blob: 442ca493d76b75b982fa02b36de62fb7896141a4 [file] [log] [blame]
Suneel Garapati40e61332019-10-19 18:03:01 -07001// SPDX-License-Identifier: GPL-2.0
2/*
3 * Copyright (C) 2019 Marvell International Ltd.
4 *
5 * https://spdx.org/licenses
6 */
7
8//#define DEBUG
9#include <cpu_func.h>
10#include <dm.h>
11#include <dm/lists.h>
12#include <env.h>
13#include <errno.h>
14#include <fdtdec.h>
15#include <log.h>
16#include <malloc.h>
17#include <memalign.h>
18#include <mmc.h>
19#include <part.h>
20#include <pci.h>
21#include <pci_ids.h>
22#include <time.h>
23#include <watchdog.h>
24
25#include <linux/delay.h>
26#include <linux/kernel.h>
27#include <linux/libfdt.h>
28
29#include <asm/arch/board.h>
30#include <asm/arch/clock.h>
31#include <asm/arch/csrs/csrs-mio_emm.h>
32#include <asm/io.h>
Simon Glass95588622020-12-22 19:30:28 -070033#include <dm/device-internal.h>
Suneel Garapati40e61332019-10-19 18:03:01 -070034
35#include <power/regulator.h>
36
37#include "octeontx_hsmmc.h"
38
39#define MMC_TIMEOUT_SHORT 20 /* in ms */
40#define MMC_TIMEOUT_LONG 1000
41#define MMC_TIMEOUT_ERASE 10000
42
43#define MMC_DEFAULT_DATA_IN_TAP 10
44#define MMC_DEFAULT_CMD_IN_TAP 10
45#define MMC_DEFAULT_CMD_OUT_TAP 39
46#define MMC_DEFAULT_DATA_OUT_TAP 39
47#define MMC_DEFAULT_HS200_CMD_IN_TAP 24
48#define MMC_DEFAULT_HS200_DATA_IN_TAP 24
49#define MMC_DEFAULT_HS200_CMD_OUT_TAP (otx_is_soc(CN95XX) ? 10 : 5)
50#define MMC_DEFAULT_HS200_DATA_OUT_TAP (otx_is_soc(CN95XX) ? 10 : 5)
51#define MMC_DEFAULT_HS400_CMD_OUT_TAP (otx_is_soc(CN95XX) ? 10 : 5)
52#define MMC_DEFAULT_HS400_DATA_OUT_TAP (otx_is_soc(CN95XX) ? 5 : 3)
53#define MMC_DEFAULT_HS200_CMD_OUT_DLY 800 /* Delay in ps */
54#define MMC_DEFAULT_HS200_DATA_OUT_DLY 800 /* Delay in ps */
55#define MMC_DEFAULT_HS400_CMD_OUT_DLY 800 /* Delay in ps */
56#define MMC_DEFAULT_HS400_DATA_OUT_DLY 400 /* Delay in ps */
57#define MMC_DEFAULT_SD_UHS_SDR104_CMD_OUT_TAP MMC_DEFAULT_HS200_CMD_OUT_TAP
58#define MMC_DEFAULT_SD_UHS_SDR104_DATA_OUT_TAP MMC_DEFAULT_HS200_DATA_OUT_TAP
59#define MMC_LEGACY_DEFAULT_CMD_OUT_TAP 39
60#define MMC_LEGACY_DEFAULT_DATA_OUT_TAP 39
61#define MMC_SD_LEGACY_DEFAULT_CMD_OUT_TAP 63
62#define MMC_SD_LEGACY_DEFAULT_DATA_OUT_TAP 63
63#define MMC_HS_CMD_OUT_TAP 32
64#define MMC_HS_DATA_OUT_TAP 32
65#define MMC_SD_HS_CMD_OUT_TAP 26
66#define MMC_SD_HS_DATA_OUT_TAP 26
67#define MMC_SD_UHS_SDR25_CMD_OUT_TAP 26
68#define MMC_SD_UHS_SDR25_DATA_OUT_TAP 26
69#define MMC_SD_UHS_SDR50_CMD_OUT_TAP 26
70#define MMC_SD_UHS_SDR50_DATA_OUT_TAP 26
71#define MMC_DEFAULT_TAP_DELAY 4
72#define TOTAL_NO_OF_TAPS 512
73static void octeontx_mmc_switch_to(struct mmc *mmc);
74static int octeontx_mmc_configure_delay(struct mmc *mmc);
75static void octeontx_mmc_set_timing(struct mmc *mmc);
76static void set_wdog(struct mmc *mmc, u64 us);
77static void do_switch(struct mmc *mmc, union mio_emm_switch emm_switch);
78static int octeontx_mmc_send_cmd(struct mmc *mmc, struct mmc_cmd *cmd,
79 struct mmc_data *data);
80static int octeontx2_mmc_calc_delay(struct mmc *mmc, int delay);
81static int octeontx_mmc_calibrate_delay(struct mmc *mmc);
82static int octeontx_mmc_set_input_bus_timing(struct mmc *mmc);
83static int octeontx_mmc_set_output_bus_timing(struct mmc *mmc);
84
85static bool host_probed;
86
87/**
88 * Get the slot data structure from a MMC data structure
89 */
90static inline struct octeontx_mmc_slot *mmc_to_slot(struct mmc *mmc)
91{
92 return container_of(mmc, struct octeontx_mmc_slot, mmc);
93}
94
95static inline struct octeontx_mmc_host *mmc_to_host(struct mmc *mmc)
96{
97 return mmc_to_slot(mmc)->host;
98}
99
100static inline struct octeontx_mmc_slot *dev_to_mmc_slot(struct udevice *dev)
101{
102 return dev_get_priv(dev);
103}
104
105static inline struct mmc *dev_to_mmc(struct udevice *dev)
106{
107 return &((struct octeontx_mmc_slot *)dev_get_priv(dev))->mmc;
108}
109
110#ifdef DEBUG
111const char *mmc_reg_str(u64 reg)
112{
113 if (reg == MIO_EMM_DMA_CFG())
114 return "MIO_EMM_DMA_CFG";
115 if (reg == MIO_EMM_DMA_ADR())
116 return "MIO_EMM_DMA_ADR";
117 if (reg == MIO_EMM_DMA_INT())
118 return "MIO_EMM_DMA_INT";
119 if (reg == MIO_EMM_CFG())
120 return "MIO_EMM_CFG";
121 if (reg == MIO_EMM_MODEX(0))
122 return "MIO_EMM_MODE0";
123 if (reg == MIO_EMM_MODEX(1))
124 return "MIO_EMM_MODE1";
125 if (reg == MIO_EMM_MODEX(2))
126 return "MIO_EMM_MODE2";
127 if (reg == MIO_EMM_MODEX(3))
128 return "MIO_EMM_MODE3";
129 if (reg == MIO_EMM_IO_CTL())
130 return "MIO_EMM_IO_CTL";
131 if (reg == MIO_EMM_SWITCH())
132 return "MIO_EMM_SWITCH";
133 if (reg == MIO_EMM_DMA())
134 return "MIO_EMM_DMA";
135 if (reg == MIO_EMM_CMD())
136 return "MIO_EMM_CMD";
137 if (reg == MIO_EMM_RSP_STS())
138 return "MIO_EMM_RSP_STS";
139 if (reg == MIO_EMM_RSP_LO())
140 return "MIO_EMM_RSP_LO";
141 if (reg == MIO_EMM_RSP_HI())
142 return "MIO_EMM_RSP_HI";
143 if (reg == MIO_EMM_INT())
144 return "MIO_EMM_INT";
145 if (reg == MIO_EMM_WDOG())
146 return "MIO_EMM_WDOG";
147 if (reg == MIO_EMM_DMA_ARG())
148 return "MIO_EMM_DMA_ARG";
149 if (IS_ENABLED(CONFIG_ARCH_OCTEONTX)) {
150 if (reg == MIO_EMM_SAMPLE())
151 return "MIO_EMM_SAMPLE";
152 }
153 if (reg == MIO_EMM_STS_MASK())
154 return "MIO_EMM_STS_MASK";
155 if (reg == MIO_EMM_RCA())
156 return "MIO_EMM_RCA";
157 if (reg == MIO_EMM_BUF_IDX())
158 return "MIO_EMM_BUF_IDX";
159 if (reg == MIO_EMM_BUF_DAT())
160 return "MIO_EMM_BUF_DAT";
161 if (!IS_ENABLED(CONFIG_ARCH_OCTEONTX)) {
162 if (reg == MIO_EMM_CALB())
163 return "MIO_EMM_CALB";
164 if (reg == MIO_EMM_TAP())
165 return "MIO_EMM_TAP";
166 if (reg == MIO_EMM_TIMING())
167 return "MIO_EMM_TIMING";
168 if (reg == MIO_EMM_DEBUG())
169 return "MIO_EMM_DEBUG";
170 }
171
172 return "UNKNOWN";
173}
174#endif
175
176static void octeontx_print_rsp_sts(struct mmc *mmc)
177{
178#ifdef DEBUG
179 union mio_emm_rsp_sts emm_rsp_sts;
180 const struct octeontx_mmc_host *host = mmc_to_host(mmc);
181 static const char * const ctype_xor_str[] = {
182 "No data",
183 "Read data into Dbuf",
184 "Write data from Dbuf",
185 "Reserved"
186 };
187
188 static const char * const rtype_xor_str[] = {
189 "No response",
190 "R1, 48 bits",
191 "R2, 136 bits",
192 "R3, 48 bits",
193 "R4, 48 bits",
194 "R5, 48 bits",
195 "Reserved 6",
196 "Reserved 7"
197 };
198
199 emm_rsp_sts.u = readq(host->base_addr + MIO_EMM_RSP_STS());
200 printf("\nMIO_EMM_RSP_STS: 0x%016llx\n", emm_rsp_sts.u);
201 printf(" 60-61: bus_id: %u\n", emm_rsp_sts.s.bus_id);
202 printf(" 59: cmd_val: %s\n",
203 emm_rsp_sts.s.cmd_val ? "yes" : "no");
204 printf(" 58: switch_val: %s\n",
205 emm_rsp_sts.s.switch_val ? "yes" : "no");
206 printf(" 57: dma_val: %s\n",
207 emm_rsp_sts.s.dma_val ? "yes" : "no");
208 printf(" 56: dma_pend: %s\n",
209 emm_rsp_sts.s.dma_pend ? "yes" : "no");
210 printf(" 28: dbuf_err: %s\n",
211 emm_rsp_sts.s.dbuf_err ? "yes" : "no");
212 printf(" 23: dbuf: %u\n", emm_rsp_sts.s.dbuf);
213 printf(" 22: blk_timeout: %s\n",
214 emm_rsp_sts.s.blk_timeout ? "yes" : "no");
215 printf(" 21: blk_crc_err: %s\n",
216 emm_rsp_sts.s.blk_crc_err ? "yes" : "no");
217 printf(" 20: rsp_busybit: %s\n",
218 emm_rsp_sts.s.rsp_busybit ? "yes" : "no");
219 printf(" 19: stp_timeout: %s\n",
220 emm_rsp_sts.s.stp_timeout ? "yes" : "no");
221 printf(" 18: stp_crc_err: %s\n",
222 emm_rsp_sts.s.stp_crc_err ? "yes" : "no");
223 printf(" 17: stp_bad_sts: %s\n",
224 emm_rsp_sts.s.stp_bad_sts ? "yes" : "no");
225 printf(" 16: stp_val: %s\n",
226 emm_rsp_sts.s.stp_val ? "yes" : "no");
227 printf(" 15: rsp_timeout: %s\n",
228 emm_rsp_sts.s.rsp_timeout ? "yes" : "no");
229 printf(" 14: rsp_crc_err: %s\n",
230 emm_rsp_sts.s.rsp_crc_err ? "yes" : "no");
231 printf(" 13: rsp_bad_sts: %s\n",
232 emm_rsp_sts.s.rsp_bad_sts ? "yes" : "no");
233 printf(" 12: rsp_val: %s\n",
234 emm_rsp_sts.s.rsp_val ? "yes" : "no");
235 printf(" 9-11: rsp_type: %s\n",
236 rtype_xor_str[emm_rsp_sts.s.rsp_type]);
237 printf(" 7-8: cmd_type: %s\n",
238 ctype_xor_str[emm_rsp_sts.s.cmd_type]);
239 printf(" 1-6: cmd_idx: %u\n",
240 emm_rsp_sts.s.cmd_idx);
241 printf(" 0: cmd_done: %s\n",
242 emm_rsp_sts.s.cmd_done ? "yes" : "no");
243#endif
244}
245
246static inline u64 read_csr(struct mmc *mmc, u64 reg)
247{
248 const struct octeontx_mmc_host *host = mmc_to_host(mmc);
249 u64 value = readq(host->base_addr + reg);
250#ifdef DEBUG_CSR
251 printf(" %s: %s(0x%p) => 0x%llx\n", __func__,
252 mmc_reg_str(reg), host->base_addr + reg,
253 value);
254#endif
255 return value;
256}
257
258/**
259 * Writes to a CSR register
260 *
261 * @param[in] mmc pointer to mmc data structure
262 * @param reg register offset
263 * @param value value to write to register
264 */
265static inline void write_csr(struct mmc *mmc, u64 reg, u64 value)
266{
267 const struct octeontx_mmc_host *host = mmc_to_host(mmc);
268 void *addr = host->base_addr + reg;
269
270#ifdef DEBUG_CSR
271 printf(" %s: %s(0x%p) <= 0x%llx\n", __func__, mmc_reg_str(reg),
272 addr, value);
273#endif
274 writeq(value, addr);
275}
276
277#ifdef DEBUG
278static void mmc_print_status(u32 status)
279{
280#ifdef DEBUG_STATUS
281 static const char * const state[] = {
282 "Idle", /* 0 */
283 "Ready", /* 1 */
284 "Ident", /* 2 */
285 "Standby", /* 3 */
286 "Tran", /* 4 */
287 "Data", /* 5 */
288 "Receive", /* 6 */
289 "Program", /* 7 */
290 "Dis", /* 8 */
291 "Btst", /* 9 */
292 "Sleep", /* 10 */
293 "reserved", /* 11 */
294 "reserved", /* 12 */
295 "reserved", /* 13 */
296 "reserved", /* 14 */
297 "reserved" /* 15 */ };
298 if (status & R1_APP_CMD)
299 puts("MMC ACMD\n");
300 if (status & R1_SWITCH_ERROR)
301 puts("MMC switch error\n");
302 if (status & R1_READY_FOR_DATA)
303 puts("MMC ready for data\n");
304 printf("MMC %s state\n", state[R1_CURRENT_STATE(status)]);
305 if (status & R1_ERASE_RESET)
306 puts("MMC erase reset\n");
307 if (status & R1_WP_ERASE_SKIP)
308 puts("MMC partial erase due to write protected blocks\n");
309 if (status & R1_CID_CSD_OVERWRITE)
310 puts("MMC CID/CSD overwrite error\n");
311 if (status & R1_ERROR)
312 puts("MMC undefined device error\n");
313 if (status & R1_CC_ERROR)
314 puts("MMC device error\n");
315 if (status & R1_CARD_ECC_FAILED)
316 puts("MMC internal ECC failed to correct data\n");
317 if (status & R1_ILLEGAL_COMMAND)
318 puts("MMC illegal command\n");
319 if (status & R1_COM_CRC_ERROR)
320 puts("MMC CRC of previous command failed\n");
321 if (status & R1_LOCK_UNLOCK_FAILED)
322 puts("MMC sequence or password error in lock/unlock device command\n");
323 if (status & R1_CARD_IS_LOCKED)
324 puts("MMC device locked by host\n");
325 if (status & R1_WP_VIOLATION)
326 puts("MMC attempt to program write protected block\n");
327 if (status & R1_ERASE_PARAM)
328 puts("MMC invalid selection of erase groups for erase\n");
329 if (status & R1_ERASE_SEQ_ERROR)
330 puts("MMC error in sequence of erase commands\n");
331 if (status & R1_BLOCK_LEN_ERROR)
332 puts("MMC block length error\n");
333 if (status & R1_ADDRESS_ERROR)
334 puts("MMC address misalign error\n");
335 if (status & R1_OUT_OF_RANGE)
336 puts("MMC address out of range\n");
337#endif
338}
339#endif
340
341/**
342 * Print out all of the register values where mmc is optional
343 *
344 * @param mmc MMC device (can be NULL)
345 * @param host Pointer to host data structure (can be NULL if mmc is !NULL)
346 */
347static void octeontx_mmc_print_registers2(struct mmc *mmc,
348 struct octeontx_mmc_host *host)
349{
350 struct octeontx_mmc_slot *slot = mmc ? mmc->priv : NULL;
351 union mio_emm_dma_cfg emm_dma_cfg;
352 union mio_emm_dma_adr emm_dma_adr;
353 union mio_emm_dma_int emm_dma_int;
354 union mio_emm_cfg emm_cfg;
355 union mio_emm_modex emm_mode;
356 union mio_emm_switch emm_switch;
357 union mio_emm_dma emm_dma;
358 union mio_emm_cmd emm_cmd;
359 union mio_emm_rsp_sts emm_rsp_sts;
360 union mio_emm_rsp_lo emm_rsp_lo;
361 union mio_emm_rsp_hi emm_rsp_hi;
362 union mio_emm_int emm_int;
363 union mio_emm_wdog emm_wdog;
364 union mio_emm_sample emm_sample;
365 union mio_emm_calb emm_calb;
366 union mio_emm_tap emm_tap;
367 union mio_emm_timing emm_timing;
368 union mio_emm_io_ctl io_ctl;
369 union mio_emm_debug emm_debug;
370 union mio_emm_sts_mask emm_sts_mask;
371 union mio_emm_rca emm_rca;
372 int bus;
373
374 static const char * const bus_width_str[] = {
375 "1-bit data bus (power on)",
376 "4-bit data bus",
377 "8-bit data bus",
378 "reserved (3)",
379 "reserved (4)",
380 "4-bit data bus (dual data rate)",
381 "8-bit data bus (dual data rate)",
382 "reserved (7)",
383 "reserved (8)",
384 "invalid (9)",
385 "invalid (10)",
386 "invalid (11)",
387 "invalid (12)",
388 "invalid (13)",
389 "invalid (14)",
390 "invalid (15)",
391 };
392 static const char * const ctype_xor_str[] = {
393 "No data",
394 "Read data into Dbuf",
395 "Write data from Dbuf",
396 "Reserved"
397 };
398
399 static const char * const rtype_xor_str[] = {
400 "No response",
401 "R1, 48 bits",
402 "R2, 136 bits",
403 "R3, 48 bits",
404 "R4, 48 bits",
405 "R5, 48 bits",
406 "Reserved 6",
407 "Reserved 7"
408 };
409
410 if (!host && mmc)
411 host = mmc_to_host(mmc);
412
413 if (mmc)
414 printf("%s: bus id: %u\n", __func__, slot->bus_id);
415 emm_dma_cfg.u = readq(host->base_addr + MIO_EMM_DMA_CFG());
416 printf("MIO_EMM_DMA_CFG: 0x%016llx\n",
417 emm_dma_cfg.u);
418 printf(" 63: en: %s\n",
419 emm_dma_cfg.s.en ? "enabled" : "disabled");
420 printf(" 62: rw: %s\n",
421 emm_dma_cfg.s.rw ? "write" : "read");
422 printf(" 61: clr: %s\n",
423 emm_dma_cfg.s.clr ? "clear" : "not clear");
424 printf(" 59: swap32: %s\n",
425 emm_dma_cfg.s.swap32 ? "yes" : "no");
426 printf(" 58: swap16: %s\n",
427 emm_dma_cfg.s.swap16 ? "yes" : "no");
428 printf(" 57: swap8: %s\n",
429 emm_dma_cfg.s.swap8 ? "yes" : "no");
430 printf(" 56: endian: %s\n",
431 emm_dma_cfg.s.endian ? "little" : "big");
432 printf(" 36-55: size: %u\n",
433 emm_dma_cfg.s.size);
434
435 emm_dma_adr.u = readq(host->base_addr + MIO_EMM_DMA_ADR());
436 printf("MIO_EMM_DMA_ADR: 0x%016llx\n", emm_dma_adr.u);
437 printf(" 0-49: adr: 0x%llx\n",
438 (u64)emm_dma_adr.s.adr);
439
440 emm_dma_int.u = readq(host->base_addr + MIO_EMM_DMA_INT());
441 printf("\nMIO_EMM_DMA_INT: 0x%016llx\n",
442 emm_dma_int.u);
443 printf(" 1: FIFO: %s\n",
444 emm_dma_int.s.fifo ? "yes" : "no");
445 printf(" 0: Done: %s\n",
446 emm_dma_int.s.done ? "yes" : "no");
447 emm_cfg.u = readq(host->base_addr + MIO_EMM_CFG());
448
449 printf("\nMIO_EMM_CFG: 0x%016llx\n",
450 emm_cfg.u);
451 printf(" 3: bus_ena3: %s\n",
452 emm_cfg.s.bus_ena & 0x08 ? "yes" : "no");
453 printf(" 2: bus_ena2: %s\n",
454 emm_cfg.s.bus_ena & 0x04 ? "yes" : "no");
455 printf(" 1: bus_ena1: %s\n",
456 emm_cfg.s.bus_ena & 0x02 ? "yes" : "no");
457 printf(" 0: bus_ena0: %s\n",
458 emm_cfg.s.bus_ena & 0x01 ? "yes" : "no");
459 for (bus = 0; bus < 4; bus++) {
460 emm_mode.u = readq(host->base_addr + MIO_EMM_MODEX(bus));
461 printf("\nMIO_EMM_MODE%u: 0x%016llx\n",
462 bus, emm_mode.u);
463 if (!IS_ENABLED(CONFIG_ARCH_OCTEONTX)) {
464 printf(" 50: hs400_timing: %s\n",
465 emm_mode.s.hs400_timing ? "yes" : "no");
466 printf(" 49: hs200_timing: %s\n",
467 emm_mode.s.hs200_timing ? "yes" : "no");
468 }
469 printf(" 48: hs_timing: %s\n",
470 emm_mode.s.hs_timing ? "yes" : "no");
471 printf(" 40-42: bus_width: %s\n",
472 bus_width_str[emm_mode.s.bus_width]);
473 printf(" 32-35: power_class %u\n",
474 emm_mode.s.power_class);
475 printf(" 16-31: clk_hi: %u\n",
476 emm_mode.s.clk_hi);
477 printf(" 0-15: clk_lo: %u\n",
478 emm_mode.s.clk_lo);
479 }
480
481 emm_switch.u = readq(host->base_addr + MIO_EMM_SWITCH());
482 printf("\nMIO_EMM_SWITCH: 0x%016llx\n", emm_switch.u);
483 printf(" 60-61: bus_id: %u\n", emm_switch.s.bus_id);
484 printf(" 59: switch_exe: %s\n",
485 emm_switch.s.switch_exe ? "yes" : "no");
486 printf(" 58: switch_err0: %s\n",
487 emm_switch.s.switch_err0 ? "yes" : "no");
488 printf(" 57: switch_err1: %s\n",
489 emm_switch.s.switch_err1 ? "yes" : "no");
490 printf(" 56: switch_err2: %s\n",
491 emm_switch.s.switch_err2 ? "yes" : "no");
492 printf(" 48: hs_timing: %s\n",
493 emm_switch.s.hs_timing ? "yes" : "no");
494 printf(" 42-40: bus_width: %s\n",
495 bus_width_str[emm_switch.s.bus_width]);
496 printf(" 32-35: power_class: %u\n",
497 emm_switch.s.power_class);
498 printf(" 16-31: clk_hi: %u\n",
499 emm_switch.s.clk_hi);
500 printf(" 0-15: clk_lo: %u\n", emm_switch.s.clk_lo);
501
502 emm_dma.u = readq(host->base_addr + MIO_EMM_DMA());
503 printf("\nMIO_EMM_DMA: 0x%016llx\n", emm_dma.u);
504 printf(" 60-61: bus_id: %u\n", emm_dma.s.bus_id);
505 printf(" 59: dma_val: %s\n",
506 emm_dma.s.dma_val ? "yes" : "no");
507 printf(" 58: sector: %s mode\n",
508 emm_dma.s.sector ? "sector" : "byte");
509 printf(" 57: dat_null: %s\n",
510 emm_dma.s.dat_null ? "yes" : "no");
511 printf(" 51-56: thres: %u\n", emm_dma.s.thres);
512 printf(" 50: rel_wr: %s\n",
513 emm_dma.s.rel_wr ? "yes" : "no");
514 printf(" 49: rw: %s\n",
515 emm_dma.s.rw ? "write" : "read");
516 printf(" 48: multi: %s\n",
517 emm_dma.s.multi ? "yes" : "no");
518 printf(" 32-47: block_cnt: %u\n",
519 emm_dma.s.block_cnt);
