android/qemu/memcheck/memcheck_mmrange_map.c - emulator-unstable-refactoring - Git at Google

 /* Copyright (C) 2007-2010 The Android Open Source Project
 **
 ** This software is licensed under the terms of the GNU General Public
 ** License version 2, as published by the Free Software Foundation, and
 ** may be copied, distributed, and modified under those terms.
 **
 ** 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.
 */

 /*
  * Contains implementation of routines that implement a red-black tree of
  * memory mappings in the guest system.
  */

 #include "android/qemu/memcheck/memcheck_mmrange_map.h"
 #include "android/qemu/memcheck/memcheck_logging.h"

 /* Memory range descriptor stored in the map. */
 typedef struct MMRangeMapEntry {
     /* R-B tree entry. */
     RB_ENTRY(MMRangeMapEntry)   rb_entry;

     /* Memory range descriptor for this entry. */
     MMRangeDesc                 desc;
 } MMRangeMapEntry;

 // =============================================================================
 // R-B Tree implementation
 // =============================================================================

 /* Compare routine for the map.
  * Param:
  *  d1 - First map entry to compare.
  *  d2 - Second map entry to compare.
  * Return:
  *  0 - Descriptors are equal. Note that descriptors are considered to be
  *      equal iff memory blocks they describe intersect in any part.
  *  1 - d1 is greater than d2
  *  -1 - d1 is less than d2.
  */
 static inline int
 cmp_rb(MMRangeMapEntry* d1, MMRangeMapEntry* d2)
 {
     const target_ulong start1 = d1->desc.map_start;
     const target_ulong start2 = d2->desc.map_start;

     if (start1 < start2) {
         return (d1->desc.map_end - 1) < start2 ? -1 : 0;
     }
     return (d2->desc.map_end - 1) < start1 ? 1 : 0;
 }

 /* Expands RB macros here. */
 RB_GENERATE(MMRangeMap, MMRangeMapEntry, rb_entry, cmp_rb);

 // =============================================================================
 // Static routines
 // =============================================================================

 /* Inserts new (or replaces existing) entry into the map.
  * See comments on mmrangemap_insert routine in the header file for details
  * about this routine.
  */
 static RBTMapResult
 mmrangemap_insert_desc(MMRangeMap* map,
                        MMRangeMapEntry* rdesc,
                        MMRangeDesc* replaced)
 {
     MMRangeMapEntry* existing = MMRangeMap_RB_INSERT(map, rdesc);
     if (existing == NULL) {
         return RBT_MAP_RESULT_ENTRY_INSERTED;
     }

     // Matching entry exists. Lets see if we need to replace it.
     if (replaced == NULL) {
         return RBT_MAP_RESULT_ENTRY_ALREADY_EXISTS;
     }

     /* Copy existing entry to the provided buffer and replace it
      * with the new one. */
     memcpy(replaced, &existing->desc, sizeof(MMRangeDesc));
     MMRangeMap_RB_REMOVE(map, existing);
     g_free(existing);
     MMRangeMap_RB_INSERT(map, rdesc);
     return RBT_MAP_RESULT_ENTRY_REPLACED;
 }

 /* Finds an entry in the map that matches the given address range.
  * Param:
  *  map - Map where to search for an entry.
  *  start - Starting address of a mapping range.
  *  end - Ending address of a mapping range.
  * Return:
  *  Address of a map entry that matches the given range, or NULL if no
  *  such entry has been found.
  */
 static inline MMRangeMapEntry*
 mmrangemap_find_entry(const MMRangeMap* map,
                       target_ulong start,
                       target_ulong end)
 {
     MMRangeMapEntry rdesc;
     rdesc.desc.map_start = start;
     rdesc.desc.map_end = end;
     return MMRangeMap_RB_FIND((MMRangeMap*)map, &rdesc);
 }

