rtc-stm32.c source code [linux/drivers/rtc/rtc-stm32.c]

1	// SPDX-License-Identifier: GPL-2.0
2	/*
3	* Copyright (C) STMicroelectronics 2017
4	* Author: Amelie Delaunay <amelie.delaunay@st.com>
5	*/
6
7	#include <linux/bcd.h>
8	#include <linux/bitfield.h>
9	#include <linux/clk.h>
10	#include <linux/clk-provider.h>
11	#include <linux/errno.h>
12	#include <linux/iopoll.h>
13	#include <linux/ioport.h>
14	#include <linux/mfd/syscon.h>
15	#include <linux/module.h>
16	#include <linux/of.h>
17	#include <linux/pinctrl/pinctrl.h>
18	#include <linux/pinctrl/pinconf-generic.h>
19	#include <linux/pinctrl/pinmux.h>
20	#include <linux/platform_device.h>
21	#include <linux/pm_wakeirq.h>
22	#include <linux/regmap.h>
23	#include <linux/rtc.h>
24
25	#define DRIVER_NAME "stm32_rtc"
26
27	/ STM32_RTC_TR bit fields /
28	#define STM32_RTC_TR_SEC_SHIFT 0
29	#define STM32_RTC_TR_SEC GENMASK(6, 0)
30	#define STM32_RTC_TR_MIN_SHIFT 8
31	#define STM32_RTC_TR_MIN GENMASK(14, 8)
32	#define STM32_RTC_TR_HOUR_SHIFT 16
33	#define STM32_RTC_TR_HOUR GENMASK(21, 16)
34
35	/ STM32_RTC_DR bit fields /
36	#define STM32_RTC_DR_DATE_SHIFT 0
37	#define STM32_RTC_DR_DATE GENMASK(5, 0)
38	#define STM32_RTC_DR_MONTH_SHIFT 8
39	#define STM32_RTC_DR_MONTH GENMASK(12, 8)
40	#define STM32_RTC_DR_WDAY_SHIFT 13
41	#define STM32_RTC_DR_WDAY GENMASK(15, 13)
42	#define STM32_RTC_DR_YEAR_SHIFT 16
43	#define STM32_RTC_DR_YEAR GENMASK(23, 16)
44
45	/ STM32_RTC_CR bit fields /
46	#define STM32_RTC_CR_FMT BIT(6)
47	#define STM32_RTC_CR_ALRAE BIT(8)
48	#define STM32_RTC_CR_ALRAIE BIT(12)
49	#define STM32_RTC_CR_OSEL GENMASK(22, 21)
50	#define STM32_RTC_CR_OSEL_ALARM_A FIELD_PREP(STM32_RTC_CR_OSEL, 0x01)
51	#define STM32_RTC_CR_COE BIT(23)
52	#define STM32_RTC_CR_TAMPOE BIT(26)
53	#define STM32_RTC_CR_TAMPALRM_TYPE BIT(30)
54	#define STM32_RTC_CR_OUT2EN BIT(31)
55
56	/ STM32_RTC_ISR/STM32_RTC_ICSR bit fields /
57	#define STM32_RTC_ISR_ALRAWF BIT(0)
58	#define STM32_RTC_ISR_INITS BIT(4)
59	#define STM32_RTC_ISR_RSF BIT(5)
60	#define STM32_RTC_ISR_INITF BIT(6)
61	#define STM32_RTC_ISR_INIT BIT(7)
62	#define STM32_RTC_ISR_ALRAF BIT(8)
63
64	/ STM32_RTC_PRER bit fields /
65	#define STM32_RTC_PRER_PRED_S_SHIFT 0
66	#define STM32_RTC_PRER_PRED_S GENMASK(14, 0)
67	#define STM32_RTC_PRER_PRED_A_SHIFT 16
68	#define STM32_RTC_PRER_PRED_A GENMASK(22, 16)
69
70	/ STM32_RTC_ALRMAR and STM32_RTC_ALRMBR bit fields /
71	#define STM32_RTC_ALRMXR_SEC_SHIFT 0
72	#define STM32_RTC_ALRMXR_SEC GENMASK(6, 0)
73	#define STM32_RTC_ALRMXR_SEC_MASK BIT(7)
74	#define STM32_RTC_ALRMXR_MIN_SHIFT 8
75	#define STM32_RTC_ALRMXR_MIN GENMASK(14, 8)
76	#define STM32_RTC_ALRMXR_MIN_MASK BIT(15)
77	#define STM32_RTC_ALRMXR_HOUR_SHIFT 16
78	#define STM32_RTC_ALRMXR_HOUR GENMASK(21, 16)
79	#define STM32_RTC_ALRMXR_PM BIT(22)
80	#define STM32_RTC_ALRMXR_HOUR_MASK BIT(23)
81	#define STM32_RTC_ALRMXR_DATE_SHIFT 24
82	#define STM32_RTC_ALRMXR_DATE GENMASK(29, 24)
83	#define STM32_RTC_ALRMXR_WDSEL BIT(30)
84	#define STM32_RTC_ALRMXR_WDAY_SHIFT 24
85	#define STM32_RTC_ALRMXR_WDAY GENMASK(27, 24)
86	#define STM32_RTC_ALRMXR_DATE_MASK BIT(31)
87
88	/ STM32_RTC_SR/_SCR bit fields /
89	#define STM32_RTC_SR_ALRA BIT(0)
90
91	/ STM32_RTC_CFGR bit fields /
92	#define STM32_RTC_CFGR_OUT2_RMP BIT(0)
93	#define STM32_RTC_CFGR_LSCOEN GENMASK(2, 1)
94	#define STM32_RTC_CFGR_LSCOEN_OUT1 1
95	#define STM32_RTC_CFGR_LSCOEN_OUT2_RMP 2
96
97	/ STM32_RTC_VERR bit fields /
98	#define STM32_RTC_VERR_MINREV_SHIFT 0
99	#define STM32_RTC_VERR_MINREV GENMASK(3, 0)
100	#define STM32_RTC_VERR_MAJREV_SHIFT 4
101	#define STM32_RTC_VERR_MAJREV GENMASK(7, 4)
102
103	/ STM32_RTC_SECCFGR bit fields /
104	#define STM32_RTC_SECCFGR 0x20
105	#define STM32_RTC_SECCFGR_ALRA_SEC BIT(0)
106	#define STM32_RTC_SECCFGR_INIT_SEC BIT(14)
107	#define STM32_RTC_SECCFGR_SEC BIT(15)
108
109	/ STM32_RTC_RXCIDCFGR bit fields /
110	#define STM32_RTC_RXCIDCFGR(x) (0x80 + 0x4 * (x))
111	#define STM32_RTC_RXCIDCFGR_CFEN BIT(0)
112	#define STM32_RTC_RXCIDCFGR_CID GENMASK(6, 4)
113	#define STM32_RTC_RXCIDCFGR_CID1 1
114
115	/ STM32_RTC_WPR key constants /
116	#define RTC_WPR_1ST_KEY 0xCA
117	#define RTC_WPR_2ND_KEY 0x53
118	#define RTC_WPR_WRONG_KEY 0xFF
119
120	/ Max STM32 RTC register offset is 0x3FC /
121	#define UNDEF_REG 0xFFFF
122
123	/ STM32 RTC driver time helpers /
124	#define SEC_PER_DAY (24 * 60 * 60)
125
126	/ STM32 RTC pinctrl helpers /
127	#define STM32_RTC_PINMUX(_name, _action, ...) { \
128	.name = (_name), \
129	.action = (_action), \
130	.groups = ((const char *[]){ __VA_ARGS__ }), \
131	.num_groups = ARRAY_SIZE(((const char *[]){ __VA_ARGS__ })), \
132	}
133
134	struct stm32_rtc;
135
136	struct stm32_rtc_registers {
137	u16 tr;
138	u16 dr;
139	u16 cr;
140	u16 isr;
141	u16 prer;
142	u16 alrmar;
143	u16 wpr;
144	u16 sr;
145	u16 scr;
146	u16 cfgr;
147	u16 verr;
148	};
149
150	struct stm32_rtc_events {
151	u32 alra;
152	};
153
154	struct stm32_rtc_data {
155	const struct stm32_rtc_registers regs;
156	const struct stm32_rtc_events events;
157	void (clear_events)(struct* stm32_rtc rtc, unsigned* int flags);
158	bool has_pclk;
159	bool need_dbp;
160	bool need_accuracy;
