3 ;;; C type representation implementation
5 ;;; (c) 2009 Straylight/Edgeware
8 ;;;----- Licensing notice ---------------------------------------------------
10 ;;; This file is part of the Sensible Object Design, an object system for C.
12 ;;; SOD is free software; you can redistribute it and/or modify
13 ;;; it under the terms of the GNU General Public License as published by
14 ;;; the Free Software Foundation; either version 2 of the License, or
15 ;;; (at your option) any later version.
17 ;;; SOD is distributed in the hope that it will be useful,
18 ;;; but WITHOUT ANY WARRANTY; without even the implied warranty of
19 ;;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
20 ;;; GNU General Public License for more details.
22 ;;; You should have received a copy of the GNU General Public License
23 ;;; along with SOD; if not, write to the Free Software Foundation,
24 ;;; Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
28 ;;;--------------------------------------------------------------------------
31 (defparameter *c-type-intern-map* (make-hash-table :test #'equal)
32 "Hash table mapping lists describing types to their distinguished
35 (defun intern-c-type (class &rest initargs)
36 "If the CLASS and INITARGS have already been interned, then return the
37 existing object; otherwise make a new one."
38 (let ((list (cons class initargs)))
39 (or (gethash list *c-type-intern-map*)
40 (let ((new (apply #'make-instance class initargs)))
41 (setf (gethash new *c-type-intern-map*) t
42 (gethash list *c-type-intern-map*) new)))))
45 (defun check-type-intern-map ()
46 "Sanity check for the type-intern map."
47 (let ((map (make-hash-table)))
49 ;; Pass 1: check that interned types are consistent with their keys.
50 ;; Remember interned types.
51 (maphash (lambda (k v)
53 (let ((ty (apply #'make-instance k)))
54 (assert (c-type-equal-p ty v)))
55 (setf (gethash v map) t)))
58 ;; Pass 2: check that the interned type indicators are correct.
59 (maphash (lambda (k v)
61 (assert (gethash k *c-type-intern-map*)))
63 (maphash (lambda (k v)
65 (when (typep k 'c-type)
66 (assert (gethash k map))))
67 *c-type-intern-map*)))
69 (defmethod qualify-c-type ((type qualifiable-c-type) qualifiers)
70 (let ((initargs (instance-initargs type)))
71 (remf initargs :qualifiers)
72 (apply (if (gethash type *c-type-intern-map*)
73 #'intern-c-type #'make-instance)
75 :qualifiers (canonify-qualifiers
76 (append qualifiers (c-type-qualifiers type)))
79 ;;;--------------------------------------------------------------------------
84 (export '(simple-c-type c-type-name))
85 (defclass simple-c-type (qualifiable-c-type)
86 ((name :initarg :name :type string :reader c-type-name))
88 "C types with simple forms."))
90 ;; Constructor function and interning.
92 (export 'make-simple-type)
93 (defun make-simple-type (name &optional qualifiers)
94 "Make a distinguished object for the simple type called NAME."
95 (intern-c-type 'simple-c-type
97 :qualifiers (canonify-qualifiers qualifiers)))
99 ;; Comparison protocol.
101 (defmethod c-type-equal-p and
102 ((type-a simple-c-type) (type-b simple-c-type))
103 (string= (c-type-name type-a) (c-type-name type-b)))
105 ;; C syntax output protocol.
107 (defmethod pprint-c-type ((type simple-c-type) stream kernel)
108 (pprint-logical-block (stream nil)
109 (format stream "~{~(~A~) ~@_~}~A"
110 (c-type-qualifiers type)
112 (funcall kernel stream 0 t)))
114 ;; S-expression notation protocol.
116 (defparameter *simple-type-map* (make-hash-table)
117 "Hash table mapping strings of C syntax to symbolic names.")
119 (defmethod print-c-type (stream (type simple-c-type) &optional colon atsign)
120 (declare (ignore colon atsign))
121 (let* ((name (c-type-name type))
122 (symbol (gethash name *simple-type-map*)))
123 (format stream "~:[~S~;~:@<~S~0@*~{ ~_~S~}~:>~]"
124 (c-type-qualifiers type) (or symbol name))))
126 (eval-when (:compile-toplevel :load-toplevel :execute)
127 (defmethod expand-c-type-spec ((spec string))
128 `(make-simple-type ,spec))
129 (defmethod expand-c-type-form ((head string) tail)
130 `(make-simple-type ,head (list ,@tail))))
132 (export 'define-simple-c-type)
133 (defmacro define-simple-c-type (names type &key export)
134 "Define each of NAMES to be a simple type called TYPE."
