Lisp_Object Vascii_downcase_table, Vascii_upcase_table;
Lisp_Object Vascii_canon_table, Vascii_eqv_table;
-static void compute_trt_inverse ();
+/* Used as a temporary in DOWNCASE and other macros in lisp.h. No
+ need to mark it, since it is used only very temporarily. */
+Lisp_Object case_temp1, case_temp2;
+
+static void set_canon ();
+static void set_identity ();
+static void shuffle ();
DEFUN ("case-table-p", Fcase_table_p, Scase_table_p, 1, 1, 0,
"Return t iff OBJECT is a case table.\n\
int standard;
{
Lisp_Object up, canon, eqv;
+ Lisp_Object indices[3];
check_case_table (table);
if (NILP (up))
{
up = Fmake_char_table (Qcase_table, Qnil);
- compute_trt_inverse (table, up);
+ map_char_table (set_identity, Qnil, table, up, 0, indices);
+ map_char_table (shuffle, Qnil, table, up, 0, indices);
XCHAR_TABLE (table)->extras[0] = up;
}
if (NILP (canon))
{
- register int i;
- Lisp_Object *upvec = XCHAR_TABLE (up)->contents;
- Lisp_Object *downvec = XCHAR_TABLE (table)->contents;
-
canon = Fmake_char_table (Qcase_table, Qnil);
-
- /* Set up the CANON vector; for each character,
- this sequence of upcasing and downcasing ought to
- get the "preferred" lowercase equivalent. */
- for (i = 0; i < CHAR_TABLE_SINGLE_BYTE_SLOTS; i++)
- XCHAR_TABLE (canon)->contents[i] = downvec[upvec[downvec[i]]];
XCHAR_TABLE (table)->extras[1] = canon;
+ map_char_table (set_canon, Qnil, table, table, 0, indices);
}
if (NILP (eqv))
{
eqv = Fmake_char_table (Qcase_table, Qnil);
- compute_trt_inverse (canon, eqv);
+ map_char_table (set_identity, Qnil, canon, eqv, 0, indices);
+ map_char_table (shuffle, Qnil, canon, eqv, 0, indices);
XCHAR_TABLE (table)->extras[2] = eqv;
}
return table;
}
\f
-/* Using the scratch array at BYTES of which the first DEPTH elements
- are already set, and using the multi-byte structure inherited from
- TRT, make INVERSE be an identity mapping. That is, for each slot
- that's indexed by a single byte, store that byte in INVERSE.
- Where TRT has a subtable, make a corresponding subtable in INVERSE
- and recursively initialize that subtable so that its elements are
- the multi-byte characters that correspond to the index bytes.
- This is the first step in generating an inverse mapping. */
+/* The following functions are called in map_char_table. */
+
+/* Set CANON char-table element for C to a translated ELT by UP and
+ DOWN char-tables. This is done only when ELT is a character. The
+ char-tables CANON, UP, and DOWN are in CASE_TABLE. */
static void
-compute_trt_identity (bytes, depth, trt, inverse)
- unsigned char *bytes;
- int depth;
- struct Lisp_Char_Table *trt, *inverse;
+set_canon (case_table, c, elt)
+ Lisp_Object case_table, c, elt;
{
- register int i;
- int lim = (depth == 0 ? CHAR_TABLE_ORDINARY_SLOTS : SUB_CHAR_TABLE_ORDINARY_SLOTS);
+ Lisp_Object up = XCHAR_TABLE (case_table)->extras[0];
+ Lisp_Object canon = XCHAR_TABLE (case_table)->extras[1];
- for (i = 0; i < lim; i++)
- {
- if (NATNUMP (trt->contents[i]))
- {
- bytes[depth] = i;
- XSETFASTINT (inverse->contents[i],
- (depth == 0 && i < CHAR_TABLE_SINGLE_BYTE_SLOTS ? i
- : MAKE_NON_ASCII_CHAR (bytes[0], bytes[1], bytes[2])));
- }
- else if (SUB_CHAR_TABLE_P (trt->contents[i]))
- {
- bytes[depth] = i - 128;
- inverse->contents[i] = make_sub_char_table (Qnil);
- compute_trt_identity (bytes, depth + 1,
- XCHAR_TABLE (trt->contents[i]),
- XCHAR_TABLE (inverse->contents[i]));
- }
- else /* must be Qnil or Qidentity */
- inverse->contents[i] = trt->contents[i];
- }
+ if (NATNUMP (elt))
+ Faset (canon, c, Faref (case_table, Faref (up, elt)));
}
-/* Using the scratch array at BYTES of which the first DEPTH elements
- are already set, permute the elements of INVERSE (which is initially
- an identity mapping) so that it has one cycle for each equivalence
- class induced by the translation table TRT. IBASE is the lispy
- version of the outermost (depth 0) instance of INVERSE. */
+/* Set elements of char-table TABLE for C to C itself. This is done
+ only when ELT is a character. This is called in map_char_table. */
static void
-compute_trt_shuffle (bytes, depth, ibase, trt, inverse)
- unsigned char *bytes;
- int depth;
- Lisp_Object ibase;
- struct Lisp_Char_Table *trt, *inverse;
+set_identity (table, c, elt)
+ Lisp_Object table, c, elt;
{
- register int i;
- Lisp_Object j, tem, q;
- int lim = (depth == 0 ? CHAR_TABLE_ORDINARY_SLOTS : SUB_CHAR_TABLE_ORDINARY_SLOTS);
-
- for (i = 0; i < lim; i++)
- {
- bytes[depth] = i;
- XSETFASTINT (j,
- (depth == 0 && i < CHAR_TABLE_SINGLE_BYTE_SLOTS ? i
- : MAKE_NON_ASCII_CHAR (bytes[0], bytes[1], bytes[2])));
- q = trt->contents[i];
- if (NATNUMP (q) && XFASTINT (q) != XFASTINT (j))
- {
- tem = Faref (ibase, q);
- Faset (ibase, q, j);
- Faset (ibase, j, tem);
- }
- else if (SUB_CHAR_TABLE_P (q))
- {
- bytes[depth] = i - 128;
- compute_trt_shuffle (bytes, depth + 1, ibase,
- XCHAR_TABLE (trt->contents[i]),
- XCHAR_TABLE (inverse->contents[i]));
- }
- }
+ if (NATNUMP (elt))
+ Faset (table, c, c);
}
-/* Given a translate table TRT, store the inverse mapping into INVERSE.
- Since TRT is not one-to-one, INVERSE is not a simple mapping.
- Instead, it divides the space of characters into equivalence classes.
- All characters in a given class form one circular list, chained through
- the elements of INVERSE. */
+/* Permute the elements of TABLE (which is initially an identity
+ mapping) so that it has one cycle for each equivalence class
+ induced by the translation table on which map_char_table is
+ operated. */
static void
-compute_trt_inverse (trt, inv)
- Lisp_Object trt, inv;
+shuffle (table, c, elt)
+ Lisp_Object table, c, elt;
{
- unsigned char bytes[3];
- compute_trt_identity (bytes, 0, XCHAR_TABLE (trt), XCHAR_TABLE (inv));
- compute_trt_shuffle (bytes, 0, inv, XCHAR_TABLE (trt), XCHAR_TABLE (inv));
+ if (NATNUMP (elt) && c != elt)
+ {
+ Lisp_Object tem = Faref (table, elt);
+ Faset (table, elt, c);
+ Faset (table, c, tem);
+ }
}
\f
init_casetab_once ()