| blob | 48d2d40a53bda8e060b577a15c18a587db46ef33 |
1 /*
2 * xHCI host controller driver
3 *
4 * Copyright (C) 2008 Intel Corp.
5 *
6 * Author: Sarah Sharp
7 * Some code borrowed from the Linux EHCI driver.
8 *
9 * This program is free software; you can redistribute it and/or modify
10 * it under the terms of the GNU General Public License version 2 as
11 * published by the Free Software Foundation.
12 *
13 * This program is distributed in the hope that it will be useful, but
14 * WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
15 * or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
16 * for more details.
17 *
18 * You should have received a copy of the GNU General Public License
19 * along with this program; if not, write to the Free Software Foundation,
20 * Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
21 */
23 /*
24 * Ring initialization rules:
25 * 1. Each segment is initialized to zero, except for link TRBs.
26 * 2. Ring cycle state = 0. This represents Producer Cycle State (PCS) or
27 * Consumer Cycle State (CCS), depending on ring function.
28 * 3. Enqueue pointer = dequeue pointer = address of first TRB in the segment.
29 *
30 * Ring behavior rules:
31 * 1. A ring is empty if enqueue == dequeue. This means there will always be at
32 * least one free TRB in the ring. This is useful if you want to turn that
33 * into a link TRB and expand the ring.
34 * 2. When incrementing an enqueue or dequeue pointer, if the next TRB is a
35 * link TRB, then load the pointer with the address in the link TRB. If the
36 * link TRB had its toggle bit set, you may need to update the ring cycle
37 * state (see cycle bit rules). You may have to do this multiple times
38 * until you reach a non-link TRB.
39 * 3. A ring is full if enqueue++ (for the definition of increment above)
40 * equals the dequeue pointer.
41 *
42 * Cycle bit rules:
43 * 1. When a consumer increments a dequeue pointer and encounters a toggle bit
44 * in a link TRB, it must toggle the ring cycle state.
45 * 2. When a producer increments an enqueue pointer and encounters a toggle bit
46 * in a link TRB, it must toggle the ring cycle state.
47 *
48 * Producer rules:
49 * 1. Check if ring is full before you enqueue.
50 * 2. Write the ring cycle state to the cycle bit in the TRB you're enqueuing.
51 * Update enqueue pointer between each write (which may update the ring
52 * cycle state).
53 * 3. Notify consumer. If SW is producer, it rings the doorbell for command
54 * and endpoint rings. If HC is the producer for the event ring,
55 * and it generates an interrupt according to interrupt modulation rules.
56 *
57 * Consumer rules:
58 * 1. Check if TRB belongs to you. If the cycle bit == your ring cycle state,
59 * the TRB is owned by the consumer.
60 * 2. Update dequeue pointer (which may update the ring cycle state) and
61 * continue processing TRBs until you reach a TRB which is not owned by you.
62 * 3. Notify the producer. SW is the consumer for the event ring, and it
63 * updates event ring dequeue pointer. HC is the consumer for the command and
64 * endpoint rings; it generates events on the event ring for these.
65 */
67 #include <linux/scatterlist.h>
68 #include <linux/slab.h>
72 /*
73 * Returns zero if the TRB isn't in this segment, otherwise it returns the DMA
74 * address of the TRB.
75 */
78 {
83 /* offset in TRBs */
88 }
90 /* Does this link TRB point to the first segment in a ring,
91 * or was the previous TRB the last TRB on the last segment in the ERST?
92 */
95 {
99 else
101 }
103 /* Is this TRB a link TRB or was the last TRB the last TRB in this event ring
104 * segment? I.e. would the updated event TRB pointer step off the end of the
105 * event seg?
106 */
109 {
112 else
114 }
117 {
120 }
122 /* Updates trb to point to the next TRB in the ring, and updates seg if the next
123 * TRB is in a new segment. This does not skip over link TRBs, and it does not
124 * effect the ring dequeue or enqueue pointers.
125 */
130 {
136 }
137 }
139 /*
140 * See Cycle bit rules. SW is the consumer for the event ring only.
141 * Don't make a ring full of link TRBs. That would be dumb and this would loop.
142 */
144 {
147 /*
148 * If this is not event ring, and the dequeue pointer
149 * is not on a link TRB, there is one more usable TRB
150 */
156 /*
157 * Update the dequeue pointer further if that was a link TRB or
158 * we're at the end of an event ring segment (which doesn't have
159 * link TRBS)
160 */
166 }
171 }
173 }
175 /*
176 * See Cycle bit rules. SW is the consumer for the event ring only.
177 * Don't make a ring full of link TRBs. That would be dumb and this would loop.
178 *
179 * If we've just enqueued a TRB that is in the middle of a TD (meaning the
180 * chain bit is set), then set the chain bit in all the following link TRBs.
181 * If we've enqueued the last TRB in a TD, make sure the following link TRBs
182 * have their chain bit cleared (so that each Link TRB is a separate TD).
183 *
184 * Section 6.4.4.1 of the 0.95 spec says link TRBs cannot have the chain bit
185 * set, but other sections talk about dealing with the chain bit set. This was
186 * fixed in the 0.96 specification errata, but we have to assume that all 0.95
187 * xHCI hardware can't handle the chain bit being cleared on a link TRB.
188 *
189 * @more_trbs_coming: Will you enqueue more TRBs before calling
190 * prepare_transfer()?
191 */
194 {
195 u32 chain;
199 /* If this is not event ring, there is one less usable TRB */
206 /* Update the dequeue pointer further if that was a link TRB or we're at
207 * the end of an event ring segment (which doesn't have link TRBS)
208 */
211 /*
212 * If the caller doesn't plan on enqueueing more
213 * TDs before ringing the doorbell, then we
214 * don't want to give the link TRB to the
215 * hardware just yet. We'll give the link TRB
216 * back in prepare_ring() just before we enqueue
217 * the TD at the top of the ring.
218 */
222 /* If we're not dealing with 0.95 hardware or
223 * isoc rings on AMD 0.96 host,
224 * carry over the chain bit of the previous TRB
225 * (which may mean the chain bit is cleared).
226 */
234 }
235 /* Give this link TRB to the hardware */
239 /* Toggle the cycle bit after the last ring segment. */
242 }
243 }
247 }
248 }
250 /*
251 * Check to see if there's room to enqueue num_trbs on the ring and make sure
252 * enqueue pointer will not advance into dequeue segment. See rules above.
