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

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

 \name{UseMethod}
 \title{Class Methods}
 \alias{UseMethod}
 \alias{NextMethod}
 \alias{S3Methods}
 \alias{.Method}
 \alias{.Generic}
 \alias{.Class}
 \description{
   \R possesses a simple generic function mechanism which can be used for
   an object-oriented style of programming.  Method dispatch takes place
   based on the class(es) of the first argument to the generic function or of
   the object supplied as an argument to \code{UseMethod} or \code{NextMethod}.
 }
 \usage{
 UseMethod(generic, object)

 NextMethod(generic = NULL, object = NULL, \dots)
 }
 \arguments{
   \item{generic}{a character string naming a function (and not a
     built-in operator).  Required for \code{UseMethod}.}
   \item{object}{for \code{UseMethod}: an object whose class will
     determine the method to be dispatched.  Defaults to the first
     argument of the enclosing function.}
   \item{\dots}{further arguments to be passed to the next method.}
 }
 \details{
   An \R object is a data object which has a \code{class}
   attribute (and this can be tested by \code{\link{is.object}}).
   A class attribute is a character vector giving the names of
   the classes from which the object \emph{inherits}.
   If the object does not have a class attribute, it has an implicit
   class.  Matrices and arrays have class \code{"matrix"}
   or\code{"array"} followed by the class of the underlying vector.
   Most vectors have class the result of \code{\link{mode}(x)}, except
   that integer vectors have class \code{c("integer", "numeric")} and
   real vectors have class \code{c("double", "numeric")}.

   When a function calling \code{UseMethod("fun")} is applied to an
   object with class attribute \code{c("first", "second")}, the system
   searches for a function called \code{fun.first} and, if it finds it,
   applies it to the object.  If no such function is found a function
   called \code{fun.second} is tried.  If no class name produces a
   suitable function, the function \code{fun.default} is used, if it
   exists, or an error results.

   Function \code{\link{methods}} can be used to find out about the
   methods for a particular generic function or class.

   \code{UseMethod} is a primitive function but uses standard argument
   matching.  It is not the only means of dispatch of methods, for there
   are \link{internal generic} and \link{group generic} functions.
   \code{UseMethod} currently dispatches on the implicit class even for
   arguments that are not objects, but the other means of dispatch do
   not.

   \code{NextMethod} invokes the next method (determined by the
   class vector, either of the object supplied to the generic, or of
   the first argument to the function containing \code{NextMethod} if a
   method was invoked directly).  Normally \code{NextMethod} is used with
   only one argument, \code{generic}, but if further arguments are
   supplied these modify the call to the next method.

   \code{NextMethod} should not be called except in methods called by
   \code{UseMethod} or from internal generics (see
   \link{InternalGenerics}).  In particular it will not work inside
   anonymous calling functions (e.g., \code{get("print.ts")(AirPassengers)}).

   Namespaces can register methods for generic functions.  To support
   this, \code{UseMethod} and \code{NextMethod} search for methods in
   two places: in the environment in which the generic function
   is called, and in the registration data base for the
   environment in which the generic is defined (typically a namespace).
   So methods for a generic function need to be available in the
   environment of the call to the generic, or they must be registered.
   (It does not matter whether they are visible in the environment in
   which the generic is defined.)  As from \R 3.5.0, the registration
   data base is searched after the top level environment (see
   \code{\link{topenv}}) of the calling environment (but before the
   parents of the top level environment).
 }
 \section{Technical Details}{
   Now for some obscure details that need to appear somewhere.  These
   comments will be slightly different than those in Chambers(1992).
   (See also the draft \sQuote{R Language Definition}.)
   \code{UseMethod} creates a new function call with
   arguments matched as they came in to the generic.  Any local variables
   defined before the call to \code{UseMethod} are retained (unlike S).  Any
   statements after the call to \code{UseMethod} will not be evaluated as
   \code{UseMethod} does not return.  \code{UseMethod} can be called with
   more than two arguments: a warning will be given and additional
   arguments ignored.  (They are not completely ignored in S.)  If it is
   called with just one argument, the class of the first argument of the
   enclosing function is used as \code{object}: unlike S this is the first
   actual argument passed and not the current value of the object of that
   name.

