glib/tests/memchunks.c - nest-cam/4320010/glib - Git at Google

 /* GLIB - Library of useful routines for C programming
  * Copyright (C) 1995-1997  Peter Mattis, Spencer Kimball and Josh MacDonald
  *
  * This library is free software; you can redistribute it and/or
  * modify it under the terms of the GNU Lesser General Public
  * License as published by the Free Software Foundation; either
  * version 2 of the License, or (at your option) any later version.
  *
  * This library 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
  * Lesser General Public License for more details.
  *
  * You should have received a copy of the GNU Lesser General Public
  * License along with this library; if not, see <http://www.gnu.org/licenses/>.
  */

 /*
  * Modified by the GLib Team and others 1997-2000.  See the AUTHORS
  * file for a list of people on the GLib Team.  See the ChangeLog
  * files for a list of changes.  These files are distributed with
  * GLib at ftp://ftp.gtk.org/pub/gtk/.
  */

 /*
  * MT safe
  */

 #include "config.h"

 #include <stdlib.h>
 #include <string.h>
 #include <signal.h>

 #include "glib.h"

 /* notes on macros:
  * if ENABLE_GC_FRIENDLY is defined, freed memory should be 0-wiped.
  */

 #define MEM_PROFILE_TABLE_SIZE 4096

 #define MEM_AREA_SIZE 4L

 static guint mem_chunk_recursion = 0;
 #  define MEM_CHUNK_ROUTINE_COUNT()	(mem_chunk_recursion)
 #  define ENTER_MEM_CHUNK_ROUTINE()	(mem_chunk_recursion = MEM_CHUNK_ROUTINE_COUNT () + 1)
 #  define LEAVE_MEM_CHUNK_ROUTINE()	(mem_chunk_recursion = MEM_CHUNK_ROUTINE_COUNT () - 1)

 /* --- old memchunk prototypes --- */
 GMemChunk*      old_mem_chunk_new       (const gchar  *name,
                                          gint          atom_size,
                                          gulong        area_size,
                                          gint          type);
 void            old_mem_chunk_destroy   (GMemChunk *mem_chunk);
 gpointer        old_mem_chunk_alloc     (GMemChunk *mem_chunk);
 gpointer        old_mem_chunk_alloc0    (GMemChunk *mem_chunk);
 void            old_mem_chunk_free      (GMemChunk *mem_chunk,
                                          gpointer   mem);
 void            old_mem_chunk_clean     (GMemChunk *mem_chunk);
 void            old_mem_chunk_reset     (GMemChunk *mem_chunk);
 void            old_mem_chunk_print     (GMemChunk *mem_chunk);
 void            old_mem_chunk_info      (void);


 /* --- MemChunks --- */
 #ifndef G_ALLOC_AND_FREE
 typedef struct _GAllocator GAllocator;
 typedef struct _GMemChunk  GMemChunk;
 #define G_ALLOC_ONLY	  1
 #define G_ALLOC_AND_FREE  2
 #endif

 typedef struct _GFreeAtom      GFreeAtom;
 typedef struct _GMemArea       GMemArea;

 struct _GFreeAtom
 {
   GFreeAtom *next;
 };

 struct _GMemArea
 {
   GMemArea *next;            /* the next mem area */
   GMemArea *prev;            /* the previous mem area */
   gulong index;              /* the current index into the "mem" array */
   gulong free;               /* the number of free bytes in this mem area */
   gulong allocated;          /* the number of atoms allocated from this area */
   gulong mark;               /* is this mem area marked for deletion */
   gchar mem[MEM_AREA_SIZE];  /* the mem array from which atoms get allocated
 			      * the actual size of this array is determined by
 			      *  the mem chunk "area_size". ANSI says that it
 			      *  must be declared to be the maximum size it
 			      *  can possibly be (even though the actual size
 			      *  may be less).
 			      */
 };

 struct _GMemChunk
 {
   const gchar *name;         /* name of this MemChunk...used for debugging output */
   gint type;                 /* the type of MemChunk: ALLOC_ONLY or ALLOC_AND_FREE */
   gint num_mem_areas;        /* the number of memory areas */
   gint num_marked_areas;     /* the number of areas marked for deletion */
   guint atom_size;           /* the size of an atom */
   gulong area_size;          /* the size of a memory area */
   GMemArea *mem_area;        /* the current memory area */
   GMemArea *mem_areas;       /* a list of all the mem areas owned by this chunk */
   GMemArea *free_mem_area;   /* the free area...which is about to be destroyed */
   GFreeAtom *free_atoms;     /* the free atoms list */
   GTree *mem_tree;           /* tree of mem areas sorted by memory address */
   GMemChunk *next;           /* pointer to the next chunk */
   GMemChunk *prev;           /* pointer to the previous chunk */
 };


 static gulong old_mem_chunk_compute_size (gulong    size,
                                           gulong    min_size) G_GNUC_CONST;
 static gint   old_mem_chunk_area_compare (GMemArea *a,
                                           GMemArea *b);
 static gint   old_mem_chunk_area_search  (GMemArea *a,
                                           gchar    *addr);

