drivers/net/dsa/sja1105/sja1105_tas.c - hafnium/third_party/linux - Git at Google

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

 #define SJA1105_TAS_CLKSRC_DISABLED	0
 #define SJA1105_TAS_CLKSRC_STANDALONE	1
 #define SJA1105_TAS_CLKSRC_AS6802	2
 #define SJA1105_TAS_CLKSRC_PTP		3
 #define SJA1105_TAS_MAX_DELTA		BIT(19)
 #define SJA1105_GATE_MASK		GENMASK_ULL(SJA1105_NUM_TC - 1, 0)

 /* This is not a preprocessor macro because the "ns" argument may or may not be
  * s64 at caller side. This ensures it is properly type-cast before div_s64.
  */
 static s64 ns_to_sja1105_delta(s64 ns)
 {
 	return div_s64(ns, 200);
 }

 /* Lo and behold: the egress scheduler from hell.
  *
  * At the hardware level, the Time-Aware Shaper holds a global linear arrray of
  * all schedule entries for all ports. These are the Gate Control List (GCL)
  * entries, let's call them "timeslots" for short. This linear array of
  * timeslots is held in BLK_IDX_SCHEDULE.
  *
  * Then there are a maximum of 8 "execution threads" inside the switch, which
  * iterate cyclically through the "schedule". Each "cycle" has an entry point
  * and an exit point, both being timeslot indices in the schedule table. The
  * hardware calls each cycle a "subschedule".
  *
  * Subschedule (cycle) i starts when
  *   ptpclkval >= ptpschtm + BLK_IDX_SCHEDULE_ENTRY_POINTS[i].delta.
  *
  * The hardware scheduler iterates BLK_IDX_SCHEDULE with a k ranging from
  *   k = BLK_IDX_SCHEDULE_ENTRY_POINTS[i].address to
  *   k = BLK_IDX_SCHEDULE_PARAMS.subscheind[i]
  *
  * For each schedule entry (timeslot) k, the engine executes the gate control
  * list entry for the duration of BLK_IDX_SCHEDULE[k].delta.
  *
  *         +---------+
  *         |         | BLK_IDX_SCHEDULE_ENTRY_POINTS_PARAMS
  *         +---------+
  *              |
  *              +-----------------+
  *                                | .actsubsch
  *  BLK_IDX_SCHEDULE_ENTRY_POINTS v
  *                 +-------+-------+
  *                 |cycle 0|cycle 1|
  *                 +-------+-------+
  *                   |  |      |  |
  *  +----------------+  |      |  +-------------------------------------+
  *  |   .subschindx     |      |             .subschindx                |
  *  |                   |      +---------------+                        |
  *  |          .address |        .address      |                        |
  *  |                   |                      |                        |
  *  |                   |                      |                        |
  *  |  BLK_IDX_SCHEDULE v                      v                        |
  *  |              +-------+-------+-------+-------+-------+------+     |
  *  |              |entry 0|entry 1|entry 2|entry 3|entry 4|entry5|     |
  *  |              +-------+-------+-------+-------+-------+------+     |
  *  |                                  ^                    ^  ^  ^     |
  *  |                                  |                    |  |  |     |
  *  |        +-------------------------+                    |  |  |     |
  *  |        |              +-------------------------------+  |  |     |
  *  |        |              |              +-------------------+  |     |
  *  |        |              |              |                      |     |
  *  | +---------------------------------------------------------------+ |
  *  | |subscheind[0]<=subscheind[1]<=subscheind[2]<=...<=subscheind[7]| |
  *  | +---------------------------------------------------------------+ |
  *  |        ^              ^                BLK_IDX_SCHEDULE_PARAMS    |
  *  |        |              |                                           |
  *  +--------+              +-------------------------------------------+
  *
  *  In the above picture there are two subschedules (cycles):
  *
  *  - cycle 0: iterates the schedule table from 0 to 2 (and back)
  *  - cycle 1: iterates the schedule table from 3 to 5 (and back)
  *
  *  All other possible execution threads must be marked as unused by making
  *  their "subschedule end index" (subscheind) equal to the last valid
  *  subschedule's end index (in this case 5).
  */
 static int sja1105_init_scheduling(struct sja1105_private *priv)
 {
 	struct sja1105_schedule_entry_points_entry *schedule_entry_points;
 	struct sja1105_schedule_entry_points_params_entry
 					*schedule_entry_points_params;
 	struct sja1105_schedule_params_entry *schedule_params;
 	struct sja1105_tas_data *tas_data = &priv->tas_data;
 	struct sja1105_schedule_entry *schedule;
 	struct sja1105_table *table;
 	int schedule_start_idx;
 	s64 entry_point_delta;
 	int schedule_end_idx;
 	int num_entries = 0;
 	int num_cycles = 0;
 	int cycle = 0;
 	int i, k = 0;
 	int port;

