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2455 lines
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2455 lines
88 KiB
Plaintext
@c -*- mode: texinfo; coding: utf-8 -*-
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@c This is part of the GNU Emacs Lisp Reference Manual.
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@c Copyright (C) 1990--1995, 1998--1999, 2001--2022 Free Software
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@c Foundation, Inc.
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@c See the file elisp.texi for copying conditions.
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@node Lisp Data Types
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@chapter Lisp Data Types
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@cindex object
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@cindex Lisp object
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@cindex type
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@cindex data type
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A Lisp @dfn{object} is a piece of data used and manipulated by Lisp
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programs. For our purposes, a @dfn{type} or @dfn{data type} is a set of
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possible objects.
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Every object belongs to at least one type. Objects of the same type
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have similar structures and may usually be used in the same contexts.
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Types can overlap, and objects can belong to two or more types.
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Consequently, we can ask whether an object belongs to a particular type,
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but not for @emph{the} type of an object.
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@cindex primitive type
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A few fundamental object types are built into Emacs. These, from
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which all other types are constructed, are called @dfn{primitive types}.
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Each object belongs to one and only one primitive type. These types
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include @dfn{integer}, @dfn{float}, @dfn{cons}, @dfn{symbol},
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@dfn{string}, @dfn{vector}, @dfn{hash-table}, @dfn{subr},
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@dfn{byte-code function}, and @dfn{record}, plus several special
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types, such as @dfn{buffer}, that are related to editing.
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(@xref{Editing Types}.)
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Each primitive type has a corresponding Lisp function that checks
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whether an object is a member of that type.
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Lisp is unlike many other languages in that its objects are
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@dfn{self-typing}: the primitive type of each object is implicit in
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the object itself. For example, if an object is a vector, nothing can
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treat it as a number; Lisp knows it is a vector, not a number.
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In most languages, the programmer must declare the data type of each
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variable, and the type is known by the compiler but not represented in
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the data. Such type declarations do not exist in Emacs Lisp. A Lisp
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variable can have any type of value, and it remembers whatever value
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you store in it, type and all. (Actually, a small number of Emacs
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Lisp variables can only take on values of a certain type.
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@xref{Variables with Restricted Values}.)
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This chapter describes the purpose, printed representation, and read
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syntax of each of the standard types in GNU Emacs Lisp. Details on how
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to use these types can be found in later chapters.
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@menu
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* Printed Representation:: How Lisp objects are represented as text.
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* Special Read Syntax:: An overview of all the special sequences.
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* Comments:: Comments and their formatting conventions.
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* Programming Types:: Types found in all Lisp systems.
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* Editing Types:: Types specific to Emacs.
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* Circular Objects:: Read syntax for circular structure.
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* Type Predicates:: Tests related to types.
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* Equality Predicates:: Tests of equality between any two objects.
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* Mutability:: Some objects should not be modified.
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@end menu
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@node Printed Representation
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@section Printed Representation and Read Syntax
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@cindex printed representation
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@cindex read syntax
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The @dfn{printed representation} of an object is the format of the
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output generated by the Lisp printer (the function @code{prin1}) for
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that object. Every data type has a unique printed representation.
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The @dfn{read syntax} of an object is the format of the input accepted
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by the Lisp reader (the function @code{read}) for that object. This
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is not necessarily unique; many kinds of object have more than one
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syntax. @xref{Read and Print}.
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@cindex hash notation
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In most cases, an object's printed representation is also a read
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syntax for the object. However, some types have no read syntax, since
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it does not make sense to enter objects of these types as constants in
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a Lisp program. These objects are printed in @dfn{hash notation},
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which consists of the characters @samp{#<}, a descriptive string
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(typically the type name followed by the name of the object), and a
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closing @samp{>}. For example:
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@example
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(current-buffer)
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@result{} #<buffer objects.texi>
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@end example
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@noindent
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Hash notation cannot be read at all, so the Lisp reader signals the
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error @code{invalid-read-syntax} whenever it encounters @samp{#<}.
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@kindex invalid-read-syntax
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In other languages, an expression is text; it has no other form. In
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Lisp, an expression is primarily a Lisp object and only secondarily the
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text that is the object's read syntax. Often there is no need to
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emphasize this distinction, but you must keep it in the back of your
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mind, or you will occasionally be very confused.
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When you evaluate an expression interactively, the Lisp interpreter
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first reads the textual representation of it, producing a Lisp object,
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and then evaluates that object (@pxref{Evaluation}). However,
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evaluation and reading are separate activities. Reading returns the
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Lisp object represented by the text that is read; the object may or may
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not be evaluated later. @xref{Input Functions}, for a description of
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@code{read}, the basic function for reading objects.
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@node Special Read Syntax
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@section Special Read Syntax
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@cindex special read syntax
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Emacs Lisp represents many special objects and constructs via
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special hash notations.
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@table @samp
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@item #<@dots{}>
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Objects that have no read syntax are presented like this
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(@pxref{Printed Representation}).
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@item ##
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The printed representation of an interned symbol whose name is an
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empty string (@pxref{Symbol Type}).
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@item #'
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This is a shortcut for @code{function}, see @ref{Anonymous Functions}.
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@item #:
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The printed representation of an uninterned symbol whose name is
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@var{foo} is @samp{#:@var{foo}} (@pxref{Symbol Type}).
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@item #N
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When printing circular structures, this construct is used to represent
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where the structure loops back onto itself, and @samp{N} is the
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starting list count:
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@lisp
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(let ((a (list 1)))
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(setcdr a a))
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=> (1 . #0)
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@end lisp
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@item #N=
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@itemx #N#
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@samp{#N=} gives the name to an object, and @samp{#N#} represents that
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object, so when reading back the object, they will be the same object
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instead of copies (@pxref{Circular Objects}).
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@item #xN
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@samp{N} represented as a hexadecimal number (@samp{#x2a}).
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@item #oN
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@samp{N} represented as an octal number (@samp{#o52}).
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@item #bN
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@samp{N} represented as a binary number (@samp{#b101010}).
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||
@item #(@dots{})
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String text properties (@pxref{Text Props and Strings}).
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@item #^
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A char table (@pxref{Char-Table Type}).
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@item #s(hash-table @dots{})
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A hash table (@pxref{Hash Table Type}).
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@item ?C
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A character (@pxref{Basic Char Syntax}).
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@item #$
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The current file name in byte-compiled files (@pxref{Docs and
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Compilation}). This is not meant to be used in Emacs Lisp source
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files.
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@item #@@N
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Skip the next @samp{N} characters (@pxref{Comments}). This is used in
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byte-compiled files, and is not meant to be used in Emacs Lisp source
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files.
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@end table
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@node Comments
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@section Comments
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@cindex comments
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@cindex @samp{;} for commenting
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A @dfn{comment} is text that is written in a program only for the
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sake of humans that read the program, and that has no effect on the
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meaning of the program. In Lisp, an unescaped semicolon (@samp{;})
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starts a comment if it is not within a string or character constant.
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The comment continues to the end of line. The Lisp reader discards
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comments; they do not become part of the Lisp objects which represent
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the program within the Lisp system.
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The @samp{#@@@var{count}} construct, which skips the next @var{count}
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characters, is useful for program-generated comments containing binary
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data. The Emacs Lisp byte compiler uses this in its output files
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(@pxref{Byte Compilation}). It isn't meant for source files, however.
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@xref{Comment Tips}, for conventions for formatting comments.
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@node Programming Types
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@section Programming Types
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@cindex programming types
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There are two general categories of types in Emacs Lisp: those having
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to do with Lisp programming, and those having to do with editing. The
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former exist in many Lisp implementations, in one form or another. The
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latter are unique to Emacs Lisp.
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@menu
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* Integer Type:: Numbers without fractional parts.
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* Floating-Point Type:: Numbers with fractional parts and with a large range.
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* Character Type:: The representation of letters, numbers and
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control characters.
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* Symbol Type:: A multi-use object that refers to a function,
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variable, or property list, and has a unique identity.
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* Sequence Type:: Both lists and arrays are classified as sequences.
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* Cons Cell Type:: Cons cells, and lists (which are made from cons cells).
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* Array Type:: Arrays include strings and vectors.
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* String Type:: An (efficient) array of characters.
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* Vector Type:: One-dimensional arrays.
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* Char-Table Type:: One-dimensional sparse arrays indexed by characters.
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* Bool-Vector Type:: One-dimensional arrays of @code{t} or @code{nil}.
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* Hash Table Type:: Super-fast lookup tables.
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* Function Type:: A piece of executable code you can call from elsewhere.
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* Macro Type:: A method of expanding an expression into another
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expression, more fundamental but less pretty.
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* Primitive Function Type:: A function written in C, callable from Lisp.
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* Byte-Code Type:: A function written in Lisp, then compiled.
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* Record Type:: Compound objects with programmer-defined types.
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* Type Descriptors:: Objects holding information about types.
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* Autoload Type:: A type used for automatically loading seldom-used
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functions.
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* Finalizer Type:: Runs code when no longer reachable.
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||
@end menu
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||
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@node Integer Type
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@subsection Integer Type
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Under the hood, there are two kinds of integers---small integers,
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called @dfn{fixnums}, and large integers, called @dfn{bignums}.
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The range of values for a fixnum depends on the machine. The
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minimum range is @minus{}536,870,912 to 536,870,911 (30 bits; i.e.,
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@ifnottex
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@minus{}2**29
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@end ifnottex
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@tex
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@math{-2^{29}}
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@end tex
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||
to
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@ifnottex
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2**29 @minus{} 1)
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@end ifnottex
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@tex
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@math{2^{29}-1})
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@end tex
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but many machines provide a wider range.
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Bignums can have arbitrary precision. Operations that overflow a
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fixnum will return a bignum instead.
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All numbers can be compared with @code{eql} or @code{=}; fixnums can
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also be compared with @code{eq}. To test whether an integer is a fixnum or a
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bignum, you can compare it to @code{most-negative-fixnum} and
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@code{most-positive-fixnum}, or you can use the convenience predicates
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@code{fixnump} and @code{bignump} on any object.
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The read syntax for integers is a sequence of (base ten) digits with an
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optional sign at the beginning and an optional period at the end. The
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printed representation produced by the Lisp interpreter never has a
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leading @samp{+} or a final @samp{.}.
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@example
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@group
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-1 ; @r{The integer @minus{}1.}
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1 ; @r{The integer 1.}
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1. ; @r{Also the integer 1.}
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+1 ; @r{Also the integer 1.}
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@end group
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@end example
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@noindent
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@xref{Numbers}, for more information.
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@node Floating-Point Type
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@subsection Floating-Point Type
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Floating-point numbers are the computer equivalent of scientific
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notation; you can think of a floating-point number as a fraction
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together with a power of ten. The precise number of significant
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figures and the range of possible exponents is machine-specific; Emacs
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uses the C data type @code{double} to store the value, and internally
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this records a power of 2 rather than a power of 10.
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The printed representation for floating-point numbers requires either
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a decimal point (with at least one digit following), an exponent, or
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both. For example, @samp{1500.0}, @samp{+15e2}, @samp{15.0e+2},
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@samp{+1500000e-3}, and @samp{.15e4} are five ways of writing a floating-point
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number whose value is 1500. They are all equivalent.
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@xref{Numbers}, for more information.
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@node Character Type
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@subsection Character Type
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@cindex @acronym{ASCII} character codes
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A @dfn{character} in Emacs Lisp is nothing more than an integer. In
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other words, characters are represented by their character codes. For
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example, the character @kbd{A} is represented as the @w{integer 65}.
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Individual characters are used occasionally in programs, but it is
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more common to work with @emph{strings}, which are sequences composed
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of characters. @xref{String Type}.
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Characters in strings and buffers are currently limited to the range
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of 0 to 4194303---twenty two bits (@pxref{Character Codes}). Codes 0
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through 127 are @acronym{ASCII} codes; the rest are
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non-@acronym{ASCII} (@pxref{Non-ASCII Characters}). Characters that
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represent keyboard input have a much wider range, to encode modifier
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keys such as Control, Meta and Shift.
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There are special functions for producing a human-readable textual
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description of a character for the sake of messages. @xref{Describing
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Characters}.
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@menu
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* Basic Char Syntax:: Syntax for regular characters.
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* General Escape Syntax:: How to specify characters by their codes.
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* Ctl-Char Syntax:: Syntax for control characters.
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* Meta-Char Syntax:: Syntax for meta-characters.
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* Other Char Bits:: Syntax for hyper-, super-, and alt-characters.
