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Revision 1.82 - (hide annotations)
Thu Nov 21 01:09:54 2002 UTC (11 years, 5 months ago) by toy
Branch: MAIN
Changes since 1.81: +3 -1 lines
Reinstate the check for properly formed vars list.
1 ram 1.1 ;;; -*- Log: code.log; Package: Lisp -*-
2     ;;;
3     ;;; **********************************************************************
4 ram 1.20 ;;; This code was written as part of the CMU Common Lisp project at
5     ;;; Carnegie Mellon University, and has been placed in the public domain.
6     ;;;
7     (ext:file-comment
8 toy 1.82 "$Header: /tiger/var/lib/cvsroots/cmucl/src/code/macros.lisp,v 1.82 2002/11/21 01:09:54 toy Exp $")
9 ram 1.20 ;;;
10 ram 1.1 ;;; **********************************************************************
11     ;;;
12     ;;; This file contains the macros that are part of the standard
13     ;;; Spice Lisp environment.
14     ;;;
15     ;;; Written by Scott Fahlman and Rob MacLachlan.
16 ram 1.22 ;;; Modified by Bill Chiles to adhere to the wall.
17 ram 1.1 ;;;
18 wlott 1.10 (in-package "LISP")
19 wlott 1.13 (export '(defvar defparameter defconstant when unless setf
20 ram 1.39 defsetf psetf shiftf rotatef push pushnew pop
21 ram 1.1 incf decf remf case typecase with-open-file
22     with-open-stream with-input-from-string with-output-to-string
23     locally etypecase ctypecase ecase ccase
24 ram 1.39 get-setf-expansion define-setf-expander
25 ram 1.18 define-modify-macro destructuring-bind nth-value
26 wlott 1.33 otherwise ; Sacred to CASE and related macros.
27 pw 1.67 define-compiler-macro))
28 ram 1.1
29     (in-package "EXTENSIONS")
30     (export '(do-anonymous collect iterate))
31    
32     (in-package "LISP")
33    
34    
35     ;;; Parse-Body -- Public
36     ;;;
37     ;;; Parse out declarations and doc strings, *not* expanding macros.
38     ;;; Eventually the environment arg should be flushed, since macros can't expand
39     ;;; into declarations anymore.
40     ;;;
41     (defun parse-body (body environment &optional (doc-string-allowed t))
42     "This function is to parse the declarations and doc-string out of the body of
43     a defun-like form. Body is the list of stuff which is to be parsed.
44     Environment is ignored. If Doc-String-Allowed is true, then a doc string
45     will be parsed out of the body and returned. If it is false then a string
46     will terminate the search for declarations. Three values are returned: the
47     tail of Body after the declarations and doc strings, a list of declare forms,
48     and the doc-string, or NIL if none."
49     (declare (ignore environment))
50     (let ((decls ())
51     (doc nil))
52     (do ((tail body (cdr tail)))
53     ((endp tail)
54     (values tail (nreverse decls) doc))
55     (let ((form (car tail)))
56     (cond ((and (stringp form) (cdr tail))
57     (if doc-string-allowed
58 pw 1.70 (setq doc form
59     ;; Only one doc string is allowed.
60     doc-string-allowed nil)
61 ram 1.1 (return (values tail (nreverse decls) doc))))
62     ((not (and (consp form) (symbolp (car form))))
63     (return (values tail (nreverse decls) doc)))
64     ((eq (car form) 'declare)
65     (push form decls))
66     (t
67     (return (values tail (nreverse decls) doc))))))))
68    
69    
70     ;;;; DEFMACRO:
71    
72     ;;; Defmacro -- Public
73     ;;;
74     ;;; Parse the definition and make an expander function. The actual
75     ;;; definition is done by %defmacro which we expand into.
76     ;;;
77     (defmacro defmacro (name lambda-list &body body)
78 wlott 1.13 (let ((whole (gensym "WHOLE-"))
79     (environment (gensym "ENV-")))
80 ram 1.1 (multiple-value-bind
81     (body local-decs doc)
82 wlott 1.13 (parse-defmacro lambda-list whole body name 'defmacro
83     :environment environment)
84 ram 1.1 (let ((def `(lambda (,whole ,environment)
85     ,@local-decs
86     (block ,name
87     ,body))))
88 pw 1.69 `(progn
89     (eval-when (:compile-toplevel)
90     (c::do-macro-compile-time ',name #',def))
91     (eval-when (:load-toplevel :execute)
92     (c::%defmacro ',name #',def ',lambda-list ,doc)))))))
93 ram 1.1
94    
95     ;;; %Defmacro, %%Defmacro -- Internal
96     ;;;
97     ;;; Defmacro expands into %Defmacro which is a function that is treated
98     ;;; magically the compiler. After the compiler has gotten the information it
99     ;;; wants out of macro definition, it compiles a call to %%Defmacro which
100     ;;; happens at load time. We have a %Defmacro function which just calls
101     ;;; %%Defmacro in order to keep the interpreter happy.
102     ;;;
103     ;;; Eventually %%Defmacro should deal with clearing old compiler information
104     ;;; for the functional value.
105     ;;;
106     (defun c::%defmacro (name definition lambda-list doc)
107 wlott 1.13 (assert (eval:interpreted-function-p definition))
108     (setf (eval:interpreted-function-name definition)
109     (format nil "DEFMACRO ~S" name))
110     (setf (eval:interpreted-function-arglist definition) lambda-list)
111 ram 1.1 (c::%%defmacro name definition doc))
112     ;;;
113     (defun c::%%defmacro (name definition doc)
114     (clear-info function where-from name)
115 wlott 1.10 (setf (macro-function name) definition)
116 ram 1.1 (setf (documentation name 'function) doc)
117     name)
118 wlott 1.33
119    
120    
121     ;;;; DEFINE-COMPILER-MACRO
122    
123     (defmacro define-compiler-macro (name lambda-list &body body)
124     "Define a compiler-macro for NAME."
125     (let ((whole (gensym "WHOLE-"))
126     (environment (gensym "ENV-")))
127     (multiple-value-bind
128     (body local-decs doc)
129     (parse-defmacro lambda-list whole body name 'define-compiler-macro
130     :environment environment)
131     (let ((def `(lambda (,whole ,environment)
132     ,@local-decs
133     (block ,name
134     ,body))))
135 pw 1.69 `(progn
136     (eval-when (:compile-toplevel)
137     (c::do-compiler-macro-compile-time ',name #',def))
138     (eval-when (:load-toplevel :execute)
139     (c::%define-compiler-macro ',name #',def ',lambda-list ,doc)))))))
140    
141 wlott 1.33
142     (defun c::%define-compiler-macro (name definition lambda-list doc)
143     (assert (eval:interpreted-function-p definition))
144     (setf (eval:interpreted-function-name definition)
145     (let ((*print-case* :upcase))
146     (format nil "DEFINE-COMPILER-MACRO ~S" name)))
147     (setf (eval:interpreted-function-arglist definition) lambda-list)
148     (c::%%define-compiler-macro name definition doc))
149     ;;;
150     (defun c::%%define-compiler-macro (name definition doc)
151     (setf (compiler-macro-function name) definition)
152     (setf (documentation name 'compiler-macro) doc)
153     name)
154    
155 ram 1.1
156 dtc 1.63
157     ;;;; DEFINE-SYMBOL-MACRO
158    
159     ;;; define-symbol-macro -- Public
160     ;;;
161     (defmacro define-symbol-macro (name expansion)
162     `(eval-when (compile load eval)
163     (%define-symbol-macro ',name ',expansion)))
164     ;;;
165     (defun %define-symbol-macro (name expansion)
166     (unless (symbolp name)
167     (error 'simple-type-error :datum name :expected-type 'symbol
168     :format-control "Symbol macro name is not a symbol: ~S."
169     :format-arguments (list name)))
170     (ecase (info variable kind name)
171     ((:macro :global nil)
172     (setf (info variable kind name) :macro)
173     (setf (info variable macro-expansion name) expansion))
174     (:special
175     (error 'simple-program-error
176     :format-control "Symbol macro name already declared special: ~S."
177     :format-arguments (list name)))
178     (:constant
179     (error 'simple-program-error
180     :format-control "Symbol macro name already declared constant: ~S."
181     :format-arguments (list name))))
182     name)
183    
184 ram 1.1
185     ;;; DEFTYPE is a lot like DEFMACRO.
186    
187     (defmacro deftype (name arglist &body body)
188     "Syntax like DEFMACRO, but defines a new type."
189     (unless (symbolp name)
190     (error "~S -- Type name not a symbol." name))
191    
192 wlott 1.13 (let ((whole (gensym "WHOLE-")))
193 ram 1.1 (multiple-value-bind (body local-decs doc)
194 wlott 1.13 (parse-defmacro arglist whole body name 'deftype
195     :default-default ''*)
196     `(eval-when (compile load eval)
197     (%deftype ',name
198     #'(lambda (,whole)
199     ,@local-decs
200     (block ,name ,body))
201     ,@(when doc `(,doc)))))))
202 ram 1.7 ;;;
203     (defun %deftype (name expander &optional doc)
204 ram 1.12 (ecase (info type kind name)
205     (:primitive
206 ram 1.36 (when *type-system-initialized*
207     (error "Illegal to redefine standard type: ~S." name)))
208     (:instance
209     (warn "Redefining class ~S to be a DEFTYPE." name)
210 ram 1.43 (undefine-structure (layout-info (class-layout (find-class name))))
211     (setf (class-cell-class (find-class-cell name)) nil)
212 ram 1.36 (setf (info type compiler-layout name) nil)
213     (setf (info type kind name) :defined))
214     (:defined)
215     ((nil)
216     (setf (info type kind name) :defined)))
217    
218 wlott 1.13 (setf (info type expander name) expander)
219 ram 1.7 (when doc
220     (setf (documentation name 'type) doc))
221 wlott 1.10 ;; ### Bootstrap hack -- we need to define types before %note-type-defined
222     ;; is defined.
223 ram 1.12 (when (fboundp 'c::%note-type-defined)
224 wlott 1.10 (c::%note-type-defined name))
225 ram 1.7 name)
226    
227 ram 1.1
228 ram 1.39 ;;; And so is DEFINE-SETF-EXPANDER.
229 ram 1.1
230     (defparameter defsetf-error-string "Setf expander for ~S cannot be called with ~S args.")