 	/* Discard previous Schedule Table */
 	table = &priv->static_config.tables[BLK_IDX_SCHEDULE];
 	if (table->entry_count) {
 		kfree(table->entries);
 		table->entry_count = 0;
 	}

 	/* Discard previous Schedule Entry Points Parameters Table */
 	table = &priv->static_config.tables[BLK_IDX_SCHEDULE_ENTRY_POINTS_PARAMS];
 	if (table->entry_count) {
 		kfree(table->entries);
 		table->entry_count = 0;
 	}

 	/* Discard previous Schedule Parameters Table */
 	table = &priv->static_config.tables[BLK_IDX_SCHEDULE_PARAMS];
 	if (table->entry_count) {
 		kfree(table->entries);
 		table->entry_count = 0;
 	}

 	/* Discard previous Schedule Entry Points Table */
 	table = &priv->static_config.tables[BLK_IDX_SCHEDULE_ENTRY_POINTS];
 	if (table->entry_count) {
 		kfree(table->entries);
 		table->entry_count = 0;
 	}

 	/* Figure out the dimensioning of the problem */
 	for (port = 0; port < SJA1105_NUM_PORTS; port++) {
 		if (tas_data->offload[port]) {
 			num_entries += tas_data->offload[port]->num_entries;
 			num_cycles++;
 		}
 	}

 	/* Nothing to do */
 	if (!num_cycles)
 		return 0;

 	/* Pre-allocate space in the static config tables */

 	/* Schedule Table */
 	table = &priv->static_config.tables[BLK_IDX_SCHEDULE];
 	table->entries = kcalloc(num_entries, table->ops->unpacked_entry_size,
 				 GFP_KERNEL);
 	if (!table->entries)
 		return -ENOMEM;
 	table->entry_count = num_entries;
 	schedule = table->entries;

 	/* Schedule Points Parameters Table */
 	table = &priv->static_config.tables[BLK_IDX_SCHEDULE_ENTRY_POINTS_PARAMS];
 	table->entries = kcalloc(SJA1105_MAX_SCHEDULE_ENTRY_POINTS_PARAMS_COUNT,
 				 table->ops->unpacked_entry_size, GFP_KERNEL);
 	if (!table->entries)
 		/* Previously allocated memory will be freed automatically in
 		 * sja1105_static_config_free. This is true for all early
 		 * returns below.
 		 */
 		return -ENOMEM;
 	table->entry_count = SJA1105_MAX_SCHEDULE_ENTRY_POINTS_PARAMS_COUNT;
 	schedule_entry_points_params = table->entries;

 	/* Schedule Parameters Table */
 	table = &priv->static_config.tables[BLK_IDX_SCHEDULE_PARAMS];
 	table->entries = kcalloc(SJA1105_MAX_SCHEDULE_PARAMS_COUNT,
 				 table->ops->unpacked_entry_size, GFP_KERNEL);
 	if (!table->entries)
 		return -ENOMEM;
 	table->entry_count = SJA1105_MAX_SCHEDULE_PARAMS_COUNT;
 	schedule_params = table->entries;

 	/* Schedule Entry Points Table */
 	table = &priv->static_config.tables[BLK_IDX_SCHEDULE_ENTRY_POINTS];
 	table->entries = kcalloc(num_cycles, table->ops->unpacked_entry_size,
 				 GFP_KERNEL);
 	if (!table->entries)
 		return -ENOMEM;
 	table->entry_count = num_cycles;
 	schedule_entry_points = table->entries;

