3 ;;;; This software is part of the SBCL system. See the README file for
6 ;;;; This software is derived from the CMU CL system, which was
7 ;;;; written at Carnegie Mellon University and released into the
8 ;;;; public domain. The software is in the public domain and is
9 ;;;; provided with absolutely no warranty. See the COPYING and CREDITS
10 ;;;; files for more information.
12 (in-package "SB!IMPL")
14 ;;;; exported printer control variables
16 ;;; FIXME: Many of these have nontrivial types, e.g. *PRINT-LEVEL*,
17 ;;; *PRINT-LENGTH*, and *PRINT-LINES* are (OR NULL UNSIGNED-BYTE).
19 (defvar *print-readably* nil
21 "If true, all objects will printed readably. If readable printing is
22 impossible, an error will be signalled. This overrides the value of
24 (defvar *print-escape* T
26 "Should we print in a reasonably machine-readable way? (possibly
27 overridden by *PRINT-READABLY*)")
28 (defvar *print-pretty* nil ; (set later when pretty-printer is initialized)
30 "Should pretty printing be used?")
31 (defvar *print-base* 10.
33 "the output base for RATIONALs (including integers)")
34 (defvar *print-radix* nil
36 "Should base be verified when printing RATIONALs?")
37 (defvar *print-level* nil
39 "How many levels should be printed before abbreviating with \"#\"?")
40 (defvar *print-length* nil
42 "How many elements at any level should be printed before abbreviating
44 (defvar *print-circle* nil
46 "Should we use #n= and #n# notation to preserve uniqueness in general (and
47 circularity in particular) when printing?")
48 (defvar *print-case* :upcase
50 "What case should the printer should use default?")
51 (defvar *print-array* t
53 "Should the contents of arrays be printed?")
54 (defvar *print-gensym* t
56 "Should #: prefixes be used when printing symbols with null SYMBOL-PACKAGE?")
57 (defvar *print-lines* nil
59 "the maximum number of lines to print per object")
60 (defvar *print-right-margin* nil
62 "the position of the right margin in ems (for pretty-printing)")
63 (defvar *print-miser-width* nil
65 "If the remaining space between the current column and the right margin
66 is less than this, then print using ``miser-style'' output. Miser
67 style conditional newlines are turned on, and all indentations are
68 turned off. If NIL, never use miser mode.")
69 (defvar *print-pprint-dispatch*)
71 (setf (fdocumentation '*print-pprint-dispatch* 'variable)
72 "the pprint-dispatch-table that controls how to pretty-print objects")
74 (defmacro with-standard-io-syntax (&body body)
76 "Bind the reader and printer control variables to values that enable READ
77 to reliably read the results of PRINT. These values are:
78 *PACKAGE* the COMMON-LISP-USER package
88 *PRINT-MISER-WIDTH* NIL
92 *PRINT-RIGHT-MARGIN* NIL
94 *READ-DEFAULT-FLOAT-FORMAT* SINGLE-FLOAT
97 *READTABLE* the standard readtable"
98 `(%with-standard-io-syntax (lambda () ,@body)))
100 (defun %with-standard-io-syntax (function)
101 (declare (type function function))
102 (let ((*package* (find-package "COMMON-LISP-USER"))
105 (*print-case* :upcase)
112 (*print-miser-width* nil)
116 (*print-right-margin* nil)
118 (*read-default-float-format* 'single-float)
120 (*read-suppress* nil)
121 ;; FIXME: It doesn't seem like a good idea to expose our
122 ;; disaster-recovery *STANDARD-READTABLE* here. What if some
123 ;; enterprising user corrupts the disaster-recovery readtable
124 ;; by doing destructive readtable operations within
125 ;; WITH-STANDARD-IO-SYNTAX? Perhaps we should do a
126 ;; COPY-READTABLE? The consing would be unfortunate, though.
127 (*readtable* *standard-readtable*))
130 ;;;; routines to print objects
132 (defun write (object &key
133 ((:stream stream) *standard-output*)
134 ((:escape *print-escape*) *print-escape*)
135 ((:radix *print-radix*) *print-radix*)
136 ((:base *print-base*) *print-base*)
137 ((:circle *print-circle*) *print-circle*)
138 ((:pretty *print-pretty*) *print-pretty*)
139 ((:level *print-level*) *print-level*)
140 ((:length *print-length*) *print-length*)
141 ((:case *print-case*) *print-case*)
142 ((:array *print-array*) *print-array*)
143 ((:gensym *print-gensym*) *print-gensym*)
144 ((:readably *print-readably*) *print-readably*)
145 ((:right-margin *print-right-margin*)
146 *print-right-margin*)
147 ((:miser-width *print-miser-width*)
149 ((:lines *print-lines*) *print-lines*)
150 ((:pprint-dispatch *print-pprint-dispatch*)
151 *print-pprint-dispatch*))
153 "Output OBJECT to the specified stream, defaulting to *STANDARD-OUTPUT*"
154 (output-object object (out-synonym-of stream))
157 (defun prin1 (object &optional stream)
159 "Output a mostly READable printed representation of OBJECT on the specified
161 (let ((*print-escape* T))
162 (output-object object (out-synonym-of stream)))
165 (defun princ (object &optional stream)
167 "Output an aesthetic but not necessarily READable printed representation
168 of OBJECT on the specified STREAM."
169 (let ((*print-escape* NIL)
170 (*print-readably* NIL))
171 (output-object object (out-synonym-of stream)))
174 (defun print (object &optional stream)
176 "Output a newline, the mostly READable printed representation of OBJECT, and
177 space to the specified STREAM."
178 (let ((stream (out-synonym-of stream)))
180 (prin1 object stream)
181 (write-char #\space stream)
184 (defun pprint (object &optional stream)
186 "Prettily output OBJECT preceded by a newline."
187 (let ((*print-pretty* t)
189 (stream (out-synonym-of stream)))
191 (output-object object stream))
194 (defun write-to-string
196 ((:escape *print-escape*) *print-escape*)
197 ((:radix *print-radix*) *print-radix*)
198 ((:base *print-base*) *print-base*)
199 ((:circle *print-circle*) *print-circle*)
200 ((:pretty *print-pretty*) *print-pretty*)
201 ((:level *print-level*) *print-level*)
202 ((:length *print-length*) *print-length*)
203 ((:case *print-case*) *print-case*)
204 ((:array *print-array*) *print-array*)
205 ((:gensym *print-gensym*) *print-gensym*)
206 ((:readably *print-readably*) *print-readably*)
207 ((:right-margin *print-right-margin*) *print-right-margin*)
208 ((:miser-width *print-miser-width*) *print-miser-width*)
209 ((:lines *print-lines*) *print-lines*)
210 ((:pprint-dispatch *print-pprint-dispatch*)
211 *print-pprint-dispatch*))
213 "Return the printed representation of OBJECT as a string."
214 (stringify-object object))
216 (defun prin1-to-string (object)
218 "Return the printed representation of OBJECT as a string with
220 (stringify-object object t))
222 (defun princ-to-string (object)
224 "Return the printed representation of OBJECT as a string with
226 (stringify-object object nil))
228 ;;; This produces the printed representation of an object as a string.
229 ;;; The few ...-TO-STRING functions above call this.
