| blob | 6c78d471fab70b8ebe50c50f49401c6fb42f5747 |
1 /*
2 * linux/arch/arm/mach-omap24xx/clock.h
3 *
4 * Copyright (C) 2005 Texas Instruments Inc.
5 * Richard Woodruff <r-woodruff2@ti.com>
6 * Created for OMAP2.
7 *
8 * Copyright (C) 2004 Nokia corporation
9 * Written by Tuukka Tikkanen <tuukka.tikkanen@elektrobit.com>
10 * Based on clocks.h by Tony Lindgren, Gordon McNutt and RidgeRun, Inc
11 *
12 * This program is free software; you can redistribute it and/or modify
13 * it under the terms of the GNU General Public License version 2 as
14 * published by the Free Software Foundation.
15 */
17 #ifndef __ARCH_ARM_MACH_OMAP2_CLOCK_H
18 #define __ARCH_ARM_MACH_OMAP2_CLOCK_H
33 #define RATE_IN_242X (1 << 0)
34 #define RATE_IN_243X (1 << 1)
36 /* Key dividers which make up a PRCM set. Ratio's for a PRCM are mandated.
37 * xtal_speed, dpll_speed, mpu_speed, CM_CLKSEL_MPU,CM_CLKSEL_DSP
38 * CM_CLKSEL_GFX, CM_CLKSEL1_CORE, CM_CLKSEL1_PLL CM_CLKSEL2_PLL, CM_CLKSEL_MDM
39 */
53 };
55 /* Mask for clksel which support parent settign in set_rate */
56 #define SRC_SEL_MASK (CM_CORE_SEL1 | CM_CORE_SEL2 | CM_WKUP_SEL1 | \
57 CM_PLL_SEL1 | CM_PLL_SEL2 | CM_SYSCLKOUT_SEL1)
59 /* Mask for clksel regs which support rate operations */
60 #define SRC_RATE_SEL_MASK (CM_MPU_SEL1 | CM_DSP_SEL1 | CM_GFX_SEL1 | \
61 CM_MODEM_SEL1 | CM_CORE_SEL1 | CM_CORE_SEL2 | \
62 CM_WKUP_SEL1 | CM_PLL_SEL1 | CM_PLL_SEL2 | \
63 CM_SYSCLKOUT_SEL1)
65 /*
66 * The OMAP2 processor can be run at several discrete 'PRCM configurations'.
67 * These configurations are characterized by voltage and speed for clocks.
68 * The device is only validated for certain combinations. One way to express
69 * these combinations is via the 'ratio's' which the clocks operate with
70 * respect to each other. These ratio sets are for a given voltage/DPLL
71 * setting. All configurations can be described by a DPLL setting and a ratio
72 * There are 3 ratio sets for the 2430 and X ratio sets for 2420.
73 *
74 * 2430 differs from 2420 in that there are no more phase synchronizers used.
