Contributors: 18
Author Tokens Token Proportion Commits Commit Proportion
Chen-Yu Tsai 2048 55.08% 6 15.00%
Maxime Ripard 731 19.66% 7 17.50%
Samuel Holland 328 8.82% 5 12.50%
Andre Przywara 278 7.48% 4 10.00%
Ondrej Jirman 85 2.29% 1 2.50%
Alexandre Belloni 74 1.99% 3 7.50%
Alejandro González 63 1.69% 1 2.50%
Jernej Škrabec 53 1.43% 2 5.00%
Colin Ian King 18 0.48% 2 5.00%
Dinghao Liu 18 0.48% 1 2.50%
Wei Yongjun 5 0.13% 1 2.50%
Gustavo A. R. Silva 5 0.13% 1 2.50%
Icenowy Zheng 4 0.11% 1 2.50%
Michael Trimarchi 3 0.08% 1 2.50%
Thomas Gleixner 2 0.05% 1 2.50%
Stephen Boyd 1 0.03% 1 2.50%
Rob Herring 1 0.03% 1 2.50%
Bartosz Golaszewski 1 0.03% 1 2.50%
Total 3718 40


// SPDX-License-Identifier: GPL-2.0-or-later
/*
 * An RTC driver for Allwinner A31/A23
 *
 * Copyright (c) 2014, Chen-Yu Tsai <wens@csie.org>
 *
 * based on rtc-sunxi.c
 *
 * An RTC driver for Allwinner A10/A20
 *
 * Copyright (c) 2013, Carlo Caione <carlo.caione@gmail.com>
 */

#include <linux/clk.h>
#include <linux/clk-provider.h>
#include <linux/clk/sunxi-ng.h>
#include <linux/delay.h>
#include <linux/err.h>
#include <linux/fs.h>
#include <linux/init.h>
#include <linux/interrupt.h>
#include <linux/io.h>
#include <linux/kernel.h>
#include <linux/module.h>
#include <linux/of.h>
#include <linux/of_address.h>
#include <linux/platform_device.h>
#include <linux/rtc.h>
#include <linux/slab.h>
#include <linux/types.h>

/* Control register */
#define SUN6I_LOSC_CTRL				0x0000
#define SUN6I_LOSC_CTRL_KEY			(0x16aa << 16)
#define SUN6I_LOSC_CTRL_AUTO_SWT_BYPASS		BIT(15)
#define SUN6I_LOSC_CTRL_ALM_DHMS_ACC		BIT(9)
#define SUN6I_LOSC_CTRL_RTC_HMS_ACC		BIT(8)
#define SUN6I_LOSC_CTRL_RTC_YMD_ACC		BIT(7)
#define SUN6I_LOSC_CTRL_EXT_LOSC_EN		BIT(4)
#define SUN6I_LOSC_CTRL_EXT_OSC			BIT(0)
#define SUN6I_LOSC_CTRL_ACC_MASK		GENMASK(9, 7)

#define SUN6I_LOSC_CLK_PRESCAL			0x0008

/* RTC */
#define SUN6I_RTC_YMD				0x0010
#define SUN6I_RTC_HMS				0x0014

/* Alarm 0 (counter) */
#define SUN6I_ALRM_COUNTER			0x0020
/* This holds the remaining alarm seconds on older SoCs (current value) */
#define SUN6I_ALRM_COUNTER_HMS			0x0024
#define SUN6I_ALRM_EN				0x0028
#define SUN6I_ALRM_EN_CNT_EN			BIT(0)
#define SUN6I_ALRM_IRQ_EN			0x002c
#define SUN6I_ALRM_IRQ_EN_CNT_IRQ_EN		BIT(0)
#define SUN6I_ALRM_IRQ_STA			0x0030
#define SUN6I_ALRM_IRQ_STA_CNT_IRQ_PEND		BIT(0)

/* Alarm 1 (wall clock) */
#define SUN6I_ALRM1_EN				0x0044
#define SUN6I_ALRM1_IRQ_EN			0x0048
#define SUN6I_ALRM1_IRQ_STA			0x004c
#define SUN6I_ALRM1_IRQ_STA_WEEK_IRQ_PEND	BIT(0)

/* Alarm config */
#define SUN6I_ALARM_CONFIG			0x0050
#define SUN6I_ALARM_CONFIG_WAKEUP		BIT(0)

#define SUN6I_LOSC_OUT_GATING			0x0060
#define SUN6I_LOSC_OUT_GATING_EN_OFFSET		0

/* General-purpose data */
#define SUN6I_GP_DATA				0x0100
#define SUN6I_GP_DATA_SIZE			0x20

