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1/*
2 * Copyright (C) STMicroelectronics 2009
3 * Copyright (C) ST-Ericsson SA 2010
4 *
5 * License Terms: GNU General Public License v2
6 * Author: Kumar Sanghvi <kumar.sanghvi@stericsson.com>
7 * Author: Sundar Iyer <sundar.iyer@stericsson.com>
8 * Author: Mattias Nilsson <mattias.i.nilsson@stericsson.com>
9 *
10 * U8500 PRCM Unit interface driver
11 *
12 */
13#include <linux/module.h>
14#include <linux/kernel.h>
15#include <linux/delay.h>
16#include <linux/errno.h>
17#include <linux/err.h>
18#include <linux/spinlock.h>
19#include <linux/io.h>
20#include <linux/slab.h>
21#include <linux/mutex.h>
22#include <linux/completion.h>
23#include <linux/irq.h>
24#include <linux/jiffies.h>
25#include <linux/bitops.h>
26#include <linux/fs.h>
27#include <linux/of.h>
28#include <linux/of_irq.h>
29#include <linux/platform_device.h>
30#include <linux/uaccess.h>
31#include <linux/mfd/core.h>
32#include <linux/mfd/dbx500-prcmu.h>
33#include <linux/mfd/abx500/ab8500.h>
34#include <linux/regulator/db8500-prcmu.h>
35#include <linux/regulator/machine.h>
36#include <linux/cpufreq.h>
37#include <linux/platform_data/ux500_wdt.h>
38#include <linux/platform_data/db8500_thermal.h>
39#include "dbx500-prcmu-regs.h"
40
41/* Index of different voltages to be used when accessing AVSData */
42#define PRCM_AVS_BASE 0x2FC
43#define PRCM_AVS_VBB_RET (PRCM_AVS_BASE + 0x0)
44#define PRCM_AVS_VBB_MAX_OPP (PRCM_AVS_BASE + 0x1)
45#define PRCM_AVS_VBB_100_OPP (PRCM_AVS_BASE + 0x2)
46#define PRCM_AVS_VBB_50_OPP (PRCM_AVS_BASE + 0x3)
47#define PRCM_AVS_VARM_MAX_OPP (PRCM_AVS_BASE + 0x4)
48#define PRCM_AVS_VARM_100_OPP (PRCM_AVS_BASE + 0x5)
49#define PRCM_AVS_VARM_50_OPP (PRCM_AVS_BASE + 0x6)
50#define PRCM_AVS_VARM_RET (PRCM_AVS_BASE + 0x7)
51#define PRCM_AVS_VAPE_100_OPP (PRCM_AVS_BASE + 0x8)
52#define PRCM_AVS_VAPE_50_OPP (PRCM_AVS_BASE + 0x9)
53#define PRCM_AVS_VMOD_100_OPP (PRCM_AVS_BASE + 0xA)
54#define PRCM_AVS_VMOD_50_OPP (PRCM_AVS_BASE + 0xB)
55#define PRCM_AVS_VSAFE (PRCM_AVS_BASE + 0xC)
56
57#define PRCM_AVS_VOLTAGE 0
58#define PRCM_AVS_VOLTAGE_MASK 0x3f
59#define PRCM_AVS_ISSLOWSTARTUP 6
60#define PRCM_AVS_ISSLOWSTARTUP_MASK (1 << PRCM_AVS_ISSLOWSTARTUP)
61#define PRCM_AVS_ISMODEENABLE 7
62#define PRCM_AVS_ISMODEENABLE_MASK (1 << PRCM_AVS_ISMODEENABLE)
63
64#define PRCM_BOOT_STATUS 0xFFF
65#define PRCM_ROMCODE_A2P 0xFFE
66#define PRCM_ROMCODE_P2A 0xFFD
67#define PRCM_XP70_CUR_PWR_STATE 0xFFC /* 4 BYTES */
68
69#define PRCM_SW_RST_REASON 0xFF8 /* 2 bytes */
70
71#define _PRCM_MBOX_HEADER 0xFE8 /* 16 bytes */
72#define PRCM_MBOX_HEADER_REQ_MB0 (_PRCM_MBOX_HEADER + 0x0)
73#define PRCM_MBOX_HEADER_REQ_MB1 (_PRCM_MBOX_HEADER + 0x1)
74#define PRCM_MBOX_HEADER_REQ_MB2 (_PRCM_MBOX_HEADER + 0x2)
75#define PRCM_MBOX_HEADER_REQ_MB3 (_PRCM_MBOX_HEADER + 0x3)
76#define PRCM_MBOX_HEADER_REQ_MB4 (_PRCM_MBOX_HEADER + 0x4)
77#define PRCM_MBOX_HEADER_REQ_MB5 (_PRCM_MBOX_HEADER + 0x5)
78#define PRCM_MBOX_HEADER_ACK_MB0 (_PRCM_MBOX_HEADER + 0x8)
79
80/* Req Mailboxes */
81#define PRCM_REQ_MB0 0xFDC /* 12 bytes */
82#define PRCM_REQ_MB1 0xFD0 /* 12 bytes */
83#define PRCM_REQ_MB2 0xFC0 /* 16 bytes */
84#define PRCM_REQ_MB3 0xE4C /* 372 bytes */
85#define PRCM_REQ_MB4 0xE48 /* 4 bytes */
86#define PRCM_REQ_MB5 0xE44 /* 4 bytes */
87
88/* Ack Mailboxes */
89#define PRCM_ACK_MB0 0xE08 /* 52 bytes */
90#define PRCM_ACK_MB1 0xE04 /* 4 bytes */
91#define PRCM_ACK_MB2 0xE00 /* 4 bytes */
92#define PRCM_ACK_MB3 0xDFC /* 4 bytes */
93#define PRCM_ACK_MB4 0xDF8 /* 4 bytes */
94#define PRCM_ACK_MB5 0xDF4 /* 4 bytes */
95
96/* Mailbox 0 headers */
97#define MB0H_POWER_STATE_TRANS 0
98#define MB0H_CONFIG_WAKEUPS_EXE 1
99#define MB0H_READ_WAKEUP_ACK 3
100#define MB0H_CONFIG_WAKEUPS_SLEEP 4
101
102#define MB0H_WAKEUP_EXE 2
103#define MB0H_WAKEUP_SLEEP 5
104
105/* Mailbox 0 REQs */
106#define PRCM_REQ_MB0_AP_POWER_STATE (PRCM_REQ_MB0 + 0x0)
107#define PRCM_REQ_MB0_AP_PLL_STATE (PRCM_REQ_MB0 + 0x1)
108#define PRCM_REQ_MB0_ULP_CLOCK_STATE (PRCM_REQ_MB0 + 0x2)
109#define PRCM_REQ_MB0_DO_NOT_WFI (PRCM_REQ_MB0 + 0x3)
110#define PRCM_REQ_MB0_WAKEUP_8500 (PRCM_REQ_MB0 + 0x4)
111#define PRCM_REQ_MB0_WAKEUP_4500 (PRCM_REQ_MB0 + 0x8)
112
113/* Mailbox 0 ACKs */
114#define PRCM_ACK_MB0_AP_PWRSTTR_STATUS (PRCM_ACK_MB0 + 0x0)
115#define PRCM_ACK_MB0_READ_POINTER (PRCM_ACK_MB0 + 0x1)
116#define PRCM_ACK_MB0_WAKEUP_0_8500 (PRCM_ACK_MB0 + 0x4)
117#define PRCM_ACK_MB0_WAKEUP_0_4500 (PRCM_ACK_MB0 + 0x8)
118#define PRCM_ACK_MB0_WAKEUP_1_8500 (PRCM_ACK_MB0 + 0x1C)
119#define PRCM_ACK_MB0_WAKEUP_1_4500 (PRCM_ACK_MB0 + 0x20)
120#define PRCM_ACK_MB0_EVENT_4500_NUMBERS 20
121
122/* Mailbox 1 headers */
123#define MB1H_ARM_APE_OPP 0x0
124#define MB1H_RESET_MODEM 0x2
125#define MB1H_REQUEST_APE_OPP_100_VOLT 0x3
126#define MB1H_RELEASE_APE_OPP_100_VOLT 0x4
127#define MB1H_RELEASE_USB_WAKEUP 0x5
128#define MB1H_PLL_ON_OFF 0x6
129
130/* Mailbox 1 Requests */
131#define PRCM_REQ_MB1_ARM_OPP (PRCM_REQ_MB1 + 0x0)
132#define PRCM_REQ_MB1_APE_OPP (PRCM_REQ_MB1 + 0x1)
133#define PRCM_REQ_MB1_PLL_ON_OFF (PRCM_REQ_MB1 + 0x4)
134#define PLL_SOC0_OFF 0x1
135#define PLL_SOC0_ON 0x2
136#define PLL_SOC1_OFF 0x4
137#define PLL_SOC1_ON 0x8
138
139/* Mailbox 1 ACKs */
140#define PRCM_ACK_MB1_CURRENT_ARM_OPP (PRCM_ACK_MB1 + 0x0)
141#define PRCM_ACK_MB1_CURRENT_APE_OPP (PRCM_ACK_MB1 + 0x1)
142#define PRCM_ACK_MB1_APE_VOLTAGE_STATUS (PRCM_ACK_MB1 + 0x2)
143#define PRCM_ACK_MB1_DVFS_STATUS (PRCM_ACK_MB1 + 0x3)
144
145/* Mailbox 2 headers */
146#define MB2H_DPS 0x0
147#define MB2H_AUTO_PWR 0x1
148
149/* Mailbox 2 REQs */
150#define PRCM_REQ_MB2_SVA_MMDSP (PRCM_REQ_MB2 + 0x0)
151#define PRCM_REQ_MB2_SVA_PIPE (PRCM_REQ_MB2 + 0x1)
152#define PRCM_REQ_MB2_SIA_MMDSP (PRCM_REQ_MB2 + 0x2)
153#define PRCM_REQ_MB2_SIA_PIPE (PRCM_REQ_MB2 + 0x3)
154#define PRCM_REQ_MB2_SGA (PRCM_REQ_MB2 + 0x4)
155#define PRCM_REQ_MB2_B2R2_MCDE (PRCM_REQ_MB2 + 0x5)
156#define PRCM_REQ_MB2_ESRAM12 (PRCM_REQ_MB2 + 0x6)
157#define PRCM_REQ_MB2_ESRAM34 (PRCM_REQ_MB2 + 0x7)
158#define PRCM_REQ_MB2_AUTO_PM_SLEEP (PRCM_REQ_MB2 + 0x8)
159#define PRCM_REQ_MB2_AUTO_PM_IDLE (PRCM_REQ_MB2 + 0xC)
160
161/* Mailbox 2 ACKs */
162#define PRCM_ACK_MB2_DPS_STATUS (PRCM_ACK_MB2 + 0x0)
163#define HWACC_PWR_ST_OK 0xFE
164
165/* Mailbox 3 headers */
166#define MB3H_ANC 0x0
167#define MB3H_SIDETONE 0x1
168#define MB3H_SYSCLK 0xE
169
170/* Mailbox 3 Requests */
171#define PRCM_REQ_MB3_ANC_FIR_COEFF (PRCM_REQ_MB3 + 0x0)
172#define PRCM_REQ_MB3_ANC_IIR_COEFF (PRCM_REQ_MB3 + 0x20)
173#define PRCM_REQ_MB3_ANC_SHIFTER (PRCM_REQ_MB3 + 0x60)
174#define PRCM_REQ_MB3_ANC_WARP (PRCM_REQ_MB3 + 0x64)
175#define PRCM_REQ_MB3_SIDETONE_FIR_GAIN (PRCM_REQ_MB3 + 0x68)
176#define PRCM_REQ_MB3_SIDETONE_FIR_COEFF (PRCM_REQ_MB3 + 0x6C)
177#define PRCM_REQ_MB3_SYSCLK_MGT (PRCM_REQ_MB3 + 0x16C)
178
179/* Mailbox 4 headers */
180#define MB4H_DDR_INIT 0x0
181#define MB4H_MEM_ST 0x1
182#define MB4H_HOTDOG 0x12
183#define MB4H_HOTMON 0x13
184#define MB4H_HOT_PERIOD 0x14
185#define MB4H_A9WDOG_CONF 0x16
186#define MB4H_A9WDOG_EN 0x17
187#define MB4H_A9WDOG_DIS 0x18
188#define MB4H_A9WDOG_LOAD 0x19
189#define MB4H_A9WDOG_KICK 0x20
190
191/* Mailbox 4 Requests */
192#define PRCM_REQ_MB4_DDR_ST_AP_SLEEP_IDLE (PRCM_REQ_MB4 + 0x0)
193#define PRCM_REQ_MB4_DDR_ST_AP_DEEP_IDLE (PRCM_REQ_MB4 + 0x1)
194#define PRCM_REQ_MB4_ESRAM0_ST (PRCM_REQ_MB4 + 0x3)
195#define PRCM_REQ_MB4_HOTDOG_THRESHOLD (PRCM_REQ_MB4 + 0x0)
196#define PRCM_REQ_MB4_HOTMON_LOW (PRCM_REQ_MB4 + 0x0)
197#define PRCM_REQ_MB4_HOTMON_HIGH (PRCM_REQ_MB4 + 0x1)
198#define PRCM_REQ_MB4_HOTMON_CONFIG (PRCM_REQ_MB4 + 0x2)
199#define PRCM_REQ_MB4_HOT_PERIOD (PRCM_REQ_MB4 + 0x0)
200#define HOTMON_CONFIG_LOW BIT(0)
201#define HOTMON_CONFIG_HIGH BIT(1)
202#define PRCM_REQ_MB4_A9WDOG_0 (PRCM_REQ_MB4 + 0x0)
203#define PRCM_REQ_MB4_A9WDOG_1 (PRCM_REQ_MB4 + 0x1)
204#define PRCM_REQ_MB4_A9WDOG_2 (PRCM_REQ_MB4 + 0x2)
205#define PRCM_REQ_MB4_A9WDOG_3 (PRCM_REQ_MB4 + 0x3)
206#define A9WDOG_AUTO_OFF_EN BIT(7)
207#define A9WDOG_AUTO_OFF_DIS 0
208#define A9WDOG_ID_MASK 0xf
209
210/* Mailbox 5 Requests */
211#define PRCM_REQ_MB5_I2C_SLAVE_OP (PRCM_REQ_MB5 + 0x0)
212#define PRCM_REQ_MB5_I2C_HW_BITS (PRCM_REQ_MB5 + 0x1)
213#define PRCM_REQ_MB5_I2C_REG (PRCM_REQ_MB5 + 0x2)
214#define PRCM_REQ_MB5_I2C_VAL (PRCM_REQ_MB5 + 0x3)
215#define PRCMU_I2C_WRITE(slave) (((slave) << 1) | BIT(6))
216#define PRCMU_I2C_READ(slave) (((slave) << 1) | BIT(0) | BIT(6))
217#define PRCMU_I2C_STOP_EN BIT(3)
218
219/* Mailbox 5 ACKs */
220#define PRCM_ACK_MB5_I2C_STATUS (PRCM_ACK_MB5 + 0x1)
221#define PRCM_ACK_MB5_I2C_VAL (PRCM_ACK_MB5 + 0x3)
222#define I2C_WR_OK 0x1
223#define I2C_RD_OK 0x2
224
225#define NUM_MB 8
226#define MBOX_BIT BIT
227#define ALL_MBOX_BITS (MBOX_BIT(NUM_MB) - 1)
228
229/*
230 * Wakeups/IRQs
231 */
232
233#define WAKEUP_BIT_RTC BIT(0)
234#define WAKEUP_BIT_RTT0 BIT(1)
235#define WAKEUP_BIT_RTT1 BIT(2)
236#define WAKEUP_BIT_HSI0 BIT(3)
237#define WAKEUP_BIT_HSI1 BIT(4)
238#define WAKEUP_BIT_CA_WAKE BIT(5)
239#define WAKEUP_BIT_USB BIT(6)
240#define WAKEUP_BIT_ABB BIT(7)
241#define WAKEUP_BIT_ABB_FIFO BIT(8)
242#define WAKEUP_BIT_SYSCLK_OK BIT(9)
243#define WAKEUP_BIT_CA_SLEEP BIT(10)
244#define WAKEUP_BIT_AC_WAKE_ACK BIT(11)
245#define WAKEUP_BIT_SIDE_TONE_OK BIT(12)
246#define WAKEUP_BIT_ANC_OK BIT(13)
247#define WAKEUP_BIT_SW_ERROR BIT(14)
248#define WAKEUP_BIT_AC_SLEEP_ACK BIT(15)
249#define WAKEUP_BIT_ARM BIT(17)
250#define WAKEUP_BIT_HOTMON_LOW BIT(18)
251#define WAKEUP_BIT_HOTMON_HIGH BIT(19)
252#define WAKEUP_BIT_MODEM_SW_RESET_REQ BIT(20)
253#define WAKEUP_BIT_GPIO0 BIT(23)
254#define WAKEUP_BIT_GPIO1 BIT(24)
255#define WAKEUP_BIT_GPIO2 BIT(25)
256#define WAKEUP_BIT_GPIO3 BIT(26)
257#define WAKEUP_BIT_GPIO4 BIT(27)
258#define WAKEUP_BIT_GPIO5 BIT(28)
259#define WAKEUP_BIT_GPIO6 BIT(29)
260#define WAKEUP_BIT_GPIO7 BIT(30)
261#define WAKEUP_BIT_GPIO8 BIT(31)
262
263static struct {
264 bool valid;
265 struct prcmu_fw_version version;
266} fw_info;
267
268static struct irq_domain *db8500_irq_domain;
269
270/*
271 * This vector maps irq numbers to the bits in the bit field used in
272 * communication with the PRCMU firmware.
273 *
274 * The reason for having this is to keep the irq numbers contiguous even though
275 * the bits in the bit field are not. (The bits also have a tendency to move
276 * around, to further complicate matters.)
277 */
278#define IRQ_INDEX(_name) ((IRQ_PRCMU_##_name))
279#define IRQ_ENTRY(_name)[IRQ_INDEX(_name)] = (WAKEUP_BIT_##_name)
280
281#define IRQ_PRCMU_RTC 0
282#define IRQ_PRCMU_RTT0 1
283#define IRQ_PRCMU_RTT1 2
284#define IRQ_PRCMU_HSI0 3
285#define IRQ_PRCMU_HSI1 4
286#define IRQ_PRCMU_CA_WAKE 5
287#define IRQ_PRCMU_USB 6
288#define IRQ_PRCMU_ABB 7
289#define IRQ_PRCMU_ABB_FIFO 8
290#define IRQ_PRCMU_ARM 9
291#define IRQ_PRCMU_MODEM_SW_RESET_REQ 10
292#define IRQ_PRCMU_GPIO0 11
293#define IRQ_PRCMU_GPIO1 12
294#define IRQ_PRCMU_GPIO2 13
295#define IRQ_PRCMU_GPIO3 14
296#define IRQ_PRCMU_GPIO4 15
297#define IRQ_PRCMU_GPIO5 16
298#define IRQ_PRCMU_GPIO6 17
299#define IRQ_PRCMU_GPIO7 18
300#define IRQ_PRCMU_GPIO8 19
301#define IRQ_PRCMU_CA_SLEEP 20
302#define IRQ_PRCMU_HOTMON_LOW 21
303#define IRQ_PRCMU_HOTMON_HIGH 22
304#define NUM_PRCMU_WAKEUPS 23
305
306static u32 prcmu_irq_bit[NUM_PRCMU_WAKEUPS] = {
307 IRQ_ENTRY(RTC),
308 IRQ_ENTRY(RTT0),
309 IRQ_ENTRY(RTT1),
310 IRQ_ENTRY(HSI0),
311 IRQ_ENTRY(HSI1),
312 IRQ_ENTRY(CA_WAKE),
313 IRQ_ENTRY(USB),
314 IRQ_ENTRY(ABB),
315 IRQ_ENTRY(ABB_FIFO),
316 IRQ_ENTRY(CA_SLEEP),
317 IRQ_ENTRY(ARM),
318 IRQ_ENTRY(HOTMON_LOW),
319 IRQ_ENTRY(HOTMON_HIGH),
320 IRQ_ENTRY(MODEM_SW_RESET_REQ),
321 IRQ_ENTRY(GPIO0),
322 IRQ_ENTRY(GPIO1),
323 IRQ_ENTRY(GPIO2),
324 IRQ_ENTRY(GPIO3),
325 IRQ_ENTRY(GPIO4),
326 IRQ_ENTRY(GPIO5),
327 IRQ_ENTRY(GPIO6),
328 IRQ_ENTRY(GPIO7),
329 IRQ_ENTRY(GPIO8)
330};
331
332#define VALID_WAKEUPS (BIT(NUM_PRCMU_WAKEUP_INDICES) - 1)
333#define WAKEUP_ENTRY(_name)[PRCMU_WAKEUP_INDEX_##_name] = (WAKEUP_BIT_##_name)
334static u32 prcmu_wakeup_bit[NUM_PRCMU_WAKEUP_INDICES] = {
335 WAKEUP_ENTRY(RTC),
336 WAKEUP_ENTRY(RTT0),
337 WAKEUP_ENTRY(RTT1),
338 WAKEUP_ENTRY(HSI0),
339 WAKEUP_ENTRY(HSI1),
340 WAKEUP_ENTRY(USB),
341 WAKEUP_ENTRY(ABB),
342 WAKEUP_ENTRY(ABB_FIFO),
343 WAKEUP_ENTRY(ARM)
344};
345
346/*
347 * mb0_transfer - state needed for mailbox 0 communication.
348 * @lock: The transaction lock.
349 * @dbb_events_lock: A lock used to handle concurrent access to (parts of)
350 * the request data.
351 * @mask_work: Work structure used for (un)masking wakeup interrupts.
352 * @req: Request data that need to persist between requests.
353 */
354static struct {
355 spinlock_t lock;
356 spinlock_t dbb_irqs_lock;
357 struct work_struct mask_work;
358 struct mutex ac_wake_lock;
359 struct completion ac_wake_work;
360 struct {
361 u32 dbb_irqs;
362 u32 dbb_wakeups;
363 u32 abb_events;
364 } req;
365} mb0_transfer;
366
367/*
368 * mb1_transfer - state needed for mailbox 1 communication.
369 * @lock: The transaction lock.
370 * @work: The transaction completion structure.
371 * @ape_opp: The current APE OPP.
372 * @ack: Reply ("acknowledge") data.
373 */
374static struct {
375 struct mutex lock;
376 struct completion work;
377 u8 ape_opp;
378 struct {
379 u8 header;
380 u8 arm_opp;
381 u8 ape_opp;
382 u8 ape_voltage_status;
383 } ack;
384} mb1_transfer;
385
386/*
387 * mb2_transfer - state needed for mailbox 2 communication.
388 * @lock: The transaction lock.
389 * @work: The transaction completion structure.
390 * @auto_pm_lock: The autonomous power management configuration lock.
391 * @auto_pm_enabled: A flag indicating whether autonomous PM is enabled.
392 * @req: Request data that need to persist between requests.
393 * @ack: Reply ("acknowledge") data.
394 */
395static struct {
396 struct mutex lock;
397 struct completion work;
398 spinlock_t auto_pm_lock;
399 bool auto_pm_enabled;
400 struct {
401 u8 status;
402 } ack;
403} mb2_transfer;
404
405/*
406 * mb3_transfer - state needed for mailbox 3 communication.
407 * @lock: The request lock.
408 * @sysclk_lock: A lock used to handle concurrent sysclk requests.
409 * @sysclk_work: Work structure used for sysclk requests.
410 */
411static struct {
412 spinlock_t lock;
413 struct mutex sysclk_lock;
414 struct completion sysclk_work;
415} mb3_transfer;
416
417/*
418 * mb4_transfer - state needed for mailbox 4 communication.
419 * @lock: The transaction lock.
420 * @work: The transaction completion structure.
421 */
422static struct {
423 struct mutex lock;
424 struct completion work;
425} mb4_transfer;
426
427/*
428 * mb5_transfer - state needed for mailbox 5 communication.
429 * @lock: The transaction lock.
430 * @work: The transaction completion structure.
431 * @ack: Reply ("acknowledge") data.
432 */
433static struct {
434 struct mutex lock;
435 struct completion work;
436 struct {
437 u8 status;
438 u8 value;
439 } ack;
440} mb5_transfer;
441
442static atomic_t ac_wake_req_state = ATOMIC_INIT(0);
443
444/* Spinlocks */
445static DEFINE_SPINLOCK(prcmu_lock);
446static DEFINE_SPINLOCK(clkout_lock);
447
448/* Global var to runtime determine TCDM base for v2 or v1 */
449static __iomem void *tcdm_base;
450static __iomem void *prcmu_base;
451
452struct clk_mgt {
453 u32 offset;
454 u32 pllsw;
455 int branch;
456 bool clk38div;
457};
458
459enum {
460 PLL_RAW,
461 PLL_FIX,
462 PLL_DIV
463};
464
465static DEFINE_SPINLOCK(clk_mgt_lock);
466
467#define CLK_MGT_ENTRY(_name, _branch, _clk38div)[PRCMU_##_name] = \
468 { (PRCM_##_name##_MGT), 0 , _branch, _clk38div}
469static struct clk_mgt clk_mgt[PRCMU_NUM_REG_CLOCKS] = {
470 CLK_MGT_ENTRY(SGACLK, PLL_DIV, false),
471 CLK_MGT_ENTRY(UARTCLK, PLL_FIX, true),
472 CLK_MGT_ENTRY(MSP02CLK, PLL_FIX, true),
473 CLK_MGT_ENTRY(MSP1CLK, PLL_FIX, true),
474 CLK_MGT_ENTRY(I2CCLK, PLL_FIX, true),
475 CLK_MGT_ENTRY(SDMMCCLK, PLL_DIV, true),
476 CLK_MGT_ENTRY(SLIMCLK, PLL_FIX, true),
477 CLK_MGT_ENTRY(PER1CLK, PLL_DIV, true),
478 CLK_MGT_ENTRY(PER2CLK, PLL_DIV, true),
479 CLK_MGT_ENTRY(PER3CLK, PLL_DIV, true),
480 CLK_MGT_ENTRY(PER5CLK, PLL_DIV, true),
481 CLK_MGT_ENTRY(PER6CLK, PLL_DIV, true),
482 CLK_MGT_ENTRY(PER7CLK, PLL_DIV, true),
483 CLK_MGT_ENTRY(LCDCLK, PLL_FIX, true),
484 CLK_MGT_ENTRY(BMLCLK, PLL_DIV, true),
485 CLK_MGT_ENTRY(HSITXCLK, PLL_DIV, true),
486 CLK_MGT_ENTRY(HSIRXCLK, PLL_DIV, true),
487 CLK_MGT_ENTRY(HDMICLK, PLL_FIX, false),
488 CLK_MGT_ENTRY(APEATCLK, PLL_DIV, true),
489 CLK_MGT_ENTRY(APETRACECLK, PLL_DIV, true),
490 CLK_MGT_ENTRY(MCDECLK, PLL_DIV, true),
491 CLK_MGT_ENTRY(IPI2CCLK, PLL_FIX, true),
492 CLK_MGT_ENTRY(DSIALTCLK, PLL_FIX, false),
493 CLK_MGT_ENTRY(DMACLK, PLL_DIV, true),
494 CLK_MGT_ENTRY(B2R2CLK, PLL_DIV, true),
495 CLK_MGT_ENTRY(TVCLK, PLL_FIX, true),
496 CLK_MGT_ENTRY(SSPCLK, PLL_FIX, true),
497 CLK_MGT_ENTRY(RNGCLK, PLL_FIX, true),
498 CLK_MGT_ENTRY(UICCCLK, PLL_FIX, false),
499};
500
501struct dsiclk {
502 u32 divsel_mask;
503 u32 divsel_shift;
504 u32 divsel;
505};
506
507static struct dsiclk dsiclk[2] = {
508 {
509 .divsel_mask = PRCM_DSI_PLLOUT_SEL_DSI0_PLLOUT_DIVSEL_MASK,
510 .divsel_shift = PRCM_DSI_PLLOUT_SEL_DSI0_PLLOUT_DIVSEL_SHIFT,
511 .divsel = PRCM_DSI_PLLOUT_SEL_PHI,
512 },
513 {
514 .divsel_mask = PRCM_DSI_PLLOUT_SEL_DSI1_PLLOUT_DIVSEL_MASK,
515 .divsel_shift = PRCM_DSI_PLLOUT_SEL_DSI1_PLLOUT_DIVSEL_SHIFT,
516 .divsel = PRCM_DSI_PLLOUT_SEL_PHI,
517 }
518};
519
520struct dsiescclk {
521 u32 en;
522 u32 div_mask;
523 u32 div_shift;
524};
525
526static struct dsiescclk dsiescclk[3] = {
527 {
528 .en = PRCM_DSITVCLK_DIV_DSI0_ESC_CLK_EN,
529 .div_mask = PRCM_DSITVCLK_DIV_DSI0_ESC_CLK_DIV_MASK,
530 .div_shift = PRCM_DSITVCLK_DIV_DSI0_ESC_CLK_DIV_SHIFT,
531 },
532 {
533 .en = PRCM_DSITVCLK_DIV_DSI1_ESC_CLK_EN,
534 .div_mask = PRCM_DSITVCLK_DIV_DSI1_ESC_CLK_DIV_MASK,
535 .div_shift = PRCM_DSITVCLK_DIV_DSI1_ESC_CLK_DIV_SHIFT,
536 },
537 {
538 .en = PRCM_DSITVCLK_DIV_DSI2_ESC_CLK_EN,
539 .div_mask = PRCM_DSITVCLK_DIV_DSI2_ESC_CLK_DIV_MASK,
540 .div_shift = PRCM_DSITVCLK_DIV_DSI2_ESC_CLK_DIV_SHIFT,
541 }
542};
543
544
545/*
546* Used by MCDE to setup all necessary PRCMU registers
547*/
548#define PRCMU_RESET_DSIPLL 0x00004000
549#define PRCMU_UNCLAMP_DSIPLL 0x00400800
550
551#define PRCMU_CLK_PLL_DIV_SHIFT 0
552#define PRCMU_CLK_PLL_SW_SHIFT 5
553#define PRCMU_CLK_38 (1 << 9)
554#define PRCMU_CLK_38_SRC (1 << 10)
555#define PRCMU_CLK_38_DIV (1 << 11)
556
557/* PLLDIV=12, PLLSW=4 (PLLDDR) */
558#define PRCMU_DSI_CLOCK_SETTING 0x0000008C
559
560/* DPI 50000000 Hz */
561#define PRCMU_DPI_CLOCK_SETTING ((1 << PRCMU_CLK_PLL_SW_SHIFT) | \
562 (16 << PRCMU_CLK_PLL_DIV_SHIFT))
563#define PRCMU_DSI_LP_CLOCK_SETTING 0x00000E00
564
565/* D=101, N=1, R=4, SELDIV2=0 */
566#define PRCMU_PLLDSI_FREQ_SETTING 0x00040165
567
568#define PRCMU_ENABLE_PLLDSI 0x00000001
569#define PRCMU_DISABLE_PLLDSI 0x00000000
570#define PRCMU_RELEASE_RESET_DSS 0x0000400C
571#define PRCMU_DSI_PLLOUT_SEL_SETTING 0x00000202
572/* ESC clk, div0=1, div1=1, div2=3 */
573#define PRCMU_ENABLE_ESCAPE_CLOCK_DIV 0x07030101
574#define PRCMU_DISABLE_ESCAPE_CLOCK_DIV 0x00030101
575#define PRCMU_DSI_RESET_SW 0x00000007
576
577#define PRCMU_PLLDSI_LOCKP_LOCKED 0x3
578
579int db8500_prcmu_enable_dsipll(void)
580{
581 int i;
582
583 /* Clear DSIPLL_RESETN */
584 writel(PRCMU_RESET_DSIPLL, PRCM_APE_RESETN_CLR);
585 /* Unclamp DSIPLL in/out */
586 writel(PRCMU_UNCLAMP_DSIPLL, PRCM_MMIP_LS_CLAMP_CLR);
587
588 /* Set DSI PLL FREQ */
589 writel(PRCMU_PLLDSI_FREQ_SETTING, PRCM_PLLDSI_FREQ);
590 writel(PRCMU_DSI_PLLOUT_SEL_SETTING, PRCM_DSI_PLLOUT_SEL);
591 /* Enable Escape clocks */
592 writel(PRCMU_ENABLE_ESCAPE_CLOCK_DIV, PRCM_DSITVCLK_DIV);
593
594 /* Start DSI PLL */
595 writel(PRCMU_ENABLE_PLLDSI, PRCM_PLLDSI_ENABLE);
596 /* Reset DSI PLL */
597 writel(PRCMU_DSI_RESET_SW, PRCM_DSI_SW_RESET);
598 for (i = 0; i < 10; i++) {
599 if ((readl(PRCM_PLLDSI_LOCKP) & PRCMU_PLLDSI_LOCKP_LOCKED)
600 == PRCMU_PLLDSI_LOCKP_LOCKED)
601 break;
602 udelay(100);
603 }
604 /* Set DSIPLL_RESETN */
605 writel(PRCMU_RESET_DSIPLL, PRCM_APE_RESETN_SET);
606 return 0;
607}
608
609int db8500_prcmu_disable_dsipll(void)
610{
611 /* Disable dsi pll */
612 writel(PRCMU_DISABLE_PLLDSI, PRCM_PLLDSI_ENABLE);
613 /* Disable escapeclock */
614 writel(PRCMU_DISABLE_ESCAPE_CLOCK_DIV, PRCM_DSITVCLK_DIV);
615 return 0;
616}
617
618int db8500_prcmu_set_display_clocks(void)
619{
620 unsigned long flags;
621
622 spin_lock_irqsave(&clk_mgt_lock, flags);
623
624 /* Grab the HW semaphore. */
625 while ((readl(PRCM_SEM) & PRCM_SEM_PRCM_SEM) != 0)
626 cpu_relax();
627
628 writel(PRCMU_DSI_CLOCK_SETTING, prcmu_base + PRCM_HDMICLK_MGT);
629 writel(PRCMU_DSI_LP_CLOCK_SETTING, prcmu_base + PRCM_TVCLK_MGT);
630 writel(PRCMU_DPI_CLOCK_SETTING, prcmu_base + PRCM_LCDCLK_MGT);
631
632 /* Release the HW semaphore. */
633 writel(0, PRCM_SEM);
634
635 spin_unlock_irqrestore(&clk_mgt_lock, flags);
636
637 return 0;
638}
639
640u32 db8500_prcmu_read(unsigned int reg)
641{
642 return readl(prcmu_base + reg);
643}
644
645void db8500_prcmu_write(unsigned int reg, u32 value)
646{
647 unsigned long flags;
648
649 spin_lock_irqsave(&prcmu_lock, flags);
650 writel(value, (prcmu_base + reg));
651 spin_unlock_irqrestore(&prcmu_lock, flags);
652}
653
654void db8500_prcmu_write_masked(unsigned int reg, u32 mask, u32 value)
655{
656 u32 val;
657 unsigned long flags;
658
659 spin_lock_irqsave(&prcmu_lock, flags);
660 val = readl(prcmu_base + reg);
661 val = ((val & ~mask) | (value & mask));
662 writel(val, (prcmu_base + reg));
663 spin_unlock_irqrestore(&prcmu_lock, flags);
664}
665
666struct prcmu_fw_version *prcmu_get_fw_version(void)
667{
668 return fw_info.valid ? &fw_info.version : NULL;
669}
670
671bool prcmu_has_arm_maxopp(void)
672{
673 return (readb(tcdm_base + PRCM_AVS_VARM_MAX_OPP) &
674 PRCM_AVS_ISMODEENABLE_MASK) == PRCM_AVS_ISMODEENABLE_MASK;
675}
676
677/**
678 * prcmu_set_rc_a2p - This function is used to run few power state sequences
679 * @val: Value to be set, i.e. transition requested
680 * Returns: 0 on success, -EINVAL on invalid argument
681 *
682 * This function is used to run the following power state sequences -
683 * any state to ApReset, ApDeepSleep to ApExecute, ApExecute to ApDeepSleep
684 */
685int prcmu_set_rc_a2p(enum romcode_write val)
686{
687 if (val < RDY_2_DS || val > RDY_2_XP70_RST)
688 return -EINVAL;
689 writeb(val, (tcdm_base + PRCM_ROMCODE_A2P));
690 return 0;
691}
692
693/**
694 * prcmu_get_rc_p2a - This function is used to get power state sequences
695 * Returns: the power transition that has last happened
696 *
697 * This function can return the following transitions-
698 * any state to ApReset, ApDeepSleep to ApExecute, ApExecute to ApDeepSleep
699 */
700enum romcode_read prcmu_get_rc_p2a(void)
701{
702 return readb(tcdm_base + PRCM_ROMCODE_P2A);
703}
704
705/**
706 * prcmu_get_current_mode - Return the current XP70 power mode
707 * Returns: Returns the current AP(ARM) power mode: init,
708 * apBoot, apExecute, apDeepSleep, apSleep, apIdle, apReset
709 */
710enum ap_pwrst prcmu_get_xp70_current_state(void)
711{
712 return readb(tcdm_base + PRCM_XP70_CUR_PWR_STATE);
713}
714
715/**
716 * prcmu_config_clkout - Configure one of the programmable clock outputs.