253 */
256 {
266 }
269 }
271 /* Ring the host controller doorbell after placing a command on the ring */
273 {
279 /* Flush PCI posted writes */
281 }
284 {
285 u64 temp_64;
295 /* Section 4.6.1.2 of xHCI 1.0 spec says software should
296 * time the completion od all xHCI commands, including
297 * the Command Abort operation. If software doesn't see
298 * CRR negated in a timely manner (e.g. longer than 5
299 * seconds), then it should assume that the there are
300 * larger problems with the xHC and assert HCRST.
301 */
305 /* we are about to kill xhci, give it one more chance */
320 }
323 }
329 {
334 /* Don't ring the doorbell for this endpoint if there are pending
335 * cancellations because we don't want to interrupt processing.
336 * We don't want to restart any stream rings if there's a set dequeue
337 * pointer command pending because the device can choose to start any
338 * stream once the endpoint is on the HW schedule.
339 */
344 /* The CPU has better things to do at this point than wait for a
345 * write-posting flush. It'll get there soon enough.
346 */
347 }
349 /* Ring the doorbell for any rings with pending URBs */
353 {
359 /* A ring has pending URBs if its TD list is not empty */
364 }
367 stream_id++) {
371 stream_id);
372 }
373 }
378 {
382 /* Common case: no streams */
388 "WARN: Slot ID %u, ep index %u has streams, "
392 }
398 "WARN: Slot ID %u, ep index %u has "
399 "stream IDs 1 to %u allocated, "
403 stream_id);
405 }
407 /* Get the right ring for the given URB.
408 * If the endpoint supports streams, boundary check the URB's stream ID.
409 * If the endpoint doesn't support streams, return the singular endpoint ring.
410 */
413 {
416 }
418 /*
419 * Move the xHC's endpoint ring dequeue pointer past cur_td.
420 * Record the new state of the xHC's endpoint ring dequeue segment,
421 * dequeue pointer, and new consumer cycle state in state.
422 * Update our internal representation of the ring's dequeue pointer.
423 *
424 * We do this in three jumps:
425 * - First we update our new ring state to be the same as when the xHC stopped.
426 * - Then we traverse the ring to find the segment that contains
427 * the last TRB in the TD. We toggle the xHC's new cycle state when we pass
428 * any link TRBs with the toggle cycle bit set.
429 * - Finally we move the dequeue state one TRB further, toggling the cycle bit
430 * if we've moved it past a link TRB with the toggle cycle bit set.
431 *
432 * Some of the uses of xhci_generic_trb are grotty, but if they're done
433 * with correct __le32 accesses they should work fine. Only users of this are
434 * in here.
435 */
440 {
446 dma_addr_t addr;
447 u64 hw_dequeue;
456 stream_id);
458 }
460 /* Dig out the cycle state saved by the xHC during the stop ep cmd */
463 /* 4.6.9 the css flag is written to the stream context for streams */
472 }
478 /*
479 * We want to find the pointer, segment and cycle state of the new trb
480 * (the one after current TD's last_trb). We know the cycle state at
481 * hw_dequeue, so walk the ring until both hw_dequeue and last_trb are
482 * found.
483 */
490 }
501 /* Search wrapped around, bail out */
507 }
514 /* Don't update the ring cycle state for the producer (us). */
525 }
527 /* flip_cycle means flip the cycle bit of all but the first and last TRB.
528 * (The last TRB actually points to the ring enqueue pointer, which is not part
529 * of this TD.) This is used to remove partially enqueued isoc TDs from a ring.
530 */
533 {
541 /* Unchain any chained Link TRBs, but
542 * leave the pointers intact.
543 */
545 /* Flip the cycle bit (link TRBs can't be the first
546 * or last TRB).
547 */
554 "Address = %p (0x%llx dma); "
556 cur_trb,
558 cur_seg,
564 /* Preserve only the cycle bit of this TRB */
566 /* Flip the cycle bit except on the first or last TRB */
577 }
580 }
581 }
585 {
587 /* Can't del_timer_sync in interrupt, so we attempt to cancel. If the
588 * timer is running on another CPU, we don't decrement stop_cmds_pending
589 * (since we didn't successfully stop the watchdog timer).
590 */
593 }
595 /* Must be called with xhci->lock held in interrupt context */
598 {
608 /* Only giveback urb when this is the last td in urb */
615 }
616 }
623 }
624 }
626 /*
627 * When we get a command completion for a Stop Endpoint Command, we need to
628 * unlink any cancelled TDs from the ring. There are two ways to do that:
629 *
630 * 1. If the HW was in the middle of processing the TD that needs to be
631 * cancelled, then we must move the ring's dequeue pointer past the last TRB
632 * in the TD with a Set Dequeue Pointer Command.
633 * 2. Otherwise, we turn all the TRBs in the TD into No-op TRBs (with the chain
634 * bit cleared) so that the HW will skip over them.
635 */
638 {
652 slot_id);
654 }
665 }
667 /* Fix up the ep ring first, so HW stops executing cancelled TDs.
668 * We have the xHCI lock, so nothing can modify this list until we drop
669 * it. We're also in the event handler, so we can't get re-interrupted
670 * if another Stop Endpoint command completes
671 */
680 /* This shouldn't happen unless a driver is mucking
681 * with the stream ID after submission. This will
682 * leave the TD on the hardware ring, and the hardware
683 * will try to execute it, and may access a buffer
684 * that has already been freed. In the best case, the
685 * hardware will execute it, and the event handler will
686 * ignore the completion event for that TD, since it was
687 * removed from the td_list for that endpoint. In
688 * short, don't muck with the stream ID after
689 * submission.
690 */
696 }
697 /*
698 * If we stopped on the TD we need to cancel, then we have to
699 * move the xHC endpoint ring dequeue pointer past this TD.
700 */
705 else
707 remove_finished_td:
708 /*
709 * The event handler won't see a completion for this TD anymore,
710 * so remove it from the endpoint ring's TD list. Keep it in
711 * the cancelled TD list for URB completion later.
712 */
714 }
718 /* If necessary, queue a Set Transfer Ring Dequeue Pointer command */
724 /* Otherwise ring the doorbell(s) to restart queued transfers */
726 }
730 /*
731 * Drop the lock and complete the URBs in the cancelled TD list.