 // =============================================================================
 // Map API
 // =============================================================================

 void
 mmrangemap_init(MMRangeMap* map)
 {
     RB_INIT(map);
 }

 RBTMapResult
 mmrangemap_insert(MMRangeMap* map,
                   const MMRangeDesc* desc,
                   MMRangeDesc* replaced)
 {
     RBTMapResult ret;

     // Allocate and initialize new map entry.
     MMRangeMapEntry* rdesc = g_malloc(sizeof(MMRangeMapEntry));
     if (rdesc == NULL) {
         ME("memcheck: Unable to allocate new MMRangeMapEntry on insert.");
         return RBT_MAP_RESULT_ERROR;
     }
     memcpy(&rdesc->desc, desc, sizeof(MMRangeDesc));

     // Insert new entry into the map.
     ret = mmrangemap_insert_desc(map, rdesc, replaced);
     if (ret == RBT_MAP_RESULT_ENTRY_ALREADY_EXISTS ||
         ret == RBT_MAP_RESULT_ERROR) {
         /* Another descriptor already exists for this block, or an error
          * occurred. We have to free new descriptor, as it wasn't inserted. */
         g_free(rdesc);
     }
     return ret;
 }

 MMRangeDesc*
 mmrangemap_find(const MMRangeMap* map, target_ulong start, target_ulong end)
 {
     MMRangeMapEntry* rdesc = mmrangemap_find_entry(map, start, end);
     return rdesc != NULL ? &rdesc->desc : NULL;
 }

 int
 mmrangemap_pull(MMRangeMap* map,
                 target_ulong start,
                 target_ulong end,
                 MMRangeDesc* pulled)
 {
     MMRangeMapEntry* rdesc = mmrangemap_find_entry(map, start, end);
     if (rdesc != NULL) {
         memcpy(pulled, &rdesc->desc, sizeof(MMRangeDesc));
         MMRangeMap_RB_REMOVE(map, rdesc);
         g_free(rdesc);
         return 0;
     } else {
         return -1;
     }
 }

 int
 mmrangemap_pull_first(MMRangeMap* map, MMRangeDesc* pulled)
 {
     MMRangeMapEntry* first = RB_MIN(MMRangeMap, map);
     if (first != NULL) {
         memcpy(pulled, &first->desc, sizeof(MMRangeDesc));
         MMRangeMap_RB_REMOVE(map, first);
         g_free(first);
         return 0;
     } else {
         return -1;
     }
 }

 int
 mmrangemap_copy(MMRangeMap* to, const MMRangeMap* from)
 {
     MMRangeMapEntry* entry;
     RB_FOREACH(entry, MMRangeMap, (MMRangeMap*)from) {
         RBTMapResult ins_res;
         MMRangeMapEntry* new_entry =
                 (MMRangeMapEntry*)g_malloc(sizeof(MMRangeMapEntry));
         if (new_entry == NULL) {
             ME("memcheck: Unable to allocate new MMRangeMapEntry on copy.");
             return -1;
         }
         memcpy(new_entry, entry, sizeof(MMRangeMapEntry));
         new_entry->desc.path = g_malloc(strlen(entry->desc.path) + 1);
         if (new_entry->desc.path == NULL) {
             ME("memcheck: Unable to allocate new path for MMRangeMapEntry on copy.");
             g_free(new_entry);
             return -1;
         }
         strcpy(new_entry->desc.path, entry->desc.path);
         ins_res = mmrangemap_insert_desc(to, new_entry, NULL);
         if (ins_res != RBT_MAP_RESULT_ENTRY_INSERTED) {
             ME("memcheck: Unable to insert new range map entry on copy. Insert returned %u",
                ins_res);
             g_free(new_entry->desc.path);
             g_free(new_entry);
             return -1;
         }
     }

     return 0;
 }

 int
 mmrangemap_empty(MMRangeMap* map)
 {
     MMRangeDesc pulled;
     int removed = 0;

     while (!mmrangemap_pull_first(map, &pulled)) {
         g_free(pulled.path);
         removed++;
     }

     return removed;
 }
	/* Copyright (C) 2007-2010 The Android Open Source Project
	**
	** This software is licensed under the terms of the GNU General Public
	** License version 2, as published by the Free Software Foundation, and
	** may be copied, distributed, and modified under those terms.
	**
	** 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.
	*/

