gdb/addrmap.c - binutils-gdb - Git at Google

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

    Copyright (C) 2007-2024 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 "gdbsupport/gdb_obstack.h"
 #include "addrmap.h"
 #include "gdbsupport/selftest.h"

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


 /* Fixed address maps.  */

 void *
 addrmap_fixed::do_find (CORE_ADDR addr) const
 {
   const struct addrmap_transition *bottom = &transitions[0];
   const struct addrmap_transition *top = &transitions[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).  */
       const 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;
 }


 void
 addrmap_fixed::relocate (CORE_ADDR offset)
 {
   size_t i;

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


 int
 addrmap_fixed::do_foreach (addrmap_foreach_fn fn) const
 {
   size_t i;

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

       if (res != 0)
 	return res;
     }

   return 0;
 }


 /* Mutable address maps.  */

 /* Allocate a copy of CORE_ADDR.  */
 splay_tree_key
 addrmap_mutable::allocate_key (CORE_ADDR addr)
 {
   CORE_ADDR *key = XNEW (CORE_ADDR);

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


 /* Type-correct wrappers for splay tree access.  */
 splay_tree_node
 addrmap_mutable::splay_tree_lookup (CORE_ADDR addr) const
 {
   return ::splay_tree_lookup (tree, (splay_tree_key) &addr);
 }


 splay_tree_node
 addrmap_mutable::splay_tree_predecessor (CORE_ADDR addr) const
 {
   return ::splay_tree_predecessor (tree, (splay_tree_key) &addr);
 }


 splay_tree_node
 addrmap_mutable::splay_tree_successor (CORE_ADDR addr)
 {
   return ::splay_tree_successor (tree, (splay_tree_key) &addr);
 }


 void
 addrmap_mutable::splay_tree_remove (CORE_ADDR addr)
 {
   ::splay_tree_remove (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;
 }


 void
 addrmap_mutable::splay_tree_insert (CORE_ADDR key, void *value)
 {
   ::splay_tree_insert (tree,
 		       allocate_key (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.  */
 void
 addrmap_mutable::force_transition (CORE_ADDR addr)
 {
   splay_tree_node n = splay_tree_lookup (addr);

   if (! n)
     {
       n = splay_tree_predecessor (addr);
       splay_tree_insert (addr, n ? addrmap_node_value (n) : NULL);
     }
 }


 void
 addrmap_mutable::set_empty (CORE_ADDR start, CORE_ADDR end_inclusive,
 			    void *obj)
 {
   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 (start);
   if (end_inclusive < CORE_ADDR_MAX)
     force_transition (end_inclusive + 1);

   /* Walk the area, changing all NULL regions to OBJ.  */
   for (n = splay_tree_lookup (start), gdb_assert (n);
        n && addrmap_node_key (n) <= end_inclusive;
        n = splay_tree_successor (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 = splay_tree_predecessor (start);
   prior_value = n ? addrmap_node_value (n) : NULL;
   for (n = splay_tree_lookup (start), gdb_assert (n);
        n && (end_inclusive == CORE_ADDR_MAX
 	     || addrmap_node_key (n) <= end_inclusive + 1);
        n = next)
     {
       next = splay_tree_successor (addrmap_node_key (n));
       if (addrmap_node_value (n) == prior_value)
 	splay_tree_remove (addrmap_node_key (n));
       else
 	prior_value = addrmap_node_value (n);
     }
 }


 void *
 addrmap_mutable::do_find (CORE_ADDR addr) const
 {
   splay_tree_node n = splay_tree_lookup (addr);
   if (n != nullptr)
     {
       gdb_assert (addrmap_node_key (n) == addr);
       return addrmap_node_value (n);
     }

   n = splay_tree_predecessor (addr);
   if (n != nullptr)
     {
       gdb_assert (addrmap_node_key (n) < addr);
       return addrmap_node_value (n);
     }

   return nullptr;
 }


 addrmap_fixed::addrmap_fixed (struct obstack *obstack, addrmap_mutable *mut)
 {
   size_t transition_count = 0;

   /* Count the number of transitions in the tree.  */
   mut->foreach ([&] (CORE_ADDR start, void *obj)
     {
       ++transition_count;
       return 0;
     });