732 * New TDs to be cancelled might be added to the end of the list before
733 * we can complete all the URBs for the TDs we already unlinked.
734 * So stop when we've completed the URB for the last TD we unlinked.
735 */
741 /* Clean up the cancelled URB */
742 /* Doesn't matter what we pass for status, since the core will
743 * just overwrite it (because the URB has been unlinked).
744 */
747 /* Stop processing the cancelled list if the watchdog timer is
748 * running.
749 */
754 /* Return to the event handler with xhci->lock re-acquired */
755 }
758 {
768 }
769 }
773 {
784 stream_id++) {
790 }
799 }
805 }
806 }
808 /* Watchdog timer function for when a stop endpoint command fails to complete.
809 * In this case, we assume the host controller is broken or dying or dead. The
810 * host may still be completing some other events, so we have to be careful to
811 * let the event ring handler and the URB dequeueing/enqueueing functions know
812 * through xhci->state.
813 *
814 * The timer may also fire if the host takes a very long time to respond to the
815 * command, and the stop endpoint command completion handler cannot delete the
816 * timer before the timer function is called. Another endpoint cancellation may
817 * sneak in before the timer function can grab the lock, and that may queue
818 * another stop endpoint command and add the timer back. So we cannot use a
819 * simple flag to say whether there is a pending stop endpoint command for a
820 * particular endpoint.
821 *
822 * Instead we use a combination of that flag and a counter for the number of
823 * pending stop endpoint commands. If the timer is the tail end of the last
824 * stop endpoint command, and the endpoint's command is still pending, we assume
825 * the host is dying.
826 */
828 {
842 "Stop EP timer ran, but another timer marked "
846 }
849 "Stop EP timer ran, but no command pending, "
853 }
857 /* Oops, HC is dead or dying or at least not responding to the stop
858 * endpoint command.
859 */
861 /* Disable interrupts from the host controller and start halting it */
869 /* This is bad; the host is not responding to commands and it's
870 * not allowing itself to be halted. At least interrupts are
871 * disabled. If we call usb_hc_died(), it will attempt to
872 * disconnect all device drivers under this host. Those
873 * disconnect() methods will wait for all URBs to be unlinked,
874 * so we must complete them.
875 */
878 /* We could turn all TDs on the rings to no-ops. This won't
879 * help if the host has cached part of the ring, and is slow if
880 * we want to preserve the cycle bit. Skip it and hope the host
881 * doesn't touch the memory.
882 */
883 }
889 }
896 }
903 {
911 /* If we get two back-to-back stalls, and the first stalled transfer
912 * ends just before a link TRB, the dequeue pointer will be left on
913 * the link TRB by the code in the while loop. So we have to update
914 * the dequeue pointer one segment further, or we'll jump off
915 * the segment into la-la-land.
916 */
920 }
923 /* We have more usable TRBs */
933 }
937 }
938 }
943 }
944 }
946 /*
947 * When we get a completion for a Set Transfer Ring Dequeue Pointer command,
948 * we need to clear the set deq pending flag in the endpoint ring state, so that
949 * the TD queueing code can ring the doorbell again. We also need to ring the
950 * endpoint doorbell to restart the ring, but only if there aren't more
951 * cancellations pending.
952 */
955 {
972 stream_id);
973 /* XXX: Harmless??? */
975 }
1000 slot_id);
1004 cmd_comp_code);
1006 }
1007 /* OK what do we do now? The endpoint state is hosed, and we
1008 * should never get to this point if the synchronization between
1009 * queueing, and endpoint state are correct. This might happen
1010 * if the device gets disconnected after we've finished
1011 * cancelling URBs, which might not be an error...
1012 */
1014 u64 deq;
1015 /* 4.6.10 deq ptr is written to the stream ctx for streams */
1022 }
1027 /* Update the ring's dequeue segment and dequeue pointer
1028 * to reflect the new position.
1029 */
1036 }
1037 }
1039 cleanup:
1043 /* Restart any rings with pending URBs */
1045 }
1049 {
1053 /* This command will only fail if the endpoint wasn't halted,
1054 * but we don't care.
1055 */
1059 /* HW with the reset endpoint quirk needs to have a configure endpoint
1060 * command complete before the endpoint can be used. Queue that here
1061 * because the HW can't handle two commands being queued in a row.
1062 */
1069 }
1077 /* Clear our internal halted state */
1079 }
1080 }
1083 u32 cmd_comp_code)
1084 {
1087 else
1089 }
1092 {
1099 /* Delete default control endpoint resources */
1102 }
1106 {
1113 /*
1114 * Configure endpoint commands can come from the USB core
1115 * configuration or alt setting changes, or because the HW
1116 * needed an extra configure endpoint command after a reset
1117 * endpoint command or streams were being configured.
1118 * If the command was for a halted endpoint, the xHCI driver
1119 * is not waiting on the configure endpoint command.
1120 */
1126 }
1130 /* Input ctx add_flags are the endpoint index plus one */
1133 /* A usb_set_interface() call directly after clearing a halted
1134 * condition may race on this quirky hardware. Not worth
1135 * worrying about, since this is prototype hardware. Not sure
1136 * if this will work for streams, but streams support was
1137 * untested on this prototype.
1138 */
1146 "Completed config ep cmd - "
1149 /* Clear internal halted state and restart ring(s) */
1153 }
1155 }
1159 {
1164 }
1168 {
1172 }
1177 }
1180 {
1188 }
1189 }
1192 {
1196 }
1198 /*
1199 * Turn all commands on command ring with status set to "aborted" to no-op trbs.
1200 * If there are other commands waiting then restart the ring and kick the timer.
1201 * This must be called with command ring stopped and xhci->lock held.
1202 */
1205 {
1207 u32 cycle_state;
1209 /* Turn all aborted commands in list to no-ops, then restart */
1211 cmd_list) {
1220 /* get cycle state from the original cmd trb */
1223 /* modify the command trb to no-op command */
1230 /*
1231 * caller waiting for completion is called when command
1232 * completion event is received for these no-op commands
1233 */
1234 }
1238 /* ring command ring doorbell to restart the command ring */
1244 }
1246 }
1250 {
1254 u64 hw_ring_state;
1258 /* mark this command to be cancelled */
1263 }
1266 /* Make sure command ring is running before aborting it */
1279 }
1281 }
1282 /* command timeout on stopped ring, ring can't be aborted */
1287 }
1291 {
1293 u64 cmd_dma;
1294 dma_addr_t cmd_dequeue_dma;
1295 u32 cmd_comp_code;
1298 u32 cmd_type;
1303 cmd_trb);
1304 /* Is the command ring deq ptr out of sync with the deq seg ptr? */
1308 }
1309 /* Does the DMA address match our internal dequeue pointer address? */
1313 }
1321 }
1329 /* If CMD ring stopped we own the trbs between enqueue and dequeue */
1333 }
1334 /*
1335 * Host aborted the command ring, check if the current command was
1336 * supposed to be aborted, otherwise continue normally.
