google3/third_party/grte/v4_src/glibc-2.19/elf/dl-hwcaps.c - GRTEv4 - Git at Google

 /* Hardware capability support for run-time dynamic loader.
    Copyright (C) 2012-2014 Free Software Foundation, Inc.
    This file is part of the GNU C Library.

    The GNU C Library is free software; you can redistribute it and/or
    modify it under the terms of the GNU Lesser General Public
    License as published by the Free Software Foundation; either
    version 2.1 of the License, or (at your option) any later version.

    The GNU C Library 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
    Lesser General Public License for more details.

    You should have received a copy of the GNU Lesser General Public
    License along with the GNU C Library; if not, see
    <http://www.gnu.org/licenses/>.  */

 #include <assert.h>
 #include <elf.h>
 #include <errno.h>
 #include <libintl.h>
 #include <unistd.h>
 #include <ldsodefs.h>

 #include <dl-procinfo.h>

 #ifdef _DL_FIRST_PLATFORM
 # define _DL_FIRST_EXTRA (_DL_FIRST_PLATFORM + _DL_PLATFORMS_COUNT)
 #else
 # define _DL_FIRST_EXTRA _DL_HWCAP_COUNT
 #endif

 /* Return an array of useful/necessary hardware capability names.  */
 const struct r_strlenpair *
 internal_function
 _dl_important_hwcaps (const char *platform, size_t platform_len, size_t *sz,
 		      size_t *max_capstrlen)
 {
   /* Determine how many important bits are set.  */
   uint64_t masked = GLRO(dl_hwcap) & GLRO(dl_hwcap_mask);
   size_t cnt = platform != NULL;
   size_t n, m;
   size_t total;
   struct r_strlenpair *result;
   struct r_strlenpair *rp;
   char *cp;

   /* Count the number of bits set in the masked value.  */
   for (n = 0; (~((1ULL << n) - 1) & masked) != 0; ++n)
     if ((masked & (1ULL << n)) != 0)
       ++cnt;

 #ifdef NEED_DL_SYSINFO_DSO
   /* The system-supplied DSO can contain a note of type 2, vendor "GNU".
      This gives us a list of names to treat as fake hwcap bits.  */

   const char *dsocaps = NULL;
   size_t dsocapslen = 0;
   if (GLRO(dl_sysinfo_map) != NULL)
     {
       const ElfW(Phdr) *const phdr = GLRO(dl_sysinfo_map)->l_phdr;
       const ElfW(Word) phnum = GLRO(dl_sysinfo_map)->l_phnum;
       for (uint_fast16_t i = 0; i < phnum; ++i)
 	if (phdr[i].p_type == PT_NOTE)
 	  {
 	    const ElfW(Addr) start = (phdr[i].p_vaddr
 				      + GLRO(dl_sysinfo_map)->l_addr);
 	    /* The standard ELF note layout is exactly as the anonymous struct.
 	       The next element is a variable length vendor name of length
 	       VENDORLEN (with a real length rounded to ElfW(Word)), followed
 	       by the data of length DATALEN (with a real length rounded to
 	       ElfW(Word)).  */
 	    const struct
 	    {
 	      ElfW(Word) vendorlen;
 	      ElfW(Word) datalen;
 	      ElfW(Word) type;
 	    } *note = (const void *) start;
 	    while ((ElfW(Addr)) (note + 1) - start < phdr[i].p_memsz)
 	      {
 #define ROUND(len) (((len) + sizeof (ElfW(Word)) - 1) & -sizeof (ElfW(Word)))
 		/* The layout of the type 2, vendor "GNU" note is as follows:
 		   .long <Number of capabilities enabled by this note>
 		   .long <Capabilities mask> (as mask >> _DL_FIRST_EXTRA).
 		   .byte <The bit number for the next capability>
 		   .asciz <The name of the capability>.  */
 		if (note->type == NT_GNU_HWCAP
 		    && note->vendorlen == sizeof "GNU"
 		    && !memcmp ((note + 1), "GNU", sizeof "GNU")
 		    && note->datalen > 2 * sizeof (ElfW(Word)) + 2)
 		  {
 		    const ElfW(Word) *p = ((const void *) (note + 1)
 					   + ROUND (sizeof "GNU"));
 		    cnt += *p++;
 		    ++p;	/* Skip mask word.  */
 		    dsocaps = (const char *) p; /* Pseudo-string "<b>name"  */
 		    dsocapslen = note->datalen - sizeof *p * 2;
 		    break;
 		  }
 		note = ((const void *) (note + 1)
 			+ ROUND (note->vendorlen) + ROUND (note->datalen));
 #undef ROUND
 	      }
 	    if (dsocaps != NULL)
 	      break;
 	  }
     }
 #endif