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

   num_transitions = 1;
   transitions = XOBNEWVEC (obstack, struct addrmap_transition,
 			   transition_count);
   transitions[0].addr = 0;
   transitions[0].value = NULL;

   /* Copy all entries from the splay tree to the array, in order
      of increasing address.  */
   mut->foreach ([&] (CORE_ADDR start, void *obj)
     {
       transitions[num_transitions].addr = start;
       transitions[num_transitions].value = obj;
       ++num_transitions;
       return 0;
     });

   /* We should have filled the array.  */
   gdb_assert (num_transitions == transition_count);
 }


 void
 addrmap_mutable::relocate (CORE_ADDR offset)
 {
   /* Not needed yet.  */
   internal_error (_("addrmap_relocate is not implemented yet "
 		    "for mutable addrmaps"));
 }


 /* This is a splay_tree_foreach_fn.  */

 static int
 addrmap_mutable_foreach_worker (splay_tree_node node, void *data)
 {
   addrmap_foreach_fn *fn = (addrmap_foreach_fn *) data;

   return (*fn) (addrmap_node_key (node), addrmap_node_value (node));
 }


 int
 addrmap_mutable::do_foreach (addrmap_foreach_fn fn) const
 {
   return splay_tree_foreach (tree, addrmap_mutable_foreach_worker, &fn);
 }


 /* 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;
 }


 static void
 xfree_wrapper (splay_tree_key key)
 {
   xfree ((void *) key);
 }

 addrmap_mutable::addrmap_mutable ()
   : tree (splay_tree_new (splay_compare_CORE_ADDR_ptr, xfree_wrapper,
 			  nullptr /* no delete value */))
 {
 }

 addrmap_mutable::~addrmap_mutable ()
 {
   splay_tree_delete (tree);
 }


 /* See addrmap.h.  */

 void
 addrmap_dump (struct addrmap *map, struct ui_file *outfile, void *payload)
 {
   /* True if the previously printed addrmap entry was for PAYLOAD.
      If so, we want to print the next one as well (since the next
      addrmap entry defines the end of the range).  */
   bool previous_matched = false;

   auto callback = [&] (CORE_ADDR start_addr, const void *obj)
   {
     QUIT;

     bool matches = payload == nullptr || payload == obj;
     const char *addr_str = nullptr;
     if (matches)
       addr_str = host_address_to_string (obj);
     else if (previous_matched)
       addr_str = "<ends here>";

     if (matches || previous_matched)
       gdb_printf (outfile, "  %s%s %s\n",
 		  payload != nullptr ? "  " : "",
 		  core_addr_to_string (start_addr),
 		  addr_str);

     previous_matched = matches;

     return 0;
   };

   map->foreach (callback);
 }

 #if GDB_SELF_TEST
 namespace selftests {

 /* Convert P to CORE_ADDR.  */

 static CORE_ADDR
 core_addr (void *p)
 {
   return (CORE_ADDR)(uintptr_t)p;
 }

 /* Check that &ARRAY[LOW]..&ARRAY[HIGH] has VAL in MAP.  */

 #define CHECK_ADDRMAP_FIND(MAP, ARRAY, LOW, HIGH, VAL)			\
   do									\
     {									\
       for (unsigned i = LOW; i <= HIGH; ++i)				\
 	SELF_CHECK (MAP->find (core_addr (&ARRAY[i])) == VAL);		\
     }									\
   while (0)

 /* Entry point for addrmap unit tests.  */

 static void
 test_addrmap ()
 {
   /* We'll verify using the addresses of the elements of this array.  */
   char array[20];

   /* We'll verify using these values stored into the map.  */
   void *val1 = &array[1];
   void *val2 = &array[2];

   /* Create mutable addrmap.  */
   auto_obstack temp_obstack;
   auto map = std::make_unique<struct addrmap_mutable> ();
   SELF_CHECK (map != nullptr);

   /* Check initial state.  */
   CHECK_ADDRMAP_FIND (map, array, 0, 19, nullptr);

   /* Insert address range into mutable addrmap.  */
   map->set_empty (core_addr (&array[10]), core_addr (&array[12]), val1);
   CHECK_ADDRMAP_FIND (map, array, 0, 9, nullptr);
   CHECK_ADDRMAP_FIND (map, array, 10, 12, val1);
   CHECK_ADDRMAP_FIND (map, array, 13, 19, nullptr);