1337 * The command ring is stopped now, but the xHC will issue a Command
1338 * Ring Stopped event which will cause us to restart it.
1339 */
1344 }
1357 cmd_comp_code);
1374 /* Is this an aborted command turned to NO-OP? */
1384 /* SLOT_ID field in reset device cmd completion event TRB is 0.
1385 * Use the SLOT_ID from the command TRB instead (xhci 4.6.11)
1386 */
1395 /* Skip over unknown commands on the event ring */
1398 }
1400 /* restart timer if this wasn't the last command */
1405 }
1407 event_handled:
1411 }
1415 {
1416 u32 trb_type;
1422 }
1424 /* @port_id: the one-based port ID from the hardware (indexed from array of all
1425 * port registers -- USB 3.0 and USB 2.0).
1426 *
1427 * Returns a zero-based port number, which is suitable for indexing into each of
1428 * the split roothubs' port arrays and bus state arrays.
1429 * Add one to it in order to call xhci_find_slot_id_by_port.
1430 */
1433 {
1437 /* port_id from the hardware is 1-based, but port_array[], usb3_ports[],
1438 * and usb2_ports are 0-based indexes. Count the number of similar
1439 * speed ports, up to 1 port before this port.
1440 */
1444 /*
1445 * Skip ports that don't have known speeds, or have duplicate
1446 * Extended Capabilities port speed entries.
1447 */
1451 /*
1452 * USB 3.0 ports are always under a USB 3.0 hub. USB 2.0 and
1453 * 1.1 ports are under the USB 2.0 hub. If the port speed
1454 * matches the device speed, it's a similar speed port.
1455 */
1457 num_similar_speed_ports++;
1458 }
1460 }
1464 {
1465 u32 slot_id;
1473 }
1476 slot_id);
1480 }
1484 {
1486 u32 port_id;
1491 u8 major_revision;
1496 /* Port status change events always have a successful completion code */
1500 }
1509 }
1511 /* Figure out which usb_hcd this port is attached to:
1512 * is it a USB 3.0 port or a USB 2.0/1.1 port?
1513 */
1516 /* Find the right roothub. */
1524 port_id);
1527 }
1531 port_id);
1534 }
1536 /*
1537 * Hardware port IDs reported by a Port Status Change Event include USB
1538 * 3.0 and USB 2.0 ports. We want to check if the port has reported a
1539 * resume event, but we first need to translate the hardware port ID
1540 * into the index into the ports on the correct split roothub, and the
1541 * correct bus_state structure.
1542 */
1546 else
1548 /* Find the faked port hub number */
1550 port_id);
1556 }
1568 }
1572 /* Set a flag to say the port signaled remote wakeup,
1573 * so we can tell the difference between the end of
1574 * device and host initiated resume.
1575 */
1580 XDEV_U0);
1581 /* Need to wait until the next link state change
1582 * indicates the device is actually in U0.
1583 */
1593 /* Do the rest in GetPortStatus */
1594 }
1595 }
1600 /* We've just brought the device into U0 through either the
1601 * Resume state after a device remote wakeup, or through the
1602 * U3Exit state after a host-initiated resume. If it's a device
1603 * initiated remote wake, don't pass up the link state change,
1604 * so the roothub behavior is consistent with external
1605 * USB 3.0 hub behavior.
1606 */
1620 }
1621 }
1623 /*
1624 * Check to see if xhci-hub.c is waiting on RExit to U0 transition (or
1625 * RExit to a disconnect state). If so, let the the driver know it's
1626 * out of the RExit state.
1627 */
1634 }
1638 PORT_PLC);
1640 cleanup:
1641 /* Update event ring dequeue pointer before dropping the lock */
1644 /* Don't make the USB core poll the roothub if we got a bad port status
1645 * change event. Besides, at that point we can't tell which roothub
1646 * (USB 2.0 or USB 3.0) to kick.
1647 */
1651 /*
1652 * xHCI port-status-change events occur when the "or" of all the
1653 * status-change bits in the portsc register changes from 0 to 1.
1654 * New status changes won't cause an event if any other change
1655 * bits are still set. When an event occurs, switch over to
1656 * polling to avoid losing status changes.
1657 */
1661 /* Pass this up to the core */
1664 }
1666 /*
1667 * This TD is defined by the TRBs starting at start_trb in start_seg and ending
1668 * at end_trb, which may be in another segment. If the suspect DMA address is a
1669 * TRB in this TD, this function returns that TRB's segment. Otherwise it
1670 * returns 0.
1671 */
1676 dma_addr_t suspect_dma,
1678 {
1679 dma_addr_t start_dma;
1680 dma_addr_t end_seg_dma;
1681 dma_addr_t end_trb_dma;
1690 /* We may get an event for a Link TRB in the middle of a TD */
1693 /* If the end TRB isn't in this segment, this is set to 0 */
1698 "Looking for event-dma %016llx trb-start %016llx trb-end %016llx seg-start %016llx seg-end %016llx\n",
1706 /* The end TRB is in this segment, so suspect should be here */
1711 /* Case for one segment with
1712 * a TD wrapped around to the top
1713 */
1719 }
1722 /* Might still be somewhere in this segment */
1725 }
1731 }
1737 {
1753 }
1755 /* Check if an error has halted the endpoint ring. The class driver will
1756 * cleanup the halt for a non-default control endpoint if we indicate a stall.
1757 * However, a babble and other errors also halt the endpoint ring, and the class
1758 * driver won't clear the halt in that case, so we need to issue a Set Transfer
1759 * Ring Dequeue Pointer command manually.
1760 */
1764 {
1765 /* TRB completion codes that may require a manual halt cleanup */
1769 /* The 0.96 spec says a babbling control endpoint
1770 * is not halted. The 0.96 spec says it is. Some HW
1771 * claims to be 0.95 compliant, but it halts the control
1772 * endpoint anyway. Check if a babble halted the
1773 * endpoint.
