ppc970-pmu.c 13 KB

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  1. /*
  2. * Performance counter support for PPC970-family processors.
  3. *
  4. * Copyright 2008-2009 Paul Mackerras, IBM Corporation.
  5. *
  6. * This program is free software; you can redistribute it and/or
  7. * modify it under the terms of the GNU General Public License
  8. * as published by the Free Software Foundation; either version
  9. * 2 of the License, or (at your option) any later version.
  10. */
  11. #include <linux/string.h>
  12. #include <linux/perf_event.h>
  13. #include <asm/reg.h>
  14. #include <asm/cputable.h>
  15. /*
  16. * Bits in event code for PPC970
  17. */
  18. #define PM_PMC_SH 12 /* PMC number (1-based) for direct events */
  19. #define PM_PMC_MSK 0xf
  20. #define PM_UNIT_SH 8 /* TTMMUX number and setting - unit select */
  21. #define PM_UNIT_MSK 0xf
  22. #define PM_SPCSEL_SH 6
  23. #define PM_SPCSEL_MSK 3
  24. #define PM_BYTE_SH 4 /* Byte number of event bus to use */
  25. #define PM_BYTE_MSK 3
  26. #define PM_PMCSEL_MSK 0xf
  27. /* Values in PM_UNIT field */
  28. #define PM_NONE 0
  29. #define PM_FPU 1
  30. #define PM_VPU 2
  31. #define PM_ISU 3
  32. #define PM_IFU 4
  33. #define PM_IDU 5
  34. #define PM_STS 6
  35. #define PM_LSU0 7
  36. #define PM_LSU1U 8
  37. #define PM_LSU1L 9
  38. #define PM_LASTUNIT 9
  39. /*
  40. * Bits in MMCR0 for PPC970
  41. */
  42. #define MMCR0_PMC1SEL_SH 8
  43. #define MMCR0_PMC2SEL_SH 1
  44. #define MMCR_PMCSEL_MSK 0x1f
  45. /*
  46. * Bits in MMCR1 for PPC970
  47. */
  48. #define MMCR1_TTM0SEL_SH 62
  49. #define MMCR1_TTM1SEL_SH 59
  50. #define MMCR1_TTM3SEL_SH 53
  51. #define MMCR1_TTMSEL_MSK 3
  52. #define MMCR1_TD_CP_DBG0SEL_SH 50
  53. #define MMCR1_TD_CP_DBG1SEL_SH 48
  54. #define MMCR1_TD_CP_DBG2SEL_SH 46
  55. #define MMCR1_TD_CP_DBG3SEL_SH 44
  56. #define MMCR1_PMC1_ADDER_SEL_SH 39
  57. #define MMCR1_PMC2_ADDER_SEL_SH 38
  58. #define MMCR1_PMC6_ADDER_SEL_SH 37
  59. #define MMCR1_PMC5_ADDER_SEL_SH 36
  60. #define MMCR1_PMC8_ADDER_SEL_SH 35
  61. #define MMCR1_PMC7_ADDER_SEL_SH 34
  62. #define MMCR1_PMC3_ADDER_SEL_SH 33
  63. #define MMCR1_PMC4_ADDER_SEL_SH 32
  64. #define MMCR1_PMC3SEL_SH 27
  65. #define MMCR1_PMC4SEL_SH 22
  66. #define MMCR1_PMC5SEL_SH 17
  67. #define MMCR1_PMC6SEL_SH 12
  68. #define MMCR1_PMC7SEL_SH 7
  69. #define MMCR1_PMC8SEL_SH 2
  70. static short mmcr1_adder_bits[8] = {
  71. MMCR1_PMC1_ADDER_SEL_SH,
