| blob | 8d194912c695ba86afc235c5792556c912da71f3 |
1 /*
2 * Copyright (c) 2006 Oracle. All rights reserved.
3 *
4 * This software is available to you under a choice of one of two
5 * licenses. You may choose to be licensed under the terms of the GNU
6 * General Public License (GPL) Version 2, available from the file
7 * COPYING in the main directory of this source tree, or the
8 * OpenIB.org BSD license below:
9 *
10 * Redistribution and use in source and binary forms, with or
11 * without modification, are permitted provided that the following
12 * conditions are met:
13 *
14 * - Redistributions of source code must retain the above
15 * copyright notice, this list of conditions and the following
16 * disclaimer.
17 *
18 * - Redistributions in binary form must reproduce the above
19 * copyright notice, this list of conditions and the following
20 * disclaimer in the documentation and/or other materials
21 * provided with the distribution.
22 *
23 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
24 * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
25 * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
26 * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
27 * BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
28 * ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
29 * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
30 * SOFTWARE.
31 *
32 */
33 #include <linux/kernel.h>
34 #include <linux/slab.h>
35 #include <linux/pci.h>
36 #include <linux/dma-mapping.h>
37 #include <rdma/rdma_cm.h>
47 {
49 u32 i;
71 }
72 }
74 /*
75 * The entire 'from' list, including the from element itself, is put on
76 * to the tail of the 'to' list.
77 */
80 {
85 }
88 {
95 else
97 }
98 }
101 {
113 }
118 }
121 {
129 }
132 }
136 {
145 }
146 }
151 }
152 }
155 {
170 }
180 }
181 }
183 /* fwd decl */
189 /* Recycle frag and attached recv buffer f_sg */
192 {
196 }
198 /* Recycle inc after freeing attached frags */
200 {
208 /* Free attached frags */
212 }
217 }
221 {
225 }
230 }
231 }
234 {
235 u32 i;
239 }
242 gfp_t slab_mask)
243 {
257 }
262 }
263 }
268 }
272 {
291 }
292 }
297 }
301 {
311 }
318 /*
319 * ibinc was taken from recv if recv contained the start of a message.
320 * recvs that were continuations will still have this allocated.
321 */
326 }
346 out:
348 }
350 /*
351 * This tries to allocate and post unused work requests after making sure that
352 * they have all the allocations they need to queue received fragments into
353 * sockets.
354 *
355 * -1 is returned if posting fails due to temporary resource exhaustion.
356 */
358 {
364 u32 pos;
370 pos);
372 }
378 }
380 /* XXX when can this fail? */
387 "%pI4 returned %d, disconnecting and "
389 ret);
391 }
393 posted++;
394 }
396 /* We're doing flow control - update the window. */
402 }
404 /*
405 * We want to recycle several types of recv allocations, like incs and frags.
406 * To use this, the *_free() function passes in the ptr to a list_head within
407 * the recyclee, as well as the cache to put it on.
408 *
409 * First, we put the memory on a percpu list. When this reaches a certain size,
410 * We move it to an intermediate non-percpu list in a lockless manner, with some
411 * xchg/compxchg wizardry.
412 *
413 * N.B. Instead of a list_head as the anchor, we use a single pointer, which can
414 * be NULL and xchg'd. The list is actually empty when the pointer is NULL, and
415 * list_empty() will return true with one element is actually present.
416 */
419 {
437 /*
438 * Return our per-cpu first list to the cache's xfer by atomically
439 * grabbing the current xfer list, appending it to our per-cpu list,
440 * and then atomically returning that entire list back to the
441 * cache's xfer list as long as it's still empty.
442 */
452 end:
454 }
457 {
466 }
469 }
473 {
482 u32 len;
493 }
496 iov++;
497 }
508 /* XXX needs + offset for multiple recvs per page */
512 to_copy);
516 }
521 }
524 }
526 /* ic starts out kzalloc()ed */
528 {
541 }
543 /*
544 * You'd think that with reliable IB connections you wouldn't need to ack
545 * messages that have been received. The problem is that IB hardware generates
546 * an ack message before it has DMAed the message into memory. This creates a
547 * potential message loss if the HCA is disabled for any reason between when it
548 * sends the ack and before the message is DMAed and processed. This is only a
549 * potential issue if another HCA is available for fail-over.
550 *
551 * When the remote host receives our ack they'll free the sent message from
552 * their send queue. To decrease the latency of this we always send an ack
553 * immediately after we've received messages.
554 *
555 * For simplicity, we only have one ack in flight at a time. This puts
556 * pressure on senders to have deep enough send queues to absorb the latency of
557 * a single ack frame being in flight. This might not be good enough.
558 *
559 * This is implemented by have a long-lived send_wr and sge which point to a
560 * statically allocated ack frame. This ack wr does not fall under the ring
561 * accounting that the tx and rx wrs do. The QP attribute specifically makes
562 * room for it beyond the ring size. Send completion notices its special
563 * wr_id and avoids working with the ring in that case.
564 */
565 #ifndef KERNEL_HAS_ATOMIC64
568 {
576 }
579 {
581 u64 seq;
590 }
591 #else
594 {
599 }
600 }
603 {
608 }
609 #endif
613 {
616 u64 seq;
630 /* Failed to send. Release the WR, and
631 * force another ACK.
