[deliverable/binutils-gdb.git] / gdb / addrmap.c

/* addrmap.c --- implementation of address map data structure.

   Copyright (C) 2007-2020 Free Software Foundation, Inc.

   This file is part of GDB.

   This program is free software; you can redistribute it and/or modify
   it under the terms of the GNU General Public License as published by
   the Free Software Foundation; either version 3 of the License, or
   (at your option) any later version.

   This program 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 General Public License for more details.

   You should have received a copy of the GNU General Public License
   along with this program.  If not, see <http://www.gnu.org/licenses/>.  */

#include "defs.h"
#include "splay-tree.h"
#include "gdb_obstack.h"
#include "addrmap.h"

/* Make sure splay trees can actually hold the values we want to
   store in them.  */
gdb_static_assert (sizeof (splay_tree_key) >= sizeof (CORE_ADDR *));
gdb_static_assert (sizeof (splay_tree_value) >= sizeof (void *));

\f
/* The "abstract class".  */

/* Functions implementing the addrmap functions for a particular
   implementation.  */
struct addrmap_funcs
{
  void (*set_empty) (struct addrmap *self,
                     CORE_ADDR start, CORE_ADDR end_inclusive,
                     void *obj);
  void *(*find) (struct addrmap *self, CORE_ADDR addr);
  struct addrmap *(*create_fixed) (struct addrmap *self,
                                   struct obstack *obstack);
  void (*relocate) (struct addrmap *self, CORE_ADDR offset);
  int (*foreach) (struct addrmap *self, addrmap_foreach_fn fn, void *data);
};


struct addrmap
{
  const struct addrmap_funcs *funcs;
};


void
addrmap_set_empty (struct addrmap *map,
                   CORE_ADDR start, CORE_ADDR end_inclusive,
                   void *obj)
{
  map->funcs->set_empty (map, start, end_inclusive, obj);
}


void *
addrmap_find (struct addrmap *map, CORE_ADDR addr)
{
  return map->funcs->find (map, addr);
}


struct addrmap *
addrmap_create_fixed (struct addrmap *original, struct obstack *obstack)
{
  return original->funcs->create_fixed (original, obstack);
}


/* Relocate all the addresses in MAP by OFFSET.  (This can be applied
   to either mutable or immutable maps.)  */
void
addrmap_relocate (struct addrmap *map, CORE_ADDR offset)
{
  map->funcs->relocate (map, offset);
}


int
addrmap_foreach (struct addrmap *map, addrmap_foreach_fn fn, void *data)
{
  return map->funcs->foreach (map, fn, data);
}
\f
/* Fixed address maps.  */

/* A transition: a point in an address map where the value changes.
   The map maps ADDR to VALUE, but if ADDR > 0, it maps ADDR-1 to
   something else.  */
struct addrmap_transition
{
  CORE_ADDR addr;
  void *value;
};


struct addrmap_fixed
{
  struct addrmap addrmap;

  /* The number of transitions in TRANSITIONS.  */
  size_t num_transitions;

  /* An array of transitions, sorted by address.  For every point in
     the map where either ADDR == 0 or ADDR is mapped to one value and
     ADDR - 1 is mapped to something different, we have an entry here
     containing ADDR and VALUE.  (Note that this means we always have
     an entry for address 0).  */
  struct addrmap_transition transitions[1];
};


static void
addrmap_fixed_set_empty (struct addrmap *self,
                   CORE_ADDR start, CORE_ADDR end_inclusive,
                   void *obj)
{
  internal_error (__FILE__, __LINE__,
                  "addrmap_fixed_set_empty: "
                  "fixed addrmaps can't be changed\n");
}


static void *
addrmap_fixed_find (struct addrmap *self, CORE_ADDR addr)
{
  struct addrmap_fixed *map = (struct addrmap_fixed *) self;
  struct addrmap_transition *bottom = &map->transitions[0];
  struct addrmap_transition *top = &map->transitions[map->num_transitions - 1];

  while (bottom < top)
    {
      /* This needs to round towards top, or else when top = bottom +
         1 (i.e., two entries are under consideration), then mid ==
         bottom, and then we may not narrow the range when (mid->addr
         < addr).  */
      struct addrmap_transition *mid = top - (top - bottom) / 2;

      if (mid->addr == addr)
        {
          bottom = mid;
          break;
        }
      else if (mid->addr < addr)
        /* We don't eliminate mid itself here, since each transition
           covers all subsequent addresses until the next.  This is why
           we must round up in computing the midpoint.  */
        bottom = mid;
      else
        top = mid - 1;
    }

  return bottom->value;
}


static struct addrmap *
addrmap_fixed_create_fixed (struct addrmap *self, struct obstack *obstack)
{
  internal_error (__FILE__, __LINE__,
                  _("addrmap_create_fixed is not implemented yet "
                    "for fixed addrmaps"));
}


static void
addrmap_fixed_relocate (struct addrmap *self, CORE_ADDR offset)
{
  struct addrmap_fixed *map = (struct addrmap_fixed *) self;
  size_t i;

  for (i = 0; i < map->num_transitions; i++)
    map->transitions[i].addr += offset;
}


static int
addrmap_fixed_foreach (struct addrmap *self, addrmap_foreach_fn fn,
		       void *data)
{
  struct addrmap_fixed *map = (struct addrmap_fixed *) self;
  size_t i;

  for (i = 0; i < map->num_transitions; i++)
    {
      int res = fn (data, map->transitions[i].addr, map->transitions[i].value);

      if (res != 0)
	return res;
    }

  return 0;
}


static const struct addrmap_funcs addrmap_fixed_funcs =
{
  addrmap_fixed_set_empty,
  addrmap_fixed_find,
  addrmap_fixed_create_fixed,
  addrmap_fixed_relocate,
  addrmap_fixed_foreach
};