/*
 * Get date values
 */
#define SUN6I_DATE_GET_DAY_VALUE(x)		((x)  & 0x0000001f)
#define SUN6I_DATE_GET_MON_VALUE(x)		(((x) & 0x00000f00) >> 8)
#define SUN6I_DATE_GET_YEAR_VALUE(x)		(((x) & 0x003f0000) >> 16)
#define SUN6I_LEAP_GET_VALUE(x)			(((x) & 0x00400000) >> 22)

/*
 * Get time values
 */
#define SUN6I_TIME_GET_SEC_VALUE(x)		((x)  & 0x0000003f)
#define SUN6I_TIME_GET_MIN_VALUE(x)		(((x) & 0x00003f00) >> 8)
#define SUN6I_TIME_GET_HOUR_VALUE(x)		(((x) & 0x001f0000) >> 16)

/*
 * Set date values
 */
#define SUN6I_DATE_SET_DAY_VALUE(x)		((x)       & 0x0000001f)
#define SUN6I_DATE_SET_MON_VALUE(x)		((x) <<  8 & 0x00000f00)
#define SUN6I_DATE_SET_YEAR_VALUE(x)		((x) << 16 & 0x003f0000)
#define SUN6I_LEAP_SET_VALUE(x)			((x) << 22 & 0x00400000)

/*
 * Set time values
 */
#define SUN6I_TIME_SET_SEC_VALUE(x)		((x)       & 0x0000003f)
#define SUN6I_TIME_SET_MIN_VALUE(x)		((x) <<  8 & 0x00003f00)
#define SUN6I_TIME_SET_HOUR_VALUE(x)		((x) << 16 & 0x001f0000)

/*
 * The year parameter passed to the driver is usually an offset relative to
 * the year 1900. This macro is used to convert this offset to another one
 * relative to the minimum year allowed by the hardware.
 *
 * The year range is 1970 - 2033. This range is selected to match Allwinner's
 * driver, even though it is somewhat limited.
 */
#define SUN6I_YEAR_MIN				1970
#define SUN6I_YEAR_OFF				(SUN6I_YEAR_MIN - 1900)

#define SECS_PER_DAY				(24 * 3600ULL)

/*
 * There are other differences between models, including:
 *
 *   - number of GPIO pins that can be configured to hold a certain level
 *   - crypto-key related registers (H5, H6)
 *   - boot process related (super standby, secondary processor entry address)
 *     registers (R40, H6)
 *   - SYS power domain controls (R40)
 *   - DCXO controls (H6)
 *   - RC oscillator calibration (H6)
 *
 * These functions are not covered by this driver.
 */
struct sun6i_rtc_clk_data {
	unsigned long rc_osc_rate;
	unsigned int fixed_prescaler : 16;
	unsigned int has_prescaler : 1;
	unsigned int has_out_clk : 1;
	unsigned int has_losc_en : 1;
	unsigned int has_auto_swt : 1;
};

#define RTC_LINEAR_DAY	BIT(0)

struct sun6i_rtc_dev {
	struct rtc_device *rtc;
	const struct sun6i_rtc_clk_data *data;
	void __iomem *base;
	int irq;
	time64_t alarm;
	unsigned long flags;

	struct clk_hw hw;
	struct clk_hw *int_osc;
	struct clk *losc;
	struct clk *ext_losc;

	spinlock_t lock;
};

static struct sun6i_rtc_dev *sun6i_rtc;

static unsigned long sun6i_rtc_osc_recalc_rate(struct clk_hw *hw,
					       unsigned long parent_rate)
{
	struct sun6i_rtc_dev *rtc = container_of(hw, struct sun6i_rtc_dev, hw);
	u32 val = 0;

	val = readl(rtc->base + SUN6I_LOSC_CTRL);
	if (val & SUN6I_LOSC_CTRL_EXT_OSC)
		return parent_rate;

	if (rtc->data->fixed_prescaler)
		parent_rate /= rtc->data->fixed_prescaler;

	if (rtc->data->has_prescaler) {
		val = readl(rtc->base + SUN6I_LOSC_CLK_PRESCAL);
		val &= GENMASK(4, 0);
	}

	return parent_rate / (val + 1);
}

static u8 sun6i_rtc_osc_get_parent(struct clk_hw *hw)
{
	struct sun6i_rtc_dev *rtc = container_of(hw, struct sun6i_rtc_dev, hw);