231    
232 ram 1.39 (defmacro define-setf-expander (access-fn lambda-list &body body)
233 pw 1.68 "Syntax like DEFMACRO, but creates a Setf-Expansion generator. The body
234 ram 1.1 must be a form that returns the five magical values."
235     (unless (symbolp access-fn)
236 dtc 1.58 (error "~S -- Access-function name not a symbol in DEFINE-SETF-EXPANDER."
237 ram 1.1 access-fn))
238    
239 wlott 1.13 (let ((whole (gensym "WHOLE-"))
240     (environment (gensym "ENV-")))
241 ram 1.1 (multiple-value-bind (body local-decs doc)
242     (parse-defmacro lambda-list whole body access-fn
243 dtc 1.58 'define-setf-expander
244 wlott 1.13 :environment environment)
245 ram 1.1 `(eval-when (load compile eval)
246 ram 1.22 (%define-setf-macro
247     ',access-fn
248     #'(lambda (,whole ,environment)
249     ,@local-decs
250     (block ,access-fn ,body))
251     nil
252     ',doc)))))
253 ram 1.1
254 ram 1.39 (defmacro define-setf-method (&rest stuff)
255     "Obsolete, use define-setf-expander."
256     `(define-setf-expander ,@stuff))
257 ram 1.22
258 ram 1.39
259 ram 1.22 ;;; %DEFINE-SETF-MACRO -- Internal
260     ;;;
261     ;;; Do stuff for defining a setf macro.
262     ;;;
263     (defun %define-setf-macro (name expander inverse doc)
264     (cond ((not (fboundp `(setf ,name))))
265     ((info function accessor-for name)
266     (warn "Defining setf macro for destruct slot accessor; redefining as ~
267     a normal function:~% ~S"
268     name)
269     (c::define-function-name name))
270     ((not (eq (symbol-package name) (symbol-package 'aref)))
271     (warn "Defining setf macro for ~S, but ~S is fbound."
272     name `(setf ,name))))
273     (when (or inverse (info setf inverse name))
274     (setf (info setf inverse name) inverse))
275     (when (or expander (info setf expander name))
276     (setf (info setf expander name) expander))
277     (when doc
278     (setf (documentation name 'setf) doc))
279     name)
280    
281 wlott 1.13
282     ;;;; Destructuring-bind
283 ram 1.1
284 wlott 1.13 (defmacro destructuring-bind (lambda-list arg-list &rest body)
285     "Bind the variables in LAMBDA-LIST to the contents of ARG-LIST."
286     (let* ((arg-list-name (gensym "ARG-LIST-")))
287     (multiple-value-bind
288 wlott 1.14 (body local-decls)
289 wlott 1.17 (parse-defmacro lambda-list arg-list-name body nil 'destructuring-bind
290 wlott 1.13 :annonymousp t :doc-string-allowed nil)
291     `(let ((,arg-list-name ,arg-list))
292 wlott 1.14 ,@local-decls
293 wlott 1.13 ,body))))
294    
295 ram 1.1
296     ;;;; Defun, Defvar, Defparameter, Defconstant:
297    
298     ;;; Defun -- Public
299     ;;;
300     ;;; Very similar to Defmacro, but simpler. We don't have to parse the
301     ;;; lambda-list.
302     ;;;
303 wlott 1.13 (defmacro defun (&whole source name lambda-list &body (body decls doc))
304 ram 1.1 (let ((def `(lambda ,lambda-list
305     ,@decls
306     (block ,(if (and (consp name) (eq (car name) 'setf))
307     (cadr name)
308     name)
309     ,@body))))
310     `(c::%defun ',name #',def ,doc ',source)))
311    
312    
313     ;;; %Defun, %%Defun -- Internal
314     ;;;
315     ;;; Similar to %Defmacro, ...
316     ;;;
317     (defun c::%%defun (name def doc &optional inline-expansion)
318     (setf (fdefinition name) def)
319     (when doc
320     (if (and (consp name) (eq (first name) 'setf))
321     (setf (documentation (second name) 'setf) doc)
322     (setf (documentation name 'function) doc)))
323 ram 1.12 (c::define-function-name name)
324     (when (eq (info function where-from name) :assumed)
325     (setf (info function where-from name) :defined)
326     (when (info function assumed-type name)
327     (setf (info function assumed-type name) nil)))
328 ram 1.1 (when (or inline-expansion
329     (info function inline-expansion name))
330     (setf (info function inline-expansion name) inline-expansion))
331     name)
332     ;;;
333     (defun c::%defun (name def doc source)
334     (declare (ignore source))
335 ram 1.3 (assert (eval:interpreted-function-p def))
336     (setf (eval:interpreted-function-name def) name)
337 ram 1.1 (c::%%defun name def doc))
338    
339    
340     ;;; DEFCONSTANT -- Public
341     ;;;
342     (defmacro defconstant (var val &optional doc)
343     "For defining global constants at top level. The DEFCONSTANT says that the
344     value is constant and may be compiled into code. If the variable already has
345     a value, and this is not equal to the init, an error is signalled. The third
346     argument is an optional documentation string for the variable."
347 moore 1.72 `(progn
348     (eval-when (:compile-toplevel)
349     (c::do-defconstant-compile-time ',var ,val ',doc))
350     (eval-when (:load-toplevel :execute)
351     (c::%%defconstant ',var ,val ',doc))))
352 ram 1.1
353     ;;; %Defconstant, %%Defconstant -- Internal
354     ;;;
355     ;;; Like the other %mumbles except that we currently actually do something
356     ;;; interesting at load time, namely checking if the constant is being
357     ;;; redefined.
358     ;;;
359     (defun c::%defconstant (name value doc)
360     (c::%%defconstant name value doc))
361     ;;;
362     (defun c::%%defconstant (name value doc)
363     (when doc
364     (setf (documentation name 'variable) doc))
365     (when (boundp name)
366     (unless (equalp (symbol-value name) value)
367     (cerror "Go ahead and change the value."
368     "Constant ~S being redefined." name)))
369     (setf (symbol-value name) value)
370     (setf (info variable kind name) :constant)
371     (clear-info variable constant-value name)
372     name)
373    
374    
375     (defmacro defvar (var &optional (val nil valp) (doc nil docp))
376     "For defining global variables at top level. Declares the variable
377     SPECIAL and, optionally, initializes it. If the variable already has a
378     value, the old value is not clobbered. The third argument is an optional
379     documentation string for the variable."
380     `(progn
381 pw 1.66 (declaim (special ,var))
382 ram 1.1 ,@(when valp
383     `((unless (boundp ',var)
384     (setq ,var ,val))))
385     ,@(when docp
386     `((setf (documentation ',var 'variable) ',doc)))
387     ',var))
388    
389     (defmacro defparameter (var val &optional (doc nil docp))
390     "Defines a parameter that is not normally changed by the program,
391     but that may be changed without causing an error. Declares the
392     variable special and sets its value to VAL. The third argument is
393     an optional documentation string for the parameter."
394     `(progn
395 pw 1.66 (declaim (special ,var))
396 ram 1.1 (setq ,var ,val)
397     ,@(when docp
398     `((setf (documentation ',var 'variable) ',doc)))
399     ',var))
400    
401    
402     ;;;; ASSORTED CONTROL STRUCTURES
403    
404    
405     (defmacro when (test &body forms)
406     "First arg is a predicate. If it is non-null, the rest of the forms are
407     evaluated as a PROGN."
408     `(cond (,test nil ,@forms)))
409    
410     (defmacro unless (test &rest forms)
411     "First arg is a predicate. If it is null, the rest of the forms are
412     evaluated as a PROGN."
413     `(cond ((not ,test) nil ,@forms)))
414    
415    
416     (defmacro return (&optional (value nil))
417     `(return-from nil ,value))
418    
419     (defmacro prog (varlist &body (body decls))
420     `(block nil
421     (let ,varlist
422     ,@decls
423     (tagbody ,@body))))
424    
425     (defmacro prog* (varlist &body (body decls))
426     `(block nil
427     (let* ,varlist
428     ,@decls
429     (tagbody ,@body))))
430    
431    
432     ;;; Prog1, Prog2 -- Public
433     ;;;
434     ;;; These just turn into a Let.
435     ;;;
436     (defmacro prog1 (result &rest body)
437     (let ((n-result (gensym)))
438     `(let ((,n-result ,result))
439     ,@body
440     ,n-result)))
441     ;;;
442     (defmacro prog2 (form1 result &rest body)
443     `(prog1 (progn ,form1 ,result) ,@body))
444    
445    
446     ;;; And, Or -- Public
447     ;;;
448     ;;; AND and OR are defined in terms of IF.
449     ;;;
450     (defmacro and (&rest forms)
451     (cond ((endp forms) t)
452     ((endp (rest forms)) (first forms))
453     (t
454     `(if ,(first forms)
455     (and ,@(rest forms))
456     nil))))
457     ;;;
458     (defmacro or (&rest forms)
459     (cond ((endp forms) nil)
460     ((endp (rest forms)) (first forms))
461     (t
462     (let ((n-result (gensym)))
463     `(let ((,n-result ,(first forms)))
464     (if ,n-result
465     ,n-result
466     (or ,@(rest forms))))))))
467    
468    
469     ;;; Cond -- Public
470     ;;;
471     ;;; COND also turns into IF.
472     ;;;
473     (defmacro cond (&rest clauses)
474     (if (endp clauses)
475     nil
476     (let ((clause (first clauses)))
477     (when (atom clause)
478     (error "Cond clause is not a list: ~S." clause))
479     (let ((test (first clause))
480     (forms (rest clause)))
481     (if (endp forms)
482     (let ((n-result (gensym)))
483     `(let ((,n-result ,test))
484     (if ,n-result
485     ,n-result
486     (cond ,@(rest clauses)))))
487     `(if ,test
488     (progn ,@forms)
489     (cond ,@(rest clauses))))))))
490    
491    
492     ;;;; Multiple value macros:
493    
494     ;;; Multiple-Value-XXX -- Public
495     ;;;
496     ;;; All the multiple-value receiving forms are defined in terms of
497     ;;; Multiple-Value-Call.
