Update rtestint problem 237 to match the actual result.
[maxima.git] / src / grind.lisp
bloba5814deecd571b13012866c512261777f5d75288
1 ;;; -*- Mode: Lisp; Package: Maxima; Syntax: Common-Lisp; Base: 10 -*- ;;;;
2 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3 ;;; The data in this file contains enhancements. ;;;;;
4 ;;; ;;;;;
5 ;;; Copyright (c) 1984,1987 by William Schelter,University of Texas ;;;;;
6 ;;; All rights reserved ;;;;;
7 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
8 ;;; (c) Copyright 1981 Massachusetts Institute of Technology ;;;
9 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
11 (in-package :maxima)
13 (macsyma-module grind)
15 (declare-top (special lop rop *grind-charlist* chrps))
17 (defun chrct* () (- $linel chrps))
19 (defmspec $grind (x)
20 (setq x (cdr x))
21 (let (($lispdisp t) y)
22 (fresh-line)
23 (cond
24 ((null x))
25 ((cdr x) (mapc #'(lambda (xx) (funcall (get '$grind 'mfexpr*) `(($grind) ,xx))) x))
26 ((or
27 (symbolp (setq x (strmeval (car x))))
28 (and (stringp x) (symbolp (getopr x))))
29 (setq x ($verbify x))
30 (cond ((setq y (mget x 'mexpr))
31 (mgrind (list '(mdefine) (cons (list x) (cdadr y)) (caddr y)) nil))
32 ((setq y (mget x 'mmacro))
33 (mgrind (list '(mdefmacro) (cons (list x) (cdadr y)) (caddr y)) nil))
34 ((setq y (mget x 'aexpr))
35 (mgrind (list '(mdefine) (cons (list x 'array) (cdadr y)) (caddr y)) nil))
36 (t (mgrind x nil)))
37 (write-char #\$ nil) (write-char #\Newline nil))
38 (t (mgrind x nil) (write-char #\$ nil) (write-char #\Newline nil)))
39 '$done))
41 ;;Msize returns a list whose first member is the number of characters
42 ;;in the printed representation of the rest of the list.
44 (defun i-$grind (x)
45 (let (y)
46 (fresh-line)
47 (cond ((symbolp (setq x (strmeval x)))
48 (setq x ($verbify x))
49 (cond ((setq y (mget x 'mexpr))
50 (mgrind (list '(mdefine) (cons (list x) (cdadr y)) (caddr y)) nil))
51 ((setq y (mget x 'mmacro))
52 (mgrind (list '(mdefmacro) (cons (list x) (cdadr y)) (caddr y)) nil))
53 ((setq y (mget x 'aexpr))
54 (mgrind (list '(mdefine) (cons (list x 'array) (cdadr y)) (caddr y)) nil))
55 (t (mgrind x nil)))
56 (write-char #\$ nil))
57 (t (mgrind x nil) (write-char #\$ nil)))
58 '$done))
61 (defun mgrind (x out)
62 (setq chrps 0)
63 (mprint (msize x nil nil 'mparen 'mparen) out))
65 (defun mprint (x out)
66 (cond ((characterp x)
67 (incf chrps)
68 (write-char x out))
69 ((< (car x) (chrct*)) (mapc #'(lambda (l) (mprint l out)) (cdr x)))
70 (t (prog (i) (setq i chrps)
71 (mprint (cadr x) out)
72 (cond ((null (cddr x)) (return nil))
73 ((and (or (atom (cadr x)) (< (caadr x) (chrct*)))
74 (or (> (chrct*) (truncate $linel 2))
75 (atom (caddr x)) (< (caaddr x) (chrct*))))
76 (setq i chrps)
77 (mprint (caddr x) out))
78 (t (setq i (1+ i)) (setq chrps 0) (terpri out)
79 (mtyotbsp i out) (mprint (caddr x) out)))
80 (do ((l (cdddr x) (cdr l))) ((null l))
81 (cond
82 ((or (atom (car l)) (< (caar l) (chrct*))) nil)
83 (t (setq chrps 0) (terpri out) (mtyotbsp i out)))
84 (mprint (car l) out))))))
86 (defun mtyotbsp (n out)
