| blob | 9339edbd90821af008ded99335d017145fcaeb13 |
1 // SPDX-License-Identifier: GPL-2.0
2 /* Copyright(c) 1999 - 2018 Intel Corporation. */
5 #include <linux/ptp_classify.h>
6 #include <linux/clocksource.h>
8 /*
9 * The 82599 and the X540 do not have true 64bit nanosecond scale
10 * counter registers. Instead, SYSTIME is defined by a fixed point
11 * system which allows the user to define the scale counter increment
12 * value at every level change of the oscillator driving the SYSTIME
13 * value. For both devices the TIMINCA:IV field defines this
14 * increment. On the X540 device, 31 bits are provided. However on the
15 * 82599 only provides 24 bits. The time unit is determined by the
16 * clock frequency of the oscillator in combination with the TIMINCA
17 * register. When these devices link at 10Gb the oscillator has a
18 * period of 6.4ns. In order to convert the scale counter into
19 * nanoseconds the cyclecounter and timecounter structures are
20 * used. The SYSTIME registers need to be converted to ns values by use
21 * of only a right shift (division by power of 2). The following math
22 * determines the largest incvalue that will fit into the available
23 * bits in the TIMINCA register.
24 *
25 * PeriodWidth: Number of bits to store the clock period
26 * MaxWidth: The maximum width value of the TIMINCA register
27 * Period: The clock period for the oscillator
28 * round(): discard the fractional portion of the calculation
29 *
30 * Period * [ 2 ^ ( MaxWidth - PeriodWidth ) ]
31 *
32 * For the X540, MaxWidth is 31 bits, and the base period is 6.4 ns
33 * For the 82599, MaxWidth is 24 bits, and the base period is 6.4 ns
34 *
35 * The period also changes based on the link speed:
36 * At 10Gb link or no link, the period remains the same.
37 * At 1Gb link, the period is multiplied by 10. (64ns)
38 * At 100Mb link, the period is multiplied by 100. (640ns)
39 *
40 * The calculated value allows us to right shift the SYSTIME register
41 * value in order to quickly convert it into a nanosecond clock,
42 * while allowing for the maximum possible adjustment value.
43 *
44 * These diagrams are only for the 10Gb link period
45 *
46 * SYSTIMEH SYSTIMEL
47 * +--------------+ +--------------+
48 * X540 | 32 | | 1 | 3 | 28 |
49 * *--------------+ +--------------+
50 * \________ 36 bits ______/ fract
51 *
52 * +--------------+ +--------------+
53 * 82599 | 32 | | 8 | 3 | 21 |
54 * *--------------+ +--------------+
55 * \________ 43 bits ______/ fract
56 *
57 * The 36 bit X540 SYSTIME overflows every
58 * 2^36 * 10^-9 / 60 = 1.14 minutes or 69 seconds
59 *
60 * The 43 bit 82599 SYSTIME overflows every
61 * 2^43 * 10^-9 / 3600 = 2.4 hours
62 */
63 #define IXGBE_INCVAL_10GB 0x66666666
64 #define IXGBE_INCVAL_1GB 0x40000000
65 #define IXGBE_INCVAL_100 0x50000000
67 #define IXGBE_INCVAL_SHIFT_10GB 28
68 #define IXGBE_INCVAL_SHIFT_1GB 24
69 #define IXGBE_INCVAL_SHIFT_100 21
71 #define IXGBE_INCVAL_SHIFT_82599 7
72 #define IXGBE_INCPER_SHIFT_82599 24
74 #define IXGBE_OVERFLOW_PERIOD (HZ * 30)
75 #define IXGBE_PTP_TX_TIMEOUT (HZ)
77 /* We use our own definitions instead of NSEC_PER_SEC because we want to mark
78 * the value as a ULL to force precision when bit shifting.