 	/* Finally start populating the static config tables */
 	schedule_entry_points_params->clksrc = SJA1105_TAS_CLKSRC_STANDALONE;
 	schedule_entry_points_params->actsubsch = num_cycles - 1;

 	for (port = 0; port < SJA1105_NUM_PORTS; port++) {
 		const struct tc_taprio_qopt_offload *offload;

 		offload = tas_data->offload[port];
 		if (!offload)
 			continue;

 		schedule_start_idx = k;
 		schedule_end_idx = k + offload->num_entries - 1;
 		/* TODO this is the base time for the port's subschedule,
 		 * relative to PTPSCHTM. But as we're using the standalone
 		 * clock source and not PTP clock as time reference, there's
 		 * little point in even trying to put more logic into this,
 		 * like preserving the phases between the subschedules of
 		 * different ports. We'll get all of that when switching to the
 		 * PTP clock source.
 		 */
 		entry_point_delta = 1;

 		schedule_entry_points[cycle].subschindx = cycle;
 		schedule_entry_points[cycle].delta = entry_point_delta;
 		schedule_entry_points[cycle].address = schedule_start_idx;

 		/* The subschedule end indices need to be
 		 * monotonically increasing.
 		 */
 		for (i = cycle; i < 8; i++)
 			schedule_params->subscheind[i] = schedule_end_idx;

 		for (i = 0; i < offload->num_entries; i++, k++) {
 			s64 delta_ns = offload->entries[i].interval;

 			schedule[k].delta = ns_to_sja1105_delta(delta_ns);
 			schedule[k].destports = BIT(port);
 			schedule[k].resmedia_en = true;
 			schedule[k].resmedia = SJA1105_GATE_MASK &
 					~offload->entries[i].gate_mask;
 		}
 		cycle++;
 	}

 	return 0;
 }

 /* Be there 2 port subschedules, each executing an arbitrary number of gate
  * open/close events cyclically.
  * None of those gate events must ever occur at the exact same time, otherwise
  * the switch is known to act in exotically strange ways.
  * However the hardware doesn't bother performing these integrity checks.
  * So here we are with the task of validating whether the new @admin offload
  * has any conflict with the already established TAS configuration in
  * tas_data->offload.  We already know the other ports are in harmony with one
  * another, otherwise we wouldn't have saved them.
  * Each gate event executes periodically, with a period of @cycle_time and a
  * phase given by its cycle's @base_time plus its offset within the cycle
  * (which in turn is given by the length of the events prior to it).
  * There are two aspects to possible collisions:
  * - Collisions within one cycle's (actually the longest cycle's) time frame.
  *   For that, we need to compare the cartesian product of each possible
  *   occurrence of each event within one cycle time.
  * - Collisions in the future. Events may not collide within one cycle time,
  *   but if two port schedules don't have the same periodicity (aka the cycle
  *   times aren't multiples of one another), they surely will some time in the
  *   future (actually they will collide an infinite amount of times).
  */
 static bool
 sja1105_tas_check_conflicts(struct sja1105_private *priv, int port,
 			    const struct tc_taprio_qopt_offload *admin)
 {
 	struct sja1105_tas_data *tas_data = &priv->tas_data;
 	const struct tc_taprio_qopt_offload *offload;
 	s64 max_cycle_time, min_cycle_time;
 	s64 delta1, delta2;
 	s64 rbt1, rbt2;
 	s64 stop_time;
 	s64 t1, t2;
 	int i, j;
 	s32 rem;

 	offload = tas_data->offload[port];
 	if (!offload)
 		return false;

 	/* Check if the two cycle times are multiples of one another.
 	 * If they aren't, then they will surely collide.
 	 */
 	max_cycle_time = max(offload->cycle_time, admin->cycle_time);
 	min_cycle_time = min(offload->cycle_time, admin->cycle_time);
 	div_s64_rem(max_cycle_time, min_cycle_time, &rem);
 	if (rem)
 		return true;