87 (declare (fixnum n))
88 (incf chrps n)
89 (do () ((< n 1)) (write-char #\space out) (decf n)))
91 (defun strgrind (x)
92 (let (*grind-charlist* (chrps 0))
93 (strprint (msize x nil nil 'mparen 'mparen))
94 (nreverse *grind-charlist*)))
96 (defun strprint (x)
97 (cond ((atom x) (styo x))
98 ((< (car x) (chrct*)) (mapc #'strprint (cdr x)))
99 (t (prog (i)
100 (setq i chrps)
101 (strprint (cadr x))
102 (cond ((null (cddr x)) (return nil))
103 ((and (or (atom (cadr x)) (< (caadr x) (chrct*)))
104 (or (> (chrct*) (truncate $linel 2))
105 (atom (caddr x)) (< (caaddr x) (chrct*))))
106 (setq i chrps)
107 (strprint (caddr x)))
108 (t (setq i (1+ i)) (setq chrps 0) (sterpri)
109 (styotbsp i) (strprint (caddr x))))
110 (do ((l (cdddr x) (cdr l))) ((null l))
111 (cond
112 ((or (atom (car l)) (< (caar l) (chrct*))) nil)
113 (t (setq chrps 0) (sterpri) (styotbsp i)))
114 (strprint (car l)))))))
116 (defun styo (x) (setq *grind-charlist* (cons x *grind-charlist*) chrps (1+ chrps)))
118 (defun sterpri () (setq *grind-charlist* (cons #\newline *grind-charlist*) chrps 0))
120 (defun styotbsp (n) (declare (fixnum n)) (setq chrps n)
121 (do () ((< n 1)) (setq *grind-charlist* (cons #\space *grind-charlist*) n (1- n))))
123 (defun mstring (x)
124 (nreverse (string1 (msize x nil nil 'mparen 'mparen) nil)))
126 (defun string1 (x l)
127 (cond
128 ((atom x) (cons x l))
129 (t (setq x (cdr x))
130 (do () ((null x) l) (setq l (string1 (car x) l) x (cdr x))))))
132 (defun msize (x l r lop rop)
133 (setq x (nformat-check x))
134 (cond ((atom x) (msize-atom x l r))
135 ((and (atom (car x)) (setq x (cons '(mprogn) x)) nil))
136 ((or (<= (lbp (caar x)) (rbp lop)) (>= (lbp rop) (rbp (caar x))))
137 (msize-paren x l r))
138 ((member 'array (cdar x) :test #'eq) (msize-array x l r))
139 ((safe-get (caar x) 'grind)
140 (the #-ecl (values t) #+ecl t (funcall (get (caar x) 'grind) x l r)))
141 (t (msize-function x l r nil))))
143 (defun msize-atom (x l r)
144 (prog (y)
145 (cond ((numberp x) (setq y (exploden x)))
146 ((stringp x)
147 (setq y (coerce x 'list))
148 (do ((l y (cdr l))) ((null l))
149 (cond ((member (car l) '(#\" #\\ ) :test #'equal)
150 (rplacd l (cons (car l) (cdr l)))
151 (rplaca l #\\ )
152 (setq l (cdr l)))))
153 (setq y (cons #\" (nconc y (list #\")))))
154 ((and (setq y (safe-get x 'reversealias))
155 (not (and (member x $aliases :test #'eq) (get x 'noun))))
156 (setq y (exploden (stripdollar y))))
157 ((null (setq y (exploden x))))
158 ((safe-get x 'noun) (return (msize-atom (get x 'noun) l r)))
159 ((char= #\$ (car y)) (setq y (slash (cdr y))))
160 ((member (marray-type x) '(array hash-table $functional))
161 (return (msize-array-object x l r)))
162 (t (setq y (if $lispdisp (cons #\? (slash y)) (slash y)))))
163 (return (msz y l r))))
165 (defun msz (x l r)
166 (setq x (nreconc l (nconc x r))) (cons (length x) x))
168 (defun slash (x)
169 (do ((l (cdr x) (cdr l))) ((null l))
170 ; Following test is the same (except backslash is not included,
171 ; so backslash is preceded by backslash) as in SCAN-TOKEN (src/nparse.lisp).
