Mercurial > hg > xemacs-beta
view src/casetab.c @ 4844:91b3d00e717f
Various cleanups for Dynarr code, from Unicode-internal ws
dynarr.c: Add comment explaining Dynarr_largest() use.
dynarr.c: In Dynarr_insert_many(), don't call Dynarr_resize() unless we
actually need to resize, and note that an assert() that we are
inserting at or below the current end could be wrong if code
wants to access stuff between `len' and `largest'.
dynarr.c: Don't just Dynarr_resize() to the right size; instead use
Dynarr_reset() then Dynarr_add_many(), so that the 'len' and
'largest' and such get set properly.
dynarr.c, faces.c, gutter.c, lisp.h, lread.c, lrecord.h, redisplay-output.c, redisplay.c: Rename Dynarr member 'cur' to 'len' since it's the length of
the dynarr, not really a pointer to a "current insertion point".
Use type_checking_assert() instead of just assert() in some places.
Add additional assertions (Dynarr_verify*()) to check that we're
being given positions within range. Use them in Dynarr_at,
Dynarr_atp, etc. New Dynarr_atp_allow_end() for retrieving a
pointer to a position that might be the element past the last one.
New Dynarr_past_lastp() to retrieve a pointer to the position
past the last one, using Dynarr_atp_allow_end(). Change code
appropriately to use it.
Rename Dynarr_end() to Dynarr_lastp() (pointer to the last
element) for clarity, and change code appropriately to use it.
Change code appropriately to use Dynarr_begin().
Rewrite Dynarr_add_many(). New version can accept a NULL pointer
to mean "reserve space but don't put anything in it". Used by
stack_like_malloc().
| author | Ben Wing <ben@xemacs.org> |
|---|---|
| date | Wed, 13 Jan 2010 04:07:42 -0600 |
| parents | 4ee73bbe4f8e |
| children | a98ca4640147 e0db3c197671 |
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/* XEmacs routines to deal with case tables. Copyright (C) 1987, 1992, 1993, 1994 Free Software Foundation, Inc. Copyright (C) 1995 Sun Microsystems, Inc. Copyright (C) 2002 Ben Wing. This file is part of XEmacs. XEmacs is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. XEmacs is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with XEmacs; see the file COPYING. If not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /* Synched up with: FSF 19.28. Between FSF 19.28 and 19.30, casetab.c was rewritten to use junky FSF char tables. Meanwhile I rewrote it to use more logical char tables. --ben */ /* Written by Howard Gayle. */ /* Modified for Mule by Ben Wing. */ /* The four tables in a case table are downcase, upcase, canon, and eqv. Each is a char-table. Their workings are rather non-obvious. (1) `downcase' is the only obvious table: Map a character to its lowercase equivalent. (2) `upcase' does *NOT* map a character to its uppercase equivalent, despite its name. Rather, it maps lowercase characters to their uppercase equivalent, and uppercase characters to *ANYTHING BUT* their uppercase equivalent (currently, their lowercase equivalent), and characters without case to themselves. It is used to determine if a character "has no case" (no uppercase or lowercase mapping). #### This is way bogus. Just use the obvious implementation of uppercase mapping and of NOCASE_P. (3) `canon' maps each character to a "canonical" lowercase, such that if two different uppercase characters map to the same lowercase character, or vice versa, both characters will have the same entry in