is less than this, then print using ``miser-style'' output. Miser
style conditional newlines are turned on, and all indentations are
turned off. If NIL, never use miser mode.")
-(defvar *print-pprint-dispatch* nil
- #!+sb-doc
- "the pprint-dispatch-table that controls how to pretty-print objects")
+(defvar *print-pprint-dispatch*)
+#!+sb-doc
+(setf (fdocumentation '*print-pprint-dispatch* 'variable)
+ "the pprint-dispatch-table that controls how to pretty-print objects")
(defmacro with-standard-io-syntax (&body body)
#!+sb-doc
`(%with-standard-io-syntax (lambda () ,@body)))
(defun %with-standard-io-syntax (function)
+ (declare (type function function))
(let ((*package* (find-package "COMMON-LISP-USER"))
(*print-array* t)
(*print-base* 10)
;;; guts of PRINT-UNREADABLE-OBJECT
(defun %print-unreadable-object (object stream type identity body)
+ (declare (type (or null function) body))
(when *print-readably*
(error 'print-not-readable :object object))
(flet ((print-description ()
\f
;;;; OUTPUT-OBJECT -- the main entry point
-;;; the current pretty printer. This should be either a function that
-;;; takes two arguments (the object and the stream) or NIL to indicate
-;;; that there is no pretty printer installed.
-(defvar *pretty-printer* nil)
-
;;; Objects whose print representation identifies them EQLly don't
;;; need to be checked for circularity.
(defun uniquely-identified-by-print-p (x)
(defun output-object (object stream)
(labels ((print-it (stream)
(if *print-pretty*
- (if *pretty-printer*
- (funcall *pretty-printer* object stream)
- (let ((*print-pretty* nil))
- (output-ugly-object object stream)))
+ (sb!pretty:output-pretty-object object stream)
(output-ugly-object object stream)))
(check-it (stream)
(multiple-value-bind (marker initiate)
(check-for-circularity object t)
;; initialization of the circulation detect noise ...
(if (eq initiate :initiate)
- (let ((*circularity-hash-table*
- (make-hash-table :test 'eq)))
- (check-it (make-broadcast-stream))
- (let ((*circularity-counter* 0))
- (check-it stream)))
- ;; otherwise
- (if marker
- (when (handle-circularity marker stream)
- (print-it stream))
- (print-it stream))))))
+ (let ((*circularity-hash-table*
+ (make-hash-table :test 'eq)))
+ (check-it (make-broadcast-stream))
+ (let ((*circularity-counter* 0))
+ (check-it stream)))
+ ;; otherwise
+ (if marker
+ (when (handle-circularity marker stream)
+ (print-it stream))
+ (print-it stream))))))
(cond (;; Maybe we don't need to bother with circularity detection.
(or (not *print-circle*)
(uniquely-identified-by-print-p object))
*print-object-is-disabled-p*))
(print-object object stream))
((typep object 'structure-object)
- (default-structure-print object stream *current-level*))
+ (default-structure-print object stream *current-level-in-print*))
(t
(write-string "#<INSTANCE but not STRUCTURE-OBJECT>" stream))))
(function
(unless (and (funcallable-instance-p object)
(printed-as-funcallable-standard-class object stream))
- (output-function object stream)))
+ (output-fun object stream)))
(symbol
(output-symbol object stream))
(number
;;; This variable contains the current definition of one of three
;;; symbol printers. SETUP-PRINTER-STATE sets this variable.
-(defvar *internal-symbol-output-function* nil)
+(defvar *internal-symbol-output-fun* nil)
;;; This function sets the internal global symbol
-;;; *INTERNAL-SYMBOL-OUTPUT-FUNCTION* to the right function depending
-;;; on the value of *PRINT-CASE*. See the manual for details. The
-;;; print buffer stream is also reset.
+;;; *INTERNAL-SYMBOL-OUTPUT-FUN* to the right function depending on
+;;; the value of *PRINT-CASE*. See the manual for details. The print
+;;; buffer stream is also reset.
(defun setup-printer-state ()
(unless (and (eq *print-case* *previous-case*)
(eq (readtable-case *readtable*) *previous-readtable-case*))
(setf (readtable-case *readtable*) :upcase)
(error "invalid READTABLE-CASE value: ~S" *previous-readtable-case*))
- (setq *internal-symbol-output-function*
+ (setq *internal-symbol-output-fun*
(case *previous-readtable-case*
(:upcase
(case *print-case*
;;; words, diddle its case according to *PRINT-CASE* and
;;; READTABLE-CASE.
(defun output-symbol-name (name stream &optional (maybe-quote t))
- (declare (type simple-base-string name))
+ (declare (type simple-string name))
(setup-printer-state)
(if (and maybe-quote (symbol-quotep name))
(output-quoted-symbol-name name stream)
- (funcall *internal-symbol-output-function* name stream)))
+ (funcall *internal-symbol-output-fun* name stream)))
\f
;;;; escaping symbols
:initial-element 36))
(declaim (type (simple-array (unsigned-byte 8) (#.char-code-limit))
*digit-bases*))
-
(dotimes (i 36)
(let ((char (digit-char i 36)))
(setf (aref *digit-bases* (char-code char)) i)))
(return t)
MARKER ; number marker in a numeric number...
