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dea4d055 MW |
1 | ;;; -*-lisp-*- |
2 | ;;; | |
3 | ;;; Various handy utilities | |
4 | ;;; | |
5 | ;;; (c) 2009 Straylight/Edgeware | |
6 | ;;; | |
7 | ||
8 | ;;;----- Licensing notice --------------------------------------------------- | |
9 | ;;; | |
e0808c47 | 10 | ;;; This file is part of the Sensible Object Design, an object system for C. |
dea4d055 MW |
11 | ;;; |
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. | |
16 | ;;; | |
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. | |
21 | ;;; | |
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. | |
25 | ||
bb99b695 MW |
26 | (eval-when (:compile-toplevel :load-toplevel :execute) |
27 | (handler-bind ((warning #'muffle-warning)) | |
28 | (cl:defpackage #:sod-utilities | |
29 | (:use #:common-lisp | |
30 | ||
31 | ;; MOP from somewhere. | |
32 | #+sbcl #:sb-mop | |
33 | #+(or cmu clisp) #:mop | |
34 | #+ecl #:clos)))) | |
dea4d055 MW |
35 | |
36 | (cl:in-package #:sod-utilities) | |
37 | ||
8e3552b3 MW |
38 | ;;;-------------------------------------------------------------------------- |
39 | ;;; Common symbols. | |
40 | ;;; | |
41 | ;;; Sometimes, logically independent packages will want to use the same | |
42 | ;;; symbol, and these uses (by careful design) don't conflict with each | |
43 | ;;; other. If we export the symbols here, then the necessary sharing will | |
44 | ;;; happen automatically. | |
45 | ||
46 | (export 'int) ; used by c-types and optparse | |
47 | ||
dea4d055 MW |
48 | ;;;-------------------------------------------------------------------------- |
49 | ;;; Macro hacks. | |
50 | ||
51 | (export 'with-gensyms) | |
52 | (defmacro with-gensyms ((&rest binds) &body body) | |
53 | "Evaluate BODY with variables bound to fresh symbols. | |
54 | ||
55 | The BINDS are a list of entries (VAR [NAME]), and a singleton list can be | |
56 | replaced by just a symbol; each VAR is bound to a fresh symbol generated | |
57 | by (gensym NAME), where NAME defaults to the symbol-name of VAR." | |
58 | `(let (,@(mapcar (lambda (bind) | |
59 | (multiple-value-bind (var name) | |
60 | (if (atom bind) | |
61 | (values bind (concatenate 'string | |
62 | (symbol-name bind) "-")) | |
63 | (destructuring-bind | |
64 | (var &optional | |
65 | (name (concatenate 'string | |
66 | (symbol-name var) "-"))) | |
67 | bind | |
68 | (values var name))) | |
69 | `(,var (gensym ,name)))) | |
70 | binds)) | |
71 | ,@body)) | |
72 | ||
73 | (eval-when (:compile-toplevel :load-toplevel :execute) | |
74 | (defun strip-quote (form) | |
75 | "If FORM looks like (quote FOO) for self-evaluating FOO, return FOO. | |
76 | ||
77 | If FORM is a symbol whose constant value is `nil' then return `nil'. | |
78 | Otherwise return FORM unchanged. This makes it easier to inspect constant | |
79 | things. This is a utility for `once-only'." | |
80 | ||
81 | (cond ((and (consp form) | |
82 | (eq (car form) 'quote) | |
83 | (cdr form) | |
84 | (null (cddr form))) | |
85 | (let ((body (cadr form))) | |
86 | (if (or (not (or (consp body) (symbolp body))) | |
87 | (member body '(t nil)) | |
88 | (keywordp body)) | |
89 | body | |
90 | form))) | |
91 | ((and (symbolp form) (boundp form) (null (symbol-value form))) | |
92 | nil) | |
93 | (t | |
94 | form)))) | |
95 | ||
96 | (export 'once-only) | |
74ca1bf5 | 97 | (defmacro once-only ((&rest binds) &body body) |
dea4d055 MW |
98 | "Macro helper for preventing repeated evaluation. |
99 | ||
100 | The syntax is actually hairier than shown: | |
101 | ||
102 | once-only ( [[ :environment ENV ]] { VAR | (VAR [VALUE-FORM]) }* ) | |
103 | { FORM }* | |
104 | ||
105 | So, the BINDS are a list of entries (VAR [VALUE-FORM]); a singleton list | |
106 | can be replaced by just a symbol VAR, and the VALUE-FORM defaults to VAR. | |
107 | But before them you can have keyword arguments. Only one is defined so | |
108 | far. See below for the crazy things that does. | |
109 | ||
110 | The result of evaluating a ONCE-ONLY form is a form with the structure | |
111 | ||
112 | (let ((#:GS1 VALUE-FORM1) | |
113 | ... | |
114 | (#:GSn VALUE-FORMn)) | |
115 | STUFF) | |
116 | ||
117 | where STUFF is the value of the BODY forms, as an implicit progn, in an | |
118 | environment with the VARs bound to the corresponding gensyms. | |
119 | ||
120 | As additional magic, if any of the VALUE-FORMs is actually constant (as | |
121 | determined by inspection, and aided by `constantp' if an :environment is | |
122 | supplied, then no gensym is constructed for it, and the VAR is bound | |
123 | directly to the constant form. Moreover, if the constant form looks like | |
124 | (quote FOO) for a self-evaluating FOO then the outer layer of quoting is | |
125 | stripped away." | |
126 | ||
127 | ;; We need an extra layer of gensyms in our expansion: we'll want the | |
128 | ;; expansion to examine the various VALUE-FORMs to find out whether they're | |
129 | ;; constant without evaluating them repeatedly. This also helps with | |
130 | ;; another problem: we explicitly encourage the rebinding of a VAR | |
131 | ;; (probably a macro argument) to a gensym which will be bound to the value | |
132 | ;; of the form previously held in VAR itself -- so the gensym and value | |
133 | ;; form must exist at the same time and we need two distinct variables. | |
134 | ||
135 | (with-gensyms ((envvar "ENV-") lets sym (bodyfunc "BODY-")) | |
136 | (let ((env nil)) | |
137 | ||
138 | ;; First things first: let's pick up the keywords. | |
139 | (loop | |
140 | (unless (and binds (keywordp (car binds))) | |
141 | (return)) | |
142 | (ecase (pop binds) | |
143 | (:environment (setf env (pop binds))))) | |
144 | ||
145 | ;; Now we'll investigate the bindings. Turn each one into a list (VAR | |
146 | ;; VALUE-FORM TEMP) where TEMP is an appropriate gensym -- see the note | |
147 | ;; above. | |
148 | (let ((canon (mapcar (lambda (bind) | |
149 | (multiple-value-bind (var form) | |
150 | (if (atom bind) | |
151 | (values bind bind) | |
152 | (destructuring-bind | |
153 | (var &optional (form var)) bind | |
154 | (values var form))) | |
155 | (list var form | |
156 | (gensym (format nil "T-~A-" | |
157 | (symbol-name var)))))) | |
158 | binds))) | |
159 | ||
160 | `(let* (,@(and env `((,envvar ,env))) | |
161 | (,lets nil) | |
162 | ,@(mapcar (lambda (bind) | |
163 | (destructuring-bind (var form temp) bind | |
164 | (declare (ignore var)) | |
165 | `(,temp ,form))) | |
166 | canon) | |
167 | ,@(mapcar (lambda (bind) | |
168 | (destructuring-bind (var form temp) bind | |
169 | (declare (ignore form)) | |
170 | `(,var | |
171 | (cond ((constantp ,temp | |