\f
/* Mutable address maps.  */

struct addrmap_mutable
{
  struct addrmap addrmap;

  /* The obstack to use for allocations for this map.  */
  struct obstack *obstack;

  /* A splay tree, with a node for each transition; there is a
     transition at address T if T-1 and T map to different objects.

     Any addresses below the first node map to NULL.  (Unlike
     fixed maps, we have no entry at (CORE_ADDR) 0; it doesn't 
     simplify enough.)

     The last region is assumed to end at CORE_ADDR_MAX.

     Since we can't know whether CORE_ADDR is larger or smaller than
     splay_tree_key (unsigned long) --- I think both are possible,
     given all combinations of 32- and 64-bit hosts and targets ---
     our keys are pointers to CORE_ADDR values.  Since the splay tree
     library doesn't pass any closure pointer to the key free
     function, we can't keep a freelist for keys.  Since mutable
     addrmaps are only used temporarily right now, we just leak keys
     from deleted nodes; they'll be freed when the obstack is freed.  */
  splay_tree tree;

  /* A freelist for splay tree nodes, allocated on obstack, and
     chained together by their 'right' pointers.  */
  splay_tree_node free_nodes;
};


/* Allocate a copy of CORE_ADDR in MAP's obstack.  */
static splay_tree_key
allocate_key (struct addrmap_mutable *map, CORE_ADDR addr)
{
  CORE_ADDR *key = XOBNEW (map->obstack, CORE_ADDR);

  *key = addr;
  return (splay_tree_key) key;
}


/* Type-correct wrappers for splay tree access.  */
static splay_tree_node
addrmap_splay_tree_lookup (struct addrmap_mutable *map, CORE_ADDR addr)
{
  return splay_tree_lookup (map->tree, (splay_tree_key) &addr);
}


static splay_tree_node
addrmap_splay_tree_predecessor (struct addrmap_mutable *map, CORE_ADDR addr)
{
  return splay_tree_predecessor (map->tree, (splay_tree_key) &addr);
}


static splay_tree_node
addrmap_splay_tree_successor (struct addrmap_mutable *map, CORE_ADDR addr)
{
  return splay_tree_successor (map->tree, (splay_tree_key) &addr);
}


static void
addrmap_splay_tree_remove (struct addrmap_mutable *map, CORE_ADDR addr)
{
  splay_tree_remove (map->tree, (splay_tree_key) &addr);
}


static CORE_ADDR
addrmap_node_key (splay_tree_node node)
{
  return * (CORE_ADDR *) node->key;
}


static void *
addrmap_node_value (splay_tree_node node)
{
  return (void *) node->value;
}


static void
addrmap_node_set_value (splay_tree_node node, void *value)
{
  node->value = (splay_tree_value) value;
}


static void
addrmap_splay_tree_insert (struct addrmap_mutable *map,
			   CORE_ADDR key, void *value)
{
  splay_tree_insert (map->tree,
                     allocate_key (map, key),
                     (splay_tree_value) value);
}


/* Without changing the mapping of any address, ensure that there is a
   tree node at ADDR, even if it would represent a "transition" from
   one value to the same value.  */
static void
force_transition (struct addrmap_mutable *self, CORE_ADDR addr)
{
  splay_tree_node n
    = addrmap_splay_tree_lookup (self, addr);

  if (! n)
    {
      n = addrmap_splay_tree_predecessor (self, addr);
      addrmap_splay_tree_insert (self, addr,
                                 n ? addrmap_node_value (n) : NULL);
    }
}


static void
addrmap_mutable_set_empty (struct addrmap *self,
                           CORE_ADDR start, CORE_ADDR end_inclusive,
                           void *obj)
{
  struct addrmap_mutable *map = (struct addrmap_mutable *) self;
  splay_tree_node n, next;
  void *prior_value;

  /* If we're being asked to set all empty portions of the given
     address range to empty, then probably the caller is confused.
     (If that turns out to be useful in some cases, then we can change
     this to simply return, since overriding NULL with NULL is a
     no-op.)  */
  gdb_assert (obj);

  /* We take a two-pass approach, for simplicity.
     - Establish transitions where we think we might need them.
     - First pass: change all NULL regions to OBJ.
     - Second pass: remove any unnecessary transitions.  */