 	/* Calculate the "reduced" base time of each of the two cycles
 	 * (transposed back as close to 0 as possible) by dividing to
 	 * the cycle time.
 	 */
 	div_s64_rem(offload->base_time, offload->cycle_time, &rem);
 	rbt1 = rem;

 	div_s64_rem(admin->base_time, admin->cycle_time, &rem);
 	rbt2 = rem;

 	stop_time = max_cycle_time + max(rbt1, rbt2);

 	/* delta1 is the relative base time of each GCL entry within
 	 * the established ports' TAS config.
 	 */
 	for (i = 0, delta1 = 0;
 	     i < offload->num_entries;
 	     delta1 += offload->entries[i].interval, i++) {
 		/* delta2 is the relative base time of each GCL entry
 		 * within the newly added TAS config.
 		 */
 		for (j = 0, delta2 = 0;
 		     j < admin->num_entries;
 		     delta2 += admin->entries[j].interval, j++) {
 			/* t1 follows all possible occurrences of the
 			 * established ports' GCL entry i within the
 			 * first cycle time.
 			 */
 			for (t1 = rbt1 + delta1;
 			     t1 <= stop_time;
 			     t1 += offload->cycle_time) {
 				/* t2 follows all possible occurrences
 				 * of the newly added GCL entry j
 				 * within the first cycle time.
 				 */
 				for (t2 = rbt2 + delta2;
 				     t2 <= stop_time;
 				     t2 += admin->cycle_time) {
 					if (t1 == t2) {
 						dev_warn(priv->ds->dev,
 							 "GCL entry %d collides with entry %d of port %d\n",
 							 j, i, port);
 						return true;
 					}
 				}
 			}
 		}
 	}

 	return false;
 }

 int sja1105_setup_tc_taprio(struct dsa_switch *ds, int port,
 			    struct tc_taprio_qopt_offload *admin)
 {
 	struct sja1105_private *priv = ds->priv;
 	struct sja1105_tas_data *tas_data = &priv->tas_data;
 	int other_port, rc, i;

 	/* Can't change an already configured port (must delete qdisc first).
 	 * Can't delete the qdisc from an unconfigured port.
 	 */
 	if (!!tas_data->offload[port] == admin->enable)
 		return -EINVAL;

 	if (!admin->enable) {
 		taprio_offload_free(tas_data->offload[port]);
 		tas_data->offload[port] = NULL;

 		rc = sja1105_init_scheduling(priv);
 		if (rc < 0)
 			return rc;

 		return sja1105_static_config_reload(priv);
 	}

 	/* The cycle time extension is the amount of time the last cycle from
 	 * the old OPER needs to be extended in order to phase-align with the
 	 * base time of the ADMIN when that becomes the new OPER.
 	 * But of course our switch needs to be reset to switch-over between
 	 * the ADMIN and the OPER configs - so much for a seamless transition.
 	 * So don't add insult over injury and just say we don't support cycle
 	 * time extension.
 	 */
 	if (admin->cycle_time_extension)
 		return -ENOTSUPP;

 	if (!ns_to_sja1105_delta(admin->base_time)) {
 		dev_err(ds->dev, "A base time of zero is not hardware-allowed\n");
 		return -ERANGE;
 	}

 	for (i = 0; i < admin->num_entries; i++) {
 		s64 delta_ns = admin->entries[i].interval;
 		s64 delta_cycles = ns_to_sja1105_delta(delta_ns);
 		bool too_long, too_short;

 		too_long = (delta_cycles >= SJA1105_TAS_MAX_DELTA);
 		too_short = (delta_cycles == 0);
 		if (too_long || too_short) {
 			dev_err(priv->ds->dev,
 				"Interval %llu too %s for GCL entry %d\n",
 				delta_ns, too_long ? "long" : "short", i);
 			return -ERANGE;
 		}
 	}

 	for (other_port = 0; other_port < SJA1105_NUM_PORTS; other_port++) {
 		if (other_port == port)
 			continue;

 		if (sja1105_tas_check_conflicts(priv, other_port, admin))
 			return -ERANGE;
 	}

 	tas_data->offload[port] = taprio_offload_get(admin);

 	rc = sja1105_init_scheduling(priv);
 	if (rc < 0)
 		return rc;

 	return sja1105_static_config_reload(priv);
 }

 void sja1105_tas_setup(struct dsa_switch *ds)
 {
 }

 void sja1105_tas_teardown(struct dsa_switch *ds)
 {
 	struct sja1105_private *priv = ds->priv;
 	struct tc_taprio_qopt_offload *offload;
 	int port;

 	for (port = 0; port < SJA1105_NUM_PORTS; port++) {
 		offload = priv->tas_data.offload[port];
 		if (!offload)
 			continue;