79 */
80 #define NS_PER_SEC 1000000000ULL
81 #define NS_PER_HALF_SEC 500000000ULL
83 /* In contrast, the X550 controller has two registers, SYSTIMEH and SYSTIMEL
84 * which contain measurements of seconds and nanoseconds respectively. This
85 * matches the standard linux representation of time in the kernel. In addition,
86 * the X550 also has a SYSTIMER register which represents residue, or
87 * subnanosecond overflow adjustments. To control clock adjustment, the TIMINCA
88 * register is used, but it is unlike the X540 and 82599 devices. TIMINCA
89 * represents units of 2^-32 nanoseconds, and uses 31 bits for this, with the
90 * high bit representing whether the adjustent is positive or negative. Every
91 * clock cycle, the X550 will add 12.5 ns + TIMINCA which can result in a range
92 * of 12 to 13 nanoseconds adjustment. Unlike the 82599 and X540 devices, the
93 * X550's clock for purposes of SYSTIME generation is constant and not dependent
94 * on the link speed.
95 *
96 * SYSTIMEH SYSTIMEL SYSTIMER
97 * +--------------+ +--------------+ +-------------+
98 * X550 | 32 | | 32 | | 32 |
99 * *--------------+ +--------------+ +-------------+
100 * \____seconds___/ \_nanoseconds_/ \__2^-32 ns__/
101 *
102 * This results in a full 96 bits to represent the clock, with 32 bits for
103 * seconds, 32 bits for nanoseconds (largest value is 0d999999999 or just under
104 * 1 second) and an additional 32 bits to measure sub nanosecond adjustments for
105 * underflow of adjustments.
106 *
107 * The 32 bits of seconds for the X550 overflows every
108 * 2^32 / ( 365.25 * 24 * 60 * 60 ) = ~136 years.
109 *
110 * In order to adjust the clock frequency for the X550, the TIMINCA register is
111 * provided. This register represents a + or minus nearly 0.5 ns adjustment to
112 * the base frequency. It is measured in 2^-32 ns units, with the high bit being
113 * the sign bit. This register enables software to calculate frequency
114 * adjustments and apply them directly to the clock rate.
115 *
116 * The math for converting scaled_ppm into TIMINCA values is fairly
117 * straightforward.
118 *
119 * TIMINCA value = ( Base_Frequency * scaled_ppm ) / 1000000ULL << 16
120 *
121 * To avoid overflow, we simply use mul_u64_u64_div_u64.
122 *
123 * This assumes that scaled_ppm is never high enough to create a value bigger
124 * than TIMINCA's 31 bits can store. This is ensured by the stack, and is
125 * measured in parts per billion. Calculating this value is also simple.
126 * Max ppb = ( Max Adjustment / Base Frequency ) / 1000000000ULL
127 *
128 * For the X550, the Max adjustment is +/- 0.5 ns, and the base frequency is
129 * 12.5 nanoseconds. This means that the Max ppb is 39999999
130 * Note: We subtract one in order to ensure no overflow, because the TIMINCA
131 * register can only hold slightly under 0.5 nanoseconds.
132 *
133 * Because TIMINCA is measured in 2^-32 ns units, we have to convert 12.5 ns
134 * into 2^-32 units, which is
135 *
136 * 12.5 * 2^32 = C80000000
137 *
138 * Some revisions of hardware have a faster base frequency than the registers
139 * were defined for. To fix this, we use a timecounter structure with the
140 * proper mult and shift to convert the cycles into nanoseconds of time.
141 */
142 #define IXGBE_X550_BASE_PERIOD 0xC80000000ULL
143 #define INCVALUE_MASK 0x7FFFFFFF
144 #define ISGN 0x80000000
146 /**
147 * ixgbe_ptp_setup_sdp_X540
148 * @adapter: private adapter structure
149 *
150 * this function enables or disables the clock out feature on SDP0 for
151 * the X540 device. It will create a 1 second periodic output that can
152 * be used as the PPS (via an interrupt).
