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Don’t use “constant” for values you shouldn’t change
Inspired by patch proposed by Dmitry Gutov (Bug#40671#393) and by further comments by him and by Michael Heerdegen in the same bug report. * doc/lispintro/emacs-lisp-intro.texi (setcar): Don’t push mutability here. * doc/lispref/eval.texi (Self-Evaluating Forms, Quoting) (Backquote): * doc/lispref/lists.texi (Modifying Lists): * doc/lispref/objects.texi (Lisp Data Types, Mutability): * doc/lispref/sequences.texi (Array Functions, Vectors): * doc/lispref/strings.texi (String Basics, Modifying Strings): Don’t use the word “constant” to describe all values that a program should not change. * doc/lispref/objects.texi (Mutability): Rename from “Constants and Mutability”. All uses changed. In a footnote, contrast the Emacs behavior with that of Common Lisp, Python, etc. for clarity, and say the goal is to be nicer.
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@ -7317,8 +7317,6 @@ which leave the original list as it was. One way to find out how this
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works is to experiment. We will start with the @code{setcar} function.
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@need 1200
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@cindex constant lists
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@cindex mutable lists
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First, we can make a list and then set the value of a variable to the
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list, using the @code{setq} special form. Because we intend to use
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@code{setcar} to change the list, this @code{setq} should not use the
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@ -7327,8 +7325,7 @@ a list that is part of the program and bad things could happen if we
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tried to change part of the program while running it. Generally
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speaking an Emacs Lisp program's components should be constant (or
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unchanged) while the program is running. So we instead construct an
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animal list that is @dfn{mutable} (or changeable) by using the
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@code{list} function, as follows:
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animal list by using the @code{list} function, as follows:
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@smallexample
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(setq animals (list 'antelope 'giraffe 'lion 'tiger))
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@ -297,7 +297,7 @@ Lisp Data Types
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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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* Constants and Mutability:: Whether an object's value can change.
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* Mutability:: Some objects should not be modified.
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Programming Types
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@ -158,11 +158,11 @@ contents unchanged.
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@end group
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@end example
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A self-evaluating form yields constant conses, vectors and strings, and you
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should not attempt to modify their contents via @code{setcar}, @code{aset} or
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A self-evaluating form yields a value that becomes part of the program,
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and you should not try to modify it via @code{setcar}, @code{aset} or
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similar operations. The Lisp interpreter might unify the constants
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yielded by your program's self-evaluating forms, so that these
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constants might share structure. @xref{Constants and Mutability}.
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constants might share structure. @xref{Mutability}.
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It is common to write numbers, characters, strings, and even vectors
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in Lisp code, taking advantage of the fact that they self-evaluate.
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@ -564,8 +564,8 @@ and vectors.)
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@defspec quote object
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This special form returns @var{object}, without evaluating it.
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The returned value is a constant, and should not be modified.
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@xref{Constants and Mutability}.
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The returned value might be shared and should not be modified.
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@xref{Self-Evaluating Forms}.
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@end defspec
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@cindex @samp{'} for quoting
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@ -608,9 +608,9 @@ Here are some examples of expressions that use @code{quote}:
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Although the expressions @code{(list '+ 1 2)} and @code{'(+ 1 2)}
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both yield lists equal to @code{(+ 1 2)}, the former yields a
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freshly-minted mutable list whereas the latter yields a constant list
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built from conses that may be shared with other constants.
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@xref{Constants and Mutability}.
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freshly-minted mutable list whereas the latter yields a list
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built from conses that might be shared and should not be modified.
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@xref{Self-Evaluating Forms}.
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Other quoting constructs include @code{function} (@pxref{Anonymous
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Functions}), which causes an anonymous lambda expression written in Lisp
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@ -710,8 +710,9 @@ Here are some examples:
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@end example
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If a subexpression of a backquote construct has no substitutions or
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splices, it acts like @code{quote} in that it yields constant conses,
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vectors and strings that should not be modified.