717 * @clkout: The CLKOUT number (0 or 1).
718 * @source: The clock to be used (one of the PRCMU_CLKSRC_*).
719 * @div: The divider to be applied.
720 *
721 * Configures one of the programmable clock outputs (CLKOUTs).
722 * @div should be in the range [1,63] to request a configuration, or 0 to
723 * inform that the configuration is no longer requested.
724 */
725int prcmu_config_clkout(u8 clkout, u8 source, u8 div)
726{
727 static int requests[2];
728 int r = 0;
729 unsigned long flags;
730 u32 val;
731 u32 bits;
732 u32 mask;
733 u32 div_mask;
734
735 BUG_ON(clkout > 1);
736 BUG_ON(div > 63);
737 BUG_ON((clkout == 0) && (source > PRCMU_CLKSRC_CLK009));
738
739 if (!div && !requests[clkout])
740 return -EINVAL;
741
742 if (clkout == 0) {
743 div_mask = PRCM_CLKOCR_CLKODIV0_MASK;
744 mask = (PRCM_CLKOCR_CLKODIV0_MASK | PRCM_CLKOCR_CLKOSEL0_MASK);
745 bits = ((source << PRCM_CLKOCR_CLKOSEL0_SHIFT) |
746 (div << PRCM_CLKOCR_CLKODIV0_SHIFT));
747 } else {
748 div_mask = PRCM_CLKOCR_CLKODIV1_MASK;
749 mask = (PRCM_CLKOCR_CLKODIV1_MASK | PRCM_CLKOCR_CLKOSEL1_MASK |
750 PRCM_CLKOCR_CLK1TYPE);
751 bits = ((source << PRCM_CLKOCR_CLKOSEL1_SHIFT) |
752 (div << PRCM_CLKOCR_CLKODIV1_SHIFT));
753 }
754 bits &= mask;
755
756 spin_lock_irqsave(&clkout_lock, flags);
757
758 val = readl(PRCM_CLKOCR);
759 if (val & div_mask) {
760 if (div) {
761 if ((val & mask) != bits) {
762 r = -EBUSY;
763 goto unlock_and_return;
764 }
765 } else {
766 if ((val & mask & ~div_mask) != bits) {
767 r = -EINVAL;
768 goto unlock_and_return;
769 }
770 }
771 }
772 writel((bits | (val & ~mask)), PRCM_CLKOCR);
773 requests[clkout] += (div ? 1 : -1);
774
775unlock_and_return:
776 spin_unlock_irqrestore(&clkout_lock, flags);
777
778 return r;
779}
780
781int db8500_prcmu_set_power_state(u8 state, bool keep_ulp_clk, bool keep_ap_pll)
782{
783 unsigned long flags;
784
785 BUG_ON((state < PRCMU_AP_SLEEP) || (PRCMU_AP_DEEP_IDLE < state));
786
787 spin_lock_irqsave(&mb0_transfer.lock, flags);
788
789 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(0))
790 cpu_relax();
791
792 writeb(MB0H_POWER_STATE_TRANS, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB0));
793 writeb(state, (tcdm_base + PRCM_REQ_MB0_AP_POWER_STATE));
794 writeb((keep_ap_pll ? 1 : 0), (tcdm_base + PRCM_REQ_MB0_AP_PLL_STATE));
795 writeb((keep_ulp_clk ? 1 : 0),
796 (tcdm_base + PRCM_REQ_MB0_ULP_CLOCK_STATE));
797 writeb(0, (tcdm_base + PRCM_REQ_MB0_DO_NOT_WFI));
798 writel(MBOX_BIT(0), PRCM_MBOX_CPU_SET);
799
800 spin_unlock_irqrestore(&mb0_transfer.lock, flags);
801
802 return 0;
803}
804
805u8 db8500_prcmu_get_power_state_result(void)
806{
807 return readb(tcdm_base + PRCM_ACK_MB0_AP_PWRSTTR_STATUS);
808}
809
810/* This function should only be called while mb0_transfer.lock is held. */
811static void config_wakeups(void)
812{
813 const u8 header[2] = {
814 MB0H_CONFIG_WAKEUPS_EXE,
815 MB0H_CONFIG_WAKEUPS_SLEEP
816 };
817 static u32 last_dbb_events;
818 static u32 last_abb_events;
819 u32 dbb_events;
820 u32 abb_events;
821 unsigned int i;
822
823 dbb_events = mb0_transfer.req.dbb_irqs | mb0_transfer.req.dbb_wakeups;
824 dbb_events |= (WAKEUP_BIT_AC_WAKE_ACK | WAKEUP_BIT_AC_SLEEP_ACK);
825
826 abb_events = mb0_transfer.req.abb_events;
827
828 if ((dbb_events == last_dbb_events) && (abb_events == last_abb_events))
829 return;
830
831 for (i = 0; i < 2; i++) {
832 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(0))
833 cpu_relax();
834 writel(dbb_events, (tcdm_base + PRCM_REQ_MB0_WAKEUP_8500));
835 writel(abb_events, (tcdm_base + PRCM_REQ_MB0_WAKEUP_4500));
836 writeb(header[i], (tcdm_base + PRCM_MBOX_HEADER_REQ_MB0));
837 writel(MBOX_BIT(0), PRCM_MBOX_CPU_SET);
838 }
839 last_dbb_events = dbb_events;
840 last_abb_events = abb_events;
841}
842
843void db8500_prcmu_enable_wakeups(u32 wakeups)
844{
845 unsigned long flags;
846 u32 bits;
847 int i;
848
849 BUG_ON(wakeups != (wakeups & VALID_WAKEUPS));
850
851 for (i = 0, bits = 0; i < NUM_PRCMU_WAKEUP_INDICES; i++) {
852 if (wakeups & BIT(i))
853 bits |= prcmu_wakeup_bit[i];
854 }
855
856 spin_lock_irqsave(&mb0_transfer.lock, flags);
857
858 mb0_transfer.req.dbb_wakeups = bits;
859 config_wakeups();
860
861 spin_unlock_irqrestore(&mb0_transfer.lock, flags);
862}
863
864void db8500_prcmu_config_abb_event_readout(u32 abb_events)
865{
866 unsigned long flags;
867
868 spin_lock_irqsave(&mb0_transfer.lock, flags);
869
870 mb0_transfer.req.abb_events = abb_events;
871 config_wakeups();
872
873 spin_unlock_irqrestore(&mb0_transfer.lock, flags);
874}
875
876void db8500_prcmu_get_abb_event_buffer(void __iomem **buf)
877{
878 if (readb(tcdm_base + PRCM_ACK_MB0_READ_POINTER) & 1)
879 *buf = (tcdm_base + PRCM_ACK_MB0_WAKEUP_1_4500);
880 else
881 *buf = (tcdm_base + PRCM_ACK_MB0_WAKEUP_0_4500);
882}
883
884/**
885 * db8500_prcmu_set_arm_opp - set the appropriate ARM OPP
886 * @opp: The new ARM operating point to which transition is to be made
887 * Returns: 0 on success, non-zero on failure
888 *
889 * This function sets the the operating point of the ARM.
890 */
891int db8500_prcmu_set_arm_opp(u8 opp)
892{
893 int r;
894
895 if (opp < ARM_NO_CHANGE || opp > ARM_EXTCLK)
896 return -EINVAL;
897
898 r = 0;
899
900 mutex_lock(&mb1_transfer.lock);
901
902 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(1))
903 cpu_relax();
904
905 writeb(MB1H_ARM_APE_OPP, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB1));
906 writeb(opp, (tcdm_base + PRCM_REQ_MB1_ARM_OPP));
907 writeb(APE_NO_CHANGE, (tcdm_base + PRCM_REQ_MB1_APE_OPP));
908
909 writel(MBOX_BIT(1), PRCM_MBOX_CPU_SET);
910 wait_for_completion(&mb1_transfer.work);
911
912 if ((mb1_transfer.ack.header != MB1H_ARM_APE_OPP) ||
913 (mb1_transfer.ack.arm_opp != opp))
914 r = -EIO;
915
916 mutex_unlock(&mb1_transfer.lock);
917
918 return r;
919}
920
921/**
922 * db8500_prcmu_get_arm_opp - get the current ARM OPP
923 *
924 * Returns: the current ARM OPP
925 */
926int db8500_prcmu_get_arm_opp(void)
927{
928 return readb(tcdm_base + PRCM_ACK_MB1_CURRENT_ARM_OPP);
929}
930
931/**
932 * db8500_prcmu_get_ddr_opp - get the current DDR OPP
933 *
934 * Returns: the current DDR OPP
935 */
936int db8500_prcmu_get_ddr_opp(void)
937{
938 return readb(PRCM_DDR_SUBSYS_APE_MINBW);
939}
940
941/**
942 * db8500_set_ddr_opp - set the appropriate DDR OPP
943 * @opp: The new DDR operating point to which transition is to be made
944 * Returns: 0 on success, non-zero on failure
945 *
946 * This function sets the operating point of the DDR.
947 */
948static bool enable_set_ddr_opp;
949int db8500_prcmu_set_ddr_opp(u8 opp)
950{
951 if (opp < DDR_100_OPP || opp > DDR_25_OPP)
952 return -EINVAL;
953 /* Changing the DDR OPP can hang the hardware pre-v21 */
954 if (enable_set_ddr_opp)
955 writeb(opp, PRCM_DDR_SUBSYS_APE_MINBW);
956
957 return 0;
958}
959
960/* Divide the frequency of certain clocks by 2 for APE_50_PARTLY_25_OPP. */
961static void request_even_slower_clocks(bool enable)
962{
963 u32 clock_reg[] = {
964 PRCM_ACLK_MGT,
965 PRCM_DMACLK_MGT
966 };
967 unsigned long flags;
968 unsigned int i;
969
970 spin_lock_irqsave(&clk_mgt_lock, flags);
971
972 /* Grab the HW semaphore. */
973 while ((readl(PRCM_SEM) & PRCM_SEM_PRCM_SEM) != 0)
974 cpu_relax();
975
976 for (i = 0; i < ARRAY_SIZE(clock_reg); i++) {
977 u32 val;
978 u32 div;
979
980 val = readl(prcmu_base + clock_reg[i]);
981 div = (val & PRCM_CLK_MGT_CLKPLLDIV_MASK);
982 if (enable) {
983 if ((div <= 1) || (div > 15)) {
984 pr_err("prcmu: Bad clock divider %d in %s\n",
985 div, __func__);
986 goto unlock_and_return;
987 }
988 div <<= 1;
989 } else {
990 if (div <= 2)
991 goto unlock_and_return;
992 div >>= 1;
993 }
994 val = ((val & ~PRCM_CLK_MGT_CLKPLLDIV_MASK) |
995 (div & PRCM_CLK_MGT_CLKPLLDIV_MASK));
996 writel(val, prcmu_base + clock_reg[i]);
997 }
998
999unlock_and_return:
1000 /* Release the HW semaphore. */
1001 writel(0, PRCM_SEM);
1002
1003 spin_unlock_irqrestore(&clk_mgt_lock, flags);
1004}
1005
1006/**
1007 * db8500_set_ape_opp - set the appropriate APE OPP
1008 * @opp: The new APE operating point to which transition is to be made
1009 * Returns: 0 on success, non-zero on failure
1010 *
1011 * This function sets the operating point of the APE.
1012 */
1013int db8500_prcmu_set_ape_opp(u8 opp)
1014{
1015 int r = 0;
1016
1017 if (opp == mb1_transfer.ape_opp)
1018 return 0;
1019
1020 mutex_lock(&mb1_transfer.lock);
1021
1022 if (mb1_transfer.ape_opp == APE_50_PARTLY_25_OPP)
1023 request_even_slower_clocks(false);
1024
1025 if ((opp != APE_100_OPP) && (mb1_transfer.ape_opp != APE_100_OPP))
1026 goto skip_message;
1027
1028 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(1))
1029 cpu_relax();
1030
1031 writeb(MB1H_ARM_APE_OPP, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB1));
1032 writeb(ARM_NO_CHANGE, (tcdm_base + PRCM_REQ_MB1_ARM_OPP));
1033 writeb(((opp == APE_50_PARTLY_25_OPP) ? APE_50_OPP : opp),
1034 (tcdm_base + PRCM_REQ_MB1_APE_OPP));
1035
1036 writel(MBOX_BIT(1), PRCM_MBOX_CPU_SET);
1037 wait_for_completion(&mb1_transfer.work);
1038
1039 if ((mb1_transfer.ack.header != MB1H_ARM_APE_OPP) ||
1040 (mb1_transfer.ack.ape_opp != opp))
1041 r = -EIO;
1042
1043skip_message:
1044 if ((!r && (opp == APE_50_PARTLY_25_OPP)) ||
1045 (r && (mb1_transfer.ape_opp == APE_50_PARTLY_25_OPP)))
1046 request_even_slower_clocks(true);
1047 if (!r)
1048 mb1_transfer.ape_opp = opp;
1049
1050 mutex_unlock(&mb1_transfer.lock);
1051
1052 return r;
1053}
1054
1055/**
1056 * db8500_prcmu_get_ape_opp - get the current APE OPP
1057 *
1058 * Returns: the current APE OPP
1059 */
1060int db8500_prcmu_get_ape_opp(void)
1061{
1062 return readb(tcdm_base + PRCM_ACK_MB1_CURRENT_APE_OPP);
1063}
1064
1065/**
1066 * db8500_prcmu_request_ape_opp_100_voltage - Request APE OPP 100% voltage
1067 * @enable: true to request the higher voltage, false to drop a request.
1068 *
1069 * Calls to this function to enable and disable requests must be balanced.
1070 */
1071int db8500_prcmu_request_ape_opp_100_voltage(bool enable)
1072{
1073 int r = 0;
1074 u8 header;
1075 static unsigned int requests;
1076
1077 mutex_lock(&mb1_transfer.lock);
1078
1079 if (enable) {
1080 if (0 != requests++)
1081 goto unlock_and_return;
1082 header = MB1H_REQUEST_APE_OPP_100_VOLT;
1083 } else {
1084 if (requests == 0) {
1085 r = -EIO;
1086 goto unlock_and_return;
1087 } else if (1 != requests--) {
1088 goto unlock_and_return;
1089 }
1090 header = MB1H_RELEASE_APE_OPP_100_VOLT;
1091 }
1092
1093 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(1))
1094 cpu_relax();
1095
1096 writeb(header, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB1));
1097
1098 writel(MBOX_BIT(1), PRCM_MBOX_CPU_SET);
1099 wait_for_completion(&mb1_transfer.work);
1100
1101 if ((mb1_transfer.ack.header != header) ||
1102 ((mb1_transfer.ack.ape_voltage_status & BIT(0)) != 0))
1103 r = -EIO;
1104
1105unlock_and_return:
1106 mutex_unlock(&mb1_transfer.lock);
1107
1108 return r;
1109}
1110
1111/**
1112 * prcmu_release_usb_wakeup_state - release the state required by a USB wakeup
1113 *
1114 * This function releases the power state requirements of a USB wakeup.
1115 */
1116int prcmu_release_usb_wakeup_state(void)
1117{
1118 int r = 0;
1119
1120 mutex_lock(&mb1_transfer.lock);
1121
1122 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(1))
1123 cpu_relax();
1124
1125 writeb(MB1H_RELEASE_USB_WAKEUP,
1126 (tcdm_base + PRCM_MBOX_HEADER_REQ_MB1));
1127
1128 writel(MBOX_BIT(1), PRCM_MBOX_CPU_SET);
1129 wait_for_completion(&mb1_transfer.work);
1130
1131 if ((mb1_transfer.ack.header != MB1H_RELEASE_USB_WAKEUP) ||
1132 ((mb1_transfer.ack.ape_voltage_status & BIT(0)) != 0))
1133 r = -EIO;
1134
1135 mutex_unlock(&mb1_transfer.lock);
1136
1137 return r;
1138}
1139
1140static int request_pll(u8 clock, bool enable)
1141{
1142 int r = 0;
1143
1144 if (clock == PRCMU_PLLSOC0)
1145 clock = (enable ? PLL_SOC0_ON : PLL_SOC0_OFF);
1146 else if (clock == PRCMU_PLLSOC1)
1147 clock = (enable ? PLL_SOC1_ON : PLL_SOC1_OFF);
1148 else
1149 return -EINVAL;
1150
1151 mutex_lock(&mb1_transfer.lock);
1152
1153 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(1))
1154 cpu_relax();
1155
1156 writeb(MB1H_PLL_ON_OFF, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB1));
1157 writeb(clock, (tcdm_base + PRCM_REQ_MB1_PLL_ON_OFF));
1158
1159 writel(MBOX_BIT(1), PRCM_MBOX_CPU_SET);
1160 wait_for_completion(&mb1_transfer.work);
1161
1162 if (mb1_transfer.ack.header != MB1H_PLL_ON_OFF)
1163 r = -EIO;
1164
1165 mutex_unlock(&mb1_transfer.lock);
1166
1167 return r;
1168}
1169
1170/**
1171 * db8500_prcmu_set_epod - set the state of a EPOD (power domain)
1172 * @epod_id: The EPOD to set
1173 * @epod_state: The new EPOD state
1174 *
1175 * This function sets the state of a EPOD (power domain). It may not be called
1176 * from interrupt context.
1177 */
1178int db8500_prcmu_set_epod(u16 epod_id, u8 epod_state)
1179{
1180 int r = 0;
1181 bool ram_retention = false;
1182 int i;
1183
1184 /* check argument */
1185 BUG_ON(epod_id >= NUM_EPOD_ID);
1186
1187 /* set flag if retention is possible */
1188 switch (epod_id) {
1189 case EPOD_ID_SVAMMDSP:
1190 case EPOD_ID_SIAMMDSP:
1191 case EPOD_ID_ESRAM12:
1192 case EPOD_ID_ESRAM34:
1193 ram_retention = true;
1194 break;
1195 }
1196
1197 /* check argument */
1198 BUG_ON(epod_state > EPOD_STATE_ON);
1199 BUG_ON(epod_state == EPOD_STATE_RAMRET && !ram_retention);
1200
1201 /* get lock */
1202 mutex_lock(&mb2_transfer.lock);
1203
1204 /* wait for mailbox */
1205 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(2))
1206 cpu_relax();
1207
1208 /* fill in mailbox */
1209 for (i = 0; i < NUM_EPOD_ID; i++)
1210 writeb(EPOD_STATE_NO_CHANGE, (tcdm_base + PRCM_REQ_MB2 + i));
1211 writeb(epod_state, (tcdm_base + PRCM_REQ_MB2 + epod_id));
1212
1213 writeb(MB2H_DPS, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB2));
1214
1215 writel(MBOX_BIT(2), PRCM_MBOX_CPU_SET);
1216
1217 /*
1218 * The current firmware version does not handle errors correctly,
1219 * and we cannot recover if there is an error.
1220 * This is expected to change when the firmware is updated.
1221 */
1222 if (!wait_for_completion_timeout(&mb2_transfer.work,
1223 msecs_to_jiffies(20000))) {
1224 pr_err("prcmu: %s timed out (20 s) waiting for a reply.\n",
1225 __func__);
1226 r = -EIO;
1227 goto unlock_and_return;
1228 }
1229
1230 if (mb2_transfer.ack.status != HWACC_PWR_ST_OK)
1231 r = -EIO;
1232
1233unlock_and_return:
1234 mutex_unlock(&mb2_transfer.lock);
1235 return r;
1236}
1237
1238/**
1239 * prcmu_configure_auto_pm - Configure autonomous power management.
1240 * @sleep: Configuration for ApSleep.
1241 * @idle: Configuration for ApIdle.
1242 */
1243void prcmu_configure_auto_pm(struct prcmu_auto_pm_config *sleep,
1244 struct prcmu_auto_pm_config *idle)
1245{
1246 u32 sleep_cfg;
1247 u32 idle_cfg;
1248 unsigned long flags;
1249
1250 BUG_ON((sleep == NULL) || (idle == NULL));
1251
1252 sleep_cfg = (sleep->sva_auto_pm_enable & 0xF);
1253 sleep_cfg = ((sleep_cfg << 4) | (sleep->sia_auto_pm_enable & 0xF));
1254 sleep_cfg = ((sleep_cfg << 8) | (sleep->sva_power_on & 0xFF));
1255 sleep_cfg = ((sleep_cfg << 8) | (sleep->sia_power_on & 0xFF));
1256 sleep_cfg = ((sleep_cfg << 4) | (sleep->sva_policy & 0xF));
1257 sleep_cfg = ((sleep_cfg << 4) | (sleep->sia_policy & 0xF));
1258
1259 idle_cfg = (idle->sva_auto_pm_enable & 0xF);
1260 idle_cfg = ((idle_cfg << 4) | (idle->sia_auto_pm_enable & 0xF));
1261 idle_cfg = ((idle_cfg << 8) | (idle->sva_power_on & 0xFF));
1262 idle_cfg = ((idle_cfg << 8) | (idle->sia_power_on & 0xFF));
1263 idle_cfg = ((idle_cfg << 4) | (idle->sva_policy & 0xF));
1264 idle_cfg = ((idle_cfg << 4) | (idle->sia_policy & 0xF));
1265
1266 spin_lock_irqsave(&mb2_transfer.auto_pm_lock, flags);
1267
1268 /*
1269 * The autonomous power management configuration is done through
1270 * fields in mailbox 2, but these fields are only used as shared
1271 * variables - i.e. there is no need to send a message.
1272 */
1273 writel(sleep_cfg, (tcdm_base + PRCM_REQ_MB2_AUTO_PM_SLEEP));
1274 writel(idle_cfg, (tcdm_base + PRCM_REQ_MB2_AUTO_PM_IDLE));
1275
1276 mb2_transfer.auto_pm_enabled =
1277 ((sleep->sva_auto_pm_enable == PRCMU_AUTO_PM_ON) ||
1278 (sleep->sia_auto_pm_enable == PRCMU_AUTO_PM_ON) ||
1279 (idle->sva_auto_pm_enable == PRCMU_AUTO_PM_ON) ||
1280 (idle->sia_auto_pm_enable == PRCMU_AUTO_PM_ON));
1281
1282 spin_unlock_irqrestore(&mb2_transfer.auto_pm_lock, flags);
1283}
1284EXPORT_SYMBOL(prcmu_configure_auto_pm);
1285
1286bool prcmu_is_auto_pm_enabled(void)
1287{
1288 return mb2_transfer.auto_pm_enabled;
1289}
1290
1291static int request_sysclk(bool enable)
1292{
1293 int r;
1294 unsigned long flags;
1295
1296 r = 0;
1297
1298 mutex_lock(&mb3_transfer.sysclk_lock);
1299
1300 spin_lock_irqsave(&mb3_transfer.lock, flags);
1301
1302 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(3))
1303 cpu_relax();
1304
1305 writeb((enable ? ON : OFF), (tcdm_base + PRCM_REQ_MB3_SYSCLK_MGT));
1306
1307 writeb(MB3H_SYSCLK, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB3));
1308 writel(MBOX_BIT(3), PRCM_MBOX_CPU_SET);
1309
1310 spin_unlock_irqrestore(&mb3_transfer.lock, flags);
1311
1312 /*
1313 * The firmware only sends an ACK if we want to enable the
1314 * SysClk, and it succeeds.
1315 */
1316 if (enable && !wait_for_completion_timeout(&mb3_transfer.sysclk_work,
1317 msecs_to_jiffies(20000))) {
1318 pr_err("prcmu: %s timed out (20 s) waiting for a reply.\n",
1319 __func__);
1320 r = -EIO;
1321 }
1322
1323 mutex_unlock(&mb3_transfer.sysclk_lock);
1324
1325 return r;
1326}
1327
1328static int request_timclk(bool enable)
1329{
1330 u32 val = (PRCM_TCR_DOZE_MODE | PRCM_TCR_TENSEL_MASK);
1331
1332 if (!enable)
1333 val |= PRCM_TCR_STOP_TIMERS;
1334 writel(val, PRCM_TCR);
1335
1336 return 0;
1337}
1338
1339static int request_clock(u8 clock, bool enable)
1340{
1341 u32 val;
1342 unsigned long flags;
1343
1344 spin_lock_irqsave(&clk_mgt_lock, flags);
1345
1346 /* Grab the HW semaphore. */
1347 while ((readl(PRCM_SEM) & PRCM_SEM_PRCM_SEM) != 0)
1348 cpu_relax();
1349
1350 val = readl(prcmu_base + clk_mgt[clock].offset);
1351 if (enable) {
1352 val |= (PRCM_CLK_MGT_CLKEN | clk_mgt[clock].pllsw);
1353 } else {
1354 clk_mgt[clock].pllsw = (val & PRCM_CLK_MGT_CLKPLLSW_MASK);
1355 val &= ~(PRCM_CLK_MGT_CLKEN | PRCM_CLK_MGT_CLKPLLSW_MASK);
1356 }
1357 writel(val, prcmu_base + clk_mgt[clock].offset);
1358
1359 /* Release the HW semaphore. */
1360 writel(0, PRCM_SEM);
1361
1362 spin_unlock_irqrestore(&clk_mgt_lock, flags);
1363
1364 return 0;
1365}
1366
1367static int request_sga_clock(u8 clock, bool enable)
1368{
1369 u32 val;
1370 int ret;
1371
1372 if (enable) {
1373 val = readl(PRCM_CGATING_BYPASS);
1374 writel(val | PRCM_CGATING_BYPASS_ICN2, PRCM_CGATING_BYPASS);
1375 }
1376
1377 ret = request_clock(clock, enable);
1378
1379 if (!ret && !enable) {
1380 val = readl(PRCM_CGATING_BYPASS);
1381 writel(val & ~PRCM_CGATING_BYPASS_ICN2, PRCM_CGATING_BYPASS);
1382 }
1383
1384 return ret;
1385}
1386
1387static inline bool plldsi_locked(void)
1388{
1389 return (readl(PRCM_PLLDSI_LOCKP) &
1390 (PRCM_PLLDSI_LOCKP_PRCM_PLLDSI_LOCKP10 |
1391 PRCM_PLLDSI_LOCKP_PRCM_PLLDSI_LOCKP3)) ==
1392 (PRCM_PLLDSI_LOCKP_PRCM_PLLDSI_LOCKP10 |
1393 PRCM_PLLDSI_LOCKP_PRCM_PLLDSI_LOCKP3);
1394}
1395
1396static int request_plldsi(bool enable)
1397{
1398 int r = 0;
1399 u32 val;
1400
1401 writel((PRCM_MMIP_LS_CLAMP_DSIPLL_CLAMP |
1402 PRCM_MMIP_LS_CLAMP_DSIPLL_CLAMPI), (enable ?
1403 PRCM_MMIP_LS_CLAMP_CLR : PRCM_MMIP_LS_CLAMP_SET));
1404
1405 val = readl(PRCM_PLLDSI_ENABLE);
1406 if (enable)
1407 val |= PRCM_PLLDSI_ENABLE_PRCM_PLLDSI_ENABLE;
1408 else
1409 val &= ~PRCM_PLLDSI_ENABLE_PRCM_PLLDSI_ENABLE;
1410 writel(val, PRCM_PLLDSI_ENABLE);
1411
1412 if (enable) {
1413 unsigned int i;
1414 bool locked = plldsi_locked();
1415
1416 for (i = 10; !locked && (i > 0); --i) {
1417 udelay(100);
1418 locked = plldsi_locked();
1419 }
1420 if (locked) {
1421 writel(PRCM_APE_RESETN_DSIPLL_RESETN,
1422 PRCM_APE_RESETN_SET);
1423 } else {
1424 writel((PRCM_MMIP_LS_CLAMP_DSIPLL_CLAMP |
1425 PRCM_MMIP_LS_CLAMP_DSIPLL_CLAMPI),
1426 PRCM_MMIP_LS_CLAMP_SET);
1427 val &= ~PRCM_PLLDSI_ENABLE_PRCM_PLLDSI_ENABLE;
1428 writel(val, PRCM_PLLDSI_ENABLE);
1429 r = -EAGAIN;
1430 }
1431 } else {
1432 writel(PRCM_APE_RESETN_DSIPLL_RESETN, PRCM_APE_RESETN_CLR);
1433 }
1434 return r;
1435}
1436
1437static int request_dsiclk(u8 n, bool enable)
1438{
1439 u32 val;
1440
1441 val = readl(PRCM_DSI_PLLOUT_SEL);
1442 val &= ~dsiclk[n].divsel_mask;
1443 val |= ((enable ? dsiclk[n].divsel : PRCM_DSI_PLLOUT_SEL_OFF) <<
1444 dsiclk[n].divsel_shift);
1445 writel(val, PRCM_DSI_PLLOUT_SEL);
1446 return 0;
1447}
1448
1449static int request_dsiescclk(u8 n, bool enable)
1450{
1451 u32 val;
1452
1453 val = readl(PRCM_DSITVCLK_DIV);
1454 enable ? (val |= dsiescclk[n].en) : (val &= ~dsiescclk[n].en);
1455 writel(val, PRCM_DSITVCLK_DIV);
1456 return 0;
1457}
1458
1459/**
1460 * db8500_prcmu_request_clock() - Request for a clock to be enabled or disabled.
1461 * @clock: The clock for which the request is made.
1462 * @enable: Whether the clock should be enabled (true) or disabled (false).
1463 *
1464 * This function should only be used by the clock implementation.
1465 * Do not use it from any other place!