  72. MMCR1_PMC2_ADDER_SEL_SH,
  73. MMCR1_PMC3_ADDER_SEL_SH,
  74. MMCR1_PMC4_ADDER_SEL_SH,
  75. MMCR1_PMC5_ADDER_SEL_SH,
  76. MMCR1_PMC6_ADDER_SEL_SH,
  77. MMCR1_PMC7_ADDER_SEL_SH,
  78. MMCR1_PMC8_ADDER_SEL_SH
  79. };
  80. /*
  81. * Layout of constraint bits:
  82. * 6666555555555544444444443333333333222222222211111111110000000000
  83. * 3210987654321098765432109876543210987654321098765432109876543210
  84. * <><><>[ >[ >[ >< >< >< >< ><><><><><><><><>
  85. * SPT0T1 UC PS1 PS2 B0 B1 B2 B3 P1P2P3P4P5P6P7P8
  86. *
  87. * SP - SPCSEL constraint
  88. * 48-49: SPCSEL value 0x3_0000_0000_0000
  89. *
  90. * T0 - TTM0 constraint
  91. * 46-47: TTM0SEL value (0=FPU, 2=IFU, 3=VPU) 0xC000_0000_0000
  92. *
  93. * T1 - TTM1 constraint
  94. * 44-45: TTM1SEL value (0=IDU, 3=STS) 0x3000_0000_0000
  95. *
  96. * UC - unit constraint: can't have all three of FPU|IFU|VPU, ISU, IDU|STS
  97. * 43: UC3 error 0x0800_0000_0000
  98. * 42: FPU|IFU|VPU events needed 0x0400_0000_0000
  99. * 41: ISU events needed 0x0200_0000_0000
  100. * 40: IDU|STS events needed 0x0100_0000_0000
  101. *
  102. * PS1
  103. * 39: PS1 error 0x0080_0000_0000
  104. * 36-38: count of events needing PMC1/2/5/6 0x0070_0000_0000
  105. *
  106. * PS2
  107. * 35: PS2 error 0x0008_0000_0000
  108. * 32-34: count of events needing PMC3/4/7/8 0x0007_0000_0000
  109. *
  110. * B0
  111. * 28-31: Byte 0 event source 0xf000_0000
  112. * Encoding as for the event code
  113. *
  114. * B1, B2, B3
  115. * 24-27, 20-23, 16-19: Byte 1, 2, 3 event sources
  116. *
  117. * P1
  118. * 15: P1 error 0x8000
  119. * 14-15: Count of events needing PMC1
  120. *
  121. * P2..P8
  122. * 0-13: Count of events needing PMC2..PMC8
  123. */
  124. static unsigned char direct_marked_event[8] = {
  125. (1<<2) | (1<<3), /* PMC1: PM_MRK_GRP_DISP, PM_MRK_ST_CMPL */
  126. (1<<3) | (1<<5), /* PMC2: PM_THRESH_TIMEO, PM_MRK_BRU_FIN */
  127. (1<<3) | (1<<5), /* PMC3: PM_MRK_ST_CMPL_INT, PM_MRK_VMX_FIN */
  128. (1<<4) | (1<<5), /* PMC4: PM_MRK_GRP_CMPL, PM_MRK_CRU_FIN */
  129. (1<<4) | (1<<5), /* PMC5: PM_GRP_MRK, PM_MRK_GRP_TIMEO */
  130. (1<<3) | (1<<4) | (1<<5),
  131. /* PMC6: PM_MRK_ST_STS, PM_MRK_FXU_FIN, PM_MRK_GRP_ISSUED */
  132. (1<<4) | (1<<5), /* PMC7: PM_MRK_FPU_FIN, PM_MRK_INST_FIN */
  133. (1<<4) /* PMC8: PM_MRK_LSU_FIN */
  134. };
  135. /*
  136. * Returns 1 if event counts things relating to marked instructions
  137. * and thus needs the MMCRA_SAMPLE_ENABLE bit set, or 0 if not.