 /* here we can't use StaticMutexes, as they depend upon a working
  * g_malloc, the same holds true for StaticPrivate
  */
 static GMutex         mem_chunks_lock;
 static GMemChunk     *mem_chunks = NULL;

 GMemChunk*
 old_mem_chunk_new (const gchar  *name,
                    gint          atom_size,
                    gulong        area_size,
                    gint          type)
 {
   GMemChunk *mem_chunk;
   gulong rarea_size;

   g_return_val_if_fail (atom_size > 0, NULL);
   g_return_val_if_fail (area_size >= atom_size, NULL);

   ENTER_MEM_CHUNK_ROUTINE ();

   area_size = (area_size + atom_size - 1) / atom_size;
   area_size *= atom_size;

   mem_chunk = g_new (GMemChunk, 1);
   mem_chunk->name = name;
   mem_chunk->type = type;
   mem_chunk->num_mem_areas = 0;
   mem_chunk->num_marked_areas = 0;
   mem_chunk->mem_area = NULL;
   mem_chunk->free_mem_area = NULL;
   mem_chunk->free_atoms = NULL;
   mem_chunk->mem_tree = NULL;
   mem_chunk->mem_areas = NULL;
   mem_chunk->atom_size = atom_size;

   if (mem_chunk->type == G_ALLOC_AND_FREE)
     mem_chunk->mem_tree = g_tree_new ((GCompareFunc) old_mem_chunk_area_compare);

   if (mem_chunk->atom_size % G_MEM_ALIGN)
     mem_chunk->atom_size += G_MEM_ALIGN - (mem_chunk->atom_size % G_MEM_ALIGN);

   rarea_size = area_size + sizeof (GMemArea) - MEM_AREA_SIZE;
   rarea_size = old_mem_chunk_compute_size (rarea_size, atom_size + sizeof (GMemArea) - MEM_AREA_SIZE);
   mem_chunk->area_size = rarea_size - (sizeof (GMemArea) - MEM_AREA_SIZE);

   g_mutex_lock (&mem_chunks_lock);
   mem_chunk->next = mem_chunks;
   mem_chunk->prev = NULL;
   if (mem_chunks)
     mem_chunks->prev = mem_chunk;
   mem_chunks = mem_chunk;
   g_mutex_unlock (&mem_chunks_lock);

   LEAVE_MEM_CHUNK_ROUTINE ();

   return mem_chunk;
 }

 void
 old_mem_chunk_destroy (GMemChunk *mem_chunk)
 {
   GMemArea *mem_areas;
   GMemArea *temp_area;

   g_return_if_fail (mem_chunk != NULL);

   ENTER_MEM_CHUNK_ROUTINE ();

   mem_areas = mem_chunk->mem_areas;
   while (mem_areas)
     {
       temp_area = mem_areas;
       mem_areas = mem_areas->next;
       g_free (temp_area);
     }

   g_mutex_lock (&mem_chunks_lock);
   if (mem_chunk->next)
     mem_chunk->next->prev = mem_chunk->prev;
   if (mem_chunk->prev)
     mem_chunk->prev->next = mem_chunk->next;

   if (mem_chunk == mem_chunks)
     mem_chunks = mem_chunks->next;
   g_mutex_unlock (&mem_chunks_lock);

   if (mem_chunk->type == G_ALLOC_AND_FREE)
     g_tree_destroy (mem_chunk->mem_tree);

   g_free (mem_chunk);

   LEAVE_MEM_CHUNK_ROUTINE ();
 }

 gpointer
 old_mem_chunk_alloc (GMemChunk *mem_chunk)
 {
   GMemArea *temp_area;
   gpointer mem;

   ENTER_MEM_CHUNK_ROUTINE ();

   g_return_val_if_fail (mem_chunk != NULL, NULL);

   while (mem_chunk->free_atoms)
     {
       /* Get the first piece of memory on the "free_atoms" list.
        * We can go ahead and destroy the list node we used to keep
        *  track of it with and to update the "free_atoms" list to
        *  point to its next element.
        */
       mem = mem_chunk->free_atoms;
       mem_chunk->free_atoms = mem_chunk->free_atoms->next;

       /* Determine which area this piece of memory is allocated from */
       temp_area = g_tree_search (mem_chunk->mem_tree,
 				 (GCompareFunc) old_mem_chunk_area_search,
 				 mem);

       /* If the area has been marked, then it is being destroyed.
        *  (ie marked to be destroyed).
        * We check to see if all of the segments on the free list that
        *  reference this area have been removed. This occurs when
        *  the amount of free memory is less than the allocatable size.
        * If the chunk should be freed, then we place it in the "free_mem_area".
        * This is so we make sure not to free the mem area here and then
        *  allocate it again a few lines down.
        * If we don't allocate a chunk a few lines down then the "free_mem_area"
        *  will be freed.
        * If there is already a "free_mem_area" then we'll just free this mem area.
        */
       if (temp_area->mark)
         {
           /* Update the "free" memory available in that area */
           temp_area->free += mem_chunk->atom_size;

           if (temp_area->free == mem_chunk->area_size)
             {
               if (temp_area == mem_chunk->mem_area)
                 mem_chunk->mem_area = NULL;

