gdb/prologue-value.c - third_party/binutils-gdb - Git at Google

 /* Prologue value handling for GDB.
    Copyright (C) 2003-2016 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 "prologue-value.h"
 #include "regcache.h"


 /* Constructors.  */

 pv_t
 pv_unknown (void)
 {
   pv_t v = { pvk_unknown, 0, 0 };

   return v;
 }


 pv_t
 pv_constant (CORE_ADDR k)
 {
   pv_t v;

   v.kind = pvk_constant;
   v.reg = -1;                   /* for debugging */
   v.k = k;

   return v;
 }


 pv_t
 pv_register (int reg, CORE_ADDR k)
 {
   pv_t v;

   v.kind = pvk_register;
   v.reg = reg;
   v.k = k;

   return v;
 }


 /* Arithmetic operations.  */

 /* If one of *A and *B is a constant, and the other isn't, swap the
    values as necessary to ensure that *B is the constant.  This can
    reduce the number of cases we need to analyze in the functions
    below.  */
 static void
 constant_last (pv_t *a, pv_t *b)
 {
   if (a->kind == pvk_constant
       && b->kind != pvk_constant)
     {
       pv_t temp = *a;
       *a = *b;
       *b = temp;
     }
 }


 pv_t
 pv_add (pv_t a, pv_t b)
 {
   constant_last (&a, &b);

   /* We can add a constant to a register.  */
   if (a.kind == pvk_register
       && b.kind == pvk_constant)
     return pv_register (a.reg, a.k + b.k);

   /* We can add a constant to another constant.  */
   else if (a.kind == pvk_constant
            && b.kind == pvk_constant)
     return pv_constant (a.k + b.k);

   /* Anything else we don't know how to add.  We don't have a
      representation for, say, the sum of two registers, or a multiple
      of a register's value (adding a register to itself).  */
   else
     return pv_unknown ();
 }


 pv_t
 pv_add_constant (pv_t v, CORE_ADDR k)
 {
   /* Rather than thinking of all the cases we can and can't handle,
      we'll just let pv_add take care of that for us.  */
   return pv_add (v, pv_constant (k));
 }


 pv_t
 pv_subtract (pv_t a, pv_t b)
 {
   /* This isn't quite the same as negating B and adding it to A, since
      we don't have a representation for the negation of anything but a
      constant.  For example, we can't negate { pvk_register, R1, 10 },
      but we do know that { pvk_register, R1, 10 } minus { pvk_register,
      R1, 5 } is { pvk_constant, <ignored>, 5 }.

      This means, for example, that we could subtract two stack
      addresses; they're both relative to the original SP.  Since the
      frame pointer is set based on the SP, its value will be the
      original SP plus some constant (probably zero), so we can use its
      value just fine, too.  */

   constant_last (&a, &b);

   /* We can subtract two constants.  */
   if (a.kind == pvk_constant
       && b.kind == pvk_constant)
     return pv_constant (a.k - b.k);

   /* We can subtract a constant from a register.  */
   else if (a.kind == pvk_register
            && b.kind == pvk_constant)
     return pv_register (a.reg, a.k - b.k);

   /* We can subtract a register from itself, yielding a constant.  */
   else if (a.kind == pvk_register
            && b.kind == pvk_register
            && a.reg == b.reg)
     return pv_constant (a.k - b.k);

   /* We don't know how to subtract anything else.  */
   else
     return pv_unknown ();
 }


 pv_t
 pv_logical_and (pv_t a, pv_t b)
 {
   constant_last (&a, &b);

   /* We can 'and' two constants.  */
   if (a.kind == pvk_constant
       && b.kind == pvk_constant)
     return pv_constant (a.k & b.k);

   /* We can 'and' anything with the constant zero.  */
   else if (b.kind == pvk_constant
            && b.k == 0)
     return pv_constant (0);

   /* We can 'and' anything with ~0.  */
   else if (b.kind == pvk_constant
            && b.k == ~ (CORE_ADDR) 0)
     return a;

   /* We can 'and' a register with itself.  */
   else if (a.kind == pvk_register
            && b.kind == pvk_register
            && a.reg == b.reg
            && a.k == b.k)
     return a;

