[lisp] / mdw-base.lisp

;;; -*-lisp-*-
;;;
;;; $Id$
;;;
;;; Basic definitions
;;;
;;; (c) 2005 Mark Wooding
;;;

;;;----- Licensing notice ---------------------------------------------------
;;;
;;; This program is free software; you can redistribute it and/or modify
;;; it under the terms of the GNU General Public License as published by
;;; the Free Software Foundation; either version 2 of the License, or
;;; (at your option) any later version.
;;; 
;;; This program is distributed in the hope that it will be useful,
;;; but WITHOUT ANY WARRANTY; without even the implied warranty of
;;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
;;; GNU General Public License for more details.
;;; 
;;; You should have received a copy of the GNU General Public License
;;; along with this program; if not, write to the Free Software Foundation,
;;; Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.

;;;--------------------------------------------------------------------------
;;; Package things.

(defpackage #:mdw.base
  (:use #:common-lisp)
  (:export #:compile-time-defun
	   #:show
	   #:stringify #:listify #:fix-pair #:pairify #:parse-body
	   #:whitespace-char-p
	   #:slot-uninitialized
	   #:nlet #:while #:case2 #:ecase2
	   #:with-gensyms #:let*/gensyms #:with-places
	   #:locp #:locf #:ref #:with-locatives
	   #:update-place #:update-place-after
	   #:incf-after #:decf-after))
(in-package #:mdw.base)

;;;--------------------------------------------------------------------------
;;; Some simple macros to get things going.

(defmacro compile-time-defun (name args &body body)
  "Define a function which can be used by macros during the compilation
   process."
  `(eval-when (:compile-toplevel :load-toplevel)
     (defun ,name ,args ,@body)))

(defmacro show (x)
  "Debugging tool: print the expression X and its value."
  (let ((tmp (gensym)))
    `(let ((,tmp ,x))
       (format t "~&~S: ~S~%" ',x ,tmp)
       ,tmp)))

(defun stringify (str)
  "Return a string representation of STR.  Strings are returned unchanged;
   symbols are converted to their names (unqualified!).  Other objects are
   converted to their print representations."
  (typecase str
    (string str)
    (symbol (symbol-name str))
    (t (with-output-to-string (s)
	 (princ str s)))))

(compile-time-defun listify (x)
  "If X is a (possibly empty) list, return X; otherwise return (list X)."
  (if (listp x) x (list x)))

(compile-time-defun do-fix-pair (x y defaultp)
  "Helper function for fix-pair and pairify."
  (flet ((singleton (x) (values x (if defaultp y x))))
    (cond ((atom x) (singleton x))
	  ((null (cdr x)) (singleton (car x)))
	  ((atom (cdr x)) (values (car x) (cdr x)))
	  ((cddr x) (error "Too many elements for a pair."))
	  (t (values (car x) (cadr x))))))

(compile-time-defun fix-pair (x &optional (y nil defaultp))
  "Return two values extracted from X.  It works as follows:
     (A) -> A, Y
     (A B) -> A, B
     (A B . C) -> error
     (A . B) -> A, B
     A -> A, Y
   where Y defaults to A if not specified."
  (do-fix-pair x y defaultp))

(compile-time-defun pairify (x &optional (y nil defaultp))
  "As for fix-pair, but returns a list instead of two values."
  (multiple-value-call #'list (do-fix-pair x y defaultp)))

(defun whitespace-char-p (ch)
  "Return whether CH is a whitespace character or not."
  (case ch
    ((#\space #\tab #\newline #\return #\vt #\formfeed) t)
    (t nil)))

(declaim (ftype (function nil ()) slot-unitialized))
(defun slot-uninitialized ()
  "A function which signals an error.  Can be used as an initializer form in
   structure definitions without doom ensuing."
  (error "No initializer for slot."))

