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Update.
1999-12-13 Andreas Jaeger <aj@suse.de> * resolv/resolv.h: Remove K&R compatibility. * resolv/res_libc.c: Move definition of _res after res_init, res_init should use the threaded specific context. * resolv/Makefile (+cflags): Remove -Wno-comment since it's not needed anymore. * locale/langinfo.h: Add constants for wide character collation data. * locale/categories.def: Add appropriate entries for collate entries. * locale/C-collate.c: Add initializers for new entries. * locale/programs/ld-collate.c: Implement output of wide character tables. * locale/programs/ld-ctype.c (allocate_arrays): Change algorithm to compute wide character table size a bit: it now gives up a bit of total table size for fewer levels.
This commit is contained in:
parent
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20
ChangeLog
20
ChangeLog
@ -1,5 +1,25 @@
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1999-12-13 Andreas Jaeger <aj@suse.de>
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* resolv/resolv.h: Remove K&R compatibility.
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* resolv/res_libc.c: Move definition of _res after res_init,
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res_init should use the threaded specific context.
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* resolv/Makefile (+cflags): Remove -Wno-comment since it's not
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needed anymore.
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1999-12-29 Ulrich Drepper <drepper@cygnus.com>
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* locale/langinfo.h: Add constants for wide character collation data.
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* locale/categories.def: Add appropriate entries for collate entries.
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* locale/C-collate.c: Add initializers for new entries.
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* locale/programs/ld-collate.c: Implement output of wide character
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tables.
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* locale/programs/ld-ctype.c (allocate_arrays): Change algorithm to
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compute wide character table size a bit: it now gives up a bit of
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total table size for fewer levels.
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* soft-fp/*: Tons of new files to implement floating-point arithmetic
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in software.
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Contributed by Richard Henderson, Jakub Jelinek and others.
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4
NEWS
4
NEWS
@ -22,6 +22,10 @@ Version 2.2
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* ldconfig program added by Andreas Jaeger and Jakub Jelinek.
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* The resolver code has been updated from bind 8.2.2-5 which supports
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threads. No changes should be necessary for user programs. The
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integration was done by Andreas Jaeger and Adam D. Bradley.
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Version 2.1.2
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@ -150,8 +150,15 @@ const struct locale_data _nl_C_LC_COLLATE =
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_nl_C_name,
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NULL, 0, 0, /* no file mapped */
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UNDELETABLE,
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6,
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13,
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{
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{ word: 0 },
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{ string: NULL },
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{ string: NULL },
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{ string: NULL },
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{ string: NULL },
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{ string: NULL },
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{ word: 0 },
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{ word: 0 },
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{ string: NULL },
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{ string: NULL },
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@ -48,6 +48,13 @@ DEFINE_CATEGORY
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DEFINE_ELEMENT (_NL_COLLATE_WEIGHTMB, "collate-weightmb", std, string)
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DEFINE_ELEMENT (_NL_COLLATE_EXTRAMB, "collate-extramb", std, string)
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DEFINE_ELEMENT (_NL_COLLATE_INDIRECTMB, "collate-indirectmb", std, string)
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DEFINE_ELEMENT (_NL_COLLATE_HASH_SIZE, "collate-hash-size", std, word)
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DEFINE_ELEMENT (_NL_COLLATE_HASH_LAYERS, "collate-hash-layers", std, word)
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DEFINE_ELEMENT (_NL_COLLATE_NAMES, "collate-names", std, string)
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DEFINE_ELEMENT (_NL_COLLATE_TABLEWC, "collate-tablewc", std, string)
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DEFINE_ELEMENT (_NL_COLLATE_WEIGHTWC, "collate-weightwc", std, string)
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DEFINE_ELEMENT (_NL_COLLATE_EXTRAWC, "collate-extrawc", std, string)
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DEFINE_ELEMENT (_NL_COLLATE_INDIRECTWC, "collate-indirectwc", std, string)
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), NO_POSTLOAD)
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@ -236,6 +236,13 @@ enum
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_NL_COLLATE_WEIGHTMB,
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_NL_COLLATE_EXTRAMB,
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_NL_COLLATE_INDIRECTMB,
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_NL_COLLATE_HASH_SIZE,
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_NL_COLLATE_HASH_LAYERS,
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_NL_COLLATE_NAMES,
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_NL_COLLATE_TABLEWC,
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_NL_COLLATE_WEIGHTWC,
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_NL_COLLATE_EXTRAWC,
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_NL_COLLATE_INDIRECTWC,
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_NL_NUM_LC_COLLATE,
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/* LC_CTYPE category: character classification.