   /* Otherwise, we don't know.  */
   else
     return pv_unknown ();
 }


 /* Examining prologue values.  */

 int
 pv_is_identical (pv_t a, pv_t b)
 {
   if (a.kind != b.kind)
     return 0;

   switch (a.kind)
     {
     case pvk_unknown:
       return 1;
     case pvk_constant:
       return (a.k == b.k);
     case pvk_register:
       return (a.reg == b.reg && a.k == b.k);
     default:
       gdb_assert_not_reached ("unexpected prologue value kind");
     }
 }


 int
 pv_is_constant (pv_t a)
 {
   return (a.kind == pvk_constant);
 }


 int
 pv_is_register (pv_t a, int r)
 {
   return (a.kind == pvk_register
           && a.reg == r);
 }


 int
 pv_is_register_k (pv_t a, int r, CORE_ADDR k)
 {
   return (a.kind == pvk_register
           && a.reg == r
           && a.k == k);
 }


 enum pv_boolean
 pv_is_array_ref (pv_t addr, CORE_ADDR size,
                  pv_t array_addr, CORE_ADDR array_len,
                  CORE_ADDR elt_size,
                  int *i)
 {
   /* Note that, since .k is a CORE_ADDR, and CORE_ADDR is unsigned, if
      addr is *before* the start of the array, then this isn't going to
      be negative...  */
   pv_t offset = pv_subtract (addr, array_addr);

   if (offset.kind == pvk_constant)
     {
       /* This is a rather odd test.  We want to know if the SIZE bytes
          at ADDR don't overlap the array at all, so you'd expect it to
          be an || expression: "if we're completely before || we're
          completely after".  But with unsigned arithmetic, things are
          different: since it's a number circle, not a number line, the
          right values for offset.k are actually one contiguous range.  */
       if (offset.k <= -size
           && offset.k >= array_len * elt_size)
         return pv_definite_no;
       else if (offset.k % elt_size != 0
                || size != elt_size)
         return pv_maybe;
       else
         {
           *i = offset.k / elt_size;
           return pv_definite_yes;
         }
     }
   else
     return pv_maybe;
 }


 /* Areas.  */


 /* A particular value known to be stored in an area.

    Entries form a ring, sorted by unsigned offset from the area's base
    register's value.  Since entries can straddle the wrap-around point,
    unsigned offsets form a circle, not a number line, so the list
    itself is structured the same way --- there is no inherent head.
    The entry with the lowest offset simply follows the entry with the
    highest offset.  Entries may abut, but never overlap.  The area's
    'entry' pointer points to an arbitrary node in the ring.  */
 struct area_entry
 {
   /* Links in the doubly-linked ring.  */
   struct area_entry *prev, *next;

   /* Offset of this entry's address from the value of the base
      register.  */
   CORE_ADDR offset;

   /* The size of this entry.  Note that an entry may wrap around from
      the end of the address space to the beginning.  */
   CORE_ADDR size;

   /* The value stored here.  */
   pv_t value;
 };


 struct pv_area
 {
   /* This area's base register.  */
   int base_reg;

   /* The mask to apply to addresses, to make the wrap-around happen at
      the right place.  */
   CORE_ADDR addr_mask;

   /* An element of the doubly-linked ring of entries, or zero if we
      have none.  */
   struct area_entry *entry;
 };


 struct pv_area *
 make_pv_area (int base_reg, int addr_bit)
 {
   struct pv_area *a = XNEW (struct pv_area);

   memset (a, 0, sizeof (*a));

   a->base_reg = base_reg;
   a->entry = 0;

