blob: 34d761c73079bfbcaeaa2302792ad2facea1af17 [file] [log] [blame]
Sheetal Tigadolib0156702020-01-05 14:59:04 +05301/*
2 * Copyright (c) 2016 - 2020, Broadcom
3 *
4 * SPDX-License-Identifier: BSD-3-Clause
5 */
6
7#include <assert.h>
8#include <string.h>
9
10#include <lib/mmio.h>
11
12#include <platform_def.h>
13
14#include "bcm_emmc.h"
15#include "emmc_chal_types.h"
16#include "emmc_chal_sd.h"
17#include "emmc_pboot_hal_memory_drv.h"
18
19extern void emmc_soft_reset(void);
20
21#define SD_VDD_WINDOW_1_6_TO_1_7 0x00000010 // 1.6 V to 1.7 Volts
22#define SD_VDD_WINDOW_1_7_TO_1_8 0x00000020 // 1.7 V to 1.8 Volts
23#define SD_VDD_WINDOW_1_8_TO_1_9 0x00000040 // 1.8 V to 1.9 Volts
24#define SD_VDD_WINDOW_1_9_TO_2_0 0x00000080 // 1.9 V to 2.0 Volts
25#define SD_VDD_WINDOW_2_0_TO_2_1 0x00000100 // 2.0 V to 2.1 Volts
26#define SD_VDD_WINDOW_2_1_TO_2_2 0x00000200 // 2.1 V to 2.2 Volts
27#define SD_VDD_WINDOW_2_2_TO_2_3 0x00000400 // 2.2 V to 2.3 Volts
28#define SD_VDD_WINDOW_2_3_TO_2_4 0x00000800 // 2.3 V to 2.4 Volts
29#define SD_VDD_WINDOW_2_4_TO_2_5 0x00001000 // 2.4 V to 2.5 Volts
30#define SD_VDD_WINDOW_2_5_TO_2_6 0x00002000 // 2.5 V to 2.6 Volts
31#define SD_VDD_WINDOW_2_6_TO_2_7 0x00004000 // 2.6 V to 2.7 Volts
32#define SD_VDD_WINDOW_2_7_TO_2_8 0x00008000 // 2.7 V to 2.8 Volts
33#define SD_VDD_WINDOW_2_8_TO_2_9 0x00010000 // 2.8 V to 2.9 Volts
34#define SD_VDD_WINDOW_2_9_TO_3_0 0x00020000 // 2.9 V to 3.0 Volts
35#define SD_VDD_WINDOW_3_0_TO_3_1 0x00040000 // 3.0 V to 3.1 Volts
36#define SD_VDD_WINDOW_3_1_TO_3_2 0x00080000 // 3.1 V to 3.2 Volts
37#define SD_VDD_WINDOW_3_2_TO_3_3 0x00100000 // 3.2 V to 3.3 Volts
38#define SD_VDD_WINDOW_3_3_TO_3_4 0x00200000 // 3.3 V to 3.4 Volts
39#define SD_VDD_WINDOW_3_4_TO_3_5 0x00400000 // 3.4 V to 3.5 Volts
40#define SD_VDD_WINDOW_3_5_TO_3_6 0x00800000 // 3.5 V to 3.6 Volts
41
42#define SD_VDD_WINDOW_1_6_TO_2_6 (SD_VDD_WINDOW_1_6_TO_1_7 | \
43 SD_VDD_WINDOW_1_7_TO_1_8 | \
44 SD_VDD_WINDOW_1_8_TO_1_9 | \
45 SD_VDD_WINDOW_1_9_TO_2_0 | \
46 SD_VDD_WINDOW_2_0_TO_2_1 | \
47 SD_VDD_WINDOW_2_1_TO_2_2 | \
48 SD_VDD_WINDOW_2_2_TO_2_3 | \
49 SD_VDD_WINDOW_2_3_TO_2_4 | \
50 SD_VDD_WINDOW_2_4_TO_2_5 | \
51 SD_VDD_WINDOW_2_5_TO_2_6)
52
53#define SD_VDD_WINDOW_2_6_TO_3_2 (SD_VDD_WINDOW_2_6_TO_2_7 | \
54 SD_VDD_WINDOW_2_7_TO_2_8 | \
55 SD_VDD_WINDOW_2_8_TO_2_9 | \
56 SD_VDD_WINDOW_2_9_TO_3_0 | \
57 SD_VDD_WINDOW_3_0_TO_3_1 | \
58 SD_VDD_WINDOW_3_1_TO_3_2)
59
60#define SD_VDD_WINDOW_3_2_TO_3_6 (SD_VDD_WINDOW_3_2_TO_3_3 | \
61 SD_VDD_WINDOW_3_3_TO_3_4 | \
62 SD_VDD_WINDOW_3_4_TO_3_5 | \
63 SD_VDD_WINDOW_3_5_TO_3_6)
64
65
66static int32_t chal_sd_set_power(struct sd_dev *handle,
67 uint32_t voltage, uint32_t state);
68
69static void chal_sd_set_dma_boundary(struct sd_dev *handle, uint32_t boundary);
70
71static int32_t chal_sd_setup_handler(struct sd_dev *handle,
72 uint32_t sdBbase, uint32_t hostBase);
73
74/*
75 * Configure host controller pwr settings,
76 * to match voltage requirements by SD Card
77 */
78static int32_t chal_sd_set_power(struct sd_dev *handle,
79 uint32_t voltage, uint32_t state)
80{
81 int32_t rc, rval = SD_FAIL;
82 uint32_t time = 0;
83
84 if (handle == NULL)
85 return SD_INVALID_HANDLE;
86
87 mmio_clrsetbits_32(handle->ctrl.sdRegBaseAddr +
88 SD4_EMMC_TOP_CTRL_OFFSET,
89 (SD4_EMMC_TOP_CTRL_SDVSELVDD1_MASK |
90 SD4_EMMC_TOP_CTRL_SDPWR_MASK),
91 (voltage << 9));
92
93 /*
94 * Long delay is required here in emulation. Without this, the initial
95 * commands sent to the eMMC card timeout. We don't know if this
96 * delay is necessary with silicon, leaving in for safety.
