google3/third_party/grte/v5_src/glibc-2.27/elf/dl-misc.c - GRTEv5 - Git at Google

 /* Miscellaneous support functions for dynamic linker
    Copyright (C) 1997-2018 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 <fcntl.h>
 #include <ldsodefs.h>
 #include <limits.h>
 #include <link.h>
 #include <stdarg.h>
 #include <stdlib.h>
 #include <string.h>
 #include <unistd.h>
 #include <stdint.h>
 #include <sys/mman.h>
 #include <sys/param.h>
 #include <sys/stat.h>
 #include <sys/uio.h>
 #include <sysdep.h>
 #include <_itoa.h>
 #include <dl-writev.h>


 /* Read the whole contents of FILE into new mmap'd space with given
    protections.  *SIZEP gets the size of the file.  On error MAP_FAILED
    is returned.  */

 void *
 _dl_sysdep_read_whole_file (const char *file, size_t *sizep, int prot)
 {
   void *result = MAP_FAILED;
   struct stat64 st;
   int fd = __open (file, O_RDONLY | O_CLOEXEC);
   if (fd >= 0)
     {
       if (__fxstat64 (_STAT_VER, fd, &st) >= 0)
 	{
 	  *sizep = st.st_size;

 	  /* No need to map the file if it is empty.  */
 	  if (*sizep != 0)
 	    /* Map a copy of the file contents.  */
 	    result = __mmap (NULL, *sizep, prot,
 #ifdef MAP_COPY
 			     MAP_COPY
 #else
 			     MAP_PRIVATE
 #endif
 #ifdef MAP_FILE
 			     | MAP_FILE
 #endif
 			     , fd, 0);
 	}
       __close (fd);
     }
   return result;
 }


 /* Bare-bones printf implementation.  This function only knows about
    the formats and flags needed and can handle only up to 64 stripes in
    the output.  */
 static void
 _dl_debug_vdprintf (int fd, int tag_p, const char *fmt, va_list arg)
 {
 # define NIOVMAX 64
   struct iovec iov[NIOVMAX];
   int niov = 0;
   pid_t pid = 0;
   char pidbuf[23];
   pid_t tid = 0;
   /* Start with a known bad value, should never get used.  */
   char *tag_start = NULL;

   while (*fmt != '\0')
     {
       const char *startp = fmt;

       if (tag_p > 0)
 	{
 	  /* Generate the tag line once.  It consists of the PID and a
 	     colon followed by a tab.  */
 	  if (pid == 0)
 	    {
 	      char *p = &pidbuf[21];

 	      pid = __getpid ();
 	      assert (pid >= 0 && sizeof (pid_t) <= 4);

               /* If we are doing thread-related output, maybe add a thread id,
                  taking care that pid continues to appear at the same
                  positions.  */
               tid = _dl_tls_tid ();
               if (tid > 0)
                 {
                   p = _itoa (tid, p, 10, 0);
                   *--p = '/';
                 }
               tag_start = p - 10;
 	      p = _itoa (pid, p, 10, 0);
 	      while (p > tag_start)
 		*--p = ' ';
 	      pidbuf[21] = ':';
 	      pidbuf[22] = '\t';
 	    }

 	  /* Append to the output.  */
 	  assert (niov < NIOVMAX);
 	  iov[niov].iov_len = &(pidbuf[23]) - tag_start;
 	  iov[niov++].iov_base = tag_start;

 	  /* No more tags until we see the next newline.  */
 	  tag_p = -1;
 	}

       /* Skip everything except % and \n (if tags are needed).  */
       while (*fmt != '\0' && *fmt != '%' && (! tag_p || *fmt != '\n'))
 	++fmt;

       /* Append constant string.  */
       assert (niov < NIOVMAX);
       if ((iov[niov].iov_len = fmt - startp) != 0)
 	iov[niov++].iov_base = (char *) startp;

       if (*fmt == '%')
 	{
 	  /* It is a format specifier.  */
 	  char fill = ' ';
 	  int width = -1;
 	  int prec = -1;
 #if LONG_MAX != INT_MAX
 	  int long_mod = 0;
 #endif