	return readl(rtc->base + SUN6I_LOSC_CTRL) & SUN6I_LOSC_CTRL_EXT_OSC;
}

static int sun6i_rtc_osc_set_parent(struct clk_hw *hw, u8 index)
{
	struct sun6i_rtc_dev *rtc = container_of(hw, struct sun6i_rtc_dev, hw);
	unsigned long flags;
	u32 val;

	if (index > 1)
		return -EINVAL;

	spin_lock_irqsave(&rtc->lock, flags);
	val = readl(rtc->base + SUN6I_LOSC_CTRL);
	val &= ~SUN6I_LOSC_CTRL_EXT_OSC;
	val |= SUN6I_LOSC_CTRL_KEY;
	val |= index ? SUN6I_LOSC_CTRL_EXT_OSC : 0;
	if (rtc->data->has_losc_en) {
		val &= ~SUN6I_LOSC_CTRL_EXT_LOSC_EN;
		val |= index ? SUN6I_LOSC_CTRL_EXT_LOSC_EN : 0;
	}
	writel(val, rtc->base + SUN6I_LOSC_CTRL);
	spin_unlock_irqrestore(&rtc->lock, flags);

	return 0;
}

static const struct clk_ops sun6i_rtc_osc_ops = {
	.recalc_rate	= sun6i_rtc_osc_recalc_rate,
	.determine_rate	= clk_hw_determine_rate_no_reparent,

	.get_parent	= sun6i_rtc_osc_get_parent,
	.set_parent	= sun6i_rtc_osc_set_parent,
};

static void __init sun6i_rtc_clk_init(struct device_node *node,
				      const struct sun6i_rtc_clk_data *data)
{
	struct clk_hw_onecell_data *clk_data;
	struct sun6i_rtc_dev *rtc;
	struct clk_init_data init = {
		.ops		= &sun6i_rtc_osc_ops,
		.name		= "losc",
	};
	const char *iosc_name = "rtc-int-osc";
	const char *clkout_name = "osc32k-out";
	const char *parents[2];
	u32 reg;

	rtc = kzalloc(sizeof(*rtc), GFP_KERNEL);
	if (!rtc)
		return;

	rtc->data = data;
	clk_data = kzalloc(struct_size(clk_data, hws, 3), GFP_KERNEL);
	if (!clk_data) {
		kfree(rtc);
		return;
	}

	spin_lock_init(&rtc->lock);

	rtc->base = of_io_request_and_map(node, 0, of_node_full_name(node));
	if (IS_ERR(rtc->base)) {
		pr_crit("Can't map RTC registers");
		goto err;
	}

	reg = SUN6I_LOSC_CTRL_KEY;
	if (rtc->data->has_auto_swt) {
		/* Bypass auto-switch to int osc, on ext losc failure */
		reg |= SUN6I_LOSC_CTRL_AUTO_SWT_BYPASS;
		writel(reg, rtc->base + SUN6I_LOSC_CTRL);
	}

	/* Switch to the external, more precise, oscillator, if present */
	if (of_property_present(node, "clocks")) {
		reg |= SUN6I_LOSC_CTRL_EXT_OSC;
		if (rtc->data->has_losc_en)
			reg |= SUN6I_LOSC_CTRL_EXT_LOSC_EN;
	}
	writel(reg, rtc->base + SUN6I_LOSC_CTRL);

	/* Yes, I know, this is ugly. */
	sun6i_rtc = rtc;

	of_property_read_string_index(node, "clock-output-names", 2,
				      &iosc_name);

	rtc->int_osc = clk_hw_register_fixed_rate_with_accuracy(NULL,
								iosc_name,
								NULL, 0,
								rtc->data->rc_osc_rate,
								300000000);
	if (IS_ERR(rtc->int_osc)) {
		pr_crit("Couldn't register the internal oscillator\n");
		goto err;
	}

	parents[0] = clk_hw_get_name(rtc->int_osc);
	/* If there is no external oscillator, this will be NULL and ... */
	parents[1] = of_clk_get_parent_name(node, 0);

	rtc->hw.init = &init;

	init.parent_names = parents;
	/* ... number of clock parents will be 1. */
	init.num_parents = of_clk_get_parent_count(node) + 1;
	of_property_read_string_index(node, "clock-output-names", 0,
				      &init.name);

	rtc->losc = clk_register(NULL, &rtc->hw);
	if (IS_ERR(rtc->losc)) {
		pr_crit("Couldn't register the LOSC clock\n");
		goto err_register;
	}

