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// Copyright 2018 Developers of the Rand project. // Copyright 2017-2018 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. //! Random number generation traits //! //! This crate is mainly of interest to crates publishing implementations of //! [`RngCore`]. Other users are encouraged to use the [`rand`] crate instead //! which re-exports the main traits and error types. //! //! [`RngCore`] is the core trait implemented by algorithmic pseudo-random number //! generators and external random-number sources. //! //! [`SeedableRng`] is an extension trait for construction from fixed seeds and //! other random number generators. //! //! [`Error`] is provided for error-handling. It is safe to use in `no_std` //! environments. //! //! The [`impls`] and [`le`] sub-modules include a few small functions to assist //! implementation of [`RngCore`]. //! //! [`rand`]: https://docs.rs/rand #![doc( html_logo_url = "https://www.rust-lang.org/logos/rust-logo-128x128-blk.png", html_favicon_url = "https://www.rust-lang.org/favicon.ico", html_root_url = "https://rust-random.github.io/rand/" )] #![deny(missing_docs)] #![deny(missing_debug_implementations)] #![doc(test(attr(allow(unused_variables), deny(warnings))))] #![cfg_attr(doc_cfg, feature(doc_cfg))] #![no_std] use core::convert::AsMut; use core::default::Default; #[cfg(feature = "std")] extern crate std; #[cfg(feature = "alloc")] extern crate alloc; #[cfg(feature = "alloc")] use alloc::boxed::Box; pub use error::Error; #[cfg(feature = "getrandom")] pub use os::OsRng; pub mod block; mod error; pub mod impls; pub mod le; #[cfg(feature = "getrandom")] mod os; /// The core of a random number generator. /// /// This trait encapsulates the low-level functionality common to all /// generators, and is the "back end", to be implemented by generators. /// End users should normally use the `Rng` trait from the [`rand`] crate, /// which is automatically implemented for every type implementing `RngCore`. /// /// Three different methods for generating random data are provided since the /// optimal implementation of each is dependent on the type of generator. There /// is no required relationship between the output of each; e.g. many /// implementations of [`fill_bytes`] consume a whole number of `u32` or `u64` /// values and drop any remaining unused bytes. The same can happen with the /// [`next_u32`] and [`next_u64`] methods, implementations may discard some /// random bits for efficiency. /// /// The [`try_fill_bytes`] method is a variant of [`fill_bytes`] allowing error /// handling; it is not deemed sufficiently useful to add equivalents for /// [`next_u32`] or [`next_u64`] since the latter methods are almost always used /// with algorithmic generators (PRNGs), which are normally infallible. /// /// Algorithmic generators implementing [`SeedableRng`] should normally have /// *portable, reproducible* output, i.e. fix Endianness when converting values /// to avoid platform differences, and avoid making any changes which affect /// output (except by communicating that the release has breaking changes). /// /// Typically implementators will implement only one of the methods available /// in this trait directly, then use the helper functions from the /// [`impls`] module to implement the other methods. /// /// It is recommended that implementations also implement: /// /// - `Debug` with a custom implementation which *does not* print any internal /// state (at least, [`CryptoRng`]s should not risk leaking state through /// `Debug`). /// - `Serialize` and `Deserialize` (from Serde), preferably making Serde /// support optional at the crate level in PRNG libs. /// - `Clone`, if possible. /// - *never* implement `Copy` (accidental copies may cause repeated values). /// - *do not* implement `Default` for pseudorandom generators, but instead /// implement [`SeedableRng`], to guide users towards proper seeding. /// External / hardware RNGs can choose to implement `Default`. /// - `Eq` and `PartialEq` could be implemented, but are probably not useful. /// /// # Example /// /// A simple example, obviously not generating very *random* output: /// /// ``` /// #![allow(dead_code)] /// use rand_core::{RngCore, Error, impls}; /// /// struct CountingRng(u64); /// /// impl RngCore for CountingRng { /// fn next_u32(&mut self) -> u32 { /// self.next_u64() as