97 * It is observed that 403ms on emulation system and as per the clock
98 * calculations it is expected to complete with in 1ms on chip
99 */
100 do {
101 rc = mmio_read_32(handle->ctrl.sdRegBaseAddr +
102 SD4_EMMC_TOP_INTR_OFFSET);
103
104 if ((rc & SD4_EMMC_TOP_INTR_CRDINS_MASK) ==
105 SD4_EMMC_TOP_INTR_CRDINS_MASK)
106 break;
107
108 mdelay(1);
109 } while (time++ < EMMC_CARD_DETECT_TIMEOUT_MS);
110
111 if (time >= EMMC_CARD_DETECT_TIMEOUT_MS) {
112 ERROR("EMMC: Card insert event detection timeout\n");
113 return rval;
114 }
115
116 VERBOSE("EMMC: Card detection delay: %dms\n", time);
117
118 if (state)
119 mmio_setbits_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CTRL_OFFSET,
120 SD4_EMMC_TOP_CTRL_SDPWR_MASK);
121
122 /* dummy write & ack to verify if the sdio is ready to send commads */
123 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_ARG_OFFSET, 0);
124 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CMD_OFFSET, 0);
125
126 /*
127 * 63ms observed on emulation system, As per clock calculations
128 * it will complete < 1ms on chip.
129 */
130 time = 0;
131 do {
132 rc = mmio_read_32(handle->ctrl.sdRegBaseAddr +
133 SD4_EMMC_TOP_INTR_OFFSET);
134
135 if (rc & SD4_EMMC_TOP_INTR_ERRIRQ_MASK)
136 break;
137
138 if ((rc & SD4_EMMC_TOP_INTR_CMDDONE_MASK) ==
139 SD4_EMMC_TOP_INTR_CMDDONE_MASK)
140 break;
141
142 mdelay(1);
143 } while (time++ < EMMC_CMD_TIMEOUT_MS);
144
145 if (time >= EMMC_CMD_TIMEOUT_MS) {
146 WARN("%s %d Initial dummy command timeout is happened\n",
147 __func__, __LINE__);
148 return rval;
149 }
150
151 VERBOSE("EMMC: Dummy Command delay: %dms\n", time);
152
153 return SD_OK;
154}
155
156/*
157 * Configure DMA Boundaries
158 */
159static void chal_sd_set_dma_boundary(struct sd_dev *handle, uint32_t boundary)
160{
161 if (handle == NULL)
162 return;
163
164 mmio_clrsetbits_32(handle->ctrl.sdRegBaseAddr +
165 SD4_EMMC_TOP_BLOCK_OFFSET,
166 SD4_EMMC_TOP_BLOCK_HSBS_MASK, boundary);
167}
168
169static int32_t chal_sd_setup_handler(struct sd_dev *handle, uint32_t sdBase,
170 uint32_t hostBase)
171{
172 if (handle == NULL)
173 return SD_INVALID_HANDLE;
174
175 handle->ctrl.sdRegBaseAddr = sdBase;
176 handle->ctrl.hostRegBaseAddr = hostBase;
177 handle->ctrl.present = 0;
178 handle->ctrl.rca = 0;
179 handle->ctrl.blkGapEnable = 0;
180 handle->ctrl.cmdStatus = 0;
181
182 return SD_OK;
183}
184
185/*
186 * Initialize SD Host controller
187 */
188int32_t chal_sd_init(CHAL_HANDLE *sd_handle)
189{
190 uint32_t cap_val_l = 0;
191 uint32_t ctl_val, voltage;
192 uint32_t timeout_val;
193 struct sd_dev *handle;
194 uint32_t reg_val;
195 int32_t rval = SD_FAIL;
196
197 if (sd_handle == NULL)
198 return SD_INVALID_HANDLE;
199
200 handle = (struct sd_dev *)sd_handle;
201
202 /*
203 * Set SDIO Host Controller capabilities register
204 */
205 EMMC_TRACE("Set Host Controller Capabilities register\n");
206
207 reg_val = 0;
208 reg_val |= (1 << ICFG_SDIO0_CAP0__SLOT_TYPE_R);
209 reg_val |= (0 << ICFG_SDIO0_CAP0__INT_MODE_R);
210 reg_val |= (0 << ICFG_SDIO0_CAP0__SYS_BUS_64BIT_R);
211 reg_val |= (1 << ICFG_SDIO0_CAP0__VOLTAGE_1P8V_R);
212 reg_val |= (1 << ICFG_SDIO0_CAP0__VOLTAGE_3P0V_R);
213 reg_val |= (1 << ICFG_SDIO0_CAP0__VOLTAGE_3P3V_R);
214 reg_val |= (1 << ICFG_SDIO0_CAP0__SUSPEND_RESUME_R);
215 reg_val |= (1 << ICFG_SDIO0_CAP0__SDMA_R);
216 reg_val |= (1 << ICFG_SDIO0_CAP0__HIGH_SPEED_R);
