sb_edac.c 97 KB

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  1. // SPDX-License-Identifier: GPL-2.0-only
  2. /* Intel Sandy Bridge -EN/-EP/-EX Memory Controller kernel module
  3. *
  4. * This driver supports the memory controllers found on the Intel
  5. * processor family Sandy Bridge.
  6. *
  7. * Copyright (c) 2011 by:
  8. * Mauro Carvalho Chehab
  9. */
  10. #include <linux/module.h>
  11. #include <linux/init.h>
  12. #include <linux/pci.h>
  13. #include <linux/pci_ids.h>
  14. #include <linux/slab.h>
  15. #include <linux/delay.h>
  16. #include <linux/edac.h>
  17. #include <linux/mmzone.h>
  18. #include <linux/smp.h>
  19. #include <linux/bitmap.h>
  20. #include <linux/math64.h>
  21. #include <linux/mod_devicetable.h>
  22. #include <asm/cpu_device_id.h>
  23. #include <asm/intel-family.h>
  24. #include <asm/processor.h>
  25. #include <asm/mce.h>
  26. #include "edac_module.h"
  27. /* Static vars */
  28. static LIST_HEAD(sbridge_edac_list);
  29. static char sb_msg[256];
  30. static char sb_msg_full[512];
  31. /*
  32. * Alter this version for the module when modifications are made
  33. */
  34. #define SBRIDGE_REVISION " Ver: 1.1.2 "
  35. #define EDAC_MOD_STR "sb_edac"
  36. /*
  37. * Debug macros
  38. */
  39. #define sbridge_printk(level, fmt, arg...) \
  40. edac_printk(level, "sbridge", fmt, ##arg)
  41. #define sbridge_mc_printk(mci, level, fmt, arg...) \
  42. edac_mc_chipset_printk(mci, level, "sbridge", fmt, ##arg)
  43. /*
  44. * Get a bit field at register value <v>, from bit <lo> to bit <hi>
  45. */
  46. #define GET_BITFIELD(v, lo, hi) \
  47. (((v) & GENMASK_ULL(hi, lo)) >> (lo))
  48. /* Devices 12 Function 6, Offsets 0x80 to 0xcc */
  49. static const u32 sbridge_dram_rule[] = {
  50. 0x80, 0x88, 0x90, 0x98, 0xa0,
  51. 0xa8, 0xb0, 0xb8, 0xc0, 0xc8,
  52. };
  53. static const u32 ibridge_dram_rule[] = {
  54. 0x60, 0x68, 0x70, 0x78, 0x80,
  55. 0x88, 0x90, 0x98, 0xa0, 0xa8,
  56. 0xb0, 0xb8, 0xc0, 0xc8, 0xd0,
  57. 0xd8, 0xe0, 0xe8, 0xf0, 0xf8,
  58. };
  59. static const u32 knl_dram_rule[] = {
  60. 0x60, 0x68, 0x70, 0x78, 0x80, /* 0-4 */
  61. 0x88, 0x90, 0x98, 0xa0, 0xa8, /* 5-9 */
  62. 0xb0, 0xb8, 0xc0, 0xc8, 0xd0, /* 10-14 */
  63. 0xd8, 0xe0, 0xe8, 0xf0, 0xf8, /* 15-19 */
  64. 0x100, 0x108, 0x110, 0x118, /* 20-23 */
  65. };
  66. #define DRAM_RULE_ENABLE(reg) GET_BITFIELD(reg, 0, 0)
  67. #define A7MODE(reg) GET_BITFIELD(reg, 26, 26)
  68. static char *show_dram_attr(u32 attr)
  69. {
  70. switch (attr) {
  71. case 0:
  72. return "DRAM";
  73. case 1:
  74. return "MMCFG";
  75. case 2:
  76. return "NXM";
  77. default:
  78. return "unknown";
  79. }
  80. }
  81. static const u32 sbridge_interleave_list[] = {
  82. 0x84, 0x8c, 0x94, 0x9c, 0xa4,
  83. 0xac, 0xb4, 0xbc, 0xc4, 0xcc,
  84. };
  85. static const u32 ibridge_interleave_list[] = {
  86. 0x64, 0x6c, 0x74, 0x7c, 0x84,
  87. 0x8c, 0x94, 0x9c, 0xa4, 0xac,
  88. 0xb4, 0xbc, 0xc4, 0xcc, 0xd4,
  89. 0xdc, 0xe4, 0xec, 0xf4, 0xfc,
  90. };
  91. static const u32 knl_interleave_list[] = {
  92. 0x64, 0x6c, 0x74, 0x7c, 0x84, /* 0-4 */
  93. 0x8c, 0x94, 0x9c, 0xa4, 0xac, /* 5-9 */
  94. 0xb4, 0xbc, 0xc4, 0xcc, 0xd4, /* 10-14 */
  95. 0xdc, 0xe4, 0xec, 0xf4, 0xfc, /* 15-19 */
  96. 0x104, 0x10c, 0x114, 0x11c, /* 20-23 */
  97. };
  98. #define MAX_INTERLEAVE \
  99. (MAX_T(unsigned int, ARRAY_SIZE(sbridge_interleave_list), \
  100. MAX_T(unsigned int, ARRAY_SIZE(ibridge_interleave_list), \
  101. ARRAY_SIZE(knl_interleave_list))))
  102. struct interleave_pkg {
  103. unsigned char start;
  104. unsigned char end;
  105. };
  106. static const struct interleave_pkg sbridge_interleave_pkg[] = {
  107. { 0, 2 },
  108. { 3, 5 },
  109. { 8, 10 },
  110. { 11, 13 },
  111. { 16, 18 },
  112. { 19, 21 },
  113. { 24, 26 },
  114. { 27, 29 },
  115. };
  116. static const struct interleave_pkg ibridge_interleave_pkg[] = {
  117. { 0, 3 },
  118. { 4, 7 },
  119. { 8, 11 },
  120. { 12, 15 },
  121. { 16, 19 },
  122. { 20, 23 },
  123. { 24, 27 },
  124. { 28, 31 },
  125. };
  126. static inline int sad_pkg(const struct interleave_pkg *table, u32 reg,
  127. int interleave)
  128. {
  129. return GET_BITFIELD(reg, table[interleave].start,
  130. table[interleave].end);
  131. }
  132. /* Devices 12 Function 7 */
  133. #define TOLM 0x80
  134. #define TOHM 0x84
  135. #define HASWELL_TOLM 0xd0
  136. #define HASWELL_TOHM_0 0xd4
  137. #define HASWELL_TOHM_1 0xd8
  138. #define KNL_TOLM 0xd0
  139. #define KNL_TOHM_0 0xd4
  140. #define KNL_TOHM_1 0xd8
  141. #define GET_TOLM(reg) ((GET_BITFIELD(reg, 0, 3) << 28) | 0x3ffffff)
  142. #define GET_TOHM(reg) ((GET_BITFIELD(reg, 0, 20) << 25) | 0x3ffffff)
  143. /* Device 13 Function 6 */
  144. #define SAD_TARGET 0xf0
  145. #define SOURCE_ID(reg) GET_BITFIELD(reg, 9, 11)
  146. #define SOURCE_ID_KNL(reg) GET_BITFIELD(reg, 12, 14)
  147. #define SAD_CONTROL 0xf4
  148. /* Device 14 function 0 */
  149. static const u32 tad_dram_rule[] = {
  150. 0x40, 0x44, 0x48, 0x4c,
  151. 0x50, 0x54, 0x58, 0x5c,
  152. 0x60, 0x64, 0x68, 0x6c,
  153. };
  154. #define MAX_TAD ARRAY_SIZE(tad_dram_rule)
  155. #define TAD_LIMIT(reg) ((GET_BITFIELD(reg, 12, 31) << 26) | 0x3ffffff)
  156. #define TAD_SOCK(reg) GET_BITFIELD(reg, 10, 11)
  157. #define TAD_CH(reg) GET_BITFIELD(reg, 8, 9)
  158. #define TAD_TGT3(reg) GET_BITFIELD(reg, 6, 7)
  159. #define TAD_TGT2(reg) GET_BITFIELD(reg, 4, 5)
  160. #define TAD_TGT1(reg) GET_BITFIELD(reg, 2, 3)
  161. #define TAD_TGT0(reg) GET_BITFIELD(reg, 0, 1)
  162. /* Device 15, function 0 */
  163. #define MCMTR 0x7c
  164. #define KNL_MCMTR 0x624
  165. #define IS_ECC_ENABLED(mcmtr) GET_BITFIELD(mcmtr, 2, 2)
  166. #define IS_LOCKSTEP_ENABLED(mcmtr) GET_BITFIELD(mcmtr, 1, 1)
  167. #define IS_CLOSE_PG(mcmtr) GET_BITFIELD(mcmtr, 0, 0)
  168. /* Device 15, function 1 */
  169. #define RASENABLES 0xac
  170. #define IS_MIRROR_ENABLED(reg) GET_BITFIELD(reg, 0, 0)
  171. /* Device 15, functions 2-5 */
  172. static const int mtr_regs[] = {
  173. 0x80, 0x84, 0x88,
  174. };
  175. static const int knl_mtr_reg = 0xb60;
  176. #define RANK_DISABLE(mtr) GET_BITFIELD(mtr, 16, 19)
  177. #define IS_DIMM_PRESENT(mtr) GET_BITFIELD(mtr, 14, 14)
  178. #define RANK_CNT_BITS(mtr) GET_BITFIELD(mtr, 12, 13)
  179. #define RANK_WIDTH_BITS(mtr) GET_BITFIELD(mtr, 2, 4)
  180. #define COL_WIDTH_BITS(mtr) GET_BITFIELD(mtr, 0, 1)
  181. static const u32 tad_ch_nilv_offset[] = {
  182. 0x90, 0x94, 0x98, 0x9c,
  183. 0xa0, 0xa4, 0xa8, 0xac,
  184. 0xb0, 0xb4, 0xb8, 0xbc,
  185. };
  186. #define CHN_IDX_OFFSET(reg) GET_BITFIELD(reg, 28, 29)
  187. #define TAD_OFFSET(reg) (GET_BITFIELD(reg, 6, 25) << 26)
  188. static const u32 rir_way_limit[] = {
  189. 0x108, 0x10c, 0x110, 0x114, 0x118,
  190. };
  191. #define MAX_RIR_RANGES ARRAY_SIZE(rir_way_limit)
  192. #define IS_RIR_VALID(reg) GET_BITFIELD(reg, 31, 31)
  193. #define RIR_WAY(reg) GET_BITFIELD(reg, 28, 29)
  194. #define MAX_RIR_WAY 8
  195. static const u32 rir_offset[MAX_RIR_RANGES][MAX_RIR_WAY] = {
  196. { 0x120, 0x124, 0x128, 0x12c, 0x130, 0x134, 0x138, 0x13c },
  197. { 0x140, 0x144, 0x148, 0x14c, 0x150, 0x154, 0x158, 0x15c },
  198. { 0x160, 0x164, 0x168, 0x16c, 0x170, 0x174, 0x178, 0x17c },
  199. { 0x180, 0x184, 0x188, 0x18c, 0x190, 0x194, 0x198, 0x19c },
  200. { 0x1a0, 0x1a4, 0x1a8, 0x1ac, 0x1b0, 0x1b4, 0x1b8, 0x1bc },
  201. };
  202. #define RIR_RNK_TGT(type, reg) (((type) == BROADWELL) ? \
  203. GET_BITFIELD(reg, 20, 23) : GET_BITFIELD(reg, 16, 19))
  204. #define RIR_OFFSET(type, reg) (((type) == HASWELL || (type) == BROADWELL) ? \
  205. GET_BITFIELD(reg, 2, 15) : GET_BITFIELD(reg, 2, 14))
  206. /* Device 16, functions 2-7 */
  207. /*
  208. * FIXME: Implement the error count reads directly
  209. */
  210. #define RANK_ODD_OV(reg) GET_BITFIELD(reg, 31, 31)
  211. #define RANK_ODD_ERR_CNT(reg) GET_BITFIELD(reg, 16, 30)
  212. #define RANK_EVEN_OV(reg) GET_BITFIELD(reg, 15, 15)
  213. #define RANK_EVEN_ERR_CNT(reg) GET_BITFIELD(reg, 0, 14)
  214. #if 0 /* Currently unused*/
  215. static const u32 correrrcnt[] = {
  216. 0x104, 0x108, 0x10c, 0x110,
  217. };
  218. static const u32 correrrthrsld[] = {
  219. 0x11c, 0x120, 0x124, 0x128,
  220. };
  221. #endif
  222. #define RANK_ODD_ERR_THRSLD(reg) GET_BITFIELD(reg, 16, 30)
  223. #define RANK_EVEN_ERR_THRSLD(reg) GET_BITFIELD(reg, 0, 14)
  224. /* Device 17, function 0 */
  225. #define SB_RANK_CFG_A 0x0328
  226. #define IB_RANK_CFG_A 0x0320
  227. /*
  228. * sbridge structs
  229. */
  230. #define NUM_CHANNELS 6 /* Max channels per MC */
  231. #define MAX_DIMMS 3 /* Max DIMMS per channel */
  232. #define KNL_MAX_CHAS 38 /* KNL max num. of Cache Home Agents */
  233. #define KNL_MAX_CHANNELS 6 /* KNL max num. of PCI channels */
  234. #define KNL_MAX_EDCS 8 /* Embedded DRAM controllers */
  235. #define CHANNEL_UNSPECIFIED 0xf /* Intel IA32 SDM 15-14 */
  236. enum type {
  237. SANDY_BRIDGE,
  238. IVY_BRIDGE,
  239. HASWELL,
  240. BROADWELL,
  241. KNIGHTS_LANDING,
  242. };
  243. enum domain {
  244. IMC0 = 0,
  245. IMC1,
  246. SOCK,
  247. };
  248. enum mirroring_mode {
  249. NON_MIRRORING,
  250. ADDR_RANGE_MIRRORING,
  251. FULL_MIRRORING,
  252. };
  253. struct sbridge_pvt;
  254. struct sbridge_info {
  255. enum type type;
  256. u32 mcmtr;
  257. u32 rankcfgr;
  258. u64 (*get_tolm)(struct sbridge_pvt *pvt);
  259. u64 (*get_tohm)(struct sbridge_pvt *pvt);
  260. u64 (*rir_limit)(u32 reg);
  261. u64 (*sad_limit)(u32 reg);
  262. u32 (*interleave_mode)(u32 reg);
  263. u32 (*dram_attr)(u32 reg);
  264. const u32 *dram_rule;
  265. const u32 *interleave_list;
  266. const struct interleave_pkg *interleave_pkg;
  267. u8 max_sad;
  268. u8 (*get_node_id)(struct sbridge_pvt *pvt);
  269. u8 (*get_ha)(u8 bank);
  270. enum mem_type (*get_memory_type)(struct sbridge_pvt *pvt);
  271. enum dev_type (*get_width)(struct sbridge_pvt *pvt, u32 mtr);
  272. struct pci_dev *pci_vtd;
  273. };
  274. struct sbridge_channel {
  275. u32 ranks;
  276. u32 dimms;
  277. struct dimm {
  278. u32 rowbits;
  279. u32 colbits;
  280. u32 bank_xor_enable;
  281. u32 amap_fine;
  282. } dimm[MAX_DIMMS];
  283. };
  284. struct pci_id_descr {
  285. int dev_id;
  286. int optional;
  287. enum domain dom;
  288. };
  289. struct pci_id_table {
  290. const struct pci_id_descr *descr;
  291. int n_devs_per_imc;
  292. int n_devs_per_sock;
  293. int n_imcs_per_sock;
  294. enum type type;
  295. };
  296. struct sbridge_dev {
  297. struct list_head list;
  298. int seg;
  299. u8 bus, mc;
  300. u8 node_id, source_id;
  301. struct pci_dev **pdev;
  302. enum domain dom;
  303. int n_devs;
  304. int i_devs;
  305. struct mem_ctl_info *mci;
  306. };
  307. struct knl_pvt {
  308. struct pci_dev *pci_cha[KNL_MAX_CHAS];
  309. struct pci_dev *pci_channel[KNL_MAX_CHANNELS];
  310. struct pci_dev *pci_mc0;
  311. struct pci_dev *pci_mc1;
  312. struct pci_dev *pci_mc0_misc;
  313. struct pci_dev *pci_mc1_misc;
  314. struct pci_dev *pci_mc_info; /* tolm, tohm */
  315. };
  316. struct sbridge_pvt {
  317. /* Devices per socket */
  318. struct pci_dev *pci_ddrio;
  319. struct pci_dev *pci_sad0, *pci_sad1;
  320. struct pci_dev *pci_br0, *pci_br1;
  321. /* Devices per memory controller */
  322. struct pci_dev *pci_ha, *pci_ta, *pci_ras;
  323. struct pci_dev *pci_tad[NUM_CHANNELS];
  324. struct sbridge_dev *sbridge_dev;
  325. struct sbridge_info info;
  326. struct sbridge_channel channel[NUM_CHANNELS];
  327. /* Memory type detection */
  328. bool is_cur_addr_mirrored, is_lockstep, is_close_pg;
  329. bool is_chan_hash;
  330. enum mirroring_mode mirror_mode;
  331. /* Memory description */
  332. u64 tolm, tohm;
  333. struct knl_pvt knl;
  334. };
  335. #define PCI_DESCR(device_id, opt, domain) \
  336. .dev_id = (device_id), \
  337. .optional = opt, \
  338. .dom = domain
  339. static const struct pci_id_descr pci_dev_descr_sbridge[] = {
  340. /* Processor Home Agent */
  341. { PCI_DESCR(PCI_DEVICE_ID_INTEL_SBRIDGE_IMC_HA0, 0, IMC0) },
  342. /* Memory controller */
  343. { PCI_DESCR(PCI_DEVICE_ID_INTEL_SBRIDGE_IMC_TA, 0, IMC0) },
  344. { PCI_DESCR(PCI_DEVICE_ID_INTEL_SBRIDGE_IMC_RAS, 0, IMC0) },
  345. { PCI_DESCR(PCI_DEVICE_ID_INTEL_SBRIDGE_IMC_TAD0, 0, IMC0) },
  346. { PCI_DESCR(PCI_DEVICE_ID_INTEL_SBRIDGE_IMC_TAD1, 0, IMC0) },
  347. { PCI_DESCR(PCI_DEVICE_ID_INTEL_SBRIDGE_IMC_TAD2, 0, IMC0) },
  348. { PCI_DESCR(PCI_DEVICE_ID_INTEL_SBRIDGE_IMC_TAD3, 0, IMC0) },
  349. { PCI_DESCR(PCI_DEVICE_ID_INTEL_SBRIDGE_IMC_DDRIO, 1, SOCK) },
  350. /* System Address Decoder */
  351. { PCI_DESCR(PCI_DEVICE_ID_INTEL_SBRIDGE_SAD0, 0, SOCK) },
  352. { PCI_DESCR(PCI_DEVICE_ID_INTEL_SBRIDGE_SAD1, 0, SOCK) },
  353. /* Broadcast Registers */
  354. { PCI_DESCR(PCI_DEVICE_ID_INTEL_SBRIDGE_BR, 0, SOCK) },
  355. };
  356. #define PCI_ID_TABLE_ENTRY(A, N, M, T) { \
  357. .descr = A, \
  358. .n_devs_per_imc = N, \
  359. .n_devs_per_sock = ARRAY_SIZE(A), \
  360. .n_imcs_per_sock = M, \
  361. .type = T \
  362. }
  363. static const struct pci_id_table pci_dev_descr_sbridge_table[] = {
  364. PCI_ID_TABLE_ENTRY(pci_dev_descr_sbridge, ARRAY_SIZE(pci_dev_descr_sbridge), 1, SANDY_BRIDGE),
  365. { NULL, }
  366. };
  367. /* This changes depending if 1HA or 2HA:
  368. * 1HA:
  369. * 0x0eb8 (17.0) is DDRIO0
  370. * 2HA:
  371. * 0x0ebc (17.4) is DDRIO0
  372. */
  373. #define PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_1HA_DDRIO0 0x0eb8
  374. #define PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_2HA_DDRIO0 0x0ebc
  375. /* pci ids */
  376. #define PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0 0x0ea0
  377. #define PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_TA 0x0ea8
  378. #define PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_RAS 0x0e71
  379. #define PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_TAD0 0x0eaa
  380. #define PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_TAD1 0x0eab
  381. #define PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_TAD2 0x0eac
  382. #define PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_TAD3 0x0ead
  383. #define PCI_DEVICE_ID_INTEL_IBRIDGE_SAD 0x0ec8
  384. #define PCI_DEVICE_ID_INTEL_IBRIDGE_BR0 0x0ec9
  385. #define PCI_DEVICE_ID_INTEL_IBRIDGE_BR1 0x0eca
  386. #define PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1 0x0e60
  387. #define PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_TA 0x0e68
  388. #define PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_RAS 0x0e79
  389. #define PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_TAD0 0x0e6a
  390. #define PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_TAD1 0x0e6b
  391. #define PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_TAD2 0x0e6c
  392. #define PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_TAD3 0x0e6d
  393. static const struct pci_id_descr pci_dev_descr_ibridge[] = {
  394. /* Processor Home Agent */
  395. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0, 0, IMC0) },
  396. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1, 1, IMC1) },
  397. /* Memory controller */
  398. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_TA, 0, IMC0) },
  399. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_RAS, 0, IMC0) },
  400. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_TAD0, 0, IMC0) },
  401. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_TAD1, 0, IMC0) },
  402. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_TAD2, 0, IMC0) },
  403. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_TAD3, 0, IMC0) },
  404. /* Optional, mode 2HA */
  405. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_TA, 1, IMC1) },
  406. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_RAS, 1, IMC1) },
  407. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_TAD0, 1, IMC1) },
  408. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_TAD1, 1, IMC1) },
  409. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_TAD2, 1, IMC1) },
  410. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_TAD3, 1, IMC1) },
  411. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_1HA_DDRIO0, 1, SOCK) },
  412. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_2HA_DDRIO0, 1, SOCK) },
  413. /* System Address Decoder */
  414. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_SAD, 0, SOCK) },
  415. /* Broadcast Registers */
  416. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_BR0, 1, SOCK) },
  417. { PCI_DESCR(PCI_DEVICE_ID_INTEL_IBRIDGE_BR1, 0, SOCK) },
  418. };
  419. static const struct pci_id_table pci_dev_descr_ibridge_table[] = {
  420. PCI_ID_TABLE_ENTRY(pci_dev_descr_ibridge, 12, 2, IVY_BRIDGE),
  421. { NULL, }
  422. };
  423. /* Haswell support */
  424. /* EN processor:
  425. * - 1 IMC
  426. * - 3 DDR3 channels, 2 DPC per channel
  427. * EP processor:
  428. * - 1 or 2 IMC
  429. * - 4 DDR4 channels, 3 DPC per channel
  430. * EP 4S processor:
  431. * - 2 IMC
  432. * - 4 DDR4 channels, 3 DPC per channel
  433. * EX processor:
  434. * - 2 IMC
  435. * - each IMC interfaces with a SMI 2 channel
  436. * - each SMI channel interfaces with a scalable memory buffer
  437. * - each scalable memory buffer supports 4 DDR3/DDR4 channels, 3 DPC
