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authorRichard M. Stallman <rms@gnu.org>1994-03-21 17:36:52 +0000
committerRichard M. Stallman <rms@gnu.org>1994-03-21 17:36:52 +0000
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+@c -*-texinfo-*-
+@c This is part of the GNU Emacs Lisp Reference Manual.
+@c Copyright (C) 1990, 1991, 1992, 1993, 1994 Free Software Foundation, Inc.
+@c See the file elisp.texi for copying conditions.
+@setfilename ../info/control
+@node Control Structures, Variables, Evaluation, Top
+@chapter Control Structures
+@cindex special forms for control structures
+@cindex control structures
+
+ A Lisp program consists of expressions or @dfn{forms} (@pxref{Forms}).
+We control the order of execution of the forms by enclosing them in
+@dfn{control structures}. Control structures are special forms which
+control when, whether, or how many times to execute the forms they contain.
+
+ The simplest control structure is sequential execution: first form
+@var{a}, then form @var{b}, and so on. This is what happens when you
+write several forms in succession in the body of a function, or at top
+level in a file of Lisp code---the forms are executed in the order they
+are written. We call this @dfn{textual order}. For example, if a
+function body consists of two forms @var{a} and @var{b}, evaluation of
+the function evaluates first @var{a} and then @var{b}, and the
+function's value is the value of @var{b}.
+
+ Emacs Lisp provides several kinds of control structure, including
+other varieties of sequencing, function calls, conditionals, iteration,
+and (controlled) jumps. The built-in control structures are special
+forms since their subforms are not necessarily evaluated. You can use
+macros to define your own control structure constructs (@pxref{Macros}).
+
+@menu
+* Sequencing:: Evaluation in textual order.
+* Conditionals:: @code{if}, @code{cond}.
+* Combining Conditions:: @code{and}, @code{or}, @code{not}.
+* Iteration:: @code{while} loops.
+* Nonlocal Exits:: Jumping out of a sequence.
+@end menu
+
+@node Sequencing
+@section Sequencing
+
+ Evaluating forms in the order they are written is the most common
+control structure. Sometimes this happens automatically, such as in a
+function body. Elsewhere you must use a control structure construct to
+do this: @code{progn}, the simplest control construct of Lisp.
+
+ A @code{progn} special form looks like this:
+
+@example
+@group
+(progn @var{a} @var{b} @var{c} @dots{})
+@end group
+@end example
+
+@noindent
+and it says to execute the forms @var{a}, @var{b}, @var{c} and so on, in
+that order. These forms are called the body of the @code{progn} form.
+The value of the last form in the body becomes the value of the entire
+@code{progn}.
+
+@cindex implicit @code{progn}
+ In the early days of Lisp, @code{progn} was the only way to execute
+two or more forms in succession and use the value of the last of them.
+But programmers found they often needed to use a @code{progn} in the
+body of a function, where (at that time) only one form was allowed. So
+the body of a function was made into an ``implicit @code{progn}'':
+several forms are allowed just as in the body of an actual @code{progn}.
+Many other control structures likewise contain an implicit @code{progn}.
+As a result, @code{progn} is not used as often as it used to be. It is
+needed now most often inside of an @code{unwind-protect}, @code{and},
+@code{or}, or the @var{else}-part of an @code{if}.
+
+@defspec progn forms@dots{}
+This special form evaluates all of the @var{forms}, in textual
+order, returning the result of the final form.
+
+@example
+@group
+(progn (print "The first form")
+ (print "The second form")
+ (print "The third form"))
+ @print{} "The first form"
+ @print{} "The second form"
+ @print{} "The third form"
+@result{} "The third form"
+@end group
+@end example
+@end defspec
+
+ Two other control constructs likewise evaluate a series of forms but return
+a different value:
+
+@defspec prog1 form1 forms@dots{}
+This special form evaluates @var{form1} and all of the @var{forms}, in
+textual order, returning the result of @var{form1}.
+
+@example
+@group
+(prog1 (print "The first form")
+ (print "The second form")
+ (print "The third form"))
+ @print{} "The first form"
+ @print{} "The second form"
+ @print{} "The third form"
+@result{} "The first form"
+@end group
+@end example
+
+Here is a way to remove the first element from a list in the variable
+@code{x}, then return the value of that former element:
+
+@example
+(prog1 (car x) (setq x (cdr x)))
+@end example
+@end defspec
+
+@defspec prog2 form1 form2 forms@dots{}
+This special form evaluates @var{form1}, @var{form2}, and all of the
+following @var{forms}, in textual order, returning the result of
+@var{form2}.
+
+@example
+@group
+(prog2 (print "The first form")
+ (print "The second form")
+ (print "The third form"))
+ @print{} "The first form"
+ @print{} "The second form"
+ @print{} "The third form"
+@result{} "The second form"
+@end group
+@end example
+@end defspec
+
+@node Conditionals
+@section Conditionals
+@cindex conditional evaluation
+
+ Conditional control structures choose among alternatives. Emacs Lisp
+has two conditional forms: @code{if}, which is much the same as in other
+languages, and @code{cond}, which is a generalized case statement.