  /* Establish transitions at the start and end.  */
  force_transition (map, start);
  if (end_inclusive < CORE_ADDR_MAX)
    force_transition (map, end_inclusive + 1);

  /* Walk the area, changing all NULL regions to OBJ.  */
  for (n = addrmap_splay_tree_lookup (map, start), gdb_assert (n);
       n && addrmap_node_key (n) <= end_inclusive;
       n = addrmap_splay_tree_successor (map, addrmap_node_key (n)))
    {
      if (! addrmap_node_value (n))
        addrmap_node_set_value (n, obj);
    }

  /* Walk the area again, removing transitions from any value to
     itself.  Be sure to visit both the transitions we forced
     above.  */
  n = addrmap_splay_tree_predecessor (map, start);
  prior_value = n ? addrmap_node_value (n) : NULL;
  for (n = addrmap_splay_tree_lookup (map, start), gdb_assert (n);
       n && (end_inclusive == CORE_ADDR_MAX
             || addrmap_node_key (n) <= end_inclusive + 1);
       n = next)
    {
      next = addrmap_splay_tree_successor (map, addrmap_node_key (n));
      if (addrmap_node_value (n) == prior_value)
        addrmap_splay_tree_remove (map, addrmap_node_key (n));
      else
        prior_value = addrmap_node_value (n);
    }
}


static void *
addrmap_mutable_find (struct addrmap *self, CORE_ADDR addr)
{
  /* Not needed yet.  */
  internal_error (__FILE__, __LINE__,
                  _("addrmap_find is not implemented yet "
                    "for mutable addrmaps"));
}


/* A function to pass to splay_tree_foreach to count the number of nodes
   in the tree.  */
static int
splay_foreach_count (splay_tree_node n, void *closure)
{
  size_t *count = (size_t *) closure;

  (*count)++;
  return 0;
}


/* A function to pass to splay_tree_foreach to copy entries into a
   fixed address map.  */
static int
splay_foreach_copy (splay_tree_node n, void *closure)
{
  struct addrmap_fixed *fixed = (struct addrmap_fixed *) closure;
  struct addrmap_transition *t = &fixed->transitions[fixed->num_transitions];

  t->addr = addrmap_node_key (n);
  t->value = addrmap_node_value (n);
  fixed->num_transitions++;

  return 0;
}


static struct addrmap *
addrmap_mutable_create_fixed (struct addrmap *self, struct obstack *obstack)
{
  struct addrmap_mutable *mutable_obj = (struct addrmap_mutable *) self;
  struct addrmap_fixed *fixed;
  size_t num_transitions;
  size_t alloc_len;

  /* Count the number of transitions in the tree.  */
  num_transitions = 0;
  splay_tree_foreach (mutable_obj->tree, splay_foreach_count, &num_transitions);

  /* Include an extra entry for the transition at zero (which fixed
     maps have, but mutable maps do not.)  */
  num_transitions++;

  alloc_len = sizeof (*fixed)
	      + (num_transitions * sizeof (fixed->transitions[0]));
  fixed = (struct addrmap_fixed *) obstack_alloc (obstack, alloc_len);
  fixed->addrmap.funcs = &addrmap_fixed_funcs;
  fixed->num_transitions = 1;
  fixed->transitions[0].addr = 0;
  fixed->transitions[0].value = NULL;

  /* Copy all entries from the splay tree to the array, in order 
     of increasing address.  */
  splay_tree_foreach (mutable_obj->tree, splay_foreach_copy, fixed);

  /* We should have filled the array.  */
  gdb_assert (fixed->num_transitions == num_transitions);

  return (struct addrmap *) fixed;
}


static void
addrmap_mutable_relocate (struct addrmap *self, CORE_ADDR offset)
{
  /* Not needed yet.  */
  internal_error (__FILE__, __LINE__,
                  _("addrmap_relocate is not implemented yet "
                    "for mutable addrmaps"));
}


/* Struct to map addrmap's foreach function to splay_tree's version.  */
struct mutable_foreach_data
{
  addrmap_foreach_fn fn;
  void *data;
};


/* This is a splay_tree_foreach_fn.  */

static int
addrmap_mutable_foreach_worker (splay_tree_node node, void *data)
{
  struct mutable_foreach_data *foreach_data
    = (struct mutable_foreach_data *) data;

  return foreach_data->fn (foreach_data->data,
			   addrmap_node_key (node),
			   addrmap_node_value (node));
}


static int
addrmap_mutable_foreach (struct addrmap *self, addrmap_foreach_fn fn,
			 void *data)
{
  struct addrmap_mutable *mutable_obj = (struct addrmap_mutable *) self;
  struct mutable_foreach_data foreach_data;

  foreach_data.fn = fn;
  foreach_data.data = data;
  return splay_tree_foreach (mutable_obj->tree, addrmap_mutable_foreach_worker,
			     &foreach_data);
}


static const struct addrmap_funcs addrmap_mutable_funcs =
{
  addrmap_mutable_set_empty,
  addrmap_mutable_find,
  addrmap_mutable_create_fixed,
  addrmap_mutable_relocate,
  addrmap_mutable_foreach
};


static void *
splay_obstack_alloc (int size, void *closure)
{
  struct addrmap_mutable *map = (struct addrmap_mutable *) closure;
  splay_tree_node n;

