// Copyright 2013 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 ISAAC random number generator. #![allow(non_camel_case_types)] use core::slice; use core::iter::repeat; use core::num::Wrapping as w; use core::fmt; use {Rng, SeedableRng, Rand}; #[allow(bad_style)] type w32 = w; const RAND_SIZE_LEN: usize = 8; const RAND_SIZE: u32 = 1 << RAND_SIZE_LEN; const RAND_SIZE_USIZE: usize = 1 << RAND_SIZE_LEN; /// A random number generator that uses the ISAAC algorithm[1]. /// /// The ISAAC algorithm is generally accepted as suitable for /// cryptographic purposes, but this implementation has not be /// verified as such. Prefer a generator like `OsRng` that defers to /// the operating system for cases that need high security. /// /// [1]: Bob Jenkins, [*ISAAC: A fast cryptographic random number /// generator*](http://www.burtleburtle.net/bob/rand/isaacafa.html) #[derive(Copy)] pub struct IsaacRng { cnt: u32, rsl: [w32; RAND_SIZE_USIZE], mem: [w32; RAND_SIZE_USIZE], a: w32, b: w32, c: w32, } static EMPTY: IsaacRng = IsaacRng { cnt: 0, rsl: [w(0); RAND_SIZE_USIZE], mem: [w(0); RAND_SIZE_USIZE], a: w(0), b: w(0), c: w(0), }; impl IsaacRng { /// Create an ISAAC random number generator using the default /// fixed seed. pub fn new_unseeded() -> IsaacRng { let mut rng = EMPTY; rng.init(false); rng } /// Initialises `self`. If `use_rsl` is true, then use the current value /// of `rsl` as a seed, otherwise construct one algorithmically (not /// randomly). fn init(&mut self, use_rsl: bool) { let mut a = w(0x9e3779b9); let mut b = a; let mut c = a; let mut d = a; let mut e = a; let mut f = a; let mut g = a; let mut h = a; macro_rules! mix { () => {{ a=a^(b<<11); d=d+a; b=b+c; b=b^(c>>2); e=e+b; c=c+d; c=c^(d<<8); f=f+c; d=d+e; d=d^(e>>16); g=g+d; e=e+f; e=e^(f<<10); h=h+e; f=f+g; f=f^(g>>4); a=a+f; g=g+h; g=g^(h<<8); b=b+g; h=h+a; h=h^(a>>9); c=c+h; a=a+b; }} } for _ in 0..4 { mix!(); } if use_rsl { macro_rules! memloop { ($arr:expr) => {{ for i in (0..RAND_SIZE_USIZE/8).map(|i| i * 8) { a=a+$arr[i ]; b=b+$arr[i+1]; c=c+$arr[i+2]; d=d+$arr[i+3]; e=e+$arr[i+4]; f=f+$arr[i+5]; g=g+$arr[i+6]; h=h+$arr[i+7]; mix!(); self.mem[i ]=a; self.mem[i+1]=b; self.mem[i+2]=c; self.mem[i+3]=d; self.mem[i+4]=e; self.mem[i+5]=f; self.mem[i+6]=g; self.mem[i+7]=h; } }} } memloop!(self.rsl); memloop!(self.mem); } else { for i in (0..RAND_SIZE_USIZE/8).map(|i| i * 8) { mix!(); self.mem[i ]=a; self.mem[i+1]=b; self.mem[i+2]=c; self.mem[i+3]=d; self.mem[i+4]=e; self.mem[i+5]=f; self.mem[i+6]=g; self.mem[i+7]=h; } } self.isaac(); } /// Refills the output buffer (`self.rsl`) #[inline] fn isaac(&mut self) { self.c = self.c + w(1); // abbreviations let mut a = self.a; let mut b = self.b + self.c; const MIDPOINT: usize = RAND_SIZE_USIZE / 2; macro_rules! ind { ($x:expr) => ( self.mem[($x >> 2usize).0 as usize & (RAND_SIZE_USIZE - 1)] ) } let r = [(0, MIDPOINT), (MIDPOINT, 0)]; for &(mr_offset, m2_offset) in r.iter() { macro_rules! rngstepp { ($j:expr, $shift:expr) => {{ let base = $j; let mix = a << $shift; let x = self.mem[base + mr_offset]; a = (a ^ mix) + self.mem[base + m2_offset]; let y = ind!(x) + a + b; self.mem[base + mr_offset] = y; b = ind!(y >> RAND_SIZE_LEN) + x; self.rsl[base + mr_offset] = b; }} } macro_rules! rngstepn { ($j:expr, $shift:expr) => {{ let base = $j; let mix = a >> $shift; let x = self.mem[base + mr_offset]; a = (a ^ mix) + self.mem[base + m2_offset]; let y = ind!(x) + a + b; self.mem[base + mr_offset] = y; b = ind!(y >> RAND_SIZE_LEN) + x; self.rsl[base + mr_offset] = b; }} } for i in (0..MIDPOINT/4).map(|i| i * 4) { rngstepp!(i + 0, 13); rngstepn!(i + 1, 6); rngstepp!(i + 2, 2); rngstepn!