172 | ,@(and env `(,envvar))) | |
173 | (strip-quote ,temp)) | |
174 | ((symbolp ,temp) | |
175 | ,temp) | |
176 | (t | |
177 | (let ((,sym (gensym | |
178 | ,(concatenate 'string | |
179 | (symbol-name var) | |
180 | "-")))) | |
181 | (push (list ,sym ,temp) ,lets) | |
182 | ,sym)))))) | |
183 | canon)) | |
184 | (flet ((,bodyfunc () ,@body)) | |
185 | (if ,lets | |
186 | `(let (,@(nreverse ,lets)) ,(,bodyfunc)) | |
187 | (,bodyfunc)))))))) | |
188 | ||
189 | (export 'parse-body) | |
b8c698ee | 190 | (defun parse-body (body &key (docp t) (declp t)) |
dea4d055 MW |
191 | "Parse the BODY into a docstring, declarations and the body forms. |
192 | ||
193 | These are returned as three lists, so that they can be spliced into a | |
194 | macro expansion easily. The declarations are consolidated into a single | |
b8c698ee MW |
195 | `declare' form. If DOCP is nil then a docstring is not permitted; if |
196 | DECLP is nil, then declarations are not permitted." | |
dea4d055 MW |
197 | (let ((decls nil) |
198 | (doc nil)) | |
199 | (loop | |
200 | (cond ((null body) (return)) | |
b8c698ee | 201 | ((and declp (consp (car body)) (eq (caar body) 'declare)) |
dea4d055 | 202 | (setf decls (append decls (cdr (pop body))))) |
b8c698ee | 203 | ((and docp (stringp (car body)) (not doc) (cdr body)) |
dea4d055 MW |
204 | (setf doc (pop body))) |
205 | (t (return)))) | |
206 | (values (and doc (list doc)) | |
207 | (and decls (list (cons 'declare decls))) | |
208 | body))) | |
209 | ||
e8abb286 MW |
210 | ;;;-------------------------------------------------------------------------- |
211 | ;;; Locatives. | |
212 | ||
213 | (export '(loc locp)) | |
214 | (defstruct (loc (:predicate locp) (:constructor make-loc (reader writer))) | |
215 | "Locative data type. See `locf' and `ref'." | |
216 | (reader nil :type function) | |
217 | (writer nil :type function)) | |
218 | ||
219 | (export 'locf) | |
220 | (defmacro locf (place &environment env) | |
221 | "Slightly cheesy locatives. | |
222 | ||
223 | (locf PLACE) returns an object which, using the `ref' function, can be | |
224 | used to read or set the value of PLACE. It's cheesy because it uses | |
225 | closures rather than actually taking the address of something. Also, | |
226 | unlike Zetalisp, we don't overload `car' to do our dirty work." | |
227 | (multiple-value-bind | |
228 | (valtmps valforms newtmps setform getform) | |
229 | (get-setf-expansion place env) | |
230 | `(let* (,@(mapcar #'list valtmps valforms)) | |
231 | (make-loc (lambda () ,getform) | |
232 | (lambda (,@newtmps) ,setform))))) | |
233 | ||
234 | (export 'ref) | |
235 | (declaim (inline ref (setf ref))) | |
236 | (defun ref (loc) | |
237 | "Fetch the value referred to by a locative." | |
238 | (funcall (loc-reader loc))) | |
239 | (defun (setf ref) (new loc) | |
240 | "Store a new value in the place referred to by a locative." | |
241 | (funcall (loc-writer loc) new)) | |
242 | ||
243 | (export 'with-locatives) | |
244 | (defmacro with-locatives (locs &body body) | |
245 | "Evaluate BODY with implicit locatives. | |
246 | ||
247 | LOCS is a list of items of the form (SYM [LOC-EXPR]), where SYM is a | |
248 | symbol and LOC-EXPR evaluates to a locative. If LOC-EXPR is omitted, it | |
249 | defaults to SYM. As an abbreviation for a common case, LOCS may be a | |
250 | symbol instead of a list. | |
251 | ||
252 | The BODY is evaluated in an environment where each SYM is a symbol macro | |
253 | which expands to (ref LOC-EXPR) -- or, in fact, something similar which | |
254 | doesn't break if LOC-EXPR has side-effects. Thus, references, including | |
255 | `setf' forms, fetch or modify the thing referred to by the LOC-EXPR. | |
256 | Useful for covering over where something uses a locative." | |
257 | (setf locs (mapcar (lambda (item) | |
258 | (cond ((atom item) (list item item)) | |
259 | ((null (cdr item)) (list (car item) (car item))) | |
260 | (t item))) | |
261 | (if (listp locs) locs (list locs)))) | |
262 | (let ((tt (mapcar (lambda (l) (declare (ignore l)) (gensym)) locs)) | |
263 | (ll (mapcar #'cadr locs)) | |
264 | (ss (mapcar #'car locs))) | |
265 | `(let (,@(mapcar (lambda (tmp loc) `(,tmp ,loc)) tt ll)) | |
266 | (symbol-macrolet (,@(mapcar (lambda (sym tmp) | |
267 | `(,sym (ref ,tmp))) ss tt)) | |
268 | ,@body)))) | |
269 | ||
dea4d055 MW |
270 | ;;;-------------------------------------------------------------------------- |
271 | ;;; Anaphorics. | |
272 | ||
273 | (export 'it) | |
274 | ||
275 | (export 'aif) | |
276 | (defmacro aif (cond cons &optional (alt nil altp)) | |
277 | "If COND is not nil, evaluate CONS with `it' bound to the value of COND. | |
278 | ||
279 | Otherwise, if given, evaluate ALT; `it' isn't bound in ALT." | |
280 | (once-only (cond) | |
281 | `(if ,cond (let ((it ,cond)) ,cons) ,@(and altp `(,alt))))) | |
282 | ||
283 | (export 'awhen) | |
284 | (defmacro awhen (cond &body body) | |
285 | "If COND, evaluate BODY as a progn with `it' bound to the value of COND." | |
286 | `(let ((it ,cond)) (when it ,@body))) | |
287 | ||
3e166443 MW |
288 | (export 'aand) |
289 | (defmacro aand (&rest forms) | |
290 | "Like `and', but anaphoric. | |
291 | ||
292 | Each FORM except the first is evaluated with `it' bound to the value of | |
293 | the previous one. If there are no forms, then the result it `t'; if there | |
294 | is exactly one, then wrapping it in `aand' is pointless." | |
295 | (labels ((doit (first rest) | |
296 | (if (null rest) | |
297 | first | |
298 | `(let ((it ,first)) | |
299 | (if it ,(doit (car rest) (cdr rest)) nil))))) | |
300 | (if (null forms) | |
301 | 't | |
302 | (doit (car forms) (cdr forms))))) | |
303 | ||
dea4d055 | 304 | (export 'acond) |
bf090e02 | 305 | (defmacro acond (&body clauses &environment env) |
dea4d055 MW |
306 | "Like COND, but with `it' bound to the value of the condition. |
307 | ||
308 | Each of the CLAUSES has the form (CONDITION FORM*); if a CONDITION is | |
309 | non-nil then evaluate the FORMs with `it' bound to the non-nil value, and | |
310 | return the value of the last FORM; if there are no FORMs, then return `it' | |
311 | itself. If the CONDITION is nil then continue with the next clause; if | |
312 | all clauses evaluate to nil then the result is nil." | |
313 | (labels ((walk (clauses) | |
314 | (if (null clauses) | |
315 | `nil | |
316 | (once-only (:environment env (cond (caar clauses))) | |
317 | (if (and (constantp cond) | |
318 | (if (and (consp cond) (eq (car cond) 'quote)) | |
319 | (cadr cond) cond)) | |
320 | (if (cdar clauses) | |
321 | `(let ((it ,cond)) | |
322 | (declare (ignorable it)) | |
323 | ,@(cdar clauses)) | |
