tjh.dev
Linux kernel mirror (for testing)
git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git
kernel
os
linux
1/*
2 * U300 clock implementation
3 * Copyright (C) 2007-2012 ST-Ericsson AB
4 * License terms: GNU General Public License (GPL) version 2
5 * Author: Linus Walleij <linus.walleij@stericsson.com>
6 * Author: Jonas Aaberg <jonas.aberg@stericsson.com>
7 */
8#include <linux/clk.h>
9#include <linux/clkdev.h>
10#include <linux/err.h>
11#include <linux/io.h>
12#include <linux/clk-provider.h>
13#include <linux/spinlock.h>
14#include <mach/syscon.h>
15
16/*
17 * The clocking hierarchy currently looks like this.
18 * NOTE: the idea is NOT to show how the clocks are routed on the chip!
19 * The ideas is to show dependencies, so a clock higher up in the
20 * hierarchy has to be on in order for another clock to be on. Now,
21 * both CPU and DMA can actually be on top of the hierarchy, and that
22 * is not modeled currently. Instead we have the backbone AMBA bus on
23 * top. This bus cannot be programmed in any way but conceptually it
24 * needs to be active for the bridges and devices to transport data.
25 *
26 * Please be aware that a few clocks are hw controlled, which mean that
27 * the hw itself can turn on/off or change the rate of the clock when
28 * needed!
29 *
30 * AMBA bus
31 * |
32 * +- CPU
33 * +- FSMC NANDIF NAND Flash interface
34 * +- SEMI Shared Memory interface
35 * +- ISP Image Signal Processor (U335 only)
36 * +- CDS (U335 only)
37 * +- DMA Direct Memory Access Controller
38 * +- AAIF APP/ACC Inteface (Mobile Scalable Link, MSL)
39 * +- APEX
40 * +- VIDEO_ENC AVE2/3 Video Encoder
41 * +- XGAM Graphics Accelerator Controller
42 * +- AHB
43 * |
44 * +- ahb:0 AHB Bridge
45 * | |
46 * | +- ahb:1 INTCON Interrupt controller
47 * | +- ahb:3 MSPRO Memory Stick Pro controller
48 * | +- ahb:4 EMIF External Memory interface
49 * |
50 * +- fast:0 FAST bridge
51 * | |
52 * | +- fast:1 MMCSD MMC/SD card reader controller
53 * | +- fast:2 I2S0 PCM I2S channel 0 controller
54 * | +- fast:3 I2S1 PCM I2S channel 1 controller
55 * | +- fast:4 I2C0 I2C channel 0 controller
56 * | +- fast:5 I2C1 I2C channel 1 controller
57 * | +- fast:6 SPI SPI controller
58 * | +- fast:7 UART1 Secondary UART (U335 only)
59 * |
60 * +- slow:0 SLOW bridge
61 * |
62 * +- slow:1 SYSCON (not possible to control)
63 * +- slow:2 WDOG Watchdog
64 * +- slow:3 UART0 primary UART
65 * +- slow:4 TIMER_APP Application timer - used in Linux
66 * +- slow:5 KEYPAD controller
67 * +- slow:6 GPIO controller
68 * +- slow:7 RTC controller
69 * +- slow:8 BT Bus Tracer (not used currently)
70 * +- slow:9 EH Event Handler (not used currently)
71 * +- slow:a TIMER_ACC Access style timer (not used currently)
72 * +- slow:b PPM (U335 only, what is that?)
