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[/] [openrisc/] [trunk/] [gnu-old/] [gdb-7.1/] [gdb/] [testsuite/] [gdb.base/] [bigcore.c] - Blame information for rev 833

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Line No. Rev Author Line
1 227 jeremybenn
/* This testcase is part of GDB, the GNU debugger.
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   Copyright 2004, 2007, 2008, 2009, 2010 Free Software Foundation, Inc.
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   This program is free software; you can redistribute it and/or modify
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   it under the terms of the GNU General Public License as published by
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   the Free Software Foundation; either version 3 of the License, or
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   (at your option) any later version.
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   This program is distributed in the hope that it will be useful,
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   but WITHOUT ANY WARRANTY; without even the implied warranty of
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   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
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   GNU General Public License for more details.
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   You should have received a copy of the GNU General Public License
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   along with this program.  If not, see <http://www.gnu.org/licenses/>.  */
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/* Get 64-bit stuff if on a GNU system.  */
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#define _GNU_SOURCE
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#include <sys/types.h>
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#include <sys/time.h>
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#include <sys/resource.h>
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#include <sys/stat.h>
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#include <fcntl.h>
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#include <stdlib.h>
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#include <unistd.h>
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/* This test was written for >2GB core files on 32-bit systems.  On
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   current 64-bit systems, generating a >4EB (2 ** 63) core file is
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   not practical, and getting as close as we can takes a lot of
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   useless CPU time.  So limit ourselves to a bit bigger than
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   32-bit, which is still a useful test.  */
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#define RLIMIT_CAP (1ULL << 34)
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/* Print routines:
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   The following are so that printf et.al. can be avoided.  Those
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   might try to use malloc() and that, for this code, would be a
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   disaster.  */
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#define printf do not use
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const char digit[] = "0123456789abcdefghijklmnopqrstuvwxyz";
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static void
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print_char (char c)
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{
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  write (1, &c, sizeof (c));
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}
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static void
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print_unsigned (unsigned long long u)
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{
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  if (u >= 10)
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    print_unsigned (u / 10);
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  print_char (digit[u % 10]);
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}
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static void
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print_hex (unsigned long long u)
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{
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  if (u >= 16)
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    print_hex (u / 16);
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  print_char (digit[u % 16]);
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}
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static void
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print_string (const char *s)
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{
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  for (; (*s) != '\0'; s++)
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    print_char ((*s));
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}
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static void
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print_address (const void *a)
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{
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  print_string ("0x");
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  print_hex ((unsigned long) a);
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}
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static void
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print_byte_count (unsigned long long u)
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{
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  print_unsigned (u);
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  print_string (" (");
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  print_string ("0x");
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  print_hex (u);
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  print_string (") bytes");
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}
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/* Print the current values of RESOURCE.  */
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static void
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print_rlimit (int resource)
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{
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  struct rlimit rl;
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  getrlimit (resource, &rl);
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  print_string ("cur=0x");
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  print_hex (rl.rlim_cur);
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  print_string (" max=0x");
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  print_hex (rl.rlim_max);
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}
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static void
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maximize_rlimit (int resource, const char *prefix)
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{
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  struct rlimit rl;
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  print_string ("  ");
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  print_string (prefix);
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  print_string (": ");
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  print_rlimit (resource);
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  getrlimit (resource, &rl);
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  rl.rlim_cur = rl.rlim_max;
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  if (sizeof (rl.rlim_cur) >= sizeof (RLIMIT_CAP))
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    rl.rlim_cur = (rlim_t) RLIMIT_CAP;
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  setrlimit (resource, &rl);
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  print_string (" -> ");
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  print_rlimit (resource);
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  print_string ("\n");
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}
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/* Maintain a doublely linked list.  */
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struct list
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{
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  struct list *next;
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  struct list *prev;
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  size_t size;
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};
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/* Put the "heap" in the DATA section.  That way it is more likely
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   that the variable will occur early in the core file (an address
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   before the heap) and hence more likely that GDB will at least get
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   its value right.
