Random
Random Number Generation
Description
.Random.seed
is an integer vector, containing the random number generator (RNG) state for random number generation in R. It can be saved and restored, but should not be altered by the user.
RNGkind
is a more friendly interface to query or set the kind of RNG in use.
RNGversion
can be used to set the random generators as they were in an earlier R version (for reproducibility).
set.seed
is the recommended way to specify seeds.
Usage
.Random.seed <- c(rng.kind, n1, n2, ...) RNGkind(kind = NULL, normal.kind = NULL, sample.kind = NULL) RNGversion(vstr) set.seed(seed, kind = NULL, normal.kind = NULL, sample.kind = NULL)
Arguments
kind | character or |
normal.kind | character string or |
sample.kind | character string or |
seed | a single value, interpreted as an integer, or |
vstr | a character string containing a version number, e.g., |
rng.kind | integer code in |
n1, n2, ... | integers. See the details for how many are required (which depends on |
Details
The currently available RNG kinds are given below. kind
is partially matched to this list. The default is "Mersenne-Twister"
.
"Wichmann-Hill"
-
The seed,
.Random.seed[-1] == r[1:3]
is an integer vector of length 3, where eachr[i]
is in1:(p[i] - 1)
, wherep
is the length 3 vector of primes,p = (30269, 30307, 30323)
. The Wichmann–Hill generator has a cycle length of 6.9536e12 (=prod(p-1)/4
, see Applied Statistics (1984) 33, 123 which corrects the original article). -
"Marsaglia-Multicarry"
: -
A multiply-with-carry RNG is used, as recommended by George Marsaglia in his post to the mailing list ‘sci.stat.math’. It has a period of more than 2^60 and has passed all tests (according to Marsaglia). The seed is two integers (all values allowed).
-
"Super-Duper"
: -
Marsaglia's famous Super-Duper from the 70's. This is the original version which does not pass the MTUPLE test of the Diehard battery. It has a period of about 4.6*10^18 for most initial seeds. The seed is two integers (all values allowed for the first seed: the second must be odd).
We use the implementation by Reeds et al (1982–84).
The two seeds are the Tausworthe and congruence long integers, respectively. A one-to-one mapping to S's
.Random.seed[1:12]
is possible but we will not publish one, not least as this generator is not exactly the same as that in recent versions of S-PLUS. -
"Mersenne-Twister"
: -
From Matsumoto and Nishimura (1998); code updated in 2002. A twisted GFSR with period 2^19937 - 1 and equidistribution in 623 consecutive dimensions (over the whole period). The ‘seed’ is a 624-dimensional set of 32-bit integers plus a current position in that set.
R uses its own initialization method due to B. D. Ripley and is not affected by the initialization issue in the 1998 code of Matsumoto and Nishimura addressed in a 2002 update.
-
"Knuth-TAOCP-2002"
: -
A 32-bit integer GFSR using lagged Fibonacci sequences with subtraction. That is, the recurrence used is
X[j] = (X[j-100] - X[j-37]) mod 2^30
and the ‘seed’ is the set of the 100 last numbers (actually recorded as 101 numbers, the last being a cyclic shift of the buffer). The period is around 2^129.
-
"Knuth-TAOCP"
: -
An earlier version from Knuth (1997).
The 2002 version was not backwards compatible with the earlier version: the initialization of the GFSR from the seed was altered. R did not allow you to choose consecutive seeds, the reported ‘weakness’, and already scrambled the seeds.
Initialization of this generator is done in interpreted R code and so takes a short but noticeable time.
-
"L'Ecuyer-CMRG"
: -
A ‘combined multiple-recursive generator’ from L'Ecuyer (1999), each element of which is a feedback multiplicative generator with three integer elements: thus the seed is a (signed) integer vector of length 6. The period is around 2^191.
The 6 elements of the seed are internally regarded as 32-bit unsigned integers. Neither the first three nor the last three should be all zero, and they are limited to less than
4294967087
and4294944443
respectively.This is not particularly interesting of itself, but provides the basis for the multiple streams used in package parallel.
