(declaim (maybe-inline digit-char-p digit-weight))
(deftype char-code ()
- `(integer 0 (,char-code-limit)))
+ `(integer 0 (,sb!xc:char-code-limit)))
#!+sb-unicode
(progn
array))))
(let ((character-database (read-ub8-vector (file "ucd" "dat")))
(decompositions (read-ub8-vector (file "decomp" "dat")))
- (long-decompositions (read-ub8-vector (file "ldecomp" "dat"))))
+ (long-decompositions (read-ub8-vector (file "ldecomp" "dat")))
+ (primary-compositions (read-ub8-vector (file "comp" "dat"))))
`(progn
- (declaim (type (simple-array (unsigned-byte 8) (*)) **character-database** **character-decompositions** **character-long-decompositions**))
+ (declaim (type (simple-array (unsigned-byte 8) (*))
+ **character-database**
+ **character-decompositions**
+ **character-long-decompositions**))
(defglobal **character-database** ,character-database)
(defglobal **character-decompositions** ,decompositions)
(defglobal **character-long-decompositions** ,long-decompositions)
+ ;; KLUDGE: temporary value, fixed up in cold-load
+ (defglobal **character-primary-compositions** ,primary-compositions)
(defun !character-database-cold-init ()
- (setf **character-database** ,character-database))
+ (setf **character-database** ,character-database)
+ (setf **character-primary-compositions**
+ (let ((table (make-hash-table))
+ (info ,primary-compositions))
+ (flet ((code (j)
+ (dpb (aref info (* 4 j))
+ (byte 8 24)
+ (dpb (aref info (+ (* 4 j) 1))
+ (byte 8 16)
+ (dpb (aref info (+ (* 4 j) 2))
+ (byte 8 8)
+ (aref info (+ (* 4 j) 3)))))))
+ #!+sb-unicode
+ (dotimes (i (/ (length info) 12))
+ (setf (gethash (dpb (code (* 3 i)) (byte 21 21)
+ (code (1+ (* 3 i))))
+ table)
+ (code-char (code (+ (* 3 i) 2)))))
+ table))))
,(with-open-file (stream (file "ucd-names" "lisp-expr")
:direction :input
:element-type 'character)
\f
;;;; UCD accessor functions
-;;; The first (* 8 395) => 3160 entries in **CHARACTER-DATABASE**
+;;; The first (* 8 396) => 3168 entries in **CHARACTER-DATABASE**
;;; contain entries for the distinct character attributes:
;;; specifically, indexes into the GC kinds, Bidi kinds, CCC kinds,
;;; the decimal digit property, the digit property and the
;;;
;;; To look up information about a character, take the high 13 bits of
;;; its code point, and index the character database with that and a
-;;; base of 3160 (going past the miscellaneous information[*], so
+;;; base of 3168 (going past the miscellaneous information[*], so
;;; treating (a) as the start of the array). This, labelled A, gives
;;; us another index into the detailed pages[-], which we can use to
;;; look up the details for the character in question: we add the low
;;; 8 bits of the character, shifted twice (because we have four-byte
-;;; table entries) to 1024 times the `page' index, with a base of 6088
+;;; table entries) to 1024 times the `page' index, with a base of 7520
;;; to skip over everything else. This gets us to point B. If we're
;;; after a transformed code point (i.e. an upcase or downcase
;;; operation), we can simply read it off now, beginning with an
(defun ucd-index (char)
(let* ((cp (char-code char))
(cp-high (ash cp -8))
- (page (aref **character-database** (+ 3160 cp-high))))
- (+ 7512 (ash page 10) (ash (ldb (byte 8 0) cp) 2))))
+ (page (aref **character-database** (+ 3168 cp-high))))
+ (+ 7520 (ash page 10) (ash (ldb (byte 8 0) cp) 2))))
(declaim (ftype (sfunction (t) (unsigned-byte 11)) ucd-value-0))
(defun ucd-value-0 (char)
#!+sb-doc
"The argument must be a character object; UPPER-CASE-P returns T if the
argument is an upper-case character, NIL otherwise."
- (< (ucd-value-0 char) 4))
+ (< (ucd-value-0 char) 5))
(defun lower-case-p (char)
#!+sb-doc
"The argument must be a character object; LOWER-CASE-P returns T if the
argument is a lower-case character, NIL otherwise."