  /* We should only be asked to allocate nodes and larger things.
     (If, at some point in the future, this is no longer true, we can
     just round up the size to sizeof (*n).)  */
  gdb_assert (size >= sizeof (*n));

  if (map->free_nodes)
    {
      n = map->free_nodes;
      map->free_nodes = n->right;
      return n;
    }
  else
    return obstack_alloc (map->obstack, size);
}


static void
splay_obstack_free (void *obj, void *closure)
{
  struct addrmap_mutable *map = (struct addrmap_mutable *) closure;
  splay_tree_node n = (splay_tree_node) obj;

  /* We've asserted in the allocation function that we only allocate
     nodes or larger things, so it should be safe to put whatever
     we get passed back on the free list.  */
  n->right = map->free_nodes;
  map->free_nodes = n;
}


/* Compare keys as CORE_ADDR * values.  */
static int
splay_compare_CORE_ADDR_ptr (splay_tree_key ak, splay_tree_key bk)
{
  CORE_ADDR a = * (CORE_ADDR *) ak;
  CORE_ADDR b = * (CORE_ADDR *) bk;

  /* We can't just return a-b here, because of over/underflow.  */
  if (a < b)
    return -1;
  else if (a == b)
    return 0;
  else
    return 1;
}


struct addrmap *
addrmap_create_mutable (struct obstack *obstack)
{
  struct addrmap_mutable *map = XOBNEW (obstack, struct addrmap_mutable);

  map->addrmap.funcs = &addrmap_mutable_funcs;
  map->obstack = obstack;

  /* splay_tree_new_with_allocator uses the provided allocation
     function to allocate the main splay_tree structure itself, so our
     free list has to be initialized before we create the tree.  */
  map->free_nodes = NULL;

  map->tree = splay_tree_new_with_allocator (splay_compare_CORE_ADDR_ptr,
                                             NULL, /* no delete key */
                                             NULL, /* no delete value */
                                             splay_obstack_alloc,
                                             splay_obstack_free,
                                             map);