the canon table. (4) `eqv' lists the "equivalence classes" defined by `canon'. Imagine that all characters are divided into groups having the same `canon' entry; these groups are called "equivalence classes" and `eqv' lists them by linking the characters in each equivalence class together in a circular list. That is, to find out all all the members of a given char's equivalence classe, you need something like the following code: (let* ((char ?i) (original-char char) (standard-case-eqv (case-table-eqv (standard-case-table)))) (loop with res = (list char) until (eq (setq char (get-char-table char standard-case-eqv)) original-char) do (push char res) finally return res)) (Where #'case-table-eqv doesn't yet exist, and probably never will, given that the C code needs to keep it in a consistent state so Lisp can't mess around with it.) `canon' is used when doing case-insensitive comparisons. `eqv' is used in the Boyer-Moore search code. */ #include <config.h> #include "lisp.h" #include "buffer.h" #include "opaque.h" #include "chartab.h" #include "casetab.h" Lisp_Object Qcase_tablep, Qdowncase, Qupcase; Lisp_Object Vstandard_case_table; Lisp_Object case_table_char (Lisp_Object ch, Lisp_Object table); #define STRING256_P(obj) ((STRINGP (obj) && string_char_length (obj) == 256)) static Lisp_Object mark_case_table (Lisp_Object obj) { Lisp_Case_Table *ct = XCASE_TABLE (obj); mark_object (CASE_TABLE_DOWNCASE (ct)); mark_object (CASE_TABLE_UPCASE (ct)); mark_object (CASE_TABLE_CANON (ct)); mark_object (CASE_TABLE_EQV (ct)); return Qnil; } static void print_case_table (Lisp_Object obj, Lisp_Object printcharfun, int UNUSED (escapeflag)) { Lisp_Case_Table *ct = XCASE_TABLE (obj); if (print_readably) printing_unreadable_object ("#<case-table 0x%x>", ct->header.uid); write_fmt_string_lisp (printcharfun, "#<case-table downcase=%s upcase=%s canon=%s eqv=%s ", 4, CASE_TABLE_DOWNCASE (ct), CASE_TABLE_UPCASE (ct), CASE_TABLE_CANON (ct), CASE_TABLE_EQV (ct)); write_fmt_string (printcharfun, "0x%x>", ct->header.uid); } static const struct memory_description case_table_description [] = { { XD_LISP_OBJECT, offsetof (Lisp_Case_Table, downcase_table) }, { XD_LISP_OBJECT, offsetof (Lisp_Case_Table, upcase_table) }, { XD_LISP_OBJECT, offsetof (Lisp_Case_Table, case_canon_table) }, { XD_LISP_OBJECT, offsetof (Lisp_Case_Table, case_eqv_table) }, { XD_END } }; DEFINE_LRECORD_IMPLEMENTATION("case-table", case_table, 1, /*dumpable-flag*/ mark_case_table, print_case_table, 0, 0, 0, case_table_description, Lisp_Case_Table); static Lisp_Object allocate_case_table (int init_tables) { Lisp_Case_Table *ct = ALLOC_LCRECORD_TYPE (Lisp_Case_Table, &lrecord_case_table); if (init_tables) { SET_CASE_TABLE_DOWNCASE (ct, MAKE_TRT_TABLE ()); SET_CASE_TABLE_UPCASE (ct, MAKE_TRT_TABLE ()); SET_CASE_TABLE_CANON (ct, MAKE_TRT_TABLE ()); SET_CASE_TABLE_EQV (ct, MAKE_TRT_TABLE ()); } else { SET_CASE_TABLE_DOWNCASE (ct, Qnil); SET_CASE_TABLE_UPCASE (ct, Qnil); SET_CASE_TABLE_CANON (ct, Qnil); SET_CASE_TABLE_EQV (ct, Qnil); } return wrap_case_table (ct); } DEFUN ("make-case-table", Fmake_case_table, 0, 0, 0, /* Create a new, empty case table. */ ()) { return allocate_case_table (1); } DEFUN ("case-table-p", Fcase_table_p, 1, 1, 0, /* Return t if OBJECT is a case table. See `set-case-table' for more information on these data structures. */ (object)) { if (CASE_TABLEP (object)) return Qt; else { Lisp_Object