172 (if (or (ascii-numberp (car l)) (alphabetp (car l)))
174 (progn (rplacd l (cons (car l) (cdr l)))
175 (rplaca l #\\) (setq l (cdr l)))))
176 (if (alphabetp (car x)) x (cons #\\ x)))
178 ;;#-cl
179 ;;(DEFUN ALPHANUMP (N) (DECLARE (FIXNUM N))
180 ;; (OR (ASCII-NUMBERP N) (ALPHABETP N)))
182 (defun msize-paren (x l r)
183 (msize x (cons #\( l) (cons #\) r) 'mparen 'mparen))
185 ;; The variables LB and RB are not uses here syntactically, but for
186 ;; communication. The FORTRAN program rebinds them to #/( and #/) since
187 ;; Fortran array references are printed with parens instead of brackets.
189 (defvar *lb* #\[)
190 (defvar *rb* #\])
192 (defun msize-array (x l r &aux f)
193 (if (eq (caar x) 'mqapply) (setq f (cadr x) x (cdr x)) (setq f (caar x)))
194 (cond ((atom (car x)))
195 ((and (symbolp (caar x)) (get (caar x) 'verb) (get (caar x) 'alias))
196 (setq l (revappend '(#\' #\') l)))
197 ((and (symbolp (caar x))
198 (get (caar x) 'noun)
199 (not (member (caar x) (cdr $aliases) :test #'eq))
200 (not (get (caar x) 'reversealias)))
201 (setq l (cons #\' l))))
202 (setq l (msize f l (list *lb*) lop 'mfunction)
203 r (msize-list (cdr x) nil (cons *rb* r)))
204 (cons (+ (car l) (car r)) (cons l (cdr r))))
206 (defun msize-function (x l r op)
207 (cond ((not (symbolp (caar x))))
208 ((and (get (caar x) 'verb) (get (caar x) 'alias))
209 (setq l (revappend '(#\' #\') l)))
210 ((and (get (caar x) 'noun) (not (member (caar x) (cdr $aliases) :test #'eq))
211 (not (get (caar x) 'reversealias)))
212 (setq l (cons #\' l))))
213 (setq l (msize (if op (getop (caar x)) (caar x)) l (ncons #\( ) 'mparen 'mparen)
214 r (msize-list (cdr x) nil (cons #\) r)))
215 (cons (+ (car l) (car r)) (cons l (cdr r))))
217 (defun msize-list (x l r)
218 (if (null x) (msz nil l r)
219 (do ((nl) (w 0))
220 ((null (cdr x))
221 (setq nl (cons (msize (car x) l r 'mparen 'mparen) nl))
222 (cons (+ w (caar nl)) (nreverse nl)))
223 (declare (fixnum w))
224 (setq nl (cons (msize (car x) l (list #\,) 'mparen 'mparen) nl)
225 w (+ w (caar nl)) x (cdr x) l nil))))
227 (defun msize-prefix (x l r)
228 (msize (cadr x) (revappend (strsym (caar x)) l) r (caar x) rop))
230 (defun msize-infix (x l r)
231 (if (not (= (length (cdr x)) 2))
232 (return-from msize-infix (msize-function x l r t)))
233 (setq l (msize (cadr x) l nil lop (caar x))
234 r (msize (caddr x) (reverse (strsym (caar x))) r (caar x) rop))
235 (list (+ (car l) (car r)) l r))
237 (defun msize-postfix (x l r)
