drivers/counter/counter_cmos.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2019 Intel Corp.
  * SPDX-License-Identifier: Apache-2.0
  *
  * This barebones driver enables the use of the PC AT-style RTC
  * (the so-called "CMOS" clock) as a primitive, 1Hz monotonic counter.
  *
  * Reading a reliable value from the RTC is a fairly slow process, because
  * we use legacy I/O ports and do a lot of iterations with spinlocks to read
  * the RTC state. Plus we have to read the state multiple times because we're
  * crossing clock domains (no pun intended). Use accordingly.
  */

 #define DT_DRV_COMPAT motorola_mc146818

 #include <zephyr/drivers/counter.h>
 #include <zephyr/device.h>
 #include <soc.h>

 /* The "CMOS" device is accessed via an address latch and data port. */

 #define X86_CMOS_ADDR (DT_INST_REG_ADDR_BY_IDX(0, 0))
 #define X86_CMOS_DATA (DT_INST_REG_ADDR_BY_IDX(0, 1))

 /*
  * A snapshot of the RTC state, or at least the state we're
  * interested in. This struct should not be modified without
  * serious consideration, for two reasons:
  *
  *	1. Order of the element is important, and must correlate
  *	   with addrs[] and NR_BCD_VALS (see below), and
  *	2. if it doesn't remain exactly 8 bytes long, the
  *	   type-punning to compare states will break.
  */

 struct state {
 	uint8_t second,
 	     minute,
 	     hour,
 	     day,
 	     month,
 	     year,
 	     status_a,
 	     status_b;
 };

 /*
  * If the clock is in BCD mode, the first NR_BCD_VALS
  * values in 'struct state' are BCD-encoded.
  */

 #define NR_BCD_VALS 6

 /*
  * Indices into the CMOS address space that correspond to
  * the members of 'struct state'.
  */

 const uint8_t addrs[] = { 0, 2, 4, 7, 8, 9, 10, 11 };

 /*
  * Interesting bits in 'struct state'.
  */

 #define STATUS_B_24HR	0x02	/* 24-hour (vs 12-hour) mode */
 #define STATUS_B_BIN	0x01	/* binary (vs BCD) mode */
 #define HOUR_PM		0x80	/* high bit of hour set = PM */

 /*
  * Read a value from the CMOS. Because of the address latch,
  * we have to spinlock to make the access atomic.
  */

 static uint8_t read_register(uint8_t addr)
 {
 	static struct k_spinlock lock;
 	k_spinlock_key_t k;
 	uint8_t val;

 	k = k_spin_lock(&lock);
 	sys_out8(addr, X86_CMOS_ADDR);
 	val = sys_in8(X86_CMOS_DATA);
 	k_spin_unlock(&lock, k);

 	return val;
 }

 /* Populate 'state' with current RTC state. */

 void read_state(struct state *state)
 {
 	int i;
 	uint8_t *p;

 	p = (uint8_t *) state;
 	for (i = 0; i < sizeof(*state); ++i) {
 		*p++ = read_register(addrs[i]);
 	}
 }

 /* Convert 8-bit (2-digit) BCD to binary equivalent. */

 static inline uint8_t decode_bcd(uint8_t val)
 {
 	return (((val >> 4) & 0x0F) * 10) + (val & 0x0F);
 }

 /*
  * Hinnant's algorithm to calculate the number of days offset from the epoch.
  */

 static uint32_t hinnant(int y, int m, int d)
 {
 	unsigned yoe;
 	unsigned doy;
 	unsigned doe;
 	int era;

 	y -= (m <= 2);
 	era = ((y >= 0) ? y : (y - 399)) / 400;
 	yoe = y - era * 400;
 	doy = (153 * (m + ((m > 2) ? -3 : 9)) + 2)/5 + d - 1;
 	doe = yoe * 365 + yoe / 4 - yoe / 100 + doy;

 	return era * 146097 + ((int) doe) - 719468;
 }

 /*
  * Get the Unix epoch time (assuming UTC) read from the CMOS RTC.
  * This function is long, but linear and easy to follow.
  */

 int get_value(const struct device *dev, uint32_t *ticks)
 {
 	struct state state, state2;
 	uint64_t *pun = (uint64_t *) &state;
 	uint64_t *pun2 = (uint64_t *) &state2;
 	bool pm;
 	uint32_t epoch;

