1 This is ../info/lispref.info, produced by makeinfo version 4.0 from
4 INFO-DIR-SECTION XEmacs Editor
6 * Lispref: (lispref). XEmacs Lisp Reference Manual.
11 GNU Emacs Lisp Reference Manual Second Edition (v2.01), May 1993 GNU
12 Emacs Lisp Reference Manual Further Revised (v2.02), August 1993 Lucid
13 Emacs Lisp Reference Manual (for 19.10) First Edition, March 1994
14 XEmacs Lisp Programmer's Manual (for 19.12) Second Edition, April 1995
15 GNU Emacs Lisp Reference Manual v2.4, June 1995 XEmacs Lisp
16 Programmer's Manual (for 19.13) Third Edition, July 1995 XEmacs Lisp
17 Reference Manual (for 19.14 and 20.0) v3.1, March 1996 XEmacs Lisp
18 Reference Manual (for 19.15 and 20.1, 20.2, 20.3) v3.2, April, May,
19 November 1997 XEmacs Lisp Reference Manual (for 21.0) v3.3, April 1998
21 Copyright (C) 1990, 1991, 1992, 1993, 1994, 1995 Free Software
22 Foundation, Inc. Copyright (C) 1994, 1995 Sun Microsystems, Inc.
23 Copyright (C) 1995, 1996 Ben Wing.
25 Permission is granted to make and distribute verbatim copies of this
26 manual provided the copyright notice and this permission notice are
27 preserved on all copies.
29 Permission is granted to copy and distribute modified versions of
30 this manual under the conditions for verbatim copying, provided that the
31 entire resulting derived work is distributed under the terms of a
32 permission notice identical to this one.
34 Permission is granted to copy and distribute translations of this
35 manual into another language, under the above conditions for modified
36 versions, except that this permission notice may be stated in a
37 translation approved by the Foundation.
39 Permission is granted to copy and distribute modified versions of
40 this manual under the conditions for verbatim copying, provided also
41 that the section entitled "GNU General Public License" is included
42 exactly as in the original, and provided that the entire resulting
43 derived work is distributed under the terms of a permission notice
44 identical to this one.
46 Permission is granted to copy and distribute translations of this
47 manual into another language, under the above conditions for modified
48 versions, except that the section entitled "GNU General Public License"
49 may be included in a translation approved by the Free Software
50 Foundation instead of in the original English.
53 File: lispref.info, Node: Self-Evaluating Forms, Next: Symbol Forms, Up: Forms
58 A "self-evaluating form" is any form that is not a list or symbol.
59 Self-evaluating forms evaluate to themselves: the result of evaluation
60 is the same object that was evaluated. Thus, the number 25 evaluates to
61 25, and the string `"foo"' evaluates to the string `"foo"'. Likewise,
62 evaluation of a vector does not cause evaluation of the elements of the
63 vector--it returns the same vector with its contents unchanged.
65 '123 ; An object, shown without evaluation.
67 123 ; Evaluated as usual--result is the same.
69 (eval '123) ; Evaluated "by hand"--result is the same.
71 (eval (eval '123)) ; Evaluating twice changes nothing.
74 It is common to write numbers, characters, strings, and even vectors
75 in Lisp code, taking advantage of the fact that they self-evaluate.
76 However, it is quite unusual to do this for types that lack a read
77 syntax, because there's no way to write them textually. It is possible
78 to construct Lisp expressions containing these types by means of a Lisp
79 program. Here is an example:
81 ;; Build an expression containing a buffer object.
82 (setq buffer (list 'print (current-buffer)))
83 => (print #<buffer eval.texi>)
86 -| #<buffer eval.texi>
87 => #<buffer eval.texi>
90 File: lispref.info, Node: Symbol Forms, Next: Classifying Lists, Prev: Self-Evaluating Forms, Up: Forms
95 When a symbol is evaluated, it is treated as a variable. The result
96 is the variable's value, if it has one. If it has none (if its value
97 cell is void), an error is signaled. For more information on the use of
98 variables, see *Note Variables::.
100 In the following example, we set the value of a symbol with `setq'.
101 Then we evaluate the symbol, and get back the value that `setq' stored.
110 The symbols `nil' and `t' are treated specially, so that the value
111 of `nil' is always `nil', and the value of `t' is always `t'; you
112 cannot set or bind them to any other values. Thus, these two symbols
113 act like self-evaluating forms, even though `eval' treats them like any
117 File: lispref.info, Node: Classifying Lists, Next: Function Indirection, Prev: Symbol Forms, Up: Forms
119 Classification of List Forms
120 ----------------------------
122 A form that is a nonempty list is either a function call, a macro
123 call, or a special form, according to its first element. These three
124 kinds of forms are evaluated in different ways, described below. The
125 remaining list elements constitute the "arguments" for the function,
126 macro, or special form.
128 The first step in evaluating a nonempty list is to examine its first
129 element. This element alone determines what kind of form the list is
130 and how the rest of the list is to be processed. The first element is
131 _not_ evaluated, as it would be in some Lisp dialects such as Scheme.
