drivers/net/dsa/sja1105/sja1105_ptp.c - linux/torvalds/linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0
 /* Copyright (c) 2019, Vladimir Oltean <olteanv@gmail.com>
  */
 #include "sja1105.h"

 /* The adjfine API clamps ppb between [-32,768,000, 32,768,000], and
  * therefore scaled_ppm between [-2,147,483,648, 2,147,483,647].
  * Set the maximum supported ppb to a round value smaller than the maximum.
  *
  * Percentually speaking, this is a +/- 0.032x adjustment of the
  * free-running counter (0.968x to 1.032x).
  */
 #define SJA1105_MAX_ADJ_PPB		32000000
 #define SJA1105_SIZE_PTP_CMD		4

 /* Timestamps are in units of 8 ns clock ticks (equivalent to a fixed
  * 125 MHz clock) so the scale factor (MULT / SHIFT) needs to be 8.
  * Furthermore, wisely pick SHIFT as 28 bits, which translates
  * MULT into 2^31 (0x80000000).  This is the same value around which
  * the hardware PTPCLKRATE is centered, so the same ppb conversion
  * arithmetic can be reused.
  */
 #define SJA1105_CC_SHIFT		28
 #define SJA1105_CC_MULT			(8 << SJA1105_CC_SHIFT)

 /* Having 33 bits of cycle counter left until a 64-bit overflow during delta
  * conversion, we multiply this by the 8 ns counter resolution and arrive at
  * a comfortable 68.71 second refresh interval until the delta would cause
  * an integer overflow, in absence of any other readout.
  * Approximate to 1 minute.
  */
 #define SJA1105_REFRESH_INTERVAL	(HZ * 60)

 /*            This range is actually +/- SJA1105_MAX_ADJ_PPB
  *            divided by 1000 (ppb -> ppm) and with a 16-bit
  *            "fractional" part (actually fixed point).
  *                                    |
  *                                    v
  * Convert scaled_ppm from the +/- ((10^6) << 16) range
  * into the +/- (1 << 31) range.
  *
  * This forgoes a "ppb" numeric representation (up to NSEC_PER_SEC)
  * and defines the scaling factor between scaled_ppm and the actual
  * frequency adjustments (both cycle counter and hardware).
  *
  *   ptpclkrate = scaled_ppm * 2^31 / (10^6 * 2^16)
  *   simplifies to
  *   ptpclkrate = scaled_ppm * 2^9 / 5^6
  */
 #define SJA1105_CC_MULT_NUM		(1 << 9)
 #define SJA1105_CC_MULT_DEM		15625

 #define ptp_to_sja1105(d) container_of((d), struct sja1105_private, ptp_caps)
 #define cc_to_sja1105(d) container_of((d), struct sja1105_private, tstamp_cc)
 #define dw_to_sja1105(d) container_of((d), struct sja1105_private, refresh_work)

 struct sja1105_ptp_cmd {
 	u64 resptp;       /* reset */
 };

 int sja1105_get_ts_info(struct dsa_switch *ds, int port,
 			struct ethtool_ts_info *info)
 {
 	struct sja1105_private *priv = ds->priv;

 	/* Called during cleanup */
 	if (!priv->clock)
 		return -ENODEV;

 	info->so_timestamping = SOF_TIMESTAMPING_TX_HARDWARE |
 				SOF_TIMESTAMPING_RX_HARDWARE |
 				SOF_TIMESTAMPING_RAW_HARDWARE;
 	info->tx_types = (1 << HWTSTAMP_TX_OFF) |
 			 (1 << HWTSTAMP_TX_ON);
 	info->rx_filters = (1 << HWTSTAMP_FILTER_NONE) |
 			   (1 << HWTSTAMP_FILTER_PTP_V2_L2_EVENT);
 	info->phc_index = ptp_clock_index(priv->clock);
 	return 0;
 }