498     ;;;
499 toy 1.81 (defmacro multiple-value-setq (vars value-form)
500 toy 1.82 (unless (and (listp vars) (every #'symbolp vars))
501     (error "Varlist is not a list of symbols: ~S." varlist))
502 toy 1.81 `(values (setf (values ,@vars) ,value-form)))
503    
504 ram 1.1 ;;;
505     (defmacro multiple-value-bind (varlist value-form &body body)
506     (unless (and (listp varlist) (every #'symbolp varlist))
507     (error "Varlist is not a list of symbols: ~S." varlist))
508     (if (= (length varlist) 1)
509     `(let ((,(car varlist) ,value-form))
510     ,@body)
511     (let ((ignore (gensym)))
512     `(multiple-value-call #'(lambda (&optional ,@varlist &rest ,ignore)
513     (declare (ignore ,ignore))
514     ,@body)
515     ,value-form))))
516     ;;;
517     (defmacro multiple-value-list (value-form)
518     `(multiple-value-call #'list ,value-form))
519 ram 1.18
520    
521     (defmacro nth-value (n form)
522     "Evaluates FORM and returns the Nth value (zero based). This involves no
523     consing when N is a trivial constant integer."
524     (if (integerp n)
525     (let ((dummy-list nil)
526 wlott 1.30 (keeper (gensym "KEEPER-")))
527 ram 1.26 ;; We build DUMMY-LIST, a list of variables to bind to useless
528     ;; values, then we explicitly IGNORE those bindings and return
529 wlott 1.30 ;; KEEPER, the only thing we're really interested in right now.
530 ram 1.26 (dotimes (i n)
531 wlott 1.30 (push (gensym "IGNORE-") dummy-list))
532     `(multiple-value-bind (,@dummy-list ,keeper)
533 ram 1.26 ,form
534     (declare (ignore ,@dummy-list))
535 wlott 1.30 ,keeper))
536     (once-only ((n n))
537 dtc 1.62 `(case (the (values fixnum &rest t) ,n)
538 wlott 1.30 (0 (nth-value 0 ,form))
539     (1 (nth-value 1 ,form))
540     (2 (nth-value 2 ,form))
541 dtc 1.62 (T (nth (the (values fixnum &rest t) ,n)
542     (multiple-value-list ,form)))))))
543 ram 1.1
544    
545     ;;;; SETF and friends.
546    
547     ;;; Note: The expansions for SETF and friends sometimes create needless
548     ;;; LET-bindings of argument values. The compiler will remove most of
549     ;;; these spurious bindings, so SETF doesn't worry too much about creating
550     ;;; them.
551    
552     ;;; The inverse for a generalized-variable reference function is stored in
553     ;;; one of two ways:
554     ;;;
555 ram 1.38 ;;; A SETF inverse property corresponds to the short form of DEFSETF. It is
556 ram 1.1 ;;; the name of a function takes the same args as the reference form, plus a
557     ;;; new-value arg at the end.
558     ;;;
559 ram 1.38 ;;; A SETF method expander is created by the long form of DEFSETF or
560 dtc 1.58 ;;; by DEFINE-SETF-EXPANDER. It is a function that is called on the reference
561 ram 1.1 ;;; form and that produces five values: a list of temporary variables, a list
562     ;;; of value forms, a list of the single store-value form, a storing function,
563     ;;; and an accessing function.
564    
565 ram 1.39 (defun get-setf-expansion (form &optional environment)
566 ram 1.1 "Returns five values needed by the SETF machinery: a list of temporary
567 wlott 1.29 variables, a list of values with which to fill them, a list of temporaries
568     for the new values, the setting function, and the accessing function."
569 ram 1.1 (let (temp)
570     (cond ((symbolp form)
571 wlott 1.32 (multiple-value-bind
572     (expansion expanded)
573     (macroexpand-1 form environment)
574     (if expanded
575 ram 1.39 (get-setf-expansion expansion environment)
576 wlott 1.32 (let ((new-var (gensym)))
577     (values nil nil (list new-var)
578     `(setq ,form ,new-var) form)))))
579 ram 1.25 ;;
580     ;; Local functions inhibit global setf methods...
581 ram 1.22 ((and environment
582 ram 1.36 (let ((name (car form)))
583     (dolist (x (c::lexenv-functions environment) nil)
584     (when (and (eq (car x) name)
585     (not (c::defined-function-p (cdr x))))
586     (return t)))))
587 ram 1.38 (expand-or-get-setf-inverse form environment))
588 ram 1.1 ((setq temp (info setf inverse (car form)))
589 wlott 1.10 (get-setf-method-inverse form `(,temp) nil))
590 ram 1.1 ((setq temp (info setf expander (car form)))
591     (funcall temp form environment))
592     (t
593 ram 1.38 (expand-or-get-setf-inverse form environment)))))
594    
595 ram 1.39 (defun get-setf-method-multiple-value (form &optional env)
596     "Obsolete: use GET-SETF-EXPANSION."
597     (get-setf-expansion form env))
598 ram 1.38
599     ;;;
600     ;;; If a macro, expand one level and try again. If not, go for the
601     ;;; SETF function.
602     (defun expand-or-get-setf-inverse (form environment)
603     (multiple-value-bind
604     (expansion expanded)
605     (macroexpand-1 form environment)
606     (if expanded
607 ram 1.39 (get-setf-expansion expansion environment)
608 ram 1.38 (get-setf-method-inverse form `(funcall #'(setf ,(car form)))
609     t))))
610    
611 ram 1.1
612 wlott 1.10 (defun get-setf-method-inverse (form inverse setf-function)
613 ram 1.1 (let ((new-var (gensym))
614     (vars nil)
615     (vals nil))
616     (dolist (x (cdr form))
617     (push (gensym) vars)
618     (push x vals))
619     (setq vals (nreverse vals))
620     (values vars vals (list new-var)
621 wlott 1.10 (if setf-function
622     `(,@inverse ,new-var ,@vars)
623     `(,@inverse ,@vars ,new-var))
624 ram 1.1 `(,(car form) ,@vars))))
625    
626    
627 wlott 1.29 (defun get-setf-method (form &optional environment)
628 ram 1.39 "Obsolete: use GET-SETF-EXPANSION and handle multiple store values."
629 wlott 1.29 (multiple-value-bind
630     (temps value-forms store-vars store-form access-form)
631 ram 1.39 (get-setf-expansion form environment)
632 wlott 1.29 (when (cdr store-vars)
633     (error "GET-SETF-METHOD used for a form with multiple store ~
634     variables:~% ~S" form))
635     (values temps value-forms store-vars store-form access-form)))
636 ram 1.1
637 wlott 1.29
638 wlott 1.16 (defun defsetter (fn rest)
639 wlott 1.14 (let ((arglist (car rest))
640     (arglist-var (gensym "ARGS-"))
641     (new-var (car (cadr rest))))
642     (multiple-value-bind
643     (body local-decs doc)
644 wlott 1.16 (parse-defmacro arglist arglist-var (cddr rest) fn 'defsetf)
645 ram 1.1 (values
646 wlott 1.14 `(lambda (,arglist-var ,new-var)
647     ,@local-decs
648 wlott 1.16 ,body)
649 wlott 1.15 doc))))
650 ram 1.1
651    
652 wlott 1.16 (defmacro defsetf (access-fn &rest rest)
653 ram 1.1 "Associates a SETF update function or macro with the specified access
654     function or macro. The format is complex. See the manual for
655     details."
656     (cond ((not (listp (car rest)))
657     `(eval-when (load compile eval)
658 ram 1.22 (%define-setf-macro ',access-fn nil ',(car rest)
659     ,(when (and (car rest) (stringp (cadr rest)))
660     `',(cadr rest)))))
661 wlott 1.29 ((and (cdr rest) (listp (cadr rest)))
662     (destructuring-bind
663     (lambda-list (&rest store-variables) &body body)
664     rest
665     (let ((arglist-var (gensym "ARGS-"))
666     (access-form-var (gensym "ACCESS-FORM-"))
667     (env-var (gensym "ENVIRONMENT-")))
668     (multiple-value-bind
669     (body local-decs doc)
670     (parse-defmacro `(,lambda-list ,@store-variables)
671     arglist-var body access-fn 'defsetf
672     :annonymousp t)
673     `(eval-when (load compile eval)
674     (%define-setf-macro
675     ',access-fn
676     #'(lambda (,access-form-var ,env-var)
677     (declare (ignore ,env-var))
678     (%defsetf ,access-form-var ,(length store-variables)
679     #'(lambda (,arglist-var)
680     ,@local-decs
681     (block ,access-fn
682     ,body))))
683     nil
684     ',doc))))))
685     (t
686     (error "Ill-formed DEFSETF for ~S." access-fn))))
687 ram 1.1
688 wlott 1.29 (defun %defsetf (orig-access-form num-store-vars expander)
689 wlott 1.34 (collect ((subforms) (subform-vars) (subform-exprs) (store-vars))
690     (dolist (subform (cdr orig-access-form))
691     (if (constantp subform)
692     (subforms subform)
693     (let ((var (gensym)))
694     (subforms var)
695     (subform-vars var)
696     (subform-exprs subform))))
697     (dotimes (i num-store-vars)
698     (store-vars (gensym)))
699     (values (subform-vars)
700     (subform-exprs)
701     (store-vars)
702     (funcall expander (cons (subforms) (store-vars)))
703     `(,(car orig-access-form) ,@(subforms)))))
704 wlott 1.29
705    
706 ram 1.23 ;;; SETF -- Public
707     ;;;
708     ;;; Except for atoms, we always call GET-SETF-METHOD, since it has some
709     ;;; non-trivial semantics. But when there is a setf inverse, and G-S-M uses
710     ;;; it, then we return a call to the inverse, rather than returning a hairy let
711     ;;; form. This is probably important mainly as a convenince in allowing the
712     ;;; use of setf inverses without the full interpreter.
713     ;;;
714 ram 1.1 (defmacro setf (&rest args &environment env)
715     "Takes pairs of arguments like SETQ. The first is a place and the second
716     is the value that is supposed to go into that place. Returns the last
717     value. The place argument may be any of the access forms for which SETF
718     knows a corresponding setting form."