+
+@defspec if condition then-form else-forms@dots{}
+@code{if} chooses between the @var{then-form} and the @var{else-forms}
+based on the value of @var{condition}. If the evaluated @var{condition} is
+non-@code{nil}, @var{then-form} is evaluated and the result returned.
+Otherwise, the @var{else-forms} are evaluated in textual order, and the
+value of the last one is returned. (The @var{else} part of @code{if} is
+an example of an implicit @code{progn}. @xref{Sequencing}.)
+
+If @var{condition} has the value @code{nil}, and no @var{else-forms} are
+given, @code{if} returns @code{nil}.
+
+@code{if} is a special form because the branch which is not selected is
+never evaluated---it is ignored. Thus, in the example below,
+@code{true} is not printed because @code{print} is never called.
+
+@example
+@group
+(if nil
+ (print 'true)
+ 'very-false)
+@result{} very-false
+@end group
+@end example
+@end defspec
+
+@defspec cond clause@dots{}
+@code{cond} chooses among an arbitrary number of alternatives. Each
+@var{clause} in the @code{cond} must be a list. The @sc{car} of this
+list is the @var{condition}; the remaining elements, if any, the
+@var{body-forms}. Thus, a clause looks like this:
+
+@example
+(@var{condition} @var{body-forms}@dots{})
+@end example
+
+@code{cond} tries the clauses in textual order, by evaluating the
+@var{condition} of each clause. If the value of @var{condition} is
+non-@code{nil}, the clause ``succeeds''; then @code{cond} evaluates its
+@var{body-forms}, and the value of the last of @var{body-forms} becomes
+the value of the @code{cond}. The remaining clauses are ignored.
+
+If the value of @var{condition} is @code{nil}, the clause ``fails'', so
+the @code{cond} moves on to the following clause, trying its
+@var{condition}.
+
+If every @var{condition} evaluates to @code{nil}, so that every clause
+fails, @code{cond} returns @code{nil}.
+
+A clause may also look like this:
+
+@example
+(@var{condition})
+@end example
+
+@noindent
+Then, if @var{condition} is non-@code{nil} when tested, the value of
+@var{condition} becomes the value of the @code{cond} form.
+
+The following example has four clauses, which test for the cases where
+the value of @code{x} is a number, string, buffer and symbol,
+respectively:
+
+@example
+@group
+(cond ((numberp x) x)
+ ((stringp x) x)
+ ((bufferp x)
+ (setq temporary-hack x) ; @r{multiple body-forms}
+ (buffer-name x)) ; @r{in one clause}
+ ((symbolp x) (symbol-value x)))
+@end group
+@end example
+
+Often we want to execute the last clause whenever none of the previous
+clauses was successful. To do this, we use @code{t} as the
+@var{condition} of the last clause, like this: @code{(t
+@var{body-forms})}. The form @code{t} evaluates to @code{t}, which is
+never @code{nil}, so this clause never fails, provided the @code{cond}
+gets to it at all.
+
+For example,
+
+@example
+@group
+(cond ((eq a 1) 'foo)
+ (t "default"))
+@result{} "default"
+@end group
+@end example
+
+@noindent
+This expression is a @code{cond} which returns @code{foo} if the value
+of @code{a} is 1, and returns the string @code{"default"} otherwise.
+@end defspec
+
+Both @code{cond} and @code{if} can usually be written in terms of the
+other. Therefore, the choice between them is a matter of style. For
+example:
+
+@example
+@group
+(if @var{a} @var{b} @var{c})
+@equiv{}
+(cond (@var{a} @var{b}) (t @var{c}))
+@end group
+@end example
+
+@node Combining Conditions
+@section Constructs for Combining Conditions
+
+ This section describes three constructs that are often used together
+with @code{if} and @code{cond} to express complicated conditions. The
+constructs @code{and} and @code{or} can also be used individually as
+kinds of multiple conditional constructs.
+
+@defun not condition
+This function tests for the falsehood of @var{condition}. It returns
+@code{t} if @var{condition} is @code{nil}, and @code{nil} otherwise.
+The function @code{not} is identical to @code{null}, and we recommend
+using the name @code{null} if you are testing for an empty list.
+@end defun
+
+@defspec and conditions@dots{}
+The @code{and} special form tests whether all the @var{conditions} are
+true. It works by evaluating the @var{conditions} one by one in the
+order written.
+
+If any of the @var{conditions} evaluates to @code{nil}, then the result
+of the @code{and} must be @code{nil} regardless of the remaining
+@var{conditions}; so @code{and} returns right away, ignoring the
+remaining @var{conditions}.
+
+If all the @var{conditions} turn out non-@code{nil}, then the value of
+the last of them becomes the value of the @code{and} form.
+
+Here is an example. The first condition returns the integer 1, which is
+not @code{nil}. Similarly, the second condition returns the integer 2,
+which is not @code{nil}. The third condition is @code{nil}, so the
+remaining condition is never evaluated.