1774 */
1780 }
1783 {
1785 /* Vendor defined "informational" completion code,
1786 * treat as not-an-error.
1787 */
1789 trb_comp_code);
1792 }
1794 }
1796 /*
1797 * Finish the td processing, remove the td from td list;
1798 * Return 1 if the urb can be given back.
1799 */
1803 {
1812 u32 trb_comp_code;
1827 /* The Endpoint Stop Command completion will take care of any
1828 * stopped TDs. A stopped TD may be restarted, so don't update
1829 * the ring dequeue pointer or take this TD off any lists yet.
1830 */
1833 }
1836 trb_comp_code)) {
1837 /* Issue a reset endpoint command to clear the host side
1838 * halt, followed by a set dequeue command to move the
1839 * dequeue pointer past the TD.
1840 * The class driver clears the device side halt later.
1841 */
1845 /* Update ring dequeue pointer */
1849 }
1851 td_cleanup:
1852 /* Clean up the endpoint's TD list */
1856 /* Do one last check of the actual transfer length.
1857 * If the host controller said we transferred more data than the buffer
1858 * length, urb->actual_length will be a very big number (since it's
1859 * unsigned). Play it safe and say we didn't transfer anything.
1860 */
1868 else
1870 }
1872 /* Was this TD slated to be cancelled but completed anyway? */
1877 /* Giveback the urb when all the tds are completed */
1885 }
1886 }
1887 }
1890 }
1892 /*
1893 * Process control tds, update urb status and actual_length.
1894 */
1898 {
1904 u32 trb_comp_code;
1925 }
1930 else
1936 else
1942 /* Did we stop at data stage? */
1947 /* fall through */
1957 /* else fall through */
1959 /* Did we transfer part of the data (middle) phase? */
1969 }
1970 /*
1971 * Did we transfer any data, despite the errors that might have
1972 * happened? I.e. did we get past the setup stage?
1973 */
1975 /* The event was for the status stage */
1978 /* Don't overwrite a previously set error code
1979 */
1983 /* Did we already see a short data
1984 * stage? */
1989 }
1991 /*
1992 * Maybe the event was for the data stage? If so, update
1993 * already the actual_length of the URB and flag it as
1994 * set, so that it is not overwritten in the event for
1995 * the last TRB.
1996 */
2004 }
2005 }
2008 }
2010 /*
2011 * Process isochronous tds, update urb packet status and actual_length.
2012 */
2016 {
2024 u32 trb_comp_code;
2033 /* handle completion code */
2039 }
2042 /* fallthrough */
2074 }
2090 }
2097 }
2098 }
2101 }
2106 {
2117 /* The transfer is partly done. */
2120 /* calc actual length */
2123 /* Update ring dequeue pointer */
2129 }
2131 /*
2132 * Process bulk and interrupt tds, update urb status and actual_length.
2133 */
2137 {
2141 u32 trb_comp_code;
2148 /* Double check that the HW transferred everything. */
2155 else
2161 }
2167 else
2171 /* Others already handled above */
2173 }
2180 /* Stopped - short packet completion */
2190 /* status will be set by usb core for canceled urbs */
2191 }
2192 /* Fast path - was this the last TRB in the TD for this URB? */
2206 else
2208 }
2209 /* Don't overwrite a previously set error code */
2213 else
2215 }
2219 /* Ignore a short packet completion if the
2220 * untransferred length was zero.
2221 */
2224 }
2226 /* Slow path - walk the list, starting from the dequeue
2227 * pointer, to get the actual length transferred.
2228 */
2237 }
2238 /* If the ring didn't stop on a Link or No-op TRB, add
2239 * in the actual bytes transferred from the Normal TRB
2240 */
2245 }
2248 }
2250 /*
2251 * If this function returns an error condition, it means it got a Transfer
2252 * event with a corrupted Slot ID, Endpoint ID, or TRB DMA address.
2253 * At this point, the host controller is probably hosed and should be reset.
2254 */
2259 {
2266 dma_addr_t event_dma;
2274 u32 trb_comp_code;
2293 }
2295 /* Endpoint ID is 1 based, our index is zero based */
2302 EP_STATE_DISABLED) {
2316 }
2318 /* Count current td numbers if ep->skip is set */
2321 td_num++;
2322 }
2326 /* Look for common error cases */
2328 /* Skip codes that require special handling depending on
2329 * transfer type
2330 */
2336 else
2379 /*
2380 * When the Isoch ring is empty, the xHC will generate
2381 * a Ring Overrun Event for IN Isoch endpoint or Ring
2382 * Underrun Event for OUT Isoch endpoint.
2383 */
2389 ep_index);
2397 ep_index);
2404 /*
2405 * When encounter missed service error, one or more isoc tds
2406 * may be missed by xHC.
2407 * Set skip flag of the ep_ring; Complete the missed tds as
2408 * short transfer when process the ep_ring next time.
2409 */
2417 }
2419 trb_comp_code);
2421 }
2424 /* This TRB should be in the TD at the head of this ring's
2425 * TD list.
2426 */
2428 /*
2429 * A stopped endpoint may generate an extra completion
2430 * event if the device was suspended. Don't print
2431 * warnings.
2432 */
2437 ep_index);
2442 }
2447 }
2450 }
2452 /* We've skipped all the TDs on the ep ring when ep->skip set */
2459 }
2463 td_num--;
2465 /* Is this a TRB in the currently executing TD? */
2469 /*
2470 * Skip the Force Stopped Event. The event_trb(event_dma) of FSE
2471 * is not in the current TD pointed by ep_ring->dequeue because
2472 * that the hardware dequeue pointer still at the previous TRB
2473 * of the current TD. The previous TRB maybe a Link TD or the
2474 * last TRB of the previous TD. The command completion handle
2475 * will take care the rest.
2476 */
2481 }
2486 /* Some host controllers give a spurious
2487 * successful event after a short transfer.
2488 * Ignore it.
2489 */
2495 }
2496 /* HC is busted, give up! */
2498 "ERROR Transfer event TRB DMA ptr not "
2499 "part of current TD ep_index %d "
2501 trb_comp_code);
2506 }
2510 }
2513 else
2519 }
2523 /*
2524 * No-op TRB should not trigger interrupts.