               if (mem_chunk->free_mem_area)
                 {
                   mem_chunk->num_mem_areas -= 1;

                   if (temp_area->next)
                     temp_area->next->prev = temp_area->prev;
                   if (temp_area->prev)
                     temp_area->prev->next = temp_area->next;
                   if (temp_area == mem_chunk->mem_areas)
                     mem_chunk->mem_areas = mem_chunk->mem_areas->next;

 		  if (mem_chunk->type == G_ALLOC_AND_FREE)
 		    g_tree_remove (mem_chunk->mem_tree, temp_area);
                   g_free (temp_area);
                 }
               else
                 mem_chunk->free_mem_area = temp_area;

 	      mem_chunk->num_marked_areas -= 1;
 	    }
 	}
       else
         {
           /* Update the number of allocated atoms count.
 	   */
           temp_area->allocated += 1;

           /* The area wasn't marked...return the memory
 	   */
 	  goto outa_here;
         }
     }

   /* If there isn't a current mem area or the current mem area is out of space
    *  then allocate a new mem area. We'll first check and see if we can use
    *  the "free_mem_area". Otherwise we'll just malloc the mem area.
    */
   if ((!mem_chunk->mem_area) ||
       ((mem_chunk->mem_area->index + mem_chunk->atom_size) > mem_chunk->area_size))
     {
       if (mem_chunk->free_mem_area)
         {
           mem_chunk->mem_area = mem_chunk->free_mem_area;
 	  mem_chunk->free_mem_area = NULL;
         }
       else
         {
 #ifdef ENABLE_GC_FRIENDLY
 	  mem_chunk->mem_area = (GMemArea*) g_malloc0 (sizeof (GMemArea) -
 						       MEM_AREA_SIZE +
 						       mem_chunk->area_size);
 #else /* !ENABLE_GC_FRIENDLY */
 	  mem_chunk->mem_area = (GMemArea*) g_malloc (sizeof (GMemArea) -
 						      MEM_AREA_SIZE +
 						      mem_chunk->area_size);
 #endif /* ENABLE_GC_FRIENDLY */

 	  mem_chunk->num_mem_areas += 1;
 	  mem_chunk->mem_area->next = mem_chunk->mem_areas;
 	  mem_chunk->mem_area->prev = NULL;

 	  if (mem_chunk->mem_areas)
 	    mem_chunk->mem_areas->prev = mem_chunk->mem_area;
 	  mem_chunk->mem_areas = mem_chunk->mem_area;

 	  if (mem_chunk->type == G_ALLOC_AND_FREE)
 	    g_tree_insert (mem_chunk->mem_tree, mem_chunk->mem_area, mem_chunk->mem_area);
         }

       mem_chunk->mem_area->index = 0;
       mem_chunk->mem_area->free = mem_chunk->area_size;
       mem_chunk->mem_area->allocated = 0;
       mem_chunk->mem_area->mark = 0;
     }

   /* Get the memory and modify the state variables appropriately.
    */
   mem = (gpointer) &mem_chunk->mem_area->mem[mem_chunk->mem_area->index];
   mem_chunk->mem_area->index += mem_chunk->atom_size;
   mem_chunk->mem_area->free -= mem_chunk->atom_size;
   mem_chunk->mem_area->allocated += 1;

  outa_here:

   LEAVE_MEM_CHUNK_ROUTINE ();

   return mem;
 }

 gpointer
 old_mem_chunk_alloc0 (GMemChunk *mem_chunk)
 {
   gpointer mem;

   mem = old_mem_chunk_alloc (mem_chunk);
   if (mem)
     {
       memset (mem, 0, mem_chunk->atom_size);
     }

   return mem;
 }

 void
 old_mem_chunk_free (GMemChunk *mem_chunk,
                     gpointer   mem)
 {
   GMemArea *temp_area;
   GFreeAtom *free_atom;

   g_return_if_fail (mem_chunk != NULL);
   g_return_if_fail (mem != NULL);

   ENTER_MEM_CHUNK_ROUTINE ();

 #ifdef ENABLE_GC_FRIENDLY
   memset (mem, 0, mem_chunk->atom_size);
 #endif /* ENABLE_GC_FRIENDLY */

   /* Don't do anything if this is an ALLOC_ONLY chunk
    */
   if (mem_chunk->type == G_ALLOC_AND_FREE)
     {
       /* Place the memory on the "free_atoms" list
        */
       free_atom = (GFreeAtom*) mem;
       free_atom->next = mem_chunk->free_atoms;
       mem_chunk->free_atoms = free_atom;

       temp_area = g_tree_search (mem_chunk->mem_tree,
 				 (GCompareFunc) old_mem_chunk_area_search,
 				 mem);

       temp_area->allocated -= 1;

       if (temp_area->allocated == 0)
 	{
 	  temp_area->mark = 1;
 	  mem_chunk->num_marked_areas += 1;
 	}
     }