   /* Remember that shift amounts equal to the type's width are
      undefined.  */
   a->addr_mask = ((((CORE_ADDR) 1 << (addr_bit - 1)) - 1) << 1) | 1;

   return a;
 }


 /* Delete all entries from AREA.  */
 static void
 clear_entries (struct pv_area *area)
 {
   struct area_entry *e = area->entry;

   if (e)
     {
       /* This needs to be a do-while loop, in order to actually
          process the node being checked for in the terminating
          condition.  */
       do
         {
           struct area_entry *next = e->next;

           xfree (e);
           e = next;
         }
       while (e != area->entry);

       area->entry = 0;
     }
 }


 void
 free_pv_area (struct pv_area *area)
 {
   clear_entries (area);
   xfree (area);
 }


 static void
 do_free_pv_area_cleanup (void *arg)
 {
   free_pv_area ((struct pv_area *) arg);
 }


 struct cleanup *
 make_cleanup_free_pv_area (struct pv_area *area)
 {
   return make_cleanup (do_free_pv_area_cleanup, (void *) area);
 }


 int
 pv_area_store_would_trash (struct pv_area *area, pv_t addr)
 {
   /* It may seem odd that pvk_constant appears here --- after all,
      that's the case where we know the most about the address!  But
      pv_areas are always relative to a register, and we don't know the
      value of the register, so we can't compare entry addresses to
      constants.  */
   return (addr.kind == pvk_unknown
           || addr.kind == pvk_constant
           || (addr.kind == pvk_register && addr.reg != area->base_reg));
 }


 /* Return a pointer to the first entry we hit in AREA starting at
    OFFSET and going forward.

    This may return zero, if AREA has no entries.

    And since the entries are a ring, this may return an entry that
    entirely precedes OFFSET.  This is the correct behavior: depending
    on the sizes involved, we could still overlap such an area, with
    wrap-around.  */
 static struct area_entry *
 find_entry (struct pv_area *area, CORE_ADDR offset)
 {
   struct area_entry *e = area->entry;

   if (! e)
     return 0;

   /* If the next entry would be better than the current one, then scan
      forward.  Since we use '<' in this loop, it always terminates.

      Note that, even setting aside the addr_mask stuff, we must not
      simplify this, in high school algebra fashion, to
      (e->next->offset < e->offset), because of the way < interacts
      with wrap-around.  We have to subtract offset from both sides to
      make sure both things we're comparing are on the same side of the
      discontinuity.  */
   while (((e->next->offset - offset) & area->addr_mask)
          < ((e->offset - offset) & area->addr_mask))
     e = e->next;

   /* If the previous entry would be better than the current one, then
      scan backwards.  */
   while (((e->prev->offset - offset) & area->addr_mask)
          < ((e->offset - offset) & area->addr_mask))
     e = e->prev;

   /* In case there's some locality to the searches, set the area's
      pointer to the entry we've found.  */
   area->entry = e;

   return e;
 }


 /* Return non-zero if the SIZE bytes at OFFSET would overlap ENTRY;
    return zero otherwise.  AREA is the area to which ENTRY belongs.  */
 static int
 overlaps (struct pv_area *area,
           struct area_entry *entry,
           CORE_ADDR offset,
           CORE_ADDR size)
 {
   /* Think carefully about wrap-around before simplifying this.  */
   return (((entry->offset - offset) & area->addr_mask) < size
           || ((offset - entry->offset) & area->addr_mask) < entry->size);
 }


 void
 pv_area_store (struct pv_area *area,
                pv_t addr,
                CORE_ADDR size,
                pv_t value)
 {
   /* Remove any (potentially) overlapping entries.  */
   if (pv_area_store_would_trash (area, addr))
     clear_entries (area);
   else
     {
       CORE_ADDR offset = addr.k;
       struct area_entry *e = find_entry (area, offset);

       /* Delete all entries that we would overlap.  */
       while (e && overlaps (area, e, offset, size))
         {
           struct area_entry *next = (e->next == e) ? 0 : e->next;

           e->prev->next = e->next;
           e->next->prev = e->prev;

           xfree (e);
           e = next;
         }

       /* Move the area's pointer to the next remaining entry.  This
          will also zero the pointer if we've deleted all the entries.  */
       area->entry = e;
     }

   /* Now, there are no entries overlapping us, and area->entry is
      either zero or pointing at the closest entry after us.  We can
      just insert ourselves before that.