	of_property_read_string_index(node, "clock-output-names", 1,
				      &clkout_name);
	rtc->ext_losc = clk_register_gate(NULL, clkout_name, init.name,
					  0, rtc->base + SUN6I_LOSC_OUT_GATING,
					  SUN6I_LOSC_OUT_GATING_EN_OFFSET, 0,
					  &rtc->lock);
	if (IS_ERR(rtc->ext_losc)) {
		pr_crit("Couldn't register the LOSC external gate\n");
		goto err_register;
	}

	clk_data->num = 3;
	clk_data->hws[0] = &rtc->hw;
	clk_data->hws[1] = __clk_get_hw(rtc->ext_losc);
	clk_data->hws[2] = rtc->int_osc;
	of_clk_add_hw_provider(node, of_clk_hw_onecell_get, clk_data);
	return;

err_register:
	clk_hw_unregister_fixed_rate(rtc->int_osc);
err:
	kfree(clk_data);
}

static const struct sun6i_rtc_clk_data sun6i_a31_rtc_data = {
	.rc_osc_rate = 667000, /* datasheet says 600 ~ 700 KHz */
	.has_prescaler = 1,
};

static void __init sun6i_a31_rtc_clk_init(struct device_node *node)
{
	sun6i_rtc_clk_init(node, &sun6i_a31_rtc_data);
}
CLK_OF_DECLARE_DRIVER(sun6i_a31_rtc_clk, "allwinner,sun6i-a31-rtc",
		      sun6i_a31_rtc_clk_init);

static const struct sun6i_rtc_clk_data sun8i_a23_rtc_data = {
	.rc_osc_rate = 667000, /* datasheet says 600 ~ 700 KHz */
	.has_prescaler = 1,
	.has_out_clk = 1,
};

static void __init sun8i_a23_rtc_clk_init(struct device_node *node)
{
	sun6i_rtc_clk_init(node, &sun8i_a23_rtc_data);
}
CLK_OF_DECLARE_DRIVER(sun8i_a23_rtc_clk, "allwinner,sun8i-a23-rtc",
		      sun8i_a23_rtc_clk_init);

static const struct sun6i_rtc_clk_data sun8i_h3_rtc_data = {
	.rc_osc_rate = 16000000,
	.fixed_prescaler = 32,
	.has_prescaler = 1,
	.has_out_clk = 1,
};

static void __init sun8i_h3_rtc_clk_init(struct device_node *node)
{
	sun6i_rtc_clk_init(node, &sun8i_h3_rtc_data);
}
CLK_OF_DECLARE_DRIVER(sun8i_h3_rtc_clk, "allwinner,sun8i-h3-rtc",
		      sun8i_h3_rtc_clk_init);
/* As far as we are concerned, clocks for H5 are the same as H3 */
CLK_OF_DECLARE_DRIVER(sun50i_h5_rtc_clk, "allwinner,sun50i-h5-rtc",
		      sun8i_h3_rtc_clk_init);

static const struct sun6i_rtc_clk_data sun50i_h6_rtc_data = {
	.rc_osc_rate = 16000000,
	.fixed_prescaler = 32,
	.has_prescaler = 1,
	.has_out_clk = 1,
	.has_losc_en = 1,
	.has_auto_swt = 1,
};

static void __init sun50i_h6_rtc_clk_init(struct device_node *node)
{
	sun6i_rtc_clk_init(node, &sun50i_h6_rtc_data);
}
CLK_OF_DECLARE_DRIVER(sun50i_h6_rtc_clk, "allwinner,sun50i-h6-rtc",
		      sun50i_h6_rtc_clk_init);

/*
 * The R40 user manual is self-conflicting on whether the prescaler is
 * fixed or configurable. The clock diagram shows it as fixed, but there
 * is also a configurable divider in the RTC block.
 */
static const struct sun6i_rtc_clk_data sun8i_r40_rtc_data = {
	.rc_osc_rate = 16000000,
	.fixed_prescaler = 512,
};
static void __init sun8i_r40_rtc_clk_init(struct device_node *node)
{
	sun6i_rtc_clk_init(node, &sun8i_r40_rtc_data);
}
CLK_OF_DECLARE_DRIVER(sun8i_r40_rtc_clk, "allwinner,sun8i-r40-rtc",
		      sun8i_r40_rtc_clk_init);

static const struct sun6i_rtc_clk_data sun8i_v3_rtc_data = {
	.rc_osc_rate = 32000,
	.has_out_clk = 1,
};

static void __init sun8i_v3_rtc_clk_init(struct device_node *node)
{
	sun6i_rtc_clk_init(node, &sun8i_v3_rtc_data);
}
CLK_OF_DECLARE_DRIVER(sun8i_v3_rtc_clk, "allwinner,sun8i-v3-rtc",
		      sun8i_v3_rtc_clk_init);