 int sja1105et_ptp_cmd(const void *ctx, const void *data)
 {
 	const struct sja1105_ptp_cmd *cmd = data;
 	const struct sja1105_private *priv = ctx;
 	const struct sja1105_regs *regs = priv->info->regs;
 	const int size = SJA1105_SIZE_PTP_CMD;
 	u8 buf[SJA1105_SIZE_PTP_CMD] = {0};
 	/* No need to keep this as part of the structure */
 	u64 valid = 1;

 	sja1105_pack(buf, &valid,           31, 31, size);
 	sja1105_pack(buf, &cmd->resptp,      2,  2, size);

 	return sja1105_spi_send_packed_buf(priv, SPI_WRITE, regs->ptp_control,
 					   buf, SJA1105_SIZE_PTP_CMD);
 }

 int sja1105pqrs_ptp_cmd(const void *ctx, const void *data)
 {
 	const struct sja1105_ptp_cmd *cmd = data;
 	const struct sja1105_private *priv = ctx;
 	const struct sja1105_regs *regs = priv->info->regs;
 	const int size = SJA1105_SIZE_PTP_CMD;
 	u8 buf[SJA1105_SIZE_PTP_CMD] = {0};
 	/* No need to keep this as part of the structure */
 	u64 valid = 1;

 	sja1105_pack(buf, &valid,           31, 31, size);
 	sja1105_pack(buf, &cmd->resptp,      3,  3, size);

 	return sja1105_spi_send_packed_buf(priv, SPI_WRITE, regs->ptp_control,
 					   buf, SJA1105_SIZE_PTP_CMD);
 }

 /* The switch returns partial timestamps (24 bits for SJA1105 E/T, which wrap
  * around in 0.135 seconds, and 32 bits for P/Q/R/S, wrapping around in 34.35
  * seconds).
  *
  * This receives the RX or TX MAC timestamps, provided by hardware as
  * the lower bits of the cycle counter, sampled at the time the timestamp was
  * collected.
  *
  * To reconstruct into a full 64-bit-wide timestamp, the cycle counter is
  * read and the high-order bits are filled in.
  *
  * Must be called within one wraparound period of the partial timestamp since
  * it was generated by the MAC.
  */
 u64 sja1105_tstamp_reconstruct(struct sja1105_private *priv, u64 now,
 			       u64 ts_partial)
 {
 	u64 partial_tstamp_mask = CYCLECOUNTER_MASK(priv->info->ptp_ts_bits);
 	u64 ts_reconstructed;

 	ts_reconstructed = (now & ~partial_tstamp_mask) | ts_partial;

 	/* Check lower bits of current cycle counter against the timestamp.
 	 * If the current cycle counter is lower than the partial timestamp,
 	 * then wraparound surely occurred and must be accounted for.
 	 */
 	if ((now & partial_tstamp_mask) <= ts_partial)
 		ts_reconstructed -= (partial_tstamp_mask + 1);

 	return ts_reconstructed;
 }

 /* Reads the SPI interface for an egress timestamp generated by the switch
  * for frames sent using management routes.
  *
  * SJA1105 E/T layout of the 4-byte SPI payload:
  *
  * 31    23    15    7     0
  * |     |     |     |     |
  * +-----+-----+-----+     ^
  *          ^              |
  *          |              |
  *  24-bit timestamp   Update bit
  *
  *
  * SJA1105 P/Q/R/S layout of the 8-byte SPI payload:
  *
  * 31    23    15    7     0     63    55    47    39    32
  * |     |     |     |     |     |     |     |     |     |
  *                         ^     +-----+-----+-----+-----+
  *                         |                 ^
  *                         |                 |
  *                    Update bit    32-bit timestamp
  *
  * Notice that the update bit is in the same place.
  * To have common code for E/T and P/Q/R/S for reading the timestamp,
  * we need to juggle with the offset and the bit indices.
  */
 int sja1105_ptpegr_ts_poll(struct sja1105_private *priv, int port, u64 *ts)
 {
 	const struct sja1105_regs *regs = priv->info->regs;
 	int tstamp_bit_start, tstamp_bit_end;
 	int timeout = 10;
 	u8 packed_buf[8];
 	u64 update;
 	int rc;