1466 */
1467int db8500_prcmu_request_clock(u8 clock, bool enable)
1468{
1469 if (clock == PRCMU_SGACLK)
1470 return request_sga_clock(clock, enable);
1471 else if (clock < PRCMU_NUM_REG_CLOCKS)
1472 return request_clock(clock, enable);
1473 else if (clock == PRCMU_TIMCLK)
1474 return request_timclk(enable);
1475 else if ((clock == PRCMU_DSI0CLK) || (clock == PRCMU_DSI1CLK))
1476 return request_dsiclk((clock - PRCMU_DSI0CLK), enable);
1477 else if ((PRCMU_DSI0ESCCLK <= clock) && (clock <= PRCMU_DSI2ESCCLK))
1478 return request_dsiescclk((clock - PRCMU_DSI0ESCCLK), enable);
1479 else if (clock == PRCMU_PLLDSI)
1480 return request_plldsi(enable);
1481 else if (clock == PRCMU_SYSCLK)
1482 return request_sysclk(enable);
1483 else if ((clock == PRCMU_PLLSOC0) || (clock == PRCMU_PLLSOC1))
1484 return request_pll(clock, enable);
1485 else
1486 return -EINVAL;
1487}
1488
1489static unsigned long pll_rate(void __iomem *reg, unsigned long src_rate,
1490 int branch)
1491{
1492 u64 rate;
1493 u32 val;
1494 u32 d;
1495 u32 div = 1;
1496
1497 val = readl(reg);
1498
1499 rate = src_rate;
1500 rate *= ((val & PRCM_PLL_FREQ_D_MASK) >> PRCM_PLL_FREQ_D_SHIFT);
1501
1502 d = ((val & PRCM_PLL_FREQ_N_MASK) >> PRCM_PLL_FREQ_N_SHIFT);
1503 if (d > 1)
1504 div *= d;
1505
1506 d = ((val & PRCM_PLL_FREQ_R_MASK) >> PRCM_PLL_FREQ_R_SHIFT);
1507 if (d > 1)
1508 div *= d;
1509
1510 if (val & PRCM_PLL_FREQ_SELDIV2)
1511 div *= 2;
1512
1513 if ((branch == PLL_FIX) || ((branch == PLL_DIV) &&
1514 (val & PRCM_PLL_FREQ_DIV2EN) &&
1515 ((reg == PRCM_PLLSOC0_FREQ) ||
1516 (reg == PRCM_PLLARM_FREQ) ||
1517 (reg == PRCM_PLLDDR_FREQ))))
1518 div *= 2;
1519
1520 (void)do_div(rate, div);
1521
1522 return (unsigned long)rate;
1523}
1524
1525#define ROOT_CLOCK_RATE 38400000
1526
1527static unsigned long clock_rate(u8 clock)
1528{
1529 u32 val;
1530 u32 pllsw;
1531 unsigned long rate = ROOT_CLOCK_RATE;
1532
1533 val = readl(prcmu_base + clk_mgt[clock].offset);
1534
1535 if (val & PRCM_CLK_MGT_CLK38) {
1536 if (clk_mgt[clock].clk38div && (val & PRCM_CLK_MGT_CLK38DIV))
1537 rate /= 2;
1538 return rate;
1539 }
1540
1541 val |= clk_mgt[clock].pllsw;
1542 pllsw = (val & PRCM_CLK_MGT_CLKPLLSW_MASK);
1543
1544 if (pllsw == PRCM_CLK_MGT_CLKPLLSW_SOC0)
1545 rate = pll_rate(PRCM_PLLSOC0_FREQ, rate, clk_mgt[clock].branch);
1546 else if (pllsw == PRCM_CLK_MGT_CLKPLLSW_SOC1)
1547 rate = pll_rate(PRCM_PLLSOC1_FREQ, rate, clk_mgt[clock].branch);
1548 else if (pllsw == PRCM_CLK_MGT_CLKPLLSW_DDR)
1549 rate = pll_rate(PRCM_PLLDDR_FREQ, rate, clk_mgt[clock].branch);
1550 else
1551 return 0;
1552
1553 if ((clock == PRCMU_SGACLK) &&
1554 (val & PRCM_SGACLK_MGT_SGACLKDIV_BY_2_5_EN)) {
1555 u64 r = (rate * 10);
1556
1557 (void)do_div(r, 25);
1558 return (unsigned long)r;
1559 }
1560 val &= PRCM_CLK_MGT_CLKPLLDIV_MASK;
1561 if (val)
1562 return rate / val;
1563 else
1564 return 0;
1565}
1566
1567static unsigned long armss_rate(void)
1568{
1569 u32 r;
1570 unsigned long rate;
1571
1572 r = readl(PRCM_ARM_CHGCLKREQ);
1573
1574 if (r & PRCM_ARM_CHGCLKREQ_PRCM_ARM_CHGCLKREQ) {
1575 /* External ARMCLKFIX clock */
1576
1577 rate = pll_rate(PRCM_PLLDDR_FREQ, ROOT_CLOCK_RATE, PLL_FIX);
1578
1579 /* Check PRCM_ARM_CHGCLKREQ divider */
1580 if (!(r & PRCM_ARM_CHGCLKREQ_PRCM_ARM_DIVSEL))
1581 rate /= 2;
1582
1583 /* Check PRCM_ARMCLKFIX_MGT divider */
1584 r = readl(PRCM_ARMCLKFIX_MGT);
1585 r &= PRCM_CLK_MGT_CLKPLLDIV_MASK;
1586 rate /= r;
1587
1588 } else {/* ARM PLL */
1589 rate = pll_rate(PRCM_PLLARM_FREQ, ROOT_CLOCK_RATE, PLL_DIV);
1590 }
1591
1592 return rate;
1593}
1594
1595static unsigned long dsiclk_rate(u8 n)
1596{
1597 u32 divsel;
1598 u32 div = 1;
1599
1600 divsel = readl(PRCM_DSI_PLLOUT_SEL);
1601 divsel = ((divsel & dsiclk[n].divsel_mask) >> dsiclk[n].divsel_shift);
1602
1603 if (divsel == PRCM_DSI_PLLOUT_SEL_OFF)
1604 divsel = dsiclk[n].divsel;
1605 else
1606 dsiclk[n].divsel = divsel;
1607
1608 switch (divsel) {
1609 case PRCM_DSI_PLLOUT_SEL_PHI_4:
1610 div *= 2;
1611 case PRCM_DSI_PLLOUT_SEL_PHI_2:
1612 div *= 2;
1613 case PRCM_DSI_PLLOUT_SEL_PHI:
1614 return pll_rate(PRCM_PLLDSI_FREQ, clock_rate(PRCMU_HDMICLK),
1615 PLL_RAW) / div;
1616 default:
1617 return 0;
1618 }
1619}
1620
1621static unsigned long dsiescclk_rate(u8 n)
1622{
1623 u32 div;
1624
1625 div = readl(PRCM_DSITVCLK_DIV);
1626 div = ((div & dsiescclk[n].div_mask) >> (dsiescclk[n].div_shift));
1627 return clock_rate(PRCMU_TVCLK) / max((u32)1, div);
1628}
1629
1630unsigned long prcmu_clock_rate(u8 clock)
1631{
1632 if (clock < PRCMU_NUM_REG_CLOCKS)
1633 return clock_rate(clock);
1634 else if (clock == PRCMU_TIMCLK)
1635 return ROOT_CLOCK_RATE / 16;
1636 else if (clock == PRCMU_SYSCLK)
1637 return ROOT_CLOCK_RATE;
1638 else if (clock == PRCMU_PLLSOC0)
1639 return pll_rate(PRCM_PLLSOC0_FREQ, ROOT_CLOCK_RATE, PLL_RAW);
1640 else if (clock == PRCMU_PLLSOC1)
1641 return pll_rate(PRCM_PLLSOC1_FREQ, ROOT_CLOCK_RATE, PLL_RAW);
1642 else if (clock == PRCMU_ARMSS)
1643 return armss_rate();
1644 else if (clock == PRCMU_PLLDDR)
1645 return pll_rate(PRCM_PLLDDR_FREQ, ROOT_CLOCK_RATE, PLL_RAW);
1646 else if (clock == PRCMU_PLLDSI)
1647 return pll_rate(PRCM_PLLDSI_FREQ, clock_rate(PRCMU_HDMICLK),
1648 PLL_RAW);
1649 else if ((clock == PRCMU_DSI0CLK) || (clock == PRCMU_DSI1CLK))
1650 return dsiclk_rate(clock - PRCMU_DSI0CLK);
1651 else if ((PRCMU_DSI0ESCCLK <= clock) && (clock <= PRCMU_DSI2ESCCLK))
1652 return dsiescclk_rate(clock - PRCMU_DSI0ESCCLK);
1653 else
1654 return 0;
1655}
1656
1657static unsigned long clock_source_rate(u32 clk_mgt_val, int branch)
1658{
1659 if (clk_mgt_val & PRCM_CLK_MGT_CLK38)
1660 return ROOT_CLOCK_RATE;
1661 clk_mgt_val &= PRCM_CLK_MGT_CLKPLLSW_MASK;
1662 if (clk_mgt_val == PRCM_CLK_MGT_CLKPLLSW_SOC0)
1663 return pll_rate(PRCM_PLLSOC0_FREQ, ROOT_CLOCK_RATE, branch);
1664 else if (clk_mgt_val == PRCM_CLK_MGT_CLKPLLSW_SOC1)
1665 return pll_rate(PRCM_PLLSOC1_FREQ, ROOT_CLOCK_RATE, branch);
1666 else if (clk_mgt_val == PRCM_CLK_MGT_CLKPLLSW_DDR)
1667 return pll_rate(PRCM_PLLDDR_FREQ, ROOT_CLOCK_RATE, branch);
1668 else
1669 return 0;
1670}
1671
1672static u32 clock_divider(unsigned long src_rate, unsigned long rate)
1673{
1674 u32 div;
1675
1676 div = (src_rate / rate);
1677 if (div == 0)
1678 return 1;
1679 if (rate < (src_rate / div))
1680 div++;
1681 return div;
1682}
1683
1684static long round_clock_rate(u8 clock, unsigned long rate)
1685{
1686 u32 val;
1687 u32 div;
1688 unsigned long src_rate;
1689 long rounded_rate;
1690
1691 val = readl(prcmu_base + clk_mgt[clock].offset);
1692 src_rate = clock_source_rate((val | clk_mgt[clock].pllsw),
1693 clk_mgt[clock].branch);
1694 div = clock_divider(src_rate, rate);
1695 if (val & PRCM_CLK_MGT_CLK38) {
1696 if (clk_mgt[clock].clk38div) {
1697 if (div > 2)
1698 div = 2;
1699 } else {
1700 div = 1;
1701 }
1702 } else if ((clock == PRCMU_SGACLK) && (div == 3)) {
1703 u64 r = (src_rate * 10);
1704
1705 (void)do_div(r, 25);
1706 if (r <= rate)
1707 return (unsigned long)r;
1708 }
1709 rounded_rate = (src_rate / min(div, (u32)31));
1710
1711 return rounded_rate;
1712}
1713
1714/* CPU FREQ table, may be changed due to if MAX_OPP is supported. */
1715static struct cpufreq_frequency_table db8500_cpufreq_table[] = {
1716 { .frequency = 200000, .driver_data = ARM_EXTCLK,},
1717 { .frequency = 400000, .driver_data = ARM_50_OPP,},
1718 { .frequency = 800000, .driver_data = ARM_100_OPP,},
1719 { .frequency = CPUFREQ_TABLE_END,}, /* To be used for MAX_OPP. */
1720 { .frequency = CPUFREQ_TABLE_END,},
1721};
1722
1723static long round_armss_rate(unsigned long rate)
1724{
1725 struct cpufreq_frequency_table *pos;
1726 long freq = 0;
1727
1728 /* cpufreq table frequencies is in KHz. */
1729 rate = rate / 1000;
1730
1731 /* Find the corresponding arm opp from the cpufreq table. */
1732 cpufreq_for_each_entry(pos, db8500_cpufreq_table) {
1733 freq = pos->frequency;
1734 if (freq == rate)
1735 break;
1736 }
1737
1738 /* Return the last valid value, even if a match was not found. */
1739 return freq * 1000;
1740}
1741
1742#define MIN_PLL_VCO_RATE 600000000ULL
1743#define MAX_PLL_VCO_RATE 1680640000ULL
1744
1745static long round_plldsi_rate(unsigned long rate)
1746{
1747 long rounded_rate = 0;
1748 unsigned long src_rate;
1749 unsigned long rem;
1750 u32 r;
1751
1752 src_rate = clock_rate(PRCMU_HDMICLK);
1753 rem = rate;
1754
1755 for (r = 7; (rem > 0) && (r > 0); r--) {
1756 u64 d;
1757
1758 d = (r * rate);
1759 (void)do_div(d, src_rate);
1760 if (d < 6)
1761 d = 6;
1762 else if (d > 255)
1763 d = 255;
1764 d *= src_rate;
1765 if (((2 * d) < (r * MIN_PLL_VCO_RATE)) ||
1766 ((r * MAX_PLL_VCO_RATE) < (2 * d)))
1767 continue;
1768 (void)do_div(d, r);
1769 if (rate < d) {
1770 if (rounded_rate == 0)
1771 rounded_rate = (long)d;
1772 break;
1773 }
1774 if ((rate - d) < rem) {
1775 rem = (rate - d);
1776 rounded_rate = (long)d;
1777 }
1778 }
1779 return rounded_rate;
1780}
1781
1782static long round_dsiclk_rate(unsigned long rate)
1783{
1784 u32 div;
1785 unsigned long src_rate;
1786 long rounded_rate;
1787
1788 src_rate = pll_rate(PRCM_PLLDSI_FREQ, clock_rate(PRCMU_HDMICLK),
1789 PLL_RAW);
1790 div = clock_divider(src_rate, rate);
1791 rounded_rate = (src_rate / ((div > 2) ? 4 : div));
1792
1793 return rounded_rate;
1794}
1795
1796static long round_dsiescclk_rate(unsigned long rate)
1797{
1798 u32 div;
1799 unsigned long src_rate;
1800 long rounded_rate;
1801
1802 src_rate = clock_rate(PRCMU_TVCLK);
1803 div = clock_divider(src_rate, rate);
1804 rounded_rate = (src_rate / min(div, (u32)255));
1805
1806 return rounded_rate;
1807}
1808
1809long prcmu_round_clock_rate(u8 clock, unsigned long rate)
1810{
1811 if (clock < PRCMU_NUM_REG_CLOCKS)
1812 return round_clock_rate(clock, rate);
1813 else if (clock == PRCMU_ARMSS)
1814 return round_armss_rate(rate);
1815 else if (clock == PRCMU_PLLDSI)
1816 return round_plldsi_rate(rate);
1817 else if ((clock == PRCMU_DSI0CLK) || (clock == PRCMU_DSI1CLK))
1818 return round_dsiclk_rate(rate);
1819 else if ((PRCMU_DSI0ESCCLK <= clock) && (clock <= PRCMU_DSI2ESCCLK))
1820 return round_dsiescclk_rate(rate);
1821 else
1822 return (long)prcmu_clock_rate(clock);
1823}
1824
1825static void set_clock_rate(u8 clock, unsigned long rate)
1826{
1827 u32 val;
1828 u32 div;
1829 unsigned long src_rate;
1830 unsigned long flags;
1831
1832 spin_lock_irqsave(&clk_mgt_lock, flags);
1833
1834 /* Grab the HW semaphore. */
1835 while ((readl(PRCM_SEM) & PRCM_SEM_PRCM_SEM) != 0)
1836 cpu_relax();
1837
1838 val = readl(prcmu_base + clk_mgt[clock].offset);
1839 src_rate = clock_source_rate((val | clk_mgt[clock].pllsw),
1840 clk_mgt[clock].branch);
1841 div = clock_divider(src_rate, rate);
1842 if (val & PRCM_CLK_MGT_CLK38) {
1843 if (clk_mgt[clock].clk38div) {
1844 if (div > 1)
1845 val |= PRCM_CLK_MGT_CLK38DIV;
1846 else
1847 val &= ~PRCM_CLK_MGT_CLK38DIV;
1848 }
1849 } else if (clock == PRCMU_SGACLK) {
1850 val &= ~(PRCM_CLK_MGT_CLKPLLDIV_MASK |
1851 PRCM_SGACLK_MGT_SGACLKDIV_BY_2_5_EN);
1852 if (div == 3) {
1853 u64 r = (src_rate * 10);
1854
1855 (void)do_div(r, 25);
1856 if (r <= rate) {
1857 val |= PRCM_SGACLK_MGT_SGACLKDIV_BY_2_5_EN;
1858 div = 0;
1859 }
1860 }
1861 val |= min(div, (u32)31);
1862 } else {
1863 val &= ~PRCM_CLK_MGT_CLKPLLDIV_MASK;
1864 val |= min(div, (u32)31);
1865 }
1866 writel(val, prcmu_base + clk_mgt[clock].offset);
1867
1868 /* Release the HW semaphore. */
1869 writel(0, PRCM_SEM);
1870
1871 spin_unlock_irqrestore(&clk_mgt_lock, flags);
1872}
1873
1874static int set_armss_rate(unsigned long rate)
1875{
1876 struct cpufreq_frequency_table *pos;
1877
1878 /* cpufreq table frequencies is in KHz. */
1879 rate = rate / 1000;
1880
1881 /* Find the corresponding arm opp from the cpufreq table. */
1882 cpufreq_for_each_entry(pos, db8500_cpufreq_table)
1883 if (pos->frequency == rate)
1884 break;
1885
1886 if (pos->frequency != rate)
1887 return -EINVAL;
1888
1889 /* Set the new arm opp. */
1890 return db8500_prcmu_set_arm_opp(pos->driver_data);
1891}
1892
1893static int set_plldsi_rate(unsigned long rate)
1894{
1895 unsigned long src_rate;
1896 unsigned long rem;
1897 u32 pll_freq = 0;
1898 u32 r;
1899
1900 src_rate = clock_rate(PRCMU_HDMICLK);
1901 rem = rate;
1902
1903 for (r = 7; (rem > 0) && (r > 0); r--) {
1904 u64 d;
1905 u64 hwrate;
1906
1907 d = (r * rate);
1908 (void)do_div(d, src_rate);
1909 if (d < 6)
1910 d = 6;
1911 else if (d > 255)
1912 d = 255;
1913 hwrate = (d * src_rate);
1914 if (((2 * hwrate) < (r * MIN_PLL_VCO_RATE)) ||
1915 ((r * MAX_PLL_VCO_RATE) < (2 * hwrate)))
1916 continue;
1917 (void)do_div(hwrate, r);
1918 if (rate < hwrate) {
1919 if (pll_freq == 0)
1920 pll_freq = (((u32)d << PRCM_PLL_FREQ_D_SHIFT) |
1921 (r << PRCM_PLL_FREQ_R_SHIFT));
1922 break;
1923 }
1924 if ((rate - hwrate) < rem) {
1925 rem = (rate - hwrate);
1926 pll_freq = (((u32)d << PRCM_PLL_FREQ_D_SHIFT) |
1927 (r << PRCM_PLL_FREQ_R_SHIFT));
1928 }
1929 }
1930 if (pll_freq == 0)
1931 return -EINVAL;
1932
1933 pll_freq |= (1 << PRCM_PLL_FREQ_N_SHIFT);
1934 writel(pll_freq, PRCM_PLLDSI_FREQ);
1935
1936 return 0;
1937}
1938
1939static void set_dsiclk_rate(u8 n, unsigned long rate)
1940{
1941 u32 val;
1942 u32 div;
1943
1944 div = clock_divider(pll_rate(PRCM_PLLDSI_FREQ,
1945 clock_rate(PRCMU_HDMICLK), PLL_RAW), rate);
1946
1947 dsiclk[n].divsel = (div == 1) ? PRCM_DSI_PLLOUT_SEL_PHI :
1948 (div == 2) ? PRCM_DSI_PLLOUT_SEL_PHI_2 :
1949 /* else */ PRCM_DSI_PLLOUT_SEL_PHI_4;
1950
1951 val = readl(PRCM_DSI_PLLOUT_SEL);
1952 val &= ~dsiclk[n].divsel_mask;
1953 val |= (dsiclk[n].divsel << dsiclk[n].divsel_shift);
1954 writel(val, PRCM_DSI_PLLOUT_SEL);
1955}
1956
1957static void set_dsiescclk_rate(u8 n, unsigned long rate)
1958{
1959 u32 val;
1960 u32 div;
1961
1962 div = clock_divider(clock_rate(PRCMU_TVCLK), rate);
1963 val = readl(PRCM_DSITVCLK_DIV);
1964 val &= ~dsiescclk[n].div_mask;
1965 val |= (min(div, (u32)255) << dsiescclk[n].div_shift);
1966 writel(val, PRCM_DSITVCLK_DIV);
1967}
1968
1969int prcmu_set_clock_rate(u8 clock, unsigned long rate)
1970{
1971 if (clock < PRCMU_NUM_REG_CLOCKS)
1972 set_clock_rate(clock, rate);
1973 else if (clock == PRCMU_ARMSS)
1974 return set_armss_rate(rate);
1975 else if (clock == PRCMU_PLLDSI)
1976 return set_plldsi_rate(rate);
1977 else if ((clock == PRCMU_DSI0CLK) || (clock == PRCMU_DSI1CLK))
1978 set_dsiclk_rate((clock - PRCMU_DSI0CLK), rate);
1979 else if ((PRCMU_DSI0ESCCLK <= clock) && (clock <= PRCMU_DSI2ESCCLK))
1980 set_dsiescclk_rate((clock - PRCMU_DSI0ESCCLK), rate);
1981 return 0;
1982}
1983
1984int db8500_prcmu_config_esram0_deep_sleep(u8 state)
1985{
1986 if ((state > ESRAM0_DEEP_SLEEP_STATE_RET) ||
1987 (state < ESRAM0_DEEP_SLEEP_STATE_OFF))
1988 return -EINVAL;
1989
1990 mutex_lock(&mb4_transfer.lock);
1991
1992 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(4))
1993 cpu_relax();
1994
1995 writeb(MB4H_MEM_ST, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB4));
1996 writeb(((DDR_PWR_STATE_OFFHIGHLAT << 4) | DDR_PWR_STATE_ON),
1997 (tcdm_base + PRCM_REQ_MB4_DDR_ST_AP_SLEEP_IDLE));
1998 writeb(DDR_PWR_STATE_ON,
1999 (tcdm_base + PRCM_REQ_MB4_DDR_ST_AP_DEEP_IDLE));
2000 writeb(state, (tcdm_base + PRCM_REQ_MB4_ESRAM0_ST));
2001
2002 writel(MBOX_BIT(4), PRCM_MBOX_CPU_SET);
2003 wait_for_completion(&mb4_transfer.work);
2004
2005 mutex_unlock(&mb4_transfer.lock);
2006
2007 return 0;
2008}
2009
2010int db8500_prcmu_config_hotdog(u8 threshold)
2011{
2012 mutex_lock(&mb4_transfer.lock);
2013
2014 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(4))
2015 cpu_relax();
2016
2017 writeb(threshold, (tcdm_base + PRCM_REQ_MB4_HOTDOG_THRESHOLD));
2018 writeb(MB4H_HOTDOG, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB4));
2019
2020 writel(MBOX_BIT(4), PRCM_MBOX_CPU_SET);
2021 wait_for_completion(&mb4_transfer.work);
2022
2023 mutex_unlock(&mb4_transfer.lock);
2024
2025 return 0;
2026}
2027
2028int db8500_prcmu_config_hotmon(u8 low, u8 high)
2029{
2030 mutex_lock(&mb4_transfer.lock);
2031
2032 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(4))
2033 cpu_relax();
2034
2035 writeb(low, (tcdm_base + PRCM_REQ_MB4_HOTMON_LOW));
2036 writeb(high, (tcdm_base + PRCM_REQ_MB4_HOTMON_HIGH));
2037 writeb((HOTMON_CONFIG_LOW | HOTMON_CONFIG_HIGH),
2038 (tcdm_base + PRCM_REQ_MB4_HOTMON_CONFIG));
2039 writeb(MB4H_HOTMON, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB4));
2040
2041 writel(MBOX_BIT(4), PRCM_MBOX_CPU_SET);
2042 wait_for_completion(&mb4_transfer.work);
2043
2044 mutex_unlock(&mb4_transfer.lock);
2045
2046 return 0;
2047}
2048EXPORT_SYMBOL_GPL(db8500_prcmu_config_hotmon);
2049
2050static int config_hot_period(u16 val)
2051{
2052 mutex_lock(&mb4_transfer.lock);
2053
2054 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(4))
2055 cpu_relax();
2056
2057 writew(val, (tcdm_base + PRCM_REQ_MB4_HOT_PERIOD));
2058 writeb(MB4H_HOT_PERIOD, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB4));
2059
2060 writel(MBOX_BIT(4), PRCM_MBOX_CPU_SET);
2061 wait_for_completion(&mb4_transfer.work);
2062
2063 mutex_unlock(&mb4_transfer.lock);
2064
2065 return 0;
2066}
2067
2068int db8500_prcmu_start_temp_sense(u16 cycles32k)
2069{
2070 if (cycles32k == 0xFFFF)
2071 return -EINVAL;
2072
2073 return config_hot_period(cycles32k);
2074}
2075EXPORT_SYMBOL_GPL(db8500_prcmu_start_temp_sense);
2076
2077int db8500_prcmu_stop_temp_sense(void)
2078{
2079 return config_hot_period(0xFFFF);
2080}
2081EXPORT_SYMBOL_GPL(db8500_prcmu_stop_temp_sense);
2082
2083static int prcmu_a9wdog(u8 cmd, u8 d0, u8 d1, u8 d2, u8 d3)
2084{
2085
2086 mutex_lock(&mb4_transfer.lock);
2087
2088 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(4))
2089 cpu_relax();
2090
2091 writeb(d0, (tcdm_base + PRCM_REQ_MB4_A9WDOG_0));
2092 writeb(d1, (tcdm_base + PRCM_REQ_MB4_A9WDOG_1));
2093 writeb(d2, (tcdm_base + PRCM_REQ_MB4_A9WDOG_2));
2094 writeb(d3, (tcdm_base + PRCM_REQ_MB4_A9WDOG_3));
2095
2096 writeb(cmd, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB4));
2097
2098 writel(MBOX_BIT(4), PRCM_MBOX_CPU_SET);
2099 wait_for_completion(&mb4_transfer.work);
2100
2101 mutex_unlock(&mb4_transfer.lock);
2102
2103 return 0;
2104
2105}
2106
2107int db8500_prcmu_config_a9wdog(u8 num, bool sleep_auto_off)
2108{
2109 BUG_ON(num == 0 || num > 0xf);
2110 return prcmu_a9wdog(MB4H_A9WDOG_CONF, num, 0, 0,
2111 sleep_auto_off ? A9WDOG_AUTO_OFF_EN :
2112 A9WDOG_AUTO_OFF_DIS);
2113}
2114EXPORT_SYMBOL(db8500_prcmu_config_a9wdog);
2115
2116int db8500_prcmu_enable_a9wdog(u8 id)
2117{
2118 return prcmu_a9wdog(MB4H_A9WDOG_EN, id, 0, 0, 0);
2119}
2120EXPORT_SYMBOL(db8500_prcmu_enable_a9wdog);
2121
2122int db8500_prcmu_disable_a9wdog(u8 id)
2123{
2124 return prcmu_a9wdog(MB4H_A9WDOG_DIS, id, 0, 0, 0);
2125}
2126EXPORT_SYMBOL(db8500_prcmu_disable_a9wdog);
2127
2128int db8500_prcmu_kick_a9wdog(u8 id)
2129{
2130 return prcmu_a9wdog(MB4H_A9WDOG_KICK, id, 0, 0, 0);
2131}
2132EXPORT_SYMBOL(db8500_prcmu_kick_a9wdog);
2133
2134/*
2135 * timeout is 28 bit, in ms.
2136 */
2137int db8500_prcmu_load_a9wdog(u8 id, u32 timeout)
2138{
2139 return prcmu_a9wdog(MB4H_A9WDOG_LOAD,
2140 (id & A9WDOG_ID_MASK) |
2141 /*
2142 * Put the lowest 28 bits of timeout at
2143 * offset 4. Four first bits are used for id.
2144 */
2145 (u8)((timeout << 4) & 0xf0),
2146 (u8)((timeout >> 4) & 0xff),
2147 (u8)((timeout >> 12) & 0xff),
2148 (u8)((timeout >> 20) & 0xff));
2149}
2150EXPORT_SYMBOL(db8500_prcmu_load_a9wdog);
2151
2152/**
2153 * prcmu_abb_read() - Read register value(s) from the ABB.
2154 * @slave: The I2C slave address.
2155 * @reg: The (start) register address.
2156 * @value: The read out value(s).
2157 * @size: The number of registers to read.
2158 *
2159 * Reads register value(s) from the ABB.
2160 * @size has to be 1 for the current firmware version.
2161 */
2162int prcmu_abb_read(u8 slave, u8 reg, u8 *value, u8 size)
2163{
2164 int r;
2165
2166 if (size != 1)
2167 return -EINVAL;
2168
2169 mutex_lock(&mb5_transfer.lock);
2170
2171 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(5))
2172 cpu_relax();
2173
2174 writeb(0, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB5));
2175 writeb(PRCMU_I2C_READ(slave), (tcdm_base + PRCM_REQ_MB5_I2C_SLAVE_OP));
2176 writeb(PRCMU_I2C_STOP_EN, (tcdm_base + PRCM_REQ_MB5_I2C_HW_BITS));
2177 writeb(reg, (tcdm_base + PRCM_REQ_MB5_I2C_REG));
2178 writeb(0, (tcdm_base + PRCM_REQ_MB5_I2C_VAL));
2179
2180 writel(MBOX_BIT(5), PRCM_MBOX_CPU_SET);
2181
2182 if (!wait_for_completion_timeout(&mb5_transfer.work,
2183 msecs_to_jiffies(20000))) {
2184 pr_err("prcmu: %s timed out (20 s) waiting for a reply.\n",
2185 __func__);
2186 r = -EIO;
2187 } else {
2188 r = ((mb5_transfer.ack.status == I2C_RD_OK) ? 0 : -EIO);
2189 }
2190
2191 if (!r)
2192 *value = mb5_transfer.ack.value;
2193
2194 mutex_unlock(&mb5_transfer.lock);
2195
2196 return r;
2197}
2198
2199/**
2200 * prcmu_abb_write_masked() - Write masked register value(s) to the ABB.
2201 * @slave: The I2C slave address.
2202 * @reg: The (start) register address.
2203 * @value: The value(s) to write.
2204 * @mask: The mask(s) to use.
2205 * @size: The number of registers to write.
2206 *
2207 * Writes masked register value(s) to the ABB.
2208 * For each @value, only the bits set to 1 in the corresponding @mask
2209 * will be written. The other bits are not changed.
2210 * @size has to be 1 for the current firmware version.
2211 */
2212int prcmu_abb_write_masked(u8 slave, u8 reg, u8 *value, u8 *mask, u8 size)
2213{
2214 int r;
2215
2216 if (size != 1)
2217 return -EINVAL;
2218
2219 mutex_lock(&mb5_transfer.lock);
2220
2221 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(5))
2222 cpu_relax();
2223
2224 writeb(~*mask, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB5));
2225 writeb(PRCMU_I2C_WRITE(slave), (tcdm_base + PRCM_REQ_MB5_I2C_SLAVE_OP));
2226 writeb(PRCMU_I2C_STOP_EN, (tcdm_base + PRCM_REQ_MB5_I2C_HW_BITS));
2227 writeb(reg, (tcdm_base + PRCM_REQ_MB5_I2C_REG));
2228 writeb(*value, (tcdm_base + PRCM_REQ_MB5_I2C_VAL));
2229
2230 writel(MBOX_BIT(5), PRCM_MBOX_CPU_SET);
2231
2232 if (!wait_for_completion_timeout(&mb5_transfer.work,
2233 msecs_to_jiffies(20000))) {
2234 pr_err("prcmu: %s timed out (20 s) waiting for a reply.\n",
2235 __func__);
2236 r = -EIO;
2237 } else {
2238 r = ((mb5_transfer.ack.status == I2C_WR_OK) ? 0 : -EIO);
2239 }
2240
2241 mutex_unlock(&mb5_transfer.lock);
2242
2243 return r;
2244}
2245
2246/**
2247 * prcmu_abb_write() - Write register value(s) to the ABB.
2248 * @slave: The I2C slave address.
2249 * @reg: The (start) register address.
2250 * @value: The value(s) to write.
2251 * @size: The number of registers to write.
2252 *
2253 * Writes register value(s) to the ABB.
2254 * @size has to be 1 for the current firmware version.
2255 */
2256int prcmu_abb_write(u8 slave, u8 reg, u8 *value, u8 size)
2257{
2258 u8 mask = ~0;
2259
2260 return prcmu_abb_write_masked(slave, reg, value, &mask, size);
2261}
2262
2263/**
2264 * prcmu_ac_wake_req - should be called whenever ARM wants to wakeup Modem
2265 */
2266int prcmu_ac_wake_req(void)
2267{
2268 u32 val;
2269 int ret = 0;
2270
2271 mutex_lock(&mb0_transfer.ac_wake_lock);
2272
2273 val = readl(PRCM_HOSTACCESS_REQ);
2274 if (val & PRCM_HOSTACCESS_REQ_HOSTACCESS_REQ)
2275 goto unlock_and_return;
2276
2277 atomic_set(&ac_wake_req_state, 1);
2278
2279 /*
2280 * Force Modem Wake-up before hostaccess_req ping-pong.