static irqreturn_t sun6i_rtc_alarmirq(int irq, void *id)
{
	struct sun6i_rtc_dev *chip = (struct sun6i_rtc_dev *) id;
	irqreturn_t ret = IRQ_NONE;
	u32 val;

	spin_lock(&chip->lock);
	val = readl(chip->base + SUN6I_ALRM_IRQ_STA);

	if (val & SUN6I_ALRM_IRQ_STA_CNT_IRQ_PEND) {
		val |= SUN6I_ALRM_IRQ_STA_CNT_IRQ_PEND;
		writel(val, chip->base + SUN6I_ALRM_IRQ_STA);

		rtc_update_irq(chip->rtc, 1, RTC_AF | RTC_IRQF);

		ret = IRQ_HANDLED;
	}
	spin_unlock(&chip->lock);

	return ret;
}

static void sun6i_rtc_setaie(int to, struct sun6i_rtc_dev *chip)
{
	u32 alrm_val = 0;
	u32 alrm_irq_val = 0;
	u32 alrm_wake_val = 0;
	unsigned long flags;

	if (to) {
		alrm_val = SUN6I_ALRM_EN_CNT_EN;
		alrm_irq_val = SUN6I_ALRM_IRQ_EN_CNT_IRQ_EN;
		alrm_wake_val = SUN6I_ALARM_CONFIG_WAKEUP;
	} else {
		writel(SUN6I_ALRM_IRQ_STA_CNT_IRQ_PEND,
		       chip->base + SUN6I_ALRM_IRQ_STA);
	}

	spin_lock_irqsave(&chip->lock, flags);
	writel(alrm_val, chip->base + SUN6I_ALRM_EN);
	writel(alrm_irq_val, chip->base + SUN6I_ALRM_IRQ_EN);
	writel(alrm_wake_val, chip->base + SUN6I_ALARM_CONFIG);
	spin_unlock_irqrestore(&chip->lock, flags);
}

static int sun6i_rtc_gettime(struct device *dev, struct rtc_time *rtc_tm)
{
	struct sun6i_rtc_dev *chip = dev_get_drvdata(dev);
	u32 date, time;

	/*
	 * read again in case it changes
	 */
	do {
		date = readl(chip->base + SUN6I_RTC_YMD);
		time = readl(chip->base + SUN6I_RTC_HMS);
	} while ((date != readl(chip->base + SUN6I_RTC_YMD)) ||
		 (time != readl(chip->base + SUN6I_RTC_HMS)));

	if (chip->flags & RTC_LINEAR_DAY) {
		/*
		 * Newer chips store a linear day number, the manual
		 * does not mandate any epoch base. The BSP driver uses
		 * the UNIX epoch, let's just copy that, as it's the
		 * easiest anyway.
		 */
		rtc_time64_to_tm((date & 0xffff) * SECS_PER_DAY, rtc_tm);
	} else {
		rtc_tm->tm_mday = SUN6I_DATE_GET_DAY_VALUE(date);
		rtc_tm->tm_mon  = SUN6I_DATE_GET_MON_VALUE(date) - 1;
		rtc_tm->tm_year = SUN6I_DATE_GET_YEAR_VALUE(date);

		/*
		 * switch from (data_year->min)-relative offset to
		 * a (1900)-relative one
		 */
		rtc_tm->tm_year += SUN6I_YEAR_OFF;
	}

	rtc_tm->tm_sec  = SUN6I_TIME_GET_SEC_VALUE(time);
	rtc_tm->tm_min  = SUN6I_TIME_GET_MIN_VALUE(time);
	rtc_tm->tm_hour = SUN6I_TIME_GET_HOUR_VALUE(time);

	return 0;
}

static int sun6i_rtc_getalarm(struct device *dev, struct rtc_wkalrm *wkalrm)
{
	struct sun6i_rtc_dev *chip = dev_get_drvdata(dev);
	unsigned long flags;
	u32 alrm_st;
	u32 alrm_en;

	spin_lock_irqsave(&chip->lock, flags);
	alrm_en = readl(chip->base + SUN6I_ALRM_IRQ_EN);
	alrm_st = readl(chip->base + SUN6I_ALRM_IRQ_STA);
	spin_unlock_irqrestore(&chip->lock, flags);

	wkalrm->enabled = !!(alrm_en & SUN6I_ALRM_EN_CNT_EN);
	wkalrm->pending = !!(alrm_st & SUN6I_ALRM_EN_CNT_EN);
	rtc_time64_to_tm(chip->alarm, &wkalrm->time);