   /* Create corresponding fixed addrmap.  */
   struct addrmap *map2
     = new (&temp_obstack) addrmap_fixed (&temp_obstack, map.get ());
   SELF_CHECK (map2 != nullptr);
   CHECK_ADDRMAP_FIND (map2, array, 0, 9, nullptr);
   CHECK_ADDRMAP_FIND (map2, array, 10, 12, val1);
   CHECK_ADDRMAP_FIND (map2, array, 13, 19, nullptr);

   /* Iterate over both addrmaps.  */
   auto callback = [&] (CORE_ADDR start_addr, void *obj)
     {
       if (start_addr == core_addr (nullptr))
 	SELF_CHECK (obj == nullptr);
       else if (start_addr == core_addr (&array[10]))
 	SELF_CHECK (obj == val1);
       else if (start_addr == core_addr (&array[13]))
 	SELF_CHECK (obj == nullptr);
       else
 	SELF_CHECK (false);
       return 0;
     };
   SELF_CHECK (map->foreach (callback) == 0);
   SELF_CHECK (map2->foreach (callback) == 0);

   /* Relocate fixed addrmap.  */
   map2->relocate (1);
   CHECK_ADDRMAP_FIND (map2, array, 0, 10, nullptr);
   CHECK_ADDRMAP_FIND (map2, array, 11, 13, val1);
   CHECK_ADDRMAP_FIND (map2, array, 14, 19, nullptr);

   /* Insert partially overlapping address range into mutable addrmap.  */
   map->set_empty (core_addr (&array[11]), core_addr (&array[13]), val2);
   CHECK_ADDRMAP_FIND (map, array, 0, 9, nullptr);
   CHECK_ADDRMAP_FIND (map, array, 10, 12, val1);
   CHECK_ADDRMAP_FIND (map, array, 13, 13, val2);
   CHECK_ADDRMAP_FIND (map, array, 14, 19, nullptr);
 }

 } // namespace selftests
 #endif /* GDB_SELF_TEST */

 void _initialize_addrmap ();
 void
 _initialize_addrmap ()
 {
 #if GDB_SELF_TEST
   selftests::register_test ("addrmap", selftests::test_addrmap);
 #endif /* GDB_SELF_TEST */
 }
	/* addrmap.c --- implementation of address map data structure.

	Copyright (C) 2007-2024 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 "gdbsupport/gdb_obstack.h"
	#include "addrmap.h"
	#include "gdbsupport/selftest.h"

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


	/* Fixed address maps. */

	void *
	addrmap_fixed::do_find (CORE_ADDR addr) const
	{
	const struct addrmap_transition *bottom = &transitions[0];
	const struct addrmap_transition *top = &transitions[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). */
	const 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;
	}


	void
	addrmap_fixed::relocate (CORE_ADDR offset)
	{
	size_t i;

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


	int
	addrmap_fixed::do_foreach (addrmap_foreach_fn fn) const
	{
	size_t i;

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

	if (res != 0)
	return res;
	}

	return 0;
	}



	/* Mutable address maps. */

	/* Allocate a copy of CORE_ADDR. */
	splay_tree_key
	addrmap_mutable::allocate_key (CORE_ADDR addr)
	{
	CORE_ADDR *key = XNEW (CORE_ADDR);

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


	/* Type-correct wrappers for splay tree access. */
	splay_tree_node
	addrmap_mutable::splay_tree_lookup (CORE_ADDR addr) const
	{
	return ::splay_tree_lookup (tree, (splay_tree_key) &addr);
	}


	splay_tree_node
	addrmap_mutable::splay_tree_predecessor (CORE_ADDR addr) const
	{
	return ::splay_tree_predecessor (tree, (splay_tree_key) &addr);
	}


	splay_tree_node
	addrmap_mutable::splay_tree_successor (CORE_ADDR addr)
	{
	return ::splay_tree_successor (tree, (splay_tree_key) &addr);
	}


	void
	addrmap_mutable::splay_tree_remove (CORE_ADDR addr)
	{
	::splay_tree_remove (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;
	}


	void
	addrmap_mutable::splay_tree_insert (CORE_ADDR key, void *value)
	{
	::splay_tree_insert (tree,
	allocate_key (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. */
	void
	addrmap_mutable::force_transition (CORE_ADDR addr)
	{
	splay_tree_node n = splay_tree_lookup (addr);

	if (! n)
	{
	n = splay_tree_predecessor (addr);
	splay_tree_insert (addr, n ? addrmap_node_value (n) : NULL);
	}
	}


	void
	addrmap_mutable::set_empty (CORE_ADDR start, CORE_ADDR end_inclusive,
	void *obj)
	{
	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 (start);
	if (end_inclusive < CORE_ADDR_MAX)
	force_transition (end_inclusive + 1);

