| blob | 97381238eb7c168f0f6887d039ae4d00f1e3a044 |
1 /*******************************************************************************
2 *
3 * Intel Ethernet Controller XL710 Family Linux Driver
4 * Copyright(c) 2013 - 2014 Intel Corporation.
5 *
6 * This program is free software; you can redistribute it and/or modify it
7 * under the terms and conditions of the GNU General Public License,
8 * version 2, as published by the Free Software Foundation.
9 *
10 * This program is distributed in the hope it will be useful, but WITHOUT
11 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
12 * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
13 * more details.
14 *
15 * You should have received a copy of the GNU General Public License along
16 * with this program. If not, see <http://www.gnu.org/licenses/>.
17 *
18 * The full GNU General Public License is included in this distribution in
19 * the file called "COPYING".
20 *
21 * Contact Information:
22 * e1000-devel Mailing List <e1000-devel@lists.sourceforge.net>
23 * Intel Corporation, 5200 N.E. Elam Young Parkway, Hillsboro, OR 97124-6497
24 *
25 ******************************************************************************/
28 #include <linux/ptp_classify.h>
30 /* The XL710 timesync is very much like Intel's 82599 design when it comes to
31 * the fundamental clock design. However, the clock operations are much simpler
32 * in the XL710 because the device supports a full 64 bits of nanoseconds.
33 * Because the field is so wide, we can forgo the cycle counter and just
34 * operate with the nanosecond field directly without fear of overflow.
35 *
36 * Much like the 82599, the update period is dependent upon the link speed:
37 * At 40Gb link or no link, the period is 1.6ns.
38 * At 10Gb link, the period is multiplied by 2. (3.2ns)
39 * At 1Gb link, the period is multiplied by 20. (32ns)
40 * 1588 functionality is not supported at 100Mbps.
41 */
42 #define I40E_PTP_40GB_INCVAL 0x0199999999ULL
43 #define I40E_PTP_10GB_INCVAL 0x0333333333ULL
44 #define I40E_PTP_1GB_INCVAL 0x2000000000ULL
46 #define I40E_PRTTSYN_CTL1_TSYNTYPE_V1 BIT(I40E_PRTTSYN_CTL1_TSYNTYPE_SHIFT)
47 #define I40E_PRTTSYN_CTL1_TSYNTYPE_V2 (2 << \
48 I40E_PRTTSYN_CTL1_TSYNTYPE_SHIFT)
50 /**
51 * i40e_ptp_read - Read the PHC time from the device
52 * @pf: Board private structure
53 * @ts: timespec structure to hold the current time value
54 *
55 * This function reads the PRTTSYN_TIME registers and stores them in a
56 * timespec. However, since the registers are 64 bits of nanoseconds, we must
57 * convert the result to a timespec before we can return.
58 **/
60 {
63 u64 ns;
65 /* The timer latches on the lowest register read. */
72 }
74 /**
75 * i40e_ptp_write - Write the PHC time to the device
76 * @pf: Board private structure
77 * @ts: timespec structure that holds the new time value
78 *
79 * This function writes the PRTTSYN_TIME registers with the user value. Since
80 * we receive a timespec from the stack, we must convert that timespec into
81 * nanoseconds before programming the registers.
82 **/
84 {
88 /* The timer will not update until the high register is written, so
89 * write the low register first.
90 */
93 }
95 /**
96 * i40e_ptp_convert_to_hwtstamp - Convert device clock to system time
97 * @hwtstamps: Timestamp structure to update
98 * @timestamp: Timestamp from the hardware
99 *
100 * We need to convert the NIC clock value into a hwtstamp which can be used by
101 * the upper level timestamping functions. Since the timestamp is simply a 64-
102 * bit nanosecond value, we can call ns_to_ktime directly to handle this.