134 File: lispref.info, Node: Function Indirection, Next: Function Forms, Prev: Classifying Lists, Up: Forms
136 Symbol Function Indirection
137 ---------------------------
139 If the first element of the list is a symbol then evaluation examines
140 the symbol's function cell, and uses its contents instead of the
141 original symbol. If the contents are another symbol, this process,
142 called "symbol function indirection", is repeated until it obtains a
143 non-symbol. *Note Function Names::, for more information about using a
144 symbol as a name for a function stored in the function cell of the
147 One possible consequence of this process is an infinite loop, in the
148 event that a symbol's function cell refers to the same symbol. Or a
149 symbol may have a void function cell, in which case the subroutine
150 `symbol-function' signals a `void-function' error. But if neither of
151 these things happens, we eventually obtain a non-symbol, which ought to
152 be a function or other suitable object.
154 More precisely, we should now have a Lisp function (a lambda
155 expression), a byte-code function, a primitive function, a Lisp macro, a
156 special form, or an autoload object. Each of these types is a case
157 described in one of the following sections. If the object is not one of
158 these types, the error `invalid-function' is signaled.
160 The following example illustrates the symbol indirection process. We
161 use `fset' to set the function cell of a symbol and `symbol-function'
162 to get the function cell contents (*note Function Cells::).
163 Specifically, we store the symbol `car' into the function cell of
164 `first', and the symbol `first' into the function cell of `erste'.
166 ;; Build this function cell linkage:
167 ;; ------------- ----- ------- -------
168 ;; | #<subr car> | <-- | car | <-- | first | <-- | erste |
169 ;; ------------- ----- ------- -------
171 (symbol-function 'car)
177 (erste '(1 2 3)) ; Call the function referenced by `erste'.
180 By contrast, the following example calls a function without any
181 symbol function indirection, because the first element is an anonymous
182 Lisp function, not a symbol.
184 ((lambda (arg) (erste arg))
188 Executing the function itself evaluates its body; this does involve
189 symbol function indirection when calling `erste'.
191 The built-in function `indirect-function' provides an easy way to
192 perform symbol function indirection explicitly.
194 - Function: indirect-function function
195 This function returns the meaning of FUNCTION as a function. If
196 FUNCTION is a symbol, then it finds FUNCTION's function definition
197 and starts over with that value. If FUNCTION is not a symbol,
198 then it returns FUNCTION itself.
200 Here is how you could define `indirect-function' in Lisp:
202 (defun indirect-function (function)
203 (if (symbolp function)
204 (indirect-function (symbol-function function))
208 File: lispref.info, Node: Function Forms, Next: Macro Forms, Prev: Function Indirection, Up: Forms
210 Evaluation of Function Forms
211 ----------------------------
213 If the first element of a list being evaluated is a Lisp function
214 object, byte-code object or primitive function object, then that list is
215 a "function call". For example, here is a call to the function `+':
219 The first step in evaluating a function call is to evaluate the
220 remaining elements of the list from left to right. The results are the
221 actual argument values, one value for each list element. The next step
222 is to call the function with this list of arguments, effectively using
223 the function `apply' (*note Calling Functions::). If the function is
224 written in Lisp, the arguments are used to bind the argument variables
225 of the function (*note Lambda Expressions::); then the forms in the
226 function body are evaluated in order, and the value of the last body
227 form becomes the value of the function call.
230 File: lispref.info, Node: Macro Forms, Next: Special Forms, Prev: Function Forms, Up: Forms
232 Lisp Macro Evaluation
233 ---------------------
235 If the first element of a list being evaluated is a macro object,
236 then the list is a "macro call". When a macro call is evaluated, the
237 elements of the rest of the list are _not_ initially evaluated.
238 Instead, these elements themselves are used as the arguments of the
239 macro. The macro definition computes a replacement form, called the
240 "expansion" of the macro, to be evaluated in place of the original
241 form. The expansion may be any sort of form: a self-evaluating
242 constant, a symbol, or a list. If the expansion is itself a macro call,
243 this process of expansion repeats until some other sort of form results.
245 Ordinary evaluation of a macro call finishes by evaluating the
246 expansion. However, the macro expansion is not necessarily evaluated
247 right away, or at all, because other programs also expand macro calls,
248 and they may or may not evaluate the expansions.
250 Normally, the argument expressions are not evaluated as part of
251 computing the macro expansion, but instead appear as part of the
252 expansion, so they are computed when the expansion is computed.
254 For example, given a macro defined as follows:
257 (list 'car (list 'cdr x)))
259 an expression such as `(cadr (assq 'handler list))' is a macro call,
260 and its expansion is:
262 (car (cdr (assq 'handler list)))
264 Note that the argument `(assq 'handler list)' appears in the expansion.
266 *Note Macros::, for a complete description of XEmacs Lisp macros.
269 File: lispref.info, Node: Special Forms, Next: Autoloading, Prev: Macro Forms, Up: Forms
274 A "special form" is a primitive function specially marked so that
275 its arguments are not all evaluated. Most special forms define control
276 structures or perform variable bindings--things which functions cannot
279 Each special form has its own rules for which arguments are evaluated
280 and which are used without evaluation. Whether a particular argument is
281 evaluated may depend on the results of evaluating other arguments.