u32 /// } /// /// fn next_u64(&mut self) -> u64 { /// self.0 += 1; /// self.0 /// } /// /// fn fill_bytes(&mut self, dest: &mut [u8]) { /// impls::fill_bytes_via_next(self, dest) /// } /// /// fn try_fill_bytes(&mut self, dest: &mut [u8]) -> Result<(), Error> { /// Ok(self.fill_bytes(dest)) /// } /// } /// ``` /// /// [`rand`]: https://docs.rs/rand /// [`try_fill_bytes`]: RngCore::try_fill_bytes /// [`fill_bytes`]: RngCore::fill_bytes /// [`next_u32`]: RngCore::next_u32 /// [`next_u64`]: RngCore::next_u64 pub trait RngCore { /// Return the next random `u32`. /// /// RNGs must implement at least one method from this trait directly. In /// the case this method is not implemented directly, it can be implemented /// using `self.next_u64() as u32` or via [`impls::next_u32_via_fill`]. fn next_u32(&mut self) -> u32; /// Return the next random `u64`. /// /// RNGs must implement at least one method from this trait directly. In /// the case this method is not implemented directly, it can be implemented /// via [`impls::next_u64_via_u32`] or via [`impls::next_u64_via_fill`]. fn next_u64(&mut self) -> u64; /// Fill `dest` with random data. /// /// RNGs must implement at least one method from this trait directly. In /// the case this method is not implemented directly, it can be implemented /// via [`impls::fill_bytes_via_next`] or /// via [`RngCore::try_fill_bytes`]; if this generator can /// fail the implementation must choose how best to handle errors here /// (e.g. panic with a descriptive message or log a warning and retry a few /// times). /// /// This method should guarantee that `dest` is entirely filled /// with new data, and may panic if this is impossible /// (e.g. reading past the end of a file that is being used as the /// source of randomness). fn fill_bytes(&mut self, dest: &mut [u8]); /// Fill `dest` entirely with random data. /// /// This is the only method which allows an RNG to report errors while /// generating random data thus making this the primary method implemented /// by external (true) RNGs (e.g. `OsRng`) which can fail. It may be used /// directly to generate keys and to seed (infallible) PRNGs. /// /// Other than error handling, this method is identical to [`RngCore::fill_bytes`]; /// thus this may be implemented using `Ok(self.fill_bytes(dest))` or /// `fill_bytes` may be implemented with /// `self.try_fill_bytes(dest).unwrap()` or more specific error handling. fn try_fill_bytes(&mut self, dest: &mut [u8]) -> Result<(), Error>; } /// A marker trait used to indicate that an [`RngCore`] or [`BlockRngCore`] /// implementation is supposed to be cryptographically secure. /// /// *Cryptographically secure generators*, also known as *CSPRNGs*, should /// satisfy an additional properties over other generators: given the first /// *k* bits of an algorithm's output /// sequence, it should not be possible using polynomial-time algorithms to /// predict the next bit with probability significantly greater than 50%. /// /// Some generators may satisfy an additional property, however this is not /// required by this trait: if the CSPRNG's state is revealed, it should not be /// computationally-feasible to reconstruct output prior to this. Some other /// generators allow backwards-computation and are consided *reversible*. /// /// Note that this trait is provided for guidance only and cannot guarantee /// suitability for cryptographic applications. In general it should only be /// implemented for well-reviewed code implementing well-regarded algorithms. /// /// Note also that use of a `CryptoRng` does not protect against other /// weaknesses such as seeding from a weak entropy source or leaking state. /// /// [`BlockRngCore`]: block::BlockRngCore pub trait CryptoRng {} /// A random number generator that can be explicitly seeded. /// /// This trait encapsulates the low-level functionality common to all /// pseudo-random number generators (PRNGs, or algorithmic generators). /// /// [`rand`]: https://docs.rs/rand pub trait SeedableRng: Sized { /// Seed type, which is restricted to types mutably-dereferencable as `u8` /// arrays (we recommend `[u8; N]` for some `N`). /// /// It is recommended to seed PRNGs with a seed of at least circa 100 bits, /// which means an array of `[u8; 12]` or greater to avoid picking RNGs with /// partially overlapping periods. /// /// For cryptographic RNG's a seed of 256 bits is recommended, `[u8; 