719 ram 1.22 (let ((nargs (length args)))
720     (cond
721     ((= nargs 2)
722 ram 1.23 (let ((place (first args))
723     (value-form (second args)))
724     (if (atom place)
725     `(setq ,place ,value-form)
726     (multiple-value-bind (dummies vals newval setter getter)
727 ram 1.39 (get-setf-expansion place env)
728 ram 1.23 (declare (ignore getter))
729     (let ((inverse (info setf inverse (car place))))
730     (if (and inverse (eq inverse (car setter)))
731     `(,inverse ,@(cdr place) ,value-form)
732 wlott 1.29 `(let* (,@(mapcar #'list dummies vals))
733     (multiple-value-bind ,newval ,value-form
734     ,setter))))))))
735 ram 1.22 ((oddp nargs)
736     (error "Odd number of args to SETF."))
737     (t
738     (do ((a args (cddr a)) (l nil))
739     ((null a) `(progn ,@(nreverse l)))
740     (setq l (cons (list 'setf (car a) (cadr a)) l)))))))
741 ram 1.1
742     (defmacro psetf (&rest args &environment env)
743     "This is to SETF as PSETQ is to SETQ. Args are alternating place
744     expressions and values to go into those places. All of the subforms and
745     values are determined, left to right, and only then are the locations
746     updated. Returns NIL."
747 wlott 1.29 (collect ((let*-bindings) (mv-bindings) (setters))
748     (do ((a args (cddr a)))
749     ((endp a))
750     (if (endp (cdr a))
751     (error "Odd number of args to PSETF."))
752     (multiple-value-bind
753     (dummies vals newval setter getter)
754 ram 1.39 (get-setf-expansion (car a) env)
755 wlott 1.29 (declare (ignore getter))
756     (let*-bindings (mapcar #'list dummies vals))
757     (mv-bindings (list newval (cadr a)))
758     (setters setter)))
759     (labels ((thunk (let*-bindings mv-bindings)
760     (if let*-bindings
761     `(let* ,(car let*-bindings)
762     (multiple-value-bind ,@(car mv-bindings)
763     ,(thunk (cdr let*-bindings) (cdr mv-bindings))))
764     `(progn ,@(setters) nil))))
765     (thunk (let*-bindings) (mv-bindings)))))
766 ram 1.1
767 toy 1.73 (defmacro shiftf (&rest args &environment env)
768 ram 1.1 "One or more SETF-style place expressions, followed by a single
769 wlott 1.29 value expression. Evaluates all of the expressions in turn, then
770     assigns the value of each expression to the place on its left,
771     returning the value of the leftmost."
772 toy 1.73 (when args
773     (collect ((let*-bindings) (mv-bindings) (setters) (getters))
774     ;; The last arg isn't necessarily a place, so we have to handle
775     ;; that separately.
776     (dolist (arg (butlast args))
777     (multiple-value-bind
778     (temps subforms store-vars setter getter)
779     (get-setf-expansion arg env)
780     (loop
781     for temp in temps
782     for subform in subforms
783     do (let*-bindings `(,temp ,subform)))
784     (mv-bindings store-vars)
785     (setters setter)
786     (getters getter)))
787     ;; Handle the last arg specially here. Just put something to
788     ;; force the setter so the setter for the previous var gets set,
789     ;; and the getter is just the last arg itself.
790     (setters nil)
791     (getters (car (last args)))
792    
793     (labels ((thunk (mv-bindings getters)
794     (if mv-bindings
795     `((multiple-value-bind
796     ,(car mv-bindings)
797     ,(car getters)
798     ,@(thunk (cdr mv-bindings) (cdr getters))))
799     `(,@(butlast (setters))))))
800     `(let* ,(let*-bindings)
801     (multiple-value-bind ,(car (mv-bindings))
802     ,(car (getters))
803     ,@(thunk (mv-bindings) (cdr (getters)))
804     (values ,@(car (mv-bindings)))))))))
805 ram 1.1
806     (defmacro rotatef (&rest args &environment env)
807     "Takes any number of SETF-style place expressions. Evaluates all of the
808 wlott 1.29 expressions in turn, then assigns to each place the value of the form to
809     its right. The rightmost form gets the value of the leftmost.
810     Returns NIL."
811     (when args
812     (collect ((let*-bindings) (mv-bindings) (setters) (getters))
813     (dolist (arg args)
814     (multiple-value-bind
815     (temps subforms store-vars setter getter)
816 ram 1.39 (get-setf-expansion arg env)
817 wlott 1.29 (loop
818     for temp in temps
819     for subform in subforms
820     do (let*-bindings `(,temp ,subform)))
821     (mv-bindings store-vars)
822     (setters setter)
823     (getters getter)))
824     (setters nil)
825     (getters (car (getters)))
826     (labels ((thunk (mv-bindings getters)
827     (if mv-bindings
828     `((multiple-value-bind
829     ,(car mv-bindings)
830     ,(car getters)
831     ,@(thunk (cdr mv-bindings) (cdr getters))))
832     (setters))))
833     `(let* ,(let*-bindings)
834     ,@(thunk (mv-bindings) (cdr (getters))))))))
835 ram 1.1
836    
837     (defmacro define-modify-macro (name lambda-list function &optional doc-string)
838     "Creates a new read-modify-write macro like PUSH or INCF."
839     (let ((other-args nil)
840     (rest-arg nil)
841     (env (gensym))
842     (reference (gensym)))
843    
844     ;; Parse out the variable names and rest arg from the lambda list.
845     (do ((ll lambda-list (cdr ll))
846     (arg nil))
847     ((null ll))
848     (setq arg (car ll))
849     (cond ((eq arg '&optional))
850     ((eq arg '&rest)
851     (if (symbolp (cadr ll))
852     (setq rest-arg (cadr ll))
853     (error "Non-symbol &rest arg in definition of ~S." name))
854     (if (null (cddr ll))
855     (return nil)
856     (error "Illegal stuff after &rest arg in Define-Modify-Macro.")))
857     ((memq arg '(&key &allow-other-keys &aux))
858     (error "~S not allowed in Define-Modify-Macro lambda list." arg))
859     ((symbolp arg)
860     (push arg other-args))
861     ((and (listp arg) (symbolp (car arg)))
862     (push (car arg) other-args))
863     (t (error "Illegal stuff in lambda list of Define-Modify-Macro."))))
864     (setq other-args (nreverse other-args))
865     `(defmacro ,name (,reference ,@lambda-list &environment ,env)
866     ,doc-string
867     (multiple-value-bind (dummies vals newval setter getter)
868 wlott 1.13 (get-setf-method ,reference ,env)
869 ram 1.1 (do ((d dummies (cdr d))
870     (v vals (cdr v))
871     (let-list nil (cons (list (car d) (car v)) let-list)))
872     ((null d)
873     (push
874     (list (car newval)
875     ,(if rest-arg
876     `(list* ',function getter ,@other-args ,rest-arg)
877     `(list ',function getter ,@other-args)))
878     let-list)
879     `(let* ,(nreverse let-list)
880     ,setter)))))))
881    
882     (defmacro push (obj place &environment env)
883     "Takes an object and a location holding a list. Conses the object onto
884 pw 1.56 the list, returning the modified list. OBJ is evaluated before PLACE."
885 toy 1.78
886     ;; This special case for place being a symbol isn't strictly needed.
887     ;; It's so we can do push (and pushnew) with a kernel.core.
888 toy 1.77 (if (and (symbolp place)
889     (eq place (macroexpand place env)))
890     `(setq ,place (cons ,obj ,place))
891     (multiple-value-bind (dummies vals newval setter getter)
892     (get-setf-expansion place env)
893 toy 1.79 (cond
894     ((cdr newval)
895     ;; Handle multiple values
896     (let ((g (mapcar #'(lambda (x)
897     (declare (ignore x))
898     (gensym))
899     (rest obj))))
900     `(multiple-value-bind ,g
901     ,obj
902     (let* (,@(mapcar #'list dummies vals))
903     (multiple-value-bind ,newval
904     (values ,@(mapcar #'(lambda (a b)
905     (list 'cons a b))
906     g (rest getter)))
907     ,setter)))))
908     (t
909     ;; A single value
910     (let ((g (gensym)))
911     `(let* ((,g ,obj)
912     ,@(mapcar #'list dummies vals)
913     (,@newval (cons ,g ,getter)))
914     ,setter)))))))
915 ram 1.1
916     (defmacro pushnew (obj place &rest keys &environment env)
917     "Takes an object and a location holding a list. If the object is already
918     in the list, does nothing. Else, conses the object onto the list. Returns
919     NIL. If there is a :TEST keyword, this is used for the comparison."
920 toy 1.77 (if (and (symbolp place)
921     (eq place (macroexpand place env)))
922     `(setq ,place (adjoin ,obj ,place ,@keys))
923     (multiple-value-bind (vars vals stores setter getter)
924 toy 1.78 (get-setf-expansion place env)
925 toy 1.79 (cond
926     ((cdr stores)
927     ;; Multiple values
928     (let ((g (mapcar #'(lambda (x)
929     (declare (ignore x))
930     (gensym))
931     (rest obj))))
932     `(multiple-value-bind ,g
933     ,obj
934     (let* (,@(mapcar #'list vars vals))
935     (multiple-value-bind ,stores
936     (values ,@(mapcar #'(lambda (a b)
937     `(adjoin ,a ,b ,@keys))
938     g (rest getter)))
939     ,setter)))))
940     (t
941     ;; Single value
942     (let ((g (gensym)))
943     `(let* ((,g ,obj)
944     ,@(mapcar #'list vars vals)
945     (,@stores (adjoin ,g ,getter ,@keys)))
946     ,setter)))))))
947 ram 1.1
948     (defmacro pop (place &environment env)
949     "The argument is a location holding a list. Pops one item off the front
950     of the list and returns it."
951 toy 1.77 (if (and (symbolp place)
952     (eq place (macroexpand place env)))
953     `(prog1 (car ,place)
954     (setq ,place (cdr ,place)))
955     (multiple-value-bind (dummies vals newval setter getter)
956     (get-setf-method place env)
957     (do* ((d dummies (cdr d))
958     (v vals (cdr v))
959     (let-list nil))
960     ((null d)
961     (push (list (car newval) getter) let-list)
962     `(let* ,(nreverse let-list)
963     (prog1 (car ,(car newval))
964     (setq ,(car newval) (cdr ,(car newval)))
965     ,setter)))
966     (push (list (car d) (car v)) let-list)))))
967 ram 1.1
968    
969     (define-modify-macro incf (&optional (delta 1)) +
970     "The first argument is some location holding a number. This number is
971     incremented by the second argument, DELTA, which defaults to 1.")