2281 * It prevents Modem to enter in Sleep while acking the hostaccess
2282 * request. The 31us delay has been calculated by HWI.
2283 */
2284 val |= PRCM_HOSTACCESS_REQ_WAKE_REQ;
2285 writel(val, PRCM_HOSTACCESS_REQ);
2286
2287 udelay(31);
2288
2289 val |= PRCM_HOSTACCESS_REQ_HOSTACCESS_REQ;
2290 writel(val, PRCM_HOSTACCESS_REQ);
2291
2292 if (!wait_for_completion_timeout(&mb0_transfer.ac_wake_work,
2293 msecs_to_jiffies(5000))) {
2294 pr_crit("prcmu: %s timed out (5 s) waiting for a reply.\n",
2295 __func__);
2296 ret = -EFAULT;
2297 }
2298
2299unlock_and_return:
2300 mutex_unlock(&mb0_transfer.ac_wake_lock);
2301 return ret;
2302}
2303
2304/**
2305 * prcmu_ac_sleep_req - called when ARM no longer needs to talk to modem
2306 */
2307void prcmu_ac_sleep_req(void)
2308{
2309 u32 val;
2310
2311 mutex_lock(&mb0_transfer.ac_wake_lock);
2312
2313 val = readl(PRCM_HOSTACCESS_REQ);
2314 if (!(val & PRCM_HOSTACCESS_REQ_HOSTACCESS_REQ))
2315 goto unlock_and_return;
2316
2317 writel((val & ~PRCM_HOSTACCESS_REQ_HOSTACCESS_REQ),
2318 PRCM_HOSTACCESS_REQ);
2319
2320 if (!wait_for_completion_timeout(&mb0_transfer.ac_wake_work,
2321 msecs_to_jiffies(5000))) {
2322 pr_crit("prcmu: %s timed out (5 s) waiting for a reply.\n",
2323 __func__);
2324 }
2325
2326 atomic_set(&ac_wake_req_state, 0);
2327
2328unlock_and_return:
2329 mutex_unlock(&mb0_transfer.ac_wake_lock);
2330}
2331
2332bool db8500_prcmu_is_ac_wake_requested(void)
2333{
2334 return (atomic_read(&ac_wake_req_state) != 0);
2335}
2336
2337/**
2338 * db8500_prcmu_system_reset - System reset
2339 *
2340 * Saves the reset reason code and then sets the APE_SOFTRST register which
2341 * fires interrupt to fw
2342 */
2343void db8500_prcmu_system_reset(u16 reset_code)
2344{
2345 writew(reset_code, (tcdm_base + PRCM_SW_RST_REASON));
2346 writel(1, PRCM_APE_SOFTRST);
2347}
2348
2349/**
2350 * db8500_prcmu_get_reset_code - Retrieve SW reset reason code
2351 *
2352 * Retrieves the reset reason code stored by prcmu_system_reset() before
2353 * last restart.
2354 */
2355u16 db8500_prcmu_get_reset_code(void)
2356{
2357 return readw(tcdm_base + PRCM_SW_RST_REASON);
2358}
2359
2360/**
2361 * db8500_prcmu_reset_modem - ask the PRCMU to reset modem
2362 */
2363void db8500_prcmu_modem_reset(void)
2364{
2365 mutex_lock(&mb1_transfer.lock);
2366
2367 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(1))
2368 cpu_relax();
2369
2370 writeb(MB1H_RESET_MODEM, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB1));
2371 writel(MBOX_BIT(1), PRCM_MBOX_CPU_SET);
2372 wait_for_completion(&mb1_transfer.work);
2373
2374 /*
2375 * No need to check return from PRCMU as modem should go in reset state
2376 * This state is already managed by upper layer
2377 */
2378
2379 mutex_unlock(&mb1_transfer.lock);
2380}
2381
2382static void ack_dbb_wakeup(void)
2383{
2384 unsigned long flags;
2385
2386 spin_lock_irqsave(&mb0_transfer.lock, flags);
2387
2388 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(0))
2389 cpu_relax();
2390
2391 writeb(MB0H_READ_WAKEUP_ACK, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB0));
2392 writel(MBOX_BIT(0), PRCM_MBOX_CPU_SET);
2393
2394 spin_unlock_irqrestore(&mb0_transfer.lock, flags);
2395}
2396
2397static inline void print_unknown_header_warning(u8 n, u8 header)
2398{
2399 pr_warning("prcmu: Unknown message header (%d) in mailbox %d.\n",
2400 header, n);
2401}
2402
2403static bool read_mailbox_0(void)
2404{
2405 bool r;
2406 u32 ev;
2407 unsigned int n;
2408 u8 header;
2409
2410 header = readb(tcdm_base + PRCM_MBOX_HEADER_ACK_MB0);
2411 switch (header) {
2412 case MB0H_WAKEUP_EXE:
2413 case MB0H_WAKEUP_SLEEP:
2414 if (readb(tcdm_base + PRCM_ACK_MB0_READ_POINTER) & 1)
2415 ev = readl(tcdm_base + PRCM_ACK_MB0_WAKEUP_1_8500);
2416 else
2417 ev = readl(tcdm_base + PRCM_ACK_MB0_WAKEUP_0_8500);
2418
2419 if (ev & (WAKEUP_BIT_AC_WAKE_ACK | WAKEUP_BIT_AC_SLEEP_ACK))
2420 complete(&mb0_transfer.ac_wake_work);
2421 if (ev & WAKEUP_BIT_SYSCLK_OK)
2422 complete(&mb3_transfer.sysclk_work);
2423
2424 ev &= mb0_transfer.req.dbb_irqs;
2425
2426 for (n = 0; n < NUM_PRCMU_WAKEUPS; n++) {
2427 if (ev & prcmu_irq_bit[n])
2428 generic_handle_irq(irq_find_mapping(db8500_irq_domain, n));
2429 }
2430 r = true;
2431 break;
2432 default:
2433 print_unknown_header_warning(0, header);
2434 r = false;
2435 break;
2436 }
2437 writel(MBOX_BIT(0), PRCM_ARM_IT1_CLR);
2438 return r;
2439}
2440
2441static bool read_mailbox_1(void)
2442{
2443 mb1_transfer.ack.header = readb(tcdm_base + PRCM_MBOX_HEADER_REQ_MB1);
2444 mb1_transfer.ack.arm_opp = readb(tcdm_base +
2445 PRCM_ACK_MB1_CURRENT_ARM_OPP);
2446 mb1_transfer.ack.ape_opp = readb(tcdm_base +
2447 PRCM_ACK_MB1_CURRENT_APE_OPP);
2448 mb1_transfer.ack.ape_voltage_status = readb(tcdm_base +
2449 PRCM_ACK_MB1_APE_VOLTAGE_STATUS);
2450 writel(MBOX_BIT(1), PRCM_ARM_IT1_CLR);
2451 complete(&mb1_transfer.work);
2452 return false;
2453}
2454
2455static bool read_mailbox_2(void)
2456{
2457 mb2_transfer.ack.status = readb(tcdm_base + PRCM_ACK_MB2_DPS_STATUS);
2458 writel(MBOX_BIT(2), PRCM_ARM_IT1_CLR);
2459 complete(&mb2_transfer.work);
2460 return false;
2461}
2462
2463static bool read_mailbox_3(void)
2464{
2465 writel(MBOX_BIT(3), PRCM_ARM_IT1_CLR);
2466 return false;
2467}
2468
2469static bool read_mailbox_4(void)
2470{
2471 u8 header;
2472 bool do_complete = true;
2473
2474 header = readb(tcdm_base + PRCM_MBOX_HEADER_REQ_MB4);
2475 switch (header) {
2476 case MB4H_MEM_ST:
2477 case MB4H_HOTDOG:
2478 case MB4H_HOTMON:
2479 case MB4H_HOT_PERIOD:
2480 case MB4H_A9WDOG_CONF:
2481 case MB4H_A9WDOG_EN:
2482 case MB4H_A9WDOG_DIS:
2483 case MB4H_A9WDOG_LOAD:
2484 case MB4H_A9WDOG_KICK:
2485 break;
2486 default:
2487 print_unknown_header_warning(4, header);
2488 do_complete = false;
2489 break;
2490 }
2491
2492 writel(MBOX_BIT(4), PRCM_ARM_IT1_CLR);
2493
2494 if (do_complete)
2495 complete(&mb4_transfer.work);
2496
2497 return false;
2498}
2499
2500static bool read_mailbox_5(void)
2501{
2502 mb5_transfer.ack.status = readb(tcdm_base + PRCM_ACK_MB5_I2C_STATUS);
2503 mb5_transfer.ack.value = readb(tcdm_base + PRCM_ACK_MB5_I2C_VAL);
2504 writel(MBOX_BIT(5), PRCM_ARM_IT1_CLR);
2505 complete(&mb5_transfer.work);
2506 return false;
2507}
2508
2509static bool read_mailbox_6(void)
2510{
2511 writel(MBOX_BIT(6), PRCM_ARM_IT1_CLR);
2512 return false;
2513}
2514
2515static bool read_mailbox_7(void)
2516{
2517 writel(MBOX_BIT(7), PRCM_ARM_IT1_CLR);
2518 return false;
2519}
2520
2521static bool (* const read_mailbox[NUM_MB])(void) = {
2522 read_mailbox_0,
2523 read_mailbox_1,
2524 read_mailbox_2,
2525 read_mailbox_3,
2526 read_mailbox_4,
2527 read_mailbox_5,
2528 read_mailbox_6,
2529 read_mailbox_7
2530};
2531
2532static irqreturn_t prcmu_irq_handler(int irq, void *data)
2533{
2534 u32 bits;
2535 u8 n;
2536 irqreturn_t r;
2537
2538 bits = (readl(PRCM_ARM_IT1_VAL) & ALL_MBOX_BITS);
2539 if (unlikely(!bits))
2540 return IRQ_NONE;
2541
2542 r = IRQ_HANDLED;
2543 for (n = 0; bits; n++) {
2544 if (bits & MBOX_BIT(n)) {
2545 bits -= MBOX_BIT(n);
2546 if (read_mailbox[n]())
2547 r = IRQ_WAKE_THREAD;
2548 }
2549 }
2550 return r;
2551}
2552
2553static irqreturn_t prcmu_irq_thread_fn(int irq, void *data)
2554{
2555 ack_dbb_wakeup();
2556 return IRQ_HANDLED;
2557}
2558
2559static void prcmu_mask_work(struct work_struct *work)
2560{
2561 unsigned long flags;
2562
2563 spin_lock_irqsave(&mb0_transfer.lock, flags);
2564
2565 config_wakeups();
2566
2567 spin_unlock_irqrestore(&mb0_transfer.lock, flags);
2568}
2569
2570static void prcmu_irq_mask(struct irq_data *d)
2571{
2572 unsigned long flags;
2573
2574 spin_lock_irqsave(&mb0_transfer.dbb_irqs_lock, flags);
2575
2576 mb0_transfer.req.dbb_irqs &= ~prcmu_irq_bit[d->hwirq];
2577
2578 spin_unlock_irqrestore(&mb0_transfer.dbb_irqs_lock, flags);
2579
2580 if (d->irq != IRQ_PRCMU_CA_SLEEP)
2581 schedule_work(&mb0_transfer.mask_work);
2582}
2583
2584static void prcmu_irq_unmask(struct irq_data *d)
2585{
2586 unsigned long flags;
2587
2588 spin_lock_irqsave(&mb0_transfer.dbb_irqs_lock, flags);
2589
2590 mb0_transfer.req.dbb_irqs |= prcmu_irq_bit[d->hwirq];
2591
2592 spin_unlock_irqrestore(&mb0_transfer.dbb_irqs_lock, flags);
2593
2594 if (d->irq != IRQ_PRCMU_CA_SLEEP)
2595 schedule_work(&mb0_transfer.mask_work);
2596}
2597
2598static void noop(struct irq_data *d)
2599{
2600}
2601
2602static struct irq_chip prcmu_irq_chip = {
2603 .name = "prcmu",
2604 .irq_disable = prcmu_irq_mask,
2605 .irq_ack = noop,
2606 .irq_mask = prcmu_irq_mask,
2607 .irq_unmask = prcmu_irq_unmask,
2608};
2609
2610static __init char *fw_project_name(u32 project)
2611{
2612 switch (project) {
2613 case PRCMU_FW_PROJECT_U8500:
2614 return "U8500";
2615 case PRCMU_FW_PROJECT_U8400:
2616 return "U8400";
2617 case PRCMU_FW_PROJECT_U9500:
2618 return "U9500";
2619 case PRCMU_FW_PROJECT_U8500_MBB:
2620 return "U8500 MBB";
2621 case PRCMU_FW_PROJECT_U8500_C1:
2622 return "U8500 C1";
2623 case PRCMU_FW_PROJECT_U8500_C2:
2624 return "U8500 C2";
2625 case PRCMU_FW_PROJECT_U8500_C3:
2626 return "U8500 C3";
2627 case PRCMU_FW_PROJECT_U8500_C4:
2628 return "U8500 C4";
2629 case PRCMU_FW_PROJECT_U9500_MBL:
2630 return "U9500 MBL";
2631 case PRCMU_FW_PROJECT_U8500_MBL:
2632 return "U8500 MBL";
2633 case PRCMU_FW_PROJECT_U8500_MBL2:
2634 return "U8500 MBL2";
2635 case PRCMU_FW_PROJECT_U8520:
2636 return "U8520 MBL";
2637 case PRCMU_FW_PROJECT_U8420:
2638 return "U8420";
2639 case PRCMU_FW_PROJECT_U9540:
2640 return "U9540";
2641 case PRCMU_FW_PROJECT_A9420:
2642 return "A9420";
2643 case PRCMU_FW_PROJECT_L8540:
2644 return "L8540";
2645 case PRCMU_FW_PROJECT_L8580:
2646 return "L8580";
2647 default:
2648 return "Unknown";
2649 }
2650}
2651
2652static int db8500_irq_map(struct irq_domain *d, unsigned int virq,
2653 irq_hw_number_t hwirq)
2654{
2655 irq_set_chip_and_handler(virq, &prcmu_irq_chip,
2656 handle_simple_irq);
2657
2658 return 0;
2659}
2660
2661static const struct irq_domain_ops db8500_irq_ops = {
2662 .map = db8500_irq_map,
2663 .xlate = irq_domain_xlate_twocell,
2664};
2665
2666static int db8500_irq_init(struct device_node *np)
2667{
2668 int i;
2669
2670 db8500_irq_domain = irq_domain_add_simple(
2671 np, NUM_PRCMU_WAKEUPS, 0,
2672 &db8500_irq_ops, NULL);
2673
2674 if (!db8500_irq_domain) {
2675 pr_err("Failed to create irqdomain\n");
2676 return -ENOSYS;
2677 }
2678
2679 /* All wakeups will be used, so create mappings for all */
2680 for (i = 0; i < NUM_PRCMU_WAKEUPS; i++)
2681 irq_create_mapping(db8500_irq_domain, i);
2682
2683 return 0;
2684}
2685
2686static void dbx500_fw_version_init(struct platform_device *pdev,
2687 u32 version_offset)
2688{
2689 struct resource *res;
2690 void __iomem *tcpm_base;
2691 u32 version;
2692
2693 res = platform_get_resource_byname(pdev, IORESOURCE_MEM,
2694 "prcmu-tcpm");
2695 if (!res) {
2696 dev_err(&pdev->dev,
2697 "Error: no prcmu tcpm memory region provided\n");
2698 return;
2699 }
2700 tcpm_base = ioremap(res->start, resource_size(res));
2701 if (!tcpm_base) {
2702 dev_err(&pdev->dev, "no prcmu tcpm mem region provided\n");
2703 return;
2704 }
2705
2706 version = readl(tcpm_base + version_offset);
2707 fw_info.version.project = (version & 0xFF);
2708 fw_info.version.api_version = (version >> 8) & 0xFF;
2709 fw_info.version.func_version = (version >> 16) & 0xFF;
2710 fw_info.version.errata = (version >> 24) & 0xFF;
2711 strncpy(fw_info.version.project_name,
2712 fw_project_name(fw_info.version.project),
2713 PRCMU_FW_PROJECT_NAME_LEN);
2714 fw_info.valid = true;
2715 pr_info("PRCMU firmware: %s(%d), version %d.%d.%d\n",
2716 fw_info.version.project_name,
2717 fw_info.version.project,
2718 fw_info.version.api_version,
2719 fw_info.version.func_version,
2720 fw_info.version.errata);
2721 iounmap(tcpm_base);
2722}
2723
2724void __init db8500_prcmu_early_init(u32 phy_base, u32 size)
2725{
2726 /*
2727 * This is a temporary remap to bring up the clocks. It is
2728 * subsequently replaces with a real remap. After the merge of
2729 * the mailbox subsystem all of this early code goes away, and the
2730 * clock driver can probe independently. An early initcall will
2731 * still be needed, but it can be diverted into drivers/clk/ux500.
2732 */
2733 prcmu_base = ioremap(phy_base, size);
2734 if (!prcmu_base)
2735 pr_err("%s: ioremap() of prcmu registers failed!\n", __func__);
2736
2737 spin_lock_init(&mb0_transfer.lock);
2738 spin_lock_init(&mb0_transfer.dbb_irqs_lock);
2739 mutex_init(&mb0_transfer.ac_wake_lock);
2740 init_completion(&mb0_transfer.ac_wake_work);
2741 mutex_init(&mb1_transfer.lock);
2742 init_completion(&mb1_transfer.work);
2743 mb1_transfer.ape_opp = APE_NO_CHANGE;
2744 mutex_init(&mb2_transfer.lock);
2745 init_completion(&mb2_transfer.work);
2746 spin_lock_init(&mb2_transfer.auto_pm_lock);
2747 spin_lock_init(&mb3_transfer.lock);
2748 mutex_init(&mb3_transfer.sysclk_lock);
2749 init_completion(&mb3_transfer.sysclk_work);
2750 mutex_init(&mb4_transfer.lock);
2751 init_completion(&mb4_transfer.work);
2752 mutex_init(&mb5_transfer.lock);
2753 init_completion(&mb5_transfer.work);
2754
2755 INIT_WORK(&mb0_transfer.mask_work, prcmu_mask_work);
2756}
2757
2758static void __init init_prcm_registers(void)
2759{
2760 u32 val;
2761
2762 val = readl(PRCM_A9PL_FORCE_CLKEN);
2763 val &= ~(PRCM_A9PL_FORCE_CLKEN_PRCM_A9PL_FORCE_CLKEN |
2764 PRCM_A9PL_FORCE_CLKEN_PRCM_A9AXI_FORCE_CLKEN);
2765 writel(val, (PRCM_A9PL_FORCE_CLKEN));
2766}
2767
2768/*
2769 * Power domain switches (ePODs) modeled as regulators for the DB8500 SoC
2770 */
2771static struct regulator_consumer_supply db8500_vape_consumers[] = {
2772 REGULATOR_SUPPLY("v-ape", NULL),
2773 REGULATOR_SUPPLY("v-i2c", "nmk-i2c.0"),
2774 REGULATOR_SUPPLY("v-i2c", "nmk-i2c.1"),
2775 REGULATOR_SUPPLY("v-i2c", "nmk-i2c.2"),
2776 REGULATOR_SUPPLY("v-i2c", "nmk-i2c.3"),
2777 REGULATOR_SUPPLY("v-i2c", "nmk-i2c.4"),
2778 /* "v-mmc" changed to "vcore" in the mainline kernel */
2779 REGULATOR_SUPPLY("vcore", "sdi0"),
2780 REGULATOR_SUPPLY("vcore", "sdi1"),
2781 REGULATOR_SUPPLY("vcore", "sdi2"),
2782 REGULATOR_SUPPLY("vcore", "sdi3"),
2783 REGULATOR_SUPPLY("vcore", "sdi4"),
2784 REGULATOR_SUPPLY("v-dma", "dma40.0"),
2785 REGULATOR_SUPPLY("v-ape", "ab8500-usb.0"),
2786 /* "v-uart" changed to "vcore" in the mainline kernel */
2787 REGULATOR_SUPPLY("vcore", "uart0"),
2788 REGULATOR_SUPPLY("vcore", "uart1"),
2789 REGULATOR_SUPPLY("vcore", "uart2"),
2790 REGULATOR_SUPPLY("v-ape", "nmk-ske-keypad.0"),
2791 REGULATOR_SUPPLY("v-hsi", "ste_hsi.0"),
2792 REGULATOR_SUPPLY("vddvario", "smsc911x.0"),
2793};
2794
2795static struct regulator_consumer_supply db8500_vsmps2_consumers[] = {
2796 REGULATOR_SUPPLY("musb_1v8", "ab8500-usb.0"),
2797 /* AV8100 regulator */
2798 REGULATOR_SUPPLY("hdmi_1v8", "0-0070"),
2799};
2800
2801static struct regulator_consumer_supply db8500_b2r2_mcde_consumers[] = {
2802 REGULATOR_SUPPLY("vsupply", "b2r2_bus"),
2803 REGULATOR_SUPPLY("vsupply", "mcde"),
2804};
2805
2806/* SVA MMDSP regulator switch */
2807static struct regulator_consumer_supply db8500_svammdsp_consumers[] = {
2808 REGULATOR_SUPPLY("sva-mmdsp", "cm_control"),
2809};
2810
2811/* SVA pipe regulator switch */
2812static struct regulator_consumer_supply db8500_svapipe_consumers[] = {
2813 REGULATOR_SUPPLY("sva-pipe", "cm_control"),
2814};
2815
2816/* SIA MMDSP regulator switch */
2817static struct regulator_consumer_supply db8500_siammdsp_consumers[] = {
2818 REGULATOR_SUPPLY("sia-mmdsp", "cm_control"),
2819};
2820
2821/* SIA pipe regulator switch */
2822static struct regulator_consumer_supply db8500_siapipe_consumers[] = {
2823 REGULATOR_SUPPLY("sia-pipe", "cm_control"),
2824};
2825
2826static struct regulator_consumer_supply db8500_sga_consumers[] = {
2827 REGULATOR_SUPPLY("v-mali", NULL),
2828};
2829
2830/* ESRAM1 and 2 regulator switch */
2831static struct regulator_consumer_supply db8500_esram12_consumers[] = {
2832 REGULATOR_SUPPLY("esram12", "cm_control"),
2833};
2834
2835/* ESRAM3 and 4 regulator switch */
2836static struct regulator_consumer_supply db8500_esram34_consumers[] = {
2837 REGULATOR_SUPPLY("v-esram34", "mcde"),
2838 REGULATOR_SUPPLY("esram34", "cm_control"),
2839 REGULATOR_SUPPLY("lcla_esram", "dma40.0"),
2840};
2841
2842static struct regulator_init_data db8500_regulators[DB8500_NUM_REGULATORS] = {
2843 [DB8500_REGULATOR_VAPE] = {
2844 .constraints = {
2845 .name = "db8500-vape",
2846 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2847 .always_on = true,
2848 },
2849 .consumer_supplies = db8500_vape_consumers,
2850 .num_consumer_supplies = ARRAY_SIZE(db8500_vape_consumers),
2851 },
2852 [DB8500_REGULATOR_VARM] = {
2853 .constraints = {
2854 .name = "db8500-varm",
2855 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2856 },
2857 },
2858 [DB8500_REGULATOR_VMODEM] = {
2859 .constraints = {
2860 .name = "db8500-vmodem",
2861 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2862 },
2863 },
2864 [DB8500_REGULATOR_VPLL] = {
2865 .constraints = {
2866 .name = "db8500-vpll",
2867 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2868 },
2869 },
2870 [DB8500_REGULATOR_VSMPS1] = {
2871 .constraints = {
2872 .name = "db8500-vsmps1",
2873 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2874 },
2875 },
2876 [DB8500_REGULATOR_VSMPS2] = {
2877 .constraints = {
2878 .name = "db8500-vsmps2",
2879 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2880 },
2881 .consumer_supplies = db8500_vsmps2_consumers,
2882 .num_consumer_supplies = ARRAY_SIZE(db8500_vsmps2_consumers),
2883 },
2884 [DB8500_REGULATOR_VSMPS3] = {
2885 .constraints = {
2886 .name = "db8500-vsmps3",
2887 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2888 },
2889 },
2890 [DB8500_REGULATOR_VRF1] = {
2891 .constraints = {
2892 .name = "db8500-vrf1",
2893 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2894 },
2895 },
2896 [DB8500_REGULATOR_SWITCH_SVAMMDSP] = {
2897 /* dependency to u8500-vape is handled outside regulator framework */
2898 .constraints = {
2899 .name = "db8500-sva-mmdsp",
2900 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2901 },
2902 .consumer_supplies = db8500_svammdsp_consumers,
2903 .num_consumer_supplies = ARRAY_SIZE(db8500_svammdsp_consumers),
2904 },
2905 [DB8500_REGULATOR_SWITCH_SVAMMDSPRET] = {
2906 .constraints = {
2907 /* "ret" means "retention" */
2908 .name = "db8500-sva-mmdsp-ret",
2909 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2910 },
2911 },
2912 [DB8500_REGULATOR_SWITCH_SVAPIPE] = {
2913 /* dependency to u8500-vape is handled outside regulator framework */
2914 .constraints = {
2915 .name = "db8500-sva-pipe",
2916 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2917 },
2918 .consumer_supplies = db8500_svapipe_consumers,
2919 .num_consumer_supplies = ARRAY_SIZE(db8500_svapipe_consumers),
2920 },
2921 [DB8500_REGULATOR_SWITCH_SIAMMDSP] = {
2922 /* dependency to u8500-vape is handled outside regulator framework */
2923 .constraints = {
2924 .name = "db8500-sia-mmdsp",
2925 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2926 },
2927 .consumer_supplies = db8500_siammdsp_consumers,
2928 .num_consumer_supplies = ARRAY_SIZE(db8500_siammdsp_consumers),
2929 },
2930 [DB8500_REGULATOR_SWITCH_SIAMMDSPRET] = {
2931 .constraints = {
2932 .name = "db8500-sia-mmdsp-ret",
2933 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2934 },
2935 },
2936 [DB8500_REGULATOR_SWITCH_SIAPIPE] = {
2937 /* dependency to u8500-vape is handled outside regulator framework */
2938 .constraints = {
2939 .name = "db8500-sia-pipe",
2940 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2941 },
2942 .consumer_supplies = db8500_siapipe_consumers,
2943 .num_consumer_supplies = ARRAY_SIZE(db8500_siapipe_consumers),
2944 },
2945 [DB8500_REGULATOR_SWITCH_SGA] = {
2946 .supply_regulator = "db8500-vape",
2947 .constraints = {
2948 .name = "db8500-sga",
2949 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2950 },
2951 .consumer_supplies = db8500_sga_consumers,
2952 .num_consumer_supplies = ARRAY_SIZE(db8500_sga_consumers),
2953
2954 },
2955 [DB8500_REGULATOR_SWITCH_B2R2_MCDE] = {
2956 .supply_regulator = "db8500-vape",
2957 .constraints = {
2958 .name = "db8500-b2r2-mcde",
2959 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2960 },
2961 .consumer_supplies = db8500_b2r2_mcde_consumers,
2962 .num_consumer_supplies = ARRAY_SIZE(db8500_b2r2_mcde_consumers),
2963 },
2964 [DB8500_REGULATOR_SWITCH_ESRAM12] = {
2965 /*
2966 * esram12 is set in retention and supplied by Vsafe when Vape is off,
2967 * no need to hold Vape
2968 */
2969 .constraints = {
2970 .name = "db8500-esram12",
2971 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2972 },
2973 .consumer_supplies = db8500_esram12_consumers,
2974 .num_consumer_supplies = ARRAY_SIZE(db8500_esram12_consumers),
2975 },
2976 [DB8500_REGULATOR_SWITCH_ESRAM12RET] = {
2977 .constraints = {
2978 .name = "db8500-esram12-ret",
2979 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2980 },
2981 },
2982 [DB8500_REGULATOR_SWITCH_ESRAM34] = {
2983 /*
2984 * esram34 is set in retention and supplied by Vsafe when Vape is off,
2985 * no need to hold Vape
2986 */
2987 .constraints = {
2988 .name = "db8500-esram34",