135 (let ((names (if (listp names) names (list names))))
137 (setf (gethash ,type *simple-type-map*) ',(car names))
138 (defctype ,names ,type :export ,export)
139 (define-c-type-syntax ,(car names) (&rest quals)
140 `(make-simple-type ,',type (list ,@quals))))))
144 (define-simple-c-type void "void" :export t)
146 (define-simple-c-type char "char" :export t)
147 (define-simple-c-type (unsigned-char uchar) "unsigned char" :export t)
148 (define-simple-c-type (signed-char schar) "signed char" :export t)
149 (define-simple-c-type wchar-t "wchar-t" :export t)
151 (define-simple-c-type (int signed signed-int sint) "int" :export t)
152 (define-simple-c-type (unsigned unsigned-int uint) "unsigned" :export t)
154 (define-simple-c-type (short signed-short short-int signed-short-int sshort)
156 (define-simple-c-type (unsigned-short unsigned-short-int ushort)
157 "unsigned short" :export t)
159 (define-simple-c-type (long signed-long long-int signed-long-int slong)
161 (define-simple-c-type (unsigned-long unsigned-long-int ulong)
162 "unsigned long" :export t)
164 (define-simple-c-type (long-long signed-long-long long-long-int
165 signed-long-long-int llong sllong)
166 "long long" :export t)
167 (define-simple-c-type (unsigned-long-long unsigned-long-long-int ullong)
168 "unsigned long long" :export t)
170 (define-simple-c-type float "float" :export t)
171 (define-simple-c-type double "double" :export t)
172 (define-simple-c-type long-double "long double" :export t)
174 (define-simple-c-type bool "_Bool" :export t)
176 (define-simple-c-type float-complex "float _Complex" :export t)
177 (define-simple-c-type double-complex "double _Complex" :export t)
178 (define-simple-c-type long-double-complex "long double _Complex" :export t)
180 (define-simple-c-type float-imaginary "float _Imaginary" :export t)
181 (define-simple-c-type double-imaginary "double _Imaginary" :export t)
182 (define-simple-c-type long-double-imaginary
183 "long double _Imaginary" :export t)
185 (define-simple-c-type va-list "va_list" :export t)
186 (define-simple-c-type size-t "size_t" :export t)
187 (define-simple-c-type ptrdiff-t "ptrdiff_t" :export t)
189 ;;;--------------------------------------------------------------------------
190 ;;; Tagged types (enums, structs and unions).
194 (export '(tagged-c-type c-type-tag))
195 (defclass tagged-c-type (qualifiable-c-type)
196 ((tag :initarg :tag :type string :reader c-type-tag))
198 "C types with tags."))
200 ;; Subclass definitions.
202 (export 'c-tagged-type-kind)
203 (defgeneric c-tagged-type-kind (type)
205 "Return the kind of tagged type that TYPE is, as a keyword."))
207 (export 'kind-c-tagged-type)
208 (defgeneric kind-c-tagged-type (kind)
210 "Given a keyword KIND, return the appropriate class name."))
212 (export 'make-c-tagged-type)
213 (defun make-c-tagged-type (kind tag &optional qualifiers)
214 "Return a tagged type with the given KIND (keyword) and TAG (string)."
215 (intern-c-type (kind-c-tagged-type kind)
217 :qualifiers (canonify-qualifiers qualifiers)))
219 (macrolet ((define-tagged-type (kind what)
220 (let* ((type (symbolicate 'c- kind '-type))
221 (keyword (intern (symbol-name kind) :keyword))
222 (constructor (symbolicate 'make- kind '-type)))
224 (export '(,type ,kind ,constructor))
225 (defclass ,type (tagged-c-type) ()
226 (:documentation ,(format nil "C ~a types." what)))
227 (defmethod c-tagged-type-kind ((type ,type))
229 (defmethod kind-c-tagged-type ((kind (eql ',keyword)))
231 (defun ,constructor (tag &optional qualifiers)
232 (intern-c-type ',type :tag tag
233 :qualifiers (canonify-qualifiers
235 (define-c-type-syntax ,kind (tag &rest quals)
236 ,(format nil "Construct ~A type named TAG" what)
237 `(,',constructor ,tag (list ,@quals)))))))
238 (define-tagged-type enum "enumerated")
239 (define-tagged-type struct "structure")
240 (define-tagged-type union "union"))
242 ;; Comparison protocol.