 	  /* Recognize zero-digit fill flag.  */
 	  if (*++fmt == '0')
 	    {
 	      fill = '0';
 	      ++fmt;
 	    }

 	  /* See whether with comes from a parameter.  Note that no other
 	     way to specify the width is implemented.  */
 	  if (*fmt == '*')
 	    {
 	      width = va_arg (arg, int);
 	      ++fmt;
 	    }

 	  /* Handle precision.  */
 	  if (*fmt == '.' && fmt[1] == '*')
 	    {
 	      prec = va_arg (arg, int);
 	      fmt += 2;
 	    }

 	  /* Recognize the l modifier.  It is only important on some
 	     platforms where long and int have a different size.  We
 	     can use the same code for size_t.  */
 	  if (*fmt == 'l' || *fmt == 'Z')
 	    {
 #if LONG_MAX != INT_MAX
 	      long_mod = 1;
 #endif
 	      ++fmt;
 	    }

 	  switch (*fmt)
 	    {
 	      /* Integer formatting.  */
 	    case 'u':
 	    case 'x':
 	      {
 		/* We have to make a difference if long and int have a
 		   different size.  */
 #if LONG_MAX != INT_MAX
 		unsigned long int num = (long_mod
 					 ? va_arg (arg, unsigned long int)
 					 : va_arg (arg, unsigned int));
 #else
 		unsigned long int num = va_arg (arg, unsigned int);
 #endif
 		/* We use alloca() to allocate the buffer with the most
 		   pessimistic guess for the size.  Using alloca() allows
 		   having more than one integer formatting in a call.  */
 		char *buf = (char *) alloca (3 * sizeof (unsigned long int));
 		char *endp = &buf[3 * sizeof (unsigned long int)];
 		char *cp = _itoa (num, endp, *fmt == 'x' ? 16 : 10, 0);

 		/* Pad to the width the user specified.  */
 		if (width != -1)
 		  while (endp - cp < width)
 		    *--cp = fill;

 		iov[niov].iov_base = cp;
 		iov[niov].iov_len = endp - cp;
 		++niov;
 	      }
 	      break;

 	    case 's':
 	      /* Get the string argument.  */
 	      iov[niov].iov_base = va_arg (arg, char *);
 	      iov[niov].iov_len = strlen (iov[niov].iov_base);
 	      if (prec != -1)
 		iov[niov].iov_len = MIN ((size_t) prec, iov[niov].iov_len);
 	      ++niov;
 	      break;

 	    case '%':
 	      iov[niov].iov_base = (void *) fmt;
 	      iov[niov].iov_len = 1;
 	      ++niov;
 	      break;

 	    default:
 	      assert (! "invalid format specifier");
 	    }
 	  ++fmt;
 	}
       else if (*fmt == '\n')
 	{
 	  /* See whether we have to print a single newline character.  */
 	  if (fmt == startp)
 	    {
 	      iov[niov].iov_base = (char *) startp;
 	      iov[niov++].iov_len = 1;
 	    }
 	  else
 	    /* No, just add it to the rest of the string.  */
 	    ++iov[niov - 1].iov_len;

 	  /* Next line, print a tag again.  */
 	  tag_p = 1;
 	  ++fmt;
 	}
     }

   /* Finally write the result.  */
   _dl_writev (fd, iov, niov);
 }


 /* Write to debug file.  */
 void
 _dl_debug_printf (const char *fmt, ...)
 {
   va_list arg;

   va_start (arg, fmt);
   _dl_debug_vdprintf (GLRO(dl_debug_fd), 1, fmt, arg);
   va_end (arg);
 }


 /* Write to debug file but don't start with a tag.  */
 void
 _dl_debug_printf_c (const char *fmt, ...)
 {
   va_list arg;

   va_start (arg, fmt);
   _dl_debug_vdprintf (GLRO(dl_debug_fd), -1, fmt, arg);
   va_end (arg);
 }


 /* Write the given file descriptor.  */
 void
 _dl_dprintf (int fd, const char *fmt, ...)
 {
   va_list arg;

   va_start (arg, fmt);
   _dl_debug_vdprintf (fd, 0, fmt, arg);
   va_end (arg);
 }