  138. */
  139. static int p970_marked_instr_event(u64 event)
  140. {
  141. int pmc, psel, unit, byte, bit;
  142. unsigned int mask;
  143. pmc = (event >> PM_PMC_SH) & PM_PMC_MSK;
  144. psel = event & PM_PMCSEL_MSK;
  145. if (pmc) {
  146. if (direct_marked_event[pmc - 1] & (1 << psel))
  147. return 1;
  148. if (psel == 0) /* add events */
  149. bit = (pmc <= 4)? pmc - 1: 8 - pmc;
  150. else if (psel == 7 || psel == 13) /* decode events */
  151. bit = 4;
  152. else
  153. return 0;
  154. } else
  155. bit = psel;
  156. byte = (event >> PM_BYTE_SH) & PM_BYTE_MSK;
  157. unit = (event >> PM_UNIT_SH) & PM_UNIT_MSK;
  158. mask = 0;
  159. switch (unit) {
  160. case PM_VPU:
  161. mask = 0x4c; /* byte 0 bits 2,3,6 */
  162. break;
  163. case PM_LSU0:
  164. /* byte 2 bits 0,2,3,4,6; all of byte 1 */
  165. mask = 0x085dff00;
  166. break;
  167. case PM_LSU1L:
  168. mask = 0x50 << 24; /* byte 3 bits 4,6 */
  169. break;
  170. }
  171. return (mask >> (byte * 8 + bit)) & 1;
  172. }
  173. /* Masks and values for using events from the various units */
  174. static unsigned long unit_cons[PM_LASTUNIT+1][2] = {
  175. [PM_FPU] = { 0xc80000000000ull, 0x040000000000ull },
  176. [PM_VPU] = { 0xc80000000000ull, 0xc40000000000ull },
  177. [PM_ISU] = { 0x080000000000ull, 0x020000000000ull },
  178. [PM_IFU] = { 0xc80000000000ull, 0x840000000000ull },
  179. [PM_IDU] = { 0x380000000000ull, 0x010000000000ull },
  180. [PM_STS] = { 0x380000000000ull, 0x310000000000ull },
  181. };
  182. static int p970_get_constraint(u64 event, unsigned long *maskp,
  183. unsigned long *valp)
  184. {
  185. int pmc, byte, unit, sh, spcsel;
  186. unsigned long mask = 0, value = 0;
  187. int grp = -1;
  188. pmc = (event >> PM_PMC_SH) & PM_PMC_MSK;
  189. if (pmc) {
  190. if (pmc > 8)
  191. return -1;
  192. sh = (pmc - 1) * 2;
  193. mask |= 2 << sh;
  194. value |= 1 << sh;
  195. grp = ((pmc - 1) >> 1) & 1;
  196. }
  197. unit = (event >> PM_UNIT_SH) & PM_UNIT_MSK;
  198. if (unit) {
  199. if (unit > PM_LASTUNIT)
  200. return -1;
  201. mask |= unit_cons[unit][0];
  202. value |= unit_cons[unit][1];
  203. byte = (event >> PM_BYTE_SH) & PM_BYTE_MSK;
  204. /*
  205. * Bus events on bytes 0 and 2 can be counted
  206. * on PMC1/2/5/6; bytes 1 and 3 on PMC3/4/7/8.
  207. */
  208. if (!pmc)
  209. grp = byte & 1;
  210. /* Set byte lane select field */
  211. mask |= 0xfULL << (28 - 4 * byte);
  212. value |= (unsigned long)unit << (28 - 4 * byte);
  213. }
  214. if (grp == 0) {
  215. /* increment PMC1/2/5/6 field */
  216. mask |= 0x8000000000ull;
  217. value |= 0x1000000000ull;
  218. } else if (grp == 1) {
  219. /* increment PMC3/4/7/8 field */
  220. mask |= 0x800000000ull;
  221. value |= 0x100000000ull;
  222. }
  223. spcsel = (event >> PM_SPCSEL_SH) & PM_SPCSEL_MSK;
  224. if (spcsel) {
  225. mask |= 3ull << 48;
  226. value |= (unsigned long)spcsel << 48;
  227. }
