mtd_intel_dg.c 20 KB

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  1. // SPDX-License-Identifier: GPL-2.0
  2. /*
  3. * Copyright(c) 2019-2025, Intel Corporation. All rights reserved.
  4. */
  5. #include <linux/bitfield.h>
  6. #include <linux/bits.h>
  7. #include <linux/cleanup.h>
  8. #include <linux/delay.h>
  9. #include <linux/device.h>
  10. #include <linux/intel_dg_nvm_aux.h>
  11. #include <linux/io.h>
  12. #include <linux/io-64-nonatomic-lo-hi.h>
  13. #include <linux/kernel.h>
  14. #include <linux/module.h>
  15. #include <linux/mtd/mtd.h>
  16. #include <linux/mtd/partitions.h>
  17. #include <linux/pm_runtime.h>
  18. #include <linux/string.h>
  19. #include <linux/slab.h>
  20. #include <linux/sizes.h>
  21. #include <linux/types.h>
  22. #define INTEL_DG_NVM_RPM_TIMEOUT_MS 500
  23. struct intel_dg_nvm {
  24. struct kref refcnt;
  25. struct mtd_info mtd;
  26. struct device *dev;
  27. struct mutex lock; /* region access lock */
  28. void __iomem *base;
  29. void __iomem *base2;
  30. bool non_posted_erase;
  31. size_t size;
  32. unsigned int nregions;
  33. struct {
  34. const char *name;
  35. u8 id;
  36. u64 offset;
  37. u64 size;
  38. unsigned int is_readable:1;
  39. unsigned int is_writable:1;
  40. } regions[] __counted_by(nregions);
  41. };
  42. #define NVM_TRIGGER_REG 0x00000000
  43. #define NVM_VALSIG_REG 0x00000010
  44. #define NVM_ADDRESS_REG 0x00000040
  45. #define NVM_REGION_ID_REG 0x00000044
  46. #define NVM_DEBUG_REG 0x00000000
  47. /*
  48. * [15:0]-Erase size = 0x0010 4K 0x0080 32K 0x0100 64K
  49. * [23:16]-Reserved
  50. * [31:24]-Erase MEM RegionID
  51. */
  52. #define NVM_ERASE_REG 0x00000048
  53. #define NVM_ACCESS_ERROR_REG 0x00000070
  54. #define NVM_ADDRESS_ERROR_REG 0x00000074
  55. /* Flash Valid Signature */
  56. #define NVM_FLVALSIG 0x0FF0A55A
  57. #define NVM_MAP_ADDR_MASK GENMASK(7, 0)
  58. #define NVM_MAP_ADDR_SHIFT 0x00000004
  59. #define NVM_REGION_ID_DESCRIPTOR 0
  60. /* Flash Region Base Address */
  61. #define NVM_FRBA 0x40
  62. /* Flash Region __n - Flash Descriptor Record */
  63. #define NVM_FLREG(__n) (NVM_FRBA + ((__n) * 4))
  64. /* Flash Map 1 Register */
  65. #define NVM_FLMAP1_REG 0x18
  66. #define NVM_FLMSTR4_OFFSET 0x00C
  67. #define NVM_ACCESS_ERROR_PCIE_MASK 0x7
  68. #define NVM_FREG_BASE_MASK GENMASK(15, 0)
  69. #define NVM_FREG_ADDR_MASK GENMASK(31, 16)
  70. #define NVM_FREG_ADDR_SHIFT 12
  71. #define NVM_FREG_MIN_REGION_SIZE 0xFFF
  72. #define NVM_NON_POSTED_ERASE_DONE BIT(23)
  73. #define NVM_NON_POSTED_ERASE_DONE_ITER 3000
  74. static inline void idg_nvm_set_region_id(struct intel_dg_nvm *nvm, u8 region)
  75. {
  76. iowrite32((u32)region, nvm->base + NVM_REGION_ID_REG);
  77. }
  78. static inline u32 idg_nvm_error(struct intel_dg_nvm *nvm)
  79. {
  80. void __iomem *base = nvm->base;
  81. u32 reg = ioread32(base + NVM_ACCESS_ERROR_REG) & NVM_ACCESS_ERROR_PCIE_MASK;
  82. /* reset error bits */
  83. if (reg)
  84. iowrite32(reg, base + NVM_ACCESS_ERROR_REG);
  85. return reg;
  86. }
  87. static inline u32 idg_nvm_read32(struct intel_dg_nvm *nvm, u32 address)