32]`. /// /// /// # Implementing `SeedableRng` for RNGs with large seeds /// /// Note that the required traits `core::default::Default` and /// `core::convert::AsMut<u8>` are not implemented for large arrays /// `[u8; N]` with `N` > 32. To be able to implement the traits required by /// `SeedableRng` for RNGs with such large seeds, the newtype pattern can be /// used: /// /// ``` /// use rand_core::SeedableRng; /// /// const N: usize = 64; /// pub struct MyRngSeed(pub [u8; N]); /// pub struct MyRng(MyRngSeed); /// /// impl Default for MyRngSeed { /// fn default() -> MyRngSeed { /// MyRngSeed([0; N]) /// } /// } /// /// impl AsMut<[u8]> for MyRngSeed { /// fn as_mut(&mut self) -> &mut [u8] { /// &mut self.0 /// } /// } /// /// impl SeedableRng for MyRng { /// type Seed = MyRngSeed; /// /// fn from_seed(seed: MyRngSeed) -> MyRng { /// MyRng(seed) /// } /// } /// ``` type Seed: Sized + Default + AsMut<[u8]>; /// Create a new PRNG using the given seed. /// /// PRNG implementations are allowed to assume that bits in the seed are /// well distributed. That means usually that the number of one and zero /// bits are roughly equal, and values like 0, 1 and (size - 1) are unlikely. /// Note that many non-cryptographic PRNGs will show poor quality output /// if this is not adhered to. If you wish to seed from simple numbers, use /// `seed_from_u64` instead. /// /// All PRNG implementations should be reproducible unless otherwise noted: /// given a fixed `seed`, the same sequence of output should be produced /// on all runs, library versions and architectures (e.g. check endianness). /// Any "value-breaking" changes to the generator should require bumping at /// least the minor version and documentation of the change. /// /// It is not required that this function yield the same state as a /// reference implementation of the PRNG given equivalent seed; if necessary /// another constructor replicating behaviour from a reference /// implementation can be added. /// /// PRNG implementations should make sure `from_seed` never panics. In the /// case that some special values (like an all zero seed) are not viable /// seeds it is preferable to map these to alternative constant value(s), /// for example `0xBAD5EEDu32` or `0x0DDB1A5E5BAD5EEDu64` ("odd biases? bad /// seed"). This is assuming only a small number of values must be rejected. fn from_seed(seed: Self::Seed) -> Self; /// Create a new PRNG using a `u64` seed. /// /// This is a convenience-wrapper around `from_seed` to allow construction /// of any `SeedableRng` from a simple `u64` value. It is designed such that /// low Hamming Weight numbers like 0 and 1 can be used and should still /// result in good, independent seeds to the PRNG which is returned. /// /// This **is not suitable for cryptography**, as should be clear given that /// the input size is only 64 bits. /// /// Implementations for PRNGs *may* provide their own implementations of /// this function, but the default implementation should be good enough for /// all purposes. *Changing* the implementation of this function should be /// considered a value-breaking change. fn seed_from_u64(mut state: u64) -> Self { // We use PCG32 to generate a u32 sequence, and copy to the seed fn pcg32(state: &mut u64) -> [u8; 4] { const MUL: u64 = 6364136223846793005; const INC: u64 = 11634580027462260723; // We advance the state first (to get away from the input value, // in case it has low Hamming Weight). *state = state.wrapping_mul(MUL).wrapping_add(INC); let state = *state; // Use PCG output function with to_le to generate x: let xorshifted = (((state >> 18) ^ state) >> 27) as u32; let rot = (state >> 59) as u32; let x = xorshifted.rotate_right(rot); x.to_le_bytes() } let mut seed = Self::Seed::default(); let mut iter = seed.as_mut().chunks_exact_mut(4); for chunk in &mut iter { chunk.copy_from_slice(&pcg32(&mut state)); } let rem = iter.into_remainder(); if !rem.is_empty() { rem.copy_from_slice(&pcg32(&mut state)[..rem.len()]); } Self::from_seed(seed) } /// Create a new PRNG seeded from another `Rng`. /// /// This may be useful when needing to rapidly seed many PRNGs from a master /// PRNG, and to allow forking of PRNGs. It may be considered deterministic. /// /// The master PRNG should be at least as high quality as the child PRNGs. /// When seeding non-cryptographic child PRNGs, we recommend using a /// different algorithm