	/*
	* Contains implementation of routines that implement a red-black tree of
	* memory mappings in the guest system.
	*/

	#include "android/qemu/memcheck/memcheck_mmrange_map.h"
	#include "android/qemu/memcheck/memcheck_logging.h"

	/* Memory range descriptor stored in the map. */
	typedef struct MMRangeMapEntry {
	/* R-B tree entry. */
	RB_ENTRY(MMRangeMapEntry) rb_entry;

	/* Memory range descriptor for this entry. */
	MMRangeDesc desc;
	} MMRangeMapEntry;

	// =============================================================================
	// R-B Tree implementation
	// =============================================================================

	/* Compare routine for the map.
	* Param:
	* d1 - First map entry to compare.
	* d2 - Second map entry to compare.
	* Return:
	* 0 - Descriptors are equal. Note that descriptors are considered to be
	* equal iff memory blocks they describe intersect in any part.
	* 1 - d1 is greater than d2
	* -1 - d1 is less than d2.
	*/
	static inline int
	cmp_rb(MMRangeMapEntry* d1, MMRangeMapEntry* d2)
	{
	const target_ulong start1 = d1->desc.map_start;
	const target_ulong start2 = d2->desc.map_start;

	if (start1 < start2) {
	return (d1->desc.map_end - 1) < start2 ? -1 : 0;
	}
	return (d2->desc.map_end - 1) < start1 ? 1 : 0;
	}

	/* Expands RB macros here. */
	RB_GENERATE(MMRangeMap, MMRangeMapEntry, rb_entry, cmp_rb);

	// =============================================================================
	// Static routines
	// =============================================================================

	/* Inserts new (or replaces existing) entry into the map.
	* See comments on mmrangemap_insert routine in the header file for details
	* about this routine.
	*/
	static RBTMapResult
	mmrangemap_insert_desc(MMRangeMap* map,
	MMRangeMapEntry* rdesc,
	MMRangeDesc* replaced)
	{
	MMRangeMapEntry* existing = MMRangeMap_RB_INSERT(map, rdesc);
	if (existing == NULL) {
	return RBT_MAP_RESULT_ENTRY_INSERTED;
	}

	// Matching entry exists. Lets see if we need to replace it.
	if (replaced == NULL) {
	return RBT_MAP_RESULT_ENTRY_ALREADY_EXISTS;
	}

	/* Copy existing entry to the provided buffer and replace it
	* with the new one. */
	memcpy(replaced, &existing->desc, sizeof(MMRangeDesc));
	MMRangeMap_RB_REMOVE(map, existing);
	g_free(existing);
	MMRangeMap_RB_INSERT(map, rdesc);
	return RBT_MAP_RESULT_ENTRY_REPLACED;
	}

	/* Finds an entry in the map that matches the given address range.
	* Param:
	* map - Map where to search for an entry.
	* start - Starting address of a mapping range.
	* end - Ending address of a mapping range.
	* Return:
	* Address of a map entry that matches the given range, or NULL if no
	* such entry has been found.
	*/
	static inline MMRangeMapEntry*
	mmrangemap_find_entry(const MMRangeMap* map,
	target_ulong start,
	target_ulong end)
	{
	MMRangeMapEntry rdesc;
	rdesc.desc.map_start = start;
	rdesc.desc.map_end = end;
	return MMRangeMap_RB_FIND((MMRangeMap*)map, &rdesc);
	}