153 *
154 * It calculates when the system time will be on an exact second, and then
155 * aligns the start of the PPS signal to that value.
156 *
157 * This works by using the cycle counter shift and mult values in reverse, and
158 * assumes that the values we're shifting will not overflow.
159 */
161 {
168 /* disable the pin first */
177 /* enable the SDP0 pin as output, and connected to the
178 * native function for Timesync (ClockOut)
179 */
181 IXGBE_ESDP_SDP0_NATIVE;
183 /* enable the Clock Out feature on SDP0, and allow
184 * interrupts to occur when the pin changes
185 */
187 IXGBE_TSAUXC_SYNCLK |
188 IXGBE_TSAUXC_SDP0_INT);
190 /* Determine the clock time period to use. This assumes that the
191 * cycle counter shift is small enough to avoid overflow.
192 */
197 /* Read the current clock time, and save the cycle counter value */
203 /* Figure out how many seconds to add in order to round up */
206 /* Figure out how many nanoseconds to add to round the clock edge up
207 * to the next full second
208 */
211 /* Adjust the clock edge to align with the next full second. */
225 }
227 /**
228 * ixgbe_ptp_setup_sdp_X550
229 * @adapter: private adapter structure
230 *
231 * Enable or disable a clock output signal on SDP 0 for X550 hardware.
232 *
233 * Use the target time feature to align the output signal on the next full
234 * second.
235 *
236 * This works by using the cycle counter shift and mult values in reverse, and
237 * assumes that the values we're shifting will not overflow.
238 */
240 {
248 /* disable the pin first */
257 /* enable the SDP0 pin as output, and connected to the
258 * native function for Timesync (ClockOut)
259 */
261 IXGBE_ESDP_SDP0_NATIVE;
263 /* enable the Clock Out feature on SDP0, and use Target Time 0 to
264 * enable generation of interrupts on the clock change.
265 */
266 #define IXGBE_TSAUXC_DIS_TS_CLEAR 0x40000000
269 IXGBE_TSAUXC_DIS_TS_CLEAR);
272 IXGBE_TSSDP_TS_SDP0_CLK0);
274 /* Determine the clock time period to use. This assumes that the
275 * cycle counter shift is small enough to avoid overflowing a 32bit
276 * value.
277 */
280 /* Read the current clock time, and save the cycle counter value */
286 /* Figure out how far past the next second we are */
289 /* Figure out how many nanoseconds to add to round the clock edge up
290 * to the next full second
291 */
294 /* Adjust the clock edge to align with the next full second. */
297 /* X550 hardware stores the time in 32bits of 'billions of cycles' and
298 * 32bits of 'cycles'. There's no guarantee that cycles represents
299 * nanoseconds. However, we can use the math from a timespec64 to
300 * convert into the hardware representation.
301 *
302 * See ixgbe_ptp_read_X550() for more details.
303 */
317 }
319 /**
320 * ixgbe_ptp_read_X550 - read cycle counter value
321 * @cc: cyclecounter structure
322 *
323 * This function reads SYSTIME registers. It is called by the cyclecounter
324 * structure to convert from internal representation into nanoseconds. We need
325 * this for X550 since some skews do not have expected clock frequency and
326 * result of SYSTIME is 32bits of "billions of cycles" and 32 bits of
327 * "cycles", rather than seconds and nanoseconds.
328 */
330 {
336 /* storage is 32 bits of 'billions of cycles' and 32 bits of 'cycles'.
337 * Some revisions of hardware run at a higher frequency and so the
338 * cycles are not guaranteed to be nanoseconds. The timespec64 created
339 * here is used for its math/conversions but does not necessarily
340 * represent nominal time.
341 *
342 * It should be noted that this cyclecounter will overflow at a
343 * non-bitmask field since we have to convert our billions of cycles
344 * into an actual cycles count. This results in some possible weird
345 * situations at high cycle counter stamps. However given that 32 bits
346 * of "seconds" is ~138 years this isn't a problem. Even at the
347 * increased frequency of some revisions, this is still ~103 years.
