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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:
Ulrich Drepper 1999-12-30 08:09:32 +00:00
parent d876f53279
commit 66ac0abe03
10 changed files with 533 additions and 46 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

20
ChangeLog
View File

@ -1,5 +1,25 @@
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.
1999-12-29 Ulrich Drepper <drepper@cygnus.com>
* 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.
* soft-fp/*: Tons of new files to implement floating-point arithmetic
in software.
Contributed by Richard Henderson, Jakub Jelinek and others.

4
NEWS
View File

@ -22,6 +22,10 @@ Version 2.2
* ldconfig program added by Andreas Jaeger and Jakub Jelinek.
* The resolver code has been updated from bind 8.2.2-5 which supports
threads. No changes should be necessary for user programs. The
integration was done by Andreas Jaeger and Adam D. Bradley.
Version 2.1.2

9
locale/C-collate.c
View File

@ -150,8 +150,15 @@ const struct locale_data _nl_C_LC_COLLATE =
_nl_C_name,
NULL, 0, 0, /* no file mapped */
UNDELETABLE,
6,
13,
{
{ word: 0 },
{ string: NULL },
{ string: NULL },
{ string: NULL },
{ string: NULL },
{ string: NULL },
{ word: 0 },
{ word: 0 },
{ string: NULL },
{ string: NULL },

7
locale/categories.def
View File

@ -48,6 +48,13 @@ DEFINE_CATEGORY
DEFINE_ELEMENT (_NL_COLLATE_WEIGHTMB, "collate-weightmb", std, string)
DEFINE_ELEMENT (_NL_COLLATE_EXTRAMB, "collate-extramb", std, string)
DEFINE_ELEMENT (_NL_COLLATE_INDIRECTMB, "collate-indirectmb", std, string)
DEFINE_ELEMENT (_NL_COLLATE_HASH_SIZE, "collate-hash-size", std, word)
DEFINE_ELEMENT (_NL_COLLATE_HASH_LAYERS, "collate-hash-layers", std, word)
DEFINE_ELEMENT (_NL_COLLATE_NAMES, "collate-names", std, string)
DEFINE_ELEMENT (_NL_COLLATE_TABLEWC, "collate-tablewc", std, string)
DEFINE_ELEMENT (_NL_COLLATE_WEIGHTWC, "collate-weightwc", std, string)
DEFINE_ELEMENT (_NL_COLLATE_EXTRAWC, "collate-extrawc", std, string)
DEFINE_ELEMENT (_NL_COLLATE_INDIRECTWC, "collate-indirectwc", std, string)
), NO_POSTLOAD)

7
locale/langinfo.h
View File

@ -236,6 +236,13 @@ enum
_NL_COLLATE_WEIGHTMB,
_NL_COLLATE_EXTRAMB,
_NL_COLLATE_INDIRECTMB,
_NL_COLLATE_HASH_SIZE,
_NL_COLLATE_HASH_LAYERS,
_NL_COLLATE_NAMES,
_NL_COLLATE_TABLEWC,
_NL_COLLATE_WEIGHTWC,
_NL_COLLATE_EXTRAWC,
_NL_COLLATE_INDIRECTWC,
_NL_NUM_LC_COLLATE,
/* LC_CTYPE category: character classification.