75 * They both have a slightly different clock domain setup. 2420(iva1,dsp) vs
76 * 2430 (iva2.1, NOdsp, mdm)
77 */
79 /* Core fields for cm_clksel, not ratio governed */
80 #define RX_CLKSEL_DSS1 (0x10 << 8)
81 #define RX_CLKSEL_DSS2 (0x0 << 13)
82 #define RX_CLKSEL_SSI (0x5 << 20)
84 /*-------------------------------------------------------------------------
85 * Voltage/DPLL ratios
86 *-------------------------------------------------------------------------*/
88 /* 2430 Ratio's, 2430-Ratio Config 1 */
89 #define R1_CLKSEL_L3 (4 << 0)
90 #define R1_CLKSEL_L4 (2 << 5)
91 #define R1_CLKSEL_USB (4 << 25)
92 #define R1_CM_CLKSEL1_CORE_VAL R1_CLKSEL_USB | RX_CLKSEL_SSI | \
93 RX_CLKSEL_DSS2 | RX_CLKSEL_DSS1 | \
94 R1_CLKSEL_L4 | R1_CLKSEL_L3
95 #define R1_CLKSEL_MPU (2 << 0)
96 #define R1_CM_CLKSEL_MPU_VAL R1_CLKSEL_MPU
97 #define R1_CLKSEL_DSP (2 << 0)
98 #define R1_CLKSEL_DSP_IF (2 << 5)
99 #define R1_CM_CLKSEL_DSP_VAL R1_CLKSEL_DSP | R1_CLKSEL_DSP_IF
100 #define R1_CLKSEL_GFX (2 << 0)
101 #define R1_CM_CLKSEL_GFX_VAL R1_CLKSEL_GFX
102 #define R1_CLKSEL_MDM (4 << 0)
103 #define R1_CM_CLKSEL_MDM_VAL R1_CLKSEL_MDM
105 /* 2430-Ratio Config 2 */
106 #define R2_CLKSEL_L3 (6 << 0)
107 #define R2_CLKSEL_L4 (2 << 5)
108 #define R2_CLKSEL_USB (2 << 25)
109 #define R2_CM_CLKSEL1_CORE_VAL R2_CLKSEL_USB | RX_CLKSEL_SSI | \
110 RX_CLKSEL_DSS2 | RX_CLKSEL_DSS1 | \
111 R2_CLKSEL_L4 | R2_CLKSEL_L3
112 #define R2_CLKSEL_MPU (2 << 0)
113 #define R2_CM_CLKSEL_MPU_VAL R2_CLKSEL_MPU
114 #define R2_CLKSEL_DSP (2 << 0)
115 #define R2_CLKSEL_DSP_IF (3 << 5)
116 #define R2_CM_CLKSEL_DSP_VAL R2_CLKSEL_DSP | R2_CLKSEL_DSP_IF
117 #define R2_CLKSEL_GFX (2 << 0)
118 #define R2_CM_CLKSEL_GFX_VAL R2_CLKSEL_GFX
119 #define R2_CLKSEL_MDM (6 << 0)
120 #define R2_CM_CLKSEL_MDM_VAL R2_CLKSEL_MDM
122 /* 2430-Ratio Bootm (BYPASS) */
123 #define RB_CLKSEL_L3 (1 << 0)
124 #define RB_CLKSEL_L4 (1 << 5)
125 #define RB_CLKSEL_USB (1 << 25)
126 #define RB_CM_CLKSEL1_CORE_VAL RB_CLKSEL_USB | RX_CLKSEL_SSI | \
127 RX_CLKSEL_DSS2 | RX_CLKSEL_DSS1 | \
128 RB_CLKSEL_L4 | RB_CLKSEL_L3
129 #define RB_CLKSEL_MPU (1 << 0)
130 #define RB_CM_CLKSEL_MPU_VAL RB_CLKSEL_MPU
131 #define RB_CLKSEL_DSP (1 << 0)
132 #define RB_CLKSEL_DSP_IF (1 << 5)
133 #define RB_CM_CLKSEL_DSP_VAL RB_CLKSEL_DSP | RB_CLKSEL_DSP_IF
134 #define RB_CLKSEL_GFX (1 << 0)