348 * Since the SYSTIME values start at 0 and we never write them, it is
349 * highly unlikely for the cyclecounter to overflow in practice.
350 */
356 }
358 /**
359 * ixgbe_ptp_read_82599 - read raw cycle counter (to be used by time counter)
360 * @cc: the cyclecounter structure
361 *
362 * this function reads the cyclecounter registers and is called by the
363 * cyclecounter structure used to construct a ns counter from the
364 * arbitrary fixed point registers
365 */
367 {
377 }
379 /**
380 * ixgbe_ptp_convert_to_hwtstamp - convert register value to hw timestamp
381 * @adapter: private adapter structure
382 * @hwtstamp: stack timestamp structure
383 * @timestamp: unsigned 64bit system time value
384 *
385 * We need to convert the adapter's RX/TXSTMP registers into a hwtstamp value
386 * which can be used by the stack's ptp functions.
387 *
388 * The lock is used to protect consistency of the cyclecounter and the SYSTIME
389 * registers. However, it does not need to protect against the Rx or Tx
390 * timestamp registers, as there can't be a new timestamp until the old one is
391 * unlatched by reading.
392 *
393 * In addition to the timestamp in hardware, some controllers need a software
394 * overflow cyclecounter, and this function takes this into account as well.
395 **/
398 u64 timestamp)
399 {
402 u64 ns;
407 /* X550 and later hardware supposedly represent time using a seconds
408 * and nanoseconds counter, instead of raw 64bits nanoseconds. We need
409 * to convert the timestamp into cycles before it can be fed to the
410 * cyclecounter. We need an actual cyclecounter because some revisions
411 * of hardware run at a higher frequency and thus the counter does
412 * not represent seconds/nanoseconds. Instead it can be thought of as
413 * cycles and billions of cycles.
414 */
418 /* Upper 32 bits represent billions of cycles, lower 32 bits
419 * represent cycles. However, we use timespec64_to_ns for the
420 * correct math even though the units haven't been corrected
421 * yet.
422 */
430 }
437 }
439 /**
440 * ixgbe_ptp_adjfine_82599
441 * @ptp: the ptp clock structure
442 * @scaled_ppm: scaled parts per million adjustment from base
443 *
444 * Adjust the frequency of the ptp cycle counter by the
445 * indicated scaled_ppm from the base frequency.
446 *
447 * Scaled parts per million is ppm with a 16-bit binary fractional field.
448 */
450 {
454 u64 incval;
475 }
478 }
480 /**
481 * ixgbe_ptp_adjfine_X550
482 * @ptp: the ptp clock structure
483 * @scaled_ppm: scaled parts per million adjustment from base
484 *
485 * Adjust the frequency of the SYSTIME registers by the indicated scaled_ppm
486 * from base frequency.
487 *
488 * Scaled parts per million is ppm with a 16-bit binary fractional field.
489 */
491 {
496 u64 rate;
497 u32 inca;
501 /* warn if rate is too large */
512 }
514 /**
515 * ixgbe_ptp_adjtime
516 * @ptp: the ptp clock structure
517 * @delta: offset to adjust the cycle counter by
518 *
519 * adjust the timer by resetting the timecounter structure.
520 */
522 {
535 }
537 /**
538 * ixgbe_ptp_gettimex
539 * @ptp: the ptp clock structure
540 * @ts: timespec to hold the PHC timestamp
541 * @sts: structure to hold the system time before and after reading the PHC
542 *
543 * read the timecounter and return the correct value on ns,
544 * after converting it into a struct timespec.
545 */
549 {
562 /* Upper 32 bits represent billions of cycles, lower 32 bits
563 * represent cycles. However, we use timespec64_to_ns for the
564 * correct math even though the units haven't been corrected
565 * yet.