520 printf(" 0-31: card_addr: 0x%x\n",
521 emm_dma.s.card_addr);
522
523 emm_cmd.u = readq(host->base_addr + MIO_EMM_CMD());
524 printf("\nMIO_EMM_CMD: 0x%016llx\n", emm_cmd.u);
525 printf("\n 62: skip_busy: %s\n",
526 emm_cmd.s.skip_busy ? "yes" : "no");
527 printf(" 60-61: bus_id: %u\n", emm_cmd.s.bus_id);
528 printf(" 59: cmd_val: %s\n",
529 emm_cmd.s.cmd_val ? "yes" : "no");
530 printf(" 55: dbuf: %u\n", emm_cmd.s.dbuf);
531 printf(" 49-54: offset: %u\n", emm_cmd.s.offset);
532 printf(" 41-42: ctype_xor: %s\n",
533 ctype_xor_str[emm_cmd.s.ctype_xor]);
534 printf(" 38-40: rtype_xor: %s\n",
535 rtype_xor_str[emm_cmd.s.rtype_xor]);
536 printf(" 32-37: cmd_idx: %u\n", emm_cmd.s.cmd_idx);
537 printf(" 0-31: arg: 0x%x\n", emm_cmd.s.arg);
538
539 emm_rsp_sts.u = readq(host->base_addr + MIO_EMM_RSP_STS());
540 printf("\nMIO_EMM_RSP_STS: 0x%016llx\n", emm_rsp_sts.u);
541 printf(" 60-61: bus_id: %u\n", emm_rsp_sts.s.bus_id);
542 printf(" 59: cmd_val: %s\n",
543 emm_rsp_sts.s.cmd_val ? "yes" : "no");
544 printf(" 58: switch_val: %s\n",
545 emm_rsp_sts.s.switch_val ? "yes" : "no");
546 printf(" 57: dma_val: %s\n",
547 emm_rsp_sts.s.dma_val ? "yes" : "no");
548 printf(" 56: dma_pend: %s\n",
549 emm_rsp_sts.s.dma_pend ? "yes" : "no");
550 printf(" 28: dbuf_err: %s\n",
551 emm_rsp_sts.s.dbuf_err ? "yes" : "no");
552 printf(" 23: dbuf: %u\n", emm_rsp_sts.s.dbuf);
553 printf(" 22: blk_timeout: %s\n",
554 emm_rsp_sts.s.blk_timeout ? "yes" : "no");
555 printf(" 21: blk_crc_err: %s\n",
556 emm_rsp_sts.s.blk_crc_err ? "yes" : "no");
557 printf(" 20: rsp_busybit: %s\n",
558 emm_rsp_sts.s.rsp_busybit ? "yes" : "no");
559 printf(" 19: stp_timeout: %s\n",
560 emm_rsp_sts.s.stp_timeout ? "yes" : "no");
561 printf(" 18: stp_crc_err: %s\n",
562 emm_rsp_sts.s.stp_crc_err ? "yes" : "no");
563 printf(" 17: stp_bad_sts: %s\n",
564 emm_rsp_sts.s.stp_bad_sts ? "yes" : "no");
565 printf(" 16: stp_val: %s\n",
566 emm_rsp_sts.s.stp_val ? "yes" : "no");
567 printf(" 15: rsp_timeout: %s\n",
568 emm_rsp_sts.s.rsp_timeout ? "yes" : "no");
569 printf(" 14: rsp_crc_err: %s\n",
570 emm_rsp_sts.s.rsp_crc_err ? "yes" : "no");
571 printf(" 13: rsp_bad_sts: %s\n",
572 emm_rsp_sts.s.rsp_bad_sts ? "yes" : "no");
573 printf(" 12: rsp_val: %s\n",
574 emm_rsp_sts.s.rsp_val ? "yes" : "no");
575 printf(" 9-11: rsp_type: %s\n",
576 rtype_xor_str[emm_rsp_sts.s.rsp_type]);
577 printf(" 7-8: cmd_type: %s\n",
578 ctype_xor_str[emm_rsp_sts.s.cmd_type]);
579 printf(" 1-6: cmd_idx: %u\n",
580 emm_rsp_sts.s.cmd_idx);
581 printf(" 0: cmd_done: %s\n",
582 emm_rsp_sts.s.cmd_done ? "yes" : "no");
583
584 emm_rsp_lo.u = readq(host->base_addr + MIO_EMM_RSP_LO());
585 printf("\nMIO_EMM_RSP_STS_LO: 0x%016llx\n", emm_rsp_lo.u);
586
587 emm_rsp_hi.u = readq(host->base_addr + MIO_EMM_RSP_HI());
588 printf("\nMIO_EMM_RSP_STS_HI: 0x%016llx\n", emm_rsp_hi.u);
589
590 emm_int.u = readq(host->base_addr + MIO_EMM_INT());
591 printf("\nMIO_EMM_INT: 0x%016llx\n", emm_int.u);
592 printf(" 6: switch_err: %s\n",
593 emm_int.s.switch_err ? "yes" : "no");
594 printf(" 5: switch_done: %s\n",
595 emm_int.s.switch_done ? "yes" : "no");
596 printf(" 4: dma_err: %s\n",
597 emm_int.s.dma_err ? "yes" : "no");
598 printf(" 3: cmd_err: %s\n",
599 emm_int.s.cmd_err ? "yes" : "no");
600 printf(" 2: dma_done: %s\n",
601 emm_int.s.dma_done ? "yes" : "no");
602 printf(" 1: cmd_done: %s\n",
603 emm_int.s.cmd_done ? "yes" : "no");
604 printf(" 0: buf_done: %s\n",
605 emm_int.s.buf_done ? "yes" : "no");
606
607 emm_wdog.u = readq(host->base_addr + MIO_EMM_WDOG());
608 printf("\nMIO_EMM_WDOG: 0x%016llx (%u)\n",
609 emm_wdog.u, emm_wdog.s.clk_cnt);
610
611 if (IS_ENABLED(CONFIG_ARCH_OCTEONTX)) {
612 emm_sample.u = readq(host->base_addr + MIO_EMM_SAMPLE());
613 printf("\nMIO_EMM_SAMPLE: 0x%016llx\n",
614 emm_sample.u);
615 printf(" 16-25: cmd_cnt: %u\n",
616 emm_sample.s.cmd_cnt);
617 printf(" 0-9: dat_cnt: %u\n",
618 emm_sample.s.dat_cnt);
619 }
620
621 emm_sts_mask.u = readq(host->base_addr + MIO_EMM_STS_MASK());
622 printf("\nMIO_EMM_STS_MASK: 0x%016llx\n", emm_sts_mask.u);
623
624 emm_rca.u = readq(host->base_addr + MIO_EMM_RCA());
625 printf("\nMIO_EMM_RCA: 0x%016llx\n", emm_rca.u);
626 printf(" 0-15: card_rca: 0x%04x\n",
627 emm_rca.s.card_rca);
628 if (!IS_ENABLED(CONFIG_ARCH_OCTEONTX)) {
629 emm_calb.u = readq(host->base_addr + MIO_EMM_CALB());
630 printf("\nMIO_EMM_CALB: 0x%016llx\n",
631 emm_calb.u);
632 printf(" 0: start: %u\n",
633 emm_calb.s.start);
634 emm_tap.u = readq(host->base_addr + MIO_EMM_TAP());
635 printf("\nMIO_EMM_TAP: 0x%016llx\n",
636 emm_tap.u);
637 printf(" 7-0: delay: %u\n", emm_tap.s.delay);
638 emm_timing.u = readq(host->base_addr + MIO_EMM_TIMING());
639 printf("\nMIO_EMM_TIMING: 0x%016llx\n",
640 emm_timing.u);
641 printf(" 53-48: cmd_in_tap: %u\n",
642 emm_timing.s.cmd_in_tap);
643 printf(" 37-32: cmd_out_tap: %u\n",
644 emm_timing.s.cmd_out_tap);
645 printf(" 21-16: data_in_tap: %u\n",
646 emm_timing.s.data_in_tap);
647 printf(" 5-0: data_out_tap: %u\n",
648 emm_timing.s.data_out_tap);
649 io_ctl.u = readq(host->base_addr + MIO_EMM_IO_CTL());
650 printf("\nMIO_IO_CTL: 0x%016llx\n", io_ctl.u);
651 printf(" 3-2: drive: %u (%u mA)\n",
652 io_ctl.s.drive, 2 << io_ctl.s.drive);
653 printf(" 0: slew: %u %s\n", io_ctl.s.slew,
654 io_ctl.s.slew ? "high" : "low");
655 emm_debug.u = readq(host->base_addr + MIO_EMM_DEBUG());
656 printf("\nMIO_EMM_DEBUG: 0x%016llx\n",
657 emm_debug.u);
658 printf(" 21: rdsync_rst 0x%x\n",
659 emm_debug.s.rdsync_rst);
660 printf(" 20: emmc_clk_disable 0x%x\n",
661 emm_debug.s.emmc_clk_disable);
662 printf(" 19-16: dma_sm: 0x%x\n",
663 emm_debug.s.dma_sm);
664 printf(" 15-12: data_sm: 0x%x\n",
665 emm_debug.s.data_sm);
666 printf(" 11-8: cmd_sm: 0x%x\n",
667 emm_debug.s.cmd_sm);
668 printf(" 0: clk_on: 0x%x\n",
669 emm_debug.s.clk_on);
670 }
671
672 puts("\n");
673}
674
675/**
676 * Print out all of the register values
677 *
678 * @param mmc MMC device
679 */
680static void octeontx_mmc_print_registers(struct mmc *mmc)
681{
682#ifdef DEBUG_REGISTERS
683 const int print = 1;
684#else
685 const int print = 0;
686#endif
687 if (print)
688 octeontx_mmc_print_registers2(mmc, mmc_to_host(mmc));
689}
690
691static const struct octeontx_sd_mods octeontx_cr_types[] = {
692{ {0, 0}, {0, 0}, {0, 0} }, /* CMD0 */
693{ {0, 3}, {0, 3}, {0, 0} }, /* CMD1 */
694{ {0, 2}, {0, 2}, {0, 0} }, /* CMD2 */
695{ {0, 1}, {0, 3}, {0, 0} }, /* CMD3 SD_CMD_SEND_RELATIVE_ADDR 0, 2 */
696{ {0, 0}, {0, 0}, {0, 0} }, /* CMD4 */
697{ {0, 1}, {0, 1}, {0, 0} }, /* CMD5 */
698{ {0, 1}, {1, 1}, {0, 1} }, /*
699 * CMD6 SD_CMD_SWITCH_FUNC 1,0
700 * (ACMD) SD_APP_SET_BUS_WIDTH
701 */
702{ {0, 1}, {0, 1}, {0, 0} }, /* CMD7 */
703{ {1, 1}, {0, 3}, {0, 0} }, /* CMD8 SD_CMD_SEND_IF_COND 1,2 */
704{ {0, 2}, {0, 2}, {0, 0} }, /* CMD9 */
705{ {0, 2}, {0, 2}, {0, 0} }, /* CMD10 */
706{ {1, 1}, {0, 1}, {1, 1} }, /* CMD11 SD_CMD_SWITCH_UHS18V 1,0 */
707{ {0, 1}, {0, 1}, {0, 0} }, /* CMD12 */
708{ {0, 1}, {0, 1}, {1, 3} }, /* CMD13 (ACMD)) SD_CMD_APP_SD_STATUS 1,2 */
709{ {1, 1}, {1, 1}, {0, 0} }, /* CMD14 */
710{ {0, 0}, {0, 0}, {0, 0} }, /* CMD15 */
711{ {0, 1}, {0, 1}, {0, 0} }, /* CMD16 */
712{ {1, 1}, {1, 1}, {0, 0} }, /* CMD17 */
713{ {1, 1}, {1, 1}, {0, 0} }, /* CMD18 */
714{ {3, 1}, {3, 1}, {0, 0} }, /* CMD19 */
715{ {2, 1}, {0, 0}, {0, 0} }, /* CMD20 */ /* SD 2,0 */
716{ {0, 0}, {0, 0}, {0, 0} }, /* CMD21 */
717{ {0, 0}, {0, 0}, {1, 1} }, /* CMD22 (ACMD) SD_APP_SEND_NUM_WR_BLKS 1,0 */
718{ {0, 1}, {0, 1}, {0, 1} }, /* CMD23 */ /* SD ACMD 1,0 */
719{ {2, 1}, {2, 1}, {2, 1} }, /* CMD24 */
720{ {2, 1}, {2, 1}, {2, 1} }, /* CMD25 */
721{ {2, 1}, {2, 1}, {2, 1} }, /* CMD26 */
722{ {2, 1}, {2, 1}, {2, 1} }, /* CMD27 */
723{ {0, 1}, {0, 1}, {0, 1} }, /* CMD28 */
724{ {0, 1}, {0, 1}, {0, 1} }, /* CMD29 */
725{ {1, 1}, {1, 1}, {1, 1} }, /* CMD30 */
726{ {1, 1}, {1, 1}, {1, 1} }, /* CMD31 */
727{ {0, 0}, {0, 1}, {0, 0} }, /* CMD32 SD_CMD_ERASE_WR_BLK_START 0,1 */
728{ {0, 0}, {0, 1}, {0, 0} }, /* CMD33 SD_CMD_ERASE_WR_BLK_END 0,1 */
729{ {0, 0}, {0, 0}, {0, 0} }, /* CMD34 */
730{ {0, 1}, {0, 1}, {0, 1} }, /* CMD35 */
731{ {0, 1}, {0, 1}, {0, 1} }, /* CMD36 */
732{ {0, 0}, {0, 0}, {0, 0} }, /* CMD37 */
733{ {0, 1}, {0, 1}, {0, 1} }, /* CMD38 */
734{ {0, 4}, {0, 4}, {0, 4} }, /* CMD39 */
735{ {0, 5}, {0, 5}, {0, 5} }, /* CMD40 */
736{ {0, 0}, {0, 0}, {0, 3} }, /* CMD41 (ACMD) SD_CMD_APP_SEND_OP_COND 0,3 */
737{ {2, 1}, {2, 1}, {2, 1} }, /* CMD42 */
738{ {0, 0}, {0, 0}, {0, 0} }, /* CMD43 */
739{ {0, 0}, {0, 0}, {0, 0} }, /* CMD44 */
740{ {0, 0}, {0, 0}, {0, 0} }, /* CMD45 */
741{ {0, 0}, {0, 0}, {0, 0} }, /* CMD46 */
742{ {0, 0}, {0, 0}, {0, 0} }, /* CMD47 */
743{ {0, 0}, {1, 0}, {0, 0} }, /* CMD48 SD_CMD_READ_EXTR_SINGLE */
744{ {0, 0}, {2, 0}, {0, 0} }, /* CMD49 SD_CMD_WRITE_EXTR_SINGLE */
745{ {0, 0}, {0, 0}, {0, 0} }, /* CMD50 */
746{ {0, 0}, {0, 0}, {1, 1} }, /* CMD51 (ACMD) SD_CMD_APP_SEND_SCR 1,1 */
747{ {0, 0}, {0, 0}, {0, 0} }, /* CMD52 */
748{ {0, 0}, {0, 0}, {0, 0} }, /* CMD53 */
749{ {0, 0}, {0, 0}, {0, 0} }, /* CMD54 */
750{ {0, 1}, {0, 1}, {0, 1} }, /* CMD55 */
751{ {0xff, 0xff}, {0xff, 0xff}, {0xff, 0xff} }, /* CMD56 */
752{ {0, 0}, {0, 0}, {0, 0} }, /* CMD57 */
753{ {0, 0}, {0, 3}, {0, 3} }, /* CMD58 SD_CMD_SPI_READ_OCR 0,3 */
754{ {0, 0}, {0, 1}, {0, 0} }, /* CMD59 SD_CMD_SPI_CRC_ON_OFF 0,1 */
755{ {0, 0}, {0, 0}, {0, 0} }, /* CMD60 */
756{ {0, 0}, {0, 0}, {0, 0} }, /* CMD61 */
757{ {0, 0}, {0, 0}, {0, 0} }, /* CMD62 */
758{ {0, 0}, {0, 0}, {0, 0} } /* CMD63 */
759};
760
761/**
762 * Returns XOR values needed for SD commands and other quirks
763 *
764 * @param mmc mmc device
765 * @param cmd command information
766 *
767 * @return octeontx_mmc_cr_mods data structure with various quirks and flags
768 */
769static struct octeontx_mmc_cr_mods
770octeontx_mmc_get_cr_mods(struct mmc *mmc, const struct mmc_cmd *cmd,
771 const struct mmc_data *data)
772{
773 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
774 struct octeontx_mmc_cr_mods cr = {0, 0};
775 const struct octeontx_sd_mods *sdm =
776 &octeontx_cr_types[cmd->cmdidx & 0x3f];
777 u8 c = sdm->mmc.c, r = sdm->mmc.r;
778 u8 desired_ctype = 0;
779
780 if (IS_MMC(mmc)) {
781#ifdef MMC_SUPPORTS_TUNING
782 if (cmd->cmdidx == MMC_CMD_SEND_TUNING_BLOCK_HS200) {
783 if (cmd->resp_type == MMC_RSP_R1)
784 cr.rtype_xor = 1;
785 if (data && data->flags & MMC_DATA_READ)
786 cr.ctype_xor = 1;
787 }
788#endif
789 return cr;
790 }
791
792 if (cmd->cmdidx == 56)
793 c = (cmd->cmdarg & 1) ? 1 : 2;
794
795 if (data) {
796 if (data->flags & MMC_DATA_READ)
797 desired_ctype = 1;
798 else if (data->flags & MMC_DATA_WRITE)
799 desired_ctype = 2;
800 }
801
802 cr.ctype_xor = c ^ desired_ctype;
803 if (slot->is_acmd)
804 cr.rtype_xor = r ^ sdm->sdacmd.r;
805 else
806 cr.rtype_xor = r ^ sdm->sd.r;
807
808 debug("%s(%s): mmc c: %d, mmc r: %d, desired c: %d, xor c: %d, xor r: %d\n",
809 __func__, mmc->dev->name, c, r, desired_ctype,
810 cr.ctype_xor, cr.rtype_xor);
811 return cr;
812}
813
814/**
815 * Keep track of switch commands internally
816 */
817static void octeontx_mmc_track_switch(struct mmc *mmc, u32 cmd_arg)
818{
819 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
820 u8 how = (cmd_arg >> 24) & 3;
821 u8 where = (u8)(cmd_arg >> 16);
822 u8 val = (u8)(cmd_arg >> 8);
823
824 slot->want_switch = slot->cached_switch;
825
826 if (slot->is_acmd)
827 return;
828
829 if (how != 3)
830 return;
831
832 switch (where) {
833 case EXT_CSD_BUS_WIDTH:
834 slot->want_switch.s.bus_width = val;
835 break;
836 case EXT_CSD_POWER_CLASS:
837 slot->want_switch.s.power_class = val;
838 break;
839 case EXT_CSD_HS_TIMING:
840 slot->want_switch.s.hs_timing = 0;
841 slot->want_switch.s.hs200_timing = 0;
842 slot->want_switch.s.hs400_timing = 0;
843 switch (val & 0xf) {
844 case 0:
845 break;
846 case 1:
847 slot->want_switch.s.hs_timing = 1;
848 break;
849 case 2:
850 if (!slot->is_asim && !slot->is_emul)
851 slot->want_switch.s.hs200_timing = 1;
852 break;
853 case 3:
854 if (!slot->is_asim && !slot->is_emul)
855 slot->want_switch.s.hs400_timing = 1;
856 break;
857 default:
858 pr_err("%s(%s): Unsupported timing mode 0x%x\n",
859 __func__, mmc->dev->name, val & 0xf);
860 break;
861 }
862 break;
863 default:
864 break;
865 }
866}
867
868static int octeontx_mmc_print_rsp_errors(struct mmc *mmc,
869 union mio_emm_rsp_sts rsp_sts)
870{
871 bool err = false;
872 const char *name = mmc->dev->name;
873
874 if (rsp_sts.s.acc_timeout) {
875 pr_warn("%s(%s): acc_timeout\n", __func__, name);
876 err = true;
877 }
878 if (rsp_sts.s.dbuf_err) {
879 pr_warn("%s(%s): dbuf_err\n", __func__, name);
880 err = true;
881 }
882 if (rsp_sts.s.blk_timeout) {
883 pr_warn("%s(%s): blk_timeout\n", __func__, name);
884 err = true;
885 }
886 if (rsp_sts.s.blk_crc_err) {
887 pr_warn("%s(%s): blk_crc_err\n", __func__, name);
888 err = true;
889 }
890 if (rsp_sts.s.stp_timeout) {
891 pr_warn("%s(%s): stp_timeout\n", __func__, name);
892 err = true;
893 }
894 if (rsp_sts.s.stp_crc_err) {
895 pr_warn("%s(%s): stp_crc_err\n", __func__, name);
896 err = true;
897 }
898 if (rsp_sts.s.stp_bad_sts) {
899 pr_warn("%s(%s): stp_bad_sts\n", __func__, name);
900 err = true;
901 }
902 if (err)
903 pr_warn(" rsp_sts: 0x%llx\n", rsp_sts.u);
904
905 return err ? -1 : 0;
906}
907
908/**
909 * Starts a DMA operation for block read/write
910 *
911 * @param mmc mmc device
912 * @param write true if write operation
913 * @param clear true to clear DMA operation
914 * @param adr source or destination DMA address
915 * @param size size in blocks
916 * @param timeout timeout in ms
917 */
918static void octeontx_mmc_start_dma(struct mmc *mmc, bool write,
919 bool clear, u32 block, dma_addr_t adr,
920 u32 size, int timeout)
921{
922 const struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
923 union mio_emm_dma_cfg emm_dma_cfg;
924 union mio_emm_dma_adr emm_dma_adr;
925 union mio_emm_dma emm_dma;
926
927 /* Clear any interrupts */
928 write_csr(mmc, MIO_EMM_DMA_INT(),
929 read_csr(mmc, MIO_EMM_DMA_INT()));
930
931 emm_dma_cfg.u = 0;
932 emm_dma_cfg.s.en = 1;
933 emm_dma_cfg.s.rw = !!write;
934 emm_dma_cfg.s.clr = !!clear;
935 emm_dma_cfg.s.size = ((u64)(size * mmc->read_bl_len) / 8) - 1;
936#if __BYTE_ORDER != __BIG_ENDIAN
937 emm_dma_cfg.s.endian = 1;
938#endif
939 emm_dma_adr.u = 0;
940 emm_dma_adr.s.adr = adr;
941 write_csr(mmc, MIO_EMM_DMA_ADR(), emm_dma_adr.u);
942 write_csr(mmc, MIO_EMM_DMA_CFG(), emm_dma_cfg.u);
943
944 emm_dma.u = 0;
945 emm_dma.s.bus_id = slot->bus_id;
946 emm_dma.s.dma_val = 1;
947 emm_dma.s.rw = !!write;
948 emm_dma.s.sector = mmc->high_capacity ? 1 : 0;
949
950 if (size > 1 && ((IS_SD(mmc) && (mmc->scr[0] & 2)) || !IS_SD(mmc)))
951 emm_dma.s.multi = 1;
952 else
953 emm_dma.s.multi = 0;
954
955 emm_dma.s.block_cnt = size;
956 if (!mmc->high_capacity)
957 block *= mmc->read_bl_len;
958 emm_dma.s.card_addr = block;
959 debug("%s(%s): card address: 0x%x, size: %d, multi: %d\n",
960 __func__, mmc->dev->name, block, size, emm_dma.s.multi);
961
962 if (timeout > 0)
963 timeout = (timeout * 1000) - 1000;
964 set_wdog(mmc, timeout);
965
966 debug(" Writing 0x%llx to mio_emm_dma\n", emm_dma.u);
967 write_csr(mmc, MIO_EMM_DMA(), emm_dma.u);
968}
969
970/**
971 * Waits for a DMA operation to complete
972 *
973 * @param mmc mmc device
974 * @param timeout timeout in ms
975 *
976 * @return 0 for success (could be DMA errors), -ETIMEDOUT on timeout
977 */
978
979/**
980 * Cleanup DMA engine after a failure
981 *
982 * @param mmc mmc device
983 * @param rsp_sts rsp status
984 */
985static void octeontx_mmc_cleanup_dma(struct mmc *mmc,
986 union mio_emm_rsp_sts rsp_sts)
987{
988 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
989 union mio_emm_dma emm_dma;
990 ulong start;
991 int retries = 3;
992
993 do {
994 debug("%s(%s): rsp_sts: 0x%llx, rsp_lo: 0x%llx, dma_int: 0x%llx\n",
995 __func__, mmc->dev->name, rsp_sts.u,
996 read_csr(mmc, MIO_EMM_RSP_LO()),
997 read_csr(mmc, MIO_EMM_DMA_INT()));
998 emm_dma.u = read_csr(mmc, MIO_EMM_DMA());
999 emm_dma.s.dma_val = 1;
1000 emm_dma.s.dat_null = 1;
1001 emm_dma.s.bus_id = slot->bus_id;
1002 write_csr(mmc, MIO_EMM_DMA(), emm_dma.u);
1003 start = get_timer(0);
1004 do {
1005 rsp_sts.u = read_csr(mmc, MIO_EMM_RSP_STS());
1006 WATCHDOG_RESET();
1007 } while (get_timer(start) < 100 &&
1008 (rsp_sts.s.dma_val || rsp_sts.s.dma_pend));
1009 } while (retries-- >= 0 && rsp_sts.s.dma_pend);
1010 if (rsp_sts.s.dma_val)
1011 pr_err("%s(%s): Error: could not clean up DMA. RSP_STS: 0x%llx, RSP_LO: 0x%llx\n",
1012 __func__, mmc->dev->name, rsp_sts.u,
1013 read_csr(mmc, MIO_EMM_RSP_LO()));
1014 debug(" rsp_sts after clearing up DMA: 0x%llx\n",
1015 read_csr(mmc, MIO_EMM_RSP_STS()));
1016}
1017
1018/**
1019 * Waits for a DMA operation to complete
1020 *
1021 * @param mmc mmc device
1022 * @param timeout timeout in ms
1023 * @param verbose true to print out error information
1024 *
1025 * @return 0 for success (could be DMA errors), -ETIMEDOUT on timeout
1026 * or -EIO if IO error.