 	do {
 		rc = sja1105_spi_send_packed_buf(priv, SPI_READ,
 						 regs->ptpegr_ts[port],
 						 packed_buf,
 						 priv->info->ptpegr_ts_bytes);
 		if (rc < 0)
 			return rc;

 		sja1105_unpack(packed_buf, &update, 0, 0,
 			       priv->info->ptpegr_ts_bytes);
 		if (update)
 			break;

 		usleep_range(10, 50);
 	} while (--timeout);

 	if (!timeout)
 		return -ETIMEDOUT;

 	/* Point the end bit to the second 32-bit word on P/Q/R/S,
 	 * no-op on E/T.
 	 */
 	tstamp_bit_end = (priv->info->ptpegr_ts_bytes - 4) * 8;
 	/* Shift the 24-bit timestamp on E/T to be collected from 31:8.
 	 * No-op on P/Q/R/S.
 	 */
 	tstamp_bit_end += 32 - priv->info->ptp_ts_bits;
 	tstamp_bit_start = tstamp_bit_end + priv->info->ptp_ts_bits - 1;

 	*ts = 0;

 	sja1105_unpack(packed_buf, ts, tstamp_bit_start, tstamp_bit_end,
 		       priv->info->ptpegr_ts_bytes);

 	return 0;
 }

 int sja1105_ptp_reset(struct sja1105_private *priv)
 {
 	struct dsa_switch *ds = priv->ds;
 	struct sja1105_ptp_cmd cmd = {0};
 	int rc;

 	mutex_lock(&priv->ptp_lock);

 	cmd.resptp = 1;
 	dev_dbg(ds->dev, "Resetting PTP clock\n");
 	rc = priv->info->ptp_cmd(priv, &cmd);

 	timecounter_init(&priv->tstamp_tc, &priv->tstamp_cc,
 			 ktime_to_ns(ktime_get_real()));

 	mutex_unlock(&priv->ptp_lock);

 	return rc;
 }

 static int sja1105_ptp_gettime(struct ptp_clock_info *ptp,
 			       struct timespec64 *ts)
 {
 	struct sja1105_private *priv = ptp_to_sja1105(ptp);
 	u64 ns;

 	mutex_lock(&priv->ptp_lock);
 	ns = timecounter_read(&priv->tstamp_tc);
 	mutex_unlock(&priv->ptp_lock);

 	*ts = ns_to_timespec64(ns);

 	return 0;
 }

 static int sja1105_ptp_settime(struct ptp_clock_info *ptp,
 			       const struct timespec64 *ts)
 {
 	struct sja1105_private *priv = ptp_to_sja1105(ptp);
 	u64 ns = timespec64_to_ns(ts);

 	mutex_lock(&priv->ptp_lock);
 	timecounter_init(&priv->tstamp_tc, &priv->tstamp_cc, ns);
 	mutex_unlock(&priv->ptp_lock);

 	return 0;
 }

 static int sja1105_ptp_adjfine(struct ptp_clock_info *ptp, long scaled_ppm)
 {
 	struct sja1105_private *priv = ptp_to_sja1105(ptp);
 	s64 clkrate;

 	clkrate = (s64)scaled_ppm * SJA1105_CC_MULT_NUM;
 	clkrate = div_s64(clkrate, SJA1105_CC_MULT_DEM);

 	mutex_lock(&priv->ptp_lock);