- (< 3 (ucd-value-0 char) 8))
+ (< 4 (ucd-value-0 char) 9))
(defun both-case-p (char)
#!+sb-doc
"The argument must be a character object. BOTH-CASE-P returns T if the
argument is an alphabetic character and if the character exists in both upper
and lower case. For ASCII, this is the same as ALPHA-CHAR-P."
- (< (ucd-value-0 char) 8))
+ (< (ucd-value-0 char) 9))
(defun digit-char-p (char &optional (radix 10.))
#!+sb-doc
(defmacro equal-char-code (character)
(let ((ch (gensym)))
`(let ((,ch ,character))
- (if (= (ucd-value-0 ,ch) 0)
+ (if (< (ucd-value-0 ,ch) 5)
(ucd-value-1 ,ch)
(char-code ,ch)))))
(defun two-arg-char-equal (c1 c2)
- (= (equal-char-code c1) (equal-char-code c2)))
+ (flet ((base-char-equal-p ()
+ (let* ((code1 (char-code c1))
+ (code2 (char-code c2))
+ (sum (logxor code1 code2)))
+ (when (eql sum #x20)
+ (let ((sum (+ code1 code2)))
+ (or (and (> sum 161) (< sum 213))
+ (and (> sum 415) (< sum 461))
+ (and (> sum 463) (< sum 477))))))))
+ (declare (inline base-char-equal-p))
+ (or (eq c1 c2)
+ #!-sb-unicode
+ (base-char-equal-p)
+ #!+sb-unicode
+ (typecase c1
+ (base-char
+ (and (base-char-p c2)
+ (base-char-equal-p)))
+ (t
+ (= (equal-char-code c1) (equal-char-code c2)))))))
+
+(defun char-equal-constant (x char reverse-case-char)
+ (declare (type character x))
+ (or (eq char x)
+ (eq reverse-case-char x)))
(defun char-equal (character &rest more-characters)
#!+sb-doc
#!+sb-doc
"Return CHAR converted to upper-case if that is possible. Don't convert
lowercase eszet (U+DF)."
- (if (< 3 (ucd-value-0 char) 8)
+ (if (< 4 (ucd-value-0 char) 9)
(code-char (ucd-value-1 char))
char))
(defun char-downcase (char)
#!+sb-doc
"Return CHAR converted to lower-case if that is possible."
- (if (< (ucd-value-0 char) 4)
+ (if (< (ucd-value-0 char) 5)
(code-char (ucd-value-1 char))
char))
(dpb v2 (byte 8 8) v3))))
(if (= length 1)
(string (code-char entry))
- (let ((result (make-string length))
- (e (* 4 entry)))
- (dotimes (i length result)
- (let ((code (dpb (aref long-decompositions (+ e 1))
- (byte 8 16)
- (dpb (aref long-decompositions (+ e 2))
- (byte 8 8)
- (aref long-decompositions (+ e 3))))))
- (setf (char result i) (code-char code)))
- (incf e 4))))))
+ (if (<= #xac00 cp #xd7a3)
+ ;; see Unicode 6.2, section 3-12
+ (let* ((sbase #xac00)
+ (lbase #x1100)
+ (vbase #x1161)
+ (tbase #x11a7)
+ (lcount 19)
+ (vcount 21)
+ (tcount 28)
+ (ncount (* vcount tcount))
+ (scount (* lcount ncount))
+ (sindex (- cp sbase))
+ (lindex (floor sindex ncount))
+ (vindex (floor (mod sindex ncount) tcount))
+ (tindex (mod sindex tcount))
+ (result (make-string length)))
+ (declare (ignore scount))
+ (setf (char result 0) (code-char (+ lbase lindex)))
+ (setf (char result 1) (code-char (+ vbase vindex)))
+ (when (> tindex 0)
+ (setf (char result 2) (code-char (+ tbase tindex))))
+ result)
+ (let ((result (make-string length))
+ (e (* 4 entry)))
+ (dotimes (i length result)
+ (let ((code (dpb (aref long-decompositions (+ e 1))
+ (byte 8 16)
+ (dpb (aref long-decompositions (+ e 2))
+ (byte 8 8)
+ (aref long-decompositions (+ e 3))))))
+ (setf (char result i) (code-char code)))
+ (incf e 4)))))))
(defun decompose-char (char)
(if (= (char-decomposition-info char) 0)
((null end) (push (subseq string start end) result))
(unless (= start end)
(push (subseq string start end) result))
- (push (decompose-char (char string end)) result))
+ ;; FIXME: this recursive call to DECOMPOSE-STRING is necessary
+ ;; for correctness given our direct encoding of the
+ ;; decomposition data in UnicodeData.txt. It would, however,
+ ;; be straightforward enough to perform the recursion in table
+ ;; construction, and then have this simply revert to a single
+ ;; lookup. (Wait for tests to be hooked in, then implement).
