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

 % File src/library/base/man/funprog.Rd
 % Part of the R package, https://www.R-project.org
 % Copyright 1995-2016 R Core Team
 % Distributed under GPL 2 or later
 \name{funprog}
 \alias{Filter}
 \alias{Find}
 \alias{Map}
 \alias{Negate}
 \alias{Reduce}
 \alias{Position}
 \title{Common Higher-Order Functions in Functional Programming Languages}
 \description{
   \code{Reduce} uses a binary function to successively combine the
   elements of a given vector and a possibly given initial value.
   \code{Filter} extracts the elements of a vector for which a predicate
   (logical) function gives true.  \code{Find} and \code{Position} give
   the first or last such element and its position in the vector,
   respectively.  \code{Map} applies a function to the corresponding
   elements of given vectors.  \code{Negate} creates the negation of a
   given function.
 }
 \usage{
 Reduce(f, x, init, right = FALSE, accumulate = FALSE)
 Filter(f, x)
 Find(f, x, right = FALSE, nomatch = NULL)
 Map(f, ...)
 Negate(f)
 Position(f, x, right = FALSE, nomatch = NA_integer_)
 }
 \arguments{
   \item{f}{a function of the appropriate arity (binary for
     \code{Reduce}, unary for \code{Filter}, \code{Find} and
     \code{Position}, \eqn{k}-ary for \code{Map} if this is called with
     \eqn{k} arguments).  An arbitrary predicate function for
     \code{Negate}.}
   \item{x}{a vector.}
   \item{init}{an \R object of the same kind as the elements of
     \code{x}.}
   \item{right}{a logical indicating whether to proceed from left to
     right (default) or from right to left.}
   \item{accumulate}{a logical indicating whether the successive reduce
     combinations should be accumulated.  By default, only the final
     combination is used.}
   \item{nomatch}{the value to be returned in the case when
     \dQuote{no match} (no element satisfying the predicate) is found.}
   \item{\dots}{vectors.}
 }
 \details{
   If \code{init} is given, \code{Reduce} logically adds it to the start
   (when proceeding left to right) or the end of \code{x}, respectively.
   If this possibly augmented vector \eqn{v} has \eqn{n > 1} elements,
   \code{Reduce} successively applies \eqn{f} to the elements of \eqn{v}
   from left to right or right to left, respectively.  I.e., a left
   reduce computes \eqn{l_1 = f(v_1, v_2)}, \eqn{l_2 = f(l_1, v_3)}, etc.,
   and returns \eqn{l_{n-1} = f(l_{n-2}, v_n)}, and a right reduce does
   \eqn{r_{n-1} = f(v_{n-1}, v_n)}, \eqn{r_{n-2} = f(v_{n-2}, r_{n-1})}
   and returns \eqn{r_1 = f(v_1, r_2)}.  (E.g., if \eqn{v} is the
   sequence (2, 3, 4) and \eqn{f} is division, left and right reduce give
   \eqn{(2 / 3) / 4 = 1/6} and \eqn{2 / (3 / 4) = 8/3}, respectively.)
   If \eqn{v} has only a single element, this is returned; if there are
   no elements, \code{NULL} is returned.  Thus, it is ensured that
   \code{f} is always called with 2 arguments.

   The current implementation is non-recursive to ensure stability and
   scalability.

   \code{Reduce} is patterned after Common Lisp's \code{reduce}.  A
   reduce is also known as a fold (e.g., in Haskell) or an accumulate
   (e.g., in the C++ Standard Template Library).  The accumulative
   version corresponds to Haskell's scan functions.

   \code{Filter} applies the unary predicate function \code{f} to each
   element of \code{x}, coercing to logical if necessary, and returns the
   subset of \code{x} for which this gives true.  Note that possible
   \code{NA} values are currently always taken as false; control over
   \code{NA} handling may be added in the future.  \code{Filter}
   corresponds to \code{filter} in Haskell or \code{remove-if-not} in
   Common Lisp.

   \code{Find} and \code{Position} are patterned after Common Lisp's
   \code{find-if} and \code{position-if}, respectively.  If there is an
   element for which the predicate function gives true, then the first or
   last such element or its position is returned depending on whether
   \code{right} is false (default) or true, respectively.  If there is no
   such element, the value specified by \code{nomatch} is returned.  The
   current implementation is not optimized for performance.

   \code{Map} is a simple wrapper to \code{\link{mapply}} which does not
   attempt to simplify the result, similar to Common Lisp's \code{mapcar}
   (with arguments being recycled, however).  Future versions may allow
   some control of the result type.

   \code{Negate} corresponds to Common Lisp's \code{complement}.  Given a
   (predicate) function \code{f}, it creates a function which returns the
   logical negation of what \code{f} returns.
 }

 \seealso{
   Function \code{\link{clusterMap}} and \code{\link{mcmapply}} (not
   Windows) in package \pkg{parallel} provide parallel versions of \code{Map}.
 }

 \examples{
 ## A general-purpose adder:
 add <- function(x) Reduce("+", x)
 add(list(1, 2, 3))
 ## Like sum(), but can also used for adding matrices etc., as it will
 ## use the appropriate '+' method in each reduction step.
 ## More generally, many generics meant to work on arbitrarily many
 ## arguments can be defined via reduction:
 FOO <- function(...) Reduce(FOO2, list(...))
 FOO2 <- function(x, y) UseMethod("FOO2")
 ## FOO() methods can then be provided via FOO2() methods.