161	bool rif_protected;
162	bool has_lsco;
163	bool has_alarm_out;
164	};
165
166	struct stm32_rtc {
167	struct rtc_device *rtc_dev;
168	void __iomem *base;
169	struct regmap *dbp;
170	unsigned int dbp_reg;
171	unsigned int dbp_mask;
172	struct clk *pclk;
173	struct clk *rtc_ck;
174	const struct stm32_rtc_data *data;
175	int irq_alarm;
176	struct clk *clk_lsco;
177	};
178
179	struct stm32_rtc_rif_resource {
180	unsigned int num;
181	u32 bit;
182	};
183
184	static const struct stm32_rtc_rif_resource STM32_RTC_RES_ALRA = {`0`, STM32_RTC_SECCFGR_ALRA_SEC};
185	static const struct stm32_rtc_rif_resource STM32_RTC_RES_INIT = {`5`, STM32_RTC_SECCFGR_INIT_SEC};
186
187	static void stm32_rtc_wpr_unlock(struct stm32_rtc *rtc)
188	{
189	const struct stm32_rtc_registers *regs = &rtc->data->regs;
190
191	writel_relaxed(RTC_WPR_1ST_KEY, rtc->base + regs->wpr);
192	writel_relaxed(RTC_WPR_2ND_KEY, rtc->base + regs->wpr);
193	}
194
195	static void stm32_rtc_wpr_lock(struct stm32_rtc *rtc)
196	{
197	const struct stm32_rtc_registers *regs = &rtc->data->regs;
198
199	writel_relaxed(RTC_WPR_WRONG_KEY, rtc->base + regs->wpr);
200	}
201
202	enum stm32_rtc_pin_name {
203	NONE,
204	OUT1,
205	OUT2,
206	OUT2_RMP
207	};
208
209	static const struct pinctrl_pin_desc stm32_rtc_pinctrl_pins[] = {
210	PINCTRL_PIN(OUT1, "out1"),
211	PINCTRL_PIN(OUT2, "out2"),
212	PINCTRL_PIN(OUT2_RMP, "out2_rmp"),
213	};
214
215	static int stm32_rtc_pinctrl_get_groups_count(struct pinctrl_dev *pctldev)
216	{
217	return ARRAY_SIZE(stm32_rtc_pinctrl_pins);
218	}
219
220	static const char stm32_rtc_pinctrl_get_group_name(struct* pinctrl_dev *pctldev,
221	unsigned int selector)
222	{
223	return stm32_rtc_pinctrl_pins[selector].name;
224	}
225
226	static int stm32_rtc_pinctrl_get_group_pins(struct pinctrl_dev *pctldev,
227	unsigned int selector,
228	const unsigned int **pins,
229	unsigned int *num_pins)
230	{
231	*pins = &stm32_rtc_pinctrl_pins[selector].number;
232	*num_pins = `1`;
233	return `0`;
234	}
235
236	static const struct pinctrl_ops stm32_rtc_pinctrl_ops = {
237	.dt_node_to_map = pinconf_generic_dt_node_to_map_all,
238	.dt_free_map = pinconf_generic_dt_free_map,
239	.get_groups_count = stm32_rtc_pinctrl_get_groups_count,
240	.get_group_name = stm32_rtc_pinctrl_get_group_name,
241	.get_group_pins = stm32_rtc_pinctrl_get_group_pins,
242	};
243
244	struct stm32_rtc_pinmux_func {
245	const char *name;
246	const char * const *groups;
247	const unsigned int num_groups;
248	int (action)(struct* pinctrl_dev pctl_dev, unsigned* int pin);
249	};
250
251	static int stm32_rtc_pinmux_action_alarm(struct pinctrl_dev pctldev, unsigned* int pin)
252	{
253	struct stm32_rtc *rtc = pinctrl_dev_get_drvdata(pctldev);
254	struct stm32_rtc_registers regs = rtc->data->regs;
255	unsigned int cr = readl_relaxed(rtc->base + regs.cr);
256	unsigned int cfgr = readl_relaxed(rtc->base + regs.cfgr);
257
258	if (!rtc->data->has_alarm_out)
259	return -EPERM;
260
261	cr &= ~STM32_RTC_CR_OSEL;
262	cr \|= STM32_RTC_CR_OSEL_ALARM_A;
263	cr &= ~STM32_RTC_CR_TAMPOE;
264	cr &= ~STM32_RTC_CR_COE;
265	cr &= ~STM32_RTC_CR_TAMPALRM_TYPE;
266
267	switch (pin) {
268	case OUT1:
269	cr &= ~STM32_RTC_CR_OUT2EN;
270	cfgr &= ~STM32_RTC_CFGR_OUT2_RMP;
271	break;
272	case OUT2:
273	cr \|= STM32_RTC_CR_OUT2EN;
274	cfgr &= ~STM32_RTC_CFGR_OUT2_RMP;
275	break;
276	case OUT2_RMP:
277	cr \|= STM32_RTC_CR_OUT2EN;
278	cfgr \|= STM32_RTC_CFGR_OUT2_RMP;
279	break;
280	default:
281	return -EINVAL;
282	}
283
284	stm32_rtc_wpr_unlock(rtc);
285	writel_relaxed(cr, rtc->base + regs.cr);
286	writel_relaxed(cfgr, rtc->base + regs.cfgr);
287	stm32_rtc_wpr_lock(rtc);
288
289	return `0`;
290	}
291
292	static int stm32_rtc_pinmux_lsco_available(struct pinctrl_dev pctldev, unsigned* int pin)
293	{
294	struct stm32_rtc *rtc = pinctrl_dev_get_drvdata(pctldev);
295	struct stm32_rtc_registers regs = rtc->data->regs;
296	unsigned int cr = readl_relaxed(rtc->base + regs.cr);
297	unsigned int cfgr = readl_relaxed(rtc->base + regs.cfgr);
298	unsigned int calib = STM32_RTC_CR_COE;
299	unsigned int tampalrm = STM32_RTC_CR_TAMPOE \| STM32_RTC_CR_OSEL;
300
301	switch (pin) {
302	case OUT1:
303	if ((!(cr & STM32_RTC_CR_OUT2EN) &&
304	((cr & calib) \|\| cr & tampalrm)) \|\|
305	((cr & calib) && (cr & tampalrm)))
306	return -EBUSY;
307	break;
308	case OUT2_RMP:
309	if ((cr & STM32_RTC_CR_OUT2EN) &&
310	(cfgr & STM32_RTC_CFGR_OUT2_RMP) &&
311	((cr & calib) \|\| (cr & tampalrm)))
312	return -EBUSY;
313	break;
314	default:
315	return -EINVAL;
316	}
317
318	if (clk_get_rate(clk: rtc->rtc_ck) != `32768`)
319	return -ERANGE;
320
321	return `0`;
322	}
323
324	static int stm32_rtc_pinmux_action_lsco(struct pinctrl_dev pctldev, unsigned* int pin)
325	{
326	struct stm32_rtc *rtc = pinctrl_dev_get_drvdata(pctldev);
327	struct stm32_rtc_registers regs = rtc->data->regs;
328	struct device *dev = rtc->rtc_dev->dev.parent;
329	u8 lscoen;
330	int ret;
331
332	if (!rtc->data->has_lsco)
333	return -EPERM;
334
335	ret = stm32_rtc_pinmux_lsco_available(pctldev, pin);
336	if (ret)
337	return ret;
338
339	lscoen = (pin == OUT1) ? STM32_RTC_CFGR_LSCOEN_OUT1 : STM32_RTC_CFGR_LSCOEN_OUT2_RMP;
340