283 Here is a list, in alphabetical order, of all of the special forms in
284 XEmacs Lisp with a reference to where each is described.
287 *note Combining Conditions::
290 *note Catch and Throw::
296 *note Handling Errors::
299 *note Defining Variables::
302 *note Defining Macros::
305 *note Defining Functions::
308 *note Defining Variables::
311 *note Anonymous Functions::
317 *note Interactive Call::
321 *note Local Variables::
324 *note Combining Conditions::
334 `save-current-buffer'
343 `save-selected-window'
346 `save-window-excursion'
347 *note Window Configurations::
350 *note Setting Variables::
353 *note Creating Buffer-Local::
356 *note Nonlocal Exits::
361 `with-output-to-temp-buffer'
362 *note Temporary Displays::
364 Common Lisp note: here are some comparisons of special forms in
365 XEmacs Lisp and Common Lisp. `setq', `if', and `catch' are
366 special forms in both XEmacs Lisp and Common Lisp. `defun' is a
367 special form in XEmacs Lisp, but a macro in Common Lisp.
368 `save-excursion' is a special form in XEmacs Lisp, but doesn't
369 exist in Common Lisp. `throw' is a special form in Common Lisp
370 (because it must be able to throw multiple values), but it is a
371 function in XEmacs Lisp (which doesn't have multiple values).
374 File: lispref.info, Node: Autoloading, Prev: Special Forms, Up: Forms
379 The "autoload" feature allows you to call a function or macro whose
380 function definition has not yet been loaded into XEmacs. It specifies
381 which file contains the definition. When an autoload object appears as
382 a symbol's function definition, calling that symbol as a function
383 automatically loads the specified file; then it calls the real
384 definition loaded from that file. *Note Autoload::.
387 File: lispref.info, Node: Quoting, Prev: Forms, Up: Evaluation
392 The special form `quote' returns its single argument, as written,
393 without evaluating it. This provides a way to include constant symbols
394 and lists, which are not self-evaluating objects, in a program. (It is
395 not necessary to quote self-evaluating objects such as numbers, strings,
398 - Special Form: quote object
399 This special form returns OBJECT, without evaluating it.
401 Because `quote' is used so often in programs, Lisp provides a
402 convenient read syntax for it. An apostrophe character (`'') followed
403 by a Lisp object (in read syntax) expands to a list whose first element
404 is `quote', and whose second element is the object. Thus, the read
405 syntax `'x' is an abbreviation for `(quote x)'.
407 Here are some examples of expressions that use `quote':
422 Other quoting constructs include `function' (*note Anonymous
423 Functions::), which causes an anonymous lambda expression written in
424 Lisp to be compiled, and ``' (*note Backquote::), which is used to quote
425 only part of a list, while computing and substituting other parts.
428 File: lispref.info, Node: Control Structures, Next: Variables, Prev: Evaluation, Up: Top
433 A Lisp program consists of expressions or "forms" (*note Forms::).
434 We control the order of execution of the forms by enclosing them in
435 "control structures". Control structures are special forms which
436 control when, whether, or how many times to execute the forms they
439 The simplest order of execution is sequential execution: first form
440 A, then form B, and so on. This is what happens when you write several
441 forms in succession in the body of a function, or at top level in a
442 file of Lisp code--the forms are executed in the order written. We
443 call this "textual order". For example, if a function body consists of
444 two forms A and B, evaluation of the function evaluates first A and
445 then B, and the function's value is the value of B.
447 Explicit control structures make possible an order of execution other
450 XEmacs Lisp provides several kinds of control structure, including
451 other varieties of sequencing, conditionals, iteration, and (controlled)
452 jumps--all discussed below. The built-in control structures are
453 special forms since their subforms are not necessarily evaluated or not
454 evaluated sequentially. You can use macros to define your own control
455 structure constructs (*note Macros::).
459 * Sequencing:: Evaluation in textual order.
460 * Conditionals:: `if', `cond'.
461 * Combining Conditions:: `and', `or', `not'.
462 * Iteration:: `while' loops.
463 * Nonlocal Exits:: Jumping out of a sequence.
466 File: lispref.info, Node: Sequencing, Next: Conditionals, Up: Control Structures
471 Evaluating forms in the order they appear is the most common way
472 control passes from one form to another. In some contexts, such as in a
473 function body, this happens automatically. Elsewhere you must use a
474 control structure construct to do this: `progn', the simplest control
477 A `progn' special form looks like this:
481 and it says to execute the forms A, B, C and so on, in that order.
482 These forms are called the body of the `progn' form. The value of the
483 last form in the body becomes the value of the entire `progn'.
485 In the early days of Lisp, `progn' was the only way to execute two
486 or more forms in succession and use the value of the last of them. But
487 programmers found they often needed to use a `progn' in the body of a
488 function, where (at that time) only one form was allowed. So the body
489 of a function was made into an "implicit `progn'": several forms are
490 allowed just as in the body of an actual `progn'. Many other control
491 structures likewise contain an implicit `progn'. As a result, `progn'
492 is not used as often as it used to be. It is needed now most often
493 inside an `unwind-protect', `and', `or', or in the THEN-part of an `if'.
495 - Special Form: progn forms...
496 This special form evaluates all of the FORMS, in textual order,
497 returning the result of the final form.
499 (progn (print "The first form")
500 (print "The second form")
501 (print "The third form"))
507 Two other control constructs likewise evaluate a series of forms but
508 return a different value:
510 - Special Form: prog1 form1 forms...