  88. {
  89. void __iomem *base = nvm->base;
  90. iowrite32(address, base + NVM_ADDRESS_REG);
  91. return ioread32(base + NVM_TRIGGER_REG);
  92. }
  93. static inline u64 idg_nvm_read64(struct intel_dg_nvm *nvm, u32 address)
  94. {
  95. void __iomem *base = nvm->base;
  96. iowrite32(address, base + NVM_ADDRESS_REG);
  97. return readq(base + NVM_TRIGGER_REG);
  98. }
  99. static void idg_nvm_write32(struct intel_dg_nvm *nvm, u32 address, u32 data)
  100. {
  101. void __iomem *base = nvm->base;
  102. iowrite32(address, base + NVM_ADDRESS_REG);
  103. iowrite32(data, base + NVM_TRIGGER_REG);
  104. }
  105. static void idg_nvm_write64(struct intel_dg_nvm *nvm, u32 address, u64 data)
  106. {
  107. void __iomem *base = nvm->base;
  108. iowrite32(address, base + NVM_ADDRESS_REG);
  109. writeq(data, base + NVM_TRIGGER_REG);
  110. }
  111. static int idg_nvm_get_access_map(struct intel_dg_nvm *nvm, u32 *access_map)
  112. {
  113. u32 fmstr4_addr;
  114. u32 fmstr4;
  115. u32 flmap1;
  116. u32 fmba;
  117. idg_nvm_set_region_id(nvm, NVM_REGION_ID_DESCRIPTOR);
  118. flmap1 = idg_nvm_read32(nvm, NVM_FLMAP1_REG);
  119. if (idg_nvm_error(nvm))
  120. return -EIO;
  121. /* Get Flash Master Baser Address (FMBA) */
  122. fmba = (FIELD_GET(NVM_MAP_ADDR_MASK, flmap1) << NVM_MAP_ADDR_SHIFT);
  123. fmstr4_addr = fmba + NVM_FLMSTR4_OFFSET;
  124. fmstr4 = idg_nvm_read32(nvm, fmstr4_addr);
  125. if (idg_nvm_error(nvm))
  126. return -EIO;
  127. *access_map = fmstr4;
  128. return 0;
  129. }
  130. /*
  131. * Region read/write access encoded in the access map
  132. * in the following order from the lower bit:
  133. * [3:0] regions 12-15 read state
  134. * [7:4] regions 12-15 write state
  135. * [19:8] regions 0-11 read state
  136. * [31:20] regions 0-11 write state
  137. */
  138. static bool idg_nvm_region_readable(u32 access_map, u8 region)
  139. {
  140. if (region < 12)
  141. return access_map & BIT(region + 8); /* [19:8] */
  142. else
  143. return access_map & BIT(region - 12); /* [3:0] */
  144. }
  145. static bool idg_nvm_region_writable(u32 access_map, u8 region)
  146. {
  147. if (region < 12)
  148. return access_map & BIT(region + 20); /* [31:20] */
  149. else
  150. return access_map & BIT(region - 8); /* [7:4] */
  151. }
  152. static int idg_nvm_is_valid(struct intel_dg_nvm *nvm)
  153. {
  154. u32 is_valid;
  155. idg_nvm_set_region_id(nvm, NVM_REGION_ID_DESCRIPTOR);
  156. is_valid = idg_nvm_read32(nvm, NVM_VALSIG_REG);
  157. if (idg_nvm_error(nvm))
  158. return -EIO;
  159. if (is_valid != NVM_FLVALSIG)
  160. return -ENODEV;
  161. return 0;
  162. }
  163. static unsigned int idg_nvm_get_region(const struct intel_dg_nvm *nvm, loff_t from)
  164. {
  165. unsigned int i;
  166. for (i = 0; i < nvm->nregions; i++) {
  167. if ((nvm->regions[i].offset + nvm->regions[i].size - 1) >= from &&
  168. nvm->regions[i].offset <= from &&
  169. nvm->regions[i].size != 0)
  170. break;
  171. }
  172. return i;
  173. }
  174. static ssize_t idg_nvm_rewrite_partial(struct intel_dg_nvm *nvm, loff_t to,