341	rtc->clk_lsco = clk_register_gate(dev, name: "rtc_lsco", parent_name: __clk_get_name(clk: rtc->rtc_ck),
342	CLK_IGNORE_UNUSED \| CLK_IS_CRITICAL,
343	reg: rtc->base + regs.cfgr, bit_idx: lscoen, clk_gate_flags: `0`, NULL);
344	if (IS_ERR(ptr: rtc->clk_lsco))
345	return PTR_ERR(ptr: rtc->clk_lsco);
346
347	of_clk_add_provider(np: dev->of_node, clk_src_get: of_clk_src_simple_get, data: rtc->clk_lsco);
348
349	return `0`;
350	}
351
352	static const struct stm32_rtc_pinmux_func stm32_rtc_pinmux_functions[] = {
353	STM32_RTC_PINMUX("lsco", &stm32_rtc_pinmux_action_lsco, "out1", "out2_rmp"),
354	STM32_RTC_PINMUX("alarm-a", &stm32_rtc_pinmux_action_alarm, "out1", "out2", "out2_rmp"),
355	};
356
357	static int stm32_rtc_pinmux_get_functions_count(struct pinctrl_dev *pctldev)
358	{
359	return ARRAY_SIZE(stm32_rtc_pinmux_functions);
360	}
361
362	static const char stm32_rtc_pinmux_get_fname(struct* pinctrl_dev pctldev, unsigned* int selector)
363	{
364	return stm32_rtc_pinmux_functions[selector].name;
365	}
366
367	static int stm32_rtc_pinmux_get_groups(struct pinctrl_dev pctldev, unsigned* int selector,
368	const char * const *groups, unsigned* int * const num_groups)
369	{
370	*groups = stm32_rtc_pinmux_functions[selector].groups;
371	*num_groups = stm32_rtc_pinmux_functions[selector].num_groups;
372	return `0`;
373	}
374
375	static int stm32_rtc_pinmux_set_mux(struct pinctrl_dev pctldev, unsigned* int selector,
376	unsigned int group)
377	{
378	struct stm32_rtc_pinmux_func selected_func = stm32_rtc_pinmux_functions[selector];
379	struct pinctrl_pin_desc pin = stm32_rtc_pinctrl_pins[group];
380
381	/ Call action /
382	if (selected_func.action)
383	return selected_func.action(pctldev, pin.number);
384
385	return -EINVAL;
386	}
387
388	static const struct pinmux_ops stm32_rtc_pinmux_ops = {
389	.get_functions_count = stm32_rtc_pinmux_get_functions_count,
390	.get_function_name = stm32_rtc_pinmux_get_fname,
391	.get_function_groups = stm32_rtc_pinmux_get_groups,
392	.set_mux = stm32_rtc_pinmux_set_mux,
393	.strict = true,
394	};
395
396	static struct pinctrl_desc stm32_rtc_pdesc = {
397	.name = DRIVER_NAME,
398	.pins = stm32_rtc_pinctrl_pins,
399	.npins = ARRAY_SIZE(stm32_rtc_pinctrl_pins),
400	.owner = THIS_MODULE,
401	.pctlops = &stm32_rtc_pinctrl_ops,
402	.pmxops = &stm32_rtc_pinmux_ops,
403	};
404
405	static int stm32_rtc_enter_init_mode(struct stm32_rtc *rtc)
406	{
407	const struct stm32_rtc_registers *regs = &rtc->data->regs;
408	unsigned int isr = readl_relaxed(rtc->base + regs->isr);
409
410	if (!(isr & STM32_RTC_ISR_INITF)) {
411	isr \|= STM32_RTC_ISR_INIT;
412	writel_relaxed(isr, rtc->base + regs->isr);
413
414	/*
415	* It takes around 2 rtc_ck clock cycles to enter in
416	* initialization phase mode (and have INITF flag set). As
417	* slowest rtc_ck frequency may be 32kHz and highest should be
418	* 1MHz, we poll every 10 us with a timeout of 100ms.
419	*/
420	return readl_relaxed_poll_timeout_atomic(rtc->base + regs->isr, isr,
421	(isr & STM32_RTC_ISR_INITF),
422	`10`, `100000`);
423	}
424
425	return `0`;
426	}
427
428	static void stm32_rtc_exit_init_mode(struct stm32_rtc *rtc)
429	{
430	const struct stm32_rtc_registers *regs = &rtc->data->regs;
431	unsigned int isr = readl_relaxed(rtc->base + regs->isr);
432
433	isr &= ~STM32_RTC_ISR_INIT;
434	writel_relaxed(isr, rtc->base + regs->isr);
435	}
436
437	static int stm32_rtc_wait_sync(struct stm32_rtc *rtc)
438	{
439	const struct stm32_rtc_registers *regs = &rtc->data->regs;
440	unsigned int isr = readl_relaxed(rtc->base + regs->isr);
441
442	isr &= ~STM32_RTC_ISR_RSF;
443	writel_relaxed(isr, rtc->base + regs->isr);
444
445	/*
446	* Wait for RSF to be set to ensure the calendar registers are
447	* synchronised, it takes around 2 rtc_ck clock cycles
448	*/
449	return readl_relaxed_poll_timeout_atomic(rtc->base + regs->isr,
450	isr,
451	(isr & STM32_RTC_ISR_RSF),
452	`10`, `100000`);
453	}
454
455	static void stm32_rtc_clear_event_flags(struct stm32_rtc *rtc,
456	unsigned int flags)
457	{
458	rtc->data->clear_events(rtc, flags);
459	}
460
461	static irqreturn_t stm32_rtc_alarm_irq(int irq, void *dev_id)
462	{
463	struct stm32_rtc rtc = (struct* stm32_rtc *)dev_id;
464	const struct stm32_rtc_registers *regs = &rtc->data->regs;
465	const struct stm32_rtc_events *evts = &rtc->data->events;
466	unsigned int status, cr;
467
468	rtc_lock(rtc->rtc_dev);
469
470	status = readl_relaxed(rtc->base + regs->sr);
471	cr = readl_relaxed(rtc->base + regs->cr);
472
473	if ((status & evts->alra) &&
474	(cr & STM32_RTC_CR_ALRAIE)) {
475	/ Alarm A flag - Alarm interrupt /
476	dev_dbg(&rtc->rtc_dev->dev, "Alarm occurred\n");
477
478	/ Pass event to the kernel /
479	rtc_update_irq(rtc: rtc->rtc_dev, num: `1`, RTC_IRQF \| RTC_AF);
480
481	/ Clear event flags, otherwise new events won't be received /
482	stm32_rtc_clear_event_flags(rtc, flags: evts->alra);
483	}
484
485	rtc_unlock(rtc->rtc_dev);
486
487	return IRQ_HANDLED;
488	}
489
490	/ Convert rtc_time structure from bin to bcd format /
491	static void tm2bcd(struct rtc_time *tm)
492	{
493	tm->tm_sec = bin2bcd(tm->tm_sec);
494	tm->tm_min = bin2bcd(tm->tm_min);