  438. */
  439. #define HASWELL_DDRCRCLKCONTROLS 0xa10 /* Ditto on Broadwell */
  440. #define HASWELL_HASYSDEFEATURE2 0x84
  441. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_VTD_MISC 0x2f28
  442. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0 0x2fa0
  443. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1 0x2f60
  444. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TA 0x2fa8
  445. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TM 0x2f71
  446. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TA 0x2f68
  447. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TM 0x2f79
  448. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_CBO_SAD0 0x2ffc
  449. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_CBO_SAD1 0x2ffd
  450. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TAD0 0x2faa
  451. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TAD1 0x2fab
  452. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TAD2 0x2fac
  453. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TAD3 0x2fad
  454. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TAD0 0x2f6a
  455. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TAD1 0x2f6b
  456. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TAD2 0x2f6c
  457. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TAD3 0x2f6d
  458. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_DDRIO0 0x2fbd
  459. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_DDRIO1 0x2fbf
  460. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_DDRIO2 0x2fb9
  461. #define PCI_DEVICE_ID_INTEL_HASWELL_IMC_DDRIO3 0x2fbb
  462. static const struct pci_id_descr pci_dev_descr_haswell[] = {
  463. /* first item must be the HA */
  464. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0, 0, IMC0) },
  465. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1, 1, IMC1) },
  466. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TA, 0, IMC0) },
  467. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TM, 0, IMC0) },
  468. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TAD0, 0, IMC0) },
  469. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TAD1, 0, IMC0) },
  470. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TAD2, 1, IMC0) },
  471. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TAD3, 1, IMC0) },
  472. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TA, 1, IMC1) },
  473. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TM, 1, IMC1) },
  474. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TAD0, 1, IMC1) },
  475. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TAD1, 1, IMC1) },
  476. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TAD2, 1, IMC1) },
  477. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TAD3, 1, IMC1) },
  478. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_CBO_SAD0, 0, SOCK) },
  479. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_CBO_SAD1, 0, SOCK) },
  480. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_DDRIO0, 1, SOCK) },
  481. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_DDRIO1, 1, SOCK) },
  482. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_DDRIO2, 1, SOCK) },
  483. { PCI_DESCR(PCI_DEVICE_ID_INTEL_HASWELL_IMC_DDRIO3, 1, SOCK) },
  484. };
  485. static const struct pci_id_table pci_dev_descr_haswell_table[] = {
  486. PCI_ID_TABLE_ENTRY(pci_dev_descr_haswell, 13, 2, HASWELL),
  487. { NULL, }
  488. };
  489. /* Knight's Landing Support */
  490. /*
  491. * KNL's memory channels are swizzled between memory controllers.
  492. * MC0 is mapped to CH3,4,5 and MC1 is mapped to CH0,1,2
  493. */
  494. #define knl_channel_remap(mc, chan) ((mc) ? (chan) : (chan) + 3)
  495. /* Memory controller, TAD tables, error injection - 2-8-0, 2-9-0 (2 of these) */
  496. #define PCI_DEVICE_ID_INTEL_KNL_IMC_MC 0x7840
  497. /* DRAM channel stuff; bank addrs, dimmmtr, etc.. 2-8-2 - 2-9-4 (6 of these) */
  498. #define PCI_DEVICE_ID_INTEL_KNL_IMC_CHAN 0x7843
  499. /* kdrwdbu TAD limits/offsets, MCMTR - 2-10-1, 2-11-1 (2 of these) */
  500. #define PCI_DEVICE_ID_INTEL_KNL_IMC_TA 0x7844
  501. /* CHA broadcast registers, dram rules - 1-29-0 (1 of these) */
  502. #define PCI_DEVICE_ID_INTEL_KNL_IMC_SAD0 0x782a
  503. /* SAD target - 1-29-1 (1 of these) */
  504. #define PCI_DEVICE_ID_INTEL_KNL_IMC_SAD1 0x782b
  505. /* Caching / Home Agent */
  506. #define PCI_DEVICE_ID_INTEL_KNL_IMC_CHA 0x782c
  507. /* Device with TOLM and TOHM, 0-5-0 (1 of these) */
  508. #define PCI_DEVICE_ID_INTEL_KNL_IMC_TOLHM 0x7810
  509. /*
  510. * KNL differs from SB, IB, and Haswell in that it has multiple
  511. * instances of the same device with the same device ID, so we handle that
  512. * by creating as many copies in the table as we expect to find.
  513. * (Like device ID must be grouped together.)
  514. */
  515. static const struct pci_id_descr pci_dev_descr_knl[] = {
  516. [0 ... 1] = { PCI_DESCR(PCI_DEVICE_ID_INTEL_KNL_IMC_MC, 0, IMC0)},
  517. [2 ... 7] = { PCI_DESCR(PCI_DEVICE_ID_INTEL_KNL_IMC_CHAN, 0, IMC0) },
  518. [8] = { PCI_DESCR(PCI_DEVICE_ID_INTEL_KNL_IMC_TA, 0, IMC0) },
  519. [9] = { PCI_DESCR(PCI_DEVICE_ID_INTEL_KNL_IMC_TOLHM, 0, IMC0) },
  520. [10] = { PCI_DESCR(PCI_DEVICE_ID_INTEL_KNL_IMC_SAD0, 0, SOCK) },
  521. [11] = { PCI_DESCR(PCI_DEVICE_ID_INTEL_KNL_IMC_SAD1, 0, SOCK) },
  522. [12 ... 49] = { PCI_DESCR(PCI_DEVICE_ID_INTEL_KNL_IMC_CHA, 0, SOCK) },
  523. };
  524. static const struct pci_id_table pci_dev_descr_knl_table[] = {
  525. PCI_ID_TABLE_ENTRY(pci_dev_descr_knl, ARRAY_SIZE(pci_dev_descr_knl), 1, KNIGHTS_LANDING),
  526. { NULL, }
  527. };
  528. /*
  529. * Broadwell support
  530. *
  531. * DE processor:
  532. * - 1 IMC
  533. * - 2 DDR3 channels, 2 DPC per channel
  534. * EP processor:
  535. * - 1 or 2 IMC
  536. * - 4 DDR4 channels, 3 DPC per channel
  537. * EP 4S processor:
  538. * - 2 IMC
  539. * - 4 DDR4 channels, 3 DPC per channel
  540. * EX processor:
  541. * - 2 IMC
  542. * - each IMC interfaces with a SMI 2 channel
  543. * - each SMI channel interfaces with a scalable memory buffer
  544. * - each scalable memory buffer supports 4 DDR3/DDR4 channels, 3 DPC
  545. */
  546. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_VTD_MISC 0x6f28
  547. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0 0x6fa0
  548. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1 0x6f60
  549. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TA 0x6fa8
  550. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TM 0x6f71
  551. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TA 0x6f68
  552. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TM 0x6f79
  553. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_CBO_SAD0 0x6ffc
  554. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_CBO_SAD1 0x6ffd
  555. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TAD0 0x6faa
  556. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TAD1 0x6fab
  557. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TAD2 0x6fac
  558. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TAD3 0x6fad
  559. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TAD0 0x6f6a
  560. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TAD1 0x6f6b
  561. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TAD2 0x6f6c
  562. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TAD3 0x6f6d
  563. #define PCI_DEVICE_ID_INTEL_BROADWELL_IMC_DDRIO0 0x6faf
  564. static const struct pci_id_descr pci_dev_descr_broadwell[] = {
  565. /* first item must be the HA */
  566. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0, 0, IMC0) },
  567. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1, 1, IMC1) },
  568. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TA, 0, IMC0) },
  569. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TM, 0, IMC0) },
  570. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TAD0, 0, IMC0) },
  571. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TAD1, 0, IMC0) },
  572. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TAD2, 1, IMC0) },
  573. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TAD3, 1, IMC0) },
  574. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TA, 1, IMC1) },
  575. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TM, 1, IMC1) },
  576. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TAD0, 1, IMC1) },
  577. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TAD1, 1, IMC1) },
  578. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TAD2, 1, IMC1) },
  579. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TAD3, 1, IMC1) },
  580. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_CBO_SAD0, 0, SOCK) },
  581. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_CBO_SAD1, 0, SOCK) },
  582. { PCI_DESCR(PCI_DEVICE_ID_INTEL_BROADWELL_IMC_DDRIO0, 1, SOCK) },
  583. };
  584. static const struct pci_id_table pci_dev_descr_broadwell_table[] = {
  585. PCI_ID_TABLE_ENTRY(pci_dev_descr_broadwell, 10, 2, BROADWELL),
  586. { NULL, }
  587. };
  588. /****************************************************************************
  589. Ancillary status routines
  590. ****************************************************************************/
  591. static inline int numrank(enum type type, u32 mtr)
  592. {
  593. int ranks = (1 << RANK_CNT_BITS(mtr));
  594. int max = 4;
  595. if (type == HASWELL || type == BROADWELL || type == KNIGHTS_LANDING)
  596. max = 8;
  597. if (ranks > max) {
  598. edac_dbg(0, "Invalid number of ranks: %d (max = %i) raw value = %x (%04x)\n",
  599. ranks, max, (unsigned int)RANK_CNT_BITS(mtr), mtr);
  600. return -EINVAL;
  601. }
  602. return ranks;
  603. }
  604. static inline int numrow(u32 mtr)
  605. {
  606. int rows = (RANK_WIDTH_BITS(mtr) + 12);
  607. if (rows < 13 || rows > 18) {
  608. edac_dbg(0, "Invalid number of rows: %d (should be between 14 and 17) raw value = %x (%04x)\n",
  609. rows, (unsigned int)RANK_WIDTH_BITS(mtr), mtr);
  610. return -EINVAL;
  611. }
  612. return 1 << rows;
  613. }
  614. static inline int numcol(u32 mtr)
  615. {
  616. int cols = (COL_WIDTH_BITS(mtr) + 10);
  617. if (cols > 12) {
  618. edac_dbg(0, "Invalid number of cols: %d (max = 4) raw value = %x (%04x)\n",
  619. cols, (unsigned int)COL_WIDTH_BITS(mtr), mtr);
  620. return -EINVAL;
  621. }
  622. return 1 << cols;
  623. }
  624. static struct sbridge_dev *get_sbridge_dev(int seg, u8 bus, enum domain dom,
  625. int multi_bus,
  626. struct sbridge_dev *prev)
  627. {
  628. struct sbridge_dev *sbridge_dev;
  629. /*
  630. * If we have devices scattered across several busses that pertain
  631. * to the same memory controller, we'll lump them all together.
  632. */
  633. if (multi_bus) {
  634. return list_first_entry_or_null(&sbridge_edac_list,
  635. struct sbridge_dev, list);
  636. }
  637. sbridge_dev = list_entry(prev ? prev->list.next
  638. : sbridge_edac_list.next, struct sbridge_dev, list);
  639. list_for_each_entry_from(sbridge_dev, &sbridge_edac_list, list) {
  640. if ((sbridge_dev->seg == seg) && (sbridge_dev->bus == bus) &&
  641. (dom == SOCK || dom == sbridge_dev->dom))
  642. return sbridge_dev;
  643. }
  644. return NULL;
  645. }
  646. static struct sbridge_dev *alloc_sbridge_dev(int seg, u8 bus, enum domain dom,
  647. const struct pci_id_table *table)
  648. {
  649. struct sbridge_dev *sbridge_dev;
  650. sbridge_dev = kzalloc_obj(*sbridge_dev);
  651. if (!sbridge_dev)
  652. return NULL;
  653. sbridge_dev->pdev = kzalloc_objs(*sbridge_dev->pdev,
  654. table->n_devs_per_imc);
  655. if (!sbridge_dev->pdev) {
  656. kfree(sbridge_dev);
  657. return NULL;
  658. }
  659. sbridge_dev->seg = seg;
  660. sbridge_dev->bus = bus;
  661. sbridge_dev->dom = dom;
  662. sbridge_dev->n_devs = table->n_devs_per_imc;
  663. list_add_tail(&sbridge_dev->list, &sbridge_edac_list);
  664. return sbridge_dev;
  665. }
  666. static void free_sbridge_dev(struct sbridge_dev *sbridge_dev)
  667. {
  668. list_del(&sbridge_dev->list);
  669. kfree(sbridge_dev->pdev);
  670. kfree(sbridge_dev);
  671. }
  672. static u64 sbridge_get_tolm(struct sbridge_pvt *pvt)
  673. {
  674. u32 reg;
  675. /* Address range is 32:28 */
  676. pci_read_config_dword(pvt->pci_sad1, TOLM, &reg);
  677. return GET_TOLM(reg);
  678. }
  679. static u64 sbridge_get_tohm(struct sbridge_pvt *pvt)
  680. {
  681. u32 reg;
  682. pci_read_config_dword(pvt->pci_sad1, TOHM, &reg);
  683. return GET_TOHM(reg);
  684. }
  685. static u64 ibridge_get_tolm(struct sbridge_pvt *pvt)
  686. {
  687. u32 reg;
  688. pci_read_config_dword(pvt->pci_br1, TOLM, &reg);
  689. return GET_TOLM(reg);
  690. }
  691. static u64 ibridge_get_tohm(struct sbridge_pvt *pvt)
  692. {
  693. u32 reg;
  694. pci_read_config_dword(pvt->pci_br1, TOHM, &reg);
  695. return GET_TOHM(reg);
  696. }
  697. static u64 rir_limit(u32 reg)
  698. {
  699. return ((u64)GET_BITFIELD(reg, 1, 10) << 29) | 0x1fffffff;
  700. }
  701. static u64 sad_limit(u32 reg)
  702. {
  703. return (GET_BITFIELD(reg, 6, 25) << 26) | 0x3ffffff;
  704. }
  705. static u32 interleave_mode(u32 reg)
  706. {
  707. return GET_BITFIELD(reg, 1, 1);
  708. }
  709. static u32 dram_attr(u32 reg)
  710. {
  711. return GET_BITFIELD(reg, 2, 3);
  712. }
  713. static u64 knl_sad_limit(u32 reg)
  714. {
  715. return (GET_BITFIELD(reg, 7, 26) << 26) | 0x3ffffff;
  716. }
  717. static u32 knl_interleave_mode(u32 reg)
  718. {
  719. return GET_BITFIELD(reg, 1, 2);
  720. }
  721. static const char * const knl_intlv_mode[] = {
  722. "[8:6]", "[10:8]", "[14:12]", "[32:30]"
  723. };
  724. static const char *get_intlv_mode_str(u32 reg, enum type t)
  725. {
  726. if (t == KNIGHTS_LANDING)
  727. return knl_intlv_mode[knl_interleave_mode(reg)];
  728. else
  729. return interleave_mode(reg) ? "[8:6]" : "[8:6]XOR[18:16]";
  730. }
  731. static u32 dram_attr_knl(u32 reg)
  732. {
  733. return GET_BITFIELD(reg, 3, 4);
  734. }
  735. static enum mem_type get_memory_type(struct sbridge_pvt *pvt)
  736. {
  737. u32 reg;
  738. enum mem_type mtype;
  739. if (pvt->pci_ddrio) {
  740. pci_read_config_dword(pvt->pci_ddrio, pvt->info.rankcfgr,
  741. &reg);
  742. if (GET_BITFIELD(reg, 11, 11))
  743. /* FIXME: Can also be LRDIMM */
  744. mtype = MEM_RDDR3;
  745. else
  746. mtype = MEM_DDR3;
  747. } else
  748. mtype = MEM_UNKNOWN;
  749. return mtype;
  750. }
  751. static enum mem_type haswell_get_memory_type(struct sbridge_pvt *pvt)
  752. {
  753. u32 reg;
  754. bool registered = false;
  755. enum mem_type mtype = MEM_UNKNOWN;
  756. if (!pvt->pci_ddrio)
  757. goto out;
  758. pci_read_config_dword(pvt->pci_ddrio,
  759. HASWELL_DDRCRCLKCONTROLS, &reg);
  760. /* Is_Rdimm */
  761. if (GET_BITFIELD(reg, 16, 16))
  762. registered = true;
  763. pci_read_config_dword(pvt->pci_ta, MCMTR, &reg);
  764. if (GET_BITFIELD(reg, 14, 14)) {
  765. if (registered)
  766. mtype = MEM_RDDR4;
  767. else
  768. mtype = MEM_DDR4;
  769. } else {
  770. if (registered)
  771. mtype = MEM_RDDR3;
  772. else
  773. mtype = MEM_DDR3;
  774. }
  775. out:
  776. return mtype;
  777. }
  778. static enum dev_type knl_get_width(struct sbridge_pvt *pvt, u32 mtr)
  779. {
  780. /* for KNL value is fixed */
  781. return DEV_X16;
  782. }
  783. static enum dev_type sbridge_get_width(struct sbridge_pvt *pvt, u32 mtr)
  784. {
  785. /* there's no way to figure out */
  786. return DEV_UNKNOWN;
  787. }
  788. static enum dev_type __ibridge_get_width(u32 mtr)
  789. {
  790. enum dev_type type = DEV_UNKNOWN;
  791. switch (mtr) {
  792. case 2:
  793. type = DEV_X16;
  794. break;
  795. case 1:
  796. type = DEV_X8;
  797. break;
  798. case 0:
  799. type = DEV_X4;
  800. break;
  801. }
  802. return type;
  803. }
  804. static enum dev_type ibridge_get_width(struct sbridge_pvt *pvt, u32 mtr)
  805. {
  806. /*
  807. * ddr3_width on the documentation but also valid for DDR4 on
  808. * Haswell
  809. */
  810. return __ibridge_get_width(GET_BITFIELD(mtr, 7, 8));
  811. }
  812. static enum dev_type broadwell_get_width(struct sbridge_pvt *pvt, u32 mtr)
  813. {
  814. /* ddr3_width on the documentation but also valid for DDR4 */
  815. return __ibridge_get_width(GET_BITFIELD(mtr, 8, 9));
  816. }
  817. static enum mem_type knl_get_memory_type(struct sbridge_pvt *pvt)
  818. {
  819. /* DDR4 RDIMMS and LRDIMMS are supported */
  820. return MEM_RDDR4;
  821. }
  822. static u8 get_node_id(struct sbridge_pvt *pvt)
  823. {
  824. u32 reg;
  825. pci_read_config_dword(pvt->pci_br0, SAD_CONTROL, &reg);
  826. return GET_BITFIELD(reg, 0, 2);
  827. }
  828. static u8 haswell_get_node_id(struct sbridge_pvt *pvt)
  829. {
  830. u32 reg;
  831. pci_read_config_dword(pvt->pci_sad1, SAD_CONTROL, &reg);
  832. return GET_BITFIELD(reg, 0, 3);
  833. }
  834. static u8 knl_get_node_id(struct sbridge_pvt *pvt)
  835. {
  836. u32 reg;
  837. pci_read_config_dword(pvt->pci_sad1, SAD_CONTROL, &reg);
  838. return GET_BITFIELD(reg, 0, 2);
  839. }
  840. /*
  841. * Use the reporting bank number to determine which memory
  842. * controller (also known as "ha" for "home agent"). Sandy
  843. * Bridge only has one memory controller per socket, so the
  844. * answer is always zero.