 	/* Force a readout to update the timer *before* changing its frequency.
 	 *
 	 * This way, its corrected time curve can at all times be modeled
 	 * as a linear "A * x + B" function, where:
 	 *
 	 * - B are past frequency adjustments and offset shifts, all
 	 *   accumulated into the cycle_last variable.
 	 *
 	 * - A is the new frequency adjustments we're just about to set.
 	 *
 	 * Reading now makes B accumulate the correct amount of time,
 	 * corrected at the old rate, before changing it.
 	 *
 	 * Hardware timestamps then become simple points on the curve and
 	 * are approximated using the above function.  This is still better
 	 * than letting the switch take the timestamps using the hardware
 	 * rate-corrected clock (PTPCLKVAL) - the comparison in this case would
 	 * be that we're shifting the ruler at the same time as we're taking
 	 * measurements with it.
 	 *
 	 * The disadvantage is that it's possible to receive timestamps when
 	 * a frequency adjustment took place in the near past.
 	 * In this case they will be approximated using the new ppb value
 	 * instead of a compound function made of two segments (one at the old
 	 * and the other at the new rate) - introducing some inaccuracy.
 	 */
 	timecounter_read(&priv->tstamp_tc);

 	priv->tstamp_cc.mult = SJA1105_CC_MULT + clkrate;

 	mutex_unlock(&priv->ptp_lock);

 	return 0;
 }

 static int sja1105_ptp_adjtime(struct ptp_clock_info *ptp, s64 delta)
 {
 	struct sja1105_private *priv = ptp_to_sja1105(ptp);

 	mutex_lock(&priv->ptp_lock);
 	timecounter_adjtime(&priv->tstamp_tc, delta);
 	mutex_unlock(&priv->ptp_lock);

 	return 0;
 }

 static u64 sja1105_ptptsclk_read(const struct cyclecounter *cc)
 {
 	struct sja1105_private *priv = cc_to_sja1105(cc);
 	const struct sja1105_regs *regs = priv->info->regs;
 	u64 ptptsclk = 0;
 	int rc;

 	rc = sja1105_spi_send_int(priv, SPI_READ, regs->ptptsclk,
 				  &ptptsclk, 8);
 	if (rc < 0)
 		dev_err_ratelimited(priv->ds->dev,
 				    "failed to read ptp cycle counter: %d\n",
 				    rc);
 	return ptptsclk;
 }

 static void sja1105_ptp_overflow_check(struct work_struct *work)
 {
 	struct delayed_work *dw = to_delayed_work(work);
 	struct sja1105_private *priv = dw_to_sja1105(dw);
 	struct timespec64 ts;

 	sja1105_ptp_gettime(&priv->ptp_caps, &ts);

 	schedule_delayed_work(&priv->refresh_work, SJA1105_REFRESH_INTERVAL);
 }

 static const struct ptp_clock_info sja1105_ptp_caps = {
 	.owner		= THIS_MODULE,
 	.name		= "SJA1105 PHC",
 	.adjfine	= sja1105_ptp_adjfine,
 	.adjtime	= sja1105_ptp_adjtime,
 	.gettime64	= sja1105_ptp_gettime,
 	.settime64	= sja1105_ptp_settime,
 	.max_adj	= SJA1105_MAX_ADJ_PPB,
 };

 int sja1105_ptp_clock_register(struct sja1105_private *priv)
 {
 	struct dsa_switch *ds = priv->ds;

 	/* Set up the cycle counter */
 	priv->tstamp_cc = (struct cyclecounter) {
 		.read = sja1105_ptptsclk_read,
 		.mask = CYCLECOUNTER_MASK(64),
 		.shift = SJA1105_CC_SHIFT,
 		.mult = SJA1105_CC_MULT,
 	};
 	mutex_init(&priv->ptp_lock);
 	INIT_DELAYED_WORK(&priv->refresh_work, sja1105_ptp_overflow_check);

 	schedule_delayed_work(&priv->refresh_work, SJA1105_REFRESH_INTERVAL);

 	priv->ptp_caps = sja1105_ptp_caps;

 	priv->clock = ptp_clock_register(&priv->ptp_caps, ds->dev);
 	if (IS_ERR_OR_NULL(priv->clock))
 		return PTR_ERR(priv->clock);

 	return sja1105_ptp_reset(priv);
 }

 void sja1105_ptp_clock_unregister(struct sja1105_private *priv)
 {
 	if (IS_ERR_OR_NULL(priv->clock))
 		return;

 	cancel_delayed_work_sync(&priv->refresh_work);
 	ptp_clock_unregister(priv->clock);
 	priv->clock = NULL;
 }
	// SPDX-License-Identifier: GPL-2.0
	/* Copyright (c) 2019, Vladimir Oltean <olteanv@gmail.com>
	*/
	#include "sja1105.h"