217 reg_val |= (1 << ICFG_SDIO0_CAP0__ADMA2_R);
218 reg_val |= (1 << ICFG_SDIO0_CAP0__EXTENDED_MEDIA_R);
219 reg_val |= (2 << ICFG_SDIO0_CAP0__MAX_BLOCK_LEN_R);
220 reg_val |= (0xd0 << ICFG_SDIO0_CAP0__BASE_CLK_FREQ_R);
221 reg_val |= (1 << ICFG_SDIO0_CAP0__TIMEOUT_UNIT_R);
222 reg_val |= (0x30 << ICFG_SDIO0_CAP0__TIMEOUT_CLK_FREQ_R);
223
224 mmio_write_32(ICFG_SDIO0_CAP0, reg_val);
225
226 reg_val = 0;
227 reg_val |= (1 << ICFG_SDIO0_CAP1__SPI_BLOCK_MODE_R);
228 reg_val |= (1 << ICFG_SDIO0_CAP1__SPI_MODE_R);
229 reg_val |= (0 << ICFG_SDIO0_CAP1__CLK_MULT_R);
230 reg_val |= (0 << ICFG_SDIO0_CAP1__RETUNING_MODE_R);
231 reg_val |= (1 << ICFG_SDIO0_CAP1__TUNE_SDR50_R);
232 reg_val |= (1 << ICFG_SDIO0_CAP1__TIME_RETUNE_R);
233 reg_val |= (1 << ICFG_SDIO0_CAP1__DRIVER_D_R);
234 reg_val |= (1 << ICFG_SDIO0_CAP1__DRIVER_C_R);
235 reg_val |= (1 << ICFG_SDIO0_CAP1__DRIVER_A_R);
236 reg_val |= (1 << ICFG_SDIO0_CAP1__DDR50_R);
237 reg_val |= (1 << ICFG_SDIO0_CAP1__SDR104_R);
238 reg_val |= (1 << ICFG_SDIO0_CAP1__SDR50_R);
239
240 mmio_write_32(ICFG_SDIO0_CAP1, reg_val);
241
242 /* Reset the SDIO controller */
243 chal_sd_stop();
244
245 /* Turn on SD clock */
246 chal_sd_set_clock(sd_handle,
247 chal_sd_freq_2_div_ctrl_setting(INIT_CLK_FREQ), 1);
248
249 /* program data time out value to the max */
250 timeout_val = SD_HOST_CORE_TIMEOUT;
251
252 ctl_val = mmio_read_32(handle->ctrl.sdRegBaseAddr +
253 SD4_EMMC_TOP_CTRL1_OFFSET);
254 ctl_val |= ((timeout_val & 0xf) << SD4_EMMC_TOP_CTRL1_DTCNT_SHIFT);
255
256 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CTRL1_OFFSET,
257 ctl_val);
258
259 /* enable all interrupt status */
260 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_INTREN1_OFFSET,
261 0);
262 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_INTREN2_OFFSET,
263 0);
264
265 SD_US_DELAY(100);
266
267 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_INTREN1_OFFSET,
268 SD_NOR_INTERRUPTS | SD_ERR_INTERRUPTS);
269 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_INTREN2_OFFSET,
270 SD_NOR_INTERRUPTS | SD_ERR_INTERRUPTS);
271
272 /* Select SD bus voltage */
273 cap_val_l = mmio_read_32(handle->ctrl.sdRegBaseAddr +
274 SD4_EMMC_TOP_CAPABILITIES1_OFFSET);
275 handle->cfg.voltage = 0;
276 voltage = 0x7;
277
278 if (cap_val_l & SD4_EMMC_TOP_CAPABILITIES1_V33_MASK) {
279 handle->cfg.voltage |= SD_VDD_WINDOW_3_3_TO_3_4;
280 voltage = 0x7;
281 } else if (cap_val_l & SD4_EMMC_TOP_CAPABILITIES1_V3_MASK) {
282 handle->cfg.voltage |= SD_VDD_WINDOW_3_0_TO_3_1;
283 voltage = 0x6;
284 } else if (cap_val_l & SD4_EMMC_TOP_CAPABILITIES1_V18_MASK) {
285 handle->cfg.voltage |= SD_VDD_WINDOW_1_8_TO_1_9;
286 voltage = 0x5;
287 }
288
289 rval = chal_sd_set_power(handle, voltage, SD4_EMMC_TOP_CTRL_SDPWR_MASK);
290
291 ctl_val = mmio_read_32(handle->ctrl.sdRegBaseAddr +
292 SD4_EMMC_TOP_HCVERSIRQ_OFFSET);
293 handle->ctrl.version = ((ctl_val >> 16) & 0xFF);
294
295 return rval;
296}
297
298void chal_sd_set_speed(CHAL_HANDLE *sd_handle, uint32_t speed)
299{
300 struct sd_dev *handle;
301
302 if (sd_handle == NULL)
303 return;
304
305 handle = (struct sd_dev *) sd_handle;
306
307 if (speed) {
308 EMMC_TRACE("enable HighSpeed\n");
309 mmio_setbits_32(handle->ctrl.sdRegBaseAddr +
310 SD4_EMMC_TOP_CTRL_OFFSET,
311 SD4_EMMC_TOP_CTRL_HSEN_MASK);
312 } else {
313 EMMC_TRACE("disable HighSpeed\n");
314 mmio_clrbits_32(handle->ctrl.sdRegBaseAddr +