244 (defmethod c-type-equal-p and ((type-a tagged-c-type) (type-b tagged-c-type))
245 (string= (c-type-tag type-a) (c-type-tag type-b)))
247 ;; C syntax output protocol.
249 (defmethod pprint-c-type ((type tagged-c-type) stream kernel)
250 (pprint-logical-block (stream nil)
251 (format stream "~{~(~A~) ~@_~}~(~A~) ~A"
252 (c-type-qualifiers type)
253 (c-tagged-type-kind type)
255 (funcall kernel stream 0 t)))
257 ;; S-expression notation protocol.
259 (defmethod print-c-type (stream (type tagged-c-type) &optional colon atsign)
260 (declare (ignore colon atsign))
261 (format stream "~:@<~S ~@_~S~{ ~_~S~}~:>"
262 (c-tagged-type-kind type)
264 (c-type-qualifiers type)))
266 ;;;--------------------------------------------------------------------------
271 (export 'c-pointer-type)
272 (defclass c-pointer-type (qualifiable-c-type)
273 ((subtype :initarg :subtype :type c-type :reader c-type-subtype))
274 (:documentation "C pointer types."))
276 ;; Constructor function.
278 (export 'make-pointer-type)
279 (defun make-pointer-type (subtype &optional qualifiers)
280 "Return a (maybe distinguished) pointer type."
281 (let ((canonical (canonify-qualifiers qualifiers)))
282 (funcall (if (gethash subtype *c-type-intern-map*)
283 #'intern-c-type #'make-instance)
286 :qualifiers canonical)))
288 ;; Comparison protocol.
290 (defmethod c-type-equal-p and ((type-a c-pointer-type)
291 (type-b c-pointer-type))
292 (c-type-equal-p (c-type-subtype type-a) (c-type-subtype type-b)))
294 ;; C syntax output protocol.
296 (defmethod pprint-c-type ((type c-pointer-type) stream kernel)
297 (pprint-c-type (c-type-subtype type) stream
298 (lambda (stream prio spacep)
299 (when spacep (c-type-space stream))
300 (maybe-in-parens (stream (> prio 1))
301 (format stream "*~{~(~A~)~^ ~@_~}"
302 (c-type-qualifiers type))
303 (funcall kernel stream 1 (c-type-qualifiers type))))))
305 ;; S-expression notation protocol.
307 (defmethod print-c-type (stream (type c-pointer-type) &optional colon atsign)
308 (declare (ignore colon atsign))
309 (format stream "~:@<* ~@_~/sod:print-c-type/~{ ~_~S~}~:>"
310 (c-type-subtype type)
311 (c-type-qualifiers type)))
313 (export '(* pointer ptr))
314 (define-c-type-syntax * (sub &rest quals)
315 "Return the type of pointer-to-SUB."
316 `(make-pointer-type ,(expand-c-type-spec sub) (list ,@quals)))
317 (c-type-alias * pointer ptr)
321 (export '(string const-string))
322 (defctype string (* char))
323 (defctype const-string (* (char :const)))
325 ;;;--------------------------------------------------------------------------
330 (export '(c-array-type c-array-dimensions))
331 (defclass c-array-type (c-type)
332 ((subtype :initarg :subtype :type c-type :reader c-type-subtype)
333 (dimensions :initarg :dimensions :type list :reader c-array-dimensions))
337 ;; Constructor function.
339 (export 'make-array-type)
340 (defun make-array-type (subtype dimensions)
341 "Return a new array of SUBTYPE with given DIMENSIONS."
342 (make-instance 'c-array-type :subtype subtype
343 :dimensions (or dimensions '(nil))))
345 ;; Comparison protocol.
347 (defmethod c-type-equal-p and ((type-a c-array-type) (type-b c-array-type))
349 ;; Messy. C doesn't have multidimensional arrays, but we fake them for
350 ;; convenience's sake. But it means that we have to arrange for
351 ;; multidimensional arrays to equal vectors of vectors -- and in general
352 ;; for multidimensional arrays of multidimensional arrays to match each
353 ;; other properly, even when their dimensions don't align precisely.