      But if we're storing an unknown value, don't bother --- that's
      the default.  */
   if (value.kind == pvk_unknown)
     return;
   else
     {
       CORE_ADDR offset = addr.k;
       struct area_entry *e = XNEW (struct area_entry);

       e->offset = offset;
       e->size = size;
       e->value = value;

       if (area->entry)
         {
           e->prev = area->entry->prev;
           e->next = area->entry;
           e->prev->next = e->next->prev = e;
         }
       else
         {
           e->prev = e->next = e;
           area->entry = e;
         }
     }
 }


 pv_t
 pv_area_fetch (struct pv_area *area, pv_t addr, CORE_ADDR size)
 {
   /* If we have no entries, or we can't decide how ADDR relates to the
      entries we do have, then the value is unknown.  */
   if (! area->entry
       || pv_area_store_would_trash (area, addr))
     return pv_unknown ();
   else
     {
       CORE_ADDR offset = addr.k;
       struct area_entry *e = find_entry (area, offset);

       /* If this entry exactly matches what we're looking for, then
          we're set.  Otherwise, say it's unknown.  */
       if (e->offset == offset && e->size == size)
         return e->value;
       else
         return pv_unknown ();
     }
 }


 int
 pv_area_find_reg (struct pv_area *area,
                   struct gdbarch *gdbarch,
                   int reg,
                   CORE_ADDR *offset_p)
 {
   struct area_entry *e = area->entry;

   if (e)
     do
       {
         if (e->value.kind == pvk_register
             && e->value.reg == reg
             && e->value.k == 0
             && e->size == register_size (gdbarch, reg))
           {
             if (offset_p)
               *offset_p = e->offset;
             return 1;
           }

         e = e->next;
       }
     while (e != area->entry);

   return 0;
 }


 void
 pv_area_scan (struct pv_area *area,
               void (*func) (void *closure,
                             pv_t addr,
                             CORE_ADDR size,
                             pv_t value),
               void *closure)
 {
   struct area_entry *e = area->entry;
   pv_t addr;

   addr.kind = pvk_register;
   addr.reg = area->base_reg;

   if (e)
     do
       {
         addr.k = e->offset;
         func (closure, addr, e->size, e->value);
         e = e->next;
       }
     while (e != area->entry);
 }
	/* Prologue value handling for GDB.
	Copyright (C) 2003-2016 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 "prologue-value.h"
	#include "regcache.h"


	/* Constructors. */

	pv_t
	pv_unknown (void)
	{
	pv_t v = { pvk_unknown, 0, 0 };

	return v;
	}


	pv_t
	pv_constant (CORE_ADDR k)
	{
	pv_t v;

	v.kind = pvk_constant;
	v.reg = -1; /* for debugging */
	v.k = k;

	return v;
	}


	pv_t
	pv_register (int reg, CORE_ADDR k)
	{
	pv_t v;

	v.kind = pvk_register;
	v.reg = reg;
	v.k = k;

	return v;
	}



	/* Arithmetic operations. */

	/* If one of A and B is a constant, and the other isn't, swap the
	values as necessary to ensure that *B is the constant. This can
	reduce the number of cases we need to analyze in the functions
	below. */
	static void
	constant_last (pv_t a, pv_t b)
	{
	if (a->kind == pvk_constant
	&& b->kind != pvk_constant)
	{
	pv_t temp = *a;
	a = b;
	*b = temp;
	}
	}


	pv_t
	pv_add (pv_t a, pv_t b)
	{
	constant_last (&a, &b);

	/* We can add a constant to a register. */
	if (a.kind == pvk_register
	&& b.kind == pvk_constant)
	return pv_register (a.reg, a.k + b.k);

	/* We can add a constant to another constant. */
	else if (a.kind == pvk_constant
	&& b.kind == pvk_constant)
	return pv_constant (a.k + b.k);

	/* Anything else we don't know how to add. We don't have a
	representation for, say, the sum of two registers, or a multiple
	of a register's value (adding a register to itself). */
	else
	return pv_unknown ();
	}


	pv_t
	pv_add_constant (pv_t v, CORE_ADDR k)
	{
	/* Rather than thinking of all the cases we can and can't handle,
	we'll just let pv_add take care of that for us. */
	return pv_add (v, pv_constant (k));
	}


	pv_t
	pv_subtract (pv_t a, pv_t b)
	{
	/* This isn't quite the same as negating B and adding it to A, since
	we don't have a representation for the negation of anything but a
	constant. For example, we can't negate { pvk_register, R1, 10 },
	but we do know that { pvk_register, R1, 10 } minus { pvk_register,
	R1, 5 } is { pvk_constant, <ignored>, 5 }.

