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vmem.c

vmem.c 8.3 KB
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  1. /*
    2. 

  2.  *  arch/s390/mm/vmem.c
    3. 

  3.  *
    4. 

  4.  *    Copyright IBM Corp. 2006
    5. 

  5.  *    Author(s): Heiko Carstens <heiko.carstens@de.ibm.com>
    6. 

  6.  */
    7. 

  7. 

  8. #include <linux/bootmem.h>
    9. 

  9. #include <linux/pfn.h>
    10. 

  10. #include <linux/mm.h>
    11. 

  11. #include <linux/module.h>
    12. 

  12. #include <linux/list.h>
    13. 

  13. #include <linux/hugetlb.h>
    14. 

  14. #include <linux/slab.h>
    15. 

  15. #include <asm/pgalloc.h>
    16. 

  16. #include <asm/pgtable.h>
    17. 

  17. #include <asm/setup.h>
    18. 

  18. #include <asm/tlbflush.h>
    19. 

  19. #include <asm/sections.h>
    20. 

  20. 

  21. static DEFINE_MUTEX(vmem_mutex);
    22. 

  22. 

  23. struct memory_segment {
    24. 

  24. 	struct list_head list;
    25. 

  25. 	unsigned long start;
    26. 

  26. 	unsigned long size;
    27. 

  27. };
    28. 

  28. 

  29. static LIST_HEAD(mem_segs);
    30. 

  30. 

  31. static void __ref *vmem_alloc_pages(unsigned int order)
    32. 

  32. {
    33. 

  33. 	if (slab_is_available())
    34. 

  34. 		return (void *)__get_free_pages(GFP_KERNEL, order);
    35. 

  35. 	return alloc_bootmem_pages((1 << order) * PAGE_SIZE);
    36. 

  36. }
    37. 

  37. 

  38. static inline pud_t *vmem_pud_alloc(void)
    39. 

  39. {
    40. 

  40. 	pud_t *pud = NULL;
    41. 

  41. 

  42. #ifdef CONFIG_64BIT
    43. 

  43. 	pud = vmem_alloc_pages(2);
    44. 

  44. 	if (!pud)
    45. 

  45. 		return NULL;
    46. 

  46. 	clear_table((unsigned long *) pud, _REGION3_ENTRY_EMPTY, PAGE_SIZE * 4);
    47. 

  47. #endif
    48. 

  48. 	return pud;
    49. 

  49. }
    50. 

  50. 

  51. static inline pmd_t *vmem_pmd_alloc(void)
    52. 

  52. {
    53. 

  53. 	pmd_t *pmd = NULL;
    54. 

  54. 

  55. #ifdef CONFIG_64BIT
    56. 

  56. 	pmd = vmem_alloc_pages(2);
    57. 

  57. 	if (!pmd)
    58. 

  58. 		return NULL;
    59. 

  59. 	clear_table((unsigned long *) pmd, _SEGMENT_ENTRY_EMPTY, PAGE_SIZE * 4);
    60. 

  60. #endif
    61. 

  61. 	return pmd;
    62. 

  62. }
    63. 

  63. 

  64. static pte_t __ref *vmem_pte_alloc(void)
    65. 

  65. {
    66. 

  66. 	pte_t *pte;
    67. 

  67. 

  68. 	if (slab_is_available())
    69. 

  69. 		pte = (pte_t *) page_table_alloc(&init_mm);
    70. 

  70. 	else
    71. 

  71. 		pte = alloc_bootmem(PTRS_PER_PTE * sizeof(pte_t));
    72. 

  72. 	if (!pte)
    73. 

  73. 		return NULL;
    74. 

  74. 	clear_table((unsigned long *) pte, _PAGE_TYPE_EMPTY,
    75. 

  75. 		    PTRS_PER_PTE * sizeof(pte_t));
    76. 

  76. 	return pte;
    77. 

  77. }
    78. 

  78. 

  79. /*
    80. 