   \code{NextMethod} works by creating a special call frame for the next
   method.  If no new arguments are supplied, the arguments will be the
   same in number, order and name as those to the current method but
   their values will be promises to evaluate their name in the current
   method and environment.  Any named arguments matched to \code{\dots}
   are handled specially: they either replace existing arguments of the
   same name or are appended to the argument list.  They are passed on as
   the promise that was supplied as an argument to the current
   environment.  (S does this differently!)  If they have been evaluated
   in the current (or a previous environment) they remain evaluated.
   (This is a complex area, and subject to change: see the draft
   \sQuote{R Language Definition}.)

   The search for methods for \code{NextMethod} is slightly different
   from that for \code{UseMethod}.   Finding no \code{fun.default} is not
   necessarily an error, as the search continues to the generic
   itself.  This is to pick up an \link{internal generic} like \code{[}
   which has no separate default method, and succeeds only if the generic
   is a \link{primitive} function or a wrapper for a
   \code{\link{.Internal}} function of the same name.  (When a primitive
   is called as the default method, argument matching may not work as
   described above due to the different semantics of primitives.)

   You will see objects such as \code{.Generic}, \code{.Method}, and
   \code{.Class} used in methods.  These are set in the environment
   within which the method is evaluated by the dispatch mechanism, which
   is as follows:
   \enumerate{
     \item Find the context for the calling function (the generic): this
     gives us the unevaluated arguments for the original call.
     \item Evaluate the object (usually an argument) to be used for
     dispatch, and find a method (possibly the default method) or throw
     an error.
     \item Create an environment for evaluating the method and insert
     special variables (see below) into that environment.  Also copy any
     variables in the environment of the generic that are not formal (or
     actual) arguments.
     \item Fix up the argument list to be the arguments of the call
     matched to the formals of the method.
   }
   \code{.Generic} is a length-one character vector naming the generic function.

   \code{.Method} is a character vector (normally of length one) naming
   the method function.  (For functions in the group generic
   \code{\link[=S3groupGeneric]{Ops}} it is of length two.)

   \code{.Class} is a character vector of classes used to find the next
   method.  \code{NextMethod} adds an attribute \code{"previous"} to
   \code{.Class} giving the \code{.Class} last used for dispatch, and
   shifts \code{.Class} along to that used for dispatch.

   \code{.GenericCallEnv} and \code{.GenericDefEnv} are the environments
   of the call to be generic and defining the generic respectively.  (The
   latter is used to find methods registered for the generic.)

   Note that \code{.Class} is set when the generic is called, and is
   unchanged if the class of the dispatching argument is changed in a
   method.  It is possible to change the method that \code{NextMethod}
   would dispatch by manipulating \code{.Class}, but \sQuote{this is not
     recommended unless you understand the inheritance mechanism
     thoroughly} (Chambers & Hastie, 1992, p.\sspace{}469).
 }
 \note{
   This scheme is called \emph{S3} (S version 3).  For new projects,
   it is recommended to use the more flexible and robust \emph{S4} scheme
   provided in the \pkg{methods} package.
 }
 \seealso{
   The draft \sQuote{R Language Definition}.