238 (msize (cadr x) l (append (strsym (caar x)) r) lop (caar x)))
240 (defun msize-nary (x l r) (msznary x l r (strsym (caar x))))
242 (defun msize-nofix (x l r) (msize (caar x) l r (caar x) rop))
244 (defun msize-matchfix (x l r)
245 (setq l (nreconc l (car (strsym (caar x))))
246 l (cons (length l) l)
247 r (append (cdr (strsym (caar x))) r)
248 x (msize-list (cdr x) nil r))
249 (cons (+ (car l) (car x)) (cons l (cdr x))))
251 (defun msznary (x l r dissym)
252 (cond ((null (cddr x)) (msize-function x l r t))
253 (t (setq l (msize (cadr x) l nil lop (caar x)))
254 (do ((ol (cddr x) (cdr ol)) (nl (list l)) (w (car l)))
255 ((null (cdr ol))
256 (setq r (msize (car ol) (reverse dissym) r (caar x) rop))
257 (cons (+ (car r) w) (nreverse (cons r nl))))
258 (declare (fixnum w))
259 (setq nl (cons (msize (car ol) (reverse dissym) nil (caar x) (caar x))
261 w (+ (caar nl) w))))))
263 (defun strsym (x) (or (get x 'strsym) (get x 'dissym)))
265 (defprop bigfloat msz-bigfloat grind)
267 (defun msz-bigfloat (x l r)
268 (msz (mapcar #'get-first-char (fpformat x)) l r))
270 (defprop mprogn msize-matchfix grind)
271 (defprop mprogn ((#\( ) #\) ) strsym)
273 (defprop mlist msize-matchfix grind)
274 (setf (get '%mlist 'grind) (get 'mlist 'grind))
276 ;;; ----------------------------------------------------------------------------
278 ;; Formating a mlabel-expression
280 (defprop mlabel msize-mlabel grind)
282 (defun msize-mlabel (x l r)
283 (if *display-labels-p*
284 (setq l (cons (msize (cadr x) (list #\( ) (list #\) #\ ) nil nil) l)))
285 (msize (caddr x) l r lop rop))
287 ;;; ----------------------------------------------------------------------------
289 ;; Formating a mtext-expression
291 (defprop mtext msize-mtext grind)
293 (defun msize-mtext (x l r)
294 (setq x (cdr x))
295 (if (null x)
296 (msz nil l r)
297 (do ((nl) (w 0))
298 ((null (cdr x))
299 (setq nl (cons (if (stringp (car x))
300 (msz (makestring (car x)) l r)
301 (msize (car x) l r lop rop))
302 nl))
303 (cons (+ w (caar nl)) (nreverse nl)))
304 (setq nl (cons (if (stringp (car x))
305 (msz (makestring (car x)) l r)
306 (msize (car x) l r lop rop))
308 w (+ w (caar nl))
309 x (cdr x)
310 l nil))))
312 (defprop mqapply msz-mqapply grind)
314 (defun msz-mqapply (x l r)
315 (setq l (msize (cadr x) l (list #\( ) lop 'mfunction)
316 r (msize-list (cddr x) nil (cons #\) r)))
317 (cons (+ (car l) (car r)) (cons l (cdr r))))
319 ; SPACEOUT appears solely in trace output. See mtrace.lisp.