315 SD4_EMMC_TOP_CTRL_OFFSET,
316 SD4_EMMC_TOP_CTRL_HSEN_MASK);
317 }
318}
319
320int32_t chal_sd_stop(void)
321{
322 uintptr_t idm_rst_ctrl_addr = EMMC_IDM_RESET_CTRL_ADDR;
323
324 /* Configure IO pins */
325 emmc_soft_reset();
326
327 /* Reset the SDIO controller */
328 mmio_write_32(idm_rst_ctrl_addr, 1);
329 SD_US_DELAY(100);
330 mmio_write_32(idm_rst_ctrl_addr, 0);
331 SD_US_DELAY(100);
332
333 return SD_OK;
334}
335
336/*
337 * Check if host supports specified capability
338 * returns -ve val on error, 0 if capability not supported else 1.
339 */
340int32_t chal_sd_check_cap(CHAL_HANDLE *sd_handle, uint32_t caps)
341{
342 struct sd_dev *handle;
343
344 if (sd_handle == NULL)
345 return SD_INVALID_HANDLE;
346
347 handle = (struct sd_dev *) sd_handle;
348
349 if (caps & mmio_read_32(handle->ctrl.sdRegBaseAddr +
350 SD4_EMMC_TOP_CAPABILITIES1_OFFSET))
351 return 1;
352 else
353 return 0;
354}
355
356int32_t chal_sd_start(CHAL_HANDLE *sd_handle,
357 uint32_t mode, uint32_t sd_base, uint32_t host_base)
358{
359
360 struct sd_dev *handle;
361 int32_t rval = SD_FAIL;
362
363 if (sd_handle == NULL)
364 return SD_INVALID_HANDLE;
365
366 handle = (struct sd_dev *) sd_handle;
367
368 handle->cfg.mode = SD_PIO_MODE; /* set to PIO mode first for init */
369 handle->cfg.dma = SD_DMA_OFF;
370
371 chal_sd_setup_handler(handle, sd_base, host_base);
372
373 /* init and start hw */
374 rval = chal_sd_init(sd_handle);
375 if (rval != SD_OK)
376 return rval;
377
378 chal_sd_clear_pending_irq(sd_handle);
379
380 handle->ctrl.eventList = 0;
381 handle->cfg.mode = mode;
382
383 return SD_OK;
384}
385
386/*
387 * Function to check 8bits of err generated from auto CMD12
388 */
389int32_t chal_sd_get_atuo12_error(CHAL_HANDLE *sd_handle)
390{
391 struct sd_dev *handle;
392
393 if (sd_handle == NULL)
394 return SD_INVALID_HANDLE;
395
396 handle = (struct sd_dev *) sd_handle;
397
398 return (mmio_read_32(handle->ctrl.sdRegBaseAddr +
399 SD4_EMMC_TOP_ERRSTAT_OFFSET) & 0xFF);
400}
401
402/*
403 * Read present state register
404 */
405uint32_t chal_sd_get_present_status(CHAL_HANDLE *sd_handle)
406{
407 struct sd_dev *handle;
408
409 if (sd_handle == NULL)
410 return SD_INVALID_HANDLE;
411
412 handle = (struct sd_dev *) sd_handle;
413
414 return mmio_read_32(handle->ctrl.sdRegBaseAddr +
415 SD4_EMMC_TOP_PSTATE_OFFSET);
416}
417
418/*
419 * Set SD bus width
420 */
421int32_t chal_sd_config_bus_width(CHAL_HANDLE *sd_handle, int32_t width)
422{
423 uint32_t ctl_val;
424 struct sd_dev *handle;
425
426 if (sd_handle == NULL)
427 return SD_INVALID_HANDLE;
428
429 handle = (struct sd_dev *)sd_handle;
430
431 ctl_val = mmio_read_32(handle->ctrl.sdRegBaseAddr +
432 SD4_EMMC_TOP_CTRL_OFFSET);
433
434 switch (width) {
435#ifdef DRIVER_EMMC_ENABLE_DATA_WIDTH_8BIT
436 case SD_BUS_DATA_WIDTH_8BIT:
437 ctl_val &= ~SD_BUS_DATA_WIDTH_4BIT;
438 ctl_val |= SD_BUS_DATA_WIDTH_8BIT;
439 break;
440#endif
441 case SD_BUS_DATA_WIDTH_4BIT:
442 ctl_val &= ~SD_BUS_DATA_WIDTH_8BIT;
443 ctl_val |= SD_BUS_DATA_WIDTH_4BIT;
444 break;
445 case SD_BUS_DATA_WIDTH_1BIT:
446 ctl_val &= ~(SD_BUS_DATA_WIDTH_4BIT | SD_BUS_DATA_WIDTH_8BIT);
447 break;
448 default:
449 return SD_INV_DATA_WIDTH;
450 };
451
452 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CTRL_OFFSET,
453 ctl_val);
454
455 return SD_OK;
456}
457
458/*
459 * Function to enable or disable DMA control.
