Math::Random - Random Number Generators
use Math::Random;
Exports the following routines by default (see "Default Routines"):
random_set_seed_from_phrase random_get_seed random_seed_from_phrase random_set_seed random_uniform random_uniform_integer random_permutation random_permuted_index random_normal
In this case the extended routines (see "Extended Routines") can be used by qualifying them explicitly with Math::Random::
, for example: $stdexp = Math::Random::random_exponential();
use Math::Random qw(random_beta random_chi_square random_exponential random_f random_gamma random_multivariate_normal random_multinomial random_noncentral_chi_square random_noncentral_f random_normal random_permutation random_permuted_index random_uniform random_poisson random_uniform_integer random_negative_binomial random_binomial random_seed_from_phrase random_get_seed random_set_seed_from_phrase random_set_seed );
Exports all the routines explicitly. Use a subset of the list for the routines you want.
use Math::Random qw(:all);
Exports all the routines, as well.
Math::Random is a Perl port of the C version of randlib, which is a suite of routines for generating random deviates. See "RANDLIB" for more information.
This port supports all of the distributions from which the Fortran and C versions generate deviates. The major functionalities that are excluded are the multiple generators/splitting facility and antithetic random number generation. These facilities, along with some of the distributions which are included, are probably not of interest except to the very sophisticated user. If there is sufficient interest, the excluded facilities will be included in a future release. The code to perform the excluded facilities is available as randlib in Fortran and C source.
The routines which are exported by default are the only ones that the average Perl programmer is likely to need.
random_set_seed_from_phrase($phrase)
Sets the seed of the base generator to a value determined by $phrase. If the module is installed with the default option, the value depends on the machine collating sequence. It should, however, be the same for 7-bit ASCII character strings on all ASCII machines. In the original randlib, the value generated for a given $phrase was consistent from implementation to implementation (it did not rely on the machine collating sequence). Check with your Perl administrator to see if the module was installed with the original seed generator. Note: When the Perl processor loads package Math::Random the seed is set to a value based on the current time. The seed changes each time Math::Random generates something random.
The ability to set the seed is useful for debugging, or for those who like reproducible runs.
random_get_seed()
Returns an array of length two which contains the two integers constituting the seed (assuming a call in array context). An invocation in a scalar context returns the integer 2, which is probably not useful.
random_seed_from_phrase($phrase)
Returns an array of length two which contains the two integers constituting the seed (assuming a call in array context). An invocation in a scalar context returns the integer 2, which is probably not useful. The seed generated is the seed used to set the seed in a call to random_set_seed_from_phrase
.
Note: the following two calls (for the same $phrase) are equivalent:
random_set_seed(random_seed_from_phrase($phrase));
and
random_set_seed_from_phrase($phrase);
random_set_seed(@seed)
Sets the seed of the base generator to the value @seed[0,1]. Usually, the argument @seed should be the result of a call to random_get_seed
or random_seed_from_phrase
. @seed[0,1] must be two integers in the range (1, 1) to (2147483562, 2147483398), inclusive.
random_uniform($n, $low, $high)
random_uniform($n)
random_uniform()
When called in an array context, returns an array of $n deviates generated from a uniform($low, $high) distribution. When called in a scalar context, generates and returns only one such deviate as a scalar, regardless of the value of $n.
Argument restrictions: $low must be less than or equal to $high.
Defaults are (1, 0, 1). Note: $high must be specified if $low is specified.
random_uniform_integer($n, $low, $high)
When called in an array context, returns an array of $n integer deviates generated from a uniform($low, $high) distribution on the integers. When called in a scalar context, generates and returns only one such deviate as a scalar, regardless of the value of $n.
Argument restrictions: $low and $high are first rounded using int()
; the resulting $low must be less than or equal to $high, and the resulting range ($high - $low) must not be greater than 2147483561.
There are no defaults; all three arguments must be provided.
random_permutation(@array)
Returns @array, randomly permuted.
random_permuted_index($n)
Returns an array of array indices, randomly permuted. The indices used are (0, ... ,($n - 1)). This produces the indices used by random_permutation
for a given seed, without passing arrays.