(compile-time-defun parse-body (body &key (allow-docstring-p t))
  "Given a BODY (a list of forms), parses it into three sections: a
   docstring, a list of declarations (forms beginning with the symbol
   `declare') and the body forms.  The result is returned as three lists
   (even the docstring), suitable for interpolation into a backquoted list
   using `@,'.  If ALLOW-DOCSTRING-P is nil, docstrings aren't allowed at
   all."
  (let ((doc nil) (decls nil))
    (do ((forms body (cdr forms))) (nil)
      (let ((form (and forms (car forms))))
	(cond ((and allow-docstring-p (not doc) (stringp form) (cdr forms))
	       (setf doc form))
	      ((and (consp form)
		    (eq (car form) 'declare))
	       (setf decls (append decls (cdr form))))
	      (t (return (values (and doc (list doc))
				 (and decls (list (cons 'declare decls)))
				 forms))))))))

;;;--------------------------------------------------------------------------
;;; Generating symbols.

(defmacro with-gensyms (syms &body body)
  "Everyone's favourite macro helper."
  `(let (,@(mapcar (lambda (sym) `(,sym (gensym ,(symbol-name sym))))
                   (listify syms)))
     ,@body))

(defmacro let*/gensyms (binds &body body)
  "A macro helper.  BINDS is a list of binding pairs (VAR VALUE), where VALUE
   defaults to VAR.  The result is that BODY is evaluated in a context where
   each VAR is bound to a gensym, and in the final expansion, each of those
   gensyms will be bound to the corresponding VALUE."
  (labels ((more (binds)
             (let ((tmp (gensym "TMP")) (bind (car binds)))
               `((let ((,tmp ,(cadr bind))
                       (,(car bind) (gensym ,(symbol-name (car bind)))))
                   `(let ((,,(car bind) ,,tmp))
                      ,,@(if (cdr binds)
                             (more (cdr binds))
                             body)))))))
    (if (null binds)
        `(progn ,@body)
        (car (more (mapcar #'pairify (listify binds)))))))

;;;--------------------------------------------------------------------------
;;; Some simple yet useful control structures.

(defmacro nlet (name binds &body body)
  "Scheme's named let."
  (multiple-value-bind (vars vals)
      (loop for bind in binds
	    for (var val) = (pairify bind nil)
	    collect var into vars
	    collect val into vals
	    finally (return (values vars vals)))
    `(labels ((,name ,vars
	        ,@body))
       (,name ,@vals))))

(defmacro while (cond &body body)
  "If COND is false, evaluate to nil; otherwise evaluate BODY and try again."
  `(loop
     (unless ,cond (return))
     ,@body))

(compile-time-defun do-case2-like (kind vform clauses)
  "Helper function for `case2' and `ecase2'."
  (with-gensyms (scrutinee argument)
    `(multiple-value-bind (,scrutinee ,argument) ,vform
       (declare (ignorable ,argument))
       (,kind ,scrutinee
	 ,@(mapcar (lambda (clause)
		     (destructuring-bind
			 (cases (&optional varx vary) &rest forms)
			 clause
		       `(,cases
			 ,@(if varx
			       (list `(let ((,(or vary varx) ,argument)
					    ,@(and vary
						   `((,varx ,scrutinee))))
				        ,@forms))
			       forms))))
		   clauses)))))

(defmacro case2 (vform &body clauses)
  "VFORM is a form which evaluates to two values, SCRUTINEE and ARGUMENT.
   The CLAUSES have the form (CASES ([[SCRUVAR] ARGVAR]) FORMS...), where a
   standard `case' clause has the form (CASES FORMS...).  The `case2' form
   evaluates the VFORM, and compares the SCRUTINEE to the various CASES, in
   order, just like `case'.  If there is a match, then the corresponding
   FORMs are evaluated with ARGVAR bound to the ARGUMENT and SCRUVAR bound to
   the SCRUTINEE (where specified).  Note the bizarre defaulting behaviour:
   ARGVAR is less optional than SCRUVAR."
  (do-case2-like 'case vform clauses))

(defmacro ecase2 (vform &body clauses)
  "Like `case2', but signals an error if no clause matches the SCRUTINEE."
  (do-case2-like 'ecase vform clauses))

;;;--------------------------------------------------------------------------
;;; with-places

(defmacro %place-ref (getform setform newtmp)
  "Grim helper macro for with-places."
  (declare (ignore setform newtmp))
  getform)

