1 // SPDX-License-Identifier: GPL-2.0+
2 /*
3 *
4 * Clock initialization for OMAP4
5 *
6 * (C) Copyright 2010
7 * Texas Instruments, <www.ti.com>
8 *
9 * Aneesh V <aneesh@ti.com>
10 *
11 * Based on previous work by:
12 * Santosh Shilimkar <santosh.shilimkar@ti.com>
13 * Rajendra Nayak <rnayak@ti.com>
14 */
15 #include <common.h>
16 #include <i2c.h>
17 #include <asm/omap_common.h>
18 #include <asm/gpio.h>
19 #include <asm/arch/clock.h>
20 #include <asm/arch/sys_proto.h>
21 #include <asm/utils.h>
22 #include <asm/omap_gpio.h>
23 #include <asm/emif.h>
24
25 #ifndef CONFIG_SPL_BUILD
26 /*
27 * printing to console doesn't work unless
28 * this code is executed from SPL
29 */
30 #define printf(fmt, args...)
31 #define puts(s)
32 #endif
33
34 const u32 sys_clk_array[8] = {
35 12000000, /* 12 MHz */
36 20000000, /* 20 MHz */
37 16800000, /* 16.8 MHz */
38 19200000, /* 19.2 MHz */
39 26000000, /* 26 MHz */
40 27000000, /* 27 MHz */
41 38400000, /* 38.4 MHz */
42 };
43
__get_sys_clk_index(void)44 static inline u32 __get_sys_clk_index(void)
45 {
46 s8 ind;
47 /*
48 * For ES1 the ROM code calibration of sys clock is not reliable
49 * due to hw issue. So, use hard-coded value. If this value is not
50 * correct for any board over-ride this function in board file
51 * From ES2.0 onwards you will get this information from
52 * CM_SYS_CLKSEL
53 */
54 if (omap_revision() == OMAP4430_ES1_0)
55 ind = OMAP_SYS_CLK_IND_38_4_MHZ;
56 else {
57 /* SYS_CLKSEL - 1 to match the dpll param array indices */
58 ind = (readl((*prcm)->cm_sys_clksel) &
59 CM_SYS_CLKSEL_SYS_CLKSEL_MASK) - 1;
60 }
61 return ind;
62 }
63
64 u32 get_sys_clk_index(void)
65 __attribute__ ((weak, alias("__get_sys_clk_index")));
66
get_sys_clk_freq(void)67 u32 get_sys_clk_freq(void)
68 {
69 u8 index = get_sys_clk_index();
70 return sys_clk_array[index];
71 }
72
setup_post_dividers(u32 const base,const struct dpll_params * params)73 void setup_post_dividers(u32 const base, const struct dpll_params *params)
74 {
75 struct dpll_regs *const dpll_regs = (struct dpll_regs *)base;
76
77 /* Setup post-dividers */
78 if (params->m2 >= 0)
79 writel(params->m2, &dpll_regs->cm_div_m2_dpll);
80 if (params->m3 >= 0)
81 writel(params->m3, &dpll_regs->cm_div_m3_dpll);
82 if (params->m4_h11 >= 0)
83 writel(params->m4_h11, &dpll_regs->cm_div_m4_h11_dpll);
84 if (params->m5_h12 >= 0)
85 writel(params->m5_h12, &dpll_regs->cm_div_m5_h12_dpll);
86 if (params->m6_h13 >= 0)
87 writel(params->m6_h13, &dpll_regs->cm_div_m6_h13_dpll);
88 if (params->m7_h14 >= 0)
89 writel(params->m7_h14, &dpll_regs->cm_div_m7_h14_dpll);
90 if (params->h21 >= 0)
91 writel(params->h21, &dpll_regs->cm_div_h21_dpll);
92 if (params->h22 >= 0)
93 writel(params->h22, &dpll_regs->cm_div_h22_dpll);
94 if (params->h23 >= 0)
95 writel(params->h23, &dpll_regs->cm_div_h23_dpll);
96 if (params->h24 >= 0)
97 writel(params->h24, &dpll_regs->cm_div_h24_dpll);
98 }
99
do_bypass_dpll(u32 const base)100 static inline void do_bypass_dpll(u32 const base)
101 {
102 struct dpll_regs *dpll_regs = (struct dpll_regs *)base;
103
104 clrsetbits_le32(&dpll_regs->cm_clkmode_dpll,
105 CM_CLKMODE_DPLL_DPLL_EN_MASK,
106 DPLL_EN_FAST_RELOCK_BYPASS <<
107 CM_CLKMODE_DPLL_EN_SHIFT);
108 }
109
wait_for_bypass(u32 const base)110 static inline void wait_for_bypass(u32 const base)
111 {
112 struct dpll_regs *const dpll_regs = (struct dpll_regs *)base;
113
114 if (!wait_on_value(ST_DPLL_CLK_MASK, 0, &dpll_regs->cm_idlest_dpll,
115 LDELAY)) {
116 printf("Bypassing DPLL failed %x\n", base);
117 }
118 }
119