   LEAVE_MEM_CHUNK_ROUTINE ();
 }

 /* This doesn't free the free_area if there is one */
 void
 old_mem_chunk_clean (GMemChunk *mem_chunk)
 {
   GMemArea *mem_area;
   GFreeAtom *prev_free_atom;
   GFreeAtom *temp_free_atom;
   gpointer mem;

   g_return_if_fail (mem_chunk != NULL);

   ENTER_MEM_CHUNK_ROUTINE ();

   if (mem_chunk->type == G_ALLOC_AND_FREE)
     {
       prev_free_atom = NULL;
       temp_free_atom = mem_chunk->free_atoms;

       while (temp_free_atom)
 	{
 	  mem = (gpointer) temp_free_atom;

 	  mem_area = g_tree_search (mem_chunk->mem_tree,
 				    (GCompareFunc) old_mem_chunk_area_search,
 				    mem);

           /* If this mem area is marked for destruction then delete the
 	   *  area and list node and decrement the free mem.
            */
 	  if (mem_area->mark)
 	    {
 	      if (prev_free_atom)
 		prev_free_atom->next = temp_free_atom->next;
 	      else
 		mem_chunk->free_atoms = temp_free_atom->next;
 	      temp_free_atom = temp_free_atom->next;

 	      mem_area->free += mem_chunk->atom_size;
 	      if (mem_area->free == mem_chunk->area_size)
 		{
 		  mem_chunk->num_mem_areas -= 1;
 		  mem_chunk->num_marked_areas -= 1;

 		  if (mem_area->next)
 		    mem_area->next->prev = mem_area->prev;
 		  if (mem_area->prev)
 		    mem_area->prev->next = mem_area->next;
 		  if (mem_area == mem_chunk->mem_areas)
 		    mem_chunk->mem_areas = mem_chunk->mem_areas->next;
 		  if (mem_area == mem_chunk->mem_area)
 		    mem_chunk->mem_area = NULL;

 		  if (mem_chunk->type == G_ALLOC_AND_FREE)
 		    g_tree_remove (mem_chunk->mem_tree, mem_area);
 		  g_free (mem_area);
 		}
 	    }
 	  else
 	    {
 	      prev_free_atom = temp_free_atom;
 	      temp_free_atom = temp_free_atom->next;
 	    }
 	}
     }
   LEAVE_MEM_CHUNK_ROUTINE ();
 }

 void
 old_mem_chunk_reset (GMemChunk *mem_chunk)
 {
   GMemArea *mem_areas;
   GMemArea *temp_area;

   g_return_if_fail (mem_chunk != NULL);

   ENTER_MEM_CHUNK_ROUTINE ();

   mem_areas = mem_chunk->mem_areas;
   mem_chunk->num_mem_areas = 0;
   mem_chunk->mem_areas = NULL;
   mem_chunk->mem_area = NULL;

   while (mem_areas)
     {
       temp_area = mem_areas;
       mem_areas = mem_areas->next;
       g_free (temp_area);
     }

   mem_chunk->free_atoms = NULL;

   if (mem_chunk->mem_tree)
     {
       g_tree_destroy (mem_chunk->mem_tree);
       mem_chunk->mem_tree = g_tree_new ((GCompareFunc) old_mem_chunk_area_compare);
     }

   LEAVE_MEM_CHUNK_ROUTINE ();
 }

 void
 old_mem_chunk_print (GMemChunk *mem_chunk)
 {
   GMemArea *mem_areas;
   gulong mem;

   g_return_if_fail (mem_chunk != NULL);

   mem_areas = mem_chunk->mem_areas;
   mem = 0;

   while (mem_areas)
     {
       mem += mem_chunk->area_size - mem_areas->free;
       mem_areas = mem_areas->next;
     }

   g_log (G_LOG_DOMAIN, G_LOG_LEVEL_INFO,
 	 "%s: %ld bytes using %d mem areas",
 	 mem_chunk->name, mem, mem_chunk->num_mem_areas);
 }

 void
 old_mem_chunk_info (void)
 {
   GMemChunk *mem_chunk;
   gint count;

   count = 0;
   g_mutex_lock (&mem_chunks_lock);
   mem_chunk = mem_chunks;
   while (mem_chunk)
     {
       count += 1;
       mem_chunk = mem_chunk->next;
     }
   g_mutex_unlock (&mem_chunks_lock);

   g_log (G_LOG_DOMAIN, G_LOG_LEVEL_INFO, "%d mem chunks", count);

   g_mutex_lock (&mem_chunks_lock);
   mem_chunk = mem_chunks;
   g_mutex_unlock (&mem_chunks_lock);

   while (mem_chunk)
     {
       old_mem_chunk_print ((GMemChunk*) mem_chunk);
       mem_chunk = mem_chunk->next;
     }
 }

 static gulong
 old_mem_chunk_compute_size (gulong size,
                             gulong min_size)
 {
   gulong power_of_2;
   gulong lower, upper;

   power_of_2 = 16;
   while (power_of_2 < size)
     power_of_2 <<= 1;

   lower = power_of_2 >> 1;
   upper = power_of_2;

   if (size - lower < upper - size && lower >= min_size)
     return lower;
   else
     return upper;
 }