2989 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2990 },
2991 .consumer_supplies = db8500_esram34_consumers,
2992 .num_consumer_supplies = ARRAY_SIZE(db8500_esram34_consumers),
2993 },
2994 [DB8500_REGULATOR_SWITCH_ESRAM34RET] = {
2995 .constraints = {
2996 .name = "db8500-esram34-ret",
2997 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2998 },
2999 },
3000};
3001
3002static struct ux500_wdt_data db8500_wdt_pdata = {
3003 .timeout = 600, /* 10 minutes */
3004 .has_28_bits_resolution = true,
3005};
3006/*
3007 * Thermal Sensor
3008 */
3009
3010static struct resource db8500_thsens_resources[] = {
3011 {
3012 .name = "IRQ_HOTMON_LOW",
3013 .start = IRQ_PRCMU_HOTMON_LOW,
3014 .end = IRQ_PRCMU_HOTMON_LOW,
3015 .flags = IORESOURCE_IRQ,
3016 },
3017 {
3018 .name = "IRQ_HOTMON_HIGH",
3019 .start = IRQ_PRCMU_HOTMON_HIGH,
3020 .end = IRQ_PRCMU_HOTMON_HIGH,
3021 .flags = IORESOURCE_IRQ,
3022 },
3023};
3024
3025static struct db8500_thsens_platform_data db8500_thsens_data = {
3026 .trip_points[0] = {
3027 .temp = 70000,
3028 .type = THERMAL_TRIP_ACTIVE,
3029 .cdev_name = {
3030 [0] = "thermal-cpufreq-0",
3031 },
3032 },
3033 .trip_points[1] = {
3034 .temp = 75000,
3035 .type = THERMAL_TRIP_ACTIVE,
3036 .cdev_name = {
3037 [0] = "thermal-cpufreq-0",
3038 },
3039 },
3040 .trip_points[2] = {
3041 .temp = 80000,
3042 .type = THERMAL_TRIP_ACTIVE,
3043 .cdev_name = {
3044 [0] = "thermal-cpufreq-0",
3045 },
3046 },
3047 .trip_points[3] = {
3048 .temp = 85000,
3049 .type = THERMAL_TRIP_CRITICAL,
3050 },
3051 .num_trips = 4,
3052};
3053
3054static const struct mfd_cell common_prcmu_devs[] = {
3055 {
3056 .name = "ux500_wdt",
3057 .platform_data = &db8500_wdt_pdata,
3058 .pdata_size = sizeof(db8500_wdt_pdata),
3059 .id = -1,
3060 },
3061};
3062
3063static const struct mfd_cell db8500_prcmu_devs[] = {
3064 {
3065 .name = "db8500-prcmu-regulators",
3066 .of_compatible = "stericsson,db8500-prcmu-regulator",
3067 .platform_data = &db8500_regulators,
3068 .pdata_size = sizeof(db8500_regulators),
3069 },
3070 {
3071 .name = "cpufreq-ux500",
3072 .of_compatible = "stericsson,cpufreq-ux500",
3073 .platform_data = &db8500_cpufreq_table,
3074 .pdata_size = sizeof(db8500_cpufreq_table),
3075 },
3076 {
3077 .name = "cpuidle-dbx500",
3078 .of_compatible = "stericsson,cpuidle-dbx500",
3079 },
3080 {
3081 .name = "db8500-thermal",
3082 .num_resources = ARRAY_SIZE(db8500_thsens_resources),
3083 .resources = db8500_thsens_resources,
3084 .platform_data = &db8500_thsens_data,
3085 .pdata_size = sizeof(db8500_thsens_data),
3086 },
3087};
3088
3089static void db8500_prcmu_update_cpufreq(void)
3090{
3091 if (prcmu_has_arm_maxopp()) {
3092 db8500_cpufreq_table[3].frequency = 1000000;
3093 db8500_cpufreq_table[3].driver_data = ARM_MAX_OPP;
3094 }
3095}
3096
3097static int db8500_prcmu_register_ab8500(struct device *parent,
3098 struct ab8500_platform_data *pdata)
3099{
3100 struct device_node *np;
3101 struct resource ab8500_resource;
3102 const struct mfd_cell ab8500_cell = {
3103 .name = "ab8500-core",
3104 .of_compatible = "stericsson,ab8500",
3105 .id = AB8500_VERSION_AB8500,
3106 .platform_data = pdata,
3107 .pdata_size = sizeof(struct ab8500_platform_data),
3108 .resources = &ab8500_resource,
3109 .num_resources = 1,
3110 };
3111
3112 if (!parent->of_node)
3113 return -ENODEV;
3114
3115 /* Look up the device node, sneak the IRQ out of it */
3116 for_each_child_of_node(parent->of_node, np) {
3117 if (of_device_is_compatible(np, ab8500_cell.of_compatible))
3118 break;
3119 }
3120 if (!np) {
3121 dev_info(parent, "could not find AB8500 node in the device tree\n");
3122 return -ENODEV;
3123 }
3124 of_irq_to_resource_table(np, &ab8500_resource, 1);
3125
3126 return mfd_add_devices(parent, 0, &ab8500_cell, 1, NULL, 0, NULL);
3127}
3128
3129/**
3130 * prcmu_fw_init - arch init call for the Linux PRCMU fw init logic
3131 *
3132 */
3133static int db8500_prcmu_probe(struct platform_device *pdev)
3134{
3135 struct device_node *np = pdev->dev.of_node;
3136 struct prcmu_pdata *pdata = dev_get_platdata(&pdev->dev);
3137 int irq = 0, err = 0;
3138 struct resource *res;
3139
3140 res = platform_get_resource_byname(pdev, IORESOURCE_MEM, "prcmu");
3141 if (!res) {
3142 dev_err(&pdev->dev, "no prcmu memory region provided\n");
3143 return -EINVAL;
3144 }
3145 prcmu_base = devm_ioremap(&pdev->dev, res->start, resource_size(res));
3146 if (!prcmu_base) {
3147 dev_err(&pdev->dev,
3148 "failed to ioremap prcmu register memory\n");
3149 return -ENOMEM;
3150 }
3151 init_prcm_registers();
3152 dbx500_fw_version_init(pdev, pdata->version_offset);
3153 res = platform_get_resource_byname(pdev, IORESOURCE_MEM, "prcmu-tcdm");
3154 if (!res) {
3155 dev_err(&pdev->dev, "no prcmu tcdm region provided\n");
3156 return -EINVAL;
3157 }
3158 tcdm_base = devm_ioremap(&pdev->dev, res->start,
3159 resource_size(res));
3160 if (!tcdm_base) {
3161 dev_err(&pdev->dev,
3162 "failed to ioremap prcmu-tcdm register memory\n");
3163 return -ENOMEM;
3164 }
3165
3166 /* Clean up the mailbox interrupts after pre-kernel code. */
3167 writel(ALL_MBOX_BITS, PRCM_ARM_IT1_CLR);
3168
3169 irq = platform_get_irq(pdev, 0);
3170 if (irq <= 0) {
3171 dev_err(&pdev->dev, "no prcmu irq provided\n");
3172 return irq;
3173 }
3174
3175 err = request_threaded_irq(irq, prcmu_irq_handler,
3176 prcmu_irq_thread_fn, IRQF_NO_SUSPEND, "prcmu", NULL);
3177 if (err < 0) {
3178 pr_err("prcmu: Failed to allocate IRQ_DB8500_PRCMU1.\n");
3179 return err;
3180 }
3181
3182 db8500_irq_init(np);
3183
3184 prcmu_config_esram0_deep_sleep(ESRAM0_DEEP_SLEEP_STATE_RET);
3185
3186 db8500_prcmu_update_cpufreq();
3187
3188 err = mfd_add_devices(&pdev->dev, 0, common_prcmu_devs,
3189 ARRAY_SIZE(common_prcmu_devs), NULL, 0, db8500_irq_domain);
3190 if (err) {
3191 pr_err("prcmu: Failed to add subdevices\n");
3192 return err;
3193 }
3194
3195 /* TODO: Remove restriction when clk definitions are available. */
3196 if (!of_machine_is_compatible("st-ericsson,u8540")) {
3197 err = mfd_add_devices(&pdev->dev, 0, db8500_prcmu_devs,
3198 ARRAY_SIZE(db8500_prcmu_devs), NULL, 0,
3199 db8500_irq_domain);
3200 if (err) {
3201 mfd_remove_devices(&pdev->dev);
3202 pr_err("prcmu: Failed to add subdevices\n");
3203 return err;
3204 }
3205 }
3206
3207 err = db8500_prcmu_register_ab8500(&pdev->dev, pdata->ab_platdata);
3208 if (err) {
3209 mfd_remove_devices(&pdev->dev);
3210 pr_err("prcmu: Failed to add ab8500 subdevice\n");
3211 return err;
3212 }
3213
3214 pr_info("DB8500 PRCMU initialized\n");
3215 return err;
3216}
3217static const struct of_device_id db8500_prcmu_match[] = {
3218 { .compatible = "stericsson,db8500-prcmu"},
3219 { },
3220};
3221
3222static struct platform_driver db8500_prcmu_driver = {
3223 .driver = {
3224 .name = "db8500-prcmu",
3225 .of_match_table = db8500_prcmu_match,
3226 },
3227 .probe = db8500_prcmu_probe,
3228};
3229
3230static int __init db8500_prcmu_init(void)
3231{
3232 return platform_driver_register(&db8500_prcmu_driver);
3233}
3234
3235core_initcall(db8500_prcmu_init);
3236
3237MODULE_AUTHOR("Mattias Nilsson <mattias.i.nilsson@stericsson.com>");
3238MODULE_DESCRIPTION("DB8500 PRCM Unit driver");
3239MODULE_LICENSE("GPL v2");
1/*
2 * Copyright (C) STMicroelectronics 2009
3 * Copyright (C) ST-Ericsson SA 2010
4 *
5 * License Terms: GNU General Public License v2
6 * Author: Kumar Sanghvi <kumar.sanghvi@stericsson.com>
7 * Author: Sundar Iyer <sundar.iyer@stericsson.com>
8 * Author: Mattias Nilsson <mattias.i.nilsson@stericsson.com>
9 *
10 * U8500 PRCM Unit interface driver
11 *
12 */
13#include <linux/module.h>
14#include <linux/kernel.h>
15#include <linux/delay.h>
16#include <linux/errno.h>
17#include <linux/err.h>
18#include <linux/spinlock.h>
19#include <linux/io.h>
20#include <linux/slab.h>
21#include <linux/mutex.h>
22#include <linux/completion.h>
23#include <linux/irq.h>
24#include <linux/jiffies.h>
25#include <linux/bitops.h>
26#include <linux/fs.h>
27#include <linux/platform_device.h>
28#include <linux/uaccess.h>
29#include <linux/mfd/core.h>
30#include <linux/mfd/dbx500-prcmu.h>
31#include <linux/regulator/db8500-prcmu.h>
32#include <linux/regulator/machine.h>
33#include <asm/hardware/gic.h>
34#include <mach/hardware.h>
35#include <mach/irqs.h>
36#include <mach/db8500-regs.h>
37#include <mach/id.h>
38#include "dbx500-prcmu-regs.h"
39
40/* Offset for the firmware version within the TCPM */
41#define PRCMU_FW_VERSION_OFFSET 0xA4
42
43/* Index of different voltages to be used when accessing AVSData */
44#define PRCM_AVS_BASE 0x2FC
45#define PRCM_AVS_VBB_RET (PRCM_AVS_BASE + 0x0)
46#define PRCM_AVS_VBB_MAX_OPP (PRCM_AVS_BASE + 0x1)
47#define PRCM_AVS_VBB_100_OPP (PRCM_AVS_BASE + 0x2)
48#define PRCM_AVS_VBB_50_OPP (PRCM_AVS_BASE + 0x3)
49#define PRCM_AVS_VARM_MAX_OPP (PRCM_AVS_BASE + 0x4)
50#define PRCM_AVS_VARM_100_OPP (PRCM_AVS_BASE + 0x5)
51#define PRCM_AVS_VARM_50_OPP (PRCM_AVS_BASE + 0x6)
52#define PRCM_AVS_VARM_RET (PRCM_AVS_BASE + 0x7)
53#define PRCM_AVS_VAPE_100_OPP (PRCM_AVS_BASE + 0x8)
54#define PRCM_AVS_VAPE_50_OPP (PRCM_AVS_BASE + 0x9)
55#define PRCM_AVS_VMOD_100_OPP (PRCM_AVS_BASE + 0xA)
56#define PRCM_AVS_VMOD_50_OPP (PRCM_AVS_BASE + 0xB)
57#define PRCM_AVS_VSAFE (PRCM_AVS_BASE + 0xC)
58
59#define PRCM_AVS_VOLTAGE 0
60#define PRCM_AVS_VOLTAGE_MASK 0x3f
61#define PRCM_AVS_ISSLOWSTARTUP 6
62#define PRCM_AVS_ISSLOWSTARTUP_MASK (1 << PRCM_AVS_ISSLOWSTARTUP)
63#define PRCM_AVS_ISMODEENABLE 7
64#define PRCM_AVS_ISMODEENABLE_MASK (1 << PRCM_AVS_ISMODEENABLE)
65
66#define PRCM_BOOT_STATUS 0xFFF
67#define PRCM_ROMCODE_A2P 0xFFE
68#define PRCM_ROMCODE_P2A 0xFFD
69#define PRCM_XP70_CUR_PWR_STATE 0xFFC /* 4 BYTES */
70
71#define PRCM_SW_RST_REASON 0xFF8 /* 2 bytes */
72
73#define _PRCM_MBOX_HEADER 0xFE8 /* 16 bytes */
74#define PRCM_MBOX_HEADER_REQ_MB0 (_PRCM_MBOX_HEADER + 0x0)
75#define PRCM_MBOX_HEADER_REQ_MB1 (_PRCM_MBOX_HEADER + 0x1)
76#define PRCM_MBOX_HEADER_REQ_MB2 (_PRCM_MBOX_HEADER + 0x2)
77#define PRCM_MBOX_HEADER_REQ_MB3 (_PRCM_MBOX_HEADER + 0x3)
78#define PRCM_MBOX_HEADER_REQ_MB4 (_PRCM_MBOX_HEADER + 0x4)
79#define PRCM_MBOX_HEADER_REQ_MB5 (_PRCM_MBOX_HEADER + 0x5)
80#define PRCM_MBOX_HEADER_ACK_MB0 (_PRCM_MBOX_HEADER + 0x8)
81
82/* Req Mailboxes */
83#define PRCM_REQ_MB0 0xFDC /* 12 bytes */
84#define PRCM_REQ_MB1 0xFD0 /* 12 bytes */
85#define PRCM_REQ_MB2 0xFC0 /* 16 bytes */
86#define PRCM_REQ_MB3 0xE4C /* 372 bytes */
87#define PRCM_REQ_MB4 0xE48 /* 4 bytes */
88#define PRCM_REQ_MB5 0xE44 /* 4 bytes */
89
90/* Ack Mailboxes */
91#define PRCM_ACK_MB0 0xE08 /* 52 bytes */
92#define PRCM_ACK_MB1 0xE04 /* 4 bytes */
93#define PRCM_ACK_MB2 0xE00 /* 4 bytes */
94#define PRCM_ACK_MB3 0xDFC /* 4 bytes */
95#define PRCM_ACK_MB4 0xDF8 /* 4 bytes */
96#define PRCM_ACK_MB5 0xDF4 /* 4 bytes */
97
98/* Mailbox 0 headers */
99#define MB0H_POWER_STATE_TRANS 0
100#define MB0H_CONFIG_WAKEUPS_EXE 1
101#define MB0H_READ_WAKEUP_ACK 3
102#define MB0H_CONFIG_WAKEUPS_SLEEP 4
103
104#define MB0H_WAKEUP_EXE 2
105#define MB0H_WAKEUP_SLEEP 5
106
107/* Mailbox 0 REQs */
108#define PRCM_REQ_MB0_AP_POWER_STATE (PRCM_REQ_MB0 + 0x0)
109#define PRCM_REQ_MB0_AP_PLL_STATE (PRCM_REQ_MB0 + 0x1)
110#define PRCM_REQ_MB0_ULP_CLOCK_STATE (PRCM_REQ_MB0 + 0x2)
111#define PRCM_REQ_MB0_DO_NOT_WFI (PRCM_REQ_MB0 + 0x3)
112#define PRCM_REQ_MB0_WAKEUP_8500 (PRCM_REQ_MB0 + 0x4)
113#define PRCM_REQ_MB0_WAKEUP_4500 (PRCM_REQ_MB0 + 0x8)
114
115/* Mailbox 0 ACKs */
116#define PRCM_ACK_MB0_AP_PWRSTTR_STATUS (PRCM_ACK_MB0 + 0x0)
117#define PRCM_ACK_MB0_READ_POINTER (PRCM_ACK_MB0 + 0x1)
118#define PRCM_ACK_MB0_WAKEUP_0_8500 (PRCM_ACK_MB0 + 0x4)
119#define PRCM_ACK_MB0_WAKEUP_0_4500 (PRCM_ACK_MB0 + 0x8)
120#define PRCM_ACK_MB0_WAKEUP_1_8500 (PRCM_ACK_MB0 + 0x1C)
121#define PRCM_ACK_MB0_WAKEUP_1_4500 (PRCM_ACK_MB0 + 0x20)
122#define PRCM_ACK_MB0_EVENT_4500_NUMBERS 20
123
124/* Mailbox 1 headers */
125#define MB1H_ARM_APE_OPP 0x0
126#define MB1H_RESET_MODEM 0x2
127#define MB1H_REQUEST_APE_OPP_100_VOLT 0x3
128#define MB1H_RELEASE_APE_OPP_100_VOLT 0x4
129#define MB1H_RELEASE_USB_WAKEUP 0x5
130#define MB1H_PLL_ON_OFF 0x6
131
132/* Mailbox 1 Requests */
133#define PRCM_REQ_MB1_ARM_OPP (PRCM_REQ_MB1 + 0x0)
134#define PRCM_REQ_MB1_APE_OPP (PRCM_REQ_MB1 + 0x1)
135#define PRCM_REQ_MB1_PLL_ON_OFF (PRCM_REQ_MB1 + 0x4)
136#define PLL_SOC0_OFF 0x1
137#define PLL_SOC0_ON 0x2
138#define PLL_SOC1_OFF 0x4
139#define PLL_SOC1_ON 0x8
140
141/* Mailbox 1 ACKs */
142#define PRCM_ACK_MB1_CURRENT_ARM_OPP (PRCM_ACK_MB1 + 0x0)
143#define PRCM_ACK_MB1_CURRENT_APE_OPP (PRCM_ACK_MB1 + 0x1)
144#define PRCM_ACK_MB1_APE_VOLTAGE_STATUS (PRCM_ACK_MB1 + 0x2)
145#define PRCM_ACK_MB1_DVFS_STATUS (PRCM_ACK_MB1 + 0x3)
146
147/* Mailbox 2 headers */
148#define MB2H_DPS 0x0
149#define MB2H_AUTO_PWR 0x1
150
151/* Mailbox 2 REQs */
152#define PRCM_REQ_MB2_SVA_MMDSP (PRCM_REQ_MB2 + 0x0)
153#define PRCM_REQ_MB2_SVA_PIPE (PRCM_REQ_MB2 + 0x1)
154#define PRCM_REQ_MB2_SIA_MMDSP (PRCM_REQ_MB2 + 0x2)
155#define PRCM_REQ_MB2_SIA_PIPE (PRCM_REQ_MB2 + 0x3)
156#define PRCM_REQ_MB2_SGA (PRCM_REQ_MB2 + 0x4)
157#define PRCM_REQ_MB2_B2R2_MCDE (PRCM_REQ_MB2 + 0x5)
158#define PRCM_REQ_MB2_ESRAM12 (PRCM_REQ_MB2 + 0x6)
159#define PRCM_REQ_MB2_ESRAM34 (PRCM_REQ_MB2 + 0x7)
160#define PRCM_REQ_MB2_AUTO_PM_SLEEP (PRCM_REQ_MB2 + 0x8)
161#define PRCM_REQ_MB2_AUTO_PM_IDLE (PRCM_REQ_MB2 + 0xC)
162
163/* Mailbox 2 ACKs */
164#define PRCM_ACK_MB2_DPS_STATUS (PRCM_ACK_MB2 + 0x0)
165#define HWACC_PWR_ST_OK 0xFE
166
167/* Mailbox 3 headers */
168#define MB3H_ANC 0x0
169#define MB3H_SIDETONE 0x1
170#define MB3H_SYSCLK 0xE
171
172/* Mailbox 3 Requests */
173#define PRCM_REQ_MB3_ANC_FIR_COEFF (PRCM_REQ_MB3 + 0x0)
174#define PRCM_REQ_MB3_ANC_IIR_COEFF (PRCM_REQ_MB3 + 0x20)
175#define PRCM_REQ_MB3_ANC_SHIFTER (PRCM_REQ_MB3 + 0x60)
176#define PRCM_REQ_MB3_ANC_WARP (PRCM_REQ_MB3 + 0x64)
177#define PRCM_REQ_MB3_SIDETONE_FIR_GAIN (PRCM_REQ_MB3 + 0x68)
178#define PRCM_REQ_MB3_SIDETONE_FIR_COEFF (PRCM_REQ_MB3 + 0x6C)
179#define PRCM_REQ_MB3_SYSCLK_MGT (PRCM_REQ_MB3 + 0x16C)
180
181/* Mailbox 4 headers */
182#define MB4H_DDR_INIT 0x0
183#define MB4H_MEM_ST 0x1
184#define MB4H_HOTDOG 0x12
185#define MB4H_HOTMON 0x13
186#define MB4H_HOT_PERIOD 0x14
187#define MB4H_A9WDOG_CONF 0x16
188#define MB4H_A9WDOG_EN 0x17
189#define MB4H_A9WDOG_DIS 0x18
190#define MB4H_A9WDOG_LOAD 0x19
191#define MB4H_A9WDOG_KICK 0x20
192
193/* Mailbox 4 Requests */
194#define PRCM_REQ_MB4_DDR_ST_AP_SLEEP_IDLE (PRCM_REQ_MB4 + 0x0)
195#define PRCM_REQ_MB4_DDR_ST_AP_DEEP_IDLE (PRCM_REQ_MB4 + 0x1)
196#define PRCM_REQ_MB4_ESRAM0_ST (PRCM_REQ_MB4 + 0x3)
197#define PRCM_REQ_MB4_HOTDOG_THRESHOLD (PRCM_REQ_MB4 + 0x0)
198#define PRCM_REQ_MB4_HOTMON_LOW (PRCM_REQ_MB4 + 0x0)
199#define PRCM_REQ_MB4_HOTMON_HIGH (PRCM_REQ_MB4 + 0x1)
200#define PRCM_REQ_MB4_HOTMON_CONFIG (PRCM_REQ_MB4 + 0x2)
201#define PRCM_REQ_MB4_HOT_PERIOD (PRCM_REQ_MB4 + 0x0)
202#define HOTMON_CONFIG_LOW BIT(0)
203#define HOTMON_CONFIG_HIGH BIT(1)
204#define PRCM_REQ_MB4_A9WDOG_0 (PRCM_REQ_MB4 + 0x0)
205#define PRCM_REQ_MB4_A9WDOG_1 (PRCM_REQ_MB4 + 0x1)
206#define PRCM_REQ_MB4_A9WDOG_2 (PRCM_REQ_MB4 + 0x2)
207#define PRCM_REQ_MB4_A9WDOG_3 (PRCM_REQ_MB4 + 0x3)
208#define A9WDOG_AUTO_OFF_EN BIT(7)
209#define A9WDOG_AUTO_OFF_DIS 0
210#define A9WDOG_ID_MASK 0xf
211
212/* Mailbox 5 Requests */
213#define PRCM_REQ_MB5_I2C_SLAVE_OP (PRCM_REQ_MB5 + 0x0)
214#define PRCM_REQ_MB5_I2C_HW_BITS (PRCM_REQ_MB5 + 0x1)
215#define PRCM_REQ_MB5_I2C_REG (PRCM_REQ_MB5 + 0x2)
216#define PRCM_REQ_MB5_I2C_VAL (PRCM_REQ_MB5 + 0x3)
217#define PRCMU_I2C_WRITE(slave) \
218 (((slave) << 1) | (cpu_is_u8500v2() ? BIT(6) : 0))
219#define PRCMU_I2C_READ(slave) \
220 (((slave) << 1) | BIT(0) | (cpu_is_u8500v2() ? BIT(6) : 0))
221#define PRCMU_I2C_STOP_EN BIT(3)
222
223/* Mailbox 5 ACKs */
224#define PRCM_ACK_MB5_I2C_STATUS (PRCM_ACK_MB5 + 0x1)
225#define PRCM_ACK_MB5_I2C_VAL (PRCM_ACK_MB5 + 0x3)
226#define I2C_WR_OK 0x1
227#define I2C_RD_OK 0x2
228
229#define NUM_MB 8
230#define MBOX_BIT BIT
231#define ALL_MBOX_BITS (MBOX_BIT(NUM_MB) - 1)
232
233/*
234 * Wakeups/IRQs
235 */
236
237#define WAKEUP_BIT_RTC BIT(0)
238#define WAKEUP_BIT_RTT0 BIT(1)
239#define WAKEUP_BIT_RTT1 BIT(2)
240#define WAKEUP_BIT_HSI0 BIT(3)
241#define WAKEUP_BIT_HSI1 BIT(4)
242#define WAKEUP_BIT_CA_WAKE BIT(5)
243#define WAKEUP_BIT_USB BIT(6)
244#define WAKEUP_BIT_ABB BIT(7)
245#define WAKEUP_BIT_ABB_FIFO BIT(8)
246#define WAKEUP_BIT_SYSCLK_OK BIT(9)
247#define WAKEUP_BIT_CA_SLEEP BIT(10)
248#define WAKEUP_BIT_AC_WAKE_ACK BIT(11)
249#define WAKEUP_BIT_SIDE_TONE_OK BIT(12)
250#define WAKEUP_BIT_ANC_OK BIT(13)
251#define WAKEUP_BIT_SW_ERROR BIT(14)
252#define WAKEUP_BIT_AC_SLEEP_ACK BIT(15)
253#define WAKEUP_BIT_ARM BIT(17)
254#define WAKEUP_BIT_HOTMON_LOW BIT(18)
255#define WAKEUP_BIT_HOTMON_HIGH BIT(19)
256#define WAKEUP_BIT_MODEM_SW_RESET_REQ BIT(20)
257#define WAKEUP_BIT_GPIO0 BIT(23)
258#define WAKEUP_BIT_GPIO1 BIT(24)
259#define WAKEUP_BIT_GPIO2 BIT(25)
260#define WAKEUP_BIT_GPIO3 BIT(26)
261#define WAKEUP_BIT_GPIO4 BIT(27)
262#define WAKEUP_BIT_GPIO5 BIT(28)
263#define WAKEUP_BIT_GPIO6 BIT(29)
264#define WAKEUP_BIT_GPIO7 BIT(30)
265#define WAKEUP_BIT_GPIO8 BIT(31)
266
267static struct {
268 bool valid;
269 struct prcmu_fw_version version;
270} fw_info;
271
272/*
273 * This vector maps irq numbers to the bits in the bit field used in
274 * communication with the PRCMU firmware.
275 *
276 * The reason for having this is to keep the irq numbers contiguous even though
277 * the bits in the bit field are not. (The bits also have a tendency to move
278 * around, to further complicate matters.)
279 */
280#define IRQ_INDEX(_name) ((IRQ_PRCMU_##_name) - IRQ_PRCMU_BASE)
281#define IRQ_ENTRY(_name)[IRQ_INDEX(_name)] = (WAKEUP_BIT_##_name)
282static u32 prcmu_irq_bit[NUM_PRCMU_WAKEUPS] = {
283 IRQ_ENTRY(RTC),
284 IRQ_ENTRY(RTT0),
285 IRQ_ENTRY(RTT1),
286 IRQ_ENTRY(HSI0),
287 IRQ_ENTRY(HSI1),
288 IRQ_ENTRY(CA_WAKE),
289 IRQ_ENTRY(USB),
290 IRQ_ENTRY(ABB),
291 IRQ_ENTRY(ABB_FIFO),
292 IRQ_ENTRY(CA_SLEEP),
293 IRQ_ENTRY(ARM),
294 IRQ_ENTRY(HOTMON_LOW),
295 IRQ_ENTRY(HOTMON_HIGH),
296 IRQ_ENTRY(MODEM_SW_RESET_REQ),
297 IRQ_ENTRY(GPIO0),
298 IRQ_ENTRY(GPIO1),
299 IRQ_ENTRY(GPIO2),
300 IRQ_ENTRY(GPIO3),
301 IRQ_ENTRY(GPIO4),
302 IRQ_ENTRY(GPIO5),
303 IRQ_ENTRY(GPIO6),
304 IRQ_ENTRY(GPIO7),
305 IRQ_ENTRY(GPIO8)
306};
307
308#define VALID_WAKEUPS (BIT(NUM_PRCMU_WAKEUP_INDICES) - 1)
309#define WAKEUP_ENTRY(_name)[PRCMU_WAKEUP_INDEX_##_name] = (WAKEUP_BIT_##_name)
310static u32 prcmu_wakeup_bit[NUM_PRCMU_WAKEUP_INDICES] = {
311 WAKEUP_ENTRY(RTC),
312 WAKEUP_ENTRY(RTT0),
313 WAKEUP_ENTRY(RTT1),
314 WAKEUP_ENTRY(HSI0),
315 WAKEUP_ENTRY(HSI1),
316 WAKEUP_ENTRY(USB),
317 WAKEUP_ENTRY(ABB),
318 WAKEUP_ENTRY(ABB_FIFO),
319 WAKEUP_ENTRY(ARM)
320};
321
322/*
323 * mb0_transfer - state needed for mailbox 0 communication.
324 * @lock: The transaction lock.
325 * @dbb_events_lock: A lock used to handle concurrent access to (parts of)
326 * the request data.
327 * @mask_work: Work structure used for (un)masking wakeup interrupts.
328 * @req: Request data that need to persist between requests.
329 */
330static struct {
331 spinlock_t lock;
332 spinlock_t dbb_irqs_lock;
333 struct work_struct mask_work;
334 struct mutex ac_wake_lock;
335 struct completion ac_wake_work;
336 struct {
337 u32 dbb_irqs;
338 u32 dbb_wakeups;
339 u32 abb_events;
340 } req;
341} mb0_transfer;
342
343/*
344 * mb1_transfer - state needed for mailbox 1 communication.
345 * @lock: The transaction lock.
346 * @work: The transaction completion structure.
347 * @ape_opp: The current APE OPP.
348 * @ack: Reply ("acknowledge") data.
349 */
350static struct {
351 struct mutex lock;
352 struct completion work;
353 u8 ape_opp;
354 struct {
355 u8 header;
356 u8 arm_opp;
357 u8 ape_opp;
358 u8 ape_voltage_status;
359 } ack;
360} mb1_transfer;
361
362/*
363 * mb2_transfer - state needed for mailbox 2 communication.
364 * @lock: The transaction lock.
365 * @work: The transaction completion structure.
366 * @auto_pm_lock: The autonomous power management configuration lock.
367 * @auto_pm_enabled: A flag indicating whether autonomous PM is enabled.
368 * @req: Request data that need to persist between requests.
369 * @ack: Reply ("acknowledge") data.
370 */
371static struct {
372 struct mutex lock;
373 struct completion work;
374 spinlock_t auto_pm_lock;
375 bool auto_pm_enabled;
376 struct {
377 u8 status;
378 } ack;
379} mb2_transfer;
380
381/*
382 * mb3_transfer - state needed for mailbox 3 communication.
383 * @lock: The request lock.
384 * @sysclk_lock: A lock used to handle concurrent sysclk requests.
385 * @sysclk_work: Work structure used for sysclk requests.
386 */
387static struct {
388 spinlock_t lock;
389 struct mutex sysclk_lock;
390 struct completion sysclk_work;
391} mb3_transfer;
392
393/*
394 * mb4_transfer - state needed for mailbox 4 communication.
395 * @lock: The transaction lock.
396 * @work: The transaction completion structure.
397 */
398static struct {
399 struct mutex lock;
400 struct completion work;
401} mb4_transfer;
402
403/*
404 * mb5_transfer - state needed for mailbox 5 communication.
405 * @lock: The transaction lock.
406 * @work: The transaction completion structure.
407 * @ack: Reply ("acknowledge") data.