   /* For TLS enabled builds always add 'tls'.  */
   ++cnt;

   /* Create temporary data structure to generate result table.  */
   struct r_strlenpair temp[cnt];
   m = 0;
 #ifdef NEED_DL_SYSINFO_DSO
   if (dsocaps != NULL)
     {
       /* dsocaps points to the .asciz string, and -1 points to the mask
          .long just before the string.  */
       const ElfW(Word) mask = ((const ElfW(Word) *) dsocaps)[-1];
       GLRO(dl_hwcap) |= (uint64_t) mask << _DL_FIRST_EXTRA;
       /* Note that we add the dsocaps to the set already chosen by the
 	 LD_HWCAP_MASK environment variable (or default HWCAP_IMPORTANT).
 	 So there is no way to request ignoring an OS-supplied dsocap
 	 string and bit like you can ignore an OS-supplied HWCAP bit.  */
       GLRO(dl_hwcap_mask) |= (uint64_t) mask << _DL_FIRST_EXTRA;
       size_t len;
       for (const char *p = dsocaps; p < dsocaps + dsocapslen; p += len + 1)
 	{
 	  uint_fast8_t bit = *p++;
 	  len = strlen (p);

 	  /* Skip entries that are not enabled in the mask word.  */
 	  if (__builtin_expect (mask & ((ElfW(Word)) 1 << bit), 1))
 	    {
 	      temp[m].str = p;
 	      temp[m].len = len;
 	      ++m;
 	    }
 	  else
 	    --cnt;
 	}
     }
 #endif
   for (n = 0; masked != 0; ++n)
     if ((masked & (1ULL << n)) != 0)
       {
 	temp[m].str = _dl_hwcap_string (n);
 	temp[m].len = strlen (temp[m].str);
 	masked ^= 1ULL << n;
 	++m;
       }
   if (platform != NULL)
     {
       temp[m].str = platform;
       temp[m].len = platform_len;
       ++m;
     }

   temp[m].str = "tls";
   temp[m].len = 3;
   ++m;

   assert (m == cnt);

   /* Determine the total size of all strings together.  */
   if (cnt == 1)
     total = temp[0].len + 1;
   else
     {
       total = temp[0].len + temp[cnt - 1].len + 2;
       if (cnt > 2)
 	{
 	  total <<= 1;
 	  for (n = 1; n + 1 < cnt; ++n)
 	    total += temp[n].len + 1;
 	  if (cnt > 3
 	      && (cnt >= sizeof (size_t) * 8
 		  || total + (sizeof (*result) << 3)
 		     >= (1UL << (sizeof (size_t) * 8 - cnt + 3))))
 	    _dl_signal_error (ENOMEM, NULL, NULL,
 			      N_("cannot create capability list"));

 	  total <<= cnt - 3;
 	}
     }

   /* The result structure: we use a very compressed way to store the
      various combinations of capability names.  */
   *sz = 1 << cnt;
   result = (struct r_strlenpair *) malloc (*sz * sizeof (*result) + total);
   if (result == NULL)
     _dl_signal_error (ENOMEM, NULL, NULL,
 		      N_("cannot create capability list"));

   if (cnt == 1)
     {
       result[0].str = (char *) (result + *sz);
       result[0].len = temp[0].len + 1;
       result[1].str = (char *) (result + *sz);
       result[1].len = 0;
       cp = __mempcpy ((char *) (result + *sz), temp[0].str, temp[0].len);
       *cp = '/';
       *sz = 2;
       *max_capstrlen = result[0].len;