324 | cond) | |
325 | `(if ,cond | |
326 | ,(if (cdar clauses) | |
327 | `(let ((it ,cond)) | |
328 | (declare (ignorable it)) | |
329 | ,@(cdar clauses)) | |
330 | cond) | |
331 | ,(walk (cdr clauses)))))))) | |
332 | (walk clauses))) | |
333 | ||
334 | (export '(acase aecase atypecase aetypecase)) | |
335 | (defmacro acase (value &body clauses) | |
336 | `(let ((it ,value)) (case it ,@clauses))) | |
337 | (defmacro aecase (value &body clauses) | |
338 | `(let ((it ,value)) (ecase it ,@clauses))) | |
339 | (defmacro atypecase (value &body clauses) | |
340 | `(let ((it ,value)) (typecase it ,@clauses))) | |
341 | (defmacro aetypecase (value &body clauses) | |
342 | `(let ((it ,value)) (etypecase it ,@clauses))) | |
343 | ||
344 | (export 'asetf) | |
345 | (defmacro asetf (&rest places-and-values &environment env) | |
346 | "Anaphoric update of places. | |
347 | ||
348 | The PLACES-AND-VALUES are alternating PLACEs and VALUEs. Each VALUE is | |
349 | evaluated with IT bound to the current value stored in the corresponding | |
350 | PLACE." | |
351 | `(progn ,@(loop for (place value) on places-and-values by #'cddr | |
352 | collect (multiple-value-bind | |
353 | (temps inits newtemps setform getform) | |
354 | (get-setf-expansion place env) | |
355 | `(let* (,@(mapcar #'list temps inits) | |
356 | (it ,getform)) | |
357 | (multiple-value-bind ,newtemps ,value | |
358 | ,setform)))))) | |
359 | ||
360 | ;;;-------------------------------------------------------------------------- | |
361 | ;;; MOP hacks (not terribly demanding). | |
362 | ||
bf090e02 MW |
363 | (export 'instance-initargs) |
364 | (defgeneric instance-initargs (instance) | |
365 | (:documentation | |
366 | "Return a plausble list of initargs for INSTANCE. | |
367 | ||
368 | The idea is that you can make a copy of INSTANCE by invoking | |
369 | ||
370 | (apply #'make-instance (class-of INSTANCE) | |
371 | (instance-initargs INSTANCE)) | |
372 | ||
373 | The default implementation works by inspecting the slot definitions and | |
374 | extracting suitable initargs, so this will only succeed if enough slots | |
375 | actually have initargs specified that `initialize-instance' can fill in | |
376 | the rest correctly. | |
377 | ||
378 | The list returned is freshly consed, and you can destroy it if you like.") | |
379 | (:method ((instance standard-object)) | |
380 | (mapcan (lambda (slot) | |
381 | (aif (slot-definition-initargs slot) | |
382 | (list (car it) | |
383 | (slot-value instance (slot-definition-name slot))) | |
384 | nil)) | |
385 | (class-slots (class-of instance))))) | |
386 | ||
dea4d055 MW |
387 | (export '(copy-instance copy-instance-using-class)) |
388 | (defgeneric copy-instance-using-class (class instance &rest initargs) | |
389 | (:documentation | |
390 | "Metaobject protocol hook for `copy-instance'.") | |
391 | (:method ((class standard-class) instance &rest initargs) | |
392 | (let ((copy (allocate-instance class))) | |
393 | (dolist (slot (class-slots class)) | |
394 | (let ((name (slot-definition-name slot))) | |
395 | (when (slot-boundp instance name) | |
396 | (setf (slot-value copy name) (slot-value instance name))))) | |
397 | (apply #'shared-initialize copy nil initargs)))) | |
398 | (defun copy-instance (object &rest initargs) | |
399 | "Construct and return a copy of OBJECT. | |
400 | ||
401 | The new object has the same class as OBJECT, and the same slot values | |
402 | except where overridden by INITARGS." | |
403 | (apply #'copy-instance-using-class (class-of object) object initargs)) | |
404 | ||
9ec578d9 MW |
405 | (export '(generic-function-methods method-specializers |
406 | eql-specializer eql-specializer-object)) | |
407 | ||
dea4d055 MW |
408 | ;;;-------------------------------------------------------------------------- |
409 | ;;; List utilities. | |
410 | ||
411 | (export 'make-list-builder) | |
412 | (defun make-list-builder (&optional initial) | |
413 | "Return a simple list builder." | |
414 | ||
415 | ;; The `builder' is just a cons cell whose cdr will be the list that's | |
416 | ;; wanted. Effectively, then, we have a list that's one item longer than | |
417 | ;; we actually want. The car of this extra initial cons cell is always the | |
418 | ;; last cons in the list -- which is now well defined because there's | |
419 | ;; always at least one. | |
420 | ||
421 | (let ((builder (cons nil initial))) | |
422 | (setf (car builder) (last builder)) | |
423 | builder)) | |
424 | ||
425 | (export 'lbuild-add) | |
426 | (defun lbuild-add (builder item) | |
427 | "Add an ITEM to the end of a list BUILDER." | |
428 | (let ((new (cons item nil))) | |
429 | (setf (cdar builder) new | |
430 | (car builder) new)) | |
431 | builder) | |
432 | ||
433 | (export 'lbuild-add-list) | |
434 | (defun lbuild-add-list (builder list) | |
435 | "Add a LIST to the end of a list BUILDER. The LIST will be clobbered." | |
436 | (when list | |
437 | (setf (cdar builder) list | |
438 | (car builder) (last list))) | |
439 | builder) | |
440 | ||
441 | (export 'lbuild-list) | |
442 | (defun lbuild-list (builder) | |
443 | "Return the constructed list." | |
444 | (cdr builder)) | |
445 | ||
446 | (export 'mappend) | |
447 | (defun mappend (function list &rest more-lists) | |
69dda0c9 | 448 | "Like a nondestructive `mapcan'. |
dea4d055 MW |
449 | |
450 | Map FUNCTION over the the corresponding elements of LIST and MORE-LISTS, | |
451 | and return the result of appending all of the resulting lists." | |
452 | (reduce #'append (apply #'mapcar function list more-lists) :from-end t)) | |
453 | ||
0a8f78ec MW |
454 | (export 'cross-product) |
455 | (defun cross-product (&rest pieces) | |
456 | "Return the cross product of the PIECES. | |
457 | ||
458 | Each arguments may be a list, or a (non-nil) atom, which is equivalent to | |
459 | a singleton list containing just that atom. Return a list of all possible | |
460 | lists which can be constructed by taking one item from each argument list | |
461 | in turn, in an arbitrary order." | |
462 | (reduce (lambda (piece tails) | |
463 | (mapcan (lambda (tail) | |
464 | (mapcar (lambda (head) | |
465 | (cons head tail)) | |
466 | (if (listp piece) piece | |
467 | (list piece)))) | |
468 | tails)) | |
469 | pieces | |
470 | :from-end t | |
471 | :initial-value '(nil))) | |
472 | ||
17c7c784 MW |
473 | (export 'distinguished-point-shortest-paths) |
474 | (defun distinguished-point-shortest-paths (root neighbours-func) | |
475 | "Moderately efficient shortest-paths-from-root computation. | |
476 | ||
477 | The ROOT is a distinguished vertex in a graph. The NEIGHBOURS-FUNC | |