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@ -106,6 +106,9 @@ struct element_t
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/* Next element in multibyte output list. */
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struct element_t *mbnext;
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/* Next element in wide character output list. */
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struct element_t *wcnext;
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};
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/* Special element value. */
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@ -171,6 +174,14 @@ struct locale_collate_t
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/* Arrays with heads of the list for each of the leading bytes in
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the multibyte sequences. */
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struct element_t *mbheads[256];
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/* Table size of wide character hash table. */
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size_t plane_size;
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size_t plane_cnt;
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/* Arrays with heads of the list for each of the leading bytes in
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the multibyte sequences. */
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struct element_t **wcheads;
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};
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@ -1381,6 +1392,9 @@ collate_finish (struct localedef_t *locale, struct charmap_t *charmap)
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int need_undefined = 0;
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struct section_list *sect;
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int ruleidx;
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int nr_wide_elems = 0;
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size_t min_total;
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size_t act_size;
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if (collate == NULL)
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{
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@ -1457,8 +1471,8 @@ collate_finish (struct localedef_t *locale, struct charmap_t *charmap)
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be encoded to make it possible to emit the value as a byte
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string. */
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for (i = 0; i < nrules; ++i)
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mbact[i] = 3;
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wcact = 3;
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mbact[i] = 2;
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wcact = 2;
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runp = collate->start;
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while (runp != NULL)
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{
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@ -1518,8 +1532,14 @@ collate_finish (struct localedef_t *locale, struct charmap_t *charmap)
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}
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if (runp->wcs != NULL)
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{
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runp->wcorder = wcact++;
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/* We take the opportunity to count the elements which have
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wide characters. */
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++nr_wide_elems;
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}
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/* Up to the next entry. */
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runp = runp->next;
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}
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@ -1533,6 +1553,165 @@ collate_finish (struct localedef_t *locale, struct charmap_t *charmap)
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collate->mbheads[i] = &collate->undefined;
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}
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/* Now to the wide character case. Here we have to find first a good
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mapping function to get the wide range of wide character values
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(0x00000000 to 0x7fffffff) to a managable table. This might take
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some time so we issue a warning.
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We use a very trivial hashing function to store the sparse
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table. CH % TABSIZE is used as an index. To solve multiple hits
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we have N planes. This guarantees a fixed search time for a
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character [N / 2]. In the following code we determine the minimum
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value for TABSIZE * N, where TABSIZE >= 256.
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Some people complained that this algorithm takes too long. Well,
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go on, improve it. But changing the step size is *not* an
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option. Some people changed this to use only sizes of prime
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numbers. Think again, do some math. We are looking for the
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optimal solution, not something which works in general. Unless
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somebody can provide a dynamic programming solution I think this
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implementation is as good as it can get. */
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if (nr_wide_elems > 512 && !be_quiet)
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fputs (_("\
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Computing table size for collation table might take a while..."),
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stderr);
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min_total = UINT_MAX;
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act_size = 256;
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/* While we want to have a small total size we are willing to use a
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little bit larger table if this reduces the number of layers.
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Therefore we add a little penalty to the number of planes.