321 (defprop spaceout msize-spaceout grind)
323 (defun msize-spaceout (x ll r)
324 (declare (ignore ll r))
325 (let ((n (cadr x))
327 (dotimes (i n)
328 (push #\space l))
329 (cons n l)))
331 (defprop mquote msize-prefix grind)
333 (defprop msetq msize-infix grind)
334 (defprop msetq (#\:) strsym)
335 (defprop msetq 180. lbp)
336 (defprop msetq 20. rbp)
338 (defprop mset msize-infix grind)
339 (defprop mset (#\: #\:) strsym)
340 (defprop mset 180. lbp)
341 (defprop mset 20. rbp)
343 ;;; ----------------------------------------------------------------------------
345 ;; Formating a mdefine or mdefmacro expression
347 (defprop mdefine msz-mdef grind)
348 (defprop mdefine (#\: #\=) strsym)
349 (defprop mdefine 180 lbp)
350 (defprop mdefine 20 rbp)
352 ;; copy binding powers to nounified operator
353 (setf (get '%mdefine 'lbp) (get 'mdefine 'lbp))
354 (setf (get '%mdefine 'rbp) (get 'mdefine 'rbp))
356 (defprop mdefmacro msz-mdef grind)
357 (defprop mdefmacro (#\: #\: #\=) strsym)
358 (defprop mdefmacro 180 lbp)
359 (defprop mdefmacro 20 rbp)
361 ;; copy binding powers to nounified operator
362 (setf (get '%mdefmacro 'lbp) (get 'mdefmacro 'lbp))
363 (setf (get '%mdefmacro 'rbp) (get 'mdefmacro 'rbp))
365 (defun msz-mdef (x l r)
366 (setq l (msize (cadr x) l (copy-list (strsym (caar x))) lop (caar x))
367 r (msize (caddr x) nil r (caar x) rop))
368 (cond ((not (atom (cadr l)))
369 ;; An expression like g(x):=x:
370 ;; left side l = (6 (2 #\g #\( ) (4 #\x #\) #\: #\= ))
371 ;; right side r = (1 #\x )
372 ;; the result is (7 (2 #\g #\( ) (4 #\x #\) #\: #\= ) (1 #\x ))
373 (setq x (cons (- (car l) (caadr l)) (cddr l)))
374 (if (and (not (atom (cadr r)))
375 (not (atom (caddr r)))
376 (< (+ (car l) (caadr r) (caaddr r)) $linel))
377 (setq x (nconc x (list (cadr r) (caddr r)))
378 r (cons (car r) (cdddr r))))
379 (cons (+ (car l) (car r)) (cons (cadr l) (cons x (cdr r)))))
381 ;; An expression like x f :=x or f x:=x, where f is a postfix or a
382 ;; prefix operator. Example for a postfix operator:
383 ;; left side l = (5 #\x #\space #\f #\: #\= )
384 ;; right side r = (1 #\x)
385 ;; the result is (6 (5 #\x #\space #\f #\: #\=) (1 #\x))
386 (cons (+ (car l) (car r)) (cons l (ncons r))))))
388 (defprop mfactorial msize-postfix grind)
389 (defprop mfactorial 160. lbp)
390 (defprop mfactorial 159. rbp)
392 (defprop mexpt msz-mexpt grind)
393 (defprop mexpt 140. lbp)
394 (defprop mexpt 139. rbp)
396 (defun msz-mexpt (x l r)
397 (setq l (msize (cadr x) l nil lop 'mexpt)
398 r (if (mmminusp (setq x (nformat-check (caddr x))))
399 (msize (cadr x) (reverse '(#\^ #\-)) r 'mexpt rop)
400 (msize x (list #\^) r 'mexpt rop)))
401 (list (+ (car l) (car r)) l r))
404 (defprop mncexpt msize-infix grind)
405 (defprop mncexpt 140. lbp)
406 (defprop mncexpt 139. rbp)
408 (defprop mnctimes msize-nary grind)
409 (defprop mnctimes 130. lbp)
410 (defprop mnctimes 129. rbp)
412 (defprop mtimes msz-mtimes grind)
413 (defprop mtimes 120. lbp)
414 (defprop mtimes 120. rbp)
416 (defun msz-mtimes (x l r) (msznary x l r '(#\*)))