for the master PRNG (ideally a CSPRNG) to avoid /// correlations between the child PRNGs. If this is not possible (e.g. /// forking using small non-crypto PRNGs) ensure that your PRNG has a good /// mixing function on the output or consider use of a hash function with /// `from_seed`. /// /// Note that seeding `XorShiftRng` from another `XorShiftRng` provides an /// extreme example of what can go wrong: the new PRNG will be a clone /// of the parent. /// /// PRNG implementations are allowed to assume that a good RNG is provided /// for seeding, and that it is cryptographically secure when appropriate. /// As of `rand` 0.7 / `rand_core` 0.5, implementations overriding this /// method should ensure the implementation satisfies reproducibility /// (in prior versions this was not required). /// /// [`rand`]: https://docs.rs/rand fn from_rng<R: RngCore>(mut rng: R) -> Result<Self, Error> { let mut seed = Self::Seed::default(); rng.try_fill_bytes(seed.as_mut())?; Ok(Self::from_seed(seed)) } /// Creates a new instance of the RNG seeded via [`getrandom`]. /// /// This method is the recommended way to construct non-deterministic PRNGs /// since it is convenient and secure. /// /// In case the overhead of using [`getrandom`] to seed *many* PRNGs is an /// issue, one may prefer to seed from a local PRNG, e.g. /// `from_rng(thread_rng()).unwrap()`. /// /// # Panics /// /// If [`getrandom`] is unable to provide secure entropy this method will panic. /// /// [`getrandom`]: https://docs.rs/getrandom #[cfg(feature = "getrandom")] #[cfg_attr(doc_cfg, doc(cfg(feature = "getrandom")))] fn from_entropy() -> Self { let mut seed = Self::Seed::default(); if let Err(err) = getrandom::getrandom(seed.as_mut()) { panic!("from_entropy failed: {}", err); } Self::from_seed(seed) } } // Implement `RngCore` for references to an `RngCore`. // Force inlining all functions, so that it is up to the `RngCore` // implementation and the optimizer to decide on inlining. impl<'a, R: RngCore + ?Sized> RngCore for &'a mut R { #[inline(always)] fn next_u32(&mut self) -> u32 { (**self).next_u32() } #[inline(always)] fn next_u64(&mut self) -> u64 { (**self).next_u64() } #[inline(always)] fn fill_bytes(&mut self, dest: &mut [u8]) { (**self).fill_bytes(dest) } #[inline(always)] fn try_fill_bytes(&mut self, dest: &mut [u8]) -> Result<(), Error> { (**self).try_fill_bytes(dest) } } // Implement `RngCore` for boxed references to an `RngCore`. // Force inlining all functions, so that it is up to the `RngCore` // implementation and the optimizer to decide on inlining. #[cfg(feature = "alloc")] impl<R: RngCore + ?Sized> RngCore for Box<R> { #[inline(always)] fn next_u32(&mut self) -> u32 { (**self).next_u32() } #[inline(always)] fn next_u64(&mut self) -> u64 { (**self).next_u64() } #[inline(always)] fn fill_bytes(&mut self, dest: &mut [u8]) { (**self).fill_bytes(dest) } #[inline(always)] fn try_fill_bytes(&mut self, dest: &mut [u8]) -> Result<(), Error> { (**self).try_fill_bytes(dest) } } #[cfg(feature = "std")] impl std::io::Read for dyn RngCore { fn read(&mut self, buf: &mut [u8]) -> Result<usize, std::io::Error> { self.try_fill_bytes(buf)?; Ok(buf.len()) } } // Implement `CryptoRng` for references to an `CryptoRng`. impl<'a, R: CryptoRng + ?Sized> CryptoRng for &'a mut R {} // Implement `CryptoRng` for boxed references to an `CryptoRng`. #[cfg(feature = "alloc")] impl<R: CryptoRng + ?Sized> CryptoRng for Box<R> {} #[cfg(test)] mod test { use super::*; #[test] fn test_seed_from_u64() { struct SeedableNum(u64); impl SeedableRng for SeedableNum { type Seed = [u8; 8]; fn from_seed(seed: Self::Seed) -> Self { let mut x = [0u64; 1]; le::read_u64_into(&seed, &mut x); SeedableNum(x[0]) } } const N: usize = 8; const SEEDS: [u64; N] = [0u64, 1, 2, 3, 4, 8, 16, -1i64 as u64]; let mut results = [0u64; N]; for (i, seed) in SEEDS.iter().enumerate() { let SeedableNum(x) = SeedableNum::seed_from_u64(*seed); results[i] = x; } for (i1, r1) in results.iter().enumerate() { let weight = r1.count_ones(); // This is the binomial distribution B(64, 0.5), so chance of // weight < 20 is binocdf(19, 64, 0.5) = 7.8e-4, and same for // weight > 44. assert!(weight >= 20 && weight <= 44); for (i2, r2) in results.iter().enumerate() { if i1 == i2 { continue; } let diff_weight = (r1 ^ r2).count_ones(); assert!(diff_weight >= 20); } } // value-breakage test: assert_eq!(results[0], 5029875928683246316); } }