230 (defvar *string-output-streams* ())
231 (defun stringify-object (object &optional (*print-escape* *print-escape*))
232 (let ((stream (if *string-output-streams*
233 (pop *string-output-streams*)
234 (make-string-output-stream))))
235 (setup-printer-state)
236 (output-object object stream)
238 (get-output-stream-string stream)
239 (push stream *string-output-streams*))))
241 ;;;; support for the PRINT-UNREADABLE-OBJECT macro
243 ;;; guts of PRINT-UNREADABLE-OBJECT
244 (defun %print-unreadable-object (object stream type identity body)
245 (declare (type (or null function) body))
246 (when *print-readably*
247 (error 'print-not-readable :object object))
248 (flet ((print-description ()
250 (write (type-of object) :stream stream :circle nil
251 :level nil :length nil)
252 (when (or body identity)
253 (write-char #\space stream)
254 (pprint-newline :fill stream)))
259 (write-char #\space stream)
260 (pprint-newline :fill stream))
261 (write-char #\{ stream)
262 (write (get-lisp-obj-address object) :stream stream
264 (write-char #\} stream))))
265 (cond ((print-pretty-on-stream-p stream)
266 ;; Since we're printing prettily on STREAM, format the
267 ;; object within a logical block. PPRINT-LOGICAL-BLOCK does
268 ;; not rebind the stream when it is already a pretty stream,
269 ;; so output from the body will go to the same stream.
270 (pprint-logical-block (stream nil :prefix "#<" :suffix ">")
271 (print-description)))
273 (write-string "#<" stream)
275 (write-char #\> stream))))
278 ;;;; circularity detection stuff
280 ;;; When *PRINT-CIRCLE* is T, this gets bound to a hash table that
281 ;;; (eventually) ends up with entries for every object printed. When
282 ;;; we are initially looking for circularities, we enter a T when we
283 ;;; find an object for the first time, and a 0 when we encounter an
284 ;;; object a second time around. When we are actually printing, the 0
285 ;;; entries get changed to the actual marker value when they are first
287 (defvar *circularity-hash-table* nil)
289 ;;; When NIL, we are just looking for circularities. After we have
290 ;;; found them all, this gets bound to 0. Then whenever we need a new
291 ;;; marker, it is incremented.
292 (defvar *circularity-counter* nil)
294 ;;; Check to see whether OBJECT is a circular reference, and return
295 ;;; something non-NIL if it is. If ASSIGN is T, then the number to use
296 ;;; in the #n= and #n# noise is assigned at this time.
297 ;;; If ASSIGN is true, reference bookkeeping will only be done for
298 ;;; existing entries, no new references will be recorded!
300 ;;; Note: CHECK-FOR-CIRCULARITY must be called *exactly* once with
301 ;;; ASSIGN true, or the circularity detection noise will get confused
302 ;;; about when to use #n= and when to use #n#. If this returns non-NIL
303 ;;; when ASSIGN is true, then you must call HANDLE-CIRCULARITY on it.
304 ;;; If CHECK-FOR-CIRCULARITY returns :INITIATE as the second value,
305 ;;; you need to initiate the circularity detection noise, e.g. bind
306 ;;; *CIRCULARITY-HASH-TABLE* and *CIRCULARITY-COUNTER* to suitable values
307 ;;; (see #'OUTPUT-OBJECT for an example).
308 (defun check-for-circularity (object &optional assign)
309 (cond ((null *print-circle*)
310 ;; Don't bother, nobody cares.
312 ((null *circularity-hash-table*)
313 (values nil :initiate))
314 ((null *circularity-counter*)
315 (ecase (gethash object *circularity-hash-table*)
318 (setf (gethash object *circularity-hash-table*) t)
319 ;; We need to keep looking.
323 (setf (gethash object *circularity-hash-table*) 0)
324 ;; It's a circular reference.
327 ;; It's a circular reference.
330 (let ((value (gethash object *circularity-hash-table*)))
333 ;; If NIL, we found an object that wasn't there the
334 ;; first time around. If T, this object appears exactly
335 ;; once. Either way, just print the thing without any
336 ;; special processing. Note: you might argue that
337 ;; finding a new object means that something is broken,
338 ;; but this can happen. If someone uses the ~@<...~:>
339 ;; format directive, it conses a new list each time
340 ;; though format (i.e. the &REST list), so we will have
345 (let ((value (incf *circularity-counter*)))
346 ;; first occurrence of this object: Set the counter.
347 (setf (gethash object *circularity-hash-table*) value)
351 ;; second or later occurrence
354 ;;; Handle the results of CHECK-FOR-CIRCULARITY. If this returns T then
355 ;;; you should go ahead and print the object. If it returns NIL, then
356 ;;; you should blow it off.
357 (defun handle-circularity (marker stream)
360 ;; Someone forgot to initiate circularity detection.
361 (let ((*print-circle* nil))
362 (error "trying to use CHECK-FOR-CIRCULARITY when ~
363 circularity checking isn't initiated")))
365 ;; It's a second (or later) reference to the object while we are
366 ;; just looking. So don't bother groveling it again.
369 (write-char #\# stream)
370 (let ((*print-base* 10) (*print-radix* nil))
371 (cond ((minusp marker)
372 (output-integer (- marker) stream)
373 (write-char #\# stream)
376 (output-integer marker stream)
377 (write-char #\= stream)
380 ;;;; OUTPUT-OBJECT -- the main entry point
382 ;;; Objects whose print representation identifies them EQLly don't
383 ;;; need to be checked for circularity.
384 (defun uniquely-identified-by-print-p (x)
388 (symbol-package x))))
390 ;;; Output OBJECT to STREAM observing all printer control variables.
391 (defun output-object (object stream)
392 (labels ((print-it (stream)
394 (sb!pretty:output-pretty-object object stream)
395 (output-ugly-object object stream)))
397 (multiple-value-bind (marker initiate)
398 (check-for-circularity object t)
399 ;; initialization of the circulation detect noise ...
400 (if (eq initiate :initiate)
401 (let ((*circularity-hash-table*
402 (make-hash-table :test 'eq)))
403 (check-it (make-broadcast-stream))
404 (let ((*circularity-counter* 0))
408 (when (handle-circularity marker stream)
410 (print-it stream))))))
411 (cond (;; Maybe we don't need to bother with circularity detection.
412 (or (not *print-circle*)
413 (uniquely-identified-by-print-p object))
415 (;; If we have already started circularity detection, this
416 ;; object might be a shared reference. If we have not, then
417 ;; if it is a compound object it might contain a circular
418 ;; reference to itself or multiple shared references.
419 (or *circularity-hash-table*
420 (compound-object-p object))
423 (print-it stream)))))
425 ;;; a hack to work around recurring gotchas with printing while
426 ;;; DEFGENERIC PRINT-OBJECT is being built
428 ;;; (hopefully will go away naturally when CLOS moves into cold init)
429 (defvar *print-object-is-disabled-p*)
431 ;;; Output OBJECT to STREAM observing all printer control variables
432 ;;; except for *PRINT-PRETTY*. Note: if *PRINT-PRETTY* is non-NIL,
433 ;;; then the pretty printer will be used for any components of OBJECT,
434 ;;; just not for OBJECT itself.
435 (defun output-ugly-object (object stream)
437 ;; KLUDGE: The TYPECASE approach here is non-ANSI; the ANSI definition of
438 ;; PRINT-OBJECT says it provides printing and we're supposed to provide
439 ;; PRINT-OBJECT methods covering all classes. We deviate from this
440 ;; by using PRINT-OBJECT only when we print instance values. However,
441 ;; ANSI makes it hard to tell that we're deviating from this:
442 ;; (1) ANSI specifies that the user isn't supposed to call PRINT-OBJECT
444 ;; (2) ANSI (section 11.1.2.1.2) says it's undefined to define
445 ;; a method on an external symbol in the CL package which is
446 ;; applicable to arg lists containing only direct instances of
447 ;; standardized classes.