103 **/
105 u64 timestamp)
106 {
110 }
112 /**
113 * i40e_ptp_adjfreq - Adjust the PHC frequency
114 * @ptp: The PTP clock structure
115 * @ppb: Parts per billion adjustment from the base
116 *
117 * Adjust the frequency of the PHC by the indicated parts per billion from the
118 * base frequency.
119 **/
121 {
130 }
141 else
148 }
150 /**
151 * i40e_ptp_adjtime - Adjust the PHC time
152 * @ptp: The PTP clock structure
153 * @delta: Offset in nanoseconds to adjust the PHC time by
154 *
155 * Adjust the frequency of the PHC by the indicated parts per billion from the
156 * base frequency.
157 **/
159 {
172 }
174 /**
175 * i40e_ptp_gettime - Get the time of the PHC
176 * @ptp: The PTP clock structure
177 * @ts: timespec structure to hold the current time value
178 *
179 * Read the device clock and return the correct value on ns, after converting it
180 * into a timespec struct.
181 **/
183 {
191 }
193 /**
194 * i40e_ptp_settime - Set the time of the PHC
195 * @ptp: The PTP clock structure
196 * @ts: timespec structure that holds the new time value
197 *
198 * Set the device clock to the user input value. The conversion from timespec
199 * to ns happens in the write function.
200 **/
203 {
211 }
213 /**
214 * i40e_ptp_feature_enable - Enable/disable ancillary features of the PHC subsystem
215 * @ptp: The PTP clock structure
216 * @rq: The requested feature to change
217 * @on: Enable/disable flag
218 *
219 * The XL710 does not support any of the ancillary features of the PHC
220 * subsystem, so this function may just return.
221 **/
224 {
226 }
228 /**
229 * i40e_ptp_update_latch_events - Read I40E_PRTTSYN_STAT_1 and latch events
230 * @pf: the PF data structure
231 *
232 * This function reads I40E_PRTTSYN_STAT_1 and updates the corresponding timers
233 * for noticed latch events. This allows the driver to keep track of the first
234 * time a latch event was noticed which will be used to help clear out Rx
235 * timestamps for packets that got dropped or lost.
236 *
237 * This function will return the current value of I40E_PRTTSYN_STAT_1 and is
238 * expected to be called only while under the ptp_rx_lock.
239 **/
241 {
249 /* Update the jiffies time for any newly latched timestamp. This
250 * ensures that we store the time that we first discovered a timestamp
251 * was latched by the hardware. The service task will later determine
252 * if we should free the latch and drop that timestamp should too much
253 * time pass. This flow ensures that we only update jiffies for new
254 * events latched since the last time we checked, and not all events
255 * currently latched, so that the service task accounting remains
256 * accurate.
257 */
261 }
263 /* Finally, we store the current status of the Rx timestamp latches */
267 }
269 /**
270 * i40e_ptp_rx_hang - Detect error case when Rx timestamp registers are hung
271 * @pf: The PF private data structure
272 * @vsi: The VSI with the rings relevant to 1588
273 *
274 * This watchdog task is scheduled to detect error case where hardware has
275 * dropped an Rx packet that was timestamped when the ring is full. The
276 * particular error is rare but leaves the device in a state unable to timestamp
277 * any future packets.
278 **/
280 {
284 /* Since we cannot turn off the Rx timestamp logic if the device is
285 * configured for Tx timestamping, we check if Rx timestamping is
286 * configured. We don't want to spuriously warn about Rx timestamp
287 * hangs if we don't care about the timestamps.
288 */
294 /* Update current latch times for Rx events */
297 /* Check all the currently latched Rx events and see whether they have
298 * been latched for over a second. It is assumed that any timestamp
299 * should have been cleared within this time, or else it was captured
300 * for a dropped frame that the driver never received. Thus, we will
301 * clear any timestamp that has been latched for over 1 second.
302 */
308 cleared++;
309 }
310 }
314 /* Log a warning if more than 2 timestamps got dropped in the same
315 * check. We don't want to warn about all drops because it can occur
316 * in normal scenarios such as PTP frames on multicast addresses we
317 * aren't listening to. However, administrator should know if this is
318 * the reason packets aren't receiving timestamps.