354 (labels ((check (sub-a dim-a sub-b dim-b)
357 (c-type-equal-p sub-a sub-b))
358 ((typep sub-a 'c-array-type)
359 (check (c-type-subtype sub-a)
360 (c-array-dimensions sub-a)
365 (check sub-b dim-b sub-a dim-a))
366 ((equal (car dim-a) (car dim-b))
367 (check sub-a (cdr dim-a) sub-b (cdr dim-b)))
370 (check (c-type-subtype type-a) (c-array-dimensions type-a)
371 (c-type-subtype type-b) (c-array-dimensions type-b))))
373 ;; C syntax output protocol.
375 (defmethod pprint-c-type ((type c-array-type) stream kernel)
376 (pprint-c-type (c-type-subtype type) stream
377 (lambda (stream prio spacep)
378 (maybe-in-parens (stream (> prio 2))
379 (funcall kernel stream 2 spacep)
380 (format stream "~@<~{[~@[~A~]]~^~_~}~:>"
381 (c-array-dimensions type))))))
383 ;; S-expression notation protocol.
385 (defmethod print-c-type (stream (type c-array-type) &optional colon atsign)
386 (declare (ignore colon atsign))
387 (format stream "~:@<[] ~@_~:I~/sod:print-c-type/~{ ~_~S~}~:>"
388 (c-type-subtype type)
389 (c-array-dimensions type)))
391 (export '([] array vec))
392 (define-c-type-syntax [] (sub &rest dims)
393 "Return the type of arrays of SUB with the dimensions DIMS.
395 If the DIMS are omitted, a single unknown-length dimension is added."
396 `(make-array-type ,(expand-c-type-spec sub)
397 (list ,@(or dims '(nil)))))
398 (c-type-alias [] array vec)
400 ;;;--------------------------------------------------------------------------
403 ;; Function arguments.
405 (defun argument-lists-equal-p (list-a list-b)
406 "Return whether LIST-A and LIST-B match.
408 They must have the same number of arguments, and each argument must have
409 the same type, or be `:ellipsis'. The argument names are not inspected."
410 (and (= (length list-a) (length list-b))
411 (every (lambda (arg-a arg-b)
412 (if (eq arg-a :ellipsis)
414 (and (argumentp arg-a) (argumentp arg-b)
415 (c-type-equal-p (argument-type arg-a)
416 (argument-type arg-b)))))
419 (defun fix-and-check-keyword-argument-list (list)
420 "Check the keyword argument LIST is valid; if so, fix it up and return it.
422 Check that the keyword arguments have distinct names. Fix the list up by
423 sorting it by keyword name."
425 (unless (every #'argumentp list)
426 (error "(INTERNAL) not an argument value"))
428 (let ((list (sort (copy-list list) #'string< :key #'argument-name)))
429 (do ((list (cdr list) (cdr list))
430 (this (car list) (car list))
434 (let ((this-name (argument-name this))
435 (prev-name (argument-name prev)))
436 (when (string= this-name prev-name)
437 (error "Duplicate keyword argument name `~A'." this-name)))))
440 (export 'merge-keyword-lists)
441 (defun merge-keyword-lists (lists)
442 "Return the union of keyword argument lists.
444 The LISTS parameter consists of pairs (ARGS . WHAT), where ARGS is a list
445 of `argument' objects, and WHAT is either nil or a printable object
446 describing the origin of the corresponding argument list suitable for
447 quoting in an error message.
449 The resulting list contains exactly one argument for each distinct
450 argument name appearing in the input lists; this argument will contain the
451 default value corresponding to the name's earliest occurrence in the input
454 If the same name appears in multiple input lists with different types, an
455 error is signalled; this error will quote the origins of a representative
456 conflicting pair of arguments."
458 ;; The easy way through all of this is with a hash table mapping argument
459 ;; names to (ARGUMENT . WHAT) pairs.
461 (let ((argmap (make-hash-table :test #'equal)))
463 ;; Set up the table. When we find a duplicate, check that the types
466 (let ((args (car item))
469 (let* ((name (argument-name arg))
470 (other-item (gethash name argmap)))
471 (if (null other-item)
472 (setf (gethash name argmap) (cons arg what))
473 (let* ((type (argument-type arg))
474 (other (car other-item))
475 (other-type (argument-type other))
476 (other-what (cdr other-item)))
477 (unless (c-type-equal-p type other-type)
478 (error "Type mismatch for keyword argument `~A': ~
479 ~A~@[ (~A)~] doesn't match ~A~@[ (~A)~]."
482 other-type other-what))))))))
484 ;; Now it's just a matter of picking the arguments out again.