495	tm->tm_hour = bin2bcd(tm->tm_hour);
496
497	tm->tm_mday = bin2bcd(tm->tm_mday);
498	tm->tm_mon = bin2bcd(tm->tm_mon + `1`);
499	tm->tm_year = bin2bcd(tm->tm_year - `100`);
500	/*
501	* Number of days since Sunday
502	* - on kernel side, 0=Sunday...6=Saturday
503	* - on rtc side, 0=invalid,1=Monday...7=Sunday
504	*/
505	tm->tm_wday = (!tm->tm_wday) ? `7` : tm->tm_wday;
506	}
507
508	/ Convert rtc_time structure from bcd to bin format /
509	static void bcd2tm(struct rtc_time *tm)
510	{
511	tm->tm_sec = bcd2bin(tm->tm_sec);
512	tm->tm_min = bcd2bin(tm->tm_min);
513	tm->tm_hour = bcd2bin(tm->tm_hour);
514
515	tm->tm_mday = bcd2bin(tm->tm_mday);
516	tm->tm_mon = bcd2bin(tm->tm_mon) - `1`;
517	tm->tm_year = bcd2bin(tm->tm_year) + `100`;
518	/*
519	* Number of days since Sunday
520	* - on kernel side, 0=Sunday...6=Saturday
521	* - on rtc side, 0=invalid,1=Monday...7=Sunday
522	*/
523	tm->tm_wday %= `7`;
524	}
525
526	static int stm32_rtc_read_time(struct device dev, struct* rtc_time *tm)
527	{
528	struct stm32_rtc *rtc = dev_get_drvdata(dev);
529	const struct stm32_rtc_registers *regs = &rtc->data->regs;
530	unsigned int tr, dr;
531
532	/ Time and Date in BCD format /
533	tr = readl_relaxed(rtc->base + regs->tr);
534	dr = readl_relaxed(rtc->base + regs->dr);
535
536	tm->tm_sec = (tr & STM32_RTC_TR_SEC) >> STM32_RTC_TR_SEC_SHIFT;
537	tm->tm_min = (tr & STM32_RTC_TR_MIN) >> STM32_RTC_TR_MIN_SHIFT;
538	tm->tm_hour = (tr & STM32_RTC_TR_HOUR) >> STM32_RTC_TR_HOUR_SHIFT;
539
540	tm->tm_mday = (dr & STM32_RTC_DR_DATE) >> STM32_RTC_DR_DATE_SHIFT;
541	tm->tm_mon = (dr & STM32_RTC_DR_MONTH) >> STM32_RTC_DR_MONTH_SHIFT;
542	tm->tm_year = (dr & STM32_RTC_DR_YEAR) >> STM32_RTC_DR_YEAR_SHIFT;
543	tm->tm_wday = (dr & STM32_RTC_DR_WDAY) >> STM32_RTC_DR_WDAY_SHIFT;
544
545	/ We don't report tm_yday and tm_isdst /
546
547	bcd2tm(tm);
548
549	return `0`;
550	}
551
552	static int stm32_rtc_set_time(struct device dev, struct* rtc_time *tm)
553	{
554	struct stm32_rtc *rtc = dev_get_drvdata(dev);
555	const struct stm32_rtc_registers *regs = &rtc->data->regs;
556	unsigned int tr, dr;
557	int ret = `0`;
558
559	tm2bcd(tm);
560
561	/ Time in BCD format /
562	tr = ((tm->tm_sec << STM32_RTC_TR_SEC_SHIFT) & STM32_RTC_TR_SEC) \|
563	((tm->tm_min << STM32_RTC_TR_MIN_SHIFT) & STM32_RTC_TR_MIN) \|
564	((tm->tm_hour << STM32_RTC_TR_HOUR_SHIFT) & STM32_RTC_TR_HOUR);
565
566	/ Date in BCD format /
567	dr = ((tm->tm_mday << STM32_RTC_DR_DATE_SHIFT) & STM32_RTC_DR_DATE) \|
568	((tm->tm_mon << STM32_RTC_DR_MONTH_SHIFT) & STM32_RTC_DR_MONTH) \|
569	((tm->tm_year << STM32_RTC_DR_YEAR_SHIFT) & STM32_RTC_DR_YEAR) \|
570	((tm->tm_wday << STM32_RTC_DR_WDAY_SHIFT) & STM32_RTC_DR_WDAY);
571
572	stm32_rtc_wpr_unlock(rtc);
573
574	ret = stm32_rtc_enter_init_mode(rtc);
575	if (ret) {
576	dev_err(dev, "Can't enter in init mode. Set time aborted.\n");
577	goto end;
578	}
579
580	writel_relaxed(tr, rtc->base + regs->tr);
581	writel_relaxed(dr, rtc->base + regs->dr);
582
583	stm32_rtc_exit_init_mode(rtc);
584
585	ret = stm32_rtc_wait_sync(rtc);
586	end:
587	stm32_rtc_wpr_lock(rtc);
588
589	return ret;
590	}
591
592	static int stm32_rtc_read_alarm(struct device dev, struct* rtc_wkalrm *alrm)
593	{
594	struct stm32_rtc *rtc = dev_get_drvdata(dev);
595	const struct stm32_rtc_registers *regs = &rtc->data->regs;
596	const struct stm32_rtc_events *evts = &rtc->data->events;
597	struct rtc_time *tm = &alrm->time;
598	unsigned int alrmar, cr, status;
599
600	alrmar = readl_relaxed(rtc->base + regs->alrmar);
601	cr = readl_relaxed(rtc->base + regs->cr);
602	status = readl_relaxed(rtc->base + regs->sr);
603
604	if (alrmar & STM32_RTC_ALRMXR_DATE_MASK) {
605	/*
606	* Date/day doesn't matter in Alarm comparison so alarm
607	* triggers every day
608	*/
609	tm->tm_mday = -`1`;
610	tm->tm_wday = -`1`;
611	} else {
612	if (alrmar & STM32_RTC_ALRMXR_WDSEL) {
613	/ Alarm is set to a day of week /
614	tm->tm_mday = -`1`;
615	tm->tm_wday = (alrmar & STM32_RTC_ALRMXR_WDAY) >>
616	STM32_RTC_ALRMXR_WDAY_SHIFT;
617	tm->tm_wday %= `7`;
618	} else {
619	/ Alarm is set to a day of month /
620	tm->tm_wday = -`1`;
621	tm->tm_mday = (alrmar & STM32_RTC_ALRMXR_DATE) >>
622	STM32_RTC_ALRMXR_DATE_SHIFT;
623	}
624	}
625
626	if (alrmar & STM32_RTC_ALRMXR_HOUR_MASK) {
627	/ Hours don't matter in Alarm comparison /
628	tm->tm_hour = -`1`;
629	} else {
630	tm->tm_hour = (alrmar & STM32_RTC_ALRMXR_HOUR) >>
631	STM32_RTC_ALRMXR_HOUR_SHIFT;
632	if (alrmar & STM32_RTC_ALRMXR_PM)
633	tm->tm_hour += `12`;
634	}
635
636	if (alrmar & STM32_RTC_ALRMXR_MIN_MASK) {
637	/ Minutes don't matter in Alarm comparison /
638	tm->tm_min = -`1`;
639	} else {
640	tm->tm_min = (alrmar & STM32_RTC_ALRMXR_MIN) >>
641	STM32_RTC_ALRMXR_MIN_SHIFT;
642	}
643
644	if (alrmar & STM32_RTC_ALRMXR_SEC_MASK) {
645	/ Seconds don't matter in Alarm comparison /
646	tm->tm_sec = -`1`;
647	} else {
648	tm->tm_sec = (alrmar & STM32_RTC_ALRMXR_SEC) >>
649	STM32_RTC_ALRMXR_SEC_SHIFT;
650	}
651
652	bcd2tm(tm);
653
654	alrm->enabled = (cr & STM32_RTC_CR_ALRAE) ? `1` : `0`;
655	alrm->pending = (status & evts->alra) ? `1` : `0`;
656
657	return `0`;
658	}
659