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Maybe this constant has to be adjusted a bit. */
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#define PENALTY 128
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do
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{
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size_t cnt[act_size];
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struct element_t *elem[act_size];
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size_t act_planes = 1;
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memset (cnt, '\0', sizeof cnt);
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memset (elem, '\0', sizeof elem);
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runp = collate->start;
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while (runp != NULL)
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{
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if (runp->wcs != NULL)
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{
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size_t nr = runp->wcs[0] % act_size;
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struct element_t *elemp = elem[nr];
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while (elemp != NULL)
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{
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if (elemp->wcs[0] == runp->wcs[0])
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break;
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elemp = elemp->wcnext;
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}
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if (elemp == NULL && ++cnt[nr] > act_planes)
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{
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act_planes = cnt[nr];
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runp->wcnext = elem[nr];
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elem[nr] = runp;
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if ((act_size + PENALTY) * act_planes >= min_total)
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break;
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}
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}
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/* Up to the next entry. */
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runp = runp->next;
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}
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if ((act_size + PENALTY) * act_planes < min_total)
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{
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min_total = (act_size + PENALTY) * act_planes;
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collate->plane_size = act_size;
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collate->plane_cnt = act_planes;
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}
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++act_size;
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}
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while (act_size < min_total);
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if (nr_wide_elems > 512 && !be_quiet)
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fputs (_(" done\n"), stderr);
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/* Now that we know how large the table has to be we are able to
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allocate the array and start adding the characters to the lists
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in the same way we did it for the multibyte characters. */
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collate->wcheads = (struct element_t **)
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obstack_alloc (&collate->mempool, (collate->plane_size
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* collate->plane_cnt
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* sizeof (struct element_t *)));
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memset (collate->wcheads, '\0', (collate->plane_size
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* collate->plane_cnt
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* sizeof (struct element_t *)));
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/* Start adding. */
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runp = collate->start;
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while (runp != NULL)
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{
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if (runp->wcs != NULL)
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{
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struct element_t **eptr;
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size_t idx;
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/* Find a free index. */
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idx = runp->wcs[0] % collate->plane_size;