448 ;; Thus, in order for the user to detect our sleaziness in conforming
449 ;; code, he has to do something relatively obscure like
450 ;; (1) actually use tools like FIND-METHOD to look for PRINT-OBJECT
452 ;; (2) define a PRINT-OBJECT method which is specialized on the stream
453 ;; value (e.g. a Gray stream object).
454 ;; As long as no one comes up with a non-obscure way of detecting this
455 ;; sleaziness, fixing this nonconformity will probably have a low
456 ;; priority. -- WHN 2001-11-25
458 (output-integer object stream))
461 (output-symbol object stream)
462 (output-list object stream)))
464 (cond ((not (and (boundp '*print-object-is-disabled-p*)
465 *print-object-is-disabled-p*))
466 (print-object object stream))
467 ((typep object 'structure-object)
468 (default-structure-print object stream *current-level-in-print*))
470 (write-string "#<INSTANCE but not STRUCTURE-OBJECT>" stream))))
472 (unless (and (funcallable-instance-p object)
473 (printed-as-funcallable-standard-class object stream))
474 (output-fun object stream)))
476 (output-symbol object stream))
480 (output-integer object stream))
482 (output-float object stream))
484 (output-ratio object stream))
486 (output-ratio object stream))
488 (output-complex object stream))))
490 (output-character object stream))
492 (output-vector object stream))
494 (output-array object stream))
496 (output-sap object stream))
498 (output-weak-pointer object stream))
500 (output-lra object stream))
502 (output-code-component object stream))
504 (output-fdefn object stream))
506 (output-random object stream))))
510 ;;; values of *PRINT-CASE* and (READTABLE-CASE *READTABLE*) the last
511 ;;; time the printer was called
512 (defvar *previous-case* nil)
513 (defvar *previous-readtable-case* nil)
515 ;;; This variable contains the current definition of one of three
516 ;;; symbol printers. SETUP-PRINTER-STATE sets this variable.
517 (defvar *internal-symbol-output-fun* nil)
519 ;;; This function sets the internal global symbol
520 ;;; *INTERNAL-SYMBOL-OUTPUT-FUN* to the right function depending on
521 ;;; the value of *PRINT-CASE*. See the manual for details. The print
522 ;;; buffer stream is also reset.
523 (defun setup-printer-state ()
524 (unless (and (eq *print-case* *previous-case*)
525 (eq (readtable-case *readtable*) *previous-readtable-case*))
526 (setq *previous-case* *print-case*)
527 (setq *previous-readtable-case* (readtable-case *readtable*))
528 (unless (member *print-case* '(:upcase :downcase :capitalize))
529 (setq *print-case* :upcase)
530 (error "invalid *PRINT-CASE* value: ~S" *previous-case*))
531 (unless (member *previous-readtable-case*
532 '(:upcase :downcase :invert :preserve))
533 (setf (readtable-case *readtable*) :upcase)
534 (error "invalid READTABLE-CASE value: ~S" *previous-readtable-case*))
536 (setq *internal-symbol-output-fun*
537 (case *previous-readtable-case*
540 (:upcase #'output-preserve-symbol)
541 (:downcase #'output-lowercase-symbol)
542 (:capitalize #'output-capitalize-symbol)))
545 (:upcase #'output-uppercase-symbol)
546 (:downcase #'output-preserve-symbol)
547 (:capitalize #'output-capitalize-symbol)))
548 (:preserve #'output-preserve-symbol)
549 (:invert #'output-invert-symbol)))))
551 ;;; Output PNAME (a symbol-name or package-name) surrounded with |'s,
552 ;;; and with any embedded |'s or \'s escaped.
553 (defun output-quoted-symbol-name (pname stream)
554 (write-char #\| stream)
555 (dotimes (index (length pname))
556 (let ((char (schar pname index)))
557 (when (or (char= char #\\) (char= char #\|))
558 (write-char #\\ stream))
559 (write-char char stream)))
560 (write-char #\| stream))
562 (defun output-symbol (object stream)
563 (if (or *print-escape* *print-readably*)
564 (let ((package (symbol-package object))
565 (name (symbol-name object)))
567 ;; The ANSI spec "22.1.3.3.1 Package Prefixes for Symbols"
568 ;; requires that keywords be printed with preceding colons
569 ;; always, regardless of the value of *PACKAGE*.
570 ((eq package *keyword-package*)
571 (write-char #\: stream))
572 ;; Otherwise, if the symbol's home package is the current
573 ;; one, then a prefix is never necessary.
574 ((eq package (sane-package)))
575 ;; Uninterned symbols print with a leading #:.
577 (when (or *print-gensym* *print-readably*)
578 (write-string "#:" stream)))
580 (multiple-value-bind (symbol accessible)
581 (find-symbol name (sane-package))
582 ;; If we can find the symbol by looking it up, it need not
583 ;; be qualified. This can happen if the symbol has been
584 ;; inherited from a package other than its home package.
585 (unless (and accessible (eq symbol object))
586 (output-symbol-name (package-name package) stream)
587 (multiple-value-bind (symbol externalp)
588 (find-external-symbol name package)
589 (declare (ignore symbol))
591 (write-char #\: stream)
592 (write-string "::" stream)))))))
593 (output-symbol-name name stream))
594 (output-symbol-name (symbol-name object) stream nil)))
596 ;;; Output the string NAME as if it were a symbol name. In other
597 ;;; words, diddle its case according to *PRINT-CASE* and
599 (defun output-symbol-name (name stream &optional (maybe-quote t))
600 (declare (type simple-base-string name))
601 (setup-printer-state)
602 (if (and maybe-quote (symbol-quotep name))
603 (output-quoted-symbol-name name stream)
604 (funcall *internal-symbol-output-fun* name stream)))
606 ;;;; escaping symbols
608 ;;; When we print symbols we have to figure out if they need to be
609 ;;; printed with escape characters. This isn't a whole lot easier than
610 ;;; reading symbols in the first place.
612 ;;; For each character, the value of the corresponding element is a
613 ;;; fixnum with bits set corresponding to attributes that the
614 ;;; character has. At characters have at least one bit set, so we can
615 ;;; search for any character with a positive test.
616 (defvar *character-attributes*
617 (make-array char-code-limit
618 :element-type '(unsigned-byte 16)
620 (declaim (type (simple-array (unsigned-byte 16) (#.char-code-limit))
621 *character-attributes*))
623 ;;; constants which are a bit-mask for each interesting character attribute
624 (defconstant other-attribute (ash 1 0)) ; Anything else legal.
625 (defconstant number-attribute (ash 1 1)) ; A numeric digit.
626 (defconstant uppercase-attribute (ash 1 2)) ; An uppercase letter.
627 (defconstant lowercase-attribute (ash 1 3)) ; A lowercase letter.
628 (defconstant sign-attribute (ash 1 4)) ; +-
629 (defconstant extension-attribute (ash 1 5)) ; ^_
630 (defconstant dot-attribute (ash 1 6)) ; .
631 (defconstant slash-attribute (ash 1 7)) ; /
632 (defconstant funny-attribute (ash 1 8)) ; Anything illegal.
634 (eval-when (:compile-toplevel :load-toplevel :execute)
636 ;;; LETTER-ATTRIBUTE is a local of SYMBOL-QUOTEP. It matches letters
637 ;;; that don't need to be escaped (according to READTABLE-CASE.)