511 This special form evaluates FORM1 and all of the FORMS, in textual
512 order, returning the result of FORM1.
514 (prog1 (print "The first form")
515 (print "The second form")
516 (print "The third form"))
522 Here is a way to remove the first element from a list in the
523 variable `x', then return the value of that former element:
525 (prog1 (car x) (setq x (cdr x)))
527 - Special Form: prog2 form1 form2 forms...
528 This special form evaluates FORM1, FORM2, and all of the following
529 FORMS, in textual order, returning the result of FORM2.
531 (prog2 (print "The first form")
532 (print "The second form")
533 (print "The third form"))
540 File: lispref.info, Node: Conditionals, Next: Combining Conditions, Prev: Sequencing, Up: Control Structures
545 Conditional control structures choose among alternatives. XEmacs
546 Lisp has two conditional forms: `if', which is much the same as in other
547 languages, and `cond', which is a generalized case statement.
549 - Special Form: if condition then-form else-forms...
550 `if' chooses between the THEN-FORM and the ELSE-FORMS based on the
551 value of CONDITION. If the evaluated CONDITION is non-`nil',
552 THEN-FORM is evaluated and the result returned. Otherwise, the
553 ELSE-FORMS are evaluated in textual order, and the value of the
554 last one is returned. (The ELSE part of `if' is an example of an
555 implicit `progn'. *Note Sequencing::.)
557 If CONDITION has the value `nil', and no ELSE-FORMS are given,
560 `if' is a special form because the branch that is not selected is
561 never evaluated--it is ignored. Thus, in the example below,
562 `true' is not printed because `print' is never called.
569 - Special Form: cond clause...
570 `cond' chooses among an arbitrary number of alternatives. Each
571 CLAUSE in the `cond' must be a list. The CAR of this list is the
572 CONDITION; the remaining elements, if any, the BODY-FORMS. Thus,
573 a clause looks like this:
575 (CONDITION BODY-FORMS...)
577 `cond' tries the clauses in textual order, by evaluating the
578 CONDITION of each clause. If the value of CONDITION is non-`nil',
579 the clause "succeeds"; then `cond' evaluates its BODY-FORMS, and
580 the value of the last of BODY-FORMS becomes the value of the
581 `cond'. The remaining clauses are ignored.
583 If the value of CONDITION is `nil', the clause "fails", so the
584 `cond' moves on to the following clause, trying its CONDITION.
586 If every CONDITION evaluates to `nil', so that every clause fails,
587 `cond' returns `nil'.
589 A clause may also look like this:
593 Then, if CONDITION is non-`nil' when tested, the value of
594 CONDITION becomes the value of the `cond' form.
596 The following example has four clauses, which test for the cases
597 where the value of `x' is a number, string, buffer and symbol,
600 (cond ((numberp x) x)
603 (setq temporary-hack x) ; multiple body-forms
604 (buffer-name x)) ; in one clause
605 ((symbolp x) (symbol-value x)))
607 Often we want to execute the last clause whenever none of the
608 previous clauses was successful. To do this, we use `t' as the
609 CONDITION of the last clause, like this: `(t BODY-FORMS)'. The
610 form `t' evaluates to `t', which is never `nil', so this clause
611 never fails, provided the `cond' gets to it at all.
615 (cond ((eq a 'hack) 'foo)
619 This expression is a `cond' which returns `foo' if the value of
620 `a' is 1, and returns the string `"default"' otherwise.
622 Any conditional construct can be expressed with `cond' or with `if'.
623 Therefore, the choice between them is a matter of style. For example:
630 File: lispref.info, Node: Combining Conditions, Next: Iteration, Prev: Conditionals, Up: Control Structures
632 Constructs for Combining Conditions
633 ===================================
635 This section describes three constructs that are often used together
636 with `if' and `cond' to express complicated conditions. The constructs
637 `and' and `or' can also be used individually as kinds of multiple
638 conditional constructs.
640 - Function: not condition
641 This function tests for the falsehood of CONDITION. It returns
642 `t' if CONDITION is `nil', and `nil' otherwise. The function
643 `not' is identical to `null', and we recommend using the name
644 `null' if you are testing for an empty list.
646 - Special Form: and conditions...
647 The `and' special form tests whether all the CONDITIONS are true.
648 It works by evaluating the CONDITIONS one by one in the order
651 If any of the CONDITIONS evaluates to `nil', then the result of
652 the `and' must be `nil' regardless of the remaining CONDITIONS; so
653 `and' returns right away, ignoring the remaining CONDITIONS.
655 If all the CONDITIONS turn out non-`nil', then the value of the
656 last of them becomes the value of the `and' form.
658 Here is an example. The first condition returns the integer 1,
659 which is not `nil'. Similarly, the second condition returns the
660 integer 2, which is not `nil'. The third condition is `nil', so
661 the remaining condition is never evaluated.
663 (and (print 1) (print 2) nil (print 3))
668 Here is a more realistic example of using `and':
670 (if (and (consp foo) (eq (car foo) 'x))
671 (message "foo is a list starting with x"))
673 Note that `(car foo)' is not executed if `(consp foo)' returns
674 `nil', thus avoiding an error.