566 */
580 }
589 }
591 /**
592 * ixgbe_ptp_settime
593 * @ptp: the ptp clock structure
594 * @ts: the timespec containing the new time for the cycle counter
595 *
596 * reset the timecounter to use a new base value instead of the kernel
597 * wall timer value.
598 */
601 {
607 /* reset the timecounter */
615 }
617 /**
618 * ixgbe_ptp_feature_enable
619 * @ptp: the ptp clock structure
620 * @rq: the requested feature to change
621 * @on: whether to enable or disable the feature
622 *
623 * enable (or disable) ancillary features of the phc subsystem.
624 * our driver only supports the PPS feature on the X540
625 */
628 {
632 /**
633 * When PPS is enabled, unmask the interrupt for the ClockOut
634 * feature, so that the interrupt handler can send the PPS
635 * event when the clock SDP triggers. Clear mask when PPS is
636 * disabled
637 */
643 else
648 }
650 /**
651 * ixgbe_ptp_check_pps_event
652 * @adapter: the private adapter structure
653 *
654 * This function is called by the interrupt routine when checking for
655 * interrupts. It will check and handle a pps event.
656 */
658 {
664 /* this check is necessary in case the interrupt was enabled via some
665 * alternative means (ex. debug_fs). Better to check here than
666 * everywhere that calls this function.
667 */
677 }
678 }
680 /**
681 * ixgbe_ptp_overflow_check - watchdog task to detect SYSTIME overflow
682 * @adapter: private adapter struct
683 *
684 * this watchdog task periodically reads the timecounter
685 * in order to prevent missing when the system time registers wrap
686 * around. This needs to be run approximately twice a minute.
687 */
689 {
691 IXGBE_OVERFLOW_PERIOD);
695 /* Update the timecounter */
701 }
702 }
704 /**
705 * ixgbe_ptp_rx_hang - detect error case when Rx timestamp registers latched
706 * @adapter: private network adapter structure
707 *
708 * this watchdog task is scheduled to detect error case where hardware has
709 * dropped an Rx packet that was timestamped when the ring is full. The
710 * particular error is rare but leaves the device in a state unable to timestamp
711 * any future packets.
712 */
714 {
721 /* if we don't have a valid timestamp in the registers, just update the
722 * timeout counter and exit
723 */
727 }
729 /* determine the most recent watchdog or rx_timestamp event */
735 }
737 /* only need to read the high RXSTMP register to clear the lock */
744 }
745 }
747 /**
748 * ixgbe_ptp_clear_tx_timestamp - utility function to clear Tx timestamp state
749 * @adapter: the private adapter structure
750 *
751 * This function should be called whenever the state related to a Tx timestamp
752 * needs to be cleared. This helps ensure that all related bits are reset for
753 * the next Tx timestamp event.
754 */
756 {
763 }
765 }
767 /**
768 * ixgbe_ptp_tx_hang - detect error case where Tx timestamp never finishes
769 * @adapter: private network adapter structure
770 */
772 {
774 IXGBE_PTP_TX_TIMEOUT);
782 /* If we haven't received a timestamp within the timeout, it is
783 * reasonable to assume that it will never occur, so we can unlock the
784 * timestamp bit when this occurs.
785 */
791 }
792 }
794 /**
795 * ixgbe_ptp_tx_hwtstamp - utility function which checks for TX time stamp
796 * @adapter: the private adapter struct
797 *
798 * if the timestamp is valid, we convert it into the timecounter ns
799 * value, then store that result into the shhwtstamps structure which
800 * is passed up the network stack
801 */
803 {
813 /* Handle cleanup of the ptp_tx_skb ourselves, and unlock the state
814 * bit prior to notifying the stack via skb_tstamp_tx(). This prevents
815 * well behaved applications from attempting to timestamp again prior
816 * to the lock bit being clear.