73 */
74
75/* Global syscon virtual base */
76static void __iomem *syscon_vbase;
77
78/**
79 * struct clk_syscon - U300 syscon clock
80 * @hw: corresponding clock hardware entry
81 * @hw_ctrld: whether this clock is hardware controlled (for refcount etc)
82 * and does not need any magic pokes to be enabled/disabled
83 * @reset: state holder, whether this block's reset line is asserted or not
84 * @res_reg: reset line enable/disable flag register
85 * @res_bit: bit for resetting or taking this consumer out of reset
86 * @en_reg: clock line enable/disable flag register
87 * @en_bit: bit for enabling/disabling this consumer clock line
88 * @clk_val: magic value to poke in the register to enable/disable
89 * this one clock
90 */
91struct clk_syscon {
92 struct clk_hw hw;
93 bool hw_ctrld;
94 bool reset;
95 void __iomem *res_reg;
96 u8 res_bit;
97 void __iomem *en_reg;
98 u8 en_bit;
99 u16 clk_val;
100};
101
102#define to_syscon(_hw) container_of(_hw, struct clk_syscon, hw)
103
104static DEFINE_SPINLOCK(syscon_resetreg_lock);
105
106/*
107 * Reset control functions. We remember if a block has been
108 * taken out of reset and don't remove the reset assertion again
109 * and vice versa. Currently we only remove resets so the
110 * enablement function is defined out.
111 */
112static void syscon_block_reset_enable(struct clk_syscon *sclk)
113{
114 unsigned long iflags;
115 u16 val;
116
117 /* Not all blocks support resetting */
118 if (!sclk->res_reg)
119 return;
120 spin_lock_irqsave(&syscon_resetreg_lock, iflags);
121 val = readw(sclk->res_reg);
122 val |= BIT(sclk->res_bit);
123 writew(val, sclk->res_reg);
124 spin_unlock_irqrestore(&syscon_resetreg_lock, iflags);
125 sclk->reset = true;
126}
127
128static void syscon_block_reset_disable(struct clk_syscon *sclk)
129{
130 unsigned long iflags;
131 u16 val;
132
133 /* Not all blocks support resetting */
134 if (!sclk->res_reg)
135 return;
136 spin_lock_irqsave(&syscon_resetreg_lock, iflags);
137 val = readw(sclk->res_reg);
138 val &= ~BIT(sclk->res_bit);
139 writew(val, sclk->res_reg);
140 spin_unlock_irqrestore(&syscon_resetreg_lock, iflags);
141 sclk->reset = false;
142}
143
144static int syscon_clk_prepare(struct clk_hw *hw)
145{
146 struct clk_syscon *sclk = to_syscon(hw);
147
148 /* If the block is in reset, bring it out */
149 if (sclk->reset)
150 syscon_block_reset_disable(sclk);
151 return 0;
152}
153
154static void syscon_clk_unprepare(struct clk_hw *hw)
155{
156 struct clk_syscon *sclk = to_syscon(hw);
157
158 /* Please don't force the console into reset */
159 if (sclk->clk_val == U300_SYSCON_SBCER_UART_CLK_EN)
160 return;
161 /* When unpreparing, force block into reset */
162 if (!sclk->reset)
163 syscon_block_reset_enable(sclk);
164}
165
166static int syscon_clk_enable(struct clk_hw *hw)
167{
168 struct clk_syscon *sclk = to_syscon(hw);
169
170 /* Don't touch the hardware controlled clocks */
171 if (sclk->hw_ctrld)
172 return 0;
173 /* These cannot be controlled */
174 if (sclk->clk_val == 0xFFFFU)
175 return 0;
176