+
+@example
+@group
+(and (print 1) (print 2) nil (print 3))
+ @print{} 1
+ @print{} 2
+@result{} nil
+@end group
+@end example
+
+Here is a more realistic example of using @code{and}:
+
+@example
+@group
+(if (and (consp foo) (eq (car foo) 'x))
+ (message "foo is a list starting with x"))
+@end group
+@end example
+
+@noindent
+Note that @code{(car foo)} is not executed if @code{(consp foo)} returns
+@code{nil}, thus avoiding an error.
+
+@code{and} can be expressed in terms of either @code{if} or @code{cond}.
+For example:
+
+@example
+@group
+(and @var{arg1} @var{arg2} @var{arg3})
+@equiv{}
+(if @var{arg1} (if @var{arg2} @var{arg3}))
+@equiv{}
+(cond (@var{arg1} (cond (@var{arg2} @var{arg3}))))
+@end group
+@end example
+@end defspec
+
+@defspec or conditions@dots{}
+The @code{or} special form tests whether at least one of the
+@var{conditions} is true. It works by evaluating all the
+@var{conditions} one by one in the order written.
+
+If any of the @var{conditions} evaluates to a non-@code{nil} value, then
+the result of the @code{or} must be non-@code{nil}; so @code{or} returns
+right away, ignoring the remaining @var{conditions}. The value it
+returns is the non-@code{nil} value of the condition just evaluated.
+
+If all the @var{conditions} turn out @code{nil}, then the @code{or}
+expression returns @code{nil}.
+
+For example, this expression tests whether @code{x} is either 0 or
+@code{nil}:
+
+@example
+(or (eq x nil) (eq x 0))
+@end example
+
+Like the @code{and} construct, @code{or} can be written in terms of
+@code{cond}. For example:
+
+@example
+@group
+(or @var{arg1} @var{arg2} @var{arg3})
+@equiv{}
+(cond (@var{arg1})
+ (@var{arg2})
+ (@var{arg3}))
+@end group
+@end example
+
+You could almost write @code{or} in terms of @code{if}, but not quite:
+
+@example
+@group
+(if @var{arg1} @var{arg1}
+ (if @var{arg2} @var{arg2}
+ @var{arg3}))
+@end group
+@end example
+
+@noindent
+This is not completely equivalent because it can evaluate @var{arg1} or
+@var{arg2} twice. By contrast, @code{(or @var{arg1} @var{arg2}
+@var{arg3})} never evaluates any argument more than once.
+@end defspec
+
+@node Iteration
+@section Iteration
+@cindex iteration
+@cindex recursion
+
+ Iteration means executing part of a program repetitively. For
+example, you might want to repeat some computation once for each element
+of a list, or once for each integer from 0 to @var{n}. You can do this
+in Emacs Lisp with the special form @code{while}:
+
+@defspec while condition forms@dots{}
+@code{while} first evaluates @var{condition}. If the result is
+non-@code{nil}, it evaluates @var{forms} in textual order. Then it
+reevaluates @var{condition}, and if the result is non-@code{nil}, it
+evaluates @var{forms} again. This process repeats until @var{condition}
+evaluates to @code{nil}.
+
+There is no limit on the number of iterations that may occur. The loop
+will continue until either @var{condition} evaluates to @code{nil} or
+until an error or @code{throw} jumps out of it (@pxref{Nonlocal Exits}).
+
+The value of a @code{while} form is always @code{nil}.
+
+@example
+@group
+(setq num 0)
+ @result{} 0
+@end group
+@group
+(while (< num 4)
+ (princ (format "Iteration %d." num))
+ (setq num (1+ num)))
+ @print{} Iteration 0.
+ @print{} Iteration 1.
+ @print{} Iteration 2.
+ @print{} Iteration 3.
+ @result{} nil
+@end group
+@end example
+
+If you would like to execute something on each iteration before the
+end-test, put it together with the end-test in a @code{progn} as the
+first argument of @code{while}, as shown here:
+
+@example
+@group
+(while (progn
+ (forward-line 1)
+ (not (looking-at "^$"))))
+@end group
+@end example
+
+@noindent
+This moves forward one line and continues moving by lines until an empty
+line is reached.
+@end defspec
+
+@node Nonlocal Exits
+@section Nonlocal Exits
+@cindex nonlocal exits
+
+ A @dfn{nonlocal exit} is a transfer of control from one point in a
+program to another remote point. Nonlocal exits can occur in Emacs Lisp
+as a result of errors; you can also use them under explicit control.
+Nonlocal exits unbind all variable bindings made by the constructs being
+exited.
+
+@menu
+* Catch and Throw:: Nonlocal exits for the program's own purposes.
+* Examples of Catch:: Showing how such nonlocal exits can be written.
+* Errors:: How errors are signaled and handled.
+* Cleanups:: Arranging to run a cleanup form if an error happens.