	// =============================================================================
	// Map API
	// =============================================================================

	void
	mmrangemap_init(MMRangeMap* map)
	{
	RB_INIT(map);
	}

	RBTMapResult
	mmrangemap_insert(MMRangeMap* map,
	const MMRangeDesc* desc,
	MMRangeDesc* replaced)
	{
	RBTMapResult ret;

	// Allocate and initialize new map entry.
	MMRangeMapEntry* rdesc = g_malloc(sizeof(MMRangeMapEntry));
	if (rdesc == NULL) {
	ME("memcheck: Unable to allocate new MMRangeMapEntry on insert.");
	return RBT_MAP_RESULT_ERROR;
	}
	memcpy(&rdesc->desc, desc, sizeof(MMRangeDesc));

	// Insert new entry into the map.
	ret = mmrangemap_insert_desc(map, rdesc, replaced);
	if (ret == RBT_MAP_RESULT_ENTRY_ALREADY_EXISTS \|\|
	ret == RBT_MAP_RESULT_ERROR) {
	/* Another descriptor already exists for this block, or an error
	* occurred. We have to free new descriptor, as it wasn't inserted. */
	g_free(rdesc);
	}
	return ret;
	}

	MMRangeDesc*
	mmrangemap_find(const MMRangeMap* map, target_ulong start, target_ulong end)
	{
	MMRangeMapEntry* rdesc = mmrangemap_find_entry(map, start, end);
	return rdesc != NULL ? &rdesc->desc : NULL;
	}

	int
	mmrangemap_pull(MMRangeMap* map,
	target_ulong start,
	target_ulong end,
	MMRangeDesc* pulled)
	{
	MMRangeMapEntry* rdesc = mmrangemap_find_entry(map, start, end);
	if (rdesc != NULL) {
	memcpy(pulled, &rdesc->desc, sizeof(MMRangeDesc));
	MMRangeMap_RB_REMOVE(map, rdesc);
	g_free(rdesc);
	return 0;
	} else {
	return -1;
	}
	}

	int
	mmrangemap_pull_first(MMRangeMap* map, MMRangeDesc* pulled)
	{
	MMRangeMapEntry* first = RB_MIN(MMRangeMap, map);
	if (first != NULL) {
	memcpy(pulled, &first->desc, sizeof(MMRangeDesc));
	MMRangeMap_RB_REMOVE(map, first);
	g_free(first);
	return 0;
	} else {
	return -1;
	}
	}

	int
	mmrangemap_copy(MMRangeMap* to, const MMRangeMap* from)
	{
	MMRangeMapEntry* entry;
	RB_FOREACH(entry, MMRangeMap, (MMRangeMap*)from) {
	RBTMapResult ins_res;
	MMRangeMapEntry* new_entry =
	(MMRangeMapEntry*)g_malloc(sizeof(MMRangeMapEntry));
	if (new_entry == NULL) {
	ME("memcheck: Unable to allocate new MMRangeMapEntry on copy.");
	return -1;
	}
	memcpy(new_entry, entry, sizeof(MMRangeMapEntry));
	new_entry->desc.path = g_malloc(strlen(entry->desc.path) + 1);
	if (new_entry->desc.path == NULL) {
	ME("memcheck: Unable to allocate new path for MMRangeMapEntry on copy.");
	g_free(new_entry);
	return -1;
	}
	strcpy(new_entry->desc.path, entry->desc.path);
	ins_res = mmrangemap_insert_desc(to, new_entry, NULL);
	if (ins_res != RBT_MAP_RESULT_ENTRY_INSERTED) {
	ME("memcheck: Unable to insert new range map entry on copy. Insert returned %u",
	ins_res);
	g_free(new_entry->desc.path);
	g_free(new_entry);
	return -1;
	}
	}

	return 0;
	}

	int
	mmrangemap_empty(MMRangeMap* map)
	{
	MMRangeDesc pulled;
	int removed = 0;

	while (!mmrangemap_pull_first(map, &pulled)) {
	g_free(pulled.path);
	removed++;
	}

	return removed;
	}