478 | accepts a VERTEX as its only argument, and returns a list of conses (V . | |
479 | C) for each of the VERTEX's neighbours, indicating that there is an edge | |
480 | from VERTEX to V, with cost C. | |
481 | ||
482 | The return value is a list of entries (COST . REV-PATH) for each vertex | |
483 | reachable from the ROOT; the COST is the total cost of the shortest path, | |
484 | and REV-PATH is the path from the ROOT, in reverse order -- so the first | |
485 | element is the vertex itself and the last element is the ROOT. | |
486 | ||
487 | The NEIGHBOURS-FUNC is called at most N times, and may take O(N) time to | |
488 | produce its output list. The computation as a whole takes O(N^2) time, | |
489 | where N is the number of vertices in the graph, assuming there is at most | |
490 | one edge between any pair of vertices." | |
491 | ||
492 | ;; This is a listish version of Dijkstra's shortest-path algorithm. It | |
493 | ;; could be made more efficient by using a fancy priority queue rather than | |
494 | ;; a linear search for finding the nearest live element (see below), but it | |
495 | ;; still runs pretty well. | |
496 | ||
497 | (let ((map (make-hash-table)) | |
498 | (dead nil) | |
499 | (live (list (list 0 root)))) | |
500 | (setf (gethash root map) (cons :live (car live))) | |
501 | (loop | |
502 | ;; The dead list contains a record, in output format (COST . PATH), for | |
503 | ;; each vertex whose shortest path has been finally decided. The live | |
504 | ;; list contains a record for the vertices of current interest, also in | |
505 | ;; output format; the COST for a live record shows the best cost for a | |
506 | ;; path using only dead vertices. | |
507 | ;; | |
508 | ;; Each time through here, we pull an item off the live list and | |
509 | ;; push it onto the dead list, so we do at most N iterations total. | |
510 | ||
511 | ;; If there are no more live items, then we're done; the remaining | |
512 | ;; vertices, if any, are unreachable from the ROOT. | |
513 | (when (null live) (return)) | |
514 | ||
515 | ;; Find the closest live vertex to the root. The linear scan through | |
516 | ;; the live list costs at most N time. | |
517 | (let* ((best (reduce (lambda (x y) (if (< (car x) (car y)) x y)) live)) | |
518 | (best-cost (car best)) | |
519 | (best-path (cdr best)) | |
520 | (best-vertex (car best-path))) | |
521 | ||
522 | ;; Remove the chosen vertex from the LIVE list, and add the | |
523 | ;; appropriate record to the dead list. We must have the shortest | |
524 | ;; path to this vertex now: we have the shortest path using currently | |
525 | ;; dead vertices; any other path must use at least one live vertex, | |
526 | ;; and, by construction, the path through any such vertex must be | |
527 | ;; further than the path we already have. | |
528 | ;; | |
529 | ;; Removal from the live list uses a linear scan which costs N time. | |
530 | (setf live (delete best live)) | |
531 | (push best dead) | |
532 | (setf (car (gethash best-vertex map)) :dead) | |
533 | ||
534 | ;; Work through the chosen vertex's neighbours, adding each of them | |
535 | ;; to the live list if they're not already there. If a neighbour is | |
536 | ;; already live, and we find a shorter path to it through our chosen | |
537 | ;; vertex, then update the neighbour's record. | |
538 | ;; | |
539 | ;; The chosen vertex obviously has at most N neighbours. There's no | |
540 | ;; more looping in here, so performance is as claimed. | |
541 | (dolist (neigh (funcall neighbours-func best-vertex)) | |
542 | (let* ((neigh-vertex (car neigh)) | |
543 | (neigh-cost (+ best-cost (cdr neigh))) | |
544 | (neigh-record (gethash neigh-vertex map))) | |
545 | (cond ((null neigh-record) | |
546 | ;; If the neighbour isn't known, then now's the time to | |
547 | ;; make a fresh live record for it. | |
548 | (let ((new-record (list* :live neigh-cost | |
549 | neigh-vertex best-path))) | |
550 | (push (cdr new-record) live) | |
551 | (setf (gethash neigh-vertex map) new-record))) | |
552 | ((and (eq (car neigh-record) :live) | |
553 | (< neigh-cost (cadr neigh-record))) | |
554 | ;; If the neighbour is live, and we've found a better path | |
555 | ;; to it, then update its record. | |
556 | (setf (cadr neigh-record) neigh-cost | |
557 | (cdddr neigh-record) best-path))))))) | |
558 | dead)) | |
559 | ||
38b78e87 MW |
560 | (export '(inconsistent-merge-error |
561 | merge-error-candidates merge-error-present-function)) | |
dea4d055 MW |
562 | (define-condition inconsistent-merge-error (error) |
563 | ((candidates :initarg :candidates | |
38b78e87 MW |
564 | :reader merge-error-candidates) |
565 | (present :initarg :present :initform #'identity | |
566 | :reader merge-error-present-function)) | |
dea4d055 | 567 | (:documentation |
9fb4a980 | 568 | "Reports an inconsistency in the arguments passed to `merge-lists'.") |
dea4d055 | 569 | (:report (lambda (condition stream) |
e2838dc5 MW |
570 | (format stream "Merge inconsistency: failed to decide between ~ |
571 | ~{~#[~;~A~;~A and ~A~:;~ | |
572 | ~@{~A, ~#[~;and ~A~]~}~]~}" | |
38b78e87 MW |
573 | (mapcar (merge-error-present-function condition) |
574 | (merge-error-candidates condition)))))) | |
dea4d055 MW |
575 | |
576 | (export 'merge-lists) | |
e2838dc5 | 577 | (defun merge-lists (lists &key pick (test #'eql) (present #'identity)) |
dea4d055 MW |
578 | "Return a merge of the given LISTS. |
579 | ||
e8c5a09e | 580 | The resulting list contains the items of the given LISTS, with duplicates |
dea4d055 MW |
581 | removed. The order of the resulting list is consistent with the orders of |
582 | the input LISTS in the sense that if A precedes B in some input list then | |
583 | A will also precede B in the output list. If the lists aren't consistent | |
584 | (e.g., some list contains A followed by B, and another contains B followed | |
e2838dc5 MW |
585 | by A) then an error of type `inconsistent-merge-error' is signalled. The |
586 | offending items are filtered for presentation through the PRESENT function | |
587 | before being attached to the condition, so as to produce a more useful | |
588 | diagnostic message. | |
dea4d055 MW |
589 | |
590 | Item equality is determined by TEST. | |
591 | ||
592 | If there is an ambiguity at any point -- i.e., a choice between two or | |
593 | more possible next items to emit -- then PICK is called to arbitrate. | |
594 | PICK is called with two arguments: the list of candidate next items, and | |
e8c5a09e MW |
595 | the current output list. It should return one of the candidate items. |
596 | The order of the candidates in the list given to the PICK function | |