817 */
821 /* Notify the stack and then free the skb after we've unlocked */
824 }
826 /**
827 * ixgbe_ptp_tx_hwtstamp_work
828 * @work: pointer to the work struct
829 *
830 * This work item polls TSYNCTXCTL valid bit to determine when a Tx hardware
831 * timestamp has been taken for the current skb. It is necessary, because the
832 * descriptor's "done" bit does not correlate with the timestamp event.
833 */
835 {
837 ptp_tx_work);
840 IXGBE_PTP_TX_TIMEOUT);
841 u32 tsynctxctl;
843 /* we have to have a valid skb to poll for a timestamp */
847 }
849 /* stop polling once we have a valid timestamp */
854 }
861 /* reschedule to keep checking if it's not available yet */
863 }
864 }
866 /**
867 * ixgbe_ptp_rx_pktstamp - utility function to get RX time stamp from buffer
868 * @q_vector: structure containing interrupt and ring information
869 * @skb: the packet
870 *
871 * This function will be called by the Rx routine of the timestamp for this
872 * packet is stored in the buffer. The value is stored in little endian format
873 * starting at the end of the packet data.
874 */
877 {
878 __le64 regval;
880 /* copy the bits out of the skb, and then trim the skb length */
882 IXGBE_TS_HDR_LEN);
885 /* The timestamp is recorded in little endian format, and is stored at
886 * the end of the packet.
887 *
888 * DWORD: N N + 1 N + 2
889 * Field: End of Packet SYSTIMH SYSTIML
890 */
893 }
895 /**
896 * ixgbe_ptp_rx_rgtstamp - utility function which checks for RX time stamp
897 * @q_vector: structure containing interrupt and ring information
898 * @skb: particular skb to send timestamp with
899 *
900 * if the timestamp is valid, we convert it into the timecounter ns
901 * value, then store that result into the shhwtstamps structure which
902 * is passed up the network stack
903 */
906 {
910 u32 tsyncrxctl;
912 /* we cannot process timestamps on a ring without a q_vector */
919 /* Read the tsyncrxctl register afterwards in order to prevent taking an
920 * I/O hit on every packet.
921 */
931 }
933 /**
934 * ixgbe_ptp_get_ts_config - get current hardware timestamping configuration
935 * @adapter: pointer to adapter structure
936 * @ifr: ioctl data
937 *
938 * This function returns the current timestamping settings. Rather than
939 * attempt to deconstruct registers to fill in the values, simply keep a copy
940 * of the old settings around, and return a copy when requested.
941 */
943 {
948 }
950 /**
951 * ixgbe_ptp_set_timestamp_mode - setup the hardware for the requested mode
952 * @adapter: the private ixgbe adapter structure
953 * @config: the hwtstamp configuration requested
954 *
955 * Outgoing time stamping can be enabled and disabled. Play nice and
956 * disable it when requested, although it shouldn't cause any overhead
957 * when no packet needs it. At most one packet in the queue may be
958 * marked for time stamping, otherwise it would be impossible to tell
959 * for sure to which packet the hardware time stamp belongs.
960 *
961 * Incoming time stamping has to be configured via the hardware
962 * filters. Not all combinations are supported, in particular event
963 * type has to be specified. Matching the kind of event packet is
964 * not supported, with the exception of "all V2 events regardless of
965 * level 2 or 4".
966 *
967 * Since hardware always timestamps Path delay packets when timestamping V2
968 * packets, regardless of the type specified in the register, only use V2
969 * Event mode. This more accurately tells the user what the hardware is going
970 * to do anyways.
971 *
972 * Note: this may modify the hwtstamp configuration towards a more general
973 * mode, if required to support the specifically requested mode.