638 (defparameter *attribute-names*
639 `((number . number-attribute) (lowercase . lowercase-attribute)
640 (uppercase . uppercase-attribute) (letter . letter-attribute)
641 (sign . sign-attribute) (extension . extension-attribute)
642 (dot . dot-attribute) (slash . slash-attribute)
643 (other . other-attribute) (funny . funny-attribute)))
647 (flet ((set-bit (char bit)
648 (let ((code (char-code char)))
649 (setf (aref *character-attributes* code)
650 (logior bit (aref *character-attributes* code))))))
652 (dolist (char '(#\! #\@ #\$ #\% #\& #\* #\= #\~ #\[ #\] #\{ #\}
654 (set-bit char other-attribute))
657 (set-bit (digit-char i) number-attribute))
659 (do ((code (char-code #\A) (1+ code))
660 (end (char-code #\Z)))
662 (declare (fixnum code end))
663 (set-bit (code-char code) uppercase-attribute)
664 (set-bit (char-downcase (code-char code)) lowercase-attribute))
666 (set-bit #\- sign-attribute)
667 (set-bit #\+ sign-attribute)
668 (set-bit #\^ extension-attribute)
669 (set-bit #\_ extension-attribute)
670 (set-bit #\. dot-attribute)
671 (set-bit #\/ slash-attribute)
673 ;; Mark anything not explicitly allowed as funny.
674 (dotimes (i char-code-limit)
675 (when (zerop (aref *character-attributes* i))
676 (setf (aref *character-attributes* i) funny-attribute))))
678 ;;; For each character, the value of the corresponding element is the
679 ;;; lowest base in which that character is a digit.
680 (defvar *digit-bases*
681 (make-array char-code-limit
682 :element-type '(unsigned-byte 8)
683 :initial-element 36))
684 (declaim (type (simple-array (unsigned-byte 8) (#.char-code-limit))
687 (let ((char (digit-char i 36)))
688 (setf (aref *digit-bases* (char-code char)) i)))
690 ;;; A FSM-like thingie that determines whether a symbol is a potential
691 ;;; number or has evil characters in it.
692 (defun symbol-quotep (name)
693 (declare (simple-string name))
694 (macrolet ((advance (tag &optional (at-end t))
697 ,(if at-end '(go TEST-SIGN) '(return nil)))
698 (setq current (schar name index)
699 code (char-code current)
700 bits (aref attributes code))
703 (test (&rest attributes)
715 `(< (the fixnum (aref bases code)) base)))
717 (prog ((len (length name))
718 (attributes *character-attributes*)
719 (bases *digit-bases*)
722 (case (readtable-case *readtable*)
723 (:upcase uppercase-attribute)
724 (:downcase lowercase-attribute)
725 (t (logior lowercase-attribute uppercase-attribute))))
730 (declare (fixnum len base index bits code))
733 TEST-SIGN ; At end, see whether it is a sign...
734 (return (not (test sign)))
736 OTHER ; not potential number, see whether funny chars...
737 (let ((mask (logxor (logior lowercase-attribute uppercase-attribute
740 (do ((i (1- index) (1+ i)))
741 ((= i len) (return-from symbol-quotep nil))
742 (unless (zerop (logand (aref attributes (char-code (schar name i)))
744 (return-from symbol-quotep t))))
749 (advance LAST-DIGIT-ALPHA)
751 (when (test letter number other slash) (advance OTHER nil))
752 (when (char= current #\.) (advance DOT-FOUND))
753 (when (test sign extension) (advance START-STUFF nil))
756 DOT-FOUND ; leading dots...
757 (when (test letter) (advance START-DOT-MARKER nil))
758 (when (digitp) (advance DOT-DIGIT))
759 (when (test number other) (advance OTHER nil))
760 (when (test extension slash sign) (advance START-DOT-STUFF nil))
761 (when (char= current #\.) (advance DOT-FOUND))
764 START-STUFF ; leading stuff before any dot or digit
767 (advance LAST-DIGIT-ALPHA)
769 (when (test number other) (advance OTHER nil))
770 (when (test letter) (advance START-MARKER nil))
771 (when (char= current #\.) (advance START-DOT-STUFF nil))
772 (when (test sign extension slash) (advance START-STUFF nil))
775 START-MARKER ; number marker in leading stuff...
776 (when (test letter) (advance OTHER nil))
779 START-DOT-STUFF ; leading stuff containing dot without digit...
780 (when (test letter) (advance START-DOT-STUFF nil))
781 (when (digitp) (advance DOT-DIGIT))
782 (when (test sign extension dot slash) (advance START-DOT-STUFF nil))
783 (when (test number other) (advance OTHER nil))
786 START-DOT-MARKER ; number marker in leading stuff with dot..
787 ;; leading stuff containing dot without digit followed by letter...
788 (when (test letter) (advance OTHER nil))
791 DOT-DIGIT ; in a thing with dots...
792 (when (test letter) (advance DOT-MARKER))
793 (when (digitp) (advance DOT-DIGIT))
794 (when (test number other) (advance OTHER nil))
795 (when (test sign extension dot slash) (advance DOT-DIGIT))
798 DOT-MARKER ; number marker in number with dot...
799 (when (test letter) (advance OTHER nil))
802 LAST-DIGIT-ALPHA ; previous char is a letter digit...
803 (when (or (digitp) (test sign slash))
804 (advance ALPHA-DIGIT))
805 (when (test letter number other dot) (advance OTHER nil))
808 ALPHA-DIGIT ; seen a digit which is a letter...
809 (when (or (digitp) (test sign slash))
811 (advance LAST-DIGIT-ALPHA)
812 (advance ALPHA-DIGIT)))
813 (when (test letter) (advance ALPHA-MARKER))
814 (when (test number other dot) (advance OTHER nil))
817 ALPHA-MARKER ; number marker in number with alpha digit...
818 (when (test letter) (advance OTHER nil))
821 DIGIT ; seen only ordinary (non-alphabetic) numeric digits...
824 (advance ALPHA-DIGIT)
826 (when (test number other) (advance OTHER nil))
827 (when (test letter) (advance MARKER))
828 (when (test extension slash sign) (advance DIGIT))
829 (when (char= current #\.) (advance DOT-DIGIT))
832 MARKER ; number marker in a numeric number...
833 ;; ("What," you may ask, "is a 'number marker'?" It's something
834 ;; that a conforming implementation might use in number syntax.
835 ;; See ANSI 2.3.1.1 "Potential Numbers as Tokens".)
836 (when (test letter) (advance OTHER nil))
839 ;;;; *INTERNAL-SYMBOL-OUTPUT-FUN*
841 ;;;; case hackery: These functions are stored in
842 ;;;; *INTERNAL-SYMBOL-OUTPUT-FUN* according to the values of
843 ;;;; *PRINT-CASE* and READTABLE-CASE.