(define-setf-expander %place-ref (getform setform newtmp)
  "Grim helper macro for with-places."
  (values nil nil newtmp setform getform))

(defmacro with-places ((&key environment) places &body body)
  "A hairy helper, for writing setf-like macros.  PLACES is a list of binding
   pairs (VAR PLACE), where PLACE defaults to VAR.  The result is that BODY
   is evaluated in a context where each VAR is bound to a gensym, and in the
   final expansion, each of those gensyms will be bound to a symbol-macro
   capable of reading or setting the value of the corresponding PLACE."
  (if (null places)
      `(progn ,@body)
      (let*/gensyms (environment)
        (labels
            ((more (places)
               (let ((place (car places)))
                 (with-gensyms (tmp valtmps valforms
                                    newtmps setform getform)
                   `((let ((,tmp ,(cadr place))
                           (,(car place)
                            (gensym ,(symbol-name (car place)))))
                       (multiple-value-bind
                           (,valtmps ,valforms
                            ,newtmps ,setform ,getform)
                           (get-setf-expansion ,tmp
                                               ,environment)
                         (list 'let*
                               (mapcar #'list ,valtmps ,valforms)
                               `(symbol-macrolet ((,,(car place)
                                                   (%place-ref ,,getform
                                                               ,,setform
                                                               ,,newtmps)))
                                  ,,@(if (cdr places)
                                         (more (cdr places))
                                         body))))))))))
          (car (more (mapcar #'pairify (listify places))))))))

;;;--------------------------------------------------------------------------
;;; Update-in-place macros built using with-places.

(defmacro update-place (op place arg &environment env)
  "Update PLACE with the value of OP PLACE ARG, returning the new value."
  (with-places (:environment env) (place)
    `(setf ,place (,op ,place ,arg))))

(defmacro update-place-after (op place arg &environment env)
  "Update PLACE with the value of OP PLACE ARG, returning the old value."
  (with-places (:environment env) (place)
    (with-gensyms (x)
      `(let ((,x ,place))
	 (setf ,place (,op ,x ,arg))
	 ,x))))

(defmacro incf-after (place &optional (by 1))
  "Increment PLACE by BY, returning the old value."
  `(update-place-after + ,place ,by))

(defmacro decf-after (place &optional (by 1))
  "Decrement PLACE by BY, returning the old value."
  `(update-place-after - ,place ,by))

;;;--------------------------------------------------------------------------
;;; Locatives.

(defstruct (loc (:predicate locp) (:constructor make-loc (reader writer)))
  "Locative data type.  See `locf' and `ref'."
  (reader (slot-uninitialized) :type function)
  (writer (slot-uninitialized) :type function))

(defmacro locf (place &environment env)
  "Slightly cheesy locatives.  (locf PLACE) returns an object which, using
   the `ref' function, can be used to read or set the value of PLACE.  It's
   cheesy because it uses closures rather than actually taking the address of
   something.  Also, unlike Zetalisp, we don't overload `car' to do our dirty
   work."
  (multiple-value-bind
      (valtmps valforms newtmps setform getform)
      (get-setf-expansion place env)
    `(let* (,@(mapcar #'list valtmps valforms))
       (make-loc (lambda () ,getform)
                 (lambda (,@newtmps) ,setform)))))

(declaim (inline loc (setf loc)))

(defun ref (loc)
  "Fetch the value referred to by a locative."
  (funcall (loc-reader loc)))

(defun (setf ref) (new loc)
  "Store a new value in the place referred to by a locative."
  (funcall (loc-writer loc) new))