177 writew(sclk->clk_val, syscon_vbase + U300_SYSCON_SBCER);
178 return 0;
179}
180
181static void syscon_clk_disable(struct clk_hw *hw)
182{
183 struct clk_syscon *sclk = to_syscon(hw);
184
185 /* Don't touch the hardware controlled clocks */
186 if (sclk->hw_ctrld)
187 return;
188 if (sclk->clk_val == 0xFFFFU)
189 return;
190 /* Please don't disable the console port */
191 if (sclk->clk_val == U300_SYSCON_SBCER_UART_CLK_EN)
192 return;
193
194 writew(sclk->clk_val, syscon_vbase + U300_SYSCON_SBCDR);
195}
196
197static int syscon_clk_is_enabled(struct clk_hw *hw)
198{
199 struct clk_syscon *sclk = to_syscon(hw);
200 u16 val;
201
202 /* If no enable register defined, it's always-on */
203 if (!sclk->en_reg)
204 return 1;
205
206 val = readw(sclk->en_reg);
207 val &= BIT(sclk->en_bit);
208
209 return val ? 1 : 0;
210}
211
212static u16 syscon_get_perf(void)
213{
214 u16 val;
215
216 val = readw(syscon_vbase + U300_SYSCON_CCR);
217 val &= U300_SYSCON_CCR_CLKING_PERFORMANCE_MASK;
218 return val;
219}
220
221static unsigned long
222syscon_clk_recalc_rate(struct clk_hw *hw,
223 unsigned long parent_rate)
224{
225 struct clk_syscon *sclk = to_syscon(hw);
226 u16 perf = syscon_get_perf();
227
228 switch(sclk->clk_val) {
229 case U300_SYSCON_SBCER_FAST_BRIDGE_CLK_EN:
230 case U300_SYSCON_SBCER_I2C0_CLK_EN:
231 case U300_SYSCON_SBCER_I2C1_CLK_EN:
232 case U300_SYSCON_SBCER_MMC_CLK_EN:
233 case U300_SYSCON_SBCER_SPI_CLK_EN:
234 /* The FAST clocks have one progression */
235 switch(perf) {
236 case U300_SYSCON_CCR_CLKING_PERFORMANCE_LOW_POWER:
237 case U300_SYSCON_CCR_CLKING_PERFORMANCE_LOW:
238 return 13000000;
239 default:
240 return parent_rate; /* 26 MHz */
241 }
242 case U300_SYSCON_SBCER_DMAC_CLK_EN:
243 case U300_SYSCON_SBCER_NANDIF_CLK_EN:
244 case U300_SYSCON_SBCER_XGAM_CLK_EN:
245 /* AMBA interconnect peripherals */
246 switch(perf) {
247 case U300_SYSCON_CCR_CLKING_PERFORMANCE_LOW_POWER:
248 case U300_SYSCON_CCR_CLKING_PERFORMANCE_LOW:
249 return 6500000;
250 case U300_SYSCON_CCR_CLKING_PERFORMANCE_INTERMEDIATE:
251 return 26000000;
252 default:
253 return parent_rate; /* 52 MHz */
254 }
255 case U300_SYSCON_SBCER_SEMI_CLK_EN:
256 case U300_SYSCON_SBCER_EMIF_CLK_EN:
257 /* EMIF speeds */
258 switch(perf) {
259 case U300_SYSCON_CCR_CLKING_PERFORMANCE_LOW_POWER:
260 case U300_SYSCON_CCR_CLKING_PERFORMANCE_LOW:
261 return 13000000;
262 case U300_SYSCON_CCR_CLKING_PERFORMANCE_INTERMEDIATE:
263 return 52000000;
264 default:
265 return 104000000;
266 }
267 case U300_SYSCON_SBCER_CPU_CLK_EN:
268 /* And the fast CPU clock */
269 switch(perf) {
270 case U300_SYSCON_CCR_CLKING_PERFORMANCE_LOW_POWER:
271 case U300_SYSCON_CCR_CLKING_PERFORMANCE_LOW:
272 return 13000000;
273 case U300_SYSCON_CCR_CLKING_PERFORMANCE_INTERMEDIATE:
274 return 52000000;
275 case U300_SYSCON_CCR_CLKING_PERFORMANCE_HIGH:
276 return 104000000;
277 default:
278 return parent_rate; /* 208 MHz */
279 }
280 default:
281 /*
282 * The SLOW clocks and default just inherit the rate of
283 * their parent (typically PLL13 13 MHz).