 /* Test whether given NAME matches any of the names of the given object.  */
 int
 _dl_name_match_p (const char *name, const struct link_map *map)
 {
   if (strcmp (name, map->l_name) == 0)
     return 1;

   struct libname_list *runp = map->l_libname;

   while (runp != NULL)
     if (strcmp (name, runp->name) == 0)
       return 1;
     else
       runp = runp->next;

   return 0;
 }


 unsigned long int
 _dl_higher_prime_number (unsigned long int n)
 {
   /* These are primes that are near, but slightly smaller than, a
      power of two.  */
   static const uint32_t primes[] = {
     UINT32_C (7),
     UINT32_C (13),
     UINT32_C (31),
     UINT32_C (61),
     UINT32_C (127),
     UINT32_C (251),
     UINT32_C (509),
     UINT32_C (1021),
     UINT32_C (2039),
     UINT32_C (4093),
     UINT32_C (8191),
     UINT32_C (16381),
     UINT32_C (32749),
     UINT32_C (65521),
     UINT32_C (131071),
     UINT32_C (262139),
     UINT32_C (524287),
     UINT32_C (1048573),
     UINT32_C (2097143),
     UINT32_C (4194301),
     UINT32_C (8388593),
     UINT32_C (16777213),
     UINT32_C (33554393),
     UINT32_C (67108859),
     UINT32_C (134217689),
     UINT32_C (268435399),
     UINT32_C (536870909),
     UINT32_C (1073741789),
     UINT32_C (2147483647),
 				       /* 4294967291L */
     UINT32_C (2147483647) + UINT32_C (2147483644)
   };

   const uint32_t *low = &primes[0];
   const uint32_t *high = &primes[sizeof (primes) / sizeof (primes[0])];

   while (low != high)
     {
       const uint32_t *mid = low + (high - low) / 2;
       if (n > *mid)
        low = mid + 1;
       else
        high = mid;
     }

 #if 0
   /* If we've run out of primes, abort.  */
   if (n > *low)
     {
       fprintf (stderr, "Cannot find prime bigger than %lu\n", n);
       abort ();
     }
 #endif

   return *low;
 }

 /* A stripped down strtoul-like implementation for very early use.  It
    does not set errno if the result is outside bounds because it may get
    called before errno may have been set up.  */

 uint64_t
 _dl_strtoul (const char *nptr, char **endptr)
 {
   uint64_t result = 0;
   bool positive = true;
   unsigned max_digit;

   while (*nptr == ' ' || *nptr == '\t')
     ++nptr;

   if (*nptr == '-')
     {
       positive = false;
       ++nptr;
     }
   else if (*nptr == '+')
     ++nptr;

   if (*nptr < '0' || *nptr > '9')
     {
       if (endptr != NULL)
 	*endptr = (char *) nptr;
       return 0UL;
     }

   int base = 10;
   max_digit = 9;
   if (*nptr == '0')
     {
       if (nptr[1] == 'x' || nptr[1] == 'X')
 	{
 	  base = 16;
 	  nptr += 2;
 	}
       else
 	{
 	  base = 8;
 	  max_digit = 7;
 	}
     }

   while (1)
     {
       int digval;
       if (*nptr >= '0' && *nptr <= '0' + max_digit)
         digval = *nptr - '0';
       else if (base == 16)
         {
 	  if (*nptr >= 'a' && *nptr <= 'f')
 	    digval = *nptr - 'a' + 10;
 	  else if (*nptr >= 'A' && *nptr <= 'F')
 	    digval = *nptr - 'A' + 10;
 	  else
 	    break;
 	}
       else
         break;

       if (result >= (UINT64_MAX - digval) / base)
 	{
 	  if (endptr != NULL)
 	    *endptr = (char *) nptr;
 	  return UINT64_MAX;
 	}
       result *= base;
       result += digval;
       ++nptr;
     }

   if (endptr != NULL)
     *endptr = (char *) nptr;