	This means, for example, that we could subtract two stack
	addresses; they're both relative to the original SP. Since the
	frame pointer is set based on the SP, its value will be the
	original SP plus some constant (probably zero), so we can use its
	value just fine, too. */

	constant_last (&a, &b);

	/* We can subtract two constants. */
	if (a.kind == pvk_constant
	&& b.kind == pvk_constant)
	return pv_constant (a.k - b.k);

	/* We can subtract a constant from a register. */
	else if (a.kind == pvk_register
	&& b.kind == pvk_constant)
	return pv_register (a.reg, a.k - b.k);

	/* We can subtract a register from itself, yielding a constant. */
	else if (a.kind == pvk_register
	&& b.kind == pvk_register
	&& a.reg == b.reg)
	return pv_constant (a.k - b.k);

	/* We don't know how to subtract anything else. */
	else
	return pv_unknown ();
	}


	pv_t
	pv_logical_and (pv_t a, pv_t b)
	{
	constant_last (&a, &b);

	/* We can 'and' two constants. */
	if (a.kind == pvk_constant
	&& b.kind == pvk_constant)
	return pv_constant (a.k & b.k);

	/* We can 'and' anything with the constant zero. */
	else if (b.kind == pvk_constant
	&& b.k == 0)
	return pv_constant (0);

	/* We can 'and' anything with ~0. */
	else if (b.kind == pvk_constant
	&& b.k == ~ (CORE_ADDR) 0)
	return a;

	/* We can 'and' a register with itself. */
	else if (a.kind == pvk_register
	&& b.kind == pvk_register
	&& a.reg == b.reg
	&& a.k == b.k)
	return a;

	/* Otherwise, we don't know. */
	else
	return pv_unknown ();
	}



	/* Examining prologue values. */

	int
	pv_is_identical (pv_t a, pv_t b)
	{
	if (a.kind != b.kind)
	return 0;

	switch (a.kind)
	{
	case pvk_unknown:
	return 1;
	case pvk_constant:
	return (a.k == b.k);
	case pvk_register:
	return (a.reg == b.reg && a.k == b.k);
	default:
	gdb_assert_not_reached ("unexpected prologue value kind");
	}
	}


	int
	pv_is_constant (pv_t a)
	{
	return (a.kind == pvk_constant);
	}


	int
	pv_is_register (pv_t a, int r)
	{
	return (a.kind == pvk_register
	&& a.reg == r);
	}


	int
	pv_is_register_k (pv_t a, int r, CORE_ADDR k)
	{
	return (a.kind == pvk_register
	&& a.reg == r
	&& a.k == k);
	}


	enum pv_boolean
	pv_is_array_ref (pv_t addr, CORE_ADDR size,
	pv_t array_addr, CORE_ADDR array_len,
	CORE_ADDR elt_size,
	int *i)
	{
	/* Note that, since .k is a CORE_ADDR, and CORE_ADDR is unsigned, if
	addr is before the start of the array, then this isn't going to
	be negative... */
	pv_t offset = pv_subtract (addr, array_addr);

	if (offset.kind == pvk_constant)
	{
	/* This is a rather odd test. We want to know if the SIZE bytes
	at ADDR don't overlap the array at all, so you'd expect it to
	be an \|\| expression: "if we're completely before \|\| we're
	completely after". But with unsigned arithmetic, things are
	different: since it's a number circle, not a number line, the
	right values for offset.k are actually one contiguous range. */
	if (offset.k <= -size
	&& offset.k >= array_len * elt_size)
	return pv_definite_no;
	else if (offset.k % elt_size != 0
	\|\| size != elt_size)
	return pv_maybe;
	else
	{
	*i = offset.k / elt_size;
	return pv_definite_yes;
	}
	}
	else
	return pv_maybe;
	}



	/* Areas. */


	/* A particular value known to be stored in an area.

