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reference:random:legacy
docs/reference:random:legacy
Legacy random generation
The RandomState provides access to legacy generators. This generator is considered frozen and will have no further improvements. It is guaranteed to produce the same values as the final point release of NumPy v1.16. These all depend on Box-Muller normals or inverse CDF exponentials or gammas. This class should only be used if it is essential to have randoms that are identical to what would have been produced by previous versions of NumPy.
RandomState adds additional information to the state which is required when using Box-Muller normals since these are produced in pairs. It is important to use RandomState.get_state, and not the underlying bit generators state, when accessing the state so that these extra values are saved.
Although we provide the MT19937 BitGenerator for use independent of RandomState, note that its default seeding uses SeedSequence rather than the legacy seeding algorithm. RandomState will use the legacy seeding algorithm. The methods to use the legacy seeding algorithm are currently private as the main reason to use them is just to implement RandomState. However, one can reset the state of MT19937 using the state of the RandomState:
from numpy.random import MT19937 from numpy.random import RandomState rs = RandomState(12345) mt19937 = MT19937() mt19937.state = rs.get_state() rs2 = RandomState(mt19937) # Same output rs.standard_normal() rs2.standard_normal() rs.random() rs2.random() rs.standard_exponential() rs2.standard_exponential()
Seeding and state
.. autosummary:: :toctree:generated/ ~RandomState.get_state ~RandomState.set_state ~RandomState.seed
Simple random data
.. autosummary:: :toctree:generated/ ~RandomState.rand ~RandomState.randn ~RandomState.randint ~RandomState.random_integers ~RandomState.random_sample ~RandomState.choice ~RandomState.bytes
Permutations
.. autosummary:: :toctree:generated/ ~RandomState.shuffle ~RandomState.permutation
Distributions
.. autosummary:: :toctree:generated/ ~RandomState.beta ~RandomState.binomial ~RandomState.chisquare ~RandomState.dirichlet ~RandomState.exponential ~RandomState.f ~RandomState.gamma ~RandomState.geometric ~RandomState.gumbel ~RandomState.hypergeometric ~RandomState.laplace ~RandomState.logistic ~RandomState.lognormal ~RandomState.logseries ~RandomState.multinomial ~RandomState.multivariate_normal ~RandomState.negative_binomial ~RandomState.noncentral_chisquare ~RandomState.noncentral_f ~RandomState.normal ~RandomState.pareto ~RandomState.poisson ~RandomState.power ~RandomState.rayleigh ~RandomState.standard_cauchy ~RandomState.standard_exponential ~RandomState.standard_gamma ~RandomState.standard_normal ~RandomState.standard_t ~RandomState.triangular ~RandomState.uniform ~RandomState.vonmises ~RandomState.wald ~RandomState.weibull ~RandomState.zipf
Functions in numpy.random
Many of the RandomState methods above are exported as functions in numpy.random This usage is discouraged, as it is implemented via a global RandomState instance which is not advised on two counts:
It uses global state, which means results will change as the code changes
It uses a
RandomStaterather than the more modernGenerator.
For backward compatible legacy reasons, we will not change this.
.. autosummary:: :toctree:generated/ beta binomial bytes chisquare choice dirichlet exponential f gamma geometric get_state gumbel hypergeometric laplace logistic lognormal logseries multinomial multivariate_normal negative_binomial noncentral_chisquare noncentral_f normal pareto permutation poisson power rand randint randn random random_integers random_sample ranf rayleigh sample seed set_state shuffle standard_cauchy standard_exponential standard_gamma standard_normal standard_t triangular uniform vonmises wald weibull zipf