+@end menu
+
+@node Catch and Throw
+@subsection Explicit Nonlocal Exits: @code{catch} and @code{throw}
+
+ Most control constructs affect only the flow of control within the
+construct itself. The function @code{throw} is the exception to this
+rule of normal program execution: it performs a nonlocal exit on
+request. (There are other exceptions, but they are for error handling
+only.) @code{throw} is used inside a @code{catch}, and jumps back to
+that @code{catch}. For example:
+
+@example
+@group
+(catch 'foo
+ (progn
+ @dots{}
+ (throw 'foo t)
+ @dots{}))
+@end group
+@end example
+
+@noindent
+The @code{throw} transfers control straight back to the corresponding
+@code{catch}, which returns immediately. The code following the
+@code{throw} is not executed. The second argument of @code{throw} is used
+as the return value of the @code{catch}.
+
+ The @code{throw} and the @code{catch} are matched through the first
+argument: @code{throw} searches for a @code{catch} whose first argument
+is @code{eq} to the one specified. Thus, in the above example, the
+@code{throw} specifies @code{foo}, and the @code{catch} specifies the
+same symbol, so that @code{catch} is applicable. If there is more than
+one applicable @code{catch}, the innermost one takes precedence.
+
+ Executing @code{throw} exits all Lisp constructs up to the matching
+@code{catch}, including function calls. When binding constructs such as
+@code{let} or function calls are exited in this way, the bindings are
+unbound, just as they are when these constructs exit normally
+(@pxref{Local Variables}). Likewise, @code{throw} restores the buffer
+and position saved by @code{save-excursion} (@pxref{Excursions}), and
+the narrowing status saved by @code{save-restriction} and the window
+selection saved by @code{save-window-excursion} (@pxref{Window
+Configurations}). It also runs any cleanups established with the
+@code{unwind-protect} special form when it exits that form.
+
+ The @code{throw} need not appear lexically within the @code{catch}
+that it jumps to. It can equally well be called from another function
+called within the @code{catch}. As long as the @code{throw} takes place
+chronologically after entry to the @code{catch}, and chronologically
+before exit from it, it has access to that @code{catch}. This is why
+@code{throw} can be used in commands such as @code{exit-recursive-edit}
+which throw back to the editor command loop (@pxref{Recursive Editing}).
+
+@cindex CL note---only @code{throw} in Emacs
+@quotation
+@b{Common Lisp note:} most other versions of Lisp, including Common Lisp,
+have several ways of transferring control nonsequentially: @code{return},
+@code{return-from}, and @code{go}, for example. Emacs Lisp has only
+@code{throw}.
+@end quotation
+
+@defspec catch tag body@dots{}
+@cindex tag on run time stack
+@code{catch} establishes a return point for the @code{throw} function. The
+return point is distinguished from other such return points by @var{tag},
+which may be any Lisp object. The argument @var{tag} is evaluated normally
+before the return point is established.
+
+With the return point in effect, @code{catch} evaluates the forms of the
+@var{body} in textual order. If the forms execute normally, without
+error or nonlocal exit, the value of the last body form is returned from
+the @code{catch}.
+
+If a @code{throw} is done within @var{body} specifying the same value
+@var{tag}, the @code{catch} exits immediately; the value it returns is
+whatever was specified as the second argument of @code{throw}.
+@end defspec
+
+@defun throw tag value
+The purpose of @code{throw} is to return from a return point previously
+established with @code{catch}. The argument @var{tag} is used to choose
+among the various existing return points; it must be @code{eq} to the value
+specified in the @code{catch}. If multiple return points match @var{tag},
+the innermost one is used.
+
+The argument @var{value} is used as the value to return from that
+@code{catch}.
+
+@kindex no-catch
+If no return point is in effect with tag @var{tag}, then a @code{no-catch}
+error is signaled with data @code{(@var{tag} @var{value})}.
+@end defun
+
+@node Examples of Catch
+@subsection Examples of @code{catch} and @code{throw}
+
+ One way to use @code{catch} and @code{throw} is to exit from a doubly
+nested loop. (In most languages, this would be done with a ``go to''.)
+Here we compute @code{(foo @var{i} @var{j})} for @var{i} and @var{j}
+varying from 0 to 9:
+
+@example
+@group
+(defun search-foo ()
+ (catch 'loop
+ (let ((i 0))
+ (while (< i 10)
+ (let ((j 0))
+ (while (< j 10)
+ (if (foo i j)
+ (throw 'loop (list i j)))
+ (setq j (1+ j))))
+ (setq i (1+ i))))))
+@end group
+@end example
+
+@noindent
+If @code{foo} ever returns non-@code{nil}, we stop immediately and return a
+list of @var{i} and @var{j}. If @code{foo} always returns @code{nil}, the
+@code{catch} returns normally, and the value is @code{nil}, since that
+is the result of the @code{while}.