	Entries form a ring, sorted by unsigned offset from the area's base
	register's value. Since entries can straddle the wrap-around point,
	unsigned offsets form a circle, not a number line, so the list
	itself is structured the same way --- there is no inherent head.
	The entry with the lowest offset simply follows the entry with the
	highest offset. Entries may abut, but never overlap. The area's
	'entry' pointer points to an arbitrary node in the ring. */
	struct area_entry
	{
	/* Links in the doubly-linked ring. */
	struct area_entry prev, next;

	/* Offset of this entry's address from the value of the base
	register. */
	CORE_ADDR offset;

	/* The size of this entry. Note that an entry may wrap around from
	the end of the address space to the beginning. */
	CORE_ADDR size;

	/* The value stored here. */
	pv_t value;
	};


	struct pv_area
	{
	/* This area's base register. */
	int base_reg;

	/* The mask to apply to addresses, to make the wrap-around happen at
	the right place. */
	CORE_ADDR addr_mask;

	/* An element of the doubly-linked ring of entries, or zero if we
	have none. */
	struct area_entry *entry;
	};


	struct pv_area *
	make_pv_area (int base_reg, int addr_bit)
	{
	struct pv_area *a = XNEW (struct pv_area);

	memset (a, 0, sizeof (*a));

	a->base_reg = base_reg;
	a->entry = 0;

	/* Remember that shift amounts equal to the type's width are
	undefined. */
	a->addr_mask = ((((CORE_ADDR) 1 << (addr_bit - 1)) - 1) << 1) \| 1;

	return a;
	}


	/* Delete all entries from AREA. */
	static void
	clear_entries (struct pv_area *area)
	{
	struct area_entry *e = area->entry;

	if (e)
	{
	/* This needs to be a do-while loop, in order to actually
	process the node being checked for in the terminating
	condition. */
	do
	{
	struct area_entry *next = e->next;

	xfree (e);
	e = next;
	}
	while (e != area->entry);

	area->entry = 0;
	}
	}


	void
	free_pv_area (struct pv_area *area)
	{
	clear_entries (area);
	xfree (area);
	}


	static void
	do_free_pv_area_cleanup (void *arg)
	{
	free_pv_area ((struct pv_area *) arg);
	}


	struct cleanup *
	make_cleanup_free_pv_area (struct pv_area *area)
	{
	return make_cleanup (do_free_pv_area_cleanup, (void *) area);
	}


	int
	pv_area_store_would_trash (struct pv_area *area, pv_t addr)
	{
	/* It may seem odd that pvk_constant appears here --- after all,
	that's the case where we know the most about the address! But
	pv_areas are always relative to a register, and we don't know the
	value of the register, so we can't compare entry addresses to
	constants. */
	return (addr.kind == pvk_unknown
	\|\| addr.kind == pvk_constant
	\|\| (addr.kind == pvk_register && addr.reg != area->base_reg));
	}


	/* Return a pointer to the first entry we hit in AREA starting at
	OFFSET and going forward.

	This may return zero, if AREA has no entries.

	And since the entries are a ring, this may return an entry that
	entirely precedes OFFSET. This is the correct behavior: depending
	on the sizes involved, we could still overlap such an area, with
	wrap-around. */
	static struct area_entry *
	find_entry (struct pv_area *area, CORE_ADDR offset)
	{
	struct area_entry *e = area->entry;

	if (! e)
	return 0;

	/* If the next entry would be better than the current one, then scan
	forward. Since we use '<' in this loop, it always terminates.