846 ;;; READTABLE-CASE *PRINT-CASE*
848 ;;; :DOWNCASE :DOWNCASE
850 (defun output-preserve-symbol (pname stream)
851 (declare (simple-string pname))
852 (write-string pname stream))
855 ;;; READTABLE-CASE *PRINT-CASE*
856 ;;; :UPCASE :DOWNCASE
857 (defun output-lowercase-symbol (pname stream)
858 (declare (simple-string pname))
859 (dotimes (index (length pname))
860 (let ((char (schar pname index)))
861 (write-char (char-downcase char) stream))))
864 ;;; READTABLE-CASE *PRINT-CASE*
865 ;;; :DOWNCASE :UPCASE
866 (defun output-uppercase-symbol (pname stream)
867 (declare (simple-string pname))
868 (dotimes (index (length pname))
869 (let ((char (schar pname index)))
870 (write-char (char-upcase char) stream))))
873 ;;; READTABLE-CASE *PRINT-CASE*
874 ;;; :UPCASE :CAPITALIZE
875 ;;; :DOWNCASE :CAPITALIZE
876 (defun output-capitalize-symbol (pname stream)
877 (declare (simple-string pname))
878 (let ((prev-not-alpha t)
879 (up (eq (readtable-case *readtable*) :upcase)))
880 (dotimes (i (length pname))
881 (let ((char (char pname i)))
883 (if (or prev-not-alpha (lower-case-p char))
885 (char-downcase char))
890 (setq prev-not-alpha (not (alpha-char-p char)))))))
893 ;;; READTABLE-CASE *PRINT-CASE*
895 (defun output-invert-symbol (pname stream)
896 (declare (simple-string pname))
899 (dotimes (i (length pname))
900 (let ((ch (schar pname i)))
901 (when (both-case-p ch)
902 (if (upper-case-p ch)
904 (setq all-upper nil)))))
905 (cond (all-upper (output-lowercase-symbol pname stream))
906 (all-lower (output-uppercase-symbol pname stream))
908 (write-string pname stream)))))
912 (let ((*readtable* (copy-readtable nil)))
913 (format t "READTABLE-CASE Input Symbol-name~@
914 ----------------------------------~%")
915 (dolist (readtable-case '(:upcase :downcase :preserve :invert))
916 (setf (readtable-case *readtable*) readtable-case)
917 (dolist (input '("ZEBRA" "Zebra" "zebra"))
918 (format t "~&:~A~16T~A~24T~A"
919 (string-upcase readtable-case)
921 (symbol-name (read-from-string input)))))))
924 (let ((*readtable* (copy-readtable nil)))
925 (format t "READTABLE-CASE *PRINT-CASE* Symbol-name Output Princ~@
926 --------------------------------------------------------~%")
927 (dolist (readtable-case '(:upcase :downcase :preserve :invert))
928 (setf (readtable-case *readtable*) readtable-case)
929 (dolist (*print-case* '(:upcase :downcase :capitalize))
930 (dolist (symbol '(|ZEBRA| |Zebra| |zebra|))
931 (format t "~&:~A~15T:~A~29T~A~42T~A~50T~A"
932 (string-upcase readtable-case)
933 (string-upcase *print-case*)
935 (prin1-to-string symbol)
936 (princ-to-string symbol)))))))
939 ;;;; recursive objects
941 (defun output-list (list stream)
942 (descend-into (stream)
943 (write-char #\( stream)
947 (punt-print-if-too-long length stream)
948 (output-object (pop list) stream)
951 (when (or (atom list)
952 (check-for-circularity list))
953 (write-string " . " stream)
954 (output-object list stream)
956 (write-char #\space stream)
958 (write-char #\) stream)))
960 (defun output-vector (vector stream)
961 (declare (vector vector))
962 (cond ((stringp vector)
963 (cond ((or *print-escape* *print-readably*)
964 (write-char #\" stream)
965 (quote-string vector stream)
966 (write-char #\" stream))
968 (write-string vector stream))))
969 ((not (or *print-array* *print-readably*))
970 (output-terse-array vector stream))
971 ((bit-vector-p vector)
972 (write-string "#*" stream)
973 (dovector (bit vector)
974 ;; (Don't use OUTPUT-OBJECT here, since this code
975 ;; has to work for all possible *PRINT-BASE* values.)
976 (write-char (if (zerop bit) #\0 #\1) stream)))
978 (when (and *print-readably*
979 (not (array-readably-printable-p array)))
980 (error 'print-not-readable :object vector))
981 (descend-into (stream)
982 (write-string "#(" stream)
983 (dotimes (i (length vector))
985 (write-char #\space stream))
986 (punt-print-if-too-long i stream)
987 (output-object (aref vector i) stream))
988 (write-string ")" stream)))))
990 ;;; This function outputs a string quoting characters sufficiently
991 ;;; so that someone can read it in again. Basically, put a slash in
992 ;;; front of an character satisfying NEEDS-SLASH-P.
993 (defun quote-string (string stream)
994 (macrolet ((needs-slash-p (char)
995 ;; KLUDGE: We probably should look at the readtable, but just do
996 ;; this for now. [noted by anonymous long ago] -- WHN 19991130
997 `(or (char= ,char #\\)
999 (with-array-data ((data string) (start) (end (length string)))
1000 (do ((index start (1+ index)))
1002 (let ((char (schar data index)))
1003 (when (needs-slash-p char) (write-char #\\ stream))
1004 (write-char char stream))))))
1006 (defun array-readably-printable-p (array)
1007 (and (eq (array-element-type array) t)
1008 (let ((zero (position 0 (array-dimensions array)))
1009 (number (position 0 (array-dimensions array)
1010 :test (complement #'eql)
1012 (or (null zero) (null number) (> zero number)))))
1014 ;;; Output the printed representation of any array in either the #< or #A
1016 (defun output-array (array stream)
1017 (if (or *print-array* *print-readably*)
1018 (output-array-guts array stream)
1019 (output-terse-array array stream)))
1021 ;;; Output the abbreviated #< form of an array.
1022 (defun output-terse-array (array stream)
1023 (let ((*print-level* nil)
1024 (*print-length* nil))
1025 (print-unreadable-object (array stream :type t :identity t))))
1027 ;;; Output the readable #A form of an array.
1028 (defun output-array-guts (array stream)
1029 (when (and *print-readably*
1030 (not (array-readably-printable-p array)))
1031 (error 'print-not-readable :object array))
1032 (write-char #\# stream)
1033 (let ((*print-base* 10))
1034 (output-integer (array-rank array) stream))
1035 (write-char #\A stream)
1036 (with-array-data ((data array) (start) (end))
1037 (declare (ignore end))
1038 (sub-output-array-guts data (array-dimensions array) stream start)))
1040 (defun sub-output-array-guts (array dimensions stream index)
1041 (declare (type (simple-array * (*)) array) (fixnum index))
1042 (cond ((null dimensions)
1043 (output-object (aref array index) stream))
1045 (descend-into (stream)
1046 (write-char #\( stream)
1047 (let* ((dimension (car dimensions))
1048 (dimensions (cdr dimensions))
1049 (count (reduce #'* dimensions)))
1050 (dotimes (i dimension)
1052 (write-char #\space stream))
1053 (punt-print-if-too-long i stream)
1054 (sub-output-array-guts array dimensions stream index)
1055 (incf index count)))
1056 (write-char #\) stream)))))
1058 ;;; a trivial non-generic-function placeholder for PRINT-OBJECT, for
1059 ;;; use until CLOS is set up (at which time it will be replaced with
1060 ;;; the real generic function implementation)
1061 (defun print-object (instance stream)
1062 (default-structure-print instance stream *current-level-in-print*))
1064 ;;;; integer, ratio, and complex printing (i.e. everything but floats)
1066 (defun output-integer (integer stream)
1067 ;; FIXME: This UNLESS form should be pulled out into something like
1068 ;; (SANE-PRINT-BASE), along the lines of (SANE-PACKAGE) for the
1069 ;; *PACKAGE* variable.
1070 (unless (and (fixnump *print-base*)
1071 (< 1 *print-base* 37))
1072 (let ((obase *print-base*))
1073 (setq *print-base* 10.)
1074 (error "~A is not a reasonable value for *PRINT-BASE*." obase)))
1075 (when (and (not (= *print-base* 10.))
1077 ;; First print leading base information, if any.
1078 (write-char #\# stream)
1079 (write-char (case *print-base*
1083 (T (let ((fixbase *print-base*)
1086 (sub-output-integer fixbase stream))
1089 ;; Then output a minus sign if the number is negative, then output
1090 ;; the absolute value of the number.