 static gint
 old_mem_chunk_area_compare (GMemArea *a,
                             GMemArea *b)
 {
   if (a->mem > b->mem)
     return 1;
   else if (a->mem < b->mem)
     return -1;
   return 0;
 }

 static gint
 old_mem_chunk_area_search (GMemArea *a,
                            gchar    *addr)
 {
   if (a->mem <= addr)
     {
       if (addr < &a->mem[a->index])
 	return 0;
       return 1;
     }
   return -1;
 }
	/* GLIB - Library of useful routines for C programming
	* Copyright (C) 1995-1997 Peter Mattis, Spencer Kimball and Josh MacDonald
	*
	* This library is free software; you can redistribute it and/or
	* modify it under the terms of the GNU Lesser General Public
	* License as published by the Free Software Foundation; either
	* version 2 of the License, or (at your option) any later version.
	*
	* This library 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
	* Lesser General Public License for more details.
	*
	* You should have received a copy of the GNU Lesser General Public
	* License along with this library; if not, see <http://www.gnu.org/licenses/>.
	*/

	/*
	* Modified by the GLib Team and others 1997-2000. See the AUTHORS
	* file for a list of people on the GLib Team. See the ChangeLog
	* files for a list of changes. These files are distributed with
	* GLib at ftp://ftp.gtk.org/pub/gtk/.
	*/

	/*
	* MT safe
	*/

	#include "config.h"

	#include <stdlib.h>
	#include <string.h>
	#include <signal.h>

	#include "glib.h"

	/* notes on macros:
	* if ENABLE_GC_FRIENDLY is defined, freed memory should be 0-wiped.
	*/

	#define MEM_PROFILE_TABLE_SIZE 4096

	#define MEM_AREA_SIZE 4L

	static guint mem_chunk_recursion = 0;
	# define MEM_CHUNK_ROUTINE_COUNT() (mem_chunk_recursion)
	# define ENTER_MEM_CHUNK_ROUTINE() (mem_chunk_recursion = MEM_CHUNK_ROUTINE_COUNT () + 1)
	# define LEAVE_MEM_CHUNK_ROUTINE() (mem_chunk_recursion = MEM_CHUNK_ROUTINE_COUNT () - 1)

	/* --- old memchunk prototypes --- */
	GMemChunk* old_mem_chunk_new (const gchar *name,
	gint atom_size,
	gulong area_size,
	gint type);
	void old_mem_chunk_destroy (GMemChunk *mem_chunk);
	gpointer old_mem_chunk_alloc (GMemChunk *mem_chunk);
	gpointer old_mem_chunk_alloc0 (GMemChunk *mem_chunk);
	void old_mem_chunk_free (GMemChunk *mem_chunk,
	gpointer mem);
	void old_mem_chunk_clean (GMemChunk *mem_chunk);
	void old_mem_chunk_reset (GMemChunk *mem_chunk);
	void old_mem_chunk_print (GMemChunk *mem_chunk);
	void old_mem_chunk_info (void);


	/* --- MemChunks --- */
	#ifndef G_ALLOC_AND_FREE
	typedef struct _GAllocator GAllocator;
	typedef struct _GMemChunk GMemChunk;
	#define G_ALLOC_ONLY 1
	#define G_ALLOC_AND_FREE 2
	#endif

	typedef struct _GFreeAtom GFreeAtom;
	typedef struct _GMemArea GMemArea;

	struct _GFreeAtom
	{
	GFreeAtom *next;
	};

	struct _GMemArea
	{
	GMemArea next; / the next mem area */
	GMemArea prev; / the previous mem area */
	gulong index; /* the current index into the "mem" array */
	gulong free; /* the number of free bytes in this mem area */
	gulong allocated; /* the number of atoms allocated from this area */
	gulong mark; /* is this mem area marked for deletion */
	gchar mem[MEM_AREA_SIZE]; /* the mem array from which atoms get allocated
	* the actual size of this array is determined by
	* the mem chunk "area_size". ANSI says that it
	* must be declared to be the maximum size it
	* can possibly be (even though the actual size
	* may be less).
	*/
	};

	struct _GMemChunk
	{
	const gchar name; / name of this MemChunk...used for debugging output */
	gint type; /* the type of MemChunk: ALLOC_ONLY or ALLOC_AND_FREE */
	gint num_mem_areas; /* the number of memory areas */
	gint num_marked_areas; /* the number of areas marked for deletion */
	guint atom_size; /* the size of an atom */
	gulong area_size; /* the size of a memory area */
	GMemArea mem_area; / the current memory area */
	GMemArea mem_areas; / a list of all the mem areas owned by this chunk */
	GMemArea free_mem_area; / the free area...which is about to be destroyed */
	GFreeAtom free_atoms; / the free atoms list */
	GTree mem_tree; / tree of mem areas sorted by memory address */
	GMemChunk next; / pointer to the next chunk */
	GMemChunk prev; / pointer to the previous chunk */
	};


	static gulong old_mem_chunk_compute_size (gulong size,
	gulong min_size) G_GNUC_CONST;
	static gint old_mem_chunk_area_compare (GMemArea *a,
	GMemArea *b);
	static gint old_mem_chunk_area_search (GMemArea *a,
	gchar *addr);