  845. */
  846. static u8 sbridge_get_ha(u8 bank)
  847. {
  848. return 0;
  849. }
  850. /*
  851. * On Ivy Bridge, Haswell and Broadwell the error may be in a
  852. * home agent bank (7, 8), or one of the per-channel memory
  853. * controller banks (9 .. 16).
  854. */
  855. static u8 ibridge_get_ha(u8 bank)
  856. {
  857. switch (bank) {
  858. case 7 ... 8:
  859. return bank - 7;
  860. case 9 ... 16:
  861. return (bank - 9) / 4;
  862. default:
  863. return 0xff;
  864. }
  865. }
  866. /* Not used, but included for safety/symmetry */
  867. static u8 knl_get_ha(u8 bank)
  868. {
  869. return 0xff;
  870. }
  871. static u64 haswell_get_tolm(struct sbridge_pvt *pvt)
  872. {
  873. u32 reg;
  874. pci_read_config_dword(pvt->info.pci_vtd, HASWELL_TOLM, &reg);
  875. return (GET_BITFIELD(reg, 26, 31) << 26) | 0x3ffffff;
  876. }
  877. static u64 haswell_get_tohm(struct sbridge_pvt *pvt)
  878. {
  879. u64 rc;
  880. u32 reg;
  881. pci_read_config_dword(pvt->info.pci_vtd, HASWELL_TOHM_0, &reg);
  882. rc = GET_BITFIELD(reg, 26, 31);
  883. pci_read_config_dword(pvt->info.pci_vtd, HASWELL_TOHM_1, &reg);
  884. rc = ((reg << 6) | rc) << 26;
  885. return rc | 0x3ffffff;
  886. }
  887. static u64 knl_get_tolm(struct sbridge_pvt *pvt)
  888. {
  889. u32 reg;
  890. pci_read_config_dword(pvt->knl.pci_mc_info, KNL_TOLM, &reg);
  891. return (GET_BITFIELD(reg, 26, 31) << 26) | 0x3ffffff;
  892. }
  893. static u64 knl_get_tohm(struct sbridge_pvt *pvt)
  894. {
  895. u64 rc;
  896. u32 reg_lo, reg_hi;
  897. pci_read_config_dword(pvt->knl.pci_mc_info, KNL_TOHM_0, &reg_lo);
  898. pci_read_config_dword(pvt->knl.pci_mc_info, KNL_TOHM_1, &reg_hi);
  899. rc = ((u64)reg_hi << 32) | reg_lo;
  900. return rc | 0x3ffffff;
  901. }
  902. static u64 haswell_rir_limit(u32 reg)
  903. {
  904. return (((u64)GET_BITFIELD(reg, 1, 11) + 1) << 29) - 1;
  905. }
  906. static inline u8 sad_pkg_socket(u8 pkg)
  907. {
  908. /* on Ivy Bridge, nodeID is SASS, where A is HA and S is node id */
  909. return ((pkg >> 3) << 2) | (pkg & 0x3);
  910. }
  911. static inline u8 sad_pkg_ha(u8 pkg)
  912. {
  913. return (pkg >> 2) & 0x1;
  914. }
  915. static int haswell_chan_hash(int idx, u64 addr)
  916. {
  917. int i;
  918. /*
  919. * XOR even bits from 12:26 to bit0 of idx,
  920. * odd bits from 13:27 to bit1
  921. */
  922. for (i = 12; i < 28; i += 2)
  923. idx ^= (addr >> i) & 3;
  924. return idx;
  925. }
  926. /* Low bits of TAD limit, and some metadata. */
  927. static const u32 knl_tad_dram_limit_lo[] = {
  928. 0x400, 0x500, 0x600, 0x700,
  929. 0x800, 0x900, 0xa00, 0xb00,
  930. };
  931. /* Low bits of TAD offset. */
  932. static const u32 knl_tad_dram_offset_lo[] = {
  933. 0x404, 0x504, 0x604, 0x704,
  934. 0x804, 0x904, 0xa04, 0xb04,
  935. };
  936. /* High 16 bits of TAD limit and offset. */
  937. static const u32 knl_tad_dram_hi[] = {
  938. 0x408, 0x508, 0x608, 0x708,
  939. 0x808, 0x908, 0xa08, 0xb08,
  940. };
  941. /* Number of ways a tad entry is interleaved. */
  942. static const u32 knl_tad_ways[] = {
  943. 8, 6, 4, 3, 2, 1,
  944. };
  945. /*
  946. * Retrieve the n'th Target Address Decode table entry
  947. * from the memory controller's TAD table.
  948. *
  949. * @pvt: driver private data
  950. * @entry: which entry you want to retrieve
  951. * @mc: which memory controller (0 or 1)
  952. * @offset: output tad range offset
  953. * @limit: output address of first byte above tad range
  954. * @ways: output number of interleave ways
  955. *
  956. * The offset value has curious semantics. It's a sort of running total
  957. * of the sizes of all the memory regions that aren't mapped in this
  958. * tad table.
  959. */
  960. static int knl_get_tad(const struct sbridge_pvt *pvt,
  961. const int entry,
  962. const int mc,
  963. u64 *offset,
  964. u64 *limit,
  965. int *ways)
  966. {
  967. u32 reg_limit_lo, reg_offset_lo, reg_hi;
  968. struct pci_dev *pci_mc;
  969. int way_id;
  970. switch (mc) {
  971. case 0:
  972. pci_mc = pvt->knl.pci_mc0;
  973. break;
  974. case 1:
  975. pci_mc = pvt->knl.pci_mc1;
  976. break;
  977. default:
  978. WARN_ON(1);
  979. return -EINVAL;
  980. }
  981. pci_read_config_dword(pci_mc,
  982. knl_tad_dram_limit_lo[entry], &reg_limit_lo);
  983. pci_read_config_dword(pci_mc,
  984. knl_tad_dram_offset_lo[entry], &reg_offset_lo);
  985. pci_read_config_dword(pci_mc,
  986. knl_tad_dram_hi[entry], &reg_hi);
  987. /* Is this TAD entry enabled? */
  988. if (!GET_BITFIELD(reg_limit_lo, 0, 0))
  989. return -ENODEV;
  990. way_id = GET_BITFIELD(reg_limit_lo, 3, 5);
  991. if (way_id < ARRAY_SIZE(knl_tad_ways)) {
  992. *ways = knl_tad_ways[way_id];
  993. } else {
  994. *ways = 0;
  995. sbridge_printk(KERN_ERR,
  996. "Unexpected value %d in mc_tad_limit_lo wayness field\n",
  997. way_id);
  998. return -ENODEV;
  999. }
  1000. /*
  1001. * The least significant 6 bits of base and limit are truncated.
  1002. * For limit, we fill the missing bits with 1s.
  1003. */
  1004. *offset = ((u64) GET_BITFIELD(reg_offset_lo, 6, 31) << 6) |
  1005. ((u64) GET_BITFIELD(reg_hi, 0, 15) << 32);
  1006. *limit = ((u64) GET_BITFIELD(reg_limit_lo, 6, 31) << 6) | 63 |
  1007. ((u64) GET_BITFIELD(reg_hi, 16, 31) << 32);
  1008. return 0;
  1009. }
  1010. /* Determine which memory controller is responsible for a given channel. */
  1011. static int knl_channel_mc(int channel)
  1012. {
  1013. WARN_ON(channel < 0 || channel >= 6);
  1014. return channel < 3 ? 1 : 0;
  1015. }
  1016. /*
  1017. * Get the Nth entry from EDC_ROUTE_TABLE register.
  1018. * (This is the per-tile mapping of logical interleave targets to
  1019. * physical EDC modules.)
  1020. *
  1021. * entry 0: 0:2
  1022. * 1: 3:5
  1023. * 2: 6:8
  1024. * 3: 9:11
  1025. * 4: 12:14
  1026. * 5: 15:17
  1027. * 6: 18:20
  1028. * 7: 21:23
  1029. * reserved: 24:31
  1030. */
  1031. static u32 knl_get_edc_route(int entry, u32 reg)
  1032. {
  1033. WARN_ON(entry >= KNL_MAX_EDCS);
  1034. return GET_BITFIELD(reg, entry*3, (entry*3)+2);
  1035. }
  1036. /*
  1037. * Get the Nth entry from MC_ROUTE_TABLE register.
  1038. * (This is the per-tile mapping of logical interleave targets to
  1039. * physical DRAM channels modules.)
  1040. *
  1041. * entry 0: mc 0:2 channel 18:19
  1042. * 1: mc 3:5 channel 20:21
  1043. * 2: mc 6:8 channel 22:23
  1044. * 3: mc 9:11 channel 24:25
  1045. * 4: mc 12:14 channel 26:27
  1046. * 5: mc 15:17 channel 28:29
  1047. * reserved: 30:31
  1048. *
  1049. * Though we have 3 bits to identify the MC, we should only see
  1050. * the values 0 or 1.
  1051. */
  1052. static u32 knl_get_mc_route(int entry, u32 reg)
  1053. {
  1054. int mc, chan;
  1055. WARN_ON(entry >= KNL_MAX_CHANNELS);
  1056. mc = GET_BITFIELD(reg, entry*3, (entry*3)+2);
  1057. chan = GET_BITFIELD(reg, (entry*2) + 18, (entry*2) + 18 + 1);
  1058. return knl_channel_remap(mc, chan);
  1059. }
  1060. /*
  1061. * Render the EDC_ROUTE register in human-readable form.
  1062. * Output string s should be at least KNL_MAX_EDCS*2 bytes.
  1063. */
  1064. static void knl_show_edc_route(u32 reg, char *s)
  1065. {
  1066. int i;
  1067. for (i = 0; i < KNL_MAX_EDCS; i++) {
  1068. s[i*2] = knl_get_edc_route(i, reg) + '0';
  1069. s[i*2+1] = '-';
  1070. }
  1071. s[KNL_MAX_EDCS*2 - 1] = '\0';
  1072. }
  1073. /*
  1074. * Render the MC_ROUTE register in human-readable form.
  1075. * Output string s should be at least KNL_MAX_CHANNELS*2 bytes.
  1076. */
  1077. static void knl_show_mc_route(u32 reg, char *s)
  1078. {
  1079. int i;
  1080. for (i = 0; i < KNL_MAX_CHANNELS; i++) {
  1081. s[i*2] = knl_get_mc_route(i, reg) + '0';
  1082. s[i*2+1] = '-';
  1083. }
  1084. s[KNL_MAX_CHANNELS*2 - 1] = '\0';
  1085. }
  1086. #define KNL_EDC_ROUTE 0xb8
  1087. #define KNL_MC_ROUTE 0xb4
  1088. /* Is this dram rule backed by regular DRAM in flat mode? */
  1089. #define KNL_EDRAM(reg) GET_BITFIELD(reg, 29, 29)
  1090. /* Is this dram rule cached? */
  1091. #define KNL_CACHEABLE(reg) GET_BITFIELD(reg, 28, 28)
  1092. /* Is this rule backed by edc ? */
  1093. #define KNL_EDRAM_ONLY(reg) GET_BITFIELD(reg, 29, 29)
  1094. /* Is this rule backed by DRAM, cacheable in EDRAM? */
  1095. #define KNL_CACHEABLE(reg) GET_BITFIELD(reg, 28, 28)
  1096. /* Is this rule mod3? */
  1097. #define KNL_MOD3(reg) GET_BITFIELD(reg, 27, 27)
  1098. /*
  1099. * Figure out how big our RAM modules are.
  1100. *
  1101. * The DIMMMTR register in KNL doesn't tell us the size of the DIMMs, so we
  1102. * have to figure this out from the SAD rules, interleave lists, route tables,
  1103. * and TAD rules.
  1104. *
  1105. * SAD rules can have holes in them (e.g. the 3G-4G hole), so we have to
  1106. * inspect the TAD rules to figure out how large the SAD regions really are.
  1107. *
  1108. * When we know the real size of a SAD region and how many ways it's
  1109. * interleaved, we know the individual contribution of each channel to
  1110. * TAD is size/ways.
  1111. *
  1112. * Finally, we have to check whether each channel participates in each SAD
  1113. * region.
  1114. *
  1115. * Fortunately, KNL only supports one DIMM per channel, so once we know how
  1116. * much memory the channel uses, we know the DIMM is at least that large.
  1117. * (The BIOS might possibly choose not to map all available memory, in which
  1118. * case we will underreport the size of the DIMM.)
  1119. *
  1120. * In theory, we could try to determine the EDC sizes as well, but that would
  1121. * only work in flat mode, not in cache mode.
  1122. *
  1123. * @mc_sizes: Output sizes of channels (must have space for KNL_MAX_CHANNELS
  1124. * elements)
  1125. */
  1126. static int knl_get_dimm_capacity(struct sbridge_pvt *pvt, u64 *mc_sizes)
  1127. {
  1128. u64 sad_base, sad_limit = 0;
  1129. u64 tad_base, tad_size, tad_limit, tad_deadspace, tad_livespace;
  1130. int sad_rule = 0;
  1131. int tad_rule = 0;
  1132. int intrlv_ways, tad_ways;
  1133. u32 first_pkg, pkg;
  1134. int i;
  1135. u64 sad_actual_size[2]; /* sad size accounting for holes, per mc */
  1136. u32 dram_rule, interleave_reg;
  1137. u32 mc_route_reg[KNL_MAX_CHAS];
  1138. u32 edc_route_reg[KNL_MAX_CHAS];
  1139. int edram_only;
  1140. char edc_route_string[KNL_MAX_EDCS*2];
  1141. char mc_route_string[KNL_MAX_CHANNELS*2];
  1142. int cur_reg_start;
  1143. int mc;
  1144. int channel;
  1145. int participants[KNL_MAX_CHANNELS];
  1146. for (i = 0; i < KNL_MAX_CHANNELS; i++)
  1147. mc_sizes[i] = 0;
  1148. /* Read the EDC route table in each CHA. */
  1149. cur_reg_start = 0;
  1150. for (i = 0; i < KNL_MAX_CHAS; i++) {
  1151. pci_read_config_dword(pvt->knl.pci_cha[i],
  1152. KNL_EDC_ROUTE, &edc_route_reg[i]);
  1153. if (i > 0 && edc_route_reg[i] != edc_route_reg[i-1]) {
  1154. knl_show_edc_route(edc_route_reg[i-1],
  1155. edc_route_string);
  1156. if (cur_reg_start == i-1)
  1157. edac_dbg(0, "edc route table for CHA %d: %s\n",
  1158. cur_reg_start, edc_route_string);
  1159. else
  1160. edac_dbg(0, "edc route table for CHA %d-%d: %s\n",
  1161. cur_reg_start, i-1, edc_route_string);
  1162. cur_reg_start = i;
  1163. }
  1164. }
  1165. knl_show_edc_route(edc_route_reg[i-1], edc_route_string);
  1166. if (cur_reg_start == i-1)
  1167. edac_dbg(0, "edc route table for CHA %d: %s\n",
  1168. cur_reg_start, edc_route_string);
  1169. else
  1170. edac_dbg(0, "edc route table for CHA %d-%d: %s\n",
  1171. cur_reg_start, i-1, edc_route_string);
  1172. /* Read the MC route table in each CHA. */
  1173. cur_reg_start = 0;
  1174. for (i = 0; i < KNL_MAX_CHAS; i++) {
  1175. pci_read_config_dword(pvt->knl.pci_cha[i],
  1176. KNL_MC_ROUTE, &mc_route_reg[i]);
  1177. if (i > 0 && mc_route_reg[i] != mc_route_reg[i-1]) {
  1178. knl_show_mc_route(mc_route_reg[i-1], mc_route_string);
  1179. if (cur_reg_start == i-1)
  1180. edac_dbg(0, "mc route table for CHA %d: %s\n",
  1181. cur_reg_start, mc_route_string);
  1182. else
  1183. edac_dbg(0, "mc route table for CHA %d-%d: %s\n",
  1184. cur_reg_start, i-1, mc_route_string);
  1185. cur_reg_start = i;
  1186. }
  1187. }
  1188. knl_show_mc_route(mc_route_reg[i-1], mc_route_string);
  1189. if (cur_reg_start == i-1)
  1190. edac_dbg(0, "mc route table for CHA %d: %s\n",
  1191. cur_reg_start, mc_route_string);
  1192. else
  1193. edac_dbg(0, "mc route table for CHA %d-%d: %s\n",
  1194. cur_reg_start, i-1, mc_route_string);
  1195. /* Process DRAM rules */
  1196. for (sad_rule = 0; sad_rule < pvt->info.max_sad; sad_rule++) {
  1197. /* previous limit becomes the new base */
  1198. sad_base = sad_limit;
  1199. pci_read_config_dword(pvt->pci_sad0,
  1200. pvt->info.dram_rule[sad_rule], &dram_rule);
  1201. if (!DRAM_RULE_ENABLE(dram_rule))
  1202. break;
  1203. edram_only = KNL_EDRAM_ONLY(dram_rule);
  1204. sad_limit = pvt->info.sad_limit(dram_rule)+1;
  1205. pci_read_config_dword(pvt->pci_sad0,
  1206. pvt->info.interleave_list[sad_rule], &interleave_reg);
  1207. /*
  1208. * Find out how many ways this dram rule is interleaved.