284 */
285 return parent_rate;
286 }
287}
288
289static long
290syscon_clk_round_rate(struct clk_hw *hw, unsigned long rate,
291 unsigned long *prate)
292{
293 struct clk_syscon *sclk = to_syscon(hw);
294
295 if (sclk->clk_val != U300_SYSCON_SBCER_CPU_CLK_EN)
296 return *prate;
297 /* We really only support setting the rate of the CPU clock */
298 if (rate <= 13000000)
299 return 13000000;
300 if (rate <= 52000000)
301 return 52000000;
302 if (rate <= 104000000)
303 return 104000000;
304 return 208000000;
305}
306
307static int syscon_clk_set_rate(struct clk_hw *hw, unsigned long rate,
308 unsigned long parent_rate)
309{
310 struct clk_syscon *sclk = to_syscon(hw);
311 u16 val;
312
313 /* We only support setting the rate of the CPU clock */
314 if (sclk->clk_val != U300_SYSCON_SBCER_CPU_CLK_EN)
315 return -EINVAL;
316 switch (rate) {
317 case 13000000:
318 val = U300_SYSCON_CCR_CLKING_PERFORMANCE_LOW_POWER;
319 break;
320 case 52000000:
321 val = U300_SYSCON_CCR_CLKING_PERFORMANCE_INTERMEDIATE;
322 break;
323 case 104000000:
324 val = U300_SYSCON_CCR_CLKING_PERFORMANCE_HIGH;
325 break;
326 case 208000000:
327 val = U300_SYSCON_CCR_CLKING_PERFORMANCE_BEST;
328 break;
329 default:
330 return -EINVAL;
331 }
332 val |= readw(syscon_vbase + U300_SYSCON_CCR) &
333 ~U300_SYSCON_CCR_CLKING_PERFORMANCE_MASK ;
334 writew(val, syscon_vbase + U300_SYSCON_CCR);
335 return 0;
336}
337
338static const struct clk_ops syscon_clk_ops = {
339 .prepare = syscon_clk_prepare,
340 .unprepare = syscon_clk_unprepare,
341 .enable = syscon_clk_enable,
342 .disable = syscon_clk_disable,
343 .is_enabled = syscon_clk_is_enabled,
344 .recalc_rate = syscon_clk_recalc_rate,
345 .round_rate = syscon_clk_round_rate,
346 .set_rate = syscon_clk_set_rate,
347};
348
349static struct clk * __init
350syscon_clk_register(struct device *dev, const char *name,
351 const char *parent_name, unsigned long flags,
352 bool hw_ctrld,
353 void __iomem *res_reg, u8 res_bit,
354 void __iomem *en_reg, u8 en_bit,
355 u16 clk_val)
356{
357 struct clk *clk;
358 struct clk_syscon *sclk;
359 struct clk_init_data init;
360
361 sclk = kzalloc(sizeof(struct clk_syscon), GFP_KERNEL);
362 if (!sclk) {
363 pr_err("could not allocate syscon clock %s\n",
364 name);
365 return ERR_PTR(-ENOMEM);
366 }
367 init.name = name;
368 init.ops = &syscon_clk_ops;
369 init.flags = flags;
370 init.parent_names = (parent_name ? &parent_name : NULL);
371 init.num_parents = (parent_name ? 1 : 0);
372 sclk->hw.init = &init;
373 sclk->hw_ctrld = hw_ctrld;
374 /* Assume the block is in reset at registration */
375 sclk->reset = true;
376 sclk->res_reg = res_reg;
377 sclk->res_bit = res_bit;
378 sclk->en_reg = en_reg;
379 sclk->en_bit = en_bit;
380 sclk->clk_val = clk_val;
381
382 clk = clk_register(dev, &sclk->hw);
383 if (IS_ERR(clk))
384 kfree(sclk);
385
386 return clk;
387}
388
389/**
390 * struct clk_mclk - U300 MCLK clock (MMC/SD clock)