       return result;
     }

   /* Fill in the information.  This follows the following scheme
      (indices from TEMP for four strings):
 	entry #0: 0, 1, 2, 3	binary: 1111
 	      #1: 0, 1, 3		1101
 	      #2: 0, 2, 3		1011
 	      #3: 0, 3			1001
      This allows the representation of all possible combinations of
      capability names in the string.  First generate the strings.  */
   result[1].str = result[0].str = cp = (char *) (result + *sz);
 #define add(idx) \
       cp = __mempcpy (__mempcpy (cp, temp[idx].str, temp[idx].len), "/", 1);
   if (cnt == 2)
     {
       add (1);
       add (0);
     }
   else
     {
       n = 1 << (cnt - 1);
       do
 	{
 	  n -= 2;

 	  /* We always add the last string.  */
 	  add (cnt - 1);

 	  /* Add the strings which have the bit set in N.  */
 	  for (m = cnt - 2; m > 0; --m)
 	    if ((n & (1 << m)) != 0)
 	      add (m);

 	  /* Always add the first string.  */
 	  add (0);
 	}
       while (n != 0);
     }
 #undef add

   /* Now we are ready to install the string pointers and length.  */
   for (n = 0; n < (1UL << cnt); ++n)
     result[n].len = 0;
   n = cnt;
   do
     {
       size_t mask = 1 << --n;

       rp = result;
       for (m = 1 << cnt; m > 0; ++rp)
 	if ((--m & mask) != 0)
 	  rp->len += temp[n].len + 1;
     }
   while (n != 0);

   /* The first half of the strings all include the first string.  */
   n = (1 << cnt) - 2;
   rp = &result[2];
   while (n != (1UL << (cnt - 1)))
     {
       if ((--n & 1) != 0)
 	rp[0].str = rp[-2].str + rp[-2].len;
       else
 	rp[0].str = rp[-1].str;
       ++rp;
     }

   /* The second half starts right after the first part of the string of
      the corresponding entry in the first half.  */
   do
     {
       rp[0].str = rp[-(1 << (cnt - 1))].str + temp[cnt - 1].len + 1;
       ++rp;
     }
   while (--n != 0);

   /* The maximum string length.  */
   *max_capstrlen = result[0].len;

   return result;
 }
	/* Hardware capability support for run-time dynamic loader.
	Copyright (C) 2012-2014 Free Software Foundation, Inc.
	This file is part of the GNU C Library.

	The GNU C Library is free software; you can redistribute it and/or
	modify it under the terms of the GNU Lesser General Public
	License as published by the Free Software Foundation; either
	version 2.1 of the License, or (at your option) any later version.

	The GNU C Library 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
	Lesser General Public License for more details.

	You should have received a copy of the GNU Lesser General Public
	License along with the GNU C Library; if not, see
	<http://www.gnu.org/licenses/>. */

	#include <assert.h>
	#include <elf.h>
	#include <errno.h>
	#include <libintl.h>
	#include <unistd.h>
	#include <ldsodefs.h>

	#include <dl-procinfo.h>

	#ifdef _DL_FIRST_PLATFORM
	# define _DL_FIRST_EXTRA (_DL_FIRST_PLATFORM + _DL_PLATFORMS_COUNT)
	#else
	# define _DL_FIRST_EXTRA _DL_HWCAP_COUNT
	#endif

	/* Return an array of useful/necessary hardware capability names. */
	const struct r_strlenpair *
	internal_function
	_dl_important_hwcaps (const char platform, size_t platform_len, size_t sz,
	size_t *max_capstrlen)
	{
	/* Determine how many important bits are set. */
	uint64_t masked = GLRO(dl_hwcap) & GLRO(dl_hwcap_mask);
	size_t cnt = platform != NULL;
	size_t n, m;
	size_t total;
	struct r_strlenpair *result;
	struct r_strlenpair *rp;
	char *cp;