442
locale/programs/ld-collate.c
View File

@ -106,6 +106,9 @@ struct element_t
/* Next element in multibyte output list. */
struct element_t *mbnext;
/* Next element in wide character output list. */
struct element_t *wcnext;
};
/* Special element value. */
@ -171,6 +174,14 @@ struct locale_collate_t
/* Arrays with heads of the list for each of the leading bytes in
the multibyte sequences. */
struct element_t *mbheads[256];
/* Table size of wide character hash table. */
size_t plane_size;
size_t plane_cnt;
/* Arrays with heads of the list for each of the leading bytes in
the multibyte sequences. */
struct element_t **wcheads;
};
@ -1381,6 +1392,9 @@ collate_finish (struct localedef_t *locale, struct charmap_t *charmap)
int need_undefined = 0;
struct section_list *sect;
int ruleidx;
int nr_wide_elems = 0;
size_t min_total;
size_t act_size;
if (collate == NULL)
{
@ -1457,8 +1471,8 @@ collate_finish (struct localedef_t *locale, struct charmap_t *charmap)
be encoded to make it possible to emit the value as a byte
string. */
for (i = 0; i < nrules; ++i)
mbact[i] = 3;
wcact = 3;
mbact[i] = 2;
wcact = 2;
runp = collate->start;
while (runp != NULL)
{
@ -1518,7 +1532,13 @@ collate_finish (struct localedef_t *locale, struct charmap_t *charmap)
}
if (runp->wcs != NULL)
runp->wcorder = wcact++;
{
runp->wcorder = wcact++;
/* We take the opportunity to count the elements which have
wide characters. */
++nr_wide_elems;
}
/* Up to the next entry. */
runp = runp->next;
@ -1533,6 +1553,165 @@ collate_finish (struct localedef_t *locale, struct charmap_t *charmap)
collate->mbheads[i] = &collate->undefined;
}
/* Now to the wide character case. Here we have to find first a good
mapping function to get the wide range of wide character values
(0x00000000 to 0x7fffffff) to a managable table. This might take
some time so we issue a warning.
We use a very trivial hashing function to store the sparse
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.
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. */
if (nr_wide_elems > 512 && !be_quiet)
fputs (_("\
Computing table size for collation table might take a while..."),
stderr);
min_total = UINT_MAX;
act_size = 256;
/* 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];
struct element_t *elem[act_size];
size_t act_planes = 1;
memset (cnt, '\0', sizeof cnt);
memset (elem, '\0', sizeof elem);
runp = collate->start;
while (runp != NULL)
{
if (runp->wcs != NULL)
{
size_t nr = runp->wcs[0] % act_size;
struct element_t *elemp = elem[nr];
while (elemp != NULL)
{
if (elemp->wcs[0] == runp->wcs[0])
break;
elemp = elemp->wcnext;
}
if (elemp == NULL && ++cnt[nr] > act_planes)
{
act_planes = cnt[nr];
runp->wcnext = elem[nr];
elem[nr] = runp;
if ((act_size + PENALTY) * act_planes >= min_total)
break;
}
}
/* Up to the next entry. */
runp = runp->next;
}
if ((act_size + PENALTY) * act_planes < min_total)
{
min_total = (act_size + PENALTY) * act_planes;
collate->plane_size = act_size;
collate->plane_cnt = act_planes;
}
++act_size;
}
while (act_size < min_total);
if (nr_wide_elems > 512 && !be_quiet)
fputs (_(" done\n"), stderr);
/* Now that we know how large the table has to be we are able to
allocate the array and start adding the characters to the lists
in the same way we did it for the multibyte characters. */
collate->wcheads = (struct element_t **)
obstack_alloc (&collate->mempool, (collate->plane_size
* collate->plane_cnt
* sizeof (struct element_t *)));
memset (collate->wcheads, '\0', (collate->plane_size
* collate->plane_cnt
* sizeof (struct element_t *)));
/* Start adding. */
runp = collate->start;
while (runp != NULL)
{
if (runp->wcs != NULL)
{
struct element_t **eptr;
size_t idx;
/* Find a free index. */
idx = runp->wcs[0] % collate->plane_size;
while (collate->wcheads[idx] != NULL)
{
/* Stop if this is an entry with the same starting character. */
if (collate->wcheads[idx]->wcs[0] == runp->wcs[0])
break;