486 (maphash (lambda (name item)
487 (declare (ignore name))
488 (push (car item) result))
490 (fix-and-check-keyword-argument-list result))))
494 (export '(c-function-type c-function-arguments))
495 (defclass c-function-type (c-type)
496 ((subtype :initarg :subtype :type c-type :reader c-type-subtype)
497 (arguments :type list :reader c-function-arguments))
499 "C function types. The subtype is the return type, as implied by the C
500 syntax for function declarations."))
502 (defmethod shared-initialize :after
503 ((type c-function-type) slot-names &key (arguments nil argsp))
504 (declare (ignore slot-names))
506 (setf (slot-value type 'arguments)
508 (null (cdr arguments))
509 (not (eq (car arguments) :ellipsis))
510 (eq (argument-type (car arguments)) c-type-void))
514 (export '(c-keyword-function-type c-function-keywords))
515 (defclass c-keyword-function-type (c-function-type)
516 ((keywords :initarg :keywords :type list
517 :reader c-function-keywords))
519 "C function types for `functions' which take keyword arguments."))
521 (defmethod shared-initialize :after
522 ((type c-keyword-function-type) slot-names &key (keywords nil keysp))
523 (declare (ignore slot-names))
525 (setf (slot-value type 'keywords)
526 (fix-and-check-keyword-argument-list keywords))))
528 ;; Constructor function.
530 (export 'make-function-type)
531 (defun make-function-type (subtype arguments)
532 "Return a new function type, returning SUBTYPE and accepting ARGUMENTS.
534 As a helper for dealing with the S-expression syntax for keyword
535 functions, if ARGUMENTS has the form (ARGS ... :keys KEYWORDS ...)' then
536 return a keyword function with arguments (ARGS ...) and keywords (KEYWORDS
538 (let ((split (member :keys arguments)))
540 (make-instance 'c-keyword-function-type
542 :arguments (ldiff arguments split)
543 :keywords (cdr split))
544 (make-instance 'c-function-type
546 :arguments arguments))))
548 (export 'make-keyword-function-type)
549 (defun make-keyword-function-type (subtype arguments keywords)
550 "Return a new keyword-function type, returning SUBTYPE and accepting
551 ARGUMENTS and KEYWORDS."
552 (make-instance 'c-keyword-function-type :subtype subtype
553 :arguments arguments :keywords keywords))
555 ;; Comparison protocol.
557 (defmethod c-type-equal-p and
558 ((type-a c-function-type) (type-b c-function-type))
559 (and (c-type-equal-p (c-type-subtype type-a) (c-type-subtype type-b))
560 (argument-lists-equal-p (c-function-arguments type-a)
561 (c-function-arguments type-b))))
563 (defmethod c-type-equal-p and
564 ((type-a c-keyword-function-type) (type-b c-keyword-function-type))
565 ;; Actually, there's nothing to check here. I'm happy as long as both
566 ;; functions notionally accept keyword arguments.
569 ;; C syntax output protocol.
571 (export 'pprint-c-function-type)
572 (defun pprint-c-function-type (return-type stream print-args print-kernel)
573 "Common top-level printing for function types.
575 Prints RETURN-TYPE (KERNEL(ARGS)), where RETURN-TYPE is the actual return
576 type, and ARGS and KERNEL are whatever is printed by the PRINT-ARGS and
577 PRINT-KERNEL functions.
579 The PRINT-KERNEL function is the standard such thing for the
580 `pprint-c-type' protocol; PRINT-ARGS accepts just an output stream."
581 (pprint-c-type return-type stream
582 (lambda (stream prio spacep)
583 (maybe-in-parens (stream (> prio 2))
584 (when spacep (c-type-space stream))
585 (funcall print-kernel stream 2 nil)
586 (pprint-indent :block 4 stream)
587 (pprint-newline :linear stream)
588 (pprint-logical-block
589 (stream nil :prefix "(" :suffix ")")
590 (funcall print-args stream))))))
592 (export 'pprint-argument-list)
593 (defun pprint-argument-list (args stream)
594 "Print an argument list.
596 The ARGS is a list of `argument' objects, optionally containing an
597 `:ellipsis' marker. The output is written to STREAM.