391 * @hw: corresponding clock hardware entry
392 * @is_mspro: if this is the memory stick clock rather than MMC/SD
393 */
394struct clk_mclk {
395 struct clk_hw hw;
396 bool is_mspro;
397};
398
399#define to_mclk(_hw) container_of(_hw, struct clk_mclk, hw)
400
401static int mclk_clk_prepare(struct clk_hw *hw)
402{
403 struct clk_mclk *mclk = to_mclk(hw);
404 u16 val;
405
406 /* The MMC and MSPRO clocks need some special set-up */
407 if (!mclk->is_mspro) {
408 /* Set default MMC clock divisor to 18.9 MHz */
409 writew(0x0054U, syscon_vbase + U300_SYSCON_MMF0R);
410 val = readw(syscon_vbase + U300_SYSCON_MMCR);
411 /* Disable the MMC feedback clock */
412 val &= ~U300_SYSCON_MMCR_MMC_FB_CLK_SEL_ENABLE;
413 /* Disable MSPRO frequency */
414 val &= ~U300_SYSCON_MMCR_MSPRO_FREQSEL_ENABLE;
415 writew(val, syscon_vbase + U300_SYSCON_MMCR);
416 } else {
417 val = readw(syscon_vbase + U300_SYSCON_MMCR);
418 /* Disable the MMC feedback clock */
419 val &= ~U300_SYSCON_MMCR_MMC_FB_CLK_SEL_ENABLE;
420 /* Enable MSPRO frequency */
421 val |= U300_SYSCON_MMCR_MSPRO_FREQSEL_ENABLE;
422 writew(val, syscon_vbase + U300_SYSCON_MMCR);
423 }
424
425 return 0;
426}
427
428static unsigned long
429mclk_clk_recalc_rate(struct clk_hw *hw,
430 unsigned long parent_rate)
431{
432 u16 perf = syscon_get_perf();
433
434 switch (perf) {
435 case U300_SYSCON_CCR_CLKING_PERFORMANCE_LOW_POWER:
436 /*
437 * Here, the 208 MHz PLL gets shut down and the always
438 * on 13 MHz PLL used for RTC etc kicks into use
439 * instead.
440 */
441 return 13000000;
442 case U300_SYSCON_CCR_CLKING_PERFORMANCE_LOW:
443 case U300_SYSCON_CCR_CLKING_PERFORMANCE_INTERMEDIATE:
444 case U300_SYSCON_CCR_CLKING_PERFORMANCE_HIGH:
445 case U300_SYSCON_CCR_CLKING_PERFORMANCE_BEST:
446 {
447 /*
448 * This clock is under program control. The register is
449 * divided in two nybbles, bit 7-4 gives cycles-1 to count
450 * high, bit 3-0 gives cycles-1 to count low. Distribute
451 * these with no more than 1 cycle difference between
452 * low and high and add low and high to get the actual
453 * divisor. The base PLL is 208 MHz. Writing 0x00 will
454 * divide by 1 and 1 so the highest frequency possible
455 * is 104 MHz.
456 *
457 * e.g. 0x54 =>
458 * f = 208 / ((5+1) + (4+1)) = 208 / 11 = 18.9 MHz
459 */
460 u16 val = readw(syscon_vbase + U300_SYSCON_MMF0R) &
461 U300_SYSCON_MMF0R_MASK;
462 switch (val) {
463 case 0x0054:
464 return 18900000;
465 case 0x0044:
466 return 20800000;
467 case 0x0043:
468 return 23100000;
469 case 0x0033:
470 return 26000000;
471 case 0x0032:
472 return 29700000;
473 case 0x0022:
474 return 34700000;
475 case 0x0021:
476 return 41600000;
477 case 0x0011:
478 return 52000000;
479 case 0x0000:
480 return 104000000;
481 default:
482 break;
483 }
484 }
485 default:
486 break;
487 }
488 return parent_rate;
489}
490
491static long
492mclk_clk_round_rate(struct clk_hw *hw, unsigned long rate,