  80.  * Add a physical memory range to the 1:1 mapping.
    81. 

  81.  */
    82. 

  82. static int vmem_add_mem(unsigned long start, unsigned long size, int ro)
    83. 

  83. {
    84. 

  84. 	unsigned long address;
    85. 

  85. 	pgd_t *pg_dir;
    86. 

  86. 	pud_t *pu_dir;
    87. 

  87. 	pmd_t *pm_dir;
    88. 

  88. 	pte_t *pt_dir;
    89. 

  89. 	pte_t  pte;
    90. 

  90. 	int ret = -ENOMEM;
    91. 

  91. 

  92. 	for (address = start; address < start + size; address += PAGE_SIZE) {
    93. 

  93. 		pg_dir = pgd_offset_k(address);
    94. 

  94. 		if (pgd_none(*pg_dir)) {
    95. 

  95. 			pu_dir = vmem_pud_alloc();
    96. 

  96. 			if (!pu_dir)
    97. 

  97. 				goto out;
    98. 

  98. 			pgd_populate(&init_mm, pg_dir, pu_dir);
    99. 

  99. 		}
    100. 

  100. 

  101. 		pu_dir = pud_offset(pg_dir, address);
    102. 

  102. 		if (pud_none(*pu_dir)) {
    103. 

  103. 			pm_dir = vmem_pmd_alloc();
    104. 

  104. 			if (!pm_dir)
    105. 

  105. 				goto out;
    106. 

  106. 			pud_populate(&init_mm, pu_dir, pm_dir);
    107. 

  107. 		}
    108. 

  108. 

  109. 		pte = mk_pte_phys(address, __pgprot(ro ? _PAGE_RO : 0));
    110. 

  110. 		pm_dir = pmd_offset(pu_dir, address);
    111. 

  111. 

  112. #ifdef __s390x__
    113. 

  113. 		if (MACHINE_HAS_HPAGE && !(address & ~HPAGE_MASK) &&
    114. 

  114. 		    (address + HPAGE_SIZE <= start + size) &&
    115. 

  115. 		    (address >= HPAGE_SIZE)) {
    116. 

  116. 			pte_val(pte) |= _SEGMENT_ENTRY_LARGE;
    117. 

  117. 			pmd_val(*pm_dir) = pte_val(pte);
    118. 

  118. 			address += HPAGE_SIZE - PAGE_SIZE;
    119. 

  119. 			continue;
    120. 

  120. 		}
    121. 

  121. #endif
    122. 

  122. 		if (pmd_none(*pm_dir)) {
    123. 

  123. 			pt_dir = vmem_pte_alloc();
    124. 

  124. 			if (!pt_dir)
    125. 

  125. 				goto out;
    126. 

  126. 			pmd_populate(&init_mm, pm_dir, pt_dir);
    127. 

  127. 		}
    128. 

  128. 

  129. 		pt_dir = pte_offset_kernel(pm_dir, address);
    130. 

  130. 		*pt_dir = pte;
    131. 

  131. 	}
    132. 

  132. 	ret = 0;
    133. 

  133. out:
    134. 

  134. 	flush_tlb_kernel_range(start, start + size);
    135. 

  135. 	return ret;
    136. 

  136. }
    137. 

  137. 

  138. /*
    139. 

  139.  * Remove a physical memory range from the 1:1 mapping.
    140. 

  140.  * Currently only invalidates page table entries.
    141. 

  141.  */
    142. 

  142. static void vmem_remove_range(unsigned long start, unsigned long size)
    143. 

  143. {
    144. 

  144. 	unsigned long address;
    145. 

  145. 	pgd_t *pg_dir;
    146. 

  146. 	pud_t *pu_dir;
    147. 

  147. 	pmd_t *pm_dir;
    148. 

  148. 	pte_t *pt_dir;
    149. 

  149. 	pte_t  pte;
    150. 

  150. 

  151. 	pte_val(pte) = _PAGE_TYPE_EMPTY;
    152. 