135 #define RB_CM_CLKSEL_GFX_VAL RB_CLKSEL_GFX
136 #define RB_CLKSEL_MDM (1 << 0)
137 #define RB_CM_CLKSEL_MDM_VAL RB_CLKSEL_MDM
139 /* 2420 Ratio Equivalents */
140 #define RXX_CLKSEL_VLYNQ (0x12 << 15)
141 #define RXX_CLKSEL_SSI (0x8 << 20)
143 /* 2420-PRCM III 532MHz core */
147 #define RIII_CM_CLKSEL1_CORE_VAL RIII_CLKSEL_USB | RXX_CLKSEL_SSI | \
148 RXX_CLKSEL_VLYNQ | RX_CLKSEL_DSS2 | \
149 RX_CLKSEL_DSS1 | RIII_CLKSEL_L4 | \
150 RIII_CLKSEL_L3
152 #define RIII_CM_CLKSEL_MPU_VAL RIII_CLKSEL_MPU
158 #define RIII_CM_CLKSEL_DSP_VAL RIII_SYNC_IVA | RIII_CLKSEL_IVA | \
159 RIII_SYNC_DSP | RIII_CLKSEL_DSP_IF | \
160 RIII_CLKSEL_DSP
162 #define RIII_CM_CLKSEL_GFX_VAL RIII_CLKSEL_GFX
164 /* 2420-PRCM II 600MHz core */
168 #define RII_CM_CLKSEL1_CORE_VAL RII_CLKSEL_USB | \
169 RXX_CLKSEL_SSI | RXX_CLKSEL_VLYNQ | \
170 RX_CLKSEL_DSS2 | RX_CLKSEL_DSS1 | \
171 RII_CLKSEL_L4 | RII_CLKSEL_L3
173 #define RII_CM_CLKSEL_MPU_VAL RII_CLKSEL_MPU
179 #define RII_CM_CLKSEL_DSP_VAL RII_SYNC_IVA | RII_CLKSEL_IVA | \
180 RII_SYNC_DSP | RII_CLKSEL_DSP_IF | \
181 RII_CLKSEL_DSP
183 #define RII_CM_CLKSEL_GFX_VAL RII_CLKSEL_GFX
185 /* 2420-PRCM VII (boot) */
186 #define RVII_CLKSEL_L3 (1 << 0)
187 #define RVII_CLKSEL_L4 (1 << 5)
188 #define RVII_CLKSEL_DSS1 (1 << 8)
189 #define RVII_CLKSEL_DSS2 (0 << 13)
190 #define RVII_CLKSEL_VLYNQ (1 << 15)
191 #define RVII_CLKSEL_SSI (1 << 20)
192 #define RVII_CLKSEL_USB (1 << 25)
194 #define RVII_CM_CLKSEL1_CORE_VAL RVII_CLKSEL_USB | RVII_CLKSEL_SSI | \
195 RVII_CLKSEL_VLYNQ | RVII_CLKSEL_DSS2 | \
196 RVII_CLKSEL_DSS1 | RVII_CLKSEL_L4 | RVII_CLKSEL_L3
199 #define RVII_CM_CLKSEL_MPU_VAL RVII_CLKSEL_MPU
201 #define RVII_CLKSEL_DSP (1 << 0)
202 #define RVII_CLKSEL_DSP_IF (1 << 5)
203 #define RVII_SYNC_DSP (0 << 7)
204 #define RVII_CLKSEL_IVA (1 << 8)
205 #define RVII_SYNC_IVA (0 << 13)
206 #define RVII_CM_CLKSEL_DSP_VAL RVII_SYNC_IVA | RVII_CLKSEL_IVA | RVII_SYNC_DSP | \
207 RVII_CLKSEL_DSP_IF | RVII_CLKSEL_DSP
209 #define RVII_CLKSEL_GFX (1 << 0)
210 #define RVII_CM_CLKSEL_GFX_VAL RVII_CLKSEL_GFX
212 /*-------------------------------------------------------------------------
213 * 2430 Target modes: Along with each configuration the CPU has several
214 * modes which goes along with them. Modes mainly are the addition of
215 * describe DPLL combinations to go along with a ratio.