  228. *maskp = mask;
  229. *valp = value;
  230. return 0;
  231. }
  232. static int p970_get_alternatives(u64 event, unsigned int flags, u64 alt[])
  233. {
  234. alt[0] = event;
  235. /* 2 alternatives for LSU empty */
  236. if (event == 0x2002 || event == 0x3002) {
  237. alt[1] = event ^ 0x1000;
  238. return 2;
  239. }
  240. return 1;
  241. }
  242. static int p970_compute_mmcr(u64 event[], int n_ev,
  243. unsigned int hwc[], unsigned long mmcr[], struct perf_event *pevents[])
  244. {
  245. unsigned long mmcr0 = 0, mmcr1 = 0, mmcra = 0;
  246. unsigned int pmc, unit, byte, psel;
  247. unsigned int ttm, grp;
  248. unsigned int pmc_inuse = 0;
  249. unsigned int pmc_grp_use[2];
  250. unsigned char busbyte[4];
  251. unsigned char unituse[16];
  252. unsigned char unitmap[] = { 0, 0<<3, 3<<3, 1<<3, 2<<3, 0|4, 3|4 };
  253. unsigned char ttmuse[2];
  254. unsigned char pmcsel[8];
  255. int i;
  256. int spcsel;
  257. if (n_ev > 8)
  258. return -1;
  259. /* First pass to count resource use */
  260. pmc_grp_use[0] = pmc_grp_use[1] = 0;
  261. memset(busbyte, 0, sizeof(busbyte));
  262. memset(unituse, 0, sizeof(unituse));
  263. for (i = 0; i < n_ev; ++i) {
  264. pmc = (event[i] >> PM_PMC_SH) & PM_PMC_MSK;
  265. if (pmc) {
  266. if (pmc_inuse & (1 << (pmc - 1)))
  267. return -1;
  268. pmc_inuse |= 1 << (pmc - 1);
  269. /* count 1/2/5/6 vs 3/4/7/8 use */
  270. ++pmc_grp_use[((pmc - 1) >> 1) & 1];
  271. }
  272. unit = (event[i] >> PM_UNIT_SH) & PM_UNIT_MSK;
  273. byte = (event[i] >> PM_BYTE_SH) & PM_BYTE_MSK;
  274. if (unit) {
  275. if (unit > PM_LASTUNIT)
  276. return -1;
  277. if (!pmc)
  278. ++pmc_grp_use[byte & 1];
  279. if (busbyte[byte] && busbyte[byte] != unit)
  280. return -1;
  281. busbyte[byte] = unit;
  282. unituse[unit] = 1;
  283. }
  284. }
  285. if (pmc_grp_use[0] > 4 || pmc_grp_use[1] > 4)
  286. return -1;
  287. /*
  288. * Assign resources and set multiplexer selects.
  289. *
  290. * PM_ISU can go either on TTM0 or TTM1, but that's the only
  291. * choice we have to deal with.
  292. */
  293. if (unituse[PM_ISU] &
  294. (unituse[PM_FPU] | unituse[PM_IFU] | unituse[PM_VPU]))
  295. unitmap[PM_ISU] = 2 | 4; /* move ISU to TTM1 */
  296. /* Set TTM[01]SEL fields. */
  297. ttmuse[0] = ttmuse[1] = 0;
  298. for (i = PM_FPU; i <= PM_STS; ++i) {
  299. if (!unituse[i])
  300. continue;
  301. ttm = unitmap[i];
  302. ++ttmuse[(ttm >> 2) & 1];
  303. mmcr1 |= (unsigned long)(ttm & ~4) << MMCR1_TTM1SEL_SH;
  304. }
  305. /* Check only one unit per TTMx */
  306. if (ttmuse[0] > 1 || ttmuse[1] > 1)
  307. return -1;
  308. /* Set byte lane select fields and TTM3SEL. */
  309. for (byte = 0; byte < 4; ++byte) {
  310. unit = busbyte[byte];
  311. if (!unit)
  312. continue;
  313. if (unit <= PM_STS)
  314. ttm = (unitmap[unit] >> 2) & 1;
  315. else if (unit == PM_LSU0)
  316. ttm = 2;
  317. else {
  318. ttm = 3;