676 `and' can be expressed in terms of either `if' or `cond'. For
681 (if ARG1 (if ARG2 ARG3))
683 (cond (ARG1 (cond (ARG2 ARG3))))
685 - Special Form: or conditions...
686 The `or' special form tests whether at least one of the CONDITIONS
687 is true. It works by evaluating all the CONDITIONS one by one in
690 If any of the CONDITIONS evaluates to a non-`nil' value, then the
691 result of the `or' must be non-`nil'; so `or' returns right away,
692 ignoring the remaining CONDITIONS. The value it returns is the
693 non-`nil' value of the condition just evaluated.
695 If all the CONDITIONS turn out `nil', then the `or' expression
698 For example, this expression tests whether `x' is either 0 or
701 (or (eq x nil) (eq x 0))
703 Like the `and' construct, `or' can be written in terms of `cond'.
712 You could almost write `or' in terms of `if', but not quite:
718 This is not completely equivalent because it can evaluate ARG1 or
719 ARG2 twice. By contrast, `(or ARG1 ARG2 ARG3)' never evaluates
720 any argument more than once.
723 File: lispref.info, Node: Iteration, Next: Nonlocal Exits, Prev: Combining Conditions, Up: Control Structures
728 Iteration means executing part of a program repetitively. For
729 example, you might want to repeat some computation once for each element
730 of a list, or once for each integer from 0 to N. You can do this in
731 XEmacs Lisp with the special form `while':
733 - Special Form: while condition forms...
734 `while' first evaluates CONDITION. If the result is non-`nil', it
735 evaluates FORMS in textual order. Then it reevaluates CONDITION,
736 and if the result is non-`nil', it evaluates FORMS again. This
737 process repeats until CONDITION evaluates to `nil'.
739 There is no limit on the number of iterations that may occur. The
740 loop will continue until either CONDITION evaluates to `nil' or
741 until an error or `throw' jumps out of it (*note Nonlocal Exits::).
743 The value of a `while' form is always `nil'.
748 (princ (format "Iteration %d." num))
756 If you would like to execute something on each iteration before the
757 end-test, put it together with the end-test in a `progn' as the
758 first argument of `while', as shown here:
762 (not (looking-at "^$"))))
764 This moves forward one line and continues moving by lines until it
765 reaches an empty. It is unusual in that the `while' has no body,
766 just the end test (which also does the real work of moving point).
769 File: lispref.info, Node: Nonlocal Exits, Prev: Iteration, Up: Control Structures
774 A "nonlocal exit" is a transfer of control from one point in a
775 program to another remote point. Nonlocal exits can occur in XEmacs
776 Lisp as a result of errors; you can also use them under explicit
777 control. Nonlocal exits unbind all variable bindings made by the
778 constructs being exited.
782 * Catch and Throw:: Nonlocal exits for the program's own purposes.
783 * Examples of Catch:: Showing how such nonlocal exits can be written.
784 * Errors:: How errors are signaled and handled.
785 * Cleanups:: Arranging to run a cleanup form if an error happens.
788 File: lispref.info, Node: Catch and Throw, Next: Examples of Catch, Up: Nonlocal Exits
790 Explicit Nonlocal Exits: `catch' and `throw'
791 --------------------------------------------
793 Most control constructs affect only the flow of control within the
794 construct itself. The function `throw' is the exception to this rule
795 of normal program execution: it performs a nonlocal exit on request.
796 (There are other exceptions, but they are for error handling only.)
797 `throw' is used inside a `catch', and jumps back to that `catch'. For
806 The `throw' transfers control straight back to the corresponding
807 `catch', which returns immediately. The code following the `throw' is
808 not executed. The second argument of `throw' is used as the return
809 value of the `catch'.
811 The `throw' and the `catch' are matched through the first argument:
812 `throw' searches for a `catch' whose first argument is `eq' to the one
813 specified. Thus, in the above example, the `throw' specifies `foo',
814 and the `catch' specifies the same symbol, so that `catch' is
815 applicable. If there is more than one applicable `catch', the
816 innermost one takes precedence.
818 Executing `throw' exits all Lisp constructs up to the matching
819 `catch', including function calls. When binding constructs such as
820 `let' or function calls are exited in this way, the bindings are
821 unbound, just as they are when these constructs exit normally (*note
822 Local Variables::). Likewise, `throw' restores the buffer and position
823 saved by `save-excursion' (*note Excursions::), and the narrowing
824 status saved by `save-restriction' and the window selection saved by
825 `save-window-excursion' (*note Window Configurations::). It also runs
826 any cleanups established with the `unwind-protect' special form when it
827 exits that form (*note Cleanups::).
829 The `throw' need not appear lexically within the `catch' that it
830 jumps to. It can equally well be called from another function called
831 within the `catch'. As long as the `throw' takes place chronologically
832 after entry to the `catch', and chronologically before exit from it, it
833 has access to that `catch'. This is why `throw' can be used in
834 commands such as `exit-recursive-edit' that throw back to the editor
835 command loop (*note Recursive Editing::).
837 Common Lisp note: Most other versions of Lisp, including Common
838 Lisp, have several ways of transferring control nonsequentially:
839 `return', `return-from', and `go', for example. XEmacs Lisp has
842 - Special Form: catch tag body...