419 (defprop mquotient msize-infix grind)
420 (defprop mquotient 120. lbp)
421 (defprop mquotient 120. rbp)
422 (defprop rat msize-infix grind)
423 (defprop rat 120. lbp)
424 (defprop rat 120. rbp)
426 (defprop mplus msz-mplus grind)
427 (defprop mplus 100. lbp)
428 (defprop mplus 100. rbp)
430 (defun msz-mplus (x l r)
431 (cond ((null (cddr x))
432 (if (null (cdr x))
433 (msize-function x l r t)
434 (msize (cadr x) (append (ncons #\+) l) r 'mplus rop)))
435 (t (setq l (msize (cadr x) l nil lop 'mplus) x (cddr x))
436 (do ((nl (list l)) (w (car l)) (dissym))
437 ((null (cdr x))
438 (if (mmminusp (car x)) (setq l (cadar x) dissym (list #\-))
439 (setq l (car x) dissym (list #\+)))
440 (setq r (msize l dissym r 'mplus rop))
441 (cons (+ (car r) w) (nreverse (cons r nl))))
442 (declare (fixnum w))
443 (if (mmminusp (car x)) (setq l (cadar x) dissym (list #\-))
444 (setq l (car x) dissym (list #\+)))
445 (setq nl (cons (msize l dissym nil 'mplus 'mplus) nl)
446 w (+ (caar nl) w)
447 x (cdr x))))))
449 (defprop mminus msize-mminus grind)
450 (defprop mminus (#\-) strsym)
451 (defprop mminus 134. rbp)
452 (defprop mminus 100. lbp)
454 (defun msize-mminus (x l r)
455 (cond ((null (cddr x))
456 (if (null (cdr x))
457 (msize-function x l r t)
458 (msize (cadr x) (append (ncons #\- ) l) r 'mminus rop)))
460 (setq l (msize (cadr x) l nil lop 'mminus)
461 x (cddr x))
462 (do ((nl (list l))
463 (w (car l))
464 (dissym))
465 ((null (cdr x))
466 (if (mmminusp (car x))
467 (setq l (cadar x) dissym (list #\+ ))
468 (setq l (car x) dissym (list #\- )))
469 (setq r (msize l dissym r 'mminus rop))
470 (cons (+ (car r) w) (nreverse (cons r nl))))
471 (declare (fixnum w))
472 (if (mmminusp (car x))
473 (setq l (cadar x) dissym (list #\+ ))
474 (setq l (car x) dissym (list #\- )))
475 (setq nl (cons (msize l dissym nil 'mminus 'mminus) nl)
476 w (+ (caar nl) w)
477 x (cdr x))))))
479 (defprop mequal msize-infix grind)
480 (defprop mequal 80. lbp)
481 (defprop mequal 80. rbp)
483 (defprop mnotequal msize-infix grind)
484 (defprop mnotequal 80. lbp)
485 (defprop mnotequal 80. rbp)
487 (defprop mgreaterp msize-infix grind)
488 (defprop mgreaterp 80. lbp)
489 (defprop mgreaterp 80. rbp)
491 (defprop mgeqp msize-infix grind)
492 (defprop mgeqp 80. lbp)
493 (defprop mgeqp 80. rbp)
495 (defprop mlessp msize-infix grind)
496 (defprop mlessp 80. lbp)
497 (defprop mlessp 80. rbp)
499 (defprop mleqp msize-infix grind)
500 (defprop mleqp 80. lbp)
501 (defprop mleqp 80. rbp)
503 (defprop mnot msize-prefix grind)
504 (defprop mnot 70. rbp)
506 (defprop mand msize-nary grind)
507 (defprop mand 65. lbp)
508 (defprop mand 65. rbp)
510 (defprop mor msize-nary grind)
511 (defprop mor 60. lbp)
512 (defprop mor 60. rbp)
514 (defprop mcond msz-mcond grind)
515 (defprop mcond 45. lbp)
516 (defprop mcond 45. rbp)
518 (defprop %mcond msz-mcond grind)
519 (defprop %mcond 45. lbp)
520 (defprop %mcond 45. rbp)
522 ;; See comments above DIM-MCOND in displa.lisp concerning MCOND parsing and formatting.