599 Returns non-nil if any arguments were actually printed."
601 (pprint-logical-block (stream nil)
604 (format stream ", ~_")
608 (write-string "..." stream))
610 (pprint-logical-block (stream nil)
611 (pprint-c-type (argument-type arg) stream (argument-name arg))
612 (let ((default (argument-default arg)))
614 (format stream " = ~2I~_~A" default))))))))
617 (let ((void-arglist (list (make-argument nil c-type-void))))
618 (defmethod pprint-c-type ((type c-function-type) stream kernel)
619 (let ((args (or (c-function-arguments type) void-arglist)))
620 (pprint-c-function-type (c-type-subtype type) stream
622 (pprint-argument-list args stream))
625 (defmethod pprint-c-type ((type c-keyword-function-type) stream kernel)
626 (let ((args (c-function-arguments type))
627 (keys (c-function-keywords type)))
628 (pprint-c-function-type (c-type-subtype type) stream
630 (when (pprint-argument-list args stream)
631 (format stream ", ~_"))
632 (write-char #\? stream)
633 (pprint-argument-list keys stream))
636 ;; S-expression notation protocol.
638 (defmethod print-c-type
639 (stream (type c-function-type) &optional colon atsign)
640 (declare (ignore colon atsign))
641 (format stream "~:@<~
643 ~/sod:print-c-type/~:[~; ~]~:*~_~
644 ~<~@{~:<~S ~@_~/sod:print-c-type/~:>~^ ~_~}~:>~
645 ~:[~2*~; ~_~S ~@_~<~@{~:<~S ~@_~/sod:print-c-type/~
646 ~@[ ~@_~S~]~:>~^ ~_~}~:>~]~
648 (c-type-subtype type)
649 (mapcar (lambda (arg)
650 (if (eq arg :ellipsis) arg
651 (list (argument-name arg) (argument-type arg))))
652 (c-function-arguments type))
653 (typep type 'c-keyword-function-type)
655 (and (typep type 'c-keyword-function-type)
656 (mapcar (lambda (arg)
657 (list (argument-name arg)
659 (argument-default arg)))
660 (c-function-keywords type)))))
662 (export '(fun function () func fn))
663 (define-c-type-syntax fun (ret &rest args)
664 "Return the type of functions which returns RET and has arguments ARGS.
666 The ARGS are a list of arguments of the form (NAME TYPE [DEFAULT]). The
667 NAME can be NIL to indicate that no name was given.
669 If an entry isn't a list, it's assumed to be the start of a Lisp
670 expression to compute the tail of the list; similarly, if the list is
671 improper, then it's considered to be a complete expression. The upshot of
672 this apparently bizarre rule is that you can say
674 (c-type (fun int (\"foo\" int) . arg-tail))
676 where ARG-TAIL is (almost) any old Lisp expression and have it tack the
677 arguments onto the end. Of course, there don't have to be any explicit
678 arguments at all. The only restriction is that the head of the Lisp form
679 can't be a list -- so ((lambda (...) ...) ...) is out, but you probably
680 wouldn't type that anyway."
682 `(make-function-type ,(expand-c-type-spec ret)
683 ,(do ((args args (cdr args))
685 (if (keywordp (car args))
686 (cons (car args) list)
687 (let* ((name (caar args))
688 (type (expand-c-type-spec
690 (default (and (cddar args)
693 ,name ,type ,default)))
696 (and (atom (car args))
697 (not (keywordp (car args)))))
698 (cond ((and (null args) (null list)) `nil)
699 ((null args) `(list ,@(nreverse list)))
701 (t `(list* ,@(nreverse list) ,args)))))))
702 (c-type-alias fun function () func fn)
704 ;; Additional utilities for dealing with functions.
706 (export 'commentify-argument-names)
707 (defun commentify-argument-names (arguments)
708 "Return an argument list with the arguments commentified.
710 That is, with each argument name passed through
711 `commentify-argument-name'."
712 (mapcar (lambda (arg)
713 (if (eq arg :ellipsis) arg
714 (make-argument (commentify-argument-name (argument-name arg))
716 (argument-default arg))))
719 (export 'commentify-function-type)
720 (defun commentify-function-type (type)
721 "Return a type like TYPE, but with arguments commentified.
723 This doesn't recurse into the return type or argument types."
724 (make-function-type (c-type-subtype type)
725 (commentify-argument-names
726 (c-function-arguments type))))
728 (export 'reify-variable-argument-tail)
729 (defun reify-variable-argument-tail (arguments)
730 "Replace any `:ellipsis' item in ARGUMENTS with a `va_list' argument.
732 The argument's name is taken from the variable `*sod-ap*'."
733 (substitute (make-argument *sod-ap* c-type-va-list) :ellipsis arguments))
735 ;;;----- That's all, folks --------------------------------------------------