   \code{\link{methods}}, \code{\link{class}},
   \code{\link{getS3method}}, \code{\link{is.object}}.
 }
 \references{
   Chambers, J. M. (1992)
   \emph{Classes and methods: object-oriented programming in S.}
   Appendix A of \emph{Statistical Models in S}
   eds J. M. Chambers and T. J. Hastie, Wadsworth & Brooks/Cole.
 }
 \keyword{methods}
	% File src/library/base/man/UseMethod.Rd
	% Part of the R package, https://www.R-project.org
	% Copyright 1995-2014 R Core Team
	% Distributed under GPL 2 or later

	\name{UseMethod}
	\title{Class Methods}
	\alias{UseMethod}
	\alias{NextMethod}
	\alias{S3Methods}
	\alias{.Method}
	\alias{.Generic}
	\alias{.Class}
	\description{
	\R possesses a simple generic function mechanism which can be used for
	an object-oriented style of programming. Method dispatch takes place
	based on the class(es) of the first argument to the generic function or of
	the object supplied as an argument to \code{UseMethod} or \code{NextMethod}.
	}
	\usage{
	UseMethod(generic, object)

	NextMethod(generic = NULL, object = NULL, \dots)
	}
	\arguments{
	\item{generic}{a character string naming a function (and not a
	built-in operator). Required for \code{UseMethod}.}
	\item{object}{for \code{UseMethod}: an object whose class will
	determine the method to be dispatched. Defaults to the first
	argument of the enclosing function.}
	\item{\dots}{further arguments to be passed to the next method.}
	}
	\details{
	An \R object is a data object which has a \code{class}
	attribute (and this can be tested by \code{\link{is.object}}).
	A class attribute is a character vector giving the names of
	the classes from which the object \emph{inherits}.
	If the object does not have a class attribute, it has an implicit
	class. Matrices and arrays have class \code{"matrix"}
	or\code{"array"} followed by the class of the underlying vector.
	Most vectors have class the result of \code{\link{mode}(x)}, except
	that integer vectors have class \code{c("integer", "numeric")} and
	real vectors have class \code{c("double", "numeric")}.

	When a function calling \code{UseMethod("fun")} is applied to an
	object with class attribute \code{c("first", "second")}, the system
	searches for a function called \code{fun.first} and, if it finds it,
	applies it to the object. If no such function is found a function
	called \code{fun.second} is tried. If no class name produces a
	suitable function, the function \code{fun.default} is used, if it
	exists, or an error results.

	Function \code{\link{methods}} can be used to find out about the
	methods for a particular generic function or class.

	\code{UseMethod} is a primitive function but uses standard argument
	matching. It is not the only means of dispatch of methods, for there
	are \link{internal generic} and \link{group generic} functions.
	\code{UseMethod} currently dispatches on the implicit class even for
	arguments that are not objects, but the other means of dispatch do
	not.

	\code{NextMethod} invokes the next method (determined by the
	class vector, either of the object supplied to the generic, or of
	the first argument to the function containing \code{NextMethod} if a
	method was invoked directly). Normally \code{NextMethod} is used with
	only one argument, \code{generic}, but if further arguments are
	supplied these modify the call to the next method.

	\code{NextMethod} should not be called except in methods called by
	\code{UseMethod} or from internal generics (see
	\link{InternalGenerics}). In particular it will not work inside
	anonymous calling functions (e.g., \code{get("print.ts")(AirPassengers)}).

	Namespaces can register methods for generic functions. To support
	this, \code{UseMethod} and \code{NextMethod} search for methods in
	two places: in the environment in which the generic function
	is called, and in the registration data base for the
	environment in which the generic is defined (typically a namespace).
	So methods for a generic function need to be available in the
	environment of the call to the generic, or they must be registered.
	(It does not matter whether they are visible in the environment in
	which the generic is defined.) As from \R 3.5.0, the registration
	data base is searched after the top level environment (see
	\code{\link{topenv}}) of the calling environment (but before the
	parents of the top level environment).
	}
	\section{Technical Details}{
	Now for some obscure details that need to appear somewhere. These
	comments will be slightly different than those in Chambers(1992).
	(See also the draft \sQuote{R Language Definition}.)
	\code{UseMethod} creates a new function call with
	arguments matched as they came in to the generic. Any local variables
	defined before the call to \code{UseMethod} are retained (unlike S). Any
	statements after the call to \code{UseMethod} will not be evaluated as
	\code{UseMethod} does not return. \code{UseMethod} can be called with
	more than two arguments: a warning will be given and additional
	arguments ignored. (They are not completely ignored in S.) If it is
	called with just one argument, the class of the first argument of the
	enclosing function is used as \code{object}: unlike S this is the first
	actual argument passed and not the current value of the object of that
	name.