  1209. * We stop when we see the first channel again.
  1210. */
  1211. first_pkg = sad_pkg(pvt->info.interleave_pkg,
  1212. interleave_reg, 0);
  1213. for (intrlv_ways = 1; intrlv_ways < 8; intrlv_ways++) {
  1214. pkg = sad_pkg(pvt->info.interleave_pkg,
  1215. interleave_reg, intrlv_ways);
  1216. if ((pkg & 0x8) == 0) {
  1217. /*
  1218. * 0 bit means memory is non-local,
  1219. * which KNL doesn't support
  1220. */
  1221. edac_dbg(0, "Unexpected interleave target %d\n",
  1222. pkg);
  1223. return -1;
  1224. }
  1225. if (pkg == first_pkg)
  1226. break;
  1227. }
  1228. if (KNL_MOD3(dram_rule))
  1229. intrlv_ways *= 3;
  1230. edac_dbg(3, "dram rule %d (base 0x%llx, limit 0x%llx), %d way interleave%s\n",
  1231. sad_rule,
  1232. sad_base,
  1233. sad_limit,
  1234. intrlv_ways,
  1235. edram_only ? ", EDRAM" : "");
  1236. /*
  1237. * Find out how big the SAD region really is by iterating
  1238. * over TAD tables (SAD regions may contain holes).
  1239. * Each memory controller might have a different TAD table, so
  1240. * we have to look at both.
  1241. *
  1242. * Livespace is the memory that's mapped in this TAD table,
  1243. * deadspace is the holes (this could be the MMIO hole, or it
  1244. * could be memory that's mapped by the other TAD table but
  1245. * not this one).
  1246. */
  1247. for (mc = 0; mc < 2; mc++) {
  1248. sad_actual_size[mc] = 0;
  1249. tad_livespace = 0;
  1250. for (tad_rule = 0;
  1251. tad_rule < ARRAY_SIZE(
  1252. knl_tad_dram_limit_lo);
  1253. tad_rule++) {
  1254. if (knl_get_tad(pvt,
  1255. tad_rule,
  1256. mc,
  1257. &tad_deadspace,
  1258. &tad_limit,
  1259. &tad_ways))
  1260. break;
  1261. tad_size = (tad_limit+1) -
  1262. (tad_livespace + tad_deadspace);
  1263. tad_livespace += tad_size;
  1264. tad_base = (tad_limit+1) - tad_size;
  1265. if (tad_base < sad_base) {
  1266. if (tad_limit > sad_base)
  1267. edac_dbg(0, "TAD region overlaps lower SAD boundary -- TAD tables may be configured incorrectly.\n");
  1268. } else if (tad_base < sad_limit) {
  1269. if (tad_limit+1 > sad_limit) {
  1270. edac_dbg(0, "TAD region overlaps upper SAD boundary -- TAD tables may be configured incorrectly.\n");
  1271. } else {
  1272. /* TAD region is completely inside SAD region */
  1273. edac_dbg(3, "TAD region %d 0x%llx - 0x%llx (%lld bytes) table%d\n",
  1274. tad_rule, tad_base,
  1275. tad_limit, tad_size,
  1276. mc);
  1277. sad_actual_size[mc] += tad_size;
  1278. }
  1279. }
  1280. }
  1281. }
  1282. for (mc = 0; mc < 2; mc++) {
  1283. edac_dbg(3, " total TAD DRAM footprint in table%d : 0x%llx (%lld bytes)\n",
  1284. mc, sad_actual_size[mc], sad_actual_size[mc]);
  1285. }
  1286. /* Ignore EDRAM rule */
  1287. if (edram_only)
  1288. continue;
  1289. /* Figure out which channels participate in interleave. */
  1290. for (channel = 0; channel < KNL_MAX_CHANNELS; channel++)
  1291. participants[channel] = 0;
  1292. /* For each channel, does at least one CHA have
  1293. * this channel mapped to the given target?
  1294. */
  1295. for (channel = 0; channel < KNL_MAX_CHANNELS; channel++) {
  1296. int target;
  1297. int cha;
  1298. for (target = 0; target < KNL_MAX_CHANNELS; target++) {
  1299. for (cha = 0; cha < KNL_MAX_CHAS; cha++) {
  1300. if (knl_get_mc_route(target,
  1301. mc_route_reg[cha]) == channel
  1302. && !participants[channel]) {
  1303. participants[channel] = 1;
  1304. break;
  1305. }
  1306. }
  1307. }
  1308. }
  1309. for (channel = 0; channel < KNL_MAX_CHANNELS; channel++) {
  1310. mc = knl_channel_mc(channel);
  1311. if (participants[channel]) {
  1312. edac_dbg(4, "mc channel %d contributes %lld bytes via sad entry %d\n",
  1313. channel,
  1314. sad_actual_size[mc]/intrlv_ways,
  1315. sad_rule);
  1316. mc_sizes[channel] +=
  1317. sad_actual_size[mc]/intrlv_ways;
  1318. }
  1319. }
  1320. }
  1321. return 0;
  1322. }
  1323. static void get_source_id(struct mem_ctl_info *mci)
  1324. {
  1325. struct sbridge_pvt *pvt = mci->pvt_info;
  1326. u32 reg;
  1327. if (pvt->info.type == HASWELL || pvt->info.type == BROADWELL ||
  1328. pvt->info.type == KNIGHTS_LANDING)
  1329. pci_read_config_dword(pvt->pci_sad1, SAD_TARGET, &reg);
  1330. else
  1331. pci_read_config_dword(pvt->pci_br0, SAD_TARGET, &reg);
  1332. if (pvt->info.type == KNIGHTS_LANDING)
  1333. pvt->sbridge_dev->source_id = SOURCE_ID_KNL(reg);
  1334. else
  1335. pvt->sbridge_dev->source_id = SOURCE_ID(reg);
  1336. }
  1337. static int __populate_dimms(struct mem_ctl_info *mci,
  1338. u64 knl_mc_sizes[KNL_MAX_CHANNELS],
  1339. enum edac_type mode)
  1340. {
  1341. struct sbridge_pvt *pvt = mci->pvt_info;
  1342. int channels = pvt->info.type == KNIGHTS_LANDING ? KNL_MAX_CHANNELS
  1343. : NUM_CHANNELS;
  1344. unsigned int i, j, banks, ranks, rows, cols, npages;
  1345. struct dimm_info *dimm;
  1346. enum mem_type mtype;
  1347. u64 size;
  1348. mtype = pvt->info.get_memory_type(pvt);
  1349. if (mtype == MEM_RDDR3 || mtype == MEM_RDDR4)
  1350. edac_dbg(0, "Memory is registered\n");
  1351. else if (mtype == MEM_UNKNOWN)
  1352. edac_dbg(0, "Cannot determine memory type\n");
  1353. else
  1354. edac_dbg(0, "Memory is unregistered\n");
  1355. if (mtype == MEM_DDR4 || mtype == MEM_RDDR4)
  1356. banks = 16;
  1357. else
  1358. banks = 8;
  1359. for (i = 0; i < channels; i++) {
  1360. u32 mtr, amap = 0;
  1361. int max_dimms_per_channel;
  1362. if (pvt->info.type == KNIGHTS_LANDING) {
  1363. max_dimms_per_channel = 1;
  1364. if (!pvt->knl.pci_channel[i])
  1365. continue;
  1366. } else {
  1367. max_dimms_per_channel = ARRAY_SIZE(mtr_regs);
  1368. if (!pvt->pci_tad[i])
  1369. continue;
  1370. pci_read_config_dword(pvt->pci_tad[i], 0x8c, &amap);
  1371. }
  1372. for (j = 0; j < max_dimms_per_channel; j++) {
  1373. dimm = edac_get_dimm(mci, i, j, 0);
  1374. if (pvt->info.type == KNIGHTS_LANDING) {
  1375. pci_read_config_dword(pvt->knl.pci_channel[i],
  1376. knl_mtr_reg, &mtr);
  1377. } else {
  1378. pci_read_config_dword(pvt->pci_tad[i],
  1379. mtr_regs[j], &mtr);
  1380. }
  1381. edac_dbg(4, "Channel #%d MTR%d = %x\n", i, j, mtr);
  1382. if (IS_DIMM_PRESENT(mtr)) {
  1383. if (!IS_ECC_ENABLED(pvt->info.mcmtr)) {
  1384. sbridge_printk(KERN_ERR, "CPU SrcID #%d, Ha #%d, Channel #%d has DIMMs, but ECC is disabled\n",
  1385. pvt->sbridge_dev->source_id,
  1386. pvt->sbridge_dev->dom, i);
  1387. return -ENODEV;
  1388. }
  1389. pvt->channel[i].dimms++;
  1390. ranks = numrank(pvt->info.type, mtr);
  1391. if (pvt->info.type == KNIGHTS_LANDING) {
  1392. /* For DDR4, this is fixed. */
  1393. cols = 1 << 10;
  1394. rows = knl_mc_sizes[i] /
  1395. ((u64) cols * ranks * banks * 8);
  1396. } else {
  1397. rows = numrow(mtr);
  1398. cols = numcol(mtr);
  1399. }
  1400. size = ((u64)rows * cols * banks * ranks) >> (20 - 3);
  1401. npages = MiB_TO_PAGES(size);
  1402. edac_dbg(0, "mc#%d: ha %d channel %d, dimm %d, %lld MiB (%d pages) bank: %d, rank: %d, row: %#x, col: %#x\n",
  1403. pvt->sbridge_dev->mc, pvt->sbridge_dev->dom, i, j,
  1404. size, npages,
  1405. banks, ranks, rows, cols);
  1406. dimm->nr_pages = npages;
  1407. dimm->grain = 32;
  1408. dimm->dtype = pvt->info.get_width(pvt, mtr);
  1409. dimm->mtype = mtype;
  1410. dimm->edac_mode = mode;
  1411. pvt->channel[i].dimm[j].rowbits = order_base_2(rows);
  1412. pvt->channel[i].dimm[j].colbits = order_base_2(cols);
  1413. pvt->channel[i].dimm[j].bank_xor_enable =
  1414. GET_BITFIELD(pvt->info.mcmtr, 9, 9);
  1415. pvt->channel[i].dimm[j].amap_fine = GET_BITFIELD(amap, 0, 0);
  1416. snprintf(dimm->label, sizeof(dimm->label),
  1417. "CPU_SrcID#%u_Ha#%u_Chan#%u_DIMM#%u",
  1418. pvt->sbridge_dev->source_id, pvt->sbridge_dev->dom, i, j);
  1419. }
  1420. }
  1421. }
  1422. return 0;
  1423. }
  1424. static int get_dimm_config(struct mem_ctl_info *mci)
  1425. {
  1426. struct sbridge_pvt *pvt = mci->pvt_info;
  1427. u64 knl_mc_sizes[KNL_MAX_CHANNELS];
  1428. enum edac_type mode;
  1429. u32 reg;
  1430. pvt->sbridge_dev->node_id = pvt->info.get_node_id(pvt);
  1431. edac_dbg(0, "mc#%d: Node ID: %d, source ID: %d\n",
  1432. pvt->sbridge_dev->mc,
  1433. pvt->sbridge_dev->node_id,
  1434. pvt->sbridge_dev->source_id);
  1435. /* KNL doesn't support mirroring or lockstep,
  1436. * and is always closed page
  1437. */
  1438. if (pvt->info.type == KNIGHTS_LANDING) {
  1439. mode = EDAC_S4ECD4ED;
  1440. pvt->mirror_mode = NON_MIRRORING;
  1441. pvt->is_cur_addr_mirrored = false;
  1442. if (knl_get_dimm_capacity(pvt, knl_mc_sizes) != 0)
  1443. return -1;
  1444. if (pci_read_config_dword(pvt->pci_ta, KNL_MCMTR, &pvt->info.mcmtr)) {
  1445. edac_dbg(0, "Failed to read KNL_MCMTR register\n");
  1446. return -ENODEV;
  1447. }
  1448. } else {
  1449. if (pvt->info.type == HASWELL || pvt->info.type == BROADWELL) {
  1450. if (pci_read_config_dword(pvt->pci_ha, HASWELL_HASYSDEFEATURE2, &reg)) {
  1451. edac_dbg(0, "Failed to read HASWELL_HASYSDEFEATURE2 register\n");
  1452. return -ENODEV;
  1453. }
  1454. pvt->is_chan_hash = GET_BITFIELD(reg, 21, 21);
  1455. if (GET_BITFIELD(reg, 28, 28)) {
  1456. pvt->mirror_mode = ADDR_RANGE_MIRRORING;
  1457. edac_dbg(0, "Address range partial memory mirroring is enabled\n");
  1458. goto next;
  1459. }
  1460. }
  1461. if (pci_read_config_dword(pvt->pci_ras, RASENABLES, &reg)) {
  1462. edac_dbg(0, "Failed to read RASENABLES register\n");
  1463. return -ENODEV;
  1464. }
  1465. if (IS_MIRROR_ENABLED(reg)) {
  1466. pvt->mirror_mode = FULL_MIRRORING;
  1467. edac_dbg(0, "Full memory mirroring is enabled\n");
  1468. } else {
  1469. pvt->mirror_mode = NON_MIRRORING;
  1470. edac_dbg(0, "Memory mirroring is disabled\n");
  1471. }
  1472. next:
  1473. if (pci_read_config_dword(pvt->pci_ta, MCMTR, &pvt->info.mcmtr)) {
  1474. edac_dbg(0, "Failed to read MCMTR register\n");
  1475. return -ENODEV;
  1476. }
  1477. if (IS_LOCKSTEP_ENABLED(pvt->info.mcmtr)) {
  1478. edac_dbg(0, "Lockstep is enabled\n");
  1479. mode = EDAC_S8ECD8ED;
  1480. pvt->is_lockstep = true;
  1481. } else {
  1482. edac_dbg(0, "Lockstep is disabled\n");
  1483. mode = EDAC_S4ECD4ED;
  1484. pvt->is_lockstep = false;
  1485. }
  1486. if (IS_CLOSE_PG(pvt->info.mcmtr)) {
  1487. edac_dbg(0, "address map is on closed page mode\n");
  1488. pvt->is_close_pg = true;
  1489. } else {
  1490. edac_dbg(0, "address map is on open page mode\n");
  1491. pvt->is_close_pg = false;
  1492. }
  1493. }
  1494. return __populate_dimms(mci, knl_mc_sizes, mode);
  1495. }
  1496. static void get_memory_layout(const struct mem_ctl_info *mci)
  1497. {
  1498. struct sbridge_pvt *pvt = mci->pvt_info;
  1499. int i, j, k, n_sads, n_tads, sad_interl;
  1500. u32 reg;
  1501. u64 limit, prv = 0;
  1502. u64 tmp_mb;
  1503. u32 gb, mb;
  1504. u32 rir_way;
  1505. /*
  1506. * Step 1) Get TOLM/TOHM ranges
  1507. */
  1508. pvt->tolm = pvt->info.get_tolm(pvt);
  1509. tmp_mb = (1 + pvt->tolm) >> 20;
  1510. gb = div_u64_rem(tmp_mb, 1024, &mb);
  1511. edac_dbg(0, "TOLM: %u.%03u GB (0x%016Lx)\n",
  1512. gb, (mb*1000)/1024, (u64)pvt->tolm);
  1513. /* Address range is already 45:25 */
  1514. pvt->tohm = pvt->info.get_tohm(pvt);
  1515. tmp_mb = (1 + pvt->tohm) >> 20;
  1516. gb = div_u64_rem(tmp_mb, 1024, &mb);
  1517. edac_dbg(0, "TOHM: %u.%03u GB (0x%016Lx)\n",
  1518. gb, (mb*1000)/1024, (u64)pvt->tohm);
  1519. /*
  1520. * Step 2) Get SAD range and SAD Interleave list
  1521. * TAD registers contain the interleave wayness. However, it
  1522. * seems simpler to just discover it indirectly, with the
  1523. * algorithm bellow.
