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[/] [openrisc/] [trunk/] [gnu-src/] [gdb-7.1/] [sim/] [common/] [sim-arange.c] - Blame information for rev 252

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Line No. Rev Author Line
1 227 jeremybenn
/* Address ranges.
2
   Copyright (C) 1998, 2007, 2008, 2009, 2010 Free Software Foundation, Inc.
3
   Contributed by Cygnus Solutions.
4
 
5
This file is part of the GNU Simulators.
6
 
7
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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12
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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/* Tell sim-arange.h it's us.  */
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#define SIM_ARANGE_C
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#include "libiberty.h"
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#include "sim-basics.h"
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#include "sim-assert.h"
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#ifdef HAVE_STDLIB_H
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#include <stdlib.h>
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#endif
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#ifdef HAVE_STRING_H
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#include <string.h>
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#endif
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#define DEFINE_INLINE_P (! defined (SIM_ARANGE_C_INCLUDED))
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#define DEFINE_NON_INLINE_P defined (SIM_ARANGE_C_INCLUDED)
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#if DEFINE_NON_INLINE_P
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/* Insert a range.  */
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static void
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insert_range (ADDR_SUBRANGE **pos, ADDR_SUBRANGE *asr)
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{
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  asr->next = *pos;
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  *pos = asr;
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}
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/* Delete a range.  */
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static void
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delete_range (ADDR_SUBRANGE **thisasrp)
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{
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  ADDR_SUBRANGE *thisasr;
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  thisasr = *thisasrp;
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  *thisasrp = thisasr->next;
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  free (thisasr);
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}
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/* Add or delete an address range.
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   This code was borrowed from linux's locks.c:posix_lock_file().
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   ??? Todo: Given our simpler needs this could be simplified
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   (split into two fns).  */
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static void
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frob_range (ADDR_RANGE *ar, address_word start, address_word end, int delete_p)
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{
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  ADDR_SUBRANGE *asr;
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  ADDR_SUBRANGE *new_asr, *new_asr2;
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  ADDR_SUBRANGE *left = NULL;
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  ADDR_SUBRANGE *right = NULL;
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  ADDR_SUBRANGE **before;
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  ADDR_SUBRANGE init_caller;
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  ADDR_SUBRANGE *caller = &init_caller;
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  int added_p = 0;
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  memset (caller, 0, sizeof (ADDR_SUBRANGE));
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  new_asr = ZALLOC (ADDR_SUBRANGE);
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  new_asr2 = ZALLOC (ADDR_SUBRANGE);
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  caller->start = start;
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  caller->end = end;
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  before = &ar->ranges;
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  while ((asr = *before) != NULL)
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    {
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      if (! delete_p)
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        {
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          /* Try next range if current range preceeds new one and not
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             adjacent or overlapping.  */
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          if (asr->end < caller->start - 1)
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            goto next_range;
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          /* Break out if new range preceeds current one and not
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             adjacent or overlapping.  */
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          if (asr->start > caller->end + 1)
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            break;
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          /* If we come here, the new and current ranges are adjacent or
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             overlapping. Make one range yielding from the lower start address
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             of both ranges to the higher end address.  */
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          if (asr->start > caller->start)
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            asr->start = caller->start;
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          else
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            caller->start = asr->start;
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          if (asr->end < caller->end)
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            asr->end = caller->end;
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          else
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            caller->end = asr->end;
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          if (added_p)
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            {
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              delete_range (before);
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              continue;
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            }
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          caller = asr;
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          added_p = 1;
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        }
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      else /* deleting a range */
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        {
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          /* Try next range if current range preceeds new one.  */
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          if (asr->end < caller->start)
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            goto next_range;
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          /* Break out if new range preceeds current one.  */
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          if (asr->start > caller->end)
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            break;
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          added_p = 1;
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          if (asr->start < caller->start)
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            left = asr;
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          /* If the next range in the list has a higher end
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             address than the new one, insert the new one here.  */
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          if (asr->end > caller->end)
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            {
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              right = asr;
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              break;
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            }
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          if (asr->start >= caller->start)
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            {
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              /* The new range completely replaces an old
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                 one (This may happen several times).  */
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              if (added_p)
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                {
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                  delete_range (before);
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                  continue;
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                }
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              /* Replace the old range with the new one.  */
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              asr->start = caller->start;
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              asr->end = caller->end;
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              caller = asr;
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              added_p = 1;
158
            }
159
        }
160
 
161
      /* Go on to next range.  */
162
    next_range:
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      before = &asr->next;
164
    }
165
 