216 *-------------------------------------------------------------------------*/
218 /* Hardware governed */
219 #define MX_48M_SRC (0 << 3)
220 #define MX_54M_SRC (0 << 5)
221 #define MX_APLLS_CLIKIN_12 (3 << 23)
222 #define MX_APLLS_CLIKIN_13 (2 << 23)
223 #define MX_APLLS_CLIKIN_19_2 (0 << 23)
225 /*
226 * 2430 - standalone, 2*ref*M/(n+1), M/N is for exactness not relock speed
227 * #2 (ratio1) baseport-target
228 * #5a (ratio1) baseport-target, target DPLL = 266*2 = 532MHz
229 */
230 #define M5A_DPLL_MULT_12 (133 << 12)
231 #define M5A_DPLL_DIV_12 (5 << 8)
232 #define M5A_CM_CLKSEL1_PLL_12_VAL MX_48M_SRC | MX_54M_SRC | \
233 M5A_DPLL_DIV_12 | M5A_DPLL_MULT_12 | \
234 MX_APLLS_CLIKIN_12
235 #define M5A_DPLL_MULT_13 (266 << 12)
236 #define M5A_DPLL_DIV_13 (12 << 8)
237 #define M5A_CM_CLKSEL1_PLL_13_VAL MX_48M_SRC | MX_54M_SRC | \
238 M5A_DPLL_DIV_13 | M5A_DPLL_MULT_13 | \
239 MX_APLLS_CLIKIN_13
240 #define M5A_DPLL_MULT_19 (180 << 12)
241 #define M5A_DPLL_DIV_19 (12 << 8)
242 #define M5A_CM_CLKSEL1_PLL_19_VAL MX_48M_SRC | MX_54M_SRC | \
243 M5A_DPLL_DIV_19 | M5A_DPLL_MULT_19 | \
244 MX_APLLS_CLIKIN_19_2
245 /* #5b (ratio1) target DPLL = 200*2 = 400MHz */
246 #define M5B_DPLL_MULT_12 (50 << 12)
247 #define M5B_DPLL_DIV_12 (2 << 8)
248 #define M5B_CM_CLKSEL1_PLL_12_VAL MX_48M_SRC | MX_54M_SRC | \
249 M5B_DPLL_DIV_12 | M5B_DPLL_MULT_12 | \
250 MX_APLLS_CLIKIN_12
251 #define M5B_DPLL_MULT_13 (200 << 12)
252 #define M5B_DPLL_DIV_13 (12 << 8)
254 #define M5B_CM_CLKSEL1_PLL_13_VAL MX_48M_SRC | MX_54M_SRC | \
255 M5B_DPLL_DIV_13 | M5B_DPLL_MULT_13 | \
256 MX_APLLS_CLIKIN_13
257 #define M5B_DPLL_MULT_19 (125 << 12)
258 #define M5B_DPLL_DIV_19 (31 << 8)
259 #define M5B_CM_CLKSEL1_PLL_19_VAL MX_48M_SRC | MX_54M_SRC | \
260 M5B_DPLL_DIV_19 | M5B_DPLL_MULT_19 | \
261 MX_APLLS_CLIKIN_19_2
262 /*
263 * #4 (ratio2)
264 * #3 (ratio2) baseport-target, target DPLL = 330*2 = 660MHz
265 */
266 #define M3_DPLL_MULT_12 (55 << 12)
267 #define M3_DPLL_DIV_12 (1 << 8)
268 #define M3_CM_CLKSEL1_PLL_12_VAL MX_48M_SRC | MX_54M_SRC | \
269 M3_DPLL_DIV_12 | M3_DPLL_MULT_12 | \
270 MX_APLLS_CLIKIN_12
271 #define M3_DPLL_MULT_13 (330 << 12)
272 #define M3_DPLL_DIV_13 (12 << 8)
273 #define M3_CM_CLKSEL1_PLL_13_VAL MX_48M_SRC | MX_54M_SRC | \
274 M3_DPLL_DIV_13 | M3_DPLL_MULT_13 | \
275 MX_APLLS_CLIKIN_13
276 #define M3_DPLL_MULT_19 (275 << 12)
277 #define M3_DPLL_DIV_19 (15 << 8)
278 #define M3_CM_CLKSEL1_PLL_19_VAL MX_48M_SRC | MX_54M_SRC | \
279 M3_DPLL_DIV_19 | M3_DPLL_MULT_19 | \
280 MX_APLLS_CLIKIN_19_2
281 /* boot (boot) */
282 #define MB_DPLL_MULT (1 << 12)
283 #define MB_DPLL_DIV (0 << 8)
284 #define MB_CM_CLKSEL1_PLL_12_VAL MX_48M_SRC | MX_54M_SRC | MB_DPLL_DIV |\
285 MB_DPLL_MULT | MX_APLLS_CLIKIN_12