2525 * If event_trb is a no-op TRB, it means the
2526 * corresponding TD has been cancelled. Just ignore
2527 * the TD.
2528 */
2533 }
2535 /* Now update the urb's actual_length and give back to
2536 * the core
2537 */
2544 else
2548 cleanup:
2549 /*
2550 * Do not update event ring dequeue pointer if ep->skip is set.
2551 * Will roll back to continue process missed tds.
2552 */
2555 }
2566 URB_SHORT_NOT_OK)) ||
2573 status);
2575 /* EHCI, UHCI, and OHCI always unconditionally set the
2576 * urb->status of an isochronous endpoint to 0.
2577 */
2582 }
2584 /*
2585 * If ep->skip is set, it means there are missed tds on the
2586 * endpoint ring need to take care of.
2587 * Process them as short transfer until reach the td pointed by
2588 * the event.
2589 */
2593 }
2595 /*
2596 * This function handles all OS-owned events on the event ring. It may drop
2597 * xhci->lock between event processing (e.g. to pass up port status changes).
2598 * Returns >0 for "possibly more events to process" (caller should call again),
2599 * otherwise 0 if done. In future, <0 returns should indicate error code.
2600 */
2602 {
2610 }
2613 /* Does the HC or OS own the TRB? */
2618 }
2620 /*
2621 * Barrier between reading the TRB_CYCLE (valid) flag above and any
2622 * speculative reads of the event's flags/data below.
2623 */
2625 /* FIXME: Handle more event types. */
2638 else
2648 else
2650 }
2651 /* Any of the above functions may drop and re-acquire the lock, so check
2652 * to make sure a watchdog timer didn't mark the host as non-responsive.
2653 */
2658 }
2661 /* Update SW event ring dequeue pointer */
2664 /* Are there more items on the event ring? Caller will call us again to
2665 * check.
2666 */
2668 }
2670 /*
2671 * xHCI spec says we can get an interrupt, and if the HC has an error condition,
2672 * we might get bad data out of the event ring. Section 4.10.2.7 has a list of
2673 * indicators of an event TRB error, but we check the status *first* to be safe.
2674 */
2676 {
2678 u32 status;
2679 u64 temp_64;
2681 dma_addr_t deq;
2684 /* Check if the xHC generated the interrupt, or the irq is shared */
2692 }
2696 hw_died:
2699 }
2701 /*
2702 * Clear the op reg interrupt status first,
2703 * so we can receive interrupts from other MSI-X interrupters.
2704 * Write 1 to clear the interrupt status.
2705 */
2708 /* FIXME when MSI-X is supported and there are multiple vectors */
2709 /* Clear the MSI-X event interrupt status */
2712 u32 irq_pending;
2713 /* Acknowledge the PCI interrupt */
2717 }
2722 /* Clear the event handler busy flag (RW1C);
2723 * the event ring should be empty.
2724 */
2731 }
2734 /* FIXME this should be a delayed service routine
2735 * that clears the EHB.
2736 */
2740 /* If necessary, update the HW's version of the event ring deq ptr. */
2747 /* Update HC event ring dequeue pointer */
2750 }
2752 /* Clear the event handler busy flag (RW1C); event ring is empty. */
2759 }
2762 {
2764 }
2766 /**** Endpoint Ring Operations ****/
2768 /*
2769 * Generic function for queueing a TRB on a ring.
2770 * The caller must have checked to make sure there's room on the ring.
2771 *
2772 * @more_trbs_coming: Will you enqueue more TRBs before calling
2773 * prepare_transfer()?
2774 */
2778 {
2787 }
2789 /*
2790 * Does various checks on the endpoint ring, and makes it ready to queue num_trbs.
2791 * FIXME allocate segments if the ring is full.
2792 */
2795 {
2798 /* Make sure the endpoint has been added to xHC schedule */
2801 /*
2802 * USB core changed config/interfaces without notifying us,
2803 * or hardware is reporting the wrong state.
2804 */
2809 /* FIXME event handling code for error needs to clear it */
2810 /* XXX not sure if this should be -ENOENT or not */
2819 /*
2820 * FIXME issue Configure Endpoint command to try to get the HC
2821 * back into a known state.
2822 */
2824 }
2833 }
2839 mem_flags)) {
2842 }
2843 }
2852 /* If we're not dealing with 0.95 hardware or isoc rings
2853 * on AMD 0.96 host, clear the chain bit.
2854 */
2859 else
2865 /* Toggle the cycle bit after the last ring segment. */
2868 }
2872 }
2873 }
2876 }
2885 gfp_t mem_flags)
2886 {
2896 stream_id);
2898 }
2916 }
2919 /* Add this TD to the tail of the endpoint ring's TD list */
2927 }
2930 {
2942 /* Scatter gather list entries may cross 64KB boundaries */
2947 num_trbs++;
2949 /* How many more 64KB chunks to transfer, how many more TRBs? */
2951 num_trbs++;
2953 }
2958 }
2960 }
2963 {
2971 __func__,
2976 }
2981 {
2982 /*
2983 * Pass all the TRBs to the hardware at once and make sure this write
2984 * isn't reordered.
2985 */
2989 else
2992 }
2994 /*
2995 * xHCI uses normal TRBs for both bulk and interrupt. When the interrupt
2996 * endpoint is to be serviced, the xHC will consume (at most) one TD. A TD
2997 * (comprised of sg list entries) can take several service intervals to
2998 * transmit.
2999 */
3002 {
3010 /* Convert to microframes */
3014 /* FIXME change this to a warning and a suggestion to use the new API
3015 * to set the polling interval (once the API is added).
3016 */
3023 /* Convert back to frames for LS/FS devices */
3027 }
3029 }
3031 /*
3032 * The TD size is the number of bytes remaining in the TD (including this TRB),
3033 * right shifted by 10.
3034 * It must fit in bits 21:17, so it can't be bigger than 31.
3035 */
3037 {
3042 else
3044 }
3046 /*
3047 * For xHCI 1.0 host controllers, TD size is the number of max packet sized
3048 * packets remaining in the TD (*not* including this TRB).
3049 *
3050 * Total TD packet count = total_packet_count =
3051 * DIV_ROUND_UP(TD size in bytes / wMaxPacketSize)
3052 *
3053 * Packets transferred up to and including this TRB = packets_transferred =
3054 * rounddown(total bytes transferred including this TRB / wMaxPacketSize)
3055 *
3056 * TD size = total_packet_count - packets_transferred
3057 *
3058 * It must fit in bits 21:17, so it can't be bigger than 31.