	Note that, even setting aside the addr_mask stuff, we must not
	simplify this, in high school algebra fashion, to
	(e->next->offset < e->offset), because of the way < interacts
	with wrap-around. We have to subtract offset from both sides to
	make sure both things we're comparing are on the same side of the
	discontinuity. */
	while (((e->next->offset - offset) & area->addr_mask)
	< ((e->offset - offset) & area->addr_mask))
	e = e->next;

	/* If the previous entry would be better than the current one, then
	scan backwards. */
	while (((e->prev->offset - offset) & area->addr_mask)
	< ((e->offset - offset) & area->addr_mask))
	e = e->prev;

	/* In case there's some locality to the searches, set the area's
	pointer to the entry we've found. */
	area->entry = e;

	return e;
	}


	/* Return non-zero if the SIZE bytes at OFFSET would overlap ENTRY;
	return zero otherwise. AREA is the area to which ENTRY belongs. */
	static int
	overlaps (struct pv_area *area,
	struct area_entry *entry,
	CORE_ADDR offset,
	CORE_ADDR size)
	{
	/* Think carefully about wrap-around before simplifying this. */
	return (((entry->offset - offset) & area->addr_mask) < size
	\|\| ((offset - entry->offset) & area->addr_mask) < entry->size);
	}


	void
	pv_area_store (struct pv_area *area,
	pv_t addr,
	CORE_ADDR size,
	pv_t value)
	{
	/* Remove any (potentially) overlapping entries. */
	if (pv_area_store_would_trash (area, addr))
	clear_entries (area);
	else
	{
	CORE_ADDR offset = addr.k;
	struct area_entry *e = find_entry (area, offset);

	/* Delete all entries that we would overlap. */
	while (e && overlaps (area, e, offset, size))
	{
	struct area_entry *next = (e->next == e) ? 0 : e->next;

	e->prev->next = e->next;
	e->next->prev = e->prev;

	xfree (e);
	e = next;
	}

	/* Move the area's pointer to the next remaining entry. This
	will also zero the pointer if we've deleted all the entries. */
	area->entry = e;
	}

	/* Now, there are no entries overlapping us, and area->entry is
	either zero or pointing at the closest entry after us. We can
	just insert ourselves before that.

	But if we're storing an unknown value, don't bother --- that's
	the default. */
	if (value.kind == pvk_unknown)
	return;
	else
	{
	CORE_ADDR offset = addr.k;
	struct area_entry *e = XNEW (struct area_entry);

	e->offset = offset;
	e->size = size;
	e->value = value;

	if (area->entry)
	{
	e->prev = area->entry->prev;
	e->next = area->entry;
	e->prev->next = e->next->prev = e;
	}
	else
	{
	e->prev = e->next = e;
	area->entry = e;
	}
	}
	}


	pv_t
	pv_area_fetch (struct pv_area *area, pv_t addr, CORE_ADDR size)
	{
	/* If we have no entries, or we can't decide how ADDR relates to the
	entries we do have, then the value is unknown. */
	if (! area->entry
	\|\| pv_area_store_would_trash (area, addr))
	return pv_unknown ();
	else
	{
	CORE_ADDR offset = addr.k;
	struct area_entry *e = find_entry (area, offset);

	/* If this entry exactly matches what we're looking for, then
	we're set. Otherwise, say it's unknown. */
	if (e->offset == offset && e->size == size)
	return e->value;
	else
	return pv_unknown ();
	}
	}


	int
	pv_area_find_reg (struct pv_area *area,
	struct gdbarch *gdbarch,
	int reg,
	CORE_ADDR *offset_p)
	{
	struct area_entry *e = area->entry;

	if (e)
	do
	{
	if (e->value.kind == pvk_register
	&& e->value.reg == reg
	&& e->value.k == 0
	&& e->size == register_size (gdbarch, reg))
	{
	if (offset_p)
	*offset_p = e->offset;
	return 1;
	}

	e = e->next;
	}
	while (e != area->entry);

	return 0;
	}


	void
	pv_area_scan (struct pv_area *area,
	void (func) (void closure,
	pv_t addr,
	CORE_ADDR size,
	pv_t value),
	void *closure)
	{
	struct area_entry *e = area->entry;
	pv_t addr;

	addr.kind = pvk_register;
	addr.reg = area->base_reg;

	if (e)
	do
	{
	addr.k = e->offset;
	func (closure, addr, e->size, e->value);
	e = e->next;
	}
	while (e != area->entry);
	}