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splices, it acts like @code{quote} in that it yields conses,
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vectors and strings that might be shared and should not be modified.
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@xref{Self-Evaluating Forms}.
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@node Eval
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@section Eval
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@ -873,8 +873,8 @@ primitives @code{setcar} and @code{setcdr}. These are destructive
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operations because they change existing list structure.
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Destructive operations should be applied only to mutable lists,
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that is, lists constructed via @code{cons}, @code{list} or similar
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operations. Lists created by quoting are constants and should not be
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changed by destructive operations. @xref{Constants and Mutability}.
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operations. Lists created by quoting are part of the program and
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should not be changed by destructive operations. @xref{Mutability}.
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@cindex CL note---@code{rplaca} vs @code{setcar}
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@quotation
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@ -911,7 +911,7 @@ value @var{object}. For example:
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@example
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@group
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(setq x (list 1 2)) ; @r{Create a mutable list.}
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(setq x (list 1 2))
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@result{} (1 2)
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@end group
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@group
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@ -931,7 +931,7 @@ these lists. Here is an example:
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@example
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@group
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;; @r{Create two mutable lists that are partly shared.}
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;; @r{Create two lists that are partly shared.}
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(setq x1 (list 'a 'b 'c))
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@result{} (a b c)
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(setq x2 (cons 'z (cdr x1)))
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@ -1022,11 +1022,11 @@ reached via the @sc{cdr}.
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@example
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@group
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(setq x (list 1 2 3)) ; @r{Create a mutable list.}
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(setq x (list 1 2 3))
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@result{} (1 2 3)
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@end group
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@group
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(setcdr x '(4)) ; @r{Modify the list's tail to be a constant list.}
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(setcdr x '(4))
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@result{} (4)
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@end group
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@group
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@ -1135,11 +1135,11 @@ Unlike @code{append} (@pxref{Building Lists}), the @var{lists} are
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@example
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@group
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(setq x (list 1 2 3)) ; @r{Create a mutable list.}
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(setq x (list 1 2 3))
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@result{} (1 2 3)
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@end group
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@group
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(nconc x '(4 5)) ; @r{Modify the list's tail to be a constant list.}
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(nconc x '(4 5))
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@result{} (1 2 3 4 5)
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@end group
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@group
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@ -46,10 +46,6 @@ 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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Some Lisp objects are @dfn{constant}: their values should never change.
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Others are @dfn{mutable}: their values can be changed via destructive
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operations that involve side effects.
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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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@ -63,7 +59,7 @@ to use these types can be found in later chapters.
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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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* Constants and Mutability:: Whether an object's value can change.
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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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@ -2379,51 +2375,59 @@ that for two strings to be equal, they have the same text properties.
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@end example
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@end defun
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@node Constants and Mutability
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@section Constants and Mutability
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@cindex constants
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@node Mutability
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@section Mutability
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@cindex mutable objects
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Some Lisp objects are constant: their values should never change
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during a single execution of Emacs running well-behaved Lisp code.
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For example, you can create a new integer by calculating one, but you
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cannot modify the value of an existing integer.
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Some Lisp objects should never change. For example, the Lisp
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expression @code{"aaa"} yields a string, but you should not change
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its contents. Indeed, some objects cannot be changed; for example,
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although you can create a new number by calculating one, Lisp provides
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no operation to change the value of an existing number.
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Other Lisp objects are mutable: it is safe to change their values
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via destructive operations involving side effects. For example, an
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existing marker can be changed by moving the marker to point to
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somewhere else.
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Other Lisp objects are @dfn{mutable}: it is safe to change their
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values via destructive operations involving side effects. For
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example, an existing marker can be changed by moving the marker to
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point to somewhere else.
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Although all numbers are constants and all markers are
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mutable, some types contain both constant and mutable members. These
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types include conses, vectors, strings, and symbols. For example, the string
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literal @code{"aaa"} yields a constant string, whereas the function
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call @code{(make-string 3 ?a)} yields a mutable string that can be
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changed via later calls to @code{aset}.