287 #define MB_CM_CLKSEL1_PLL_13_VAL MX_48M_SRC | MX_54M_SRC | MB_DPLL_DIV |\
288 MB_DPLL_MULT | MX_APLLS_CLIKIN_13
290 #define MB_CM_CLKSEL1_PLL_19_VAL MX_48M_SRC | MX_54M_SRC | MB_DPLL_DIV |\
291 MB_DPLL_MULT | MX_APLLS_CLIKIN_19
293 /*
294 * 2430 - chassis (sedna)
295 * 165 (ratio1) same as above #2
296 * 150 (ratio1)
297 * 133 (ratio2) same as above #4
298 * 110 (ratio2) same as above #3
299 * 104 (ratio2)
300 * boot (boot)
301 */
303 /*
304 * 2420 Equivalent - mode registers
305 * PRCM II , target DPLL = 2*300MHz = 600MHz
306 */
307 #define MII_DPLL_MULT_12 (50 << 12)
308 #define MII_DPLL_DIV_12 (1 << 8)
309 #define MII_CM_CLKSEL1_PLL_12_VAL MX_48M_SRC | MX_54M_SRC | \
310 MII_DPLL_DIV_12 | MII_DPLL_MULT_12 | \
311 MX_APLLS_CLIKIN_12
312 #define MII_DPLL_MULT_13 (300 << 12)
313 #define MII_DPLL_DIV_13 (12 << 8)
314 #define MII_CM_CLKSEL1_PLL_13_VAL MX_48M_SRC | MX_54M_SRC | \
315 MII_DPLL_DIV_13 | MII_DPLL_MULT_13 | \
316 MX_APLLS_CLIKIN_13
318 /* PRCM III target DPLL = 2*266 = 532MHz*/
319 #define MIII_DPLL_MULT_12 (133 << 12)
320 #define MIII_DPLL_DIV_12 (5 << 8)
321 #define MIII_CM_CLKSEL1_PLL_12_VAL MX_48M_SRC | MX_54M_SRC | \
322 MIII_DPLL_DIV_12 | MIII_DPLL_MULT_12 | \
323 MX_APLLS_CLIKIN_12
324 #define MIII_DPLL_MULT_13 (266 << 12)
325 #define MIII_DPLL_DIV_13 (12 << 8)
326 #define MIII_CM_CLKSEL1_PLL_13_VAL MX_48M_SRC | MX_54M_SRC | \
327 MIII_DPLL_DIV_13 | MIII_DPLL_MULT_13 | \
328 MX_APLLS_CLIKIN_13
330 /* PRCM VII (boot bypass) */
331 #define MVII_CM_CLKSEL1_PLL_12_VAL MB_CM_CLKSEL1_PLL_12_VAL
332 #define MVII_CM_CLKSEL1_PLL_13_VAL MB_CM_CLKSEL1_PLL_13_VAL
334 /* High and low operation value */
335 #define MX_CLKSEL2_PLL_2x_VAL (2 << 0)
336 #define MX_CLKSEL2_PLL_1x_VAL (1 << 0)
338 /*
339 * These represent optimal values for common parts, it won't work for all.
340 * As long as you scale down, most parameters are still work, they just
341 * become sub-optimal. The RFR value goes in the oppisite direction. If you
342 * don't adjust it down as your clock period increases the refresh interval
343 * will not be met. Setting all parameters for complete worst case may work,
344 * but may cut memory performance by 2x. Due to errata the DLLs need to be
345 * unlocked and their value needs run time calibration. A dynamic call is
346 * need for that as no single right value exists acorss production samples.
347 *
348 * Only the FULL speed values are given. Current code is such that rate
349 * changes must be made at DPLLoutx2. The actual value adjustment for low
350 * frequency operation will be handled by omap_set_performance()
351 *
352 * By having the boot loader boot up in the fastest L4 speed available likely
353 * will result in something which you can switch between.