	/* The adjfine API clamps ppb between [-32,768,000, 32,768,000], and
	* therefore scaled_ppm between [-2,147,483,648, 2,147,483,647].
	* Set the maximum supported ppb to a round value smaller than the maximum.
	*
	* Percentually speaking, this is a +/- 0.032x adjustment of the
	* free-running counter (0.968x to 1.032x).
	*/
	#define SJA1105_MAX_ADJ_PPB 32000000
	#define SJA1105_SIZE_PTP_CMD 4

	/* Timestamps are in units of 8 ns clock ticks (equivalent to a fixed
	* 125 MHz clock) so the scale factor (MULT / SHIFT) needs to be 8.
	* Furthermore, wisely pick SHIFT as 28 bits, which translates
	* MULT into 2^31 (0x80000000). This is the same value around which
	* the hardware PTPCLKRATE is centered, so the same ppb conversion
	* arithmetic can be reused.
	*/
	#define SJA1105_CC_SHIFT 28
	#define SJA1105_CC_MULT (8 << SJA1105_CC_SHIFT)

	/* Having 33 bits of cycle counter left until a 64-bit overflow during delta
	* conversion, we multiply this by the 8 ns counter resolution and arrive at
	* a comfortable 68.71 second refresh interval until the delta would cause
	* an integer overflow, in absence of any other readout.
	* Approximate to 1 minute.
	*/
	#define SJA1105_REFRESH_INTERVAL (HZ * 60)

	/* This range is actually +/- SJA1105_MAX_ADJ_PPB
	* divided by 1000 (ppb -> ppm) and with a 16-bit
	* "fractional" part (actually fixed point).
	* \|
	* v
	* Convert scaled_ppm from the +/- ((10^6) << 16) range
	* into the +/- (1 << 31) range.
	*
	* This forgoes a "ppb" numeric representation (up to NSEC_PER_SEC)
	* and defines the scaling factor between scaled_ppm and the actual
	* frequency adjustments (both cycle counter and hardware).
	*
	* ptpclkrate = scaled_ppm * 2^31 / (10^6 * 2^16)
	* simplifies to
	* ptpclkrate = scaled_ppm * 2^9 / 5^6
	*/
	#define SJA1105_CC_MULT_NUM (1 << 9)
	#define SJA1105_CC_MULT_DEM 15625

	#define ptp_to_sja1105(d) container_of((d), struct sja1105_private, ptp_caps)
	#define cc_to_sja1105(d) container_of((d), struct sja1105_private, tstamp_cc)
	#define dw_to_sja1105(d) container_of((d), struct sja1105_private, refresh_work)

	struct sja1105_ptp_cmd {
	u64 resptp; /* reset */
	};

	int sja1105_get_ts_info(struct dsa_switch *ds, int port,
	struct ethtool_ts_info *info)
	{
	struct sja1105_private *priv = ds->priv;