 	ARG_UNUSED(dev);

 	/*
 	 * Read the state until we see the same state twice in a row.
 	 */

 	read_state(&state2);
 	do {
 		state = state2;
 		read_state(&state2);
 	} while (*pun != *pun2);

 	/*
 	 * Normalize the state; 12hr -> 24hr, BCD -> decimal.
 	 * The order is a bit awkward because we need to interpret
 	 * the HOUR_PM flag before we adjust for BCD.
 	 */

 	if ((state.status_b & STATUS_B_24HR) != 0U) {
 		pm = false;
 	} else {
 		pm = ((state.hour & HOUR_PM) == HOUR_PM);
 		state.hour &= ~HOUR_PM;
 	}

 	if ((state.status_b & STATUS_B_BIN) == 0U) {
 		uint8_t *cp = (uint8_t *) &state;
 		int i;

 		for (i = 0; i < NR_BCD_VALS; ++i) {
 			*cp = decode_bcd(*cp);
 			++cp;
 		}
 	}

 	if (pm) {
 		state.hour = (state.hour + 12) % 24;
 	}

 	/*
 	 * Convert date/time to epoch time. We don't care about
 	 * timezones here, because we're just creating a mapping
 	 * that results in a monotonic clock; the absolute value
 	 * is irrelevant.
 	 */

 	epoch = hinnant(state.year + 2000, state.month, state.day);
 	epoch *= 86400; /* seconds per day */
 	epoch += state.hour * 3600; /* seconds per hour */
 	epoch += state.minute * 60; /* seconds per minute */
 	epoch += state.second;

 	*ticks = epoch;
 	return 0;
 }

 static int init(const struct device *dev)
 {
 	ARG_UNUSED(dev);

 	return 0;
 }

 static const struct counter_config_info info = {
 	.max_top_value = UINT_MAX,
 	.freq = 1
 };

 static const struct counter_driver_api api = {
 	.get_value = get_value
 };

 DEVICE_DT_INST_DEFINE(0, &init, NULL, NULL, &info,
 		      POST_KERNEL, CONFIG_COUNTER_INIT_PRIORITY, &api);
	/*
	* Copyright (c) 2019 Intel Corp.
	* SPDX-License-Identifier: Apache-2.0
	*
	* This barebones driver enables the use of the PC AT-style RTC
	* (the so-called "CMOS" clock) as a primitive, 1Hz monotonic counter.
	*
	* Reading a reliable value from the RTC is a fairly slow process, because
	* we use legacy I/O ports and do a lot of iterations with spinlocks to read
	* the RTC state. Plus we have to read the state multiple times because we're
	* crossing clock domains (no pun intended). Use accordingly.
	*/

	#define DT_DRV_COMPAT motorola_mc146818

	#include <zephyr/drivers/counter.h>
	#include <zephyr/device.h>
	#include <soc.h>

	/* The "CMOS" device is accessed via an address latch and data port. */

	#define X86_CMOS_ADDR (DT_INST_REG_ADDR_BY_IDX(0, 0))
	#define X86_CMOS_DATA (DT_INST_REG_ADDR_BY_IDX(0, 1))

	/*
	* A snapshot of the RTC state, or at least the state we're
	* interested in. This struct should not be modified without
	* serious consideration, for two reasons:
	*
	* 1. Order of the element is important, and must correlate
	* with addrs[] and NR_BCD_VALS (see below), and
	* 2. if it doesn't remain exactly 8 bytes long, the
	* type-punning to compare states will break.
	*/

	struct state {
	uint8_t second,
	minute,
	hour,
	day,
	month,
	year,
	status_a,
	status_b;
	};

	/*
	* If the clock is in BCD mode, the first NR_BCD_VALS
	* values in 'struct state' are BCD-encoded.
	*/

	#define NR_BCD_VALS 6

	/*
	* Indices into the CMOS address space that correspond to
	* the members of 'struct state'.
	*/

	const uint8_t addrs[] = { 0, 2, 4, 7, 8, 9, 10, 11 };