354 */
355 #define V24XX_SDRC_RFR_CTRL_133MHz (0x0003de00 | 1)
356 #define V24XX_SDRC_RFR_CTRL_100MHz (0x0002da01 | 1)
360 /* MPU speed defines */
361 #define S12M 12000000
362 #define S13M 13000000
363 #define S19M 19200000
364 #define S26M 26000000
365 #define S100M 100000000
366 #define S133M 133000000
367 #define S150M 150000000
368 #define S165M 165000000
369 #define S200M 200000000
370 #define S266M 266000000
371 #define S300M 300000000
372 #define S330M 330000000
373 #define S400M 400000000
374 #define S532M 532000000
375 #define S600M 600000000
376 #define S660M 660000000
378 /*-------------------------------------------------------------------------
379 * Key dividers which make up a PRCM set. Ratio's for a PRCM are mandated.
380 * xtal_speed, dpll_speed, mpu_speed, CM_CLKSEL_MPU,
381 * CM_CLKSEL_DSP, CM_CLKSEL_GFX, CM_CLKSEL1_CORE, CM_CLKSEL1_PLL,
382 * CM_CLKSEL2_PLL, CM_CLKSEL_MDM
383 *
384 * Filling in table based on H4 boards and 2430-SDPs variants available.
385 * There are quite a few more rates combinations which could be defined.
386 *
387 * When multiple values are defiend the start up will try and choose the
388 * fastest one. If a 'fast' value is defined, then automatically, the /2
389 * one should be included as it can be used. Generally having more that
390 * one fast set does not make sense, as static timings need to be changed
391 * to change the set. The exception is the bypass setting which is
392 * availble for low power bypass.
393 *
394 * Note: This table needs to be sorted, fastest to slowest.
395 *-------------------------------------------------------------------------*/
397 /* PRCM II - FAST */
402 RATE_IN_242X},
408 RATE_IN_242X},
410 /* PRCM III - FAST */
415 RATE_IN_242X},
421 RATE_IN_242X},
423 /* PRCM II - SLOW */
428 RATE_IN_242X},
434 RATE_IN_242X},
436 /* PRCM III - SLOW */
441 RATE_IN_242X},
447 RATE_IN_242X},
449 /* PRCM-VII (boot-bypass) */
454 RATE_IN_242X},
456 /* PRCM-VII (boot-bypass) */
461 RATE_IN_242X},
463 /* PRCM #3 - ratio2 (ES2) - FAST */
468 V24XX_SDRC_RFR_CTRL_110MHz,
469 RATE_IN_243X},
471 /* PRCM #5a - ratio1 - FAST */
476 V24XX_SDRC_RFR_CTRL_133MHz,
477 RATE_IN_243X},
479 /* PRCM #5b - ratio1 - FAST */
484 V24XX_SDRC_RFR_CTRL_100MHz,
485 RATE_IN_243X},
487 /* PRCM #3 - ratio2 (ES2) - SLOW */
492 V24XX_SDRC_RFR_CTRL_110MHz,
493 RATE_IN_243X},
495 /* PRCM #5a - ratio1 - SLOW */
500 V24XX_SDRC_RFR_CTRL_133MHz,
501 RATE_IN_243X},
503 /* PRCM #5b - ratio1 - SLOW*/
508 V24XX_SDRC_RFR_CTRL_100MHz,
509 RATE_IN_243X},
511 /* PRCM-boot/bypass */
516 V24XX_SDRC_RFR_CTRL_BYPASS,
517 RATE_IN_243X},
519 /* PRCM-boot/bypass */
524 V24XX_SDRC_RFR_CTRL_BYPASS,
525 RATE_IN_243X},
528 };
530 /*-------------------------------------------------------------------------
531 * 24xx clock tree.