597 | reflects their order in the input LISTS: item A will precede item B in the | |
598 | candidates list if and only if an occurrence of A appears in an earlier | |
599 | input list than any occurrence of item B. (This completely determines the | |
600 | order of the candidates: it is not possible that two candidates appear in | |
c5ef873a MW |
601 | the same input list, since that would resolve the ambiguity between them.) |
602 | If PICK is omitted then the item chosen is the one appearing in the | |
603 | earliest of the input lists: i.e., effectively, the default PICK function | |
604 | is | |
e8c5a09e MW |
605 | |
606 | (lambda (candidates output-so-far) | |
607 | (declare (ignore output-so-far)) | |
608 | (car candidates)) | |
dea4d055 MW |
609 | |
610 | The primary use of this function is in computing class precedence lists. | |
611 | By building the input lists and selecting the PICK function appropriately, | |
612 | a variety of different CPL algorithms can be implemented." | |
613 | ||
022a3499 MW |
614 | (do ((lb (make-list-builder))) |
615 | ((null lists) (lbuild-list lb)) | |
dea4d055 MW |
616 | |
617 | ;; The candidate items are the ones at the front of the input lists. | |
618 | ;; Gather them up, removing duplicates. If a candidate is somewhere in | |
619 | ;; one of the other lists other than at the front then we reject it. If | |
620 | ;; we've just rejected everything, then we can make no more progress and | |
621 | ;; the input lists were inconsistent. | |
e8c5a09e MW |
622 | (let* ((candidates (delete-duplicates (mapcar #'car lists) |
623 | :test test :from-end t)) | |
dea4d055 MW |
624 | (leasts (remove-if (lambda (item) |
625 | (some (lambda (list) | |
626 | (member item (cdr list) :test test)) | |
627 | lists)) | |
628 | candidates)) | |
629 | (winner (cond ((null leasts) | |
630 | (error 'inconsistent-merge-error | |
38b78e87 MW |
631 | :candidates candidates |
632 | :present present)) | |
dea4d055 MW |
633 | ((null (cdr leasts)) |
634 | (car leasts)) | |
635 | (pick | |
636 | (funcall pick leasts (lbuild-list lb))) | |
637 | (t (car leasts))))) | |
638 | ||
639 | ;; Check that the PICK function isn't conning us. | |
640 | (assert (member winner leasts :test test)) | |
641 | ||
642 | ;; Update the output list and remove the winning item from the input | |
643 | ;; lists. We know that it must be at the front of each input list | |
644 | ;; containing it. At this point, we discard input lists entirely when | |
645 | ;; they run out of entries. The loop ends when there are no more input | |
646 | ;; lists left, i.e., when we've munched all of the input items. | |
647 | (lbuild-add lb winner) | |
648 | (setf lists (delete nil (mapcar (lambda (list) | |
649 | (if (funcall test winner (car list)) | |
650 | (cdr list) | |
651 | list)) | |
652 | lists)))))) | |
653 | ||
654 | (export 'categorize) | |
655 | (defmacro categorize ((itemvar items &key bind) categories &body body) | |
656 | "Categorize ITEMS into lists and invoke BODY. | |
657 | ||
658 | The ITEMVAR is a symbol; as the macro iterates over the ITEMS, ITEMVAR | |
659 | will contain the current item. The BIND argument is a list of LET*-like | |
660 | clauses. The CATEGORIES are a list of clauses of the form (SYMBOL | |
661 | PREDICATE). | |
662 | ||
663 | The behaviour of the macro is as follows. ITEMVAR is assigned (not | |
664 | bound), in turn, each item in the list ITEMS. The PREDICATEs in the | |
665 | CATEGORIES list are evaluated in turn, in an environment containing | |
666 | ITEMVAR and the BINDings, until one of them evaluates to a non-nil value. | |
667 | At this point, the item is assigned to the category named by the | |
668 | corresponding SYMBOL. If none of the PREDICATEs returns non-nil then an | |
669 | error is signalled; a PREDICATE consisting only of T will (of course) | |
670 | match anything; it is detected specially so as to avoid compiler warnings. | |
671 | ||
672 | Once all of the ITEMS have been categorized in this fashion, the BODY is | |
673 | evaluated as an implicit PROGN. For each SYMBOL naming a category, a | |
674 | variable named after that symbol will be bound in the BODY's environment | |
675 | to a list of the items in that category, in the same order in which they | |
676 | were found in the list ITEMS. The final values of the macro are the final | |
677 | values of the BODY." | |
678 | ||
679 | (let* ((cat-names (mapcar #'car categories)) | |
680 | (cat-match-forms (mapcar #'cadr categories)) | |
681 | (cat-vars (mapcar (lambda (name) (gensym (concatenate 'string | |
682 | (symbol-name name) "-"))) | |
683 | cat-names)) | |
684 | (items-var (gensym "ITEMS-"))) | |
64a7e651 MW |
685 | `(let (,@(mapcar (lambda (cat-var) (list cat-var nil)) cat-vars)) |
686 | (let ((,items-var ,items)) | |
687 | (dolist (,itemvar ,items-var) | |
688 | (let* ,bind | |
689 | (cond ,@(mapcar (lambda (cat-match-form cat-var) | |
690 | `(,cat-match-form | |
691 | (push ,itemvar ,cat-var))) | |
692 | cat-match-forms cat-vars) | |
693 | ,@(and (not (member t cat-match-forms)) | |
694 | `((t (error "Failed to categorize ~A" | |
695 | ,itemvar)))))))) | |
dea4d055 MW |
696 | (let ,(mapcar (lambda (name var) |
697 | `(,name (nreverse ,var))) | |
698 | cat-names cat-vars) | |
699 | ,@body)))) | |
700 | ||
42291726 MW |
701 | (export 'partial-order-minima) |
702 | (defun partial-order-minima (items order) | |
703 | "Return a list of minimal items according to the non-strict partial ORDER. | |
704 | ||
705 | The ORDER function describes the partial order: (funcall ORDER X Y) should | |
706 | return true if X precedes or is equal to Y in the order." | |
707 | (reduce (lambda (tops this) | |
708 | (let ((new nil) (keep t)) | |
709 | (dolist (top tops) | |
710 | (cond ((funcall order top this) | |
711 | (setf keep nil) | |
712 | (push top new)) | |
713 | ((not (funcall order this top)) | |
714 | (push top new)))) | |
715 | (nreverse (if keep (cons this new) new)))) | |
716 | items | |
717 | :initial-value nil)) | |
718 | ||
64cbfb65 MW |
719 | (export 'find-duplicates) |
720 | (defun find-duplicates (report sequence &key (key #'identity) (test #'eql)) | |
721 | "Call REPORT on each pair of duplicate items in SEQUENCE. | |
722 | ||
723 | Duplicates are determined according to the KEY and TEST funcitons." | |
724 | (when (symbolp test) (setf test (symbol-function test))) | |
725 | (cond ((zerop (length sequence)) nil) | |
726 | ((or (eq test #'eq) | |
727 | (eq test #'eql) | |
728 | (eq test #'equal) | |
729 | (eq test #'equalp)) | |
730 | (let ((seen (make-hash-table :test test))) | |
731 | (map nil (lambda (item) | |
732 | (let ((k (funcall key item))) | |