460 */
461int32_t chal_sd_set_dma(CHAL_HANDLE *sd_handle, uint32_t mode)
462{
463 uint32_t val;
464 struct sd_dev *handle;
465 int32_t rc;
466
467 if (sd_handle == NULL)
468 return SD_INVALID_HANDLE;
469
470 handle = (struct sd_dev *)sd_handle;
471
472 if (mode) {
473 rc = chal_sd_check_cap(sd_handle,
474 SD4_EMMC_TOP_CAPABILITIES1_SDMA_MASK |
475 SD4_EMMC_TOP_CAPABILITIES1_ADMA2_MASK);
476 if (rc < 0)
477 return rc;
478
479 if (rc) {
480
481 handle->cfg.dma = mode;
482 val = mmio_read_32(handle->ctrl.sdRegBaseAddr +
483 SD4_EMMC_TOP_CTRL_OFFSET);
484 val &= ~(SD4_EMMC_TOP_CTRL_DMASEL_MASK);
485 val |= handle->cfg.dma - 1;
486 mmio_write_32(handle->ctrl.sdRegBaseAddr +
487 SD4_EMMC_TOP_CTRL_OFFSET, val);
488 return SD_OK;
489 }
490 }
491 handle->cfg.dma = 0;
492
493 return SD_FAIL;
494}
495
496/*
497 * Get current DMA address.
498 * Called only when there is no data transaction activity.
499 */
500uintptr_t chal_sd_get_dma_addr(CHAL_HANDLE *sd_handle)
501{
502 struct sd_dev *handle;
503
504 if (sd_handle == NULL)
505 return SD_INVALID_HANDLE;
506
507 handle = (struct sd_dev *) sd_handle;
508
509 if (handle->cfg.dma == SD_DMA_OFF)
510 return 0;
511
512 return (uintptr_t)mmio_read_32(handle->ctrl.sdRegBaseAddr +
513 SD4_EMMC_TOP_SYSADDR_OFFSET);
514}
515
516int32_t chal_sd_send_cmd(CHAL_HANDLE *sd_handle, uint32_t cmd_idx,
517 uint32_t argument, uint32_t options)
518{
519 uint32_t cmd_mode_reg = 0;
520 struct sd_dev *handle;
521
522 if (sd_handle == NULL)
523 return SD_INVALID_HANDLE;
524
525 handle = (struct sd_dev *) sd_handle;
526
527 EMMC_TRACE("%s %d cmd:%d argReg:%x options:%x\n",
528 __func__, __LINE__, cmd_idx, argument, options);
529
530 /* Configure the value for command and mode registers */
531 cmd_mode_reg = (cmd_idx << 24) | options;
532
533 /*
534 * 1. Write block size reg & block count reg,
535 * this is done in the tx or rx setup
536 */
537 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_BLOCK_OFFSET,
538 handle->ctrl.blkReg);
539
540 /* 2. Write argument reg */
541 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_ARG_OFFSET,
542 argument);
543 handle->ctrl.argReg = argument;
544
545 /*
546 * 3. Write transfer mode reg & command reg, check the DMA bit which is
547 * set before this function call if it is selected.
548 */
549 if (cmd_idx == 24 || cmd_idx == 25 || cmd_idx == 18 || cmd_idx == 17 ||
550 cmd_idx == 42 || cmd_idx == 51 || cmd_idx == 53)
551 cmd_mode_reg |= ((handle->cfg.dma) ? 1 : 0);
552
553 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CMD_OFFSET,
554 cmd_mode_reg);
555
556 handle->ctrl.cmdIndex = cmd_idx;
557
558 return SD_OK;
559}
560
561int32_t chal_sd_set_dma_addr(CHAL_HANDLE *sd_handle, uintptr_t address)
562{
563 struct sd_dev *handle;
564
565 if (sd_handle == NULL)
566 return SD_INVALID_HANDLE;
567
568 handle = (struct sd_dev *) sd_handle;
569
570 if (handle->cfg.dma == SD_DMA_OFF)
571 return SD_FAIL;
572
573 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_SYSADDR_OFFSET,
574 address);
575 return SD_OK;
576}
577
578uint32_t chal_sd_freq_2_div_ctrl_setting(uint32_t desired_freq)
579{
580 /*
581 * Divider control setting represents 1/2 of the actual divider value.