-
"user-supplied"
: -
Use a user-supplied generator. See
Random.user
for details.
normal.kind
can be "Kinderman-Ramage"
, "Buggy Kinderman-Ramage"
(not for set.seed
), "Ahrens-Dieter"
, "Box-Muller"
, "Inversion"
(the default), or "user-supplied"
. (For inversion, see the reference in qnorm
.) The Kinderman-Ramage generator used in versions prior to 1.7.0 (now called "Buggy"
) had several approximation errors and should only be used for reproduction of old results. The "Box-Muller"
generator is stateful as pairs of normals are generated and returned sequentially. The state is reset whenever it is selected (even if it is the current normal generator) and when kind
is changed.
sample.kind
can be "Rounding"
or "Rejection"
, or partial matches to these. The former was the default in versions prior to 3.6.0: it made sample
noticeably non-uniform on large populations, and should only be used for reproduction of old results. See PR#17494 for a discussion.
set.seed
uses a single integer argument to set as many seeds as are required. It is intended as a simple way to get quite different seeds by specifying small integer arguments, and also as a way to get valid seed sets for the more complicated methods (especially "Mersenne-Twister"
and "Knuth-TAOCP"
). There is no guarantee that different values of seed
will seed the RNG differently, although any exceptions would be extremely rare. If called with seed = NULL
it re-initializes (see ‘Note’) as if no seed had yet been set.
The use of kind = NULL
, normal.kind = NULL
or sample.kind = NULL
in RNGkind
or set.seed
selects the currently-used generator (including that used in the previous session if the workspace has been restored): if no generator has been used it selects "default"
.
Value
.Random.seed
is an integer
vector whose first element codes the kind of RNG and normal generator. The lowest two decimal digits are in 0:(k-1)
where k
is the number of available RNGs. The hundreds represent the type of normal generator (starting at 0
), and the ten thousands represent the type of discrete uniform sampler.
In the underlying C, .Random.seed[-1]
is unsigned
; therefore in R .Random.seed[-1]
can be negative, due to the representation of an unsigned integer by a signed integer.
RNGkind
returns a three-element character vector of the RNG, normal and sample kinds selected before the call, invisibly if either argument is not NULL
. A type starts a session as the default, and is selected either by a call to RNGkind
or by setting .Random.seed
in the workspace. (NB: prior to R 3.6.0 the first two kinds were returned in a two-element character vector.)
RNGversion
returns the same information as RNGkind
about the defaults in a specific R version.
set.seed
returns NULL
, invisibly.
Note
Initially, there is no seed; a new one is created from the current time and the process ID when one is required. Hence different sessions will give different simulation results, by default. However, the seed might be restored from a previous session if a previously saved workspace is restored.
.Random.seed
saves the seed set for the uniform random-number generator, at least for the system generators. It does not necessarily save the state of other generators, and in particular does not save the state of the Box–Muller normal generator. If you want to reproduce work later, call set.seed
(preferably with explicit values for kind
and normal.kind
) rather than set .Random.seed
.
The object .Random.seed
is only looked for in the user's workspace.
Do not rely on randomness of low-order bits from RNGs. Most of the supplied uniform generators return 32-bit integer values that are converted to doubles, so they take at most 2^32 distinct values and long runs will return duplicated values (Wichmann-Hill is the exception, and all give at least 30 varying bits.)
Author(s)
of RNGkind: Martin Maechler. Current implementation, B. D. Ripley with modifications by Duncan Murdoch.
References
Ahrens, J. H. and Dieter, U. (1973). Extensions of Forsythe's method for random sampling from the normal distribution. Mathematics of Computation, 27, 927–937.
Becker, R. A., Chambers, J. M. and Wilks, A. R. (1988). The New S Language. Wadsworth & Brooks/Cole. (set.seed
, storing in .Random.seed
.)
Box, G. E. P. and Muller, M. E. (1958). A note on the generation of normal random deviates. Annals of Mathematical Statistics, 29, 610–611. doi: 10.1214/aoms/1177706645.