1027 */
1028static int octeontx_mmc_wait_dma(struct mmc *mmc, bool write, ulong timeout,
1029 bool verbose)
1030{
1031 struct octeontx_mmc_host *host = mmc_to_host(mmc);
1032 ulong start_time = get_timer(0);
1033 union mio_emm_dma_int emm_dma_int;
1034 union mio_emm_rsp_sts rsp_sts;
1035 union mio_emm_dma emm_dma;
1036 bool timed_out = false;
1037 bool err = false;
1038
1039 debug("%s(%s, %lu, %d), delay: %uus\n", __func__, mmc->dev->name,
1040 timeout, verbose, host->dma_wait_delay);
1041
1042 udelay(host->dma_wait_delay);
1043 do {
1044 emm_dma_int.u = read_csr(mmc, MIO_EMM_DMA_INT());
1045 rsp_sts.u = read_csr(mmc, MIO_EMM_RSP_STS());
1046 if (write) {
1047 if ((rsp_sts.s.dma_pend && !rsp_sts.s.dma_val) ||
1048 rsp_sts.s.blk_timeout ||
1049 rsp_sts.s.stp_timeout ||
1050 rsp_sts.s.rsp_timeout) {
1051 err = true;
1052#ifdef DEBUG
1053 debug("%s: f1\n", __func__);
1054 octeontx_mmc_print_rsp_errors(mmc, rsp_sts);
1055#endif
1056 break;
1057 }
1058 } else {
1059 if (rsp_sts.s.blk_crc_err ||
1060 (rsp_sts.s.dma_pend && !rsp_sts.s.dma_val)) {
1061 err = true;
1062#if defined(DEBUG)
1063 octeontx_mmc_print_rsp_errors(mmc, rsp_sts);
1064#endif
1065 break;
1066 }
1067 }
1068 if (rsp_sts.s.dma_pend) {
1069 /*
1070 * If this is set then an error has occurred.
1071 * Try and restart the DMA operation.
1072 */
1073 emm_dma.u = read_csr(mmc, MIO_EMM_DMA());
1074 if (verbose) {
1075 pr_err("%s(%s): DMA pending error: rsp_sts: 0x%llx, dma_int: 0x%llx, emm_dma: 0x%llx\n",
1076 __func__, mmc->dev->name, rsp_sts.u,
1077 emm_dma_int.u, emm_dma.u);
1078 octeontx_print_rsp_sts(mmc);
1079 debug(" MIO_EMM_DEBUG: 0x%llx\n",
1080 read_csr(mmc, MIO_EMM_DEBUG()));
1081 pr_err("%s: Trying DMA resume...\n", __func__);
1082 }
1083 emm_dma.s.dma_val = 1;
1084 emm_dma.s.dat_null = 1;
1085 write_csr(mmc, MIO_EMM_DMA(), emm_dma.u);
1086 udelay(10);
1087 } else if (!rsp_sts.s.dma_val && emm_dma_int.s.done) {
1088 break;
1089 }
1090 WATCHDOG_RESET();
1091 timed_out = (get_timer(start_time) > timeout);
1092 } while (!timed_out);
1093
1094 if (timed_out || err) {
1095 if (verbose) {
1096 pr_err("%s(%s): MMC DMA %s after %lu ms, rsp_sts: 0x%llx, dma_int: 0x%llx, rsp_sts_lo: 0x%llx, emm_dma: 0x%llx\n",
1097 __func__, mmc->dev->name,
1098 timed_out ? "timed out" : "error",
1099 get_timer(start_time), rsp_sts.u,
1100 emm_dma_int.u,
1101 read_csr(mmc, MIO_EMM_RSP_LO()),
1102 read_csr(mmc, MIO_EMM_DMA()));
1103 octeontx_print_rsp_sts(mmc);
1104 }
1105 if (rsp_sts.s.dma_pend)
1106 octeontx_mmc_cleanup_dma(mmc, rsp_sts);
1107 } else {
1108 write_csr(mmc, MIO_EMM_DMA_INT(),
1109 read_csr(mmc, MIO_EMM_DMA_INT()));
1110 }
1111
1112 return timed_out ? -ETIMEDOUT : (err ? -EIO : 0);
1113}
1114
1115/**
1116 * Read blocks from the MMC/SD device
1117 *
1118 * @param mmc mmc device
1119 * @param cmd command
1120 * @param data data for read
1121 * @param verbose true to print out error information
1122 *
1123 * @return number of blocks read or 0 if error
1124 */
1125static int octeontx_mmc_read_blocks(struct mmc *mmc, struct mmc_cmd *cmd,
1126 struct mmc_data *data, bool verbose)
1127{
1128 struct octeontx_mmc_host *host = mmc_to_host(mmc);
1129 union mio_emm_rsp_sts rsp_sts;
1130 dma_addr_t dma_addr = (dma_addr_t)dm_pci_virt_to_mem(host->dev,
1131 data->dest);
1132 ulong count;
1133 ulong blkcnt = data->blocks;
1134 ulong start = cmd->cmdarg;
1135 int timeout = 1000 + blkcnt * 20;
1136 bool timed_out = false;
1137 bool multi_xfer = cmd->cmdidx == MMC_CMD_READ_MULTIPLE_BLOCK;
1138
1139 debug("%s(%s): dest: %p, dma address: 0x%llx, blkcnt: %lu, start: %lu\n",
1140 __func__, mmc->dev->name, data->dest, dma_addr, blkcnt, start);
1141 debug("%s: rsp_sts: 0x%llx\n", __func__,
1142 read_csr(mmc, MIO_EMM_RSP_STS()));
1143 /* use max timeout for multi-block transfers */
1144 /* timeout = 0; */
1145
1146 /*
1147 * If we have a valid SD card in the slot, we set the response bit
1148 * mask to check for CRC errors and timeouts only.
1149 * Otherwise, use the default power on reset value.
1150 */
1151 write_csr(mmc, MIO_EMM_STS_MASK(),
1152 IS_SD(mmc) ? 0x00b00000ull : 0xe4390080ull);
1153 invalidate_dcache_range((u64)data->dest,
1154 (u64)data->dest + blkcnt * data->blocksize);
1155
1156 if (multi_xfer) {
1157 octeontx_mmc_start_dma(mmc, false, false, start, dma_addr,
1158 blkcnt, timeout);
1159 timed_out = !!octeontx_mmc_wait_dma(mmc, false, timeout,
1160 verbose);
1161 rsp_sts.u = read_csr(mmc, MIO_EMM_RSP_STS());
1162 if (timed_out || rsp_sts.s.dma_val || rsp_sts.s.dma_pend) {
1163 if (!verbose)
1164 return 0;
1165
1166 pr_err("%s(%s): Error: DMA timed out. rsp_sts: 0x%llx, emm_int: 0x%llx, dma_int: 0x%llx, rsp_lo: 0x%llx\n",
1167 __func__, mmc->dev->name, rsp_sts.u,
1168 read_csr(mmc, MIO_EMM_INT()),
1169 read_csr(mmc, MIO_EMM_DMA_INT()),
1170 read_csr(mmc, MIO_EMM_RSP_LO()));
1171 pr_err("%s: block count: %lu, start: 0x%lx\n",
1172 __func__, blkcnt, start);
1173 octeontx_mmc_print_registers(mmc);
1174 return 0;
1175 }
1176 } else {
1177 count = blkcnt;
1178 timeout = 1000;
1179 do {
1180 octeontx_mmc_start_dma(mmc, false, false, start,
1181 dma_addr, 1, timeout);
1182 dma_addr += mmc->read_bl_len;
1183 start++;
1184
1185 timed_out = !!octeontx_mmc_wait_dma(mmc, false,
1186 timeout, verbose);
1187 rsp_sts.u = read_csr(mmc, MIO_EMM_RSP_STS());
1188 if (timed_out || rsp_sts.s.dma_val ||
1189 rsp_sts.s.dma_pend) {
1190 if (verbose) {
1191 pr_err("%s: Error: DMA timed out. rsp_sts: 0x%llx, emm_int: 0x%llx, dma_int: 0x%llx, rsp_lo: 0x%llx\n",
1192 __func__, rsp_sts.u,
1193 read_csr(mmc, MIO_EMM_INT()),
1194 read_csr(mmc, MIO_EMM_DMA_INT()),
1195 read_csr(mmc, MIO_EMM_RSP_LO()));
1196 pr_err("%s: block count: 1, start: 0x%lx\n",
1197 __func__, start);
1198 octeontx_mmc_print_registers(mmc);
1199 }
1200 return blkcnt - count;
1201 }
1202 WATCHDOG_RESET();
1203 } while (--count);
1204 }
1205#ifdef DEBUG
1206 debug("%s(%s): Read %lu (0x%lx) blocks starting at block %u (0x%x) to address %p (dma address 0x%llx)\n",
1207 __func__, mmc->dev->name, blkcnt, blkcnt,
1208 cmd->cmdarg, cmd->cmdarg, data->dest,
1209 dm_pci_virt_to_mem(host->dev, data->dest));
1210 print_buffer(0, data->dest, 1, 0x200, 0);
1211#endif
1212 return blkcnt;
1213}
1214
1215static int octeontx_mmc_poll_ready(struct mmc *mmc, ulong timeout)
1216{
1217 ulong start;
1218 struct mmc_cmd cmd;
1219 int err;
1220 bool not_ready = false;
1221
1222 memset(&cmd, 0, sizeof(cmd));
1223 cmd.cmdidx = MMC_CMD_SEND_STATUS;
1224 cmd.cmdarg = mmc->rca << 16;
1225 cmd.resp_type = MMC_RSP_R1;
1226 start = get_timer(0);
1227 do {
1228 err = octeontx_mmc_send_cmd(mmc, &cmd, NULL);
1229 if (err) {
1230 pr_err("%s(%s): MMC command error: %d; Retry...\n",
1231 __func__, mmc->dev->name, err);
1232 not_ready = true;
1233 } else if (cmd.response[0] & R1_READY_FOR_DATA) {
1234 return 0;
1235 }
1236 WATCHDOG_RESET();
1237 } while (get_timer(start) < timeout);
1238
1239 if (not_ready)
1240 pr_err("%s(%s): MMC command error; Retry timeout\n",
1241 __func__, mmc->dev->name);
1242 return -ETIMEDOUT;
1243}
1244
1245static ulong octeontx_mmc_write_blocks(struct mmc *mmc, struct mmc_cmd *cmd,
1246 struct mmc_data *data)
1247{
1248 struct octeontx_mmc_host *host = mmc_to_host(mmc);
1249 ulong start = cmd->cmdarg;
1250 ulong blkcnt = data->blocks;
1251 dma_addr_t dma_addr;
1252 union mio_emm_rsp_sts rsp_sts;
1253 union mio_emm_sts_mask emm_sts_mask;
1254 ulong timeout;
1255 int count;
1256 bool timed_out = false;
1257 bool multi_xfer = (blkcnt > 1) &&
1258 ((IS_SD(mmc) && mmc->scr[0] & 2) || !IS_SD(mmc));
1259
1260 octeontx_mmc_switch_to(mmc);
1261 emm_sts_mask.u = 0;
1262 emm_sts_mask.s.sts_msk = R1_BLOCK_WRITE_MASK;
1263 write_csr(mmc, MIO_EMM_STS_MASK(), emm_sts_mask.u);
1264
1265 if (octeontx_mmc_poll_ready(mmc, 10000)) {
1266 pr_err("%s(%s): Ready timed out\n", __func__, mmc->dev->name);
1267 return 0;
1268 }
1269 flush_dcache_range((u64)data->src,
1270 (u64)data->src + blkcnt * mmc->write_bl_len);
1271 dma_addr = (u64)dm_pci_virt_to_mem(host->dev, (void *)data->src);
1272 if (multi_xfer) {
1273 timeout = 5000 + 100 * blkcnt;
1274 octeontx_mmc_start_dma(mmc, true, false, start, dma_addr,
1275 blkcnt, timeout);
1276 timed_out = !!octeontx_mmc_wait_dma(mmc, true, timeout, true);
1277 rsp_sts.u = read_csr(mmc, MIO_EMM_RSP_STS());
1278 if (timed_out || rsp_sts.s.dma_val || rsp_sts.s.dma_pend) {
1279 pr_err("%s(%s): Error: multi-DMA timed out after %lums. rsp_sts: 0x%llx, emm_int: 0x%llx, emm_dma_int: 0x%llx, rsp_sts_lo: 0x%llx, emm_dma: 0x%llx\n",
1280 __func__, mmc->dev->name, timeout,
1281 rsp_sts.u,
1282 read_csr(mmc, MIO_EMM_INT()),
1283 read_csr(mmc, MIO_EMM_DMA_INT()),
1284 read_csr(mmc, MIO_EMM_RSP_LO()),
1285 read_csr(mmc, MIO_EMM_DMA()));
1286 return 0;
1287 }
1288 } else {
1289 timeout = 5000;
1290 count = blkcnt;
1291 do {
1292 octeontx_mmc_start_dma(mmc, true, false, start,
1293 dma_addr, 1, timeout);
1294 dma_addr += mmc->read_bl_len;
1295 start++;
1296
1297 timed_out = !!octeontx_mmc_wait_dma(mmc, true, timeout,
1298 true);
1299 rsp_sts.u = read_csr(mmc, MIO_EMM_RSP_STS());
1300 if (timed_out || rsp_sts.s.dma_val ||
1301 rsp_sts.s.dma_pend) {
1302 pr_err("%s(%s): Error: single-DMA timed out after %lums. rsp_sts: 0x%llx, emm_int: 0x%llx, emm_dma_int: 0x%llx, rsp_sts_lo: 0x%llx, emm_dma: 0x%llx\n",
1303 __func__, mmc->dev->name, timeout,
1304 rsp_sts.u,
1305 read_csr(mmc, MIO_EMM_RSP_STS()),
1306 read_csr(mmc, MIO_EMM_DMA_INT()),
1307 read_csr(mmc, MIO_EMM_RSP_LO()),
1308 read_csr(mmc, MIO_EMM_DMA()));
1309 return blkcnt - count;
1310 }
1311 WATCHDOG_RESET();
1312 } while (--count);
1313 }
1314
1315 return blkcnt;
1316}
1317
1318/**
1319 * Send a command to the eMMC/SD device
1320 *
1321 * @param mmc mmc device
1322 * @param cmd cmd to send and response
1323 * @param data additional data
1324 * @param flags
1325 * @return 0 for success, otherwise error
1326 */
1327static int octeontx_mmc_send_cmd(struct mmc *mmc, struct mmc_cmd *cmd,
1328 struct mmc_data *data)
1329{
1330 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
1331 const char *name = slot->dev->name;
1332 struct octeontx_mmc_cr_mods mods = {0, 0};
1333 union mio_emm_rsp_sts rsp_sts;
1334 union mio_emm_cmd emm_cmd;
1335 union mio_emm_rsp_lo rsp_lo;
1336 union mio_emm_buf_idx emm_buf_idx;
1337 union mio_emm_buf_dat emm_buf_dat;
1338 ulong start;
1339 int i;
1340 ulong blkcnt;
1341
1342 /**
1343 * This constant has a 1 bit for each command which should have a short
1344 * timeout and a 0 for each bit with a long timeout. Currently the
1345 * following commands have a long timeout:
1346 * CMD6, CMD17, CMD18, CMD24, CMD25, CMD32, CMD33, CMD35, CMD36 and
1347 * CMD38.
1348 */
1349 static const u64 timeout_short = 0xFFFFFFA4FCF9FFDFull;
1350 uint timeout;
1351
1352 if (cmd->cmdidx == MMC_CMD_SEND_EXT_CSD) {
1353 union mio_emm_rca emm_rca;
1354
1355 emm_rca.u = 0;
1356 emm_rca.s.card_rca = mmc->rca;
1357 write_csr(mmc, MIO_EMM_RCA(), emm_rca.u);
1358 }
1359
1360 if (timeout_short & (1ull << cmd->cmdidx))
1361 timeout = MMC_TIMEOUT_SHORT;
1362 else if (cmd->cmdidx == MMC_CMD_SWITCH && IS_SD(mmc))
1363 timeout = 2560;
1364 else if (cmd->cmdidx == MMC_CMD_ERASE)
1365 timeout = MMC_TIMEOUT_ERASE;
1366 else
1367 timeout = MMC_TIMEOUT_LONG;
1368
1369 debug("%s(%s): cmd idx: %u, arg: 0x%x, resp type: 0x%x, timeout: %u\n",
1370 __func__, name, cmd->cmdidx, cmd->cmdarg, cmd->resp_type,
1371 timeout);
1372 if (data)
1373 debug(" data: addr: %p, flags: 0x%x, blocks: %u, blocksize: %u\n",
1374 data->dest, data->flags, data->blocks, data->blocksize);
1375
1376 octeontx_mmc_switch_to(mmc);
1377
1378 /* Clear any interrupts */
1379 write_csr(mmc, MIO_EMM_INT(), read_csr(mmc, MIO_EMM_INT()));
1380
1381 /*
1382 * We need to override the default command types and response types
1383 * when dealing with SD cards.