  1524. */
  1525. prv = 0;
  1526. for (n_sads = 0; n_sads < pvt->info.max_sad; n_sads++) {
  1527. /* SAD_LIMIT Address range is 45:26 */
  1528. pci_read_config_dword(pvt->pci_sad0, pvt->info.dram_rule[n_sads],
  1529. &reg);
  1530. limit = pvt->info.sad_limit(reg);
  1531. if (!DRAM_RULE_ENABLE(reg))
  1532. continue;
  1533. if (limit <= prv)
  1534. break;
  1535. tmp_mb = (limit + 1) >> 20;
  1536. gb = div_u64_rem(tmp_mb, 1024, &mb);
  1537. edac_dbg(0, "SAD#%d %s up to %u.%03u GB (0x%016Lx) Interleave: %s reg=0x%08x\n",
  1538. n_sads,
  1539. show_dram_attr(pvt->info.dram_attr(reg)),
  1540. gb, (mb*1000)/1024,
  1541. ((u64)tmp_mb) << 20L,
  1542. get_intlv_mode_str(reg, pvt->info.type),
  1543. reg);
  1544. prv = limit;
  1545. pci_read_config_dword(pvt->pci_sad0, pvt->info.interleave_list[n_sads],
  1546. &reg);
  1547. sad_interl = sad_pkg(pvt->info.interleave_pkg, reg, 0);
  1548. for (j = 0; j < 8; j++) {
  1549. u32 pkg = sad_pkg(pvt->info.interleave_pkg, reg, j);
  1550. if (j > 0 && sad_interl == pkg)
  1551. break;
  1552. edac_dbg(0, "SAD#%d, interleave #%d: %d\n",
  1553. n_sads, j, pkg);
  1554. }
  1555. }
  1556. if (pvt->info.type == KNIGHTS_LANDING)
  1557. return;
  1558. /*
  1559. * Step 3) Get TAD range
  1560. */
  1561. prv = 0;
  1562. for (n_tads = 0; n_tads < MAX_TAD; n_tads++) {
  1563. pci_read_config_dword(pvt->pci_ha, tad_dram_rule[n_tads], &reg);
  1564. limit = TAD_LIMIT(reg);
  1565. if (limit <= prv)
  1566. break;
  1567. tmp_mb = (limit + 1) >> 20;
  1568. gb = div_u64_rem(tmp_mb, 1024, &mb);
  1569. edac_dbg(0, "TAD#%d: up to %u.%03u GB (0x%016Lx), socket interleave %d, memory interleave %d, TGT: %d, %d, %d, %d, reg=0x%08x\n",
  1570. n_tads, gb, (mb*1000)/1024,
  1571. ((u64)tmp_mb) << 20L,
  1572. (u32)(1 << TAD_SOCK(reg)),
  1573. (u32)TAD_CH(reg) + 1,
  1574. (u32)TAD_TGT0(reg),
  1575. (u32)TAD_TGT1(reg),
  1576. (u32)TAD_TGT2(reg),
  1577. (u32)TAD_TGT3(reg),
  1578. reg);
  1579. prv = limit;
  1580. }
  1581. /*
  1582. * Step 4) Get TAD offsets, per each channel
  1583. */
  1584. for (i = 0; i < NUM_CHANNELS; i++) {
  1585. if (!pvt->channel[i].dimms)
  1586. continue;
  1587. for (j = 0; j < n_tads; j++) {
  1588. pci_read_config_dword(pvt->pci_tad[i],
  1589. tad_ch_nilv_offset[j],
  1590. &reg);
  1591. tmp_mb = TAD_OFFSET(reg) >> 20;
  1592. gb = div_u64_rem(tmp_mb, 1024, &mb);
  1593. edac_dbg(0, "TAD CH#%d, offset #%d: %u.%03u GB (0x%016Lx), reg=0x%08x\n",
  1594. i, j,
  1595. gb, (mb*1000)/1024,
  1596. ((u64)tmp_mb) << 20L,
  1597. reg);
  1598. }
  1599. }
  1600. /*
  1601. * Step 6) Get RIR Wayness/Limit, per each channel
  1602. */
  1603. for (i = 0; i < NUM_CHANNELS; i++) {
  1604. if (!pvt->channel[i].dimms)
  1605. continue;
  1606. for (j = 0; j < MAX_RIR_RANGES; j++) {
  1607. pci_read_config_dword(pvt->pci_tad[i],
  1608. rir_way_limit[j],
  1609. &reg);
  1610. if (!IS_RIR_VALID(reg))
  1611. continue;
  1612. tmp_mb = pvt->info.rir_limit(reg) >> 20;
  1613. rir_way = 1 << RIR_WAY(reg);
  1614. gb = div_u64_rem(tmp_mb, 1024, &mb);
  1615. edac_dbg(0, "CH#%d RIR#%d, limit: %u.%03u GB (0x%016Lx), way: %d, reg=0x%08x\n",
  1616. i, j,
  1617. gb, (mb*1000)/1024,
  1618. ((u64)tmp_mb) << 20L,
  1619. rir_way,
  1620. reg);
  1621. for (k = 0; k < rir_way; k++) {
  1622. pci_read_config_dword(pvt->pci_tad[i],
  1623. rir_offset[j][k],
  1624. &reg);
  1625. tmp_mb = RIR_OFFSET(pvt->info.type, reg) << 6;
  1626. gb = div_u64_rem(tmp_mb, 1024, &mb);
  1627. edac_dbg(0, "CH#%d RIR#%d INTL#%d, offset %u.%03u GB (0x%016Lx), tgt: %d, reg=0x%08x\n",
  1628. i, j, k,
  1629. gb, (mb*1000)/1024,
  1630. ((u64)tmp_mb) << 20L,
  1631. (u32)RIR_RNK_TGT(pvt->info.type, reg),
  1632. reg);
  1633. }
  1634. }
  1635. }
  1636. }
  1637. static struct mem_ctl_info *get_mci_for_node_id(u8 node_id, u8 ha)
  1638. {
  1639. struct sbridge_dev *sbridge_dev;
  1640. list_for_each_entry(sbridge_dev, &sbridge_edac_list, list) {
  1641. if (sbridge_dev->node_id == node_id && sbridge_dev->dom == ha)
  1642. return sbridge_dev->mci;
  1643. }
  1644. return NULL;
  1645. }
  1646. static u8 sb_close_row[] = {
  1647. 15, 16, 17, 18, 20, 21, 22, 28, 10, 11, 12, 13, 29, 30, 31, 32, 33
  1648. };
  1649. static u8 sb_close_column[] = {
  1650. 3, 4, 5, 14, 19, 23, 24, 25, 26, 27
  1651. };
  1652. static u8 sb_open_row[] = {
  1653. 14, 15, 16, 20, 28, 21, 22, 23, 24, 25, 26, 27, 29, 30, 31, 32, 33
  1654. };
  1655. static u8 sb_open_column[] = {
  1656. 3, 4, 5, 6, 7, 8, 9, 10, 11, 12
  1657. };
  1658. static u8 sb_open_fine_column[] = {
  1659. 3, 4, 5, 7, 8, 9, 10, 11, 12, 13
  1660. };
  1661. static int sb_bits(u64 addr, int nbits, u8 *bits)
  1662. {
  1663. int i, res = 0;
  1664. for (i = 0; i < nbits; i++)
  1665. res |= ((addr >> bits[i]) & 1) << i;
  1666. return res;
  1667. }
  1668. static int sb_bank_bits(u64 addr, int b0, int b1, int do_xor, int x0, int x1)
  1669. {
  1670. int ret = GET_BITFIELD(addr, b0, b0) | (GET_BITFIELD(addr, b1, b1) << 1);
  1671. if (do_xor)
  1672. ret ^= GET_BITFIELD(addr, x0, x0) | (GET_BITFIELD(addr, x1, x1) << 1);
  1673. return ret;
  1674. }
  1675. static bool sb_decode_ddr4(struct mem_ctl_info *mci, int ch, u8 rank,
  1676. u64 rank_addr, char *msg)
  1677. {
  1678. int dimmno = 0;
  1679. int row, col, bank_address, bank_group;
  1680. struct sbridge_pvt *pvt;
  1681. u32 bg0 = 0, rowbits = 0, colbits = 0;
  1682. u32 amap_fine = 0, bank_xor_enable = 0;
  1683. dimmno = (rank < 12) ? rank / 4 : 2;
  1684. pvt = mci->pvt_info;
  1685. amap_fine = pvt->channel[ch].dimm[dimmno].amap_fine;
  1686. bg0 = amap_fine ? 6 : 13;
  1687. rowbits = pvt->channel[ch].dimm[dimmno].rowbits;
  1688. colbits = pvt->channel[ch].dimm[dimmno].colbits;
  1689. bank_xor_enable = pvt->channel[ch].dimm[dimmno].bank_xor_enable;
  1690. if (pvt->is_lockstep) {
  1691. pr_warn_once("LockStep row/column decode is not supported yet!\n");
  1692. msg[0] = '\0';
  1693. return false;
  1694. }
  1695. if (pvt->is_close_pg) {
  1696. row = sb_bits(rank_addr, rowbits, sb_close_row);
  1697. col = sb_bits(rank_addr, colbits, sb_close_column);
  1698. col |= 0x400; /* C10 is autoprecharge, always set */
  1699. bank_address = sb_bank_bits(rank_addr, 8, 9, bank_xor_enable, 22, 28);
  1700. bank_group = sb_bank_bits(rank_addr, 6, 7, bank_xor_enable, 20, 21);
  1701. } else {
  1702. row = sb_bits(rank_addr, rowbits, sb_open_row);
  1703. if (amap_fine)
  1704. col = sb_bits(rank_addr, colbits, sb_open_fine_column);
  1705. else
  1706. col = sb_bits(rank_addr, colbits, sb_open_column);
  1707. bank_address = sb_bank_bits(rank_addr, 18, 19, bank_xor_enable, 22, 23);
  1708. bank_group = sb_bank_bits(rank_addr, bg0, 17, bank_xor_enable, 20, 21);
  1709. }
  1710. row &= (1u << rowbits) - 1;
  1711. sprintf(msg, "row:0x%x col:0x%x bank_addr:%d bank_group:%d",
  1712. row, col, bank_address, bank_group);
  1713. return true;
  1714. }
  1715. static bool sb_decode_ddr3(struct mem_ctl_info *mci, int ch, u8 rank,
  1716. u64 rank_addr, char *msg)
  1717. {
  1718. pr_warn_once("DDR3 row/column decode not support yet!\n");
  1719. msg[0] = '\0';
  1720. return false;
  1721. }
  1722. static int get_memory_error_data(struct mem_ctl_info *mci,
  1723. u64 addr,
  1724. u8 *socket, u8 *ha,
  1725. long *channel_mask,
  1726. u8 *rank,
  1727. char **area_type, char *msg)
  1728. {
  1729. struct mem_ctl_info *new_mci;
  1730. struct sbridge_pvt *pvt = mci->pvt_info;
  1731. struct pci_dev *pci_ha;
  1732. int n_rir, n_sads, n_tads, sad_way, sck_xch;
  1733. int sad_interl, idx, base_ch;
  1734. int interleave_mode, shiftup = 0;
  1735. unsigned int sad_interleave[MAX_INTERLEAVE];
  1736. u32 reg, dram_rule;
  1737. u8 ch_way, sck_way, pkg, sad_ha = 0, rankid = 0;
  1738. u32 tad_offset;
  1739. u32 rir_way;
  1740. u32 mb, gb;
  1741. u64 ch_addr, offset, limit = 0, prv = 0;
  1742. u64 rank_addr;
  1743. enum mem_type mtype;
  1744. /*
  1745. * Step 0) Check if the address is at special memory ranges
  1746. * The check bellow is probably enough to fill all cases where
  1747. * the error is not inside a memory, except for the legacy
  1748. * range (e. g. VGA addresses). It is unlikely, however, that the
  1749. * memory controller would generate an error on that range.
  1750. */
  1751. if ((addr > (u64) pvt->tolm) && (addr < (1LL << 32))) {
  1752. sprintf(msg, "Error at TOLM area, on addr 0x%08Lx", addr);
  1753. return -EINVAL;
  1754. }
  1755. if (addr >= (u64)pvt->tohm) {
  1756. sprintf(msg, "Error at MMIOH area, on addr 0x%016Lx", addr);
  1757. return -EINVAL;
  1758. }
  1759. /*
  1760. * Step 1) Get socket
  1761. */
  1762. for (n_sads = 0; n_sads < pvt->info.max_sad; n_sads++) {
  1763. pci_read_config_dword(pvt->pci_sad0, pvt->info.dram_rule[n_sads],
  1764. &reg);
  1765. if (!DRAM_RULE_ENABLE(reg))
  1766. continue;
  1767. limit = pvt->info.sad_limit(reg);
  1768. if (limit <= prv) {
  1769. sprintf(msg, "Can't discover the memory socket");
  1770. return -EINVAL;
  1771. }
  1772. if (addr <= limit)
  1773. break;
  1774. prv = limit;
  1775. }
  1776. if (n_sads == pvt->info.max_sad) {
  1777. sprintf(msg, "Can't discover the memory socket");
  1778. return -EINVAL;
  1779. }
  1780. dram_rule = reg;
  1781. *area_type = show_dram_attr(pvt->info.dram_attr(dram_rule));
  1782. interleave_mode = pvt->info.interleave_mode(dram_rule);
  1783. pci_read_config_dword(pvt->pci_sad0, pvt->info.interleave_list[n_sads],
  1784. &reg);
  1785. if (pvt->info.type == SANDY_BRIDGE) {
  1786. sad_interl = sad_pkg(pvt->info.interleave_pkg, reg, 0);
  1787. for (sad_way = 0; sad_way < 8; sad_way++) {
  1788. u32 pkg = sad_pkg(pvt->info.interleave_pkg, reg, sad_way);
  1789. if (sad_way > 0 && sad_interl == pkg)
  1790. break;
  1791. sad_interleave[sad_way] = pkg;
  1792. edac_dbg(0, "SAD interleave #%d: %d\n",
  1793. sad_way, sad_interleave[sad_way]);
  1794. }
  1795. edac_dbg(0, "mc#%d: Error detected on SAD#%d: address 0x%016Lx < 0x%016Lx, Interleave [%d:6]%s\n",
  1796. pvt->sbridge_dev->mc,
  1797. n_sads,
  1798. addr,
  1799. limit,
  1800. sad_way + 7,
  1801. !interleave_mode ? "" : "XOR[18:16]");
  1802. if (interleave_mode)
  1803. idx = ((addr >> 6) ^ (addr >> 16)) & 7;
  1804. else
  1805. idx = (addr >> 6) & 7;
  1806. switch (sad_way) {
  1807. case 1:
  1808. idx = 0;
  1809. break;
  1810. case 2:
  1811. idx = idx & 1;
  1812. break;
  1813. case 4:
  1814. idx = idx & 3;
  1815. break;
  1816. case 8:
  1817. break;
  1818. default:
  1819. sprintf(msg, "Can't discover socket interleave");
  1820. return -EINVAL;
  1821. }
  1822. *socket = sad_interleave[idx];
  1823. edac_dbg(0, "SAD interleave index: %d (wayness %d) = CPU socket %d\n",
  1824. idx, sad_way, *socket);
  1825. } else if (pvt->info.type == HASWELL || pvt->info.type == BROADWELL) {
  1826. int bits, a7mode = A7MODE(dram_rule);
  1827. if (a7mode) {
  1828. /* A7 mode swaps P9 with P6 */
  1829. bits = GET_BITFIELD(addr, 7, 8) << 1;
  1830. bits |= GET_BITFIELD(addr, 9, 9);
  1831. } else
  1832. bits = GET_BITFIELD(addr, 6, 8);
  1833. if (interleave_mode == 0) {
  1834. /* interleave mode will XOR {8,7,6} with {18,17,16} */
  1835. idx = GET_BITFIELD(addr, 16, 18);
  1836. idx ^= bits;
  1837. } else
  1838. idx = bits;
  1839. pkg = sad_pkg(pvt->info.interleave_pkg, reg, idx);
  1840. *socket = sad_pkg_socket(pkg);
  1841. sad_ha = sad_pkg_ha(pkg);
  1842. if (a7mode) {
  1843. /* MCChanShiftUpEnable */
  1844. pci_read_config_dword(pvt->pci_ha, HASWELL_HASYSDEFEATURE2, &reg);
  1845. shiftup = GET_BITFIELD(reg, 22, 22);
  1846. }
  1847. edac_dbg(0, "SAD interleave package: %d = CPU socket %d, HA %i, shiftup: %i\n",
  1848. idx, *socket, sad_ha, shiftup);
  1849. } else {
  1850. /* Ivy Bridge's SAD mode doesn't support XOR interleave mode */
  1851. idx = (addr >> 6) & 7;
  1852. pkg = sad_pkg(pvt->info.interleave_pkg, reg, idx);
  1853. *socket = sad_pkg_socket(pkg);
  1854. sad_ha = sad_pkg_ha(pkg);
  1855. edac_dbg(0, "SAD interleave package: %d = CPU socket %d, HA %d\n",
  1856. idx, *socket, sad_ha);
  1857. }
  1858. *ha = sad_ha;
  1859. /*
  1860. * Move to the proper node structure, in order to access the
  1861. * right PCI registers
  1862. */
  1863. new_mci = get_mci_for_node_id(*socket, sad_ha);
  1864. if (!new_mci) {
  1865. sprintf(msg, "Struct for socket #%u wasn't initialized",
  1866. *socket);
  1867. return -EINVAL;
  1868. }
  1869. mci = new_mci;
  1870. pvt = mci->pvt_info;
  1871. /*
  1872. * Step 2) Get memory channel
  1873. */
  1874. prv = 0;
  1875. pci_ha = pvt->pci_ha;
  1876. for (n_tads = 0; n_tads < MAX_TAD; n_tads++) {
  1877. pci_read_config_dword(pci_ha, tad_dram_rule[n_tads], &reg);
  1878. limit = TAD_LIMIT(reg);
  1879. if (limit <= prv) {
  1880. sprintf(msg, "Can't discover the memory channel");
  1881. return -EINVAL;
  1882. }
  1883. if (addr <= limit)
  1884. break;
  1885. prv = limit;
  1886. }
  1887. if (n_tads == MAX_TAD) {
  1888. sprintf(msg, "Can't discover the memory channel");
  1889. return -EINVAL;
  1890. }
  1891. ch_way = TAD_CH(reg) + 1;
  1892. sck_way = TAD_SOCK(reg);
  1893. if (ch_way == 3)
  1894. idx = addr >> 6;
  1895. else {
  1896. idx = (addr >> (6 + sck_way + shiftup)) & 0x3;
  1897. if (pvt->is_chan_hash)
  1898. idx = haswell_chan_hash(idx, addr);
  1899. }
  1900. idx = idx % ch_way;
  1901. /*
  1902. * FIXME: Shouldn't we use CHN_IDX_OFFSET() here, when ch_way == 3 ???
