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

 % File src/library/base/man/agrep.Rd
 % Part of the R package, https://www.R-project.org
 % Copyright 1995-2018 R Core Team
 % Distributed under GPL 2 or later

 \name{agrep}
 \alias{agrep}
 \alias{agrepl}
 \alias{fuzzy matching}
 \alias{.amatch_bounds}
 \alias{.amatch_costs}
 \title{Approximate String Matching (Fuzzy Matching)}
 \description{
   Searches for approximate matches to \code{pattern} (the first argument)
   within each element of the string \code{x} (the second argument) using
   the generalized Levenshtein edit distance (the minimal possibly
   weighted number of insertions, deletions and substitutions needed to
   transform one string into another).
 }
 \usage{
 agrep(pattern, x, max.distance = 0.1, costs = NULL,
       ignore.case = FALSE, value = FALSE, fixed = TRUE,
       useBytes = FALSE)

 agrepl(pattern, x, max.distance = 0.1, costs = NULL,
        ignore.case = FALSE, fixed = TRUE, useBytes = FALSE)
 }
 \arguments{
   \item{pattern}{a non-empty character string or a character string
     containing a regular expression (for \code{fixed = FALSE}) to be
     matched.
     Coerced by \code{\link{as.character}} to a string if possible.}
   \item{x}{character vector where matches are sought.
     Coerced by \code{\link{as.character}} to a character vector if
     possible.}
   \item{max.distance}{Maximum distance allowed for a match.  Expressed
     either as integer, or as a fraction of the \emph{pattern} length
     times the maximal transformation cost (will be replaced by the
     smallest integer not less than the corresponding fraction), or a
     list with possible components
     \describe{
       \item{\code{cost}:}{maximum number/fraction of match cost
 	(generalized Levenshtein distance)}
       \item{\code{all}:}{maximal number/fraction of \emph{all}
 	transformations (insertions, deletions and substitutions)}
       \item{\code{insertions}:}{maximum number/fraction of insertions}
       \item{\code{deletions}:}{maximum number/fraction of deletions}
       \item{\code{substitutions}:}{maximum number/fraction of
         substitutions}
     }
     If \code{cost} is not given, \code{all} defaults to 10\%, and the
     other transformation number bounds default to \code{all}.
     The component names can be abbreviated.
   }
   \item{costs}{a numeric vector or list with names partially matching
     \samp{insertions}, \samp{deletions} and \samp{substitutions} giving
     the respective costs for computing the generalized Levenshtein
     distance, or \code{NULL} (default) indicating using unit cost for
     all three possible transformations.
     Coerced to integer via \code{\link{as.integer}} if possible.}
   \item{ignore.case}{if \code{FALSE}, the pattern matching is \emph{case
       sensitive} and if \code{TRUE}, case is ignored during matching.}
   \item{value}{if \code{FALSE}, a vector containing the (integer)
     indices of the matches determined is returned and if \code{TRUE}, a
     vector containing the matching elements themselves is returned.}
   \item{fixed}{logical.  If \code{TRUE} (default), the pattern is
     matched literally (as is).  Otherwise, it is matched as a regular
     expression.}
   \item{useBytes}{logical. in a multibyte locale, should the comparison
     be character-by-character (the default) or byte-by-byte.}
 }
 \details{
   The Levenshtein edit distance is used as measure of approximateness:
   it is the (possibly cost-weighted) total number of insertions,
   deletions and substitutions required to transform one string into
   another.

   This uses \code{tre} by Ville Laurikari
   (\url{http://laurikari.net/tre/}), which supports MBCS
   character matching.

   The main effect of \code{useBytes} is to avoid errors/warnings about
   invalid inputs and spurious matches in multibyte locales.
   It inhibits the conversion of inputs with marked encodings, and is
   forced if any input is found which is marked as \code{"bytes"} (see
   \code{\link{Encoding}}).
 }
 \note{
   Since someone who read the description carelessly even filed a bug
   report on it, do note that this matches substrings of each element of
   \code{x} (just as \code{\link{grep}} does) and \bold{not} whole
   elements.  See also \code{\link{adist}} in package \pkg{utils}, which
   optionally returns the offsets of the matched substrings.
 }
 \value{
   \code{agrep} returns a vector giving the indices of the elements that
   yielded a match, or, if \code{value} is \code{TRUE}, the matched
   elements (after coercion, preserving names but no other attributes).

   \code{agrepl} returns a logical vector.
 }
 \author{
   Original version in \R < 2.10.0 by David Meyer.
   Current version by Brian Ripley and Kurt Hornik.
 }
 \seealso{
   \code{\link{grep}}, \code{\link{adist}}.
   A different interface to approximate string matching is provided by
   \code{\link{aregexec}()}.
 }
 \examples{
 agrep("lasy", "1 lazy 2")
 agrep("lasy", c(" 1 lazy 2", "1 lasy 2"), max = list(sub = 0))
 agrep("laysy", c("1 lazy", "1", "1 LAZY"), max = 2)
 agrep("laysy", c("1 lazy", "1", "1 LAZY"), max = 2, value = TRUE)
 agrep("laysy", c("1 lazy", "1", "1 LAZY"), max = 2, ignore.case = TRUE)
 }
 \keyword{character}
	% File src/library/base/man/agrep.Rd
	% Part of the R package, https://www.R-project.org
	% Copyright 1995-2018 R Core Team
	% Distributed under GPL 2 or later