1091 (cond ((bignump integer) (print-bignum integer stream))
1093 (write-char #\- stream)
1094 (sub-output-integer (- integer) stream))
1096 (sub-output-integer integer stream)))
1097 ;; Print any trailing base information, if any.
1098 (if (and (= *print-base* 10.) *print-radix*)
1099 (write-char #\. stream)))
1101 (defun sub-output-integer (integer stream)
1104 ;; Recurse until you have all the digits pushed on the stack.
1105 (if (not (zerop (multiple-value-setq (quotient remainder)
1106 (truncate integer *print-base*))))
1107 (sub-output-integer quotient stream))
1108 ;; Then as each recursive call unwinds, turn the digit (in remainder)
1109 ;; into a character and output the character.
1110 (write-char (code-char (if (and (> remainder 9.)
1111 (> *print-base* 10.))
1112 (+ (char-code #\A) (- remainder 10.))
1113 (+ (char-code #\0) remainder)))
1116 ;;;; bignum printing
1118 ;;; *BASE-POWER* holds the number that we keep dividing into the
1119 ;;; bignum for each *print-base*. We want this number as close to
1120 ;;; *most-positive-fixnum* as possible, i.e. (floor (log
1121 ;;; most-positive-fixnum *print-base*)).
1122 (defparameter *base-power* (make-array 37 :initial-element nil))
1124 ;;; *FIXNUM-POWER--1* holds the number of digits for each *PRINT-BASE*
1125 ;;; that fit in the corresponding *base-power*.
1126 (defparameter *fixnum-power--1* (make-array 37 :initial-element nil))
1128 ;;; Print the bignum to the stream. We first generate the correct
1129 ;;; value for *base-power* and *fixnum-power--1* if we have not
1130 ;;; already. Then we call bignum-print-aux to do the printing.
1131 (defun print-bignum (big stream)
1132 (unless (aref *base-power* *print-base*)
1133 (do ((power-1 -1 (1+ power-1))
1134 (new-divisor *print-base* (* new-divisor *print-base*))
1135 (divisor 1 new-divisor))
1136 ((not (fixnump new-divisor))
1137 (setf (aref *base-power* *print-base*) divisor)
1138 (setf (aref *fixnum-power--1* *print-base*) power-1))))
1139 (bignum-print-aux (cond ((minusp big)
1140 (write-char #\- stream)
1143 (aref *base-power* *print-base*)
1144 (aref *fixnum-power--1* *print-base*)
1148 (defun bignum-print-aux (big divisor power-1 stream)
1149 (multiple-value-bind (newbig fix) (truncate big divisor)
1150 (if (fixnump newbig)
1151 (sub-output-integer newbig stream)
1152 (bignum-print-aux newbig divisor power-1 stream))
1153 (do ((zeros power-1 (1- zeros))
1154 (base-power *print-base* (* base-power *print-base*)))
1156 (dotimes (i zeros) (write-char #\0 stream))
1157 (sub-output-integer fix stream)))))
1159 (defun output-ratio (ratio stream)
1161 (write-char #\# stream)
1163 (2 (write-char #\b stream))
1164 (8 (write-char #\o stream))
1165 (16 (write-char #\x stream))
1166 (t (write *print-base* :stream stream :radix nil :base 10)))
1167 (write-char #\r stream))
1168 (let ((*print-radix* nil))
1169 (output-integer (numerator ratio) stream)
1170 (write-char #\/ stream)
1171 (output-integer (denominator ratio) stream)))
1173 (defun output-complex (complex stream)
1174 (write-string "#C(" stream)
1175 (output-object (realpart complex) stream)
1176 (write-char #\space stream)
1177 (output-object (imagpart complex) stream)
1178 (write-char #\) stream))
1182 ;;; FLONUM-TO-STRING (and its subsidiary function FLOAT-STRING) does
1183 ;;; most of the work for all printing of floating point numbers in the
1184 ;;; printer and in FORMAT. It converts a floating point number to a
1185 ;;; string in a free or fixed format with no exponent. The
1186 ;;; interpretation of the arguments is as follows:
1188 ;;; X - The floating point number to convert, which must not be
1190 ;;; WIDTH - The preferred field width, used to determine the number
1191 ;;; of fraction digits to produce if the FDIGITS parameter
1192 ;;; is unspecified or NIL. If the non-fraction digits and the
1193 ;;; decimal point alone exceed this width, no fraction digits
1194 ;;; will be produced unless a non-NIL value of FDIGITS has been
1195 ;;; specified. Field overflow is not considerd an error at this
1197 ;;; FDIGITS - The number of fractional digits to produce. Insignificant
1198 ;;; trailing zeroes may be introduced as needed. May be
1199 ;;; unspecified or NIL, in which case as many digits as possible
1200 ;;; are generated, subject to the constraint that there are no
1201 ;;; trailing zeroes.
1202 ;;; SCALE - If this parameter is specified or non-NIL, then the number
1203 ;;; printed is (* x (expt 10 scale)). This scaling is exact,
1204 ;;; and cannot lose precision.
1205 ;;; FMIN - This parameter, if specified or non-NIL, is the minimum
1206 ;;; number of fraction digits which will be produced, regardless
1207 ;;; of the value of WIDTH or FDIGITS. This feature is used by
1208 ;;; the ~E format directive to prevent complete loss of
1209 ;;; significance in the printed value due to a bogus choice of
1212 ;;; Most of the optional arguments are for the benefit for FORMAT and are not
1213 ;;; used by the printer.
1216 ;;; (VALUES DIGIT-STRING DIGIT-LENGTH LEADING-POINT TRAILING-POINT DECPNT)
1217 ;;; where the results have the following interpretation:
1219 ;;; DIGIT-STRING - The decimal representation of X, with decimal point.
1220 ;;; DIGIT-LENGTH - The length of the string DIGIT-STRING.
1221 ;;; LEADING-POINT - True if the first character of DIGIT-STRING is the
1223 ;;; TRAILING-POINT - True if the last character of DIGIT-STRING is the
1225 ;;; POINT-POS - The position of the digit preceding the decimal
1226 ;;; point. Zero indicates point before first digit.
1228 ;;; NOTE: FLONUM-TO-STRING goes to a lot of trouble to guarantee
1229 ;;; accuracy. Specifically, the decimal number printed is the closest
1230 ;;; possible approximation to the true value of the binary number to
1231 ;;; be printed from among all decimal representations with the same
1232 ;;; number of digits. In free-format output, i.e. with the number of
1233 ;;; digits unconstrained, it is guaranteed that all the information is
1234 ;;; preserved, so that a properly- rounding reader can reconstruct the
1235 ;;; original binary number, bit-for-bit, from its printed decimal
1236 ;;; representation. Furthermore, only as many digits as necessary to
1237 ;;; satisfy this condition will be printed.
1239 ;;; FLOAT-STRING actually generates the digits for positive numbers.
1240 ;;; The algorithm is essentially that of algorithm Dragon4 in "How to
1241 ;;; Print Floating-Point Numbers Accurately" by Steele and White. The
1242 ;;; current (draft) version of this paper may be found in
1243 ;;; [CMUC]<steele>tradix.press. DO NOT EVEN THINK OF ATTEMPTING TO
1244 ;;; UNDERSTAND THIS CODE WITHOUT READING THE PAPER!
1246 (defvar *digits* "0123456789")
1248 (defun flonum-to-string (x &optional width fdigits scale fmin)
1250 ;; Zero is a special case which FLOAT-STRING cannot handle.
1252 (let ((s (make-string (1+ fdigits) :initial-element #\0)))
1253 (setf (schar s 0) #\.)