408 */
409static struct {
410 struct mutex lock;
411 struct completion work;
412 struct {
413 u8 status;
414 u8 value;
415 } ack;
416} mb5_transfer;
417
418static atomic_t ac_wake_req_state = ATOMIC_INIT(0);
419
420/* Spinlocks */
421static DEFINE_SPINLOCK(prcmu_lock);
422static DEFINE_SPINLOCK(clkout_lock);
423
424/* Global var to runtime determine TCDM base for v2 or v1 */
425static __iomem void *tcdm_base;
426
427struct clk_mgt {
428 void __iomem *reg;
429 u32 pllsw;
430 int branch;
431 bool clk38div;
432};
433
434enum {
435 PLL_RAW,
436 PLL_FIX,
437 PLL_DIV
438};
439
440static DEFINE_SPINLOCK(clk_mgt_lock);
441
442#define CLK_MGT_ENTRY(_name, _branch, _clk38div)[PRCMU_##_name] = \
443 { (PRCM_##_name##_MGT), 0 , _branch, _clk38div}
444struct clk_mgt clk_mgt[PRCMU_NUM_REG_CLOCKS] = {
445 CLK_MGT_ENTRY(SGACLK, PLL_DIV, false),
446 CLK_MGT_ENTRY(UARTCLK, PLL_FIX, true),
447 CLK_MGT_ENTRY(MSP02CLK, PLL_FIX, true),
448 CLK_MGT_ENTRY(MSP1CLK, PLL_FIX, true),
449 CLK_MGT_ENTRY(I2CCLK, PLL_FIX, true),
450 CLK_MGT_ENTRY(SDMMCCLK, PLL_DIV, true),
451 CLK_MGT_ENTRY(SLIMCLK, PLL_FIX, true),
452 CLK_MGT_ENTRY(PER1CLK, PLL_DIV, true),
453 CLK_MGT_ENTRY(PER2CLK, PLL_DIV, true),
454 CLK_MGT_ENTRY(PER3CLK, PLL_DIV, true),
455 CLK_MGT_ENTRY(PER5CLK, PLL_DIV, true),
456 CLK_MGT_ENTRY(PER6CLK, PLL_DIV, true),
457 CLK_MGT_ENTRY(PER7CLK, PLL_DIV, true),
458 CLK_MGT_ENTRY(LCDCLK, PLL_FIX, true),
459 CLK_MGT_ENTRY(BMLCLK, PLL_DIV, true),
460 CLK_MGT_ENTRY(HSITXCLK, PLL_DIV, true),
461 CLK_MGT_ENTRY(HSIRXCLK, PLL_DIV, true),
462 CLK_MGT_ENTRY(HDMICLK, PLL_FIX, false),
463 CLK_MGT_ENTRY(APEATCLK, PLL_DIV, true),
464 CLK_MGT_ENTRY(APETRACECLK, PLL_DIV, true),
465 CLK_MGT_ENTRY(MCDECLK, PLL_DIV, true),
466 CLK_MGT_ENTRY(IPI2CCLK, PLL_FIX, true),
467 CLK_MGT_ENTRY(DSIALTCLK, PLL_FIX, false),
468 CLK_MGT_ENTRY(DMACLK, PLL_DIV, true),
469 CLK_MGT_ENTRY(B2R2CLK, PLL_DIV, true),
470 CLK_MGT_ENTRY(TVCLK, PLL_FIX, true),
471 CLK_MGT_ENTRY(SSPCLK, PLL_FIX, true),
472 CLK_MGT_ENTRY(RNGCLK, PLL_FIX, true),
473 CLK_MGT_ENTRY(UICCCLK, PLL_FIX, false),
474};
475
476struct dsiclk {
477 u32 divsel_mask;
478 u32 divsel_shift;
479 u32 divsel;
480};
481
482static struct dsiclk dsiclk[2] = {
483 {
484 .divsel_mask = PRCM_DSI_PLLOUT_SEL_DSI0_PLLOUT_DIVSEL_MASK,
485 .divsel_shift = PRCM_DSI_PLLOUT_SEL_DSI0_PLLOUT_DIVSEL_SHIFT,
486 .divsel = PRCM_DSI_PLLOUT_SEL_PHI,
487 },
488 {
489 .divsel_mask = PRCM_DSI_PLLOUT_SEL_DSI1_PLLOUT_DIVSEL_MASK,
490 .divsel_shift = PRCM_DSI_PLLOUT_SEL_DSI1_PLLOUT_DIVSEL_SHIFT,
491 .divsel = PRCM_DSI_PLLOUT_SEL_PHI,
492 }
493};
494
495struct dsiescclk {
496 u32 en;
497 u32 div_mask;
498 u32 div_shift;
499};
500
501static struct dsiescclk dsiescclk[3] = {
502 {
503 .en = PRCM_DSITVCLK_DIV_DSI0_ESC_CLK_EN,
504 .div_mask = PRCM_DSITVCLK_DIV_DSI0_ESC_CLK_DIV_MASK,
505 .div_shift = PRCM_DSITVCLK_DIV_DSI0_ESC_CLK_DIV_SHIFT,
506 },
507 {
508 .en = PRCM_DSITVCLK_DIV_DSI1_ESC_CLK_EN,
509 .div_mask = PRCM_DSITVCLK_DIV_DSI1_ESC_CLK_DIV_MASK,
510 .div_shift = PRCM_DSITVCLK_DIV_DSI1_ESC_CLK_DIV_SHIFT,
511 },
512 {
513 .en = PRCM_DSITVCLK_DIV_DSI2_ESC_CLK_EN,
514 .div_mask = PRCM_DSITVCLK_DIV_DSI2_ESC_CLK_DIV_MASK,
515 .div_shift = PRCM_DSITVCLK_DIV_DSI2_ESC_CLK_DIV_SHIFT,
516 }
517};
518
519/*
520* Used by MCDE to setup all necessary PRCMU registers
521*/
522#define PRCMU_RESET_DSIPLL 0x00004000
523#define PRCMU_UNCLAMP_DSIPLL 0x00400800
524
525#define PRCMU_CLK_PLL_DIV_SHIFT 0
526#define PRCMU_CLK_PLL_SW_SHIFT 5
527#define PRCMU_CLK_38 (1 << 9)
528#define PRCMU_CLK_38_SRC (1 << 10)
529#define PRCMU_CLK_38_DIV (1 << 11)
530
531/* PLLDIV=12, PLLSW=4 (PLLDDR) */
532#define PRCMU_DSI_CLOCK_SETTING 0x0000008C
533
534/* DPI 50000000 Hz */
535#define PRCMU_DPI_CLOCK_SETTING ((1 << PRCMU_CLK_PLL_SW_SHIFT) | \
536 (16 << PRCMU_CLK_PLL_DIV_SHIFT))
537#define PRCMU_DSI_LP_CLOCK_SETTING 0x00000E00
538
539/* D=101, N=1, R=4, SELDIV2=0 */
540#define PRCMU_PLLDSI_FREQ_SETTING 0x00040165
541
542#define PRCMU_ENABLE_PLLDSI 0x00000001
543#define PRCMU_DISABLE_PLLDSI 0x00000000
544#define PRCMU_RELEASE_RESET_DSS 0x0000400C
545#define PRCMU_DSI_PLLOUT_SEL_SETTING 0x00000202
546/* ESC clk, div0=1, div1=1, div2=3 */
547#define PRCMU_ENABLE_ESCAPE_CLOCK_DIV 0x07030101
548#define PRCMU_DISABLE_ESCAPE_CLOCK_DIV 0x00030101
549#define PRCMU_DSI_RESET_SW 0x00000007
550
551#define PRCMU_PLLDSI_LOCKP_LOCKED 0x3
552
553int db8500_prcmu_enable_dsipll(void)
554{
555 int i;
556
557 /* Clear DSIPLL_RESETN */
558 writel(PRCMU_RESET_DSIPLL, PRCM_APE_RESETN_CLR);
559 /* Unclamp DSIPLL in/out */
560 writel(PRCMU_UNCLAMP_DSIPLL, PRCM_MMIP_LS_CLAMP_CLR);
561
562 /* Set DSI PLL FREQ */
563 writel(PRCMU_PLLDSI_FREQ_SETTING, PRCM_PLLDSI_FREQ);
564 writel(PRCMU_DSI_PLLOUT_SEL_SETTING, PRCM_DSI_PLLOUT_SEL);
565 /* Enable Escape clocks */
566 writel(PRCMU_ENABLE_ESCAPE_CLOCK_DIV, PRCM_DSITVCLK_DIV);
567
568 /* Start DSI PLL */
569 writel(PRCMU_ENABLE_PLLDSI, PRCM_PLLDSI_ENABLE);
570 /* Reset DSI PLL */
571 writel(PRCMU_DSI_RESET_SW, PRCM_DSI_SW_RESET);
572 for (i = 0; i < 10; i++) {
573 if ((readl(PRCM_PLLDSI_LOCKP) & PRCMU_PLLDSI_LOCKP_LOCKED)
574 == PRCMU_PLLDSI_LOCKP_LOCKED)
575 break;
576 udelay(100);
577 }
578 /* Set DSIPLL_RESETN */
579 writel(PRCMU_RESET_DSIPLL, PRCM_APE_RESETN_SET);
580 return 0;
581}
582
583int db8500_prcmu_disable_dsipll(void)
584{
585 /* Disable dsi pll */
586 writel(PRCMU_DISABLE_PLLDSI, PRCM_PLLDSI_ENABLE);
587 /* Disable escapeclock */
588 writel(PRCMU_DISABLE_ESCAPE_CLOCK_DIV, PRCM_DSITVCLK_DIV);
589 return 0;
590}
591
592int db8500_prcmu_set_display_clocks(void)
593{
594 unsigned long flags;
595
596 spin_lock_irqsave(&clk_mgt_lock, flags);
597
598 /* Grab the HW semaphore. */
599 while ((readl(PRCM_SEM) & PRCM_SEM_PRCM_SEM) != 0)
600 cpu_relax();
601
602 writel(PRCMU_DSI_CLOCK_SETTING, PRCM_HDMICLK_MGT);
603 writel(PRCMU_DSI_LP_CLOCK_SETTING, PRCM_TVCLK_MGT);
604 writel(PRCMU_DPI_CLOCK_SETTING, PRCM_LCDCLK_MGT);
605
606 /* Release the HW semaphore. */
607 writel(0, PRCM_SEM);
608
609 spin_unlock_irqrestore(&clk_mgt_lock, flags);
610
611 return 0;
612}
613
614u32 db8500_prcmu_read(unsigned int reg)
615{
616 return readl(_PRCMU_BASE + reg);
617}
618
619void db8500_prcmu_write(unsigned int reg, u32 value)
620{
621 unsigned long flags;
622
623 spin_lock_irqsave(&prcmu_lock, flags);
624 writel(value, (_PRCMU_BASE + reg));
625 spin_unlock_irqrestore(&prcmu_lock, flags);
626}
627
628void db8500_prcmu_write_masked(unsigned int reg, u32 mask, u32 value)
629{
630 u32 val;
631 unsigned long flags;
632
633 spin_lock_irqsave(&prcmu_lock, flags);
634 val = readl(_PRCMU_BASE + reg);
635 val = ((val & ~mask) | (value & mask));
636 writel(val, (_PRCMU_BASE + reg));
637 spin_unlock_irqrestore(&prcmu_lock, flags);
638}
639
640struct prcmu_fw_version *prcmu_get_fw_version(void)
641{
642 return fw_info.valid ? &fw_info.version : NULL;
643}
644
645bool prcmu_has_arm_maxopp(void)
646{
647 return (readb(tcdm_base + PRCM_AVS_VARM_MAX_OPP) &
648 PRCM_AVS_ISMODEENABLE_MASK) == PRCM_AVS_ISMODEENABLE_MASK;
649}
650
651/**
652 * prcmu_get_boot_status - PRCMU boot status checking
653 * Returns: the current PRCMU boot status
654 */
655int prcmu_get_boot_status(void)
656{
657 return readb(tcdm_base + PRCM_BOOT_STATUS);
658}
659
660/**
661 * prcmu_set_rc_a2p - This function is used to run few power state sequences
662 * @val: Value to be set, i.e. transition requested
663 * Returns: 0 on success, -EINVAL on invalid argument
664 *
665 * This function is used to run the following power state sequences -
666 * any state to ApReset, ApDeepSleep to ApExecute, ApExecute to ApDeepSleep
667 */
668int prcmu_set_rc_a2p(enum romcode_write val)
669{
670 if (val < RDY_2_DS || val > RDY_2_XP70_RST)
671 return -EINVAL;
672 writeb(val, (tcdm_base + PRCM_ROMCODE_A2P));
673 return 0;
674}
675
676/**
677 * prcmu_get_rc_p2a - This function is used to get power state sequences
678 * Returns: the power transition that has last happened
679 *
680 * This function can return the following transitions-
681 * any state to ApReset, ApDeepSleep to ApExecute, ApExecute to ApDeepSleep
682 */
683enum romcode_read prcmu_get_rc_p2a(void)
684{
685 return readb(tcdm_base + PRCM_ROMCODE_P2A);
686}
687
688/**
689 * prcmu_get_current_mode - Return the current XP70 power mode
690 * Returns: Returns the current AP(ARM) power mode: init,
691 * apBoot, apExecute, apDeepSleep, apSleep, apIdle, apReset
692 */
693enum ap_pwrst prcmu_get_xp70_current_state(void)
694{
695 return readb(tcdm_base + PRCM_XP70_CUR_PWR_STATE);
696}
697
698/**
699 * prcmu_config_clkout - Configure one of the programmable clock outputs.
700 * @clkout: The CLKOUT number (0 or 1).
701 * @source: The clock to be used (one of the PRCMU_CLKSRC_*).
702 * @div: The divider to be applied.
703 *
704 * Configures one of the programmable clock outputs (CLKOUTs).
705 * @div should be in the range [1,63] to request a configuration, or 0 to
706 * inform that the configuration is no longer requested.
707 */
708int prcmu_config_clkout(u8 clkout, u8 source, u8 div)
709{
710 static int requests[2];
711 int r = 0;
712 unsigned long flags;
713 u32 val;
714 u32 bits;
715 u32 mask;
716 u32 div_mask;
717
718 BUG_ON(clkout > 1);
719 BUG_ON(div > 63);
720 BUG_ON((clkout == 0) && (source > PRCMU_CLKSRC_CLK009));
721
722 if (!div && !requests[clkout])
723 return -EINVAL;
724
725 switch (clkout) {
726 case 0:
727 div_mask = PRCM_CLKOCR_CLKODIV0_MASK;
728 mask = (PRCM_CLKOCR_CLKODIV0_MASK | PRCM_CLKOCR_CLKOSEL0_MASK);
729 bits = ((source << PRCM_CLKOCR_CLKOSEL0_SHIFT) |
730 (div << PRCM_CLKOCR_CLKODIV0_SHIFT));
731 break;
732 case 1:
733 div_mask = PRCM_CLKOCR_CLKODIV1_MASK;
734 mask = (PRCM_CLKOCR_CLKODIV1_MASK | PRCM_CLKOCR_CLKOSEL1_MASK |
735 PRCM_CLKOCR_CLK1TYPE);
736 bits = ((source << PRCM_CLKOCR_CLKOSEL1_SHIFT) |
737 (div << PRCM_CLKOCR_CLKODIV1_SHIFT));
738 break;
739 }
740 bits &= mask;
741
742 spin_lock_irqsave(&clkout_lock, flags);
743
744 val = readl(PRCM_CLKOCR);
745 if (val & div_mask) {
746 if (div) {
747 if ((val & mask) != bits) {
748 r = -EBUSY;
749 goto unlock_and_return;
750 }
751 } else {
752 if ((val & mask & ~div_mask) != bits) {
753 r = -EINVAL;
754 goto unlock_and_return;
755 }
756 }
757 }
758 writel((bits | (val & ~mask)), PRCM_CLKOCR);
759 requests[clkout] += (div ? 1 : -1);
760
761unlock_and_return:
762 spin_unlock_irqrestore(&clkout_lock, flags);
763
764 return r;
765}
766
767int db8500_prcmu_set_power_state(u8 state, bool keep_ulp_clk, bool keep_ap_pll)
768{
769 unsigned long flags;
770
771 BUG_ON((state < PRCMU_AP_SLEEP) || (PRCMU_AP_DEEP_IDLE < state));
772
773 spin_lock_irqsave(&mb0_transfer.lock, flags);
774
775 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(0))
776 cpu_relax();
777
778 writeb(MB0H_POWER_STATE_TRANS, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB0));
779 writeb(state, (tcdm_base + PRCM_REQ_MB0_AP_POWER_STATE));
780 writeb((keep_ap_pll ? 1 : 0), (tcdm_base + PRCM_REQ_MB0_AP_PLL_STATE));
781 writeb((keep_ulp_clk ? 1 : 0),
782 (tcdm_base + PRCM_REQ_MB0_ULP_CLOCK_STATE));
783 writeb(0, (tcdm_base + PRCM_REQ_MB0_DO_NOT_WFI));
784 writel(MBOX_BIT(0), PRCM_MBOX_CPU_SET);
785
786 spin_unlock_irqrestore(&mb0_transfer.lock, flags);
787
788 return 0;
789}
790
791u8 db8500_prcmu_get_power_state_result(void)
792{
793 return readb(tcdm_base + PRCM_ACK_MB0_AP_PWRSTTR_STATUS);
794}
795
796/* This function decouple the gic from the prcmu */
797int db8500_prcmu_gic_decouple(void)
798{
799 u32 val = readl(PRCM_A9_MASK_REQ);
800
801 /* Set bit 0 register value to 1 */
802 writel(val | PRCM_A9_MASK_REQ_PRCM_A9_MASK_REQ,
803 PRCM_A9_MASK_REQ);
804
805 /* Make sure the register is updated */
806 readl(PRCM_A9_MASK_REQ);
807
808 /* Wait a few cycles for the gic mask completion */
809 udelay(1);
810
811 return 0;
812}
813
814/* This function recouple the gic with the prcmu */
815int db8500_prcmu_gic_recouple(void)
816{
817 u32 val = readl(PRCM_A9_MASK_REQ);
818
819 /* Set bit 0 register value to 0 */
820 writel(val & ~PRCM_A9_MASK_REQ_PRCM_A9_MASK_REQ, PRCM_A9_MASK_REQ);
821
822 return 0;
823}
824
825#define PRCMU_GIC_NUMBER_REGS 5
826
827/*
828 * This function checks if there are pending irq on the gic. It only
829 * makes sense if the gic has been decoupled before with the
830 * db8500_prcmu_gic_decouple function. Disabling an interrupt only
831 * disables the forwarding of the interrupt to any CPU interface. It
832 * does not prevent the interrupt from changing state, for example
833 * becoming pending, or active and pending if it is already
834 * active. Hence, we have to check the interrupt is pending *and* is
835 * active.
836 */
837bool db8500_prcmu_gic_pending_irq(void)
838{
839 u32 pr; /* Pending register */
840 u32 er; /* Enable register */
841 void __iomem *dist_base = __io_address(U8500_GIC_DIST_BASE);
842 int i;
843
844 /* 5 registers. STI & PPI not skipped */
845 for (i = 0; i < PRCMU_GIC_NUMBER_REGS; i++) {
846
847 pr = readl_relaxed(dist_base + GIC_DIST_PENDING_SET + i * 4);
848 er = readl_relaxed(dist_base + GIC_DIST_ENABLE_SET + i * 4);
849
850 if (pr & er)
851 return true; /* There is a pending interrupt */
852 }
853
854 return false;
855}
856
857/*
858 * This function checks if there are pending interrupt on the
859 * prcmu which has been delegated to monitor the irqs with the
860 * db8500_prcmu_copy_gic_settings function.
861 */
862bool db8500_prcmu_pending_irq(void)
863{
864 u32 it, im;
865 int i;
866
867 for (i = 0; i < PRCMU_GIC_NUMBER_REGS - 1; i++) {
868 it = readl(PRCM_ARMITVAL31TO0 + i * 4);
869 im = readl(PRCM_ARMITMSK31TO0 + i * 4);
870 if (it & im)
871 return true; /* There is a pending interrupt */
872 }
873
874 return false;
875}
876
877/*
878 * This function checks if the specified cpu is in in WFI. It's usage
879 * makes sense only if the gic is decoupled with the db8500_prcmu_gic_decouple
880 * function. Of course passing smp_processor_id() to this function will
881 * always return false...
882 */
883bool db8500_prcmu_is_cpu_in_wfi(int cpu)
884{
885 return readl(PRCM_ARM_WFI_STANDBY) & cpu ? PRCM_ARM_WFI_STANDBY_WFI1 :
886 PRCM_ARM_WFI_STANDBY_WFI0;
887}
888
889/*
890 * This function copies the gic SPI settings to the prcmu in order to
891 * monitor them and abort/finish the retention/off sequence or state.
892 */
893int db8500_prcmu_copy_gic_settings(void)
894{
895 u32 er; /* Enable register */
896 void __iomem *dist_base = __io_address(U8500_GIC_DIST_BASE);
897 int i;
898
899 /* We skip the STI and PPI */
900 for (i = 0; i < PRCMU_GIC_NUMBER_REGS - 1; i++) {
901 er = readl_relaxed(dist_base +
902 GIC_DIST_ENABLE_SET + (i + 1) * 4);
903 writel(er, PRCM_ARMITMSK31TO0 + i * 4);
904 }
905
906 return 0;
907}
908
909/* This function should only be called while mb0_transfer.lock is held. */
910static void config_wakeups(void)
911{
912 const u8 header[2] = {
913 MB0H_CONFIG_WAKEUPS_EXE,
914 MB0H_CONFIG_WAKEUPS_SLEEP
915 };
916 static u32 last_dbb_events;
917 static u32 last_abb_events;
918 u32 dbb_events;
919 u32 abb_events;
920 unsigned int i;
921
922 dbb_events = mb0_transfer.req.dbb_irqs | mb0_transfer.req.dbb_wakeups;
923 dbb_events |= (WAKEUP_BIT_AC_WAKE_ACK | WAKEUP_BIT_AC_SLEEP_ACK);
924
925 abb_events = mb0_transfer.req.abb_events;
926
927 if ((dbb_events == last_dbb_events) && (abb_events == last_abb_events))
928 return;
929
930 for (i = 0; i < 2; i++) {
931 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(0))
932 cpu_relax();
933 writel(dbb_events, (tcdm_base + PRCM_REQ_MB0_WAKEUP_8500));
934 writel(abb_events, (tcdm_base + PRCM_REQ_MB0_WAKEUP_4500));
935 writeb(header[i], (tcdm_base + PRCM_MBOX_HEADER_REQ_MB0));
936 writel(MBOX_BIT(0), PRCM_MBOX_CPU_SET);
937 }
938 last_dbb_events = dbb_events;
939 last_abb_events = abb_events;
940}
941
942void db8500_prcmu_enable_wakeups(u32 wakeups)
943{
944 unsigned long flags;
945 u32 bits;
946 int i;
947
948 BUG_ON(wakeups != (wakeups & VALID_WAKEUPS));
949
950 for (i = 0, bits = 0; i < NUM_PRCMU_WAKEUP_INDICES; i++) {
951 if (wakeups & BIT(i))
952 bits |= prcmu_wakeup_bit[i];
953 }
954
955 spin_lock_irqsave(&mb0_transfer.lock, flags);
956
957 mb0_transfer.req.dbb_wakeups = bits;
958 config_wakeups();
959
960 spin_unlock_irqrestore(&mb0_transfer.lock, flags);
961}
962
963void db8500_prcmu_config_abb_event_readout(u32 abb_events)
964{
965 unsigned long flags;
966
967 spin_lock_irqsave(&mb0_transfer.lock, flags);
968
969 mb0_transfer.req.abb_events = abb_events;
970 config_wakeups();
971
972 spin_unlock_irqrestore(&mb0_transfer.lock, flags);
973}
974
975void db8500_prcmu_get_abb_event_buffer(void __iomem **buf)
976{
977 if (readb(tcdm_base + PRCM_ACK_MB0_READ_POINTER) & 1)
978 *buf = (tcdm_base + PRCM_ACK_MB0_WAKEUP_1_4500);
979 else
980 *buf = (tcdm_base + PRCM_ACK_MB0_WAKEUP_0_4500);
981}
982
983/**
984 * db8500_prcmu_set_arm_opp - set the appropriate ARM OPP
985 * @opp: The new ARM operating point to which transition is to be made
986 * Returns: 0 on success, non-zero on failure
987 *
988 * This function sets the the operating point of the ARM.
989 */
990int db8500_prcmu_set_arm_opp(u8 opp)
991{
992 int r;
993
994 if (opp < ARM_NO_CHANGE || opp > ARM_EXTCLK)
995 return -EINVAL;
996
997 r = 0;
998
999 mutex_lock(&mb1_transfer.lock);
1000
1001 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(1))
1002 cpu_relax();
1003
1004 writeb(MB1H_ARM_APE_OPP, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB1));
1005 writeb(opp, (tcdm_base + PRCM_REQ_MB1_ARM_OPP));
1006 writeb(APE_NO_CHANGE, (tcdm_base + PRCM_REQ_MB1_APE_OPP));
1007
1008 writel(MBOX_BIT(1), PRCM_MBOX_CPU_SET);
1009 wait_for_completion(&mb1_transfer.work);
1010
1011 if ((mb1_transfer.ack.header != MB1H_ARM_APE_OPP) ||
1012 (mb1_transfer.ack.arm_opp != opp))
1013 r = -EIO;
1014
1015 mutex_unlock(&mb1_transfer.lock);
1016
1017 return r;
1018}
1019
1020/**
1021 * db8500_prcmu_get_arm_opp - get the current ARM OPP
1022 *
1023 * Returns: the current ARM OPP
1024 */
1025int db8500_prcmu_get_arm_opp(void)
1026{
1027 return readb(tcdm_base + PRCM_ACK_MB1_CURRENT_ARM_OPP);
1028}
1029
1030/**
1031 * db8500_prcmu_get_ddr_opp - get the current DDR OPP
1032 *
1033 * Returns: the current DDR OPP
1034 */
1035int db8500_prcmu_get_ddr_opp(void)
1036{
1037 return readb(PRCM_DDR_SUBSYS_APE_MINBW);
1038}
1039
1040/**
1041 * db8500_set_ddr_opp - set the appropriate DDR OPP
1042 * @opp: The new DDR operating point to which transition is to be made
1043 * Returns: 0 on success, non-zero on failure
1044 *
1045 * This function sets the operating point of the DDR.
1046 */
1047int db8500_prcmu_set_ddr_opp(u8 opp)
1048{
1049 if (opp < DDR_100_OPP || opp > DDR_25_OPP)
1050 return -EINVAL;
1051 /* Changing the DDR OPP can hang the hardware pre-v21 */
1052 if (cpu_is_u8500v20_or_later() && !cpu_is_u8500v20())
1053 writeb(opp, PRCM_DDR_SUBSYS_APE_MINBW);
1054
1055 return 0;
1056}
1057
1058/* Divide the frequency of certain clocks by 2 for APE_50_PARTLY_25_OPP. */
1059static void request_even_slower_clocks(bool enable)
1060{
1061 void __iomem *clock_reg[] = {
1062 PRCM_ACLK_MGT,
1063 PRCM_DMACLK_MGT
1064 };
1065 unsigned long flags;
1066 unsigned int i;
1067
1068 spin_lock_irqsave(&clk_mgt_lock, flags);
1069
1070 /* Grab the HW semaphore. */
1071 while ((readl(PRCM_SEM) & PRCM_SEM_PRCM_SEM) != 0)
1072 cpu_relax();
1073
1074 for (i = 0; i < ARRAY_SIZE(clock_reg); i++) {
1075 u32 val;
1076 u32 div;
1077
1078 val = readl(clock_reg[i]);
1079 div = (val & PRCM_CLK_MGT_CLKPLLDIV_MASK);
1080 if (enable) {
1081 if ((div <= 1) || (div > 15)) {
1082 pr_err("prcmu: Bad clock divider %d in %s\n",
1083 div, __func__);
1084 goto unlock_and_return;
1085 }
1086 div <<= 1;
1087 } else {
1088 if (div <= 2)
1089 goto unlock_and_return;
1090 div >>= 1;
1091 }
1092 val = ((val & ~PRCM_CLK_MGT_CLKPLLDIV_MASK) |
1093 (div & PRCM_CLK_MGT_CLKPLLDIV_MASK));
1094 writel(val, clock_reg[i]);
1095 }
1096
1097unlock_and_return:
1098 /* Release the HW semaphore. */
1099 writel(0, PRCM_SEM);
1100
1101 spin_unlock_irqrestore(&clk_mgt_lock, flags);
1102}
1103
1104/**
1105 * db8500_set_ape_opp - set the appropriate APE OPP
1106 * @opp: The new APE operating point to which transition is to be made
1107 * Returns: 0 on success, non-zero on failure
1108 *
1109 * This function sets the operating point of the APE.
1110 */
1111int db8500_prcmu_set_ape_opp(u8 opp)
1112{
1113 int r = 0;
1114
1115 if (opp == mb1_transfer.ape_opp)
1116 return 0;
1117
1118 mutex_lock(&mb1_transfer.lock);
1119
1120 if (mb1_transfer.ape_opp == APE_50_PARTLY_25_OPP)
1121 request_even_slower_clocks(false);
1122
1123 if ((opp != APE_100_OPP) && (mb1_transfer.ape_opp != APE_100_OPP))
1124 goto skip_message;
1125
1126 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(1))
1127 cpu_relax();
1128
1129 writeb(MB1H_ARM_APE_OPP, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB1));
1130 writeb(ARM_NO_CHANGE, (tcdm_base + PRCM_REQ_MB1_ARM_OPP));
1131 writeb(((opp == APE_50_PARTLY_25_OPP) ? APE_50_OPP : opp),
1132 (tcdm_base + PRCM_REQ_MB1_APE_OPP));
1133
1134 writel(MBOX_BIT(1), PRCM_MBOX_CPU_SET);
1135 wait_for_completion(&mb1_transfer.work);
1136
1137 if ((mb1_transfer.ack.header != MB1H_ARM_APE_OPP) ||
1138 (mb1_transfer.ack.ape_opp != opp))
1139 r = -EIO;
1140
1141skip_message:
1142 if ((!r && (opp == APE_50_PARTLY_25_OPP)) ||
1143 (r && (mb1_transfer.ape_opp == APE_50_PARTLY_25_OPP)))
1144 request_even_slower_clocks(true);
1145 if (!r)
1146 mb1_transfer.ape_opp = opp;
1147
1148 mutex_unlock(&mb1_transfer.lock);
1149
1150 return r;
1151}
1152
1153/**
1154 * db8500_prcmu_get_ape_opp - get the current APE OPP
1155 *
1156 * Returns: the current APE OPP
1157 */
1158int db8500_prcmu_get_ape_opp(void)
1159{
1160 return readb(tcdm_base + PRCM_ACK_MB1_CURRENT_APE_OPP);
1161}
1162
1163/**
1164 * prcmu_request_ape_opp_100_voltage - Request APE OPP 100% voltage
1165 * @enable: true to request the higher voltage, false to drop a request.
1166 *
1167 * Calls to this function to enable and disable requests must be balanced.
1168 */
1169int prcmu_request_ape_opp_100_voltage(bool enable)
1170{
1171 int r = 0;
1172 u8 header;
1173 static unsigned int requests;
1174
1175 mutex_lock(&mb1_transfer.lock);
1176
1177 if (enable) {
1178 if (0 != requests++)
1179 goto unlock_and_return;
1180 header = MB1H_REQUEST_APE_OPP_100_VOLT;
1181 } else {
1182 if (requests == 0) {
1183 r = -EIO;
1184 goto unlock_and_return;
1185 } else if (1 != requests--) {
1186 goto unlock_and_return;
1187 }
1188 header = MB1H_RELEASE_APE_OPP_100_VOLT;
1189 }
1190
1191 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(1))
1192 cpu_relax();
1193
1194 writeb(header, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB1));
1195
1196 writel(MBOX_BIT(1), PRCM_MBOX_CPU_SET);
1197 wait_for_completion(&mb1_transfer.work);
1198
1199 if ((mb1_transfer.ack.header != header) ||
1200 ((mb1_transfer.ack.ape_voltage_status & BIT(0)) != 0))
1201 r = -EIO;
1202
1203unlock_and_return:
1204 mutex_unlock(&mb1_transfer.lock);
1205
1206 return r;
1207}
1208
1209/**
1210 * prcmu_release_usb_wakeup_state - release the state required by a USB wakeup
1211 *
1212 * This function releases the power state requirements of a USB wakeup.
1213 */
1214int prcmu_release_usb_wakeup_state(void)
1215{
1216 int r = 0;
1217
1218 mutex_lock(&mb1_transfer.lock);
1219
1220 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(1))
1221 cpu_relax();
1222
1223 writeb(MB1H_RELEASE_USB_WAKEUP,
1224 (tcdm_base + PRCM_MBOX_HEADER_REQ_MB1));
1225
1226 writel(MBOX_BIT(1), PRCM_MBOX_CPU_SET);
1227 wait_for_completion(&mb1_transfer.work);
1228
1229 if ((mb1_transfer.ack.header != MB1H_RELEASE_USB_WAKEUP) ||
1230 ((mb1_transfer.ack.ape_voltage_status & BIT(0)) != 0))
1231 r = -EIO;
1232
1233 mutex_unlock(&mb1_transfer.lock);
1234
1235 return r;
1236}
1237
1238static int request_pll(u8 clock, bool enable)
1239{
1240 int r = 0;
1241
1242 if (clock == PRCMU_PLLSOC0)
1243 clock = (enable ? PLL_SOC0_ON : PLL_SOC0_OFF);
1244 else if (clock == PRCMU_PLLSOC1)
1245 clock = (enable ? PLL_SOC1_ON : PLL_SOC1_OFF);
1246 else
1247 return -EINVAL;
1248
1249 mutex_lock(&mb1_transfer.lock);
1250
1251 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(1))
1252 cpu_relax();
1253
1254 writeb(MB1H_PLL_ON_OFF, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB1));
1255 writeb(clock, (tcdm_base + PRCM_REQ_MB1_PLL_ON_OFF));
1256
1257 writel(MBOX_BIT(1), PRCM_MBOX_CPU_SET);
1258 wait_for_completion(&mb1_transfer.work);
1259
1260 if (mb1_transfer.ack.header != MB1H_PLL_ON_OFF)
1261 r = -EIO;
1262
1263 mutex_unlock(&mb1_transfer.lock);
1264
1265 return r;
1266}
1267
1268/**
1269 * db8500_prcmu_set_epod - set the state of a EPOD (power domain)
1270 * @epod_id: The EPOD to set
1271 * @epod_state: The new EPOD state
1272 *
1273 * This function sets the state of a EPOD (power domain). It may not be called
1274 * from interrupt context.
1275 */
1276int db8500_prcmu_set_epod(u16 epod_id, u8 epod_state)
1277{
1278 int r = 0;
1279 bool ram_retention = false;
1280 int i;
1281
1282 /* check argument */
1283 BUG_ON(epod_id >= NUM_EPOD_ID);
1284
1285 /* set flag if retention is possible */
1286 switch (epod_id) {
1287 case EPOD_ID_SVAMMDSP:
1288 case EPOD_ID_SIAMMDSP:
1289 case EPOD_ID_ESRAM12:
1290 case EPOD_ID_ESRAM34:
1291 ram_retention = true;
1292 break;
1293 }
1294
1295 /* check argument */
1296 BUG_ON(epod_state > EPOD_STATE_ON);
1297 BUG_ON(epod_state == EPOD_STATE_RAMRET && !ram_retention);
1298
1299 /* get lock */
1300 mutex_lock(&mb2_transfer.lock);
1301
1302 /* wait for mailbox */
1303 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(2))
1304 cpu_relax();
1305
1306 /* fill in mailbox */
1307 for (i = 0; i < NUM_EPOD_ID; i++)
1308 writeb(EPOD_STATE_NO_CHANGE, (tcdm_base + PRCM_REQ_MB2 + i));
1309 writeb(epod_state, (tcdm_base + PRCM_REQ_MB2 + epod_id));
1310
1311 writeb(MB2H_DPS, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB2));
1312
1313 writel(MBOX_BIT(2), PRCM_MBOX_CPU_SET);
1314
1315 /*
1316 * The current firmware version does not handle errors correctly,
1317 * and we cannot recover if there is an error.
1318 * This is expected to change when the firmware is updated.
1319 */
1320 if (!wait_for_completion_timeout(&mb2_transfer.work,
1321 msecs_to_jiffies(20000))) {
1322 pr_err("prcmu: %s timed out (20 s) waiting for a reply.\n",
1323 __func__);
1324 r = -EIO;
1325 goto unlock_and_return;
1326 }
1327
1328 if (mb2_transfer.ack.status != HWACC_PWR_ST_OK)
1329 r = -EIO;
1330
1331unlock_and_return:
1332 mutex_unlock(&mb2_transfer.lock);
1333 return r;
1334}
1335
1336/**
1337 * prcmu_configure_auto_pm - Configure autonomous power management.
1338 * @sleep: Configuration for ApSleep.
1339 * @idle: Configuration for ApIdle.
1340 */
1341void prcmu_configure_auto_pm(struct prcmu_auto_pm_config *sleep,
1342 struct prcmu_auto_pm_config *idle)
1343{
1344 u32 sleep_cfg;
1345 u32 idle_cfg;
1346 unsigned long flags;
1347
1348 BUG_ON((sleep == NULL) || (idle == NULL));
1349
1350 sleep_cfg = (sleep->sva_auto_pm_enable & 0xF);
1351 sleep_cfg = ((sleep_cfg << 4) | (sleep->sia_auto_pm_enable & 0xF));
1352 sleep_cfg = ((sleep_cfg << 8) | (sleep->sva_power_on & 0xFF));
1353 sleep_cfg = ((sleep_cfg << 8) | (sleep->sia_power_on & 0xFF));
1354 sleep_cfg = ((sleep_cfg << 4) | (sleep->sva_policy & 0xF));
1355 sleep_cfg = ((sleep_cfg << 4) | (sleep->sia_policy & 0xF));
1356
1357 idle_cfg = (idle->sva_auto_pm_enable & 0xF);
1358 idle_cfg = ((idle_cfg << 4) | (idle->sia_auto_pm_enable & 0xF));
1359 idle_cfg = ((idle_cfg << 8) | (idle->sva_power_on & 0xFF));
1360 idle_cfg = ((idle_cfg << 8) | (idle->sia_power_on & 0xFF));
1361 idle_cfg = ((idle_cfg << 4) | (idle->sva_policy & 0xF));
1362 idle_cfg = ((idle_cfg << 4) | (idle->sia_policy & 0xF));
1363
1364 spin_lock_irqsave(&mb2_transfer.auto_pm_lock, flags);
1365
1366 /*
1367 * The autonomous power management configuration is done through
1368 * fields in mailbox 2, but these fields are only used as shared
1369 * variables - i.e. there is no need to send a message.