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

	#define SJA1105_TAS_CLKSRC_DISABLED 0
	#define SJA1105_TAS_CLKSRC_STANDALONE 1
	#define SJA1105_TAS_CLKSRC_AS6802 2
	#define SJA1105_TAS_CLKSRC_PTP 3
	#define SJA1105_TAS_MAX_DELTA BIT(19)
	#define SJA1105_GATE_MASK GENMASK_ULL(SJA1105_NUM_TC - 1, 0)

	/* This is not a preprocessor macro because the "ns" argument may or may not be
	* s64 at caller side. This ensures it is properly type-cast before div_s64.
	*/
	static s64 ns_to_sja1105_delta(s64 ns)
	{
	return div_s64(ns, 200);
	}

	/* Lo and behold: the egress scheduler from hell.
	*
	* At the hardware level, the Time-Aware Shaper holds a global linear arrray of
	* all schedule entries for all ports. These are the Gate Control List (GCL)
	* entries, let's call them "timeslots" for short. This linear array of
	* timeslots is held in BLK_IDX_SCHEDULE.
	*
	* Then there are a maximum of 8 "execution threads" inside the switch, which
	* iterate cyclically through the "schedule". Each "cycle" has an entry point
	* and an exit point, both being timeslot indices in the schedule table. The
	* hardware calls each cycle a "subschedule".
	*
	* Subschedule (cycle) i starts when
	* ptpclkval >= ptpschtm + BLK_IDX_SCHEDULE_ENTRY_POINTS[i].delta.
	*
	* The hardware scheduler iterates BLK_IDX_SCHEDULE with a k ranging from
	* k = BLK_IDX_SCHEDULE_ENTRY_POINTS[i].address to
	* k = BLK_IDX_SCHEDULE_PARAMS.subscheind[i]
	*
	* For each schedule entry (timeslot) k, the engine executes the gate control
	* list entry for the duration of BLK_IDX_SCHEDULE[k].delta.
	*
	* +---------+
	* \| \| BLK_IDX_SCHEDULE_ENTRY_POINTS_PARAMS
	* +---------+
	* \|
	* +-----------------+
	* \| .actsubsch
	* BLK_IDX_SCHEDULE_ENTRY_POINTS v
	* +-------+-------+
	* \|cycle 0\|cycle 1\|
	* +-------+-------+
	* \| \| \| \|
	* +----------------+ \| \| +-------------------------------------+
	* \| .subschindx \| \| .subschindx \|
	* \| \| +---------------+ \|
	* \| .address \| .address \| \|
	* \| \| \| \|
	* \| \| \| \|
	* \| BLK_IDX_SCHEDULE v v \|
	* \| +-------+-------+-------+-------+-------+------+ \|
	* \| \|entry 0\|entry 1\|entry 2\|entry 3\|entry 4\|entry5\| \|
	* \| +-------+-------+-------+-------+-------+------+ \|
	* \| ^ ^ ^ ^ \|
	* \| \| \| \| \| \|
	* \| +-------------------------+ \| \| \| \|
	* \| \| +-------------------------------+ \| \| \|
	* \| \| \| +-------------------+ \| \|
	* \| \| \| \| \| \|
	* \| +---------------------------------------------------------------+ \|
	* \| \|subscheind[0]<=subscheind[1]<=subscheind[2]<=...<=subscheind[7]\| \|
	* \| +---------------------------------------------------------------+ \|
	* \| ^ ^ BLK_IDX_SCHEDULE_PARAMS \|
	* \| \| \| \|
	* +--------+ +-------------------------------------------+
	*
	* In the above picture there are two subschedules (cycles):
	*
	* - cycle 0: iterates the schedule table from 0 to 2 (and back)
	* - cycle 1: iterates the schedule table from 3 to 5 (and back)
	*
	* All other possible execution threads must be marked as unused by making
	* their "subschedule end index" (subscheind) equal to the last valid
	* subschedule's end index (in this case 5).
	*/
	static int sja1105_init_scheduling(struct sja1105_private *priv)
	{
	struct sja1105_schedule_entry_points_entry *schedule_entry_points;
	struct sja1105_schedule_entry_points_params_entry
	*schedule_entry_points_params;
	struct sja1105_schedule_params_entry *schedule_params;
	struct sja1105_tas_data *tas_data = &priv->tas_data;
	struct sja1105_schedule_entry *schedule;
	struct sja1105_table *table;
	int schedule_start_idx;
	s64 entry_point_delta;
	int schedule_end_idx;
	int num_entries = 0;
	int num_cycles = 0;
	int cycle = 0;
	int i, k = 0;
	int port;