	/* Walk the area, changing all NULL regions to OBJ. */
	for (n = splay_tree_lookup (start), gdb_assert (n);
	n && addrmap_node_key (n) <= end_inclusive;
	n = splay_tree_successor (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 = splay_tree_predecessor (start);
	prior_value = n ? addrmap_node_value (n) : NULL;
	for (n = splay_tree_lookup (start), gdb_assert (n);
	n && (end_inclusive == CORE_ADDR_MAX
	\|\| addrmap_node_key (n) <= end_inclusive + 1);
	n = next)
	{
	next = splay_tree_successor (addrmap_node_key (n));
	if (addrmap_node_value (n) == prior_value)
	splay_tree_remove (addrmap_node_key (n));
	else
	prior_value = addrmap_node_value (n);
	}
	}


	void *
	addrmap_mutable::do_find (CORE_ADDR addr) const
	{
	splay_tree_node n = splay_tree_lookup (addr);
	if (n != nullptr)
	{
	gdb_assert (addrmap_node_key (n) == addr);
	return addrmap_node_value (n);
	}

	n = splay_tree_predecessor (addr);
	if (n != nullptr)
	{
	gdb_assert (addrmap_node_key (n) < addr);
	return addrmap_node_value (n);
	}

	return nullptr;
	}


	addrmap_fixed::addrmap_fixed (struct obstack obstack, addrmap_mutable mut)
	{
	size_t transition_count = 0;

	/* Count the number of transitions in the tree. */
	mut->foreach ([&] (CORE_ADDR start, void *obj)
	{
	++transition_count;
	return 0;
	});

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

	num_transitions = 1;
	transitions = XOBNEWVEC (obstack, struct addrmap_transition,
	transition_count);
	transitions[0].addr = 0;
	transitions[0].value = NULL;

	/* Copy all entries from the splay tree to the array, in order
	of increasing address. */
	mut->foreach ([&] (CORE_ADDR start, void *obj)
	{
	transitions[num_transitions].addr = start;
	transitions[num_transitions].value = obj;
	++num_transitions;
	return 0;
	});

	/* We should have filled the array. */
	gdb_assert (num_transitions == transition_count);
	}


	void
	addrmap_mutable::relocate (CORE_ADDR offset)
	{
	/* Not needed yet. */
	internal_error (_("addrmap_relocate is not implemented yet "
	"for mutable addrmaps"));
	}


	/* This is a splay_tree_foreach_fn. */

	static int
	addrmap_mutable_foreach_worker (splay_tree_node node, void *data)
	{
	addrmap_foreach_fn fn = (addrmap_foreach_fn ) data;

	return (*fn) (addrmap_node_key (node), addrmap_node_value (node));
	}


	int
	addrmap_mutable::do_foreach (addrmap_foreach_fn fn) const
	{
	return splay_tree_foreach (tree, addrmap_mutable_foreach_worker, &fn);
	}


	/* 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;
	}


	static void
	xfree_wrapper (splay_tree_key key)
	{
	xfree ((void *) key);
	}

	addrmap_mutable::addrmap_mutable ()
	: tree (splay_tree_new (splay_compare_CORE_ADDR_ptr, xfree_wrapper,
	nullptr /* no delete value */))
	{
	}

	addrmap_mutable::~addrmap_mutable ()
	{
	splay_tree_delete (tree);
	}


	/* See addrmap.h. */

	void
	addrmap_dump (struct addrmap map, struct ui_file outfile, void *payload)
	{
	/* True if the previously printed addrmap entry was for PAYLOAD.
	If so, we want to print the next one as well (since the next
	addrmap entry defines the end of the range). */
	bool previous_matched = false;

	auto callback = [&] (CORE_ADDR start_addr, const void *obj)
	{
	QUIT;