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Although numbers never change and all markers are mutable,
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some types have members some of which are mutable and others not. These
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types include conses, vectors, and strings. For example,
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although @code{"aaa"} yields a string that should not be changed,
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@code{(make-string 3 ?a)} yields a mutable string that can be
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changed via later calls to @code{aset}. Another example:
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@code{(symbol-name 'cons)} yields a string @code{"cons"} that should
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not be changed.
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A mutable object can become constant if it is part of an expression
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that is evaluated. The reverse does not occur: constant objects
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should stay constant.
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A mutable object stops being mutable if it is part of an expression
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that is evaluated. For example:
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Trying to modify a constant variable signals an error
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(@pxref{Constant Variables}).
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A program should not attempt to modify other types of constants because the
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resulting behavior is undefined: the Lisp interpreter might or might
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not detect the error, and if it does not detect the error the
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interpreter can behave unpredictably thereafter. Another way to put
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this is that although mutable objects are safe to change and constant
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variables reliably prevent attempts to change them, other constants
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are not safely mutable: if a misbehaving program tries to change such a
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constant then the constant's value might actually change, or the
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program might crash or worse. This problem occurs
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with types that have both constant and mutable members, and that have
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mutators like @code{setcar} and @code{aset} that are valid on mutable
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objects but hazardous on constants.
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@example
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(let* ((x (list 0.5))
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(y (eval (list 'quote x))))
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(setcar x 1.5) ;; The program should not do this.
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y)
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@end example
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When the same constant occurs multiple times in a program, the Lisp
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@noindent
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Although the list @code{(0.5)} was mutable when it was created, it should not
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have been changed via @code{setcar} because it given to @code{eval}. The
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reverse does not occur: an object that should not be changed never
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becomes mutable afterwards.
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If a program attempts to change objects that should not be
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changed, the resulting behavior is undefined: the Lisp interpreter
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might signal an error, or it might crash or behave unpredictably in
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other ways.@footnote{This is the behavior specified for languages like
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Common Lisp and C, and it differs from the behavior of languages like
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JavaScript and Python where an interpreter is required to signal an
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error if a program attempts to change a constant. Ideally the Emacs
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Lisp interpreter will evolve in latter direction.}
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When similar constants occur as parts of a program, the Lisp
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interpreter might save time or space by reusing existing constants or
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constant components. For example, @code{(eq "abc" "abc")} returns
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their components. For example, @code{(eq "abc" "abc")} returns
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@code{t} if the interpreter creates only one instance of the string
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constant @code{"abc"}, and returns @code{nil} if it creates two
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literal @code{"abc"}, and returns @code{nil} if it creates two
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instances. Lisp programs should be written so that they work
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regardless of whether this optimization is in use.
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@ -183,11 +183,11 @@ for other ways to copy sequences.
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@example
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@group
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(setq bar (list 1 2)) ; @r{Create a mutable list.}
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(setq bar (list 1 2))
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@result{} (1 2)
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@end group
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@group
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(setq x (vector 'foo bar)) ; @r{Create a mutable vector.}
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(setq x (vector 'foo bar))
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@result{} [foo (1 2)]
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@end group
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@group
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@ -278,7 +278,7 @@ Unlike @code{reverse} the original @var{sequence} may be modified.
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@example
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@group
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(setq x (list 'a 'b 'c)) ; @r{Create a mutable list.}
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(setq x (list 'a 'b 'c))
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@result{} (a b c)
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@end group
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@group
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@ -320,7 +320,7 @@ presented graphically:
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For the vector, it is even simpler because you don't need setq:
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@example
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(setq x (copy-sequence [1 2 3 4])) ; @r{Create a mutable vector.}
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(setq x (copy-sequence [1 2 3 4]))
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@result{} [1 2 3 4]
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(nreverse x)
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@result{} [4 3 2 1]
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@ -331,6 +331,7 @@ x
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Note that unlike @code{reverse}, this function doesn't work with strings.