	/* Called during cleanup */
	if (!priv->clock)
	return -ENODEV;

	info->so_timestamping = SOF_TIMESTAMPING_TX_HARDWARE \|
	SOF_TIMESTAMPING_RX_HARDWARE \|
	SOF_TIMESTAMPING_RAW_HARDWARE;
	info->tx_types = (1 << HWTSTAMP_TX_OFF) \|
	(1 << HWTSTAMP_TX_ON);
	info->rx_filters = (1 << HWTSTAMP_FILTER_NONE) \|
	(1 << HWTSTAMP_FILTER_PTP_V2_L2_EVENT);
	info->phc_index = ptp_clock_index(priv->clock);
	return 0;
	}

	int sja1105et_ptp_cmd(const void ctx, const void data)
	{
	const struct sja1105_ptp_cmd *cmd = data;
	const struct sja1105_private *priv = ctx;
	const struct sja1105_regs *regs = priv->info->regs;
	const int size = SJA1105_SIZE_PTP_CMD;
	u8 buf[SJA1105_SIZE_PTP_CMD] = {0};
	/* No need to keep this as part of the structure */
	u64 valid = 1;

	sja1105_pack(buf, &valid, 31, 31, size);
	sja1105_pack(buf, &cmd->resptp, 2, 2, size);

	return sja1105_spi_send_packed_buf(priv, SPI_WRITE, regs->ptp_control,
	buf, SJA1105_SIZE_PTP_CMD);
	}

	int sja1105pqrs_ptp_cmd(const void ctx, const void data)
	{
	const struct sja1105_ptp_cmd *cmd = data;
	const struct sja1105_private *priv = ctx;
	const struct sja1105_regs *regs = priv->info->regs;
	const int size = SJA1105_SIZE_PTP_CMD;
	u8 buf[SJA1105_SIZE_PTP_CMD] = {0};
	/* No need to keep this as part of the structure */
	u64 valid = 1;

	sja1105_pack(buf, &valid, 31, 31, size);
	sja1105_pack(buf, &cmd->resptp, 3, 3, size);

	return sja1105_spi_send_packed_buf(priv, SPI_WRITE, regs->ptp_control,
	buf, SJA1105_SIZE_PTP_CMD);
	}

	/* The switch returns partial timestamps (24 bits for SJA1105 E/T, which wrap
	* around in 0.135 seconds, and 32 bits for P/Q/R/S, wrapping around in 34.35
	* seconds).
	*
	* This receives the RX or TX MAC timestamps, provided by hardware as
	* the lower bits of the cycle counter, sampled at the time the timestamp was
	* collected.
	*
	* To reconstruct into a full 64-bit-wide timestamp, the cycle counter is
	* read and the high-order bits are filled in.
	*
	* Must be called within one wraparound period of the partial timestamp since
	* it was generated by the MAC.
	*/
	u64 sja1105_tstamp_reconstruct(struct sja1105_private *priv, u64 now,
	u64 ts_partial)
	{
	u64 partial_tstamp_mask = CYCLECOUNTER_MASK(priv->info->ptp_ts_bits);
	u64 ts_reconstructed;

	ts_reconstructed = (now & ~partial_tstamp_mask) \| ts_partial;

	/* Check lower bits of current cycle counter against the timestamp.
	* If the current cycle counter is lower than the partial timestamp,
	* then wraparound surely occurred and must be accounted for.
	*/
	if ((now & partial_tstamp_mask) <= ts_partial)
	ts_reconstructed -= (partial_tstamp_mask + 1);

	return ts_reconstructed;
	}

	/* Reads the SPI interface for an egress timestamp generated by the switch
	* for frames sent using management routes.
	*
	* SJA1105 E/T layout of the 4-byte SPI payload:
	*
	* 31 23 15 7 0
	* \| \| \| \| \|
	* +-----+-----+-----+ ^
	* ^ \|
	* \| \|
	* 24-bit timestamp Update bit
	*
	*
	* SJA1105 P/Q/R/S layout of the 8-byte SPI payload:
	*
	* 31 23 15 7 0 63 55 47 39 32
	* \| \| \| \| \| \| \| \| \| \|
	* ^ +-----+-----+-----+-----+
	* \| ^
	* \| \|
	* Update bit 32-bit timestamp
	*
	* Notice that the update bit is in the same place.
	* To have common code for E/T and P/Q/R/S for reading the timestamp,
	* we need to juggle with the offset and the bit indices.
	*/
	int sja1105_ptpegr_ts_poll(struct sja1105_private priv, int port, u64 ts)
	{
	const struct sja1105_regs *regs = priv->info->regs;
	int tstamp_bit_start, tstamp_bit_end;
	int timeout = 10;
	u8 packed_buf[8];
	u64 update;
	int rc;