   /* Avoid 64-bit multiplication.  */
   if (!positive)
     result = -result;

   return result;
 }

 /* To support accessing TLS variables from signal handlers, we need an
    async signal safe memory allocator.  These routines are never
    themselves invoked reentrantly (all calls to them are surrounded by
    signal masks) but may be invoked concurrently from many threads.
    The current implementation is not particularly performant nor space
    efficient, but it will be used rarely (and only in binaries that use
    dlopen.)  The API matches that of malloc() and friends.  */

 struct __signal_safe_allocator_header
 {
   size_t size;
   void *start;
 };

 static inline struct __signal_safe_allocator_header *
 ptr_to_signal_safe_allocator_header (void *ptr)
 {
   return (struct __signal_safe_allocator_header *)
     ((char *) (ptr) - sizeof (struct __signal_safe_allocator_header));
 }

 void *weak_function
 __signal_safe_memalign (size_t boundary, size_t size)
 {
   struct __signal_safe_allocator_header *header;

   if (boundary < sizeof (*header))
     boundary = sizeof (*header);

   /* Boundary must be a power of two.  */
   if (!powerof2 (boundary))
     return NULL;

   size_t pg = GLRO (dl_pagesize);
   size_t padded_size;
   if (boundary <= pg)
     {
       /* We'll get a pointer certainly aligned to boundary, so just
 	 add one more boundary-sized chunk to hold the header.  */
       padded_size = roundup (size, boundary) + boundary;
     }
   else
     {
       /* If we want K pages aligned to a J-page boundary, K+J+1 pages
 	 contains at least one such region that isn't directly at the start
 	 (so we can place the header.)	This is wasteful, but you're the one
 	 who wanted 64K-aligned TLS.  */
       padded_size = roundup (size, pg) + boundary + pg;
     }


   size_t actual_size = roundup (padded_size, pg);
   void *actual = mmap (NULL, actual_size, PROT_READ | PROT_WRITE,
 		       MAP_ANONYMOUS | MAP_PRIVATE, -1, 0);
   if (actual == MAP_FAILED)
     return NULL;

   if (boundary <= pg)
     {
       header = actual + boundary - sizeof (*header);
     }
   else
     {
       intptr_t actual_pg = ((intptr_t) actual) / pg;
       intptr_t boundary_pg = boundary / pg;
       intptr_t start_pg = actual_pg + boundary_pg;
       start_pg -= start_pg % boundary_pg;
       if (start_pg > (actual_pg + 1))
 	{
 	  int ret = munmap (actual, (start_pg - actual_pg - 1) * pg);
 	  assert (ret == 0);
 	  actual = (void *) ((start_pg - 1) * pg);
 	}
       char *start = (void *) (start_pg * pg);
       header = ptr_to_signal_safe_allocator_header (start);
     }

   header->size = actual_size;
   header->start = actual;
   void *ptr = header;
   ptr += sizeof (*header);
   if (((intptr_t) ptr) % boundary != 0)
     _dl_fatal_printf ("__signal_safe_memalign produced incorrect alignment\n");
   return ptr;
 }

 void * weak_function
 __signal_safe_malloc (size_t size)
 {
   if (!GLRO(dl_async_signal_safe))
     return malloc (size);

   return __signal_safe_memalign (1, size);
 }

 void weak_function
 __signal_safe_free (void *ptr)
 {
   if (!GLRO(dl_async_signal_safe))
     {
       free (ptr);
       return;
     }

   if (ptr == NULL)
     return;

   struct __signal_safe_allocator_header *header
     = ptr_to_signal_safe_allocator_header (ptr);
   int ret = munmap (header->start, header->size);

   assert (ret == 0);
 }

 void * weak_function
 __signal_safe_realloc (void *ptr, size_t size)
 {
   if (!GLRO(dl_async_signal_safe))
     return realloc (ptr, size);

   if (size == 0)
     {
       __signal_safe_free (ptr);
       return NULL;
     }
   if (ptr == NULL)
     return __signal_safe_malloc (size);

   struct __signal_safe_allocator_header *header
     = ptr_to_signal_safe_allocator_header (ptr);
   size_t old_size = header->size;
   if (old_size - sizeof (*header) >= size)
     return ptr;

   void *new_ptr = __signal_safe_malloc (size);
   if (new_ptr == NULL)
     return NULL;

