 256-bit key const STATE_WORDS : usize = 16; const CHACHA_ROUNDS: u32 = 20; // Cryptographically secure from 8 upwards as of this writing /// A random number generator that uses the ChaCha20 algorithm [1]. /// /// The ChaCha algorithm is widely accepted as suitable for /// cryptographic purposes, but this implementation has not been /// verified as such. Prefer a generator like `OsRng` that defers to /// the operating system for cases that need high security. /// /// [1]: D. J. Bernstein, [*ChaCha, a variant of /// Salsa20*](http://cr.yp.to/chacha.html) #[derive(Copy, Clone, Debug)] pub struct ChaChaRng { buffer: [w32; STATE_WORDS], // Internal buffer of output state: [w32; STATE_WORDS], // Initial state index: usize, // Index into state } static EMPTY: ChaChaRng = ChaChaRng { buffer: [w(0); STATE_WORDS], state: [w(0); STATE_WORDS], index: STATE_WORDS }; macro_rules! quarter_round{ ($a: expr, $b: expr, $c: expr, $d: expr) => {{ $a = $a + $b; $d = $d ^ $a; $d = w($d.0.rotate_left(16)); $c = $c + $d; $b = $b ^ $c; $b = w($b.0.rotate_left(12)); $a = $a + $b; $d = $d ^ $a; $d = w($d.0.rotate_left( 8)); $c = $c + $d; $b = $b ^ $c; $b = w($b.0.rotate_left( 7)); }} } macro_rules! double_round{ ($x: expr) => {{ // Column round quarter_round!($x[ 0], $x[ 4], $x[ 8], $x[12]); quarter_round!($x[ 1], $x[ 5], $x[ 9], $x[13]); quarter_round!($x[ 2], $x[ 6], $x[10], $x[14]); quarter_round!($x[ 3], $x[ 7], $x[11], $x[15]); // Diagonal round quarter_round!($x[ 0], $x[ 5], $x[10], $x[15]); quarter_round!($x[ 1], $x[ 6], $x[11], $x[12]); quarter_round!($x[ 2], $x[ 7], $x[ 8], $x[13]); quarter_round!($x[ 3], $x[ 4], $x[ 9], $x[14]); }} } #[inline] fn core(output: &mut [w32; STATE_WORDS], input: &[w32; STATE_WORDS]) { *output = *input; for _ in 0..CHACHA_ROUNDS / 2 { double_round!(output); } for i in 0..STATE_WORDS { output[i] = output[i] + input[i]; } } impl ChaChaRng { /// Create an ChaCha random number generator using the default /// fixed key of 8 zero words. /// /// # Examples /// /// ```rust /// use rand::{Rng, ChaChaRng}; /// /// let mut ra = ChaChaRng::new_unseeded(); /// println!("{:?}", ra.next_u32()); /// println!("{:?}", ra.next_u32()); /// ``` /// /// Since this equivalent to a RNG with a fixed seed, repeated executions /// of an unseeded RNG will produce the same result. This code sample will /// consistently produce: /// /// - 2917185654 /// - 2419978656 pub fn new_unseeded() -> ChaChaRng { let mut rng = EMPTY; rng.init(&[0; KEY_WORDS]); rng } /// Sets the internal 128-bit ChaCha counter to /// a user-provided value. This permits jumping /// arbitrarily ahead (or backwards) in the pseudorandom stream. /// /// Since the nonce words are used to extend the counter to 128 bits, /// users wishing to obtain the conventional ChaCha pseudorandom stream /// associated with a particular nonce can call this function with /// arguments `0, desired_nonce`. /// /// # Examples /// /// ```rust /// use rand::{Rng, ChaChaRng}; /// /// let mut ra = ChaChaRng::new_unseeded(); /// ra.set_counter(0u64, 1234567890u64); /// println!("{:?}", ra.next_u32()); /// println!("{:?}", ra.next_u32()); /// ``` pub fn set_counter(&mut self, counter_low: u64, counter_high: u64) { self.state[12] = w((counter_low >> 0) as u32); self.state[13] = w((counter_low >> 32) as u32); self.state[14] = w((counter_high >> 0) as u32); self.state[15] = w((counter_high >> 32) as u32); self.index = STATE_WORDS; // force recomputation } /// Initializes `self.state` with the appropriate key and constants /// /// We deviate slightly from the ChaCha specification regarding /// the nonce, which is used to extend the counter to 128 bits. /// This is provably as strong as the original cipher, though, /// since any distinguishing attack on our variant also works /// against ChaCha with a chosen-nonce. See the XSalsa20 [1] /// security proof for a more involved example of this. /// /// The modified word layout is: /// ```text /// constant constant constant constant /// key key key key /// key key key key /// counter counter counter counter /// ``` /// [1]: Daniel J. Bernstein. [*Extending the Salsa20 /// nonce.