974 */
977 {
984 u32 regval;
994 }
1001 IXGBE_FLAG_RX_HWTSTAMP_IN_REGISTER);
1007 IXGBE_FLAG_RX_HWTSTAMP_IN_REGISTER);
1013 IXGBE_FLAG_RX_HWTSTAMP_IN_REGISTER);
1028 IXGBE_FLAG_RX_HWTSTAMP_IN_REGISTER);
1033 /* The X550 controller is capable of timestamping all packets,
1034 * which allows it to accept any filter.
1035 */
1041 }
1042 fallthrough;
1044 /*
1045 * register RXMTRL must be set in order to do V1 packets,
1046 * therefore it is not possible to time stamp both V1 Sync and
1047 * Delay_Req messages and hardware does not support
1048 * timestamping all packets => return error
1049 */
1052 }
1056 IXGBE_FLAG_RX_HWTSTAMP_IN_REGISTER);
1060 }
1062 /* Per-packet timestamping only works if the filter is set to all
1063 * packets. Since this is desired, always timestamp all packets as long
1064 * as any Rx filter was configured.
1065 */
1070 /* enable timestamping all packets only if at least some
1071 * packets were requested. Otherwise, play nice and disable
1072 * timestamping
1073 */
1078 IXGBE_TSYNCRXCTL_TYPE_ALL |
1079 IXGBE_TSYNCRXCTL_TSIP_UT_EN;
1087 }
1089 /* define ethertype filter for timestamping L2 packets */
1095 else
1098 /* enable/disable TX */
1104 /* enable/disable RX */
1110 /* define which PTP packets are time stamped */
1115 /* configure adapter flags only when HW is actually configured */
1118 /* clear TX/RX time stamp registers, just to be sure */
1123 }
1125 /**
1126 * ixgbe_ptp_set_ts_config - user entry point for timestamp mode
1127 * @adapter: pointer to adapter struct
1128 * @ifr: ioctl data
1129 *
1130 * Set hardware to requested mode. If unsupported, return an error with no
1131 * changes. Otherwise, store the mode for future reference.
1132 */
1134 {
1145 /* save these settings for future reference */
1151 }
1155 {
1156 /**
1157 * Scale the NIC cycle counter by a large factor so that
1158 * relatively small corrections to the frequency can be added
1159 * or subtracted. The drawbacks of a large factor include
1160 * (a) the clock register overflows more quickly, (b) the cycle
1161 * counter structure must be able to convert the systime value
1162 * to nanoseconds using only a multiplier and a right-shift,
1163 * and (c) the value must fit within the timinca register space
1164 * => math based on internal DMA clock rate and available bits
1165 *
1166 * Note that when there is no link, internal DMA clock is same as when
1167 * link speed is 10Gb. Set the registers correctly even when link is
1168 * down to preserve the clock setting
1169 */
1184 }
1185 }
1187 /**
1188 * ixgbe_ptp_start_cyclecounter - create the cycle counter from hw
1189 * @adapter: pointer to the adapter structure
1190 *
1191 * This function should be called to set the proper values for the TIMINCA
1192 * register and tell the cyclecounter structure what the tick rate of SYSTIME
1193 * is. It does not directly modify SYSTIME registers or the timecounter
1194 * structure. It should be called whenever a new TIMINCA value is necessary,
1195 * such as during initialization or when the link speed changes.
1196 */
1198 {
1205 /* For some of the boards below this mask is technically incorrect.
1206 * The timestamp mask overflows at approximately 61bits. However the
1207 * particular hardware does not overflow on an even bitmask value.
1208 * Instead, it overflows due to conversion of upper 32bits billions of
1209 * cycles. Timecounters are not really intended for this purpose so
1210 * they do not properly function if the overflow point isn't 2^N-1.
1211 * However, the actual SYSTIME values in question take ~138 years to
1212 * overflow. In practice this means they won't actually overflow. A
1213 * proper fix to this problem would require modification of the
1214 * timecounter delta calculations.