  152. 	for (address = start; address < start + size; address += PAGE_SIZE) {
    153. 

  153. 		pg_dir = pgd_offset_k(address);
    154. 

  154. 		pu_dir = pud_offset(pg_dir, address);
    155. 

  155. 		if (pud_none(*pu_dir))
    156. 

  156. 			continue;
    157. 

  157. 		pm_dir = pmd_offset(pu_dir, address);
    158. 

  158. 		if (pmd_none(*pm_dir))
    159. 

  159. 			continue;
    160. 

  160. 

  161. 		if (pmd_huge(*pm_dir)) {
    162. 

  162. 			pmd_clear(pm_dir);
    163. 

  163. 			address += HPAGE_SIZE - PAGE_SIZE;
    164. 

  164. 			continue;
    165. 

  165. 		}
    166. 

  166. 

  167. 		pt_dir = pte_offset_kernel(pm_dir, address);
    168. 

  168. 		*pt_dir = pte;
    169. 

  169. 	}
    170. 

  170. 	flush_tlb_kernel_range(start, start + size);
    171. 

  171. }
    172. 

  172. 

  173. /*
    174. 

  174.  * Add a backed mem_map array to the virtual mem_map array.
    175. 

  175.  */
    176. 

  176. int __meminit vmemmap_populate(struct page *start, unsigned long nr, int node)
    177. 

  177. {
    178. 

  178. 	unsigned long address, start_addr, end_addr;
    179. 

  179. 	pgd_t *pg_dir;
    180. 

  180. 	pud_t *pu_dir;
    181. 

  181. 	pmd_t *pm_dir;
    182. 

  182. 	pte_t *pt_dir;
    183. 

  183. 	pte_t  pte;
    184. 

  184. 	int ret = -ENOMEM;
    185. 

  185. 

  186. 	start_addr = (unsigned long) start;
    187. 

  187. 	end_addr = (unsigned long) (start + nr);
    188. 

  188. 

  189. 	for (address = start_addr; address < end_addr; address += PAGE_SIZE) {
    190. 

  190. 		pg_dir = pgd_offset_k(address);
    191. 

  191. 		if (pgd_none(*pg_dir)) {
    192. 

  192. 			pu_dir = vmem_pud_alloc();
    193. 

  193. 			if (!pu_dir)
    194. 

  194. 				goto out;
    195. 

  195. 			pgd_populate(&init_mm, pg_dir, pu_dir);
    196. 

  196. 		}
    197. 

  197. 

  198. 		pu_dir = pud_offset(pg_dir, address);
    199. 

  199. 		if (pud_none(*pu_dir)) {
    200. 

  200. 			pm_dir = vmem_pmd_alloc();
    201. 

  201. 			if (!pm_dir)
    202. 

  202. 				goto out;
    203. 

  203. 			pud_populate(&init_mm, pu_dir, pm_dir);
    204. 

  204. 		}
    205. 

  205. 

  206. 		pm_dir = pmd_offset(pu_dir, address);
    207. 

  207. 		if (pmd_none(*pm_dir)) {
    208. 

  208. 			pt_dir = vmem_pte_alloc();
    209. 

  209. 			if (!pt_dir)
    210. 

  210. 				goto out;
    211. 

  211. 			pmd_populate(&init_mm, pm_dir, pt_dir);
    212. 

  212. 		}
    213. 

  213. 

  214. 		pt_dir = pte_offset_kernel(pm_dir, address);
    215. 

  215. 		if (pte_none(*pt_dir)) {
    216. 

  216. 			unsigned long new_page;
    217. 

  217. 

  218. 			new_page =__pa(vmem_alloc_pages(0));
    219. 

  219. 			if (!new_page)
    220. 

  220. 				goto out;
    221. 

  221. 			pte = pfn_pte(new_page >> PAGE_SHIFT, PAGE_KERNEL);
    222. 

  222. 			*pt_dir = pte;
    223. 

  223. 		}
    224. 