319 */
323 cleared);
325 /* Finally, update the rx_hwtstamp_cleared counter */
327 }
329 /**
330 * i40e_ptp_tx_hang - Detect error case when Tx timestamp register is hung
331 * @pf: The PF private data structure
332 *
333 * This watchdog task is run periodically to make sure that we clear the Tx
334 * timestamp logic if we don't obtain a timestamp in a reasonable amount of
335 * time. It is unexpected in the normal case but if it occurs it results in
336 * permanently prevent timestamps of future packets
337 **/
339 {
343 /* Nothing to do if we're not already waiting for a timestamp */
347 /* We already have a handler routine which is run when we are notified
348 * of a Tx timestamp in the hardware. If we don't get an interrupt
349 * within a second it is reasonable to assume that we never will.
350 */
356 }
357 }
359 /**
360 * i40e_ptp_tx_hwtstamp - Utility function which returns the Tx timestamp
361 * @pf: Board private structure
362 *
363 * Read the value of the Tx timestamp from the registers, convert it into a
364 * value consumable by the stack, and store that result into the shhwtstamps
365 * struct before returning it up the stack.
366 **/
368 {
373 u64 ns;
378 /* don't attempt to timestamp if we don't have an skb */
388 /* Clear the bit lock as soon as possible after reading the register,
389 * and prior to notifying the stack via skb_tstamp_tx(). Otherwise
390 * applications might wake up and attempt to request another transmit
391 * timestamp prior to the bit lock being cleared.
392 */
396 /* Notify the stack and free the skb after we've unlocked */
399 }
401 /**
402 * i40e_ptp_rx_hwtstamp - Utility function which checks for an Rx timestamp
403 * @pf: Board private structure
404 * @skb: Particular skb to send timestamp with
405 * @index: Index into the receive timestamp registers for the timestamp
406 *
407 * The XL710 receives a notification in the receive descriptor with an offset
408 * into the set of RXTIME registers where the timestamp is for that skb. This
409 * function goes and fetches the receive timestamp from that offset, if a valid
410 * one exists. The RXTIME registers are in ns, so we must convert the result
411 * first.
412 **/
414 {
417 u64 ns;
419 /* Since we cannot turn off the Rx timestamp logic if the device is
420 * doing Tx timestamping, check if Rx timestamping is configured.
421 */
429 /* Get current Rx events and update latch times */
432 /* TODO: Should we warn about missing Rx timestamp event? */
436 }
438 /* Clear the latched event since we're about to read its register */
449 }
451 /**
452 * i40e_ptp_set_increment - Utility function to update clock increment rate
453 * @pf: Board private structure
454 *
455 * During a link change, the DMA frequency that drives the 1588 logic will
456 * change. In order to keep the PRTTSYN_TIME registers in units of nanoseconds,
457 * we must update the increment value per clock tick.
458 **/
460 {
463 u64 incval;
477 {
483 warn_once++;
484 }
487 }
492 }
494 /* Write the new increment value into the increment register. The
495 * hardware will not update the clock until both registers have been
496 * written.
497 */
501 /* Update the base adjustement value. */
504 }
506 /**
507 * i40e_ptp_get_ts_config - ioctl interface to read the HW timestamping
508 * @pf: Board private structure
509 * @ifreq: ioctl data
510 *
511 * Obtain the current hardware timestamping settigs as requested. To do this,
512 * keep a shadow copy of the timestamp settings rather than attempting to
513 * deconstruct it from the registers.
514 **/
516 {
524 }
526 /**
527 * i40e_ptp_set_timestamp_mode - setup hardware for requested timestamp mode
528 * @pf: Board private structure
529 * @config: hwtstamp settings requested or saved
530 *
531 * Control hardware registers to enter the specific mode requested by the
532 * user. Also used during reset path to ensure that timestamp settings are
533 * maintained.