493 unsigned long *prate)
494{
495 if (rate <= 18900000)
496 return 18900000;
497 if (rate <= 20800000)
498 return 20800000;
499 if (rate <= 23100000)
500 return 23100000;
501 if (rate <= 26000000)
502 return 26000000;
503 if (rate <= 29700000)
504 return 29700000;
505 if (rate <= 34700000)
506 return 34700000;
507 if (rate <= 41600000)
508 return 41600000;
509 /* Highest rate */
510 return 52000000;
511}
512
513static int mclk_clk_set_rate(struct clk_hw *hw, unsigned long rate,
514 unsigned long parent_rate)
515{
516 u16 val;
517 u16 reg;
518
519 switch (rate) {
520 case 18900000:
521 val = 0x0054;
522 break;
523 case 20800000:
524 val = 0x0044;
525 break;
526 case 23100000:
527 val = 0x0043;
528 break;
529 case 26000000:
530 val = 0x0033;
531 break;
532 case 29700000:
533 val = 0x0032;
534 break;
535 case 34700000:
536 val = 0x0022;
537 break;
538 case 41600000:
539 val = 0x0021;
540 break;
541 case 52000000:
542 val = 0x0011;
543 break;
544 case 104000000:
545 val = 0x0000;
546 break;
547 default:
548 return -EINVAL;
549 }
550
551 reg = readw(syscon_vbase + U300_SYSCON_MMF0R) &
552 ~U300_SYSCON_MMF0R_MASK;
553 writew(reg | val, syscon_vbase + U300_SYSCON_MMF0R);
554 return 0;
555}
556
557static const struct clk_ops mclk_ops = {
558 .prepare = mclk_clk_prepare,
559 .recalc_rate = mclk_clk_recalc_rate,
560 .round_rate = mclk_clk_round_rate,
561 .set_rate = mclk_clk_set_rate,
562};
563
564static struct clk * __init
565mclk_clk_register(struct device *dev, const char *name,
566 const char *parent_name, bool is_mspro)
567{
568 struct clk *clk;
569 struct clk_mclk *mclk;
570 struct clk_init_data init;
571
572 mclk = kzalloc(sizeof(struct clk_mclk), GFP_KERNEL);
573 if (!mclk) {
574 pr_err("could not allocate MMC/SD clock %s\n",
575 name);
576 return ERR_PTR(-ENOMEM);
577 }
578 init.name = "mclk";
579 init.ops = &mclk_ops;
580 init.flags = 0;
581 init.parent_names = (parent_name ? &parent_name : NULL);
582 init.num_parents = (parent_name ? 1 : 0);
583 mclk->hw.init = &init;
584 mclk->is_mspro = is_mspro;
585
586 clk = clk_register(dev, &mclk->hw);
587 if (IS_ERR(clk))
588 kfree(mclk);
589
590 return clk;
591}
592
593void __init u300_clk_init(void __iomem *base)
594{
595 u16 val;
596 struct clk *clk;
597
598 syscon_vbase = base;
599
600 /* Set system to run at PLL208, max performance, a known state. */
601 val = readw(syscon_vbase + U300_SYSCON_CCR);
602 val &= ~U300_SYSCON_CCR_CLKING_PERFORMANCE_MASK;
603 writew(val, syscon_vbase + U300_SYSCON_CCR);
604 /* Wait for the PLL208 to lock if not locked in yet */
605 while (!(readw(syscon_vbase + U300_SYSCON_CSR) &
606 U300_SYSCON_CSR_PLL208_LOCK_IND));
607
608 /* Power management enable */
609 val = readw(syscon_vbase + U300_SYSCON_PMCR);
610 val |= U300_SYSCON_PMCR_PWR_MGNT_ENABLE;
611 writew(val, syscon_vbase + U300_SYSCON_PMCR);
612
613 /* These are always available (RTC and PLL13) */
614 clk = clk_register_fixed_rate(NULL, "app_32_clk", NULL,