  224. 	}
    225. 

  225. 	memset(start, 0, nr * sizeof(struct page));
    226. 

  226. 	ret = 0;
    227. 

  227. out:
    228. 

  228. 	flush_tlb_kernel_range(start_addr, end_addr);
    229. 

  229. 	return ret;
    230. 

  230. }
    231. 

  231. 

  232. /*
    233. 

  233.  * Add memory segment to the segment list if it doesn't overlap with
    234. 

  234.  * an already present segment.
    235. 

  235.  */
    236. 

  236. static int insert_memory_segment(struct memory_segment *seg)
    237. 

  237. {
    238. 

  238. 	struct memory_segment *tmp;
    239. 

  239. 

  240. 	if (seg->start + seg->size > VMEM_MAX_PHYS ||
    241. 

  241. 	    seg->start + seg->size < seg->start)
    242. 

  242. 		return -ERANGE;
    243. 

  243. 

  244. 	list_for_each_entry(tmp, &mem_segs, list) {
    245. 

  245. 		if (seg->start >= tmp->start + tmp->size)
    246. 

  246. 			continue;
    247. 

  247. 		if (seg->start + seg->size <= tmp->start)
    248. 

  248. 			continue;
    249. 

  249. 		return -ENOSPC;
    250. 

  250. 	}
    251. 

  251. 	list_add(&seg->list, &mem_segs);
    252. 

  252. 	return 0;
    253. 

  253. }
    254. 

  254. 

  255. /*
    256. 

  256.  * Remove memory segment from the segment list.
    257. 

  257.  */
    258. 

  258. static void remove_memory_segment(struct memory_segment *seg)
    259. 

  259. {
    260. 

  260. 	list_del(&seg->list);
    261. 

  261. }
    262. 

  262. 

  263. static void __remove_shared_memory(struct memory_segment *seg)
    264. 

  264. {
    265. 

  265. 	remove_memory_segment(seg);
    266. 

  266. 	vmem_remove_range(seg->start, seg->size);
    267. 

  267. }
    268. 

  268. 

  269. int vmem_remove_mapping(unsigned long start, unsigned long size)
    270. 

  270. {
    271. 

  271. 	struct memory_segment *seg;
    272. 

  272. 	int ret;
    273. 

  273. 

  274. 	mutex_lock(&vmem_mutex);
    275. 

  275. 

  276. 	ret = -ENOENT;
    277. 

  277. 	list_for_each_entry(seg, &mem_segs, list) {
    278. 

  278. 		if (seg->start == start && seg->size == size)
    279. 

  279. 			break;
    280. 

  280. 	}
    281. 

  281. 

  282. 	if (seg->start != start || seg->size != size)
    283. 

  283. 		goto out;
    284. 

  284. 

  285. 	ret = 0;
    286. 

  286. 	__remove_shared_memory(seg);
    287. 

  287. 	kfree(seg);
    288. 

  288. out:
    289. 

  289. 	mutex_unlock(&vmem_mutex);
    290. 

  290. 	return ret;
    291. 

  291. }
    292. 

  292. 

  293. int vmem_add_mapping(unsigned long start, unsigned long size)
    294. 

  294. {
    295. 

  295. 	struct memory_segment *seg;
    296. 

  296. 	int ret;
    297. 

  297. 

  298. 	mutex_lock(&vmem_mutex);
    299. 

  299. 	ret = -ENOMEM;
    300. 

  300. 	seg = kzalloc(sizeof(*seg), GFP_KERNEL);
    301. 

  301. 	if (!seg)
    302. 

  302. 		goto out;
    303. 

  303. 	seg->start = start;
    304. 

  304. 	seg->size = size;
    305. 

  305. 

  306. 	ret = insert_memory_segment(seg);
    307. 

  307. 	if (ret)
    308. 

  308. 		goto out_free;
    309. 

  309. 

  310. 	ret = vmem_add_mem(start, size, 0);
    311. 