 ## A general-purpose cumulative adder:
 cadd <- function(x) Reduce("+", x, accumulate = TRUE)
 cadd(seq_len(7))

 ## A simple function to compute continued fractions:
 cfrac <- function(x) Reduce(function(u, v) u + 1 / v, x, right = TRUE)
 ## Continued fraction approximation for pi:
 cfrac(c(3, 7, 15, 1, 292))
 ## Continued fraction approximation for Euler's number (e):
 cfrac(c(2, 1, 2, 1, 1, 4, 1, 1, 6, 1, 1, 8))

 ## Iterative function application:
 Funcall <- function(f, ...) f(...)
 ## Compute log(exp(acos(cos(0))))
 Reduce(Funcall, list(log, exp, acos, cos), 0, right = TRUE)
 ## n-fold iterate of a function, functional style:
 Iterate <- function(f, n = 1)
     function(x) Reduce(Funcall, rep.int(list(f), n), x, right = TRUE)
 ## Continued fraction approximation to the golden ratio:
 Iterate(function(x) 1 + 1 / x, 30)(1)
 ## which is the same as
 cfrac(rep.int(1, 31))
 ## Computing square root approximations for x as fixed points of the
 ## function t |-> (t + x / t) / 2, as a function of the initial value:
 asqrt <- function(x, n) Iterate(function(t) (t + x / t) / 2, n)
 asqrt(2, 30)(10) # Starting from a positive value => +sqrt(2)
 asqrt(2, 30)(-1) # Starting from a negative value => -sqrt(2)

 ## A list of all functions in the base environment:
 funs <- Filter(is.function, sapply(ls(baseenv()), get, baseenv()))
 ## Functions in base with more than 10 arguments:
 names(Filter(function(f) length(formals(f)) > 10, funs))
 ## Number of functions in base with a '...' argument:
 length(Filter(function(f)
               any(names(formals(f)) \%in\% "..."),
               funs))
 \donttest{
 ## Find all objects in the base environment which are *not* functions:
 Filter(Negate(is.function),  sapply(ls(baseenv()), get, baseenv()))
 }}
 \keyword{programming}
	% File src/library/base/man/funprog.Rd
	% Part of the R package, https://www.R-project.org
	% Copyright 1995-2016 R Core Team
	% Distributed under GPL 2 or later
	\name{funprog}
	\alias{Filter}
	\alias{Find}
	\alias{Map}
	\alias{Negate}
	\alias{Reduce}
	\alias{Position}
	\title{Common Higher-Order Functions in Functional Programming Languages}
	\description{
	\code{Reduce} uses a binary function to successively combine the
	elements of a given vector and a possibly given initial value.
	\code{Filter} extracts the elements of a vector for which a predicate
	(logical) function gives true. \code{Find} and \code{Position} give
	the first or last such element and its position in the vector,
	respectively. \code{Map} applies a function to the corresponding
	elements of given vectors. \code{Negate} creates the negation of a
	given function.
	}
	\usage{
	Reduce(f, x, init, right = FALSE, accumulate = FALSE)
	Filter(f, x)
	Find(f, x, right = FALSE, nomatch = NULL)
	Map(f, ...)
	Negate(f)
	Position(f, x, right = FALSE, nomatch = NA_integer_)
	}
	\arguments{
	\item{f}{a function of the appropriate arity (binary for
	\code{Reduce}, unary for \code{Filter}, \code{Find} and
	\code{Position}, \eqn{k}-ary for \code{Map} if this is called with
	\eqn{k} arguments). An arbitrary predicate function for
	\code{Negate}.}
	\item{x}{a vector.}
	\item{init}{an \R object of the same kind as the elements of
	\code{x}.}
	\item{right}{a logical indicating whether to proceed from left to
	right (default) or from right to left.}
	\item{accumulate}{a logical indicating whether the successive reduce
	combinations should be accumulated. By default, only the final
	combination is used.}
	\item{nomatch}{the value to be returned in the case when
	\dQuote{no match} (no element satisfying the predicate) is found.}
	\item{\dots}{vectors.}
	}
	\details{
	If \code{init} is given, \code{Reduce} logically adds it to the start
	(when proceeding left to right) or the end of \code{x}, respectively.
	If this possibly augmented vector \eqn{v} has \eqn{n > 1} elements,
	\code{Reduce} successively applies \eqn{f} to the elements of \eqn{v}
	from left to right or right to left, respectively. I.e., a left
	reduce computes \eqn{l_1 = f(v_1, v_2)}, \eqn{l_2 = f(l_1, v_3)}, etc.,
	and returns \eqn{l_{n-1} = f(l_{n-2}, v_n)}, and a right reduce does
	\eqn{r_{n-1} = f(v_{n-1}, v_n)}, \eqn{r_{n-2} = f(v_{n-2}, r_{n-1})}
	and returns \eqn{r_1 = f(v_1, r_2)}. (E.g., if \eqn{v} is the
	sequence (2, 3, 4) and \eqn{f} is division, left and right reduce give
	\eqn{(2 / 3) / 4 = 1/6} and \eqn{2 / (3 / 4) = 8/3}, respectively.)
	If \eqn{v} has only a single element, this is returned; if there are
	no elements, \code{NULL} is returned. Thus, it is ensured that
	\code{f} is always called with 2 arguments.