582 *
583 * DesiredFreq = BaseClockFreq / (2 * div_ctrl_setting)
584 *
585 * ==> div_ctrl_setting = BaseClockFreq / (2 * DesiredFreq)
586 */
587 uint32_t div_ctrl_setting;
588 uint32_t actual_freq;
589
590 assert(desired_freq != 0);
591
592 /* Special case, 0 = divider of 1. */
593 if (desired_freq >= BASE_CLK_FREQ)
594 return 0;
595
596 /* Normal case, desired_freq < BASE_CLK_FREQ */
597 div_ctrl_setting = BASE_CLK_FREQ / (2 * desired_freq);
598
599 actual_freq = BASE_CLK_FREQ / (2 * div_ctrl_setting);
600
601 if (actual_freq > desired_freq) {
602 /*
603 * Division does not result in exact freqency match.
604 * Make sure resulting frequency does not exceed requested freq.
605 */
606 div_ctrl_setting++;
607 }
608
609 return div_ctrl_setting;
610}
611
612int32_t chal_sd_set_clock(CHAL_HANDLE *sd_handle, uint32_t div_ctrl_setting,
613 uint32_t on)
614{
615 uint32_t value;
616 struct sd_dev *handle;
617 uint32_t time;
618 uint32_t clk_sel_high_byte = 0xFF & (div_ctrl_setting >> 8);
619 uint32_t clk_sel_low_byte = 0xFF & div_ctrl_setting;
620
621 if (sd_handle == NULL)
622 return SD_INVALID_HANDLE;
623
624 EMMC_TRACE("set_clock(div_ctrl_setting=%d,on=%d)\n",
625 div_ctrl_setting, on);
626
627 handle = (struct sd_dev *) sd_handle;
628
629 /* Read control register content. */
630 value = mmio_read_32(handle->ctrl.sdRegBaseAddr +
631 SD4_EMMC_TOP_CTRL1_OFFSET);
632
633 /* Disable Clock */
634 value &= ~(SD4_EMMC_TOP_CTRL1_SDCLKEN_MASK);
635
636 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CTRL1_OFFSET,
637 value);
638
639 /* Clear bits of interest. */
640 value &= ~(SD4_EMMC_TOP_CTRL1_SDCLKSEL_MASK |
641 SD4_EMMC_TOP_CTRL1_SDCLKSEL_UP_MASK);
642
643 /* Set bits of interest to new value. */
644 value |= (SD4_EMMC_TOP_CTRL1_SDCLKSEL_MASK &
645 (clk_sel_low_byte << SD4_EMMC_TOP_CTRL1_SDCLKSEL_SHIFT));
646 value |= (SD4_EMMC_TOP_CTRL1_SDCLKSEL_UP_MASK &
647 (clk_sel_high_byte << SD4_EMMC_TOP_CTRL1_SDCLKSEL_UP_SHIFT));
648 value |= SD4_EMMC_TOP_CTRL1_ICLKEN_MASK;
649
650 /* Write updated value back to control register. */
651 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CTRL1_OFFSET,
652 value);
653
654 time = 0;
655 do {
656 value = mmio_read_32(handle->ctrl.sdRegBaseAddr +
657 SD4_EMMC_TOP_CTRL1_OFFSET);
658
659 if ((value & SD4_EMMC_TOP_CTRL1_ICLKSTB_MASK) ==
660 SD4_EMMC_TOP_CTRL1_ICLKSTB_MASK)
661 break;
662
663 mdelay(1);
664 } while (time++ < EMMC_CLOCK_SETTING_TIMEOUT_MS);
665
666 if (time >= EMMC_CLOCK_SETTING_TIMEOUT_MS)
667 WARN("%s %d clock settings timeout happenedi (%dms)\n",
668 __func__, __LINE__, time);
669
670 VERBOSE("EMMC: clock settings delay: %dms\n", time);
671
672 value = mmio_read_32(handle->ctrl.sdRegBaseAddr +
673 SD4_EMMC_TOP_CTRL1_OFFSET);
674
675 if (on)
676 value |= SD4_EMMC_TOP_CTRL1_SDCLKEN_MASK;
677
678 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CTRL1_OFFSET,
679 value);
680
681 return SD_OK;
682}
683
684/*
685 * function to setup DMA buffer and data length, calculates block
686 * size and the number of blocks to be transferred and return
687 * the DMA buffer address.
688 */
689int32_t chal_sd_setup_xfer(CHAL_HANDLE *sd_handle,
690 uint8_t *data, uint32_t length, int32_t dir)
691{
692 uint32_t blocks = 0;
693 struct sd_dev *handle;
694
695 if (sd_handle == NULL)
696 return SD_INVALID_HANDLE;
697
698 handle = (struct sd_dev *) sd_handle;
699
700 if (length <= handle->cfg.blockSize) {
701 handle->ctrl.blkReg = length | handle->cfg.dmaBoundary;
702 } else {
703 blocks = length / handle->cfg.blockSize;
704 handle->ctrl.blkReg = (blocks << 16) | handle->cfg.blockSize |
705 handle->cfg.dmaBoundary;
706 }
707
708 if (handle->cfg.dma != SD_DMA_OFF) {
709 /* For DMA target address setting, physical address should be used */
710 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_SYSADDR_OFFSET,
711 (uintptr_t)data);
712 }
713
714 return SD_OK;
715}
716
717#ifdef INCLUDE_EMMC_DRIVER_WRITE_CODE
718/*
719 * function to write one block data directly to the
720 * host controller's FIFO which is 1K uint8_t or
721 * 2K uint8_t in size.