  1903. */
  1904. switch (idx) {
  1905. case 0:
  1906. base_ch = TAD_TGT0(reg);
  1907. break;
  1908. case 1:
  1909. base_ch = TAD_TGT1(reg);
  1910. break;
  1911. case 2:
  1912. base_ch = TAD_TGT2(reg);
  1913. break;
  1914. case 3:
  1915. base_ch = TAD_TGT3(reg);
  1916. break;
  1917. default:
  1918. sprintf(msg, "Can't discover the TAD target");
  1919. return -EINVAL;
  1920. }
  1921. *channel_mask = 1 << base_ch;
  1922. pci_read_config_dword(pvt->pci_tad[base_ch], tad_ch_nilv_offset[n_tads], &tad_offset);
  1923. if (pvt->mirror_mode == FULL_MIRRORING ||
  1924. (pvt->mirror_mode == ADDR_RANGE_MIRRORING && n_tads == 0)) {
  1925. *channel_mask |= 1 << ((base_ch + 2) % 4);
  1926. switch(ch_way) {
  1927. case 2:
  1928. case 4:
  1929. sck_xch = (1 << sck_way) * (ch_way >> 1);
  1930. break;
  1931. default:
  1932. sprintf(msg, "Invalid mirror set. Can't decode addr");
  1933. return -EINVAL;
  1934. }
  1935. pvt->is_cur_addr_mirrored = true;
  1936. } else {
  1937. sck_xch = (1 << sck_way) * ch_way;
  1938. pvt->is_cur_addr_mirrored = false;
  1939. }
  1940. if (pvt->is_lockstep)
  1941. *channel_mask |= 1 << ((base_ch + 1) % 4);
  1942. offset = TAD_OFFSET(tad_offset);
  1943. edac_dbg(0, "TAD#%d: address 0x%016Lx < 0x%016Lx, socket interleave %d, channel interleave %d (offset 0x%08Lx), index %d, base ch: %d, ch mask: 0x%02lx\n",
  1944. n_tads,
  1945. addr,
  1946. limit,
  1947. sck_way,
  1948. ch_way,
  1949. offset,
  1950. idx,
  1951. base_ch,
  1952. *channel_mask);
  1953. /* Calculate channel address */
  1954. /* Remove the TAD offset */
  1955. if (offset > addr) {
  1956. sprintf(msg, "Can't calculate ch addr: TAD offset 0x%08Lx is too high for addr 0x%08Lx!",
  1957. offset, addr);
  1958. return -EINVAL;
  1959. }
  1960. ch_addr = addr - offset;
  1961. ch_addr >>= (6 + shiftup);
  1962. ch_addr /= sck_xch;
  1963. ch_addr <<= (6 + shiftup);
  1964. ch_addr |= addr & ((1 << (6 + shiftup)) - 1);
  1965. /*
  1966. * Step 3) Decode rank
  1967. */
  1968. for (n_rir = 0; n_rir < MAX_RIR_RANGES; n_rir++) {
  1969. pci_read_config_dword(pvt->pci_tad[base_ch], rir_way_limit[n_rir], &reg);
  1970. if (!IS_RIR_VALID(reg))
  1971. continue;
  1972. limit = pvt->info.rir_limit(reg);
  1973. gb = div_u64_rem(limit >> 20, 1024, &mb);
  1974. edac_dbg(0, "RIR#%d, limit: %u.%03u GB (0x%016Lx), way: %d\n",
  1975. n_rir,
  1976. gb, (mb*1000)/1024,
  1977. limit,
  1978. 1 << RIR_WAY(reg));
  1979. if (ch_addr <= limit)
  1980. break;
  1981. }
  1982. if (n_rir == MAX_RIR_RANGES) {
  1983. sprintf(msg, "Can't discover the memory rank for ch addr 0x%08Lx",
  1984. ch_addr);
  1985. return -EINVAL;
  1986. }
  1987. rir_way = RIR_WAY(reg);
  1988. if (pvt->is_close_pg)
  1989. idx = (ch_addr >> 6);
  1990. else
  1991. idx = (ch_addr >> 13); /* FIXME: Datasheet says to shift by 15 */
  1992. idx %= 1 << rir_way;
  1993. pci_read_config_dword(pvt->pci_tad[base_ch], rir_offset[n_rir][idx], &reg);
  1994. *rank = RIR_RNK_TGT(pvt->info.type, reg);
  1995. if (pvt->info.type == BROADWELL) {
  1996. if (pvt->is_close_pg)
  1997. shiftup = 6;
  1998. else
  1999. shiftup = 13;
  2000. rank_addr = ch_addr >> shiftup;
  2001. rank_addr /= (1 << rir_way);
  2002. rank_addr <<= shiftup;
  2003. rank_addr |= ch_addr & GENMASK_ULL(shiftup - 1, 0);
  2004. rank_addr -= RIR_OFFSET(pvt->info.type, reg);
  2005. mtype = pvt->info.get_memory_type(pvt);
  2006. rankid = *rank;
  2007. if (mtype == MEM_DDR4 || mtype == MEM_RDDR4)
  2008. sb_decode_ddr4(mci, base_ch, rankid, rank_addr, msg);
  2009. else
  2010. sb_decode_ddr3(mci, base_ch, rankid, rank_addr, msg);
  2011. } else {
  2012. msg[0] = '\0';
  2013. }
  2014. edac_dbg(0, "RIR#%d: channel address 0x%08Lx < 0x%08Lx, RIR interleave %d, index %d\n",
  2015. n_rir,
  2016. ch_addr,
  2017. limit,
  2018. rir_way,
  2019. idx);
  2020. return 0;
  2021. }
  2022. static int get_memory_error_data_from_mce(struct mem_ctl_info *mci,
  2023. const struct mce *m, u8 *socket,
  2024. u8 *ha, long *channel_mask,
  2025. char *msg)
  2026. {
  2027. u32 reg, channel = GET_BITFIELD(m->status, 0, 3);
  2028. struct mem_ctl_info *new_mci;
  2029. struct sbridge_pvt *pvt;
  2030. struct pci_dev *pci_ha;
  2031. bool tad0;
  2032. if (channel >= NUM_CHANNELS) {
  2033. sprintf(msg, "Invalid channel 0x%x", channel);
  2034. return -EINVAL;
  2035. }
  2036. pvt = mci->pvt_info;
  2037. if (!pvt->info.get_ha) {
  2038. sprintf(msg, "No get_ha()");
  2039. return -EINVAL;
  2040. }
  2041. *ha = pvt->info.get_ha(m->bank);
  2042. if (*ha != 0 && *ha != 1) {
  2043. sprintf(msg, "Impossible bank %d", m->bank);
  2044. return -EINVAL;
  2045. }
  2046. *socket = m->socketid;
  2047. new_mci = get_mci_for_node_id(*socket, *ha);
  2048. if (!new_mci) {
  2049. strcpy(msg, "mci socket got corrupted!");
  2050. return -EINVAL;
  2051. }
  2052. pvt = new_mci->pvt_info;
  2053. pci_ha = pvt->pci_ha;
  2054. pci_read_config_dword(pci_ha, tad_dram_rule[0], &reg);
  2055. tad0 = m->addr <= TAD_LIMIT(reg);
  2056. *channel_mask = 1 << channel;
  2057. if (pvt->mirror_mode == FULL_MIRRORING ||
  2058. (pvt->mirror_mode == ADDR_RANGE_MIRRORING && tad0)) {
  2059. *channel_mask |= 1 << ((channel + 2) % 4);
  2060. pvt->is_cur_addr_mirrored = true;
  2061. } else {
  2062. pvt->is_cur_addr_mirrored = false;
  2063. }
  2064. if (pvt->is_lockstep)
  2065. *channel_mask |= 1 << ((channel + 1) % 4);
  2066. return 0;
  2067. }
  2068. /****************************************************************************
  2069. Device initialization routines: put/get, init/exit
  2070. ****************************************************************************/
  2071. /*
  2072. * sbridge_put_all_devices 'put' all the devices that we have
  2073. * reserved via 'get'
  2074. */
  2075. static void sbridge_put_devices(struct sbridge_dev *sbridge_dev)
  2076. {
  2077. int i;
  2078. edac_dbg(0, "\n");
  2079. for (i = 0; i < sbridge_dev->n_devs; i++) {
  2080. struct pci_dev *pdev = sbridge_dev->pdev[i];
  2081. if (!pdev)
  2082. continue;
  2083. edac_dbg(0, "Removing dev %02x:%02x.%d\n",
  2084. pdev->bus->number,
  2085. PCI_SLOT(pdev->devfn), PCI_FUNC(pdev->devfn));
  2086. pci_dev_put(pdev);
  2087. }
  2088. }
  2089. static void sbridge_put_all_devices(void)
  2090. {
  2091. struct sbridge_dev *sbridge_dev, *tmp;
  2092. list_for_each_entry_safe(sbridge_dev, tmp, &sbridge_edac_list, list) {
  2093. sbridge_put_devices(sbridge_dev);
  2094. free_sbridge_dev(sbridge_dev);
  2095. }
  2096. }
  2097. static int sbridge_get_onedevice(struct pci_dev **prev,
  2098. u8 *num_mc,
  2099. const struct pci_id_table *table,
  2100. const unsigned devno,
  2101. const int multi_bus)
  2102. {
  2103. struct sbridge_dev *sbridge_dev = NULL;
  2104. const struct pci_id_descr *dev_descr = &table->descr[devno];
  2105. struct pci_dev *pdev = NULL;
  2106. int seg = 0;
  2107. u8 bus = 0;
  2108. int i = 0;
  2109. sbridge_printk(KERN_DEBUG,
  2110. "Seeking for: PCI ID %04x:%04x\n",
  2111. PCI_VENDOR_ID_INTEL, dev_descr->dev_id);
  2112. pdev = pci_get_device(PCI_VENDOR_ID_INTEL,
  2113. dev_descr->dev_id, *prev);
  2114. if (!pdev) {
  2115. if (*prev) {
  2116. *prev = pdev;
  2117. return 0;
  2118. }
  2119. if (dev_descr->optional)
  2120. return 0;
  2121. /* if the HA wasn't found */
  2122. if (devno == 0)
  2123. return -ENODEV;
  2124. sbridge_printk(KERN_INFO,
  2125. "Device not found: %04x:%04x\n",
  2126. PCI_VENDOR_ID_INTEL, dev_descr->dev_id);
  2127. /* End of list, leave */
  2128. return -ENODEV;
  2129. }
  2130. seg = pci_domain_nr(pdev->bus);
  2131. bus = pdev->bus->number;
  2132. next_imc:
  2133. sbridge_dev = get_sbridge_dev(seg, bus, dev_descr->dom,
  2134. multi_bus, sbridge_dev);
  2135. if (!sbridge_dev) {
  2136. /* If the HA1 wasn't found, don't create EDAC second memory controller */
  2137. if (dev_descr->dom == IMC1 && devno != 1) {
  2138. edac_dbg(0, "Skip IMC1: %04x:%04x (since HA1 was absent)\n",
  2139. PCI_VENDOR_ID_INTEL, dev_descr->dev_id);
  2140. pci_dev_put(pdev);
  2141. return 0;
  2142. }
  2143. if (dev_descr->dom == SOCK)
  2144. goto out_imc;
  2145. sbridge_dev = alloc_sbridge_dev(seg, bus, dev_descr->dom, table);
  2146. if (!sbridge_dev) {
  2147. pci_dev_put(pdev);
  2148. return -ENOMEM;
  2149. }
  2150. (*num_mc)++;
  2151. }
  2152. if (sbridge_dev->pdev[sbridge_dev->i_devs]) {
  2153. sbridge_printk(KERN_ERR,
  2154. "Duplicated device for %04x:%04x\n",
  2155. PCI_VENDOR_ID_INTEL, dev_descr->dev_id);
  2156. pci_dev_put(pdev);
  2157. return -ENODEV;
  2158. }
  2159. sbridge_dev->pdev[sbridge_dev->i_devs++] = pdev;
  2160. /* pdev belongs to more than one IMC, do extra gets */
  2161. if (++i > 1)
  2162. pci_dev_get(pdev);
  2163. if (dev_descr->dom == SOCK && i < table->n_imcs_per_sock)
  2164. goto next_imc;
  2165. out_imc:
  2166. /* Be sure that the device is enabled */
  2167. if (unlikely(pci_enable_device(pdev) < 0)) {
  2168. sbridge_printk(KERN_ERR,
  2169. "Couldn't enable %04x:%04x\n",
  2170. PCI_VENDOR_ID_INTEL, dev_descr->dev_id);
  2171. return -ENODEV;
  2172. }
  2173. edac_dbg(0, "Detected %04x:%04x\n",
  2174. PCI_VENDOR_ID_INTEL, dev_descr->dev_id);
  2175. /*
  2176. * As stated on drivers/pci/search.c, the reference count for
  2177. * @from is always decremented if it is not %NULL. So, as we need
  2178. * to get all devices up to null, we need to do a get for the device
  2179. */
  2180. pci_dev_get(pdev);
  2181. *prev = pdev;
  2182. return 0;
  2183. }
  2184. /*
  2185. * sbridge_get_all_devices - Find and perform 'get' operation on the MCH's
  2186. * devices we want to reference for this driver.
  2187. * @num_mc: pointer to the memory controllers count, to be incremented in case
  2188. * of success.
  2189. * @table: model specific table
  2190. *
  2191. * returns 0 in case of success or error code
  2192. */
  2193. static int sbridge_get_all_devices(u8 *num_mc,
  2194. const struct pci_id_table *table)
  2195. {
  2196. int i, rc;
  2197. struct pci_dev *pdev = NULL;
  2198. int allow_dups = 0;
  2199. int multi_bus = 0;
  2200. if (table->type == KNIGHTS_LANDING)
  2201. allow_dups = multi_bus = 1;
  2202. while (table && table->descr) {
  2203. for (i = 0; i < table->n_devs_per_sock; i++) {
  2204. if (!allow_dups || i == 0 ||
  2205. table->descr[i].dev_id !=
  2206. table->descr[i-1].dev_id) {
  2207. pdev = NULL;
  2208. }
  2209. do {
  2210. rc = sbridge_get_onedevice(&pdev, num_mc,
  2211. table, i, multi_bus);
  2212. if (rc < 0) {
  2213. if (i == 0) {
  2214. i = table->n_devs_per_sock;
  2215. break;
  2216. }
  2217. sbridge_put_all_devices();
  2218. return -ENODEV;
  2219. }
  2220. } while (pdev && !allow_dups);
  2221. }
  2222. table++;
  2223. }
  2224. return 0;
  2225. }
  2226. /*
  2227. * Device IDs for {SBRIDGE,IBRIDGE,HASWELL,BROADWELL}_IMC_HA0_TAD0 are in
  2228. * the format: XXXa. So we can convert from a device to the corresponding
  2229. * channel like this
  2230. */
  2231. #define TAD_DEV_TO_CHAN(dev) (((dev) & 0xf) - 0xa)
  2232. static int sbridge_mci_bind_devs(struct mem_ctl_info *mci,
  2233. struct sbridge_dev *sbridge_dev)
  2234. {
  2235. struct sbridge_pvt *pvt = mci->pvt_info;
  2236. struct pci_dev *pdev;
  2237. u8 saw_chan_mask = 0;
  2238. int i;
  2239. for (i = 0; i < sbridge_dev->n_devs; i++) {
  2240. pdev = sbridge_dev->pdev[i];
  2241. if (!pdev)
  2242. continue;
  2243. switch (pdev->device) {
  2244. case PCI_DEVICE_ID_INTEL_SBRIDGE_SAD0:
  2245. pvt->pci_sad0 = pdev;
  2246. break;
  2247. case PCI_DEVICE_ID_INTEL_SBRIDGE_SAD1:
  2248. pvt->pci_sad1 = pdev;
  2249. break;
  2250. case PCI_DEVICE_ID_INTEL_SBRIDGE_BR:
  2251. pvt->pci_br0 = pdev;
  2252. break;
  2253. case PCI_DEVICE_ID_INTEL_SBRIDGE_IMC_HA0:
  2254. pvt->pci_ha = pdev;
  2255. break;
  2256. case PCI_DEVICE_ID_INTEL_SBRIDGE_IMC_TA:
  2257. pvt->pci_ta = pdev;
  2258. break;
  2259. case PCI_DEVICE_ID_INTEL_SBRIDGE_IMC_RAS:
  2260. pvt->pci_ras = pdev;
  2261. break;
  2262. case PCI_DEVICE_ID_INTEL_SBRIDGE_IMC_TAD0:
  2263. case PCI_DEVICE_ID_INTEL_SBRIDGE_IMC_TAD1:
  2264. case PCI_DEVICE_ID_INTEL_SBRIDGE_IMC_TAD2:
  2265. case PCI_DEVICE_ID_INTEL_SBRIDGE_IMC_TAD3:
  2266. {
  2267. int id = TAD_DEV_TO_CHAN(pdev->device);
  2268. pvt->pci_tad[id] = pdev;
  2269. saw_chan_mask |= 1 << id;
  2270. }
  2271. break;
  2272. case PCI_DEVICE_ID_INTEL_SBRIDGE_IMC_DDRIO:
  2273. pvt->pci_ddrio = pdev;
  2274. break;
  2275. default:
  2276. goto error;
  2277. }
  2278. edac_dbg(0, "Associated PCI %02x:%02x, bus %d with dev = %p\n",
  2279. pdev->vendor, pdev->device,
  2280. sbridge_dev->bus,
  2281. pdev);
  2282. }
  2283. /* Check if everything were registered */
  2284. if (!pvt->pci_sad0 || !pvt->pci_sad1 || !pvt->pci_ha ||
  2285. !pvt->pci_ras || !pvt->pci_ta)
  2286. goto enodev;
  2287. if (saw_chan_mask != 0x0f)
  2288. goto enodev;
  2289. return 0;
  2290. enodev:
  2291. sbridge_printk(KERN_ERR, "Some needed devices are missing\n");
  2292. return -ENODEV;
  2293. error:
  2294. sbridge_printk(KERN_ERR, "Unexpected device %02x:%02x\n",
  2295. PCI_VENDOR_ID_INTEL, pdev->device);
  2296. return -EINVAL;
  2297. }
  2298. static int ibridge_mci_bind_devs(struct mem_ctl_info *mci,
  2299. struct sbridge_dev *sbridge_dev)
  2300. {
  2301. struct sbridge_pvt *pvt = mci->pvt_info;
  2302. struct pci_dev *pdev;
  2303. u8 saw_chan_mask = 0;
  2304. int i;
  2305. for (i = 0; i < sbridge_dev->n_devs; i++) {
  2306. pdev = sbridge_dev->pdev[i];
  2307. if (!pdev)
  2308. continue;
  2309. switch (pdev->device) {
  2310. case PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0:
  2311. case PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1:
  2312. pvt->pci_ha = pdev;
  2313. break;
  2314. case PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_TA:
  2315. case PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_TA:
  2316. pvt->pci_ta = pdev;
  2317. break;
  2318. case PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_RAS:
  2319. case PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_RAS:
  2320. pvt->pci_ras = pdev;
  2321. break;
  2322. case PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_TAD0:
  2323. case PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_TAD1:
  2324. case PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_TAD2:
  2325. case PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA0_TAD3:
  2326. case PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_TAD0:
  2327. case PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_TAD1:
  2328. case PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_TAD2:
  2329. case PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_HA1_TAD3:
  2330. {
  2331. int id = TAD_DEV_TO_CHAN(pdev->device);
  2332. pvt->pci_tad[id] = pdev;
  2333. saw_chan_mask |= 1 << id;
  2334. }
  2335. break;
  2336. case PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_2HA_DDRIO0:
  2337. pvt->pci_ddrio = pdev;
  2338. break;
  2339. case PCI_DEVICE_ID_INTEL_IBRIDGE_IMC_1HA_DDRIO0:
  2340. pvt->pci_ddrio = pdev;
  2341. break;
  2342. case PCI_DEVICE_ID_INTEL_IBRIDGE_SAD:
  2343. pvt->pci_sad0 = pdev;
  2344. break;
  2345. case PCI_DEVICE_ID_INTEL_IBRIDGE_BR0:
  2346. pvt->pci_br0 = pdev;
  2347. break;
  2348. case PCI_DEVICE_ID_INTEL_IBRIDGE_BR1:
  2349. pvt->pci_br1 = pdev;
  2350. break;
  2351. default:
  2352. goto error;
  2353. }
  2354. edac_dbg(0, "Associated PCI %02x.%02d.%d with dev = %p\n",
  2355. sbridge_dev->bus,
  2356. PCI_SLOT(pdev->devfn), PCI_FUNC(pdev->devfn),
  2357. pdev);
  2358. }
  2359. /* Check if everything were registered */
  2360. if (!pvt->pci_sad0 || !pvt->pci_ha || !pvt->pci_br0 ||
  2361. !pvt->pci_br1 || !pvt->pci_ras || !pvt->pci_ta)
  2362. goto enodev;
  2363. if (saw_chan_mask != 0x0f && /* -EN/-EX */
  2364. saw_chan_mask != 0x03) /* -EP */
  2365. goto enodev;
  2366. return 0;
  2367. enodev:
  2368. sbridge_printk(KERN_ERR, "Some needed devices are missing\n");
  2369. return -ENODEV;