	return 0;
}

static int sun6i_rtc_setalarm(struct device *dev, struct rtc_wkalrm *wkalrm)
{
	struct sun6i_rtc_dev *chip = dev_get_drvdata(dev);
	struct rtc_time *alrm_tm = &wkalrm->time;
	struct rtc_time tm_now;
	time64_t time_set;
	u32 counter_val, counter_val_hms;
	int ret;

	time_set = rtc_tm_to_time64(alrm_tm);

	if (chip->flags & RTC_LINEAR_DAY) {
		/*
		 * The alarm registers hold the actual alarm time, encoded
		 * in the same way (linear day + HMS) as the current time.
		 */
		counter_val_hms = SUN6I_TIME_SET_SEC_VALUE(alrm_tm->tm_sec)  |
				  SUN6I_TIME_SET_MIN_VALUE(alrm_tm->tm_min)  |
				  SUN6I_TIME_SET_HOUR_VALUE(alrm_tm->tm_hour);
		/* The division will cut off the H:M:S part of alrm_tm. */
		counter_val = div_u64(rtc_tm_to_time64(alrm_tm), SECS_PER_DAY);
	} else {
		/* The alarm register holds the number of seconds left. */
		time64_t time_now;

		ret = sun6i_rtc_gettime(dev, &tm_now);
		if (ret < 0) {
			dev_err(dev, "Error in getting time\n");
			return -EINVAL;
		}

		time_now = rtc_tm_to_time64(&tm_now);
		if (time_set <= time_now) {
			dev_err(dev, "Date to set in the past\n");
			return -EINVAL;
		}
		if ((time_set - time_now) > U32_MAX) {
			dev_err(dev, "Date too far in the future\n");
			return -EINVAL;
		}

		counter_val = time_set - time_now;
	}

	sun6i_rtc_setaie(0, chip);
	writel(0, chip->base + SUN6I_ALRM_COUNTER);
	if (chip->flags & RTC_LINEAR_DAY)
		writel(0, chip->base + SUN6I_ALRM_COUNTER_HMS);
	usleep_range(100, 300);

	writel(counter_val, chip->base + SUN6I_ALRM_COUNTER);
	if (chip->flags & RTC_LINEAR_DAY)
		writel(counter_val_hms, chip->base + SUN6I_ALRM_COUNTER_HMS);
	chip->alarm = time_set;

	sun6i_rtc_setaie(wkalrm->enabled, chip);

	return 0;
}

static int sun6i_rtc_wait(struct sun6i_rtc_dev *chip, int offset,
			  unsigned int mask, unsigned int ms_timeout)
{
	const unsigned long timeout = jiffies + msecs_to_jiffies(ms_timeout);
	u32 reg;

	do {
		reg = readl(chip->base + offset);
		reg &= mask;

		if (!reg)
			return 0;

	} while (time_before(jiffies, timeout));

	return -ETIMEDOUT;
}

static int sun6i_rtc_settime(struct device *dev, struct rtc_time *rtc_tm)
{
	struct sun6i_rtc_dev *chip = dev_get_drvdata(dev);
	u32 date = 0;
	u32 time = 0;

	time = SUN6I_TIME_SET_SEC_VALUE(rtc_tm->tm_sec)  |
		SUN6I_TIME_SET_MIN_VALUE(rtc_tm->tm_min)  |
		SUN6I_TIME_SET_HOUR_VALUE(rtc_tm->tm_hour);

	if (chip->flags & RTC_LINEAR_DAY) {
		/* The division will cut off the H:M:S part of rtc_tm. */
		date = div_u64(rtc_tm_to_time64(rtc_tm), SECS_PER_DAY);
	} else {
		rtc_tm->tm_year -= SUN6I_YEAR_OFF;
		rtc_tm->tm_mon += 1;

		date = SUN6I_DATE_SET_DAY_VALUE(rtc_tm->tm_mday) |
			SUN6I_DATE_SET_MON_VALUE(rtc_tm->tm_mon)  |
			SUN6I_DATE_SET_YEAR_VALUE(rtc_tm->tm_year);

		if (is_leap_year(rtc_tm->tm_year + SUN6I_YEAR_MIN))
			date |= SUN6I_LEAP_SET_VALUE(1);
	}

	/* Check whether registers are writable */
	if (sun6i_rtc_wait(chip, SUN6I_LOSC_CTRL,
			   SUN6I_LOSC_CTRL_ACC_MASK, 50)) {
		dev_err(dev, "rtc is still busy.\n");
		return -EBUSY;
	}

	writel(time, chip->base + SUN6I_RTC_HMS);