(defmacro with-locatives (locs &body body)
  "LOCS is a list of items of the form (SYM [LOC-EXPR]), where SYM is a
   symbol and LOC-EXPR evaluates to a locative.  If LOC-EXPR is omitted, it
   defaults to SYM.  As an abbreviation for a common case, LOCS may be a
   symbol instead of a list.  The BODY is evaluated in an environment where
   each SYM is a symbol macro which expands to (ref LOC-EXPR) -- or, in fact,
   something similar which doesn't break if LOC-EXPR has side-effects.  Thus,
   references, including `setf' forms, fetch or modify the thing referred to
   by the LOC-EXPR.  Useful for covering over where something uses a
   locative."
  (setf locs (mapcar #'pairify (listify locs)))
  (let ((tt (mapcar (lambda (l) (declare (ignore l)) (gensym)) locs))
	(ll (mapcar #'cadr locs))
	(ss (mapcar #'car locs)))
    `(let (,@(mapcar (lambda (tmp loc) `(,tmp ,loc)) tt ll))
       (symbol-macrolet (,@(mapcar (lambda (sym tmp)
				     `(,sym (ref ,tmp))) ss tt))
	 ,@body))))

;;;----- That's all, folks --------------------------------------------------
Commit	Line	Data
861345b4	1	;;; --lisp--
	2	;;;
	3	;;; $Id$
	4	;;;
	5	;;; Basic definitions
	6	;;;
	7	;;; (c) 2005 Mark Wooding
	8	;;;
	9
	10	;;;----- Licensing notice ---------------------------------------------------
	11	;;;
	12	;;; This program 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.
	16	;;;
	17	;;; This program 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.
	21	;;;
	22	;;; You should have received a copy of the GNU General Public License
	23	;;; along with this program; if not, write to the Free Software Foundation,
	24	;;; Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
	25
02866e07 MW	26	;;;--------------------------------------------------------------------------
	27	;;; Package things.
	28
861345b4	29	(defpackage #:mdw.base
	30	(:use #:common-lisp)
	31	(:export #:compile-time-defun
	32	#:show
9d3ccec7	33	#:stringify #:listify #:fix-pair #:pairify #:parse-body
861345b4	34	#:whitespace-char-p
861345b4	35	#:slot-uninitialized
560e1186	36	#:nlet #:while #:case2 #:ecase2
861345b4	37	#:with-gensyms #:let*/gensyms #:with-places
e979e568 MW	38	#:locp #:locf #:ref #:with-locatives
	39	#:update-place #:update-place-after
	40	#:incf-after #:decf-after))
861345b4	41	(in-package #:mdw.base)
861345b4	42
02866e07 MW	43	;;;--------------------------------------------------------------------------
	44	;;; Some simple macros to get things going.
	45
861345b4	46	(defmacro compile-time-defun (name args &body body)
861345b4	47	"Define a function which can be used by macros during the compilation
0ff9df03	48	process."
861345b4	49	`(eval-when (:compile-toplevel :load-toplevel)
	50	(defun ,name ,args ,@body)))
	51
	52	(defmacro show (x)
	53	"Debugging tool: print the expression X and its value."
	54	(let ((tmp (gensym)))
	55	`(let ((,tmp ,x))
	56	(format t "~&~S: ~S~%" ',x ,tmp)
	57	,tmp)))
	58
	59	(defun stringify (str)
	60	"Return a string representation of STR. Strings are returned unchanged;
0ff9df03 MW	61	symbols are converted to their names (unqualified!). Other objects are
0ff9df03 MW	62	converted to their print representations."
861345b4	63	(typecase str
	64	(string str)
	65	(symbol (symbol-name str))
	66	(t (with-output-to-string (s)
	67	(princ str s)))))
02866e07	68
861345b4	69	(compile-time-defun listify (x)
	70	"If X is a (possibly empty) list, return X; otherwise return (list X)."
	71	(if (listp x) x (list x)))
02866e07	72
861345b4	73	(compile-time-defun do-fix-pair (x y defaultp)
	74	"Helper function for fix-pair and pairify."