843 `catch' establishes a return point for the `throw' function. The
844 return point is distinguished from other such return points by TAG,
845 which may be any Lisp object. The argument TAG is evaluated
846 normally before the return point is established.
848 With the return point in effect, `catch' evaluates the forms of the
849 BODY in textual order. If the forms execute normally, without
850 error or nonlocal exit, the value of the last body form is
851 returned from the `catch'.
853 If a `throw' is done within BODY specifying the same value TAG,
854 the `catch' exits immediately; the value it returns is whatever
855 was specified as the second argument of `throw'.
857 - Function: throw tag value
858 The purpose of `throw' is to return from a return point previously
859 established with `catch'. The argument TAG is used to choose
860 among the various existing return points; it must be `eq' to the
861 value specified in the `catch'. If multiple return points match
862 TAG, the innermost one is used.
864 The argument VALUE is used as the value to return from that
867 If no return point is in effect with tag TAG, then a `no-catch'
868 error is signaled with data `(TAG VALUE)'.
871 File: lispref.info, Node: Examples of Catch, Next: Errors, Prev: Catch and Throw, Up: Nonlocal Exits
873 Examples of `catch' and `throw'
874 -------------------------------
876 One way to use `catch' and `throw' is to exit from a doubly nested
877 loop. (In most languages, this would be done with a "go to".) Here we
878 compute `(foo I J)' for I and J varying from 0 to 9:
887 (throw 'loop (list i j)))
891 If `foo' ever returns non-`nil', we stop immediately and return a list
892 of I and J. If `foo' always returns `nil', the `catch' returns
893 normally, and the value is `nil', since that is the result of the
896 Here are two tricky examples, slightly different, showing two return
897 points at once. First, two return points with the same tag, `hack':
905 (print (catch2 'hack))
910 Since both return points have tags that match the `throw', it goes to
911 the inner one, the one established in `catch2'. Therefore, `catch2'
912 returns normally with value `yes', and this value is printed. Finally
913 the second body form in the outer `catch', which is `'no', is evaluated
914 and returned from the outer `catch'.
916 Now let's change the argument given to `catch2':
924 (print (catch2 'quux))
928 We still have two return points, but this time only the outer one has
929 the tag `hack'; the inner one has the tag `quux' instead. Therefore,
930 `throw' makes the outer `catch' return the value `yes'. The function
931 `print' is never called, and the body-form `'no' is never evaluated.
934 File: lispref.info, Node: Errors, Next: Cleanups, Prev: Examples of Catch, Up: Nonlocal Exits
939 When XEmacs Lisp attempts to evaluate a form that, for some reason,
940 cannot be evaluated, it "signals" an "error".
942 When an error is signaled, XEmacs's default reaction is to print an
943 error message and terminate execution of the current command. This is
944 the right thing to do in most cases, such as if you type `C-f' at the
947 In complicated programs, simple termination may not be what you want.
948 For example, the program may have made temporary changes in data
949 structures, or created temporary buffers that should be deleted before
950 the program is finished. In such cases, you would use `unwind-protect'
951 to establish "cleanup expressions" to be evaluated in case of error.
952 (*Note Cleanups::.) Occasionally, you may wish the program to continue
953 execution despite an error in a subroutine. In these cases, you would
954 use `condition-case' to establish "error handlers" to recover control
957 Resist the temptation to use error handling to transfer control from
958 one part of the program to another; use `catch' and `throw' instead.
959 *Note Catch and Throw::.
963 * Signaling Errors:: How to report an error.
964 * Processing of Errors:: What XEmacs does when you report an error.
965 * Handling Errors:: How you can trap errors and continue execution.
966 * Error Symbols:: How errors are classified for trapping them.
969 File: lispref.info, Node: Signaling Errors, Next: Processing of Errors, Up: Errors
971 How to Signal an Error
972 ......................
974 Most errors are signaled "automatically" within Lisp primitives
975 which you call for other purposes, such as if you try to take the CAR
976 of an integer or move forward a character at the end of the buffer; you
977 can also signal errors explicitly with the functions `error', `signal',
980 Quitting, which happens when the user types `C-g', is not considered
981 an error, but it is handled almost like an error. *Note Quitting::.
983 - Function: error format-string &rest args
984 This function signals an error with an error message constructed by
985 applying `format' (*note String Conversion::) to FORMAT-STRING and
988 This error is not continuable: you cannot continue execution after
989 the error using the debugger `r' or `c' commands. If you wish the
990 user to be able to continue execution, use `cerror' or `signal'
993 These examples show typical uses of `error':
995 (error "You have committed an error.
996 Try something else.")
997 error--> You have committed an error.
1000 (error "You have committed %d errors." 10)
1001 error--> You have committed 10 errors.
1003 `error' works by calling `signal' with two arguments: the error
1004 symbol `error', and a list containing the string returned by
1005 `format'. This is repeated in an endless loop, to ensure that
1006 `error' never returns.
1008 If you want to use your own string as an error message verbatim,
1009 don't just write `(error STRING)'. If STRING contains `%', it
1010 will be interpreted as a format specifier, with undesirable
1011 results. Instead, use `(error "%s" STRING)'.
1013 - Function: cerror format-string &rest args
1014 This function behaves like `error', except that the error it
1015 signals is continuable. That means that debugger commands `c' and
1016 `r' can resume execution.