	/* here we can't use StaticMutexes, as they depend upon a working
	* g_malloc, the same holds true for StaticPrivate
	*/
	static GMutex mem_chunks_lock;
	static GMemChunk *mem_chunks = NULL;

	GMemChunk*
	old_mem_chunk_new (const gchar *name,
	gint atom_size,
	gulong area_size,
	gint type)
	{
	GMemChunk *mem_chunk;
	gulong rarea_size;

	g_return_val_if_fail (atom_size > 0, NULL);
	g_return_val_if_fail (area_size >= atom_size, NULL);

	ENTER_MEM_CHUNK_ROUTINE ();

	area_size = (area_size + atom_size - 1) / atom_size;
	area_size *= atom_size;

	mem_chunk = g_new (GMemChunk, 1);
	mem_chunk->name = name;
	mem_chunk->type = type;
	mem_chunk->num_mem_areas = 0;
	mem_chunk->num_marked_areas = 0;
	mem_chunk->mem_area = NULL;
	mem_chunk->free_mem_area = NULL;
	mem_chunk->free_atoms = NULL;
	mem_chunk->mem_tree = NULL;
	mem_chunk->mem_areas = NULL;
	mem_chunk->atom_size = atom_size;

	if (mem_chunk->type == G_ALLOC_AND_FREE)
	mem_chunk->mem_tree = g_tree_new ((GCompareFunc) old_mem_chunk_area_compare);

	if (mem_chunk->atom_size % G_MEM_ALIGN)
	mem_chunk->atom_size += G_MEM_ALIGN - (mem_chunk->atom_size % G_MEM_ALIGN);

	rarea_size = area_size + sizeof (GMemArea) - MEM_AREA_SIZE;
	rarea_size = old_mem_chunk_compute_size (rarea_size, atom_size + sizeof (GMemArea) - MEM_AREA_SIZE);
	mem_chunk->area_size = rarea_size - (sizeof (GMemArea) - MEM_AREA_SIZE);

	g_mutex_lock (&mem_chunks_lock);
	mem_chunk->next = mem_chunks;
	mem_chunk->prev = NULL;
	if (mem_chunks)
	mem_chunks->prev = mem_chunk;
	mem_chunks = mem_chunk;
	g_mutex_unlock (&mem_chunks_lock);

	LEAVE_MEM_CHUNK_ROUTINE ();

	return mem_chunk;
	}

	void
	old_mem_chunk_destroy (GMemChunk *mem_chunk)
	{
	GMemArea *mem_areas;
	GMemArea *temp_area;

	g_return_if_fail (mem_chunk != NULL);

	ENTER_MEM_CHUNK_ROUTINE ();

	mem_areas = mem_chunk->mem_areas;
	while (mem_areas)
	{
	temp_area = mem_areas;
	mem_areas = mem_areas->next;
	g_free (temp_area);
	}

	g_mutex_lock (&mem_chunks_lock);
	if (mem_chunk->next)
	mem_chunk->next->prev = mem_chunk->prev;
	if (mem_chunk->prev)
	mem_chunk->prev->next = mem_chunk->next;

	if (mem_chunk == mem_chunks)
	mem_chunks = mem_chunks->next;
	g_mutex_unlock (&mem_chunks_lock);

	if (mem_chunk->type == G_ALLOC_AND_FREE)
	g_tree_destroy (mem_chunk->mem_tree);

	g_free (mem_chunk);

	LEAVE_MEM_CHUNK_ROUTINE ();
	}

	gpointer
	old_mem_chunk_alloc (GMemChunk *mem_chunk)
	{
	GMemArea *temp_area;
	gpointer mem;

	ENTER_MEM_CHUNK_ROUTINE ();

	g_return_val_if_fail (mem_chunk != NULL, NULL);

	while (mem_chunk->free_atoms)
	{
	/* Get the first piece of memory on the "free_atoms" list.
	* We can go ahead and destroy the list node we used to keep
	* track of it with and to update the "free_atoms" list to
	* point to its next element.
	*/
	mem = mem_chunk->free_atoms;
	mem_chunk->free_atoms = mem_chunk->free_atoms->next;

	/* Determine which area this piece of memory is allocated from */
	temp_area = g_tree_search (mem_chunk->mem_tree,
	(GCompareFunc) old_mem_chunk_area_search,
	mem);

	/* If the area has been marked, then it is being destroyed.
	* (ie marked to be destroyed).
	* We check to see if all of the segments on the free list that
	* reference this area have been removed. This occurs when
	* the amount of free memory is less than the allocatable size.
	* If the chunk should be freed, then we place it in the "free_mem_area".
	* This is so we make sure not to free the mem area here and then
	* allocate it again a few lines down.
	* If we don't allocate a chunk a few lines down then the "free_mem_area"
	* will be freed.
	* If there is already a "free_mem_area" then we'll just free this mem area.
	*/
	if (temp_area->mark)
	{
	/* Update the "free" memory available in that area */
	temp_area->free += mem_chunk->atom_size;

	if (temp_area->free == mem_chunk->area_size)
	{
	if (temp_area == mem_chunk->mem_area)
	mem_chunk->mem_area = NULL;