532 *
533 * NOTE:In many cases here we are assigning a 'default' parent. In many
534 * cases the parent is selectable. The get/set parent calls will also
535 * switch sources.
536 *
537 * Many some clocks say always_enabled, but they can be auto idled for
538 * power savings. They will always be available upon clock request.
539 *
540 * Several sources are given initial rates which may be wrong, this will
541 * be fixed up in the init func.
542 *
543 * Things are broadly separated below by clock domains. It is
544 * noteworthy that most periferals have dependencies on multiple clock
545 * domains. Many get their interface clocks from the L4 domain, but get
546 * functional clocks from fixed sources or other core domain derived
547 * clocks.
548 *-------------------------------------------------------------------------*/
550 /* Base external input clocks */
556 };
558 /* Typical 12/13MHz in standalone mode, will be 26Mhz in chassis mode */
564 };
566 /* With out modem likely 12MHz, with modem likely 13MHz */
575 };
583 };
585 /*
586 * Analog domain root source clocks
587 */
589 /* dpll_ck, is broken out in to special cases through clksel */
596 };
607 };
618 };
620 /*
621 * PRCM digital base sources
622 */
633 };
641 };
649 };
660 };
672 };
683 };
685 /* Secure timer, only available in secure mode */
691 };
704 };
706 /* In 2430, new in 2420 ES2 */
718 };
728 };
730 /*
731 * MPU clock domain
732 * Clocks:
733 * MPU_FCLK, MPU_ICLK
734 * INT_M_FCLK, INT_M_I_CLK
735 *
736 * - Individual clocks are hardware managed.
737 * - Base divider comes from: CM_CLKSEL_MPU
738 *
739 */
748 };
750 /*
751 * DSP (2430-IVA2.1) (2420-UMA+IVA1) clock domain
752 * Clocks:
753 * 2430: IVA2.1_FCLK, IVA2.1_ICLK
754 * 2420: UMA_FCLK, UMA_ICLK, IVA_MPU, IVA_COP
755 */
761 CONFIG_PARTICIPANT,
766 };
775 };
777 /*
778 * Won't be too specific here. The core clock comes into this block
779 * it is divided then tee'ed. One branch goes directly to xyz enable
780 * controls. The other branch gets further divided by 2 then possibly
781 * routed into a synchronizer and out of clocks abc.
782 */
792 };
803 };
814 };
816 /* IVA1 mpu/int/i/f clocks are /2 of parent */
824 };
826 /*
827 * L3 clock domain
828 * L3 clocks are used for both interface and functional clocks to
829 * multiple entities. Some of these clocks are completely managed
830 * by hardware, and some others allow software control. Hardware
831 * managed ones general are based on directly CLK_REQ signals and
832 * various auto idle settings. The functional spec sets many of these
833 * as 'tie-high' for their enables.
834 *
835 * I-CLOCKS:
836 * L3-Interconnect, SMS, GPMC, SDRC, OCM_RAM, OCM_ROM, SDMA
837 * CAM, HS-USB.
838 * F-CLOCK
839 * SSI.
840 *
841 * GPMC memories and SDRC have timing and clock sensitive registers which
842 * may very well need notification when the clock changes. Currently for low
843 * operating points, these are taken care of in sleep.S.
844 */
851 RATE_PROPAGATES,
854 };
861 CONFIG_PARTICIPANT,
866 };
868 /*
869 * SSI is in L3 management domain, its direct parent is core not l3,
870 * many core power domain entities are grouped into the L3 clock
871 * domain.
872 * SSI_SSR_FCLK, SSI_SST_FCLK, SSI_L4_CLIK
873 *
874 * ssr = core/1/2/3/4/5, sst = 1/2 ssr.
875 */
885 };
887 /*
888 * GFX clock domain
889 * Clocks:
890 * GFX_FCLK, GFX_ICLK
891 * GFX_CG1(2d), GFX_CG2(3d)
892 *
893 * GFX_FCLK runs from L3, and is divided by (1,2,3,4)
894 * The 2d and 3d clocks run at a hardware determined
895 * divided value of fclk.