+ (push (decompose-string (decompose-char (char string end)) kind)
+ result))
(apply 'concatenate 'string (nreverse result)))))
(defun sort-combiners (string)
(go again)))
(apply 'concatenate 'string (nreverse result))))
-#+nil
(defun primary-composition (char1 char2)
- (when (and (char= char1 #\e)
- (char= char2 #\combining_acute_accent))
- #\latin_small_letter_e_with_acute))
-
-;;; generic sequences. *sigh*.
+ (let ((c1 (char-code char1))
+ (c2 (char-code char2)))
+ (cond
+ ((gethash (dpb (char-code char1) (byte 21 21) (char-code char2))
+ **character-primary-compositions**))
+ ((and (<= #x1100 c1) (<= c1 #x1112)
+ (<= #x1161 c2) (<= c2 #x1175))
+ (let ((lindex (- c1 #x1100))
+ (vindex (- c2 #x1161)))
+ (code-char (+ #xac00 (* lindex 588) (* vindex 28)))))
+ ((and (<= #xac00 c1) (<= c1 #.(+ #xac00 11171))
+ (<= #x11a8 c2) (<= c2 #x11c2)
+ (= 0 (rem (- c1 #xac00) 28)))
+ (code-char (+ c1 (- c2 #x11a7)))))))
+
+;;; This implements a sequence data structure, specialized for
+;;; efficient deletion of characters at an index, along with tolerable
+;;; random access. The purpose is to support the canonical
+;;; composition algorithm from Unicode, which involves replacing (not
+;;; necessarily consecutive) pairs of code points with a single code
+;;; point (e.g. [#\e #\combining_acute_accent] with
+;;; #\latin_small_letter_e_with_acute). The data structure is a list
+;;; of three-element lists, each denoting a chunk of string data
+;;; starting at the first index and ending at the second.
+;;;
+;;; Actually, the implementation isn't particularly efficient, and
+;;; would probably benefit from being rewritten in terms of displaced
+;;; arrays, which would substantially reduce copying.
+;;;
+;;; (also, generic sequences. *sigh*.)
(defun lref (lstring index)
(dolist (l lstring)
(when (and (<= (first l) index)
(labels ()
(let* ((result (list (list 0 (length string) string)))
(previous-starter-index (position 0 string :key #'ucd-ccc))
- (i (1+ previous-starter-index)))
- (when (= i (length string))
+ (i (and previous-starter-index (1+ previous-starter-index))))
+ (when (or (not i) (= i (length string)))
(return-from canonically-compose string))
(tagbody
again
- (when (and (> (- i previous-starter-index) 2)
- (= (ucd-ccc (lref result i)) (ucd-ccc (lref result (1- i)))))
+ (when (and (>= (- i previous-starter-index) 2)
+ ;; test for Blocked (Unicode 3.11 para. D115)
+ ;;
+ ;; (assumes here that string has sorted combiners,
+ ;; so can look back just one step)
+ (>= (ucd-ccc (lref result (1- i)))
+ (ucd-ccc (lref result i))))
(when (= (ucd-ccc (lref result i)) 0)
(setf previous-starter-index i))
(incf i)
(defun normalize-string (string &optional (form :nfd))
(declare (type (member :nfd :nfkd :nfc :nfkc) form))
+ #!-sb-unicode
+ (etypecase string
+ ((array nil (*)) string)
+ (string
+ (ecase form
+ ((:nfc :nfkc) string)
+ ((:nfd :nfkd) (error "Cannot normalize to ~A form in #-SB-UNICODE builds" form)))))
+ #!+sb-unicode
(etypecase string
- (simple-base-string string)
- ((simple-array character (*))
+ (base-string string)
+ ((array character (*))
(ecase form
+ ((:nfc)
+ (canonically-compose (sort-combiners (decompose-string string))))
((:nfd)
(sort-combiners (decompose-string string)))
+ ((:nfkc)
+ (canonically-compose (sort-combiners (decompose-string string :compatibility))))
((:nfkd)
(sort-combiners (decompose-string string :compatibility)))))
- ((simple-array nil (*)) string)))
+ ((array nil (*)) string)))