  2370. error:
  2371. sbridge_printk(KERN_ERR,
  2372. "Unexpected device %02x:%02x\n", PCI_VENDOR_ID_INTEL,
  2373. pdev->device);
  2374. return -EINVAL;
  2375. }
  2376. static int haswell_mci_bind_devs(struct mem_ctl_info *mci,
  2377. struct sbridge_dev *sbridge_dev)
  2378. {
  2379. struct sbridge_pvt *pvt = mci->pvt_info;
  2380. struct pci_dev *pdev;
  2381. u8 saw_chan_mask = 0;
  2382. int i;
  2383. /* there's only one device per system; not tied to any bus */
  2384. if (pvt->info.pci_vtd == NULL)
  2385. /* result will be checked later */
  2386. pvt->info.pci_vtd = pci_get_device(PCI_VENDOR_ID_INTEL,
  2387. PCI_DEVICE_ID_INTEL_HASWELL_IMC_VTD_MISC,
  2388. NULL);
  2389. for (i = 0; i < sbridge_dev->n_devs; i++) {
  2390. pdev = sbridge_dev->pdev[i];
  2391. if (!pdev)
  2392. continue;
  2393. switch (pdev->device) {
  2394. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_CBO_SAD0:
  2395. pvt->pci_sad0 = pdev;
  2396. break;
  2397. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_CBO_SAD1:
  2398. pvt->pci_sad1 = pdev;
  2399. break;
  2400. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0:
  2401. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1:
  2402. pvt->pci_ha = pdev;
  2403. break;
  2404. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TA:
  2405. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TA:
  2406. pvt->pci_ta = pdev;
  2407. break;
  2408. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TM:
  2409. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TM:
  2410. pvt->pci_ras = pdev;
  2411. break;
  2412. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TAD0:
  2413. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TAD1:
  2414. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TAD2:
  2415. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA0_TAD3:
  2416. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TAD0:
  2417. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TAD1:
  2418. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TAD2:
  2419. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_HA1_TAD3:
  2420. {
  2421. int id = TAD_DEV_TO_CHAN(pdev->device);
  2422. pvt->pci_tad[id] = pdev;
  2423. saw_chan_mask |= 1 << id;
  2424. }
  2425. break;
  2426. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_DDRIO0:
  2427. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_DDRIO1:
  2428. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_DDRIO2:
  2429. case PCI_DEVICE_ID_INTEL_HASWELL_IMC_DDRIO3:
  2430. if (!pvt->pci_ddrio)
  2431. pvt->pci_ddrio = pdev;
  2432. break;
  2433. default:
  2434. break;
  2435. }
  2436. edac_dbg(0, "Associated PCI %02x.%02d.%d with dev = %p\n",
  2437. sbridge_dev->bus,
  2438. PCI_SLOT(pdev->devfn), PCI_FUNC(pdev->devfn),
  2439. pdev);
  2440. }
  2441. /* Check if everything were registered */
  2442. if (!pvt->pci_sad0 || !pvt->pci_ha || !pvt->pci_sad1 ||
  2443. !pvt->pci_ras || !pvt->pci_ta || !pvt->info.pci_vtd)
  2444. goto enodev;
  2445. if (saw_chan_mask != 0x0f && /* -EN/-EX */
  2446. saw_chan_mask != 0x03) /* -EP */
  2447. goto enodev;
  2448. return 0;
  2449. enodev:
  2450. sbridge_printk(KERN_ERR, "Some needed devices are missing\n");
  2451. return -ENODEV;
  2452. }
  2453. static int broadwell_mci_bind_devs(struct mem_ctl_info *mci,
  2454. struct sbridge_dev *sbridge_dev)
  2455. {
  2456. struct sbridge_pvt *pvt = mci->pvt_info;
  2457. struct pci_dev *pdev;
  2458. u8 saw_chan_mask = 0;
  2459. int i;
  2460. /* there's only one device per system; not tied to any bus */
  2461. if (pvt->info.pci_vtd == NULL)
  2462. /* result will be checked later */
  2463. pvt->info.pci_vtd = pci_get_device(PCI_VENDOR_ID_INTEL,
  2464. PCI_DEVICE_ID_INTEL_BROADWELL_IMC_VTD_MISC,
  2465. NULL);
  2466. for (i = 0; i < sbridge_dev->n_devs; i++) {
  2467. pdev = sbridge_dev->pdev[i];
  2468. if (!pdev)
  2469. continue;
  2470. switch (pdev->device) {
  2471. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_CBO_SAD0:
  2472. pvt->pci_sad0 = pdev;
  2473. break;
  2474. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_CBO_SAD1:
  2475. pvt->pci_sad1 = pdev;
  2476. break;
  2477. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0:
  2478. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1:
  2479. pvt->pci_ha = pdev;
  2480. break;
  2481. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TA:
  2482. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TA:
  2483. pvt->pci_ta = pdev;
  2484. break;
  2485. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TM:
  2486. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TM:
  2487. pvt->pci_ras = pdev;
  2488. break;
  2489. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TAD0:
  2490. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TAD1:
  2491. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TAD2:
  2492. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA0_TAD3:
  2493. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TAD0:
  2494. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TAD1:
  2495. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TAD2:
  2496. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_HA1_TAD3:
  2497. {
  2498. int id = TAD_DEV_TO_CHAN(pdev->device);
  2499. pvt->pci_tad[id] = pdev;
  2500. saw_chan_mask |= 1 << id;
  2501. }
  2502. break;
  2503. case PCI_DEVICE_ID_INTEL_BROADWELL_IMC_DDRIO0:
  2504. pvt->pci_ddrio = pdev;
  2505. break;
  2506. default:
  2507. break;
  2508. }
  2509. edac_dbg(0, "Associated PCI %02x.%02d.%d with dev = %p\n",
  2510. sbridge_dev->bus,
  2511. PCI_SLOT(pdev->devfn), PCI_FUNC(pdev->devfn),
  2512. pdev);
  2513. }
  2514. /* Check if everything were registered */
  2515. if (!pvt->pci_sad0 || !pvt->pci_ha || !pvt->pci_sad1 ||
  2516. !pvt->pci_ras || !pvt->pci_ta || !pvt->info.pci_vtd)
  2517. goto enodev;
  2518. if (saw_chan_mask != 0x0f && /* -EN/-EX */
  2519. saw_chan_mask != 0x03) /* -EP */
  2520. goto enodev;
  2521. return 0;
  2522. enodev:
  2523. sbridge_printk(KERN_ERR, "Some needed devices are missing\n");
  2524. return -ENODEV;
  2525. }
  2526. static int knl_mci_bind_devs(struct mem_ctl_info *mci,
  2527. struct sbridge_dev *sbridge_dev)
  2528. {
  2529. struct sbridge_pvt *pvt = mci->pvt_info;
  2530. struct pci_dev *pdev;
  2531. int dev, func;
  2532. int i;
  2533. int devidx;
  2534. for (i = 0; i < sbridge_dev->n_devs; i++) {
  2535. pdev = sbridge_dev->pdev[i];
  2536. if (!pdev)
  2537. continue;
  2538. /* Extract PCI device and function. */
  2539. dev = (pdev->devfn >> 3) & 0x1f;
  2540. func = pdev->devfn & 0x7;
  2541. switch (pdev->device) {
  2542. case PCI_DEVICE_ID_INTEL_KNL_IMC_MC:
  2543. if (dev == 8)
  2544. pvt->knl.pci_mc0 = pdev;
  2545. else if (dev == 9)
  2546. pvt->knl.pci_mc1 = pdev;
  2547. else {
  2548. sbridge_printk(KERN_ERR,
  2549. "Memory controller in unexpected place! (dev %d, fn %d)\n",
  2550. dev, func);
  2551. continue;
  2552. }
  2553. break;
  2554. case PCI_DEVICE_ID_INTEL_KNL_IMC_SAD0:
  2555. pvt->pci_sad0 = pdev;
  2556. break;
  2557. case PCI_DEVICE_ID_INTEL_KNL_IMC_SAD1:
  2558. pvt->pci_sad1 = pdev;
  2559. break;
  2560. case PCI_DEVICE_ID_INTEL_KNL_IMC_CHA:
  2561. /* There are one of these per tile, and range from
  2562. * 1.14.0 to 1.18.5.
  2563. */
  2564. devidx = ((dev-14)*8)+func;
  2565. if (devidx < 0 || devidx >= KNL_MAX_CHAS) {
  2566. sbridge_printk(KERN_ERR,
  2567. "Caching and Home Agent in unexpected place! (dev %d, fn %d)\n",
  2568. dev, func);
  2569. continue;
  2570. }
  2571. WARN_ON(pvt->knl.pci_cha[devidx] != NULL);
  2572. pvt->knl.pci_cha[devidx] = pdev;
  2573. break;
  2574. case PCI_DEVICE_ID_INTEL_KNL_IMC_CHAN:
  2575. devidx = -1;
  2576. /*
  2577. * MC0 channels 0-2 are device 9 function 2-4,
  2578. * MC1 channels 3-5 are device 8 function 2-4.
  2579. */
  2580. if (dev == 9)
  2581. devidx = func-2;
  2582. else if (dev == 8)
  2583. devidx = 3 + (func-2);
  2584. if (devidx < 0 || devidx >= KNL_MAX_CHANNELS) {
  2585. sbridge_printk(KERN_ERR,
  2586. "DRAM Channel Registers in unexpected place! (dev %d, fn %d)\n",
  2587. dev, func);
  2588. continue;
  2589. }
  2590. WARN_ON(pvt->knl.pci_channel[devidx] != NULL);
  2591. pvt->knl.pci_channel[devidx] = pdev;
  2592. break;
  2593. case PCI_DEVICE_ID_INTEL_KNL_IMC_TOLHM:
  2594. pvt->knl.pci_mc_info = pdev;
  2595. break;
  2596. case PCI_DEVICE_ID_INTEL_KNL_IMC_TA:
  2597. pvt->pci_ta = pdev;
  2598. break;
  2599. default:
  2600. sbridge_printk(KERN_ERR, "Unexpected device %d\n",
  2601. pdev->device);
  2602. break;
  2603. }
  2604. }
  2605. if (!pvt->knl.pci_mc0 || !pvt->knl.pci_mc1 ||
  2606. !pvt->pci_sad0 || !pvt->pci_sad1 ||
  2607. !pvt->pci_ta) {
  2608. goto enodev;
  2609. }
  2610. for (i = 0; i < KNL_MAX_CHANNELS; i++) {
  2611. if (!pvt->knl.pci_channel[i]) {
  2612. sbridge_printk(KERN_ERR, "Missing channel %d\n", i);
  2613. goto enodev;
  2614. }
  2615. }
  2616. for (i = 0; i < KNL_MAX_CHAS; i++) {
  2617. if (!pvt->knl.pci_cha[i]) {
  2618. sbridge_printk(KERN_ERR, "Missing CHA %d\n", i);
  2619. goto enodev;
  2620. }
  2621. }
  2622. return 0;
  2623. enodev:
  2624. sbridge_printk(KERN_ERR, "Some needed devices are missing\n");
  2625. return -ENODEV;
  2626. }
  2627. /****************************************************************************
  2628. Error check routines
  2629. ****************************************************************************/
  2630. /*
  2631. * While Sandy Bridge has error count registers, SMI BIOS read values from
  2632. * and resets the counters. So, they are not reliable for the OS to read
  2633. * from them. So, we have no option but to just trust on whatever MCE is
  2634. * telling us about the errors.
  2635. */
  2636. static void sbridge_mce_output_error(struct mem_ctl_info *mci,
  2637. const struct mce *m)
  2638. {
  2639. struct mem_ctl_info *new_mci;
  2640. struct sbridge_pvt *pvt = mci->pvt_info;
  2641. enum hw_event_mc_err_type tp_event;
  2642. bool ripv = GET_BITFIELD(m->mcgstatus, 0, 0);
  2643. bool overflow = GET_BITFIELD(m->status, 62, 62);
  2644. bool uncorrected_error = GET_BITFIELD(m->status, 61, 61);
  2645. bool recoverable;
  2646. u32 core_err_cnt = GET_BITFIELD(m->status, 38, 52);
  2647. u32 mscod = GET_BITFIELD(m->status, 16, 31);
  2648. u32 errcode = GET_BITFIELD(m->status, 0, 15);
  2649. u32 channel = GET_BITFIELD(m->status, 0, 3);
  2650. u32 optypenum = GET_BITFIELD(m->status, 4, 6);
  2651. /*
  2652. * Bits 5-0 of MCi_MISC give the least significant bit that is valid.
  2653. * A value 6 is for cache line aligned address, a value 12 is for page
  2654. * aligned address reported by patrol scrubber.
  2655. */
  2656. u32 lsb = GET_BITFIELD(m->misc, 0, 5);
  2657. char *optype, *area_type = "DRAM";
  2658. long channel_mask, first_channel;
  2659. u8 rank = 0xff, socket, ha;
  2660. int rc, dimm;
  2661. if (pvt->info.type != SANDY_BRIDGE)
  2662. recoverable = true;
  2663. else
  2664. recoverable = GET_BITFIELD(m->status, 56, 56);
  2665. if (uncorrected_error) {
  2666. core_err_cnt = 1;
  2667. if (ripv) {
  2668. tp_event = HW_EVENT_ERR_UNCORRECTED;
  2669. } else {
  2670. tp_event = HW_EVENT_ERR_FATAL;
  2671. }
  2672. } else {
  2673. tp_event = HW_EVENT_ERR_CORRECTED;
  2674. }
  2675. /*
  2676. * According with Table 15-9 of the Intel Architecture spec vol 3A,
  2677. * memory errors should fit in this mask:
  2678. * 000f 0000 1mmm cccc (binary)
  2679. * where:
  2680. * f = Correction Report Filtering Bit. If 1, subsequent errors
  2681. * won't be shown
  2682. * mmm = error type
  2683. * cccc = channel
  2684. * If the mask doesn't match, report an error to the parsing logic
  2685. */
  2686. switch (optypenum) {
  2687. case 0:
  2688. optype = "generic undef request error";
  2689. break;
  2690. case 1:
  2691. optype = "memory read error";
  2692. break;
  2693. case 2:
  2694. optype = "memory write error";
  2695. break;
  2696. case 3:
  2697. optype = "addr/cmd error";
  2698. break;
  2699. case 4:
  2700. optype = "memory scrubbing error";
  2701. break;
  2702. default:
  2703. optype = "reserved";
  2704. break;
  2705. }
  2706. if (pvt->info.type == KNIGHTS_LANDING) {
  2707. if (channel == 14) {
  2708. edac_dbg(0, "%s%s err_code:%04x:%04x EDRAM bank %d\n",
  2709. overflow ? " OVERFLOW" : "",
  2710. (uncorrected_error && recoverable)
  2711. ? " recoverable" : "",
  2712. mscod, errcode,
  2713. m->bank);
  2714. } else {
  2715. char A = *("A");
  2716. /*
  2717. * Reported channel is in range 0-2, so we can't map it
  2718. * back to mc. To figure out mc we check machine check
  2719. * bank register that reported this error.
  2720. * bank15 means mc0 and bank16 means mc1.
  2721. */
  2722. channel = knl_channel_remap(m->bank == 16, channel);
  2723. channel_mask = 1 << channel;
  2724. snprintf(sb_msg, sizeof(sb_msg),
  2725. "%s%s err_code:%04x:%04x channel:%d (DIMM_%c)",
  2726. overflow ? " OVERFLOW" : "",
  2727. (uncorrected_error && recoverable)
  2728. ? " recoverable" : " ",
  2729. mscod, errcode, channel, A + channel);
  2730. edac_mc_handle_error(tp_event, mci, core_err_cnt,
  2731. m->addr >> PAGE_SHIFT, m->addr & ~PAGE_MASK, 0,
  2732. channel, 0, -1,
  2733. optype, sb_msg);
  2734. }
  2735. return;
  2736. } else if (lsb < 12) {
  2737. rc = get_memory_error_data(mci, m->addr, &socket, &ha,
  2738. &channel_mask, &rank,
  2739. &area_type, sb_msg);
  2740. } else {
  2741. rc = get_memory_error_data_from_mce(mci, m, &socket, &ha,
  2742. &channel_mask, sb_msg);
  2743. }
  2744. if (rc < 0)
  2745. goto err_parsing;
  2746. new_mci = get_mci_for_node_id(socket, ha);
  2747. if (!new_mci) {
  2748. strscpy(sb_msg, "Error: socket got corrupted!");
  2749. goto err_parsing;
  2750. }
  2751. mci = new_mci;
  2752. pvt = mci->pvt_info;
  2753. first_channel = find_first_bit(&channel_mask, NUM_CHANNELS);
  2754. if (rank == 0xff)
  2755. dimm = -1;
  2756. else if (rank < 4)
  2757. dimm = 0;
  2758. else if (rank < 8)
  2759. dimm = 1;
  2760. else
  2761. dimm = 2;
  2762. /*
  2763. * FIXME: On some memory configurations (mirror, lockstep), the
  2764. * Memory Controller can't point the error to a single DIMM. The
  2765. * EDAC core should be handling the channel mask, in order to point
  2766. * to the group of dimm's where the error may be happening.
  2767. */
  2768. if (!pvt->is_lockstep && !pvt->is_cur_addr_mirrored && !pvt->is_close_pg)
  2769. channel = first_channel;
  2770. snprintf(sb_msg_full, sizeof(sb_msg_full),
  2771. "%s%s area:%s err_code:%04x:%04x socket:%d ha:%d channel_mask:%ld rank:%d %s",
  2772. overflow ? " OVERFLOW" : "",
  2773. (uncorrected_error && recoverable) ? " recoverable" : "",
  2774. area_type,
  2775. mscod, errcode,
  2776. socket, ha,
  2777. channel_mask,
  2778. rank, sb_msg);
  2779. edac_dbg(0, "%s\n", sb_msg_full);
  2780. /* FIXME: need support for channel mask */
  2781. if (channel == CHANNEL_UNSPECIFIED)
  2782. channel = -1;
  2783. /* Call the helper to output message */
  2784. edac_mc_handle_error(tp_event, mci, core_err_cnt,
  2785. m->addr >> PAGE_SHIFT, m->addr & ~PAGE_MASK, 0,
  2786. channel, dimm, -1,
  2787. optype, sb_msg_full);
  2788. return;
  2789. err_parsing:
  2790. edac_mc_handle_error(tp_event, mci, core_err_cnt, 0, 0, 0,
  2791. -1, -1, -1,
  2792. sb_msg, "");
  2793. }
  2794. /*
  2795. * Check that logging is enabled and that this is the right type
  2796. * of error for us to handle.
  2797. */
  2798. static int sbridge_mce_check_error(struct notifier_block *nb, unsigned long val,
  2799. void *data)
  2800. {
  2801. struct mce *mce = (struct mce *)data;
  2802. struct mem_ctl_info *mci;
  2803. char *type;
  2804. if (mce->kflags & MCE_HANDLED_CEC)
  2805. return NOTIFY_DONE;
  2806. /*
  2807. * Just let mcelog handle it if the error is
  2808. * outside the memory controller. A memory error
  2809. * is indicated by bit 7 = 1 and bits = 8-11,13-15 = 0.
