memmgr.h 7.4 KB

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  1. /* Copyright (C) 2014 Stony Brook University
  2. This file is part of Graphene Library OS.
  3. Graphene Library OS is free software: you can redistribute it and/or
  4. modify it under the terms of the GNU Lesser General Public License
  5. as published by the Free Software Foundation, either version 3 of the
  6. License, or (at your option) any later version.
  7. Graphene Library OS is distributed in the hope that it will be useful,
  8. but WITHOUT ANY WARRANTY; without even the implied warranty of
  9. MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
  10. GNU Lesser General Public License for more details.
  11. You should have received a copy of the GNU Lesser General Public License
  12. along with this program. If not, see <http://www.gnu.org/licenses/>. */
  13. /*
  14. * memmgr.h
  15. *
  16. * This file contains implementation of fixed-size memory allocator.
  17. */
  18. #ifndef MEMMGR_H
  19. #define MEMMGR_H
  20. #include <sys/mman.h>
  21. #include "api.h"
  22. #include "assert.h"
  23. #include "list.h"
  24. #ifndef OBJ_TYPE
  25. #error "OBJ_TYPE not defined"
  26. #endif
  27. #ifndef system_malloc
  28. #error "macro \"void * system_malloc (size_t size)\" not declared"
  29. #endif
  30. #ifndef system_free
  31. #error "macro \"void * system_free (void * ptr, size_t size)\" not declared"
  32. #endif
  33. #ifndef SYSTEM_LOCK
  34. #define SYSTEM_LOCK() ({})
  35. #endif
  36. #ifndef SYSTEM_UNLOCK
  37. #define SYSTEM_UNLOCK() ({})
  38. #endif
  39. DEFINE_LIST(mem_obj);
  40. typedef struct mem_obj {
  41. union {
  42. LIST_TYPE(mem_obj) __list;
  43. OBJ_TYPE obj;
  44. };
  45. } MEM_OBJ_TYPE, *MEM_OBJ;
  46. DEFINE_LIST(mem_area);
  47. typedef struct mem_area {
  48. LIST_TYPE(mem_area) __list;
  49. unsigned int size;
  50. MEM_OBJ_TYPE objs[];
  51. } MEM_AREA_TYPE, *MEM_AREA;
  52. DEFINE_LISTP(mem_area);
  53. DEFINE_LISTP(mem_obj);
  54. typedef struct mem_mgr {
  55. LISTP_TYPE(mem_area) area_list;
  56. LISTP_TYPE(mem_obj) free_list;
  57. size_t size;
  58. MEM_OBJ_TYPE* obj;
  59. MEM_OBJ_TYPE* obj_top;
  60. MEM_AREA active_area;
  61. } MEM_MGR_TYPE, *MEM_MGR;
  62. #define __SUM_OBJ_SIZE(size) (sizeof(MEM_OBJ_TYPE) * (size))
  63. #define __MIN_MEM_SIZE() (sizeof(MEM_MGR_TYPE) + sizeof(MEM_AREA_TYPE))
  64. #define __MAX_MEM_SIZE(size) (__MIN_MEM_SIZE() + __SUM_OBJ_SIZE(size))
  65. #ifdef ALLOC_ALIGNMENT
  66. static inline int size_align_down(int size) {
  67. assert(IS_POWER_OF_2(ALLOC_ALIGNMENT));
  68. int s = __MAX_MEM_SIZE(size) - sizeof(MEM_MGR_TYPE);
  69. int p = s - ALIGN_DOWN_POW2(s, ALLOC_ALIGNMENT);
  70. int o = __SUM_OBJ_SIZE(1);
  71. return size - p / o - (p % o ? 1 : 0);
  72. }
  73. static inline int size_align_up(int size) {
  74. assert(IS_POWER_OF_2(ALLOC_ALIGNMENT));
  75. int s = __MAX_MEM_SIZE(size) - sizeof(MEM_MGR_TYPE);
  76. int p = ALIGN_UP_POW2(s, ALLOC_ALIGNMENT) - s;
  77. int o = __SUM_OBJ_SIZE(1);
  78. return size + p / o;
  79. }
  80. static inline int init_align_down(int size) {
  81. assert(IS_POWER_OF_2(ALLOC_ALIGNMENT));
  82. int s = __MAX_MEM_SIZE(size);
  83. int p = s - ALIGN_DOWN_POW2(s, ALLOC_ALIGNMENT);
  84. int o = __SUM_OBJ_SIZE(1);
  85. return size - p / o - (p % o ? 1 : 0);
  86. }
  87. static inline int init_align_up(int size) {
  88. assert(IS_POWER_OF_2(ALLOC_ALIGNMENT));
  89. int s = __MAX_MEM_SIZE(size);
  90. int p = ALIGN_UP_POW2(s, ALLOC_ALIGNMENT) - s;
  91. int o = __SUM_OBJ_SIZE(1);
  92. return size + p / o;
  93. }
  94. #endif
  95. static inline void __set_free_mem_area(MEM_AREA area, MEM_MGR mgr) {
  96. mgr->size += area->size;
  97. mgr->obj = area->objs;
  98. mgr->obj_top = area->objs + area->size;
  99. mgr->active_area = area;
  100. }
  101. static inline MEM_MGR create_mem_mgr(unsigned int size) {
  102. void* mem = system_malloc(__MAX_MEM_SIZE(size));
  103. MEM_AREA area;
  104. MEM_MGR mgr;
  105. if (!mem)
  106. return NULL;
  107. mgr = (MEM_MGR)mem;
  108. mgr->size = 0;
