src/library/base/man/sample.Rd - R - Git at Google

 % File src/library/base/man/sample.Rd
 % Part of the R package, https://www.R-project.org
 % Copyright 1995-2019 R Core Team
 % Distributed under GPL 2 or later

 \name{sample}
 \alias{sample}
 \alias{sample.int}
 \title{Random Samples and Permutations}
 \description{
   \code{sample} takes a sample of the specified size from the elements
   of \code{x} using either with or without replacement.
 }
 \usage{
 sample(x, size, replace = FALSE, prob = NULL)

 sample.int(n, size = n, replace = FALSE, prob = NULL,
            useHash = (!replace && is.null(prob) && size <= n/2 && n > 1e7))
 }
 \arguments{
   \item{x}{either a vector of one or more elements from which to choose,
     or a positive integer.  See \sQuote{Details.}}
   \item{n}{a positive number, the number of items to choose from.  See
     \sQuote{Details.}}
   \item{size}{a non-negative integer giving the number of items to choose.}
   \item{replace}{should sampling be with replacement?}
   \item{prob}{a vector of probability weights for obtaining the elements
     of the vector being sampled.}
   \item{useHash}{\code{\link{logical}} indicating if the hash-version of
     the algorithm should be used.  Can only be used for \code{replace =
       FALSE}, \code{prob = NULL}, and \code{size <= n/2}, and really
     should be used for large \code{n}, as \code{useHash=FALSE} will use
     memory proportional to \code{n}.}
 }
 \details{
   If \code{x} has length 1, is numeric (in the sense of
   \code{\link{is.numeric}}) and \code{x >= 1}, sampling \emph{via}
   \code{sample} takes place from \code{1:x}.  \emph{Note} that this
   convenience feature may lead to undesired behaviour when \code{x} is
   of varying length in calls such as \code{sample(x)}.  See the examples.

   Otherwise \code{x} can be any \R object for which \code{length} and
   subsetting by integers make sense: S3 or S4 methods for these
   operations will be dispatched as appropriate.

   For \code{sample} the default for \code{size} is the number of items
   inferred from the first argument, so that \code{sample(x)} generates a
   random permutation of the elements of \code{x} (or \code{1:x}).

   It is allowed to ask for \code{size = 0} samples with \code{n = 0} or
   a length-zero \code{x}, but otherwise \code{n > 0} or positive
   \code{length(x)} is required.

   Non-integer positive numerical values of \code{n} or \code{x} will be
   truncated to the next smallest integer, which has to be no larger than
   \code{\link{.Machine}$integer.max}.

   The optional \code{prob} argument can be used to give a vector of
   weights for obtaining the elements of the vector being sampled.  They
   need not sum to one, but they should be non-negative and not all zero.
   If \code{replace} is true, Walker's alias method (Ripley, 1987) is
   used when there are more than 200 reasonably probable values: this
   gives results incompatible with those from \R < 2.2.0.

   If \code{replace} is false, these probabilities are applied
   sequentially, that is the probability of choosing the next item is
   proportional to the weights amongst the remaining items.  The number
   of nonzero weights must be at least \code{size} in this case.

   \code{sample.int} is a bare interface in which both \code{n} and
   \code{size} must be supplied as integers.

   Argument \code{n} can be larger than the largest integer of
   type \code{integer}, up to the largest representable integer in type
   \code{double}.  Only uniform sampling is supported.  Two
   random numbers are used to ensure uniform sampling of large integers.
 }

 \value{
   For \code{sample} a vector of length \code{size} with elements
   drawn from either \code{x} or from the integers \code{1:x}.

   For \code{sample.int}, an integer vector of length \code{size} with
   elements from \code{1:n}, or a double vector if
   \eqn{n \ge 2^{31}}{n >= 2^31}.
 }

 \references{
   Becker, R. A., Chambers, J. M. and Wilks, A. R. (1988)
   \emph{The New S Language}.
   Wadsworth & Brooks/Cole.

   Ripley, B. D. (1987) \emph{Stochastic Simulation}. Wiley.
 }
 \seealso{
   \code{\link{RNGkind}(sample.kind = ..)} about random number generation,
   notably the change of \code{sample()} results with \R version 3.6.0.

   CRAN package \CRANpkg{sampling} for other methods of weighted sampling
   without replacement.
 }
 \examples{
 x <- 1:12
 # a random permutation
 sample(x)
 # bootstrap resampling -- only if length(x) > 1 !
 sample(x, replace = TRUE)

 # 100 Bernoulli trials
 sample(c(0,1), 100, replace = TRUE)

 ## More careful bootstrapping --  Consider this when using sample()
 ## programmatically (i.e., in your function or simulation)!