  return (struct addrmap *) map;
}
Commit	Line	Data
801e3a5b JB	1	/* addrmap.c --- implementation of address map data structure.
801e3a5b JB	2
b811d2c2	3	Copyright (C) 2007-2020 Free Software Foundation, Inc.
801e3a5b JB	4
	5	This file is part of GDB.
	6
	7	This program is free software; you can redistribute it and/or modify
	8	it under the terms of the GNU General Public License as published by
2fff4d11	9	the Free Software Foundation; either version 3 of the License, or
801e3a5b JB	10	(at your option) any later version.
	11
	12	This program is distributed in the hope that it will be useful,
	13	but WITHOUT ANY WARRANTY; without even the implied warranty of
	14	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	15	GNU General Public License for more details.
	16
	17	You should have received a copy of the GNU General Public License
2fff4d11	18	along with this program. If not, see <http://www.gnu.org/licenses/>. */
801e3a5b JB	19
801e3a5b JB	20	#include "defs.h"
d55e5aa6	21	#include "splay-tree.h"
4de283e4 TT	22	#include "gdb_obstack.h"
4de283e4 TT	23	#include "addrmap.h"
801e3a5b	24
90421c56 SM	25	/* Make sure splay trees can actually hold the values we want to
	26	store in them. */
	27	gdb_static_assert (sizeof (splay_tree_key) >= sizeof (CORE_ADDR *));
	28	gdb_static_assert (sizeof (splay_tree_value) >= sizeof (void *));
	29
801e3a5b JB	30	\f
	31	/* The "abstract class". */
	32
	33	/* Functions implementing the addrmap functions for a particular
	34	implementation. */
	35	struct addrmap_funcs
	36	{
fe978cb0	37	void (set_empty) (struct addrmap self,
801e3a5b JB	38	CORE_ADDR start, CORE_ADDR end_inclusive,
801e3a5b JB	39	void *obj);
fe978cb0 PA	40	void (find) (struct addrmap *self, CORE_ADDR addr);
fe978cb0 PA	41	struct addrmap (create_fixed) (struct addrmap *self,
801e3a5b	42	struct obstack *obstack);
fe978cb0 PA	43	void (relocate) (struct addrmap self, CORE_ADDR offset);
fe978cb0 PA	44	int (foreach) (struct addrmap self, addrmap_foreach_fn fn, void *data);
801e3a5b JB	45	};
	46
	47
	48	struct addrmap
	49	{
2fff4d11	50	const struct addrmap_funcs *funcs;
801e3a5b JB	51	};
	52
	53
	54	void
	55	addrmap_set_empty (struct addrmap *map,
	56	CORE_ADDR start, CORE_ADDR end_inclusive,
	57	void *obj)
	58	{
	59	map->funcs->set_empty (map, start, end_inclusive, obj);
	60	}
	61
	62
	63	void *
	64	addrmap_find (struct addrmap *map, CORE_ADDR addr)
	65	{
	66	return map->funcs->find (map, addr);
	67	}
	68
	69
	70	struct addrmap *
	71	addrmap_create_fixed (struct addrmap original, struct obstack obstack)
	72	{
	73	return original->funcs->create_fixed (original, obstack);
	74	}
	75
	76
	77	/* Relocate all the addresses in MAP by OFFSET. (This can be applied
	78	to either mutable or immutable maps.) */
	79	void
	80	addrmap_relocate (struct addrmap *map, CORE_ADDR offset)
	81	{
	82	map->funcs->relocate (map, offset);
	83	}
	84
	85
855c153f DE	86	int
	87	addrmap_foreach (struct addrmap map, addrmap_foreach_fn fn, void data)
	88	{
	89	return map->funcs->foreach (map, fn, data);
	90	}
801e3a5b JB	91	\f
	92	/* Fixed address maps. */
	93
	94	/* A transition: a point in an address map where the value changes.
	95	The map maps ADDR to VALUE, but if ADDR > 0, it maps ADDR-1 to
	96	something else. */
	97	struct addrmap_transition
	98	{
	99	CORE_ADDR addr;
	100	void *value;
	101	};
	102
	103
	104	struct addrmap_fixed
	105	{
	106	struct addrmap addrmap;
	107
	108	/* The number of transitions in TRANSITIONS. */
	109	size_t num_transitions;
	110
	111	/* An array of transitions, sorted by address. For every point in
	112	the map where either ADDR == 0 or ADDR is mapped to one value and
	113	ADDR - 1 is mapped to something different, we have an entry here
	114	containing ADDR and VALUE. (Note that this means we always have
	115	an entry for address 0). */
	116	struct addrmap_transition transitions[1];
	117	};
	118
	119
	120	static void
fe978cb0	121	addrmap_fixed_set_empty (struct addrmap *self,
801e3a5b JB	122	CORE_ADDR start, CORE_ADDR end_inclusive,
	123	void *obj)
	124	{
	125	internal_error (__FILE__, __LINE__,
	126	"addrmap_fixed_set_empty: "
	127	"fixed addrmaps can't be changed\n");
	128	}
	129
	130
	131	static void *
fe978cb0	132	addrmap_fixed_find (struct addrmap *self, CORE_ADDR addr)
801e3a5b	133	{
fe978cb0	134	struct addrmap_fixed map = (struct addrmap_fixed ) self;
801e3a5b JB	135	struct addrmap_transition *bottom = &map->transitions[0];
	136	struct addrmap_transition *top = &map->transitions[map->num_transitions - 1];
	137
	138	while (bottom < top)
	139	{
	140	/* This needs to round towards top, or else when top = bottom +
	141	1 (i.e., two entries are under consideration), then mid ==
	142	bottom, and then we may not narrow the range when (mid->addr