do_lock_dpll(u32 const base)120 static inline void do_lock_dpll(u32 const base)
121 {
122 struct dpll_regs *const dpll_regs = (struct dpll_regs *)base;
123
124 clrsetbits_le32(&dpll_regs->cm_clkmode_dpll,
125 CM_CLKMODE_DPLL_DPLL_EN_MASK,
126 DPLL_EN_LOCK << CM_CLKMODE_DPLL_EN_SHIFT);
127 }
128
wait_for_lock(u32 const base)129 static inline void wait_for_lock(u32 const base)
130 {
131 struct dpll_regs *const dpll_regs = (struct dpll_regs *)base;
132
133 if (!wait_on_value(ST_DPLL_CLK_MASK, ST_DPLL_CLK_MASK,
134 &dpll_regs->cm_idlest_dpll, LDELAY)) {
135 printf("DPLL locking failed for %x\n", base);
136 hang();
137 }
138 }
139
check_for_lock(u32 const base)140 inline u32 check_for_lock(u32 const base)
141 {
142 struct dpll_regs *const dpll_regs = (struct dpll_regs *)base;
143 u32 lock = readl(&dpll_regs->cm_idlest_dpll) & ST_DPLL_CLK_MASK;
144
145 return lock;
146 }
147
get_mpu_dpll_params(struct dplls const * dpll_data)148 const struct dpll_params *get_mpu_dpll_params(struct dplls const *dpll_data)
149 {
150 u32 sysclk_ind = get_sys_clk_index();
151 return &dpll_data->mpu[sysclk_ind];
152 }
153
get_core_dpll_params(struct dplls const * dpll_data)154 const struct dpll_params *get_core_dpll_params(struct dplls const *dpll_data)
155 {
156 u32 sysclk_ind = get_sys_clk_index();
157 return &dpll_data->core[sysclk_ind];
158 }
159
get_per_dpll_params(struct dplls const * dpll_data)160 const struct dpll_params *get_per_dpll_params(struct dplls const *dpll_data)
161 {
162 u32 sysclk_ind = get_sys_clk_index();
163 return &dpll_data->per[sysclk_ind];
164 }
165
get_iva_dpll_params(struct dplls const * dpll_data)166 const struct dpll_params *get_iva_dpll_params(struct dplls const *dpll_data)
167 {
168 u32 sysclk_ind = get_sys_clk_index();
169 return &dpll_data->iva[sysclk_ind];
170 }
171
get_usb_dpll_params(struct dplls const * dpll_data)172 const struct dpll_params *get_usb_dpll_params(struct dplls const *dpll_data)
173 {
174 u32 sysclk_ind = get_sys_clk_index();
175 return &dpll_data->usb[sysclk_ind];
176 }
177
get_abe_dpll_params(struct dplls const * dpll_data)178 const struct dpll_params *get_abe_dpll_params(struct dplls const *dpll_data)
179 {
180 #ifdef CONFIG_SYS_OMAP_ABE_SYSCK
181 u32 sysclk_ind = get_sys_clk_index();
182 return &dpll_data->abe[sysclk_ind];
183 #else
184 return dpll_data->abe;
185 #endif
186 }
187
get_ddr_dpll_params(struct dplls const * dpll_data)188 static const struct dpll_params *get_ddr_dpll_params
189 (struct dplls const *dpll_data)
190 {
191 u32 sysclk_ind = get_sys_clk_index();
192
193 if (!dpll_data->ddr)
194 return NULL;
195 return &dpll_data->ddr[sysclk_ind];
196 }
197
198 #ifdef CONFIG_DRIVER_TI_CPSW
get_gmac_dpll_params(struct dplls const * dpll_data)199 static const struct dpll_params *get_gmac_dpll_params
200 (struct dplls const *dpll_data)
201 {
202 u32 sysclk_ind = get_sys_clk_index();
203
204 if (!dpll_data->gmac)
205 return NULL;
206 return &dpll_data->gmac[sysclk_ind];
207 }
208 #endif
209
do_setup_dpll(u32 const base,const struct dpll_params * params,u8 lock,char * dpll)210 static void do_setup_dpll(u32 const base, const struct dpll_params *params,
211 u8 lock, char *dpll)
212 {
213 u32 temp, M, N;
214 struct dpll_regs *const dpll_regs = (struct dpll_regs *)base;
215
216 if (!params)
217 return;
218
219 temp = readl(&dpll_regs->cm_clksel_dpll);
220
221 if (check_for_lock(base)) {
222 /*
223 * The Dpll has already been locked by rom code using CH.
224 * Check if M,N are matching with Ideal nominal opp values.
225 * If matches, skip the rest otherwise relock.