	/* Discard previous Schedule Table */
	table = &priv->static_config.tables[BLK_IDX_SCHEDULE];
	if (table->entry_count) {
	kfree(table->entries);
	table->entry_count = 0;
	}

	/* Discard previous Schedule Entry Points Parameters Table */
	table = &priv->static_config.tables[BLK_IDX_SCHEDULE_ENTRY_POINTS_PARAMS];
	if (table->entry_count) {
	kfree(table->entries);
	table->entry_count = 0;
	}

	/* Discard previous Schedule Parameters Table */
	table = &priv->static_config.tables[BLK_IDX_SCHEDULE_PARAMS];
	if (table->entry_count) {
	kfree(table->entries);
	table->entry_count = 0;
	}

	/* Discard previous Schedule Entry Points Table */
	table = &priv->static_config.tables[BLK_IDX_SCHEDULE_ENTRY_POINTS];
	if (table->entry_count) {
	kfree(table->entries);
	table->entry_count = 0;
	}

	/* Figure out the dimensioning of the problem */
	for (port = 0; port < SJA1105_NUM_PORTS; port++) {
	if (tas_data->offload[port]) {
	num_entries += tas_data->offload[port]->num_entries;
	num_cycles++;
	}
	}

	/* Nothing to do */
	if (!num_cycles)
	return 0;

	/* Pre-allocate space in the static config tables */

	/* Schedule Table */
	table = &priv->static_config.tables[BLK_IDX_SCHEDULE];
	table->entries = kcalloc(num_entries, table->ops->unpacked_entry_size,
	GFP_KERNEL);
	if (!table->entries)
	return -ENOMEM;
	table->entry_count = num_entries;
	schedule = table->entries;

	/* Schedule Points Parameters Table */
	table = &priv->static_config.tables[BLK_IDX_SCHEDULE_ENTRY_POINTS_PARAMS];
	table->entries = kcalloc(SJA1105_MAX_SCHEDULE_ENTRY_POINTS_PARAMS_COUNT,
	table->ops->unpacked_entry_size, GFP_KERNEL);
	if (!table->entries)
	/* Previously allocated memory will be freed automatically in
	* sja1105_static_config_free. This is true for all early
	* returns below.
	*/
	return -ENOMEM;
	table->entry_count = SJA1105_MAX_SCHEDULE_ENTRY_POINTS_PARAMS_COUNT;
	schedule_entry_points_params = table->entries;

	/* Schedule Parameters Table */
	table = &priv->static_config.tables[BLK_IDX_SCHEDULE_PARAMS];
	table->entries = kcalloc(SJA1105_MAX_SCHEDULE_PARAMS_COUNT,
	table->ops->unpacked_entry_size, GFP_KERNEL);
	if (!table->entries)
	return -ENOMEM;
	table->entry_count = SJA1105_MAX_SCHEDULE_PARAMS_COUNT;
	schedule_params = table->entries;

	/* Schedule Entry Points Table */
	table = &priv->static_config.tables[BLK_IDX_SCHEDULE_ENTRY_POINTS];
	table->entries = kcalloc(num_cycles, table->ops->unpacked_entry_size,
	GFP_KERNEL);
	if (!table->entries)
	return -ENOMEM;
	table->entry_count = num_cycles;
	schedule_entry_points = table->entries;