	143	< addr). */
	144	struct addrmap_transition *mid = top - (top - bottom) / 2;
	145
	146	if (mid->addr == addr)
	147	{
	148	bottom = mid;
	149	break;
	150	}
	151	else if (mid->addr < addr)
	152	/* We don't eliminate mid itself here, since each transition
	153	covers all subsequent addresses until the next. This is why
	154	we must round up in computing the midpoint. */
	155	bottom = mid;
	156	else
	157	top = mid - 1;
	158	}
	159
	160	return bottom->value;
	161	}
	162
	163
	164	static struct addrmap *
fe978cb0	165	addrmap_fixed_create_fixed (struct addrmap self, struct obstack obstack)
801e3a5b	166	{
2fff4d11 JB	167	internal_error (__FILE__, __LINE__,
	168	_("addrmap_create_fixed is not implemented yet "
	169	"for fixed addrmaps"));
801e3a5b JB	170	}
	171
	172
	173	static void
fe978cb0	174	addrmap_fixed_relocate (struct addrmap *self, CORE_ADDR offset)
801e3a5b	175	{
fe978cb0	176	struct addrmap_fixed map = (struct addrmap_fixed ) self;
801e3a5b JB	177	size_t i;
	178
	179	for (i = 0; i < map->num_transitions; i++)
	180	map->transitions[i].addr += offset;
	181	}
	182
	183
855c153f	184	static int
fe978cb0	185	addrmap_fixed_foreach (struct addrmap *self, addrmap_foreach_fn fn,
855c153f DE	186	void *data)
855c153f DE	187	{
fe978cb0	188	struct addrmap_fixed map = (struct addrmap_fixed ) self;
855c153f DE	189	size_t i;
	190
	191	for (i = 0; i < map->num_transitions; i++)
	192	{
	193	int res = fn (data, map->transitions[i].addr, map->transitions[i].value);
	194
	195	if (res != 0)
	196	return res;
	197	}
	198
	199	return 0;
	200	}
	201
	202
2fff4d11	203	static const struct addrmap_funcs addrmap_fixed_funcs =
801e3a5b	204	{
2fff4d11 JB	205	addrmap_fixed_set_empty,
	206	addrmap_fixed_find,
	207	addrmap_fixed_create_fixed,
855c153f DE	208	addrmap_fixed_relocate,
855c153f DE	209	addrmap_fixed_foreach
801e3a5b JB	210	};
	211
	212
	213	\f
	214	/* Mutable address maps. */
	215
	216	struct addrmap_mutable
	217	{
	218	struct addrmap addrmap;
	219
	220	/* The obstack to use for allocations for this map. */
	221	struct obstack *obstack;
	222
	223	/* A splay tree, with a node for each transition; there is a
	224	transition at address T if T-1 and T map to different objects.
	225
	226	Any addresses below the first node map to NULL. (Unlike
	227	fixed maps, we have no entry at (CORE_ADDR) 0; it doesn't
	228	simplify enough.)
	229
	230	The last region is assumed to end at CORE_ADDR_MAX.
	231
	232	Since we can't know whether CORE_ADDR is larger or smaller than
	233	splay_tree_key (unsigned long) --- I think both are possible,
	234	given all combinations of 32- and 64-bit hosts and targets ---
	235	our keys are pointers to CORE_ADDR values. Since the splay tree
	236	library doesn't pass any closure pointer to the key free
	237	function, we can't keep a freelist for keys. Since mutable
	238	addrmaps are only used temporarily right now, we just leak keys
	239	from deleted nodes; they'll be freed when the obstack is freed. */
	240	splay_tree tree;
	241
	242	/* A freelist for splay tree nodes, allocated on obstack, and
	243	chained together by their 'right' pointers. */
	244	splay_tree_node free_nodes;
	245	};
	246
	247
	248	/* Allocate a copy of CORE_ADDR in MAP's obstack. */
	249	static splay_tree_key
	250	allocate_key (struct addrmap_mutable *map, CORE_ADDR addr)
	251	{
8d749320	252	CORE_ADDR *key = XOBNEW (map->obstack, CORE_ADDR);
801e3a5b	253
5b4ee69b	254	*key = addr;
801e3a5b JB	255	return (splay_tree_key) key;
	256	}
	257
	258
	259	/* Type-correct wrappers for splay tree access. */
	260	static splay_tree_node
	261	addrmap_splay_tree_lookup (struct addrmap_mutable *map, CORE_ADDR addr)
	262	{
	263	return splay_tree_lookup (map->tree, (splay_tree_key) &addr);
	264	}
	265
	266
	267	static splay_tree_node
	268	addrmap_splay_tree_predecessor (struct addrmap_mutable *map, CORE_ADDR addr)
	269	{
	270	return splay_tree_predecessor (map->tree, (splay_tree_key) &addr);
	271	}
	272
	273
	274	static splay_tree_node
	275	addrmap_splay_tree_successor (struct addrmap_mutable *map, CORE_ADDR addr)
	276	{
	277	return splay_tree_successor (map->tree, (splay_tree_key) &addr);
	278	}
	279
	280
cb446409 JB	281	static void
	282	addrmap_splay_tree_remove (struct addrmap_mutable *map, CORE_ADDR addr)
	283	{
	284	splay_tree_remove (map->tree, (splay_tree_key) &addr);
	285	}
	286
	287
801e3a5b JB	288	static CORE_ADDR
	289	addrmap_node_key (splay_tree_node node)
	290	{
	291	return * (CORE_ADDR *) node->key;
	292	}
	293
	294
	295	static void *
	296	addrmap_node_value (splay_tree_node node)
	297	{
	298	return (void *) node->value;
	299	}
	300
	301
	302	static void
	303	addrmap_node_set_value (splay_tree_node node, void *value)
	304	{
	305	node->value = (splay_tree_value) value;