660	static int stm32_rtc_alarm_irq_enable(struct device dev, unsigned* int enabled)
661	{
662	struct stm32_rtc *rtc = dev_get_drvdata(dev);
663	const struct stm32_rtc_registers *regs = &rtc->data->regs;
664	const struct stm32_rtc_events *evts = &rtc->data->events;
665	unsigned int cr;
666
667	cr = readl_relaxed(rtc->base + regs->cr);
668
669	stm32_rtc_wpr_unlock(rtc);
670
671	/ We expose Alarm A to the kernel /
672	if (enabled)
673	cr \|= (STM32_RTC_CR_ALRAIE \| STM32_RTC_CR_ALRAE);
674	else
675	cr &= ~(STM32_RTC_CR_ALRAIE \| STM32_RTC_CR_ALRAE);
676	writel_relaxed(cr, rtc->base + regs->cr);
677
678	/ Clear event flags, otherwise new events won't be received /
679	stm32_rtc_clear_event_flags(rtc, flags: evts->alra);
680
681	stm32_rtc_wpr_lock(rtc);
682
683	return `0`;
684	}
685
686	static int stm32_rtc_valid_alrm(struct device dev, struct* rtc_time *tm)
687	{
688	static struct rtc_time now;
689	time64_t max_alarm_time64;
690	int max_day_forward;
691	int next_month;
692	int next_year;
693
694	/*
695	* Assuming current date is M-D-Y H:M:S.
696	* RTC alarm can't be set on a specific month and year.
697	* So the valid alarm range is:
698	* M-D-Y H:M:S < alarm <= (M+1)-D-Y H:M:S
699	*/
700	stm32_rtc_read_time(dev, tm: &now);
701
702	/*
703	* Find the next month and the year of the next month.
704	* Note: tm_mon and next_month are from 0 to 11
705	*/
706	next_month = now.tm_mon + `1`;
707	if (next_month == `12`) {
708	next_month = `0`;
709	next_year = now.tm_year + `1`;
710	} else {
711	next_year = now.tm_year;
712	}
713
714	/ Find the maximum limit of alarm in days. /
715	max_day_forward = rtc_month_days(month: now.tm_mon, year: now.tm_year)
716	- now.tm_mday
717	+ min(rtc_month_days(next_month, next_year), now.tm_mday);
718
719	/ Convert to timestamp and compare the alarm time and its upper limit /
720	max_alarm_time64 = rtc_tm_to_time64(tm: &now) + max_day_forward * SEC_PER_DAY;
721	return rtc_tm_to_time64(tm) <= max_alarm_time64 ? `0` : -EINVAL;
722	}
723
724	static int stm32_rtc_set_alarm(struct device dev, struct* rtc_wkalrm *alrm)
725	{
726	struct stm32_rtc *rtc = dev_get_drvdata(dev);
727	const struct stm32_rtc_registers *regs = &rtc->data->regs;
728	struct rtc_time *tm = &alrm->time;
729	unsigned int cr, isr, alrmar;
730	int ret = `0`;
731
732	/*
733	* RTC alarm can't be set on a specific date, unless this date is
734	* up to the same day of month next month.
735	*/
736	if (stm32_rtc_valid_alrm(dev, tm) < `0`) {
737	dev_err(dev, "Alarm can be set only on upcoming month.\n");
738	return -EINVAL;
739	}
740
741	tm2bcd(tm);
742
743	alrmar = `0`;
744	/ tm_year and tm_mon are not used because not supported by RTC /
745	alrmar \|= (tm->tm_mday << STM32_RTC_ALRMXR_DATE_SHIFT) &
746	STM32_RTC_ALRMXR_DATE;
747	/ 24-hour format /
748	alrmar &= ~STM32_RTC_ALRMXR_PM;
749	alrmar \|= (tm->tm_hour << STM32_RTC_ALRMXR_HOUR_SHIFT) &
750	STM32_RTC_ALRMXR_HOUR;
751	alrmar \|= (tm->tm_min << STM32_RTC_ALRMXR_MIN_SHIFT) &
752	STM32_RTC_ALRMXR_MIN;
753	alrmar \|= (tm->tm_sec << STM32_RTC_ALRMXR_SEC_SHIFT) &
754	STM32_RTC_ALRMXR_SEC;
755
756	stm32_rtc_wpr_unlock(rtc);
757
758	/ Disable Alarm /
759	cr = readl_relaxed(rtc->base + regs->cr);
760	cr &= ~STM32_RTC_CR_ALRAE;
761	writel_relaxed(cr, rtc->base + regs->cr);
762
763	/*
764	* Poll Alarm write flag to be sure that Alarm update is allowed: it
765	* takes around 2 rtc_ck clock cycles
766	*/
767	ret = readl_relaxed_poll_timeout_atomic(rtc->base + regs->isr,
768	isr,
769	(isr & STM32_RTC_ISR_ALRAWF),
770	`10`, `100000`);
771
772	if (ret) {
773	dev_err(dev, "Alarm update not allowed\n");
774	goto end;
775	}
776
777	/ Write to Alarm register /
778	writel_relaxed(alrmar, rtc->base + regs->alrmar);
779
780	stm32_rtc_alarm_irq_enable(dev, enabled: alrm->enabled);
781	end:
782	stm32_rtc_wpr_lock(rtc);
783
784	return ret;
785	}
786
787	static const struct rtc_class_ops stm32_rtc_ops = {
788	.read_time = stm32_rtc_read_time,
789	.set_time = stm32_rtc_set_time,
790	.read_alarm = stm32_rtc_read_alarm,
791	.set_alarm = stm32_rtc_set_alarm,
792	.alarm_irq_enable = stm32_rtc_alarm_irq_enable,
793	};
794
795	static void stm32_rtc_clear_events(struct stm32_rtc *rtc,
796	unsigned int flags)
797	{
798	const struct stm32_rtc_registers *regs = &rtc->data->regs;
799
800	/ Flags are cleared by writing 0 in RTC_ISR /
801	writel_relaxed(readl_relaxed(rtc->base + regs->isr) & ~flags,
802	rtc->base + regs->isr);
803	}
804
805	static const struct stm32_rtc_data stm32_rtc_data = {
806	.has_pclk = false,
807	.need_dbp = true,
808	.need_accuracy = false,
809	.rif_protected = false,
810	.has_lsco = false,
811	.has_alarm_out = false,
812	.regs = {
813	.tr = `0x00`,
814	.dr = `0x04`,
815	.cr = `0x08`,
816	.isr = `0x0C`,
817	.prer = `0x10`,
818	.alrmar = `0x1C`,
819	.wpr = `0x24`,
820	.sr = `0x0C`, / set to ISR offset to ease alarm management /
821	.scr = UNDEF_REG,
822	.cfgr = UNDEF_REG,
823	.verr = UNDEF_REG,
824	},
825	.events = {
826	.alra = STM32_RTC_ISR_ALRAF,
827	},
828	.clear_events = stm32_rtc_clear_events,
829	};
830
831	static const struct stm32_rtc_data stm32h7_rtc_data = {
832	.has_pclk = true,
833	.need_dbp = true,
834	.need_accuracy = false,