	if (mem_chunk->free_mem_area)
	{
	mem_chunk->num_mem_areas -= 1;

	if (temp_area->next)
	temp_area->next->prev = temp_area->prev;
	if (temp_area->prev)
	temp_area->prev->next = temp_area->next;
	if (temp_area == mem_chunk->mem_areas)
	mem_chunk->mem_areas = mem_chunk->mem_areas->next;

	if (mem_chunk->type == G_ALLOC_AND_FREE)
	g_tree_remove (mem_chunk->mem_tree, temp_area);
	g_free (temp_area);
	}
	else
	mem_chunk->free_mem_area = temp_area;

	mem_chunk->num_marked_areas -= 1;
	}
	}
	else
	{
	/* Update the number of allocated atoms count.
	*/
	temp_area->allocated += 1;

	/* The area wasn't marked...return the memory
	*/
	goto outa_here;
	}
	}

	/* If there isn't a current mem area or the current mem area is out of space
	* then allocate a new mem area. We'll first check and see if we can use
	* the "free_mem_area". Otherwise we'll just malloc the mem area.
	*/
	if ((!mem_chunk->mem_area) \|\|
	((mem_chunk->mem_area->index + mem_chunk->atom_size) > mem_chunk->area_size))
	{
	if (mem_chunk->free_mem_area)
	{
	mem_chunk->mem_area = mem_chunk->free_mem_area;
	mem_chunk->free_mem_area = NULL;
	}
	else
	{
	#ifdef ENABLE_GC_FRIENDLY
	mem_chunk->mem_area = (GMemArea*) g_malloc0 (sizeof (GMemArea) -
	MEM_AREA_SIZE +
	mem_chunk->area_size);
	#else /* !ENABLE_GC_FRIENDLY */
	mem_chunk->mem_area = (GMemArea*) g_malloc (sizeof (GMemArea) -
	MEM_AREA_SIZE +
	mem_chunk->area_size);
	#endif /* ENABLE_GC_FRIENDLY */

	mem_chunk->num_mem_areas += 1;
	mem_chunk->mem_area->next = mem_chunk->mem_areas;
	mem_chunk->mem_area->prev = NULL;

	if (mem_chunk->mem_areas)
	mem_chunk->mem_areas->prev = mem_chunk->mem_area;
	mem_chunk->mem_areas = mem_chunk->mem_area;

	if (mem_chunk->type == G_ALLOC_AND_FREE)
	g_tree_insert (mem_chunk->mem_tree, mem_chunk->mem_area, mem_chunk->mem_area);
	}

	mem_chunk->mem_area->index = 0;
	mem_chunk->mem_area->free = mem_chunk->area_size;
	mem_chunk->mem_area->allocated = 0;
	mem_chunk->mem_area->mark = 0;
	}

	/* Get the memory and modify the state variables appropriately.
	*/
	mem = (gpointer) &mem_chunk->mem_area->mem[mem_chunk->mem_area->index];
	mem_chunk->mem_area->index += mem_chunk->atom_size;
	mem_chunk->mem_area->free -= mem_chunk->atom_size;
	mem_chunk->mem_area->allocated += 1;

	outa_here:

	LEAVE_MEM_CHUNK_ROUTINE ();

	return mem;
	}

	gpointer
	old_mem_chunk_alloc0 (GMemChunk *mem_chunk)
	{
	gpointer mem;

	mem = old_mem_chunk_alloc (mem_chunk);
	if (mem)
	{
	memset (mem, 0, mem_chunk->atom_size);
	}

	return mem;
	}

	void
	old_mem_chunk_free (GMemChunk *mem_chunk,
	gpointer mem)
	{
	GMemArea *temp_area;
	GFreeAtom *free_atom;

	g_return_if_fail (mem_chunk != NULL);
	g_return_if_fail (mem != NULL);

	ENTER_MEM_CHUNK_ROUTINE ();

	#ifdef ENABLE_GC_FRIENDLY
	memset (mem, 0, mem_chunk->atom_size);
	#endif /* ENABLE_GC_FRIENDLY */

	/* Don't do anything if this is an ALLOC_ONLY chunk
	*/
	if (mem_chunk->type == G_ALLOC_AND_FREE)
	{
	/* Place the memory on the "free_atoms" list
	*/
	free_atom = (GFreeAtom*) mem;
	free_atom->next = mem_chunk->free_atoms;
	mem_chunk->free_atoms = free_atom;

	temp_area = g_tree_search (mem_chunk->mem_tree,
	(GCompareFunc) old_mem_chunk_area_search,
	mem);

	temp_area->allocated -= 1;

	if (temp_area->allocated == 0)
	{
	temp_area->mark = 1;
	mem_chunk->num_marked_areas += 1;
	}
	}

	LEAVE_MEM_CHUNK_ROUTINE ();
	}

	/* This doesn't free the free_area if there is one */
	void
	old_mem_chunk_clean (GMemChunk *mem_chunk)
	{
	GMemArea *mem_area;
	GFreeAtom *prev_free_atom;
	GFreeAtom *temp_free_atom;
	gpointer mem;

	g_return_if_fail (mem_chunk != NULL);