  175. loff_t offset, size_t len, const u32 *newdata)
  176. {
  177. u32 data = idg_nvm_read32(nvm, to);
  178. if (idg_nvm_error(nvm))
  179. return -EIO;
  180. memcpy((u8 *)&data + offset, newdata, len);
  181. idg_nvm_write32(nvm, to, data);
  182. if (idg_nvm_error(nvm))
  183. return -EIO;
  184. return len;
  185. }
  186. static ssize_t idg_write(struct intel_dg_nvm *nvm, u8 region,
  187. loff_t to, size_t len, const unsigned char *buf)
  188. {
  189. size_t len_s = len;
  190. size_t to_shift;
  191. size_t len8;
  192. size_t len4;
  193. ssize_t ret;
  194. size_t to4;
  195. size_t i;
  196. idg_nvm_set_region_id(nvm, region);
  197. to4 = ALIGN_DOWN(to, sizeof(u32));
  198. to_shift = min(sizeof(u32) - ((size_t)to - to4), len);
  199. if (to - to4) {
  200. ret = idg_nvm_rewrite_partial(nvm, to4, to - to4, to_shift, (u32 *)&buf[0]);
  201. if (ret < 0)
  202. return ret;
  203. buf += to_shift;
  204. to += to_shift;
  205. len_s -= to_shift;
  206. }
  207. if (!IS_ALIGNED(to, sizeof(u64)) &&
  208. ((to ^ (to + len_s)) & GENMASK(31, 10))) {
  209. /*
  210. * Workaround reads/writes across 1k-aligned addresses
  211. * (start u32 before 1k, end u32 after)
  212. * as this fails on hardware.
  213. */
  214. u32 data;
  215. memcpy(&data, &buf[0], sizeof(u32));
  216. idg_nvm_write32(nvm, to, data);
  217. if (idg_nvm_error(nvm))
  218. return -EIO;
  219. buf += sizeof(u32);
  220. to += sizeof(u32);
  221. len_s -= sizeof(u32);
  222. }
  223. len8 = ALIGN_DOWN(len_s, sizeof(u64));
  224. for (i = 0; i < len8; i += sizeof(u64)) {
  225. u64 data;
  226. memcpy(&data, &buf[i], sizeof(u64));
  227. idg_nvm_write64(nvm, to + i, data);
  228. if (idg_nvm_error(nvm))
  229. return -EIO;
  230. }
  231. len4 = len_s - len8;
  232. if (len4 >= sizeof(u32)) {
  233. u32 data;
  234. memcpy(&data, &buf[i], sizeof(u32));
  235. idg_nvm_write32(nvm, to + i, data);
  236. if (idg_nvm_error(nvm))
  237. return -EIO;
  238. i += sizeof(u32);
  239. len4 -= sizeof(u32);
  240. }
  241. if (len4 > 0) {
  242. ret = idg_nvm_rewrite_partial(nvm, to + i, 0, len4, (u32 *)&buf[i]);
  243. if (ret < 0)
  244. return ret;
  245. }
  246. return len;
  247. }
  248. static ssize_t idg_read(struct intel_dg_nvm *nvm, u8 region,
  249. loff_t from, size_t len, unsigned char *buf)
  250. {
  251. size_t len_s = len;
  252. size_t from_shift;
  253. size_t from4;
  254. size_t len8;
  255. size_t len4;
  256. size_t i;
  257. idg_nvm_set_region_id(nvm, region);
  258. from4 = ALIGN_DOWN(from, sizeof(u32));
  259. from_shift = min(sizeof(u32) - ((size_t)from - from4), len);
  260. if (from - from4) {
  261. u32 data = idg_nvm_read32(nvm, from4);
  262. if (idg_nvm_error(nvm))
  263. return -EIO;
  264. memcpy(&buf[0], (u8 *)&data + (from - from4), from_shift);
  265. len_s -= from_shift;
  266. buf += from_shift;
  267. from += from_shift;
  268. }
  269. if (!IS_ALIGNED(from, sizeof(u64)) &&
  270. ((from ^ (from + len_s)) & GENMASK(31, 10))) {
  271. /*
  272. * Workaround reads/writes across 1k-aligned addresses
  273. * (start u32 before 1k, end u32 after)
  274. * as this fails on hardware.