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while (collate->wcheads[idx] != NULL)
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{
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/* Stop if this is an entry with the same starting character. */
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if (collate->wcheads[idx]->wcs[0] == runp->wcs[0])
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break;
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idx += collate->plane_size;
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}
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/* Find the point where to insert in the list. */
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eptr = &collate->wcheads[idx];
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while (*eptr != NULL)
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{
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if ((*eptr)->nwcs < runp->nwcs)
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break;
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if ((*eptr)->nwcs == runp->nwcs)
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{
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int c = wmemcmp ((wchar_t *) (*eptr)->wcs,
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(wchar_t *) runp->wcs, runp->nwcs);
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if (c == 0)
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{
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/* This should not happen. It means that we have
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to symbols with the same byte sequence. It is
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of course an error. */
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error_at_line (0, 0, (*eptr)->file, (*eptr)->line,
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_("symbol `%s' has same encoding as"),
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(*eptr)->name);
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error_at_line (0, 0, runp->file, runp->line,
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_("symbol `%s'"), runp->name);
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goto dont_insertwc;
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}
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else if (c < 0)
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/* Insert it here. */
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break;
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}
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/* To the next entry. */
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eptr = &(*eptr)->wcnext;
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}
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/* Set the pointers. */
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runp->wcnext = *eptr;
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*eptr = runp;
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dont_insertwc:
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}
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/* Up to the next entry. */
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runp = runp->next;
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}
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/* Now determine whether the UNDEFINED entry is needed and if yes,
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whether it was defined. */
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collate->undefined.used_in_level = need_undefined ? ~0ul : 0;
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@ -1620,6 +1799,45 @@ output_weight (struct obstack *pool, struct locale_collate_t *collate,
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}
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static int32_t
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output_weightwc (struct obstack *pool, struct locale_collate_t *collate,
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struct element_t *elem)
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{
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size_t cnt;
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int32_t retval;
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/* Optimize the use of UNDEFINED. */
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if (elem == &collate->undefined)
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/* The weights are already inserted. */
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return 0;
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/* This byte can start exactly one collation element and this is
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a single byte. We can directly give the index to the weights. */
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retval = obstack_object_size (pool);