down, up, canon, eqv; if (!CONSP (object)) return Qnil; down = XCAR (object); object = XCDR (object); if (!CONSP (object)) return Qnil; up = XCAR (object); object = XCDR (object); if (!CONSP (object)) return Qnil; canon = XCAR (object); object = XCDR (object); if (!CONSP (object)) return Qnil; eqv = XCAR (object); return ((STRING256_P (down) && (NILP (up) || STRING256_P (up)) && ((NILP (canon) && NILP (eqv)) || STRING256_P (canon)) && (NILP (eqv) || STRING256_P (eqv))) ? Qt : Qnil); } } static Lisp_Object check_case_table (Lisp_Object object) { /* This function can GC */ while (NILP (Fcase_table_p (object))) object = wrong_type_argument (Qcase_tablep, object); return object; } Lisp_Object case_table_char (Lisp_Object ch, Lisp_Object table) { Lisp_Object ct_char; ct_char = get_char_table (XCHAR (ch), table); if (NILP (ct_char)) return ch; else return ct_char; } DEFUN ("get-case-table", Fget_case_table, 3, 3, 0, /* Return CHAR-CASE version of CHARACTER in CASE-TABLE. CHAR-CASE is either `downcase' or `upcase'. */ (char_case, character, case_table)) { CHECK_CHAR (character); CHECK_CASE_TABLE (case_table); if (EQ (char_case, Qdowncase)) return case_table_char (character, XCASE_TABLE_DOWNCASE (case_table)); else if (EQ (char_case, Qupcase)) return case_table_char (character, XCASE_TABLE_UPCASE (case_table)); else invalid_constant ("Char case must be downcase or upcase", char_case); return Qnil; /* Not reached. */ } DEFUN ("put-case-table", Fput_case_table, 4, 4, 0, /* Set CHAR-CASE version of CHARACTER to be VALUE in CASE-TABLE. CHAR-CASE is either `downcase' or `upcase'. See also `put-case-table-pair'. */ (char_case, character, value, case_table)) { CHECK_CHAR (character); CHECK_CHAR (value); if (EQ (char_case, Qdowncase)) { Fput_char_table (character, value, XCASE_TABLE_DOWNCASE (case_table)); /* This one is not at all intuitive. See comment at top of file. */ Fput_char_table (character, value, XCASE_TABLE_UPCASE (case_table)); } else if (EQ (char_case, Qupcase)) { Fput_char_table (character, value, XCASE_TABLE_UPCASE (case_table)); Fput_char_table (character, character, XCASE_TABLE_DOWNCASE (case_table)); } else invalid_constant ("CHAR-CASE must be downcase or upcase", char_case); XCASE_TABLE (case_table)->dirty = 1; return Qnil; } DEFUN ("put-case-table-pair", Fput_case_table_pair, 3, 3, 0, /* Make UC and LC a pair of inter-case-converting letters in CASE-TABLE. UC is an uppercase character and LC is a downcase character. */ (uc, lc, case_table)) { CHECK_CHAR (uc); CHECK_CHAR (lc); CHECK_CASE_TABLE (case_table); Fput_char_table (lc, lc, XCASE_TABLE_DOWNCASE (case_table)); Fput_char_table (uc, lc, XCASE_TABLE_UPCASE (case_table)); Fput_char_table (uc, lc, XCASE_TABLE_DOWNCASE (case_table)); Fput_char_table (lc, uc, XCASE_TABLE_UPCASE (case_table)); XCASE_TABLE (case_table)->dirty = 1; return Qnil; } DEFUN ("copy-case-table", Fcopy_case_table, 1, 1, 0, /* Return a new case table which is a copy of CASE-TABLE */ (case_table)) { Lisp_Object new_obj; CHECK_CASE_TABLE (case_table); new_obj = allocate_case_table (0); XSET_CASE_TABLE_DOWNCASE (new_obj, Fcopy_char_table (XCASE_TABLE_DOWNCASE (case_table))); XSET_CASE_TABLE_UPCASE (new_obj, Fcopy_char_table (XCASE_TABLE_UPCASE (case_table))); XSET_CASE_TABLE_CANON (new_obj, Fcopy_char_table (XCASE_TABLE_CANON (case_table))); XSET_CASE_TABLE_EQV (new_obj, Fcopy_char_table (XCASE_TABLE_EQV (case_table))); return