  319. if (unit == PM_LSU1L && byte >= 2)
  320. mmcr1 |= 1ull << (MMCR1_TTM3SEL_SH + 3 - byte);
  321. }
  322. mmcr1 |= (unsigned long)ttm
  323. << (MMCR1_TD_CP_DBG0SEL_SH - 2 * byte);
  324. }
  325. /* Second pass: assign PMCs, set PMCxSEL and PMCx_ADDER_SEL fields */
  326. memset(pmcsel, 0x8, sizeof(pmcsel)); /* 8 means don't count */
  327. for (i = 0; i < n_ev; ++i) {
  328. pmc = (event[i] >> PM_PMC_SH) & PM_PMC_MSK;
  329. unit = (event[i] >> PM_UNIT_SH) & PM_UNIT_MSK;
  330. byte = (event[i] >> PM_BYTE_SH) & PM_BYTE_MSK;
  331. psel = event[i] & PM_PMCSEL_MSK;
  332. if (!pmc) {
  333. /* Bus event or any-PMC direct event */
  334. if (unit)
  335. psel |= 0x10 | ((byte & 2) << 2);
  336. else
  337. psel |= 8;
  338. for (pmc = 0; pmc < 8; ++pmc) {
  339. if (pmc_inuse & (1 << pmc))
  340. continue;
  341. grp = (pmc >> 1) & 1;
  342. if (unit) {
  343. if (grp == (byte & 1))
  344. break;
  345. } else if (pmc_grp_use[grp] < 4) {
  346. ++pmc_grp_use[grp];
  347. break;
  348. }
  349. }
  350. pmc_inuse |= 1 << pmc;
  351. } else {
  352. /* Direct event */
  353. --pmc;
  354. if (psel == 0 && (byte & 2))
  355. /* add events on higher-numbered bus */
  356. mmcr1 |= 1ull << mmcr1_adder_bits[pmc];
  357. }
  358. pmcsel[pmc] = psel;
  359. hwc[i] = pmc;
  360. spcsel = (event[i] >> PM_SPCSEL_SH) & PM_SPCSEL_MSK;
  361. mmcr1 |= spcsel;
  362. if (p970_marked_instr_event(event[i]))
  363. mmcra |= MMCRA_SAMPLE_ENABLE;
  364. }
  365. for (pmc = 0; pmc < 2; ++pmc)
  366. mmcr0 |= pmcsel[pmc] << (MMCR0_PMC1SEL_SH - 7 * pmc);
  367. for (; pmc < 8; ++pmc)
  368. mmcr1 |= (unsigned long)pmcsel[pmc]
  369. << (MMCR1_PMC3SEL_SH - 5 * (pmc - 2));
  370. if (pmc_inuse & 1)
  371. mmcr0 |= MMCR0_PMC1CE;
  372. if (pmc_inuse & 0xfe)
  373. mmcr0 |= MMCR0_PMCjCE;
  374. mmcra |= 0x2000; /* mark only one IOP per PPC instruction */
  375. /* Return MMCRx values */
  376. mmcr[0] = mmcr0;
  377. mmcr[1] = mmcr1;
  378. mmcr[2] = mmcra;
  379. return 0;
  380. }
  381. static void p970_disable_pmc(unsigned int pmc, unsigned long mmcr[])
  382. {
  383. int shift, i;
  384. if (pmc <= 1) {
  385. shift = MMCR0_PMC1SEL_SH - 7 * pmc;
  386. i = 0;
  387. } else {
  388. shift = MMCR1_PMC3SEL_SH - 5 * (pmc - 2);
  389. i = 1;
  390. }
  391. /*
  392. * Setting the PMCxSEL field to 0x08 disables PMC x.
  393. */
  394. mmcr[i] = (mmcr[i] & ~(0x1fUL << shift)) | (0x08UL << shift);
  395. }
  396. static int ppc970_generic_events[] = {
  397. [PERF_COUNT_HW_CPU_CYCLES] = 7,
  398. [PERF_COUNT_HW_INSTRUCTIONS] = 1,
  399. [PERF_COUNT_HW_CACHE_REFERENCES] = 0x8810, /* PM_LD_REF_L1 */
  400. [PERF_COUNT_HW_CACHE_MISSES] = 0x3810, /* PM_LD_MISS_L1 */
  401. [PERF_COUNT_HW_BRANCH_INSTRUCTIONS] = 0x431, /* PM_BR_ISSUED */
  402. [PERF_COUNT_HW_BRANCH_MISSES] = 0x327, /* PM_GRP_BR_MPRED */
  403. };
  404. #define C(x) PERF_COUNT_HW_CACHE_##x
  405. /*
  406. * Table of generalized cache-related events.
