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

 % File src/library/base/man/cut.Rd
 % Part of the R package, https://www.R-project.org
 % Copyright 1995-2014 R Core Team
 % Distributed under GPL 2 or later

 \name{cut}
 \title{Convert Numeric to Factor}
 \usage{
 cut(x, \dots)

 \method{cut}{default}(x, breaks, labels = NULL,
     include.lowest = FALSE, right = TRUE, dig.lab = 3,
     ordered_result = FALSE, \dots)
 }
 \alias{cut}
 \alias{cut.default}
 \arguments{
   \item{x}{a numeric vector which is to be converted to a factor by cutting.}
   \item{breaks}{either a numeric vector of two or more unique cut points or a
     single number (greater than or equal to 2) giving the number of
     intervals into which \code{x} is to be cut.}
   \item{labels}{labels for the levels of the resulting category.  By default,
     labels are constructed using \code{"(a,b]"} interval notation.  If
     \code{labels = FALSE}, simple integer codes are returned instead of
     a factor.}
   \item{include.lowest}{logical, indicating if an \sQuote{x[i]} equal to
     the lowest (or highest, for \code{right = FALSE}) \sQuote{breaks}
     value should be included.}
   \item{right}{logical, indicating if the intervals should be closed on
     the right (and open on the left) or vice versa.}
   \item{dig.lab}{integer which is used when labels are not given.  It
     determines the number of digits used in formatting the break numbers.}
   \item{ordered_result}{logical: should the result be an ordered factor?}
   \item{\dots}{further arguments passed to or from other methods.}
 }
 \description{
   \code{cut} divides the range of \code{x} into intervals
   and codes the values in \code{x} according to which
   interval they fall.  The leftmost interval corresponds to level one,
   the next leftmost to level two and so on.
 }
 \details{
   When \code{breaks} is specified as a single number, the range of the
   data is divided into \code{breaks} pieces of equal length, and then
   the outer limits are moved away by 0.1\% of the range to ensure that
   the extreme values both fall within the break intervals.  (If \code{x}
   is a constant vector, equal-length intervals are created, one of
   which includes the single value.)

   If a \code{labels} parameter is specified, its values are used to name
   the factor levels.  If none is specified, the factor level labels are
   constructed as \code{"(b1, b2]"}, \code{"(b2, b3]"} etc. for
   \code{right = TRUE} and as \code{"[b1, b2)"}, \ldots if \code{right =
     FALSE}.
   In this case, \code{dig.lab} indicates the minimum number of digits
   should be used in formatting the numbers \code{b1}, \code{b2}, \ldots.
   A larger value (up to 12) will be used if needed to distinguish
   between any pair of endpoints: if this fails labels such as
   \code{"Range3"} will be used.  Formatting is done by
   \code{\link{formatC}}.

   The default method will sort a numeric vector of \code{breaks}, but
   other methods are not required to and \code{labels} will correspond to
   the intervals after sorting.

   As from \R 3.2.0, \code{getOption("OutDec")} is consulted when labels
   are constructed for \code{labels = NULL}.
 }
 \value{
   A \code{\link{factor}} is returned, unless \code{labels = FALSE} which
   results in an integer vector of level codes.

   Values which fall outside the range of \code{breaks} are coded as
   \code{NA}, as are \code{NaN} and \code{NA} values.
 }
 \note{
   Instead of \code{table(cut(x, br))}, \code{hist(x, br, plot = FALSE)} is
   more efficient and less memory hungry.  Instead of \code{cut(*,
     labels = FALSE)}, \code{\link{findInterval}()} is more efficient.
 }
 \references{
   Becker, R. A., Chambers, J. M. and Wilks, A. R. (1988)
   \emph{The New S Language}.
   Wadsworth & Brooks/Cole.
 }
 \seealso{
   \code{\link{split}} for splitting a variable according to a group factor;
   \code{\link{factor}}, \code{\link{tabulate}}, \code{\link{table}},
   \code{\link{findInterval}}.

   \code{\link{quantile}} for ways of choosing breaks of roughly equal
   content (rather than length).