  275. */
  276. u32 data = idg_nvm_read32(nvm, from);
  277. if (idg_nvm_error(nvm))
  278. return -EIO;
  279. memcpy(&buf[0], &data, sizeof(data));
  280. len_s -= sizeof(u32);
  281. buf += sizeof(u32);
  282. from += sizeof(u32);
  283. }
  284. len8 = ALIGN_DOWN(len_s, sizeof(u64));
  285. for (i = 0; i < len8; i += sizeof(u64)) {
  286. u64 data = idg_nvm_read64(nvm, from + i);
  287. if (idg_nvm_error(nvm))
  288. return -EIO;
  289. memcpy(&buf[i], &data, sizeof(data));
  290. }
  291. len4 = len_s - len8;
  292. if (len4 >= sizeof(u32)) {
  293. u32 data = idg_nvm_read32(nvm, from + i);
  294. if (idg_nvm_error(nvm))
  295. return -EIO;
  296. memcpy(&buf[i], &data, sizeof(data));
  297. i += sizeof(u32);
  298. len4 -= sizeof(u32);
  299. }
  300. if (len4 > 0) {
  301. u32 data = idg_nvm_read32(nvm, from + i);
  302. if (idg_nvm_error(nvm))
  303. return -EIO;
  304. memcpy(&buf[i], &data, len4);
  305. }
  306. return len;
  307. }
  308. static ssize_t
  309. idg_erase(struct intel_dg_nvm *nvm, u8 region, loff_t from, u64 len, u64 *fail_addr)
  310. {
  311. void __iomem *base2 = nvm->base2;
  312. void __iomem *base = nvm->base;
  313. const u32 block = 0x10;
  314. u32 iter = 0;
  315. u32 reg;
  316. u64 i;
  317. for (i = 0; i < len; i += SZ_4K) {
  318. iowrite32(from + i, base + NVM_ADDRESS_REG);
  319. iowrite32(region << 24 | block, base + NVM_ERASE_REG);
  320. if (nvm->non_posted_erase) {
  321. /* Wait for Erase Done */
  322. reg = ioread32(base2 + NVM_DEBUG_REG);
  323. while (!(reg & NVM_NON_POSTED_ERASE_DONE) &&
  324. ++iter < NVM_NON_POSTED_ERASE_DONE_ITER) {
  325. msleep(10);
  326. reg = ioread32(base2 + NVM_DEBUG_REG);
  327. }
  328. if (reg & NVM_NON_POSTED_ERASE_DONE) {
  329. /* Clear Erase Done */
  330. iowrite32(reg, base2 + NVM_DEBUG_REG);
  331. } else {
  332. *fail_addr = from + i;
  333. return -ETIME;
  334. }
  335. }
  336. /* Since the writes are via sgunit
  337. * we cannot do back to back erases.