	75	(flet ((singleton (x) (values x (if defaultp y x))))
	76	(cond ((atom x) (singleton x))
	77	((null (cdr x)) (singleton (car x)))
	78	((atom (cdr x)) (values (car x) (cdr x)))
	79	((cddr x) (error "Too many elements for a pair."))
	80	(t (values (car x) (cadr x))))))
02866e07	81
861345b4	82	(compile-time-defun fix-pair (x &optional (y nil defaultp))
861345b4	83	"Return two values extracted from X. It works as follows:
0ff9df03 MW	84	(A) -> A, Y
	85	(A B) -> A, B
	86	(A B . C) -> error
	87	(A . B) -> A, B
	88	A -> A, Y
	89	where Y defaults to A if not specified."
861345b4	90	(do-fix-pair x y defaultp))
02866e07	91
861345b4	92	(compile-time-defun pairify (x &optional (y nil defaultp))
	93	"As for fix-pair, but returns a list instead of two values."
	94	(multiple-value-call #'list (do-fix-pair x y defaultp)))
	95
	96	(defun whitespace-char-p (ch)
	97	"Return whether CH is a whitespace character or not."
	98	(case ch
	99	((#\space #\tab #\newline #\return #\vt #\formfeed) t)
	100	(t nil)))
	101
	102	(declaim (ftype (function nil ()) slot-unitialized))
	103	(defun slot-uninitialized ()
	104	"A function which signals an error. Can be used as an initializer form in
0ff9df03	105	structure definitions without doom ensuing."
861345b4	106	(error "No initializer for slot."))
861345b4	107
e2a3c923	108	(compile-time-defun parse-body (body &key (allow-docstring-p t))
9d3ccec7	109	"Given a BODY (a list of forms), parses it into three sections: a
0ff9df03 MW	110	docstring, a list of declarations (forms beginning with the symbol
	111	`declare') and the body forms. The result is returned as three lists
	112	(even the docstring), suitable for interpolation into a backquoted list
e2a3c923 MW	113	using `@,'. If ALLOW-DOCSTRING-P is nil, docstrings aren't allowed at
	114	all."
	115	(let ((doc nil) (decls nil))
	116	(do ((forms body (cdr forms))) (nil)
	117	(let ((form (and forms (car forms))))
	118	(cond ((and allow-docstring-p (not doc) (stringp form) (cdr forms))
	119	(setf doc form))
	120	((and (consp form)
	121	(eq (car form) 'declare))
	122	(setf decls (append decls (cdr form))))
	123	(t (return (values (and doc (list doc))
	124	(and decls (list (cons 'declare decls)))
	125	forms))))))))
9d3ccec7	126
02866e07 MW	127	;;;--------------------------------------------------------------------------
	128	;;; Generating symbols.
	129
861345b4	130	(defmacro with-gensyms (syms &body body)
	131	"Everyone's favourite macro helper."
	132	`(let (,@(mapcar (lambda (sym) `(,sym (gensym ,(symbol-name sym))))
	133	(listify syms)))
	134	,@body))
	135
	136	(defmacro let*/gensyms (binds &body body)
	137	"A macro helper. BINDS is a list of binding pairs (VAR VALUE), where VALUE
0ff9df03 MW	138	defaults to VAR. The result is that BODY is evaluated in a context where
	139	each VAR is bound to a gensym, and in the final expansion, each of those
	140	gensyms will be bound to the corresponding VALUE."
861345b4	141	(labels ((more (binds)
	142	(let ((tmp (gensym "TMP")) (bind (car binds)))
	143	`((let ((,tmp ,(cadr bind))
	144	(,(car bind) (gensym ,(symbol-name (car bind)))))
	145	`(let ((,,(car bind) ,,tmp))
	146	,,@(if (cdr binds)
	147	(more (cdr binds))
	148	body)))))))
	149	(if (null binds)
	150	`(progn ,@body)
	151	(car (more (mapcar #'pairify (listify binds)))))))
	152
02866e07	153	;;;--------------------------------------------------------------------------
f2d46aaa MW	154	;;; Some simple yet useful control structures.
	155
	156	(defmacro nlet (name binds &body body)
	157	"Scheme's named let."
	158	(multiple-value-bind (vars vals)
	159	(loop for bind in binds