	/* Finally start populating the static config tables */
	schedule_entry_points_params->clksrc = SJA1105_TAS_CLKSRC_STANDALONE;
	schedule_entry_points_params->actsubsch = num_cycles - 1;

	for (port = 0; port < SJA1105_NUM_PORTS; port++) {
	const struct tc_taprio_qopt_offload *offload;

	offload = tas_data->offload[port];
	if (!offload)
	continue;

	schedule_start_idx = k;
	schedule_end_idx = k + offload->num_entries - 1;
	/* TODO this is the base time for the port's subschedule,
	* relative to PTPSCHTM. But as we're using the standalone
	* clock source and not PTP clock as time reference, there's
	* little point in even trying to put more logic into this,
	* like preserving the phases between the subschedules of
	* different ports. We'll get all of that when switching to the
	* PTP clock source.
	*/
	entry_point_delta = 1;

	schedule_entry_points[cycle].subschindx = cycle;
	schedule_entry_points[cycle].delta = entry_point_delta;
	schedule_entry_points[cycle].address = schedule_start_idx;

	/* The subschedule end indices need to be
	* monotonically increasing.
	*/
	for (i = cycle; i < 8; i++)
	schedule_params->subscheind[i] = schedule_end_idx;

	for (i = 0; i < offload->num_entries; i++, k++) {
	s64 delta_ns = offload->entries[i].interval;

	schedule[k].delta = ns_to_sja1105_delta(delta_ns);
	schedule[k].destports = BIT(port);
	schedule[k].resmedia_en = true;
	schedule[k].resmedia = SJA1105_GATE_MASK &
	~offload->entries[i].gate_mask;
	}
	cycle++;
	}

	return 0;
	}

	/* Be there 2 port subschedules, each executing an arbitrary number of gate
	* open/close events cyclically.
	* None of those gate events must ever occur at the exact same time, otherwise
	* the switch is known to act in exotically strange ways.
	* However the hardware doesn't bother performing these integrity checks.
	* So here we are with the task of validating whether the new @admin offload
	* has any conflict with the already established TAS configuration in
	* tas_data->offload. We already know the other ports are in harmony with one
	* another, otherwise we wouldn't have saved them.
	* Each gate event executes periodically, with a period of @cycle_time and a
	* phase given by its cycle's @base_time plus its offset within the cycle
	* (which in turn is given by the length of the events prior to it).
	* There are two aspects to possible collisions:
	* - Collisions within one cycle's (actually the longest cycle's) time frame.
	* For that, we need to compare the cartesian product of each possible
	* occurrence of each event within one cycle time.
	* - Collisions in the future. Events may not collide within one cycle time,
	* but if two port schedules don't have the same periodicity (aka the cycle
	* times aren't multiples of one another), they surely will some time in the
	* future (actually they will collide an infinite amount of times).
	*/
	static bool
	sja1105_tas_check_conflicts(struct sja1105_private *priv, int port,
	const struct tc_taprio_qopt_offload *admin)
	{
	struct sja1105_tas_data *tas_data = &priv->tas_data;
	const struct tc_taprio_qopt_offload *offload;
	s64 max_cycle_time, min_cycle_time;
	s64 delta1, delta2;
	s64 rbt1, rbt2;
	s64 stop_time;
	s64 t1, t2;
	int i, j;
	s32 rem;

	offload = tas_data->offload[port];
	if (!offload)
	return false;

	/* Check if the two cycle times are multiples of one another.
	* If they aren't, then they will surely collide.
	*/
	max_cycle_time = max(offload->cycle_time, admin->cycle_time);
	min_cycle_time = min(offload->cycle_time, admin->cycle_time);
	div_s64_rem(max_cycle_time, min_cycle_time, &rem);
	if (rem)
	return true;

	/* Calculate the "reduced" base time of each of the two cycles
	* (transposed back as close to 0 as possible) by dividing to
	* the cycle time.
	*/
	div_s64_rem(offload->base_time, offload->cycle_time, &rem);
	rbt1 = rem;

	div_s64_rem(admin->base_time, admin->cycle_time, &rem);
	rbt2 = rem;

	stop_time = max_cycle_time + max(rbt1, rbt2);