896 *
897 */
907 };
918 };
924 RATE_CKCTL,
928 };
930 /*
931 * Modem clock domain (2430)
932 * CLOCKS:
933 * MDM_OSC_CLK
934 * MDM_ICLK
935 */
945 };
955 };
957 /*
958 * L4 clock management domain
959 *
960 * This domain contains lots of interface clocks from the L4 interface, some
961 * functional clocks. Fixed APLL functional source clocks are managed in
962 * this domain.
963 */
972 };
981 };
983 /*
984 * DSS clock domain
985 * CLOCKs:
986 * DSS_L4_ICLK, DSS_L3_ICLK,
987 * DSS_CLK1, DSS_CLK2, DSS_54MHz_CLK
988 *
989 * DSS is both initiator and target.
990 */
998 };
1010 };
1021 };
1032 };
1034 /*
1035 * CORE power domain ICLK & FCLK defines.
1036 * Many of the these can have more than one possible parent. Entries
1037 * here will likely have an L4 interface parent, and may have multiple
1038 * functional clock parents.
1039 */
1047 };
1053 CM_WKUP_SEL1,
1058 };
1067 };
1073 CM_CORE_SEL2,
1078 };
1087 };
1093 CM_CORE_SEL2,
1098 };
1107 };
1113 CM_CORE_SEL2,
1118 };
1127 };
1133 CM_CORE_SEL2,
1138 };
1147 };
1153 CM_CORE_SEL2,
1158 };
1167 };
1173 CM_CORE_SEL2,
1178 };
1187 };
1193 CM_CORE_SEL2,
1198 };
1207 };
1213 CM_CORE_SEL2,
1218 };
1227 };
1233 CM_CORE_SEL2,
1238 };
1247 };
1253 CM_CORE_SEL2,
1258 };
1267 };
1273 CM_CORE_SEL2,
1278 };
1287 };
1296 };
1305 };
1314 };
1323 };
1332 };
1341 };
1350 };
1359 };
1368 };
1377 };
1386 };
1395 };
1404 };
1413 };
1422 };
1431 };
1440 };
1449 };
1458 };
1467 };
1476 };
1485 };
1494 };
1503 };
1512 };
1521 };
1529 };
1537 };
1545 };
1554 };
1563 };
1572 };
1581 };
1590 };
1599 };
1608 };
1617 };
1626 };
1635 };
1644 };
1653 };
1662 };
1671 };
1680 };
1689 };
1698 };
1708 };
1718 };
1727 };
1737 };
1747 };
1756 };
1765 };
1775 };
1784 };
1793 };
1802 };
1811 };
1820 };
1829 };
1838 };
1847 };
1856 };
1865 };
1874 };
1883 };
1892 };
1901 };
1910 };
1919 };
1928 };
1930 /*
1931 * This clock is a composite clock which does entire set changes then
1932 * forces a rebalance. It keys on the MPU speed, but it really could
1933 * be any key speed part of a set in the rate table.
1934 *
1935 * to really change a set, you need memory table sets which get changed
1936 * in sram, pre-notifiers & post notifiers, changing the top set, without
1937 * having low level display recalc's won't work... this is why dpm notifiers
1938 * work, isr's off, walk a list of clocks already _off_ and not messing with
1939 * the bus.
1940 *
1941 * This clock should have no parent. It embodies the entire upper level
1942 * active set. A parent will mess up some of the init also.
1943 */
1952 };
1955 /* external root sources */
1960 /* internal analog sources */
1964 /* internal prcm root sources */
1975 /* mpu domain clocks */
1977 /* dsp domain clocks */
1984 /* GFX domain clocks */
1988 /* Modem domain clocks */
1991 /* DSS domain clocks */
1996 /* L3 domain clocks */
2000 /* L4 domain clocks */
2003 /* virtual meta-group clock */
2005 /* general l4 interface ck, multi-parent functional clk */
2102 };
2104 #endif