3059 * The last TRB in a TD must have the TD size set to zero.
3060 */
3064 {
3067 /* One TRB with a zero-length data packet. */
3071 /* All the TRB queueing functions don't count the current TRB in
3072 * running_total.
3073 */
3080 }
3084 {
3096 u64 addr;
3119 /* Deal with URB_ZERO_PACKET - need one more td/trb */
3123 num_trbs++;
3130 }
3134 /*
3135 * Don't give the first TRB to the hardware (by toggling the cycle bit)
3136 * until we've finished creating all the other TRBs. The ring's cycle
3137 * state may change as we enqueue the other TRBs, so save it too.
3138 */
3143 /*
3144 * How much data is in the first TRB?
3145 *
3146 * There are three forces at work for TRB buffer pointers and lengths:
3147 * 1. We don't want to walk off the end of this sg-list entry buffer.
3148 * 2. The transfer length that the driver requested may be smaller than
3149 * the amount of memory allocated for this scatter-gather list.
3150 * 3. TRBs buffers can't cross 64KB boundaries.
3151 */
3162 /* Queue the first TRB, even if it's zero-length */
3168 /* Don't change the cycle bit of the first TRB until later */
3176 /* Chain all the TRBs together; clear the chain bit in the last
3177 * TRB to indicate it's the last TRB in the chain.
3178 */
3188 }
3190 /* Only set interrupt on short packet for IN endpoints */
3200 }
3202 /* Set the TRB length, TD size, and interrupter fields. */
3206 running_total);
3211 }
3213 remainder |
3218 else
3223 length_field,
3228 /* Calculate length for next transfer --
3229 * Are we done queueing all the TRBs for this sg entry?
3230 */
3241 }
3247 trb_buff_len =
3255 }
3257 /* This is very similar to what ehci-q.c qtd_fill() does */
3260 {
3275 u64 addr;
3285 /* How much data is (potentially) left before the 64KB boundary? */
3290 /* If there's some data on this 64KB chunk, or we have to send a
3291 * zero-length transfer, we need at least one TRB
3292 */
3294 num_trbs++;
3295 /* How many more 64KB chunks to transfer, how many more TRBs? */
3297 num_trbs++;
3299 }
3309 /* Deal with URB_ZERO_PACKET - need one more td/trb */
3313 num_trbs++;
3320 }
3324 /*
3325 * Don't give the first TRB to the hardware (by toggling the cycle bit)
3326 * until we've finished creating all the other TRBs. The ring's cycle
3327 * state may change as we enqueue the other TRBs, so save it too.
3328 */
3335 /* How much data is in the first TRB? */
3344 /* Queue the first TRB, even if it's zero-length */
3349 /* Don't change the cycle bit of the first TRB until later */
3357 /* Chain all the TRBs together; clear the chain bit in the last
3358 * TRB to indicate it's the last TRB in the chain.
3359 */
3369 }
3371 /* Only set interrupt on short packet for IN endpoints */
3375 /* Set the TRB length, TD size, and interrupter fields. */
3379 running_total);
3384 }
3386 remainder |
3391 else
3396 length_field,
3401 /* Calculate length for next transfer */
3412 }
3414 /* Caller must have locked xhci->lock */
3417 {
3432 /*
3433 * Need to copy setup packet into setup TRB, so we can't use the setup
3434 * DMA address.
3435 */
3439 /* 1 TRB for setup, 1 for status */
3441 /*
3442 * Don't need to check if we need additional event data and normal TRBs,
3443 * since data in control transfers will never get bigger than 16MB
3444 * XXX: can we get a buffer that crosses 64KB boundaries?
3445 */
3447 num_trbs++;
3457 /*
3458 * Don't give the first TRB to the hardware (by toggling the cycle bit)
3459 * until we've finished creating all the other TRBs. The ring's cycle
3460 * state may change as we enqueue the other TRBs, so save it too.
3461 */
3465 /* Queue setup TRB - see section 6.4.1.2.1 */
3466 /* FIXME better way to translate setup_packet into two u32 fields? */
3473 /* xHCI 1.0/1.1 6.4.1.2.1: Transfer Type field */
3478 else
3480 }
3481 }
3487 /* Immediate data in pointer */
3488 field);
3490 /* If there's data, queue data TRBs */
3491 /* Only set interrupt on short packet for IN endpoints */
3494 else
3506 length_field,
3508 }
3510 /* Save the DMA address of the last TRB in the TD */
3513 /* Queue status TRB - see Table 7 and sections 4.11.2.2 and 6.4.1.2.3 */
3514 /* If the device sent data, the status stage is an OUT transfer */
3517 else
3523 /* Event on completion */
3529 }
3533 {
3541 TRB_MAX_BUFF_SIZE);
3543 num_trbs++;
3546 }
3548 /*
3549 * The transfer burst count field of the isochronous TRB defines the number of
3550 * bursts that are required to move all packets in this TD. Only SuperSpeed
3551 * devices can burst up to bMaxBurst number of packets per service interval.
3552 * This field is zero based, meaning a value of zero in the field means one
3553 * burst. Basically, for everything but SuperSpeed devices, this field will be
3554 * zero. Only xHCI 1.0 host controllers support this field.
3555 */
3559 {
3567 }
3569 /*
3570 * Returns the number of packets in the last "burst" of packets. This field is
3571 * valid for all speeds of devices. USB 2.0 devices can only do one "burst", so
3572 * the last burst packet count is equal to the total number of packets in the
3573 * TD. SuperSpeed endpoints can have up to 3 bursts. All but the last burst
3574 * must contain (bMaxBurst + 1) number of packets, but the last burst can
3575 * contain 1 to (bMaxBurst + 1) packets.
3576 */
3580 {
3589 /* bMaxBurst is zero based: 0 means 1 packet per burst */
3592 /* If residue is zero, the last burst contains (max_burst + 1)
3593 * number of packets, but the TLBPC field is zero-based.
3594 */
3602 }
3603 }
3605 /*
3606 * Calculates Frame ID field of the isochronous TRB identifies the
3607 * target frame that the Interval associated with this Isochronous
3608 * Transfer Descriptor will start on. Refer to 4.11.2.5 in 1.1 spec.
3609 *
3610 * Returns actual frame id on success, negative value on error.