1384 */
1385 mods = octeontx_mmc_get_cr_mods(mmc, cmd, data);
1386
1387 /* Handle block read/write/stop operations */
1388 switch (cmd->cmdidx) {
1389 case MMC_CMD_GO_IDLE_STATE:
1390 slot->tuned = false;
1391 slot->hs200_tuned = false;
1392 slot->hs400_tuned = false;
1393 break;
1394 case MMC_CMD_STOP_TRANSMISSION:
1395 return 0;
1396 case MMC_CMD_READ_MULTIPLE_BLOCK:
1397 case MMC_CMD_READ_SINGLE_BLOCK:
1398 pr_debug("%s(%s): Reading blocks\n", __func__, name);
1399 blkcnt = octeontx_mmc_read_blocks(mmc, cmd, data, true);
1400 return (blkcnt > 0) ? 0 : -1;
1401 case MMC_CMD_WRITE_MULTIPLE_BLOCK:
1402 case MMC_CMD_WRITE_SINGLE_BLOCK:
1403 blkcnt = octeontx_mmc_write_blocks(mmc, cmd, data);
1404 return (blkcnt > 0) ? 0 : -1;
1405 case MMC_CMD_SELECT_CARD:
1406 /* Set the RCA register (is it set automatically?) */
1407 if (IS_SD(mmc)) {
1408 union mio_emm_rca emm_rca;
1409
1410 emm_rca.u = 0;
1411 emm_rca.s.card_rca = (cmd->cmdarg >> 16);
1412 write_csr(mmc, MIO_EMM_RCA(), emm_rca.u);
1413 debug("%s: Set SD relative address (RCA) to 0x%x\n",
1414 __func__, emm_rca.s.card_rca);
1415 }
1416 break;
1417
1418 case MMC_CMD_SWITCH:
1419 if (!data && !slot->is_acmd)
1420 octeontx_mmc_track_switch(mmc, cmd->cmdarg);
1421 break;
1422 }
1423
1424 emm_cmd.u = 0;
1425 emm_cmd.s.cmd_val = 1;
1426 emm_cmd.s.bus_id = slot->bus_id;
1427 emm_cmd.s.cmd_idx = cmd->cmdidx;
1428 emm_cmd.s.arg = cmd->cmdarg;
1429 emm_cmd.s.ctype_xor = mods.ctype_xor;
1430 emm_cmd.s.rtype_xor = mods.rtype_xor;
1431 if (data && data->blocks == 1 && data->blocksize != 512) {
1432 emm_cmd.s.offset =
1433 64 - ((data->blocks * data->blocksize) / 8);
1434 debug("%s: offset set to %u\n", __func__, emm_cmd.s.offset);
1435 }
1436
1437 if (data && data->flags & MMC_DATA_WRITE) {
1438 u8 *src = (u8 *)data->src;
1439
1440 if (!src) {
1441 pr_err("%s(%s): Error: data source for cmd 0x%x is NULL!\n",
1442 __func__, name, cmd->cmdidx);
1443 return -1;
1444 }
1445 if (data->blocksize > 512) {
1446 pr_err("%s(%s): Error: data for cmd 0x%x exceeds 512 bytes\n",
1447 __func__, name, cmd->cmdidx);
1448 return -1;
1449 }
1450#ifdef DEBUG
1451 debug("%s: Sending %d bytes data\n", __func__, data->blocksize);
1452 print_buffer(0, src, 1, data->blocksize, 0);
1453#endif
1454 emm_buf_idx.u = 0;
1455 emm_buf_idx.s.inc = 1;
1456 write_csr(mmc, MIO_EMM_BUF_IDX(), emm_buf_idx.u);
1457 for (i = 0; i < (data->blocksize + 7) / 8; i++) {
1458 memcpy(&emm_buf_dat.u, src, sizeof(emm_buf_dat.u));
1459 write_csr(mmc, MIO_EMM_BUF_DAT(),
1460 cpu_to_be64(emm_buf_dat.u));
1461 src += sizeof(emm_buf_dat.u);
1462 }
1463 write_csr(mmc, MIO_EMM_BUF_IDX(), 0);
1464 }
1465 debug("%s(%s): Sending command %u (emm_cmd: 0x%llx)\n", __func__,
1466 name, cmd->cmdidx, emm_cmd.u);
1467 set_wdog(mmc, timeout * 1000);
1468 write_csr(mmc, MIO_EMM_CMD(), emm_cmd.u);
1469
1470 /* Wait for command to finish or time out */
1471 start = get_timer(0);
1472 do {
1473 rsp_sts.u = read_csr(mmc, MIO_EMM_RSP_STS());
1474 WATCHDOG_RESET();
1475 } while (!rsp_sts.s.cmd_done && !rsp_sts.s.rsp_timeout &&
1476 (get_timer(start) < timeout + 10));
1477 octeontx_mmc_print_rsp_errors(mmc, rsp_sts);
1478 if (rsp_sts.s.rsp_timeout || !rsp_sts.s.cmd_done) {
1479 debug("%s(%s): Error: command %u(0x%x) timed out. rsp_sts: 0x%llx\n",
1480 __func__, name, cmd->cmdidx, cmd->cmdarg, rsp_sts.u);
1481 octeontx_mmc_print_registers(mmc);
1482 return -ETIMEDOUT;
1483 }
1484 if (rsp_sts.s.rsp_crc_err) {
1485 debug("%s(%s): RSP CRC error, rsp_sts: 0x%llx, cmdidx: %u, arg: 0x%08x\n",
1486 __func__, name, rsp_sts.u, cmd->cmdidx, cmd->cmdarg);
1487 octeontx_mmc_print_registers(mmc);
1488 return -1;
1489 }
1490 if (slot->bus_id != rsp_sts.s.bus_id) {
1491 pr_warn("%s(%s): bus id mismatch, got %d, expected %d for command 0x%x(0x%x)\n",
1492 __func__, name,
1493 rsp_sts.s.bus_id, slot->bus_id,
1494 cmd->cmdidx, cmd->cmdarg);
1495 goto error;
1496 }
1497 if (rsp_sts.s.rsp_bad_sts) {
1498 rsp_lo.u = read_csr(mmc, MIO_EMM_RSP_LO());
1499 debug("%s: Bad response for bus id %d, cmd id %d:\n"
1500 " rsp_timeout: %d\n"
1501 " rsp_bad_sts: %d\n"
1502 " rsp_crc_err: %d\n",
1503 __func__, slot->bus_id, cmd->cmdidx,
1504 rsp_sts.s.rsp_timeout,
1505 rsp_sts.s.rsp_bad_sts,
1506 rsp_sts.s.rsp_crc_err);
1507 if (rsp_sts.s.rsp_type == 1 && rsp_sts.s.rsp_bad_sts) {
1508 debug(" Response status: 0x%llx\n",
1509 (rsp_lo.u >> 8) & 0xffffffff);
1510#ifdef DEBUG
1511 mmc_print_status((rsp_lo.u >> 8) & 0xffffffff);
1512#endif
1513 }
1514 goto error;
1515 }
1516 if (rsp_sts.s.cmd_idx != cmd->cmdidx) {
1517 debug("%s(%s): Command response index %d does not match command index %d\n",
1518 __func__, name, rsp_sts.s.cmd_idx, cmd->cmdidx);
1519 octeontx_print_rsp_sts(mmc);
1520 debug("%s: rsp_lo: 0x%llx\n", __func__,
1521 read_csr(mmc, MIO_EMM_RSP_LO()));
1522
1523 goto error;
1524 }
1525
1526 slot->is_acmd = (cmd->cmdidx == MMC_CMD_APP_CMD);
1527
1528 if (!cmd->resp_type & MMC_RSP_PRESENT)
1529 debug(" Response type: 0x%x, no response expected\n",
1530 cmd->resp_type);
1531 /* Get the response if present */
1532 if (rsp_sts.s.rsp_val && (cmd->resp_type & MMC_RSP_PRESENT)) {
1533 union mio_emm_rsp_hi rsp_hi;
1534
1535 rsp_lo.u = read_csr(mmc, MIO_EMM_RSP_LO());
1536
1537 switch (rsp_sts.s.rsp_type) {
1538 case 1:
1539 case 3:
1540 case 4:
1541 case 5:
1542 cmd->response[0] = (rsp_lo.u >> 8) & 0xffffffffull;
1543 debug(" response: 0x%08x\n",
1544 cmd->response[0]);
1545 cmd->response[1] = 0;
1546 cmd->response[2] = 0;
1547 cmd->response[3] = 0;
1548 break;
1549 case 2:
1550 cmd->response[3] = rsp_lo.u & 0xffffffff;
1551 cmd->response[2] = (rsp_lo.u >> 32) & 0xffffffff;
1552 rsp_hi.u = read_csr(mmc, MIO_EMM_RSP_HI());
1553 cmd->response[1] = rsp_hi.u & 0xffffffff;
1554 cmd->response[0] = (rsp_hi.u >> 32) & 0xffffffff;
1555 debug(" response: 0x%08x 0x%08x 0x%08x 0x%08x\n",
1556 cmd->response[0], cmd->response[1],
1557 cmd->response[2], cmd->response[3]);
1558 break;
1559 default:
1560 pr_err("%s(%s): Unknown response type 0x%x for command %d, arg: 0x%x, rsp_sts: 0x%llx\n",
1561 __func__, name, rsp_sts.s.rsp_type, cmd->cmdidx,
1562 cmd->cmdarg, rsp_sts.u);
1563 return -1;
1564 }
1565 } else {
1566 debug(" Response not expected\n");
1567 }
1568
1569 if (data && data->flags & MMC_DATA_READ) {
1570 u8 *dest = (u8 *)data->dest;
1571
1572 if (!dest) {
1573 pr_err("%s(%s): Error, destination buffer NULL!\n",
1574 __func__, mmc->dev->name);
1575 goto error;
1576 }
1577 if (data->blocksize > 512) {
1578 printf("%s(%s): Error: data size %u exceeds 512\n",
1579 __func__, mmc->dev->name,
1580 data->blocksize);
1581 goto error;
1582 }
1583 emm_buf_idx.u = 0;
1584 emm_buf_idx.s.inc = 1;
1585 write_csr(mmc, MIO_EMM_BUF_IDX(), emm_buf_idx.u);
1586 for (i = 0; i < (data->blocksize + 7) / 8; i++) {
1587 emm_buf_dat.u = read_csr(mmc, MIO_EMM_BUF_DAT());
1588 emm_buf_dat.u = be64_to_cpu(emm_buf_dat.u);
1589 memcpy(dest, &emm_buf_dat.u, sizeof(emm_buf_dat.u));
1590 dest += sizeof(emm_buf_dat.u);
1591 }
1592 write_csr(mmc, MIO_EMM_BUF_IDX(), 0);
1593#ifdef DEBUG
1594 debug("%s: Received %d bytes data\n", __func__,
1595 data->blocksize);
1596 print_buffer(0, data->dest, 1, data->blocksize, 0);
1597#endif
1598 }
1599
1600 return 0;
1601error:
1602#ifdef DEBUG
1603 octeontx_mmc_print_registers(mmc);
1604#endif
1605 return -1;
1606}
1607
1608static int octeontx_mmc_dev_send_cmd(struct udevice *dev, struct mmc_cmd *cmd,
1609 struct mmc_data *data)
1610{
1611 return octeontx_mmc_send_cmd(dev_to_mmc(dev), cmd, data);
1612}
1613
1614#ifdef MMC_SUPPORTS_TUNING
1615static int octeontx_mmc_test_cmd(struct mmc *mmc, u32 opcode, int *statp)
1616{
1617 struct mmc_cmd cmd;
1618 int err;
1619
1620 memset(&cmd, 0, sizeof(cmd));
1621
1622 debug("%s(%s, %u, %p)\n", __func__, mmc->dev->name, opcode, statp);
1623 cmd.cmdidx = opcode;
1624 cmd.resp_type = MMC_RSP_R1;
1625 cmd.cmdarg = mmc->rca << 16;
1626
1627 err = octeontx_mmc_send_cmd(mmc, &cmd, NULL);
1628 if (err)
1629 debug("%s(%s, %u) returned %d\n", __func__,
1630 mmc->dev->name, opcode, err);
1631 if (statp)
1632 *statp = cmd.response[0];
1633 return err;
1634}
1635
1636static int octeontx_mmc_test_get_ext_csd(struct mmc *mmc, u32 opcode,
1637 int *statp)
1638{
1639 struct mmc_cmd cmd;
1640 struct mmc_data data;
1641 int err;
1642 u8 ext_csd[MMC_MAX_BLOCK_LEN];
1643
1644 debug("%s(%s, %u, %p)\n", __func__, mmc->dev->name, opcode, statp);
1645 memset(&cmd, 0, sizeof(cmd));
1646
1647 cmd.cmdidx = MMC_CMD_SEND_EXT_CSD;
1648 cmd.resp_type = MMC_RSP_R1;
1649 cmd.cmdarg = 0;
1650
1651 data.dest = (char *)ext_csd;
1652 data.blocks = 1;
1653 data.blocksize = MMC_MAX_BLOCK_LEN;
1654 data.flags = MMC_DATA_READ;
1655
1656 err = octeontx_mmc_send_cmd(mmc, &cmd, &data);
1657 if (statp)
1658 *statp = cmd.response[0];
1659
1660 return err;
1661}
1662
1663/**
1664 * Wrapper to set the MIO_EMM_TIMING register
1665 *
1666 * @param mmc pointer to mmc data structure
1667 * @param emm_timing New emm_timing register value
1668 *
1669 * On some devices it is possible that changing the data out value can
1670 * cause a glitch on an internal fifo. This works around this problem
1671 * by performing a soft-reset immediately before setting the timing register.
1672 *
1673 * Note: this function should not be called from any function that
1674 * performs DMA or block operations since not all registers are
1675 * preserved.
1676 */
1677static void octeontx_mmc_set_emm_timing(struct mmc *mmc,
1678 union mio_emm_timing emm_timing)
1679{
1680 union mio_emm_cfg emm_cfg;
1681 struct octeontx_mmc_slot *slot = mmc->priv;
1682 union mio_emm_debug emm_debug;
1683
1684 debug("%s(%s, 0x%llx) din: %u\n", __func__, mmc->dev->name,
1685 emm_timing.u, emm_timing.s.data_in_tap);
1686
1687 udelay(1);
1688 if (slot->host->tap_requires_noclk) {
1689 /* Turn off the clock */
1690 emm_debug.u = read_csr(mmc, MIO_EMM_DEBUG());
1691 emm_debug.s.emmc_clk_disable = 1;
1692 write_csr(mmc, MIO_EMM_DEBUG(), emm_debug.u);
1693 udelay(1);
1694 emm_debug.s.rdsync_rst = 1;
1695 write_csr(mmc, MIO_EMM_DEBUG(), emm_debug.u);
1696 }
1697 emm_cfg.u = read_csr(mmc, MIO_EMM_CFG());
1698 emm_cfg.s.bus_ena = 1 << 3;
1699 write_csr(mmc, MIO_EMM_CFG(), emm_cfg.u);
1700
1701 udelay(1);
1702 write_csr(mmc, MIO_EMM_TIMING(), emm_timing.u);
1703 udelay(1);
1704
1705 if (slot->host->tap_requires_noclk) {
1706 /* Turn on the clock */
1707 emm_debug.s.rdsync_rst = 0;
1708 write_csr(mmc, MIO_EMM_DEBUG(), emm_debug.u);
1709 udelay(1);
1710 emm_debug.s.emmc_clk_disable = 0;
1711 write_csr(mmc, MIO_EMM_DEBUG(), emm_debug.u);
1712 udelay(1);
1713 }
1714 emm_cfg.s.bus_ena = 1 << mmc_to_slot(mmc)->bus_id;
1715 write_csr(mmc, MIO_EMM_CFG(), emm_cfg.u);
1716}
1717
1718static const u8 octeontx_hs400_tuning_block[512] = {
1719 0xff, 0xff, 0x00, 0xff, 0xff, 0xff, 0x00, 0x00,
1720 0xff, 0xff, 0xcc, 0xcc, 0xcc, 0x33, 0xcc, 0xcc,
1721 0xcc, 0x33, 0x33, 0xcc, 0xcc, 0xcc, 0xff, 0xff,
1722 0xff, 0xee, 0xff, 0xff, 0xff, 0xee, 0xee, 0xff,
1723 0xff, 0xff, 0xdd, 0xff, 0xff, 0xff, 0xdd, 0xdd,
1724 0xff, 0xff, 0xff, 0xbb, 0xff, 0xff, 0xff, 0xbb,
1725 0xbb, 0xff, 0xff, 0xff, 0x77, 0xff, 0xff, 0xff,
1726 0x77, 0x77, 0xff, 0x77, 0xbb, 0xdd, 0xee, 0xff,
1727 0xff, 0xff, 0xff, 0x00, 0xff, 0xff, 0xff, 0x00,
1728 0x00, 0xff, 0xff, 0xcc, 0xcc, 0xcc, 0x33, 0xcc,
1729 0xcc, 0xcc, 0x33, 0x33, 0xcc, 0xcc, 0xcc, 0xff,
1730 0xff, 0xff, 0xee, 0xff, 0xff, 0xff, 0xee, 0xee,
1731 0xff, 0xff, 0xff, 0xdd, 0xff, 0xff, 0xff, 0xdd,
1732 0xdd, 0xff, 0xff, 0xff, 0xbb, 0xff, 0xff, 0xff,
1733 0xbb, 0xbb, 0xff, 0xff, 0xff, 0x77, 0xff, 0xff,
1734 0xff, 0x77, 0x77, 0xff, 0x77, 0xbb, 0xdd, 0xee,
1735 0xff, 0xff, 0x00, 0xff, 0xff, 0xff, 0x00, 0x00,
1736 0xff, 0xff, 0xcc, 0xcc, 0xcc, 0x33, 0xcc, 0xcc,
1737 0xcc, 0x33, 0x33, 0xcc, 0xcc, 0xcc, 0xff, 0xff,
1738 0xff, 0xee, 0xff, 0xff, 0xff, 0xee, 0xee, 0xff,
1739 0xff, 0xff, 0xdd, 0xff, 0xff, 0xff, 0xdd, 0xdd,
1740 0xff, 0xff, 0xff, 0xbb, 0xff, 0xff, 0xff, 0xbb,
1741 0xbb, 0xff, 0xff, 0xff, 0x77, 0xff, 0xff, 0xff,
1742 0x77, 0x77, 0xff, 0x77, 0xbb, 0xdd, 0xee, 0xff,
1743 0xff, 0xff, 0xff, 0x00, 0xff, 0xff, 0xff, 0x00,
1744 0x00, 0xff, 0xff, 0xcc, 0xcc, 0xcc, 0x33, 0xcc,
1745 0xcc, 0xcc, 0x33, 0x33, 0xcc, 0xcc, 0xcc, 0xff,
1746 0xff, 0xff, 0xee, 0xff, 0xff, 0xff, 0xee, 0xee,
1747 0xff, 0xff, 0xff, 0xdd, 0xff, 0xff, 0xff, 0xdd,
1748 0xdd, 0xff, 0xff, 0xff, 0xbb, 0xff, 0xff, 0xff,
1749 0xbb, 0xbb, 0xff, 0xff, 0xff, 0x77, 0xff, 0xff,
1750 0xff, 0x77, 0x77, 0xff, 0x77, 0xbb, 0xdd, 0xee,
1751 0xff, 0xff, 0x00, 0xff, 0xff, 0xff, 0x00, 0x00,
1752 0xff, 0xff, 0xcc, 0xcc, 0xcc, 0x33, 0xcc, 0xcc,
1753 0xcc, 0x33, 0x33, 0xcc, 0xcc, 0xcc, 0xff, 0xff,
1754 0xff, 0xee, 0xff, 0xff, 0xff, 0xee, 0xee, 0xff,
1755 0xff, 0xff, 0xdd, 0xff, 0xff, 0xff, 0xdd, 0xdd,
1756 0xff, 0xff, 0xff, 0xbb, 0xff, 0xff, 0xff, 0xbb,
1757 0xbb, 0xff, 0xff, 0xff, 0x77, 0xff, 0xff, 0xff,
1758 0x77, 0x77, 0xff, 0x77, 0xbb, 0xdd, 0xee, 0xff,
1759 0xff, 0xff, 0xff, 0x00, 0xff, 0xff, 0xff, 0x00,
1760 0x00, 0xff, 0xff, 0xcc, 0xcc, 0xcc, 0x33, 0xcc,
1761 0xcc, 0xcc, 0x33, 0x33, 0xcc, 0xcc, 0xcc, 0xff,
1762 0xff, 0xff, 0xee, 0xff, 0xff, 0xff, 0xee, 0xee,
1763 0xff, 0xff, 0xff, 0xdd, 0xff, 0xff, 0xff, 0xdd,
1764 0xdd, 0xff, 0xff, 0xff, 0xbb, 0xff, 0xff, 0xff,
1765 0xbb, 0xbb, 0xff, 0xff, 0xff, 0x77, 0xff, 0xff,
1766 0xff, 0x77, 0x77, 0xff, 0x77, 0xbb, 0xdd, 0xee,
1767 0xff, 0x00, 0x00, 0xff, 0xff, 0x00, 0xff, 0x00,
1768 0x00, 0xff, 0x00, 0xff, 0x55, 0xaa, 0x55, 0xaa,
1769 0xcc, 0x33, 0x33, 0xcc, 0xcc, 0xcc, 0xff, 0xff,
1770 0xff, 0xee, 0xff, 0xff, 0xff, 0xee, 0xee, 0xff,
1771 0xff, 0xff, 0xdd, 0xff, 0xff, 0xff, 0xdd, 0xdd,
1772 0xff, 0xff, 0xff, 0xbb, 0xff, 0xff, 0xff, 0xbb,
1773 0xbb, 0xff, 0xff, 0xff, 0x77, 0xff, 0xff, 0xff,
1774 0x77, 0x77, 0xff, 0x77, 0xbb, 0xdd, 0xee, 0xff,
1775 0xff, 0x00, 0xff, 0x00, 0xff, 0x00, 0xff, 0x00,
1776 0x00, 0xff, 0x00, 0xff, 0x00, 0xff, 0x00, 0xff,
1777 0x01, 0xfe, 0x01, 0xfe, 0xcc, 0xcc, 0xcc, 0xff,
1778 0xff, 0xff, 0xee, 0xff, 0xff, 0xff, 0xee, 0xee,
1779 0xff, 0xff, 0xff, 0xdd, 0xff, 0xff, 0xff, 0xdd,
1780 0xdd, 0xff, 0xff, 0xff, 0xbb, 0xff, 0xff, 0xff,
1781 0xbb, 0xbb, 0xff, 0xff, 0xff, 0x77, 0xff, 0xff,
1782 0xff, 0x77, 0x77, 0xff, 0x77, 0xbb, 0xdd, 0xee,
1783
1784};
1785
1786/**
1787 * Perform tuning in HS400 mode
1788 *
1789 * @param[in] mmc mmc data structure
1790 *
1791 * @ret 0 for success, otherwise error
1792 */
1793static int octeontx_tune_hs400(struct mmc *mmc)
1794{
1795 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
1796 struct mmc_cmd cmd;
1797 struct mmc_data data;
1798 union mio_emm_timing emm_timing;
1799 u8 buffer[mmc->read_bl_len];
1800 int tap_adj;
1801 int err = -1;
1802 int tap;
1803 int run = 0;
1804 int start_run = -1;
1805 int best_run = 0;
1806 int best_start = -1;
1807 bool prev_ok = false;
1808 char env_name[64];
1809 char how[MAX_NO_OF_TAPS + 1] = "";
1810
1811 if (slot->hs400_tuning_block == -1)
1812 return 0;
1813
1814 /* The eMMC standard disables all tuning support when operating in
1815 * DDR modes like HS400. The problem with this is that there are
1816 * many cases where the HS200 tuning does not work for HS400 mode.
1817 * In order to perform this tuning, while in HS200 a block is written
1818 * to a block specified in the device tree (marvell,hs400-tuning-block)
1819 * which is used for tuning in this function by repeatedly reading
1820 * this block and comparing the data and return code. This function
1821 * chooses the data input tap in the middle of the longest run of
1822 * successful read operations.