	160	for (var val) = (pairify bind nil)
	161	collect var into vars
	162	collect val into vals
	163	finally (return (values vars vals)))
	164	`(labels ((,name ,vars
	165	,@body))
	166	(,name ,@vals))))
	167
	168	(defmacro while (cond &body body)
	169	"If COND is false, evaluate to nil; otherwise evaluate BODY and try again."
	170	`(loop
93f04724	171	(unless ,cond (return))
f2d46aaa MW	172	,@body))
f2d46aaa MW	173
560e1186 MW	174	(compile-time-defun do-case2-like (kind vform clauses)
	175	"Helper function for `case2' and `ecase2'."
	176	(with-gensyms (scrutinee argument)
	177	`(multiple-value-bind (,scrutinee ,argument) ,vform
	178	(declare (ignorable ,argument))
	179	(,kind ,scrutinee
	180	,@(mapcar (lambda (clause)
	181	(destructuring-bind
b3bc3745	182	(cases (&optional varx vary) &rest forms)
560e1186 MW	183	clause
560e1186 MW	184	`(,cases
b3bc3745 MW	185	,@(if varx
	186	(list `(let ((,(or vary varx) ,argument)
	187	,@(and vary
	188	`((,varx ,scrutinee))))
	189	,@forms))
560e1186 MW	190	forms))))
	191	clauses)))))
	192
	193	(defmacro case2 (vform &body clauses)
	194	"VFORM is a form which evaluates to two values, SCRUTINEE and ARGUMENT.
b3bc3745 MW	195	The CLAUSES have the form (CASES ([[SCRUVAR] ARGVAR]) FORMS...), where a
	196	standard `case' clause has the form (CASES FORMS...). The `case2' form
	197	evaluates the VFORM, and compares the SCRUTINEE to the various CASES, in
	198	order, just like `case'. If there is a match, then the corresponding
	199	FORMs are evaluated with ARGVAR bound to the ARGUMENT and SCRUVAR bound to
	200	the SCRUTINEE (where specified). Note the bizarre defaulting behaviour:
	201	ARGVAR is less optional than SCRUVAR."
560e1186 MW	202	(do-case2-like 'case vform clauses))
	203
	204	(defmacro ecase2 (vform &body clauses)
	205	"Like `case2', but signals an error if no clause matches the SCRUTINEE."
	206	(do-case2-like 'ecase vform clauses))
	207
f2d46aaa	208	;;;--------------------------------------------------------------------------
02866e07 MW	209	;;; with-places
02866e07 MW	210
861345b4	211	(defmacro %place-ref (getform setform newtmp)
	212	"Grim helper macro for with-places."
	213	(declare (ignore setform newtmp))
	214	getform)
02866e07	215
861345b4	216	(define-setf-expander %place-ref (getform setform newtmp)
	217	"Grim helper macro for with-places."
	218	(values nil nil newtmp setform getform))
02866e07	219
861345b4	220	(defmacro with-places ((&key environment) places &body body)
861345b4	221	"A hairy helper, for writing setf-like macros. PLACES is a list of binding
0ff9df03 MW	222	pairs (VAR PLACE), where PLACE defaults to VAR. The result is that BODY
	223	is evaluated in a context where each VAR is bound to a gensym, and in the
	224	final expansion, each of those gensyms will be bound to a symbol-macro
	225	capable of reading or setting the value of the corresponding PLACE."
861345b4	226	(if (null places)
	227	`(progn ,@body)
	228	(let*/gensyms (environment)
	229	(labels
	230	((more (places)
	231	(let ((place (car places)))
	232	(with-gensyms (tmp valtmps valforms
	233	newtmps setform getform)
	234	`((let ((,tmp ,(cadr place))
	235	(,(car place)
	236	(gensym ,(symbol-name (car place)))))
	237	(multiple-value-bind
	238	(,valtmps ,valforms
	239	,newtmps ,setform ,getform)
	240	(get-setf-expansion ,tmp
	241	,environment)
	242	(list 'let*
	243	(mapcar #'list ,valtmps ,valforms)
	244	`(symbol-macrolet ((,,(car place)
	245	(%place-ref ,,getform
	246	,,setform
	247	,,newtmps)))
	248	,,@(if (cdr places)
	249	(more (cdr places))
	250	body))))))))))
	251	(car (more (mapcar #'pairify (listify places))))))))