534 *
535 * Note: modifies config in place, and may update the requested mode to be
536 * more broad if the specific filter is not directly supported.
537 **/
540 {
544 /* Reserved for future extensions. */
557 }
562 /* We set the type to V1, but do not enable UDP packet
563 * recognition. In this way, we should be as close to
564 * disabling PTP Rx timestamps as possible since V1 packets
565 * are always UDP, since L2 packets are a V2 feature.
566 */
576 I40E_PRTTSYN_CTL1_TSYNTYPE_V1 |
577 I40E_PRTTSYN_CTL1_UDP_ENA_MASK;
588 /* fall through */
594 I40E_PRTTSYN_CTL1_TSYNTYPE_V2;
600 }
606 }
608 /* Clear out all 1588-related registers to clear and unlatch them. */
619 /* Enable/disable the Tx timestamp interrupt based on user input. */
623 else
630 else
634 /* Although there is no simple on/off switch for Rx, we "disable" Rx
635 * timestamps by setting to V1 only mode and clear the UDP
636 * recognition. This ought to disable all PTP Rx timestamps as V1
637 * packets are always over UDP. Note that software is configured to
638 * ignore Rx timestamps via the pf->ptp_rx flag.
639 */
641 /* clear everything but the enable bit */
643 /* now enable bits for desired Rx timestamps */
648 }
650 /**
651 * i40e_ptp_set_ts_config - ioctl interface to control the HW timestamping
652 * @pf: Board private structure
653 * @ifreq: ioctl data
654 *
655 * Respond to the user filter requests and make the appropriate hardware
656 * changes here. The XL710 cannot support splitting of the Tx/Rx timestamping
657 * logic, so keep track in software of whether to indicate these timestamps
658 * or not.
659 *
660 * It is permissible to "upgrade" the user request to a broader filter, as long
661 * as the user receives the timestamps they care about and the user is notified
662 * the filter has been broadened.
663 **/
665 {
679 /* save these settings for future reference */
684 }
686 /**
687 * i40e_ptp_create_clock - Create PTP clock device for userspace
688 * @pf: Board private structure
689 *
690 * This function creates a new PTP clock device. It only creates one if we
691 * don't already have one, so it is safe to call. Will return error if it
692 * can't create one, but success if we already have a device. Should be used
693 * by i40e_ptp_init to create clock initially, and prevent global resets from
694 * creating new clock devices.
695 **/
697 {
698 /* no need to create a clock device if we already have one */
713 /* Attempt to register the clock before enabling the hardware. */
718 /* clear the hwtstamp settings here during clock create, instead of
719 * during regular init, so that we can maintain settings across a
720 * reset or suspend.
721 */
726 }
728 /**
729 * i40e_ptp_init - Initialize the 1588 support after device probe or reset
730 * @pf: Board private structure
731 *
732 * This function sets device up for 1588 support. The first time it is run, it
733 * will create a PHC clock device. It does not create a clock device if one
734 * already exists. It also reconfigures the device after a reset.
735 **/
737 {
740 u32 pf_id;
743 /* Only one PF is assigned to control 1588 logic per port. Do not
744 * enable any support for PFs not assigned via PRTTSYN_CTL0.PF_ID
745 */
747 I40E_PRTTSYN_CTL0_PF_ID_SHIFT;
751 __func__,
754 }
759 /* ensure we have a clock device */
764 __func__);
767 u32 regval;
773 /* Ensure the clocks are running. */
781 /* Set the increment value per clock tick. */
784 /* reset timestamping mode */
787 /* Set the clock value. */
790 }
791 }
793 /**
794 * i40e_ptp_stop - Disable the driver/hardware support and unregister the PHC
795 * @pf: Board private structure
796 *
797 * This function handles the cleanup work required from the initialization by
798 * clearing out the important information and unregistering the PHC.
799 **/
801 {
810 }
817 }
818 }