615 CLK_IS_ROOT, 32768);
616 /* The watchdog sits directly on the 32 kHz clock */
617 clk_register_clkdev(clk, NULL, "coh901327_wdog");
618 clk = clk_register_fixed_rate(NULL, "pll13", NULL,
619 CLK_IS_ROOT, 13000000);
620
621 /* These derive from PLL208 */
622 clk = clk_register_fixed_rate(NULL, "pll208", NULL,
623 CLK_IS_ROOT, 208000000);
624 clk = clk_register_fixed_factor(NULL, "app_208_clk", "pll208",
625 0, 1, 1);
626 clk = clk_register_fixed_factor(NULL, "app_104_clk", "pll208",
627 0, 1, 2);
628 clk = clk_register_fixed_factor(NULL, "app_52_clk", "pll208",
629 0, 1, 4);
630 /* The 52 MHz is divided down to 26 MHz */
631 clk = clk_register_fixed_factor(NULL, "app_26_clk", "app_52_clk",
632 0, 1, 2);
633
634 /* Directly on the AMBA interconnect */
635 clk = syscon_clk_register(NULL, "cpu_clk", "app_208_clk", 0, true,
636 syscon_vbase + U300_SYSCON_RRR, 3,
637 syscon_vbase + U300_SYSCON_CERR, 3,
638 U300_SYSCON_SBCER_CPU_CLK_EN);
639 clk = syscon_clk_register(NULL, "dmac_clk", "app_52_clk", 0, true,
640 syscon_vbase + U300_SYSCON_RRR, 4,
641 syscon_vbase + U300_SYSCON_CERR, 4,
642 U300_SYSCON_SBCER_DMAC_CLK_EN);
643 clk_register_clkdev(clk, NULL, "dma");
644 clk = syscon_clk_register(NULL, "fsmc_clk", "app_52_clk", 0, false,
645 syscon_vbase + U300_SYSCON_RRR, 6,
646 syscon_vbase + U300_SYSCON_CERR, 6,
647 U300_SYSCON_SBCER_NANDIF_CLK_EN);
648 clk_register_clkdev(clk, NULL, "fsmc-nand");
649 clk = syscon_clk_register(NULL, "xgam_clk", "app_52_clk", 0, true,
650 syscon_vbase + U300_SYSCON_RRR, 8,
651 syscon_vbase + U300_SYSCON_CERR, 8,
652 U300_SYSCON_SBCER_XGAM_CLK_EN);
653 clk_register_clkdev(clk, NULL, "xgam");
654 clk = syscon_clk_register(NULL, "semi_clk", "app_104_clk", 0, false,
655 syscon_vbase + U300_SYSCON_RRR, 9,
656 syscon_vbase + U300_SYSCON_CERR, 9,
657 U300_SYSCON_SBCER_SEMI_CLK_EN);
658 clk_register_clkdev(clk, NULL, "semi");
659
660 /* AHB bridge clocks */
661 clk = syscon_clk_register(NULL, "ahb_subsys_clk", "app_52_clk", 0, true,
662 syscon_vbase + U300_SYSCON_RRR, 10,
663 syscon_vbase + U300_SYSCON_CERR, 10,
664 U300_SYSCON_SBCER_AHB_SUBSYS_BRIDGE_CLK_EN);
665 clk = syscon_clk_register(NULL, "intcon_clk", "ahb_subsys_clk", 0, false,
666 syscon_vbase + U300_SYSCON_RRR, 12,
667 syscon_vbase + U300_SYSCON_CERR, 12,
668 /* Cannot be enabled, just taken out of reset */
669 0xFFFFU);
670 clk_register_clkdev(clk, NULL, "intcon");
671 clk = syscon_clk_register(NULL, "emif_clk", "ahb_subsys_clk", 0, false,
672 syscon_vbase + U300_SYSCON_RRR, 5,
673 syscon_vbase + U300_SYSCON_CERR, 5,
674 U300_SYSCON_SBCER_EMIF_CLK_EN);
675 clk_register_clkdev(clk, NULL, "pl172");
676
677 /* FAST bridge clocks */
678 clk = syscon_clk_register(NULL, "fast_clk", "app_26_clk", 0, true,
679 syscon_vbase + U300_SYSCON_RFR, 0,
680 syscon_vbase + U300_SYSCON_CEFR, 0,
681 U300_SYSCON_SBCER_FAST_BRIDGE_CLK_EN);
682 clk = syscon_clk_register(NULL, "i2c0_p_clk", "fast_clk", 0, false,