166
  if (!added_p)
167
    {
168
      if (delete_p)
169
        goto out;
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      new_asr->start = caller->start;
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      new_asr->end = caller->end;
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      insert_range (before, new_asr);
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      new_asr = NULL;
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    }
175
  if (right)
176
    {
177
      if (left == right)
178
        {
179
          /* The new range breaks the old one in two pieces,
180
             so we have to use the second new range.  */
181
          new_asr2->start = right->start;
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          new_asr2->end = right->end;
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          left = new_asr2;
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          insert_range (before, left);
185
          new_asr2 = NULL;
186
        }
187
      right->start = caller->end + 1;
188
    }
189
  if (left)
190
    {
191
      left->end = caller->start - 1;
192
    }
193
 
194
 out:
195
  if (new_asr)
196
    free(new_asr);
197
  if (new_asr2)
198
    free(new_asr2);
199
}
200
 
201
/* Free T and all subtrees.  */
202
 
203
static void
204
free_search_tree (ADDR_RANGE_TREE *t)
205
{
206
  if (t != NULL)
207
    {
208
      free_search_tree (t->lower);
209
      free_search_tree (t->higher);
210
      free (t);
211
    }
212
}
213
 
214
/* Subroutine of build_search_tree to recursively build a balanced tree.
215
   ??? It's not an optimum tree though.  */
216
 
217
static ADDR_RANGE_TREE *
218
build_tree_1 (ADDR_SUBRANGE **asrtab, unsigned int n)
219
{
220
  unsigned int mid = n / 2;
221
  ADDR_RANGE_TREE *t;
222
 
223
  if (n == 0)
224
    return NULL;
225
  t = (ADDR_RANGE_TREE *) xmalloc (sizeof (ADDR_RANGE_TREE));
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  t->start = asrtab[mid]->start;
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  t->end = asrtab[mid]->end;
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  if (mid != 0)
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    t->lower = build_tree_1 (asrtab, mid);
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  else
231
    t->lower = NULL;
232
  if (n > mid + 1)
233
    t->higher = build_tree_1 (asrtab + mid + 1, n - mid - 1);
234
  else
235
    t->higher = NULL;
236
  return t;
237
}
238
 
239
/* Build a search tree for address range AR.  */
240
 
241
static void
242
build_search_tree (ADDR_RANGE *ar)
243
{
244
  /* ??? Simple version for now.  */
245
  ADDR_SUBRANGE *asr,**asrtab;
246
  unsigned int i, n;
247
 
248
  for (n = 0, asr = ar->ranges; asr != NULL; ++n, asr = asr->next)
249
    continue;
250
  asrtab = (ADDR_SUBRANGE **) xmalloc (n * sizeof (ADDR_SUBRANGE *));
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  for (i = 0, asr = ar->ranges; i < n; ++i, asr = asr->next)
252
    asrtab[i] = asr;
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  ar->range_tree = build_tree_1 (asrtab, n);
254
  free (asrtab);
255
}
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257
void
258
sim_addr_range_add (ADDR_RANGE *ar, address_word start, address_word end)
259
{
260
  frob_range (ar, start, end, 0);
261
 
262
  /* Rebuild the search tree.  */
263
  /* ??? Instead of rebuilding it here it could be done in a module resume
264
     handler, say by first checking for a `changed' flag, assuming of course
265
     this would never be done while the simulation is running.  */
266
  free_search_tree (ar->range_tree);
267
  build_search_tree (ar);
268
}
269
 
270
void
271
sim_addr_range_delete (ADDR_RANGE *ar, address_word start, address_word end)
272
{
273
  frob_range (ar, start, end, 1);
274
 
275
  /* Rebuild the search tree.  */
276
  /* ??? Instead of rebuilding it here it could be done in a module resume
277
     handler, say by first checking for a `changed' flag, assuming of course
278
     this would never be done while the simulation is running.  */
279
  free_search_tree (ar->range_tree);
280
  build_search_tree (ar);
281
}
282
 
283
#endif /* DEFINE_NON_INLINE_P */
284
 
285
#if DEFINE_INLINE_P
286
 
287
SIM_ARANGE_INLINE int
288
sim_addr_range_hit_p (ADDR_RANGE *ar, address_word addr)
289
{
290
  ADDR_RANGE_TREE *t = ar->range_tree;
291
 
292
  while (t != NULL)
293
    {
294
      if (addr < t->start)
295
        t = t->lower;
296
      else if (addr > t->end)
297
        t = t->higher;
298
      else
299
        return 1;
300
    }
301
  return 0;
302
}
303
 
304
#endif /* DEFINE_INLINE_P */

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