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   To simplify the list append logic, start the heap out with one
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   entry (that lives in the BSS section).  */
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static struct list dummy;
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static struct list heap = { &dummy, &dummy };
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static unsigned long bytes_allocated;
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#ifdef O_LARGEFILE
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#define large_off_t off64_t
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#define large_lseek lseek64
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#else
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#define large_off_t off_t
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#define O_LARGEFILE 0
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#define large_lseek lseek
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#endif
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int
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main ()
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{
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  size_t max_chunk_size;
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  large_off_t max_core_size;
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  /* Try to expand all the resource limits beyond the point of sanity
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     - we're after the biggest possible core file.  */
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  print_string ("Maximize resource limits ...\n");
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#ifdef RLIMIT_CORE
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  maximize_rlimit (RLIMIT_CORE, "core");
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#endif
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#ifdef RLIMIT_DATA
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  maximize_rlimit (RLIMIT_DATA, "data");
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#endif
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#ifdef RLIMIT_STACK
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  maximize_rlimit (RLIMIT_STACK, "stack");
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#endif
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#ifdef RLIMIT_AS
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  maximize_rlimit (RLIMIT_AS, "stack");
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#endif
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  print_string ("Maximize allocation limits ...\n");
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  /* Compute the largest possible corefile size.  No point in trying
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     to create a corefile larger than the largest file supported by
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     the file system.  What about 64-bit lseek64?  */
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  {
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    int fd;
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    large_off_t tmp;
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    unlink ("bigcore.corefile");
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    fd = open ("bigcore.corefile", O_RDWR | O_CREAT | O_TRUNC | O_LARGEFILE,
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               0666);
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    for (tmp = 1; tmp > 0; tmp <<= 1)
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      {
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        if (large_lseek (fd, tmp, SEEK_SET) > 0)
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          max_core_size = tmp;
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      }
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    close (fd);
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  }
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  /* Compute an initial chunk size.  The math is dodgy but it works
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     for the moment.  Perhaphs there's a constant around somewhere.
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     Limit this to max_core_size bytes - no point in trying to
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     allocate more than can be written to the corefile.  */
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  {
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    size_t tmp;
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    for (tmp = 1; tmp > 0 && tmp < max_core_size; tmp <<= 1)
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      max_chunk_size = tmp;
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  }
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  print_string ("  core: ");
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  print_byte_count (max_core_size);
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  print_string ("\n");
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  print_string ("  chunk: ");
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  print_byte_count (max_chunk_size);
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  print_string ("\n");
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  print_string ("  large? ");
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  if (O_LARGEFILE)
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    print_string ("yes\n");
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  else
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    print_string ("no\n");
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  /* Allocate as much memory as possible creating a linked list of
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     each section.  The linking ensures that some, but not all, the
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     memory is allocated.  NB: Some kernels handle this efficiently -
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     only allocating and writing out referenced pages leaving holes in
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     the file for unmodified pages - while others handle this poorly -
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     writing out all pages including those that weren't modified.  */
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  print_string ("Alocating the entire heap ...\n");
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  {
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    size_t chunk_size;
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    unsigned long chunks_allocated = 0;
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    /* Create a linked list of memory chunks.  Start with
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       MAX_CHUNK_SIZE blocks of memory and then try allocating smaller
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       and smaller amounts until all (well at least most) memory has
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       been allocated.  */
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    for (chunk_size = max_chunk_size;
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         chunk_size >= sizeof (struct list);
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         chunk_size >>= 1)
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      {
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        unsigned long count = 0;
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        print_string ("  ");
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        print_byte_count (chunk_size);
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        print_string (" ... ");
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        while (bytes_allocated + (1 + count) * chunk_size
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               < max_core_size)
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          {
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            struct list *chunk = malloc (chunk_size);
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            if (chunk == NULL)
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              break;
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            chunk->size = chunk_size;
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            /* Link it in.  */
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            chunk->next = NULL;
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            chunk->prev = heap.prev;
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            heap.prev->next = chunk;
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            heap.prev = chunk;
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            count++;
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          }
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        print_unsigned (count);
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        print_string (" chunks\n");
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        chunks_allocated += count;
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        bytes_allocated += chunk_size * count;
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      }
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    print_string ("Total of ");
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    print_byte_count (bytes_allocated);
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    print_string (" bytes ");
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    print_unsigned (chunks_allocated);
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    print_string (" chunks\n");
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  }
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  /* Push everything out to disk.  */
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  print_string ("Dump core ....\n");
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  *(char*)0 = 0;
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}

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