972    
973    
974     (define-modify-macro decf (&optional (delta 1)) -
975     "The first argument is some location holding a number. This number is
976     decremented by the second argument, DELTA, which defaults to 1.")
977    
978    
979     (defmacro remf (place indicator &environment env)
980     "Place may be any place expression acceptable to SETF, and is expected
981     to hold a property list or (). This list is destructively altered to
982     remove the property specified by the indicator. Returns T if such a
983     property was present, NIL if not."
984     (multiple-value-bind (dummies vals newval setter getter)
985 wlott 1.13 (get-setf-method place env)
986 ram 1.1 (do* ((d dummies (cdr d))
987     (v vals (cdr v))
988     (let-list nil)
989     (ind-temp (gensym))
990     (local1 (gensym))
991     (local2 (gensym)))
992     ((null d)
993     (push (list (car newval) getter) let-list)
994     (push (list ind-temp indicator) let-list)
995     `(let* ,(nreverse let-list)
996     (do ((,local1 ,(car newval) (cddr ,local1))
997     (,local2 nil ,local1))
998     ((atom ,local1) nil)
999     (cond ((atom (cdr ,local1))
1000     (error "Odd-length property list in REMF."))
1001     ((eq (car ,local1) ,ind-temp)
1002     (cond (,local2
1003     (rplacd (cdr ,local2) (cddr ,local1))
1004     (return t))
1005     (t (setq ,(car newval) (cddr ,(car newval)))
1006     ,setter
1007     (return t))))))))
1008     (push (list (car d) (car v)) let-list))))
1009    
1010    
1011     ;;; The built-in DEFSETFs.
1012    
1013     (defsetf car %rplaca)
1014     (defsetf cdr %rplacd)
1015     (defsetf caar (x) (v) `(%rplaca (car ,x) ,v))
1016     (defsetf cadr (x) (v) `(%rplaca (cdr ,x) ,v))
1017     (defsetf cdar (x) (v) `(%rplacd (car ,x) ,v))
1018     (defsetf cddr (x) (v) `(%rplacd (cdr ,x) ,v))
1019     (defsetf caaar (x) (v) `(%rplaca (caar ,x) ,v))
1020     (defsetf cadar (x) (v) `(%rplaca (cdar ,x) ,v))
1021     (defsetf cdaar (x) (v) `(%rplacd (caar ,x) ,v))
1022     (defsetf cddar (x) (v) `(%rplacd (cdar ,x) ,v))
1023     (defsetf caadr (x) (v) `(%rplaca (cadr ,x) ,v))
1024     (defsetf caddr (x) (v) `(%rplaca (cddr ,x) ,v))
1025     (defsetf cdadr (x) (v) `(%rplacd (cadr ,x) ,v))
1026     (defsetf cdddr (x) (v) `(%rplacd (cddr ,x) ,v))
1027     (defsetf caaaar (x) (v) `(%rplaca (caaar ,x) ,v))
1028     (defsetf cadaar (x) (v) `(%rplaca (cdaar ,x) ,v))
1029     (defsetf cdaaar (x) (v) `(%rplacd (caaar ,x) ,v))
1030     (defsetf cddaar (x) (v) `(%rplacd (cdaar ,x) ,v))
1031     (defsetf caadar (x) (v) `(%rplaca (cadar ,x) ,v))
1032     (defsetf caddar (x) (v) `(%rplaca (cddar ,x) ,v))
1033     (defsetf cdadar (x) (v) `(%rplacd (cadar ,x) ,v))
1034     (defsetf cdddar (x) (v) `(%rplacd (cddar ,x) ,v))
1035     (defsetf caaadr (x) (v) `(%rplaca (caadr ,x) ,v))
1036     (defsetf cadadr (x) (v) `(%rplaca (cdadr ,x) ,v))
1037     (defsetf cdaadr (x) (v) `(%rplacd (caadr ,x) ,v))
1038     (defsetf cddadr (x) (v) `(%rplacd (cdadr ,x) ,v))
1039     (defsetf caaddr (x) (v) `(%rplaca (caddr ,x) ,v))
1040     (defsetf cadddr (x) (v) `(%rplaca (cdddr ,x) ,v))
1041     (defsetf cdaddr (x) (v) `(%rplacd (caddr ,x) ,v))
1042     (defsetf cddddr (x) (v) `(%rplacd (cdddr ,x) ,v))
1043    
1044     (defsetf first %rplaca)
1045     (defsetf second (x) (v) `(%rplaca (cdr ,x) ,v))
1046     (defsetf third (x) (v) `(%rplaca (cddr ,x) ,v))
1047     (defsetf fourth (x) (v) `(%rplaca (cdddr ,x) ,v))
1048     (defsetf fifth (x) (v) `(%rplaca (cddddr ,x) ,v))
1049     (defsetf sixth (x) (v) `(%rplaca (cdr (cddddr ,x)) ,v))
1050     (defsetf seventh (x) (v) `(%rplaca (cddr (cddddr ,x)) ,v))
1051     (defsetf eighth (x) (v) `(%rplaca (cdddr (cddddr ,x)) ,v))
1052     (defsetf ninth (x) (v) `(%rplaca (cddddr (cddddr ,x)) ,v))
1053     (defsetf tenth (x) (v) `(%rplaca (cdr (cddddr (cddddr ,x))) ,v))
1054     (defsetf rest %rplacd)
1055    
1056     (defsetf elt %setelt)
1057     (defsetf aref %aset)
1058 wlott 1.10 (defsetf row-major-aref %set-row-major-aref)
1059 ram 1.1 (defsetf svref %svset)
1060     (defsetf char %charset)
1061     (defsetf bit %bitset)
1062     (defsetf schar %scharset)
1063     (defsetf sbit %sbitset)
1064 wlott 1.10 (defsetf %array-dimension %set-array-dimension)
1065     (defsetf %raw-bits %set-raw-bits)
1066 ram 1.1 (defsetf symbol-value set)
1067 wlott 1.28 (defsetf symbol-function fset)
1068     (defsetf symbol-plist %set-symbol-plist)
1069 ram 1.1 (defsetf nth %setnth)
1070     (defsetf fill-pointer %set-fill-pointer)
1071     (defsetf search-list %set-search-list)
1072    
1073 wlott 1.10 (defsetf sap-ref-8 %set-sap-ref-8)
1074 wlott 1.27 (defsetf signed-sap-ref-8 %set-signed-sap-ref-8)
1075 wlott 1.10 (defsetf sap-ref-16 %set-sap-ref-16)
1076 wlott 1.27 (defsetf signed-sap-ref-16 %set-signed-sap-ref-16)
1077 wlott 1.10 (defsetf sap-ref-32 %set-sap-ref-32)
1078 wlott 1.27 (defsetf signed-sap-ref-32 %set-signed-sap-ref-32)
1079 hallgren 1.44 (defsetf sap-ref-64 %set-sap-ref-64)
1080     (defsetf signed-sap-ref-64 %set-signed-sap-ref-64)
1081 wlott 1.10 (defsetf sap-ref-sap %set-sap-ref-sap)
1082     (defsetf sap-ref-single %set-sap-ref-single)
1083     (defsetf sap-ref-double %set-sap-ref-double)
1084 dtc 1.54 #+long-float
1085     (defsetf sap-ref-long %set-sap-ref-long)
1086 ram 1.1
1087 dtc 1.58 (define-setf-expander getf (place prop &optional default &environment env)
1088 ram 1.1 (multiple-value-bind (temps values stores set get)
1089 wlott 1.13 (get-setf-method place env)
1090 ram 1.1 (let ((newval (gensym))
1091     (ptemp (gensym))
1092 wlott 1.31 (def-temp (if default (gensym))))
1093     (values `(,@temps ,ptemp ,@(if default `(,def-temp)))
1094     `(,@values ,prop ,@(if default `(,default)))
1095 ram 1.1 `(,newval)
1096 wlott 1.31 `(let ((,(car stores) (%putf ,get ,ptemp ,newval)))
1097     ,set
1098     ,newval)
1099     `(getf ,get ,ptemp ,@(if default `(,def-temp)))))))
1100 ram 1.1
1101 dtc 1.58 (define-setf-expander get (symbol prop &optional default)
1102 ram 1.1 (let ((symbol-temp (gensym))
1103     (prop-temp (gensym))
1104     (def-temp (gensym))
1105     (newval (gensym)))
1106     (values `(,symbol-temp ,prop-temp ,@(if default `(,def-temp)))
1107     `(,symbol ,prop ,@(if default `(,default)))
1108     (list newval)
1109     `(%put ,symbol-temp ,prop-temp ,newval)
1110     `(get ,symbol-temp ,prop-temp ,@(if default `(,def-temp))))))
1111    
1112 dtc 1.58 (define-setf-expander gethash (key hashtable &optional default)
1113 ram 1.1 (let ((key-temp (gensym))
1114     (hashtable-temp (gensym))
1115     (default-temp (gensym))
1116     (new-value-temp (gensym)))
1117     (values
1118     `(,key-temp ,hashtable-temp ,@(if default `(,default-temp)))
1119     `(,key ,hashtable ,@(if default `(,default)))
1120     `(,new-value-temp)
1121     `(%puthash ,key-temp ,hashtable-temp ,new-value-temp)
1122     `(gethash ,key-temp ,hashtable-temp ,@(if default `(,default-temp))))))
1123    
1124     (defsetf subseq (sequence start &optional (end nil)) (v)
1125     `(progn (replace ,sequence ,v :start1 ,start :end1 ,end)
1126     ,v))
1127    
1128    
1129 ram 1.36 ;;; Evil hack invented by the gnomes of Vassar Street (though not as evil as
1130     ;;; it used to be.) The function arg must be constant, and is converted to an
1131     ;;; APPLY of ther SETF function, which ought to exist.
1132 ram 1.22 ;;;
1133 dtc 1.58 (define-setf-expander apply (function &rest args)
1134 ram 1.22 (unless (and (listp function)
1135     (= (list-length function) 2)
1136     (eq (first function) 'function)
1137     (symbolp (second function)))
1138     (error "Setf of Apply is only defined for function args like #'symbol."))
1139 ram 1.36 (let ((function (second function))
1140     (new-var (gensym))
1141     (vars nil))
1142     (dolist (x args)
1143     (declare (ignore x))
1144     (push (gensym) vars))
1145     (values vars args (list new-var)
1146     `(apply #'(setf ,function) ,new-var ,@vars)
1147     `(apply #',function ,@vars))))
1148 ram 1.1
1149    
1150 wlott 1.10 ;;; Special-case a BYTE bytespec so that the compiler can recognize it.