835	.rif_protected = false,
836	.has_lsco = false,
837	.has_alarm_out = false,
838	.regs = {
839	.tr = `0x00`,
840	.dr = `0x04`,
841	.cr = `0x08`,
842	.isr = `0x0C`,
843	.prer = `0x10`,
844	.alrmar = `0x1C`,
845	.wpr = `0x24`,
846	.sr = `0x0C`, / set to ISR offset to ease alarm management /
847	.scr = UNDEF_REG,
848	.cfgr = UNDEF_REG,
849	.verr = UNDEF_REG,
850	},
851	.events = {
852	.alra = STM32_RTC_ISR_ALRAF,
853	},
854	.clear_events = stm32_rtc_clear_events,
855	};
856
857	static void stm32mp1_rtc_clear_events(struct stm32_rtc *rtc,
858	unsigned int flags)
859	{
860	struct stm32_rtc_registers regs = rtc->data->regs;
861
862	/ Flags are cleared by writing 1 in RTC_SCR /
863	writel_relaxed(flags, rtc->base + regs.scr);
864	}
865
866	static const struct stm32_rtc_data stm32mp1_data = {
867	.has_pclk = true,
868	.need_dbp = false,
869	.need_accuracy = true,
870	.rif_protected = false,
871	.has_lsco = true,
872	.has_alarm_out = true,
873	.regs = {
874	.tr = `0x00`,
875	.dr = `0x04`,
876	.cr = `0x18`,
877	.isr = `0x0C`, / named RTC_ICSR on stm32mp1 /
878	.prer = `0x10`,
879	.alrmar = `0x40`,
880	.wpr = `0x24`,
881	.sr = `0x50`,
882	.scr = `0x5C`,
883	.cfgr = `0x60`,
884	.verr = `0x3F4`,
885	},
886	.events = {
887	.alra = STM32_RTC_SR_ALRA,
888	},
889	.clear_events = stm32mp1_rtc_clear_events,
890	};
891
892	static const struct stm32_rtc_data stm32mp25_data = {
893	.has_pclk = true,
894	.need_dbp = false,
895	.need_accuracy = true,
896	.rif_protected = true,
897	.has_lsco = true,
898	.has_alarm_out = true,
899	.regs = {
900	.tr = `0x00`,
901	.dr = `0x04`,
902	.cr = `0x18`,
903	.isr = `0x0C`, / named RTC_ICSR on stm32mp25 /
904	.prer = `0x10`,
905	.alrmar = `0x40`,
906	.wpr = `0x24`,
907	.sr = `0x50`,
908	.scr = `0x5C`,
909	.cfgr = `0x60`,
910	.verr = `0x3F4`,
911	},
912	.events = {
913	.alra = STM32_RTC_SR_ALRA,
914	},
915	.clear_events = stm32mp1_rtc_clear_events,
916	};
917
918	static const struct of_device_id stm32_rtc_of_match[] = {
919	{ .compatible = "st,stm32-rtc", .data = &stm32_rtc_data },
920	{ .compatible = "st,stm32h7-rtc", .data = &stm32h7_rtc_data },
921	{ .compatible = "st,stm32mp1-rtc", .data = &stm32mp1_data },
922	{ .compatible = "st,stm32mp25-rtc", .data = &stm32mp25_data },
923	{}
924	};
925	MODULE_DEVICE_TABLE(of, stm32_rtc_of_match);
926
927	static void stm32_rtc_clean_outs(struct stm32_rtc *rtc)
928	{
929	struct stm32_rtc_registers regs = rtc->data->regs;
930	unsigned int cr = readl_relaxed(rtc->base + regs.cr);
931
932	cr &= ~STM32_RTC_CR_OSEL;
933	cr &= ~STM32_RTC_CR_TAMPOE;
934	cr &= ~STM32_RTC_CR_COE;
935	cr &= ~STM32_RTC_CR_TAMPALRM_TYPE;
936	cr &= ~STM32_RTC_CR_OUT2EN;
937
938	stm32_rtc_wpr_unlock(rtc);
939	writel_relaxed(cr, rtc->base + regs.cr);
940	stm32_rtc_wpr_lock(rtc);
941
942	if (regs.cfgr != UNDEF_REG) {
943	unsigned int cfgr = readl_relaxed(rtc->base + regs.cfgr);
944
945	cfgr &= ~STM32_RTC_CFGR_LSCOEN;
946	cfgr &= ~STM32_RTC_CFGR_OUT2_RMP;
947	writel_relaxed(cfgr, rtc->base + regs.cfgr);
948	}
949	}
950
951	static int stm32_rtc_check_rif(struct stm32_rtc *stm32_rtc,
952	struct stm32_rtc_rif_resource res)
953	{
954	u32 rxcidcfgr = readl_relaxed(stm32_rtc->base + STM32_RTC_RXCIDCFGR(res.num));
955	u32 seccfgr;
956
957	/ Check if RTC available for our CID /
958	if ((rxcidcfgr & STM32_RTC_RXCIDCFGR_CFEN) &&
959	(FIELD_GET(STM32_RTC_RXCIDCFGR_CID, rxcidcfgr) != STM32_RTC_RXCIDCFGR_CID1))
960	return -EACCES;
961
962	/ Check if RTC available for non secure world /
963	seccfgr = readl_relaxed(stm32_rtc->base + STM32_RTC_SECCFGR);
964	if ((seccfgr & STM32_RTC_SECCFGR_SEC) \| (seccfgr & res.bit))
965	return -EACCES;
966
967	return `0`;
968	}
969
970	static int stm32_rtc_init(struct platform_device *pdev,
971	struct stm32_rtc *rtc)
972	{
973	const struct stm32_rtc_registers *regs = &rtc->data->regs;
974	unsigned int prer, pred_a, pred_s, pred_a_max, pred_s_max, cr;
975	unsigned int rate;
976	int ret;
977
978	rate = clk_get_rate(clk: rtc->rtc_ck);
979
980	/ Find prediv_a and prediv_s to obtain the 1Hz calendar clock /
981	pred_a_max = STM32_RTC_PRER_PRED_A >> STM32_RTC_PRER_PRED_A_SHIFT;
982	pred_s_max = STM32_RTC_PRER_PRED_S >> STM32_RTC_PRER_PRED_S_SHIFT;
983
984	if (rate > (pred_a_max + `1`) * (pred_s_max + `1`)) {
985	dev_err(&pdev->dev, "rtc_ck rate is too high: %dHz\n", rate);
986	return -EINVAL;
987	}
988
989	if (rtc->data->need_accuracy) {
990	for (pred_a = `0`; pred_a <= pred_a_max; pred_a++) {
991	pred_s = (rate / (pred_a + `1`)) - `1`;
992
993	if (pred_s <= pred_s_max && ((pred_s + `1`) * (pred_a + `1`)) == rate)
994	break;
995	}
996	} else {
997	for (pred_a = pred_a_max; pred_a + `1` > `0`; pred_a--) {
998	pred_s = (rate / (pred_a + `1`)) - `1`;
999
1000	if (((pred_s + `1`) * (pred_a + `1`)) == rate)
1001	break;
1002	}
1003	}
1004
1005	/*
1006	* Can't find a 1Hz, so give priority to RTC power consumption
1007	* by choosing the higher possible value for prediv_a
1008	*/
1009	if (pred_s > pred_s_max \|\| pred_a > pred_a_max) {
1010	pred_a = pred_a_max;
1011	pred_s = (rate / (pred_a + `1`)) - `1`;
1012
1013	dev_warn(&pdev->dev, "rtc_ck is %s\n",
1014	(rate < ((pred_a + `1`) * (pred_s + `1`))) ?