1823 */
1824
1825 emm_timing = slot->hs200_taps;
1826 debug("%s(%s): Start ci: %d, co: %d, di: %d, do: %d\n",
1827 __func__, mmc->dev->name, emm_timing.s.cmd_in_tap,
1828 emm_timing.s.cmd_out_tap, emm_timing.s.data_in_tap,
1829 emm_timing.s.data_out_tap);
1830 memset(buffer, 0xdb, sizeof(buffer));
1831
1832 snprintf(env_name, sizeof(env_name), "emmc%d_data_in_tap_hs400",
1833 slot->bus_id);
1834 tap = env_get_ulong(env_name, 10, -1L);
1835 if (tap >= 0 && tap < MAX_NO_OF_TAPS) {
1836 printf("Overriding data input tap for HS400 mode to %d\n", tap);
1837 emm_timing.s.data_in_tap = tap;
1838 octeontx_mmc_set_emm_timing(mmc, emm_timing);
1839 return 0;
1840 }
1841
1842 for (tap = 0; tap <= MAX_NO_OF_TAPS; tap++, prev_ok = !err) {
1843 if (tap < MAX_NO_OF_TAPS) {
1844 debug("%s: Testing data in tap %d\n", __func__, tap);
1845 emm_timing.s.data_in_tap = tap;
1846 octeontx_mmc_set_emm_timing(mmc, emm_timing);
1847
1848 cmd.cmdidx = MMC_CMD_READ_SINGLE_BLOCK;
1849 cmd.cmdarg = slot->hs400_tuning_block;
1850 cmd.resp_type = MMC_RSP_R1;
1851 data.dest = (void *)buffer;
1852 data.blocks = 1;
1853 data.blocksize = mmc->read_bl_len;
1854 data.flags = MMC_DATA_READ;
1855 err = !octeontx_mmc_read_blocks(mmc, &cmd, &data,
1856 false);
1857 if (err || memcmp(buffer, octeontx_hs400_tuning_block,
1858 sizeof(buffer))) {
1859#ifdef DEBUG
1860 if (!err) {
1861 debug("%s: data mismatch. Read:\n",
1862 __func__);
1863 print_buffer(0, buffer, 1,
1864 sizeof(buffer), 0);
1865 debug("\nExpected:\n");
1866 print_buffer(0,
1867 octeontx_hs400_tuning_block, 1,
1868 sizeof(octeontx_hs400_tuning_block),
1869 0);
1870 } else {
1871 debug("%s: Error %d reading block\n",
1872 __func__, err);
1873 }
1874#endif
1875 err = -EINVAL;
1876 } else {
1877 debug("%s: tap %d good\n", __func__, tap);
1878 }
1879 how[tap] = "-+"[!err];
1880 } else {
1881 err = -EINVAL;
1882 }
1883
1884 if (!err) {
1885 if (!prev_ok)
1886 start_run = tap;
1887 } else if (prev_ok) {
1888 run = tap - 1 - start_run;
1889 if (start_run >= 0 && run > best_run) {
1890 best_start = start_run;
1891 best_run = run;
1892 }
1893 }
1894 }
1895
1896 how[tap - 1] = '\0';
1897 if (best_start < 0) {
1898 printf("%s(%s): %lldMHz tuning failed for HS400\n",
1899 __func__, mmc->dev->name, slot->clock / 1000000);
1900 return -EINVAL;
1901 }
1902 tap = best_start + best_run / 2;
1903
1904 snprintf(env_name, sizeof(env_name), "emmc%d_data_in_tap_adj_hs400",
1905 slot->bus_id);
1906 tap_adj = env_get_ulong(env_name, 10, slot->hs400_tap_adj);
1907 /*
1908 * Keep it in range and if out of range force it back in with a small
1909 * buffer.
1910 */
1911 if (best_run > 3) {
1912 tap = tap + tap_adj;
1913 if (tap >= best_start + best_run)
1914 tap = best_start + best_run - 2;
1915 if (tap <= best_start)
1916 tap = best_start + 2;
1917 }
1918 how[tap] = '@';
1919 debug("Tuning: %s\n", how);
1920 debug("%s(%s): HS400 tap: best run start: %d, length: %d, tap: %d\n",
1921 __func__, mmc->dev->name, best_start, best_run, tap);
1922 slot->hs400_taps = slot->hs200_taps;
1923 slot->hs400_taps.s.data_in_tap = tap;
1924 slot->hs400_tuned = true;
1925 if (env_get_yesno("emmc_export_hs400_taps") > 0) {
1926 debug("%s(%s): Exporting HS400 taps\n",
1927 __func__, mmc->dev->name);
1928 env_set_ulong("emmc_timing_tap", slot->host->timing_taps);
1929 snprintf(env_name, sizeof(env_name),
1930 "emmc%d_hs400_data_in_tap_debug",
1931 slot->bus_id);
1932 env_set(env_name, how);
1933 snprintf(env_name, sizeof(env_name),
1934 "emmc%d_hs400_data_in_tap_val",
1935 slot->bus_id);
1936 env_set_ulong(env_name, tap);
1937 snprintf(env_name, sizeof(env_name),
1938 "emmc%d_hs400_data_in_tap_start",
1939 slot->bus_id);
1940 env_set_ulong(env_name, best_start);
1941 snprintf(env_name, sizeof(env_name),
1942 "emmc%d_hs400_data_in_tap_end",
1943 slot->bus_id);
1944 env_set_ulong(env_name, best_start + best_run);
1945 snprintf(env_name, sizeof(env_name),
1946 "emmc%d_hs400_cmd_in_tap",
1947 slot->bus_id);
1948 env_set_ulong(env_name, slot->hs400_taps.s.cmd_in_tap);
1949 snprintf(env_name, sizeof(env_name),
1950 "emmc%d_hs400_cmd_out_tap",
1951 slot->bus_id);
1952 env_set_ulong(env_name, slot->hs400_taps.s.cmd_out_tap);
1953 snprintf(env_name, sizeof(env_name),
1954 "emmc%d_hs400_cmd_out_delay",
1955 slot->bus_id);
1956 env_set_ulong(env_name, slot->cmd_out_hs400_delay);
1957 snprintf(env_name, sizeof(env_name),
1958 "emmc%d_hs400_data_out_tap",
1959 slot->bus_id);
1960 env_set_ulong(env_name, slot->hs400_taps.s.data_out_tap);
1961 snprintf(env_name, sizeof(env_name),
1962 "emmc%d_hs400_data_out_delay",
1963 slot->bus_id);
1964 env_set_ulong(env_name, slot->data_out_hs400_delay);
1965 } else {
1966 debug("%s(%s): HS400 environment export disabled\n",
1967 __func__, mmc->dev->name);
1968 }
1969 octeontx_mmc_set_timing(mmc);
1970
1971 return 0;
1972}
1973
1974struct adj {
1975 const char *name;
1976 u8 mask_shift;
1977 int (*test)(struct mmc *mmc, u32 opcode, int *error);
1978 u32 opcode;
1979 bool ddr_only;
1980 bool hs200_only;
1981 bool not_hs200_only;
1982 u8 num_runs;
1983};
1984
1985struct adj adj[] = {
1986 { "CMD_IN", 48, octeontx_mmc_test_cmd, MMC_CMD_SEND_STATUS,
1987 false, false, false, 2, },
1988/* { "CMD_OUT", 32, octeontx_mmc_test_cmd, MMC_CMD_SEND_STATUS, },*/
1989 { "DATA_IN(HS200)", 16, mmc_send_tuning,
1990 MMC_CMD_SEND_TUNING_BLOCK_HS200, false, true, false, 2, },
1991 { "DATA_IN", 16, octeontx_mmc_test_get_ext_csd, 0, false, false,
1992 true, 2, },
1993/* { "DATA_OUT", 0, octeontx_mmc_test_cmd, 0, true, false},*/
1994 { NULL, },
1995};
1996
1997/**
1998 * Perform tuning tests to find optimal timing
1999 *
2000 * @param mmc mmc device
2001 * @param adj parameter to tune
2002 * @param opcode command opcode to use
2003 *
2004 * @return 0 for success, -1 if tuning failed
2005 */
2006static int octeontx_mmc_adjust_tuning(struct mmc *mmc, struct adj *adj,
2007 u32 opcode)
2008{
2009 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
2010 union mio_emm_timing timing;
2011 union mio_emm_debug emm_debug;
2012 int tap;
2013 int err = -1;
2014 int run = 0;
2015 int count;
2016 int start_run = -1;
2017 int best_run = 0;
2018 int best_start = -1;
2019 bool prev_ok = false;
2020 u64 tap_status = 0;
2021 const int tap_adj = slot->hs200_tap_adj;
2022 char how[MAX_NO_OF_TAPS + 1] = "";
2023 bool is_hs200 = mmc->selected_mode == MMC_HS_200;
2024
2025 debug("%s(%s, %s, %d), hs200: %d\n", __func__, mmc->dev->name,
2026 adj->name, opcode, is_hs200);
2027 octeontx_mmc_set_emm_timing(mmc,
2028 is_hs200 ? slot->hs200_taps : slot->taps);
2029
2030#ifdef DEBUG
2031 if (opcode == MMC_CMD_SEND_TUNING_BLOCK_HS200) {
2032 printf("%s(%s): Before tuning %s, opcode: %d\n",
2033 __func__, mmc->dev->name, adj->name, opcode);
2034 octeontx_mmc_print_registers2(mmc, NULL);
2035 }
2036#endif
2037
2038 /*
2039 * The algorithm to find the optimal timing is to start
2040 * at the end and work backwards and select the second
2041 * value that passes. Each test is repeated twice.
2042 */
2043 for (tap = 0; tap <= MAX_NO_OF_TAPS; tap++, prev_ok = !err) {
2044 if (tap < MAX_NO_OF_TAPS) {
2045 if (slot->host->tap_requires_noclk) {
2046 /* Turn off the clock */
2047 emm_debug.u = read_csr(mmc, MIO_EMM_DEBUG());
2048 emm_debug.s.emmc_clk_disable = 1;
2049 write_csr(mmc, MIO_EMM_DEBUG(), emm_debug.u);
2050 udelay(1);
2051 emm_debug.s.rdsync_rst = 1;
2052 write_csr(mmc, MIO_EMM_DEBUG(), emm_debug.u);
2053 udelay(1);
2054 }
2055
2056 timing.u = read_csr(mmc, MIO_EMM_TIMING());
2057 timing.u &= ~(0x3full << adj->mask_shift);
2058 timing.u |= (u64)tap << adj->mask_shift;
2059 write_csr(mmc, MIO_EMM_TIMING(), timing.u);
2060 debug("%s(%s): Testing ci: %d, co: %d, di: %d, do: %d\n",
2061 __func__, mmc->dev->name, timing.s.cmd_in_tap,
2062 timing.s.cmd_out_tap, timing.s.data_in_tap,
2063 timing.s.data_out_tap);
2064
2065 if (slot->host->tap_requires_noclk) {
2066 /* Turn off the clock */
2067 emm_debug.s.rdsync_rst = 0;
2068 write_csr(mmc, MIO_EMM_DEBUG(), emm_debug.u);
2069 udelay(1);
2070 emm_debug.u = read_csr(mmc, MIO_EMM_DEBUG());
2071 emm_debug.s.emmc_clk_disable = 0;
2072 write_csr(mmc, MIO_EMM_DEBUG(), emm_debug.u);
2073 udelay(1);
2074 }
2075 for (count = 0; count < 2; count++) {
2076 err = adj->test(mmc, opcode, NULL);
2077 if (err) {
2078 debug("%s(%s, %s): tap %d failed, count: %d, rsp_sts: 0x%llx, rsp_lo: 0x%llx\n",
2079 __func__, mmc->dev->name,
2080 adj->name, tap, count,
2081 read_csr(mmc,
2082 MIO_EMM_RSP_STS()),
2083 read_csr(mmc,
2084 MIO_EMM_RSP_LO()));
2085 debug("%s(%s, %s): tap: %d, do: %d, di: %d, co: %d, ci: %d\n",
2086 __func__, mmc->dev->name,
2087 adj->name, tap,
2088 timing.s.data_out_tap,
2089 timing.s.data_in_tap,
2090 timing.s.cmd_out_tap,
2091 timing.s.cmd_in_tap);
2092 break;
2093 }
2094 debug("%s(%s, %s): tap %d passed, count: %d, rsp_sts: 0x%llx, rsp_lo: 0x%llx\n",
2095 __func__, mmc->dev->name, adj->name, tap,
2096 count,
2097 read_csr(mmc, MIO_EMM_RSP_STS()),
2098 read_csr(mmc, MIO_EMM_RSP_LO()));
2099 }
2100 tap_status |= (u64)(!err) << tap;
2101 how[tap] = "-+"[!err];
2102 } else {
2103 /*
2104 * Putting the end+1 case in the loop simplifies
2105 * logic, allowing 'prev_ok' to process a sweet
2106 * spot in tuning which extends to the wall.
2107 */
2108 err = -EINVAL;
2109 }
2110 if (!err) {
2111 /*
2112 * If no CRC/etc errors in the response, but previous
2113 * failed, note the start of a new run.
2114 */
2115 debug(" prev_ok: %d\n", prev_ok);
2116 if (!prev_ok)
2117 start_run = tap;
2118 } else if (prev_ok) {
2119 run = tap - 1 - start_run;
2120 /* did we just exit a wider sweet spot? */
2121 if (start_run >= 0 && run > best_run) {
2122 best_start = start_run;
2123 best_run = run;
2124 }
2125 }
2126 }
2127 how[tap - 1] = '\0';
2128 if (best_start < 0) {
2129 printf("%s(%s, %s): %lldMHz tuning %s failed\n", __func__,
2130 mmc->dev->name, adj->name, slot->clock / 1000000,
2131 adj->name);
2132 return -EINVAL;
2133 }
2134
2135 tap = best_start + best_run / 2;
2136 debug(" tap %d is center, start: %d, run: %d\n", tap,
2137 best_start, best_run);
2138 if (is_hs200) {
2139 slot->hs200_taps.u &= ~(0x3full << adj->mask_shift);
2140 slot->hs200_taps.u |= (u64)tap << adj->mask_shift;
2141 } else {
2142 slot->taps.u &= ~(0x3full << adj->mask_shift);
2143 slot->taps.u |= (u64)tap << adj->mask_shift;
2144 }
2145 if (best_start < 0) {
2146 printf("%s(%s, %s): %lldMHz tuning %s failed\n", __func__,
2147 mmc->dev->name, adj->name, slot->clock / 1000000,
2148 adj->name);
2149 return -EINVAL;
2150 }
2151
2152 tap = best_start + best_run / 2;
2153 if (is_hs200 && (tap + tap_adj >= 0) && (tap + tap_adj < 64) &&
2154 tap_status & (1ULL << (tap + tap_adj))) {
2155 debug("Adjusting tap from %d by %d to %d\n",
2156 tap, tap_adj, tap + tap_adj);
2157 tap += tap_adj;
2158 }
2159 how[tap] = '@';
2160 debug("%s/%s %d/%d/%d %s\n", mmc->dev->name,
2161 adj->name, best_start, tap, best_start + best_run, how);
2162
2163 if (is_hs200) {
2164 slot->hs200_taps.u &= ~(0x3full << adj->mask_shift);
2165 slot->hs200_taps.u |= (u64)tap << adj->mask_shift;
2166 } else {
2167 slot->taps.u &= ~(0x3full << adj->mask_shift);
2168 slot->taps.u |= (u64)tap << adj->mask_shift;
2169 }
2170
2171#ifdef DEBUG
2172 if (opcode == MMC_CMD_SEND_TUNING_BLOCK_HS200) {
2173 debug("%s(%s, %s): After successful tuning\n",
2174 __func__, mmc->dev->name, adj->name);
2175 debug("%s(%s, %s): tap: %d, new do: %d, di: %d, co: %d, ci: %d\n",
2176 __func__, mmc->dev->name, adj->name, tap,
2177 slot->taps.s.data_out_tap,
2178 slot->taps.s.data_in_tap,
2179 slot->taps.s.cmd_out_tap,
2180 slot->taps.s.cmd_in_tap);
2181 debug("%s(%s, %s): tap: %d, new do HS200: %d, di: %d, co: %d, ci: %d\n",
2182 __func__, mmc->dev->name, adj->name, tap,
2183 slot->hs200_taps.s.data_out_tap,
2184 slot->hs200_taps.s.data_in_tap,
2185 slot->hs200_taps.s.cmd_out_tap,
2186 slot->hs200_taps.s.cmd_in_tap);
2187 }
2188#endif
2189 octeontx_mmc_set_timing(mmc);
2190
2191 if (is_hs200 && env_get_yesno("emmc_export_hs200_taps")) {
2192 char env_name[64];
2193
2194 env_set_ulong("emmc_timing_tap", slot->host->timing_taps);
2195 switch (opcode) {
2196 case MMC_CMD_SEND_TUNING_BLOCK:
2197 snprintf(env_name, sizeof(env_name),
2198 "emmc%d_hs200_data_in_tap_debug",
2199 slot->bus_id);
2200 env_set(env_name, how);
2201 snprintf(env_name, sizeof(env_name),
2202 "emmc%d_hs200_data_in_tap_val", slot->bus_id);
2203 env_set_ulong(env_name, tap);
2204 snprintf(env_name, sizeof(env_name),
2205 "emmc%d_hs200_data_in_tap_start",
2206 slot->bus_id);
2207 env_set_ulong(env_name, best_start);
2208 snprintf(env_name, sizeof(env_name),
2209 "emmc%d_hs200_data_in_tap_end",
2210 slot->bus_id);
2211 env_set_ulong(env_name, best_start + best_run);
2212 break;
2213 case MMC_CMD_SEND_STATUS:
2214 snprintf(env_name, sizeof(env_name),
2215 "emmc%d_hs200_cmd_in_tap_debug",
2216 slot->bus_id);
2217 env_set(env_name, how);
2218 snprintf(env_name, sizeof(env_name),
2219 "emmc%d_hs200_cmd_in_tap_val", slot->bus_id);
2220 env_set_ulong(env_name, tap);
2221 snprintf(env_name, sizeof(env_name),
2222 "emmc%d_hs200_cmd_in_tap_start",
2223 slot->bus_id);
2224 env_set_ulong(env_name, best_start);
2225 snprintf(env_name, sizeof(env_name),
2226 "emmc%d_hs200_cmd_in_tap_end",
2227 slot->bus_id);
2228 env_set_ulong(env_name, best_start + best_run);
2229 break;
2230 default:
2231 snprintf(env_name, sizeof(env_name),
2232 "emmc%d_hs200_data_out_tap", slot->bus_id);
2233 env_set_ulong(env_name, slot->data_out_hs200_delay);
2234 snprintf(env_name, sizeof(env_name),
2235 "emmc%d_hs200_cmd_out_tap", slot->bus_id);
2236 env_set_ulong(env_name, slot->cmd_out_hs200_delay);
2237 break;
2238 }
2239 }
2240
2241 return 0;
2242}
2243
2244static int octeontx_mmc_execute_tuning(struct udevice *dev, u32 opcode)
2245{
2246 struct mmc *mmc = dev_to_mmc(dev);
2247 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
2248 union mio_emm_timing emm_timing;
2249 int err;
2250 struct adj *a;
2251 bool is_hs200;
2252 char env_name[64];
2253
2254 pr_info("%s re-tuning, opcode 0x%x\n", dev->name, opcode);
2255
2256 if (slot->is_asim || slot->is_emul)
2257 return 0;
2258
2259 is_hs200 = (mmc->selected_mode == MMC_HS_200);
2260 if (is_hs200) {
2261 slot->hs200_tuned = false;
2262 slot->hs400_tuned = false;
2263 } else {
2264 slot->tuned = false;
2265 }
2266 octeontx_mmc_set_output_bus_timing(mmc);
2267 octeontx_mmc_set_input_bus_timing(mmc);
2268 emm_timing.u = read_csr(mmc, MIO_EMM_TIMING());
2269 if (mmc->selected_mode == MMC_HS_200) {
2270 slot->hs200_taps.s.cmd_out_tap = emm_timing.s.cmd_out_tap;
2271 slot->hs200_taps.s.data_out_tap = emm_timing.s.data_out_tap;
2272 } else {
2273 slot->taps.s.cmd_out_tap = emm_timing.s.cmd_out_tap;
2274 slot->taps.s.data_out_tap = emm_timing.s.data_out_tap;
2275 }
2276 octeontx_mmc_set_input_bus_timing(mmc);
2277 octeontx_mmc_set_output_bus_timing(mmc);
2278
2279 for (a = adj; a->name; a++) {
2280 ulong in_tap;
2281
2282 if (!strcmp(a->name, "CMD_IN")) {
2283 snprintf(env_name, sizeof(env_name),
2284 "emmc%d_cmd_in_tap", slot->bus_id);
2285 in_tap = env_get_ulong(env_name, 10, (ulong)-1);
2286 if (in_tap != (ulong)-1) {
2287 if (mmc->selected_mode == MMC_HS_200 ||
2288 a->hs200_only) {
2289 slot->hs200_taps.s.cmd_in_tap = in_tap;
2290 slot->hs400_taps.s.cmd_in_tap = in_tap;
2291 } else {
2292 slot->taps.s.cmd_in_tap = in_tap;
2293 }
2294 continue;
2295 }
2296 } else if (a->hs200_only &&
2297 !strcmp(a->name, "DATA_IN(HS200)")) {
2298 snprintf(env_name, sizeof(env_name),
2299 "emmc%d_data_in_tap_hs200", slot->bus_id);
2300 in_tap = env_get_ulong(env_name, 10, (ulong)-1);
2301 if (in_tap != (ulong)-1) {
2302 debug("%s(%s): Overriding HS200 data in tap to %d\n",
2303 __func__, dev->name, (int)in_tap);
2304 slot->hs200_taps.s.data_in_tap = in_tap;
2305 continue;
2306 }
2307 } else if (!a->hs200_only && !strcmp(a->name, "DATA_IN")) {
2308 snprintf(env_name, sizeof(env_name),
2309 "emmc%d_data_in_tap", slot->bus_id);
2310 in_tap = env_get_ulong(env_name, 10, (ulong)-1);
2311 if (in_tap != (ulong)-1) {
2312 debug("%s(%s): Overriding non-HS200 data in tap to %d\n",
2313 __func__, dev->name, (int)in_tap);
2314 slot->taps.s.data_in_tap = in_tap;
2315 continue;
2316 }
2317 }
2318
2319 debug("%s(%s): Testing: %s, mode: %s, opcode: %u\n", __func__,
2320 dev->name, a->name, mmc_mode_name(mmc->selected_mode),
2321 opcode);
2322
2323 /* Skip DDR only test when not in DDR mode */
2324 if (a->ddr_only && !mmc->ddr_mode) {
2325 debug("%s(%s): Skipping %s due to non-DDR mode\n",
2326 __func__, dev->name, a->name);
2327 continue;
2328 }
2329 /* Skip hs200 tests in non-hs200 mode and
2330 * non-hs200 tests in hs200 mode
2331 */
2332 if (is_hs200) {
2333 if (a->not_hs200_only) {
2334 debug("%s(%s): Skipping %s\n", __func__,
2335 dev->name, a->name);
2336 continue;
2337 }
2338 } else {
2339 if (a->hs200_only) {
2340 debug("%s(%s): Skipping %s\n", __func__,
2341 dev->name, a->name);
2342 continue;
2343 }
2344 }
2345
2346 err = octeontx_mmc_adjust_tuning(mmc, a, a->opcode ?