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@end menu
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@node Basic Char Syntax
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@subsubsection Basic Char Syntax
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@cindex read syntax for characters
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@cindex printed representation for characters
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@cindex syntax for characters
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@cindex @samp{?} in character constant
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@cindex question mark in character constant
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Since characters are really integers, the printed representation of
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a character is a decimal number. This is also a possible read syntax
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for a character, but writing characters that way in Lisp programs is
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not clear programming. You should @emph{always} use the special read
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syntax formats that Emacs Lisp provides for characters. These syntax
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formats start with a question mark.
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The usual read syntax for alphanumeric characters is a question mark
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followed by the character; thus, @samp{?A} for the character
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@kbd{A}, @samp{?B} for the character @kbd{B}, and @samp{?a} for the
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character @kbd{a}.
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For example:
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@example
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?Q @result{} 81 ?q @result{} 113
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@end example
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You can use the same syntax for punctuation characters. However, if
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the punctuation character has a special syntactic meaning in Lisp, you
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must quote it with a @samp{\}. For example, @samp{?\(} is the way to
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write the open-paren character. Likewise, if the character is
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@samp{\}, you must use a second @samp{\} to quote it: @samp{?\\}.
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@cindex whitespace
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@cindex bell character
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@cindex @samp{\a}
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@cindex backspace
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@cindex @samp{\b}
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@cindex tab (ASCII character)
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@cindex @samp{\t}
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@cindex vertical tab
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@cindex @samp{\v}
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@cindex formfeed
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@cindex @samp{\f}
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@cindex newline
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@cindex @samp{\n}
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@cindex return (ASCII character)
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@cindex @samp{\r}
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@cindex escape (ASCII character)
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@cindex @samp{\e}
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@cindex space (ASCII character)
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@cindex @samp{\s}
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You can express the characters control-g, backspace, tab, newline,
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vertical tab, formfeed, space, return, del, and escape as @samp{?\a},
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@samp{?\b}, @samp{?\t}, @samp{?\n}, @samp{?\v}, @samp{?\f},
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@samp{?\s}, @samp{?\r}, @samp{?\d}, and @samp{?\e}, respectively.
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(@samp{?\s} followed by a dash has a different meaning---it applies
|
||
the Super modifier to the following character.) Thus,
|
||
|
||
@example
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?\a @result{} 7 ; @r{control-g, @kbd{C-g}}
|
||
?\b @result{} 8 ; @r{backspace, @key{BS}, @kbd{C-h}}
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||
?\t @result{} 9 ; @r{tab, @key{TAB}, @kbd{C-i}}
|
||
?\n @result{} 10 ; @r{newline, @kbd{C-j}}
|
||
?\v @result{} 11 ; @r{vertical tab, @kbd{C-k}}
|
||
?\f @result{} 12 ; @r{formfeed character, @kbd{C-l}}
|
||
?\r @result{} 13 ; @r{carriage return, @key{RET}, @kbd{C-m}}
|
||
?\e @result{} 27 ; @r{escape character, @key{ESC}, @kbd{C-[}}
|
||
?\s @result{} 32 ; @r{space character, @key{SPC}}
|
||
?\\ @result{} 92 ; @r{backslash character, @kbd{\}}
|
||
?\d @result{} 127 ; @r{delete character, @key{DEL}}
|
||
@end example
|
||
|
||
@cindex escape sequence
|
||
These sequences which start with backslash are also known as
|
||
@dfn{escape sequences}, because backslash plays the role of an
|
||
escape character; this has nothing to do with the
|
||
character @key{ESC}. @samp{\s} is meant for use in character
|
||
constants; in string constants, just write the space.
|
||
|
||
A backslash is allowed, and harmless, preceding any character
|
||
without a special escape meaning; thus, @samp{?\+} is equivalent to
|
||
@samp{?+}. There is no reason to add a backslash before most
|
||
characters. However, you must add a backslash before any of the
|
||
characters @samp{()[]\;"}, and you should add a backslash before any
|
||
of the characters @samp{|'`#.,} to avoid confusing the Emacs commands
|
||
for editing Lisp code. You should also add a backslash before Unicode
|
||
characters which resemble the previously mentioned @acronym{ASCII}
|
||
ones, to avoid confusing people reading your code. Emacs will
|
||
highlight some non-escaped commonly confused characters such as
|
||
@samp{‘} to encourage this. You can also add a backslash before whitespace
|
||
characters such as space, tab, newline and formfeed. However, it is
|
||
cleaner to use one of the easily readable escape sequences, such as
|
||
@samp{\t} or @samp{\s}, instead of an actual whitespace character such
|
||
as a tab or a space. (If you do write backslash followed by a space,
|
||
you should write an extra space after the character constant to
|
||
separate it from the following text.)
|
||
|
||
@node General Escape Syntax
|
||
@subsubsection General Escape Syntax
|
||
|
||
In addition to the specific escape sequences for special important
|
||
control characters, Emacs provides several types of escape syntax that
|
||
you can use to specify non-@acronym{ASCII} text characters.
|
||
|
||
@enumerate
|
||
@item
|
||
@cindex @samp{\} in character constant
|
||
@cindex backslash in character constants
|
||
@cindex unicode character escape
|
||
You can specify characters by their Unicode names, if any.
|
||
@code{?\N@{@var{NAME}@}} represents the Unicode character named
|
||
@var{NAME}. Thus, @samp{?\N@{LATIN SMALL LETTER A WITH GRAVE@}} is
|
||
equivalent to @code{?à} and denotes the Unicode character U+00E0. To
|
||
simplify entering multi-line strings, you can replace spaces in the
|
||
names by non-empty sequences of whitespace (e.g., newlines).
|
||
|
||
@item
|
||
You can specify characters by their Unicode values.
|
||
@code{?\N@{U+@var{X}@}} represents a character with Unicode code point
|
||
@var{X}, where @var{X} is a hexadecimal number. Also,
|
||
@code{?\u@var{xxxx}} and @code{?\U@var{xxxxxxxx}} represent code
|
||
points @var{xxxx} and @var{xxxxxxxx}, respectively, where each @var{x}
|
||
is a single hexadecimal digit. For example, @code{?\N@{U+E0@}},
|
||
@code{?\u00e0} and @code{?\U000000E0} are all equivalent to @code{?à}
|
||
and to @samp{?\N@{LATIN SMALL LETTER A WITH GRAVE@}}. The Unicode
|
||
Standard defines code points only up to @samp{U+@var{10ffff}}, so if
|
||
you specify a code point higher than that, Emacs signals an error.
|
||
|
||
@item
|
||
You can specify characters by their hexadecimal character
|
||
codes. A hexadecimal escape sequence consists of a backslash,
|
||
@samp{x}, and the hexadecimal character code. Thus, @samp{?\x41} is
|
||
the character @kbd{A}, @samp{?\x1} is the character @kbd{C-a}, and
|
||
@code{?\xe0} is the character @kbd{à} (@kbd{a} with grave accent).
|
||
You can use any number of hex digits, so you can represent any
|
||
character code in this way.
|
||
|
||
@item
|
||
@cindex octal character code
|
||
You can specify characters by their character code in
|
||
octal. An octal escape sequence consists of a backslash followed by
|
||
up to three octal digits; thus, @samp{?\101} for the character
|
||
@kbd{A}, @samp{?\001} for the character @kbd{C-a}, and @code{?\002}
|
||
for the character @kbd{C-b}. Only characters up to octal code 777 can
|
||
be specified this way.
|
||
|
||
@end enumerate
|
||
|
||
These escape sequences may also be used in strings. @xref{Non-ASCII
|
||
in Strings}.
|
||
|
||
@node Ctl-Char Syntax
|
||
@subsubsection Control-Character Syntax
|
||
|
||
@cindex control characters
|
||
Control characters can be represented using yet another read syntax.
|
||
This consists of a question mark followed by a backslash, caret, and the
|
||
corresponding non-control character, in either upper or lower case. For
|
||
example, both @samp{?\^I} and @samp{?\^i} are valid read syntax for the
|
||
character @kbd{C-i}, the character whose value is 9.
|
||
|
||
Instead of the @samp{^}, you can use @samp{C-}; thus, @samp{?\C-i} is
|
||
equivalent to @samp{?\^I} and to @samp{?\^i}:
|
||
|
||
@example
|
||
?\^I @result{} 9 ?\C-I @result{} 9
|
||
@end example
|
||
|
||
In strings and buffers, the only control characters allowed are those
|
||
that exist in @acronym{ASCII}; but for keyboard input purposes, you can turn
|
||
any character into a control character with @samp{C-}. The character
|
||
codes for these non-@acronym{ASCII} control characters include the
|
||
@tex
|
||
@math{2^{26}}
|
||
@end tex
|
||
@ifnottex
|
||
2**26
|
||
@end ifnottex
|
||
bit as well as the code for the corresponding non-control character.
|
||
Not all text terminals can generate non-@acronym{ASCII} control
|
||
characters, but it is straightforward to generate them using X and
|
||
other window systems.
|
||
|
||
For historical reasons, Emacs treats the @key{DEL} character as
|
||
the control equivalent of @kbd{?}:
|
||
|
||
@example
|
||
?\^? @result{} 127 ?\C-? @result{} 127
|
||
@end example
|
||
|
||
@noindent
|
||
As a result, it is currently not possible to represent the character
|
||
@kbd{Control-?}, which is a meaningful input character under X, using
|
||
@samp{\C-}. It is not easy to change this, as various Lisp files refer
|
||
to @key{DEL} in this way.
|
||
|
||
For representing control characters to be found in files or strings,
|
||
we recommend the @samp{^} syntax; for control characters in keyboard
|
||
input, we prefer the @samp{C-} syntax. Which one you use does not
|
||
affect the meaning of the program, but may guide the understanding of
|
||
people who read it.
|
||
|
||
@node Meta-Char Syntax
|
||
@subsubsection Meta-Character Syntax
|
||
|
||
@cindex meta characters
|
||
A @dfn{meta character} is a character typed with the @key{META}
|
||
modifier key. The integer that represents such a character has the
|
||
@tex
|
||
@math{2^{27}}
|
||
@end tex
|
||
@ifnottex
|
||
2**27
|
||
@end ifnottex
|
||
bit set. We use high bits for this and other modifiers to make
|
||
possible a wide range of basic character codes.
|
||
|
||
In a string, the
|
||
@tex
|
||
@math{2^{7}}
|
||
@end tex
|
||
@ifnottex
|
||
2**7
|
||
@end ifnottex
|
||
bit attached to an @acronym{ASCII} character indicates a meta
|
||
character; thus, the meta characters that can fit in a string have
|
||
codes in the range from 128 to 255, and are the meta versions of the
|
||
ordinary @acronym{ASCII} characters. @xref{Strings of Events}, for
|
||
details about @key{META}-handling in strings.
|
||
|
||
The read syntax for meta characters uses @samp{\M-}. For example,
|
||
@samp{?\M-A} stands for @kbd{M-A}. You can use @samp{\M-} together with
|
||
octal character codes (see below), with @samp{\C-}, or with any other
|
||
syntax for a character. Thus, you can write @kbd{M-A} as @samp{?\M-A},
|
||
or as @samp{?\M-\101}. Likewise, you can write @kbd{C-M-b} as
|
||
@samp{?\M-\C-b}, @samp{?\C-\M-b}, or @samp{?\M-\002}.
|
||
|
||
@node Other Char Bits
|
||
@subsubsection Other Character Modifier Bits
|
||
|
||
The case of a graphic character is indicated by its character code;
|
||
for example, @acronym{ASCII} distinguishes between the characters @samp{a}
|
||
and @samp{A}. But @acronym{ASCII} has no way to represent whether a control
|
||
character is upper case or lower case. Emacs uses the
|
||
@tex
|
||
@math{2^{25}}
|
||
@end tex
|
||
@ifnottex
|
||
2**25
|
||
@end ifnottex
|
||
bit to indicate that the shift key was used in typing a control
|
||
character. This distinction is possible only on a graphical display
|
||
such as a GUI display on X; text terminals do not report the
|
||
distinction. The Lisp syntax for the shift bit is @samp{\S-}; thus,
|
||
@samp{?\C-\S-o} or @samp{?\C-\S-O} represents the shifted-control-o
|
||
character.
|
||
|
||
@cindex hyper characters
|
||
@cindex super characters
|
||
@cindex alt characters
|
||
The X Window System defines three other
|
||
@anchor{modifier bits}modifier bits that can be set
|
||
in a character: @dfn{hyper}, @dfn{super} and @dfn{alt}. The syntaxes
|
||
for these bits are @samp{\H-}, @samp{\s-} and @samp{\A-}. (Case is
|
||
significant in these prefixes.) Thus, @samp{?\H-\M-\A-x} represents
|
||
@kbd{Alt-Hyper-Meta-x}. (Note that @samp{\s} with no following @samp{-}
|
||
represents the space character.)