  407. * 0 means not supported, -1 means nonsensical, other values
  408. * are event codes.
  409. */
  410. static int ppc970_cache_events[C(MAX)][C(OP_MAX)][C(RESULT_MAX)] = {
  411. [C(L1D)] = { /* RESULT_ACCESS RESULT_MISS */
  412. [C(OP_READ)] = { 0x8810, 0x3810 },
  413. [C(OP_WRITE)] = { 0x7810, 0x813 },
  414. [C(OP_PREFETCH)] = { 0x731, 0 },
  415. },
  416. [C(L1I)] = { /* RESULT_ACCESS RESULT_MISS */
  417. [C(OP_READ)] = { 0, 0 },
  418. [C(OP_WRITE)] = { -1, -1 },
  419. [C(OP_PREFETCH)] = { 0, 0 },
  420. },
  421. [C(LL)] = { /* RESULT_ACCESS RESULT_MISS */
  422. [C(OP_READ)] = { 0, 0 },
  423. [C(OP_WRITE)] = { 0, 0 },
  424. [C(OP_PREFETCH)] = { 0x733, 0 },
  425. },
  426. [C(DTLB)] = { /* RESULT_ACCESS RESULT_MISS */
  427. [C(OP_READ)] = { 0, 0x704 },
  428. [C(OP_WRITE)] = { -1, -1 },
  429. [C(OP_PREFETCH)] = { -1, -1 },
  430. },
  431. [C(ITLB)] = { /* RESULT_ACCESS RESULT_MISS */
  432. [C(OP_READ)] = { 0, 0x700 },
  433. [C(OP_WRITE)] = { -1, -1 },
  434. [C(OP_PREFETCH)] = { -1, -1 },
  435. },
  436. [C(BPU)] = { /* RESULT_ACCESS RESULT_MISS */
  437. [C(OP_READ)] = { 0x431, 0x327 },
  438. [C(OP_WRITE)] = { -1, -1 },
  439. [C(OP_PREFETCH)] = { -1, -1 },
  440. },
  441. [C(NODE)] = { /* RESULT_ACCESS RESULT_MISS */
  442. [C(OP_READ)] = { -1, -1 },
  443. [C(OP_WRITE)] = { -1, -1 },
  444. [C(OP_PREFETCH)] = { -1, -1 },
  445. },
  446. };
  447. static struct power_pmu ppc970_pmu = {
  448. .name = "PPC970/FX/MP",
  449. .n_counter = 8,
  450. .max_alternatives = 2,
  451. .add_fields = 0x001100005555ull,
  452. .test_adder = 0x013300000000ull,
  453. .compute_mmcr = p970_compute_mmcr,
  454. .get_constraint = p970_get_constraint,
  455. .get_alternatives = p970_get_alternatives,
  456. .disable_pmc = p970_disable_pmc,
  457. .n_generic = ARRAY_SIZE(ppc970_generic_events),
  458. .generic_events = ppc970_generic_events,
  459. .cache_events = &ppc970_cache_events,
  460. .flags = PPMU_NO_SIPR | PPMU_NO_CONT_SAMPLING,
  461. };
  462. static int __init init_ppc970_pmu(void)
  463. {
  464. if (!cur_cpu_spec->oprofile_cpu_type ||
  465. (strcmp(cur_cpu_spec->oprofile_cpu_type, "ppc64/970")
  466. && strcmp(cur_cpu_spec->oprofile_cpu_type, "ppc64/970MP")))
  467. return -ENODEV;
  468. return register_power_pmu(&ppc970_pmu);
  469. }
  470. early_initcall(init_ppc970_pmu);