1015	"fast" : "slow");
1016	}
1017
1018	cr = readl_relaxed(rtc->base + regs->cr);
1019
1020	prer = readl_relaxed(rtc->base + regs->prer);
1021	prer &= STM32_RTC_PRER_PRED_S \| STM32_RTC_PRER_PRED_A;
1022
1023	pred_s = (pred_s << STM32_RTC_PRER_PRED_S_SHIFT) &
1024	STM32_RTC_PRER_PRED_S;
1025	pred_a = (pred_a << STM32_RTC_PRER_PRED_A_SHIFT) &
1026	STM32_RTC_PRER_PRED_A;
1027
1028	/ quit if there is nothing to initialize /
1029	if ((cr & STM32_RTC_CR_FMT) == `0` && prer == (pred_s \| pred_a))
1030	return `0`;
1031
1032	stm32_rtc_wpr_unlock(rtc);
1033
1034	ret = stm32_rtc_enter_init_mode(rtc);
1035	if (ret) {
1036	dev_err(&pdev->dev,
1037	"Can't enter in init mode. Prescaler config failed.\n");
1038	goto end;
1039	}
1040
1041	writel_relaxed(pred_s, rtc->base + regs->prer);
1042	writel_relaxed(pred_a \| pred_s, rtc->base + regs->prer);
1043
1044	/ Force 24h time format /
1045	cr &= ~STM32_RTC_CR_FMT;
1046	writel_relaxed(cr, rtc->base + regs->cr);
1047
1048	stm32_rtc_exit_init_mode(rtc);
1049
1050	ret = stm32_rtc_wait_sync(rtc);
1051	end:
1052	stm32_rtc_wpr_lock(rtc);
1053
1054	return ret;
1055	}
1056
1057	static int stm32_rtc_probe(struct platform_device *pdev)
1058	{
1059	struct stm32_rtc *rtc;
1060	const struct stm32_rtc_registers *regs;
1061	struct pinctrl_dev *pctl;
1062	int ret;
1063
1064	rtc = devm_kzalloc(dev: &pdev->dev, size: sizeof(*rtc), GFP_KERNEL);
1065	if (!rtc)
1066	return -ENOMEM;
1067
1068	rtc->base = devm_platform_ioremap_resource(pdev, index: `0`);
1069	if (IS_ERR(ptr: rtc->base))
1070	return PTR_ERR(ptr: rtc->base);
1071
1072	rtc->data = (struct stm32_rtc_data *)
1073	of_device_get_match_data(dev: &pdev->dev);
1074	regs = &rtc->data->regs;
1075
1076	if (rtc->data->need_dbp) {
1077	unsigned int args[`2`];
1078
1079	rtc->dbp = syscon_regmap_lookup_by_phandle_args(np: pdev->dev.of_node,
1080	property: "st,syscfg",
1081	arg_count: `2`, out_args: args);
1082	if (IS_ERR(ptr: rtc->dbp)) {
1083	dev_err(&pdev->dev, "no st,syscfg\n");
1084	return PTR_ERR(ptr: rtc->dbp);
1085	}
1086
1087	rtc->dbp_reg = args[`0`];
1088	rtc->dbp_mask = args[`1`];
1089	}
1090
1091	if (!rtc->data->has_pclk) {
1092	rtc->pclk = NULL;
1093	rtc->rtc_ck = devm_clk_get(dev: &pdev->dev, NULL);
1094	} else {
1095	rtc->pclk = devm_clk_get(dev: &pdev->dev, id: "pclk");
1096	if (IS_ERR(ptr: rtc->pclk))
1097	return dev_err_probe(dev: &pdev->dev, err: PTR_ERR(ptr: rtc->pclk), fmt: "no pclk clock");
1098
1099	rtc->rtc_ck = devm_clk_get(dev: &pdev->dev, id: "rtc_ck");
1100	}
1101	if (IS_ERR(ptr: rtc->rtc_ck))
1102	return dev_err_probe(dev: &pdev->dev, err: PTR_ERR(ptr: rtc->rtc_ck), fmt: "no rtc_ck clock");
1103
1104	if (rtc->data->has_pclk) {
1105	ret = clk_prepare_enable(clk: rtc->pclk);
1106	if (ret)
1107	return ret;
1108	}
1109
1110	ret = clk_prepare_enable(clk: rtc->rtc_ck);
1111	if (ret)
1112	goto err_no_rtc_ck;
1113
1114	if (rtc->data->need_dbp)
1115	regmap_update_bits(map: rtc->dbp, reg: rtc->dbp_reg,
1116	mask: rtc->dbp_mask, val: rtc->dbp_mask);
1117
1118	if (rtc->data->rif_protected) {
1119	ret = stm32_rtc_check_rif(stm32_rtc: rtc, res: STM32_RTC_RES_INIT);
1120	if (!ret)
1121	ret = stm32_rtc_check_rif(stm32_rtc: rtc, res: STM32_RTC_RES_ALRA);
1122	if (ret) {
1123	dev_err(&pdev->dev, "Failed to probe RTC due to RIF configuration\n");
1124	goto err;
1125	}
1126	}
1127
1128	/*
1129	* After a system reset, RTC_ISR.INITS flag can be read to check if
1130	* the calendar has been initialized or not. INITS flag is reset by a
1131	* power-on reset (no vbat, no power-supply). It is not reset if
1132	* rtc_ck parent clock has changed (so RTC prescalers need to be
1133	* changed). That's why we cannot rely on this flag to know if RTC
1134	* init has to be done.