1370 */
1371 writel(sleep_cfg, (tcdm_base + PRCM_REQ_MB2_AUTO_PM_SLEEP));
1372 writel(idle_cfg, (tcdm_base + PRCM_REQ_MB2_AUTO_PM_IDLE));
1373
1374 mb2_transfer.auto_pm_enabled =
1375 ((sleep->sva_auto_pm_enable == PRCMU_AUTO_PM_ON) ||
1376 (sleep->sia_auto_pm_enable == PRCMU_AUTO_PM_ON) ||
1377 (idle->sva_auto_pm_enable == PRCMU_AUTO_PM_ON) ||
1378 (idle->sia_auto_pm_enable == PRCMU_AUTO_PM_ON));
1379
1380 spin_unlock_irqrestore(&mb2_transfer.auto_pm_lock, flags);
1381}
1382EXPORT_SYMBOL(prcmu_configure_auto_pm);
1383
1384bool prcmu_is_auto_pm_enabled(void)
1385{
1386 return mb2_transfer.auto_pm_enabled;
1387}
1388
1389static int request_sysclk(bool enable)
1390{
1391 int r;
1392 unsigned long flags;
1393
1394 r = 0;
1395
1396 mutex_lock(&mb3_transfer.sysclk_lock);
1397
1398 spin_lock_irqsave(&mb3_transfer.lock, flags);
1399
1400 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(3))
1401 cpu_relax();
1402
1403 writeb((enable ? ON : OFF), (tcdm_base + PRCM_REQ_MB3_SYSCLK_MGT));
1404
1405 writeb(MB3H_SYSCLK, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB3));
1406 writel(MBOX_BIT(3), PRCM_MBOX_CPU_SET);
1407
1408 spin_unlock_irqrestore(&mb3_transfer.lock, flags);
1409
1410 /*
1411 * The firmware only sends an ACK if we want to enable the
1412 * SysClk, and it succeeds.
1413 */
1414 if (enable && !wait_for_completion_timeout(&mb3_transfer.sysclk_work,
1415 msecs_to_jiffies(20000))) {
1416 pr_err("prcmu: %s timed out (20 s) waiting for a reply.\n",
1417 __func__);
1418 r = -EIO;
1419 }
1420
1421 mutex_unlock(&mb3_transfer.sysclk_lock);
1422
1423 return r;
1424}
1425
1426static int request_timclk(bool enable)
1427{
1428 u32 val = (PRCM_TCR_DOZE_MODE | PRCM_TCR_TENSEL_MASK);
1429
1430 if (!enable)
1431 val |= PRCM_TCR_STOP_TIMERS;
1432 writel(val, PRCM_TCR);
1433
1434 return 0;
1435}
1436
1437static int request_clock(u8 clock, bool enable)
1438{
1439 u32 val;
1440 unsigned long flags;
1441
1442 spin_lock_irqsave(&clk_mgt_lock, flags);
1443
1444 /* Grab the HW semaphore. */
1445 while ((readl(PRCM_SEM) & PRCM_SEM_PRCM_SEM) != 0)
1446 cpu_relax();
1447
1448 val = readl(clk_mgt[clock].reg);
1449 if (enable) {
1450 val |= (PRCM_CLK_MGT_CLKEN | clk_mgt[clock].pllsw);
1451 } else {
1452 clk_mgt[clock].pllsw = (val & PRCM_CLK_MGT_CLKPLLSW_MASK);
1453 val &= ~(PRCM_CLK_MGT_CLKEN | PRCM_CLK_MGT_CLKPLLSW_MASK);
1454 }
1455 writel(val, clk_mgt[clock].reg);
1456
1457 /* Release the HW semaphore. */
1458 writel(0, PRCM_SEM);
1459
1460 spin_unlock_irqrestore(&clk_mgt_lock, flags);
1461
1462 return 0;
1463}
1464
1465static int request_sga_clock(u8 clock, bool enable)
1466{
1467 u32 val;
1468 int ret;
1469
1470 if (enable) {
1471 val = readl(PRCM_CGATING_BYPASS);
1472 writel(val | PRCM_CGATING_BYPASS_ICN2, PRCM_CGATING_BYPASS);
1473 }
1474
1475 ret = request_clock(clock, enable);
1476
1477 if (!ret && !enable) {
1478 val = readl(PRCM_CGATING_BYPASS);
1479 writel(val & ~PRCM_CGATING_BYPASS_ICN2, PRCM_CGATING_BYPASS);
1480 }
1481
1482 return ret;
1483}
1484
1485static inline bool plldsi_locked(void)
1486{
1487 return (readl(PRCM_PLLDSI_LOCKP) &
1488 (PRCM_PLLDSI_LOCKP_PRCM_PLLDSI_LOCKP10 |
1489 PRCM_PLLDSI_LOCKP_PRCM_PLLDSI_LOCKP3)) ==
1490 (PRCM_PLLDSI_LOCKP_PRCM_PLLDSI_LOCKP10 |
1491 PRCM_PLLDSI_LOCKP_PRCM_PLLDSI_LOCKP3);
1492}
1493
1494static int request_plldsi(bool enable)
1495{
1496 int r = 0;
1497 u32 val;
1498
1499 writel((PRCM_MMIP_LS_CLAMP_DSIPLL_CLAMP |
1500 PRCM_MMIP_LS_CLAMP_DSIPLL_CLAMPI), (enable ?
1501 PRCM_MMIP_LS_CLAMP_CLR : PRCM_MMIP_LS_CLAMP_SET));
1502
1503 val = readl(PRCM_PLLDSI_ENABLE);
1504 if (enable)
1505 val |= PRCM_PLLDSI_ENABLE_PRCM_PLLDSI_ENABLE;
1506 else
1507 val &= ~PRCM_PLLDSI_ENABLE_PRCM_PLLDSI_ENABLE;
1508 writel(val, PRCM_PLLDSI_ENABLE);
1509
1510 if (enable) {
1511 unsigned int i;
1512 bool locked = plldsi_locked();
1513
1514 for (i = 10; !locked && (i > 0); --i) {
1515 udelay(100);
1516 locked = plldsi_locked();
1517 }
1518 if (locked) {
1519 writel(PRCM_APE_RESETN_DSIPLL_RESETN,
1520 PRCM_APE_RESETN_SET);
1521 } else {
1522 writel((PRCM_MMIP_LS_CLAMP_DSIPLL_CLAMP |
1523 PRCM_MMIP_LS_CLAMP_DSIPLL_CLAMPI),
1524 PRCM_MMIP_LS_CLAMP_SET);
1525 val &= ~PRCM_PLLDSI_ENABLE_PRCM_PLLDSI_ENABLE;
1526 writel(val, PRCM_PLLDSI_ENABLE);
1527 r = -EAGAIN;
1528 }
1529 } else {
1530 writel(PRCM_APE_RESETN_DSIPLL_RESETN, PRCM_APE_RESETN_CLR);
1531 }
1532 return r;
1533}
1534
1535static int request_dsiclk(u8 n, bool enable)
1536{
1537 u32 val;
1538
1539 val = readl(PRCM_DSI_PLLOUT_SEL);
1540 val &= ~dsiclk[n].divsel_mask;
1541 val |= ((enable ? dsiclk[n].divsel : PRCM_DSI_PLLOUT_SEL_OFF) <<
1542 dsiclk[n].divsel_shift);
1543 writel(val, PRCM_DSI_PLLOUT_SEL);
1544 return 0;
1545}
1546
1547static int request_dsiescclk(u8 n, bool enable)
1548{
1549 u32 val;
1550
1551 val = readl(PRCM_DSITVCLK_DIV);
1552 enable ? (val |= dsiescclk[n].en) : (val &= ~dsiescclk[n].en);
1553 writel(val, PRCM_DSITVCLK_DIV);
1554 return 0;
1555}
1556
1557/**
1558 * db8500_prcmu_request_clock() - Request for a clock to be enabled or disabled.
1559 * @clock: The clock for which the request is made.
1560 * @enable: Whether the clock should be enabled (true) or disabled (false).
1561 *
1562 * This function should only be used by the clock implementation.
1563 * Do not use it from any other place!
1564 */
1565int db8500_prcmu_request_clock(u8 clock, bool enable)
1566{
1567 if (clock == PRCMU_SGACLK)
1568 return request_sga_clock(clock, enable);
1569 else if (clock < PRCMU_NUM_REG_CLOCKS)
1570 return request_clock(clock, enable);
1571 else if (clock == PRCMU_TIMCLK)
1572 return request_timclk(enable);
1573 else if ((clock == PRCMU_DSI0CLK) || (clock == PRCMU_DSI1CLK))
1574 return request_dsiclk((clock - PRCMU_DSI0CLK), enable);
1575 else if ((PRCMU_DSI0ESCCLK <= clock) && (clock <= PRCMU_DSI2ESCCLK))
1576 return request_dsiescclk((clock - PRCMU_DSI0ESCCLK), enable);
1577 else if (clock == PRCMU_PLLDSI)
1578 return request_plldsi(enable);
1579 else if (clock == PRCMU_SYSCLK)
1580 return request_sysclk(enable);
1581 else if ((clock == PRCMU_PLLSOC0) || (clock == PRCMU_PLLSOC1))
1582 return request_pll(clock, enable);
1583 else
1584 return -EINVAL;
1585}
1586
1587static unsigned long pll_rate(void __iomem *reg, unsigned long src_rate,
1588 int branch)
1589{
1590 u64 rate;
1591 u32 val;
1592 u32 d;
1593 u32 div = 1;
1594
1595 val = readl(reg);
1596
1597 rate = src_rate;
1598 rate *= ((val & PRCM_PLL_FREQ_D_MASK) >> PRCM_PLL_FREQ_D_SHIFT);
1599
1600 d = ((val & PRCM_PLL_FREQ_N_MASK) >> PRCM_PLL_FREQ_N_SHIFT);
1601 if (d > 1)
1602 div *= d;
1603
1604 d = ((val & PRCM_PLL_FREQ_R_MASK) >> PRCM_PLL_FREQ_R_SHIFT);
1605 if (d > 1)
1606 div *= d;
1607
1608 if (val & PRCM_PLL_FREQ_SELDIV2)
1609 div *= 2;
1610
1611 if ((branch == PLL_FIX) || ((branch == PLL_DIV) &&
1612 (val & PRCM_PLL_FREQ_DIV2EN) &&
1613 ((reg == PRCM_PLLSOC0_FREQ) ||
1614 (reg == PRCM_PLLDDR_FREQ))))
1615 div *= 2;
1616
1617 (void)do_div(rate, div);
1618
1619 return (unsigned long)rate;
1620}
1621
1622#define ROOT_CLOCK_RATE 38400000
1623
1624static unsigned long clock_rate(u8 clock)
1625{
1626 u32 val;
1627 u32 pllsw;
1628 unsigned long rate = ROOT_CLOCK_RATE;
1629
1630 val = readl(clk_mgt[clock].reg);
1631
1632 if (val & PRCM_CLK_MGT_CLK38) {
1633 if (clk_mgt[clock].clk38div && (val & PRCM_CLK_MGT_CLK38DIV))
1634 rate /= 2;
1635 return rate;
1636 }
1637
1638 val |= clk_mgt[clock].pllsw;
1639 pllsw = (val & PRCM_CLK_MGT_CLKPLLSW_MASK);
1640
1641 if (pllsw == PRCM_CLK_MGT_CLKPLLSW_SOC0)
1642 rate = pll_rate(PRCM_PLLSOC0_FREQ, rate, clk_mgt[clock].branch);
1643 else if (pllsw == PRCM_CLK_MGT_CLKPLLSW_SOC1)
1644 rate = pll_rate(PRCM_PLLSOC1_FREQ, rate, clk_mgt[clock].branch);
1645 else if (pllsw == PRCM_CLK_MGT_CLKPLLSW_DDR)
1646 rate = pll_rate(PRCM_PLLDDR_FREQ, rate, clk_mgt[clock].branch);
1647 else
1648 return 0;
1649
1650 if ((clock == PRCMU_SGACLK) &&
1651 (val & PRCM_SGACLK_MGT_SGACLKDIV_BY_2_5_EN)) {
1652 u64 r = (rate * 10);
1653
1654 (void)do_div(r, 25);
1655 return (unsigned long)r;
1656 }
1657 val &= PRCM_CLK_MGT_CLKPLLDIV_MASK;
1658 if (val)
1659 return rate / val;
1660 else
1661 return 0;
1662}
1663
1664static unsigned long dsiclk_rate(u8 n)
1665{
1666 u32 divsel;
1667 u32 div = 1;
1668
1669 divsel = readl(PRCM_DSI_PLLOUT_SEL);
1670 divsel = ((divsel & dsiclk[n].divsel_mask) >> dsiclk[n].divsel_shift);
1671
1672 if (divsel == PRCM_DSI_PLLOUT_SEL_OFF)
1673 divsel = dsiclk[n].divsel;
1674
1675 switch (divsel) {
1676 case PRCM_DSI_PLLOUT_SEL_PHI_4:
1677 div *= 2;
1678 case PRCM_DSI_PLLOUT_SEL_PHI_2:
1679 div *= 2;
1680 case PRCM_DSI_PLLOUT_SEL_PHI:
1681 return pll_rate(PRCM_PLLDSI_FREQ, clock_rate(PRCMU_HDMICLK),
1682 PLL_RAW) / div;
1683 default:
1684 return 0;
1685 }
1686}
1687
1688static unsigned long dsiescclk_rate(u8 n)
1689{
1690 u32 div;
1691
1692 div = readl(PRCM_DSITVCLK_DIV);
1693 div = ((div & dsiescclk[n].div_mask) >> (dsiescclk[n].div_shift));
1694 return clock_rate(PRCMU_TVCLK) / max((u32)1, div);
1695}
1696
1697unsigned long prcmu_clock_rate(u8 clock)
1698{
1699 if (clock < PRCMU_NUM_REG_CLOCKS)
1700 return clock_rate(clock);
1701 else if (clock == PRCMU_TIMCLK)
1702 return ROOT_CLOCK_RATE / 16;
1703 else if (clock == PRCMU_SYSCLK)
1704 return ROOT_CLOCK_RATE;
1705 else if (clock == PRCMU_PLLSOC0)
1706 return pll_rate(PRCM_PLLSOC0_FREQ, ROOT_CLOCK_RATE, PLL_RAW);
1707 else if (clock == PRCMU_PLLSOC1)
1708 return pll_rate(PRCM_PLLSOC1_FREQ, ROOT_CLOCK_RATE, PLL_RAW);
1709 else if (clock == PRCMU_PLLDDR)
1710 return pll_rate(PRCM_PLLDDR_FREQ, ROOT_CLOCK_RATE, PLL_RAW);
1711 else if (clock == PRCMU_PLLDSI)
1712 return pll_rate(PRCM_PLLDSI_FREQ, clock_rate(PRCMU_HDMICLK),
1713 PLL_RAW);
1714 else if ((clock == PRCMU_DSI0CLK) || (clock == PRCMU_DSI1CLK))
1715 return dsiclk_rate(clock - PRCMU_DSI0CLK);
1716 else if ((PRCMU_DSI0ESCCLK <= clock) && (clock <= PRCMU_DSI2ESCCLK))
1717 return dsiescclk_rate(clock - PRCMU_DSI0ESCCLK);
1718 else
1719 return 0;
1720}
1721
1722static unsigned long clock_source_rate(u32 clk_mgt_val, int branch)
1723{
1724 if (clk_mgt_val & PRCM_CLK_MGT_CLK38)
1725 return ROOT_CLOCK_RATE;
1726 clk_mgt_val &= PRCM_CLK_MGT_CLKPLLSW_MASK;
1727 if (clk_mgt_val == PRCM_CLK_MGT_CLKPLLSW_SOC0)
1728 return pll_rate(PRCM_PLLSOC0_FREQ, ROOT_CLOCK_RATE, branch);
1729 else if (clk_mgt_val == PRCM_CLK_MGT_CLKPLLSW_SOC1)
1730 return pll_rate(PRCM_PLLSOC1_FREQ, ROOT_CLOCK_RATE, branch);
1731 else if (clk_mgt_val == PRCM_CLK_MGT_CLKPLLSW_DDR)
1732 return pll_rate(PRCM_PLLDDR_FREQ, ROOT_CLOCK_RATE, branch);
1733 else
1734 return 0;
1735}
1736
1737static u32 clock_divider(unsigned long src_rate, unsigned long rate)
1738{
1739 u32 div;
1740
1741 div = (src_rate / rate);
1742 if (div == 0)
1743 return 1;
1744 if (rate < (src_rate / div))
1745 div++;
1746 return div;
1747}
1748
1749static long round_clock_rate(u8 clock, unsigned long rate)
1750{
1751 u32 val;
1752 u32 div;
1753 unsigned long src_rate;
1754 long rounded_rate;
1755
1756 val = readl(clk_mgt[clock].reg);
1757 src_rate = clock_source_rate((val | clk_mgt[clock].pllsw),
1758 clk_mgt[clock].branch);
1759 div = clock_divider(src_rate, rate);
1760 if (val & PRCM_CLK_MGT_CLK38) {
1761 if (clk_mgt[clock].clk38div) {
1762 if (div > 2)
1763 div = 2;
1764 } else {
1765 div = 1;
1766 }
1767 } else if ((clock == PRCMU_SGACLK) && (div == 3)) {
1768 u64 r = (src_rate * 10);
1769
1770 (void)do_div(r, 25);
1771 if (r <= rate)
1772 return (unsigned long)r;
1773 }
1774 rounded_rate = (src_rate / min(div, (u32)31));
1775
1776 return rounded_rate;
1777}
1778
1779#define MIN_PLL_VCO_RATE 600000000ULL
1780#define MAX_PLL_VCO_RATE 1680640000ULL
1781
1782static long round_plldsi_rate(unsigned long rate)
1783{
1784 long rounded_rate = 0;
1785 unsigned long src_rate;
1786 unsigned long rem;
1787 u32 r;
1788
1789 src_rate = clock_rate(PRCMU_HDMICLK);
1790 rem = rate;
1791
1792 for (r = 7; (rem > 0) && (r > 0); r--) {
1793 u64 d;
1794
1795 d = (r * rate);
1796 (void)do_div(d, src_rate);
1797 if (d < 6)
1798 d = 6;
1799 else if (d > 255)
1800 d = 255;
1801 d *= src_rate;
1802 if (((2 * d) < (r * MIN_PLL_VCO_RATE)) ||
1803 ((r * MAX_PLL_VCO_RATE) < (2 * d)))
1804 continue;
1805 (void)do_div(d, r);
1806 if (rate < d) {
1807 if (rounded_rate == 0)
1808 rounded_rate = (long)d;
1809 break;
1810 }
1811 if ((rate - d) < rem) {
1812 rem = (rate - d);
1813 rounded_rate = (long)d;
1814 }
1815 }
1816 return rounded_rate;
1817}
1818
1819static long round_dsiclk_rate(unsigned long rate)
1820{
1821 u32 div;
1822 unsigned long src_rate;
1823 long rounded_rate;
1824
1825 src_rate = pll_rate(PRCM_PLLDSI_FREQ, clock_rate(PRCMU_HDMICLK),
1826 PLL_RAW);
1827 div = clock_divider(src_rate, rate);
1828 rounded_rate = (src_rate / ((div > 2) ? 4 : div));
1829
1830 return rounded_rate;
1831}
1832
1833static long round_dsiescclk_rate(unsigned long rate)
1834{
1835 u32 div;
1836 unsigned long src_rate;
1837 long rounded_rate;
1838
1839 src_rate = clock_rate(PRCMU_TVCLK);
1840 div = clock_divider(src_rate, rate);
1841 rounded_rate = (src_rate / min(div, (u32)255));
1842
1843 return rounded_rate;
1844}
1845
1846long prcmu_round_clock_rate(u8 clock, unsigned long rate)
1847{
1848 if (clock < PRCMU_NUM_REG_CLOCKS)
1849 return round_clock_rate(clock, rate);
1850 else if (clock == PRCMU_PLLDSI)
1851 return round_plldsi_rate(rate);
1852 else if ((clock == PRCMU_DSI0CLK) || (clock == PRCMU_DSI1CLK))
1853 return round_dsiclk_rate(rate);
1854 else if ((PRCMU_DSI0ESCCLK <= clock) && (clock <= PRCMU_DSI2ESCCLK))
1855 return round_dsiescclk_rate(rate);
1856 else
1857 return (long)prcmu_clock_rate(clock);
1858}
1859
1860static void set_clock_rate(u8 clock, unsigned long rate)
1861{
1862 u32 val;
1863 u32 div;
1864 unsigned long src_rate;
1865 unsigned long flags;
1866
1867 spin_lock_irqsave(&clk_mgt_lock, flags);
1868
1869 /* Grab the HW semaphore. */
1870 while ((readl(PRCM_SEM) & PRCM_SEM_PRCM_SEM) != 0)
1871 cpu_relax();
1872
1873 val = readl(clk_mgt[clock].reg);
1874 src_rate = clock_source_rate((val | clk_mgt[clock].pllsw),
1875 clk_mgt[clock].branch);
1876 div = clock_divider(src_rate, rate);
1877 if (val & PRCM_CLK_MGT_CLK38) {
1878 if (clk_mgt[clock].clk38div) {
1879 if (div > 1)
1880 val |= PRCM_CLK_MGT_CLK38DIV;
1881 else
1882 val &= ~PRCM_CLK_MGT_CLK38DIV;
1883 }
1884 } else if (clock == PRCMU_SGACLK) {
1885 val &= ~(PRCM_CLK_MGT_CLKPLLDIV_MASK |
1886 PRCM_SGACLK_MGT_SGACLKDIV_BY_2_5_EN);
1887 if (div == 3) {
1888 u64 r = (src_rate * 10);
1889
1890 (void)do_div(r, 25);
1891 if (r <= rate) {
1892 val |= PRCM_SGACLK_MGT_SGACLKDIV_BY_2_5_EN;
1893 div = 0;
1894 }
1895 }
1896 val |= min(div, (u32)31);
1897 } else {
1898 val &= ~PRCM_CLK_MGT_CLKPLLDIV_MASK;
1899 val |= min(div, (u32)31);
1900 }
1901 writel(val, clk_mgt[clock].reg);
1902
1903 /* Release the HW semaphore. */
1904 writel(0, PRCM_SEM);
1905
1906 spin_unlock_irqrestore(&clk_mgt_lock, flags);
1907}
1908
1909static int set_plldsi_rate(unsigned long rate)
1910{
1911 unsigned long src_rate;
1912 unsigned long rem;
1913 u32 pll_freq = 0;
1914 u32 r;
1915
1916 src_rate = clock_rate(PRCMU_HDMICLK);
1917 rem = rate;
1918
1919 for (r = 7; (rem > 0) && (r > 0); r--) {
1920 u64 d;
1921 u64 hwrate;
1922
1923 d = (r * rate);
1924 (void)do_div(d, src_rate);
1925 if (d < 6)
1926 d = 6;
1927 else if (d > 255)
1928 d = 255;
1929 hwrate = (d * src_rate);
1930 if (((2 * hwrate) < (r * MIN_PLL_VCO_RATE)) ||
1931 ((r * MAX_PLL_VCO_RATE) < (2 * hwrate)))
1932 continue;
1933 (void)do_div(hwrate, r);
1934 if (rate < hwrate) {
1935 if (pll_freq == 0)
1936 pll_freq = (((u32)d << PRCM_PLL_FREQ_D_SHIFT) |
1937 (r << PRCM_PLL_FREQ_R_SHIFT));
1938 break;
1939 }
1940 if ((rate - hwrate) < rem) {
1941 rem = (rate - hwrate);
1942 pll_freq = (((u32)d << PRCM_PLL_FREQ_D_SHIFT) |
1943 (r << PRCM_PLL_FREQ_R_SHIFT));
1944 }
1945 }
1946 if (pll_freq == 0)
1947 return -EINVAL;
1948
1949 pll_freq |= (1 << PRCM_PLL_FREQ_N_SHIFT);
1950 writel(pll_freq, PRCM_PLLDSI_FREQ);
1951
1952 return 0;
1953}
1954
1955static void set_dsiclk_rate(u8 n, unsigned long rate)
1956{
1957 u32 val;
1958 u32 div;
1959
1960 div = clock_divider(pll_rate(PRCM_PLLDSI_FREQ,
1961 clock_rate(PRCMU_HDMICLK), PLL_RAW), rate);
1962
1963 dsiclk[n].divsel = (div == 1) ? PRCM_DSI_PLLOUT_SEL_PHI :
1964 (div == 2) ? PRCM_DSI_PLLOUT_SEL_PHI_2 :
1965 /* else */ PRCM_DSI_PLLOUT_SEL_PHI_4;
1966
1967 val = readl(PRCM_DSI_PLLOUT_SEL);
1968 val &= ~dsiclk[n].divsel_mask;
1969 val |= (dsiclk[n].divsel << dsiclk[n].divsel_shift);
1970 writel(val, PRCM_DSI_PLLOUT_SEL);
1971}
1972
1973static void set_dsiescclk_rate(u8 n, unsigned long rate)
1974{
1975 u32 val;
1976 u32 div;
1977
1978 div = clock_divider(clock_rate(PRCMU_TVCLK), rate);
1979 val = readl(PRCM_DSITVCLK_DIV);
1980 val &= ~dsiescclk[n].div_mask;
1981 val |= (min(div, (u32)255) << dsiescclk[n].div_shift);
1982 writel(val, PRCM_DSITVCLK_DIV);
1983}
1984
1985int prcmu_set_clock_rate(u8 clock, unsigned long rate)
1986{
1987 if (clock < PRCMU_NUM_REG_CLOCKS)
1988 set_clock_rate(clock, rate);
1989 else if (clock == PRCMU_PLLDSI)
1990 return set_plldsi_rate(rate);
1991 else if ((clock == PRCMU_DSI0CLK) || (clock == PRCMU_DSI1CLK))
1992 set_dsiclk_rate((clock - PRCMU_DSI0CLK), rate);
1993 else if ((PRCMU_DSI0ESCCLK <= clock) && (clock <= PRCMU_DSI2ESCCLK))
1994 set_dsiescclk_rate((clock - PRCMU_DSI0ESCCLK), rate);
1995 return 0;
1996}
1997
1998int db8500_prcmu_config_esram0_deep_sleep(u8 state)
1999{
2000 if ((state > ESRAM0_DEEP_SLEEP_STATE_RET) ||
2001 (state < ESRAM0_DEEP_SLEEP_STATE_OFF))
2002 return -EINVAL;
2003
2004 mutex_lock(&mb4_transfer.lock);
2005
2006 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(4))
2007 cpu_relax();
2008
2009 writeb(MB4H_MEM_ST, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB4));
2010 writeb(((DDR_PWR_STATE_OFFHIGHLAT << 4) | DDR_PWR_STATE_ON),
2011 (tcdm_base + PRCM_REQ_MB4_DDR_ST_AP_SLEEP_IDLE));
2012 writeb(DDR_PWR_STATE_ON,
2013 (tcdm_base + PRCM_REQ_MB4_DDR_ST_AP_DEEP_IDLE));
2014 writeb(state, (tcdm_base + PRCM_REQ_MB4_ESRAM0_ST));
2015
2016 writel(MBOX_BIT(4), PRCM_MBOX_CPU_SET);
2017 wait_for_completion(&mb4_transfer.work);
2018
2019 mutex_unlock(&mb4_transfer.lock);
2020
2021 return 0;
2022}
2023
2024int db8500_prcmu_config_hotdog(u8 threshold)
2025{
2026 mutex_lock(&mb4_transfer.lock);
2027
2028 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(4))
2029 cpu_relax();
2030
2031 writeb(threshold, (tcdm_base + PRCM_REQ_MB4_HOTDOG_THRESHOLD));
2032 writeb(MB4H_HOTDOG, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB4));
2033
2034 writel(MBOX_BIT(4), PRCM_MBOX_CPU_SET);
2035 wait_for_completion(&mb4_transfer.work);
2036
2037 mutex_unlock(&mb4_transfer.lock);
2038
2039 return 0;
2040}
2041
2042int db8500_prcmu_config_hotmon(u8 low, u8 high)
2043{
2044 mutex_lock(&mb4_transfer.lock);
2045
2046 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(4))
2047 cpu_relax();
2048
2049 writeb(low, (tcdm_base + PRCM_REQ_MB4_HOTMON_LOW));
2050 writeb(high, (tcdm_base + PRCM_REQ_MB4_HOTMON_HIGH));
2051 writeb((HOTMON_CONFIG_LOW | HOTMON_CONFIG_HIGH),
2052 (tcdm_base + PRCM_REQ_MB4_HOTMON_CONFIG));
2053 writeb(MB4H_HOTMON, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB4));
2054
2055 writel(MBOX_BIT(4), PRCM_MBOX_CPU_SET);
2056 wait_for_completion(&mb4_transfer.work);
2057
2058 mutex_unlock(&mb4_transfer.lock);
2059
2060 return 0;
2061}
2062
2063static int config_hot_period(u16 val)
2064{
2065 mutex_lock(&mb4_transfer.lock);
2066
2067 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(4))
2068 cpu_relax();
2069
2070 writew(val, (tcdm_base + PRCM_REQ_MB4_HOT_PERIOD));
2071 writeb(MB4H_HOT_PERIOD, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB4));
2072
2073 writel(MBOX_BIT(4), PRCM_MBOX_CPU_SET);
2074 wait_for_completion(&mb4_transfer.work);
2075
2076 mutex_unlock(&mb4_transfer.lock);
2077
2078 return 0;
2079}
2080
2081int db8500_prcmu_start_temp_sense(u16 cycles32k)
2082{
2083 if (cycles32k == 0xFFFF)
2084 return -EINVAL;
2085
2086 return config_hot_period(cycles32k);
2087}
2088
2089int db8500_prcmu_stop_temp_sense(void)
2090{
2091 return config_hot_period(0xFFFF);
2092}
2093
2094static int prcmu_a9wdog(u8 cmd, u8 d0, u8 d1, u8 d2, u8 d3)
2095{
2096
2097 mutex_lock(&mb4_transfer.lock);
2098
2099 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(4))
2100 cpu_relax();
2101
2102 writeb(d0, (tcdm_base + PRCM_REQ_MB4_A9WDOG_0));
2103 writeb(d1, (tcdm_base + PRCM_REQ_MB4_A9WDOG_1));
2104 writeb(d2, (tcdm_base + PRCM_REQ_MB4_A9WDOG_2));
2105 writeb(d3, (tcdm_base + PRCM_REQ_MB4_A9WDOG_3));
2106
2107 writeb(cmd, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB4));
2108
2109 writel(MBOX_BIT(4), PRCM_MBOX_CPU_SET);
2110 wait_for_completion(&mb4_transfer.work);
2111
2112 mutex_unlock(&mb4_transfer.lock);
2113
2114 return 0;
2115
2116}
2117
2118int db8500_prcmu_config_a9wdog(u8 num, bool sleep_auto_off)
2119{
2120 BUG_ON(num == 0 || num > 0xf);
2121 return prcmu_a9wdog(MB4H_A9WDOG_CONF, num, 0, 0,
2122 sleep_auto_off ? A9WDOG_AUTO_OFF_EN :
2123 A9WDOG_AUTO_OFF_DIS);
2124}
2125
2126int db8500_prcmu_enable_a9wdog(u8 id)
2127{
2128 return prcmu_a9wdog(MB4H_A9WDOG_EN, id, 0, 0, 0);
2129}
2130
2131int db8500_prcmu_disable_a9wdog(u8 id)
2132{
2133 return prcmu_a9wdog(MB4H_A9WDOG_DIS, id, 0, 0, 0);
2134}
2135
2136int db8500_prcmu_kick_a9wdog(u8 id)
2137{
2138 return prcmu_a9wdog(MB4H_A9WDOG_KICK, id, 0, 0, 0);
2139}
2140
2141/*
2142 * timeout is 28 bit, in ms.
2143 */
2144int db8500_prcmu_load_a9wdog(u8 id, u32 timeout)
2145{
2146 return prcmu_a9wdog(MB4H_A9WDOG_LOAD,
2147 (id & A9WDOG_ID_MASK) |
2148 /*
2149 * Put the lowest 28 bits of timeout at
2150 * offset 4. Four first bits are used for id.
2151 */
2152 (u8)((timeout << 4) & 0xf0),
2153 (u8)((timeout >> 4) & 0xff),
2154 (u8)((timeout >> 12) & 0xff),
2155 (u8)((timeout >> 20) & 0xff));
2156}
2157
2158/**
2159 * prcmu_abb_read() - Read register value(s) from the ABB.
2160 * @slave: The I2C slave address.
2161 * @reg: The (start) register address.
2162 * @value: The read out value(s).
2163 * @size: The number of registers to read.
2164 *
2165 * Reads register value(s) from the ABB.
2166 * @size has to be 1 for the current firmware version.
2167 */
2168int prcmu_abb_read(u8 slave, u8 reg, u8 *value, u8 size)
2169{
2170 int r;
2171
2172 if (size != 1)
2173 return -EINVAL;
2174
2175 mutex_lock(&mb5_transfer.lock);
2176
2177 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(5))
2178 cpu_relax();
2179
2180 writeb(0, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB5));
2181 writeb(PRCMU_I2C_READ(slave), (tcdm_base + PRCM_REQ_MB5_I2C_SLAVE_OP));
2182 writeb(PRCMU_I2C_STOP_EN, (tcdm_base + PRCM_REQ_MB5_I2C_HW_BITS));
2183 writeb(reg, (tcdm_base + PRCM_REQ_MB5_I2C_REG));
2184 writeb(0, (tcdm_base + PRCM_REQ_MB5_I2C_VAL));
2185
2186 writel(MBOX_BIT(5), PRCM_MBOX_CPU_SET);
2187
2188 if (!wait_for_completion_timeout(&mb5_transfer.work,
2189 msecs_to_jiffies(20000))) {
2190 pr_err("prcmu: %s timed out (20 s) waiting for a reply.\n",
2191 __func__);
2192 r = -EIO;
2193 } else {
2194 r = ((mb5_transfer.ack.status == I2C_RD_OK) ? 0 : -EIO);
2195 }
2196
2197 if (!r)
2198 *value = mb5_transfer.ack.value;
2199
2200 mutex_unlock(&mb5_transfer.lock);
2201
2202 return r;
2203}
2204
2205/**
2206 * prcmu_abb_write_masked() - Write masked register value(s) to the ABB.