	306	}
	307
	308
	309	static void
3e43a32a MS	310	addrmap_splay_tree_insert (struct addrmap_mutable *map,
3e43a32a MS	311	CORE_ADDR key, void *value)
801e3a5b JB	312	{
	313	splay_tree_insert (map->tree,
	314	allocate_key (map, key),
	315	(splay_tree_value) value);
	316	}
	317
	318
	319	/* Without changing the mapping of any address, ensure that there is a
	320	tree node at ADDR, even if it would represent a "transition" from
	321	one value to the same value. */
	322	static void
fe978cb0	323	force_transition (struct addrmap_mutable *self, CORE_ADDR addr)
801e3a5b JB	324	{
801e3a5b JB	325	splay_tree_node n
fe978cb0	326	= addrmap_splay_tree_lookup (self, addr);
801e3a5b JB	327
	328	if (! n)
	329	{
fe978cb0 PA	330	n = addrmap_splay_tree_predecessor (self, addr);
fe978cb0 PA	331	addrmap_splay_tree_insert (self, addr,
801e3a5b JB	332	n ? addrmap_node_value (n) : NULL);
	333	}
	334	}
	335
	336
	337	static void
fe978cb0	338	addrmap_mutable_set_empty (struct addrmap *self,
801e3a5b JB	339	CORE_ADDR start, CORE_ADDR end_inclusive,
	340	void *obj)
	341	{
fe978cb0	342	struct addrmap_mutable map = (struct addrmap_mutable ) self;
801e3a5b JB	343	splay_tree_node n, next;
	344	void *prior_value;
	345
	346	/* If we're being asked to set all empty portions of the given
	347	address range to empty, then probably the caller is confused.
	348	(If that turns out to be useful in some cases, then we can change
	349	this to simply return, since overriding NULL with NULL is a
	350	no-op.) */
	351	gdb_assert (obj);
	352
	353	/* We take a two-pass approach, for simplicity.
	354	- Establish transitions where we think we might need them.
	355	- First pass: change all NULL regions to OBJ.
	356	- Second pass: remove any unnecessary transitions. */
	357
	358	/* Establish transitions at the start and end. */
	359	force_transition (map, start);
	360	if (end_inclusive < CORE_ADDR_MAX)
	361	force_transition (map, end_inclusive + 1);
	362
	363	/* Walk the area, changing all NULL regions to OBJ. */
	364	for (n = addrmap_splay_tree_lookup (map, start), gdb_assert (n);
	365	n && addrmap_node_key (n) <= end_inclusive;
	366	n = addrmap_splay_tree_successor (map, addrmap_node_key (n)))
	367	{
	368	if (! addrmap_node_value (n))
	369	addrmap_node_set_value (n, obj);
	370	}
	371
	372	/* Walk the area again, removing transitions from any value to
	373	itself. Be sure to visit both the transitions we forced
	374	above. */
	375	n = addrmap_splay_tree_predecessor (map, start);
	376	prior_value = n ? addrmap_node_value (n) : NULL;
	377	for (n = addrmap_splay_tree_lookup (map, start), gdb_assert (n);
	378	n && (end_inclusive == CORE_ADDR_MAX
	379	\|\| addrmap_node_key (n) <= end_inclusive + 1);
	380	n = next)
	381	{
	382	next = addrmap_splay_tree_successor (map, addrmap_node_key (n));
	383	if (addrmap_node_value (n) == prior_value)
cb446409	384	addrmap_splay_tree_remove (map, addrmap_node_key (n));
801e3a5b JB	385	else
	386	prior_value = addrmap_node_value (n);
	387	}
	388	}
	389
	390
	391	static void *
fe978cb0	392	addrmap_mutable_find (struct addrmap *self, CORE_ADDR addr)
801e3a5b JB	393	{
801e3a5b JB	394	/* Not needed yet. */
2fff4d11 JB	395	internal_error (__FILE__, __LINE__,
	396	_("addrmap_find is not implemented yet "
	397	"for mutable addrmaps"));
801e3a5b JB	398	}
	399
	400
	401	/* A function to pass to splay_tree_foreach to count the number of nodes
	402	in the tree. */
	403	static int
	404	splay_foreach_count (splay_tree_node n, void *closure)
	405	{
	406	size_t count = (size_t ) closure;
	407
	408	(*count)++;
	409	return 0;
	410	}
	411
	412
	413	/* A function to pass to splay_tree_foreach to copy entries into a
	414	fixed address map. */
	415	static int
	416	splay_foreach_copy (splay_tree_node n, void *closure)
	417	{
	418	struct addrmap_fixed fixed = (struct addrmap_fixed ) closure;
	419	struct addrmap_transition *t = &fixed->transitions[fixed->num_transitions];
	420
	421	t->addr = addrmap_node_key (n);
	422	t->value = addrmap_node_value (n);
	423	fixed->num_transitions++;
	424
	425	return 0;
	426	}
	427
	428
	429	static struct addrmap *
fe978cb0	430	addrmap_mutable_create_fixed (struct addrmap self, struct obstack obstack)
801e3a5b	431	{
fe978cb0	432	struct addrmap_mutable mutable_obj = (struct addrmap_mutable ) self;
801e3a5b JB	433	struct addrmap_fixed *fixed;
801e3a5b JB	434	size_t num_transitions;
224c3ddb	435	size_t alloc_len;
801e3a5b JB	436
	437	/* Count the number of transitions in the tree. */
	438	num_transitions = 0;
fe978cb0	439	splay_tree_foreach (mutable_obj->tree, splay_foreach_count, &num_transitions);
801e3a5b JB	440
	441	/* Include an extra entry for the transition at zero (which fixed
	442	maps have, but mutable maps do not.) */