*](http://cr.yp.to/papers.html#xsalsa) fn init(&mut self, key: &[u32; KEY_WORDS]) { self.state[0] = w(0x61707865); self.state[1] = w(0x3320646E); self.state[2] = w(0x79622D32); self.state[3] = w(0x6B206574); for i in 0..KEY_WORDS { self.state[4+i] = w(key[i]); } self.state[12] = w(0); self.state[13] = w(0); self.state[14] = w(0); self.state[15] = w(0); self.index = STATE_WORDS; } /// Refill the internal output buffer (`self.buffer`) fn update(&mut self) { core(&mut self.buffer, &self.state); self.index = 0; // update 128-bit counter self.state[12] = self.state[12] + w(1); if self.state[12] != w(0) { return }; self.state[13] = self.state[13] + w(1); if self.state[13] != w(0) { return }; self.state[14] = self.state[14] + w(1); if self.state[14] != w(0) { return }; self.state[15] = self.state[15] + w(1); } } impl Rng for ChaChaRng { #[inline] fn next_u32(&mut self) -> u32 { if self.index == STATE_WORDS { self.update(); } let value = self.buffer[self.index % STATE_WORDS]; self.index += 1; value.0 } } impl<'a> SeedableRng<&'a [u32]> for ChaChaRng { fn reseed(&mut self, seed: &'a [u32]) { // reset state self.init(&[0u32; KEY_WORDS]); // set key in place let key = &mut self.state[4 .. 4+KEY_WORDS]; for (k, s) in key.iter_mut().zip(seed.iter()) { *k = w(*s); } } /// Create a ChaCha generator from a seed, /// obtained from a variable-length u32 array. /// Only up to 8 words are used; if less than 8 /// words are used, the remaining are set to zero. fn from_seed(seed: &'a [u32]) -> ChaChaRng { let mut rng = EMPTY; rng.reseed(seed); rng } } impl Rand for ChaChaRng { fn rand(other: &mut R) -> ChaChaRng { let mut key : [u32; KEY_WORDS] = [0; KEY_WORDS]; for word in key.iter_mut() { *word = other.gen(); } SeedableRng::from_seed(&key[..]) } } #[cfg(test)] mod test { use {Rng, SeedableRng}; use super::ChaChaRng; #[test] fn test_rng_rand_seeded() { let s = ::test::rng().gen_iter::().take(8).collect::>(); let mut ra: ChaChaRng = SeedableRng::from_seed(&s[..]); let mut rb: ChaChaRng = SeedableRng::from_seed(&s[..]); assert!(::test::iter_eq(ra.gen_ascii_chars().take(100), rb.gen_ascii_chars().take(100))); } #[test] fn test_rng_seeded() { let seed : &[_] = &[0,1,2,3,4,5,6,7]; let mut ra: ChaChaRng = SeedableRng::from_seed(seed); let mut rb: ChaChaRng = SeedableRng::from_seed(seed); assert!(::test::iter_eq(ra.gen_ascii_chars().take(100), rb.gen_ascii_chars().take(100))); } #[test] fn test_rng_reseed() { let s = ::test::rng().gen_iter::().take(8).collect::>(); let mut r: ChaChaRng = SeedableRng::from_seed(&s[..]); let string1: String = r.gen_ascii_chars().take(100).collect(); r.reseed(&s); let string2: String = r.gen_ascii_chars().take(100).collect(); assert_eq!(string1, string2); } #[test] fn test_rng_true_values() { // Test vectors 1 and 2 from // http://tools.ietf.org/html/draft-nir-cfrg-chacha20-poly1305-04 let seed : &[_] = &[0u32; 8]; let mut ra: ChaChaRng = SeedableRng::from_seed(seed); let v = (0..16).map(|_| ra.next_u32()).collect::>(); assert_eq!(v, vec!(0xade0b876, 0x903df1a0, 0xe56a5d40, 0x28bd8653, 0xb819d2bd, 0x1aed8da0, 0xccef36a8, 0xc70d778b, 0x7c5941da, 0x8d485751, 0x3fe02477, 0x374ad8b8, 0xf4b8436a, 0x1ca11815, 0x69b687c3, 0x8665eeb2)); let v = (0..16).map(|_| ra.next_u32()).collect::>(); assert_eq!(v, vec!(0xbee7079f, 0x7a385155, 0x7c97ba98, 0x0d082d73, 0xa0290fcb, 0x6965e348, 0x3e53c612, 0xed7aee32, 0x7621b729, 0x434ee69c, 0xb03371d5, 0xd539d874, 0x281fed31, 0x45fb0a51, 0x1f0ae1ac, 0x6f4d794b)); let seed : &[_] = &[0,1,2,3,4,5,6,7]; let mut ra: ChaChaRng = SeedableRng::from_seed(seed); // Store the 17*i-th 32-bit word, // i.e., the i-th word of the i-th 16-word block let mut v : Vec = Vec::new(); for _ in 0..16 { v.push(ra.next_u32()); for _ in 0..16 { ra.next_u32(); } } assert_eq!(v, vec!(0xf225c81a, 0x6ab1be57, 0x04d42951, 0x70858036, 0x49884684, 0x64efec72, 0x4be2d186, 0x3615b384, 0x11cfa18e, 0xd3c50049, 0x75c775f6, 0x434c6530, 0x2c5bad8f, 0x898881dc, 0x5f1c86d9, 0xc1f8e7f4)); } #[test] fn test_rng_clone() { let seed : &[_] = &[0u32; 8]; let mut rng: ChaChaRng = SeedableRng::from_seed(seed); let mut clone = rng.clone(); for _ in 0..16 { assert_eq!(rng.next_u64(), clone.next_u64()); } } }