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/* Construct the weight. */
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for (cnt = 0; cnt < nrules; ++cnt)
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{
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int32_t buf[elem->weights[cnt].cnt];
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int32_t i;
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for (i = 0; i < elem->weights[cnt].cnt; ++i)
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if (elem->weights[cnt].w[i] != NULL)
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buf[i] = elem->weights[cnt].w[i]->wcorder;
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/* And add the buffer content. */
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if (sizeof (int) == sizeof (int32_t))
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obstack_int_grow (pool, i);
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else
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obstack_grow (pool, &i, sizeof (int32_t));
|
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obstack_grow (pool, buf, i * sizeof (int32_t));
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}
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return retval | ((elem->section->ruleidx & 0x7f) << 24);
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}
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void
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collate_output (struct localedef_t *locale, struct charmap_t *charmap,
|
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const char *output_path)
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@ -1636,6 +1854,9 @@ collate_output (struct localedef_t *locale, struct charmap_t *charmap,
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struct obstack extrapool;
|
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struct obstack indirectpool;
|
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struct section_list *sect;
|
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uint32_t *names;
|
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uint32_t *tablewc;
|
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size_t table_size;
|
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int i;
|
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|
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data.magic = LIMAGIC (LC_COLLATE);
|
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@ -1783,7 +2004,7 @@ collate_output (struct localedef_t *locale, struct charmap_t *charmap,
|
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int i;
|
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|
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/* Now add first the initial byte sequence. */
|
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added = ((sizeof (int32_t) + 1 + 1 + 2 * (runp->nmbs - 1)
|
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added = ((sizeof (int32_t) + 1 + 2 * (runp->nmbs - 1)
|
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+ __alignof__ (int32_t) - 1)
|
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& ~(__alignof__ (int32_t) - 1));
|
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obstack_make_room (&extrapool, added);
|
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@ -1809,7 +2030,7 @@ collate_output (struct localedef_t *locale, struct charmap_t *charmap,
|
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while (1)
|
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{
|
||||
if (sizeof (int32_t) == sizeof (int))
|
||||
obstack_int_grow_fast (&extrapool, weightidx);
|
||||
obstack_int_grow (&extrapool, weightidx);
|
||||
else
|
||||
obstack_grow (&extrapool, &weightidx, sizeof (int32_t));
|
||||
|
||||
@ -1833,7 +2054,7 @@ collate_output (struct localedef_t *locale, struct charmap_t *charmap,
|
||||
|
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weightidx = output_weight (&weightpool, collate, runp);
|
||||
if (sizeof (int32_t) == sizeof (int))
|
||||
obstack_int_grow_fast (&extrapool, weightidx);
|
||||
obstack_int_grow (&extrapool, weightidx);
|
||||
else
|
||||
obstack_grow (&extrapool, &weightidx, sizeof (int32_t));
|
||||
}
|
||||
@ -1844,7 +2065,7 @@ collate_output (struct localedef_t *locale, struct charmap_t *charmap,
|
||||
tested for). */
|
||||
int i;
|
||||
|
||||
added = ((sizeof (int32_t) + 1 + 1 + runp->nmbs - 1
|
||||
added = ((sizeof (int32_t) + 1 + runp->nmbs - 1
|
||||
+ __alignof__ (int32_t) - 1)
|
||||
& ~(__alignof__ (int32_t) - 1));
|
||||
obstack_make_room (&extrapool, added);
|
||||
@ -1900,7 +2121,7 @@ collate_output (struct localedef_t *locale, struct charmap_t *charmap,
|
||||
}
|
||||
}
|
||||
|
||||
/* Now add the three tables. */
|
||||
/* Now add the four tables. */
|
||||
assert (cnt == _NL_ITEM_INDEX (_NL_COLLATE_TABLEMB));
|
||||
iov[2 + cnt].iov_base = tablemb;
|
||||
iov[2 + cnt].iov_len = sizeof (tablemb);
|
||||