	\name{agrep}
	\alias{agrep}
	\alias{agrepl}
	\alias{fuzzy matching}
	\alias{.amatch_bounds}
	\alias{.amatch_costs}
	\title{Approximate String Matching (Fuzzy Matching)}
	\description{
	Searches for approximate matches to \code{pattern} (the first argument)
	within each element of the string \code{x} (the second argument) using
	the generalized Levenshtein edit distance (the minimal possibly
	weighted number of insertions, deletions and substitutions needed to
	transform one string into another).
	}
	\usage{
	agrep(pattern, x, max.distance = 0.1, costs = NULL,
	ignore.case = FALSE, value = FALSE, fixed = TRUE,
	useBytes = FALSE)

	agrepl(pattern, x, max.distance = 0.1, costs = NULL,
	ignore.case = FALSE, fixed = TRUE, useBytes = FALSE)
	}
	\arguments{
	\item{pattern}{a non-empty character string or a character string
	containing a regular expression (for \code{fixed = FALSE}) to be
	matched.
	Coerced by \code{\link{as.character}} to a string if possible.}
	\item{x}{character vector where matches are sought.
	Coerced by \code{\link{as.character}} to a character vector if
	possible.}
	\item{max.distance}{Maximum distance allowed for a match. Expressed
	either as integer, or as a fraction of the \emph{pattern} length
	times the maximal transformation cost (will be replaced by the
	smallest integer not less than the corresponding fraction), or a
	list with possible components
	\describe{
	\item{\code{cost}:}{maximum number/fraction of match cost
	(generalized Levenshtein distance)}
	\item{\code{all}:}{maximal number/fraction of \emph{all}
	transformations (insertions, deletions and substitutions)}
	\item{\code{insertions}:}{maximum number/fraction of insertions}
	\item{\code{deletions}:}{maximum number/fraction of deletions}
	\item{\code{substitutions}:}{maximum number/fraction of
	substitutions}
	}
	If \code{cost} is not given, \code{all} defaults to 10\%, and the
	other transformation number bounds default to \code{all}.
	The component names can be abbreviated.
	}
	\item{costs}{a numeric vector or list with names partially matching
	\samp{insertions}, \samp{deletions} and \samp{substitutions} giving
	the respective costs for computing the generalized Levenshtein
	distance, or \code{NULL} (default) indicating using unit cost for
	all three possible transformations.
	Coerced to integer via \code{\link{as.integer}} if possible.}
	\item{ignore.case}{if \code{FALSE}, the pattern matching is \emph{case
	sensitive} and if \code{TRUE}, case is ignored during matching.}
	\item{value}{if \code{FALSE}, a vector containing the (integer)
	indices of the matches determined is returned and if \code{TRUE}, a
	vector containing the matching elements themselves is returned.}
	\item{fixed}{logical. If \code{TRUE} (default), the pattern is
	matched literally (as is). Otherwise, it is matched as a regular
	expression.}
	\item{useBytes}{logical. in a multibyte locale, should the comparison
	be character-by-character (the default) or byte-by-byte.}
	}
	\details{
	The Levenshtein edit distance is used as measure of approximateness:
	it is the (possibly cost-weighted) total number of insertions,
	deletions and substitutions required to transform one string into
	another.

	This uses \code{tre} by Ville Laurikari
	(\url{http://laurikari.net/tre/}), which supports MBCS
	character matching.

	The main effect of \code{useBytes} is to avoid errors/warnings about
	invalid inputs and spurious matches in multibyte locales.
	It inhibits the conversion of inputs with marked encodings, and is
	forced if any input is found which is marked as \code{"bytes"} (see
	\code{\link{Encoding}}).
	}
	\note{
	Since someone who read the description carelessly even filed a bug
	report on it, do note that this matches substrings of each element of
	\code{x} (just as \code{\link{grep}} does) and \bold{not} whole
	elements. See also \code{\link{adist}} in package \pkg{utils}, which
	optionally returns the offsets of the matched substrings.
	}
	\value{
	\code{agrep} returns a vector giving the indices of the elements that
	yielded a match, or, if \code{value} is \code{TRUE}, the matched
	elements (after coercion, preserving names but no other attributes).

	\code{agrepl} returns a logical vector.
	}
	\author{
	Original version in \R < 2.10.0 by David Meyer.
	Current version by Brian Ripley and Kurt Hornik.
	}
	\seealso{
	\code{\link{grep}}, \code{\link{adist}}.
	A different interface to approximate string matching is provided by
	\code{\link{aregexec}()}.
	}
	\examples{
	agrep("lasy", "1 lazy 2")
	agrep("lasy", c(" 1 lazy 2", "1 lasy 2"), max = list(sub = 0))
	agrep("laysy", c("1 lazy", "1", "1 LAZY"), max = 2)
	agrep("laysy", c("1 lazy", "1", "1 LAZY"), max = 2, value = TRUE)
	agrep("laysy", c("1 lazy", "1", "1 LAZY"), max = 2, ignore.case = TRUE)
	}
	\keyword{character}