   \code{\link{.bincode}} for a bare-bones version.
 }
 \examples{
 Z <- stats::rnorm(10000)
 table(cut(Z, breaks = -6:6))
 sum(table(cut(Z, breaks = -6:6, labels = FALSE)))
 sum(graphics::hist(Z, breaks = -6:6, plot = FALSE)$counts)

 cut(rep(1,5), 4) #-- dummy
 tx0 <- c(9, 4, 6, 5, 3, 10, 5, 3, 5)
 x <- rep(0:8, tx0)
 stopifnot(table(x) == tx0)

 table( cut(x, b = 8))
 table( cut(x, breaks = 3*(-2:5)))
 table( cut(x, breaks = 3*(-2:5), right = FALSE))

 ##--- some values OUTSIDE the breaks :
 table(cx  <- cut(x, breaks = 2*(0:4)))
 table(cxl <- cut(x, breaks = 2*(0:4), right = FALSE))
 which(is.na(cx));  x[is.na(cx)]  #-- the first 9  values  0
 which(is.na(cxl)); x[is.na(cxl)] #-- the last  5  values  8


 ## Label construction:
 y <- stats::rnorm(100)
 table(cut(y, breaks = pi/3*(-3:3)))
 table(cut(y, breaks = pi/3*(-3:3), dig.lab = 4))

 table(cut(y, breaks =  1*(-3:3), dig.lab = 4))
 # extra digits don't "harm" here
 table(cut(y, breaks =  1*(-3:3), right = FALSE))
 #- the same, since no exact INT!

 ## sometimes the default dig.lab is not enough to be avoid confusion:
 aaa <- c(1,2,3,4,5,2,3,4,5,6,7)
 cut(aaa, 3)
 cut(aaa, 3, dig.lab = 4, ordered = TRUE)

 ## one way to extract the breakpoints
 labs <- levels(cut(aaa, 3))
 cbind(lower = as.numeric( sub("\\\\((.+),.*", "\\\\1", labs) ),
       upper = as.numeric( sub("[^,]*,([^]]*)\\\\]", "\\\\1", labs) ))
 }
 \keyword{category}
	% File src/library/base/man/cut.Rd
	% Part of the R package, https://www.R-project.org
	% Copyright 1995-2014 R Core Team
	% Distributed under GPL 2 or later

	\name{cut}
	\title{Convert Numeric to Factor}
	\usage{
	cut(x, \dots)

	\method{cut}{default}(x, breaks, labels = NULL,
	include.lowest = FALSE, right = TRUE, dig.lab = 3,
	ordered_result = FALSE, \dots)
	}
	\alias{cut}
	\alias{cut.default}
	\arguments{
	\item{x}{a numeric vector which is to be converted to a factor by cutting.}
	\item{breaks}{either a numeric vector of two or more unique cut points or a
	single number (greater than or equal to 2) giving the number of
	intervals into which \code{x} is to be cut.}
	\item{labels}{labels for the levels of the resulting category. By default,
	labels are constructed using \code{"(a,b]"} interval notation. If
	\code{labels = FALSE}, simple integer codes are returned instead of
	a factor.}
	\item{include.lowest}{logical, indicating if an \sQuote{x[i]} equal to
	the lowest (or highest, for \code{right = FALSE}) \sQuote{breaks}
	value should be included.}
	\item{right}{logical, indicating if the intervals should be closed on
	the right (and open on the left) or vice versa.}
	\item{dig.lab}{integer which is used when labels are not given. It
	determines the number of digits used in formatting the break numbers.}
	\item{ordered_result}{logical: should the result be an ordered factor?}
	\item{\dots}{further arguments passed to or from other methods.}
	}
	\description{
	\code{cut} divides the range of \code{x} into intervals
	and codes the values in \code{x} according to which
	interval they fall. The leftmost interval corresponds to level one,
	the next leftmost to level two and so on.
	}
	\details{
	When \code{breaks} is specified as a single number, the range of the
	data is divided into \code{breaks} pieces of equal length, and then
	the outer limits are moved away by 0.1\% of the range to ensure that
	the extreme values both fall within the break intervals. (If \code{x}
	is a constant vector, equal-length intervals are created, one of
	which includes the single value.)