226 */
227 M = (temp & CM_CLKSEL_DPLL_M_MASK) >> CM_CLKSEL_DPLL_M_SHIFT;
228 N = (temp & CM_CLKSEL_DPLL_N_MASK) >> CM_CLKSEL_DPLL_N_SHIFT;
229 if ((M != (params->m)) || (N != (params->n))) {
230 debug("\n %s Dpll locked, but not for ideal M = %d,"
231 "N = %d values, current values are M = %d,"
232 "N= %d" , dpll, params->m, params->n,
233 M, N);
234 } else {
235 /* Dpll locked with ideal values for nominal opps. */
236 debug("\n %s Dpll already locked with ideal"
237 "nominal opp values", dpll);
238
239 bypass_dpll(base);
240 goto setup_post_dividers;
241 }
242 }
243
244 bypass_dpll(base);
245
246 /* Set M & N */
247 temp &= ~CM_CLKSEL_DPLL_M_MASK;
248 temp |= (params->m << CM_CLKSEL_DPLL_M_SHIFT) & CM_CLKSEL_DPLL_M_MASK;
249
250 temp &= ~CM_CLKSEL_DPLL_N_MASK;
251 temp |= (params->n << CM_CLKSEL_DPLL_N_SHIFT) & CM_CLKSEL_DPLL_N_MASK;
252
253 writel(temp, &dpll_regs->cm_clksel_dpll);
254
255 setup_post_dividers:
256 setup_post_dividers(base, params);
257
258 /* Lock */
259 if (lock)
260 do_lock_dpll(base);
261
262 /* Wait till the DPLL locks */
263 if (lock)
264 wait_for_lock(base);
265 }
266
omap_ddr_clk(void)267 u32 omap_ddr_clk(void)
268 {
269 u32 ddr_clk, sys_clk_khz, omap_rev, divider;
270 const struct dpll_params *core_dpll_params;
271
272 omap_rev = omap_revision();
273 sys_clk_khz = get_sys_clk_freq() / 1000;
274
275 core_dpll_params = get_core_dpll_params(*dplls_data);
276
277 debug("sys_clk %d\n ", sys_clk_khz * 1000);
278
279 /* Find Core DPLL locked frequency first */
280 ddr_clk = sys_clk_khz * 2 * core_dpll_params->m /
281 (core_dpll_params->n + 1);
282
283 if (omap_rev < OMAP5430_ES1_0) {
284 /*
285 * DDR frequency is PHY_ROOT_CLK/2
286 * PHY_ROOT_CLK = Fdpll/2/M2
287 */
288 divider = 4;
289 } else {
290 /*
291 * DDR frequency is PHY_ROOT_CLK
292 * PHY_ROOT_CLK = Fdpll/2/M2
293 */
294 divider = 2;
295 }
296
297 ddr_clk = ddr_clk / divider / core_dpll_params->m2;
298 ddr_clk *= 1000; /* convert to Hz */
299 debug("ddr_clk %d\n ", ddr_clk);
300
301 return ddr_clk;
302 }
303
304 /*
305 * Lock MPU dpll
306 *
307 * Resulting MPU frequencies:
308 * 4430 ES1.0 : 600 MHz
309 * 4430 ES2.x : 792 MHz (OPP Turbo)
310 * 4460 : 920 MHz (OPP Turbo) - DCC disabled
311 */
configure_mpu_dpll(void)312 void configure_mpu_dpll(void)
313 {
314 const struct dpll_params *params;
315 struct dpll_regs *mpu_dpll_regs;
316 u32 omap_rev;
317 omap_rev = omap_revision();
318
319 /*
320 * DCC and clock divider settings for 4460.
321 * DCC is required, if more than a certain frequency is required.
322 * For, 4460 > 1GHZ.
323 * 5430 > 1.4GHZ.
324 */
325 if ((omap_rev >= OMAP4460_ES1_0) && (omap_rev < OMAP5430_ES1_0)) {
326 mpu_dpll_regs =
327 (struct dpll_regs *)((*prcm)->cm_clkmode_dpll_mpu);
328 bypass_dpll((*prcm)->cm_clkmode_dpll_mpu);
329 clrbits_le32((*prcm)->cm_mpu_mpu_clkctrl,
330 MPU_CLKCTRL_CLKSEL_EMIF_DIV_MODE_MASK);
331 setbits_le32((*prcm)->cm_mpu_mpu_clkctrl,
332 MPU_CLKCTRL_CLKSEL_ABE_DIV_MODE_MASK);
333 clrbits_le32(&mpu_dpll_regs->cm_clksel_dpll,
334 CM_CLKSEL_DCC_EN_MASK);
335 }
336
337 params = get_mpu_dpll_params(*dplls_data);
338
339 do_setup_dpll((*prcm)->cm_clkmode_dpll_mpu, params, DPLL_LOCK, "mpu");
340 debug("MPU DPLL locked\n");
341 }
342
343 #if defined(CONFIG_USB_EHCI_OMAP) || defined(CONFIG_USB_XHCI_OMAP) || \
344 defined(CONFIG_USB_MUSB_OMAP2PLUS)
setup_usb_dpll(void)345 static void setup_usb_dpll(void)
346 {
347 const struct dpll_params *params;
348 u32 sys_clk_khz, sd_div, num, den;
349
350 sys_clk_khz = get_sys_clk_freq() / 1000;
351 /*
352 * USB:
353 * USB dpll is J-type. Need to set DPLL_SD_DIV for jitter correction
354 * DPLL_SD_DIV = CEILING ([DPLL_MULT/(DPLL_DIV+1)]* CLKINP / 250)
355 * - where CLKINP is sys_clk in MHz
356 * Use CLKINP in KHz and adjust the denominator accordingly so
357 * that we have enough accuracy and at the same time no overflow
358 */
359 params = get_usb_dpll_params(*dplls_data);
360 num = params->m * sys_clk_khz;
361 den = (params->n + 1) * 250 * 1000;
362 num += den - 1;
363 sd_div = num / den;
364 clrsetbits_le32((*prcm)->cm_clksel_dpll_usb,
365 CM_CLKSEL_DPLL_DPLL_SD_DIV_MASK,
366 sd_div << CM_CLKSEL_DPLL_DPLL_SD_DIV_SHIFT);
367
368 /* Now setup the dpll with the regular function */
369 do_setup_dpll((*prcm)->cm_clkmode_dpll_usb, params, DPLL_LOCK, "usb");
370 }
371 #endif
372
setup_dplls(void)373 static void setup_dplls(void)
374 {
375 u32 temp;
376 const struct dpll_params *params;
377 struct emif_reg_struct *emif = (struct emif_reg_struct *)EMIF1_BASE;
378
379 debug("setup_dplls\n");
380
381 /* CORE dpll */
382 params = get_core_dpll_params(*dplls_data); /* default - safest */
383 /*
384 * Do not lock the core DPLL now. Just set it up.