+
+ Here are two tricky examples, slightly different, showing two
+return points at once. First, two return points with the same tag,
+@code{hack}:
+
+@example
+@group
+(defun catch2 (tag)
+ (catch tag
+ (throw 'hack 'yes)))
+@result{} catch2
+@end group
+
+@group
+(catch 'hack
+ (print (catch2 'hack))
+ 'no)
+@print{} yes
+@result{} no
+@end group
+@end example
+
+@noindent
+Since both return points have tags that match the @code{throw}, it goes to
+the inner one, the one established in @code{catch2}. Therefore,
+@code{catch2} returns normally with value @code{yes}, and this value is
+printed. Finally the second body form in the outer @code{catch}, which is
+@code{'no}, is evaluated and returned from the outer @code{catch}.
+
+ Now let's change the argument given to @code{catch2}:
+
+@example
+@group
+(defun catch2 (tag)
+ (catch tag
+ (throw 'hack 'yes)))
+@result{} catch2
+@end group
+
+@group
+(catch 'hack
+ (print (catch2 'quux))
+ 'no)
+@result{} yes
+@end group
+@end example
+
+@noindent
+We still have two return points, but this time only the outer one has the
+tag @code{hack}; the inner one has the tag @code{quux} instead. Therefore,
+the @code{throw} returns the value @code{yes} from the outer return point.
+The function @code{print} is never called, and the body-form @code{'no} is
+never evaluated.
+
+@node Errors
+@subsection Errors
+@cindex errors
+
+ When Emacs Lisp attempts to evaluate a form that, for some reason,
+cannot be evaluated, it @dfn{signals} an @dfn{error}.
+
+ When an error is signaled, Emacs's default reaction is to print an
+error message and terminate execution of the current command. This is
+the right thing to do in most cases, such as if you type @kbd{C-f} at
+the end of the buffer.
+
+ In complicated programs, simple termination may not be what you want.
+For example, the program may have made temporary changes in data
+structures, or created temporary buffers which should be deleted before
+the program is finished. In such cases, you would use
+@code{unwind-protect} to establish @dfn{cleanup expressions} to be
+evaluated in case of error. Occasionally, you may wish the program to
+continue execution despite an error in a subroutine. In these cases,
+you would use @code{condition-case} to establish @dfn{error handlers} to
+recover control in case of error.
+
+ Resist the temptation to use error handling to transfer control from
+one part of the program to another; use @code{catch} and @code{throw}
+instead. @xref{Catch and Throw}.
+
+@menu
+* Signaling Errors:: How to report an error.
+* Processing of Errors:: What Emacs does when you report an error.
+* Handling Errors:: How you can trap errors and continue execution.
+* Error Names:: How errors are classified for trapping them.
+@end menu
+
+@node Signaling Errors
+@subsubsection How to Signal an Error
+@cindex signaling errors
+
+ Most errors are signaled ``automatically'' within Lisp primitives
+which you call for other purposes, such as if you try to take the
+@sc{car} of an integer or move forward a character at the end of the
+buffer; you can also signal errors explicitly with the functions
+@code{error} and @code{signal}.
+
+ Quitting, which happens when the user types @kbd{C-g}, is not
+considered an error, but it is handled almost like an error.
+@xref{Quitting}.
+
+@defun error format-string &rest args
+This function signals an error with an error message constructed by
+applying @code{format} (@pxref{String Conversion}) to
+@var{format-string} and @var{args}.
+
+These examples show typical uses of @code{error}:
+
+@example
+@group
+(error "You have committed an error.
+ Try something else.")
+ @error{} You have committed an error.
+ Try something else.
+@end group
+
+@group
+(error "You have committed %d errors." 10)
+ @error{} You have committed 10 errors.
+@end group
+@end example
+
+@code{error} works by calling @code{signal} with two arguments: the
+error symbol @code{error}, and a list containing the string returned by
+@code{format}.
+
+If you want to use your own string as an error message verbatim, don't
+just write @code{(error @var{string})}. If @var{string} contains
+@samp{%}, it will be interpreted as a format specifier, with undesirable
+results. Instead, use @code{(error "%s" @var{string})}.
+@end defun
+
+@defun signal error-symbol data
+This function signals an error named by @var{error-symbol}. The
+argument @var{data} is a list of additional Lisp objects relevant to the
+circumstances of the error.
+
+The argument @var{error-symbol} must be an @dfn{error symbol}---a symbol
+bearing a property @code{error-conditions} whose value is a list of
+condition names. This is how Emacs Lisp classifies different sorts of
+errors.
+
+The number and significance of the objects in @var{data} depends on
+@var{error-symbol}. For example, with a @code{wrong-type-arg} error,
+there are two objects in the list: a predicate which describes the type
+that was expected, and the object which failed to fit that type.
+@xref{Error Names}, for a description of error symbols.
+
+Both @var{error-symbol} and @var{data} are available to any error
+handlers which handle the error: @code{condition-case} binds a local
+variable to a list of the form @code{(@var{error-symbol} .@:
+@var{data})} (@pxref{Handling Errors}). If the error is not handled,
+these two values are used in printing the error message.
+
+The function @code{signal} never returns (though in older Emacs versions
+it could sometimes return).
+
+@smallexample
+@group
+(signal 'wrong-number-of-arguments '(x y))
+ @error{} Wrong number of arguments: x, y
+@end group
+
+@group
+(signal 'no-such-error '("My unknown error condition."))