@ -1926,6 +2147,211 @@ collate_output (struct localedef_t *locale, struct charmap_t *charmap,
|
||||
++cnt;
|
||||
|
||||
|
||||
/* Now the same for the wide character table. We need to store some
|
||||
more information here. */
|
||||
assert (cnt == _NL_ITEM_INDEX (_NL_COLLATE_HASH_SIZE));
|
||||
iov[2 + cnt].iov_base = &collate->plane_size;
|
||||
iov[2 + cnt].iov_len = sizeof (collate->plane_size);
|
||||
idx[1 + cnt] = idx[cnt] + iov[2 + cnt].iov_len;
|
||||
++cnt;
|
||||
|
||||
assert (cnt == _NL_ITEM_INDEX (_NL_COLLATE_HASH_LAYERS));
|
||||
iov[2 + cnt].iov_base = &collate->plane_cnt;
|
||||
iov[2 + cnt].iov_len = sizeof (collate->plane_cnt);
|
||||
idx[1 + cnt] = idx[cnt] + iov[2 + cnt].iov_len;
|
||||
++cnt;
|
||||
|
||||
/* Construct a table with the names. The size of the table is the same
|
||||
as the table with the pointers. */
|
||||
table_size = collate->plane_size * collate->plane_cnt;
|
||||
names = (uint32_t *) alloca (table_size * sizeof (uint32_t));
|
||||
for (ch = 0; ch < table_size; ++ch)
|
||||
if (collate->wcheads[ch] == NULL)
|
||||
names[ch] = 0;
|
||||
else
|
||||
names[ch] = collate->wcheads[ch]->wcs[0];
|
||||
|
||||
assert (cnt == _NL_ITEM_INDEX (_NL_COLLATE_NAMES));
|
||||
iov[2 + cnt].iov_base = names;
|
||||
iov[2 + cnt].iov_len = table_size * sizeof (uint32_t);
|
||||
idx[1 + cnt] = idx[cnt] + iov[2 + cnt].iov_len;
|
||||
++cnt;
|
||||
|
||||
/* Generate the table. Walk through the lists of sequences
|
||||
starting with the same byte and add them one after the other to
|
||||
the table. In case we have more than one sequence starting with
|
||||
the same byte we have to use extra indirection. */
|
||||
tablewc = (uint32_t *) alloca (table_size * sizeof (uint32_t));
|
||||
for (ch = 0; ch < table_size; ++ch)
|
||||
if (collate->wcheads[ch] == NULL)
|
||||
{
|
||||
/* Set the entry to zero. */
|
||||
tablewc[ch] = 0;
|
||||
}
|
||||
else if (collate->wcheads[ch]->wcnext == NULL
|
||||
&& collate->wcheads[ch]->nwcs == 1)
|
||||
{
|
||||
tablewc[ch] = output_weightwc (&weightpool, collate,
|
||||
collate->wcheads[ch]);
|
||||
}
|
||||
else
|
||||
{
|
||||
/* As for the singlebyte table, we recognize sequences and
|
||||
compress them. */
|
||||
struct element_t *runp = collate->wcheads[ch];
|
||||
struct element_t *lastp;
|
||||
|
||||
tablewc[ch] = -obstack_object_size (&extrapool);
|
||||
|
||||
do
|
||||
{
|
||||
/* Store the current index in the weight table. We know that
|
||||
the current position in the `extrapool' is aligned on a
|
||||
32-bit address. */
|
||||
int32_t weightidx;
|
||||
int added;
|
||||
|
||||
/* Output the weight info. */
|
||||
weightidx = output_weightwc (&weightpool, collate, runp);
|
||||
|
||||
/* Find out wether this is a single entry or we have more than
|
||||
one consecutive entry. */
|
||||
if (runp->wcnext != NULL
|
||||
&& runp->nwcs == runp->wcnext->nwcs
|
||||
&& wmemcmp ((wchar_t *) runp->wcs,
|
||||
(wchar_t *)runp->wcnext->wcs, runp->nwcs - 1) == 0
|
||||
&& (runp->wcs[runp->nwcs - 1] + 1
|
||||
== runp->wcnext->wcs[runp->nwcs - 1]))
|
||||
{
|
||||
int i;
|
||||
|
||||
/* Now add first the initial byte sequence. */
|
||||
added = (1 + 1 + 2 * (runp->nwcs - 1)) * sizeof (int32_t);
|
||||
if (sizeof (int32_t) == sizeof (int))
|
||||
obstack_make_room (&extrapool, added);
|
||||
|
||||
/* More than one consecutive entry. We mark this by having
|
||||
a negative index into the indirect table. */
|
||||
if (sizeof (int32_t) == sizeof (int))
|
||||
{
|
||||
obstack_int_grow_fast (&extrapool,
|
||||
obstack_object_size (&indirectpool)
|
||||
/ sizeof (int32_t));
|
||||
obstack_int_grow_fast (&extrapool, runp->nwcs - 1);
|
||||
}
|
||||
else
|
||||
{
|
||||
int32_t i = (obstack_object_size (&indirectpool)
|
||||
/ sizeof (int32_t));
|
||||
obstack_grow (&extrapool, &i, sizeof (int32_t));
|
||||
i = runp->nwcs - 1;
|
||||
obstack_grow (&extrapool, &i, sizeof (int32_t));
|
||||
}
|
||||
for (i = 1; i < runp->nwcs; ++i)
|
||||
if (sizeof (int32_t) == sizeof (int))
|
||||
obstack_int_grow_fast (&extrapool, runp->wcs[i]);
|
||||
else
|
||||
obstack_grow (&extrapool, &runp->wcs[i], sizeof (int32_t));
|
||||
|
||||
/* Now find the end of the consecutive sequence and
|
||||
add all the indeces in the indirect pool. */
|
||||
while (1)
|
||||
{
|
||||
if (sizeof (int32_t) == sizeof (int))
|
||||
obstack_int_grow (&extrapool, weightidx);
|
||||
else
|
||||
obstack_grow (&extrapool, &weightidx, sizeof (int32_t));
|
||||
|
||||
runp = runp->next;
|
||||
if (runp->wcnext == NULL
|
||||
|| runp->nwcs != runp->wcnext->nwcs
|
||||
|| wmemcmp ((wchar_t *) runp->wcs,
|
||||
(wchar_t *) runp->wcnext->wcs,
|
||||
runp->nwcs - 1) != 0
|
||||
|| (runp->wcs[runp->nwcs - 1] + 1
|
||||
!= runp->wcnext->wcs[runp->nwcs - 1]))
|
||||
break;
|
||||
|
||||
/* Insert the weight. */
|
||||
weightidx = output_weightwc (&weightpool, collate, runp);
|
||||
}
|
||||
|
||||
/* And add the end byte sequence. Without length this
|
||||
time. */
|
||||
for (i = 1; i < runp->nwcs; ++i)
|
||||
if (sizeof (int32_t) == sizeof (int))
|
||||