Note: the following are equivalent:
random_set_seed_from_phrase('jjv'); random_permutation(@array);
and
random_set_seed_from_phrase('jjv'); @array[(random_permuted_index(scalar(@array)))];
random_normal($n, $av, $sd)
random_normal($n, $av)
random_normal($n)
random_normal()
When called in an array context, returns an array of $n deviates generated from a normal($av, $sd^2) distribution. When called in a scalar context, generates and returns only one such deviate as a scalar, regardless of the value of $n.
Argument restrictions: $sd must be non-negative.
Defaults are (1, 0, 1).
These routines generate deviates from many other distributions.
Note: The parameterizations of these deviates are standard (insofar as there is a standard ... ) but particular attention should be paid to the distributions of the beta and gamma deviates (noted in random_beta
and random_gamma
below).
random_beta($n, $aa, $bb)
When called in an array context, returns an array of $n deviates generated from the beta distribution with parameters $aa and $bb. The density of the beta is:
X^($aa - 1) * (1 - X)^($bb - 1) / B($aa , $bb) for 0 < X < 1.
When called in a scalar context, generates and returns only one such deviate as a scalar, regardless of the value of $n.
Argument restrictions: Both $aa and $bb must not be less than 1.0E-37
.
There are no defaults; all three arguments must be provided.
random_binomial($n, $nt, $p)
When called in an array context, returns an array of $n outcomes generated from the binomial distribution with number of trials $nt and probability of an event in each trial $p. When called in a scalar context, generates and returns only one such outcome as a scalar, regardless of the value of $n.
Argument restrictions: $nt is rounded using int()
; the result must be non-negative. $p must be between 0 and 1 inclusive.
There are no defaults; both arguments must be provided.
random_chi_square($n, $df)
When called in an array context, returns an array of $n deviates generated from the chi-square distribution with $df degrees of freedom. When called in a scalar context, generates and returns only one such deviate as a scalar, regardless of the value of $n.
Argument restrictions: $df must be positive.
There are no defaults; both arguments must be provided.
random_exponential($n, $av)
random_exponential($n)
random_exponential()
When called in an array context, returns an array of $n deviates generated from the exponential distribution with mean $av. When called in a scalar context, generates and returns only one such deviate as a scalar, regardless of the value of $n.
Argument restrictions: $av must be non-negative.
Defaults are (1, 1).
random_f($n, $dfn, $dfd)
When called in an array context, returns an array of $n deviates generated from the F (variance ratio) distribution with degrees of freedom $dfn (numerator) and $dfd (denominator). When called in a scalar context, generates and returns only one such deviate as a scalar, regardless of the value of $n.
Argument restrictions: Both $dfn and $dfd must be positive.
There are no defaults; all three arguments must be provided.
random_gamma($n, $a, $r)
When called in an array context, returns an array of $n deviates generated from the gamma distribution with parameters $a and $r. The density of the gamma is:
($a**$r) / Gamma($r) * X**($r - 1) * Exp(-$a*X)
When called in a scalar context, generates and returns only one such deviate as a scalar, regardless of the value of $n.
Argument restrictions: Both $a and $r must be positive.
There are no defaults; all three arguments must be provided.
random_multinomial($n, @p)
When called in an array context, returns single observation from the multinomial distribution, with $n events classified into as many categories as the length of @p. The probability of an event being classified into category i is given by the ith element of @p. The observation is an array with length equal to @p, so when called in a scalar context it returns the length of @p. The sum of the elements of the observation is equal to $n.
Argument restrictions: $n is rounded with int()
before it is used; the result must be non-negative. @p must have length at least 2. All elements of @p except the last must be between 0 and 1 inclusive, and sum to no more than 0.99999. Note: The last element of @p is a dummy to indicate the number of categories, and it is adjusted to bring the sum of the elements of @p to 1.
There are no defaults; both arguments must be provided.
random_multivariate_normal($n, @mean, @covar)
When called in an array context, returns an array of $n deviates (each deviate being an array reference) generated from the multivariate normal distribution with mean vector @mean and variance-covariance matrix @covar. When called in a scalar context, generates and returns only one such deviate as an array reference, regardless of the value of $n.