|
||
@tex
|
||
Numerically, the bit values are @math{2^{22}} for alt, @math{2^{23}}
|
||
for super and @math{2^{24}} for hyper.
|
||
@end tex
|
||
@ifnottex
|
||
Numerically, the
|
||
bit values are 2**22 for alt, 2**23 for super and 2**24 for hyper.
|
||
@end ifnottex
|
||
|
||
@node Symbol Type
|
||
@subsection Symbol Type
|
||
|
||
A @dfn{symbol} in GNU Emacs Lisp is an object with a name. The
|
||
symbol name serves as the printed representation of the symbol. In
|
||
ordinary Lisp use, with one single obarray (@pxref{Creating Symbols}),
|
||
a symbol's name is unique---no two symbols have the same name.
|
||
|
||
A symbol can serve as a variable, as a function name, or to hold a
|
||
property list. Or it may serve only to be distinct from all other Lisp
|
||
objects, so that its presence in a data structure may be recognized
|
||
reliably. In a given context, usually only one of these uses is
|
||
intended. But you can use one symbol in all of these ways,
|
||
independently.
|
||
|
||
A symbol whose name starts with a colon (@samp{:}) is called a
|
||
@dfn{keyword symbol}. These symbols automatically act as constants,
|
||
and are normally used only by comparing an unknown symbol with a few
|
||
specific alternatives. @xref{Constant Variables}.
|
||
|
||
@cindex @samp{\} in symbols
|
||
@cindex backslash in symbols
|
||
A symbol name can contain any characters whatever. Most symbol names
|
||
are written with letters, digits, and the punctuation characters
|
||
@samp{-+=*/}. Such names require no special punctuation; the characters
|
||
of the name suffice as long as the name does not look like a number.
|
||
(If it does, write a @samp{\} at the beginning of the name to force
|
||
interpretation as a symbol.) The characters @samp{_~!@@$%^&:<>@{@}?} are
|
||
less often used but also require no special punctuation. Any other
|
||
characters may be included in a symbol's name by escaping them with a
|
||
backslash. In contrast to its use in strings, however, a backslash in
|
||
the name of a symbol simply quotes the single character that follows the
|
||
backslash. For example, in a string, @samp{\t} represents a tab
|
||
character; in the name of a symbol, however, @samp{\t} merely quotes the
|
||
letter @samp{t}. To have a symbol with a tab character in its name, you
|
||
must actually use a tab (preceded with a backslash). But it's rare to
|
||
do such a thing.
|
||
|
||
@cindex CL note---case of letters
|
||
@quotation
|
||
@b{Common Lisp note:} In Common Lisp, lower case letters are always
|
||
folded to upper case, unless they are explicitly escaped. In Emacs
|
||
Lisp, upper case and lower case letters are distinct.
|
||
@end quotation
|
||
|
||
Here are several examples of symbol names. Note that the @samp{+} in
|
||
the fourth example is escaped to prevent it from being read as a number.
|
||
This is not necessary in the sixth example because the rest of the name
|
||
makes it invalid as a number.
|
||
|
||
@example
|
||
@group
|
||
foo ; @r{A symbol named @samp{foo}.}
|
||
FOO ; @r{A symbol named @samp{FOO}, different from @samp{foo}.}
|
||
@end group
|
||
@group
|
||
1+ ; @r{A symbol named @samp{1+}}
|
||
; @r{(not @samp{+1}, which is an integer).}
|
||
@end group
|
||
@group
|
||
\+1 ; @r{A symbol named @samp{+1}}
|
||
; @r{(not a very readable name).}
|
||
@end group
|
||
@group
|
||
\(*\ 1\ 2\) ; @r{A symbol named @samp{(* 1 2)} (a worse name).}
|
||
@c the @'s in this next line use up three characters, hence the
|
||
@c apparent misalignment of the comment.
|
||
+-*/_~!@@$%^&=:<>@{@} ; @r{A symbol named @samp{+-*/_~!@@$%^&=:<>@{@}}.}
|
||
; @r{These characters need not be escaped.}
|
||
@end group
|
||
@end example
|
||
|
||
@cindex @samp{##} read syntax
|
||
@ifinfo
|
||
@c This uses "colon" instead of a literal ':' because Info cannot
|
||
@c cope with a ':' in a menu.
|
||
@cindex @samp{#@var{colon}} read syntax
|
||
@end ifinfo
|
||
@ifnotinfo
|
||
@cindex @samp{#:} read syntax
|
||
@end ifnotinfo
|
||
As an exception to the rule that a symbol's name serves as its
|
||
printed representation, @samp{##} is the printed representation for an
|
||
interned symbol whose name is an empty string. Furthermore,
|
||
@samp{#:@var{foo}} is the printed representation for an uninterned
|
||
symbol whose name is @var{foo}. (Normally, the Lisp reader interns
|
||
all symbols; @pxref{Creating Symbols}.)
|
||
|
||
@node Sequence Type
|
||
@subsection Sequence Types
|
||
|
||
A @dfn{sequence} is a Lisp object that represents an ordered set of
|
||
elements. There are two kinds of sequence in Emacs Lisp: @dfn{lists}
|
||
and @dfn{arrays}.
|
||
|
||
Lists are the most commonly-used sequences. A list can hold
|
||
elements of any type, and its length can be easily changed by adding
|
||
or removing elements. See the next subsection for more about lists.
|
||
|
||
Arrays are fixed-length sequences. They are further subdivided into
|
||
strings, vectors, char-tables and bool-vectors. Vectors can hold
|
||
elements of any type, whereas string elements must be characters, and
|
||
bool-vector elements must be @code{t} or @code{nil}. Char-tables are
|
||
like vectors except that they are indexed by any valid character code.
|
||
The characters in a string can have text properties like characters in
|
||
a buffer (@pxref{Text Properties}), but vectors do not support text
|
||
properties, even when their elements happen to be characters.
|
||
|
||
Lists, strings and the other array types also share important
|
||
similarities. For example, all have a length @var{l}, and all have
|
||
elements which can be indexed from zero to @var{l} minus one. Several
|
||
functions, called sequence functions, accept any kind of sequence.
|
||
For example, the function @code{length} reports the length of any kind
|
||
of sequence. @xref{Sequences Arrays Vectors}.
|
||
|
||
It is generally impossible to read the same sequence twice, since
|
||
sequences are always created anew upon reading. If you read the read
|
||
syntax for a sequence twice, you get two sequences with equal contents.
|
||
There is one exception: the empty list @code{()} always stands for the
|
||
same object, @code{nil}.
|
||
|
||
@node Cons Cell Type
|
||
@subsection Cons Cell and List Types
|
||
@cindex address field of register
|
||
@cindex decrement field of register
|
||
@cindex pointers
|
||
|
||
A @dfn{cons cell} is an object that consists of two slots, called
|
||
the @sc{car} slot and the @sc{cdr} slot. Each slot can @dfn{hold} any
|
||
Lisp object. We also say that the @sc{car} of this cons cell is
|
||
whatever object its @sc{car} slot currently holds, and likewise for
|
||
the @sc{cdr}.
|
||
|
||
@cindex list structure
|
||
A @dfn{list} is a series of cons cells, linked together so that the
|
||
@sc{cdr} slot of each cons cell holds either the next cons cell or the
|
||
empty list. The empty list is actually the symbol @code{nil}.
|
||
@xref{Lists}, for details. Because most cons cells are used as part
|
||
of lists, we refer to any structure made out of cons cells as a
|
||
@dfn{list structure}.
|
||
|
||
@cindex linked list
|
||
@quotation
|
||
A note to C programmers: a Lisp list thus works as a @dfn{linked list}
|
||
built up of cons cells. Because pointers in Lisp are implicit, we do
|
||
not distinguish between a cons cell slot holding a value versus
|
||
pointing to the value.
|
||
@end quotation
|
||
|
||
@cindex atoms
|
||
Because cons cells are so central to Lisp, we also have a word for
|
||
an object which is not a cons cell. These objects are called
|
||
@dfn{atoms}.
|
||
|
||
@cindex parenthesis
|
||
@cindex @samp{(@dots{})} in lists
|
||
The read syntax and printed representation for lists are identical, and
|
||
consist of a left parenthesis, an arbitrary number of elements, and a
|
||
right parenthesis. Here are examples of lists:
|
||
|
||
@example
|
||
(A 2 "A") ; @r{A list of three elements.}
|
||
() ; @r{A list of no elements (the empty list).}
|
||
nil ; @r{A list of no elements (the empty list).}
|
||
("A ()") ; @r{A list of one element: the string @code{"A ()"}.}
|
||
(A ()) ; @r{A list of two elements: @code{A} and the empty list.}
|
||
(A nil) ; @r{Equivalent to the previous.}
|
||
((A B C)) ; @r{A list of one element}
|
||
; @r{(which is a list of three elements).}
|
||
@end example
|
||
|
||
Upon reading, each object inside the parentheses becomes an element
|
||
of the list. That is, a cons cell is made for each element. The
|
||
@sc{car} slot of the cons cell holds the element, and its @sc{cdr}
|
||
slot refers to the next cons cell of the list, which holds the next
|
||
element in the list. The @sc{cdr} slot of the last cons cell is set to
|
||
hold @code{nil}.
|
||
|
||
The names @sc{car} and @sc{cdr} derive from the history of Lisp. The
|
||
original Lisp implementation ran on an @w{IBM 704} computer which
|
||
divided words into two parts, the address and the
|
||
decrement; @sc{car} was an instruction to extract the contents of
|
||
the address part of a register, and @sc{cdr} an instruction to extract
|
||
the contents of the decrement. By contrast, cons cells are named
|
||
for the function @code{cons} that creates them, which in turn was named
|
||
for its purpose, the construction of cells.
|
||
|
||
@menu
|
||
* Box Diagrams:: Drawing pictures of lists.
|
||
* Dotted Pair Notation:: A general syntax for cons cells.
|
||
* Association List Type:: A specially constructed list.
|
||
@end menu
|
||
|
||
@node Box Diagrams
|
||
@subsubsection Drawing Lists as Box Diagrams
|
||
@cindex box diagrams, for lists
|
||
@cindex diagrams, boxed, for lists
|
||
|
||
A list can be illustrated by a diagram in which the cons cells are
|
||
shown as pairs of boxes, like dominoes. (The Lisp reader cannot read
|
||
such an illustration; unlike the textual notation, which can be
|
||
understood by both humans and computers, the box illustrations can be
|
||
understood only by humans.) This picture represents the three-element
|
||
list @code{(rose violet buttercup)}:
|
||
|
||
@example
|
||
@group
|
||
--- --- --- --- --- ---
|
||
| | |--> | | |--> | | |--> nil
|
||
--- --- --- --- --- ---
|
||
| | |
|
||
| | |
|
||
--> rose --> violet --> buttercup
|
||
@end group
|
||
@end example
|
||
|
||
In this diagram, each box represents a slot that can hold or refer to
|
||
any Lisp object. Each pair of boxes represents a cons cell. Each arrow
|
||
represents a reference to a Lisp object, either an atom or another cons
|
||
cell.
|
||
|
||
In this example, the first box, which holds the @sc{car} of the first
|
||
cons cell, refers to or holds @code{rose} (a symbol). The second
|
||
box, holding the @sc{cdr} of the first cons cell, refers to the next
|
||
pair of boxes, the second cons cell. The @sc{car} of the second cons
|
||
cell is @code{violet}, and its @sc{cdr} is the third cons cell. The
|
||
@sc{cdr} of the third (and last) cons cell is @code{nil}.
|
||
|
||
Here is another diagram of the same list, @code{(rose violet
|
||
buttercup)}, sketched in a different manner:
|
||
|
||
@smallexample
|
||
@group
|
||
--------------- ---------------- -------------------
|
||
| car | cdr | | car | cdr | | car | cdr |
|
||
| rose | o-------->| violet | o-------->| buttercup | nil |
|
||
| | | | | | | | |
|
||
--------------- ---------------- -------------------
|
||
@end group
|
||
@end smallexample
|
||
|
||
@cindex @code{nil} as a list
|
||
@cindex empty list
|
||
A list with no elements in it is the @dfn{empty list}; it is identical
|
||
to the symbol @code{nil}. In other words, @code{nil} is both a symbol
|
||
and a list.