524 (defun msz-mcond (x l r)
525 (let ((if (nreconc l '(#\i #\f #\space))))
526 (setq if (cons (length if) if)
527 l (msize (cadr x) nil nil 'mcond 'mparen))
530 (let ((args (cdddr x))
531 (else-literal (reverse (exploden " else ")))
532 (elseif-literal (reverse (exploden " elseif ")))
533 (then-literal (reverse (exploden " then ")))
534 (parts)
535 (part))
537 (let ((sgra (reverse args)))
538 (if (and (or (eq (car sgra) nil) (eq (car sgra) '$false)) (eq (cadr sgra) t))
539 (setq args (reverse (cddr sgra)))))
541 (setq parts (list if l))
543 (setq part (cond ((= (length args) 0)
544 `(,(msize (caddr x) (copy-tree then-literal) r 'mcond rop)))
546 `(,(msize (caddr x) (copy-tree then-literal) nil 'mcond 'mparen))))
548 parts (append parts part))
550 (loop while (>= (length args) 2) do
551 (let ((maybe-elseif (car args)) (else-or-then (cadr args)))
552 (cond
553 ((= (length args) 2)
554 (cond
555 ((eq maybe-elseif t)
556 (let ((else-arg else-or-then))
557 (setq
558 part `(,(msize else-arg (copy-tree else-literal) r 'mcond rop))
559 parts (append parts part))))
561 (let ((elseif-arg maybe-elseif) (then-arg else-or-then))
562 (setq
563 part `(,(msize elseif-arg (copy-tree elseif-literal) nil 'mcond 'mparen)
564 ,(msize then-arg (copy-tree then-literal) r 'mcond rop))
565 parts (append parts part))))))
567 (let ((elseif-arg maybe-elseif) (then-arg else-or-then))
568 (setq
569 part `(,(msize elseif-arg (copy-tree elseif-literal) nil 'mcond 'mparen)
570 ,(msize then-arg (copy-tree then-literal) nil 'mcond 'mparen))
571 parts (append parts part))))))
573 (setq args (cddr args)))
575 (cons (apply '\+ (mapcar #'car parts)) parts))))
577 (defprop text-string msize-text-string grind)
579 (defun msize-text-string (x ll r)
580 (declare (ignore ll r))
581 (cons (length (cdr x)) (cdr x)))
583 (defprop mdo msz-mdo grind)
584 (defprop mdo 25. lbp)
585 (defprop mdo 25. rbp)
587 (defprop mdoin msz-mdoin grind)
588 (defprop mdoin 30. lbp)
589 (defprop mdoin 30. rbp)
591 (defprop %mdo msz-mdo grind)
592 (defprop %mdo 25. lbp)
593 (defprop %mdo 25. rbp)
595 (defprop %mdoin msz-mdoin grind)
596 (defprop %mdoin 30. lbp)
597 (defprop %mdoin 30. rbp)
599 (defun msz-mdo (x l r)
600 (msznary (cons '(mdo) (strmdo x)) l r '(#\space)))
602 (defun msz-mdoin (x l r)
603 (msznary (cons '(mdo) (strmdoin x)) l r '(#\space)))
605 (defun strmdo (x)
606 (nconc (cond ((second x) `($for ,(second x))))
607 (cond ((equal 1 (third x)) nil)
608 ((third x) `($from ,(third x))))
609 (cond ((equal 1 (fourth x)) nil)
610 ((fourth x) `($step ,(fourth x)))
611 ((fifth x) `($next ,(fifth x))))
612 (cond ((sixth x) `($thru ,(sixth x))))
613 (cond ((null (seventh x)) nil)
614 ((and (consp (seventh x)) (eq 'mnot (caar (seventh x))))
615 `($while ,(cadr (seventh x))))
616 (t `($unless ,(seventh x))))
617 `($do ,(eighth x))))
619 (defun strmdoin (x)
620 (nconc `($for ,(second x) $in ,(third x))
621 (cond ((sixth x) `($thru ,(sixth x))))
622 (cond ((null (seventh x)) nil)
623 ((and (consp (seventh x)) (eq 'mnot (caar (seventh x))))
624 `($while ,(cadr (seventh x))))
625 (t `($unless ,(seventh x))))
626 `($do ,(eighth x))))
628 (defprop mfunction 190. lbp)
629 (defprop mfunction 190. rbp)