  2810. * bit 12 has an special meaning.
  2811. */
  2812. if ((mce->status & 0xefff) >> 7 != 1)
  2813. return NOTIFY_DONE;
  2814. /* Check ADDRV bit in STATUS */
  2815. if (!GET_BITFIELD(mce->status, 58, 58))
  2816. return NOTIFY_DONE;
  2817. /* Check MISCV bit in STATUS */
  2818. if (!GET_BITFIELD(mce->status, 59, 59))
  2819. return NOTIFY_DONE;
  2820. /* Check address type in MISC (physical address only) */
  2821. if (GET_BITFIELD(mce->misc, 6, 8) != 2)
  2822. return NOTIFY_DONE;
  2823. mci = get_mci_for_node_id(mce->socketid, IMC0);
  2824. if (!mci)
  2825. return NOTIFY_DONE;
  2826. if (mce->mcgstatus & MCG_STATUS_MCIP)
  2827. type = "Exception";
  2828. else
  2829. type = "Event";
  2830. sbridge_mc_printk(mci, KERN_DEBUG, "HANDLING MCE MEMORY ERROR\n");
  2831. sbridge_mc_printk(mci, KERN_DEBUG, "CPU %d: Machine Check %s: %Lx "
  2832. "Bank %d: %016Lx\n", mce->extcpu, type,
  2833. mce->mcgstatus, mce->bank, mce->status);
  2834. sbridge_mc_printk(mci, KERN_DEBUG, "TSC %llx ", mce->tsc);
  2835. sbridge_mc_printk(mci, KERN_DEBUG, "ADDR %llx ", mce->addr);
  2836. sbridge_mc_printk(mci, KERN_DEBUG, "MISC %llx ", mce->misc);
  2837. sbridge_mc_printk(mci, KERN_DEBUG, "PROCESSOR %u:%x TIME %llu SOCKET "
  2838. "%u APIC %x\n", mce->cpuvendor, mce->cpuid,
  2839. mce->time, mce->socketid, mce->apicid);
  2840. sbridge_mce_output_error(mci, mce);
  2841. /* Advice mcelog that the error were handled */
  2842. mce->kflags |= MCE_HANDLED_EDAC;
  2843. return NOTIFY_OK;
  2844. }
  2845. static struct notifier_block sbridge_mce_dec = {
  2846. .notifier_call = sbridge_mce_check_error,
  2847. .priority = MCE_PRIO_EDAC,
  2848. };
  2849. /****************************************************************************
  2850. EDAC register/unregister logic
  2851. ****************************************************************************/
  2852. static void sbridge_unregister_mci(struct sbridge_dev *sbridge_dev)
  2853. {
  2854. struct mem_ctl_info *mci = sbridge_dev->mci;
  2855. if (unlikely(!mci || !mci->pvt_info)) {
  2856. edac_dbg(0, "MC: dev = %p\n", &sbridge_dev->pdev[0]->dev);
  2857. sbridge_printk(KERN_ERR, "Couldn't find mci handler\n");
  2858. return;
  2859. }
  2860. edac_dbg(0, "MC: mci = %p, dev = %p\n",
  2861. mci, &sbridge_dev->pdev[0]->dev);
  2862. /* Remove MC sysfs nodes */
  2863. edac_mc_del_mc(mci->pdev);
  2864. edac_dbg(1, "%s: free mci struct\n", mci->ctl_name);
  2865. kfree(mci->ctl_name);
  2866. edac_mc_free(mci);
  2867. sbridge_dev->mci = NULL;
  2868. }
  2869. static int sbridge_register_mci(struct sbridge_dev *sbridge_dev, enum type type)
  2870. {
  2871. struct mem_ctl_info *mci;
  2872. struct edac_mc_layer layers[2];
  2873. struct sbridge_pvt *pvt;
  2874. struct pci_dev *pdev = sbridge_dev->pdev[0];
  2875. int rc;
  2876. /* allocate a new MC control structure */
  2877. layers[0].type = EDAC_MC_LAYER_CHANNEL;
  2878. layers[0].size = type == KNIGHTS_LANDING ?
  2879. KNL_MAX_CHANNELS : NUM_CHANNELS;
  2880. layers[0].is_virt_csrow = false;
  2881. layers[1].type = EDAC_MC_LAYER_SLOT;
  2882. layers[1].size = type == KNIGHTS_LANDING ? 1 : MAX_DIMMS;
  2883. layers[1].is_virt_csrow = true;
  2884. mci = edac_mc_alloc(sbridge_dev->mc, ARRAY_SIZE(layers), layers,
  2885. sizeof(*pvt));
  2886. if (unlikely(!mci))
  2887. return -ENOMEM;
  2888. edac_dbg(0, "MC: mci = %p, dev = %p\n",
  2889. mci, &pdev->dev);
  2890. pvt = mci->pvt_info;
  2891. memset(pvt, 0, sizeof(*pvt));
  2892. /* Associate sbridge_dev and mci for future usage */
  2893. pvt->sbridge_dev = sbridge_dev;
  2894. sbridge_dev->mci = mci;
  2895. mci->mtype_cap = type == KNIGHTS_LANDING ?
  2896. MEM_FLAG_DDR4 : MEM_FLAG_DDR3;
  2897. mci->edac_ctl_cap = EDAC_FLAG_NONE;
  2898. mci->edac_cap = EDAC_FLAG_NONE;
  2899. mci->mod_name = EDAC_MOD_STR;
  2900. mci->dev_name = pci_name(pdev);
  2901. mci->ctl_page_to_phys = NULL;
  2902. pvt->info.type = type;
  2903. switch (type) {
  2904. case IVY_BRIDGE:
  2905. pvt->info.rankcfgr = IB_RANK_CFG_A;
  2906. pvt->info.get_tolm = ibridge_get_tolm;
  2907. pvt->info.get_tohm = ibridge_get_tohm;
  2908. pvt->info.dram_rule = ibridge_dram_rule;
  2909. pvt->info.get_memory_type = get_memory_type;
  2910. pvt->info.get_node_id = get_node_id;
  2911. pvt->info.get_ha = ibridge_get_ha;
  2912. pvt->info.rir_limit = rir_limit;
  2913. pvt->info.sad_limit = sad_limit;
  2914. pvt->info.interleave_mode = interleave_mode;
  2915. pvt->info.dram_attr = dram_attr;
  2916. pvt->info.max_sad = ARRAY_SIZE(ibridge_dram_rule);
  2917. pvt->info.interleave_list = ibridge_interleave_list;
  2918. pvt->info.interleave_pkg = ibridge_interleave_pkg;
  2919. pvt->info.get_width = ibridge_get_width;
  2920. /* Store pci devices at mci for faster access */
  2921. rc = ibridge_mci_bind_devs(mci, sbridge_dev);
  2922. if (unlikely(rc < 0))
  2923. goto fail0;
  2924. get_source_id(mci);
  2925. mci->ctl_name = kasprintf(GFP_KERNEL, "Ivy Bridge SrcID#%d_Ha#%d",
  2926. pvt->sbridge_dev->source_id, pvt->sbridge_dev->dom);
  2927. break;
  2928. case SANDY_BRIDGE:
  2929. pvt->info.rankcfgr = SB_RANK_CFG_A;
  2930. pvt->info.get_tolm = sbridge_get_tolm;
  2931. pvt->info.get_tohm = sbridge_get_tohm;
  2932. pvt->info.dram_rule = sbridge_dram_rule;
  2933. pvt->info.get_memory_type = get_memory_type;
  2934. pvt->info.get_node_id = get_node_id;
  2935. pvt->info.get_ha = sbridge_get_ha;
  2936. pvt->info.rir_limit = rir_limit;
  2937. pvt->info.sad_limit = sad_limit;
  2938. pvt->info.interleave_mode = interleave_mode;
  2939. pvt->info.dram_attr = dram_attr;
  2940. pvt->info.max_sad = ARRAY_SIZE(sbridge_dram_rule);
  2941. pvt->info.interleave_list = sbridge_interleave_list;
  2942. pvt->info.interleave_pkg = sbridge_interleave_pkg;
  2943. pvt->info.get_width = sbridge_get_width;
  2944. /* Store pci devices at mci for faster access */
  2945. rc = sbridge_mci_bind_devs(mci, sbridge_dev);
  2946. if (unlikely(rc < 0))
  2947. goto fail0;
  2948. get_source_id(mci);
  2949. mci->ctl_name = kasprintf(GFP_KERNEL, "Sandy Bridge SrcID#%d_Ha#%d",
  2950. pvt->sbridge_dev->source_id, pvt->sbridge_dev->dom);
  2951. break;
  2952. case HASWELL:
  2953. /* rankcfgr isn't used */
  2954. pvt->info.get_tolm = haswell_get_tolm;
  2955. pvt->info.get_tohm = haswell_get_tohm;
  2956. pvt->info.dram_rule = ibridge_dram_rule;
  2957. pvt->info.get_memory_type = haswell_get_memory_type;
  2958. pvt->info.get_node_id = haswell_get_node_id;
  2959. pvt->info.get_ha = ibridge_get_ha;
  2960. pvt->info.rir_limit = haswell_rir_limit;
  2961. pvt->info.sad_limit = sad_limit;
  2962. pvt->info.interleave_mode = interleave_mode;
  2963. pvt->info.dram_attr = dram_attr;
  2964. pvt->info.max_sad = ARRAY_SIZE(ibridge_dram_rule);
  2965. pvt->info.interleave_list = ibridge_interleave_list;
  2966. pvt->info.interleave_pkg = ibridge_interleave_pkg;
  2967. pvt->info.get_width = ibridge_get_width;
  2968. /* Store pci devices at mci for faster access */
  2969. rc = haswell_mci_bind_devs(mci, sbridge_dev);
  2970. if (unlikely(rc < 0))
  2971. goto fail0;
  2972. get_source_id(mci);
  2973. mci->ctl_name = kasprintf(GFP_KERNEL, "Haswell SrcID#%d_Ha#%d",
  2974. pvt->sbridge_dev->source_id, pvt->sbridge_dev->dom);
  2975. break;
  2976. case BROADWELL:
  2977. /* rankcfgr isn't used */
  2978. pvt->info.get_tolm = haswell_get_tolm;
  2979. pvt->info.get_tohm = haswell_get_tohm;
  2980. pvt->info.dram_rule = ibridge_dram_rule;
  2981. pvt->info.get_memory_type = haswell_get_memory_type;
  2982. pvt->info.get_node_id = haswell_get_node_id;
  2983. pvt->info.get_ha = ibridge_get_ha;
  2984. pvt->info.rir_limit = haswell_rir_limit;
  2985. pvt->info.sad_limit = sad_limit;
  2986. pvt->info.interleave_mode = interleave_mode;
  2987. pvt->info.dram_attr = dram_attr;
  2988. pvt->info.max_sad = ARRAY_SIZE(ibridge_dram_rule);
  2989. pvt->info.interleave_list = ibridge_interleave_list;
  2990. pvt->info.interleave_pkg = ibridge_interleave_pkg;
  2991. pvt->info.get_width = broadwell_get_width;
  2992. /* Store pci devices at mci for faster access */
  2993. rc = broadwell_mci_bind_devs(mci, sbridge_dev);
  2994. if (unlikely(rc < 0))
  2995. goto fail0;
  2996. get_source_id(mci);
  2997. mci->ctl_name = kasprintf(GFP_KERNEL, "Broadwell SrcID#%d_Ha#%d",
  2998. pvt->sbridge_dev->source_id, pvt->sbridge_dev->dom);
  2999. break;
  3000. case KNIGHTS_LANDING:
  3001. /* pvt->info.rankcfgr == ??? */
  3002. pvt->info.get_tolm = knl_get_tolm;
  3003. pvt->info.get_tohm = knl_get_tohm;
  3004. pvt->info.dram_rule = knl_dram_rule;
  3005. pvt->info.get_memory_type = knl_get_memory_type;
  3006. pvt->info.get_node_id = knl_get_node_id;
  3007. pvt->info.get_ha = knl_get_ha;
  3008. pvt->info.rir_limit = NULL;
  3009. pvt->info.sad_limit = knl_sad_limit;
  3010. pvt->info.interleave_mode = knl_interleave_mode;
  3011. pvt->info.dram_attr = dram_attr_knl;
  3012. pvt->info.max_sad = ARRAY_SIZE(knl_dram_rule);
  3013. pvt->info.interleave_list = knl_interleave_list;
  3014. pvt->info.interleave_pkg = ibridge_interleave_pkg;
  3015. pvt->info.get_width = knl_get_width;
  3016. rc = knl_mci_bind_devs(mci, sbridge_dev);
  3017. if (unlikely(rc < 0))
  3018. goto fail0;
  3019. get_source_id(mci);
  3020. mci->ctl_name = kasprintf(GFP_KERNEL, "Knights Landing SrcID#%d_Ha#%d",
  3021. pvt->sbridge_dev->source_id, pvt->sbridge_dev->dom);
  3022. break;
  3023. }
  3024. if (!mci->ctl_name) {
  3025. rc = -ENOMEM;
  3026. goto fail0;
  3027. }
  3028. /* Get dimm basic config and the memory layout */
  3029. rc = get_dimm_config(mci);
  3030. if (rc < 0) {
  3031. edac_dbg(0, "MC: failed to get_dimm_config()\n");
  3032. goto fail;
  3033. }
  3034. get_memory_layout(mci);
  3035. /* record ptr to the generic device */
  3036. mci->pdev = &pdev->dev;
  3037. /* add this new MC control structure to EDAC's list of MCs */
  3038. if (unlikely(edac_mc_add_mc(mci))) {
  3039. edac_dbg(0, "MC: failed edac_mc_add_mc()\n");
  3040. rc = -EINVAL;
  3041. goto fail;
  3042. }
  3043. return 0;
  3044. fail:
  3045. kfree(mci->ctl_name);
  3046. fail0:
  3047. edac_mc_free(mci);
  3048. sbridge_dev->mci = NULL;
  3049. return rc;
  3050. }
  3051. static const struct x86_cpu_id sbridge_cpuids[] = {
  3052. X86_MATCH_VFM(INTEL_SANDYBRIDGE_X, &pci_dev_descr_sbridge_table),
  3053. X86_MATCH_VFM(INTEL_IVYBRIDGE_X, &pci_dev_descr_ibridge_table),
  3054. X86_MATCH_VFM(INTEL_HASWELL_X, &pci_dev_descr_haswell_table),
  3055. X86_MATCH_VFM(INTEL_BROADWELL_X, &pci_dev_descr_broadwell_table),
  3056. X86_MATCH_VFM(INTEL_BROADWELL_D, &pci_dev_descr_broadwell_table),
  3057. X86_MATCH_VFM(INTEL_XEON_PHI_KNL, &pci_dev_descr_knl_table),
  3058. X86_MATCH_VFM(INTEL_XEON_PHI_KNM, &pci_dev_descr_knl_table),
  3059. { }
  3060. };
  3061. MODULE_DEVICE_TABLE(x86cpu, sbridge_cpuids);
  3062. /*
  3063. * sbridge_probe Get all devices and register memory controllers
  3064. * present.
  3065. * return:
  3066. * 0 for FOUND a device
  3067. * < 0 for error code
  3068. */
  3069. static int sbridge_probe(const struct x86_cpu_id *id)
  3070. {
  3071. int rc;
  3072. u8 mc, num_mc = 0;
  3073. struct sbridge_dev *sbridge_dev;
  3074. struct pci_id_table *ptable = (struct pci_id_table *)id->driver_data;
  3075. /* get the pci devices we want to reserve for our use */
  3076. rc = sbridge_get_all_devices(&num_mc, ptable);
  3077. if (unlikely(rc < 0)) {
  3078. edac_dbg(0, "couldn't get all devices\n");
  3079. goto fail0;
  3080. }
  3081. mc = 0;
  3082. list_for_each_entry(sbridge_dev, &sbridge_edac_list, list) {
  3083. edac_dbg(0, "Registering MC#%d (%d of %d)\n",
  3084. mc, mc + 1, num_mc);
  3085. sbridge_dev->mc = mc++;
  3086. rc = sbridge_register_mci(sbridge_dev, ptable->type);
  3087. if (unlikely(rc < 0))
  3088. goto fail1;
  3089. }
  3090. sbridge_printk(KERN_INFO, "%s\n", SBRIDGE_REVISION);
  3091. return 0;
  3092. fail1:
  3093. list_for_each_entry(sbridge_dev, &sbridge_edac_list, list)
  3094. sbridge_unregister_mci(sbridge_dev);
  3095. sbridge_put_all_devices();
  3096. fail0:
  3097. return rc;
  3098. }
  3099. /*
  3100. * sbridge_remove cleanup
  3101. *
  3102. */
  3103. static void sbridge_remove(void)
  3104. {
  3105. struct sbridge_dev *sbridge_dev;
  3106. edac_dbg(0, "\n");
  3107. list_for_each_entry(sbridge_dev, &sbridge_edac_list, list)
  3108. sbridge_unregister_mci(sbridge_dev);
  3109. /* Release PCI resources */
  3110. sbridge_put_all_devices();
  3111. }
  3112. /*
  3113. * sbridge_init Module entry function
  3114. * Try to initialize this module for its devices
  3115. */
  3116. static int __init sbridge_init(void)
  3117. {
  3118. const struct x86_cpu_id *id;
  3119. const char *owner;
  3120. int rc;
  3121. edac_dbg(2, "\n");
  3122. if (ghes_get_devices())
  3123. return -EBUSY;
  3124. owner = edac_get_owner();
  3125. if (owner && strncmp(owner, EDAC_MOD_STR, sizeof(EDAC_MOD_STR)))
  3126. return -EBUSY;
  3127. if (cpu_feature_enabled(X86_FEATURE_HYPERVISOR))
  3128. return -ENODEV;
  3129. id = x86_match_cpu(sbridge_cpuids);
  3130. if (!id)
  3131. return -ENODEV;
  3132. /* Ensure that the OPSTATE is set correctly for POLL or NMI */
  3133. opstate_init();
  3134. rc = sbridge_probe(id);
  3135. if (rc >= 0) {
  3136. mce_register_decode_chain(&sbridge_mce_dec);
  3137. return 0;
  3138. }
  3139. sbridge_printk(KERN_ERR, "Failed to register device with error %d.\n",
  3140. rc);
  3141. return rc;
  3142. }
  3143. /*
  3144. * sbridge_exit() Module exit function
  3145. * Unregister the driver
  3146. */
  3147. static void __exit sbridge_exit(void)
  3148. {
  3149. edac_dbg(2, "\n");
  3150. sbridge_remove();
  3151. mce_unregister_decode_chain(&sbridge_mce_dec);
  3152. }
  3153. module_init(sbridge_init);
  3154. module_exit(sbridge_exit);
  3155. module_param(edac_op_state, int, 0444);
  3156. MODULE_PARM_DESC(edac_op_state, "EDAC Error Reporting state: 0=Poll,1=NMI");
  3157. MODULE_LICENSE("GPL");
  3158. MODULE_AUTHOR("Mauro Carvalho Chehab");
  3159. MODULE_AUTHOR("Red Hat Inc. (https://www.redhat.com)");
  3160. MODULE_DESCRIPTION("MC Driver for Intel Sandy Bridge and Ivy Bridge memory controllers - "
  3161. SBRIDGE_REVISION);