	ENTER_MEM_CHUNK_ROUTINE ();

	if (mem_chunk->type == G_ALLOC_AND_FREE)
	{
	prev_free_atom = NULL;
	temp_free_atom = mem_chunk->free_atoms;

	while (temp_free_atom)
	{
	mem = (gpointer) temp_free_atom;

	mem_area = g_tree_search (mem_chunk->mem_tree,
	(GCompareFunc) old_mem_chunk_area_search,
	mem);

	/* If this mem area is marked for destruction then delete the
	* area and list node and decrement the free mem.
	*/
	if (mem_area->mark)
	{
	if (prev_free_atom)
	prev_free_atom->next = temp_free_atom->next;
	else
	mem_chunk->free_atoms = temp_free_atom->next;
	temp_free_atom = temp_free_atom->next;

	mem_area->free += mem_chunk->atom_size;
	if (mem_area->free == mem_chunk->area_size)
	{
	mem_chunk->num_mem_areas -= 1;
	mem_chunk->num_marked_areas -= 1;

	if (mem_area->next)
	mem_area->next->prev = mem_area->prev;
	if (mem_area->prev)
	mem_area->prev->next = mem_area->next;
	if (mem_area == mem_chunk->mem_areas)
	mem_chunk->mem_areas = mem_chunk->mem_areas->next;
	if (mem_area == mem_chunk->mem_area)
	mem_chunk->mem_area = NULL;

	if (mem_chunk->type == G_ALLOC_AND_FREE)
	g_tree_remove (mem_chunk->mem_tree, mem_area);
	g_free (mem_area);
	}
	}
	else
	{
	prev_free_atom = temp_free_atom;
	temp_free_atom = temp_free_atom->next;
	}
	}
	}
	LEAVE_MEM_CHUNK_ROUTINE ();
	}

	void
	old_mem_chunk_reset (GMemChunk *mem_chunk)
	{
	GMemArea *mem_areas;
	GMemArea *temp_area;

	g_return_if_fail (mem_chunk != NULL);

	ENTER_MEM_CHUNK_ROUTINE ();

	mem_areas = mem_chunk->mem_areas;
	mem_chunk->num_mem_areas = 0;
	mem_chunk->mem_areas = NULL;
	mem_chunk->mem_area = NULL;

	while (mem_areas)
	{
	temp_area = mem_areas;
	mem_areas = mem_areas->next;
	g_free (temp_area);
	}

	mem_chunk->free_atoms = NULL;

	if (mem_chunk->mem_tree)
	{
	g_tree_destroy (mem_chunk->mem_tree);
	mem_chunk->mem_tree = g_tree_new ((GCompareFunc) old_mem_chunk_area_compare);
	}

	LEAVE_MEM_CHUNK_ROUTINE ();
	}

	void
	old_mem_chunk_print (GMemChunk *mem_chunk)
	{
	GMemArea *mem_areas;
	gulong mem;

	g_return_if_fail (mem_chunk != NULL);

	mem_areas = mem_chunk->mem_areas;
	mem = 0;

	while (mem_areas)
	{
	mem += mem_chunk->area_size - mem_areas->free;
	mem_areas = mem_areas->next;
	}

	g_log (G_LOG_DOMAIN, G_LOG_LEVEL_INFO,
	"%s: %ld bytes using %d mem areas",
	mem_chunk->name, mem, mem_chunk->num_mem_areas);
	}

	void
	old_mem_chunk_info (void)
	{
	GMemChunk *mem_chunk;
	gint count;

	count = 0;
	g_mutex_lock (&mem_chunks_lock);
	mem_chunk = mem_chunks;
	while (mem_chunk)
	{
	count += 1;
	mem_chunk = mem_chunk->next;
	}
	g_mutex_unlock (&mem_chunks_lock);

	g_log (G_LOG_DOMAIN, G_LOG_LEVEL_INFO, "%d mem chunks", count);

	g_mutex_lock (&mem_chunks_lock);
	mem_chunk = mem_chunks;
	g_mutex_unlock (&mem_chunks_lock);

	while (mem_chunk)
	{
	old_mem_chunk_print ((GMemChunk*) mem_chunk);
	mem_chunk = mem_chunk->next;
	}
	}

	static gulong
	old_mem_chunk_compute_size (gulong size,
	gulong min_size)
	{
	gulong power_of_2;
	gulong lower, upper;

	power_of_2 = 16;
	while (power_of_2 < size)
	power_of_2 <<= 1;

	lower = power_of_2 >> 1;
	upper = power_of_2;

	if (size - lower < upper - size && lower >= min_size)
	return lower;
	else
	return upper;
	}

	static gint
	old_mem_chunk_area_compare (GMemArea *a,
	GMemArea *b)
	{
	if (a->mem > b->mem)
	return 1;
	else if (a->mem < b->mem)
	return -1;
	return 0;
	}

	static gint
	old_mem_chunk_area_search (GMemArea *a,
	gchar *addr)
	{
	if (a->mem <= addr)
	{
	if (addr < &a->mem[a->index])
	return 0;
	return 1;
	}
	return -1;
	}