obstack_int_grow (&extrapool, runp->wcs[i]);
|
||||
else
|
||||
obstack_grow (&extrapool, &runp->wcs[i], sizeof (int32_t));
|
||||
|
||||
weightidx = output_weightwc (&weightpool, collate, runp);
|
||||
if (sizeof (int32_t) == sizeof (int))
|
||||
obstack_int_grow (&extrapool, weightidx);
|
||||
else
|
||||
obstack_grow (&extrapool, &weightidx, sizeof (int32_t));
|
||||
}
|
||||
else
|
||||
{
|
||||
/* A single entry. Simply add the index and the length and
|
||||
string (except for the first character which is already
|
||||
tested for). */
|
||||
int i;
|
||||
|
||||
added = (1 + 1 + runp->nwcs - 1) * sizeof (int32_t);
|
||||
if (sizeof (int) == sizeof (int32_t))
|
||||
obstack_make_room (&extrapool, added);
|
||||
|
||||
if (sizeof (int32_t) == sizeof (int))
|
||||
{
|
||||
obstack_int_grow_fast (&extrapool, weightidx);
|
||||
obstack_int_grow_fast (&extrapool, runp->nwcs - 1);
|
||||
}
|
||||
else
|
||||
{
|
||||
int32_t l = runp->nwcs - 1;
|
||||
obstack_grow (&extrapool, &weightidx, sizeof (int32_t));
|
||||
obstack_grow (&extrapool, &l, sizeof (int32_t));
|
||||
}
|
||||
for (i = 1; i < runp->nwcs; ++i)
|
||||
if (sizeof (int32_t) == sizeof (int))
|
||||
obstack_int_grow_fast (&extrapool, runp->wcs[i]);
|
||||
else
|
||||
obstack_grow (&extrapool, &runp->wcs[i], sizeof (int32_t));
|
||||
}
|
||||
|
||||
/* Next entry. */
|
||||
lastp = runp;
|
||||
runp = runp->wcnext;
|
||||
}
|
||||
while (runp != NULL);
|
||||
}
|
||||
|
||||
/* Now add the four tables. */
|
||||
assert (cnt == _NL_ITEM_INDEX (_NL_COLLATE_TABLEWC));
|
||||
iov[2 + cnt].iov_base = tablewc;
|
||||
iov[2 + cnt].iov_len = table_size * sizeof (int32_t);
|
||||
idx[1 + cnt] = idx[cnt] + iov[2 + cnt].iov_len;
|
||||
++cnt;
|
||||
|
||||
assert (cnt == _NL_ITEM_INDEX (_NL_COLLATE_WEIGHTWC));
|
||||
iov[2 + cnt].iov_len = obstack_object_size (&weightpool);
|
||||
iov[2 + cnt].iov_base = obstack_finish (&weightpool);
|
||||
idx[1 + cnt] = idx[cnt] + iov[2 + cnt].iov_len;
|
||||
++cnt;
|
||||
|
||||
assert (cnt == _NL_ITEM_INDEX (_NL_COLLATE_EXTRAWC));
|
||||
iov[2 + cnt].iov_len = obstack_object_size (&extrapool);
|
||||
iov[2 + cnt].iov_base = obstack_finish (&extrapool);
|
||||
idx[1 + cnt] = idx[cnt] + iov[2 + cnt].iov_len;
|
||||
++cnt;
|
||||
|
||||
assert (cnt == _NL_ITEM_INDEX (_NL_COLLATE_INDIRECTWC));
|
||||
iov[2 + cnt].iov_len = obstack_object_size (&indirectpool);
|
||||
iov[2 + cnt].iov_base = obstack_finish (&indirectpool);
|
||||
idx[1 + cnt] = idx[cnt] + iov[2 + cnt].iov_len;
|
||||
++cnt;
|
||||
|
||||
|
||||
assert (cnt == _NL_ITEM_INDEX (_NL_NUM_LC_COLLATE));
|
||||
|
||||
write_locale_data (output_path, "LC_COLLATE", 2 + cnt, iov);
|
||||
|
@ -2937,16 +2937,29 @@ allocate_arrays (struct locale_ctype_t *ctype, struct charmap_t *charmap,
|
||||
table. CH % TABSIZE is used as an index. To solve multiple hits
|
||||
we have N planes. This guarantees a fixed search time for a
|
||||
character [N / 2]. In the following code we determine the minimum
|
||||
value for TABSIZE * N, where TABSIZE >= 256. */
|
||||
value for TABSIZE * N, where TABSIZE >= 256.
|
||||
|
||||
Some people complained that this algorithm takes too long. Well,
|
||||
go on, improve it. But changing the step size is *not* an
|
||||
option. Some people changed this to use only sizes of prime
|
||||
numbers. Think again, do some math. We are looking for the
|
||||
optimal solution, not something which works in general. Unless
|
||||
somebody can provide a dynamic programming solution I think this
|
||||
implementation is as good as it can get. */
|
||||
size_t min_total = UINT_MAX;
|
||||
size_t act_size = 256;
|
||||
|
||||
if (!be_quiet)
|
||||
if (!be_quiet && ctype->charnames_act > 512)
|
||||
fputs (_("\
|
||||
Computing table size for character classes might take a while..."),
|
||||
stderr);
|
||||
|
||||
while (act_size < min_total)
|
||||
/* While we want to have a small total size we are willing to use a
|
||||
little bit larger table if this reduces the number of layers.
|
||||
Therefore we add a little penalty to the number of planes.
|
||||
Maybe this constant has to be adjusted a bit. */
|
||||
#define PENALTY 128
|
||||
do
|
||||
{
|
||||
size_t cnt[act_size];
|
||||
size_t act_planes = 1;
|
||||
@ -2964,22 +2977,23 @@ Computing table size for character classes might take a while..."),
|
||||
if (++cnt[nr] > act_planes)
|
||||
{
|
||||
act_planes = cnt[nr];
|
||||
if (act_size * act_planes >= min_total)
|
||||
if ((act_size + PENALTY) * act_planes >= min_total)
|
||||
break;
|
||||
}
|
||||
}
|
||||
|
||||
if (act_size * act_planes < min_total)
|
||||
if ((act_size + PENALTY) * act_planes < min_total)
|
||||
{
|
||||
min_total = act_size * act_planes;
|
||||
min_total = (act_size + PENALTY) * act_planes;
|
||||
ctype->plane_size = act_size;
|
||||
ctype->plane_cnt = act_planes;
|
||||
}
|
||||
|
||||
++act_size;
|
||||
}
|
||||
while (act_size < min_total);
|
||||
|
||||
if (!be_quiet)
|
||||
if (!be_quiet && ctype->charnames_act > 512)
|
||||
fputs (_(" done\n"), stderr);