De Matteis, A. and Pagnutti, S. (1993). Long-range Correlation Analysis of the Wichmann-Hill Random Number Generator. Statistics and Computing, 3, 67–70. doi: 10.1007/BF00153065.
Kinderman, A. J. and Ramage, J. G. (1976). Computer generation of normal random variables. Journal of the American Statistical Association, 71, 893–896. doi: 10.2307/2286857.
Knuth, D. E. (1997). The Art of Computer Programming. Volume 2, third edition.
Source code at https://www-cs-faculty.stanford.edu/~knuth/taocp.html.
Knuth, D. E. (2002). The Art of Computer Programming. Volume 2, third edition, ninth printing.
L'Ecuyer, P. (1999). Good parameters and implementations for combined multiple recursive random number generators. Operations Research, 47, 159–164. doi: 10.1287/opre.47.1.159.
Marsaglia, G. (1997). A random number generator for C. Discussion paper, posting on Usenet newsgroup sci.stat.math
on September 29, 1997.
Marsaglia, G. and Zaman, A. (1994). Some portable very-long-period random number generators. Computers in Physics, 8, 117–121. doi: 10.1063/1.168514.
Matsumoto, M. and Nishimura, T. (1998). Mersenne Twister: A 623-dimensionally equidistributed uniform pseudo-random number generator, ACM Transactions on Modeling and Computer Simulation, 8, 3–30.
Source code formerly at http://www.math.keio.ac.jp/~matumoto/emt.html
.
Now see http://www.math.sci.hiroshima-u.ac.jp/~m-mat/MT/VERSIONS/C-LANG/c-lang.html.
Reeds, J., Hubert, S. and Abrahams, M. (1982–4). C implementation of SuperDuper, University of California at Berkeley. (Personal communication from Jim Reeds to Ross Ihaka.)
Wichmann, B. A. and Hill, I. D. (1982). Algorithm AS 183: An Efficient and Portable Pseudo-random Number Generator. Applied Statistics, 31, 188–190; Remarks: 34, 198 and 35, 89. doi: 10.2307/2347988.
See Also
sample
for random sampling with and without replacement.
Distributions for functions for random-variate generation from standard distributions.
Examples
require(stats) ## Seed the current RNG, i.e., set the RNG status set.seed(42); u1 <- runif(30) set.seed(42); u2 <- runif(30) # the same because of identical RNG status: stopifnot(identical(u1, u2)) ## the default random seed is 626 integers, so only print a few runif(1); .Random.seed[1:6]; runif(1); .Random.seed[1:6] ## If there is no seed, a "random" new one is created: rm(.Random.seed); runif(1); .Random.seed[1:6] ok <- RNGkind() RNGkind("Wich") # (partial string matching on 'kind') ## This shows how 'runif(.)' works for Wichmann-Hill, ## using only R functions: p.WH <- c(30269, 30307, 30323) a.WH <- c( 171, 172, 170) next.WHseed <- function(i.seed = .Random.seed[-1]) { (a.WH * i.seed) %% p.WH } my.runif1 <- function(i.seed = .Random.seed) { ns <- next.WHseed(i.seed[-1]); sum(ns / p.WH) %% 1 } set.seed(1998-12-04)# (when the next lines were added to the souRce) rs <- .Random.seed (WHs <- next.WHseed(rs[-1])) u <- runif(1) stopifnot( next.WHseed(rs[-1]) == .Random.seed[-1], all.equal(u, my.runif1(rs)) ) ## ---- .Random.seed RNGkind("Super") # matches "Super-Duper" RNGkind() .Random.seed # new, corresponding to Super-Duper ## Reset: RNGkind(ok[1]) RNGversion(getRversion()) # the default version for this R version ## ---- sum(duplicated(runif(1e6))) # around 110 for default generator ## and we would expect about almost sure duplicates beyond about qbirthday(1 - 1e-6, classes = 2e9) # 235,000
Copyright (©) 1999–2012 R Foundation for Statistical Computing.
Licensed under the GNU General Public License.