385 * Core DPLL will be locked after setting up EMIF
386 * using the FREQ_UPDATE method(freq_update_core())
387 */
388 if (emif_sdram_type(readl(&emif->emif_sdram_config)) ==
389 EMIF_SDRAM_TYPE_LPDDR2)
390 do_setup_dpll((*prcm)->cm_clkmode_dpll_core, params,
391 DPLL_NO_LOCK, "core");
392 else
393 do_setup_dpll((*prcm)->cm_clkmode_dpll_core, params,
394 DPLL_LOCK, "core");
395 /* Set the ratios for CORE_CLK, L3_CLK, L4_CLK */
396 temp = (CLKSEL_CORE_X2_DIV_1 << CLKSEL_CORE_SHIFT) |
397 (CLKSEL_L3_CORE_DIV_2 << CLKSEL_L3_SHIFT) |
398 (CLKSEL_L4_L3_DIV_2 << CLKSEL_L4_SHIFT);
399 writel(temp, (*prcm)->cm_clksel_core);
400 debug("Core DPLL configured\n");
401
402 /* lock PER dpll */
403 params = get_per_dpll_params(*dplls_data);
404 do_setup_dpll((*prcm)->cm_clkmode_dpll_per,
405 params, DPLL_LOCK, "per");
406 debug("PER DPLL locked\n");
407
408 /* MPU dpll */
409 configure_mpu_dpll();
410
411 #if defined(CONFIG_USB_EHCI_OMAP) || defined(CONFIG_USB_XHCI_OMAP) || \
412 defined(CONFIG_USB_MUSB_OMAP2PLUS)
413 setup_usb_dpll();
414 #endif
415 params = get_ddr_dpll_params(*dplls_data);
416 do_setup_dpll((*prcm)->cm_clkmode_dpll_ddrphy,
417 params, DPLL_LOCK, "ddr");
418
419 #ifdef CONFIG_DRIVER_TI_CPSW
420 params = get_gmac_dpll_params(*dplls_data);
421 do_setup_dpll((*prcm)->cm_clkmode_dpll_gmac, params,
422 DPLL_LOCK, "gmac");
423 #endif
424 }
425
get_offset_code(u32 volt_offset,struct pmic_data * pmic)426 u32 get_offset_code(u32 volt_offset, struct pmic_data *pmic)
427 {
428 u32 offset_code;
429
430 volt_offset -= pmic->base_offset;
431
432 offset_code = (volt_offset + pmic->step - 1) / pmic->step;
433
434 /*
435 * Offset codes 1-6 all give the base voltage in Palmas
436 * Offset code 0 switches OFF the SMPS
437 */
438 return offset_code + pmic->start_code;
439 }
440
do_scale_vcore(u32 vcore_reg,u32 volt_mv,struct pmic_data * pmic)441 void do_scale_vcore(u32 vcore_reg, u32 volt_mv, struct pmic_data *pmic)
442 {
443 u32 offset_code;
444 u32 offset = volt_mv;
445 int ret = 0;
446
447 if (!volt_mv)
448 return;
449
450 pmic->pmic_bus_init();
451 /* See if we can first get the GPIO if needed */
452 if (pmic->gpio_en)
453 ret = gpio_request(pmic->gpio, "PMIC_GPIO");
454
455 if (ret < 0) {
456 printf("%s: gpio %d request failed %d\n", __func__,
457 pmic->gpio, ret);
458 return;
459 }
460
461 /* Pull the GPIO low to select SET0 register, while we program SET1 */
462 if (pmic->gpio_en)
463 gpio_direction_output(pmic->gpio, 0);
464
465 /* convert to uV for better accuracy in the calculations */
466 offset *= 1000;
467
468 offset_code = get_offset_code(offset, pmic);
469
470 debug("do_scale_vcore: volt - %d offset_code - 0x%x\n", volt_mv,
471 offset_code);
472
473 if (pmic->pmic_write(pmic->i2c_slave_addr, vcore_reg, offset_code))
474 printf("Scaling voltage failed for 0x%x\n", vcore_reg);
475 if (pmic->gpio_en)
476 gpio_direction_output(pmic->gpio, 1);
477 }
478
get_voltrail_opp(int rail_offset)479 int __weak get_voltrail_opp(int rail_offset)
480 {
481 /*
482 * By default return OPP_NOM for all voltage rails.