+ @error{} peculiar error: "My unknown error condition."
+@end group
+@end smallexample
+@end defun
+
+@cindex CL note---no continuable errors
+@quotation
+@b{Common Lisp note:} Emacs Lisp has nothing like the Common Lisp
+concept of continuable errors.
+@end quotation
+
+@node Processing of Errors
+@subsubsection How Emacs Processes Errors
+
+When an error is signaled, @code{signal} searches for an active
+@dfn{handler} for the error. A handler is a sequence of Lisp
+expressions designated to be executed if an error happens in part of the
+Lisp program. If the error has an applicable handler, the handler is
+executed, and control resumes following the handler. The handler
+executes in the environment of the @code{condition-case} which
+established it; all functions called within that @code{condition-case}
+have already been exited, and the handler cannot return to them.
+
+If there is no applicable handler for the error, the current command is
+terminated and control returns to the editor command loop, because the
+command loop has an implicit handler for all kinds of errors. The
+command loop's handler uses the error symbol and associated data to
+print an error message.
+
+@cindex @code{debug-on-error} use
+An error that has no explicit handler may call the Lisp debugger. The
+debugger is enabled if the variable @code{debug-on-error} (@pxref{Error
+Debugging}) is non-@code{nil}. Unlike error handlers, the debugger runs
+in the environment of the error, so that you can examine values of
+variables precisely as they were at the time of the error.
+
+@node Handling Errors
+@subsubsection Writing Code to Handle Errors
+@cindex error handler
+@cindex handling errors
+
+ The usual effect of signaling an error is to terminate the command
+that is running and return immediately to the Emacs editor command loop.
+You can arrange to trap errors occurring in a part of your program by
+establishing an error handler, with the special form
+@code{condition-case}. A simple example looks like this:
+
+@example
+@group
+(condition-case nil
+ (delete-file filename)
+ (error nil))
+@end group
+@end example
+
+@noindent
+This deletes the file named @var{filename}, catching any error and
+returning @code{nil} if an error occurs.
+
+ The second argument of @code{condition-case} is called the
+@dfn{protected form}. (In the example above, the protected form is a
+call to @code{delete-file}.) The error handlers go into effect when
+this form begins execution and are deactivated when this form returns.
+They remain in effect for all the intervening time. In particular, they
+are in effect during the execution of subroutines called by this form,
+and their subroutines, and so on. This is a good thing, since, strictly
+speaking, errors can be signaled only by Lisp primitives (including
+@code{signal} and @code{error}) called by the protected form, not by the
+protected form itself.
+
+ The arguments after the protected form are handlers. Each handler
+lists one or more @dfn{condition names} (which are symbols) to specify
+which errors it will handle. The error symbol specified when an error
+is signaled also defines a list of condition names. A handler applies
+to an error if they have any condition names in common. In the example
+above, there is one handler, and it specifies one condition name,
+@code{error}, which covers all errors.
+
+ The search for an applicable handler checks all the established handlers
+starting with the most recently established one. Thus, if two nested
+@code{condition-case} forms offer to handle the same error, the inner of
+the two will actually handle it.
+
+ When an error is handled, control returns to the handler. Before this
+happens, Emacs unbinds all variable bindings made by binding constructs
+that are being exited and executes the cleanups of all
+@code{unwind-protect} forms that are exited. Once control arrives at
+the handler, the body of the handler is executed.
+
+ After execution of the handler body, execution continues by returning
+from the @code{condition-case} form. Because the protected form is
+exited completely before execution of the handler, the handler cannot
+resume execution at the point of the error, nor can it examine variable
+bindings that were made within the protected form. All it can do is
+clean up and proceed.
+
+ @code{condition-case} is often used to trap errors that are
+predictable, such as failure to open a file in a call to
+@code{insert-file-contents}. It is also used to trap errors that are
+totally unpredictable, such as when the program evaluates an expression
+read from the user.
+
+ Error signaling and handling have some resemblance to @code{throw} and
+@code{catch}, but they are entirely separate facilities. An error
+cannot be caught by a @code{catch}, and a @code{throw} cannot be handled
+by an error handler (though using @code{throw} when there is no suitable
+@code{catch} signals an error which can be handled).
+
+@defspec condition-case var protected-form handlers@dots{}
+This special form establishes the error handlers @var{handlers} around
+the execution of @var{protected-form}. If @var{protected-form} executes
+without error, the value it returns becomes the value of the
+@code{condition-case} form; in this case, the @code{condition-case} has
+no effect. The @code{condition-case} form makes a difference when an
+error occurs during @var{protected-form}.
+
+Each of the @var{handlers} is a list of the form @code{(@var{conditions}
+@var{body}@dots{})}. Here @var{conditions} is an error condition name
+to be handled, or a list of condition names; @var{body} is one or more
+Lisp expressions to be executed when this handler handles an error.