1254 (values s (length s) t (zerop fdigits) 0))
1255 (values "." 1 t t 0)))
1257 (multiple-value-bind (sig exp) (integer-decode-float x)
1258 (let* ((precision (float-precision x))
1259 (digits (float-digits x))
1260 (fudge (- digits precision))
1261 (width (if width (max width 1) nil)))
1262 (float-string (ash sig (- fudge)) (+ exp fudge) precision width
1263 fdigits scale fmin))))))
1265 (defun float-string (fraction exponent precision width fdigits scale fmin)
1266 (let ((r fraction) (s 1) (m- 1) (m+ 1) (k 0)
1267 (digits 0) (decpnt 0) (cutoff nil) (roundup nil) u low high
1268 (digit-string (make-array 50
1269 :element-type 'base-char
1272 ;; Represent fraction as r/s, error bounds as m+/s and m-/s.
1273 ;; Rational arithmetic avoids loss of precision in subsequent
1275 (cond ((> exponent 0)
1276 (setq r (ash fraction exponent))
1277 (setq m- (ash 1 exponent))
1280 (setq s (ash 1 (- exponent)))))
1281 ;; Adjust the error bounds m+ and m- for unequal gaps.
1282 (when (= fraction (ash 1 precision))
1283 (setq m+ (ash m+ 1))
1286 ;; Scale value by requested amount, and update error bounds.
1289 (let ((scale-factor (expt 10 (- scale))))
1290 (setq s (* s scale-factor)))
1291 (let ((scale-factor (expt 10 scale)))
1292 (setq r (* r scale-factor))
1293 (setq m+ (* m+ scale-factor))
1294 (setq m- (* m- scale-factor)))))
1295 ;; Scale r and s and compute initial k, the base 10 logarithm of r.
1297 ((>= r (ceiling s 10)))
1301 (setq m+ (* m+ 10)))
1304 ((< (+ (ash r 1) m+) (ash s 1)))
1307 ;; Determine number of fraction digits to generate.
1309 ;; Use specified number of fraction digits.
1310 (setq cutoff (- fdigits))
1311 ;;don't allow less than fmin fraction digits
1312 (if (and fmin (> cutoff (- fmin))) (setq cutoff (- fmin))))
1314 ;; Use as many fraction digits as width will permit but
1315 ;; force at least fmin digits even if width will be
1318 (setq cutoff (- 1 width))
1319 (setq cutoff (1+ (- k width))))
1320 (if (and fmin (> cutoff (- fmin))) (setq cutoff (- fmin)))))
1321 ;; If we decided to cut off digit generation before precision
1322 ;; has been exhausted, rounding the last digit may cause a carry
1323 ;; propagation. We can prevent this, preserving left-to-right
1324 ;; digit generation, with a few magical adjustments to m- and
1325 ;; m+. Of course, correct rounding is also preserved.
1326 (when (or fdigits width)
1327 (let ((a (- cutoff k))
1330 (dotimes (i a) (setq y (* y 10)))
1331 (dotimes (i (- a)) (setq y (ceiling y 10))))
1332 (setq m- (max y m-))
1333 (setq m+ (max y m+))
1334 (when (= m+ y) (setq roundup t))))
1335 (when (< (+ (ash r 1) m+) (ash s 1)) (return)))
1336 ;; Zero-fill before fraction if no integer part.
1338 (setq decpnt digits)
1339 (vector-push-extend #\. digit-string)
1341 (incf digits) (vector-push-extend #\0 digit-string)))
1342 ;; Generate the significant digits.
1346 (vector-push-extend #\. digit-string)
1347 (setq decpnt digits))
1348 (multiple-value-setq (u r) (truncate (* r 10) s))
1351 (setq low (< (ash r 1) m-))
1353 (setq high (>= (ash r 1) (- (ash s 1) m+)))
1354 (setq high (> (ash r 1) (- (ash s 1) m+))))
1355 ;; Stop when either precision is exhausted or we have printed as
1356 ;; many fraction digits as permitted.
1357 (when (or low high (and cutoff (<= k cutoff))) (return))
1358 (vector-push-extend (char *digits* u) digit-string)
1360 ;; If cutoff occurred before first digit, then no digits are
1361 ;; generated at all.
1362 (when (or (not cutoff) (>= k cutoff))
1363 ;; Last digit may need rounding
1364 (vector-push-extend (char *digits*
1365 (cond ((and low (not high)) u)
1366 ((and high (not low)) (1+ u))
1367 (t (if (<= (ash r 1) s) u (1+ u)))))
1370 ;; Zero-fill after integer part if no fraction.
1372 (dotimes (i k) (incf digits) (vector-push-extend #\0 digit-string))
1373 (vector-push-extend #\. digit-string)
1374 (setq decpnt digits))
1375 ;; Add trailing zeroes to pad fraction if fdigits specified.
1377 (dotimes (i (- fdigits (- digits decpnt)))
1379 (vector-push-extend #\0 digit-string)))
1381 (values digit-string (1+ digits) (= decpnt 0) (= decpnt digits) decpnt)))
1383 ;;; Given a non-negative floating point number, SCALE-EXPONENT returns
1384 ;;; a new floating point number Z in the range (0.1, 1.0] and an
1385 ;;; exponent E such that Z * 10^E is (approximately) equal to the
1386 ;;; original number. There may be some loss of precision due the
1387 ;;; floating point representation. The scaling is always done with
1388 ;;; long float arithmetic, which helps printing of lesser precisions
1389 ;;; as well as avoiding generic arithmetic.
1391 ;;; When computing our initial scale factor using EXPT, we pull out
1392 ;;; part of the computation to avoid over/under flow. When
1393 ;;; denormalized, we must pull out a large factor, since there is more
1394 ;;; negative exponent range than positive range.
1396 (eval-when (:compile-toplevel :execute)
1397 (setf *read-default-float-format*
1398 #!+long-float 'long-float #!-long-float 'double-float))
1399 (defun scale-exponent (original-x)
1400 (let* ((x (coerce original-x 'long-float)))
1401 (multiple-value-bind (sig exponent) (decode-float x)
1402 (declare (ignore sig))
1404 (values (float 0.0e0 original-x) 1)
1405 (let* ((ex (round (* exponent (log 2e0 10))))
1407 (if (float-denormalized-p x)
1409 (* x 1.0e16 (expt 10.0e0 (- (- ex) 16)))
1411 (* x 1.0e18 (expt 10.0e0 (- (- ex) 18)))
1412 (* x 10.0e0 (expt 10.0e0 (- (- ex) 1))))
1413 (/ x 10.0e0 (expt 10.0e0 (1- ex))))))
1414 (do ((d 10.0e0 (* d 10.0e0))
1418 (do ((m 10.0e0 (* m 10.0e0))
1422 (values (float z original-x) ex))))))))))
1423 (eval-when (:compile-toplevel :execute)
1424 (setf *read-default-float-format* 'single-float))
1426 ;;;; entry point for the float printer
1428 ;;; the float printer as called by PRINT, PRIN1, PRINC, etc. The
1429 ;;; argument is printed free-format, in either exponential or
1430 ;;; non-exponential notation, depending on its magnitude.
1432 ;;; NOTE: When a number is to be printed in exponential format, it is
1433 ;;; scaled in floating point. Since precision may be lost in this
1434 ;;; process, the guaranteed accuracy properties of FLONUM-TO-STRING
1435 ;;; are lost. The difficulty is that FLONUM-TO-STRING performs
1436 ;;; extensive computations with integers of similar magnitude to that
1437 ;;; of the number being printed. For large exponents, the bignums
1438 ;;; really get out of hand. If bignum arithmetic becomes reasonably
1439 ;;; fast and the exponent range is not too large, then it might become
1440 ;;; attractive to handle exponential notation with the same accuracy
1441 ;;; as non-exponential notation, using the method described in the
1442 ;;; Steele and White paper.