	/* Count the number of bits set in the masked value. */
	for (n = 0; (~((1ULL << n) - 1) & masked) != 0; ++n)
	if ((masked & (1ULL << n)) != 0)
	++cnt;

	#ifdef NEED_DL_SYSINFO_DSO
	/* The system-supplied DSO can contain a note of type 2, vendor "GNU".
	This gives us a list of names to treat as fake hwcap bits. */

	const char *dsocaps = NULL;
	size_t dsocapslen = 0;
	if (GLRO(dl_sysinfo_map) != NULL)
	{
	const ElfW(Phdr) *const phdr = GLRO(dl_sysinfo_map)->l_phdr;
	const ElfW(Word) phnum = GLRO(dl_sysinfo_map)->l_phnum;
	for (uint_fast16_t i = 0; i < phnum; ++i)
	if (phdr[i].p_type == PT_NOTE)
	{
	const ElfW(Addr) start = (phdr[i].p_vaddr
	+ GLRO(dl_sysinfo_map)->l_addr);
	/* The standard ELF note layout is exactly as the anonymous struct.
	The next element is a variable length vendor name of length
	VENDORLEN (with a real length rounded to ElfW(Word)), followed
	by the data of length DATALEN (with a real length rounded to
	ElfW(Word)). */
	const struct
	{
	ElfW(Word) vendorlen;
	ElfW(Word) datalen;
	ElfW(Word) type;
	} note = (const void ) start;
	while ((ElfW(Addr)) (note + 1) - start < phdr[i].p_memsz)
	{
	#define ROUND(len) (((len) + sizeof (ElfW(Word)) - 1) & -sizeof (ElfW(Word)))
	/* The layout of the type 2, vendor "GNU" note is as follows:
	.long <Number of capabilities enabled by this note>
	.long <Capabilities mask> (as mask >> _DL_FIRST_EXTRA).
	.byte <The bit number for the next capability>
	.asciz <The name of the capability>. */
	if (note->type == NT_GNU_HWCAP
	&& note->vendorlen == sizeof "GNU"
	&& !memcmp ((note + 1), "GNU", sizeof "GNU")
	&& note->datalen > 2 * sizeof (ElfW(Word)) + 2)
	{
	const ElfW(Word) p = ((const void ) (note + 1)
	+ ROUND (sizeof "GNU"));
	cnt += *p++;
	++p; /* Skip mask word. */
	dsocaps = (const char ) p; / Pseudo-string "<b>name" */
	dsocapslen = note->datalen - sizeof p 2;
	break;
	}
	note = ((const void *) (note + 1)
	+ ROUND (note->vendorlen) + ROUND (note->datalen));
	#undef ROUND
	}
	if (dsocaps != NULL)
	break;
	}
	}
	#endif

	/* For TLS enabled builds always add 'tls'. */
	++cnt;

	/* Create temporary data structure to generate result table. */
	struct r_strlenpair temp[cnt];
	m = 0;
	#ifdef NEED_DL_SYSINFO_DSO
	if (dsocaps != NULL)
	{
	/* dsocaps points to the .asciz string, and -1 points to the mask
	.long just before the string. */
	const ElfW(Word) mask = ((const ElfW(Word) *) dsocaps)[-1];
	GLRO(dl_hwcap) \|= (uint64_t) mask << _DL_FIRST_EXTRA;
	/* Note that we add the dsocaps to the set already chosen by the
	LD_HWCAP_MASK environment variable (or default HWCAP_IMPORTANT).
	So there is no way to request ignoring an OS-supplied dsocap
	string and bit like you can ignore an OS-supplied HWCAP bit. */
	GLRO(dl_hwcap_mask) \|= (uint64_t) mask << _DL_FIRST_EXTRA;
	size_t len;
	for (const char *p = dsocaps; p < dsocaps + dsocapslen; p += len + 1)
	{
	uint_fast8_t bit = *p++;
	len = strlen (p);