  338. */
  339. msleep(50);
  340. }
  341. return len;
  342. }
  343. static int intel_dg_nvm_init(struct intel_dg_nvm *nvm, struct device *device,
  344. bool non_posted_erase)
  345. {
  346. u32 access_map = 0;
  347. unsigned int i, n;
  348. int ret;
  349. nvm->dev = device;
  350. /* clean error register, previous errors are ignored */
  351. idg_nvm_error(nvm);
  352. ret = idg_nvm_is_valid(nvm);
  353. if (ret) {
  354. dev_err(device, "The MEM is not valid %d\n", ret);
  355. return ret;
  356. }
  357. if (idg_nvm_get_access_map(nvm, &access_map))
  358. return -EIO;
  359. for (i = 0, n = 0; i < nvm->nregions; i++) {
  360. u32 address, base, limit, region;
  361. u8 id = nvm->regions[i].id;
  362. address = NVM_FLREG(id);
  363. region = idg_nvm_read32(nvm, address);
  364. base = FIELD_GET(NVM_FREG_BASE_MASK, region) << NVM_FREG_ADDR_SHIFT;
  365. limit = (FIELD_GET(NVM_FREG_ADDR_MASK, region) << NVM_FREG_ADDR_SHIFT) |
  366. NVM_FREG_MIN_REGION_SIZE;
  367. dev_dbg(device, "[%d] %s: region: 0x%08X base: 0x%08x limit: 0x%08x\n",
  368. id, nvm->regions[i].name, region, base, limit);
  369. if (base >= limit || (i > 0 && limit == 0)) {
  370. dev_dbg(device, "[%d] %s: disabled\n",
  371. id, nvm->regions[i].name);
  372. nvm->regions[i].is_readable = 0;
  373. continue;
  374. }
  375. if (nvm->size < limit)
  376. nvm->size = limit;
  377. nvm->regions[i].offset = base;
  378. nvm->regions[i].size = limit - base + 1;
  379. /* No write access to descriptor; mask it out*/
  380. nvm->regions[i].is_writable = idg_nvm_region_writable(access_map, id);
  381. nvm->regions[i].is_readable = idg_nvm_region_readable(access_map, id);
  382. dev_dbg(device, "Registered, %s id=%d offset=%lld size=%lld rd=%d wr=%d\n",
  383. nvm->regions[i].name,
  384. nvm->regions[i].id,
  385. nvm->regions[i].offset,
  386. nvm->regions[i].size,
  387. nvm->regions[i].is_readable,
  388. nvm->regions[i].is_writable);
  389. if (nvm->regions[i].is_readable)
  390. n++;
  391. }
  392. nvm->non_posted_erase = non_posted_erase;
  393. dev_dbg(device, "Registered %d regions\n", n);
  394. dev_dbg(device, "Non posted erase %d\n", nvm->non_posted_erase);
  395. /* Need to add 1 to the amount of memory
  396. * so it is reported as an even block
  397. */
  398. nvm->size += 1;
  399. return n;
  400. }
  401. static int intel_dg_mtd_erase(struct mtd_info *mtd, struct erase_info *info)
  402. {
  403. struct intel_dg_nvm *nvm = mtd->priv;
  404. size_t total_len;
  405. unsigned int idx;
  406. ssize_t bytes;
  407. loff_t from;
  408. size_t len;
  409. u8 region;
  410. u64 addr;
  411. int ret;
  412. if (WARN_ON(!nvm))
  413. return -EINVAL;
  414. if (!IS_ALIGNED(info->addr, SZ_4K) || !IS_ALIGNED(info->len, SZ_4K)) {
  415. dev_err(&mtd->dev, "unaligned erase %llx %llx\n",
  416. info->addr, info->len);
  417. info->fail_addr = MTD_FAIL_ADDR_UNKNOWN;
  418. return -EINVAL;
  419. }
  420. total_len = info->len;
  421. addr = info->addr;
  422. ret = pm_runtime_resume_and_get(nvm->dev);
  423. if (ret < 0) {
  424. dev_err(&mtd->dev, "rpm: get failed %d\n", ret);
  425. return ret;
  426. }
  427. ret = 0;
  428. guard(mutex)(&nvm->lock);
  429. while (total_len > 0) {