722 * It is used in Non-DMA mode for data transmission.
723 */
724int32_t chal_sd_write_buffer(CHAL_HANDLE *sd_handle, uint32_t length,
725 uint8_t *data)
726{
727 uint32_t i, leftOver = 0, blockSize, size, value = 0;
728 struct sd_dev *handle;
729
730 if (sd_handle == NULL)
731 return SD_INVALID_HANDLE;
732
733 handle = (struct sd_dev *) sd_handle;
734
735 blockSize = handle->cfg.blockSize;
736
737 if (length == 0)
738 return SD_OK;
739
740 /* PIO mode, push into fifo word by word */
741 if (length >= blockSize) {
742 size = blockSize;
743 } else {
744 size = ((length >> 2) << 2);
745 leftOver = length % 4;
746 }
747
748 for (i = 0; i < size; i += 4) {
749 value = *(uint32_t *)(data + i);
750 mmio_write_32(handle->ctrl.sdRegBaseAddr +
751 SD4_EMMC_TOP_BUFDAT_OFFSET, value);
752 }
753/*
754 * BUG ALERT:
755 * This implementation has TWO issues that must be addressed before you
756 * can safely INCLUDE_EMMC_DRIVER_WRITE_CODE.
757 *
758 * (1) For the last leftOver bytes, driver writes full word, which means
759 * some of the eMMC content (i.e. "4 - leftOver" will be erroneously
760 * overwritten).
761 * (2) eMMC is a block device. What happens when less than a full block of
762 * data is submitted???
763 */
764 if (leftOver > 0) {
765 value = ((*(uint32_t *)(data + i)) << (4 - leftOver));
766 mmio_write_32(handle->ctrl.sdRegBaseAddr +
767 SD4_EMMC_TOP_BUFDAT_OFFSET, value);
768 }
769
770 return SD_OK;
771}
772#endif /* INCLUDE_EMMC_DRIVER_WRITE_CODE */
773
774/*
775 * Function to read maximal one block data directly
776 * from the data port of the host controller (FIFO). It is used
777 * in Non-DMA mode for data transmission.
778 */
779int32_t chal_sd_read_buffer(CHAL_HANDLE *sd_handle, uint32_t length,
780 uint8_t *data)
781{
782 uint32_t i, size, leftOver, blockSize, value;
783 struct sd_dev *handle;
784
785 if (sd_handle == NULL)
786 return SD_INVALID_HANDLE;
787
788 handle = (struct sd_dev *)sd_handle;
789
790 value = 0;
791
792 blockSize = handle->cfg.blockSize;
793
794 /* PIO mode, extract fifo word by word */
795 if (length >= blockSize) {
796 size = blockSize;
797 leftOver = 0;
798 } else {
799 leftOver = length % 4;
800 size = ((length >> 2) << 2);
801 }
802
803 for (i = 0; i < size; i += 4) {
804 value =
805 mmio_read_32(handle->ctrl.sdRegBaseAddr +
806 SD4_EMMC_TOP_BUFDAT_OFFSET);
807 memcpy((void *)(data + i), &value, sizeof(uint32_t));
808 }
809
810 if (leftOver > 0) {
811 value = mmio_read_32(handle->ctrl.sdRegBaseAddr +
812 SD4_EMMC_TOP_BUFDAT_OFFSET);
813
814 /*
815 * Copy remaining non-full word bytes.
816 * (We run ARM as Little Endian)
817 */
818 uint8_t j = 0;
819
820 for (j = 0; j < leftOver; j++) {
821 data[i + j] = (value >> (j * 8)) & 0xFF;
822 }
823 }
824
825 return SD_OK;
826}
827
828/*
829 * Resets both DAT or CMD line.
830 */
831int32_t chal_sd_reset_line(CHAL_HANDLE *sd_handle, uint32_t line)
832{
833 uint32_t control, flag;
834 struct sd_dev *handle;
835
836 if (sd_handle == NULL)
837 return SD_INVALID_HANDLE;
838
839 handle = (struct sd_dev *) sd_handle;
840
841 flag = SD4_EMMC_TOP_CTRL1_CMDRST_MASK | SD4_EMMC_TOP_CTRL1_DATRST_MASK;
842
843 if (flag != (line | flag))
844 return SD_FAIL;
845
846 control = mmio_read_32(handle->ctrl.sdRegBaseAddr +
847 SD4_EMMC_TOP_CTRL1_OFFSET);
848 control |= line;
849 mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CTRL1_OFFSET,
850 control);
851
852 /* reset CMD and DATA line should always work, no need to timed out */
853 do {
854 control = mmio_read_32(handle->ctrl.sdRegBaseAddr +
855 SD4_EMMC_TOP_CTRL1_OFFSET);
856 } while (control & line);
857
858 return SD_OK;
859}
860
861/*
862 * Function to be called once a SD command is done to read
863 * back it's response data.