 # sample()'s surprise -- example
 x <- 1:10
     sample(x[x >  8]) # length 2
     sample(x[x >  9]) # oops -- length 10!
     sample(x[x > 10]) # length 0

 ## safer version:
 resample <- function(x, ...) x[sample.int(length(x), ...)]
 resample(x[x >  8]) # length 2
 resample(x[x >  9]) # length 1
 resample(x[x > 10]) # length 0

 ## R 3.x.y only
 sample.int(1e10, 12, replace = TRUE)
 sample.int(1e10, 12) # not that there is much chance of duplicates
 }
 \keyword{distribution}
	% File src/library/base/man/sample.Rd
	% Part of the R package, https://www.R-project.org
	% Copyright 1995-2019 R Core Team
	% Distributed under GPL 2 or later

	\name{sample}
	\alias{sample}
	\alias{sample.int}
	\title{Random Samples and Permutations}
	\description{
	\code{sample} takes a sample of the specified size from the elements
	of \code{x} using either with or without replacement.
	}
	\usage{
	sample(x, size, replace = FALSE, prob = NULL)

	sample.int(n, size = n, replace = FALSE, prob = NULL,
	useHash = (!replace && is.null(prob) && size <= n/2 && n > 1e7))
	}
	\arguments{
	\item{x}{either a vector of one or more elements from which to choose,
	or a positive integer. See \sQuote{Details.}}
	\item{n}{a positive number, the number of items to choose from. See
	\sQuote{Details.}}
	\item{size}{a non-negative integer giving the number of items to choose.}
	\item{replace}{should sampling be with replacement?}
	\item{prob}{a vector of probability weights for obtaining the elements
	of the vector being sampled.}
	\item{useHash}{\code{\link{logical}} indicating if the hash-version of
	the algorithm should be used. Can only be used for \code{replace =
	FALSE}, \code{prob = NULL}, and \code{size <= n/2}, and really
	should be used for large \code{n}, as \code{useHash=FALSE} will use
	memory proportional to \code{n}.}
	}
	\details{
	If \code{x} has length 1, is numeric (in the sense of
	\code{\link{is.numeric}}) and \code{x >= 1}, sampling \emph{via}
	\code{sample} takes place from \code{1:x}. \emph{Note} that this
	convenience feature may lead to undesired behaviour when \code{x} is
	of varying length in calls such as \code{sample(x)}. See the examples.

	Otherwise \code{x} can be any \R object for which \code{length} and
	subsetting by integers make sense: S3 or S4 methods for these
	operations will be dispatched as appropriate.

	For \code{sample} the default for \code{size} is the number of items
	inferred from the first argument, so that \code{sample(x)} generates a
	random permutation of the elements of \code{x} (or \code{1:x}).

	It is allowed to ask for \code{size = 0} samples with \code{n = 0} or
	a length-zero \code{x}, but otherwise \code{n > 0} or positive
	\code{length(x)} is required.

	Non-integer positive numerical values of \code{n} or \code{x} will be
	truncated to the next smallest integer, which has to be no larger than
	\code{\link{.Machine}$integer.max}.

	The optional \code{prob} argument can be used to give a vector of
	weights for obtaining the elements of the vector being sampled. They
	need not sum to one, but they should be non-negative and not all zero.
	If \code{replace} is true, Walker's alias method (Ripley, 1987) is
	used when there are more than 200 reasonably probable values: this
	gives results incompatible with those from \R < 2.2.0.

	If \code{replace} is false, these probabilities are applied
	sequentially, that is the probability of choosing the next item is
	proportional to the weights amongst the remaining items. The number
	of nonzero weights must be at least \code{size} in this case.

	\code{sample.int} is a bare interface in which both \code{n} and
	\code{size} must be supplied as integers.

	Argument \code{n} can be larger than the largest integer of
	type \code{integer}, up to the largest representable integer in type
	\code{double}. Only uniform sampling is supported. Two
	random numbers are used to ensure uniform sampling of large integers.
	}

	\value{
	For \code{sample} a vector of length \code{size} with elements
	drawn from either \code{x} or from the integers \code{1:x}.

	For \code{sample.int}, an integer vector of length \code{size} with
	elements from \code{1:n}, or a double vector if
	\eqn{n \ge 2^{31}}{n >= 2^31}.
	}

	\references{
	Becker, R. A., Chambers, J. M. and Wilks, A. R. (1988)
	\emph{The New S Language}.
	Wadsworth & Brooks/Cole.

	Ripley, B. D. (1987) \emph{Stochastic Simulation}. Wiley.
	}
	\seealso{
	\code{\link{RNGkind}(sample.kind = ..)} about random number generation,
	notably the change of \code{sample()} results with \R version 3.6.0.

	CRAN package \CRANpkg{sampling} for other methods of weighted sampling
	without replacement.
	}
	\examples{
	x <- 1:12
	# a random permutation
	sample(x)
	# bootstrap resampling -- only if length(x) > 1 !
	sample(x, replace = TRUE)

	# 100 Bernoulli trials
	sample(c(0,1), 100, replace = TRUE)

	## More careful bootstrapping -- Consider this when using sample()
	## programmatically (i.e., in your function or simulation)!

	# sample()'s surprise -- example
	x <- 1:10
	sample(x[x > 8]) # length 2
	sample(x[x > 9]) # oops -- length 10!
	sample(x[x > 10]) # length 0

	## safer version:
	resample <- function(x, ...) x[sample.int(length(x), ...)]
	resample(x[x > 8]) # length 2
	resample(x[x > 9]) # length 1
	resample(x[x > 10]) # length 0

	## R 3.x.y only
	sample.int(1e10, 12, replace = TRUE)
	sample.int(1e10, 12) # not that there is much chance of duplicates
	}
	\keyword{distribution}