733 | (multiple-value-bind (previous matchp) | |
734 | (gethash k seen) | |
735 | (if matchp (funcall report item previous) | |
736 | (setf (gethash k seen) item))))) | |
737 | sequence))) | |
738 | ((listp sequence) | |
9a3cb461 MW |
739 | (do ((tail sequence (cdr tail)) |
740 | (i 0 (1+ i))) | |
741 | ((endp tail)) | |
742 | (let* ((item (car tail)) | |
743 | (match (find (funcall key item) sequence | |
744 | :test test :key key :end i))) | |
745 | (when match (funcall report item match))))) | |
64cbfb65 MW |
746 | ((vectorp sequence) |
747 | (dotimes (i (length sequence)) | |
748 | (let* ((item (aref sequence i)) | |
749 | (pos (position (funcall key item) sequence | |
9a3cb461 | 750 | :key key :test test :end i))) |
64cbfb65 MW |
751 | (when pos (funcall report item (aref sequence pos)))))) |
752 | (t | |
753 | (error 'type-error :datum sequence :expected-type 'sequence)))) | |
754 | ||
dea4d055 MW |
755 | ;;;-------------------------------------------------------------------------- |
756 | ;;; Strings and characters. | |
757 | ||
758 | (export 'frob-identifier) | |
759 | (defun frob-identifier (string &key (swap-case t) (swap-hyphen t)) | |
760 | "Twiddles the case of STRING. | |
761 | ||
762 | If all the letters in STRING are uppercase, and SWAP-CASE is true, then | |
763 | switch them to lowercase; if they're all lowercase then switch them to | |
764 | uppercase. If there's a mix then leave them all alone. At the same time, | |
765 | if there are underscores but no hyphens, and SWAP-HYPHEN is true, then | |
766 | switch them to hyphens, if there are hyphens and no underscores, switch | |
767 | them underscores, and if there are both then leave them alone. | |
768 | ||
769 | This is an invertible transformation, which turns vaguely plausible Lisp | |
770 | names into vaguely plausible C names and vice versa. Lisp names with | |
771 | `funny characters' like stars and percent signs won't be any use, of | |
772 | course." | |
773 | ||
774 | ;; Work out what kind of a job we've got to do. Gather flags: bit 0 means | |
775 | ;; there are upper-case letters; bit 1 means there are lower-case letters; | |
776 | ;; bit 2 means there are hyphens; bit 3 means there are underscores. | |
777 | ;; | |
778 | ;; Consequently, (logxor flags (ash flags 1)) is interesting: bit 1 is set | |
779 | ;; if we have to frob case; bit 3 is set if we have to swap hyphens and | |
780 | ;; underscores. So use this to select functions which do bits of the | |
781 | ;; mapping, and then compose them together. | |
782 | (let* ((flags (reduce (lambda (state ch) | |
783 | (logior state | |
784 | (cond ((upper-case-p ch) 1) | |
785 | ((lower-case-p ch) 2) | |
786 | ((char= ch #\-) 4) | |
787 | ((char= ch #\_) 8) | |
788 | (t 0)))) | |
789 | string | |
790 | :initial-value 0)) | |
791 | (mask (logxor flags (ash flags 1))) | |
792 | (letter (cond ((or (not swap-case) (not (logbitp 1 mask))) | |
793 | (constantly nil)) | |
794 | ((logbitp 0 flags) | |
795 | (lambda (ch) | |
796 | (and (alpha-char-p ch) (char-downcase ch)))) | |
797 | (t | |
798 | (lambda (ch) | |
799 | (and (alpha-char-p ch) (char-upcase ch)))))) | |
800 | (uscore-hyphen (cond ((or (not (logbitp 3 mask)) (not swap-hyphen)) | |
801 | (constantly nil)) | |
802 | ((logbitp 2 flags) | |
803 | (lambda (ch) (and (char= ch #\-) #\_))) | |
804 | (t | |
805 | (lambda (ch) (and (char= ch #\_) #\-)))))) | |
806 | ||
807 | (if (logbitp 3 (logior mask (ash mask 2))) | |
808 | (map 'string (lambda (ch) | |
809 | (or (funcall letter ch) | |
810 | (funcall uscore-hyphen ch) | |
811 | ch)) | |
812 | string) | |
813 | string))) | |
814 | ||
815 | (export 'whitespace-char-p) | |
816 | (declaim (inline whitespace-char-p)) | |
817 | (defun whitespace-char-p (char) | |
818 | "Returns whether CHAR is a whitespace character. | |
819 | ||
820 | Whitespaceness is determined relative to the compile-time readtable, which | |
821 | is probably good enough for most purposes." | |
822 | (case char | |
823 | (#.(loop for i below char-code-limit | |
824 | for ch = (code-char i) | |
825 | unless (with-input-from-string (in (string ch)) | |
826 | (peek-char t in nil)) | |
827 | collect ch) t) | |
828 | (t nil))) | |
829 | ||
830 | (export 'update-position) | |
831 | (declaim (inline update-position)) | |
832 | (defun update-position (char line column) | |
833 | "Updates LINE and COLUMN appropriately for having read the character CHAR. | |
834 | ||
835 | Returns the new LINE and COLUMN numbers." | |
836 | (case char | |
837 | ((#\newline #\vt #\page) | |
838 | (values (1+ line) 0)) | |
839 | ((#\tab) | |
840 | (values line (logandc2 (+ column 8) 7))) | |
841 | (t | |
842 | (values line (1+ column))))) | |
843 | ||
844 | (export 'backtrack-position) | |
845 | (declaim (inline backtrack-position)) | |
846 | (defun backtrack-position (char line column) | |
847 | "Updates LINE and COLUMN appropriately for having unread CHAR. | |
848 | ||
849 | Well, actually an approximation for it; it will likely be wrong if the | |
850 | last character was a tab. But when the character is read again, it will | |
851 | be correct." | |
852 | ||
853 | ;; This isn't perfect: if the character doesn't actually match what was | |
854 | ;; really read then it might not actually be possible: for example, if we | |
855 | ;; push back a newline while in the middle of a line, or a tab while not at | |
856 | ;; a tab stop. In that case, we'll just lose, but hopefully not too badly. | |
857 | (case char | |
858 | ||
859 | ;; In the absence of better ideas, I'll set the column number to zero. | |
860 | ;; This is almost certainly wrong, but with a little luck nobody will ask | |
861 | ;; and it'll be all right soon. | |
862 | ((#\newline #\vt #\page) (values (1- line) 0)) | |
863 | ||
864 | ;; Winding back a single space is sufficient. If the position is | |
865 | ;; currently on a tab stop then it'll advance back here next time. If | |
866 | ;; not, we're going to lose anyway because the previous character | |
867 | ;; certainly couldn't have been a tab. | |
868 | (#\tab (values line (1- column))) | |
869 | ||
870 | ;; Anything else: just decrement the column and cross fingers. | |
871 | (t (values line (1- column))))) | |
872 | ||
873 | ;;;-------------------------------------------------------------------------- | |
874 | ;;; Functions. | |
875 | ||
876 | (export 'compose) | |
b0d4e74f | 877 | (defun compose (&rest functions) |
dea4d055 MW |
878 | "Composition of functions. Functions are applied left-to-right. |
879 | ||
880 | This is the reverse order of the usual mathematical notation, but I find | |
bf090e02 MW |