2347 a->opcode : opcode);
2348 if (err) {
2349 pr_err("%s(%s, %u): tuning %s failed\n", __func__,
2350 dev->name, opcode, a->name);
2351 return err;
2352 }
2353 }
2354
2355 octeontx_mmc_set_timing(mmc);
2356 if (is_hs200)
2357 slot->hs200_tuned = true;
2358 else
2359 slot->tuned = true;
2360
2361 if (slot->hs400_tuning_block != -1) {
2362 struct mmc_cmd cmd;
2363 struct mmc_data data;
2364 u8 buffer[mmc->read_bl_len];
2365
2366 cmd.cmdidx = MMC_CMD_READ_SINGLE_BLOCK;
2367 cmd.cmdarg = slot->hs400_tuning_block;
2368 cmd.resp_type = MMC_RSP_R1;
2369 data.dest = (void *)buffer;
2370 data.blocks = 1;
2371 data.blocksize = mmc->read_bl_len;
2372 data.flags = MMC_DATA_READ;
2373 err = octeontx_mmc_read_blocks(mmc, &cmd, &data, true) != 1;
2374
2375 if (err) {
2376 printf("%s: Cannot read HS400 tuning block %u\n",
2377 dev->name, slot->hs400_tuning_block);
2378 return err;
2379 }
2380 if (memcmp(buffer, octeontx_hs400_tuning_block,
2381 sizeof(buffer))) {
2382 debug("%s(%s): Writing new HS400 tuning block to block %d\n",
2383 __func__, dev->name, slot->hs400_tuning_block);
2384 cmd.cmdidx = MMC_CMD_WRITE_SINGLE_BLOCK;
2385 data.src = (void *)octeontx_hs400_tuning_block;
2386 data.flags = MMC_DATA_WRITE;
2387 err = !octeontx_mmc_write_blocks(mmc, &cmd, &data);
2388 if (err) {
2389 printf("%s: Cannot write HS400 tuning block %u\n",
2390 dev->name, slot->hs400_tuning_block);
2391 return -EINVAL;
2392 }
2393 }
2394 }
2395
2396 return 0;
2397}
2398#else /* MMC_SUPPORTS_TUNING */
2399static void octeontx_mmc_set_emm_timing(struct mmc *mmc,
2400 union mio_emm_timing emm_timing)
2401{
2402}
2403#endif /* MMC_SUPPORTS_TUNING */
2404
2405/**
2406 * Calculate the clock period with rounding up
2407 *
2408 * @param mmc mmc device
2409 * @return clock period in system clocks for clk_lo + clk_hi
2410 */
2411static u32 octeontx_mmc_calc_clk_period(struct mmc *mmc)
2412{
2413 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
2414 struct octeontx_mmc_host *host = slot->host;
2415
2416 return DIV_ROUND_UP(host->sys_freq, mmc->clock);
2417}
2418
2419static int octeontx_mmc_set_ios(struct udevice *dev)
2420{
2421 struct octeontx_mmc_slot *slot = dev_to_mmc_slot(dev);
2422 struct mmc *mmc = &slot->mmc;
2423 struct octeontx_mmc_host *host = slot->host;
2424 union mio_emm_switch emm_switch;
2425 union mio_emm_modex mode;
2426 uint clock;
2427 int bus_width = 0;
2428 int clk_period = 0;
2429 int power_class = 10;
2430 int err = 0;
2431 bool is_hs200 = false;
2432 bool is_hs400 = false;
2433
2434 debug("%s(%s): Entry\n", __func__, dev->name);
2435 debug(" clock: %u, bus width: %u, mode: %u\n", mmc->clock,
2436 mmc->bus_width, mmc->selected_mode);
2437 debug(" host caps: 0x%x, card caps: 0x%x\n", mmc->host_caps,
2438 mmc->card_caps);
2439 octeontx_mmc_switch_to(mmc);
2440
2441 clock = mmc->clock;
2442 if (!clock)
2443 clock = mmc->cfg->f_min;
2444
2445 switch (mmc->bus_width) {
2446 case 8:
2447 bus_width = 2;
2448 break;
2449 case 4:
2450 bus_width = 1;
2451 break;
2452 case 1:
2453 bus_width = 0;
2454 break;
2455 default:
2456 pr_warn("%s(%s): Invalid bus width %d, defaulting to 1\n",
2457 __func__, dev->name, mmc->bus_width);
2458 bus_width = 0;
2459 }
2460
2461 /* DDR is available for 4/8 bit bus width */
2462 if (mmc->ddr_mode && bus_width)
2463 bus_width |= 4;
2464
2465 debug("%s: sys_freq: %llu\n", __func__, host->sys_freq);
2466 clk_period = octeontx_mmc_calc_clk_period(mmc);
2467
2468 emm_switch.u = 0;
2469 emm_switch.s.bus_width = bus_width;
2470 emm_switch.s.power_class = power_class;
2471 emm_switch.s.clk_hi = clk_period / 2;
2472 emm_switch.s.clk_lo = clk_period / 2;
2473
2474 debug("%s: last mode: %d, mode: %d, last clock: %u, clock: %u, ddr: %d\n",
2475 __func__, slot->last_mode, mmc->selected_mode,
2476 slot->last_clock, mmc->clock, mmc->ddr_mode);
2477 switch (mmc->selected_mode) {
2478 case MMC_LEGACY:
2479 break;
2480 case MMC_HS:
2481 case SD_HS:
2482 case MMC_HS_52:
2483 emm_switch.s.hs_timing = 1;
2484 break;
2485 case MMC_HS_200:
2486 is_hs200 = true;
2487 fallthrough;
2488 case UHS_SDR12:
2489 case UHS_SDR25:
2490 case UHS_SDR50:
2491 case UHS_SDR104:
2492 emm_switch.s.hs200_timing = 1;
2493 break;
2494 case MMC_HS_400:
2495 is_hs400 = true;
2496 fallthrough;
2497 case UHS_DDR50:
2498 case MMC_DDR_52:
2499 emm_switch.s.hs400_timing = 1;
2500 break;
2501 default:
2502 pr_err("%s(%s): Unsupported mode 0x%x\n", __func__, dev->name,
2503 mmc->selected_mode);
2504 return -1;
2505 }
2506 emm_switch.s.bus_id = slot->bus_id;
2507
2508 if (!is_hs200 && !is_hs400 &&
2509 (mmc->selected_mode != slot->last_mode ||
2510 mmc->clock != slot->last_clock) &&
2511 !mmc->ddr_mode) {
2512 slot->tuned = false;
2513 slot->last_mode = mmc->selected_mode;
2514 slot->last_clock = mmc->clock;
2515 }
2516
2517 if (CONFIG_IS_ENABLED(MMC_VERBOSE)) {
2518 debug("%s(%s): Setting bus mode to %s\n", __func__, dev->name,
2519 mmc_mode_name(mmc->selected_mode));
2520 } else {
2521 debug("%s(%s): Setting bus mode to 0x%x\n", __func__, dev->name,
2522 mmc->selected_mode);
2523 }
2524
2525 debug(" Trying switch 0x%llx w%d hs:%d hs200:%d hs400:%d\n",
2526 emm_switch.u, emm_switch.s.bus_width, emm_switch.s.hs_timing,
2527 emm_switch.s.hs200_timing, emm_switch.s.hs400_timing);
2528
2529 set_wdog(mmc, 1000);
2530 do_switch(mmc, emm_switch);
2531 mdelay(100);
2532 mode.u = read_csr(mmc, MIO_EMM_MODEX(slot->bus_id));
2533 debug("%s(%s): mode: 0x%llx w:%d, hs:%d, hs200:%d, hs400:%d\n",
2534 __func__, dev->name, mode.u, mode.s.bus_width,
2535 mode.s.hs_timing, mode.s.hs200_timing, mode.s.hs400_timing);
2536
2537 err = octeontx_mmc_configure_delay(mmc);
2538
2539#ifdef MMC_SUPPORTS_TUNING
2540 if (!err && mmc->selected_mode == MMC_HS_400 && !slot->hs400_tuned) {
2541 debug("%s: Tuning HS400 mode\n", __func__);
2542 err = octeontx_tune_hs400(mmc);
2543 }
2544#endif
2545
2546 return err;
2547}
2548
2549/**
2550 * Gets the status of the card detect pin
2551 */
2552static int octeontx_mmc_get_cd(struct udevice *dev)
2553{
2554 struct octeontx_mmc_slot *slot = dev_to_mmc_slot(dev);
2555 int val = 1;
2556
2557 if (dm_gpio_is_valid(&slot->cd_gpio)) {
2558 val = dm_gpio_get_value(&slot->cd_gpio);
2559 val ^= slot->cd_inverted;
2560 }
2561 debug("%s(%s): cd: %d\n", __func__, dev->name, val);
2562 return val;
2563}
2564
2565/**
2566 * Gets the status of the write protect pin
2567 */
2568static int octeontx_mmc_get_wp(struct udevice *dev)
2569{
2570 struct octeontx_mmc_slot *slot = dev_to_mmc_slot(dev);
2571 int val = 0;
2572
2573 if (dm_gpio_is_valid(&slot->wp_gpio)) {
2574 val = dm_gpio_get_value(&slot->wp_gpio);
2575 val ^= slot->wp_inverted;
2576 }
2577 debug("%s(%s): wp: %d\n", __func__, dev->name, val);
2578 return val;
2579}
2580
2581static void octeontx_mmc_set_timing(struct mmc *mmc)
2582{
2583 union mio_emm_timing timing;
2584 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
2585
2586 switch (mmc->selected_mode) {
2587 case MMC_HS_200:
2588 timing = slot->hs200_taps;
2589 break;
2590 case MMC_HS_400:
2591 timing = slot->hs400_tuned ?
2592 slot->hs400_taps : slot->hs200_taps;
2593 break;
2594 default:
2595 timing = slot->taps;
2596 break;
2597 }
2598
2599 debug("%s(%s):\n cmd_in_tap: %u\n cmd_out_tap: %u\n data_in_tap: %u\n data_out_tap: %u\n",
2600 __func__, mmc->dev->name, timing.s.cmd_in_tap,
2601 timing.s.cmd_out_tap, timing.s.data_in_tap,
2602 timing.s.data_out_tap);
2603
2604 octeontx_mmc_set_emm_timing(mmc, timing);
2605}
2606
2607static int octeontx_mmc_configure_delay(struct mmc *mmc)
2608{
2609 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
2610 struct octeontx_mmc_host *host __maybe_unused = slot->host;
2611 bool __maybe_unused is_hs200;
2612 bool __maybe_unused is_hs400;
2613
2614 debug("%s(%s)\n", __func__, mmc->dev->name);
2615
2616 if (IS_ENABLED(CONFIG_ARCH_OCTEONTX)) {
2617 union mio_emm_sample emm_sample;
2618
2619 emm_sample.u = 0;
2620 emm_sample.s.cmd_cnt = slot->cmd_cnt;
2621 emm_sample.s.dat_cnt = slot->dat_cnt;
2622 write_csr(mmc, MIO_EMM_SAMPLE(), emm_sample.u);
2623 } else {
2624 is_hs200 = (mmc->selected_mode == MMC_HS_200);
2625 is_hs400 = (mmc->selected_mode == MMC_HS_400);
2626
2627 if ((is_hs200 && slot->hs200_tuned) ||
2628 (is_hs400 && slot->hs400_tuned) ||
2629 (!is_hs200 && !is_hs400 && slot->tuned)) {
2630 octeontx_mmc_set_output_bus_timing(mmc);
2631 } else {
2632 int half = MAX_NO_OF_TAPS / 2;
2633 int dout, cout;
2634
2635 switch (mmc->selected_mode) {
2636 case MMC_LEGACY:
2637 if (IS_SD(mmc)) {
2638 cout = MMC_SD_LEGACY_DEFAULT_CMD_OUT_TAP;
2639 dout = MMC_SD_LEGACY_DEFAULT_DATA_OUT_TAP;
2640 } else {
2641 cout = MMC_LEGACY_DEFAULT_CMD_OUT_TAP;
2642 dout = MMC_LEGACY_DEFAULT_DATA_OUT_TAP;
2643 }
2644 break;
2645 case MMC_HS:
2646 cout = MMC_HS_CMD_OUT_TAP;
2647 dout = MMC_HS_DATA_OUT_TAP;
2648 break;
2649 case SD_HS:
2650 case UHS_SDR12:
2651 case UHS_SDR25:
2652 case UHS_SDR50:
2653 cout = MMC_SD_HS_CMD_OUT_TAP;
2654 dout = MMC_SD_HS_DATA_OUT_TAP;
2655 break;
2656 case UHS_SDR104:
2657 case UHS_DDR50:
2658 case MMC_HS_52:
2659 case MMC_DDR_52:
2660 cout = MMC_DEFAULT_CMD_OUT_TAP;
2661 dout = MMC_DEFAULT_DATA_OUT_TAP;
2662 break;
2663 case MMC_HS_200:
2664 cout = -1;
2665 dout = -1;
2666 if (host->timing_calibrated) {
2667 cout = octeontx2_mmc_calc_delay(
2668 mmc, slot->cmd_out_hs200_delay);
2669 dout = octeontx2_mmc_calc_delay(
2670 mmc,
2671 slot->data_out_hs200_delay);
2672 debug("%s(%s): Calibrated HS200/HS400 cmd out delay: %dps tap: %d, data out delay: %d, tap: %d\n",
2673 __func__, mmc->dev->name,
2674 slot->cmd_out_hs200_delay, cout,
2675 slot->data_out_hs200_delay, dout);
2676 } else {
2677 cout = MMC_DEFAULT_HS200_CMD_OUT_TAP;
2678 dout = MMC_DEFAULT_HS200_DATA_OUT_TAP;
2679 }
2680 is_hs200 = true;
2681 break;
2682 case MMC_HS_400:
2683 cout = -1;
2684 dout = -1;
2685 if (host->timing_calibrated) {
2686 if (slot->cmd_out_hs400_delay)
2687 cout = octeontx2_mmc_calc_delay(
2688 mmc,
2689 slot->cmd_out_hs400_delay);
2690 if (slot->data_out_hs400_delay)
2691 dout = octeontx2_mmc_calc_delay(
2692 mmc,
2693 slot->data_out_hs400_delay);
2694 debug("%s(%s): Calibrated HS200/HS400 cmd out delay: %dps tap: %d, data out delay: %d, tap: %d\n",
2695 __func__, mmc->dev->name,
2696 slot->cmd_out_hs400_delay, cout,
2697 slot->data_out_hs400_delay, dout);
2698 } else {
2699 cout = MMC_DEFAULT_HS400_CMD_OUT_TAP;
2700 dout = MMC_DEFAULT_HS400_DATA_OUT_TAP;
2701 }
2702 is_hs400 = true;
2703 break;
2704 default:
2705 pr_err("%s(%s): Invalid mode %d\n", __func__,
2706 mmc->dev->name, mmc->selected_mode);
2707 return -1;
2708 }
2709 debug("%s(%s): Not tuned, hs200: %d, hs200 tuned: %d, hs400: %d, hs400 tuned: %d, tuned: %d\n",
2710 __func__, mmc->dev->name, is_hs200,
2711 slot->hs200_tuned,
2712 is_hs400, slot->hs400_tuned, slot->tuned);
2713 /* Set some defaults */
2714 if (is_hs200) {
2715 slot->hs200_taps.u = 0;
2716 slot->hs200_taps.s.cmd_out_tap = cout;
2717 slot->hs200_taps.s.data_out_tap = dout;
2718 slot->hs200_taps.s.cmd_in_tap = half;
2719 slot->hs200_taps.s.data_in_tap = half;
2720 } else if (is_hs400) {
2721 slot->hs400_taps.u = 0;
2722 slot->hs400_taps.s.cmd_out_tap = cout;
2723 slot->hs400_taps.s.data_out_tap = dout;
2724 slot->hs400_taps.s.cmd_in_tap = half;
2725 slot->hs400_taps.s.data_in_tap = half;
2726 } else {
2727 slot->taps.u = 0;
2728 slot->taps.s.cmd_out_tap = cout;
2729 slot->taps.s.data_out_tap = dout;
2730 slot->taps.s.cmd_in_tap = half;
2731 slot->taps.s.data_in_tap = half;
2732 }
2733 }
2734
2735 if (is_hs200)
2736 debug("%s(%s): hs200 taps: ci: %u, co: %u, di: %u, do: %u\n",
2737 __func__, mmc->dev->name,
2738 slot->hs200_taps.s.cmd_in_tap,
2739 slot->hs200_taps.s.cmd_out_tap,
2740 slot->hs200_taps.s.data_in_tap,
2741 slot->hs200_taps.s.data_out_tap);
2742 else if (is_hs400)
2743 debug("%s(%s): hs400 taps: ci: %u, co: %u, di: %u, do: %u\n",
2744 __func__, mmc->dev->name,
2745 slot->hs400_taps.s.cmd_in_tap,
2746 slot->hs400_taps.s.cmd_out_tap,
2747 slot->hs400_taps.s.data_in_tap,
2748 slot->hs400_taps.s.data_out_tap);
2749 else
2750 debug("%s(%s): taps: ci: %u, co: %u, di: %u, do: %u\n",
2751 __func__, mmc->dev->name, slot->taps.s.cmd_in_tap,
2752 slot->taps.s.cmd_out_tap,
2753 slot->taps.s.data_in_tap,
2754 slot->taps.s.data_out_tap);
2755 octeontx_mmc_set_timing(mmc);
2756 debug("%s: Done\n", __func__);
2757 }
2758
2759 return 0;
2760}
2761
2762/**
2763 * Sets the MMC watchdog timer in microseconds
2764 *
2765 * @param mmc mmc device
2766 * @param us timeout in microseconds, 0 for maximum timeout
2767 */
2768static void set_wdog(struct mmc *mmc, u64 us)
2769{
2770 union mio_emm_wdog wdog;
2771 u64 val;
2772
2773 val = (us * mmc->clock) / 1000000;
2774 if (val >= (1 << 26) || !us) {
2775 if (us)
2776 pr_debug("%s: warning: timeout %llu exceeds max value %llu, truncating\n",
2777 __func__, us,
2778 (u64)(((1ULL << 26) - 1) * 1000000ULL) /
2779 mmc->clock);
2780 val = (1 << 26) - 1;
2781 }
2782 wdog.u = 0;
2783 wdog.s.clk_cnt = val;
2784 write_csr(mmc, MIO_EMM_WDOG(), wdog.u);
2785}
2786
2787/**
2788 * Set the IO drive strength and slew
2789 *
2790 * @param mmc mmc device
2791 */
2792static void octeontx_mmc_io_drive_setup(struct mmc *mmc)
2793{
2794 if (!IS_ENABLED(CONFIG_ARCH_OCTEONTX)) {
2795 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
2796 union mio_emm_io_ctl io_ctl;
2797
2798 if (slot->drive < 0 || slot->slew < 0)
2799 return;
2800
2801 io_ctl.u = 0;
2802 io_ctl.s.drive = slot->drive;
2803 io_ctl.s.slew = slot->slew;
2804 write_csr(mmc, MIO_EMM_IO_CTL(), io_ctl.u);
2805 }
2806}
2807
2808/**
2809 * Print switch errors
2810 *
2811 * @param mmc mmc device
2812 */
2813static void check_switch_errors(struct mmc *mmc)
2814{
2815 union mio_emm_switch emm_switch;
2816
2817 emm_switch.u = read_csr(mmc, MIO_EMM_SWITCH());
2818 if (emm_switch.s.switch_err0)
2819 pr_err("%s: Switch power class error\n", mmc->cfg->name);
2820 if (emm_switch.s.switch_err1)
2821 pr_err("%s: Switch HS timing error\n", mmc->cfg->name);
2822 if (emm_switch.s.switch_err2)
2823 pr_err("%s: Switch bus width error\n", mmc->cfg->name);
2824}
2825
2826static void do_switch(struct mmc *mmc, union mio_emm_switch emm_switch)
2827{
2828 union mio_emm_rsp_sts rsp_sts;
2829 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
2830 int bus_id = emm_switch.s.bus_id;
2831 ulong start;
2832
2833 if (emm_switch.s.bus_id != 0) {
2834 emm_switch.s.bus_id = 0;
2835 write_csr(mmc, MIO_EMM_SWITCH(), emm_switch.u);
2836 udelay(100);
2837 emm_switch.s.bus_id = bus_id;
2838 }
2839 debug("%s(%s, 0x%llx)\n", __func__, mmc->dev->name, emm_switch.u);
2840 write_csr(mmc, MIO_EMM_SWITCH(), emm_switch.u);
2841
2842 start = get_timer(0);
2843 do {
2844 rsp_sts.u = read_csr(mmc, MIO_EMM_RSP_STS());
2845 if (!rsp_sts.s.switch_val)
2846 break;
2847 udelay(100);
2848 } while (get_timer(start) < 10);
2849 if (rsp_sts.s.switch_val) {
2850 pr_warn("%s(%s): Warning: writing 0x%llx to emm_switch timed out, status: 0x%llx\n",
2851 __func__, mmc->dev->name, emm_switch.u, rsp_sts.u);
2852 }
2853 slot->cached_switch = emm_switch;
2854 check_switch_errors(mmc);
2855 slot->cached_switch.u = emm_switch.u;
2856 debug("%s: emm_switch: 0x%llx, rsp_lo: 0x%llx\n",
2857 __func__, read_csr(mmc, MIO_EMM_SWITCH()),
2858 read_csr(mmc, MIO_EMM_RSP_LO()));
2859}
2860
2861/**
2862 * Given a delay in ps, return the tap delay count
2863 *
2864 * @param mmc mmc data structure
2865 * @param delay delay in picoseconds
2866 *
2867 * @return Number of tap cycles or error if -1
2868 */
2869static int octeontx2_mmc_calc_delay(struct mmc *mmc, int delay)
2870{
2871 struct octeontx_mmc_host *host = mmc_to_host(mmc);
2872
2873 if (host->is_asim || host->is_emul)
2874 return 63;
2875
2876 if (!host->timing_taps) {
2877 pr_err("%s(%s): Error: host timing not calibrated\n",
2878 __func__, mmc->dev->name);
2879 return -1;
2880 }
2881 debug("%s(%s, %d) timing taps: %llu\n", __func__, mmc->dev->name,
2882 delay, host->timing_taps);
2883 return min_t(int, DIV_ROUND_UP(delay, host->timing_taps), 63);
2884}
2885
2886/**
2887 * Calibrates the delay based on the internal clock
2888 *
2889 * @param mmc Pointer to mmc data structure
2890 *
2891 * @return 0 for success or -ETIMEDOUT on error
2892 *
2893 * NOTE: On error a default value will be calculated.