|
||
|
||
Here is the list @code{(A ())}, or equivalently @code{(A nil)},
|
||
depicted with boxes and arrows:
|
||
|
||
@example
|
||
@group
|
||
--- --- --- ---
|
||
| | |--> | | |--> nil
|
||
--- --- --- ---
|
||
| |
|
||
| |
|
||
--> A --> nil
|
||
@end group
|
||
@end example
|
||
|
||
Here is a more complex illustration, showing the three-element list,
|
||
@code{((pine needles) oak maple)}, the first element of which is a
|
||
two-element list:
|
||
|
||
@example
|
||
@group
|
||
--- --- --- --- --- ---
|
||
| | |--> | | |--> | | |--> nil
|
||
--- --- --- --- --- ---
|
||
| | |
|
||
| | |
|
||
| --> oak --> maple
|
||
|
|
||
| --- --- --- ---
|
||
--> | | |--> | | |--> nil
|
||
--- --- --- ---
|
||
| |
|
||
| |
|
||
--> pine --> needles
|
||
@end group
|
||
@end example
|
||
|
||
The same list represented in the second box notation looks like this:
|
||
|
||
@example
|
||
@group
|
||
-------------- -------------- --------------
|
||
| car | cdr | | car | cdr | | car | cdr |
|
||
| o | o------->| oak | o------->| maple | nil |
|
||
| | | | | | | | | |
|
||
-- | --------- -------------- --------------
|
||
|
|
||
|
|
||
| -------------- ----------------
|
||
| | car | cdr | | car | cdr |
|
||
------>| pine | o------->| needles | nil |
|
||
| | | | | |
|
||
-------------- ----------------
|
||
@end group
|
||
@end example
|
||
|
||
@node Dotted Pair Notation
|
||
@subsubsection Dotted Pair Notation
|
||
@cindex dotted pair notation
|
||
@cindex @samp{.} in lists
|
||
|
||
@dfn{Dotted pair notation} is a general syntax for cons cells that
|
||
represents the @sc{car} and @sc{cdr} explicitly. In this syntax,
|
||
@code{(@var{a} .@: @var{b})} stands for a cons cell whose @sc{car} is
|
||
the object @var{a} and whose @sc{cdr} is the object @var{b}. Dotted
|
||
pair notation is more general than list syntax because the @sc{cdr}
|
||
does not have to be a list. However, it is more cumbersome in cases
|
||
where list syntax would work. In dotted pair notation, the list
|
||
@samp{(1 2 3)} is written as @samp{(1 . (2 . (3 . nil)))}. For
|
||
@code{nil}-terminated lists, you can use either notation, but list
|
||
notation is usually clearer and more convenient. When printing a
|
||
list, the dotted pair notation is only used if the @sc{cdr} of a cons
|
||
cell is not a list.
|
||
|
||
Here's an example using boxes to illustrate dotted pair notation.
|
||
This example shows the pair @code{(rose . violet)}:
|
||
|
||
@example
|
||
@group
|
||
--- ---
|
||
| | |--> violet
|
||
--- ---
|
||
|
|
||
|
|
||
--> rose
|
||
@end group
|
||
@end example
|
||
|
||
You can combine dotted pair notation with list notation to represent
|
||
conveniently a chain of cons cells with a non-@code{nil} final @sc{cdr}.
|
||
You write a dot after the last element of the list, followed by the
|
||
@sc{cdr} of the final cons cell. For example, @code{(rose violet
|
||
. buttercup)} is equivalent to @code{(rose . (violet . buttercup))}.
|
||
The object looks like this:
|
||
|
||
@example
|
||
@group
|
||
--- --- --- ---
|
||
| | |--> | | |--> buttercup
|
||
--- --- --- ---
|
||
| |
|
||
| |
|
||
--> rose --> violet
|
||
@end group
|
||
@end example
|
||
|
||
The syntax @code{(rose .@: violet .@: buttercup)} is invalid because
|
||
there is nothing that it could mean. If anything, it would say to put
|
||
@code{buttercup} in the @sc{cdr} of a cons cell whose @sc{cdr} is already
|
||
used for @code{violet}.
|
||
|
||
The list @code{(rose violet)} is equivalent to @code{(rose . (violet))},
|
||
and looks like this:
|
||
|
||
@example
|
||
@group
|
||
--- --- --- ---
|
||
| | |--> | | |--> nil
|
||
--- --- --- ---
|
||
| |
|
||
| |
|
||
--> rose --> violet
|
||
@end group
|
||
@end example
|
||
|
||
Similarly, the three-element list @code{(rose violet buttercup)}
|
||
is equivalent to @code{(rose . (violet . (buttercup)))}.
|
||
@ifnottex
|
||
It looks like this:
|
||
|
||
@example
|
||
@group
|
||
--- --- --- --- --- ---
|
||
| | |--> | | |--> | | |--> nil
|
||
--- --- --- --- --- ---
|
||
| | |
|
||
| | |
|
||
--> rose --> violet --> buttercup
|
||
@end group
|
||
@end example
|
||
@end ifnottex
|
||
|
||
As a somewhat peculiar side effect of @code{(a b . c)} and
|
||
@code{(a . (b . c))} being equivalent, for consistency this means
|
||
that if you replace @code{b} here with the empty sequence, then it
|
||
follows that @code{(a . c)} and @code{(a . ( . c))} are equivalent,
|
||
too. This also means that @code{( . c)} is equivalent to @code{c},
|
||
but this is seldom used.
|
||
|
||
@node Association List Type
|
||
@subsubsection Association List Type
|
||
|
||
An @dfn{association list} or @dfn{alist} is a specially-constructed
|
||
list whose elements are cons cells. In each element, the @sc{car} is
|
||
considered a @dfn{key}, and the @sc{cdr} is considered an
|
||
@dfn{associated value}. (In some cases, the associated value is stored
|
||
in the @sc{car} of the @sc{cdr}.) Association lists are often used as
|
||
stacks, since it is easy to add or remove associations at the front of
|
||
the list.
|
||
|
||
For example,
|
||
|
||
@example
|
||
(setq alist-of-colors
|
||
'((rose . red) (lily . white) (buttercup . yellow)))
|
||
@end example
|
||
|
||
@noindent
|
||
sets the variable @code{alist-of-colors} to an alist of three elements. In the
|
||
first element, @code{rose} is the key and @code{red} is the value.
|
||
|
||
@xref{Association Lists}, for a further explanation of alists and for
|
||
functions that work on alists. @xref{Hash Tables}, for another kind of
|
||
lookup table, which is much faster for handling a large number of keys.
|
||
|
||
@node Array Type
|
||
@subsection Array Type
|
||
|
||
An @dfn{array} is composed of an arbitrary number of slots for
|
||
holding or referring to other Lisp objects, arranged in a contiguous block of
|
||
memory. Accessing any element of an array takes approximately the same
|
||
amount of time. In contrast, accessing an element of a list requires
|
||
time proportional to the position of the element in the list. (Elements
|
||
at the end of a list take longer to access than elements at the
|
||
beginning of a list.)
|
||
|
||
Emacs defines four types of array: strings, vectors, bool-vectors, and
|
||
char-tables.
|
||
|
||
A string is an array of characters and a vector is an array of
|
||
arbitrary objects. A bool-vector can hold only @code{t} or @code{nil}.
|
||
These kinds of array may have any length up to the largest fixnum,
|
||
subject to system architecture limits and available memory.
|
||
Char-tables are sparse arrays indexed by any valid character code; they
|
||
can hold arbitrary objects.
|
||
|
||
The first element of an array has index zero, the second element has
|
||
index 1, and so on. This is called @dfn{zero-origin} indexing. For
|
||
example, an array of four elements has indices 0, 1, 2, @w{and 3}. The
|
||
largest possible index value is one less than the length of the array.
|
||
Once an array is created, its length is fixed.
|
||
|
||
All Emacs Lisp arrays are one-dimensional. (Most other programming
|
||
languages support multidimensional arrays, but they are not essential;
|
||
you can get the same effect with nested one-dimensional arrays.) Each
|
||
type of array has its own read syntax; see the following sections for
|
||
details.
|
||
|
||
The array type is a subset of the sequence type, and contains the
|
||
string type, the vector type, the bool-vector type, and the char-table
|
||
type.
|
||
|
||
@node String Type
|
||
@subsection String Type
|
||
|
||
A @dfn{string} is an array of characters. Strings are used for many
|
||
purposes in Emacs, as can be expected in a text editor; for example, as
|
||
the names of Lisp symbols, as messages for the user, and to represent
|
||
text extracted from buffers. Strings in Lisp are constants: evaluation
|
||
of a string returns the same string.
|
||
|
||
@xref{Strings and Characters}, for functions that operate on strings.
|
||
|
||
@menu
|
||
* Syntax for Strings:: How to specify Lisp strings.
|
||
* Non-ASCII in Strings:: International characters in strings.
|
||
* Nonprinting Characters:: Literal unprintable characters in strings.
|
||
* Text Props and Strings:: Strings with text properties.
|
||
@end menu
|
||
|
||
@node Syntax for Strings
|
||
@subsubsection Syntax for Strings
|
||
|
||
@cindex @samp{"} in strings
|
||
@cindex double-quote in strings
|
||
@cindex @samp{\} in strings
|
||
@cindex backslash in strings
|
||
The read syntax for a string is a double-quote, an arbitrary number
|
||
of characters, and another double-quote, @code{"like this"}. To
|
||
include a double-quote in a string, precede it with a backslash; thus,
|
||
@code{"\""} is a string containing just one double-quote
|
||
character. Likewise, you can include a backslash by preceding it with
|
||
another backslash, like this: @code{"this \\ is a single embedded
|
||
backslash"}.
|
||
|
||
@cindex newline in strings
|
||
The newline character is not special in the read syntax for strings;
|
||
if you write a new line between the double-quotes, it becomes a
|
||
character in the string. But an escaped newline---one that is preceded
|
||
by @samp{\}---does not become part of the string; i.e., the Lisp reader
|
||
ignores an escaped newline while reading a string. An escaped space
|
||
@w{@samp{\ }} is likewise ignored.
|
||
|
||
@example
|
||
"It is useful to include newlines
|
||
in documentation strings,
|
||
but the newline is \
|
||
ignored if escaped."
|
||
@result{} "It is useful to include newlines
|
||
in documentation strings,
|
||
but the newline is ignored if escaped."
|
||
@end example
|
||
|
||
@node Non-ASCII in Strings
|
||
@subsubsection Non-@acronym{ASCII} Characters in Strings
|
||
|
||
There are two text representations for non-@acronym{ASCII}
|
||
characters in Emacs strings: multibyte and unibyte (@pxref{Text
|
||
Representations}). Roughly speaking, unibyte strings store raw bytes,
|
||
while multibyte strings store human-readable text. Each character in
|
||
a unibyte string is a byte, i.e., its value is between 0 and 255. By
|
||
contrast, each character in a multibyte string may have a value
|
||
between 0 to 4194303 (@pxref{Character Type}). In both cases,
|
||
characters above 127 are non-@acronym{ASCII}.
|
||
|
||
You can include a non-@acronym{ASCII} character in a string constant
|
||
by writing it literally. If the string constant is read from a
|
||
multibyte source, such as a multibyte buffer or string, or a file that
|
||
would be visited as multibyte, then Emacs reads each
|
||
non-@acronym{ASCII} character as a multibyte character and
|
||
automatically makes the string a multibyte string. If the string
|
||
constant is read from a unibyte source, then Emacs reads the
|
||
non-@acronym{ASCII} character as unibyte, and makes the string
|
||
unibyte.
|
||
|
||
Instead of writing a character literally into a multibyte string,
|
||
you can write it as its character code using an escape sequence.
|
||
@xref{General Escape Syntax}, for details about escape sequences.
|
||
|
||
If you use any Unicode-style escape sequence @samp{\uNNNN} or
|
||
@samp{\U00NNNNNN} in a string constant (even for an @acronym{ASCII}
|
||
character), Emacs automatically assumes that it is multibyte.
|
||
|
||
You can also use hexadecimal escape sequences (@samp{\x@var{n}}) and
|
||
octal escape sequences (@samp{\@var{n}}) in string constants.
|
||
@strong{But beware:} If a string constant contains hexadecimal or
|
||
octal escape sequences, and these escape sequences all specify unibyte
|
||
characters (i.e., less than 256), and there are no other literal
|
||
non-@acronym{ASCII} characters or Unicode-style escape sequences in
|
||
the string, then Emacs automatically assumes that it is a unibyte
|
||
string. That is to say, it assumes that all non-@acronym{ASCII}
|
||
characters occurring in the string are 8-bit raw bytes.