Argument restrictions: If the dimension of the deviate to be generated is p, @mean should be a length p array of real numbers. @covar should be a length p array of references to length p arrays of real numbers (i.e. a p by p matrix). Further, @covar should be a symmetric positive-definite matrix, although the Perl code does not check positive-definiteness, and the underlying C code assumes the matrix is symmetric. Given that the variance-covariance matrix is symmetric, it doesn't matter if the references refer to rows or columns. If a non-positive definite matrix is passed to the function, it will abort with the following message:
COVM not positive definite in SETGMN
Also, a non-symmetric @covar may produce deviates without complaint, although they may not be from the expected distribution. For these reasons, you are encouraged to verify the arguments passed.
The Perl code does check the dimensionality of @mean and @covar for consistency. It does so by checking that the length of the argument vector passed is odd, that what should be the last element of @mean and the first element of @covar look like they are a number followed by an array reference respectively, and that the arrays referred to in @covar are as long as @mean.
There are no defaults; all three arguments must be provided.
random_negative_binomial($n, $ne, $p)
When called in an array context, returns an array of $n outcomes generated from the negative binomial distribution with number of events $ne and probability of an event in each trial $p. When called in a scalar context, generates and returns only one such outcome as a scalar, regardless of the value of $n.
Argument restrictions: $ne is rounded using int()
, the result must be positive. $p must be between 0 and 1 exclusive.
There are no defaults; both arguments must be provided.
random_noncentral_chi_square($n, $df, $nonc)
When called in an array context, returns an array of $n deviates generated from the noncentral chi-square distribution with $df degrees of freedom and noncentrality parameter $nonc. When called in a scalar context, generates and returns only one such deviate as a scalar, regardless of the value of $n.
Argument restrictions: $df must be at least 1, $nonc must be non-negative.
There are no defaults; all three arguments must be provided.
random_noncentral_f($n, $dfn, $dfd, $nonc)
When called in an array context, returns an array of $n deviates generated from the noncentral F (variance ratio) distribution with degrees of freedom $dfn (numerator) and $dfd (denominator); and noncentrality parameter $nonc. When called in a scalar context, generates and returns only one such deviate as a scalar, regardless of the value of $n.
Argument restrictions: $dfn must be at least 1, $dfd must be positive, and $nonc must be non-negative.
There are no defaults; all four arguments must be provided.
random_poisson($n, $mu)
When called in an array context, returns an array of $n outcomes generated from the Poisson distribution with mean $mu. When called in a scalar context, generates and returns only one such outcome as a scalar, regardless of the value of $n.
Argument restrictions: $mu must be non-negative.
There are no defaults; both arguments must be provided.
The Perl code should croak
if bad arguments are passed or if the underlying C code cannot allocate the necessary memory. The only error which should kill the job without croak
ing is a non-positive definite variance-covariance matrix passed to random_multivarite_normal
(see "Extended Routines").
randlib is available in Fortran and C source form, and will soon be available in Fortran90 source as well. randlib.c can be obtained from statlib. Send mail whose message is 'send randlib.c.shar from general' to:
statlib@lib.stat.cmu.edu
randlib.c can also be obtained by anonymous ftp to:
odin.mdacc.tmc.edu (143.111.62.32)
where it is available as
/pub/source/randlib.c-1.3.tar.gz
For obvious reasons, the original randlib (in Fortran) has been renamed to
/pub/source/randlib.f-1.3.tar.gz
on the same machine.
Our FTP index is on file ./pub/index
.
If you have Internet access and a browser you might note the following web site addresses:
University of Texas M. D. Anderson Cancer Center Home Page:
http://www.mdanderson.org/
Department of Biomathematics Home Page:
http://odin.mdacc.tmc.edu/
Available software:
http://biostatistics.mdanderson.org/SoftwareDownload/
This work was supported in part by grant CA-16672 from the National Cancer Institute. We are grateful to Larry and Pat McNeil of Corpus Cristi for their generous support. Some equipment used in this effort was provided by IBM as part of a cooperative study agreement; we thank them.
The C version of randlib was obtained by translating the original Fortran randlib using PROMULA.FORTRAN, and performing some hand crafting of the result.