   /* Copy over the old block (but not its header).  */
   memcpy (new_ptr, ptr, old_size - sizeof (*header));
   __signal_safe_free (ptr);

   return new_ptr;
 }

 void * weak_function
 __signal_safe_calloc (size_t nmemb, size_t size)
 {
   if (!GLRO(dl_async_signal_safe))
     return calloc (nmemb, size);

   void *ptr = __signal_safe_malloc (nmemb * size);
   if (ptr == NULL)
     return NULL;
   return memset (ptr, 0, nmemb * size);
 }
	/* Miscellaneous support functions for dynamic linker
	Copyright (C) 1997-2018 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 <fcntl.h>
	#include <ldsodefs.h>
	#include <limits.h>
	#include <link.h>
	#include <stdarg.h>
	#include <stdlib.h>
	#include <string.h>
	#include <unistd.h>
	#include <stdint.h>
	#include <sys/mman.h>
	#include <sys/param.h>
	#include <sys/stat.h>
	#include <sys/uio.h>
	#include <sysdep.h>
	#include <_itoa.h>
	#include <dl-writev.h>


	/* Read the whole contents of FILE into new mmap'd space with given
	protections. *SIZEP gets the size of the file. On error MAP_FAILED
	is returned. */

	void *
	_dl_sysdep_read_whole_file (const char file, size_t sizep, int prot)
	{
	void *result = MAP_FAILED;
	struct stat64 st;
	int fd = __open (file, O_RDONLY \| O_CLOEXEC);
	if (fd >= 0)
	{
	if (__fxstat64 (_STAT_VER, fd, &st) >= 0)
	{
	*sizep = st.st_size;

	/* No need to map the file if it is empty. */
	if (*sizep != 0)
	/* Map a copy of the file contents. */
	result = __mmap (NULL, *sizep, prot,
	#ifdef MAP_COPY
	MAP_COPY
	#else
	MAP_PRIVATE
	#endif
	#ifdef MAP_FILE
	\| MAP_FILE
	#endif
	, fd, 0);
	}
	__close (fd);
	}
	return result;
	}


	/* Bare-bones printf implementation. This function only knows about
	the formats and flags needed and can handle only up to 64 stripes in
	the output. */
	static void
	_dl_debug_vdprintf (int fd, int tag_p, const char *fmt, va_list arg)
	{
	# define NIOVMAX 64
	struct iovec iov[NIOVMAX];
	int niov = 0;
	pid_t pid = 0;
	char pidbuf[23];
	pid_t tid = 0;
	/* Start with a known bad value, should never get used. */
	char *tag_start = NULL;

	while (*fmt != '\0')
	{
	const char *startp = fmt;

	if (tag_p > 0)
	{
	/* Generate the tag line once. It consists of the PID and a
	colon followed by a tab. */
	if (pid == 0)
	{
	char *p = &pidbuf[21];

	pid = __getpid ();
	assert (pid >= 0 && sizeof (pid_t) <= 4);

	/* If we are doing thread-related output, maybe add a thread id,
	taking care that pid continues to appear at the same
	positions. */
	tid = _dl_tls_tid ();
	if (tid > 0)
	{
	p = _itoa (tid, p, 10, 0);
	*--p = '/';
	}
	tag_start = p - 10;
	p = _itoa (pid, p, 10, 0);
	while (p > tag_start)
	*--p = ' ';
	pidbuf[21] = ':';
	pidbuf[22] = '\t';
	}

	/* Append to the output. */
	assert (niov < NIOVMAX);
	iov[niov].iov_len = &(pidbuf[23]) - tag_start;
	iov[niov++].iov_base = tag_start;

	/* No more tags until we see the next newline. */
	tag_p = -1;
	}

	/* Skip everything except % and \n (if tags are needed). */
	while (fmt != '\0' && fmt != '%' && (! tag_p \|\| *fmt != '\n'))
	++fmt;

	/* Append constant string. */
	assert (niov < NIOVMAX);
	if ((iov[niov].iov_len = fmt - startp) != 0)
	iov[niov++].iov_base = (char *) startp;

	if (*fmt == '%')
	{
	/* It is a format specifier. */
	char fill = ' ';
	int width = -1;
	int prec = -1;
	#if LONG_MAX != INT_MAX
	int long_mod = 0;
	#endif