2207 * @slave: The I2C slave address.
2208 * @reg: The (start) register address.
2209 * @value: The value(s) to write.
2210 * @mask: The mask(s) to use.
2211 * @size: The number of registers to write.
2212 *
2213 * Writes masked register value(s) to the ABB.
2214 * For each @value, only the bits set to 1 in the corresponding @mask
2215 * will be written. The other bits are not changed.
2216 * @size has to be 1 for the current firmware version.
2217 */
2218int prcmu_abb_write_masked(u8 slave, u8 reg, u8 *value, u8 *mask, u8 size)
2219{
2220 int r;
2221
2222 if (size != 1)
2223 return -EINVAL;
2224
2225 mutex_lock(&mb5_transfer.lock);
2226
2227 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(5))
2228 cpu_relax();
2229
2230 writeb(~*mask, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB5));
2231 writeb(PRCMU_I2C_WRITE(slave), (tcdm_base + PRCM_REQ_MB5_I2C_SLAVE_OP));
2232 writeb(PRCMU_I2C_STOP_EN, (tcdm_base + PRCM_REQ_MB5_I2C_HW_BITS));
2233 writeb(reg, (tcdm_base + PRCM_REQ_MB5_I2C_REG));
2234 writeb(*value, (tcdm_base + PRCM_REQ_MB5_I2C_VAL));
2235
2236 writel(MBOX_BIT(5), PRCM_MBOX_CPU_SET);
2237
2238 if (!wait_for_completion_timeout(&mb5_transfer.work,
2239 msecs_to_jiffies(20000))) {
2240 pr_err("prcmu: %s timed out (20 s) waiting for a reply.\n",
2241 __func__);
2242 r = -EIO;
2243 } else {
2244 r = ((mb5_transfer.ack.status == I2C_WR_OK) ? 0 : -EIO);
2245 }
2246
2247 mutex_unlock(&mb5_transfer.lock);
2248
2249 return r;
2250}
2251
2252/**
2253 * prcmu_abb_write() - Write register value(s) to the ABB.
2254 * @slave: The I2C slave address.
2255 * @reg: The (start) register address.
2256 * @value: The value(s) to write.
2257 * @size: The number of registers to write.
2258 *
2259 * Writes register value(s) to the ABB.
2260 * @size has to be 1 for the current firmware version.
2261 */
2262int prcmu_abb_write(u8 slave, u8 reg, u8 *value, u8 size)
2263{
2264 u8 mask = ~0;
2265
2266 return prcmu_abb_write_masked(slave, reg, value, &mask, size);
2267}
2268
2269/**
2270 * prcmu_ac_wake_req - should be called whenever ARM wants to wakeup Modem
2271 */
2272void prcmu_ac_wake_req(void)
2273{
2274 u32 val;
2275 u32 status;
2276
2277 mutex_lock(&mb0_transfer.ac_wake_lock);
2278
2279 val = readl(PRCM_HOSTACCESS_REQ);
2280 if (val & PRCM_HOSTACCESS_REQ_HOSTACCESS_REQ)
2281 goto unlock_and_return;
2282
2283 atomic_set(&ac_wake_req_state, 1);
2284
2285retry:
2286 writel((val | PRCM_HOSTACCESS_REQ_HOSTACCESS_REQ), PRCM_HOSTACCESS_REQ);
2287
2288 if (!wait_for_completion_timeout(&mb0_transfer.ac_wake_work,
2289 msecs_to_jiffies(5000))) {
2290 pr_crit("prcmu: %s timed out (5 s) waiting for a reply.\n",
2291 __func__);
2292 goto unlock_and_return;
2293 }
2294
2295 /*
2296 * The modem can generate an AC_WAKE_ACK, and then still go to sleep.
2297 * As a workaround, we wait, and then check that the modem is indeed
2298 * awake (in terms of the value of the PRCM_MOD_AWAKE_STATUS
2299 * register, which may not be the whole truth).
2300 */
2301 udelay(400);
2302 status = (readl(PRCM_MOD_AWAKE_STATUS) & BITS(0, 2));
2303 if (status != (PRCM_MOD_AWAKE_STATUS_PRCM_MOD_AAPD_AWAKE |
2304 PRCM_MOD_AWAKE_STATUS_PRCM_MOD_COREPD_AWAKE)) {
2305 pr_err("prcmu: %s received ack, but modem not awake (0x%X).\n",
2306 __func__, status);
2307 udelay(1200);
2308 writel(val, PRCM_HOSTACCESS_REQ);
2309 if (wait_for_completion_timeout(&mb0_transfer.ac_wake_work,
2310 msecs_to_jiffies(5000)))
2311 goto retry;
2312 pr_crit("prcmu: %s timed out (5 s) waiting for AC_SLEEP_ACK.\n",
2313 __func__);
2314 }
2315
2316unlock_and_return:
2317 mutex_unlock(&mb0_transfer.ac_wake_lock);
2318}
2319
2320/**
2321 * prcmu_ac_sleep_req - called when ARM no longer needs to talk to modem
2322 */
2323void prcmu_ac_sleep_req()
2324{
2325 u32 val;
2326
2327 mutex_lock(&mb0_transfer.ac_wake_lock);
2328
2329 val = readl(PRCM_HOSTACCESS_REQ);
2330 if (!(val & PRCM_HOSTACCESS_REQ_HOSTACCESS_REQ))
2331 goto unlock_and_return;
2332
2333 writel((val & ~PRCM_HOSTACCESS_REQ_HOSTACCESS_REQ),
2334 PRCM_HOSTACCESS_REQ);
2335
2336 if (!wait_for_completion_timeout(&mb0_transfer.ac_wake_work,
2337 msecs_to_jiffies(5000))) {
2338 pr_crit("prcmu: %s timed out (5 s) waiting for a reply.\n",
2339 __func__);
2340 }
2341
2342 atomic_set(&ac_wake_req_state, 0);
2343
2344unlock_and_return:
2345 mutex_unlock(&mb0_transfer.ac_wake_lock);
2346}
2347
2348bool db8500_prcmu_is_ac_wake_requested(void)
2349{
2350 return (atomic_read(&ac_wake_req_state) != 0);
2351}
2352
2353/**
2354 * db8500_prcmu_system_reset - System reset
2355 *
2356 * Saves the reset reason code and then sets the APE_SOFTRST register which
2357 * fires interrupt to fw
2358 */
2359void db8500_prcmu_system_reset(u16 reset_code)
2360{
2361 writew(reset_code, (tcdm_base + PRCM_SW_RST_REASON));
2362 writel(1, PRCM_APE_SOFTRST);
2363}
2364
2365/**
2366 * db8500_prcmu_get_reset_code - Retrieve SW reset reason code
2367 *
2368 * Retrieves the reset reason code stored by prcmu_system_reset() before
2369 * last restart.
2370 */
2371u16 db8500_prcmu_get_reset_code(void)
2372{
2373 return readw(tcdm_base + PRCM_SW_RST_REASON);
2374}
2375
2376/**
2377 * db8500_prcmu_reset_modem - ask the PRCMU to reset modem
2378 */
2379void db8500_prcmu_modem_reset(void)
2380{
2381 mutex_lock(&mb1_transfer.lock);
2382
2383 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(1))
2384 cpu_relax();
2385
2386 writeb(MB1H_RESET_MODEM, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB1));
2387 writel(MBOX_BIT(1), PRCM_MBOX_CPU_SET);
2388 wait_for_completion(&mb1_transfer.work);
2389
2390 /*
2391 * No need to check return from PRCMU as modem should go in reset state
2392 * This state is already managed by upper layer
2393 */
2394
2395 mutex_unlock(&mb1_transfer.lock);
2396}
2397
2398static void ack_dbb_wakeup(void)
2399{
2400 unsigned long flags;
2401
2402 spin_lock_irqsave(&mb0_transfer.lock, flags);
2403
2404 while (readl(PRCM_MBOX_CPU_VAL) & MBOX_BIT(0))
2405 cpu_relax();
2406
2407 writeb(MB0H_READ_WAKEUP_ACK, (tcdm_base + PRCM_MBOX_HEADER_REQ_MB0));
2408 writel(MBOX_BIT(0), PRCM_MBOX_CPU_SET);
2409
2410 spin_unlock_irqrestore(&mb0_transfer.lock, flags);
2411}
2412
2413static inline void print_unknown_header_warning(u8 n, u8 header)
2414{
2415 pr_warning("prcmu: Unknown message header (%d) in mailbox %d.\n",
2416 header, n);
2417}
2418
2419static bool read_mailbox_0(void)
2420{
2421 bool r;
2422 u32 ev;
2423 unsigned int n;
2424 u8 header;
2425
2426 header = readb(tcdm_base + PRCM_MBOX_HEADER_ACK_MB0);
2427 switch (header) {
2428 case MB0H_WAKEUP_EXE:
2429 case MB0H_WAKEUP_SLEEP:
2430 if (readb(tcdm_base + PRCM_ACK_MB0_READ_POINTER) & 1)
2431 ev = readl(tcdm_base + PRCM_ACK_MB0_WAKEUP_1_8500);
2432 else
2433 ev = readl(tcdm_base + PRCM_ACK_MB0_WAKEUP_0_8500);
2434
2435 if (ev & (WAKEUP_BIT_AC_WAKE_ACK | WAKEUP_BIT_AC_SLEEP_ACK))
2436 complete(&mb0_transfer.ac_wake_work);
2437 if (ev & WAKEUP_BIT_SYSCLK_OK)
2438 complete(&mb3_transfer.sysclk_work);
2439
2440 ev &= mb0_transfer.req.dbb_irqs;
2441
2442 for (n = 0; n < NUM_PRCMU_WAKEUPS; n++) {
2443 if (ev & prcmu_irq_bit[n])
2444 generic_handle_irq(IRQ_PRCMU_BASE + n);
2445 }
2446 r = true;
2447 break;
2448 default:
2449 print_unknown_header_warning(0, header);
2450 r = false;
2451 break;
2452 }
2453 writel(MBOX_BIT(0), PRCM_ARM_IT1_CLR);
2454 return r;
2455}
2456
2457static bool read_mailbox_1(void)
2458{
2459 mb1_transfer.ack.header = readb(tcdm_base + PRCM_MBOX_HEADER_REQ_MB1);
2460 mb1_transfer.ack.arm_opp = readb(tcdm_base +
2461 PRCM_ACK_MB1_CURRENT_ARM_OPP);
2462 mb1_transfer.ack.ape_opp = readb(tcdm_base +
2463 PRCM_ACK_MB1_CURRENT_APE_OPP);
2464 mb1_transfer.ack.ape_voltage_status = readb(tcdm_base +
2465 PRCM_ACK_MB1_APE_VOLTAGE_STATUS);
2466 writel(MBOX_BIT(1), PRCM_ARM_IT1_CLR);
2467 complete(&mb1_transfer.work);
2468 return false;
2469}
2470
2471static bool read_mailbox_2(void)
2472{
2473 mb2_transfer.ack.status = readb(tcdm_base + PRCM_ACK_MB2_DPS_STATUS);
2474 writel(MBOX_BIT(2), PRCM_ARM_IT1_CLR);
2475 complete(&mb2_transfer.work);
2476 return false;
2477}
2478
2479static bool read_mailbox_3(void)
2480{
2481 writel(MBOX_BIT(3), PRCM_ARM_IT1_CLR);
2482 return false;
2483}
2484
2485static bool read_mailbox_4(void)
2486{
2487 u8 header;
2488 bool do_complete = true;
2489
2490 header = readb(tcdm_base + PRCM_MBOX_HEADER_REQ_MB4);
2491 switch (header) {
2492 case MB4H_MEM_ST:
2493 case MB4H_HOTDOG:
2494 case MB4H_HOTMON:
2495 case MB4H_HOT_PERIOD:
2496 case MB4H_A9WDOG_CONF:
2497 case MB4H_A9WDOG_EN:
2498 case MB4H_A9WDOG_DIS:
2499 case MB4H_A9WDOG_LOAD:
2500 case MB4H_A9WDOG_KICK:
2501 break;
2502 default:
2503 print_unknown_header_warning(4, header);
2504 do_complete = false;
2505 break;
2506 }
2507
2508 writel(MBOX_BIT(4), PRCM_ARM_IT1_CLR);
2509
2510 if (do_complete)
2511 complete(&mb4_transfer.work);
2512
2513 return false;
2514}
2515
2516static bool read_mailbox_5(void)
2517{
2518 mb5_transfer.ack.status = readb(tcdm_base + PRCM_ACK_MB5_I2C_STATUS);
2519 mb5_transfer.ack.value = readb(tcdm_base + PRCM_ACK_MB5_I2C_VAL);
2520 writel(MBOX_BIT(5), PRCM_ARM_IT1_CLR);
2521 complete(&mb5_transfer.work);
2522 return false;
2523}
2524
2525static bool read_mailbox_6(void)
2526{
2527 writel(MBOX_BIT(6), PRCM_ARM_IT1_CLR);
2528 return false;
2529}
2530
2531static bool read_mailbox_7(void)
2532{
2533 writel(MBOX_BIT(7), PRCM_ARM_IT1_CLR);
2534 return false;
2535}
2536
2537static bool (* const read_mailbox[NUM_MB])(void) = {
2538 read_mailbox_0,
2539 read_mailbox_1,
2540 read_mailbox_2,
2541 read_mailbox_3,
2542 read_mailbox_4,
2543 read_mailbox_5,
2544 read_mailbox_6,
2545 read_mailbox_7
2546};
2547
2548static irqreturn_t prcmu_irq_handler(int irq, void *data)
2549{
2550 u32 bits;
2551 u8 n;
2552 irqreturn_t r;
2553
2554 bits = (readl(PRCM_ARM_IT1_VAL) & ALL_MBOX_BITS);
2555 if (unlikely(!bits))
2556 return IRQ_NONE;
2557
2558 r = IRQ_HANDLED;
2559 for (n = 0; bits; n++) {
2560 if (bits & MBOX_BIT(n)) {
2561 bits -= MBOX_BIT(n);
2562 if (read_mailbox[n]())
2563 r = IRQ_WAKE_THREAD;
2564 }
2565 }
2566 return r;
2567}
2568
2569static irqreturn_t prcmu_irq_thread_fn(int irq, void *data)
2570{
2571 ack_dbb_wakeup();
2572 return IRQ_HANDLED;
2573}
2574
2575static void prcmu_mask_work(struct work_struct *work)
2576{
2577 unsigned long flags;
2578
2579 spin_lock_irqsave(&mb0_transfer.lock, flags);
2580
2581 config_wakeups();
2582
2583 spin_unlock_irqrestore(&mb0_transfer.lock, flags);
2584}
2585
2586static void prcmu_irq_mask(struct irq_data *d)
2587{
2588 unsigned long flags;
2589
2590 spin_lock_irqsave(&mb0_transfer.dbb_irqs_lock, flags);
2591
2592 mb0_transfer.req.dbb_irqs &= ~prcmu_irq_bit[d->irq - IRQ_PRCMU_BASE];
2593
2594 spin_unlock_irqrestore(&mb0_transfer.dbb_irqs_lock, flags);
2595
2596 if (d->irq != IRQ_PRCMU_CA_SLEEP)
2597 schedule_work(&mb0_transfer.mask_work);
2598}
2599
2600static void prcmu_irq_unmask(struct irq_data *d)
2601{
2602 unsigned long flags;
2603
2604 spin_lock_irqsave(&mb0_transfer.dbb_irqs_lock, flags);
2605
2606 mb0_transfer.req.dbb_irqs |= prcmu_irq_bit[d->irq - IRQ_PRCMU_BASE];
2607
2608 spin_unlock_irqrestore(&mb0_transfer.dbb_irqs_lock, flags);
2609
2610 if (d->irq != IRQ_PRCMU_CA_SLEEP)
2611 schedule_work(&mb0_transfer.mask_work);
2612}
2613
2614static void noop(struct irq_data *d)
2615{
2616}
2617
2618static struct irq_chip prcmu_irq_chip = {
2619 .name = "prcmu",
2620 .irq_disable = prcmu_irq_mask,
2621 .irq_ack = noop,
2622 .irq_mask = prcmu_irq_mask,
2623 .irq_unmask = prcmu_irq_unmask,
2624};
2625
2626static char *fw_project_name(u8 project)
2627{
2628 switch (project) {
2629 case PRCMU_FW_PROJECT_U8500:
2630 return "U8500";
2631 case PRCMU_FW_PROJECT_U8500_C2:
2632 return "U8500 C2";
2633 case PRCMU_FW_PROJECT_U9500:
2634 return "U9500";
2635 case PRCMU_FW_PROJECT_U9500_C2:
2636 return "U9500 C2";
2637 case PRCMU_FW_PROJECT_U8520:
2638 return "U8520";
2639 case PRCMU_FW_PROJECT_U8420:
2640 return "U8420";
2641 default:
2642 return "Unknown";
2643 }
2644}
2645
2646void __init db8500_prcmu_early_init(void)
2647{
2648 unsigned int i;
2649 if (cpu_is_u8500v2()) {
2650 void *tcpm_base = ioremap_nocache(U8500_PRCMU_TCPM_BASE, SZ_4K);
2651
2652 if (tcpm_base != NULL) {
2653 u32 version;
2654 version = readl(tcpm_base + PRCMU_FW_VERSION_OFFSET);
2655 fw_info.version.project = version & 0xFF;
2656 fw_info.version.api_version = (version >> 8) & 0xFF;
2657 fw_info.version.func_version = (version >> 16) & 0xFF;
2658 fw_info.version.errata = (version >> 24) & 0xFF;
2659 fw_info.valid = true;
2660 pr_info("PRCMU firmware: %s, version %d.%d.%d\n",
2661 fw_project_name(fw_info.version.project),
2662 (version >> 8) & 0xFF, (version >> 16) & 0xFF,
2663 (version >> 24) & 0xFF);
2664 iounmap(tcpm_base);
2665 }
2666
2667 tcdm_base = __io_address(U8500_PRCMU_TCDM_BASE);
2668 } else {
2669 pr_err("prcmu: Unsupported chip version\n");
2670 BUG();
2671 }
2672
2673 spin_lock_init(&mb0_transfer.lock);
2674 spin_lock_init(&mb0_transfer.dbb_irqs_lock);
2675 mutex_init(&mb0_transfer.ac_wake_lock);
2676 init_completion(&mb0_transfer.ac_wake_work);
2677 mutex_init(&mb1_transfer.lock);
2678 init_completion(&mb1_transfer.work);
2679 mb1_transfer.ape_opp = APE_NO_CHANGE;
2680 mutex_init(&mb2_transfer.lock);
2681 init_completion(&mb2_transfer.work);
2682 spin_lock_init(&mb2_transfer.auto_pm_lock);
2683 spin_lock_init(&mb3_transfer.lock);
2684 mutex_init(&mb3_transfer.sysclk_lock);
2685 init_completion(&mb3_transfer.sysclk_work);
2686 mutex_init(&mb4_transfer.lock);
2687 init_completion(&mb4_transfer.work);
2688 mutex_init(&mb5_transfer.lock);
2689 init_completion(&mb5_transfer.work);
2690
2691 INIT_WORK(&mb0_transfer.mask_work, prcmu_mask_work);
2692
2693 /* Initalize irqs. */
2694 for (i = 0; i < NUM_PRCMU_WAKEUPS; i++) {
2695 unsigned int irq;
2696
2697 irq = IRQ_PRCMU_BASE + i;
2698 irq_set_chip_and_handler(irq, &prcmu_irq_chip,
2699 handle_simple_irq);
2700 set_irq_flags(irq, IRQF_VALID);
2701 }
2702}
2703
2704static void __init init_prcm_registers(void)
2705{
2706 u32 val;
2707
2708 val = readl(PRCM_A9PL_FORCE_CLKEN);
2709 val &= ~(PRCM_A9PL_FORCE_CLKEN_PRCM_A9PL_FORCE_CLKEN |
2710 PRCM_A9PL_FORCE_CLKEN_PRCM_A9AXI_FORCE_CLKEN);
2711 writel(val, (PRCM_A9PL_FORCE_CLKEN));
2712}
2713
2714/*
2715 * Power domain switches (ePODs) modeled as regulators for the DB8500 SoC
2716 */
2717static struct regulator_consumer_supply db8500_vape_consumers[] = {
2718 REGULATOR_SUPPLY("v-ape", NULL),
2719 REGULATOR_SUPPLY("v-i2c", "nmk-i2c.0"),
2720 REGULATOR_SUPPLY("v-i2c", "nmk-i2c.1"),
2721 REGULATOR_SUPPLY("v-i2c", "nmk-i2c.2"),
2722 REGULATOR_SUPPLY("v-i2c", "nmk-i2c.3"),
2723 REGULATOR_SUPPLY("v-i2c", "nmk-i2c.4"),
2724 /* "v-mmc" changed to "vcore" in the mainline kernel */
2725 REGULATOR_SUPPLY("vcore", "sdi0"),
2726 REGULATOR_SUPPLY("vcore", "sdi1"),
2727 REGULATOR_SUPPLY("vcore", "sdi2"),
2728 REGULATOR_SUPPLY("vcore", "sdi3"),
2729 REGULATOR_SUPPLY("vcore", "sdi4"),
2730 REGULATOR_SUPPLY("v-dma", "dma40.0"),
2731 REGULATOR_SUPPLY("v-ape", "ab8500-usb.0"),
2732 /* "v-uart" changed to "vcore" in the mainline kernel */
2733 REGULATOR_SUPPLY("vcore", "uart0"),
2734 REGULATOR_SUPPLY("vcore", "uart1"),
2735 REGULATOR_SUPPLY("vcore", "uart2"),
2736 REGULATOR_SUPPLY("v-ape", "nmk-ske-keypad.0"),
2737 REGULATOR_SUPPLY("v-hsi", "ste_hsi.0"),
2738 REGULATOR_SUPPLY("vddvario", "smsc911x.0"),
2739};
2740
2741static struct regulator_consumer_supply db8500_vsmps2_consumers[] = {
2742 REGULATOR_SUPPLY("musb_1v8", "ab8500-usb.0"),
2743 /* AV8100 regulator */
2744 REGULATOR_SUPPLY("hdmi_1v8", "0-0070"),
2745};
2746
2747static struct regulator_consumer_supply db8500_b2r2_mcde_consumers[] = {
2748 REGULATOR_SUPPLY("vsupply", "b2r2_bus"),
2749 REGULATOR_SUPPLY("vsupply", "mcde"),
2750};
2751
2752/* SVA MMDSP regulator switch */
2753static struct regulator_consumer_supply db8500_svammdsp_consumers[] = {
2754 REGULATOR_SUPPLY("sva-mmdsp", "cm_control"),
2755};
2756
2757/* SVA pipe regulator switch */
2758static struct regulator_consumer_supply db8500_svapipe_consumers[] = {
2759 REGULATOR_SUPPLY("sva-pipe", "cm_control"),
2760};
2761
2762/* SIA MMDSP regulator switch */
2763static struct regulator_consumer_supply db8500_siammdsp_consumers[] = {
2764 REGULATOR_SUPPLY("sia-mmdsp", "cm_control"),
2765};
2766
2767/* SIA pipe regulator switch */
2768static struct regulator_consumer_supply db8500_siapipe_consumers[] = {
2769 REGULATOR_SUPPLY("sia-pipe", "cm_control"),
2770};
2771
2772static struct regulator_consumer_supply db8500_sga_consumers[] = {
2773 REGULATOR_SUPPLY("v-mali", NULL),
2774};
2775
2776/* ESRAM1 and 2 regulator switch */
2777static struct regulator_consumer_supply db8500_esram12_consumers[] = {
2778 REGULATOR_SUPPLY("esram12", "cm_control"),
2779};
2780
2781/* ESRAM3 and 4 regulator switch */
2782static struct regulator_consumer_supply db8500_esram34_consumers[] = {
2783 REGULATOR_SUPPLY("v-esram34", "mcde"),
2784 REGULATOR_SUPPLY("esram34", "cm_control"),
2785 REGULATOR_SUPPLY("lcla_esram", "dma40.0"),
2786};
2787
2788static struct regulator_init_data db8500_regulators[DB8500_NUM_REGULATORS] = {
2789 [DB8500_REGULATOR_VAPE] = {
2790 .constraints = {
2791 .name = "db8500-vape",
2792 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2793 .always_on = true,
2794 },
2795 .consumer_supplies = db8500_vape_consumers,
2796 .num_consumer_supplies = ARRAY_SIZE(db8500_vape_consumers),
2797 },
2798 [DB8500_REGULATOR_VARM] = {
2799 .constraints = {
2800 .name = "db8500-varm",
2801 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2802 },
2803 },
2804 [DB8500_REGULATOR_VMODEM] = {
2805 .constraints = {
2806 .name = "db8500-vmodem",
2807 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2808 },
2809 },
2810 [DB8500_REGULATOR_VPLL] = {
2811 .constraints = {
2812 .name = "db8500-vpll",
2813 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2814 },
2815 },
2816 [DB8500_REGULATOR_VSMPS1] = {
2817 .constraints = {
2818 .name = "db8500-vsmps1",
2819 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2820 },
2821 },
2822 [DB8500_REGULATOR_VSMPS2] = {
2823 .constraints = {
2824 .name = "db8500-vsmps2",
2825 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2826 },
2827 .consumer_supplies = db8500_vsmps2_consumers,
2828 .num_consumer_supplies = ARRAY_SIZE(db8500_vsmps2_consumers),
2829 },
2830 [DB8500_REGULATOR_VSMPS3] = {
2831 .constraints = {
2832 .name = "db8500-vsmps3",
2833 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2834 },
2835 },
2836 [DB8500_REGULATOR_VRF1] = {
2837 .constraints = {
2838 .name = "db8500-vrf1",
2839 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2840 },
2841 },
2842 [DB8500_REGULATOR_SWITCH_SVAMMDSP] = {
2843 /* dependency to u8500-vape is handled outside regulator framework */
2844 .constraints = {
2845 .name = "db8500-sva-mmdsp",
2846 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2847 },
2848 .consumer_supplies = db8500_svammdsp_consumers,
2849 .num_consumer_supplies = ARRAY_SIZE(db8500_svammdsp_consumers),
2850 },
2851 [DB8500_REGULATOR_SWITCH_SVAMMDSPRET] = {
2852 .constraints = {
2853 /* "ret" means "retention" */
2854 .name = "db8500-sva-mmdsp-ret",
2855 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2856 },
2857 },
2858 [DB8500_REGULATOR_SWITCH_SVAPIPE] = {
2859 /* dependency to u8500-vape is handled outside regulator framework */
2860 .constraints = {
2861 .name = "db8500-sva-pipe",
2862 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2863 },
2864 .consumer_supplies = db8500_svapipe_consumers,
2865 .num_consumer_supplies = ARRAY_SIZE(db8500_svapipe_consumers),
2866 },
2867 [DB8500_REGULATOR_SWITCH_SIAMMDSP] = {
2868 /* dependency to u8500-vape is handled outside regulator framework */
2869 .constraints = {
2870 .name = "db8500-sia-mmdsp",
2871 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2872 },
2873 .consumer_supplies = db8500_siammdsp_consumers,
2874 .num_consumer_supplies = ARRAY_SIZE(db8500_siammdsp_consumers),
2875 },
2876 [DB8500_REGULATOR_SWITCH_SIAMMDSPRET] = {
2877 .constraints = {
2878 .name = "db8500-sia-mmdsp-ret",
2879 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2880 },
2881 },
2882 [DB8500_REGULATOR_SWITCH_SIAPIPE] = {
2883 /* dependency to u8500-vape is handled outside regulator framework */
2884 .constraints = {
2885 .name = "db8500-sia-pipe",
2886 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2887 },
2888 .consumer_supplies = db8500_siapipe_consumers,
2889 .num_consumer_supplies = ARRAY_SIZE(db8500_siapipe_consumers),
2890 },
2891 [DB8500_REGULATOR_SWITCH_SGA] = {
2892 .supply_regulator = "db8500-vape",
2893 .constraints = {
2894 .name = "db8500-sga",
2895 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2896 },
2897 .consumer_supplies = db8500_sga_consumers,
2898 .num_consumer_supplies = ARRAY_SIZE(db8500_sga_consumers),
2899
2900 },
2901 [DB8500_REGULATOR_SWITCH_B2R2_MCDE] = {
2902 .supply_regulator = "db8500-vape",
2903 .constraints = {
2904 .name = "db8500-b2r2-mcde",
2905 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2906 },
2907 .consumer_supplies = db8500_b2r2_mcde_consumers,
2908 .num_consumer_supplies = ARRAY_SIZE(db8500_b2r2_mcde_consumers),
2909 },
2910 [DB8500_REGULATOR_SWITCH_ESRAM12] = {
2911 /*
2912 * esram12 is set in retention and supplied by Vsafe when Vape is off,
2913 * no need to hold Vape
2914 */
2915 .constraints = {
2916 .name = "db8500-esram12",
2917 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2918 },
2919 .consumer_supplies = db8500_esram12_consumers,
2920 .num_consumer_supplies = ARRAY_SIZE(db8500_esram12_consumers),
2921 },
2922 [DB8500_REGULATOR_SWITCH_ESRAM12RET] = {
2923 .constraints = {
2924 .name = "db8500-esram12-ret",
2925 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2926 },
2927 },
2928 [DB8500_REGULATOR_SWITCH_ESRAM34] = {
2929 /*
2930 * esram34 is set in retention and supplied by Vsafe when Vape is off,
2931 * no need to hold Vape
2932 */
2933 .constraints = {
2934 .name = "db8500-esram34",
2935 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2936 },
2937 .consumer_supplies = db8500_esram34_consumers,
2938 .num_consumer_supplies = ARRAY_SIZE(db8500_esram34_consumers),
2939 },
2940 [DB8500_REGULATOR_SWITCH_ESRAM34RET] = {
2941 .constraints = {
2942 .name = "db8500-esram34-ret",
2943 .valid_ops_mask = REGULATOR_CHANGE_STATUS,
2944 },
2945 },
2946};
2947
2948static struct mfd_cell db8500_prcmu_devs[] = {
2949 {
2950 .name = "db8500-prcmu-regulators",
2951 .platform_data = &db8500_regulators,
2952 .pdata_size = sizeof(db8500_regulators),
2953 },
2954 {
2955 .name = "cpufreq-u8500",
2956 },
2957};
2958
2959/**
2960 * prcmu_fw_init - arch init call for the Linux PRCMU fw init logic
2961 *
2962 */
2963static int __devinit db8500_prcmu_probe(struct platform_device *pdev)
2964{
2965 struct device_node *np = pdev->dev.of_node;
2966 int irq = 0, err = 0;
2967
2968 if (ux500_is_svp())
2969 return -ENODEV;
2970
2971 init_prcm_registers();
2972
2973 /* Clean up the mailbox interrupts after pre-kernel code. */
2974 writel(ALL_MBOX_BITS, PRCM_ARM_IT1_CLR);
2975
2976 if (np)
2977 irq = platform_get_irq(pdev, 0);
2978
2979 if (!np || irq <= 0)
2980 irq = IRQ_DB8500_PRCMU1;
2981
2982 err = request_threaded_irq(irq, prcmu_irq_handler,
2983 prcmu_irq_thread_fn, IRQF_NO_SUSPEND, "prcmu", NULL);
2984 if (err < 0) {
2985 pr_err("prcmu: Failed to allocate IRQ_DB8500_PRCMU1.\n");
2986 err = -EBUSY;
2987 goto no_irq_return;
2988 }
2989
2990 if (cpu_is_u8500v20_or_later())
2991 prcmu_config_esram0_deep_sleep(ESRAM0_DEEP_SLEEP_STATE_RET);
2992
2993 if (!np) {
2994 err = mfd_add_devices(&pdev->dev, 0, db8500_prcmu_devs,
2995 ARRAY_SIZE(db8500_prcmu_devs), NULL, 0);
2996 if (err) {
2997 pr_err("prcmu: Failed to add subdevices\n");
2998 return err;
2999 }
3000 }
3001
3002 pr_info("DB8500 PRCMU initialized\n");
3003
3004no_irq_return:
3005 return err;
3006}
3007
3008static struct platform_driver db8500_prcmu_driver = {
3009 .driver = {
3010 .name = "db8500-prcmu",
3011 .owner = THIS_MODULE,
3012 },
3013 .probe = db8500_prcmu_probe,
3014};
3015
3016static int __init db8500_prcmu_init(void)
3017{
3018 return platform_driver_register(&db8500_prcmu_driver);
3019}
3020
3021arch_initcall(db8500_prcmu_init);
3022
3023MODULE_AUTHOR("Mattias Nilsson <mattias.i.nilsson@stericsson.com>");
3024MODULE_DESCRIPTION("DB8500 PRCM Unit driver");
3025MODULE_LICENSE("GPL v2");