	\code{NextMethod} works by creating a special call frame for the next
	method. If no new arguments are supplied, the arguments will be the
	same in number, order and name as those to the current method but
	their values will be promises to evaluate their name in the current
	method and environment. Any named arguments matched to \code{\dots}
	are handled specially: they either replace existing arguments of the
	same name or are appended to the argument list. They are passed on as
	the promise that was supplied as an argument to the current
	environment. (S does this differently!) If they have been evaluated
	in the current (or a previous environment) they remain evaluated.
	(This is a complex area, and subject to change: see the draft
	\sQuote{R Language Definition}.)

	The search for methods for \code{NextMethod} is slightly different
	from that for \code{UseMethod}. Finding no \code{fun.default} is not
	necessarily an error, as the search continues to the generic
	itself. This is to pick up an \link{internal generic} like \code{[}
	which has no separate default method, and succeeds only if the generic
	is a \link{primitive} function or a wrapper for a
	\code{\link{.Internal}} function of the same name. (When a primitive
	is called as the default method, argument matching may not work as
	described above due to the different semantics of primitives.)

	You will see objects such as \code{.Generic}, \code{.Method}, and
	\code{.Class} used in methods. These are set in the environment
	within which the method is evaluated by the dispatch mechanism, which
	is as follows:
	\enumerate{
	\item Find the context for the calling function (the generic): this
	gives us the unevaluated arguments for the original call.
	\item Evaluate the object (usually an argument) to be used for
	dispatch, and find a method (possibly the default method) or throw
	an error.
	\item Create an environment for evaluating the method and insert
	special variables (see below) into that environment. Also copy any
	variables in the environment of the generic that are not formal (or
	actual) arguments.
	\item Fix up the argument list to be the arguments of the call
	matched to the formals of the method.
	}
	\code{.Generic} is a length-one character vector naming the generic function.

	\code{.Method} is a character vector (normally of length one) naming
	the method function. (For functions in the group generic
	\code{\link[=S3groupGeneric]{Ops}} it is of length two.)

	\code{.Class} is a character vector of classes used to find the next
	method. \code{NextMethod} adds an attribute \code{"previous"} to
	\code{.Class} giving the \code{.Class} last used for dispatch, and
	shifts \code{.Class} along to that used for dispatch.

	\code{.GenericCallEnv} and \code{.GenericDefEnv} are the environments
	of the call to be generic and defining the generic respectively. (The
	latter is used to find methods registered for the generic.)

	Note that \code{.Class} is set when the generic is called, and is
	unchanged if the class of the dispatching argument is changed in a
	method. It is possible to change the method that \code{NextMethod}
	would dispatch by manipulating \code{.Class}, but \sQuote{this is not
	recommended unless you understand the inheritance mechanism
	thoroughly} (Chambers & Hastie, 1992, p.\sspace{}469).
	}
	\note{
	This scheme is called \emph{S3} (S version 3). For new projects,
	it is recommended to use the more flexible and robust \emph{S4} scheme
	provided in the \pkg{methods} package.
	}
	\seealso{
	The draft \sQuote{R Language Definition}.

	\code{\link{methods}}, \code{\link{class}},
	\code{\link{getS3method}}, \code{\link{is.object}}.
	}
	\references{
	Chambers, J. M. (1992)
	\emph{Classes and methods: object-oriented programming in S.}
	Appendix A of \emph{Statistical Models in S}
	eds J. M. Chambers and T. J. Hastie, Wadsworth & Brooks/Cole.
	}
	\keyword{methods}