	/*
	 * After writing the RTC HH-MM-SS register, the
	 * SUN6I_LOSC_CTRL_RTC_HMS_ACC bit is set and it will not
	 * be cleared until the real writing operation is finished
	 */

	if (sun6i_rtc_wait(chip, SUN6I_LOSC_CTRL,
			   SUN6I_LOSC_CTRL_RTC_HMS_ACC, 50)) {
		dev_err(dev, "Failed to set rtc time.\n");
		return -ETIMEDOUT;
	}

	writel(date, chip->base + SUN6I_RTC_YMD);

	/*
	 * After writing the RTC YY-MM-DD register, the
	 * SUN6I_LOSC_CTRL_RTC_YMD_ACC bit is set and it will not
	 * be cleared until the real writing operation is finished
	 */

	if (sun6i_rtc_wait(chip, SUN6I_LOSC_CTRL,
			   SUN6I_LOSC_CTRL_RTC_YMD_ACC, 50)) {
		dev_err(dev, "Failed to set rtc time.\n");
		return -ETIMEDOUT;
	}

	return 0;
}

static int sun6i_rtc_alarm_irq_enable(struct device *dev, unsigned int enabled)
{
	struct sun6i_rtc_dev *chip = dev_get_drvdata(dev);

	if (!enabled)
		sun6i_rtc_setaie(enabled, chip);

	return 0;
}

static const struct rtc_class_ops sun6i_rtc_ops = {
	.read_time		= sun6i_rtc_gettime,
	.set_time		= sun6i_rtc_settime,
	.read_alarm		= sun6i_rtc_getalarm,
	.set_alarm		= sun6i_rtc_setalarm,
	.alarm_irq_enable	= sun6i_rtc_alarm_irq_enable
};

static int sun6i_rtc_nvmem_read(void *priv, unsigned int offset, void *_val, size_t bytes)
{
	struct sun6i_rtc_dev *chip = priv;
	u32 *val = _val;
	int i;

	for (i = 0; i < bytes / 4; ++i)
		val[i] = readl(chip->base + SUN6I_GP_DATA + offset + 4 * i);

	return 0;
}

static int sun6i_rtc_nvmem_write(void *priv, unsigned int offset, void *_val, size_t bytes)
{
	struct sun6i_rtc_dev *chip = priv;
	u32 *val = _val;
	int i;

	for (i = 0; i < bytes / 4; ++i)
		writel(val[i], chip->base + SUN6I_GP_DATA + offset + 4 * i);

	return 0;
}

static struct nvmem_config sun6i_rtc_nvmem_cfg = {
	.type		= NVMEM_TYPE_BATTERY_BACKED,
	.reg_read	= sun6i_rtc_nvmem_read,
	.reg_write	= sun6i_rtc_nvmem_write,
	.size		= SUN6I_GP_DATA_SIZE,
	.word_size	= 4,
	.stride		= 4,
};

#ifdef CONFIG_PM_SLEEP
/* Enable IRQ wake on suspend, to wake up from RTC. */
static int sun6i_rtc_suspend(struct device *dev)
{
	struct sun6i_rtc_dev *chip = dev_get_drvdata(dev);

	if (device_may_wakeup(dev))
		enable_irq_wake(chip->irq);

	return 0;
}

/* Disable IRQ wake on resume. */
static int sun6i_rtc_resume(struct device *dev)
{
	struct sun6i_rtc_dev *chip = dev_get_drvdata(dev);

	if (device_may_wakeup(dev))
		disable_irq_wake(chip->irq);

	return 0;
}
#endif

static SIMPLE_DEV_PM_OPS(sun6i_rtc_pm_ops,
	sun6i_rtc_suspend, sun6i_rtc_resume);

static void sun6i_rtc_bus_clk_cleanup(void *data)
{
	struct clk *bus_clk = data;

	clk_disable_unprepare(bus_clk);
}

static int sun6i_rtc_probe(struct platform_device *pdev)
{
	struct sun6i_rtc_dev *chip = sun6i_rtc;
	struct device *dev = &pdev->dev;
	struct clk *bus_clk;
	int ret;

	bus_clk = devm_clk_get_optional(dev, "bus");
	if (IS_ERR(bus_clk))
		return PTR_ERR(bus_clk);

	if (bus_clk) {
		ret = clk_prepare_enable(bus_clk);
		if (ret)
			return ret;

		ret = devm_add_action_or_reset(dev, sun6i_rtc_bus_clk_cleanup,
					       bus_clk);
		if (ret)
			return ret;
	}