|
||
|
||
In hexadecimal and octal escape sequences, the escaped character
|
||
code may contain a variable number of digits, so the first subsequent
|
||
character which is not a valid hexadecimal or octal digit terminates
|
||
the escape sequence. If the next character in a string could be
|
||
interpreted as a hexadecimal or octal digit, write @w{@samp{\ }}
|
||
(backslash and space) to terminate the escape sequence. For example,
|
||
@w{@samp{\xe0\ }} represents one character, @samp{a} with grave
|
||
accent. @w{@samp{\ }} in a string constant is just like
|
||
backslash-newline; it does not contribute any character to the string,
|
||
but it does terminate any preceding hex escape.
|
||
|
||
@node Nonprinting Characters
|
||
@subsubsection Nonprinting Characters in Strings
|
||
|
||
You can use the same backslash escape-sequences in a string constant
|
||
as in character literals (but do not use the question mark that begins a
|
||
character constant). For example, you can write a string containing the
|
||
nonprinting characters tab and @kbd{C-a}, with commas and spaces between
|
||
them, like this: @code{"\t, \C-a"}. @xref{Character Type}, for a
|
||
description of the read syntax for characters.
|
||
|
||
However, not all of the characters you can write with backslash
|
||
escape-sequences are valid in strings. The only control characters that
|
||
a string can hold are the @acronym{ASCII} control characters. Strings do not
|
||
distinguish case in @acronym{ASCII} control characters.
|
||
|
||
Properly speaking, strings cannot hold meta characters; but when a
|
||
string is to be used as a key sequence, there is a special convention
|
||
that provides a way to represent meta versions of @acronym{ASCII}
|
||
characters in a string. If you use the @samp{\M-} syntax to indicate
|
||
a meta character in a string constant, this sets the
|
||
@tex
|
||
@math{2^{7}}
|
||
@end tex
|
||
@ifnottex
|
||
2**7
|
||
@end ifnottex
|
||
bit of the character in the string. If the string is used in
|
||
@code{define-key} or @code{lookup-key}, this numeric code is translated
|
||
into the equivalent meta character. @xref{Character Type}.
|
||
|
||
Strings cannot hold characters that have the hyper, super, or alt
|
||
modifiers.
|
||
|
||
@node Text Props and Strings
|
||
@subsubsection Text Properties in Strings
|
||
|
||
@cindex @samp{#(} read syntax
|
||
@cindex text properties, read syntax
|
||
A string can hold properties for the characters it contains, in
|
||
addition to the characters themselves. This enables programs that copy
|
||
text between strings and buffers to copy the text's properties with no
|
||
special effort. @xref{Text Properties}, for an explanation of what text
|
||
properties mean. Strings with text properties use a special read and
|
||
print syntax:
|
||
|
||
@example
|
||
#("@var{characters}" @var{property-data}...)
|
||
@end example
|
||
|
||
@noindent
|
||
where @var{property-data} consists of zero or more elements, in groups
|
||
of three as follows:
|
||
|
||
@example
|
||
@var{beg} @var{end} @var{plist}
|
||
@end example
|
||
|
||
@noindent
|
||
The elements @var{beg} and @var{end} are integers, and together specify
|
||
a range of indices in the string; @var{plist} is the property list for
|
||
that range. For example,
|
||
|
||
@example
|
||
#("foo bar" 0 3 (face bold) 3 4 nil 4 7 (face italic))
|
||
@end example
|
||
|
||
@noindent
|
||
represents a string whose textual contents are @samp{foo bar}, in which
|
||
the first three characters have a @code{face} property with value
|
||
@code{bold}, and the last three have a @code{face} property with value
|
||
@code{italic}. (The fourth character has no text properties, so its
|
||
property list is @code{nil}. It is not actually necessary to mention
|
||
ranges with @code{nil} as the property list, since any characters not
|
||
mentioned in any range will default to having no properties.)
|
||
|
||
@node Vector Type
|
||
@subsection Vector Type
|
||
|
||
A @dfn{vector} is a one-dimensional array of elements of any type. It
|
||
takes a constant amount of time to access any element of a vector. (In
|
||
a list, the access time of an element is proportional to the distance of
|
||
the element from the beginning of the list.)
|
||
|
||
The printed representation of a vector consists of a left square
|
||
bracket, the elements, and a right square bracket. This is also the
|
||
read syntax. Like numbers and strings, vectors are considered constants
|
||
for evaluation.
|
||
|
||
@example
|
||
[1 "two" (three)] ; @r{A vector of three elements.}
|
||
@result{} [1 "two" (three)]
|
||
@end example
|
||
|
||
@xref{Vectors}, for functions that work with vectors.
|
||
|
||
@node Char-Table Type
|
||
@subsection Char-Table Type
|
||
|
||
A @dfn{char-table} is a one-dimensional array of elements of any type,
|
||
indexed by character codes. Char-tables have certain extra features to
|
||
make them more useful for many jobs that involve assigning information
|
||
to character codes---for example, a char-table can have a parent to
|
||
inherit from, a default value, and a small number of extra slots to use for
|
||
special purposes. A char-table can also specify a single value for
|
||
a whole character set.
|
||
|
||
@cindex @samp{#^} read syntax
|
||
The printed representation of a char-table is like a vector
|
||
except that there is an extra @samp{#^} at the beginning.@footnote{You
|
||
may also encounter @samp{#^^}, used for sub-char-tables.}
|
||
|
||
@xref{Char-Tables}, for special functions to operate on char-tables.
|
||
Uses of char-tables include:
|
||
|
||
@itemize @bullet
|
||
@item
|
||
Case tables (@pxref{Case Tables}).
|
||
|
||
@item
|
||
Character category tables (@pxref{Categories}).
|
||
|
||
@item
|
||
Display tables (@pxref{Display Tables}).
|
||
|
||
@item
|
||
Syntax tables (@pxref{Syntax Tables}).
|
||
@end itemize
|
||
|
||
@node Bool-Vector Type
|
||
@subsection Bool-Vector Type
|
||
|
||
A @dfn{bool-vector} is a one-dimensional array whose elements must
|
||
be @code{t} or @code{nil}.
|
||
|
||
The printed representation of a bool-vector is like a string, except
|
||
that it begins with @samp{#&} followed by the length. The string
|
||
constant that follows actually specifies the contents of the bool-vector
|
||
as a bitmap---each character in the string contains 8 bits, which
|
||
specify the next 8 elements of the bool-vector (1 stands for @code{t},
|
||
and 0 for @code{nil}). The least significant bits of the character
|
||
correspond to the lowest indices in the bool-vector.
|
||
|
||
@example
|
||
(make-bool-vector 3 t)
|
||
@result{} #&3"^G"
|
||
(make-bool-vector 3 nil)
|
||
@result{} #&3"^@@"
|
||
@end example
|
||
|
||
@noindent
|
||
These results make sense, because the binary code for @samp{C-g} is
|
||
111 and @samp{C-@@} is the character with code 0.
|
||
|
||
If the length is not a multiple of 8, the printed representation
|
||
shows extra elements, but these extras really make no difference. For
|
||
instance, in the next example, the two bool-vectors are equal, because
|
||
only the first 3 bits are used:
|
||
|
||
@example
|
||
(equal #&3"\377" #&3"\007")
|
||
@result{} t
|
||
@end example
|
||
|
||
@node Hash Table Type
|
||
@subsection Hash Table Type
|
||
|
||
A hash table is a very fast kind of lookup table, somewhat like an
|
||
alist in that it maps keys to corresponding values, but much faster.
|
||
The printed representation of a hash table specifies its properties
|
||
and contents, like this:
|
||
|
||
@example
|
||
(make-hash-table)
|
||
@result{} #s(hash-table size 65 test eql rehash-size 1.5
|
||
rehash-threshold 0.8125 data ())
|
||
@end example
|
||
|
||
@noindent
|
||
@xref{Hash Tables}, for more information about hash tables.
|
||
|
||
@node Function Type
|
||
@subsection Function Type
|
||
|
||
Lisp functions are executable code, just like functions in other
|
||
programming languages. In Lisp, unlike most languages, functions are
|
||
also Lisp objects. A non-compiled function in Lisp is a lambda
|
||
expression: that is, a list whose first element is the symbol
|
||
@code{lambda} (@pxref{Lambda Expressions}).
|
||
|
||
In most programming languages, it is impossible to have a function
|
||
without a name. In Lisp, a function has no intrinsic name. A lambda
|
||
expression can be called as a function even though it has no name; to
|
||
emphasize this, we also call it an @dfn{anonymous function}
|
||
(@pxref{Anonymous Functions}). A named function in Lisp is just a
|
||
symbol with a valid function in its function cell (@pxref{Defining
|
||
Functions}).
|
||
|
||
Most of the time, functions are called when their names are written in
|
||
Lisp expressions in Lisp programs. However, you can construct or obtain
|
||
a function object at run time and then call it with the primitive
|
||
functions @code{funcall} and @code{apply}. @xref{Calling Functions}.
|
||
|
||
@node Macro Type
|
||
@subsection Macro Type
|
||
|
||
A @dfn{Lisp macro} is a user-defined construct that extends the Lisp
|
||
language. It is represented as an object much like a function, but with
|
||
different argument-passing semantics. A Lisp macro has the form of a
|
||
list whose first element is the symbol @code{macro} and whose @sc{cdr}
|
||
is a Lisp function object, including the @code{lambda} symbol.
|
||
|
||
Lisp macro objects are usually defined with the built-in
|
||
@code{defmacro} macro, but any list that begins with @code{macro} is a
|
||
macro as far as Emacs is concerned. @xref{Macros}, for an explanation
|
||
of how to write a macro.
|
||
|
||
@strong{Warning}: Lisp macros and keyboard macros (@pxref{Keyboard
|
||
Macros}) are entirely different things. When we use the word ``macro''
|
||
without qualification, we mean a Lisp macro, not a keyboard macro.
|
||
|
||
@node Primitive Function Type
|
||
@subsection Primitive Function Type
|
||
@cindex primitive function
|
||
|
||
A @dfn{primitive function} is a function callable from Lisp but
|
||
written in the C programming language. Primitive functions are also
|
||
called @dfn{subrs} or @dfn{built-in functions}. (The word ``subr'' is
|
||
derived from ``subroutine''.) Most primitive functions evaluate all
|
||
their arguments when they are called. A primitive function that does
|
||
not evaluate all its arguments is called a @dfn{special form}
|
||
(@pxref{Special Forms}).
|
||
|
||
It does not matter to the caller of a function whether the function is
|
||
primitive. However, this does matter if you try to redefine a primitive
|
||
with a function written in Lisp. The reason is that the primitive
|
||
function may be called directly from C code. Calls to the redefined
|
||
function from Lisp will use the new definition, but calls from C code
|
||
may still use the built-in definition. Therefore, @strong{we discourage
|
||
redefinition of primitive functions}.
|
||
|
||
The term @dfn{function} refers to all Emacs functions, whether written
|
||
in Lisp or C@. @xref{Function Type}, for information about the
|
||
functions written in Lisp.
|
||
|
||
Primitive functions have no read syntax and print in hash notation
|
||
with the name of the subroutine.
|
||
|
||
@example
|
||
@group
|
||
(symbol-function 'car) ; @r{Access the function cell}
|
||
; @r{of the symbol.}
|
||
@result{} #<subr car>
|
||
(subrp (symbol-function 'car)) ; @r{Is this a primitive function?}
|
||
@result{} t ; @r{Yes.}
|
||
@end group
|
||
@end example
|
||
|
||
@node Byte-Code Type
|
||
@subsection Byte-Code Function Type
|
||
|
||
@dfn{Byte-code function objects} are produced by byte-compiling Lisp
|
||
code (@pxref{Byte Compilation}). Internally, a byte-code function
|
||
object is much like a vector; however, the evaluator handles this data
|
||
type specially when it appears in a function call. @xref{Byte-Code
|
||
Objects}.
|
||
|
||
The printed representation and read syntax for a byte-code function
|
||
object is like that for a vector, with an additional @samp{#} before the
|
||
opening @samp{[}.
|
||
|
||
@node Record Type
|
||
@subsection Record Type
|
||
|
||
A @dfn{record} is much like a @code{vector}. However, the first
|
||
element is used to hold its type as returned by @code{type-of}. The
|
||
purpose of records is to allow programmers to create objects with new
|
||
types that are not built into Emacs.
|
||
|
||
@xref{Records}, for functions that work with records.
|
||
|
||
@node Type Descriptors
|
||
@subsection Type Descriptors
|
||
|
||
A @dfn{type descriptor} is a @code{record} which holds information
|
||
about a type. Slot 1 in the record must be a symbol naming the type, and
|
||
@code{type-of} relies on this to return the type of @code{record}
|
||
objects. No other type descriptor slot is used by Emacs; they are
|
||
free for use by Lisp extensions.
|
||
|
||
An example of a type descriptor is any instance of
|
||
@code{cl-structure-class}.