	/* Recognize zero-digit fill flag. */
	if (*++fmt == '0')
	{
	fill = '0';
	++fmt;
	}

	/* See whether with comes from a parameter. Note that no other
	way to specify the width is implemented. */
	if (fmt == '')
	{
	width = va_arg (arg, int);
	++fmt;
	}

	/* Handle precision. */
	if (fmt == '.' && fmt[1] == '')
	{
	prec = va_arg (arg, int);
	fmt += 2;
	}

	/* Recognize the l modifier. It is only important on some
	platforms where long and int have a different size. We
	can use the same code for size_t. */
	if (fmt == 'l' \|\| fmt == 'Z')
	{
	#if LONG_MAX != INT_MAX
	long_mod = 1;
	#endif
	++fmt;
	}

	switch (*fmt)
	{
	/* Integer formatting. */
	case 'u':
	case 'x':
	{
	/* We have to make a difference if long and int have a
	different size. */
	#if LONG_MAX != INT_MAX
	unsigned long int num = (long_mod
	? va_arg (arg, unsigned long int)
	: va_arg (arg, unsigned int));
	#else
	unsigned long int num = va_arg (arg, unsigned int);
	#endif
	/* We use alloca() to allocate the buffer with the most
	pessimistic guess for the size. Using alloca() allows
	having more than one integer formatting in a call. */
	char buf = (char ) alloca (3 * sizeof (unsigned long int));
	char endp = &buf[3 sizeof (unsigned long int)];
	char cp = _itoa (num, endp, fmt == 'x' ? 16 : 10, 0);

	/* Pad to the width the user specified. */
	if (width != -1)
	while (endp - cp < width)
	*--cp = fill;

	iov[niov].iov_base = cp;
	iov[niov].iov_len = endp - cp;
	++niov;
	}
	break;

	case 's':
	/* Get the string argument. */
	iov[niov].iov_base = va_arg (arg, char *);
	iov[niov].iov_len = strlen (iov[niov].iov_base);
	if (prec != -1)
	iov[niov].iov_len = MIN ((size_t) prec, iov[niov].iov_len);
	++niov;
	break;

	case '%':
	iov[niov].iov_base = (void *) fmt;
	iov[niov].iov_len = 1;
	++niov;
	break;

	default:
	assert (! "invalid format specifier");
	}
	++fmt;
	}
	else if (*fmt == '\n')
	{
	/* See whether we have to print a single newline character. */
	if (fmt == startp)
	{
	iov[niov].iov_base = (char *) startp;
	iov[niov++].iov_len = 1;
	}
	else
	/* No, just add it to the rest of the string. */
	++iov[niov - 1].iov_len;

	/* Next line, print a tag again. */
	tag_p = 1;
	++fmt;
	}
	}

	/* Finally write the result. */
	_dl_writev (fd, iov, niov);
	}


	/* Write to debug file. */
	void
	_dl_debug_printf (const char *fmt, ...)
	{
	va_list arg;

	va_start (arg, fmt);
	_dl_debug_vdprintf (GLRO(dl_debug_fd), 1, fmt, arg);
	va_end (arg);
	}


	/* Write to debug file but don't start with a tag. */
	void
	_dl_debug_printf_c (const char *fmt, ...)
	{
	va_list arg;

	va_start (arg, fmt);
	_dl_debug_vdprintf (GLRO(dl_debug_fd), -1, fmt, arg);
	va_end (arg);
	}