	if (!chip) {
		chip = devm_kzalloc(&pdev->dev, sizeof(*chip), GFP_KERNEL);
		if (!chip)
			return -ENOMEM;

		spin_lock_init(&chip->lock);

		chip->base = devm_platform_ioremap_resource(pdev, 0);
		if (IS_ERR(chip->base))
			return PTR_ERR(chip->base);

		if (IS_REACHABLE(CONFIG_SUN6I_RTC_CCU)) {
			ret = sun6i_rtc_ccu_probe(dev, chip->base);
			if (ret)
				return ret;
		}
	}

	platform_set_drvdata(pdev, chip);

	chip->flags = (unsigned long)of_device_get_match_data(&pdev->dev);

	chip->irq = platform_get_irq(pdev, 0);
	if (chip->irq < 0)
		return chip->irq;

	ret = devm_request_irq(&pdev->dev, chip->irq, sun6i_rtc_alarmirq,
			       0, dev_name(&pdev->dev), chip);
	if (ret) {
		dev_err(&pdev->dev, "Could not request IRQ\n");
		return ret;
	}

	/* clear the alarm counter value */
	writel(0, chip->base + SUN6I_ALRM_COUNTER);

	/* disable counter alarm */
	writel(0, chip->base + SUN6I_ALRM_EN);

	/* disable counter alarm interrupt */
	writel(0, chip->base + SUN6I_ALRM_IRQ_EN);

	/* disable week alarm */
	writel(0, chip->base + SUN6I_ALRM1_EN);

	/* disable week alarm interrupt */
	writel(0, chip->base + SUN6I_ALRM1_IRQ_EN);

	/* clear counter alarm pending interrupts */
	writel(SUN6I_ALRM_IRQ_STA_CNT_IRQ_PEND,
	       chip->base + SUN6I_ALRM_IRQ_STA);

	/* clear week alarm pending interrupts */
	writel(SUN6I_ALRM1_IRQ_STA_WEEK_IRQ_PEND,
	       chip->base + SUN6I_ALRM1_IRQ_STA);

	/* disable alarm wakeup */
	writel(0, chip->base + SUN6I_ALARM_CONFIG);

	clk_prepare_enable(chip->losc);

	device_init_wakeup(&pdev->dev, 1);

	chip->rtc = devm_rtc_allocate_device(&pdev->dev);
	if (IS_ERR(chip->rtc))
		return PTR_ERR(chip->rtc);

	chip->rtc->ops = &sun6i_rtc_ops;
	if (chip->flags & RTC_LINEAR_DAY)
		chip->rtc->range_max = (65536 * SECS_PER_DAY) - 1;
	else
		chip->rtc->range_max = 2019686399LL; /* 2033-12-31 23:59:59 */

	ret = devm_rtc_register_device(chip->rtc);
	if (ret)
		return ret;

	sun6i_rtc_nvmem_cfg.priv = chip;
	ret = devm_rtc_nvmem_register(chip->rtc, &sun6i_rtc_nvmem_cfg);
	if (ret)
		return ret;

	return 0;
}

/*
 * As far as RTC functionality goes, all models are the same. The
 * datasheets claim that different models have different number of
 * registers available for non-volatile storage, but experiments show
 * that all SoCs have 16 registers available for this purpose.
 */
static const struct of_device_id sun6i_rtc_dt_ids[] = {
	{ .compatible = "allwinner,sun6i-a31-rtc" },
	{ .compatible = "allwinner,sun8i-a23-rtc" },
	{ .compatible = "allwinner,sun8i-h3-rtc" },
	{ .compatible = "allwinner,sun8i-r40-rtc" },
	{ .compatible = "allwinner,sun8i-v3-rtc" },
	{ .compatible = "allwinner,sun50i-h5-rtc" },
	{ .compatible = "allwinner,sun50i-h6-rtc" },
	{ .compatible = "allwinner,sun50i-h616-rtc",
		.data = (void *)RTC_LINEAR_DAY },
	{ .compatible = "allwinner,sun50i-r329-rtc",
		.data = (void *)RTC_LINEAR_DAY },
	{ /* sentinel */ },
};
MODULE_DEVICE_TABLE(of, sun6i_rtc_dt_ids);

static struct platform_driver sun6i_rtc_driver = {
	.probe		= sun6i_rtc_probe,
	.driver		= {
		.name		= "sun6i-rtc",
		.of_match_table = sun6i_rtc_dt_ids,
		.pm = &sun6i_rtc_pm_ops,
	},
};
builtin_platform_driver(sun6i_rtc_driver);