	do {
	rc = sja1105_spi_send_packed_buf(priv, SPI_READ,
	regs->ptpegr_ts[port],
	packed_buf,
	priv->info->ptpegr_ts_bytes);
	if (rc < 0)
	return rc;

	sja1105_unpack(packed_buf, &update, 0, 0,
	priv->info->ptpegr_ts_bytes);
	if (update)
	break;

	usleep_range(10, 50);
	} while (--timeout);

	if (!timeout)
	return -ETIMEDOUT;

	/* Point the end bit to the second 32-bit word on P/Q/R/S,
	* no-op on E/T.
	*/
	tstamp_bit_end = (priv->info->ptpegr_ts_bytes - 4) * 8;
	/* Shift the 24-bit timestamp on E/T to be collected from 31:8.
	* No-op on P/Q/R/S.
	*/
	tstamp_bit_end += 32 - priv->info->ptp_ts_bits;
	tstamp_bit_start = tstamp_bit_end + priv->info->ptp_ts_bits - 1;

	*ts = 0;

	sja1105_unpack(packed_buf, ts, tstamp_bit_start, tstamp_bit_end,
	priv->info->ptpegr_ts_bytes);

	return 0;
	}

	int sja1105_ptp_reset(struct sja1105_private *priv)
	{
	struct dsa_switch *ds = priv->ds;
	struct sja1105_ptp_cmd cmd = {0};
	int rc;

	mutex_lock(&priv->ptp_lock);

	cmd.resptp = 1;
	dev_dbg(ds->dev, "Resetting PTP clock\n");
	rc = priv->info->ptp_cmd(priv, &cmd);

	timecounter_init(&priv->tstamp_tc, &priv->tstamp_cc,
	ktime_to_ns(ktime_get_real()));

	mutex_unlock(&priv->ptp_lock);

	return rc;
	}

	static int sja1105_ptp_gettime(struct ptp_clock_info *ptp,
	struct timespec64 *ts)
	{
	struct sja1105_private *priv = ptp_to_sja1105(ptp);
	u64 ns;

	mutex_lock(&priv->ptp_lock);
	ns = timecounter_read(&priv->tstamp_tc);
	mutex_unlock(&priv->ptp_lock);

	*ts = ns_to_timespec64(ns);

	return 0;
	}

	static int sja1105_ptp_settime(struct ptp_clock_info *ptp,
	const struct timespec64 *ts)
	{
	struct sja1105_private *priv = ptp_to_sja1105(ptp);
	u64 ns = timespec64_to_ns(ts);

	mutex_lock(&priv->ptp_lock);
	timecounter_init(&priv->tstamp_tc, &priv->tstamp_cc, ns);
	mutex_unlock(&priv->ptp_lock);

	return 0;
	}

	static int sja1105_ptp_adjfine(struct ptp_clock_info *ptp, long scaled_ppm)
	{
	struct sja1105_private *priv = ptp_to_sja1105(ptp);
	s64 clkrate;

	clkrate = (s64)scaled_ppm * SJA1105_CC_MULT_NUM;
	clkrate = div_s64(clkrate, SJA1105_CC_MULT_DEM);

	mutex_lock(&priv->ptp_lock);