|
||||
|
||||
|
||||
|
@ -57,7 +57,7 @@ CPPFLAGS += -Dgethostbyname=res_gethostbyname \
|
||||
-Dgetnetbyaddr=res_getnetbyaddr
|
||||
|
||||
# The BIND code elicits some harmless warnings.
|
||||
+cflags += -Wno-strict-prototypes -Wno-comment -Wno-write-strings
|
||||
+cflags += -Wno-strict-prototypes -Wno-write-strings
|
||||
|
||||
# Depend on libc.so so a DT_NEEDED is generated in the shared objects.
|
||||
# This ensures they will load libc.so for needed symbols if loaded by
|
||||
|
@ -38,9 +38,6 @@ static const char rcsid[] = "$Id$";
|
||||
#include <string.h>
|
||||
#include <unistd.h>
|
||||
|
||||
#undef _res
|
||||
|
||||
struct __res_state _res;
|
||||
|
||||
/* This is the old res_init function. It has been moved from
|
||||
res_data.c to this file since res_init should go into libc.so but
|
||||
@ -90,6 +87,11 @@ res_init(void) {
|
||||
/* We need a resolver context - in unthreaded apps, this weak function
|
||||
provides it. */
|
||||
|
||||
#undef _res
|
||||
|
||||
struct __res_state _res;
|
||||
|
||||
|
||||
struct __res_state *
|
||||
weak_const_function
|
||||
__res_state(void)
|
||||
|
@ -136,19 +136,19 @@ struct __res_state; /* forward */
|
||||
typedef enum { res_goahead, res_nextns, res_modified, res_done, res_error }
|
||||
res_sendhookact;
|
||||
|
||||
typedef res_sendhookact (*res_send_qhook)__P((struct sockaddr_in * const *ns,
|
||||
typedef res_sendhookact (*res_send_qhook) (struct sockaddr_in * const *ns,
|
||||
const u_char **query,
|
||||
int *querylen,
|
||||
u_char *ans,
|
||||
int anssiz,
|
||||
int *resplen));
|
||||
int *resplen);
|
||||
|
||||
typedef res_sendhookact (*res_send_rhook)__P((const struct sockaddr_in *ns,
|
||||
typedef res_sendhookact (*res_send_rhook) (const struct sockaddr_in *ns,
|
||||
const u_char *query,
|
||||
int querylen,
|
||||
u_char *ans,
|
||||
int anssiz,
|
||||
int *resplen));
|
||||
int *resplen);
|
||||
|
||||
struct res_sym {
|
||||
int number; /* Identifying number, like T_MX */
|
||||
@ -270,20 +270,20 @@ extern struct __res_state _res;
|
||||
#define res_send __res_send
|
||||
|
||||
__BEGIN_DECLS
|
||||
void fp_nquery __P((const u_char *, int, FILE *));
|
||||
void fp_query __P((const u_char *, FILE *));
|
||||
const char * hostalias __P((const char *));
|
||||
void p_query __P((const u_char *));
|
||||
void res_close __P((void));
|
||||
int res_init __P((void));
|
||||
int res_isourserver __P((const struct sockaddr_in *));
|
||||
int res_mkquery __P((int, const char *, int, int, const u_char *,
|
||||
int, const u_char *, u_char *, int));
|
||||
int res_query __P((const char *, int, int, u_char *, int));
|
||||
int res_querydomain __P((const char *, const char *, int, int,
|
||||
u_char *, int));
|
||||
int res_search __P((const char *, int, int, u_char *, int));
|
||||
int res_send __P((const u_char *, int, u_char *, int));
|
||||
void fp_nquery (const u_char *, int, FILE *) __THROW;
|
||||
void fp_query (const u_char *, FILE *) __THROW;
|
||||
const char * hostalias (const char *) __THROW;
|
||||
void p_query (const u_char *) __THROW;
|
||||
void res_close (void) __THROW;
|
||||
int res_init (void) __THROW;
|
||||
int res_isourserver (const struct sockaddr_in *) __THROW;
|
||||
int res_mkquery (int, const char *, int, int, const u_char *,
|
||||
int, const u_char *, u_char *, int) __THROW;
|
||||
int res_query (const char *, int, int, u_char *, int) __THROW;
|
||||
int res_querydomain (const char *, const char *, int, int,
|
||||
u_char *, int) __THROW;
|
||||
int res_search (const char *, int, int, u_char *, int) __THROW;
|
||||
int res_send (const u_char *, int, u_char *, int) __THROW;
|
||||
__END_DECLS
|
||||
|
||||
#if !defined(SHARED_LIBBIND) || defined(_LIBC)
|
||||
|
Loading…
Reference in New Issue
Block a user