1018 - Function: signal error-symbol data
1019 This function signals a continuable error named by ERROR-SYMBOL.
1020 The argument DATA is a list of additional Lisp objects relevant to
1021 the circumstances of the error.
1023 The argument ERROR-SYMBOL must be an "error symbol"--a symbol
1024 bearing a property `error-conditions' whose value is a list of
1025 condition names. This is how XEmacs Lisp classifies different
1028 The number and significance of the objects in DATA depends on
1029 ERROR-SYMBOL. For example, with a `wrong-type-argument' error,
1030 there are two objects in the list: a predicate that describes the
1031 type that was expected, and the object that failed to fit that
1032 type. *Note Error Symbols::, for a description of error symbols.
1034 Both ERROR-SYMBOL and DATA are available to any error handlers
1035 that handle the error: `condition-case' binds a local variable to
1036 a list of the form `(ERROR-SYMBOL . DATA)' (*note Handling
1037 Errors::). If the error is not handled, these two values are used
1038 in printing the error message.
1040 The function `signal' can return, if the debugger is invoked and
1041 the user invokes the "return from signal" option. If you want the
1042 error not to be continuable, use `signal-error' instead. Note that
1043 in FSF Emacs `signal' never returns.
1045 (signal 'wrong-number-of-arguments '(x y))
1046 error--> Wrong number of arguments: x, y
1048 (signal 'no-such-error '("My unknown error condition"))
1049 error--> Peculiar error (no-such-error "My unknown error condition")
1051 - Function: signal-error error-symbol data
1052 This function behaves like `signal', except that the error it
1053 signals is not continuable.
1055 - Macro: check-argument-type predicate argument
1056 This macro checks that ARGUMENT satisfies PREDICATE. If that is
1057 not the case, it signals a continuable `wrong-type-argument' error
1058 until the returned value satisfies PREDICATE, and assigns the
1059 returned value to ARGUMENT. In other words, execution of the
1060 program will not continue until PREDICATE is met.
1062 ARGUMENT is not evaluated, and should be a symbol. PREDICATE is
1063 evaluated, and should name a function.
1065 As shown in the following example, `check-argument-type' is useful
1066 in low-level code that attempts to ensure the sanity of its data
1069 (defun cache-object-internal (object wlist)
1070 ;; Before doing anything, make sure that WLIST is indeed
1071 ;; a weak list, which is what we expect.
1072 (check-argument-type 'weak-list-p wlist)
1076 File: lispref.info, Node: Processing of Errors, Next: Handling Errors, Prev: Signaling Errors, Up: Errors
1078 How XEmacs Processes Errors
1079 ...........................
1081 When an error is signaled, `signal' searches for an active "handler"
1082 for the error. A handler is a sequence of Lisp expressions designated
1083 to be executed if an error happens in part of the Lisp program. If the
1084 error has an applicable handler, the handler is executed, and control
1085 resumes following the handler. The handler executes in the environment
1086 of the `condition-case' that established it; all functions called
1087 within that `condition-case' have already been exited, and the handler
1088 cannot return to them.
1090 If there is no applicable handler for the error, the current command
1091 is terminated and control returns to the editor command loop, because
1092 the command loop has an implicit handler for all kinds of errors. The
1093 command loop's handler uses the error symbol and associated data to
1094 print an error message.
1096 Errors in command loop are processed using the `command-error'
1097 function, which takes care of some necessary cleanup, and prints a
1098 formatted error message to the echo area. The functions that do the
1099 formatting are explained below.
1101 - Function: display-error error-object stream
1102 This function displays ERROR-OBJECT on STREAM. ERROR-OBJECT is a
1103 cons of error type, a symbol, and error arguments, a list. If the
1104 error type symbol of one of its error condition superclasses has
1105 an `display-error' property, that function is invoked for printing
1106 the actual error message. Otherwise, the error is printed as
1107 `Error: arg1, arg2, ...'.
1109 - Function: error-message-string error-object
1110 This function converts ERROR-OBJECT to an error message string,
1111 and returns it. The message is equivalent to the one that would be
1112 printed by `display-error', except that it is conveniently returned
1115 An error that has no explicit handler may call the Lisp debugger.
1116 The debugger is enabled if the variable `debug-on-error' (*note Error
1117 Debugging::) is non-`nil'. Unlike error handlers, the debugger runs in
1118 the environment of the error, so that you can examine values of
1119 variables precisely as they were at the time of the error.
1122 File: lispref.info, Node: Handling Errors, Next: Error Symbols, Prev: Processing of Errors, Up: Errors
1124 Writing Code to Handle Errors
1125 .............................
1127 The usual effect of signaling an error is to terminate the command
1128 that is running and return immediately to the XEmacs editor command
1129 loop. You can arrange to trap errors occurring in a part of your
1130 program by establishing an error handler, with the special form
1131 `condition-case'. A simple example looks like this:
1134 (delete-file filename)
1137 This deletes the file named FILENAME, catching any error and returning
1138 `nil' if an error occurs.