483 */
484 return OPP_NOM;
485 }
486
optimize_vcore_voltage(struct volts const * v,int opp)487 static u32 optimize_vcore_voltage(struct volts const *v, int opp)
488 {
489 u32 val;
490
491 if (!v->value[opp])
492 return 0;
493 if (!v->efuse.reg[opp])
494 return v->value[opp];
495
496 switch (v->efuse.reg_bits) {
497 case 16:
498 val = readw(v->efuse.reg[opp]);
499 break;
500 case 32:
501 val = readl(v->efuse.reg[opp]);
502 break;
503 default:
504 printf("Error: efuse 0x%08x bits=%d unknown\n",
505 v->efuse.reg[opp], v->efuse.reg_bits);
506 return v->value[opp];
507 }
508
509 if (!val) {
510 printf("Error: efuse 0x%08x bits=%d val=0, using %d\n",
511 v->efuse.reg[opp], v->efuse.reg_bits, v->value[opp]);
512 return v->value[opp];
513 }
514
515 debug("%s:efuse 0x%08x bits=%d Vnom=%d, using efuse value %d\n",
516 __func__, v->efuse.reg[opp], v->efuse.reg_bits, v->value[opp],
517 val);
518 return val;
519 }
520
521 #ifdef CONFIG_IODELAY_RECALIBRATION
recalibrate_iodelay(void)522 void __weak recalibrate_iodelay(void)
523 {
524 }
525 #endif
526
527 /*
528 * Setup the voltages for the main SoC core power domains.
529 * We start with the maximum voltages allowed here, as set in the corresponding
530 * vcores_data struct, and then scale (usually down) to the fused values that
531 * are retrieved from the SoC. The scaling happens only if the efuse.reg fields
532 * are initialised.
533 * Rail grouping is supported for the DRA7xx SoCs only, therefore the code is
534 * compiled conditionally. Note that the new code writes the scaled (or zeroed)
535 * values back to the vcores_data struct for eventual reuse. Zero values mean
536 * that the corresponding rails are not controlled separately, and are not sent
537 * to the PMIC.
538 */
scale_vcores(struct vcores_data const * vcores)539 void scale_vcores(struct vcores_data const *vcores)
540 {
541 int i, opp, j, ol;
542 struct volts *pv = (struct volts *)vcores;
543 struct volts *px;
544
545 for (i=0; i<(sizeof(struct vcores_data)/sizeof(struct volts)); i++) {
546 opp = get_voltrail_opp(i);
547 debug("%d -> ", pv->value[opp]);
548
549 if (pv->value[opp]) {
550 /* Handle non-empty members only */
551 pv->value[opp] = optimize_vcore_voltage(pv, opp);
552 px = (struct volts *)vcores;
553 j = 0;
554 while (px < pv) {
555 /*
556 * Scan already handled non-empty members to see
557 * if we have a group and find the max voltage,
558 * which is set to the first occurance of the
559 * particular SMPS; the other group voltages are
560 * zeroed.
561 */
562 ol = get_voltrail_opp(j);
563 if (px->value[ol] &&
564 (pv->pmic->i2c_slave_addr ==
565 px->pmic->i2c_slave_addr) &&
566 (pv->addr == px->addr)) {
567 /* Same PMIC, same SMPS */
568 if (pv->value[opp] > px->value[ol])
569 px->value[ol] = pv->value[opp];
570
571 pv->value[opp] = 0;
572 }
573 px++;
574 j++;
575 }
576 }
577 debug("%d\n", pv->value[opp]);
578 pv++;
579 }
580
581 opp = get_voltrail_opp(VOLT_CORE);
582 debug("cor: %d\n", vcores->core.value[opp]);
583 do_scale_vcore(vcores->core.addr, vcores->core.value[opp],
584 vcores->core.pmic);
585 /*
586 * IO delay recalibration should be done immediately after
587 * adjusting AVS voltages for VDD_CORE_L.
588 * Respective boards should call __recalibrate_iodelay()
589 * with proper mux, virtual and manual mode configurations.