	/* Force a readout to update the timer before changing its frequency.
	*
	* This way, its corrected time curve can at all times be modeled
	* as a linear "A * x + B" function, where:
	*
	* - B are past frequency adjustments and offset shifts, all
	* accumulated into the cycle_last variable.
	*
	* - A is the new frequency adjustments we're just about to set.
	*
	* Reading now makes B accumulate the correct amount of time,
	* corrected at the old rate, before changing it.
	*
	* Hardware timestamps then become simple points on the curve and
	* are approximated using the above function. This is still better
	* than letting the switch take the timestamps using the hardware
	* rate-corrected clock (PTPCLKVAL) - the comparison in this case would
	* be that we're shifting the ruler at the same time as we're taking
	* measurements with it.
	*
	* The disadvantage is that it's possible to receive timestamps when
	* a frequency adjustment took place in the near past.
	* In this case they will be approximated using the new ppb value
	* instead of a compound function made of two segments (one at the old
	* and the other at the new rate) - introducing some inaccuracy.
	*/
	timecounter_read(&priv->tstamp_tc);

	priv->tstamp_cc.mult = SJA1105_CC_MULT + clkrate;

	mutex_unlock(&priv->ptp_lock);

	return 0;
	}

	static int sja1105_ptp_adjtime(struct ptp_clock_info *ptp, s64 delta)
	{
	struct sja1105_private *priv = ptp_to_sja1105(ptp);

	mutex_lock(&priv->ptp_lock);
	timecounter_adjtime(&priv->tstamp_tc, delta);
	mutex_unlock(&priv->ptp_lock);

	return 0;
	}

	static u64 sja1105_ptptsclk_read(const struct cyclecounter *cc)
	{
	struct sja1105_private *priv = cc_to_sja1105(cc);
	const struct sja1105_regs *regs = priv->info->regs;
	u64 ptptsclk = 0;
	int rc;

	rc = sja1105_spi_send_int(priv, SPI_READ, regs->ptptsclk,
	&ptptsclk, 8);
	if (rc < 0)
	dev_err_ratelimited(priv->ds->dev,
	"failed to read ptp cycle counter: %d\n",
	rc);
	return ptptsclk;
	}

	static void sja1105_ptp_overflow_check(struct work_struct *work)
	{
	struct delayed_work *dw = to_delayed_work(work);
	struct sja1105_private *priv = dw_to_sja1105(dw);
	struct timespec64 ts;

	sja1105_ptp_gettime(&priv->ptp_caps, &ts);

	schedule_delayed_work(&priv->refresh_work, SJA1105_REFRESH_INTERVAL);
	}

	static const struct ptp_clock_info sja1105_ptp_caps = {
	.owner = THIS_MODULE,
	.name = "SJA1105 PHC",
	.adjfine = sja1105_ptp_adjfine,
	.adjtime = sja1105_ptp_adjtime,
	.gettime64 = sja1105_ptp_gettime,
	.settime64 = sja1105_ptp_settime,
	.max_adj = SJA1105_MAX_ADJ_PPB,
	};

	int sja1105_ptp_clock_register(struct sja1105_private *priv)
	{
	struct dsa_switch *ds = priv->ds;

	/* Set up the cycle counter */
	priv->tstamp_cc = (struct cyclecounter) {
	.read = sja1105_ptptsclk_read,
	.mask = CYCLECOUNTER_MASK(64),
	.shift = SJA1105_CC_SHIFT,
	.mult = SJA1105_CC_MULT,
	};
	mutex_init(&priv->ptp_lock);
	INIT_DELAYED_WORK(&priv->refresh_work, sja1105_ptp_overflow_check);

	schedule_delayed_work(&priv->refresh_work, SJA1105_REFRESH_INTERVAL);

	priv->ptp_caps = sja1105_ptp_caps;

	priv->clock = ptp_clock_register(&priv->ptp_caps, ds->dev);
	if (IS_ERR_OR_NULL(priv->clock))
	return PTR_ERR(priv->clock);

	return sja1105_ptp_reset(priv);
	}

	void sja1105_ptp_clock_unregister(struct sja1105_private *priv)
	{
	if (IS_ERR_OR_NULL(priv->clock))
	return;

	cancel_delayed_work_sync(&priv->refresh_work);
	ptp_clock_unregister(priv->clock);
	priv->clock = NULL;
	}