  430. if (!IS_ALIGNED(addr, SZ_4K) || !IS_ALIGNED(total_len, SZ_4K)) {
  431. dev_err(&mtd->dev, "unaligned erase %llx %zx\n", addr, total_len);
  432. info->fail_addr = addr;
  433. ret = -ERANGE;
  434. break;
  435. }
  436. idx = idg_nvm_get_region(nvm, addr);
  437. if (idx >= nvm->nregions) {
  438. dev_err(&mtd->dev, "out of range");
  439. info->fail_addr = MTD_FAIL_ADDR_UNKNOWN;
  440. ret = -ERANGE;
  441. break;
  442. }
  443. from = addr - nvm->regions[idx].offset;
  444. region = nvm->regions[idx].id;
  445. len = total_len;
  446. if (len > nvm->regions[idx].size - from)
  447. len = nvm->regions[idx].size - from;
  448. dev_dbg(&mtd->dev, "erasing region[%d] %s from %llx len %zx\n",
  449. region, nvm->regions[idx].name, from, len);
  450. bytes = idg_erase(nvm, region, from, len, &info->fail_addr);
  451. if (bytes < 0) {
  452. dev_dbg(&mtd->dev, "erase failed with %zd\n", bytes);
  453. info->fail_addr += nvm->regions[idx].offset;
  454. ret = bytes;
  455. break;
  456. }
  457. addr += len;
  458. total_len -= len;
  459. }
  460. pm_runtime_put_autosuspend(nvm->dev);
  461. return ret;
  462. }
  463. static int intel_dg_mtd_read(struct mtd_info *mtd, loff_t from, size_t len,
  464. size_t *retlen, u_char *buf)
  465. {
  466. struct intel_dg_nvm *nvm = mtd->priv;
  467. unsigned int idx;
  468. ssize_t ret;
  469. u8 region;
  470. if (WARN_ON(!nvm))
  471. return -EINVAL;
  472. idx = idg_nvm_get_region(nvm, from);
  473. dev_dbg(&mtd->dev, "reading region[%d] %s from %lld len %zd\n",
  474. nvm->regions[idx].id, nvm->regions[idx].name, from, len);
  475. if (idx >= nvm->nregions) {
  476. dev_err(&mtd->dev, "out of range");
  477. return -ERANGE;
  478. }
  479. from -= nvm->regions[idx].offset;
  480. region = nvm->regions[idx].id;
  481. if (len > nvm->regions[idx].size - from)
  482. len = nvm->regions[idx].size - from;
  483. ret = pm_runtime_resume_and_get(nvm->dev);
  484. if (ret < 0) {
  485. dev_err(&mtd->dev, "rpm: get failed %zd\n", ret);
  486. return ret;
  487. }
  488. guard(mutex)(&nvm->lock);
  489. ret = idg_read(nvm, region, from, len, buf);
  490. if (ret < 0) {
  491. dev_dbg(&mtd->dev, "read failed with %zd\n", ret);
  492. } else {
  493. *retlen = ret;
  494. ret = 0;
  495. }
  496. pm_runtime_put_autosuspend(nvm->dev);
  497. return ret;
  498. }
  499. static int intel_dg_mtd_write(struct mtd_info *mtd, loff_t to, size_t len,
  500. size_t *retlen, const u_char *buf)
  501. {
  502. struct intel_dg_nvm *nvm = mtd->priv;
  503. unsigned int idx;
  504. ssize_t ret;
  505. u8 region;
  506. if (WARN_ON(!nvm))
  507. return -EINVAL;
  508. idx = idg_nvm_get_region(nvm, to);
  509. dev_dbg(&mtd->dev, "writing region[%d] %s to %lld len %zd\n",
  510. nvm->regions[idx].id, nvm->regions[idx].name, to, len);
  511. if (idx >= nvm->nregions) {
  512. dev_err(&mtd->dev, "out of range");
  513. return -ERANGE;
  514. }
  515. to -= nvm->regions[idx].offset;
  516. region = nvm->regions[idx].id;
  517. if (len > nvm->regions[idx].size - to)
  518. len = nvm->regions[idx].size - to;
  519. ret = pm_runtime_resume_and_get(nvm->dev);
  520. if (ret < 0) {
  521. dev_err(&mtd->dev, "rpm: get failed %zd\n", ret);
  522. return ret;
  523. }