3611 */
3614 {
3621 else
3624 /* Isochronous Scheduling Threshold (IST, bits 0~3 in HCSPARAMS2):
3625 *
3626 * If bit [3] of IST is cleared to '0', software can add a TRB no
3627 * later than IST[2:0] Microframes before that TRB is scheduled to
3628 * be executed.
3629 * If bit [3] of IST is set to '1', software can add a TRB no later
3630 * than IST[2:0] Frames before that TRB is scheduled to be executed.
3631 */
3636 /* Software shall not schedule an Isoch TD with a Frame ID value that
3637 * is less than the Start Frame ID or greater than the End Frame ID,
3638 * where:
3639 *
3640 * End Frame ID = (Current MFINDEX register value + 895 ms.) MOD 2048
3641 * Start Frame ID = (Current MFINDEX register value + IST + 1) MOD 2048
3642 *
3643 * Both the End Frame ID and Start Frame ID values are calculated
3644 * in microframes. When software determines the valid Frame ID value;
3645 * The End Frame ID value should be rounded down to the nearest Frame
3646 * boundary, and the Start Frame ID value should be rounded up to the
3647 * nearest Frame boundary.
3648 */
3657 xhci_dbg(xhci, "%s: index %d, reg 0x%x start_frame_id 0x%x, end_frame_id 0x%x, start_frame 0x%x\n",
3671 }
3679 else
3682 }
3683 }
3691 }
3694 }
3696 /* This is for isoc transfer */
3699 {
3721 }
3728 /* Queue the first TRB, even if it's zero-length */
3742 /* A zero-length transfer still involves at least one packet. */
3744 total_packet_count++;
3746 total_packet_count);
3758 }
3769 /* Queue the isoc TRB */
3772 /* Calculate Frame ID and SIA fields */
3776 urb,
3777 i);
3780 else
3792 /* Queue other normal TRBs */
3795 }
3797 /* Only set interrupt on short packet for IN EPs */
3801 /* Chain all the TRBs together; clear the chain bit in
3802 * the last TRB to indicate it's the last TRB in the
3803 * chain.
3804 */
3813 XHCI_AVOID_BEI)) {
3814 /* Set BEI bit except for the last td */
3817 }
3819 }
3821 /* Calculate TRB length */
3827 /* Set the TRB length, TD size, & interrupter fields. */
3836 }
3838 remainder |
3844 length_field,
3845 field);
3850 }
3852 /* Check TD length */
3857 }
3858 }
3860 /* store the next frame id */
3867 }
3873 cleanup:
3874 /* Clean up a partially enqueued isoc transfer. */
3879 /* Use the first TD as a temporary variable to turn the TDs we've queued
3880 * into No-ops with a software-owned cycle bit. That way the hardware
3881 * won't accidentally start executing bogus TDs when we partially
3882 * overwrite them. td->first_trb and td->start_seg are already set.
3883 */
3885 /* Every TRB except the first & last will have its cycle bit flipped. */
3888 /* Reset the ring enqueue back to the first TRB and its cycle bit. */
3895 }
3899 {
3904 dma_addr_t hw_deq;
3917 }
3919 /*
3920 * Check transfer ring to guarantee there is enough room for the urb.
3921 * Update ISO URB start_frame and interval.
3922 * Update interval as xhci_queue_intr_tx does. Use xhci frame_index to
3923 * update urb->start_frame if URB_ISO_ASAP is set in transfer_flags or
3924 * Contiguous Frame ID is not supported by HC.
3925 */
3928 {
3950 /* Check the ring to guarantee there is enough room for the whole urb.
3951 * Do not insert any td of the urb to the ring if the check failed.
3952 */
3958 /*
3959 * Check interval value. This should be done before we start to
3960 * calculate the start frame value.
3961 */
3964 /* Convert to microframes */
3968 /* FIXME change this to a warning and a suggestion to use the new API
3969 * to set the polling interval (once the API is added).
3970 */
3977 /* Convert back to frames for LS/FS devices */
3981 }
3983 /* Calculate the start frame and put it in urb->start_frame. */
3988 }
3992 /*
3993 * Round up to the next frame and consider the time before trb really
3994 * gets scheduled by hardare.
3995 */
4002 /*
4003 * Round up to the next ESIT (Endpoint Service Interval Time) if ESIT
4004 * is greate than 8 microframes.
4005 */
4013 }
4015 skip_start_over:
4019 }
4021 /**** Command Ring Operations ****/
4023 /* Generic function for queueing a command TRB on the command ring.
4024 * Check to make sure there's room on the command ring for one command TRB.
4025 * Also check that there's room reserved for commands that must not fail.
4026 * If this is a command that must not fail, meaning command_must_succeed = TRUE,
4027 * then only check for the number of reserved spots.
4028 * Don't decrement xhci->cmd_ring_reserved_trbs after we've queued the TRB
4029 * because the command event handler may want to resubmit a failed command.
4030 */
4034 {
4041 }
4044 reserved_trbs++;
4054 }
4059 /* if there are no other commands queued we start the timeout timer */
4064 }
4069 }
4071 /* Queue a slot enable or disable request on the command ring */
4074 {
4077 }
4079 /* Queue an address device command TRB */
4082 {
4087 }
4091 {
4093 }
4095 /* Queue a reset device command TRB */
4097 u32 slot_id)
4098 {
4102 }
4104 /* Queue a configure endpoint command TRB */
4108 {
4112 command_must_succeed);
4113 }
4115 /* Queue an evaluate context command TRB */
4118 {
4122 command_must_succeed);
4123 }
4125 /*
4126 * Suspend is set to indicate "Stop Endpoint Command" is being issued to stop
4127 * activity on an endpoint that is about to be suspended.
4128 */
4131 {
4139 }
4141 /* Set Transfer Ring Dequeue Pointer command */
4146 {
4147 dma_addr_t addr;
4158 "Set TR Deq Ptr cmd, new deq seg = %p (0x%llx dma), new deq ptr = %p (0x%llx dma), new cycle = %u",
4173 }
4179 }
4181 /* This function gets called from contexts where it cannot sleep */
4186 }
4199 }
4201 /* Stop the TD queueing code from ringing the doorbell until
4202 * this command completes. The HC won't set the dequeue pointer
4203 * if the ring is running, and ringing the doorbell starts the
4204 * ring running.
4205 */
4207 }
4211 {
4218 }