2894 */
2895static int octeontx_mmc_calibrate_delay(struct mmc *mmc)
2896{
2897 union mio_emm_calb emm_calb;
2898 union mio_emm_tap emm_tap;
2899 union mio_emm_cfg emm_cfg;
2900 union mio_emm_io_ctl emm_io_ctl;
2901 union mio_emm_switch emm_switch;
2902 union mio_emm_wdog emm_wdog;
2903 union mio_emm_sts_mask emm_sts_mask;
2904 union mio_emm_debug emm_debug;
2905 union mio_emm_timing emm_timing;
2906 struct octeontx_mmc_host *host = mmc_to_host(mmc);
2907 ulong start;
2908 u8 bus_id, bus_ena;
2909
2910 debug("%s: Calibrating delay\n", __func__);
2911 if (host->is_asim || host->is_emul) {
2912 debug(" No calibration for ASIM\n");
2913 return 0;
2914 }
2915 emm_tap.u = 0;
2916 if (host->calibrate_glitch) {
2917 emm_tap.s.delay = MMC_DEFAULT_TAP_DELAY;
2918 } else {
2919 /* Save registers */
2920 emm_cfg.u = read_csr(mmc, MIO_EMM_CFG());
2921 emm_io_ctl.u = read_csr(mmc, MIO_EMM_IO_CTL());
2922 emm_switch.u = read_csr(mmc, MIO_EMM_SWITCH());
2923 emm_wdog.u = read_csr(mmc, MIO_EMM_WDOG());
2924 emm_sts_mask.u = read_csr(mmc, MIO_EMM_STS_MASK());
2925 emm_debug.u = read_csr(mmc, MIO_EMM_DEBUG());
2926 emm_timing.u = read_csr(mmc, MIO_EMM_TIMING());
2927 bus_ena = emm_cfg.s.bus_ena;
2928 bus_id = emm_switch.s.bus_id;
2929 emm_cfg.s.bus_ena = 0;
2930 write_csr(mmc, MIO_EMM_CFG(), emm_cfg.u);
2931 udelay(1);
2932 emm_cfg.s.bus_ena = 1ULL << 3;
2933 write_csr(mmc, MIO_EMM_CFG(), emm_cfg.u);
2934 mdelay(1);
2935 emm_calb.u = 0;
2936 write_csr(mmc, MIO_EMM_CALB(), emm_calb.u);
2937 emm_calb.s.start = 1;
2938 write_csr(mmc, MIO_EMM_CALB(), emm_calb.u);
2939 start = get_timer(0);
2940 /* This should only take 3 microseconds */
2941 do {
2942 udelay(5);
2943 emm_tap.u = read_csr(mmc, MIO_EMM_TAP());
2944 } while (!emm_tap.s.delay && get_timer(start) < 10);
2945
2946 emm_calb.s.start = 0;
2947 write_csr(mmc, MIO_EMM_CALB(), emm_calb.u);
2948
2949 emm_cfg.s.bus_ena = 0;
2950 write_csr(mmc, MIO_EMM_CFG(), emm_cfg.u);
2951 udelay(1);
2952 /* Restore registers */
2953 emm_cfg.s.bus_ena = bus_ena;
2954 write_csr(mmc, MIO_EMM_CFG(), emm_cfg.u);
2955 if (host->tap_requires_noclk) {
2956 /* Turn off the clock */
2957 emm_debug.u = read_csr(mmc, MIO_EMM_DEBUG());
2958 emm_debug.s.emmc_clk_disable = 1;
2959 write_csr(mmc, MIO_EMM_DEBUG(), emm_debug.u);
2960 udelay(1);
2961 emm_debug.s.rdsync_rst = 1;
2962 write_csr(mmc, MIO_EMM_DEBUG(), emm_debug.u);
2963 udelay(1);
2964 }
2965
2966 write_csr(mmc, MIO_EMM_TIMING(), emm_timing.u);
2967 if (host->tap_requires_noclk) {
2968 /* Turn the clock back on */
2969 udelay(1);
2970 emm_debug.s.rdsync_rst = 0;
2971 write_csr(mmc, MIO_EMM_DEBUG(), emm_debug.u);
2972 udelay(1);
2973 emm_debug.s.emmc_clk_disable = 0;
2974 write_csr(mmc, MIO_EMM_DEBUG(), emm_debug.u);
2975 }
2976 udelay(1);
2977 write_csr(mmc, MIO_EMM_IO_CTL(), emm_io_ctl.u);
2978 bus_id = emm_switch.s.bus_id;
2979 emm_switch.s.bus_id = 0;
2980 write_csr(mmc, MIO_EMM_SWITCH(), emm_switch.u);
2981 emm_switch.s.bus_id = bus_id;
2982 write_csr(mmc, MIO_EMM_SWITCH(), emm_switch.u);
2983 write_csr(mmc, MIO_EMM_WDOG(), emm_wdog.u);
2984 write_csr(mmc, MIO_EMM_STS_MASK(), emm_sts_mask.u);
2985 write_csr(mmc, MIO_EMM_RCA(), mmc->rca);
2986 write_csr(mmc, MIO_EMM_DEBUG(), emm_debug.u);
2987
2988 if (!emm_tap.s.delay) {
2989 pr_err("%s: Error: delay calibration failed, timed out.\n",
2990 __func__);
2991 /* Set to default value if timed out */
2992 emm_tap.s.delay = MMC_DEFAULT_TAP_DELAY;
2993 return -ETIMEDOUT;
2994 }
2995 }
2996 /* Round up */
2997 host->timing_taps = (10 * 1000 * emm_tap.s.delay) / TOTAL_NO_OF_TAPS;
2998 debug("%s(%s): timing taps: %llu, delay: %u\n",
2999 __func__, mmc->dev->name, host->timing_taps, emm_tap.s.delay);
3000 host->timing_calibrated = true;
3001 return 0;
3002}
3003
3004static int octeontx_mmc_set_input_bus_timing(struct mmc *mmc)
3005{
3006 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
3007
3008 if (IS_ENABLED(CONFIG_ARCH_OCTEONTX)) {
3009 union mio_emm_sample sample;
3010
3011 sample.u = 0;
3012 sample.s.cmd_cnt = slot->cmd_clk_skew;
3013 sample.s.dat_cnt = slot->dat_clk_skew;
3014 write_csr(mmc, MIO_EMM_SAMPLE(), sample.u);
3015 } else {
3016 union mio_emm_timing timing;
3017
3018 timing.u = read_csr(mmc, MIO_EMM_TIMING());
3019 if (mmc->selected_mode == MMC_HS_200) {
3020 if (slot->hs200_tuned) {
3021 timing.s.cmd_in_tap =
3022 slot->hs200_taps.s.cmd_in_tap;
3023 timing.s.data_in_tap =
3024 slot->hs200_taps.s.data_in_tap;
3025 } else {
3026 pr_warn("%s(%s): Warning: hs200 timing not tuned\n",
3027 __func__, mmc->dev->name);
3028 timing.s.cmd_in_tap =
3029 MMC_DEFAULT_HS200_CMD_IN_TAP;
3030 timing.s.data_in_tap =
3031 MMC_DEFAULT_HS200_DATA_IN_TAP;
3032 }
3033 } else if (mmc->selected_mode == MMC_HS_400) {
3034 if (slot->hs400_tuned) {
3035 timing.s.cmd_in_tap =
3036 slot->hs400_taps.s.cmd_in_tap;
3037 timing.s.data_in_tap =
3038 slot->hs400_taps.s.data_in_tap;
3039 } else if (slot->hs200_tuned) {
3040 timing.s.cmd_in_tap =
3041 slot->hs200_taps.s.cmd_in_tap;
3042 timing.s.data_in_tap =
3043 slot->hs200_taps.s.data_in_tap;
3044 } else {
3045 pr_warn("%s(%s): Warning: hs400 timing not tuned\n",
3046 __func__, mmc->dev->name);
3047 timing.s.cmd_in_tap =
3048 MMC_DEFAULT_HS200_CMD_IN_TAP;
3049 timing.s.data_in_tap =
3050 MMC_DEFAULT_HS200_DATA_IN_TAP;
3051 }
3052 } else if (slot->tuned) {
3053 timing.s.cmd_in_tap = slot->taps.s.cmd_in_tap;
3054 timing.s.data_in_tap = slot->taps.s.data_in_tap;
3055 } else {
3056 timing.s.cmd_in_tap = MMC_DEFAULT_CMD_IN_TAP;
3057 timing.s.data_in_tap = MMC_DEFAULT_DATA_IN_TAP;
3058 }
3059 octeontx_mmc_set_emm_timing(mmc, timing);
3060 }
3061
3062 return 0;
3063}
3064
3065/**
3066 * Sets the default bus timing for the current mode.
3067 *
3068 * @param mmc mmc data structure
3069 *
3070 * @return 0 for success, error otherwise
3071 */
3072static int octeontx_mmc_set_output_bus_timing(struct mmc *mmc)
3073{
3074 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
3075 union mio_emm_timing timing;
3076 int cout_bdelay, dout_bdelay;
3077 unsigned int cout_delay, dout_delay;
3078 char env_name[32];
3079
3080 if (IS_ENABLED(CONFIG_ARCH_OCTEONTX))
3081 return 0;
3082
3083 debug("%s(%s)\n", __func__, mmc->dev->name);
3084 if (slot->is_asim || slot->is_emul)
3085 return 0;
3086
3087 octeontx_mmc_calibrate_delay(mmc);
3088
3089 if (mmc->clock < 26000000) {
3090 cout_delay = 5000;
3091 dout_delay = 5000;
3092 } else if (mmc->clock <= 52000000) {
3093 cout_delay = 2500;
3094 dout_delay = 2500;
3095 } else if (!mmc_is_mode_ddr(mmc->selected_mode)) {
3096 cout_delay = slot->cmd_out_hs200_delay;
3097 dout_delay = slot->data_out_hs200_delay;
3098 } else {
3099 cout_delay = slot->cmd_out_hs400_delay;
3100 dout_delay = slot->data_out_hs400_delay;
3101 }
3102
3103 snprintf(env_name, sizeof(env_name), "mmc%d_hs200_dout_delay_ps",
3104 slot->bus_id);
3105 dout_delay = env_get_ulong(env_name, 10, dout_delay);
3106 debug("%s: dout_delay: %u\n", __func__, dout_delay);
3107
3108 cout_bdelay = octeontx2_mmc_calc_delay(mmc, cout_delay);
3109 dout_bdelay = octeontx2_mmc_calc_delay(mmc, dout_delay);
3110
3111 debug("%s: cmd output delay: %u, data output delay: %u, cmd bdelay: %d, data bdelay: %d, clock: %d\n",
3112 __func__, cout_delay, dout_delay, cout_bdelay, dout_bdelay,
3113 mmc->clock);
3114 if (cout_bdelay < 0 || dout_bdelay < 0) {
3115 pr_err("%s: Error: could not calculate command and/or data clock skew\n",
3116 __func__);
3117 return -1;
3118 }
3119 timing.u = read_csr(mmc, MIO_EMM_TIMING());
3120 timing.s.cmd_out_tap = cout_bdelay;
3121 timing.s.data_out_tap = dout_bdelay;
3122 if (mmc->selected_mode == MMC_HS_200) {
3123 slot->hs200_taps.s.cmd_out_tap = cout_bdelay;
3124 slot->hs200_taps.s.data_out_tap = dout_bdelay;
3125 } else if (mmc->selected_mode == MMC_HS_400) {
3126 slot->hs400_taps.s.cmd_out_tap = cout_bdelay;
3127 slot->hs400_taps.s.data_out_tap = dout_bdelay;
3128 } else {
3129 slot->taps.s.cmd_out_tap = cout_bdelay;
3130 slot->taps.s.data_out_tap = dout_bdelay;
3131 }
3132 octeontx_mmc_set_emm_timing(mmc, timing);
3133 debug("%s(%s): bdelay: %d/%d, clock: %d, ddr: %s, timing taps: %llu, do: %d, di: %d, co: %d, ci: %d\n",
3134 __func__, mmc->dev->name, cout_bdelay, dout_bdelay, mmc->clock,
3135 mmc->ddr_mode ? "yes" : "no",
3136 mmc_to_host(mmc)->timing_taps,
3137 timing.s.data_out_tap,
3138 timing.s.data_in_tap,
3139 timing.s.cmd_out_tap,
3140 timing.s.cmd_in_tap);
3141
3142 return 0;
3143}
3144
3145static void octeontx_mmc_set_clock(struct mmc *mmc)
3146{
3147 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
3148 uint clock;
3149
3150 clock = min(mmc->cfg->f_max, (uint)slot->clock);
3151 clock = max(mmc->cfg->f_min, clock);
3152 debug("%s(%s): f_min: %u, f_max: %u, clock: %u\n", __func__,
3153 mmc->dev->name, mmc->cfg->f_min, mmc->cfg->f_max, clock);
3154 slot->clock = clock;
3155 mmc->clock = clock;
3156}
3157
3158/**
3159 * This switches I/O power as needed when switching between slots.
3160 *
3161 * @param mmc mmc data structure
3162 */
3163static void octeontx_mmc_switch_io(struct mmc *mmc)
3164{
3165 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
3166 struct octeontx_mmc_host *host = slot->host;
3167 struct mmc *last_mmc = host->last_mmc;
3168 static struct udevice *last_reg;
3169 union mio_emm_cfg emm_cfg;
3170 int bus;
3171 static bool initialized;
3172
3173 /* First time? */
3174 if (!initialized || mmc != host->last_mmc) {
3175 struct mmc *ommc;
3176
3177 /* Switch to bus 3 which is unused */
3178 emm_cfg.u = read_csr(mmc, MIO_EMM_CFG());
3179 emm_cfg.s.bus_ena = 1 << 3;
3180 write_csr(mmc, MIO_EMM_CFG(), emm_cfg.u);
3181
3182 /* Turn off all other I/O interfaces with first initialization
3183 * if at least one supply was found.
3184 */
3185 for (bus = 0; bus <= OCTEONTX_MAX_MMC_SLOT; bus++) {
3186 ommc = &host->slots[bus].mmc;
3187
3188 /* Handle self case later */
3189 if (ommc == mmc || !ommc->vqmmc_supply)
3190 continue;
3191
3192 /* Skip if we're not switching regulators */
3193 if (last_reg == mmc->vqmmc_supply)
3194 continue;
3195
3196 /* Turn off other regulators */
3197 if (ommc->vqmmc_supply != mmc->vqmmc_supply)
3198 regulator_set_enable(ommc->vqmmc_supply, false);
3199 }
3200 /* Turn ourself on */
3201 if (mmc->vqmmc_supply && last_reg != mmc->vqmmc_supply)
3202 regulator_set_enable(mmc->vqmmc_supply, true);
3203 mdelay(1); /* Settle time */
3204 /* Switch to new bus */
3205 emm_cfg.s.bus_ena = 1 << slot->bus_id;
3206 write_csr(mmc, MIO_EMM_CFG(), emm_cfg.u);
3207 last_reg = mmc->vqmmc_supply;
3208 initialized = true;
3209 return;
3210 }
3211
3212 /* No change in device */
3213 if (last_mmc == mmc)
3214 return;
3215
3216 if (!last_mmc) {
3217 pr_warn("%s(%s): No previous slot detected in IO slot switch!\n",
3218 __func__, mmc->dev->name);
3219 return;
3220 }
3221
3222 debug("%s(%s): last: %s, supply: %p\n", __func__, mmc->dev->name,
3223 last_mmc->dev->name, mmc->vqmmc_supply);
3224
3225 /* The supply is the same so we do nothing */
3226 if (last_mmc->vqmmc_supply == mmc->vqmmc_supply)
3227 return;
3228
3229 /* Turn off the old slot I/O supply */
3230 if (last_mmc->vqmmc_supply) {
3231 debug("%s(%s): Turning off IO to %s, supply: %s\n",
3232 __func__, mmc->dev->name, last_mmc->dev->name,
3233 last_mmc->vqmmc_supply->name);
3234 regulator_set_enable(last_mmc->vqmmc_supply, false);
3235 }
3236 /* Turn on the new slot I/O supply */
3237 if (mmc->vqmmc_supply) {
3238 debug("%s(%s): Turning on IO to slot %d, supply: %s\n",
3239 __func__, mmc->dev->name, slot->bus_id,
3240 mmc->vqmmc_supply->name);
3241 regulator_set_enable(mmc->vqmmc_supply, true);
3242 }
3243 /* Allow power to settle */
3244 mdelay(1);
3245}
3246
3247/**
3248 * Called to switch between mmc devices
3249 *
3250 * @param mmc new mmc device
3251 */
3252static void octeontx_mmc_switch_to(struct mmc *mmc)
3253{
3254 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
3255 struct octeontx_mmc_slot *old_slot;
3256 struct octeontx_mmc_host *host = slot->host;
3257 union mio_emm_switch emm_switch;
3258 union mio_emm_sts_mask emm_sts_mask;
3259 union mio_emm_rca emm_rca;
3260
3261 if (slot->bus_id == host->last_slotid)
3262 return;
3263
3264 debug("%s(%s) switching from slot %d to slot %d\n", __func__,
3265 mmc->dev->name, host->last_slotid, slot->bus_id);
3266 octeontx_mmc_switch_io(mmc);
3267
3268 if (host->last_slotid >= 0 && slot->valid) {
3269 old_slot = &host->slots[host->last_slotid];
3270 old_slot->cached_switch.u = read_csr(mmc, MIO_EMM_SWITCH());
3271 old_slot->cached_rca.u = read_csr(mmc, MIO_EMM_RCA());
3272 }
3273 if (mmc->rca)
3274 write_csr(mmc, MIO_EMM_RCA(), mmc->rca);
3275 emm_switch = slot->cached_switch;
3276 do_switch(mmc, emm_switch);
3277 emm_rca.u = 0;
3278 emm_rca.s.card_rca = mmc->rca;
3279 write_csr(mmc, MIO_EMM_RCA(), emm_rca.u);
3280 mdelay(100);
3281
3282 set_wdog(mmc, 100000);
3283 if (octeontx_mmc_set_output_bus_timing(mmc) ||
3284 octeontx_mmc_set_input_bus_timing(mmc))
3285 pr_err("%s(%s): Error setting bus timing\n", __func__,
3286 mmc->dev->name);
3287 octeontx_mmc_io_drive_setup(mmc);
3288
3289 emm_sts_mask.u = 0;
3290 emm_sts_mask.s.sts_msk = 1 << 7 | 1 << 22 | 1 << 23 | 1 << 19;
3291 write_csr(mmc, MIO_EMM_STS_MASK(), emm_sts_mask.u);
3292 host->last_slotid = slot->bus_id;
3293 host->last_mmc = mmc;
3294 mdelay(10);
3295}
3296
3297/**
3298 * Perform initial timing configuration
3299 *
3300 * @param mmc mmc device
3301 *
3302 * @return 0 for success
3303 *
3304 * NOTE: This will need to be updated when new silicon comes out
3305 */
3306static int octeontx_mmc_init_timing(struct mmc *mmc)
3307{
3308 union mio_emm_timing timing;
3309
3310 if (mmc_to_slot(mmc)->is_asim || mmc_to_slot(mmc)->is_emul)
3311 return 0;
3312
3313 debug("%s(%s)\n", __func__, mmc->dev->name);
3314 timing.u = 0;
3315 timing.s.cmd_out_tap = MMC_DEFAULT_CMD_OUT_TAP;
3316 timing.s.data_out_tap = MMC_DEFAULT_DATA_OUT_TAP;
3317 timing.s.cmd_in_tap = MMC_DEFAULT_CMD_IN_TAP;
3318 timing.s.data_in_tap = MMC_DEFAULT_DATA_IN_TAP;
3319 octeontx_mmc_set_emm_timing(mmc, timing);
3320 return 0;
3321}
3322
3323/**
3324 * Perform low-level initialization
3325 *
3326 * @param mmc mmc device
3327 *
3328 * @return 0 for success, error otherwise
3329 */
3330static int octeontx_mmc_init_lowlevel(struct mmc *mmc)
3331{
3332 struct octeontx_mmc_slot *slot = mmc_to_slot(mmc);
3333 struct octeontx_mmc_host *host = slot->host;
3334 union mio_emm_switch emm_switch;
3335 u32 clk_period;
3336
3337 debug("%s(%s): lowlevel init for slot %d\n", __func__,
3338 mmc->dev->name, slot->bus_id);
3339 host->emm_cfg.s.bus_ena &= ~(1 << slot->bus_id);
3340 write_csr(mmc, MIO_EMM_CFG(), host->emm_cfg.u);
3341 udelay(100);
3342 host->emm_cfg.s.bus_ena |= 1 << slot->bus_id;
3343 write_csr(mmc, MIO_EMM_CFG(), host->emm_cfg.u);
3344 udelay(10);
3345 slot->clock = mmc->cfg->f_min;
3346 octeontx_mmc_set_clock(&slot->mmc);
3347
3348 if (IS_ENABLED(CONFIG_ARCH_OCTEONTX2)) {
3349 if (host->cond_clock_glitch) {
3350 union mio_emm_debug emm_debug;
3351
3352 emm_debug.u = read_csr(mmc, MIO_EMM_DEBUG());
3353 emm_debug.s.clk_on = 1;
3354 write_csr(mmc, MIO_EMM_DEBUG(), emm_debug.u);
3355 }
3356 octeontx_mmc_calibrate_delay(&slot->mmc);
3357 }
3358
3359 clk_period = octeontx_mmc_calc_clk_period(mmc);
3360 emm_switch.u = 0;
3361 emm_switch.s.power_class = 10;
3362 emm_switch.s.clk_lo = clk_period / 2;
3363 emm_switch.s.clk_hi = clk_period / 2;
3364
3365 emm_switch.s.bus_id = slot->bus_id;
3366 debug("%s: Performing switch\n", __func__);
3367 do_switch(mmc, emm_switch);
3368 slot->cached_switch.u = emm_switch.u;
3369
3370 if (!IS_ENABLED(CONFIG_ARCH_OCTEONTX))
3371 octeontx_mmc_init_timing(mmc);
3372
3373 set_wdog(mmc, 1000000); /* Set to 1 second */
3374 write_csr(mmc, MIO_EMM_STS_MASK(), 0xe4390080ull);
3375 write_csr(mmc, MIO_EMM_RCA(), 1);
3376 mdelay(10);
3377 debug("%s: done\n", __func__);
3378 return 0;
3379}
3380
3381/**
3382 * Translates a voltage number to bits in MMC register
3383 *
3384 * @param voltage voltage in microvolts
3385 *
3386 * @return MMC register value for voltage
3387 */
3388static u32 xlate_voltage(u32 voltage)
3389{
3390 u32 volt = 0;
3391
3392 /* Convert to millivolts */
3393 voltage /= 1000;
3394 if (voltage >= 1650 && voltage <= 1950)
3395 volt |= MMC_VDD_165_195;
3396 if (voltage >= 2000 && voltage <= 2100)
3397 volt |= MMC_VDD_20_21;
3398 if (voltage >= 2100 && voltage <= 2200)
3399 volt |= MMC_VDD_21_22;
3400 if (voltage >= 2200 && voltage <= 2300)
3401 volt |= MMC_VDD_22_23;
3402 if (voltage >= 2300 && voltage <= 2400)
3403 volt |= MMC_VDD_23_24;
3404 if (voltage >= 2400 && voltage <= 2500)
3405 volt |= MMC_VDD_24_25;
3406 if (voltage >= 2500 && voltage <= 2600)
3407 volt |= MMC_VDD_25_26;
3408 if (voltage >= 2600 && voltage <= 2700)
3409 volt |= MMC_VDD_26_27;
3410 if (voltage >= 2700 && voltage <= 2800)
3411 volt |= MMC_VDD_27_28;
3412 if (voltage >= 2800 && voltage <= 2900)
3413 volt |= MMC_VDD_28_29;
3414 if (voltage >= 2900 && voltage <= 3000)
3415 volt |= MMC_VDD_29_30;
3416 if (voltage >= 3000 && voltage <= 3100)
3417 volt |= MMC_VDD_30_31;
3418 if (voltage >= 3100 && voltage <= 3200)
3419 volt |= MMC_VDD_31_32;
3420 if (voltage >= 3200 && voltage <= 3300)
3421 volt |= MMC_VDD_32_33;
3422 if (voltage >= 3300 && voltage <= 3400)
3423 volt |= MMC_VDD_33_34;
3424 if (voltage >= 3400 && voltage <= 3500)
3425 volt |= MMC_VDD_34_35;
3426 if (voltage >= 3500 && voltage <= 3600)
3427 volt |= MMC_VDD_35_36;
3428
3429 return volt;
3430}
3431
3432/**
3433 * Check if a slot is valid in the device tree
3434 *
3435 * @param dev slot device to check
3436 *
3437 * @return true if status reports "ok" or "okay" or if no status,
3438 * false otherwise.