	bool matches = payload == nullptr \|\| payload == obj;
	const char *addr_str = nullptr;
	if (matches)
	addr_str = host_address_to_string (obj);
	else if (previous_matched)
	addr_str = "<ends here>";

	if (matches \|\| previous_matched)
	gdb_printf (outfile, " %s%s %s\n",
	payload != nullptr ? " " : "",
	core_addr_to_string (start_addr),
	addr_str);

	previous_matched = matches;

	return 0;
	};

	map->foreach (callback);
	}

	#if GDB_SELF_TEST
	namespace selftests {

	/* Convert P to CORE_ADDR. */

	static CORE_ADDR
	core_addr (void *p)
	{
	return (CORE_ADDR)(uintptr_t)p;
	}

	/* Check that &ARRAY[LOW]..&ARRAY[HIGH] has VAL in MAP. */

	#define CHECK_ADDRMAP_FIND(MAP, ARRAY, LOW, HIGH, VAL) \
	do \
	{ \
	for (unsigned i = LOW; i <= HIGH; ++i) \
	SELF_CHECK (MAP->find (core_addr (&ARRAY[i])) == VAL); \
	} \
	while (0)

	/* Entry point for addrmap unit tests. */

	static void
	test_addrmap ()
	{
	/* We'll verify using the addresses of the elements of this array. */
	char array[20];

	/* We'll verify using these values stored into the map. */
	void *val1 = &array[1];
	void *val2 = &array[2];

	/* Create mutable addrmap. */
	auto_obstack temp_obstack;
	auto map = std::make_unique<struct addrmap_mutable> ();
	SELF_CHECK (map != nullptr);

	/* Check initial state. */
	CHECK_ADDRMAP_FIND (map, array, 0, 19, nullptr);

	/* Insert address range into mutable addrmap. */
	map->set_empty (core_addr (&array[10]), core_addr (&array[12]), val1);
	CHECK_ADDRMAP_FIND (map, array, 0, 9, nullptr);
	CHECK_ADDRMAP_FIND (map, array, 10, 12, val1);
	CHECK_ADDRMAP_FIND (map, array, 13, 19, nullptr);

	/* Create corresponding fixed addrmap. */
	struct addrmap *map2
	= new (&temp_obstack) addrmap_fixed (&temp_obstack, map.get ());
	SELF_CHECK (map2 != nullptr);
	CHECK_ADDRMAP_FIND (map2, array, 0, 9, nullptr);
	CHECK_ADDRMAP_FIND (map2, array, 10, 12, val1);
	CHECK_ADDRMAP_FIND (map2, array, 13, 19, nullptr);

	/* Iterate over both addrmaps. */
	auto callback = [&] (CORE_ADDR start_addr, void *obj)
	{
	if (start_addr == core_addr (nullptr))
	SELF_CHECK (obj == nullptr);
	else if (start_addr == core_addr (&array[10]))
	SELF_CHECK (obj == val1);
	else if (start_addr == core_addr (&array[13]))
	SELF_CHECK (obj == nullptr);
	else
	SELF_CHECK (false);
	return 0;
	};
	SELF_CHECK (map->foreach (callback) == 0);
	SELF_CHECK (map2->foreach (callback) == 0);

	/* Relocate fixed addrmap. */
	map2->relocate (1);
	CHECK_ADDRMAP_FIND (map2, array, 0, 10, nullptr);
	CHECK_ADDRMAP_FIND (map2, array, 11, 13, val1);
	CHECK_ADDRMAP_FIND (map2, array, 14, 19, nullptr);

	/* Insert partially overlapping address range into mutable addrmap. */
	map->set_empty (core_addr (&array[11]), core_addr (&array[13]), val2);
	CHECK_ADDRMAP_FIND (map, array, 0, 9, nullptr);
	CHECK_ADDRMAP_FIND (map, array, 10, 12, val1);
	CHECK_ADDRMAP_FIND (map, array, 13, 13, val2);
	CHECK_ADDRMAP_FIND (map, array, 14, 19, nullptr);
	}

	} // namespace selftests
	#endif /* GDB_SELF_TEST */

	void _initialize_addrmap ();
	void
	_initialize_addrmap ()
	{
	#if GDB_SELF_TEST
	selftests::register_test ("addrmap", selftests::test_addrmap);
	#endif /* GDB_SELF_TEST */
	}