  109. area = (MEM_AREA)(mem + sizeof(MEM_MGR_TYPE));
  110. area->size = size;
  111. INIT_LIST_HEAD(area, __list);
  112. INIT_LISTP(&mgr->area_list);
  113. LISTP_ADD(area, &mgr->area_list, __list);
  114. INIT_LISTP(&mgr->free_list);
  115. __set_free_mem_area(area, mgr);
  116. return mgr;
  117. }
  118. static inline MEM_MGR enlarge_mem_mgr(MEM_MGR mgr, unsigned int size) {
  119. MEM_AREA area;
  120. area = (MEM_AREA)system_malloc(sizeof(MEM_AREA_TYPE) + __SUM_OBJ_SIZE(size));
  121. if (!area)
  122. return NULL;
  123. SYSTEM_LOCK();
  124. area->size = size;
  125. INIT_LIST_HEAD(area, __list);
  126. LISTP_ADD(area, &mgr->area_list, __list);
  127. __set_free_mem_area(area, mgr);
  128. SYSTEM_UNLOCK();
  129. return mgr;
  130. }
  131. static inline void destroy_mem_mgr(MEM_MGR mgr) {
  132. MEM_AREA tmp, n, first = NULL;
  133. first = tmp = LISTP_FIRST_ENTRY(&mgr->area_list, MEM_AREA_TYPE, __list);
  134. if (!first)
  135. goto free_mgr;
  136. LISTP_FOR_EACH_ENTRY_SAFE_CONTINUE(tmp, n, &mgr->area_list, __list) {
  137. LISTP_DEL(tmp, &mgr->area_list, __list);
  138. system_free(tmp, sizeof(MEM_AREA_TYPE) + __SUM_OBJ_SIZE(tmp->size));
  139. }
  140. free_mgr:
  141. system_free(mgr, __MAX_MEM_SIZE(first->size));
  142. }
  143. static inline OBJ_TYPE* get_mem_obj_from_mgr(MEM_MGR mgr) {
  144. MEM_OBJ mobj;
  145. SYSTEM_LOCK();
  146. if (mgr->obj == mgr->obj_top && LISTP_EMPTY(&mgr->free_list)) {
  147. SYSTEM_UNLOCK();
  148. return NULL;
  149. }
  150. if (!LISTP_EMPTY(&mgr->free_list)) {
  151. mobj = LISTP_FIRST_ENTRY(&mgr->free_list, MEM_OBJ_TYPE, __list);
  152. LISTP_DEL_INIT(mobj, &mgr->free_list, __list);
  153. CHECK_LIST_HEAD(MEM_OBJ, &mgr->free_list, __list);
  154. } else {
  155. mobj = mgr->obj++;
  156. }
  157. SYSTEM_UNLOCK();
  158. return &mobj->obj;
  159. }
  160. static inline OBJ_TYPE* get_mem_obj_from_mgr_enlarge(MEM_MGR mgr, unsigned int size) {
  161. MEM_OBJ mobj;
  162. SYSTEM_LOCK();
  163. if (mgr->obj == mgr->obj_top && LISTP_EMPTY(&mgr->free_list)) {
  164. size_t mgr_size = mgr->size;
  165. MEM_AREA area;
  166. /* If there is a previously allocated area, just activate it. */
  167. area = LISTP_PREV_ENTRY(mgr->active_area, &mgr->area_list, __list);
  168. if (area) {
  169. __set_free_mem_area(area, mgr);
  170. goto alloc;
  171. }
  172. SYSTEM_UNLOCK();
  173. if (!size)
  174. return NULL;
  175. /* There can be concurrent attempt to try to enlarge the
  176. allocator, but we prevent deadlocks or crashes. */
  177. area = (MEM_AREA)system_malloc(sizeof(MEM_AREA_TYPE) + __SUM_OBJ_SIZE(size));
  178. if (!area)
  179. return NULL;
  180. SYSTEM_LOCK();
  181. area->size = size;
  182. INIT_LIST_HEAD(area, __list);
  183. /* There can be concurrent operations to extend the manager. In case
  184. * someone has already enlarged the space, we just add the new area to
  185. * the list for later use. */
  186. LISTP_ADD(area, &mgr->area_list, __list);
  187. if (mgr_size == mgr->size) /* check if the size has changed */
  188. __set_free_mem_area(area, mgr);
  189. }
  190. alloc:
  191. if (!LISTP_EMPTY(&mgr->free_list)) {
  192. mobj = LISTP_FIRST_ENTRY(&mgr->free_list, MEM_OBJ_TYPE, __list);
  193. LISTP_DEL_INIT(mobj, &mgr->free_list, __list);
  194. CHECK_LIST_HEAD(MEM_OBJ, &mgr->free_list, __list);
  195. } else {
  196. mobj = mgr->obj++;
  197. }
  198. assert(mgr->obj <= mgr->obj_top);
  199. SYSTEM_UNLOCK();
  200. return &mobj->obj;
  201. }
  202. static inline void free_mem_obj_to_mgr(MEM_MGR mgr, OBJ_TYPE* obj) {
  203. MEM_OBJ mobj = container_of(obj, MEM_OBJ_TYPE, obj);
  204. SYSTEM_LOCK();
  205. MEM_AREA area, found = NULL;
  206. LISTP_FOR_EACH_ENTRY(area, &mgr->area_list, __list) {
  207. if (mobj >= area->objs && mobj < area->objs + area->size) {
  208. found = area;
  209. break;
  210. }
  211. }
  212. if (found) {
  213. INIT_LIST_HEAD(mobj, __list);
  214. LISTP_ADD_TAIL(mobj, &mgr->free_list, __list);
  215. CHECK_LIST_HEAD(MEM_OBJ, &mgr->free_list, __list);
  216. }
  217. SYSTEM_UNLOCK();
  218. }
  219. #endif /* MEMMGR_H */