1135	*/
1136	ret = stm32_rtc_init(pdev, rtc);
1137	if (ret)
1138	goto err;
1139
1140	rtc->irq_alarm = platform_get_irq(pdev, `0`);
1141	if (rtc->irq_alarm <= `0`) {
1142	ret = rtc->irq_alarm;
1143	goto err;
1144	}
1145
1146	ret = devm_device_init_wakeup(dev: &pdev->dev);
1147	if (ret)
1148	goto err;
1149
1150	ret = devm_pm_set_wake_irq(dev: &pdev->dev, irq: rtc->irq_alarm);
1151	if (ret)
1152	goto err;
1153
1154	platform_set_drvdata(pdev, data: rtc);
1155
1156	rtc->rtc_dev = devm_rtc_device_register(dev: &pdev->dev, name: pdev->name,
1157	ops: &stm32_rtc_ops, THIS_MODULE);
1158	if (IS_ERR(ptr: rtc->rtc_dev)) {
1159	ret = PTR_ERR(ptr: rtc->rtc_dev);
1160	dev_err(&pdev->dev, "rtc device registration failed, err=%d\n",
1161	ret);
1162	goto err;
1163	}
1164
1165	/ Handle RTC alarm interrupts /
1166	ret = devm_request_threaded_irq(dev: &pdev->dev, irq: rtc->irq_alarm, NULL,
1167	thread_fn: stm32_rtc_alarm_irq, IRQF_ONESHOT,
1168	devname: pdev->name, dev_id: rtc);
1169	if (ret) {
1170	dev_err(&pdev->dev, "IRQ%d (alarm interrupt) already claimed\n",
1171	rtc->irq_alarm);
1172	goto err;
1173	}
1174
1175	stm32_rtc_clean_outs(rtc);
1176
1177	ret = devm_pinctrl_register_and_init(dev: &pdev->dev, pctldesc: &stm32_rtc_pdesc, driver_data: rtc, pctldev: &pctl);
1178	if (ret)
1179	return dev_err_probe(dev: &pdev->dev, err: ret, fmt: "pinctrl register failed");
1180
1181	ret = pinctrl_enable(pctldev: pctl);
1182	if (ret)
1183	return dev_err_probe(dev: &pdev->dev, err: ret, fmt: "pinctrl enable failed");
1184
1185	/*
1186	* If INITS flag is reset (calendar year field set to 0x00), calendar
1187	* must be initialized
1188	*/
1189	if (!(readl_relaxed(rtc->base + regs->isr) & STM32_RTC_ISR_INITS))
1190	dev_warn(&pdev->dev, "Date/Time must be initialized\n");
1191
1192	if (regs->verr != UNDEF_REG) {
1193	u32 ver = readl_relaxed(rtc->base + regs->verr);
1194
1195	dev_info(&pdev->dev, "registered rev:%d.%d\n",
1196	(ver >> STM32_RTC_VERR_MAJREV_SHIFT) & `0xF`,
1197	(ver >> STM32_RTC_VERR_MINREV_SHIFT) & `0xF`);
1198	}
1199
1200	return `0`;
1201
1202	err:
1203	clk_disable_unprepare(clk: rtc->rtc_ck);
1204	err_no_rtc_ck:
1205	if (rtc->data->has_pclk)
1206	clk_disable_unprepare(clk: rtc->pclk);
1207
1208	if (rtc->data->need_dbp)
1209	regmap_update_bits(map: rtc->dbp, reg: rtc->dbp_reg, mask: rtc->dbp_mask, val: `0`);
1210
1211	return ret;
1212	}
1213
1214	static void stm32_rtc_remove(struct platform_device *pdev)
1215	{
1216	struct stm32_rtc *rtc = platform_get_drvdata(pdev);
1217	const struct stm32_rtc_registers *regs = &rtc->data->regs;
1218	unsigned int cr;
1219
1220	if (!IS_ERR_OR_NULL(ptr: rtc->clk_lsco))
1221	clk_unregister_gate(clk: rtc->clk_lsco);
1222
1223	/ Disable interrupts /
1224	stm32_rtc_wpr_unlock(rtc);
1225	cr = readl_relaxed(rtc->base + regs->cr);
1226	cr &= ~STM32_RTC_CR_ALRAIE;
1227	writel_relaxed(cr, rtc->base + regs->cr);
1228	stm32_rtc_wpr_lock(rtc);
1229
1230	clk_disable_unprepare(clk: rtc->rtc_ck);
1231	if (rtc->data->has_pclk)
1232	clk_disable_unprepare(clk: rtc->pclk);
1233
1234	/ Enable backup domain write protection if needed /
1235	if (rtc->data->need_dbp)
1236	regmap_update_bits(map: rtc->dbp, reg: rtc->dbp_reg, mask: rtc->dbp_mask, val: `0`);
1237	}
1238
1239	static int stm32_rtc_suspend(struct device *dev)
1240	{
1241	struct stm32_rtc *rtc = dev_get_drvdata(dev);
1242
1243	if (rtc->data->has_pclk)
1244	clk_disable_unprepare(clk: rtc->pclk);
1245
1246	return `0`;
1247	}
1248
1249	static int stm32_rtc_resume(struct device *dev)
1250	{
1251	struct stm32_rtc *rtc = dev_get_drvdata(dev);
1252	int ret = `0`;
1253
1254	if (rtc->data->has_pclk) {
1255	ret = clk_prepare_enable(clk: rtc->pclk);
1256	if (ret)
1257	return ret;
1258	}
1259
1260	ret = stm32_rtc_wait_sync(rtc);
1261	if (ret < `0`) {
1262	if (rtc->data->has_pclk)
1263	clk_disable_unprepare(clk: rtc->pclk);
1264	return ret;
1265	}
1266
1267	return ret;
1268	}
1269
1270	static const struct dev_pm_ops stm32_rtc_pm_ops = {
1271	NOIRQ_SYSTEM_SLEEP_PM_OPS(stm32_rtc_suspend, stm32_rtc_resume)
1272	};
1273
1274	static struct platform_driver stm32_rtc_driver = {
1275	.probe = stm32_rtc_probe,
1276	.remove = stm32_rtc_remove,
1277	.driver = {
1278	.name = DRIVER_NAME,
1279	.pm = &stm32_rtc_pm_ops,
1280	.of_match_table = stm32_rtc_of_match,
1281	},
1282	};
1283
1284	module_platform_driver(stm32_rtc_driver);
1285
1286	MODULE_AUTHOR("Amelie Delaunay <amelie.delaunay@st.com>");
1287	MODULE_DESCRIPTION("STMicroelectronics STM32 Real Time Clock driver");
1288	MODULE_LICENSE("GPL v2");
1289

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Definitions

stm32_rtc_registers
stm32_rtc_events
stm32_rtc_data
stm32_rtc
stm32_rtc_rif_resource
STM32_RTC_RES_ALRA
STM32_RTC_RES_INIT
stm32_rtc_wpr_unlock
stm32_rtc_wpr_lock
stm32_rtc_pin_name
stm32_rtc_pinctrl_pins
stm32_rtc_pinctrl_get_groups_count
stm32_rtc_pinctrl_get_group_name
stm32_rtc_pinctrl_get_group_pins
stm32_rtc_pinctrl_ops
stm32_rtc_pinmux_func
stm32_rtc_pinmux_action_alarm
stm32_rtc_pinmux_lsco_available
stm32_rtc_pinmux_action_lsco
stm32_rtc_pinmux_functions
stm32_rtc_pinmux_get_functions_count
stm32_rtc_pinmux_get_fname
stm32_rtc_pinmux_get_groups
stm32_rtc_pinmux_set_mux
stm32_rtc_pinmux_ops
stm32_rtc_pdesc
stm32_rtc_enter_init_mode
stm32_rtc_exit_init_mode
stm32_rtc_wait_sync
stm32_rtc_clear_event_flags
stm32_rtc_alarm_irq
tm2bcd
bcd2tm
stm32_rtc_read_time
stm32_rtc_set_time
stm32_rtc_read_alarm
stm32_rtc_alarm_irq_enable
stm32_rtc_valid_alrm
stm32_rtc_set_alarm
stm32_rtc_ops
stm32_rtc_clear_events
stm32_rtc_data
stm32h7_rtc_data
stm32mp1_rtc_clear_events
stm32mp1_data
stm32mp25_data
stm32_rtc_of_match
stm32_rtc_clean_outs
stm32_rtc_check_rif
stm32_rtc_init
stm32_rtc_probe
stm32_rtc_remove
stm32_rtc_suspend
stm32_rtc_resume
stm32_rtc_pm_ops

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Definitions

source code of linux/drivers/rtc/rtc-stm32.c