|
||
|
||
@node Autoload Type
|
||
@subsection Autoload Type
|
||
|
||
An @dfn{autoload object} is a list whose first element is the symbol
|
||
@code{autoload}. It is stored as the function definition of a symbol,
|
||
where it serves as a placeholder for the real definition. The autoload
|
||
object says that the real definition is found in a file of Lisp code
|
||
that should be loaded when necessary. It contains the name of the file,
|
||
plus some other information about the real definition.
|
||
|
||
After the file has been loaded, the symbol should have a new function
|
||
definition that is not an autoload object. The new definition is then
|
||
called as if it had been there to begin with. From the user's point of
|
||
view, the function call works as expected, using the function definition
|
||
in the loaded file.
|
||
|
||
An autoload object is usually created with the function
|
||
@code{autoload}, which stores the object in the function cell of a
|
||
symbol. @xref{Autoload}, for more details.
|
||
|
||
@node Finalizer Type
|
||
@subsection Finalizer Type
|
||
|
||
A @dfn{finalizer object} helps Lisp code clean up after objects that
|
||
are no longer needed. A finalizer holds a Lisp function object.
|
||
When a finalizer object becomes unreachable after a garbage collection
|
||
pass, Emacs calls the finalizer's associated function object.
|
||
When deciding whether a finalizer is reachable, Emacs does not count
|
||
references from finalizer objects themselves, allowing you to use
|
||
finalizers without having to worry about accidentally capturing
|
||
references to finalized objects themselves.
|
||
|
||
Errors in finalizers are printed to @code{*Messages*}. Emacs runs
|
||
a given finalizer object's associated function exactly once, even
|
||
if that function fails.
|
||
|
||
@defun make-finalizer function
|
||
Make a finalizer that will run @var{function}. @var{function} will be
|
||
called after garbage collection when the returned finalizer object
|
||
becomes unreachable. If the finalizer object is reachable only
|
||
through references from finalizer objects, it does not count as
|
||
reachable for the purpose of deciding whether to run @var{function}.
|
||
@var{function} will be run once per finalizer object.
|
||
@end defun
|
||
|
||
@node Editing Types
|
||
@section Editing Types
|
||
@cindex editing types
|
||
|
||
The types in the previous section are used for general programming
|
||
purposes, and most of them are common to most Lisp dialects. Emacs Lisp
|
||
provides several additional data types for purposes connected with
|
||
editing.
|
||
|
||
@menu
|
||
* Buffer Type:: The basic object of editing.
|
||
* Marker Type:: A position in a buffer.
|
||
* Window Type:: Buffers are displayed in windows.
|
||
* Frame Type:: Windows subdivide frames.
|
||
* Terminal Type:: A terminal device displays frames.
|
||
* Window Configuration Type:: Recording the way a frame is subdivided.
|
||
* Frame Configuration Type:: Recording the status of all frames.
|
||
* Process Type:: A subprocess of Emacs running on the underlying OS.
|
||
* Thread Type:: A thread of Emacs Lisp execution.
|
||
* Mutex Type:: An exclusive lock for thread synchronization.
|
||
* Condition Variable Type:: Condition variable for thread synchronization.
|
||
* Stream Type:: Receive or send characters.
|
||
* Keymap Type:: What function a keystroke invokes.
|
||
* Overlay Type:: How an overlay is represented.
|
||
* Font Type:: Fonts for displaying text.
|
||
* Xwidget Type:: Embeddable widgets.
|
||
@end menu
|
||
|
||
@node Buffer Type
|
||
@subsection Buffer Type
|
||
|
||
A @dfn{buffer} is an object that holds text that can be edited
|
||
(@pxref{Buffers}). Most buffers hold the contents of a disk file
|
||
(@pxref{Files}) so they can be edited, but some are used for other
|
||
purposes. Most buffers are also meant to be seen by the user, and
|
||
therefore displayed, at some time, in a window (@pxref{Windows}). But
|
||
a buffer need not be displayed in any window. Each buffer has a
|
||
designated position called @dfn{point} (@pxref{Positions}); most
|
||
editing commands act on the contents of the current buffer in the
|
||
neighborhood of point. At any time, one buffer is the @dfn{current
|
||
buffer}.
|
||
|
||
The contents of a buffer are much like a string, but buffers are not
|
||
used like strings in Emacs Lisp, and the available operations are
|
||
different. For example, you can insert text efficiently into an
|
||
existing buffer, altering the buffer's contents, whereas inserting
|
||
text into a string requires concatenating substrings, and the result
|
||
is an entirely new string object.
|
||
|
||
Many of the standard Emacs functions manipulate or test the
|
||
characters in the current buffer; a whole chapter in this manual is
|
||
devoted to describing these functions (@pxref{Text}).
|
||
|
||
Several other data structures are associated with each buffer:
|
||
|
||
@itemize @bullet
|
||
@item
|
||
a local syntax table (@pxref{Syntax Tables});
|
||
|
||
@item
|
||
a local keymap (@pxref{Keymaps}); and,
|
||
|
||
@item
|
||
a list of buffer-local variable bindings (@pxref{Buffer-Local Variables}).
|
||
|
||
@item
|
||
overlays (@pxref{Overlays}).
|
||
|
||
@item
|
||
text properties for the text in the buffer (@pxref{Text Properties}).
|
||
@end itemize
|
||
|
||
@noindent
|
||
The local keymap and variable list contain entries that individually
|
||
override global bindings or values. These are used to customize the
|
||
behavior of programs in different buffers, without actually changing the
|
||
programs.
|
||
|
||
A buffer may be @dfn{indirect}, which means it shares the text
|
||
of another buffer, but presents it differently. @xref{Indirect Buffers}.
|
||
|
||
Buffers have no read syntax. They print in hash notation, showing the
|
||
buffer name.
|
||
|
||
@example
|
||
@group
|
||
(current-buffer)
|
||
@result{} #<buffer objects.texi>
|
||
@end group
|
||
@end example
|
||
|
||
@node Marker Type
|
||
@subsection Marker Type
|
||
|
||
A @dfn{marker} denotes a position in a specific buffer. Markers
|
||
therefore have two components: one for the buffer, and one for the
|
||
position. Changes in the buffer's text automatically relocate the
|
||
position value as necessary to ensure that the marker always points
|
||
between the same two characters in the buffer.
|
||
|
||
Markers have no read syntax. They print in hash notation, giving the
|
||
current character position and the name of the buffer.
|
||
|
||
@example
|
||
@group
|
||
(point-marker)
|
||
@result{} #<marker at 10779 in objects.texi>
|
||
@end group
|
||
@end example
|
||
|
||
@xref{Markers}, for information on how to test, create, copy, and move
|
||
markers.
|
||
|
||
@node Window Type
|
||
@subsection Window Type
|
||
|
||
A @dfn{window} describes the portion of the screen that Emacs uses to
|
||
display buffers. Every live window (@pxref{Basic Windows}) has one
|
||
associated buffer, whose contents appear in that window. By contrast, a
|
||
given buffer may appear in one window, no window, or several windows.
|
||
Windows are grouped on the screen into frames; each window belongs to
|
||
one and only one frame. @xref{Frame Type}.
|
||
|
||
Though many windows may exist simultaneously, at any time one window
|
||
is designated the @dfn{selected window} (@pxref{Selecting Windows}).
|
||
This is the window where the cursor is (usually) displayed when Emacs is
|
||
ready for a command. The selected window usually displays the current
|
||
buffer (@pxref{Current Buffer}), but this is not necessarily the case.
|
||
|
||
Windows have no read syntax. They print in hash notation, giving the
|
||
window number and the name of the buffer being displayed. The window
|
||
numbers exist to identify windows uniquely, since the buffer displayed
|
||
in any given window can change frequently.
|
||
|
||
@example
|
||
@group
|
||
(selected-window)
|
||
@result{} #<window 1 on objects.texi>
|
||
@end group
|
||
@end example
|
||
|
||
@xref{Windows}, for a description of the functions that work on windows.
|
||
|
||
@node Frame Type
|
||
@subsection Frame Type
|
||
|
||
A @dfn{frame} is a screen area that contains one or more Emacs
|
||
windows; we also use the term ``frame'' to refer to the Lisp object
|
||
that Emacs uses to refer to the screen area.
|
||
|
||
Frames have no read syntax. They print in hash notation, giving the
|
||
frame's title, plus its address in core (useful to identify the frame
|
||
uniquely).
|
||
|
||
@example
|
||
@group
|
||
(selected-frame)
|
||
@result{} #<frame emacs@@psilocin.gnu.org 0xdac80>
|
||
@end group
|
||
@end example
|
||
|
||
@xref{Frames}, for a description of the functions that work on frames.
|
||
|
||
@node Terminal Type
|
||
@subsection Terminal Type
|
||
@cindex terminal type
|
||
|
||
A @dfn{terminal} is a device capable of displaying one or more
|
||
Emacs frames (@pxref{Frame Type}).
|
||
|
||
Terminals have no read syntax. They print in hash notation giving
|
||
the terminal's ordinal number and its TTY device file name.
|
||
|
||
@example
|
||
@group
|
||
(get-device-terminal nil)
|
||
@result{} #<terminal 1 on /dev/tty>
|
||
@end group
|
||
@end example
|
||
|
||
@c FIXME: add an xref to where terminal-related primitives are described.
|
||
|
||
@node Window Configuration Type
|
||
@subsection Window Configuration Type
|
||
@cindex window layout in a frame
|
||
|
||
A @dfn{window configuration} stores information about the positions,
|
||
sizes, and contents of the windows in a frame, so you can recreate the
|
||
same arrangement of windows later.
|
||
|
||
Window configurations do not have a read syntax; their print syntax
|
||
looks like @samp{#<window-configuration>}. @xref{Window
|
||
Configurations}, for a description of several functions related to
|
||
window configurations.
|
||
|
||
@node Frame Configuration Type
|
||
@subsection Frame Configuration Type
|
||
@cindex screen layout
|
||
@cindex window layout, all frames
|
||
|
||
A @dfn{frame configuration} stores information about the positions,
|
||
sizes, and contents of the windows in all frames. It is not a
|
||
primitive type---it is actually a list whose @sc{car} is
|
||
@code{frame-configuration} and whose @sc{cdr} is an alist. Each alist
|
||
element describes one frame, which appears as the @sc{car} of that
|
||
element.
|
||
|
||
@xref{Frame Configurations}, for a description of several functions
|
||
related to frame configurations.
|
||
|
||
@node Process Type
|
||
@subsection Process Type
|
||
|
||
The word @dfn{process} usually means a running program. Emacs itself
|
||
runs in a process of this sort. However, in Emacs Lisp, a process is a
|
||
Lisp object that designates a subprocess created by the Emacs process.
|
||
Programs such as shells, GDB, ftp, and compilers, running in
|
||
subprocesses of Emacs, extend the capabilities of Emacs.
|
||
An Emacs subprocess takes textual input from Emacs and returns textual
|
||
output to Emacs for further manipulation. Emacs can also send signals
|
||
to the subprocess.
|
||
|
||
Process objects have no read syntax. They print in hash notation,
|
||
giving the name of the process:
|
||
|
||
@example
|
||
@group
|
||
(process-list)
|
||
@result{} (#<process shell>)
|
||
@end group
|
||
@end example
|
||
|
||
@xref{Processes}, for information about functions that create, delete,
|
||
return information about, send input or signals to, and receive output
|
||
from processes.
|
||
|
||
@node Thread Type
|
||
@subsection Thread Type
|
||
|
||
A @dfn{thread} in Emacs represents a separate thread of Emacs Lisp
|
||
execution. It runs its own Lisp program, has its own current buffer,
|
||
and can have subprocesses locked to it, i.e.@: subprocesses whose
|
||
output only this thread can accept. @xref{Threads}.
|
||
|
||
Thread objects have no read syntax. They print in hash notation,
|
||
giving the name of the thread (if it has been given a name) or its
|
||
address in core:
|
||
|
||
@example
|
||
@group
|
||
(all-threads)
|
||
@result{} (#<thread 0176fc40>)
|
||
@end group
|
||
@end example
|
||
|
||
@node Mutex Type
|
||
@subsection Mutex Type
|
||
|
||
A @dfn{mutex} is an exclusive lock that threads can own and disown,
|
||
in order to synchronize between them. @xref{Mutexes}.