3439 */
3440static bool octeontx_mmc_get_valid(struct udevice *dev)
3441{
Simon Glassa7ece582020-12-19 10:40:14 -07003442 const char *stat = ofnode_read_string(dev_ofnode(dev), "status");
Suneel Garapati40e61332019-10-19 18:03:01 -07003443
3444 if (!stat || !strncmp(stat, "ok", 2))
3445 return true;
3446 else
3447 return false;
3448}
3449
3450/**
3451 * Reads slot configuration from the device tree
3452 *
3453 * @param dev slot device
3454 *
3455 * @return 0 on success, otherwise error
3456 */
3457static int octeontx_mmc_get_config(struct udevice *dev)
3458{
3459 struct octeontx_mmc_slot *slot = dev_to_mmc_slot(dev);
3460 uint voltages[2];
3461 uint low, high;
3462 char env_name[32];
3463 int err;
Simon Glassa7ece582020-12-19 10:40:14 -07003464 ofnode node = dev_ofnode(dev);
Suneel Garapati40e61332019-10-19 18:03:01 -07003465 int bus_width = 1;
3466 ulong new_max_freq;
3467
3468 debug("%s(%s)", __func__, dev->name);
3469 slot->cfg.name = dev->name;
3470
Simon Glassa7ece582020-12-19 10:40:14 -07003471 slot->cfg.f_max = ofnode_read_s32_default(dev_ofnode(dev),
3472 "max-frequency",
Suneel Garapati40e61332019-10-19 18:03:01 -07003473 26000000);
3474 snprintf(env_name, sizeof(env_name), "mmc_max_frequency%d",
3475 slot->bus_id);
3476
3477 new_max_freq = env_get_ulong(env_name, 10, slot->cfg.f_max);
3478 debug("Reading %s, got %lu\n", env_name, new_max_freq);
3479
3480 if (new_max_freq != slot->cfg.f_max) {
3481 printf("Overriding device tree MMC maximum frequency %u to %lu\n",
3482 slot->cfg.f_max, new_max_freq);
3483 slot->cfg.f_max = new_max_freq;
3484 }
3485 slot->cfg.f_min = 400000;
3486 slot->cfg.b_max = CONFIG_SYS_MMC_MAX_BLK_COUNT;
3487
3488 if (IS_ENABLED(CONFIG_ARCH_OCTEONTX2)) {
3489 slot->hs400_tuning_block =
Simon Glassa7ece582020-12-19 10:40:14 -07003490 ofnode_read_s32_default(dev_ofnode(dev),
Suneel Garapati40e61332019-10-19 18:03:01 -07003491 "marvell,hs400-tuning-block",
3492 -1);
3493 debug("%s(%s): mmc HS400 tuning block: %d\n", __func__,
3494 dev->name, slot->hs400_tuning_block);
3495
3496 slot->hs200_tap_adj =
Simon Glassa7ece582020-12-19 10:40:14 -07003497 ofnode_read_s32_default(dev_ofnode(dev),
Suneel Garapati40e61332019-10-19 18:03:01 -07003498 "marvell,hs200-tap-adjust", 0);
3499 debug("%s(%s): hs200-tap-adjust: %d\n", __func__, dev->name,
3500 slot->hs200_tap_adj);
3501 slot->hs400_tap_adj =
Simon Glassa7ece582020-12-19 10:40:14 -07003502 ofnode_read_s32_default(dev_ofnode(dev),
Suneel Garapati40e61332019-10-19 18:03:01 -07003503 "marvell,hs400-tap-adjust", 0);
3504 debug("%s(%s): hs400-tap-adjust: %d\n", __func__, dev->name,
3505 slot->hs400_tap_adj);
3506 }
3507
Simon Glassa7ece582020-12-19 10:40:14 -07003508 err = ofnode_read_u32_array(dev_ofnode(dev), "voltage-ranges",
3509 voltages, 2);
Suneel Garapati40e61332019-10-19 18:03:01 -07003510 if (err) {
3511 slot->cfg.voltages = MMC_VDD_32_33 | MMC_VDD_33_34;
3512 } else {
3513 low = xlate_voltage(voltages[0]);
3514 high = xlate_voltage(voltages[1]);
3515 debug(" low voltage: 0x%x (%u), high: 0x%x (%u)\n",
3516 low, voltages[0], high, voltages[1]);
3517 if (low > high || !low || !high) {
3518 pr_err("Invalid MMC voltage range [%u-%u] specified for %s\n",
3519 low, high, dev->name);
3520 return -1;
3521 }
3522 slot->cfg.voltages = 0;
3523 do {
3524 slot->cfg.voltages |= low;
3525 low <<= 1;
3526 } while (low <= high);
3527 }
3528 debug("%s: config voltages: 0x%x\n", __func__, slot->cfg.voltages);
3529 slot->slew = ofnode_read_s32_default(node, "cavium,clk-slew", -1);
3530 slot->drive = ofnode_read_s32_default(node, "cavium,drv-strength", -1);
3531 gpio_request_by_name(dev, "cd-gpios", 0, &slot->cd_gpio, GPIOD_IS_IN);
3532 slot->cd_inverted = ofnode_read_bool(node, "cd-inverted");
3533 gpio_request_by_name(dev, "wp-gpios", 0, &slot->wp_gpio, GPIOD_IS_IN);
3534 slot->wp_inverted = ofnode_read_bool(node, "wp-inverted");
3535 if (slot->cfg.voltages & MMC_VDD_165_195) {
3536 slot->is_1_8v = true;
3537 slot->is_3_3v = false;
3538 } else if (slot->cfg.voltages & (MMC_VDD_30_31 | MMC_VDD_31_32 |
3539 MMC_VDD_33_34 | MMC_VDD_34_35 |
3540 MMC_VDD_35_36)) {
3541 slot->is_1_8v = false;
3542 slot->is_3_3v = true;
3543 }
3544
3545 bus_width = ofnode_read_u32_default(node, "bus-width", 1);
3546 /* Note fall-through */
3547 switch (bus_width) {
3548 case 8:
3549 slot->cfg.host_caps |= MMC_MODE_8BIT;
3550 case 4:
3551 slot->cfg.host_caps |= MMC_MODE_4BIT;
3552 case 1:
3553 slot->cfg.host_caps |= MMC_MODE_1BIT;
3554 break;
3555 }
3556 if (ofnode_read_bool(node, "no-1-8-v")) {
3557 slot->is_3_3v = true;
3558 slot->is_1_8v = false;
3559 if (!(slot->cfg.voltages & (MMC_VDD_32_33 | MMC_VDD_33_34)))
3560 pr_warn("%s(%s): voltages indicate 3.3v but 3.3v not supported\n",
3561 __func__, dev->name);
3562 }
3563 if (ofnode_read_bool(node, "mmc-ddr-3-3v")) {
3564 slot->is_3_3v = true;
3565 slot->is_1_8v = false;
3566 if (!(slot->cfg.voltages & (MMC_VDD_32_33 | MMC_VDD_33_34)))
3567 pr_warn("%s(%s): voltages indicate 3.3v but 3.3v not supported\n",
3568 __func__, dev->name);
3569 }
3570 if (ofnode_read_bool(node, "cap-sd-highspeed") ||
3571 ofnode_read_bool(node, "cap-mmc-highspeed") ||
3572 ofnode_read_bool(node, "sd-uhs-sdr25"))
3573 slot->cfg.host_caps |= MMC_MODE_HS;
3574 if (slot->cfg.f_max >= 50000000 &&
3575 slot->cfg.host_caps & MMC_MODE_HS)
3576 slot->cfg.host_caps |= MMC_MODE_HS_52MHz | MMC_MODE_HS;
3577 if (ofnode_read_bool(node, "sd-uhs-sdr50"))
3578 slot->cfg.host_caps |= MMC_MODE_HS_52MHz | MMC_MODE_HS;
3579 if (ofnode_read_bool(node, "sd-uhs-ddr50"))
3580 slot->cfg.host_caps |= MMC_MODE_HS | MMC_MODE_HS_52MHz |
3581 MMC_MODE_DDR_52MHz;
3582
3583 if (IS_ENABLED(CONFIG_ARCH_OCTEONTX2)) {
3584 if (!slot->is_asim && !slot->is_emul) {
3585 if (ofnode_read_bool(node, "mmc-hs200-1_8v"))
3586 slot->cfg.host_caps |= MMC_MODE_HS200 |
3587 MMC_MODE_HS_52MHz;
3588 if (ofnode_read_bool(node, "mmc-hs400-1_8v"))
3589 slot->cfg.host_caps |= MMC_MODE_HS400 |
3590 MMC_MODE_HS_52MHz |
3591 MMC_MODE_HS200 |
3592 MMC_MODE_DDR_52MHz;
3593 slot->cmd_out_hs200_delay =
3594 ofnode_read_u32_default(node,
3595 "marvell,cmd-out-hs200-dly",
3596 MMC_DEFAULT_HS200_CMD_OUT_DLY);
3597 debug("%s(%s): HS200 cmd out delay: %d\n",
3598 __func__, dev->name, slot->cmd_out_hs200_delay);
3599 slot->data_out_hs200_delay =
3600 ofnode_read_u32_default(node,
3601 "marvell,data-out-hs200-dly",
3602 MMC_DEFAULT_HS200_DATA_OUT_DLY);
3603 debug("%s(%s): HS200 data out delay: %d\n",
3604 __func__, dev->name, slot->data_out_hs200_delay);
3605 slot->cmd_out_hs400_delay =
3606 ofnode_read_u32_default(node,
3607 "marvell,cmd-out-hs400-dly",
3608 MMC_DEFAULT_HS400_CMD_OUT_DLY);
3609 debug("%s(%s): HS400 cmd out delay: %d\n",
3610 __func__, dev->name, slot->cmd_out_hs400_delay);
3611 slot->data_out_hs400_delay =
3612 ofnode_read_u32_default(node,
3613 "marvell,data-out-hs400-dly",
3614 MMC_DEFAULT_HS400_DATA_OUT_DLY);
3615 debug("%s(%s): HS400 data out delay: %d\n",
3616 __func__, dev->name, slot->data_out_hs400_delay);
3617 }
3618 }
3619
3620 slot->disable_ddr = ofnode_read_bool(node, "marvell,disable-ddr");
3621 slot->non_removable = ofnode_read_bool(node, "non-removable");
3622 slot->cmd_clk_skew = ofnode_read_u32_default(node,
3623 "cavium,cmd-clk-skew", 0);
3624 slot->dat_clk_skew = ofnode_read_u32_default(node,
3625 "cavium,dat-clk-skew", 0);
3626 debug("%s(%s): host caps: 0x%x\n", __func__,
3627 dev->name, slot->cfg.host_caps);
3628 return 0;
3629}
3630
3631/**
3632 * Probes a MMC slot
3633 *
3634 * @param dev mmc device
3635 *
3636 * @return 0 for success, error otherwise
3637 */
3638static int octeontx_mmc_slot_probe(struct udevice *dev)
3639{
3640 struct octeontx_mmc_slot *slot;
3641 struct mmc *mmc;
3642 int err;
3643
Suneel Garapati40e61332019-10-19 18:03:01 -07003644 debug("%s(%s)\n", __func__, dev->name);
3645 if (!host_probed) {
3646 pr_err("%s(%s): Error: host not probed yet\n",
3647 __func__, dev->name);
3648 }
3649 slot = dev_to_mmc_slot(dev);
3650 mmc = &slot->mmc;
3651 mmc->dev = dev;
3652
3653 slot->valid = false;
3654 if (!octeontx_mmc_get_valid(dev)) {
3655 debug("%s(%s): slot is invalid\n", __func__, dev->name);
3656 return -ENODEV;
3657 }
3658
3659 debug("%s(%s): Getting config\n", __func__, dev->name);
3660 err = octeontx_mmc_get_config(dev);
3661 if (err) {
3662 pr_err("probe(%s): Error getting config\n", dev->name);
3663 return err;
3664 }
3665
3666 debug("%s(%s): mmc bind, mmc: %p\n", __func__, dev->name, &slot->mmc);
3667 err = mmc_bind(dev, &slot->mmc, &slot->cfg);
3668 if (err) {
3669 pr_err("%s(%s): Error binding mmc\n", __func__, dev->name);
3670 return -1;
3671 }
3672
3673 /* For some reason, mmc_bind always assigns priv to the device */
3674 slot->mmc.priv = slot;
3675
3676 debug("%s(%s): lowlevel init\n", __func__, dev->name);
3677 err = octeontx_mmc_init_lowlevel(mmc);
3678 if (err) {
3679 pr_err("probe(%s): Low-level init failed\n", dev->name);
3680 return err;
3681 }
3682
3683 slot->valid = true;
3684
3685 debug("%s(%s):\n"
3686 " base address : %p\n"
3687 " bus id : %d\n", __func__, dev->name,
3688 slot->base_addr, slot->bus_id);
3689
3690 return err;
3691}
3692
3693/**
3694 * MMC slot driver operations
3695 */
3696static const struct dm_mmc_ops octeontx_hsmmc_ops = {
3697 .send_cmd = octeontx_mmc_dev_send_cmd,
3698 .set_ios = octeontx_mmc_set_ios,
3699 .get_cd = octeontx_mmc_get_cd,
3700 .get_wp = octeontx_mmc_get_wp,
3701#ifdef MMC_SUPPORTS_TUNING
3702 .execute_tuning = octeontx_mmc_execute_tuning,
3703#endif
3704};
3705
3706static const struct udevice_id octeontx_hsmmc_ids[] = {
3707 { .compatible = "mmc-slot" },
3708 { }
3709};
3710
3711U_BOOT_DRIVER(octeontx_hsmmc_slot) = {
3712 .name = "octeontx_hsmmc_slot",
3713 .id = UCLASS_MMC,
3714 .of_match = of_match_ptr(octeontx_hsmmc_ids),
3715 .probe = octeontx_mmc_slot_probe,
3716 .ops = &octeontx_hsmmc_ops,
3717};
3718
3719/*****************************************************************
3720 * PCI host driver
3721 *
3722 * The PCI host driver contains the resources used by all of the
3723 * slot drivers.
3724 *
3725 * The slot drivers are pseudo drivers.
3726 */
3727
3728/**
3729 * Probe the MMC host controller
3730 *
3731 * @param dev mmc host controller device
3732 *
3733 * @return 0 for success, -1 on error
3734 */
3735static int octeontx_mmc_host_probe(struct udevice *dev)
3736{
Suneel Garapati40e61332019-10-19 18:03:01 -07003737 struct octeontx_mmc_host *host = dev_get_priv(dev);
3738 union mio_emm_int emm_int;
3739 u8 rev;
3740
3741 debug("%s(%s): Entry host: %p\n", __func__, dev->name, host);
3742
3743 if (!octeontx_mmc_get_valid(dev)) {
3744 debug("%s(%s): mmc host not valid\n", __func__, dev->name);
3745 return -ENODEV;
3746 }
3747 memset(host, 0, sizeof(*host));
3748 host->base_addr = dm_pci_map_bar(dev, PCI_BASE_ADDRESS_0,
3749 PCI_REGION_MEM);
3750 if (!host->base_addr) {
3751 pr_err("%s: Error: MMC base address not found\n", __func__);
3752 return -1;
3753 }
3754 host->dev = dev;
3755 debug("%s(%s): Base address: %p\n", __func__, dev->name,
3756 host->base_addr);
Simon Glass07c17772020-12-19 10:40:12 -07003757 if (!dev_has_ofnode(dev)) {
Suneel Garapati40e61332019-10-19 18:03:01 -07003758 pr_err("%s: No device tree information found\n", __func__);
3759 return -1;
3760 }
Simon Glassa7ece582020-12-19 10:40:14 -07003761 host->node = dev_ofnode(dev);
Suneel Garapati40e61332019-10-19 18:03:01 -07003762 host->last_slotid = -1;
3763 if (otx_is_platform(PLATFORM_ASIM))
3764 host->is_asim = true;
3765 if (otx_is_platform(PLATFORM_EMULATOR))
3766 host->is_emul = true;
3767 host->dma_wait_delay =
Simon Glassa7ece582020-12-19 10:40:14 -07003768 ofnode_read_u32_default(dev_ofnode(dev),
3769 "marvell,dma-wait-delay", 1);
Suneel Garapati40e61332019-10-19 18:03:01 -07003770 /* Force reset of eMMC */
3771 writeq(0, host->base_addr + MIO_EMM_CFG());
3772 debug("%s: Clearing MIO_EMM_CFG\n", __func__);
3773 udelay(100);
3774 emm_int.u = readq(host->base_addr + MIO_EMM_INT());
3775 debug("%s: Writing 0x%llx to MIO_EMM_INT\n", __func__, emm_int.u);
3776 writeq(emm_int.u, host->base_addr + MIO_EMM_INT());
3777
3778 debug("%s(%s): Getting I/O clock\n", __func__, dev->name);
3779 host->sys_freq = octeontx_get_io_clock();
3780 debug("%s(%s): I/O clock %llu\n", __func__, dev->name, host->sys_freq);
3781
3782 if (IS_ENABLED(CONFIG_ARCH_OCTEONTX2)) {
3783 /* Flags for issues to work around */
3784 dm_pci_read_config8(dev, PCI_REVISION_ID, &rev);
3785 if (otx_is_soc(CN96XX)) {
3786 debug("%s: CN96XX revision %d\n", __func__, rev);
3787 switch (rev) {
3788 case 0:
3789 host->calibrate_glitch = true;
3790 host->cond_clock_glitch = true;
3791 break;
3792 case 1:
3793 break;
3794 case 2:
3795 break;
3796 case 0x10: /* C0 */
3797 host->hs400_skew_needed = true;
3798 debug("HS400 skew support enabled\n");
3799 fallthrough;
3800 default:
3801 debug("CN96XX rev C0+ detected\n");
3802 host->tap_requires_noclk = true;
3803 break;
3804 }
3805 } else if (otx_is_soc(CN95XX)) {
3806 if (!rev)
3807 host->cond_clock_glitch = true;
3808 }
3809 }
3810
3811 host_probed = true;
3812
3813 return 0;
3814}
3815
3816/**
3817 * This performs some initial setup before a probe occurs.
3818 *
3819 * @param dev: MMC slot device
3820 *
3821 * @return 0 for success, -1 on failure
3822 *
3823 * Do some pre-initialization before probing a slot.
3824 */
3825static int octeontx_mmc_host_child_pre_probe(struct udevice *dev)
3826{
3827 struct octeontx_mmc_host *host = dev_get_priv(dev_get_parent(dev));
3828 struct octeontx_mmc_slot *slot;
3829 struct mmc_uclass_priv *upriv;
Simon Glassa7ece582020-12-19 10:40:14 -07003830 ofnode node = dev_ofnode(dev);
Suneel Garapati40e61332019-10-19 18:03:01 -07003831 u32 bus_id;
3832 char name[16];
3833 int err;
3834
3835 debug("%s(%s) Pre-Probe\n", __func__, dev->name);
3836 if (ofnode_read_u32(node, "reg", &bus_id)) {
3837 pr_err("%s(%s): Error: \"reg\" not found in device tree\n",
3838 __func__, dev->name);
3839 return -1;
3840 }
3841 if (bus_id > OCTEONTX_MAX_MMC_SLOT) {
3842 pr_err("%s(%s): Error: \"reg\" out of range of 0..%d\n",
3843 __func__, dev->name, OCTEONTX_MAX_MMC_SLOT);
3844 return -1;
3845 }
3846
3847 slot = &host->slots[bus_id];
Simon Glass95588622020-12-22 19:30:28 -07003848 dev_set_priv(dev, slot);
Suneel Garapati40e61332019-10-19 18:03:01 -07003849 slot->host = host;
3850 slot->bus_id = bus_id;
3851 slot->dev = dev;
3852 slot->base_addr = host->base_addr;
3853 slot->is_asim = host->is_asim;
3854 slot->is_emul = host->is_emul;
3855
3856 snprintf(name, sizeof(name), "octeontx-mmc%d", bus_id);
3857 err = device_set_name(dev, name);
3858
Simon Glass95588622020-12-22 19:30:28 -07003859 /* FIXME: This code should not be needed */
3860 if (!dev_get_uclass_priv(dev)) {
Suneel Garapati40e61332019-10-19 18:03:01 -07003861 debug("%s(%s): Allocating uclass priv\n", __func__,
3862 dev->name);
3863 upriv = calloc(1, sizeof(struct mmc_uclass_priv));
3864 if (!upriv)
3865 return -ENOMEM;
Simon Glass95588622020-12-22 19:30:28 -07003866
3867 /*
3868 * FIXME: This is not allowed
3869 * dev_set_uclass_priv(dev, upriv);
3870 * uclass_set_priv(dev->uclass, upriv);
3871 */
Suneel Garapati40e61332019-10-19 18:03:01 -07003872 } else {
Simon Glass95588622020-12-22 19:30:28 -07003873 upriv = dev_get_uclass_priv(dev);
Suneel Garapati40e61332019-10-19 18:03:01 -07003874 }
3875
3876 upriv->mmc = &slot->mmc;
3877 debug("%s: uclass priv: %p, mmc: %p\n", dev->name, upriv, upriv->mmc);
3878
3879 debug("%s: ret: %d\n", __func__, err);
3880 return err;
3881}
3882
3883static const struct udevice_id octeontx_hsmmc_host_ids[] = {
3884 { .compatible = "cavium,thunder-8890-mmc" },
3885 { }
3886};
3887
3888U_BOOT_DRIVER(octeontx_hsmmc_host) = {
3889 .name = "octeontx_hsmmc_host",
Simon Glass95588622020-12-22 19:30:28 -07003890 /* FIXME: Why is this not UCLASS_MMC? */
Suneel Garapati40e61332019-10-19 18:03:01 -07003891 .id = UCLASS_MISC,
3892 .of_match = of_match_ptr(octeontx_hsmmc_host_ids),
3893 .probe = octeontx_mmc_host_probe,
Simon Glass8a2b47f2020-12-03 16:55:17 -07003894 .priv_auto = sizeof(struct octeontx_mmc_host),
Suneel Garapati40e61332019-10-19 18:03:01 -07003895 .child_pre_probe = octeontx_mmc_host_child_pre_probe,
3896 .flags = DM_FLAG_PRE_RELOC,
3897};
3898
3899static struct pci_device_id octeontx_mmc_supported[] = {
3900 { PCI_VDEVICE(CAVIUM, PCI_DEVICE_ID_CAVIUM_EMMC) },
3901 { },
3902};
3903
3904U_BOOT_PCI_DEVICE(octeontx_hsmmc_host, octeontx_mmc_supported);