590 */
591 #ifdef CONFIG_IODELAY_RECALIBRATION
592 recalibrate_iodelay();
593 #endif
594
595 opp = get_voltrail_opp(VOLT_MPU);
596 debug("mpu: %d\n", vcores->mpu.value[opp]);
597 do_scale_vcore(vcores->mpu.addr, vcores->mpu.value[opp],
598 vcores->mpu.pmic);
599 /* Configure MPU ABB LDO after scale */
600 abb_setup(vcores->mpu.efuse.reg[opp],
601 (*ctrl)->control_wkup_ldovbb_mpu_voltage_ctrl,
602 (*prcm)->prm_abbldo_mpu_setup,
603 (*prcm)->prm_abbldo_mpu_ctrl,
604 (*prcm)->prm_irqstatus_mpu_2,
605 vcores->mpu.abb_tx_done_mask,
606 OMAP_ABB_FAST_OPP);
607
608 opp = get_voltrail_opp(VOLT_MM);
609 debug("mm: %d\n", vcores->mm.value[opp]);
610 do_scale_vcore(vcores->mm.addr, vcores->mm.value[opp],
611 vcores->mm.pmic);
612 /* Configure MM ABB LDO after scale */
613 abb_setup(vcores->mm.efuse.reg[opp],
614 (*ctrl)->control_wkup_ldovbb_mm_voltage_ctrl,
615 (*prcm)->prm_abbldo_mm_setup,
616 (*prcm)->prm_abbldo_mm_ctrl,
617 (*prcm)->prm_irqstatus_mpu,
618 vcores->mm.abb_tx_done_mask,
619 OMAP_ABB_FAST_OPP);
620
621 opp = get_voltrail_opp(VOLT_GPU);
622 debug("gpu: %d\n", vcores->gpu.value[opp]);
623 do_scale_vcore(vcores->gpu.addr, vcores->gpu.value[opp],
624 vcores->gpu.pmic);
625 /* Configure GPU ABB LDO after scale */
626 abb_setup(vcores->gpu.efuse.reg[opp],
627 (*ctrl)->control_wkup_ldovbb_gpu_voltage_ctrl,
628 (*prcm)->prm_abbldo_gpu_setup,
629 (*prcm)->prm_abbldo_gpu_ctrl,
630 (*prcm)->prm_irqstatus_mpu,
631 vcores->gpu.abb_tx_done_mask,
632 OMAP_ABB_FAST_OPP);
633
634 opp = get_voltrail_opp(VOLT_EVE);
635 debug("eve: %d\n", vcores->eve.value[opp]);
636 do_scale_vcore(vcores->eve.addr, vcores->eve.value[opp],
637 vcores->eve.pmic);
638 /* Configure EVE ABB LDO after scale */
639 abb_setup(vcores->eve.efuse.reg[opp],
640 (*ctrl)->control_wkup_ldovbb_eve_voltage_ctrl,
641 (*prcm)->prm_abbldo_eve_setup,
642 (*prcm)->prm_abbldo_eve_ctrl,
643 (*prcm)->prm_irqstatus_mpu,
644 vcores->eve.abb_tx_done_mask,
645 OMAP_ABB_FAST_OPP);
646
647 opp = get_voltrail_opp(VOLT_IVA);
648 debug("iva: %d\n", vcores->iva.value[opp]);
649 do_scale_vcore(vcores->iva.addr, vcores->iva.value[opp],
650 vcores->iva.pmic);
651 /* Configure IVA ABB LDO after scale */
652 abb_setup(vcores->iva.efuse.reg[opp],
653 (*ctrl)->control_wkup_ldovbb_iva_voltage_ctrl,
654 (*prcm)->prm_abbldo_iva_setup,
655 (*prcm)->prm_abbldo_iva_ctrl,
656 (*prcm)->prm_irqstatus_mpu,
657 vcores->iva.abb_tx_done_mask,
658 OMAP_ABB_FAST_OPP);
659 }
660
enable_clock_domain(u32 const clkctrl_reg,u32 enable_mode)661 static inline void enable_clock_domain(u32 const clkctrl_reg, u32 enable_mode)
662 {
663 clrsetbits_le32(clkctrl_reg, CD_CLKCTRL_CLKTRCTRL_MASK,
664 enable_mode << CD_CLKCTRL_CLKTRCTRL_SHIFT);
665 debug("Enable clock domain - %x\n", clkctrl_reg);
666 }
667
disable_clock_domain(u32 const clkctrl_reg)668 static inline void disable_clock_domain(u32 const clkctrl_reg)
669 {
670 clrsetbits_le32(clkctrl_reg, CD_CLKCTRL_CLKTRCTRL_MASK,
671 CD_CLKCTRL_CLKTRCTRL_SW_SLEEP <<
672 CD_CLKCTRL_CLKTRCTRL_SHIFT);
673 debug("Disable clock domain - %x\n", clkctrl_reg);
674 }
675
wait_for_clk_enable(u32 clkctrl_addr)676 static inline void wait_for_clk_enable(u32 clkctrl_addr)
677 {
678 u32 clkctrl, idlest = MODULE_CLKCTRL_IDLEST_DISABLED;
679 u32 bound = LDELAY;
680
681 while ((idlest == MODULE_CLKCTRL_IDLEST_DISABLED) ||
682 (idlest == MODULE_CLKCTRL_IDLEST_TRANSITIONING)) {
683
684 clkctrl = readl(clkctrl_addr);
685 idlest = (clkctrl & MODULE_CLKCTRL_IDLEST_MASK) >>
686 MODULE_CLKCTRL_IDLEST_SHIFT;
687 if (--bound == 0) {
688 printf("Clock enable failed for 0x%x idlest 0x%x\n",
689 clkctrl_addr, clkctrl);
690 return;
691 }
692 }
693 }
694