+Here are examples of handlers:
+
+@smallexample
+@group
+(error nil)
+
+(arith-error (message "Division by zero"))
+
+((arith-error file-error)
+ (message
+ "Either division by zero or failure to open a file"))
+@end group
+@end smallexample
+
+Each error that occurs has an @dfn{error symbol} which describes what
+kind of error it is. The @code{error-conditions} property of this
+symbol is a list of condition names (@pxref{Error Names}). Emacs
+searches all the active @code{condition-case} forms for a handler which
+specifies one or more of these condition names; the innermost matching
+@code{condition-case} handles the error. Within this
+@code{condition-case}, the first applicable handler handles the error.
+
+After executing the body of the handler, the @code{condition-case}
+returns normally, using the value of the last form in the handler body
+as the overall value.
+
+The argument @var{var} is a variable. @code{condition-case} does not
+bind this variable when executing the @var{protected-form}, only when it
+handles an error. At that time, it binds @var{var} locally to a list of
+the form @code{(@var{error-symbol} . @var{data})}, giving the
+particulars of the error. The handler can refer to this list to decide
+what to do. For example, if the error is for failure opening a file,
+the file name is the second element of @var{data}---the third element of
+@var{var}.
+
+If @var{var} is @code{nil}, that means no variable is bound. Then the
+error symbol and associated data are not available to the handler.
+@end defspec
+
+@cindex @code{arith-error} example
+Here is an example of using @code{condition-case} to handle the error
+that results from dividing by zero. The handler prints out a warning
+message and returns a very large number.
+
+@smallexample
+@group
+(defun safe-divide (dividend divisor)
+ (condition-case err
+ ;; @r{Protected form.}
+ (/ dividend divisor)
+ ;; @r{The handler.}
+ (arith-error ; @r{Condition.}
+ (princ (format "Arithmetic error: %s" err))
+ 1000000)))
+@result{} safe-divide
+@end group
+
+@group
+(safe-divide 5 0)
+ @print{} Arithmetic error: (arith-error)
+@result{} 1000000
+@end group
+@end smallexample
+
+@noindent
+The handler specifies condition name @code{arith-error} so that it will handle only division-by-zero errors. Other kinds of errors will not be handled, at least not by this @code{condition-case}. Thus,
+
+@smallexample
+@group
+(safe-divide nil 3)
+ @error{} Wrong type argument: integer-or-marker-p, nil
+@end group
+@end smallexample
+
+ Here is a @code{condition-case} that catches all kinds of errors,
+including those signaled with @code{error}:
+
+@smallexample
+@group
+(setq baz 34)
+ @result{} 34
+@end group
+
+@group
+(condition-case err
+ (if (eq baz 35)
+ t
+ ;; @r{This is a call to the function @code{error}.}
+ (error "Rats! The variable %s was %s, not 35." 'baz baz))
+ ;; @r{This is the handler; it is not a form.}
+ (error (princ (format "The error was: %s" err))
+ 2))
+@print{} The error was: (error "Rats! The variable baz was 34, not 35.")
+@result{} 2
+@end group
+@end smallexample
+
+@node Error Names
+@subsubsection Error Symbols and Condition Names
+@cindex error symbol
+@cindex error name
+@cindex condition name
+@cindex user-defined error
+@kindex error-conditions
+
+ When you signal an error, you specify an @dfn{error symbol} to specify
+the kind of error you have in mind. Each error has one and only one
+error symbol to categorize it. This is the finest classification of
+errors defined by the Emacs Lisp language.
+
+ These narrow classifications are grouped into a hierarchy of wider
+classes called @dfn{error conditions}, identified by @dfn{condition
+names}. The narrowest such classes belong to the error symbols
+themselves: each error symbol is also a condition name. There are also
+condition names for more extensive classes, up to the condition name
+@code{error} which takes in all kinds of errors. Thus, each error has
+one or more condition names: @code{error}, the error symbol if that
+is distinct from @code{error}, and perhaps some intermediate
+classifications.
+
+ In order for a symbol to be an error symbol, it must have an
+@code{error-conditions} property which gives a list of condition names.
+This list defines the conditions which this kind of error belongs to.
+(The error symbol itself, and the symbol @code{error}, should always be
+members of this list.) Thus, the hierarchy of condition names is
+defined by the @code{error-conditions} properties of the error symbols.
+
+ In addition to the @code{error-conditions} list, the error symbol
+should have an @code{error-message} property whose value is a string to
+be printed when that error is signaled but not handled. If the
+@code{error-message} property exists, but is not a string, the error
+message @samp{peculiar error} is used.
+@cindex peculiar error
+
+ Here is how we define a new error symbol, @code{new-error}:
+
+@example
+@group
+(put 'new-error
+ 'error-conditions
+ '(error my-own-errors new-error))
+@result{} (error my-own-errors new-error)
+@end group
+@group
+(put 'new-error 'error-message "A new error")
+@result{} "A new error"
+@end group
+@end example
+
+@noindent
+This error has three condition names: @code{new-error}, the narrowest
+classification; @code{my-own-errors}, which we imagine is a wider
+classification; and @code{error}, which is the widest of all.