  524. guard(mutex)(&nvm->lock);
  525. ret = idg_write(nvm, region, to, len, buf);
  526. if (ret < 0) {
  527. dev_dbg(&mtd->dev, "write failed with %zd\n", ret);
  528. } else {
  529. *retlen = ret;
  530. ret = 0;
  531. }
  532. pm_runtime_put_autosuspend(nvm->dev);
  533. return ret;
  534. }
  535. static void intel_dg_nvm_release(struct kref *kref)
  536. {
  537. struct intel_dg_nvm *nvm = container_of(kref, struct intel_dg_nvm, refcnt);
  538. int i;
  539. pr_debug("freeing intel_dg nvm\n");
  540. for (i = 0; i < nvm->nregions; i++)
  541. kfree(nvm->regions[i].name);
  542. mutex_destroy(&nvm->lock);
  543. kfree(nvm);
  544. }
  545. static int intel_dg_mtd_get_device(struct mtd_info *mtd)
  546. {
  547. struct mtd_info *master = mtd_get_master(mtd);
  548. struct intel_dg_nvm *nvm = master->priv;
  549. if (WARN_ON(!nvm))
  550. return -EINVAL;
  551. pr_debug("get mtd %s %d\n", mtd->name, kref_read(&nvm->refcnt));
  552. kref_get(&nvm->refcnt);
  553. return 0;
  554. }
  555. static void intel_dg_mtd_put_device(struct mtd_info *mtd)
  556. {
  557. struct mtd_info *master = mtd_get_master(mtd);
  558. struct intel_dg_nvm *nvm = master->priv;
  559. if (WARN_ON(!nvm))
  560. return;
  561. pr_debug("put mtd %s %d\n", mtd->name, kref_read(&nvm->refcnt));
  562. kref_put(&nvm->refcnt, intel_dg_nvm_release);
  563. }
  564. static int intel_dg_nvm_init_mtd(struct intel_dg_nvm *nvm, struct device *device,
  565. unsigned int nparts, bool writable_override)
  566. {
  567. struct mtd_partition *parts = NULL;
  568. unsigned int i, n;
  569. int ret;
  570. dev_dbg(device, "registering with mtd\n");
  571. nvm->mtd.owner = THIS_MODULE;
  572. nvm->mtd.dev.parent = device;
  573. nvm->mtd.flags = MTD_CAP_NORFLASH;
  574. nvm->mtd.type = MTD_DATAFLASH;
  575. nvm->mtd.priv = nvm;
  576. nvm->mtd._write = intel_dg_mtd_write;
  577. nvm->mtd._read = intel_dg_mtd_read;
  578. nvm->mtd._erase = intel_dg_mtd_erase;
  579. nvm->mtd._get_device = intel_dg_mtd_get_device;
  580. nvm->mtd._put_device = intel_dg_mtd_put_device;
  581. nvm->mtd.writesize = SZ_1; /* 1 byte granularity */
  582. nvm->mtd.erasesize = SZ_4K; /* 4K bytes granularity */
  583. nvm->mtd.size = nvm->size;
  584. parts = kzalloc_objs(*parts, nvm->nregions);
  585. if (!parts)
  586. return -ENOMEM;
  587. for (i = 0, n = 0; i < nvm->nregions && n < nparts; i++) {
  588. if (!nvm->regions[i].is_readable)
  589. continue;
  590. parts[n].name = nvm->regions[i].name;
  591. parts[n].offset = nvm->regions[i].offset;
  592. parts[n].size = nvm->regions[i].size;
  593. if (!nvm->regions[i].is_writable && !writable_override)
  594. parts[n].mask_flags = MTD_WRITEABLE;
  595. n++;
  596. }
  597. ret = mtd_device_register(&nvm->mtd, parts, n);
  598. kfree(parts);
  599. return ret;
  600. }
  601. static int intel_dg_mtd_probe(struct auxiliary_device *aux_dev,
  602. const struct auxiliary_device_id *aux_dev_id)
  603. {
  604. struct intel_dg_nvm_dev *invm = auxiliary_dev_to_intel_dg_nvm_dev(aux_dev);
  605. struct intel_dg_nvm *nvm;
  606. struct device *device;
  607. unsigned int nregions;
  608. unsigned int i, n;
  609. int ret;
  610. device = &aux_dev->dev;
  611. /* count available regions */