	443	num_transitions++;
	444
224c3ddb SM	445	alloc_len = sizeof (*fixed)
	446	+ (num_transitions * sizeof (fixed->transitions[0]));
	447	fixed = (struct addrmap_fixed *) obstack_alloc (obstack, alloc_len);
801e3a5b JB	448	fixed->addrmap.funcs = &addrmap_fixed_funcs;
	449	fixed->num_transitions = 1;
	450	fixed->transitions[0].addr = 0;
	451	fixed->transitions[0].value = NULL;
	452
	453	/* Copy all entries from the splay tree to the array, in order
	454	of increasing address. */
fe978cb0	455	splay_tree_foreach (mutable_obj->tree, splay_foreach_copy, fixed);
801e3a5b JB	456
	457	/* We should have filled the array. */
	458	gdb_assert (fixed->num_transitions == num_transitions);
	459
	460	return (struct addrmap *) fixed;
	461	}
	462
	463
	464	static void
fe978cb0	465	addrmap_mutable_relocate (struct addrmap *self, CORE_ADDR offset)
801e3a5b JB	466	{
801e3a5b JB	467	/* Not needed yet. */
2fff4d11 JB	468	internal_error (__FILE__, __LINE__,
	469	_("addrmap_relocate is not implemented yet "
	470	"for mutable addrmaps"));
801e3a5b JB	471	}
	472
	473
855c153f DE	474	/* Struct to map addrmap's foreach function to splay_tree's version. */
	475	struct mutable_foreach_data
	476	{
	477	addrmap_foreach_fn fn;
	478	void *data;
	479	};
	480
	481
	482	/* This is a splay_tree_foreach_fn. */
	483
	484	static int
	485	addrmap_mutable_foreach_worker (splay_tree_node node, void *data)
	486	{
9a3c8263 SM	487	struct mutable_foreach_data *foreach_data
9a3c8263 SM	488	= (struct mutable_foreach_data *) data;
855c153f DE	489
	490	return foreach_data->fn (foreach_data->data,
	491	addrmap_node_key (node),
	492	addrmap_node_value (node));
	493	}
	494
	495
	496	static int
fe978cb0	497	addrmap_mutable_foreach (struct addrmap *self, addrmap_foreach_fn fn,
855c153f DE	498	void *data)
855c153f DE	499	{
fe978cb0	500	struct addrmap_mutable mutable_obj = (struct addrmap_mutable ) self;
855c153f DE	501	struct mutable_foreach_data foreach_data;
	502
	503	foreach_data.fn = fn;
	504	foreach_data.data = data;
fe978cb0	505	return splay_tree_foreach (mutable_obj->tree, addrmap_mutable_foreach_worker,
855c153f DE	506	&foreach_data);
	507	}
	508
	509
2fff4d11	510	static const struct addrmap_funcs addrmap_mutable_funcs =
801e3a5b	511	{
2fff4d11 JB	512	addrmap_mutable_set_empty,
	513	addrmap_mutable_find,
	514	addrmap_mutable_create_fixed,
855c153f DE	515	addrmap_mutable_relocate,
855c153f DE	516	addrmap_mutable_foreach
801e3a5b JB	517	};
	518
	519
	520	static void *
	521	splay_obstack_alloc (int size, void *closure)
	522	{
9a3c8263	523	struct addrmap_mutable map = (struct addrmap_mutable ) closure;
801e3a5b JB	524	splay_tree_node n;
	525
	526	/* We should only be asked to allocate nodes and larger things.
	527	(If, at some point in the future, this is no longer true, we can
	528	just round up the size to sizeof (n).) /
	529	gdb_assert (size >= sizeof (*n));
	530
	531	if (map->free_nodes)
	532	{
	533	n = map->free_nodes;
	534	map->free_nodes = n->right;
	535	return n;
	536	}
	537	else
	538	return obstack_alloc (map->obstack, size);
	539	}
	540
	541
	542	static void
	543	splay_obstack_free (void obj, void closure)
	544	{
9a3c8263 SM	545	struct addrmap_mutable map = (struct addrmap_mutable ) closure;
9a3c8263 SM	546	splay_tree_node n = (splay_tree_node) obj;
801e3a5b JB	547
	548	/* We've asserted in the allocation function that we only allocate
	549	nodes or larger things, so it should be safe to put whatever
	550	we get passed back on the free list. */
	551	n->right = map->free_nodes;
	552	map->free_nodes = n;
	553	}
	554
	555
	556	/* Compare keys as CORE_ADDR * values. */
	557	static int
	558	splay_compare_CORE_ADDR_ptr (splay_tree_key ak, splay_tree_key bk)
	559	{
	560	CORE_ADDR a = * (CORE_ADDR *) ak;
	561	CORE_ADDR b = * (CORE_ADDR *) bk;
	562
	563	/* We can't just return a-b here, because of over/underflow. */
	564	if (a < b)
	565	return -1;
	566	else if (a == b)
	567	return 0;
	568	else
	569	return 1;
	570	}
	571
	572
	573	struct addrmap *
	574	addrmap_create_mutable (struct obstack *obstack)
	575	{
8d749320	576	struct addrmap_mutable *map = XOBNEW (obstack, struct addrmap_mutable);
801e3a5b JB	577
	578	map->addrmap.funcs = &addrmap_mutable_funcs;
	579	map->obstack = obstack;
	580
	581	/* splay_tree_new_with_allocator uses the provided allocation
	582	function to allocate the main splay_tree structure itself, so our
	583	free list has to be initialized before we create the tree. */
	584	map->free_nodes = NULL;
	585
	586	map->tree = splay_tree_new_with_allocator (splay_compare_CORE_ADDR_ptr,
	587	NULL, /* no delete key */
	588	NULL, /* no delete value */
	589	splay_obstack_alloc,
	590	splay_obstack_free,
	591	map);
	592
	593	return (struct addrmap *) map;
	594	}