	The current implementation is non-recursive to ensure stability and
	scalability.

	\code{Reduce} is patterned after Common Lisp's \code{reduce}. A
	reduce is also known as a fold (e.g., in Haskell) or an accumulate
	(e.g., in the C++ Standard Template Library). The accumulative
	version corresponds to Haskell's scan functions.

	\code{Filter} applies the unary predicate function \code{f} to each
	element of \code{x}, coercing to logical if necessary, and returns the
	subset of \code{x} for which this gives true. Note that possible
	\code{NA} values are currently always taken as false; control over
	\code{NA} handling may be added in the future. \code{Filter}
	corresponds to \code{filter} in Haskell or \code{remove-if-not} in
	Common Lisp.

	\code{Find} and \code{Position} are patterned after Common Lisp's
	\code{find-if} and \code{position-if}, respectively. If there is an
	element for which the predicate function gives true, then the first or
	last such element or its position is returned depending on whether
	\code{right} is false (default) or true, respectively. If there is no
	such element, the value specified by \code{nomatch} is returned. The
	current implementation is not optimized for performance.

	\code{Map} is a simple wrapper to \code{\link{mapply}} which does not
	attempt to simplify the result, similar to Common Lisp's \code{mapcar}
	(with arguments being recycled, however). Future versions may allow
	some control of the result type.

	\code{Negate} corresponds to Common Lisp's \code{complement}. Given a
	(predicate) function \code{f}, it creates a function which returns the
	logical negation of what \code{f} returns.
	}

	\seealso{
	Function \code{\link{clusterMap}} and \code{\link{mcmapply}} (not
	Windows) in package \pkg{parallel} provide parallel versions of \code{Map}.
	}

	\examples{
	## A general-purpose adder:
	add <- function(x) Reduce("+", x)
	add(list(1, 2, 3))
	## Like sum(), but can also used for adding matrices etc., as it will
	## use the appropriate '+' method in each reduction step.
	## More generally, many generics meant to work on arbitrarily many
	## arguments can be defined via reduction:
	FOO <- function(...) Reduce(FOO2, list(...))
	FOO2 <- function(x, y) UseMethod("FOO2")
	## FOO() methods can then be provided via FOO2() methods.

	## A general-purpose cumulative adder:
	cadd <- function(x) Reduce("+", x, accumulate = TRUE)
	cadd(seq_len(7))

	## A simple function to compute continued fractions:
	cfrac <- function(x) Reduce(function(u, v) u + 1 / v, x, right = TRUE)
	## Continued fraction approximation for pi:
	cfrac(c(3, 7, 15, 1, 292))
	## Continued fraction approximation for Euler's number (e):
	cfrac(c(2, 1, 2, 1, 1, 4, 1, 1, 6, 1, 1, 8))

	## Iterative function application:
	Funcall <- function(f, ...) f(...)
	## Compute log(exp(acos(cos(0))))
	Reduce(Funcall, list(log, exp, acos, cos), 0, right = TRUE)
	## n-fold iterate of a function, functional style:
	Iterate <- function(f, n = 1)
	function(x) Reduce(Funcall, rep.int(list(f), n), x, right = TRUE)
	## Continued fraction approximation to the golden ratio:
	Iterate(function(x) 1 + 1 / x, 30)(1)
	## which is the same as
	cfrac(rep.int(1, 31))
	## Computing square root approximations for x as fixed points of the
	## function t \|-> (t + x / t) / 2, as a function of the initial value:
	asqrt <- function(x, n) Iterate(function(t) (t + x / t) / 2, n)
	asqrt(2, 30)(10) # Starting from a positive value => +sqrt(2)
	asqrt(2, 30)(-1) # Starting from a negative value => -sqrt(2)

	## A list of all functions in the base environment:
	funs <- Filter(is.function, sapply(ls(baseenv()), get, baseenv()))
	## Functions in base with more than 10 arguments:
	names(Filter(function(f) length(formals(f)) > 10, funs))
	## Number of functions in base with a '...' argument:
	length(Filter(function(f)
	any(names(formals(f)) \%in\% "..."),
	funs))
	\donttest{
	## Find all objects in the base environment which are not functions:
	Filter(Negate(is.function), sapply(ls(baseenv()), get, baseenv()))
	}}
	\keyword{programming}