1151     ;;;
1152 dtc 1.58 (define-setf-expander ldb (bytespec place &environment env)
1153 ram 1.1 "The first argument is a byte specifier. The second is any place form
1154     acceptable to SETF. Replaces the specified byte of the number in this
1155     place with bits from the low-order end of the new value."
1156     (multiple-value-bind (dummies vals newval setter getter)
1157 wlott 1.13 (get-setf-method place env)
1158 wlott 1.10 (if (and (consp bytespec) (eq (car bytespec) 'byte))
1159     (let ((n-size (gensym))
1160     (n-pos (gensym))
1161     (n-new (gensym)))
1162     (values (list* n-size n-pos dummies)
1163     (list* (second bytespec) (third bytespec) vals)
1164     (list n-new)
1165     `(let ((,(car newval) (dpb ,n-new (byte ,n-size ,n-pos)
1166     ,getter)))
1167     ,setter
1168     ,n-new)
1169     `(ldb (byte ,n-size ,n-pos) ,getter)))
1170     (let ((btemp (gensym))
1171     (gnuval (gensym)))
1172     (values (cons btemp dummies)
1173     (cons bytespec vals)
1174     (list gnuval)
1175     `(let ((,(car newval) (dpb ,gnuval ,btemp ,getter)))
1176     ,setter
1177     ,gnuval)
1178     `(ldb ,btemp ,getter))))))
1179 ram 1.1
1180    
1181 dtc 1.58 (define-setf-expander mask-field (bytespec place &environment env)
1182 ram 1.1 "The first argument is a byte specifier. The second is any place form
1183     acceptable to SETF. Replaces the specified byte of the number in this place
1184     with bits from the corresponding position in the new value."
1185     (multiple-value-bind (dummies vals newval setter getter)
1186 wlott 1.13 (get-setf-method place env)
1187 ram 1.1 (let ((btemp (gensym))
1188     (gnuval (gensym)))
1189     (values (cons btemp dummies)
1190     (cons bytespec vals)
1191     (list gnuval)
1192     `(let ((,(car newval) (deposit-field ,gnuval ,btemp ,getter)))
1193     ,setter
1194     ,gnuval)
1195     `(mask-field ,btemp ,getter)))))
1196    
1197    
1198 dtc 1.58 (define-setf-expander the (type place &environment env)
1199 ram 1.1 (multiple-value-bind (dummies vals newval setter getter)
1200 wlott 1.13 (get-setf-method place env)
1201 ram 1.1 (values dummies
1202     vals
1203     newval
1204     (subst `(the ,type ,(car newval)) (car newval) setter)
1205     `(the ,type ,getter))))
1206 dtc 1.58
1207     (define-setf-expander values (&rest places &environment env)
1208     (collect ((setters) (getters))
1209     (let ((all-dummies '())
1210     (all-vals '())
1211     (newvals '()))
1212     (dolist (place places)
1213     (multiple-value-bind (dummies vals newval setter getter)
1214     (get-setf-expansion place env)
1215     (setf all-dummies (append all-dummies dummies))
1216     (setf all-vals (append all-vals vals))
1217     (setf newvals (append newvals newval))
1218     (setters setter)
1219     (getters getter)))
1220     (values all-dummies all-vals newvals
1221     `(values ,@(setters)) `(values ,@(getters))))))
1222 ram 1.1
1223    
1224     ;;;; CASE, TYPECASE, & Friends.
1225    
1226     (eval-when (compile load eval)
1227    
1228     ;;; CASE-BODY returns code for all the standard "case" macros. Name is the
1229     ;;; macro name, and keyform is the thing to case on. Multi-p indicates whether
1230     ;;; a branch may fire off a list of keys; otherwise, a key that is a list is
1231     ;;; interpreted in some way as a single key. When multi-p, test is applied to
1232     ;;; the value of keyform and each key for a given branch; otherwise, test is
1233     ;;; applied to the value of keyform and the entire first element, instead of
1234     ;;; each part, of the case branch. When errorp, no t or otherwise branch is
1235     ;;; permitted, and an ERROR form is generated. When proceedp, it is an error
1236     ;;; to omit errorp, and the ERROR form generated is executed within a
1237     ;;; RESTART-CASE allowing keyform to be set and retested.
1238     ;;;
1239 toy 1.74 ;;; If ALLOW-OTHERWISE, then we allow T and OTHERWISE clauses and also
1240     ;;; generate an ERROR form. (This is for CCASE and ECASE which allow
1241     ;;; using T and OTHERWISE as regular keys.)
1242     ;;;
1243     (defun case-body (name keyform cases multi-p test errorp proceedp &optional allow-otherwise)
1244 ram 1.1 (let ((keyform-value (gensym))
1245     (clauses ())
1246     (keys ()))
1247     (dolist (case cases)
1248     (cond ((atom case)
1249     (error "~S -- Bad clause in ~S." case name))
1250 toy 1.74 ((and (not allow-otherwise)
1251     (memq (car case) '(t otherwise)))
1252 ram 1.1 (if errorp
1253     (error "No default clause allowed in ~S: ~S" name case)
1254     (push `(t nil ,@(rest case)) clauses)))
1255     ((and multi-p (listp (first case)))
1256     (setf keys (append (first case) keys))
1257     (push `((or ,@(mapcar #'(lambda (key)
1258     `(,test ,keyform-value ',key))
1259     (first case)))
1260     nil ,@(rest case))
1261     clauses))
1262     (t
1263 toy 1.74 (when (and allow-otherwise
1264     (memq (car case) '(t otherwise)))
1265     (warn "Bad style to use T or OTHERWISE in ECASE or CCASE"))
1266 ram 1.1 (push (first case) keys)
1267     (push `((,test ,keyform-value
1268     ',(first case)) nil ,@(rest case)) clauses))))
1269     (case-body-aux name keyform keyform-value clauses keys errorp proceedp
1270 toy 1.74 allow-otherwise
1271 ram 1.1 `(,(if multi-p 'member 'or) ,@keys))))
1272    
1273     ;;; CASE-BODY-AUX provides the expansion once CASE-BODY has groveled all the
1274     ;;; cases. Note: it is not necessary that the resulting code signal
1275     ;;; case-failure conditions, but that's what KMP's prototype code did. We call
1276     ;;; CASE-BODY-ERROR, because of how closures are compiled. RESTART-CASE has
1277     ;;; forms with closures that the compiler causes to be generated at the top of
1278     ;;; any function using the case macros, regardless of whether they are needed.
1279     ;;;
1280     (defun case-body-aux (name keyform keyform-value clauses keys
1281 toy 1.74 errorp proceedp allow-otherwise expected-type)
1282 ram 1.1 (if proceedp
1283     (let ((block (gensym))
1284     (again (gensym)))
1285     `(let ((,keyform-value ,keyform))
1286     (block ,block
1287     (tagbody
1288     ,again
1289     (return-from
1290     ,block
1291     (cond ,@(nreverse clauses)
1292     (t
1293     (setf ,keyform-value
1294     (setf ,keyform
1295     (case-body-error
1296     ',name ',keyform ,keyform-value
1297     ',expected-type ',keys)))
1298     (go ,again))))))))
1299     `(let ((,keyform-value ,keyform))
1300 pw 1.49 ,keyform-value ; prevent warnings when key not used eg (case key (t))
1301 ram 1.1 (cond
1302     ,@(nreverse clauses)
1303 toy 1.74 ,@(if (or errorp allow-otherwise)
1304 ram 1.1 `((t (error 'conditions::case-failure
1305     :name ',name
1306     :datum ,keyform-value
1307     :expected-type ',expected-type
1308     :possibilities ',keys))))))))
1309    
1310     ); eval-when
1311    
1312     (defun case-body-error (name keyform keyform-value expected-type keys)
1313     (restart-case
1314     (error 'conditions::case-failure
1315     :name name
1316     :datum keyform-value
1317     :expected-type expected-type
1318     :possibilities keys)
1319     (store-value (value)
1320     :report (lambda (stream)
1321     (format stream "Supply a new value for ~S." keyform))
1322     :interactive read-evaluated-form
1323     value)))
1324    
1325    
1326     (defmacro case (keyform &body cases)
1327     "CASE Keyform {({(Key*) | Key} Form*)}*
1328     Evaluates the Forms in the first clause with a Key EQL to the value of
1329     Keyform. If a singleton key is T then the clause is a default clause."
1330     (case-body 'case keyform cases t 'eql nil nil))
1331    
1332     (defmacro ccase (keyform &body cases)
1333     "CCASE Keyform {({(Key*) | Key} Form*)}*
1334     Evaluates the Forms in the first clause with a Key EQL to the value of
1335     Keyform. If none of the keys matches then a correctable error is
1336     signalled."
1337 toy 1.74 (case-body 'ccase keyform cases t 'eql nil t t))
1338 ram 1.1
1339     (defmacro ecase (keyform &body cases)
1340     "ECASE Keyform {({(Key*) | Key} Form*)}*
1341     Evaluates the Forms in the first clause with a Key EQL to the value of
1342     Keyform. If none of the keys matches then an error is signalled."
1343 toy 1.74 (case-body 'ecase keyform cases t 'eql nil nil t))
1344 ram 1.1
1345     (defmacro typecase (keyform &body cases)
1346     "TYPECASE Keyform {(Type Form*)}*
1347     Evaluates the Forms in the first clause for which TYPEP of Keyform and Type
1348     is true."
1349     (case-body 'typecase keyform cases nil 'typep nil nil))
1350    
1351     (defmacro ctypecase (keyform &body cases)
1352     "CTYPECASE Keyform {(Type Form*)}*
1353     Evaluates the Forms in the first clause for which TYPEP of Keyform and Type
1354     is true. If no form is satisfied then a correctable error is signalled."
1355 toy 1.75 (case-body 'ctypecase keyform cases nil 'typep nil t t))
1356 ram 1.1
1357     (defmacro etypecase (keyform &body cases)
1358     "ETYPECASE Keyform {(Type Form*)}*
1359     Evaluates the Forms in the first clause for which TYPEP of Keyform and Type
1360     is true. If no form is satisfied then an error is signalled."