	If a \code{labels} parameter is specified, its values are used to name
	the factor levels. If none is specified, the factor level labels are
	constructed as \code{"(b1, b2]"}, \code{"(b2, b3]"} etc. for
	\code{right = TRUE} and as \code{"[b1, b2)"}, \ldots if \code{right =
	FALSE}.
	In this case, \code{dig.lab} indicates the minimum number of digits
	should be used in formatting the numbers \code{b1}, \code{b2}, \ldots.
	A larger value (up to 12) will be used if needed to distinguish
	between any pair of endpoints: if this fails labels such as
	\code{"Range3"} will be used. Formatting is done by
	\code{\link{formatC}}.

	The default method will sort a numeric vector of \code{breaks}, but
	other methods are not required to and \code{labels} will correspond to
	the intervals after sorting.

	As from \R 3.2.0, \code{getOption("OutDec")} is consulted when labels
	are constructed for \code{labels = NULL}.
	}
	\value{
	A \code{\link{factor}} is returned, unless \code{labels = FALSE} which
	results in an integer vector of level codes.

	Values which fall outside the range of \code{breaks} are coded as
	\code{NA}, as are \code{NaN} and \code{NA} values.
	}
	\note{
	Instead of \code{table(cut(x, br))}, \code{hist(x, br, plot = FALSE)} is
	more efficient and less memory hungry. Instead of \code{cut(*,
	labels = FALSE)}, \code{\link{findInterval}()} is more efficient.
	}
	\references{
	Becker, R. A., Chambers, J. M. and Wilks, A. R. (1988)
	\emph{The New S Language}.
	Wadsworth & Brooks/Cole.
	}
	\seealso{
	\code{\link{split}} for splitting a variable according to a group factor;
	\code{\link{factor}}, \code{\link{tabulate}}, \code{\link{table}},
	\code{\link{findInterval}}.

	\code{\link{quantile}} for ways of choosing breaks of roughly equal
	content (rather than length).

	\code{\link{.bincode}} for a bare-bones version.
	}
	\examples{
	Z <- stats::rnorm(10000)
	table(cut(Z, breaks = -6:6))
	sum(table(cut(Z, breaks = -6:6, labels = FALSE)))
	sum(graphics::hist(Z, breaks = -6:6, plot = FALSE)$counts)

	cut(rep(1,5), 4) #-- dummy
	tx0 <- c(9, 4, 6, 5, 3, 10, 5, 3, 5)
	x <- rep(0:8, tx0)
	stopifnot(table(x) == tx0)

	table( cut(x, b = 8))
	table( cut(x, breaks = 3*(-2:5)))
	table( cut(x, breaks = 3*(-2:5), right = FALSE))

	##--- some values OUTSIDE the breaks :
	table(cx <- cut(x, breaks = 2*(0:4)))
	table(cxl <- cut(x, breaks = 2*(0:4), right = FALSE))
	which(is.na(cx)); x[is.na(cx)] #-- the first 9 values 0
	which(is.na(cxl)); x[is.na(cxl)] #-- the last 5 values 8


	## Label construction:
	y <- stats::rnorm(100)
	table(cut(y, breaks = pi/3*(-3:3)))
	table(cut(y, breaks = pi/3*(-3:3), dig.lab = 4))

	table(cut(y, breaks = 1*(-3:3), dig.lab = 4))
	# extra digits don't "harm" here
	table(cut(y, breaks = 1*(-3:3), right = FALSE))
	#- the same, since no exact INT!

	## sometimes the default dig.lab is not enough to be avoid confusion:
	aaa <- c(1,2,3,4,5,2,3,4,5,6,7)
	cut(aaa, 3)
	cut(aaa, 3, dig.lab = 4, ordered = TRUE)

	## one way to extract the breakpoints
	labs <- levels(cut(aaa, 3))
	cbind(lower = as.numeric( sub("\\\\((.+),.*", "\\\\1", labs) ),
	upper = as.numeric( sub("[^,],([^]])\\\\]", "\\\\1", labs) ))
	}
	\keyword{category}