1444 ;;; Print the appropriate exponent marker for X and the specified exponent.
1445 (defun print-float-exponent (x exp stream)
1446 (declare (type float x) (type integer exp) (type stream stream))
1447 (let ((*print-radix* nil)
1448 (plusp (plusp exp)))
1449 (if (typep x *read-default-float-format*)
1451 (format stream "e~:[~;+~]~D" plusp exp))
1452 (format stream "~C~:[~;+~]~D"
1460 (defun output-float-infinity (x stream)
1461 (declare (float x) (stream stream))
1463 (write-string "#." stream))
1465 (error 'print-not-readable :object x))
1467 (write-string "#<" stream)))
1468 (write-string "SB-EXT:" stream)
1469 (write-string (symbol-name (float-format-name x)) stream)
1470 (write-string (if (plusp x) "-POSITIVE-" "-NEGATIVE-")
1472 (write-string "INFINITY" stream)
1474 (write-string ">" stream)))
1476 (defun output-float-nan (x stream)
1477 (print-unreadable-object (x stream)
1478 (princ (float-format-name x) stream)
1479 (write-string (if (float-trapping-nan-p x) " trapping" " quiet") stream)
1480 (write-string " NaN" stream)))
1482 ;;; the function called by OUTPUT-OBJECT to handle floats
1483 (defun output-float (x stream)
1485 ((float-infinity-p x)
1486 (output-float-infinity x stream))
1488 (output-float-nan x stream))
1490 (let ((x (cond ((minusp (float-sign x))
1491 (write-char #\- stream)
1497 (write-string "0.0" stream)
1498 (print-float-exponent x 0 stream))
1500 (output-float-aux x stream (float 1/1000 x) (float 10000000 x))))))))
1501 (defun output-float-aux (x stream e-min e-max)
1502 (if (and (>= x e-min) (< x e-max))
1504 (multiple-value-bind (str len lpoint tpoint) (flonum-to-string x)
1505 (declare (ignore len))
1506 (when lpoint (write-char #\0 stream))
1507 (write-string str stream)
1508 (when tpoint (write-char #\0 stream))
1509 (print-float-exponent x 0 stream))
1510 ;; exponential format
1511 (multiple-value-bind (f ex) (scale-exponent x)
1512 (multiple-value-bind (str len lpoint tpoint)
1513 (flonum-to-string f nil nil 1)
1514 (declare (ignore len))
1515 (when lpoint (write-char #\0 stream))
1516 (write-string str stream)
1517 (when tpoint (write-char #\0 stream))
1518 ;; Subtract out scale factor of 1 passed to FLONUM-TO-STRING.
1519 (print-float-exponent x (1- ex) stream)))))
1521 ;;;; other leaf objects
1523 ;;; If *PRINT-ESCAPE* is false, just do a WRITE-CHAR, otherwise output
1524 ;;; the character name or the character in the #\char format.
1525 (defun output-character (char stream)
1526 (if (or *print-escape* *print-readably*)
1527 (let ((name (char-name char)))
1528 (write-string "#\\" stream)
1530 (quote-string name stream)
1531 (write-char char stream)))
1532 (write-char char stream)))
1534 (defun output-sap (sap stream)
1535 (declare (type system-area-pointer sap))
1537 (format stream "#.(~S #X~8,'0X)" 'int-sap (sap-int sap)))
1539 (print-unreadable-object (sap stream)
1540 (format stream "system area pointer: #X~8,'0X" (sap-int sap))))))
1542 (defun output-weak-pointer (weak-pointer stream)
1543 (declare (type weak-pointer weak-pointer))
1544 (print-unreadable-object (weak-pointer stream)
1545 (multiple-value-bind (value validp) (weak-pointer-value weak-pointer)
1547 (write-string "weak pointer: " stream)
1548 (write value :stream stream))
1550 (write-string "broken weak pointer" stream))))))
1552 (defun output-code-component (component stream)
1553 (print-unreadable-object (component stream :identity t)
1554 (let ((dinfo (%code-debug-info component)))
1555 (cond ((eq dinfo :bogus-lra)
1556 (write-string "bogus code object" stream))
1558 (write-string "code object" stream)
1560 (write-char #\space stream)
1561 (output-object (sb!c::debug-info-name dinfo) stream)))))))
1563 (defun output-lra (lra stream)
1564 (print-unreadable-object (lra stream :identity t)
1565 (write-string "return PC object" stream)))
1567 (defun output-fdefn (fdefn stream)
1568 (print-unreadable-object (fdefn stream)
1569 (write-string "FDEFINITION object for " stream)
1570 (output-object (fdefn-name fdefn) stream)))
1574 ;;; Output OBJECT as using PRINT-OBJECT if it's a
1575 ;;; FUNCALLABLE-STANDARD-CLASS, or return NIL otherwise.
1577 ;;; The definition here is a simple temporary placeholder. It will be
1578 ;;; overwritten by a smarter version (capable of calling generic
1579 ;;; PRINT-OBJECT when appropriate) when CLOS is installed.
1580 (defun printed-as-clos-funcallable-standard-class (object stream)
1581 (declare (ignore object stream))
1584 (defun output-fun (object stream)
1585 (let* ((*print-length* 3) ; in case we have to..
1586 (*print-level* 3) ; ..print an interpreted function definition
1587 ;; FIXME: This find-the-function-name idiom ought to be
1588 ;; encapsulated in a function somewhere.
1589 (name (case (fun-subtype object)
1590 (#.sb!vm:closure-header-widetag "CLOSURE")
1591 (#.sb!vm:simple-fun-header-widetag (%simple-fun-name object))
1592 (t 'no-name-available)))
1593 (identified-by-name-p (and (symbolp name)
1595 (eq (fdefinition name) object))))
1596 (print-unreadable-object (object
1598 :identity (not identified-by-name-p))
1599 (prin1 'function stream)
1600 (unless (eq name 'no-name-available)
1601 (format stream " ~S" name)))))
1603 ;;;; catch-all for unknown things
1605 (defun output-random (object stream)
1606 (print-unreadable-object (object stream :identity t)
1607 (let ((lowtag (lowtag-of object)))
1609 (#.sb!vm:other-pointer-lowtag
1610 (let ((widetag (widetag-of object)))
1612 (#.sb!vm:value-cell-header-widetag
1613 (write-string "value cell " stream)
1614 (output-object (value-cell-ref object) stream))
1616 (write-string "unknown pointer object, widetag=" stream)
1617 (let ((*print-base* 16) (*print-radix* t))
1618 (output-integer widetag stream))))))
1619 ((#.sb!vm:fun-pointer-lowtag
1620 #.sb!vm:instance-pointer-lowtag
1621 #.sb!vm:list-pointer-lowtag)
1622 (write-string "unknown pointer object, lowtag=" stream)
1623 (let ((*print-base* 16) (*print-radix* t))
1624 (output-integer lowtag stream)))
1626 (case (widetag-of object)
1627 (#.sb!vm:unbound-marker-widetag
1628 (write-string "unbound marker" stream))
1630 (write-string "unknown immediate object, lowtag=" stream)
1631 (let ((*print-base* 2) (*print-radix* t))
1632 (output-integer lowtag stream))
1633 (write-string ", widetag=" stream)
1634 (let ((*print-base* 16) (*print-radix* t))
1635 (output-integer (widetag-of object) stream)))))))))