	/* Write the given file descriptor. */
	void
	_dl_dprintf (int fd, const char *fmt, ...)
	{
	va_list arg;

	va_start (arg, fmt);
	_dl_debug_vdprintf (fd, 0, fmt, arg);
	va_end (arg);
	}


	/* Test whether given NAME matches any of the names of the given object. */
	int
	_dl_name_match_p (const char name, const struct link_map map)
	{
	if (strcmp (name, map->l_name) == 0)
	return 1;

	struct libname_list *runp = map->l_libname;

	while (runp != NULL)
	if (strcmp (name, runp->name) == 0)
	return 1;
	else
	runp = runp->next;

	return 0;
	}


	unsigned long int
	_dl_higher_prime_number (unsigned long int n)
	{
	/* These are primes that are near, but slightly smaller than, a
	power of two. */
	static const uint32_t primes[] = {
	UINT32_C (7),
	UINT32_C (13),
	UINT32_C (31),
	UINT32_C (61),
	UINT32_C (127),
	UINT32_C (251),
	UINT32_C (509),
	UINT32_C (1021),
	UINT32_C (2039),
	UINT32_C (4093),
	UINT32_C (8191),
	UINT32_C (16381),
	UINT32_C (32749),
	UINT32_C (65521),
	UINT32_C (131071),
	UINT32_C (262139),
	UINT32_C (524287),
	UINT32_C (1048573),
	UINT32_C (2097143),
	UINT32_C (4194301),
	UINT32_C (8388593),
	UINT32_C (16777213),
	UINT32_C (33554393),
	UINT32_C (67108859),
	UINT32_C (134217689),
	UINT32_C (268435399),
	UINT32_C (536870909),
	UINT32_C (1073741789),
	UINT32_C (2147483647),
	/* 4294967291L */
	UINT32_C (2147483647) + UINT32_C (2147483644)
	};

	const uint32_t *low = &primes[0];
	const uint32_t *high = &primes[sizeof (primes) / sizeof (primes[0])];

	while (low != high)
	{
	const uint32_t *mid = low + (high - low) / 2;
	if (n > *mid)
	low = mid + 1;
	else
	high = mid;
	}

	#if 0
	/* If we've run out of primes, abort. */
	if (n > *low)
	{
	fprintf (stderr, "Cannot find prime bigger than %lu\n", n);
	abort ();
	}
	#endif

	return *low;
	}

	/* A stripped down strtoul-like implementation for very early use. It
	does not set errno if the result is outside bounds because it may get
	called before errno may have been set up. */

	uint64_t
	_dl_strtoul (const char nptr, char *endptr)
	{
	uint64_t result = 0;
	bool positive = true;
	unsigned max_digit;

	while (nptr == ' ' \|\| nptr == '\t')
	++nptr;

	if (*nptr == '-')
	{
	positive = false;
	++nptr;
	}
	else if (*nptr == '+')
	++nptr;

	if (nptr < '0' \|\| nptr > '9')
	{
	if (endptr != NULL)
	endptr = (char ) nptr;
	return 0UL;
	}

	int base = 10;
	max_digit = 9;
	if (*nptr == '0')
	{
	if (nptr[1] == 'x' \|\| nptr[1] == 'X')
	{
	base = 16;
	nptr += 2;
	}
	else
	{
	base = 8;
	max_digit = 7;
	}
	}

	while (1)
	{
	int digval;
	if (nptr >= '0' && nptr <= '0' + max_digit)
	digval = *nptr - '0';
	else if (base == 16)
	{
	if (nptr >= 'a' && nptr <= 'f')
	digval = *nptr - 'a' + 10;
	else if (nptr >= 'A' && nptr <= 'F')
	digval = *nptr - 'A' + 10;
	else
	break;
	}
	else
	break;

	if (result >= (UINT64_MAX - digval) / base)
	{
	if (endptr != NULL)
	endptr = (char ) nptr;
	return UINT64_MAX;
	}
	result *= base;
	result += digval;
	++nptr;
	}

	if (endptr != NULL)
	endptr = (char ) nptr;

	/* Avoid 64-bit multiplication. */
	if (!positive)
	result = -result;

	return result;
	}

	/* To support accessing TLS variables from signal handlers, we need an
	async signal safe memory allocator. These routines are never
	themselves invoked reentrantly (all calls to them are surrounded by
	signal masks) but may be invoked concurrently from many threads.
	The current implementation is not particularly performant nor space
	efficient, but it will be used rarely (and only in binaries that use
	dlopen.) The API matches that of malloc() and friends. */

	struct __signal_safe_allocator_header
	{
	size_t size;
	void *start;
	};

	static inline struct __signal_safe_allocator_header *
	ptr_to_signal_safe_allocator_header (void *ptr)
	{
	return (struct __signal_safe_allocator_header *)
	((char *) (ptr) - sizeof (struct __signal_safe_allocator_header));
	}

	void *weak_function
	__signal_safe_memalign (size_t boundary, size_t size)
	{
	struct __signal_safe_allocator_header *header;

	if (boundary < sizeof (*header))
	boundary = sizeof (*header);