1140 The second argument of `condition-case' is called the "protected
1141 form". (In the example above, the protected form is a call to
1142 `delete-file'.) The error handlers go into effect when this form
1143 begins execution and are deactivated when this form returns. They
1144 remain in effect for all the intervening time. In particular, they are
1145 in effect during the execution of functions called by this form, in
1146 their subroutines, and so on. This is a good thing, since, strictly
1147 speaking, errors can be signaled only by Lisp primitives (including
1148 `signal' and `error') called by the protected form, not by the
1149 protected form itself.
1151 The arguments after the protected form are handlers. Each handler
1152 lists one or more "condition names" (which are symbols) to specify
1153 which errors it will handle. The error symbol specified when an error
1154 is signaled also defines a list of condition names. A handler applies
1155 to an error if they have any condition names in common. In the example
1156 above, there is one handler, and it specifies one condition name,
1157 `error', which covers all errors.
1159 The search for an applicable handler checks all the established
1160 handlers starting with the most recently established one. Thus, if two
1161 nested `condition-case' forms offer to handle the same error, the inner
1162 of the two will actually handle it.
1164 When an error is handled, control returns to the handler. Before
1165 this happens, XEmacs unbinds all variable bindings made by binding
1166 constructs that are being exited and executes the cleanups of all
1167 `unwind-protect' forms that are exited. Once control arrives at the
1168 handler, the body of the handler is executed.
1170 After execution of the handler body, execution continues by returning
1171 from the `condition-case' form. Because the protected form is exited
1172 completely before execution of the handler, the handler cannot resume
1173 execution at the point of the error, nor can it examine variable
1174 bindings that were made within the protected form. All it can do is
1175 clean up and proceed.
1177 `condition-case' is often used to trap errors that are predictable,
1178 such as failure to open a file in a call to `insert-file-contents'. It
1179 is also used to trap errors that are totally unpredictable, such as
1180 when the program evaluates an expression read from the user.
1182 Even when an error is handled, the debugger may still be called if
1183 the variable `debug-on-signal' (*note Error Debugging::) is non-`nil'.
1184 Note that this may yield unpredictable results with code that traps
1185 expected errors as normal part of its operation. Do not set
1186 `debug-on-signal' unless you know what you are doing.
1188 Error signaling and handling have some resemblance to `throw' and
1189 `catch', but they are entirely separate facilities. An error cannot be
1190 caught by a `catch', and a `throw' cannot be handled by an error
1191 handler (though using `throw' when there is no suitable `catch' signals
1192 an error that can be handled).
1194 - Special Form: condition-case var protected-form handlers...
1195 This special form establishes the error handlers HANDLERS around
1196 the execution of PROTECTED-FORM. If PROTECTED-FORM executes
1197 without error, the value it returns becomes the value of the
1198 `condition-case' form; in this case, the `condition-case' has no
1199 effect. The `condition-case' form makes a difference when an
1200 error occurs during PROTECTED-FORM.
1202 Each of the HANDLERS is a list of the form `(CONDITIONS BODY...)'.
1203 Here CONDITIONS is an error condition name to be handled, or a
1204 list of condition names; BODY is one or more Lisp expressions to
1205 be executed when this handler handles an error. Here are examples
1210 (arith-error (message "Division by zero"))
1212 ((arith-error file-error)
1214 "Either division by zero or failure to open a file"))
1216 Each error that occurs has an "error symbol" that describes what
1217 kind of error it is. The `error-conditions' property of this
1218 symbol is a list of condition names (*note Error Symbols::). Emacs
1219 searches all the active `condition-case' forms for a handler that
1220 specifies one or more of these condition names; the innermost
1221 matching `condition-case' handles the error. Within this
1222 `condition-case', the first applicable handler handles the error.
1224 After executing the body of the handler, the `condition-case'
1225 returns normally, using the value of the last form in the handler
1226 body as the overall value.
1228 The argument VAR is a variable. `condition-case' does not bind
1229 this variable when executing the PROTECTED-FORM, only when it
1230 handles an error. At that time, it binds VAR locally to a list of
1231 the form `(ERROR-SYMBOL . DATA)', giving the particulars of the
1232 error. The handler can refer to this list to decide what to do.
1233 For example, if the error is for failure opening a file, the file
1234 name is the second element of DATA--the third element of VAR.
1236 If VAR is `nil', that means no variable is bound. Then the error
1237 symbol and associated data are not available to the handler.
1239 Here is an example of using `condition-case' to handle the error
1240 that results from dividing by zero. The handler prints out a warning
1241 message and returns a very large number.
1243 (defun safe-divide (dividend divisor)
1246 (/ dividend divisor)
1248 (arith-error ; Condition.
1249 (princ (format "Arithmetic error: %s" err))
1254 -| Arithmetic error: (arith-error)
1257 The handler specifies condition name `arith-error' so that it will
1258 handle only division-by-zero errors. Other kinds of errors will not be
1259 handled, at least not by this `condition-case'. Thus,
1262 error--> Wrong type argument: integer-or-marker-p, nil
1264 Here is a `condition-case' that catches all kinds of errors,
1265 including those signaled with `error':
1273 ;; This is a call to the function `error'.
1274 (error "Rats! The variable %s was %s, not 35" 'baz baz))
1275 ;; This is the handler; it is not a form.
1276 (error (princ (format "The error was: %s" err))
1278 -| The error was: (error "Rats! The variable baz was 34, not 35")