	/* delta1 is the relative base time of each GCL entry within
	* the established ports' TAS config.
	*/
	for (i = 0, delta1 = 0;
	i < offload->num_entries;
	delta1 += offload->entries[i].interval, i++) {
	/* delta2 is the relative base time of each GCL entry
	* within the newly added TAS config.
	*/
	for (j = 0, delta2 = 0;
	j < admin->num_entries;
	delta2 += admin->entries[j].interval, j++) {
	/* t1 follows all possible occurrences of the
	* established ports' GCL entry i within the
	* first cycle time.
	*/
	for (t1 = rbt1 + delta1;
	t1 <= stop_time;
	t1 += offload->cycle_time) {
	/* t2 follows all possible occurrences
	* of the newly added GCL entry j
	* within the first cycle time.
	*/
	for (t2 = rbt2 + delta2;
	t2 <= stop_time;
	t2 += admin->cycle_time) {
	if (t1 == t2) {
	dev_warn(priv->ds->dev,
	"GCL entry %d collides with entry %d of port %d\n",
	j, i, port);
	return true;
	}
	}
	}
	}
	}

	return false;
	}

	int sja1105_setup_tc_taprio(struct dsa_switch *ds, int port,
	struct tc_taprio_qopt_offload *admin)
	{
	struct sja1105_private *priv = ds->priv;
	struct sja1105_tas_data *tas_data = &priv->tas_data;
	int other_port, rc, i;

	/* Can't change an already configured port (must delete qdisc first).
	* Can't delete the qdisc from an unconfigured port.
	*/
	if (!!tas_data->offload[port] == admin->enable)
	return -EINVAL;

	if (!admin->enable) {
	taprio_offload_free(tas_data->offload[port]);
	tas_data->offload[port] = NULL;

	rc = sja1105_init_scheduling(priv);
	if (rc < 0)
	return rc;

	return sja1105_static_config_reload(priv);
	}

	/* The cycle time extension is the amount of time the last cycle from
	* the old OPER needs to be extended in order to phase-align with the
	* base time of the ADMIN when that becomes the new OPER.
	* But of course our switch needs to be reset to switch-over between
	* the ADMIN and the OPER configs - so much for a seamless transition.
	* So don't add insult over injury and just say we don't support cycle
	* time extension.
	*/
	if (admin->cycle_time_extension)
	return -ENOTSUPP;

	if (!ns_to_sja1105_delta(admin->base_time)) {
	dev_err(ds->dev, "A base time of zero is not hardware-allowed\n");
	return -ERANGE;
	}

	for (i = 0; i < admin->num_entries; i++) {
	s64 delta_ns = admin->entries[i].interval;
	s64 delta_cycles = ns_to_sja1105_delta(delta_ns);
	bool too_long, too_short;

	too_long = (delta_cycles >= SJA1105_TAS_MAX_DELTA);
	too_short = (delta_cycles == 0);
	if (too_long \|\| too_short) {
	dev_err(priv->ds->dev,
	"Interval %llu too %s for GCL entry %d\n",
	delta_ns, too_long ? "long" : "short", i);
	return -ERANGE;
	}
	}

	for (other_port = 0; other_port < SJA1105_NUM_PORTS; other_port++) {
	if (other_port == port)
	continue;

	if (sja1105_tas_check_conflicts(priv, other_port, admin))
	return -ERANGE;
	}

	tas_data->offload[port] = taprio_offload_get(admin);

	rc = sja1105_init_scheduling(priv);
	if (rc < 0)
	return rc;

	return sja1105_static_config_reload(priv);
	}

	void sja1105_tas_setup(struct dsa_switch *ds)
	{
	}

	void sja1105_tas_teardown(struct dsa_switch *ds)
	{
	struct sja1105_private *priv = ds->priv;
	struct tc_taprio_qopt_offload *offload;
	int port;

	for (port = 0; port < SJA1105_NUM_PORTS; port++) {
	offload = priv->tas_data.offload[port];
	if (!offload)
	continue;

	taprio_offload_free(offload);
	}
	}