683 syscon_vbase + U300_SYSCON_RFR, 1,
684 syscon_vbase + U300_SYSCON_CEFR, 1,
685 U300_SYSCON_SBCER_I2C0_CLK_EN);
686 clk_register_clkdev(clk, NULL, "stu300.0");
687 clk = syscon_clk_register(NULL, "i2c1_p_clk", "fast_clk", 0, false,
688 syscon_vbase + U300_SYSCON_RFR, 2,
689 syscon_vbase + U300_SYSCON_CEFR, 2,
690 U300_SYSCON_SBCER_I2C1_CLK_EN);
691 clk_register_clkdev(clk, NULL, "stu300.1");
692 clk = syscon_clk_register(NULL, "mmc_p_clk", "fast_clk", 0, false,
693 syscon_vbase + U300_SYSCON_RFR, 5,
694 syscon_vbase + U300_SYSCON_CEFR, 5,
695 U300_SYSCON_SBCER_MMC_CLK_EN);
696 clk_register_clkdev(clk, "apb_pclk", "mmci");
697 clk = syscon_clk_register(NULL, "spi_p_clk", "fast_clk", 0, false,
698 syscon_vbase + U300_SYSCON_RFR, 6,
699 syscon_vbase + U300_SYSCON_CEFR, 6,
700 U300_SYSCON_SBCER_SPI_CLK_EN);
701 /* The SPI has no external clock for the outward bus, uses the pclk */
702 clk_register_clkdev(clk, NULL, "pl022");
703 clk_register_clkdev(clk, "apb_pclk", "pl022");
704
705 /* SLOW bridge clocks */
706 clk = syscon_clk_register(NULL, "slow_clk", "pll13", 0, true,
707 syscon_vbase + U300_SYSCON_RSR, 0,
708 syscon_vbase + U300_SYSCON_CESR, 0,
709 U300_SYSCON_SBCER_SLOW_BRIDGE_CLK_EN);
710 clk = syscon_clk_register(NULL, "uart0_clk", "slow_clk", 0, false,
711 syscon_vbase + U300_SYSCON_RSR, 1,
712 syscon_vbase + U300_SYSCON_CESR, 1,
713 U300_SYSCON_SBCER_UART_CLK_EN);
714 /* Same clock is used for APB and outward bus */
715 clk_register_clkdev(clk, NULL, "uart0");
716 clk_register_clkdev(clk, "apb_pclk", "uart0");
717 clk = syscon_clk_register(NULL, "gpio_clk", "slow_clk", 0, false,
718 syscon_vbase + U300_SYSCON_RSR, 4,
719 syscon_vbase + U300_SYSCON_CESR, 4,
720 U300_SYSCON_SBCER_GPIO_CLK_EN);
721 clk_register_clkdev(clk, NULL, "u300-gpio");
722 clk = syscon_clk_register(NULL, "keypad_clk", "slow_clk", 0, false,
723 syscon_vbase + U300_SYSCON_RSR, 5,
724 syscon_vbase + U300_SYSCON_CESR, 6,
725 U300_SYSCON_SBCER_KEYPAD_CLK_EN);
726 clk_register_clkdev(clk, NULL, "coh901461-keypad");
727 clk = syscon_clk_register(NULL, "rtc_clk", "slow_clk", 0, true,
728 syscon_vbase + U300_SYSCON_RSR, 6,
729 /* No clock enable register bit */
730 NULL, 0, 0xFFFFU);
731 clk_register_clkdev(clk, NULL, "rtc-coh901331");
732 clk = syscon_clk_register(NULL, "app_tmr_clk", "slow_clk", 0, false,
733 syscon_vbase + U300_SYSCON_RSR, 7,
734 syscon_vbase + U300_SYSCON_CESR, 7,
735 U300_SYSCON_SBCER_APP_TMR_CLK_EN);
736 clk_register_clkdev(clk, NULL, "apptimer");
737 clk = syscon_clk_register(NULL, "acc_tmr_clk", "slow_clk", 0, false,
738 syscon_vbase + U300_SYSCON_RSR, 8,
739 syscon_vbase + U300_SYSCON_CESR, 8,
740 U300_SYSCON_SBCER_ACC_TMR_CLK_EN);
741 clk_register_clkdev(clk, NULL, "timer");
742
743 /* Then this special MMC/SD clock */
744 clk = mclk_clk_register(NULL, "mmc_clk", "mmc_p_clk", false);
745 clk_register_clkdev(clk, NULL, "mmci");
746}