+ ;; ("What," you may ask, "is a 'number marker'?" It's something
+ ;; that a conforming implementation might use in number syntax.
+ ;; See ANSI 2.3.1.1 "Potential Numbers as Tokens".)
(when (test letter) (advance OTHER nil))
(go DIGIT))))
\f
-;;;; *INTERNAL-SYMBOL-OUTPUT-FUNCTION*
+;;;; *INTERNAL-SYMBOL-OUTPUT-FUN*
;;;;
-;;;; Case hackery. These functions are stored in
-;;;; *INTERNAL-SYMBOL-OUTPUT-FUNCTION* according to the values of
+;;;; case hackery: These functions are stored in
+;;;; *INTERNAL-SYMBOL-OUTPUT-FUN* according to the values of
;;;; *PRINT-CASE* and READTABLE-CASE.
;;; called when:
(write-char (if (zerop bit) #\0 #\1) stream)))
(t
(when (and *print-readably*
- (not (eq (array-element-type vector) t)))
+ (not (array-readably-printable-p vector)))
(error 'print-not-readable :object vector))
(descend-into (stream)
(write-string "#(" stream)
(when (needs-slash-p char) (write-char #\\ stream))
(write-char char stream))))))
+(defun array-readably-printable-p (array)
+ (and (eq (array-element-type array) t)
+ (let ((zero (position 0 (array-dimensions array)))
+ (number (position 0 (array-dimensions array)
+ :test (complement #'eql)
+ :from-end t)))
+ (or (null zero) (null number) (> zero number)))))
+
;;; Output the printed representation of any array in either the #< or #A
;;; form.
(defun output-array (array stream)
;;; Output the readable #A form of an array.
(defun output-array-guts (array stream)
(when (and *print-readably*
- (not (eq (array-element-type array) t)))
+ (not (array-readably-printable-p array)))
(error 'print-not-readable :object array))
(write-char #\# stream)
(let ((*print-base* 10))
;;; use until CLOS is set up (at which time it will be replaced with
;;; the real generic function implementation)
(defun print-object (instance stream)
- (default-structure-print instance stream *current-level*))
+ (default-structure-print instance stream *current-level-in-print*))
\f
;;;; integer, ratio, and complex printing (i.e. everything but floats)
;;; part of the computation to avoid over/under flow. When
;;; denormalized, we must pull out a large factor, since there is more
;;; negative exponent range than positive range.
+
+(eval-when (:compile-toplevel :execute)
+ (setf *read-default-float-format*
+ #!+long-float 'long-float #!-long-float 'double-float))
(defun scale-exponent (original-x)
(let* ((x (coerce original-x 'long-float)))
(multiple-value-bind (sig exponent) (decode-float x)
(declare (ignore sig))
- (if (= x 0.0l0)
- (values (float 0.0l0 original-x) 1)
- (let* ((ex (round (* exponent (log 2l0 10))))
+ (if (= x 0.0e0)
+ (values (float 0.0e0 original-x) 1)
+ (let* ((ex (round (* exponent (log 2e0 10))))
(x (if (minusp ex)
(if (float-denormalized-p x)
#!-long-float
- (* x 1.0l16 (expt 10.0l0 (- (- ex) 16)))
+ (* x 1.0e16 (expt 10.0e0 (- (- ex) 16)))
#!+long-float
- (* x 1.0l18 (expt 10.0l0 (- (- ex) 18)))
- (* x 10.0l0 (expt 10.0l0 (- (- ex) 1))))
- (/ x 10.0l0 (expt 10.0l0 (1- ex))))))
- (do ((d 10.0l0 (* d 10.0l0))
+ (* x 1.0e18 (expt 10.0e0 (- (- ex) 18)))
+ (* x 10.0e0 (expt 10.0e0 (- (- ex) 1))))
+ (/ x 10.0e0 (expt 10.0e0 (1- ex))))))
+ (do ((d 10.0e0 (* d 10.0e0))
(y x (/ x d))
(ex ex (1+ ex)))
- ((< y 1.0l0)
- (do ((m 10.0l0 (* m 10.0l0))
+ ((< y 1.0e0)
+ (do ((m 10.0e0 (* m 10.0e0))
(z y (* y m))
(ex ex (1- ex)))
- ((>= z 0.1l0)
+ ((>= z 0.1e0)
(values (float z original-x) ex))))))))))
+(eval-when (:compile-toplevel :execute)
+ (setf *read-default-float-format* 'single-float))
\f
;;;; entry point for the float printer
(declare (ignore object stream))
nil)
-(defun output-function (object stream)
+(defun output-fun (object stream)
(let* ((*print-length* 3) ; in case we have to..
(*print-level* 3) ; ..print an interpreted function definition
;; FIXME: This find-the-function-name idiom ought to be
;; encapsulated in a function somewhere.
- (name (case (function-subtype object)
+ (name (case (fun-subtype object)
(#.sb!vm:closure-header-widetag "CLOSURE")
(#.sb!vm:simple-fun-header-widetag (%simple-fun-name object))
(t 'no-name-available)))