	/*
	* Interesting bits in 'struct state'.
	*/

	#define STATUS_B_24HR 0x02 /* 24-hour (vs 12-hour) mode */
	#define STATUS_B_BIN 0x01 /* binary (vs BCD) mode */
	#define HOUR_PM 0x80 /* high bit of hour set = PM */

	/*
	* Read a value from the CMOS. Because of the address latch,
	* we have to spinlock to make the access atomic.
	*/

	static uint8_t read_register(uint8_t addr)
	{
	static struct k_spinlock lock;
	k_spinlock_key_t k;
	uint8_t val;

	k = k_spin_lock(&lock);
	sys_out8(addr, X86_CMOS_ADDR);
	val = sys_in8(X86_CMOS_DATA);
	k_spin_unlock(&lock, k);

	return val;
	}

	/* Populate 'state' with current RTC state. */

	void read_state(struct state *state)
	{
	int i;
	uint8_t *p;

	p = (uint8_t *) state;
	for (i = 0; i < sizeof(*state); ++i) {
	*p++ = read_register(addrs[i]);
	}
	}

	/* Convert 8-bit (2-digit) BCD to binary equivalent. */

	static inline uint8_t decode_bcd(uint8_t val)
	{
	return (((val >> 4) & 0x0F) * 10) + (val & 0x0F);
	}

	/*
	* Hinnant's algorithm to calculate the number of days offset from the epoch.
	*/

	static uint32_t hinnant(int y, int m, int d)
	{
	unsigned yoe;
	unsigned doy;
	unsigned doe;
	int era;

	y -= (m <= 2);
	era = ((y >= 0) ? y : (y - 399)) / 400;
	yoe = y - era * 400;
	doy = (153 * (m + ((m > 2) ? -3 : 9)) + 2)/5 + d - 1;
	doe = yoe * 365 + yoe / 4 - yoe / 100 + doy;

	return era * 146097 + ((int) doe) - 719468;
	}

	/*
	* Get the Unix epoch time (assuming UTC) read from the CMOS RTC.
	* This function is long, but linear and easy to follow.
	*/

	int get_value(const struct device dev, uint32_t ticks)
	{
	struct state state, state2;
	uint64_t pun = (uint64_t ) &state;
	uint64_t pun2 = (uint64_t ) &state2;
	bool pm;
	uint32_t epoch;

	ARG_UNUSED(dev);

	/*
	* Read the state until we see the same state twice in a row.
	*/

	read_state(&state2);
	do {
	state = state2;
	read_state(&state2);
	} while (pun != pun2);

	/*
	* Normalize the state; 12hr -> 24hr, BCD -> decimal.
	* The order is a bit awkward because we need to interpret
	* the HOUR_PM flag before we adjust for BCD.
	*/

	if ((state.status_b & STATUS_B_24HR) != 0U) {
	pm = false;
	} else {
	pm = ((state.hour & HOUR_PM) == HOUR_PM);
	state.hour &= ~HOUR_PM;
	}

	if ((state.status_b & STATUS_B_BIN) == 0U) {
	uint8_t cp = (uint8_t ) &state;
	int i;

	for (i = 0; i < NR_BCD_VALS; ++i) {
	cp = decode_bcd(cp);
	++cp;
	}
	}

	if (pm) {
	state.hour = (state.hour + 12) % 24;
	}

	/*
	* Convert date/time to epoch time. We don't care about
	* timezones here, because we're just creating a mapping
	* that results in a monotonic clock; the absolute value
	* is irrelevant.
	*/

	epoch = hinnant(state.year + 2000, state.month, state.day);
	epoch = 86400; / seconds per day */
	epoch += state.hour * 3600; /* seconds per hour */
	epoch += state.minute * 60; /* seconds per minute */
	epoch += state.second;

	*ticks = epoch;
	return 0;
	}

	static int init(const struct device *dev)
	{
	ARG_UNUSED(dev);

	return 0;
	}

	static const struct counter_config_info info = {
	.max_top_value = UINT_MAX,
	.freq = 1
	};

	static const struct counter_driver_api api = {
	.get_value = get_value
	};

	DEVICE_DT_INST_DEFINE(0, &init, NULL, NULL, &info,
	POST_KERNEL, CONFIG_COUNTER_INIT_PRIORITY, &api);