+
+ Naturally, Emacs will never signal @code{new-error} on its own; only
+an explicit call to @code{signal} (@pxref{Errors}) in your code can do
+this:
+
+@example
+@group
+(signal 'new-error '(x y))
+ @error{} A new error: x, y
+@end group
+@end example
+
+ This error can be handled through any of the three condition names.
+This example handles @code{new-error} and any other errors in the class
+@code{my-own-errors}:
+
+@example
+@group
+(condition-case foo
+ (bar nil t)
+ (my-own-errors nil))
+@end group
+@end example
+
+ The significant way that errors are classified is by their condition
+names---the names used to match errors with handlers. An error symbol
+serves only as a convenient way to specify the intended error message
+and list of condition names. It would be cumbersome to give
+@code{signal} a list of condition names rather than one error symbol.
+
+ By contrast, using only error symbols without condition names would
+seriously decrease the power of @code{condition-case}. Condition names
+make it possible to categorize errors at various levels of generality
+when you write an error handler. Using error symbols alone would
+eliminate all but the narrowest level of classification.
+
+ @xref{Standard Errors}, for a list of all the standard error symbols
+and their conditions.
+
+@node Cleanups
+@subsection Cleaning Up from Nonlocal Exits
+
+ The @code{unwind-protect} construct is essential whenever you
+temporarily put a data structure in an inconsistent state; it permits
+you to ensure the data are consistent in the event of an error or throw.
+
+@defspec unwind-protect body cleanup-forms@dots{}
+@cindex cleanup forms
+@cindex protected forms
+@cindex error cleanup
+@cindex unwinding
+@code{unwind-protect} executes the @var{body} with a guarantee that the
+@var{cleanup-forms} will be evaluated if control leaves @var{body}, no
+matter how that happens. The @var{body} may complete normally, or
+execute a @code{throw} out of the @code{unwind-protect}, or cause an
+error; in all cases, the @var{cleanup-forms} will be evaluated.
+
+If the @var{body} forms finish normally, @code{unwind-protect} returns
+the value of the last @var{body} form, after it evaluates the
+@var{cleanup-forms}. If the @var{body} forms do not finish,
+@code{unwind-protect} does not return any value in the normal sense.
+
+Only the @var{body} is actually protected by the @code{unwind-protect}.
+If any of the @var{cleanup-forms} themselves exits nonlocally (e.g., via
+a @code{throw} or an error), @code{unwind-protect} is @emph{not}
+guaranteed to evaluate the rest of them. If the failure of one of the
+@var{cleanup-forms} has the potential to cause trouble, then protect it
+with another @code{unwind-protect} around that form.
+
+The number of currently active @code{unwind-protect} forms counts,
+together with the number of local variable bindings, against the limit
+@code{max-specpdl-size} (@pxref{Local Variables}).
+@end defspec
+
+ For example, here we make an invisible buffer for temporary use, and
+make sure to kill it before finishing:
+
+@smallexample
+@group
+(save-excursion
+ (let ((buffer (get-buffer-create " *temp*")))
+ (set-buffer buffer)
+ (unwind-protect
+ @var{body}
+ (kill-buffer buffer))))
+@end group
+@end smallexample
+
+@noindent
+You might think that we could just as well write @code{(kill-buffer
+(current-buffer))} and dispense with the variable @code{buffer}.
+However, the way shown above is safer, if @var{body} happens to get an
+error after switching to a different buffer! (Alternatively, you could
+write another @code{save-excursion} around the body, to ensure that the
+temporary buffer becomes current in time to kill it.)
+
+@findex ftp-login
+ Here is an actual example taken from the file @file{ftp.el}. It creates
+a process (@pxref{Processes}) to try to establish a connection to a remote
+machine. As the function @code{ftp-login} is highly susceptible to
+numerous problems which the writer of the function cannot anticipate, it is
+protected with a form that guarantees deletion of the process in the event
+of failure. Otherwise, Emacs might fill up with useless subprocesses.
+
+@smallexample
+@group
+(let ((win nil))
+ (unwind-protect
+ (progn
+ (setq process (ftp-setup-buffer host file))
+ (if (setq win (ftp-login process host user password))
+ (message "Logged in")
+ (error "Ftp login failed")))
+ (or win (and process (delete-process process)))))
+@end group
+@end smallexample
+
+ This example actually has a small bug: if the user types @kbd{C-g} to
+quit, and the quit happens immediately after the function
+@code{ftp-setup-buffer} returns but before the variable @code{process} is
+set, the process will not be killed. There is no easy way to fix this bug,
+but at least it is very unlikely.
+
+ Here is another example which uses @code{unwind-protect} to make sure
+to kill a temporary buffer. In this example, the value returned by
+@code{unwind-protect} is used.
+
+@example
+(defun shell-command-string (cmd)
+ "Return the output of the shell command CMD, as a string."
+ (save-excursion
+ (set-buffer (generate-new-buffer " OS*cmd"))
+ (shell-command cmd t)
+ (unwind-protect
+ (buffer-string)
+ (kill-buffer (current-buffer)))))
+@end example