1215 */
1222 /* SYSTIME assumes X550EM_x board frequency is 300Mhz, and is
1223 * designed to represent seconds and nanoseconds when this is
1224 * the case. However, some revisions of hardware have a 400Mhz
1225 * clock and we have to compensate for this frequency
1226 * variation using corrected mult and shift values.
1227 */
1232 }
1233 fallthrough;
1254 /* other devices aren't supported */
1256 }
1258 /* update the base incval used to calculate frequency adjustment */
1262 /* need lock to prevent incorrect read while modifying cyclecounter */
1266 }
1268 /**
1269 * ixgbe_ptp_init_systime - Initialize SYSTIME registers
1270 * @adapter: the ixgbe private board structure
1271 *
1272 * Initialize and start the SYSTIME registers.
1273 */
1275 {
1277 u32 tsauxc;
1285 /* Reset SYSTIME registers to 0 */
1290 /* Reset interrupt settings */
1294 /* Activate the SYSTIME counter */
1300 /* Reset SYSTIME registers to 0 */
1305 /* Other devices aren't supported */
1307 }
1310 }
1312 /**
1313 * ixgbe_ptp_reset
1314 * @adapter: the ixgbe private board structure
1315 *
1316 * When the MAC resets, all the hardware bits for timesync are reset. This
1317 * function is used to re-enable the device for PTP based on current settings.
1318 * We do lose the current clock time, so just reset the cyclecounter to the
1319 * system real clock time.
1320 *
1321 * This function will maintain hwtstamp_config settings, and resets the SDP
1322 * output if it was enabled.
1323 */
1325 {
1329 /* reset the hardware timestamping mode */
1332 /* 82598 does not support PTP */
1347 /* Now that the shift has been calculated and the systime
1348 * registers reset, (re-)enable the Clock out feature
1349 */
1352 }
1354 /**
1355 * ixgbe_ptp_create_clock
1356 * @adapter: the ixgbe private adapter structure
1357 *
1358 * This function performs setup of the user entry point function table and
1359 * initializes the PTP clock device, which is used to access the clock-like
1360 * features of the PTP core. It will be called by ixgbe_ptp_init, and may
1361 * reuse a previously initialized clock (such as during a suspend/resume
1362 * cycle).
1363 */
1365 {
1369 /* do nothing if we already have a clock device */
1428 }
1440 /* set default timestamp mode to disabled here. We do this in
1441 * create_clock instead of init, because we don't want to override the
1442 * previous settings during a resume cycle.
1443 */
1448 }
1450 /**
1451 * ixgbe_ptp_init
1452 * @adapter: the ixgbe private adapter structure
1453 *
1454 * This function performs the required steps for enabling PTP
1455 * support. If PTP support has already been loaded it simply calls the
1456 * cyclecounter init routine and exits.
1457 */
1459 {
1460 /* initialize the spin lock first since we can't control when a user
1461 * will call the entry functions once we have initialized the clock
1462 * device
1463 */
1466 /* obtain a PTP device, or re-use an existing device */
1470 /* we have a clock so we can initialize work now */
1473 /* reset the PTP related hardware bits */
1476 /* enter the IXGBE_PTP_RUNNING state */
1480 }
1482 /**
1483 * ixgbe_ptp_suspend - stop PTP work items
1484 * @adapter: pointer to adapter struct
1485 *
1486 * this function suspends PTP activity, and prevents more PTP work from being
1487 * generated, but does not destroy the PTP clock device.
1488 */
1490 {
1491 /* Leave the IXGBE_PTP_RUNNING state. */
1499 /* ensure that we cancel any pending PTP Tx work item in progress */
1502 }
1504 /**
1505 * ixgbe_ptp_stop - close the PTP device
1506 * @adapter: pointer to adapter struct
1507 *
1508 * completely destroy the PTP device, should only be called when the device is
1509 * being fully closed.
1510 */
1512 {
1513 /* first, suspend PTP activity */
1516 /* disable the PTP clock device */
1522 }
1523 }