  311. 	if (ret)
    312. 

  312. 		goto out_remove;
    313. 

  313. 	goto out;
    314. 

  314. 

  315. out_remove:
    316. 

  316. 	__remove_shared_memory(seg);
    317. 

  317. out_free:
    318. 

  318. 	kfree(seg);
    319. 

  319. out:
    320. 

  320. 	mutex_unlock(&vmem_mutex);
    321. 

  321. 	return ret;
    322. 

  322. }
    323. 

  323. 

  324. /*
    325. 

  325.  * map whole physical memory to virtual memory (identity mapping)
    326. 

  326.  * we reserve enough space in the vmalloc area for vmemmap to hotplug
    327. 

  327.  * additional memory segments.
    328. 

  328.  */
    329. 

  329. void __init vmem_map_init(void)
    330. 

  330. {
    331. 

  331. 	unsigned long ro_start, ro_end;
    332. 

  332. 	unsigned long start, end;
    333. 

  333. 	int i;
    334. 

  334. 

  335. 	ro_start = ((unsigned long)&_stext) & PAGE_MASK;
    336. 

  336. 	ro_end = PFN_ALIGN((unsigned long)&_eshared);
    337. 

  337. 	for (i = 0; i < MEMORY_CHUNKS && memory_chunk[i].size > 0; i++) {
    338. 

  338. 		start = memory_chunk[i].addr;
    339. 

  339. 		end = memory_chunk[i].addr + memory_chunk[i].size;
    340. 

  340. 		if (start >= ro_end || end <= ro_start)
    341. 

  341. 			vmem_add_mem(start, end - start, 0);
    342. 

  342. 		else if (start >= ro_start && end <= ro_end)
    343. 

  343. 			vmem_add_mem(start, end - start, 1);
    344. 

  344. 		else if (start >= ro_start) {
    345. 

  345. 			vmem_add_mem(start, ro_end - start, 1);
    346. 

  346. 			vmem_add_mem(ro_end, end - ro_end, 0);
    347. 

  347. 		} else if (end < ro_end) {
    348. 

  348. 			vmem_add_mem(start, ro_start - start, 0);
    349. 

  349. 			vmem_add_mem(ro_start, end - ro_start, 1);
    350. 

  350. 		} else {
    351. 

  351. 			vmem_add_mem(start, ro_start - start, 0);
    352. 

  352. 			vmem_add_mem(ro_start, ro_end - ro_start, 1);
    353. 

  353. 			vmem_add_mem(ro_end, end - ro_end, 0);
    354. 

  354. 		}
    355. 

  355. 	}
    356. 

  356. }
    357. 

  357. 

  358. /*
    359. 

  359.  * Convert memory chunk array to a memory segment list so there is a single
    360. 

  360.  * list that contains both r/w memory and shared memory segments.
    361. 

  361.  */
    362. 

  362. static int __init vmem_convert_memory_chunk(void)
    363. 

  363. {
    364. 

  364. 	struct memory_segment *seg;
    365. 

  365. 	int i;
    366. 

  366. 

  367. 	mutex_lock(&vmem_mutex);
    368. 

  368. 	for (i = 0; i < MEMORY_CHUNKS; i++) {
    369. 

  369. 		if (!memory_chunk[i].size)
    370. 

  370. 			continue;
    371. 

  371. 		seg = kzalloc(sizeof(*seg), GFP_KERNEL);
    372. 

  372. 		if (!seg)
    373. 

  373. 			panic("Out of memory...\n");
    374. 

  374. 		seg->start = memory_chunk[i].addr;
    375. 

  375. 		seg->size = memory_chunk[i].size;
    376. 

  376. 		insert_memory_segment(seg);
    377. 

  377. 	}
    378. 

  378. 	mutex_unlock(&vmem_mutex);
    379. 

  379. 	return 0;
    380. 

  380. }
    381. 

  381. 

  382. core_initcall(vmem_convert_memory_chunk);
    383. 

  383.