(i + 3, 16); } } self.a = a; self.b = b; self.cnt = RAND_SIZE; } } // Cannot be derived because [u32; 256] does not implement Clone impl Clone for IsaacRng { fn clone(&self) -> IsaacRng { *self } } impl Rng for IsaacRng { #[inline] fn next_u32(&mut self) -> u32 { if self.cnt == 0 { // make some more numbers self.isaac(); } self.cnt -= 1; // self.cnt is at most RAND_SIZE, but that is before the // subtraction above. We want to index without bounds // checking, but this could lead to incorrect code if someone // misrefactors, so we check, sometimes. // // (Changes here should be reflected in Isaac64Rng.next_u64.) debug_assert!(self.cnt < RAND_SIZE); // (the % is cheaply telling the optimiser that we're always // in bounds, without unsafe. NB. this is a power of two, so // it optimises to a bitwise mask). self.rsl[(self.cnt % RAND_SIZE) as usize].0 } } impl<'a> SeedableRng<&'a [u32]> for IsaacRng { fn reseed(&mut self, seed: &'a [u32]) { // make the seed into [seed[0], seed[1], ..., seed[seed.len() // - 1], 0, 0, ...], to fill rng.rsl. let seed_iter = seed.iter().map(|&x| x).chain(repeat(0u32)); for (rsl_elem, seed_elem) in self.rsl.iter_mut().zip(seed_iter) { *rsl_elem = w(seed_elem); } self.cnt = 0; self.a = w(0); self.b = w(0); self.c = w(0); self.init(true); } /// Create an ISAAC random number generator with a seed. This can /// be any length, although the maximum number of elements used is /// 256 and any more will be silently ignored. A generator /// constructed with a given seed will generate the same sequence /// of values as all other generators constructed with that seed. fn from_seed(seed: &'a [u32]) -> IsaacRng { let mut rng = EMPTY; rng.reseed(seed); rng } } impl Rand for IsaacRng { fn rand(other: &mut R) -> IsaacRng { let mut ret = EMPTY; unsafe { let ptr = ret.rsl.as_mut_ptr() as *mut u8; let slice = slice::from_raw_parts_mut(ptr, RAND_SIZE_USIZE * 4); other.fill_bytes(slice); } ret.cnt = 0; ret.a = w(0); ret.b = w(0); ret.c = w(0); ret.init(true); return ret; } } impl fmt::Debug for IsaacRng { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { write!(f, "IsaacRng {{}}") } } #[cfg(test)] mod test { use {Rng, SeedableRng}; use super::IsaacRng; #[test] fn test_rng_32_rand_seeded() { let s = ::test::rng().gen_iter::().take(256).collect::>(); let mut ra: IsaacRng = SeedableRng::from_seed(&s[..]); let mut rb: IsaacRng = SeedableRng::from_seed(&s[..]); assert!(::test::iter_eq(ra.gen_ascii_chars().take(100), rb.gen_ascii_chars().take(100))); } #[test] fn test_rng_32_seeded() { let seed: &[_] = &[1, 23, 456, 7890, 12345]; let mut ra: IsaacRng = SeedableRng::from_seed(seed); let mut rb: IsaacRng = SeedableRng::from_seed(seed); assert!(::test::iter_eq(ra.gen_ascii_chars().take(100), rb.gen_ascii_chars().take(100))); } #[test] fn test_rng_32_reseed() { let s = ::test::rng().gen_iter::().take(256).collect::>(); let mut r: IsaacRng = 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_32_true_values() { let seed: &[_] = &[1, 23, 456, 7890, 12345]; let mut ra: IsaacRng = SeedableRng::from_seed(seed); // Regression test that isaac is actually using the above vector let v = (0..10).map(|_| ra.next_u32()).collect::>(); assert_eq!(v, vec!(2558573138, 873787463, 263499565, 2103644246, 3595684709, 4203127393, 264982119, 2765226902, 2737944514, 3900253796)); let seed: &[_] = &[12345, 67890, 54321, 9876]; let mut rb: IsaacRng = SeedableRng::from_seed(seed); // skip forward to the 10000th number for _ in 0..10000 { rb.next_u32(); } let v = (0..10).map(|_| rb.next_u32()).collect::>(); assert_eq!(v, vec!(3676831399, 3183332890, 2834741178, 3854698763, 2717568474, 1576568959, 3507990155, 179069555, 141456972, 2478885421)); } }