881 | it easier to read. It's also slightly easier to work with in programs. |
882 | That is, (compose F1 F2 ... Fn) is what a category theorist might write as | |
883 | F1 ; F2 ; ... ; Fn, rather than F1 o F2 o ... o Fn." | |
884 | ||
dea4d055 MW |
885 | (labels ((compose1 (func-a func-b) |
886 | (lambda (&rest args) | |
887 | (multiple-value-call func-b (apply func-a args))))) | |
b0d4e74f MW |
888 | (if (null functions) #'values |
889 | (reduce #'compose1 (cdr functions) | |
890 | :initial-value (car functions))))) | |
dea4d055 | 891 | |
c34b237d MW |
892 | ;;;-------------------------------------------------------------------------- |
893 | ;;; Variables. | |
894 | ||
895 | (export 'defvar-unbound) | |
896 | (defmacro defvar-unbound (var doc) | |
897 | "Make VAR a special variable with documentation DOC, but leave it unbound." | |
898 | `(eval-when (:compile-toplevel :load-toplevel :execute) | |
899 | (defvar ,var) | |
900 | (setf (documentation ',var 'variable) ',doc) | |
901 | ',var)) | |
902 | ||
dea4d055 MW |
903 | ;;;-------------------------------------------------------------------------- |
904 | ;;; Symbols. | |
905 | ||
906 | (export 'symbolicate) | |
907 | (defun symbolicate (&rest symbols) | |
908 | "Return a symbol named after the concatenation of the names of the SYMBOLS. | |
909 | ||
3109662a | 910 | The symbol is interned in the current `*package*'. Trad." |
dea4d055 MW |
911 | (intern (apply #'concatenate 'string (mapcar #'symbol-name symbols)))) |
912 | ||
913 | ;;;-------------------------------------------------------------------------- | |
914 | ;;; Object printing. | |
915 | ||
916 | (export 'maybe-print-unreadable-object) | |
917 | (defmacro maybe-print-unreadable-object | |
918 | ((object stream &rest args) &body body) | |
919 | "Print helper for usually-unreadable objects. | |
920 | ||
3109662a | 921 | If `*print-escape*' is set then print OBJECT unreadably using BODY. |
dea4d055 MW |
922 | Otherwise just print using BODY." |
923 | (with-gensyms (print) | |
924 | `(flet ((,print () ,@body)) | |
925 | (if *print-escape* | |
926 | (print-unreadable-object (,object ,stream ,@args) | |
927 | (,print)) | |
928 | (,print))))) | |
929 | ||
08b6e064 MW |
930 | (export 'print-ugly-stuff) |
931 | (defun print-ugly-stuff (stream func) | |
932 | "Print not-pretty things to the stream underlying STREAM. | |
933 | ||
934 | The Lisp pretty-printing machinery, notably `pprint-logical-block', may | |
935 | interpose additional streams between its body and the original target | |
936 | stream. This makes it difficult to make use of the underlying stream's | |
937 | special features, whatever they might be." | |
938 | ||
939 | ;; This is unpleasant. Hacky hacky. | |
940 | #.(or #+sbcl '(if (typep stream 'sb-pretty:pretty-stream) | |
941 | (let ((target (sb-pretty::pretty-stream-target stream))) | |
942 | (pprint-newline :mandatory stream) | |
943 | (funcall func target)) | |
944 | (funcall func stream)) | |
945 | #+cmu '(if (typep stream 'pp:pretty-stream) | |
946 | (let ((target (pp::pretty-stream-target stream))) | |
947 | (pprint-newline :mandatory stream) | |
948 | (funcall func target)) | |
949 | (funcall func stream)) | |
950 | '(funcall func stream))) | |
951 | ||
dea4d055 MW |
952 | ;;;-------------------------------------------------------------------------- |
953 | ;;; Iteration macros. | |
954 | ||
955 | (export 'dosequence) | |
956 | (defmacro dosequence ((var seq &key (start 0) (end nil) indexvar) | |
957 | &body body | |
958 | &environment env) | |
959 | "Macro for iterating over general sequences. | |
960 | ||
961 | Iterates over a (sub)sequence SEQ, delimited by START and END (which are | |
962 | evaluated). For each item of SEQ, BODY is invoked with VAR bound to the | |
963 | item, and INDEXVAR (if requested) bound to the item's index. (Note that | |
964 | this is different from most iteration constructs in Common Lisp, which | |
965 | work by mutating the variable.) | |
966 | ||
967 | The loop is surrounded by an anonymous BLOCK and the loop body forms an | |
968 | implicit TAGBODY, as is usual. There is no result-form, however." | |
969 | ||
bacaaec3 MW |
970 | (once-only (:environment env start end) |
971 | (with-gensyms ((seqvar "SEQ-") (ivar "INDEX-") | |
972 | (endvar "END-") (bodyfunc "BODY-")) | |
b8c698ee MW |
973 | (multiple-value-bind (docs decls body) (parse-body body :docp nil) |
974 | (declare (ignore docs)) | |
975 | ||
976 | (flet ((loopguts (indexp listp endvar) | |
977 | ;; Build a DO-loop to do what we want. | |
978 | (let* ((do-vars nil) | |
979 | (end-condition (if endvar | |
980 | `(>= ,ivar ,endvar) | |
bacaaec3 | 981 | `(endp ,seqvar))) |
b8c698ee | 982 | (item (if listp |
bacaaec3 MW |
983 | `(car ,seqvar) |
984 | `(aref ,seqvar ,ivar))) | |
b8c698ee MW |
985 | (body-call `(,bodyfunc ,item))) |
986 | (when listp | |
bacaaec3 | 987 | (push `(,seqvar (nthcdr ,start ,seqvar) (cdr ,seqvar)) |
b8c698ee MW |
988 | do-vars)) |
989 | (when indexp | |
990 | (push `(,ivar ,start (1+ ,ivar)) do-vars)) | |
991 | (when indexvar | |
992 | (setf body-call (append body-call (list ivar)))) | |
993 | `(do ,do-vars (,end-condition) ,body-call)))) | |
994 | ||
995 | `(block nil | |
bacaaec3 MW |
996 | (let ((,seqvar ,seq)) |
997 | (flet ((,bodyfunc (,var ,@(and indexvar `(,indexvar))) | |
998 | ,@decls | |
999 | (tagbody ,@body))) | |
1000 | (etypecase ,seqvar | |
1001 | (vector | |
1002 | (let ((,endvar (or ,end (length ,seqvar)))) | |
1003 | ,(loopguts t nil endvar))) | |
1004 | (list | |
1005 | (if ,end | |
1006 | ,(loopguts t t end) | |
1007 | ,(loopguts indexvar t nil)))))))))))) | |
dea4d055 | 1008 | |
4b8e5c03 MW |
1009 | ;;;-------------------------------------------------------------------------- |
1010 | ;;; Structure accessor hacks. | |
1011 | ||
1012 | (export 'define-access-wrapper) | |
1013 | (defmacro define-access-wrapper (from to &key read-only) | |
1014 | "Make (FROM THING) work like (TO THING). | |
1015 | ||
1016 | If not READ-ONLY, then also make (setf (FROM THING) VALUE) work like | |
1017 | (setf (TO THING) VALUE). | |
1018 | ||
1019 | This is mostly useful for structure slot accessors where the slot has to | |
1020 | be given an unpleasant name to avoid it being an external symbol." | |
1021 | `(progn | |
1022 | (declaim (inline ,from ,@(and (not read-only) `((setf ,from))))) | |
1023 | (defun ,from (object) | |
1024 | (,to object)) | |
1025 | ,@(and (not read-only) | |
1026 | `((defun (setf ,from) (value object) | |
1027 | (setf (,to object) value)))))) | |
1028 | ||
db6c3279 MW |
1029 | ;;;-------------------------------------------------------------------------- |