	252
02866e07 MW	253	;;;--------------------------------------------------------------------------
	254	;;; Update-in-place macros built using with-places.
	255
e979e568 MW	256	(defmacro update-place (op place arg &environment env)
	257	"Update PLACE with the value of OP PLACE ARG, returning the new value."
	258	(with-places (:environment env) (place)
	259	`(setf ,place (,op ,place ,arg))))
02866e07	260
e979e568 MW	261	(defmacro update-place-after (op place arg &environment env)
	262	"Update PLACE with the value of OP PLACE ARG, returning the old value."
	263	(with-places (:environment env) (place)
	264	(with-gensyms (x)
	265	`(let ((,x ,place))
02866e07 MW	266	(setf ,place (,op ,x ,arg))
	267	,x))))
	268
e979e568 MW	269	(defmacro incf-after (place &optional (by 1))
	270	"Increment PLACE by BY, returning the old value."
	271	`(update-place-after + ,place ,by))
02866e07	272
e979e568 MW	273	(defmacro decf-after (place &optional (by 1))
	274	"Decrement PLACE by BY, returning the old value."
	275	`(update-place-after - ,place ,by))
	276
02866e07 MW	277	;;;--------------------------------------------------------------------------
02866e07 MW	278	;;; Locatives.
e979e568	279
861345b4	280	(defstruct (loc (:predicate locp) (:constructor make-loc (reader writer)))
	281	"Locative data type. See `locf' and `ref'."
	282	(reader (slot-uninitialized) :type function)
	283	(writer (slot-uninitialized) :type function))
02866e07	284
861345b4	285	(defmacro locf (place &environment env)
861345b4	286	"Slightly cheesy locatives. (locf PLACE) returns an object which, using
0ff9df03 MW	287	the `ref' function, can be used to read or set the value of PLACE. It's
	288	cheesy because it uses closures rather than actually taking the address of
	289	something. Also, unlike Zetalisp, we don't overload `car' to do our dirty
	290	work."
861345b4	291	(multiple-value-bind
	292	(valtmps valforms newtmps setform getform)
	293	(get-setf-expansion place env)
	294	`(let* (,@(mapcar #'list valtmps valforms))
	295	(make-loc (lambda () ,getform)
	296	(lambda (,@newtmps) ,setform)))))
02866e07	297
861345b4	298	(declaim (inline loc (setf loc)))
02866e07	299
861345b4	300	(defun ref (loc)
	301	"Fetch the value referred to by a locative."
	302	(funcall (loc-reader loc)))
02866e07	303
861345b4	304	(defun (setf ref) (new loc)
	305	"Store a new value in the place referred to by a locative."
	306	(funcall (loc-writer loc) new))
02866e07	307
861345b4	308	(defmacro with-locatives (locs &body body)
861345b4	309	"LOCS is a list of items of the form (SYM [LOC-EXPR]), where SYM is a
0ff9df03 MW	310	symbol and LOC-EXPR evaluates to a locative. If LOC-EXPR is omitted, it
	311	defaults to SYM. As an abbreviation for a common case, LOCS may be a
	312	symbol instead of a list. The BODY is evaluated in an environment where
	313	each SYM is a symbol macro which expands to (ref LOC-EXPR) -- or, in fact,
	314	something similar which doesn't break if LOC-EXPR has side-effects. Thus,
	315	references, including `setf' forms, fetch or modify the thing referred to
	316	by the LOC-EXPR. Useful for covering over where something uses a
	317	locative."
861345b4	318	(setf locs (mapcar #'pairify (listify locs)))
	319	(let ((tt (mapcar (lambda (l) (declare (ignore l)) (gensym)) locs))
	320	(ll (mapcar #'cadr locs))
	321	(ss (mapcar #'car locs)))
	322	`(let (,@(mapcar (lambda (tmp loc) `(,tmp ,loc)) tt ll))
	323	(symbol-macrolet (,@(mapcar (lambda (sym tmp)
	324	`(,sym (ref ,tmp))) ss tt))
	325	,@body))))
	326
	327	;;;----- That's all, folks --------------------------------------------------