|
||
|
||
Mutex objects have no read syntax. They print in hash notation,
|
||
giving the name of the mutex (if it has been given a name) or its
|
||
address in core:
|
||
|
||
@example
|
||
@group
|
||
(make-mutex "my-mutex")
|
||
@result{} #<mutex my-mutex>
|
||
(make-mutex)
|
||
@result{} #<mutex 01c7e4e0>
|
||
@end group
|
||
@end example
|
||
|
||
@node Condition Variable Type
|
||
@subsection Condition Variable Type
|
||
|
||
A @dfn{condition variable} is a device for a more complex thread
|
||
synchronization than the one supported by a mutex. A thread can wait
|
||
on a condition variable, to be woken up when some other thread
|
||
notifies the condition.
|
||
|
||
Condition variable objects have no read syntax. They print in hash
|
||
notation, giving the name of the condition variable (if it has been
|
||
given a name) or its address in core:
|
||
|
||
@example
|
||
@group
|
||
(make-condition-variable (make-mutex))
|
||
@result{} #<condvar 01c45ae8>
|
||
@end group
|
||
@end example
|
||
|
||
@node Stream Type
|
||
@subsection Stream Type
|
||
|
||
A @dfn{stream} is an object that can be used as a source or sink for
|
||
characters---either to supply characters for input or to accept them as
|
||
output. Many different types can be used this way: markers, buffers,
|
||
strings, and functions. Most often, input streams (character sources)
|
||
obtain characters from the keyboard, a buffer, or a file, and output
|
||
streams (character sinks) send characters to a buffer, such as a
|
||
@file{*Help*} buffer, or to the echo area.
|
||
|
||
The object @code{nil}, in addition to its other meanings, may be used
|
||
as a stream. It stands for the value of the variable
|
||
@code{standard-input} or @code{standard-output}. Also, the object
|
||
@code{t} as a stream specifies input using the minibuffer
|
||
(@pxref{Minibuffers}) or output in the echo area (@pxref{The Echo
|
||
Area}).
|
||
|
||
Streams have no special printed representation or read syntax, and
|
||
print as whatever primitive type they are.
|
||
|
||
@xref{Read and Print}, for a description of functions
|
||
related to streams, including parsing and printing functions.
|
||
|
||
@node Keymap Type
|
||
@subsection Keymap Type
|
||
|
||
A @dfn{keymap} maps keys typed by the user to commands. This mapping
|
||
controls how the user's command input is executed. A keymap is actually
|
||
a list whose @sc{car} is the symbol @code{keymap}.
|
||
|
||
@xref{Keymaps}, for information about creating keymaps, handling prefix
|
||
keys, local as well as global keymaps, and changing key bindings.
|
||
|
||
@node Overlay Type
|
||
@subsection Overlay Type
|
||
|
||
An @dfn{overlay} specifies properties that apply to a part of a
|
||
buffer. Each overlay applies to a specified range of the buffer, and
|
||
contains a property list (a list whose elements are alternating property
|
||
names and values). Overlay properties are used to present parts of the
|
||
buffer temporarily in a different display style. Overlays have no read
|
||
syntax, and print in hash notation, giving the buffer name and range of
|
||
positions.
|
||
|
||
@xref{Overlays}, for information on how you can create and use overlays.
|
||
|
||
@node Font Type
|
||
@subsection Font Type
|
||
|
||
A @dfn{font} specifies how to display text on a graphical terminal.
|
||
There are actually three separate font types---@dfn{font objects},
|
||
@dfn{font specs}, and @dfn{font entities}---each of which has slightly
|
||
different properties. None of them have a read syntax; their print
|
||
syntax looks like @samp{#<font-object>}, @samp{#<font-spec>}, and
|
||
@samp{#<font-entity>} respectively. @xref{Low-Level Font}, for a
|
||
description of these Lisp objects.
|
||
|
||
@node Xwidget Type
|
||
@subsection Xwidget Type
|
||
@cindex xwidget type
|
||
@cindex xwidget-view type
|
||
|
||
An @dfn{xwidget} is a special display element, such as a web
|
||
browser, that can be embedded inside a buffer. Each window that
|
||
displays an xwidget will also have an @dfn{xwidget view}, which on
|
||
X-Windows corresponds to a single X window used to display the widget.
|
||
|
||
Neither of these objects are readable; their print syntaxes look like
|
||
@samp{#<xwidget>} and @samp{#<xwidget-view>}, respectively.
|
||
@xref{Xwidgets}, for a more detailed description of xwidgets.
|
||
|
||
@node Circular Objects
|
||
@section Read Syntax for Circular Objects
|
||
@cindex circular structure, read syntax
|
||
@cindex shared structure, read syntax
|
||
@cindex @samp{#@var{n}=} read syntax
|
||
@cindex @samp{#@var{n}#} read syntax
|
||
|
||
To represent shared or circular structures within a complex of Lisp
|
||
objects, you can use the reader constructs @samp{#@var{n}=} and
|
||
@samp{#@var{n}#}.
|
||
|
||
Use @code{#@var{n}=} before an object to label it for later reference;
|
||
subsequently, you can use @code{#@var{n}#} to refer the same object in
|
||
another place. Here, @var{n} is some integer. For example, here is how
|
||
to make a list in which the first element recurs as the third element:
|
||
|
||
@example
|
||
(#1=(a) b #1#)
|
||
@end example
|
||
|
||
@noindent
|
||
This differs from ordinary syntax such as this
|
||
|
||
@example
|
||
((a) b (a))
|
||
@end example
|
||
|
||
@noindent
|
||
which would result in a list whose first and third elements
|
||
look alike but are not the same Lisp object. This shows the difference:
|
||
|
||
@example
|
||
(prog1 nil
|
||
(setq x '(#1=(a) b #1#)))
|
||
(eq (nth 0 x) (nth 2 x))
|
||
@result{} t
|
||
(setq x '((a) b (a)))
|
||
(eq (nth 0 x) (nth 2 x))
|
||
@result{} nil
|
||
@end example
|
||
|
||
You can also use the same syntax to make a circular structure, which
|
||
appears as an element within itself. Here is an example:
|
||
|
||
@example
|
||
#1=(a #1#)
|
||
@end example
|
||
|
||
@noindent
|
||
This makes a list whose second element is the list itself.
|
||
Here's how you can see that it really works:
|
||
|
||
@example
|
||
(prog1 nil
|
||
(setq x '#1=(a #1#)))
|
||
(eq x (cadr x))
|
||
@result{} t
|
||
@end example
|
||
|
||
The Lisp printer can produce this syntax to record circular and shared
|
||
structure in a Lisp object, if you bind the variable @code{print-circle}
|
||
to a non-@code{nil} value. @xref{Output Variables}.
|
||
|
||
@node Type Predicates
|
||
@section Type Predicates
|
||
@cindex type checking
|
||
@kindex wrong-type-argument
|
||
|
||
The Emacs Lisp interpreter itself does not perform type checking on
|
||
the actual arguments passed to functions when they are called. It could
|
||
not do so, since function arguments in Lisp do not have declared data
|
||
types, as they do in other programming languages. It is therefore up to
|
||
the individual function to test whether each actual argument belongs to
|
||
a type that the function can use.
|
||
|
||
All built-in functions do check the types of their actual arguments
|
||
when appropriate, and signal a @code{wrong-type-argument} error if an
|
||
argument is of the wrong type. For example, here is what happens if you
|
||
pass an argument to @code{+} that it cannot handle:
|
||
|
||
@example
|
||
@group
|
||
(+ 2 'a)
|
||
@error{} Wrong type argument: number-or-marker-p, a
|
||
@end group
|
||
@end example
|
||
|
||
@cindex type predicates
|
||
@cindex testing types
|
||
If you want your program to handle different types differently, you
|
||
must do explicit type checking. The most common way to check the type
|
||
of an object is to call a @dfn{type predicate} function. Emacs has a
|
||
type predicate for each type, as well as some predicates for
|
||
combinations of types.
|
||
|
||
A type predicate function takes one argument; it returns @code{t} if
|
||
the argument belongs to the appropriate type, and @code{nil} otherwise.
|
||
Following a general Lisp convention for predicate functions, most type
|
||
predicates' names end with @samp{p}.
|
||
|
||
Here is an example which uses the predicates @code{listp} to check for
|
||
a list and @code{symbolp} to check for a symbol.
|
||
|
||
@example
|
||
(defun add-on (x)
|
||
(cond ((symbolp x)
|
||
;; If X is a symbol, put it on LIST.
|
||
(setq list (cons x list)))
|
||
((listp x)
|
||
;; If X is a list, add its elements to LIST.
|
||
(setq list (append x list)))
|
||
(t
|
||
;; We handle only symbols and lists.
|
||
(error "Invalid argument %s in add-on" x))))
|
||
@end example
|
||
|
||
Here is a table of predefined type predicates, in alphabetical order,
|
||
with references to further information.
|
||
|
||
@table @code
|
||
@item atom
|
||
@xref{List-related Predicates, atom}.
|
||
|
||
@item arrayp
|
||
@xref{Array Functions, arrayp}.
|
||
|
||
@item bignump
|
||
@xref{Predicates on Numbers, floatp}.
|
||
|
||
@item bool-vector-p
|
||
@xref{Bool-Vectors, bool-vector-p}.
|
||
|
||
@item booleanp
|
||
@xref{nil and t, booleanp}.
|
||
|
||
@item bufferp
|
||
@xref{Buffer Basics, bufferp}.
|
||
|
||
@item byte-code-function-p
|
||
@xref{Byte-Code Type, byte-code-function-p}.
|
||
|
||
@item case-table-p
|
||
@xref{Case Tables, case-table-p}.
|
||
|
||
@item char-or-string-p
|
||
@xref{Predicates for Strings, char-or-string-p}.
|
||
|
||
@item char-table-p
|
||
@xref{Char-Tables, char-table-p}.
|
||
|
||
@item commandp
|
||
@xref{Interactive Call, commandp}.
|
||
|
||
@item condition-variable-p
|
||
@xref{Condition Variables, condition-variable-p}.
|
||
|
||
@item consp
|
||
@xref{List-related Predicates, consp}.
|
||
|
||
@item custom-variable-p
|
||
@xref{Variable Definitions, custom-variable-p}.
|
||
|
||
@item fixnump
|
||
@xref{Predicates on Numbers, floatp}.
|
||
|
||
@item floatp
|
||
@xref{Predicates on Numbers, floatp}.
|
||
|
||
@item fontp
|
||
@xref{Low-Level Font}.
|
||
|
||
@item frame-configuration-p
|
||
@xref{Frame Configurations, frame-configuration-p}.
|
||
|
||
@item frame-live-p
|
||
@xref{Deleting Frames, frame-live-p}.
|
||
|
||
@item framep
|
||
@xref{Frames, framep}.
|
||
|
||
@item functionp
|
||
@xref{Functions, functionp}.
|
||
|
||
@item hash-table-p
|
||
@xref{Other Hash, hash-table-p}.
|
||
|
||
@item integer-or-marker-p
|
||
@xref{Predicates on Markers, integer-or-marker-p}.
|
||
|
||
@item integerp
|
||
@xref{Predicates on Numbers, integerp}.
|
||
|
||
@item keymapp
|
||
@xref{Creating Keymaps, keymapp}.
|
||
|
||
@item keywordp
|
||
@xref{Constant Variables}.
|
||
|
||
@item listp
|
||
@xref{List-related Predicates, listp}.
|
||
|
||
@item markerp
|
||
@xref{Predicates on Markers, markerp}.
|
||
|
||
@item mutexp
|
||
@xref{Mutexes, mutexp}.
|
||
|
||
@item nlistp
|
||
@xref{List-related Predicates, nlistp}.
|
||
|
||
@item number-or-marker-p
|
||
@xref{Predicates on Markers, number-or-marker-p}.
|
||
|
||
@item numberp
|
||
@xref{Predicates on Numbers, numberp}.
|
||
|
||
@item overlayp
|
||
@xref{Overlays, overlayp}.
|
||
|
||
@item processp
|
||
@xref{Processes, processp}.
|
||
|
||
@item recordp
|
||
@xref{Record Type, recordp}.
|
||
|
||
@item sequencep
|
||
@xref{Sequence Functions, sequencep}.
|
||
|
||
@item string-or-null-p
|
||
@xref{Predicates for Strings, string-or-null-p}.
|
||
|
||
@item stringp
|
||
@xref{Predicates for Strings, stringp}.
|
||
|
||
@item subrp
|
||
@xref{Function Cells, subrp}.
|
||
|
||
@item symbolp
|
||
@xref{Symbols, symbolp}.
|
||
|
||
@item syntax-table-p
|
||
@xref{Syntax Tables, syntax-table-p}.
|
||
|
||
@item threadp
|
||
@xref{Basic Thread Functions, threadp}.
|
||
|
||
@item vectorp
|
||
@xref{Vectors, vectorp}.
|
||
|
||
@item wholenump
|
||
@xref{Predicates on Numbers, wholenump}.