  612. for (nregions = 0, i = 0; i < INTEL_DG_NVM_REGIONS; i++) {
  613. if (invm->regions[i].name)
  614. nregions++;
  615. }
  616. if (!nregions) {
  617. dev_err(device, "no regions defined\n");
  618. return -ENODEV;
  619. }
  620. nvm = kzalloc_flex(*nvm, regions, nregions);
  621. if (!nvm)
  622. return -ENOMEM;
  623. kref_init(&nvm->refcnt);
  624. mutex_init(&nvm->lock);
  625. nvm->nregions = nregions;
  626. for (n = 0, i = 0; i < INTEL_DG_NVM_REGIONS; i++) {
  627. if (!invm->regions[i].name)
  628. continue;
  629. char *name = kasprintf(GFP_KERNEL, "%s.%s",
  630. dev_name(&aux_dev->dev), invm->regions[i].name);
  631. if (!name) {
  632. ret = -ENOMEM;
  633. goto err;
  634. }
  635. nvm->regions[n].name = name;
  636. nvm->regions[n].id = i;
  637. n++;
  638. }
  639. ret = devm_pm_runtime_enable(device);
  640. if (ret < 0) {
  641. dev_err(device, "rpm: enable failed %d\n", ret);
  642. goto err_norpm;
  643. }
  644. pm_runtime_set_autosuspend_delay(device, INTEL_DG_NVM_RPM_TIMEOUT_MS);
  645. pm_runtime_use_autosuspend(device);
  646. ret = pm_runtime_resume_and_get(device);
  647. if (ret < 0) {
  648. dev_err(device, "rpm: get failed %d\n", ret);
  649. goto err_norpm;
  650. }
  651. nvm->base = devm_ioremap_resource(device, &invm->bar);
  652. if (IS_ERR(nvm->base)) {
  653. ret = PTR_ERR(nvm->base);
  654. goto err;
  655. }
  656. if (invm->non_posted_erase) {
  657. nvm->base2 = devm_ioremap_resource(device, &invm->bar2);
  658. if (IS_ERR(nvm->base2)) {
  659. ret = PTR_ERR(nvm->base2);
  660. goto err;
  661. }
  662. }
  663. ret = intel_dg_nvm_init(nvm, device, invm->non_posted_erase);
  664. if (ret < 0) {
  665. dev_err(device, "cannot initialize nvm %d\n", ret);
  666. goto err;
  667. }
  668. ret = intel_dg_nvm_init_mtd(nvm, device, ret, invm->writable_override);
  669. if (ret) {
  670. dev_err(device, "failed init mtd %d\n", ret);
  671. goto err;
  672. }
  673. dev_set_drvdata(&aux_dev->dev, nvm);
  674. pm_runtime_put(device);
  675. return 0;
  676. err:
  677. pm_runtime_put(device);
  678. err_norpm:
  679. kref_put(&nvm->refcnt, intel_dg_nvm_release);
  680. return ret;
  681. }
  682. static void intel_dg_mtd_remove(struct auxiliary_device *aux_dev)
  683. {
  684. struct intel_dg_nvm *nvm = dev_get_drvdata(&aux_dev->dev);
  685. if (!nvm)
  686. return;
  687. mtd_device_unregister(&nvm->mtd);
  688. dev_set_drvdata(&aux_dev->dev, NULL);
  689. kref_put(&nvm->refcnt, intel_dg_nvm_release);
  690. }
  691. static const struct auxiliary_device_id intel_dg_mtd_id_table[] = {
  692. {
  693. .name = "i915.nvm",
  694. },
  695. {
  696. .name = "xe.nvm",
  697. },
  698. {
  699. /* sentinel */
  700. }
  701. };
  702. MODULE_DEVICE_TABLE(auxiliary, intel_dg_mtd_id_table);
  703. static struct auxiliary_driver intel_dg_mtd_driver = {
  704. .probe = intel_dg_mtd_probe,
  705. .remove = intel_dg_mtd_remove,
  706. .driver = {
  707. /* auxiliary_driver_register() sets .name to be the modname */
  708. },
  709. .id_table = intel_dg_mtd_id_table
  710. };
  711. module_auxiliary_driver(intel_dg_mtd_driver);
  712. MODULE_LICENSE("GPL");
  713. MODULE_AUTHOR("Intel Corporation");
  714. MODULE_DESCRIPTION("Intel DGFX MTD driver");