	/* Boundary must be a power of two. */
	if (!powerof2 (boundary))
	return NULL;

	size_t pg = GLRO (dl_pagesize);
	size_t padded_size;
	if (boundary <= pg)
	{
	/* We'll get a pointer certainly aligned to boundary, so just
	add one more boundary-sized chunk to hold the header. */
	padded_size = roundup (size, boundary) + boundary;
	}
	else
	{
	/* If we want K pages aligned to a J-page boundary, K+J+1 pages
	contains at least one such region that isn't directly at the start
	(so we can place the header.) This is wasteful, but you're the one
	who wanted 64K-aligned TLS. */
	padded_size = roundup (size, pg) + boundary + pg;
	}


	size_t actual_size = roundup (padded_size, pg);
	void *actual = mmap (NULL, actual_size, PROT_READ \| PROT_WRITE,
	MAP_ANONYMOUS \| MAP_PRIVATE, -1, 0);
	if (actual == MAP_FAILED)
	return NULL;

	if (boundary <= pg)
	{
	header = actual + boundary - sizeof (*header);
	}
	else
	{
	intptr_t actual_pg = ((intptr_t) actual) / pg;
	intptr_t boundary_pg = boundary / pg;
	intptr_t start_pg = actual_pg + boundary_pg;
	start_pg -= start_pg % boundary_pg;
	if (start_pg > (actual_pg + 1))
	{
	int ret = munmap (actual, (start_pg - actual_pg - 1) * pg);
	assert (ret == 0);
	actual = (void ) ((start_pg - 1) pg);
	}
	char start = (void ) (start_pg * pg);
	header = ptr_to_signal_safe_allocator_header (start);
	}

	header->size = actual_size;
	header->start = actual;
	void *ptr = header;
	ptr += sizeof (*header);
	if (((intptr_t) ptr) % boundary != 0)
	_dl_fatal_printf ("__signal_safe_memalign produced incorrect alignment\n");
	return ptr;
	}

	void * weak_function
	__signal_safe_malloc (size_t size)
	{
	if (!GLRO(dl_async_signal_safe))
	return malloc (size);

	return __signal_safe_memalign (1, size);
	}

	void weak_function
	__signal_safe_free (void *ptr)
	{
	if (!GLRO(dl_async_signal_safe))
	{
	free (ptr);
	return;
	}

	if (ptr == NULL)
	return;

	struct __signal_safe_allocator_header *header
	= ptr_to_signal_safe_allocator_header (ptr);
	int ret = munmap (header->start, header->size);

	assert (ret == 0);
	}

	void * weak_function
	__signal_safe_realloc (void *ptr, size_t size)
	{
	if (!GLRO(dl_async_signal_safe))
	return realloc (ptr, size);

	if (size == 0)
	{
	__signal_safe_free (ptr);
	return NULL;
	}
	if (ptr == NULL)
	return __signal_safe_malloc (size);

	struct __signal_safe_allocator_header *header
	= ptr_to_signal_safe_allocator_header (ptr);
	size_t old_size = header->size;
	if (old_size - sizeof (*header) >= size)
	return ptr;

	void *new_ptr = __signal_safe_malloc (size);
	if (new_ptr == NULL)
	return NULL;

	/* Copy over the old block (but not its header). */
	memcpy (new_ptr, ptr, old_size - sizeof (*header));
	__signal_safe_free (ptr);

	return new_ptr;
	}

	void * weak_function
	__signal_safe_calloc (size_t nmemb, size_t size)
	{
	if (!GLRO(dl_async_signal_safe))
	return calloc (nmemb, size);

	void ptr = __signal_safe_malloc (nmemb size);
	if (ptr == NULL)
	return NULL;
	return memset (ptr, 0, nmemb * size);
	}