|
||
|
||
@item window-configuration-p
|
||
@xref{Window Configurations, window-configuration-p}.
|
||
|
||
@item window-live-p
|
||
@xref{Deleting Windows, window-live-p}.
|
||
|
||
@item windowp
|
||
@xref{Basic Windows, windowp}.
|
||
@end table
|
||
|
||
The most general way to check the type of an object is to call the
|
||
function @code{type-of}. Recall that each object belongs to one and
|
||
only one primitive type; @code{type-of} tells you which one (@pxref{Lisp
|
||
Data Types}). But @code{type-of} knows nothing about non-primitive
|
||
types. In most cases, it is more convenient to use type predicates than
|
||
@code{type-of}.
|
||
|
||
@defun type-of object
|
||
This function returns a symbol naming the primitive type of
|
||
@var{object}. The value is one of the symbols @code{bool-vector},
|
||
@code{buffer}, @code{char-table}, @code{compiled-function},
|
||
@code{condition-variable}, @code{cons}, @code{finalizer},
|
||
@code{float}, @code{font-entity}, @code{font-object},
|
||
@code{font-spec}, @code{frame}, @code{hash-table}, @code{integer},
|
||
@code{marker}, @code{mutex}, @code{overlay}, @code{process},
|
||
@code{string}, @code{subr}, @code{symbol}, @code{thread},
|
||
@code{vector}, @code{window}, or @code{window-configuration}.
|
||
However, if @var{object} is a record, the type specified by its first
|
||
slot is returned; @ref{Records}.
|
||
|
||
@example
|
||
(type-of 1)
|
||
@result{} integer
|
||
@group
|
||
(type-of 'nil)
|
||
@result{} symbol
|
||
(type-of '()) ; @r{@code{()} is @code{nil}.}
|
||
@result{} symbol
|
||
(type-of '(x))
|
||
@result{} cons
|
||
(type-of (record 'foo))
|
||
@result{} foo
|
||
@end group
|
||
@end example
|
||
@end defun
|
||
|
||
@node Equality Predicates
|
||
@section Equality Predicates
|
||
@cindex equality
|
||
|
||
Here we describe functions that test for equality between two
|
||
objects. Other functions test equality of contents between objects of
|
||
specific types, e.g., strings. For these predicates, see the
|
||
appropriate chapter describing the data type.
|
||
|
||
@defun eq object1 object2
|
||
This function returns @code{t} if @var{object1} and @var{object2} are
|
||
the same object, and @code{nil} otherwise.
|
||
|
||
If @var{object1} and @var{object2} are symbols with the
|
||
same name, they are normally the same object---but see @ref{Creating
|
||
Symbols} for exceptions. For other non-numeric types (e.g., lists, vectors,
|
||
strings), two arguments with the same contents or elements are not
|
||
necessarily @code{eq} to each other: they are @code{eq} only if they
|
||
are the same object, meaning that a change in the contents of one will
|
||
be reflected by the same change in the contents of the other.
|
||
|
||
If @var{object1} and @var{object2} are numbers with differing types or values,
|
||
then they cannot be the same object and @code{eq} returns @code{nil}.
|
||
If they are fixnums with the same value,
|
||
then they are the same object and @code{eq} returns @code{t}.
|
||
If they were computed separately but happen to have the same value
|
||
and the same non-fixnum numeric type, then they might or might not be
|
||
the same object, and @code{eq} returns @code{t} or @code{nil}
|
||
depending on whether the Lisp interpreter created one object or two.
|
||
|
||
@example
|
||
@group
|
||
(eq 'foo 'foo)
|
||
@result{} t
|
||
@end group
|
||
|
||
@group
|
||
(eq ?A ?A)
|
||
@result{} t
|
||
@end group
|
||
|
||
@group
|
||
(eq 3.0 3.0)
|
||
@result{} t @r{or} nil
|
||
;; @r{Equal floats may or may not be the same object.}
|
||
@end group
|
||
|
||
@group
|
||
(eq (make-string 3 ?A) (make-string 3 ?A))
|
||
@result{} nil
|
||
@end group
|
||
|
||
@group
|
||
(eq "asdf" "asdf")
|
||
@result{} t @r{or} nil
|
||
;; @r{Equal string constants or may not be the same object.}
|
||
@end group
|
||
|
||
@group
|
||
(eq '(1 (2 (3))) '(1 (2 (3))))
|
||
@result{} nil
|
||
@end group
|
||
|
||
@group
|
||
(setq foo '(1 (2 (3))))
|
||
@result{} (1 (2 (3)))
|
||
(eq foo foo)
|
||
@result{} t
|
||
(eq foo '(1 (2 (3))))
|
||
@result{} nil
|
||
@end group
|
||
|
||
@group
|
||
(eq [(1 2) 3] [(1 2) 3])
|
||
@result{} nil
|
||
@end group
|
||
|
||
@group
|
||
(eq (point-marker) (point-marker))
|
||
@result{} nil
|
||
@end group
|
||
@end example
|
||
|
||
@noindent
|
||
The @code{make-symbol} function returns an uninterned symbol, distinct
|
||
from the symbol that is used if you write the name in a Lisp expression.
|
||
Distinct symbols with the same name are not @code{eq}. @xref{Creating
|
||
Symbols}.
|
||
|
||
@example
|
||
@group
|
||
(eq (make-symbol "foo") 'foo)
|
||
@result{} nil
|
||
@end group
|
||
@end example
|
||
|
||
@noindent
|
||
@cindex identical-contents objects, and byte-compiler
|
||
@cindex objects with identical contents, and byte-compiler
|
||
The Emacs Lisp byte compiler may collapse identical literal objects,
|
||
such as literal strings, into references to the same object, with the
|
||
effect that the byte-compiled code will compare such objects as
|
||
@code{eq}, while the interpreted version of the same code will not.
|
||
Therefore, your code should never rely on objects with the same
|
||
literal contents being either @code{eq} or not @code{eq}, it should
|
||
instead use functions that compare object contents such as
|
||
@code{equal}, described below. Similarly, your code should not modify
|
||
literal objects (e.g., put text properties on literal strings), since
|
||
doing that might affect other literal objects of the same contents, if
|
||
the byte compiler collapses them.
|
||
@end defun
|
||
|
||
@defun equal object1 object2
|
||
This function returns @code{t} if @var{object1} and @var{object2} have
|
||
equal components, and @code{nil} otherwise. Whereas @code{eq} tests
|
||
if its arguments are the same object, @code{equal} looks inside
|
||
nonidentical arguments to see if their elements or contents are the
|
||
same. So, if two objects are @code{eq}, they are @code{equal}, but
|
||
the converse is not always true.
|
||
|
||
@example
|
||
@group
|
||
(equal 'foo 'foo)
|
||
@result{} t
|
||
@end group
|
||
|
||
@group
|
||
(equal 456 456)
|
||
@result{} t
|
||
@end group
|
||
|
||
@group
|
||
(equal "asdf" "asdf")
|
||
@result{} t
|
||
@end group
|
||
@group
|
||
(eq "asdf" "asdf")
|
||
@result{} nil
|
||
@end group
|
||
|
||
@group
|
||
(equal '(1 (2 (3))) '(1 (2 (3))))
|
||
@result{} t
|
||
@end group
|
||
@group
|
||
(eq '(1 (2 (3))) '(1 (2 (3))))
|
||
@result{} nil
|
||
@end group
|
||
|
||
@group
|
||
(equal [(1 2) 3] [(1 2) 3])
|
||
@result{} t
|
||
@end group
|
||
@group
|
||
(eq [(1 2) 3] [(1 2) 3])
|
||
@result{} nil
|
||
@end group
|
||
|
||
@group
|
||
(equal (point-marker) (point-marker))
|
||
@result{} t
|
||
@end group
|
||
|
||
@group
|
||
(eq (point-marker) (point-marker))
|
||
@result{} nil
|
||
@end group
|
||
@end example
|
||
|
||
Comparison of strings is case-sensitive, but does not take account of
|
||
text properties---it compares only the characters in the strings.
|
||
@xref{Text Properties}. Use @code{equal-including-properties} to also
|
||
compare text properties. For technical reasons, a unibyte string and
|
||
a multibyte string are @code{equal} if and only if they contain the
|
||
same sequence of character codes and all these codes are in the range
|
||
0 through 127 (@acronym{ASCII}).
|
||
|
||
@example
|
||
@group
|
||
(equal "asdf" "ASDF")
|
||
@result{} nil
|
||
@end group
|
||
@end example
|
||
|
||
The @code{equal} function recursively compares the contents of objects
|
||
if they are integers, strings, markers, vectors, bool-vectors,
|
||
byte-code function objects, char-tables, records, or font objects.
|
||
Other objects are considered @code{equal} only if they are @code{eq}.
|
||
For example, two distinct buffers are never considered @code{equal},
|
||
even if their textual contents are the same.
|
||
@end defun
|
||
|
||
For @code{equal}, equality is defined recursively; for example, given
|
||
two cons cells @var{x} and @var{y}, @code{(equal @var{x} @var{y})}
|
||
returns @code{t} if and only if both the expressions below return
|
||
@code{t}:
|
||
|
||
@example
|
||
(equal (car @var{x}) (car @var{y}))
|
||
(equal (cdr @var{x}) (cdr @var{y}))
|
||
@end example
|
||
|
||
Comparing circular lists may therefore cause deep recursion that leads
|
||
to an error, and this may result in counterintuitive behavior such as
|
||
@code{(equal a b)} returning @code{t} whereas @code{(equal b a)}
|
||
signals an error.
|
||
|
||
@defun equal-including-properties object1 object2
|
||
This function behaves like @code{equal} in all cases but also requires
|
||
that for two strings to be equal, they have the same text properties.
|
||
|
||
@example
|
||
@group
|
||
(equal "asdf" (propertize "asdf" 'asdf t))
|
||
@result{} t
|
||
@end group
|
||
@group
|
||
(equal-including-properties "asdf"
|
||
(propertize "asdf" 'asdf t))
|
||
@result{} nil
|
||
@end group
|
||
@end example
|
||
@end defun
|
||
|
||
@node Mutability
|
||
@section Mutability
|
||
@cindex mutable objects
|
||
|
||
Some Lisp objects should never change. For example, the Lisp
|
||
expression @code{"aaa"} yields a string, but you should not change
|
||
its contents. And some objects cannot be changed; for example,
|
||
although you can create a new number by calculating one, Lisp provides
|
||
no operation to change the value of an existing number.
|
||
|
||
Other Lisp objects are @dfn{mutable}: it is safe to change their
|
||
values via destructive operations involving side effects. For
|
||
example, an existing marker can be changed by moving the marker to
|
||
point to somewhere else.
|
||
|
||
Although numbers never change and all markers are mutable,
|
||
some types have members some of which are mutable and others not. These
|
||
types include conses, vectors, and strings. For example,
|
||
although @code{"cons"} and @code{(symbol-name 'cons)} both yield
|
||
strings that should not be changed, @code{(copy-sequence "cons")} and
|
||
@code{(make-string 3 ?a)} both yield mutable strings that can be
|
||
changed via later calls to @code{aset}.
|
||
|
||
A mutable object stops being mutable if it is part of an expression
|
||
that is evaluated. For example:
|
||
|
||
@example
|
||
(let* ((x (list 0.5))
|
||
(y (eval (list 'quote x))))
|
||
(setcar x 1.5) ;; The program should not do this.
|
||
y)
|
||
@end example
|
||
|
||
@noindent
|
||
Although the list @code{(0.5)} was mutable when it was created, it should not
|
||
have been changed via @code{setcar} because it was given to @code{eval}. The
|
||
reverse does not occur: an object that should not be changed never
|
||
becomes mutable afterwards.
|
||
|
||
If a program attempts to change objects that should not be
|
||
changed, the resulting behavior is undefined: the Lisp interpreter
|
||
might signal an error, or it might crash or behave unpredictably in
|
||
other ways.@footnote{This is the behavior specified for languages like
|
||
Common Lisp and C for constants, and this differs from languages like
|
||
JavaScript and Python where an interpreter is required to signal an
|
||
error if a program attempts to change an immutable object. Ideally the Emacs
|
||
Lisp interpreter will evolve in latter direction.}
|
||
|
||
When similar constants occur as parts of a program, the Lisp
|
||
interpreter might save time or space by reusing existing constants or
|
||
their components. For example, @code{(eq "abc" "abc")} returns
|
||
@code{t} if the interpreter creates only one instance of the string
|
||
literal @code{"abc"}, and returns @code{nil} if it creates two
|
||
instances. Lisp programs should be written so that they work
|
||
regardless of whether this optimization is in use.
|