864 */
865int32_t chal_sd_get_response(CHAL_HANDLE *sd_handle, uint32_t *resp)
866{
867 struct sd_dev *handle;
868
869 if (sd_handle == NULL)
870 return SD_INVALID_HANDLE;
871
872 handle = (struct sd_dev *) sd_handle;
873 resp[0] = mmio_read_32(handle->ctrl.sdRegBaseAddr +
874 SD4_EMMC_TOP_RESP0_OFFSET);
875 resp[1] = mmio_read_32(handle->ctrl.sdRegBaseAddr +
876 SD4_EMMC_TOP_RESP2_OFFSET);
877 resp[2] = mmio_read_32(handle->ctrl.sdRegBaseAddr +
878 SD4_EMMC_TOP_RESP4_OFFSET);
879 resp[3] = mmio_read_32(handle->ctrl.sdRegBaseAddr +
880 SD4_EMMC_TOP_RESP6_OFFSET);
881
882 return SD_OK;
883}
884
885/*
886 * The function is called to clean all the pending interrupts.
887 */
888int32_t chal_sd_clear_pending_irq(CHAL_HANDLE *sd_handle)
889{
890 uint32_t status = SD_OK;
891 struct sd_dev *handle;
892
893 if (sd_handle == NULL)
894 return SD_INVALID_HANDLE;
895
896 handle = (struct sd_dev *)sd_handle;
897
898 /* Make sure clean all interrupts */
899 do {
900 mmio_write_32(handle->ctrl.sdRegBaseAddr +
901 SD4_EMMC_TOP_INTR_OFFSET, 0xFFFFFFFF);
902 SD_US_DELAY(10);
903 } while (mmio_read_32(handle->ctrl.sdRegBaseAddr +
904 SD4_EMMC_TOP_INTR_OFFSET));
905
906 return status;
907}
908
909/*
910 * The function returns interrupt status register value.
911 */
912int32_t chal_sd_get_irq_status(CHAL_HANDLE *sd_handle)
913{
914 struct sd_dev *handle;
915
916 if (sd_handle == NULL)
917 return SD_INVALID_HANDLE;
918
919 handle = (struct sd_dev *) sd_handle;
920
921 return (mmio_read_32(handle->ctrl.sdRegBaseAddr +
922 SD4_EMMC_TOP_INTR_OFFSET));
923}
924
925/*
926 * The function clears interrupt(s) specified in the mask.
927 */
928int32_t chal_sd_clear_irq(CHAL_HANDLE *sd_handle, uint32_t mask)
929{
930 struct sd_dev *handle;
931
932 if (sd_handle == NULL)
933 return SD_INVALID_HANDLE;
934
935 handle = (struct sd_dev *) sd_handle;
936
937 /* Make sure clean masked interrupts */
938 do {
939 mmio_write_32(handle->ctrl.sdRegBaseAddr +
940 SD4_EMMC_TOP_INTR_OFFSET, mask);
941 SD_US_DELAY(10);
942 } while (mask &
943 mmio_read_32(handle->ctrl.sdRegBaseAddr +
944 SD4_EMMC_TOP_INTR_OFFSET));
945
946 return SD_OK;
947}
948
949/*
950 * Description: The function configures the SD host controller.
951 */
952int32_t chal_sd_config(CHAL_HANDLE *sd_handle, uint32_t speed, uint32_t retry,
953 uint32_t boundary, uint32_t blkSize, uint32_t dma)
954{
955 struct sd_dev *handle;
956
957 if (sd_handle == NULL)
958 return SD_INVALID_HANDLE;
959
960 handle = (struct sd_dev *) sd_handle;
961
962 handle->cfg.speedMode = speed;
963 handle->cfg.retryLimit = retry;
964 handle->cfg.dmaBoundary = boundary;
965 handle->cfg.blockSize = blkSize;
966
967 chal_sd_set_dma(sd_handle, dma);
968 SD_US_DELAY(100);
969 chal_sd_set_dma_boundary(handle, boundary);
970 SD_US_DELAY(100);
971
972 chal_sd_set_speed(sd_handle, speed);
973
974 SD_US_DELAY(100);
975 return SD_OK;
976}
977
978/*
979 * Cleans up HC FIFO.
980 */
981void chal_sd_dump_fifo(CHAL_HANDLE *sd_handle)
982{
983 struct sd_dev *handle;
984
985 if (sd_handle == NULL)
986 return;
987
988 handle = (struct sd_dev *)sd_handle;
989
990 /* in case there still data in the host buffer */
991 while (mmio_read_32(handle->ctrl.sdRegBaseAddr +
992 SD4_EMMC_TOP_PSTATE_OFFSET) & 0x800) {
993 mmio_read_32(handle->ctrl.sdRegBaseAddr +
994 SD4_EMMC_TOP_BUFDAT_OFFSET);
995 };
996}
997
998/*
999 * Enable or disable a SD interrupt signal.
1000 */
1001void chal_sd_set_irq_signal(CHAL_HANDLE *sd_handle, uint32_t mask,
1002 uint32_t state)
1003{
1004 struct sd_dev *handle;
1005
1006 if (sd_handle == NULL)
1007 return;
1008
1009 handle = (struct sd_dev *)sd_handle;
1010
1011 if (state)
1012 mmio_setbits_32(handle->ctrl.sdRegBaseAddr +
1013 SD4_EMMC_TOP_INTREN2_OFFSET, mask);
1014 else
1015 mmio_clrbits_32(handle->ctrl.sdRegBaseAddr +
1016 SD4_EMMC_TOP_INTREN2_OFFSET, mask);
1017}