1030 | ;;; Condition and error utilities. | |
1031 | ||
1032 | (export 'designated-condition) | |
1033 | (defun designated-condition (default-type datum arguments | |
1034 | &key allow-pointless-arguments) | |
1035 | "Return the condition designated by DATUM and ARGUMENTS. | |
1036 | ||
1037 | DATUM and ARGUMENTS together are a `condition designator' of (some | |
1038 | supertype of) DEFAULT-TYPE; return the condition so designated." | |
1039 | (typecase datum | |
1040 | (condition | |
1041 | (unless (or allow-pointless-arguments (null arguments)) | |
1042 | (error "Argument list provided with specific condition")) | |
1043 | datum) | |
1044 | (symbol | |
1045 | (apply #'make-condition datum arguments)) | |
1046 | ((or string function) | |
1047 | (make-condition default-type | |
1048 | :format-control datum | |
1049 | :format-arguments arguments)) | |
1050 | (t | |
1051 | (error "Unexpected condition designator datum ~S" datum)))) | |
1052 | ||
f7b60deb MW |
1053 | (export 'simple-control-error) |
1054 | (define-condition simple-control-error (control-error simple-error) | |
1055 | ()) | |
1056 | ||
1057 | (export 'invoke-associated-restart) | |
1058 | (defun invoke-associated-restart (restart condition &rest arguments) | |
1059 | "Invoke the active RESTART associated with CONDITION, with the ARGUMENTS. | |
1060 | ||
1061 | Find an active restart designated by RESTART; if CONDITION is not nil, | |
1062 | then restrict the search to restarts associated with CONDITION, and | |
1063 | restarts not associated with any condition. If no such restart is found | |
1064 | then signal an error of type `control-error'; otherwise invoke the restart | |
1065 | with the given ARGUMENTS." | |
1066 | (apply #'invoke-restart | |
1067 | (or (find-restart restart condition) | |
1068 | (error 'simple-control-error | |
1069 | :format-control "~:[Restart ~S is not active~;~ | |
1070 | No active `~(~A~)' restart~]~ | |
1071 | ~@[ for condition ~S~]" | |
1072 | :format-arguments (list (symbolp restart) | |
1073 | restart | |
1074 | condition))) | |
1075 | arguments)) | |
1076 | ||
c884ec24 MW |
1077 | (export '(enclosing-condition enclosed-condition)) |
1078 | (define-condition enclosing-condition (condition) | |
1079 | ((%enclosed-condition :initarg :condition :type condition | |
1080 | :reader enclosed-condition)) | |
1081 | (:documentation | |
1082 | "A condition which encloses another condition | |
1083 | ||
1084 | This is useful if one wants to attach additional information to an | |
1085 | existing condition. The enclosed condition can be obtained using the | |
1086 | `enclosed-condition' function.") | |
1087 | (:report (lambda (condition stream) | |
1088 | (princ (enclosed-condition condition) stream)))) | |
1089 | ||
1090 | (export 'information) | |
1091 | (define-condition information (condition) | |
1092 | ()) | |
1093 | ||
1094 | (export 'simple-information) | |
1095 | (define-condition simple-information (simple-condition information) | |
1096 | ()) | |
1097 | ||
1098 | (export 'info) | |
1099 | (defun info (datum &rest arguments) | |
1100 | "Report some useful diagnostic information. | |
1101 | ||
1102 | Establish a simple restart named `noted', and signal the condition of type | |
1103 | `information' designated by DATUM and ARGUMENTS. Return non-nil if the | |
1104 | restart was invoked, otherwise nil." | |
1105 | (restart-case | |
1106 | (signal (designated-condition 'simple-information datum arguments)) | |
1107 | (noted () :report "Noted." t))) | |
1108 | ||
1109 | (export 'noted) | |
1110 | (defun noted (&optional condition) | |
1111 | "Invoke the `noted' restart, possibly associated with the given CONDITION." | |
1112 | (invoke-associated-restart 'noted condition)) | |
1113 | ||
1114 | (export 'promiscuous-cerror) | |
1115 | (defun promiscuous-cerror (continue-string datum &rest arguments) | |
1116 | "Like standard `cerror', but robust against sneaky changes of conditions. | |
1117 | ||
1118 | It seems that `cerror' (well, at least the version in SBCL) is careful | |
1119 | to limit its restart to the specific condition it signalled. But that's | |
1120 | annoying, because `sod-parser:with-default-error-location' substitutes | |
1121 | different conditions carrying the error-location information." | |
1122 | (restart-case (apply #'error datum arguments) | |
1123 | (continue () | |
1124 | :report (lambda (stream) | |
1125 | (apply #'format stream continue-string datum arguments)) | |
1126 | nil))) | |
1127 | ||
1128 | (export 'cerror*) | |
1129 | (defun cerror* (datum &rest arguments) | |
1130 | (apply #'promiscuous-cerror "Continue" datum arguments)) | |
1131 | ||
dea4d055 MW |
1132 | ;;;-------------------------------------------------------------------------- |
1133 | ;;; CLOS hacking. | |
1134 | ||
1135 | (export 'default-slot) | |
1136 | (defmacro default-slot ((instance slot &optional (slot-names t)) | |
1137 | &body value | |
1138 | &environment env) | |
1139 | "If INSTANCE's slot named SLOT is unbound, set it to VALUE. | |
1140 | ||
1141 | Only set SLOT if it's listed in SLOT-NAMES, or SLOT-NAMES is `t' (i.e., we | |
1142 | obey the `shared-initialize' protocol). SLOT-NAMES defaults to `t', so | |
1143 | you can use it in `initialize-instance' or similar without ill effects. | |
1144 | Both INSTANCE and SLOT are evaluated; VALUE is an implicit progn and only | |
1145 | evaluated if it's needed." | |
1146 | ||
1147 | (once-only (:environment env instance slot slot-names) | |
1148 | `(when ,(if (eq slot-names t) | |
1149 | `(not (slot-boundp ,instance ,slot)) | |
1150 | `(and (not (slot-boundp ,instance ,slot)) | |
1151 | (or (eq ,slot-names t) | |
1152 | (member ,slot ,slot-names)))) | |
1153 | (setf (slot-value ,instance ,slot) | |
1154 | (progn ,@value))))) | |
1155 | ||
141283ff MW |
1156 | (export 'define-on-demand-slot) |
1157 | (defmacro define-on-demand-slot (class slot (instance) &body body) | |
1158 | "Defines a slot which computes its initial value on demand. | |
1159 | ||
1160 | Sets up the named SLOT of CLASS to establish its value as the implicit | |
1161 | progn BODY, by defining an appropriate method on `slot-unbound'." | |
b8c698ee MW |
1162 | (multiple-value-bind (docs decls body) (parse-body body) |
1163 | (with-gensyms (classvar slotvar) | |
1164 | `(defmethod slot-unbound | |
1165 | (,classvar (,instance ,class) (,slotvar (eql ',slot))) | |
1166 | ,@docs ,@decls | |
1167 | (declare (ignore ,classvar)) | |
fc09e191 | 1168 | (setf (slot-value ,instance ',slot) (block ,slot ,@body)))))) |
141283ff | 1169 | |
dea4d055 | 1170 | ;;;----- That's all, folks -------------------------------------------------- |