enable_clock_module(u32 const clkctrl_addr,u32 enable_mode,u32 wait_for_enable)695 static inline void enable_clock_module(u32 const clkctrl_addr, u32 enable_mode,
696 u32 wait_for_enable)
697 {
698 clrsetbits_le32(clkctrl_addr, MODULE_CLKCTRL_MODULEMODE_MASK,
699 enable_mode << MODULE_CLKCTRL_MODULEMODE_SHIFT);
700 debug("Enable clock module - %x\n", clkctrl_addr);
701 if (wait_for_enable)
702 wait_for_clk_enable(clkctrl_addr);
703 }
704
wait_for_clk_disable(u32 clkctrl_addr)705 static inline void wait_for_clk_disable(u32 clkctrl_addr)
706 {
707 u32 clkctrl, idlest = MODULE_CLKCTRL_IDLEST_FULLY_FUNCTIONAL;
708 u32 bound = LDELAY;
709
710 while ((idlest != MODULE_CLKCTRL_IDLEST_DISABLED)) {
711 clkctrl = readl(clkctrl_addr);
712 idlest = (clkctrl & MODULE_CLKCTRL_IDLEST_MASK) >>
713 MODULE_CLKCTRL_IDLEST_SHIFT;
714 if (--bound == 0) {
715 printf("Clock disable failed for 0x%x idlest 0x%x\n",
716 clkctrl_addr, clkctrl);
717 return;
718 }
719 }
720 }
721
disable_clock_module(u32 const clkctrl_addr,u32 wait_for_disable)722 static inline void disable_clock_module(u32 const clkctrl_addr,
723 u32 wait_for_disable)
724 {
725 clrsetbits_le32(clkctrl_addr, MODULE_CLKCTRL_MODULEMODE_MASK,
726 MODULE_CLKCTRL_MODULEMODE_SW_DISABLE <<
727 MODULE_CLKCTRL_MODULEMODE_SHIFT);
728 debug("Disable clock module - %x\n", clkctrl_addr);
729 if (wait_for_disable)
730 wait_for_clk_disable(clkctrl_addr);
731 }
732
freq_update_core(void)733 void freq_update_core(void)
734 {
735 u32 freq_config1 = 0;
736 const struct dpll_params *core_dpll_params;
737 u32 omap_rev = omap_revision();
738
739 core_dpll_params = get_core_dpll_params(*dplls_data);
740 /* Put EMIF clock domain in sw wakeup mode */
741 enable_clock_domain((*prcm)->cm_memif_clkstctrl,
742 CD_CLKCTRL_CLKTRCTRL_SW_WKUP);
743 wait_for_clk_enable((*prcm)->cm_memif_emif_1_clkctrl);
744 wait_for_clk_enable((*prcm)->cm_memif_emif_2_clkctrl);
745
746 freq_config1 = SHADOW_FREQ_CONFIG1_FREQ_UPDATE_MASK |
747 SHADOW_FREQ_CONFIG1_DLL_RESET_MASK;
748
749 freq_config1 |= (DPLL_EN_LOCK << SHADOW_FREQ_CONFIG1_DPLL_EN_SHIFT) &
750 SHADOW_FREQ_CONFIG1_DPLL_EN_MASK;
751
752 freq_config1 |= (core_dpll_params->m2 <<
753 SHADOW_FREQ_CONFIG1_M2_DIV_SHIFT) &
754 SHADOW_FREQ_CONFIG1_M2_DIV_MASK;
755
756 writel(freq_config1, (*prcm)->cm_shadow_freq_config1);
757 if (!wait_on_value(SHADOW_FREQ_CONFIG1_FREQ_UPDATE_MASK, 0,
758 (u32 *) (*prcm)->cm_shadow_freq_config1, LDELAY)) {
759 puts("FREQ UPDATE procedure failed!!");
760 hang();
761 }
762
763 /*
764 * Putting EMIF in HW_AUTO is seen to be causing issues with
765 * EMIF clocks and the master DLL. Keep EMIF in SW_WKUP
766 * in OMAP5430 ES1.0 silicon
767 */
768 if (omap_rev != OMAP5430_ES1_0) {
769 /* Put EMIF clock domain back in hw auto mode */
770 enable_clock_domain((*prcm)->cm_memif_clkstctrl,
771 CD_CLKCTRL_CLKTRCTRL_HW_AUTO);
772 wait_for_clk_enable((*prcm)->cm_memif_emif_1_clkctrl);
773 wait_for_clk_enable((*prcm)->cm_memif_emif_2_clkctrl);
774 }
775 }
776
bypass_dpll(u32 const base)777 void bypass_dpll(u32 const base)
778 {
779 do_bypass_dpll(base);
780 wait_for_bypass(base);
781 }
782
lock_dpll(u32 const base)783 void lock_dpll(u32 const base)
784 {
785 do_lock_dpll(base);
786 wait_for_lock(base);
787 }
788
setup_clocks_for_console(void)789 static void setup_clocks_for_console(void)
790 {
791 /* Do not add any spl_debug prints in this function */
792 clrsetbits_le32((*prcm)->cm_l4per_clkstctrl, CD_CLKCTRL_CLKTRCTRL_MASK,
793 CD_CLKCTRL_CLKTRCTRL_SW_WKUP <<
794 CD_CLKCTRL_CLKTRCTRL_SHIFT);
795
796 /* Enable all UARTs - console will be on one of them */
797 clrsetbits_le32((*prcm)->cm_l4per_uart1_clkctrl,
798 MODULE_CLKCTRL_MODULEMODE_MASK,
799 MODULE_CLKCTRL_MODULEMODE_SW_EXPLICIT_EN <<
800 MODULE_CLKCTRL_MODULEMODE_SHIFT);
801