Information on PROMULA.FORTRAN can be obtained from:
PROMULA Development Corporation 3620 N. High Street, Suite 301 Columbus, Ohio 43214 (614) 263-5454
wrapper.c (now obsolete) was created by using SWIG, and performing some modification of the result. SWIG also produced the skeleton of Random.pm.
Information on SWIG can be obtained from:
http://www.swig.org
The following routines, which were written by others and lightly modified for consistency in packaging, are included in randlib.
These routines are a transliteration of the Pascal in the reference to Fortran, and thence to C.
L'Ecuyer, P., and Cote, S. "Implementing a Random Number Package with Splitting Facilities." ACM Transactions on Mathematical Software, 17:98-111 (1991).
This code was obtained from Netlib.
Ahrens, J. H., and Dieter, U. "Computer Methods for Sampling from the Exponential and Normal Distributions." Comm. ACM, 15,10 (Oct. 1972), 873-882.
(Case R >= 1.0)
Ahrens, J. H., and Dieter, U. "Generating Gamma Variates by a Modified Rejection Technique." Comm. ACM, 25,1 (Jan. 1982), 47-54. Algorithm GD
(Case 0.0 <= R <= 1.0)
Ahrens, J. H., and Dieter, U. "Computer Methods for Sampling from Gamma, Beta, Poisson and Binomial Distributions." Computing, 12 (1974), 223-246. Adaptation of algorithm GS.
This code was obtained from netlib.
Ahrens, J. H., and Dieter, U. "Extensions of Forsythe's Method for Random Sampling from the Normal Distribution." Math. Comput., 27,124 (Oct. 1973), 927-937.
This code was kindly sent to Dr. Brown by Dr. Kachitvichyanukul.
Kachitvichyanukul, V., and Schmeiser, B. W. "Binomial Random Variate Generation." Comm. ACM, 31, 2 (Feb. 1988), 216.
This code was obtained from netlib.
Ahrens, J. H., and Dieter, U. "Computer Generation of Poisson Deviates from Modified Normal Distributions." ACM Trans. Math. Software, 8, 2 (June 1982), 163-179.
This code was written by us following the recipe in the following.
Cheng, R. C. H. "Generating Beta Variables with Nonintegral Shape Parameters." Comm. ACM, 21:317-322 (1978). (Algorithms BB and BC)
Routines SPOFA
and SDOT
are used to perform the Cholesky decomposition of the covariance matrix in SETGMN
(used for the generation of multivariate normal deviates).
Dongarra, J. J., Moler, C. B., Bunch, J. R., and Stewart, G. W. Linpack User's Guide. SIAM Press, Philadelphia. (1979)
The algorithm is from page 559 of Devroye, Luc Non-Uniform Random Variate Generation. New York: Springer-Verlag, 1986.
The algorithm is from page 480 of Devroye, Luc Non-Uniform Random Variate Generation. New York: Springer-Verlag, 1986.
This POD documents Math::Random version 0.71.
jvenier@mdanderson.org
Department of Biomathematics, Box 237 The University of Texas, M.D. Anderson Cancer Center 1515 Holcombe Boulevard Houston, TX 77030
Code that appeared in an ACM publication is subject to their algorithms policy:
Submittal of an algorithm for publication in one of the ACM Transactions implies that unrestricted use of the algorithm within a computer is permissible. General permission to copy and distribute the algorithm without fee is granted provided that the copies are not made or distributed for direct commercial advantage. The ACM copyright notice and the title of the publication and its date appear, and notice is given that copying is by permission of the Association for Computing Machinery. To copy otherwise, or to republish, requires a fee and/or specific permission.
Krogh, F. "Algorithms Policy." ACM Tran. Math. Softw. 13 (1987), 183-186.
Note, however, that only the particular expression of an algorithm can be copyrighted, not the algorithm per se; see 17 USC 102(b).
We place the Randlib code that we have written in the public domain.
WE PROVIDE ABSOLUTELY NO WARRANTY OF ANY KIND EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. THE ENTIRE RISK AS TO THE QUALITY AND PERFORMANCE OF THE PROGRAM IS WITH YOU. SHOULD THIS PROGRAM PROVE DEFECTIVE, YOU ASSUME THE COST OF ALL NECESSARY SERVICING, REPAIR OR CORRECTION.
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