# [−][src]Trait rand::SeedableRng

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).

## Associated Types

`type Seed: AsMut<[u8]> + Default + 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) } }

## Required methods

`fn from_seed(seed: Self::Seed) -> Self`

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.

## Provided methods

`fn seed_from_u64(state: u64) -> 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 from_rng<R>(rng: R) -> Result<Self, Error> where`

R: RngCore,

R: RngCore,

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).

`fn from_entropy() -> Self`

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.

## Implementations on Foreign Types

`impl<R> SeedableRng for BlockRng<R> where`

R: BlockRngCore + SeedableRng,

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R: BlockRngCore + SeedableRng,

`type Seed = <R as SeedableRng>::Seed`

`fn from_seed(seed: <BlockRng<R> as SeedableRng>::Seed) -> BlockRng<R>`

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`fn seed_from_u64(seed: u64) -> BlockRng<R>`

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`fn from_rng<S>(rng: S) -> Result<BlockRng<R>, Error> where`

S: RngCore,

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S: RngCore,

`impl<R> SeedableRng for BlockRng64<R> where`

R: BlockRngCore + SeedableRng,

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R: BlockRngCore + SeedableRng,

`type Seed = <R as SeedableRng>::Seed`

`fn from_seed(seed: <BlockRng64<R> as SeedableRng>::Seed) -> BlockRng64<R>`

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`fn seed_from_u64(seed: u64) -> BlockRng64<R>`

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`fn from_rng<S>(rng: S) -> Result<BlockRng64<R>, Error> where`

S: RngCore,

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S: RngCore,

`impl SeedableRng for ChaCha12Core`

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`type Seed = [u8; 32]`

`fn from_seed(seed: <ChaCha12Core as SeedableRng>::Seed) -> ChaCha12Core`

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`impl SeedableRng for ChaCha8Rng`

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`type Seed = [u8; 32]`

`fn from_seed(seed: <ChaCha8Rng as SeedableRng>::Seed) -> ChaCha8Rng`

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`impl SeedableRng for ChaCha20Core`

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`type Seed = [u8; 32]`

`fn from_seed(seed: <ChaCha20Core as SeedableRng>::Seed) -> ChaCha20Core`

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`impl SeedableRng for ChaCha8Core`

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`type Seed = [u8; 32]`

`fn from_seed(seed: <ChaCha8Core as SeedableRng>::Seed) -> ChaCha8Core`

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`impl SeedableRng for ChaCha20Rng`

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`type Seed = [u8; 32]`

`fn from_seed(seed: <ChaCha20Rng as SeedableRng>::Seed) -> ChaCha20Rng`

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`impl SeedableRng for ChaCha12Rng`

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`type Seed = [u8; 32]`

`fn from_seed(seed: <ChaCha12Rng as SeedableRng>::Seed) -> ChaCha12Rng`

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`impl SeedableRng for Lcg64Xsh32`

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We use a single 127-bit seed to initialise the state and select a stream.
One `seed`

bit (lowest bit of `seed[8]`

) is ignored.

`type Seed = [u8; 16]`

`fn from_seed(seed: <Lcg64Xsh32 as SeedableRng>::Seed) -> Lcg64Xsh32`

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`impl SeedableRng for Mcg128Xsl64`

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We use a single 126-bit seed to initialise the state and select a stream.
Two `seed`

bits (lowest order of last byte) are ignored.

`type Seed = [u8; 16]`

`fn from_seed(seed: <Mcg128Xsl64 as SeedableRng>::Seed) -> Mcg128Xsl64`

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`impl SeedableRng for Lcg128Xsl64`

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We use a single 255-bit seed to initialise the state and select a stream.
One `seed`

bit (lowest bit of `seed[8]`

) is ignored.