802 clrsetbits_le32((*prcm)->cm_l4per_uart2_clkctrl,
803 MODULE_CLKCTRL_MODULEMODE_MASK,
804 MODULE_CLKCTRL_MODULEMODE_SW_EXPLICIT_EN <<
805 MODULE_CLKCTRL_MODULEMODE_SHIFT);
806
807 clrsetbits_le32((*prcm)->cm_l4per_uart3_clkctrl,
808 MODULE_CLKCTRL_MODULEMODE_MASK,
809 MODULE_CLKCTRL_MODULEMODE_SW_EXPLICIT_EN <<
810 MODULE_CLKCTRL_MODULEMODE_SHIFT);
811
812 clrsetbits_le32((*prcm)->cm_l4per_uart4_clkctrl,
813 MODULE_CLKCTRL_MODULEMODE_MASK,
814 MODULE_CLKCTRL_MODULEMODE_SW_EXPLICIT_EN <<
815 MODULE_CLKCTRL_MODULEMODE_SHIFT);
816
817 clrsetbits_le32((*prcm)->cm_l4per_clkstctrl, CD_CLKCTRL_CLKTRCTRL_MASK,
818 CD_CLKCTRL_CLKTRCTRL_HW_AUTO <<
819 CD_CLKCTRL_CLKTRCTRL_SHIFT);
820 }
821
do_enable_clocks(u32 const * clk_domains,u32 const * clk_modules_hw_auto,u32 const * clk_modules_explicit_en,u8 wait_for_enable)822 void do_enable_clocks(u32 const *clk_domains,
823 u32 const *clk_modules_hw_auto,
824 u32 const *clk_modules_explicit_en,
825 u8 wait_for_enable)
826 {
827 u32 i, max = 100;
828
829 /* Put the clock domains in SW_WKUP mode */
830 for (i = 0; (i < max) && clk_domains && clk_domains[i]; i++) {
831 enable_clock_domain(clk_domains[i],
832 CD_CLKCTRL_CLKTRCTRL_SW_WKUP);
833 }
834
835 /* Clock modules that need to be put in HW_AUTO */
836 for (i = 0; (i < max) && clk_modules_hw_auto &&
837 clk_modules_hw_auto[i]; i++) {
838 enable_clock_module(clk_modules_hw_auto[i],
839 MODULE_CLKCTRL_MODULEMODE_HW_AUTO,
840 wait_for_enable);
841 };
842
843 /* Clock modules that need to be put in SW_EXPLICIT_EN mode */
844 for (i = 0; (i < max) && clk_modules_explicit_en &&
845 clk_modules_explicit_en[i]; i++) {
846 enable_clock_module(clk_modules_explicit_en[i],
847 MODULE_CLKCTRL_MODULEMODE_SW_EXPLICIT_EN,
848 wait_for_enable);
849 };
850
851 /* Put the clock domains in HW_AUTO mode now */
852 for (i = 0; (i < max) && clk_domains && clk_domains[i]; i++) {
853 enable_clock_domain(clk_domains[i],
854 CD_CLKCTRL_CLKTRCTRL_HW_AUTO);
855 }
856 }
857
do_disable_clocks(u32 const * clk_domains,u32 const * clk_modules_disable,u8 wait_for_disable)858 void do_disable_clocks(u32 const *clk_domains,
859 u32 const *clk_modules_disable,
860 u8 wait_for_disable)
861 {
862 u32 i, max = 100;
863
864
865 /* Clock modules that need to be put in SW_DISABLE */
866 for (i = 0; (i < max) && clk_modules_disable[i]; i++)
867 disable_clock_module(clk_modules_disable[i],
868 wait_for_disable);
869
870 /* Put the clock domains in SW_SLEEP mode */
871 for (i = 0; (i < max) && clk_domains[i]; i++)
872 disable_clock_domain(clk_domains[i]);
873 }
874
875 /**
876 * setup_early_clocks() - Setup early clocks needed for SoC
877 *
878 * Setup clocks for console, SPL basic initialization clocks and initialize
879 * the timer. This is invoked prior prcm_init.
880 */
setup_early_clocks(void)881 void setup_early_clocks(void)
882 {
883 switch (omap_hw_init_context()) {
884 case OMAP_INIT_CONTEXT_SPL:
885 case OMAP_INIT_CONTEXT_UBOOT_FROM_NOR:
886 case OMAP_INIT_CONTEXT_UBOOT_AFTER_CH:
887 setup_clocks_for_console();
888 enable_basic_clocks();
889 timer_init();
890 /* Fall through */
891 }
892 }
893
prcm_init(void)894 void prcm_init(void)
895 {
896 switch (omap_hw_init_context()) {
897 case OMAP_INIT_CONTEXT_SPL:
898 case OMAP_INIT_CONTEXT_UBOOT_FROM_NOR:
899 case OMAP_INIT_CONTEXT_UBOOT_AFTER_CH:
900 scale_vcores(*omap_vcores);
901 setup_dplls();
902 setup_warmreset_time();
903 break;
904 default:
905 break;
906 }
907
908 if (OMAP_INIT_CONTEXT_SPL != omap_hw_init_context())
909 enable_basic_uboot_clocks();
910 }
911
gpi2c_init(void)912 void gpi2c_init(void)
913 {
914 static int gpi2c = 1;
915
916 if (gpi2c) {
917 i2c_init(CONFIG_SYS_OMAP24_I2C_SPEED,
918 CONFIG_SYS_OMAP24_I2C_SLAVE);
919 gpi2c = 0;
920 }
921 }
922