1361 toy 1.75 (case-body 'etypecase keyform cases nil 'typep nil nil t))
1362 ram 1.1
1363    
1364     ;;;; ASSERT and CHECK-TYPE.
1365    
1366     ;;; ASSERT is written this way, to call ASSERT-ERROR, because of how closures
1367     ;;; are compiled. RESTART-CASE has forms with closures that the compiler
1368     ;;; causes to be generated at the top of any function using ASSERT, regardless
1369     ;;; of whether they are needed.
1370     ;;;
1371     (defmacro assert (test-form &optional places datum &rest arguments)
1372     "Signals an error if the value of test-form is nil. Continuing from this
1373     error using the CONTINUE restart will allow the user to alter the value of
1374     some locations known to SETF, starting over with test-form. Returns nil."
1375     `(loop
1376     (when ,test-form (return nil))
1377     (assert-error ',test-form ',places ,datum ,@arguments)
1378     ,@(mapcar #'(lambda (place)
1379     `(setf ,place (assert-prompt ',place ,place)))
1380     places)))
1381    
1382 ram 1.42 (defun assert-error (assertion places datum &rest arguments)
1383 ram 1.41 (let ((cond (if datum
1384     (conditions::coerce-to-condition
1385     datum arguments
1386     'simple-error 'error)
1387     (make-condition 'simple-error
1388     :format-control "The assertion ~S failed."
1389     :format-arguments (list assertion)))))
1390     (restart-case (error cond)
1391 ram 1.1 (continue ()
1392     :report (lambda (stream) (assert-report places stream))
1393 ram 1.41 nil))))
1394 ram 1.1
1395    
1396     (defun assert-report (names stream)
1397     (format stream "Retry assertion")
1398     (if names
1399     (format stream " with new value~P for ~{~S~^, ~}."
1400     (length names) names)
1401     (format stream ".")))
1402    
1403     (defun assert-prompt (name value)
1404     (cond ((y-or-n-p "The old value of ~S is ~S.~
1405     ~%Do you want to supply a new value? "
1406     name value)
1407     (format *query-io* "~&Type a form to be evaluated:~%")
1408     (flet ((read-it () (eval (read *query-io*))))
1409     (if (symbolp name) ;help user debug lexical variables
1410     (progv (list name) (list value) (read-it))
1411     (read-it))))
1412     (t value)))
1413    
1414    
1415     ;;; CHECK-TYPE is written this way, to call CHECK-TYPE-ERROR, because of how
1416     ;;; closures are compiled. RESTART-CASE has forms with closures that the
1417     ;;; compiler causes to be generated at the top of any function using
1418     ;;; CHECK-TYPE, regardless of whether they are needed. Because it would be
1419     ;;; nice if this were cheap to use, and some things can't afford this excessive
1420     ;;; consing (e.g., READ-CHAR), we bend backwards a little.
1421     ;;;
1422    
1423     (defmacro check-type (place type &optional type-string)
1424     "Signals an error of type type-error if the contents of place are not of the
1425     specified type. If an error is signaled, this can only return if
1426     STORE-VALUE is invoked. It will store into place and start over."
1427     (let ((place-value (gensym)))
1428     `(loop
1429     (let ((,place-value ,place))
1430     (when (typep ,place-value ',type) (return nil))
1431     (setf ,place
1432     (check-type-error ',place ,place-value ',type ,type-string))))))
1433    
1434     (defun check-type-error (place place-value type type-string)
1435 ram 1.41 (let ((cond (if type-string
1436     (make-condition 'simple-type-error
1437     :datum place :expected-type type
1438     :format-control
1439     "The value of ~S is ~S, which is not ~A."
1440     :format-arguments
1441     (list place place-value type-string))
1442     (make-condition 'simple-type-error
1443     :datum place :expected-type type
1444     :format-control
1445     "The value of ~S is ~S, which is not of type ~S."
1446     :format-arguments
1447     (list place place-value type)))))
1448     (restart-case (error cond)
1449     (store-value (value)
1450     :report (lambda (stream)
1451     (format stream "Supply a new value of ~S."
1452     place))
1453     :interactive read-evaluated-form
1454     value))))
1455 ram 1.1
1456     ;;; READ-EVALUATED-FORM is used as the interactive method for restart cases
1457     ;;; setup by the Common Lisp "casing" (e.g., CCASE and CTYPECASE) macros
1458     ;;; and by CHECK-TYPE.
1459     ;;;
1460     (defun read-evaluated-form ()
1461     (format *query-io* "~&Type a form to be evaluated:~%")
1462     (list (eval (read *query-io*))))
1463    
1464    
1465     ;;;; With-XXX
1466     (defmacro with-open-file ((var &rest open-args) &body (forms decls))
1467 ram 1.5 "Bindspec is of the form (Stream File-Name . Options). The file whose
1468     name is File-Name is opened using the Options and bound to the variable
1469 pw 1.47 Stream. If the call to open is unsuccessful, the forms are not
1470     evaluated. The Forms are executed, and when they
1471     terminate, normally or otherwise, the file is closed."
1472 ram 1.1 (let ((abortp (gensym)))
1473     `(let ((,var (open ,@open-args))
1474     (,abortp t))
1475     ,@decls
1476 pw 1.47 (unwind-protect
1477     (multiple-value-prog1
1478     (progn ,@forms)
1479     (setq ,abortp nil))
1480     (when ,var
1481 ram 1.1 (close ,var :abort ,abortp))))))
1482    
1483 ram 1.5
1484 ram 1.1 (defmacro with-open-stream ((var stream) &body (forms decls))
1485     "The form stream should evaluate to a stream. VAR is bound
1486     to the stream and the forms are evaluated as an implicit
1487     progn. The stream is closed upon exit."
1488     (let ((abortp (gensym)))
1489     `(let ((,var ,stream)
1490     (,abortp t))
1491     ,@decls
1492     (unwind-protect
1493     (multiple-value-prog1
1494     (progn ,@forms)
1495     (setq ,abortp nil))
1496     (when ,var
1497     (close ,var :abort ,abortp))))))
1498    
1499    
1500     (defmacro with-input-from-string ((var string &key index start end) &body (forms decls))
1501     "Binds the Var to an input stream that returns characters from String and
1502     executes the body. See manual for details."
1503 pw 1.52 ;; The once-only inhibits compiler note for unreachable code when 'end' is true.
1504     (once-only ((string string))
1505     `(let ((,var
1506     ,(cond ((null end)
1507     `(make-string-input-stream ,string ,(or start 0)))
1508     ((symbolp end)
1509     `(if ,end
1510     (make-string-input-stream ,string ,(or start 0) ,end)
1511     (make-string-input-stream ,string ,(or start 0))))
1512     (t
1513     `(make-string-input-stream ,string ,(or start 0) ,end)))))
1514     ,@decls
1515     (unwind-protect
1516     (progn ,@forms)
1517     (close ,var)
1518     ,@(if index `((setf ,index (string-input-stream-current ,var))))))))
1519 ram 1.1
1520    
1521     (defmacro with-output-to-string ((var &optional string) &body (forms decls))
1522 ram 1.5 "If *string* is specified, it must be a string with a fill pointer;
1523     the output is incrementally appended to the string (as if by use of
1524     VECTOR-PUSH-EXTEND)."
1525 ram 1.1 (if string
1526     `(let ((,var (make-fill-pointer-output-stream ,string)))
1527     ,@decls
1528     (unwind-protect
1529     (progn ,@forms)
1530     (close ,var)))
1531     `(let ((,var (make-string-output-stream)))
1532     ,@decls
1533     (unwind-protect
1534     (progn ,@forms)
1535     (close ,var))
1536     (get-output-stream-string ,var))))
1537    
1538    
1539     ;;;; Iteration macros:
1540    
1541     (defmacro dotimes ((var count &optional (result nil)) &body body)
1542     (cond ((numberp count)
1543     `(do ((,var 0 (1+ ,var)))
1544     ((>= ,var ,count) ,result)
1545 toy 1.71 (declare (type (integer 0 ,count) ,var))
1546 ram 1.1 ,@body))
1547     (t (let ((v1 (gensym)))
1548     `(do ((,var 0 (1+ ,var)) (,v1 ,count))
1549     ((>= ,var ,v1) ,result)
1550 ram 1.8 (declare (type unsigned-byte ,var))
1551 ram 1.1 ,@body)))))
1552    
1553    
1554     ;;; We repeatedly bind the var instead of setting it so that we never give the
1555     ;;; var a random value such as NIL (which might conflict with a declaration).
1556 ram 1.35 ;;; If there is a result form, we introduce a gratitous binding of the variable
1557     ;;; to NIL w/o the declarations, then evaluate the result form in that
1558     ;;; environment. We spuriously reference the gratuitous variable, since we
1559     ;;; don't want to use IGNORABLE on what might be a special var.
1560 ram 1.1 ;;;
1561     (defmacro dolist ((var list &optional (result nil)) &body body)
1562 toy 1.80 (multiple-value-bind (forms decls)
1563     (parse-body body nil nil)
1564     (let ((n-list (gensym)))
1565     `(do* ((,n-list ,list (cdr ,n-list)))
1566     ((endp ,n-list)
1567     ,@(if result
1568     `((let ((,var nil))
1569     ,var
1570     ,result))
1571     '(nil)))
1572     (let ((,var (car ,n-list)))
1573     ,@decls
1574     (tagbody
1575     ,@forms))))))
1576 ram 1.1
1577    
1578     (defmacro do (varlist endlist &body (body decls))
1579     "DO ({(Var [Init] [Step])}*) (Test Exit-Form*) Declaration* Form*
1580     Iteration construct. Each Var is initialized in parallel to the value of the
1581     specified Init form. On subsequent iterations, the Vars are assigned the
1582     value of the Step form (if any) in paralell. The Test is evaluated before
1583 dtc 1.53 each evaluation of the body Forms. When the Test is true, the Exit-Forms
1584 ram 1.1 are evaluated as a PROGN, with the result being the value of the DO. A block
1585     named NIL is established around the entire expansion, allowing RETURN to be
1586     used as an laternate exit mechanism."