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Although you can alter string data by using @code{aset}, it is strongly
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encouraged to treat strings as immutable even when they are mutable.
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@xref{Mutability}.
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@end defun
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@ -374,7 +375,7 @@ appears in a different position in the list due to the change of
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@example
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@group
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(setq nums (list 1 3 2 6 5 4 0)) ; @r{Create a mutable list.}
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(setq nums (list 1 3 2 6 5 4 0))
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@result{} (1 3 2 6 5 4 0)
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@end group
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@group
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@ -1228,7 +1229,7 @@ This function sets the @var{index}th element of @var{array} to be
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@example
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@group
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(setq w (vector 'foo 'bar 'baz)) ; @r{Create a mutable vector.}
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(setq w (vector 'foo 'bar 'baz))
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@result{} [foo bar baz]
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(aset w 0 'fu)
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@result{} fu
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@ -1237,7 +1238,7 @@ w
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@end group
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@group
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;; @r{@code{copy-sequence} creates a mutable string.}
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;; @r{@code{copy-sequence} copies the string to be modified later.}
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(setq x (copy-sequence "asdfasfd"))
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@result{} "asdfasfd"
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(aset x 3 ?Z)
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@ -1247,9 +1248,7 @@ x
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@end group
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@end example
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The @var{array} should be mutable; that is, it should not be a constant,
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such as the constants created via quoting or via self-evaluating forms.
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@xref{Constants and Mutability}.
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The @var{array} should be mutable. @xref{Mutability}.
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If @var{array} is a string and @var{object} is not a character, a
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@code{wrong-type-argument} error results. The function converts a
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@ -1262,7 +1261,6 @@ each element of @var{array} is @var{object}. It returns @var{array}.
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@example
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@group
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;; @r{Create a mutable vector and then fill it with zeros.}
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(setq a (copy-sequence [a b c d e f g]))
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@result{} [a b c d e f g]
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(fillarray a 0)
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@ -1271,7 +1269,6 @@ a
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@result{} [0 0 0 0 0 0 0]
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@end group
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@group
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;; @r{Create a mutable string and then fill it with "-".}
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(setq s (copy-sequence "When in the course"))
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@result{} "When in the course"
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(fillarray s ?-)
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@ -1310,8 +1307,8 @@ same way in Lisp input.
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evaluation: the result of evaluating it is the same vector. This does
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not evaluate or even examine the elements of the vector.
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@xref{Self-Evaluating Forms}. Vectors written with square brackets
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are constants and should not be modified via @code{aset} or other
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destructive operations. @xref{Constants and Mutability}.
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should not be modified via @code{aset} or other destructive
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operations. @xref{Mutability}.
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Here are examples illustrating these principles:
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@ -49,10 +49,9 @@ by a distinguished character code.
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Since strings are arrays, and therefore sequences as well, you can
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operate on them with the general array and sequence functions documented
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in @ref{Sequences Arrays Vectors}. For example, you can access or
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change individual characters in a string using the functions @code{aref}
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and @code{aset} (@pxref{Array Functions}). However, you should not
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try to change the contents of constant strings (@pxref{Modifying Strings}).
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in @ref{Sequences Arrays Vectors}. For example, you can access
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individual characters in a string using the function @code{aref}
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(@pxref{Array Functions}).
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There are two text representations for non-@acronym{ASCII}
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characters in Emacs strings (and in buffers): unibyte and multibyte.
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@ -382,9 +381,7 @@ usual value is @w{@code{"[ \f\t\n\r\v]+"}}.
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@cindex string modification
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You can alter the contents of a mutable string via operations
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described in this section. However, you should not try to use these
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operations to alter the contents of a constant string.
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@xref{Constants and Mutability}.
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described in this section. @xref{Mutability}.
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The most basic way to alter the contents of an existing string is with
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@code{aset} (@pxref{Array Functions}). @code{(aset @var{string}
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