new_obj; } static int compute_canon_mapper (struct chartab_range *range, Lisp_Object UNUSED (table), Lisp_Object val, void *arg) { Lisp_Object casetab = VOID_TO_LISP (arg); if (range->type == CHARTAB_RANGE_CHAR) SET_TRT_TABLE_OF (XCASE_TABLE_CANON (casetab), range->ch, TRT_TABLE_OF (XCASE_TABLE_DOWNCASE (casetab), TRT_TABLE_OF (XCASE_TABLE_UPCASE (casetab), XCHAR (val)))); return 0; } static int initialize_identity_mapper (struct chartab_range *range, Lisp_Object UNUSED (table), Lisp_Object UNUSED (val), void *arg) { Lisp_Object trt = VOID_TO_LISP (arg); if (range->type == CHARTAB_RANGE_CHAR) SET_TRT_TABLE_OF (trt, range->ch, range->ch); return 0; } static int compute_up_or_eqv_mapper (struct chartab_range *range, Lisp_Object UNUSED (table), Lisp_Object val, void *arg) { Lisp_Object inverse = VOID_TO_LISP (arg); Ichar toch = XCHAR (val); if (range->type == CHARTAB_RANGE_CHAR && range->ch != toch) { Ichar c = TRT_TABLE_OF (inverse, toch); SET_TRT_TABLE_OF (inverse, toch, range->ch); SET_TRT_TABLE_OF (inverse, range->ch, c); } return 0; } /* Recomputing the canonical and equivalency tables from scratch is a lengthy process, and doing them incrementally is extremely difficult or perhaps impossible -- and certainly not worth it. To avoid lots of excessive recomputation when lots of stuff is incrementally added, we just store a dirty flag and then recompute when a value from the canon or eqv tables is actually needed. */ void recompute_case_table (Lisp_Object casetab) { struct chartab_range range; range.type = CHARTAB_RANGE_ALL; /* Turn off dirty flag first so we don't get infinite recursion when retrieving the values below! */ XCASE_TABLE (casetab)->dirty = 0; map_char_table (XCASE_TABLE_DOWNCASE (casetab), &range, compute_canon_mapper, LISP_TO_VOID (casetab)); map_char_table (XCASE_TABLE_CANON (casetab), &range, initialize_identity_mapper, LISP_TO_VOID (XCASE_TABLE_EQV (casetab))); map_char_table (XCASE_TABLE_CANON (casetab), &range, compute_up_or_eqv_mapper, LISP_TO_VOID (XCASE_TABLE_EQV (casetab))); } DEFUN ("current-case-table", Fcurrent_case_table, 0, 1, 0, /* Return the case table of BUFFER, which defaults to the current buffer. */ (buffer)) { struct buffer *buf = decode_buffer (buffer, 0); return buf->case_table; } DEFUN ("standard-case-table", Fstandard_case_table, 0, 0, 0, /* Return the standard case table. This is the one used for new buffers. */ ()) { return Vstandard_case_table; } static void convert_old_style_syntax_string (Lisp_Object table, Lisp_Object string) { Ichar i; for (i = 0; i < 256; i++) SET_TRT_TABLE_OF (table, i, string_ichar (string, i)); } static Lisp_Object set_case_table (Lisp_Object table, int standard) { /* This function can GC */ struct buffer *buf = standard ? XBUFFER (Vbuffer_defaults) : current_buffer; check_case_table (table); if (CASE_TABLEP (table)) { if (standard) Vstandard_case_table = table; buf->case_table = table; } else { /* For backward compatibility. */ Lisp_Object down, up, canon, eqv, tail = table; Lisp_Object casetab = standard ? Vstandard_case_table : buf->case_table; struct chartab_range range; range.type = CHARTAB_RANGE_ALL; Freset_char_table (XCASE_TABLE_DOWNCASE (casetab)); Freset_char_table (XCASE_TABLE_UPCASE (casetab)); Freset_char_table (XCASE_TABLE_CANON (casetab)); Freset_char_table (XCASE_TABLE_EQV (casetab)); down = XCAR (tail); tail = XCDR (tail); up = XCAR (tail); tail = XCDR (tail); canon = XCAR (tail); tail = XCDR (tail); eqv = XCAR (tail); convert_old_style_syntax_string (XCASE_TABLE_DOWNCASE (casetab), down); if (NILP (up)) { map_char_table (XCASE_TABLE_DOWNCASE (casetab), &range, initialize_identity_mapper, LISP_TO_VOID (XCASE_TABLE_UPCASE (casetab))); map_char_table (XCASE_TABLE_DOWNCASE (casetab), &range, compute_up_or_eqv_mapper, LISP_TO_VOID (XCASE_TABLE_UPCASE (casetab))); } else convert_old_style_syntax_string (XCASE_TABLE_UPCASE (casetab), up); if (NILP (canon)) map_char_table (XCASE_TABLE_DOWNCASE (casetab), &range, compute_canon_mapper, LISP_TO_VOID (casetab)); else convert_old_style_syntax_string (XCASE_TABLE_CANON (casetab), canon); if (NILP (eqv)) { map_char_table (XCASE_TABLE_CANON (casetab), &range, initialize_identity_mapper, LISP_TO_VOID (XCASE_TABLE_EQV (casetab))); map_char_table (XCASE_TABLE_CANON (casetab), &range, compute_up_or_eqv_mapper, LISP_TO_VOID (XCASE_TABLE_EQV (casetab))); } else convert_old_style_syntax_string (XCASE_TABLE_CANON (casetab), eqv); } return buf->case_table; } DEFUN ("set-case-table", Fset_case_table, 1, 1, 0, /* Select CASE-TABLE as the new case table for the current buffer. A case table is a case-table object or list (DOWNCASE UPCASE CANONICALIZE EQUIVALENCES) where each element is either nil or a string of length 256. The latter is provided for backward-compatibility. DOWNCASE maps each character to its lower-case equivalent. UPCASE maps each character to its upper-case equivalent; if lower and upper case characters are in 1-1 correspondence, you may use nil and the upcase table will be deduced from DOWNCASE. CANONICALIZE maps each character to a canonical equivalent; any two characters that are related by case-conversion have the same canonical equivalent character; it may be nil, in which case it is deduced from DOWNCASE and UPCASE. EQUIVALENCES is a map that cyclicly permutes each equivalence class (of characters with the same canonical equivalent); it may be nil, in which case it is deduced from CANONICALIZE. See also `get-case-table', `put-case-table' and `put-case-table-pair'. */ (case_table)) { /* This function can GC */ return set_case_table (case_table, 0); } DEFUN ("set-standard-case-table", Fset_standard_case_table, 1, 1, 0, /* Select CASE-TABLE as the new standard case table for new buffers. See `set-case-table' for more info on case tables. */ (case_table)) { /* This function can GC */ return set_case_table (case_table, 1); } void syms_of_casetab (void) { INIT_LRECORD_IMPLEMENTATION (case_table); DEFSYMBOL_MULTIWORD_PREDICATE (Qcase_tablep); DEFSYMBOL (Qdowncase); DEFSYMBOL (Qupcase); DEFSUBR (Fmake_case_table); DEFSUBR (Fcase_table_p); DEFSUBR (Fget_case_table); DEFSUBR (Fput_case_table); DEFSUBR (Fput_case_table_pair); DEFSUBR (Fcurrent_case_table); DEFSUBR (Fstandard_case_table); DEFSUBR (Fcopy_case_table); DEFSUBR (Fset_case_table); DEFSUBR (Fset_standard_case_table); } void complex_vars_of_casetab (void) { REGISTER Ichar i; staticpro (&Vstandard_case_table); Vstandard_case_table = allocate_case_table (1); for (i = 0; i < 256; i++) { unsigned char lowered = tolower (i); SET_TRT_TABLE_OF (XCASE_TABLE_DOWNCASE (Vstandard_case_table), i, lowered); } for (i = 0; i < 256; i++) { unsigned char flipped = (isupper (i) ? tolower (i) : (islower (i) ? toupper (i) : i)); SET_TRT_TABLE_OF (XCASE_TABLE_UPCASE (Vstandard_case_table), i, flipped); } recompute_case_table (Vstandard_case_table); }