1587    
1588     (do-do-body varlist endlist body decls 'let 'psetq 'do nil))
1589    
1590    
1591     (defmacro do* (varlist endlist &body (body decls))
1592     "DO* ({(Var [Init] [Step])}*) (Test Exit-Form*) Declaration* Form*
1593     Iteration construct. Each Var is initialized sequentially (like LET*) to the
1594     value of the specified Init form. On subsequent iterations, the Vars are
1595     sequentially assigned the value of the Step form (if any). The Test is
1596     evaluated before each evaluation of the body Forms. When the Test is true,
1597 dtc 1.53 the Exit-Forms are evaluated as a PROGN, with the result being the value
1598 ram 1.1 of the DO. A block named NIL is established around the entire expansion,
1599     allowing RETURN to be used as an laternate exit mechanism."
1600     (do-do-body varlist endlist body decls 'let* 'setq 'do* nil))
1601    
1602    
1603     ;;;; Miscellaneous macros:
1604    
1605     (defmacro psetq (&rest pairs)
1606     (do ((lets nil)
1607     (setqs nil)
1608     (pairs pairs (cddr pairs)))
1609     ((atom (cdr pairs))
1610 dtc 1.59 `(let ,(nreverse lets) (setq ,@(nreverse setqs)) nil))
1611 ram 1.1 (let ((gen (gensym)))
1612     (push `(,gen ,(cadr pairs)) lets)
1613     (push (car pairs) setqs)
1614     (push gen setqs))))
1615 pw 1.48
1616     ;;; LAMBDA -- from the ANSI spec.
1617     ;;;
1618     (defmacro lambda (&whole form &rest bvl-decls-and-body)
1619     (declare (ignore bvl-decls-and-body))
1620     `#',form)
1621    
1622 ram 1.1
1623    
1624     ;;;; With-Compilation-Unit:
1625    
1626     ;;; True if we are within a With-Compilation-Unit form, which normally causes
1627     ;;; nested uses to be NOOPS.
1628     ;;;
1629     (defvar *in-compilation-unit* nil)
1630    
1631     ;;; Count of the number of compilation units dynamically enclosed by the
1632     ;;; current active WITH-COMPILATION-UNIT that were unwound out of.
1633     ;;;
1634     (defvar *aborted-compilation-units*)
1635    
1636 ram 1.21 (declaim (special c::*context-declarations*))
1637    
1638    
1639     ;;; EVALUATE-DECLARATION-CONTEXT -- Internal
1640     ;;;
1641     ;;; Recursively descend the context form, returning true if this subpart
1642     ;;; matches the specified context.
1643     ;;;
1644     (defun evaluate-declaration-context (context name parent)
1645 ram 1.24 (let* ((base (if (and (consp name) (consp (cdr name)))
1646     (cadr name)
1647     name))
1648     (package (and (symbolp base) (symbol-package base))))
1649 ram 1.21 (if (atom context)
1650 ram 1.24 (multiple-value-bind (ignore how)
1651     (if package
1652     (find-symbol (symbol-name base) package)
1653     (values nil nil))
1654     (declare (ignore ignore))
1655     (case context
1656     (:internal (eq how :internal))
1657     (:external (eq how :external))
1658     (:uninterned (and (symbolp base) (not package)))
1659     (:anonymous (not name))
1660     (:macro (eq parent 'defmacro))
1661     (:function (member parent '(defun labels flet function)))
1662     (:global (member parent '(defun defmacro function)))
1663     (:local (member parent '(labels flet)))
1664     (t
1665     (error "Unknown declaration context: ~S." context))))
1666 ram 1.21 (case (first context)
1667     (:or
1668     (loop for x in (rest context)
1669     thereis (evaluate-declaration-context x name parent)))
1670     (:and
1671     (loop for x in (rest context)
1672     always (evaluate-declaration-context x name parent)))
1673     (:not
1674     (evaluate-declaration-context (second context) name parent))
1675     (:member
1676     (member name (rest context) :test #'equal))
1677     (:match
1678     (let ((name (concatenate 'string "$" (string base) "$")))
1679     (loop for x in (rest context)
1680     thereis (search (string x) name))))
1681 ram 1.24 (:package
1682     (and package
1683     (loop for x in (rest context)
1684     thereis (eq (find-package (string x)) package))))
1685 ram 1.21 (t
1686     (error "Unknown declaration context: ~S." context))))))
1687    
1688    
1689     ;;; PROCESS-CONTEXT-DECLARATIONS -- Internal
1690     ;;;
1691     ;;; Given a list of context declaration specs, return a new value for
1692     ;;; C::*CONTEXT-DECLARATIONS*.
1693     ;;;
1694     (defun process-context-declarations (decls)
1695     (append
1696     (mapcar
1697     #'(lambda (decl)
1698     (unless (>= (length decl) 2)
1699     (error "Context declaration spec should have context and at ~
1700     least one DECLARE form:~% ~S" decl))
1701     #'(lambda (name parent)
1702     (when (evaluate-declaration-context (first decl) name parent)
1703     (rest decl))))
1704     decls)
1705     c::*context-declarations*))
1706    
1707    
1708 ram 1.1 ;;; With-Compilation-Unit -- Public
1709     ;;;
1710     (defmacro with-compilation-unit (options &body body)
1711 ram 1.21 "WITH-COMPILATION-UNIT ({Key Value}*) Form*
1712     This form affects compilations that take place within its dynamic extent. It
1713     is intended to be wrapped around the compilation of all files in the same
1714     system. These keywords are defined:
1715     :OVERRIDE Boolean-Form
1716     One of the effects of this form is to delay undefined warnings
1717     until the end of the form, instead of giving them at the end of each
1718     compilation. If OVERRIDE is NIL (the default), then the outermost
1719     WITH-COMPILATION-UNIT form grabs the undefined warnings. Specifying
1720     OVERRIDE true causes that form to grab any enclosed warnings, even if
1721     it is enclosed by another WITH-COMPILATION-UNIT.
1722     :OPTIMIZE Decl-Form
1723     Decl-Form should evaluate to an OPTIMIZE declaration specifier. This
1724     declaration changes the `global' policy for compilations within the
1725     body.
1726     :OPTIMIZE-INTERFACE Decl-Form
1727     Like OPTIMIZE, except that it specifies the value of the CMU extension
1728     OPTIMIZE-INTERFACE policy (which controls argument type and syntax
1729     checking.)
1730     :CONTEXT-DECLARATIONS List-of-Context-Decls-Form
1731     This is a CMU extension which allows compilation to be controlled
1732     by pattern matching on the context in which a definition appears. The
1733     argument should evaluate to a list of lists of the form:
1734     (Context-Spec Declare-Form+)
1735     In the indicated context, the specified declare forms are inserted at
1736     the head of each definition. The declare forms for all contexts that
1737     match are appended together, with earlier declarations getting
1738     predecence over later ones. A simple example:
1739     :context-declarations
1740     '((:external (declare (optimize (safety 2)))))
1741     This will cause all functions that are named by external symbols to be
1742     compiled with SAFETY 2. The full syntax of context specs is:
1743     :INTERNAL, :EXTERNAL
1744     True if the symbols is internal (external) in its home package.
1745     :UNINTERNED
1746     True if the symbol has no home package.
1747     :ANONYMOUS
1748     True if the function doesn't have any interesting name (not
1749     DEFMACRO, DEFUN, LABELS or FLET).
1750     :MACRO, :FUNCTION
1751     :MACRO is a global (DEFMACRO) macro. :FUNCTION is anything else.
1752     :LOCAL, :GLOBAL
1753     :LOCAL is a LABELS or FLET. :GLOBAL is anything else.
1754     (:OR Context-Spec*)
1755     True in any specified context.
1756     (:AND Context-Spec*)
1757     True only when all specs are true.
1758     (:NOT Context-Spec)
1759     True when the spec is false.
1760     (:MEMBER Name*)
1761     True when the name is one of these names (EQUAL test.)
1762     (:MATCH Pattern*)
1763     True when any of the patterns is a substring of the name. The name
1764     is wrapped with $'s, so $FOO matches names beginning with FOO,
1765     etc."
1766     (let ((override nil)
1767     (optimize nil)
1768     (optimize-interface nil)
1769     (context-declarations nil)
1770 ram 1.1 (n-fun (gensym))
1771     (n-abort-p (gensym)))
1772     (when (oddp (length options))
1773     (error "Odd number of key/value pairs: ~S." options))
1774     (do ((opt options (cddr opt)))
1775     ((null opt))
1776     (case (first opt)
1777 ram 1.21 (:override
1778     (setq override (second opt)))
1779     (:optimize
1780     (setq optimize (second opt)))
1781     (:optimize-interface
1782     (setq optimize-interface (second opt)))
1783     (:context-declarations
1784     (setq context-declarations (second opt)))
1785 ram 1.1 (t
1786     (warn "Ignoring unknown option: ~S." (first opt)))))
1787    
1788 ram 1.21 `(flet ((,n-fun ()
1789     (let (,@(when optimize
1790     `((c::*default-cookie*
1791     (c::process-optimize-declaration
1792     ,optimize c::*default-cookie*))))
1793     ,@(when optimize-interface
1794     `((c::*default-interface-cookie*
1795     (c::process-optimize-declaration
1796     ,optimize-interface
1797     c::*default-interface-cookie*))))
1798     ,@(when context-declarations
1799     `((c::*context-declarations*
1800     (process-context-declarations
1801     ,context-declarations)))))
1802     ,@body)))
1803     (if (or ,override (not *in-compilation-unit*))
1804 ram 1.6 (let ((c::*undefined-warnings* nil)
1805 ram 1.1 (c::*compiler-error-count* 0)
1806     (c::*compiler-warning-count* 0)
1807     (c::*compiler-note-count* 0)
1808     (*in-compilation-unit* t)
1809     (*aborted-compilation-units* 0)
1810     (,n-abort-p t))
1811 ram 1.6 (handler-bind ((c::parse-unknown-type
1812     #'(lambda (c)
1813     (c::note-undefined-reference
1814     (c::parse-unknown-type-specifier c)
1815     :type))))
1816     (unwind-protect
1817     (multiple-value-prog1
1818     (,n-fun)
1819     (setq ,n-abort-p nil))
1820     (c::print-summary ,n-abort-p *aborted-compilation-units*))))
1821 ram 1.1 (let ((,n-abort-p t))
1822     (unwind-protect
1823     (multiple-value-prog1
1824     (,n-fun)
1825     (setq ,n-abort-p nil))
1826     (when ,n-abort-p
1827     (incf *aborted-compilation-units*))))))))

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