	/* Skip entries that are not enabled in the mask word. */
	if (__builtin_expect (mask & ((ElfW(Word)) 1 << bit), 1))
	{
	temp[m].str = p;
	temp[m].len = len;
	++m;
	}
	else
	--cnt;
	}
	}
	#endif
	for (n = 0; masked != 0; ++n)
	if ((masked & (1ULL << n)) != 0)
	{
	temp[m].str = _dl_hwcap_string (n);
	temp[m].len = strlen (temp[m].str);
	masked ^= 1ULL << n;
	++m;
	}
	if (platform != NULL)
	{
	temp[m].str = platform;
	temp[m].len = platform_len;
	++m;
	}

	temp[m].str = "tls";
	temp[m].len = 3;
	++m;

	assert (m == cnt);

	/* Determine the total size of all strings together. */
	if (cnt == 1)
	total = temp[0].len + 1;
	else
	{
	total = temp[0].len + temp[cnt - 1].len + 2;
	if (cnt > 2)
	{
	total <<= 1;
	for (n = 1; n + 1 < cnt; ++n)
	total += temp[n].len + 1;
	if (cnt > 3
	&& (cnt >= sizeof (size_t) * 8
	\|\| total + (sizeof (*result) << 3)
	>= (1UL << (sizeof (size_t) * 8 - cnt + 3))))
	_dl_signal_error (ENOMEM, NULL, NULL,
	N_("cannot create capability list"));

	total <<= cnt - 3;
	}
	}

	/* The result structure: we use a very compressed way to store the
	various combinations of capability names. */
	*sz = 1 << cnt;
	result = (struct r_strlenpair ) malloc (sz * sizeof (*result) + total);
	if (result == NULL)
	_dl_signal_error (ENOMEM, NULL, NULL,
	N_("cannot create capability list"));

	if (cnt == 1)
	{
	result[0].str = (char ) (result + sz);
	result[0].len = temp[0].len + 1;
	result[1].str = (char ) (result + sz);
	result[1].len = 0;
	cp = __mempcpy ((char ) (result + sz), temp[0].str, temp[0].len);
	*cp = '/';
	*sz = 2;
	*max_capstrlen = result[0].len;

	return result;
	}

	/* Fill in the information. This follows the following scheme
	(indices from TEMP for four strings):
	entry #0: 0, 1, 2, 3 binary: 1111
	#1: 0, 1, 3 1101
	#2: 0, 2, 3 1011
	#3: 0, 3 1001
	This allows the representation of all possible combinations of
	capability names in the string. First generate the strings. */
	result[1].str = result[0].str = cp = (char ) (result + sz);
	#define add(idx) \
	cp = __mempcpy (__mempcpy (cp, temp[idx].str, temp[idx].len), "/", 1);
	if (cnt == 2)
	{
	add (1);
	add (0);
	}
	else
	{
	n = 1 << (cnt - 1);
	do
	{
	n -= 2;

	/* We always add the last string. */
	add (cnt - 1);

	/* Add the strings which have the bit set in N. */
	for (m = cnt - 2; m > 0; --m)
	if ((n & (1 << m)) != 0)
	add (m);

	/* Always add the first string. */
	add (0);
	}
	while (n != 0);
	}
	#undef add

	/* Now we are ready to install the string pointers and length. */
	for (n = 0; n < (1UL << cnt); ++n)
	result[n].len = 0;
	n = cnt;
	do
	{
	size_t mask = 1 << --n;

	rp = result;
	for (m = 1 << cnt; m > 0; ++rp)
	if ((--m & mask) != 0)
	rp->len += temp[n].len + 1;
	}
	while (n != 0);

	/* The first half of the strings all include the first string. */
	n = (1 << cnt) - 2;
	rp = &result[2];
	while (n != (1UL << (cnt - 1)))
	{
	if ((--n & 1) != 0)
	rp[0].str = rp[-2].str + rp[-2].len;
	else
	rp[0].str = rp[-1].str;
	++rp;
	}

	/* The second half starts right after the first part of the string of
	the corresponding entry in the first half. */
	do
	{
	rp[0].str = rp[-(1 << (cnt - 1))].str + temp[cnt - 1].len + 1;
	++rp;
	}
	while (--n != 0);

	/* The maximum string length. */
	*max_capstrlen = result[0].len;

	return result;
	}