idx += collate->plane_size;
}
/* Find the point where to insert in the list. */
eptr = &collate->wcheads[idx];
while (*eptr != NULL)
{
if ((*eptr)->nwcs < runp->nwcs)
break;
if ((*eptr)->nwcs == runp->nwcs)
{
int c = wmemcmp ((wchar_t *) (*eptr)->wcs,
(wchar_t *) runp->wcs, runp->nwcs);
if (c == 0)
{
/* This should not happen. It means that we have
to symbols with the same byte sequence. It is
of course an error. */
error_at_line (0, 0, (*eptr)->file, (*eptr)->line,
_("symbol `%s' has same encoding as"),
(*eptr)->name);
error_at_line (0, 0, runp->file, runp->line,
_("symbol `%s'"), runp->name);
goto dont_insertwc;
}
else if (c < 0)
/* Insert it here. */
break;
}
/* To the next entry. */
eptr = &(*eptr)->wcnext;
}
/* Set the pointers. */
runp->wcnext = *eptr;
*eptr = runp;
dont_insertwc:
}
/* Up to the next entry. */
runp = runp->next;
}
/* Now determine whether the UNDEFINED entry is needed and if yes,
whether it was defined. */
collate->undefined.used_in_level = need_undefined ? ~0ul : 0;
@ -1620,6 +1799,45 @@ output_weight (struct obstack *pool, struct locale_collate_t *collate,
}
static int32_t
output_weightwc (struct obstack *pool, struct locale_collate_t *collate,
struct element_t *elem)
{
size_t cnt;
int32_t retval;
/* Optimize the use of UNDEFINED. */
if (elem == &collate->undefined)
/* The weights are already inserted. */
return 0;
/* This byte can start exactly one collation element and this is
a single byte. We can directly give the index to the weights. */
retval = obstack_object_size (pool);
/* Construct the weight. */
for (cnt = 0; cnt < nrules; ++cnt)
{
int32_t buf[elem->weights[cnt].cnt];
int32_t i;
for (i = 0; i < elem->weights[cnt].cnt; ++i)
if (elem->weights[cnt].w[i] != NULL)
buf[i] = elem->weights[cnt].w[i]->wcorder;
/* And add the buffer content. */
if (sizeof (int) == sizeof (int32_t))
obstack_int_grow (pool, i);
else
obstack_grow (pool, &i, sizeof (int32_t));
obstack_grow (pool, buf, i * sizeof (int32_t));
}
return retval | ((elem->section->ruleidx & 0x7f) << 24);
}
void
collate_output (struct localedef_t *locale, struct charmap_t *charmap,
const char *output_path)
@ -1636,6 +1854,9 @@ collate_output (struct localedef_t *locale, struct charmap_t *charmap,
struct obstack extrapool;
struct obstack indirectpool;
struct section_list *sect;
uint32_t *names;
uint32_t *tablewc;
size_t table_size;
int i;
data.magic = LIMAGIC (LC_COLLATE);
@ -1783,7 +2004,7 @@ collate_output (struct localedef_t *locale, struct charmap_t *charmap,
int i;
/* Now add first the initial byte sequence. */
added = ((sizeof (int32_t) + 1 + 1 + 2 * (runp->nmbs - 1)
added = ((sizeof (int32_t) + 1 + 2 * (runp->nmbs - 1)
+ __alignof__ (int32_t) - 1)
& ~(__alignof__ (int32_t) - 1));
obstack_make_room (&extrapool, added);
@ -1809,7 +2030,7 @@ collate_output (struct localedef_t *locale, struct charmap_t *charmap,
while (1)
{
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,
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);

28
locale/programs/ld-ctype.c
View File

@ -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);

2
resolv/Makefile
View File

@ -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

8
resolv/res_libc.c
View File

@ -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)

52
resolv/resolv.h
View File

@ -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,
const u_char **query,
int *querylen,
u_char *ans,
int anssiz,
int *resplen));
typedef res_sendhookact (*res_send_qhook) (struct sockaddr_in * const *ns,
const u_char **query,
int *querylen,
u_char *ans,
int anssiz,
int *resplen);
typedef res_sendhookact (*res_send_rhook)__P((const struct sockaddr_in *ns,
const u_char *query,
int querylen,
u_char *ans,
int anssiz,
int *resplen));
typedef res_sendhookact (*res_send_rhook) (const struct sockaddr_in *ns,
const u_char *query,
int querylen,
u_char *ans,
int anssiz,
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)