632 */
641 }
643 /*
644 * There are 3 ways of getting acknowledgements to the peer:
645 * 1. We call rds_ib_attempt_ack from the recv completion handler
646 * to send an ACK-only frame.
647 * However, there can be only one such frame in the send queue
648 * at any time, so we may have to postpone it.
649 * 2. When another (data) packet is transmitted while there's
650 * an ACK in the queue, we piggyback the ACK sequence number
651 * on the data packet.
652 * 3. If the ACK WR is done sending, we get called from the
653 * send queue completion handler, and check whether there's
654 * another ACK pending (postponed because the WR was on the
655 * queue). If so, we transmit it.
656 *
657 * We maintain 2 variables:
658 * - i_ack_flags, which keeps track of whether the ACK WR
659 * is currently in the send queue or not (IB_ACK_IN_FLIGHT)
660 * - i_ack_next, which is the last sequence number we received
661 *
662 * Potentially, send queue and receive queue handlers can run concurrently.
663 * It would be nice to not have to use a spinlock to synchronize things,
664 * but the one problem that rules this out is that 64bit updates are
665 * not atomic on all platforms. Things would be a lot simpler if
666 * we had atomic64 or maybe cmpxchg64 everywhere.
667 *
668 * Reconnecting complicates this picture just slightly. When we
669 * reconnect, we may be seeing duplicate packets. The peer
670 * is retransmitting them, because it hasn't seen an ACK for
671 * them. It is important that we ACK these.
672 *
673 * ACK mitigation adds a header flag "ACK_REQUIRED"; any packet with
674 * this flag set *MUST* be acknowledged immediately.
675 */
677 /*
678 * When we get here, we're called from the recv queue handler.
679 * Check whether we ought to transmit an ACK.
680 */
682 {
691 }
693 /* Can we get a send credit? */
698 }
702 }
704 /*
705 * We get here from the send completion handler, when the
706 * adapter tells us the ACK frame was sent.
707 */
709 {
712 }
714 /*
715 * This is called by the regular xmit code when it wants to piggyback
716 * an ACK on an outgoing frame.
717 */
719 {
723 }
725 /*
726 * It's kind of lame that we're copying from the posted receive pages into
727 * long-lived bitmaps. We could have posted the bitmaps and rdma written into
728 * them. But receiving new congestion bitmaps should be a *rare* event, so
729 * hopefully we won't need to invest that complexity in making it more
730 * efficient. By copying we can share a simpler core with TCP which has to
731 * copy.
732 */
735 {
746 /* catch completely corrupt packets */
771 /* Record ports that became uncongested, ie
772 * bits that changed from 0 to 1. */
775 }
783 map_page++;
784 }
791 }
792 }
794 /* the congestion map is in little endian order */
798 }
800 /*
801 * Rings are posted with all the allocations they'll need to queue the
802 * incoming message to the receiving socket so this can't fail.
803 * All fragments start with a header, so we can make sure we're not receiving
804 * garbage, and we can tell a small 8 byte fragment from an ACK frame.
805 */
807 u64 ack_next;
808 u64 ack_recv;
812 };
817 {
822 /* XXX shut down the connection if port 0,0 are seen? */
825 data_len);
829 "from %pI4 didn't include a "
830 "header, disconnecting and "
834 }
839 /* Validate the checksum. */
842 "from %pI4 has corrupted header - "
847 }
849 /* Process the ACK sequence which comes with every packet */
853 /* Process the credits update if there was one */
858 /* This is an ACK-only packet. The fact that it gets
859 * special treatment here is that historically, ACKs
860 * were rather special beasts.
861 */
864 /*
865 * Usually the frags make their way on to incs and are then freed as
866 * the inc is freed. We don't go that route, so we have to drop the
867 * page ref ourselves. We can't just leave the page on the recv
868 * because that confuses the dma mapping of pages and each recv's use
869 * of a partial page.
870 *
871 * FIXME: Fold this into the code path below.
872 */
876 }
878 /*
879 * If we don't already have an inc on the connection then this
880 * fragment has a header and starts a message.. copy its header
881 * into the inc and save the inc so we can hang upcoming fragments
882 * off its list.
883 */
897 /* We can't just use memcmp here; fragments of a
898 * single message may carry different ACKs */
906 }
907 }
925 }
927 /* Evaluate the ACK_REQUIRED flag *after* we received
928 * the complete frame, and after bumping the next_rx
929 * sequence. */
933 }
936 }
937 }
939 /*
940 * Plucking the oldest entry from the ring can be done concurrently with
941 * the thread refilling the ring. Each ring operation is protected by
942 * spinlocks and the transient state of refilling doesn't change the
943 * recording of which entry is oldest.
944 *
945 * This relies on IB only calling one cq comp_handler for each cq so that
946 * there will only be one caller of rds_recv_incoming() per RDS connection.
947 */
949 {
958 }
962 {
978 /*
979 * Also process recvs in connecting state because it is possible
980 * to get a recv completion _before_ the rdmacm ESTABLISHED
981 * event is processed.
982 */
986 /* We expect errors as the qp is drained during shutdown */
989 "status %u (%s), disconnecting and "
993 }
995 /*
996 * It's very important that we only free this ring entry if we've truly
997 * freed the resources allocated to the entry. The refilling path can
998 * leak if we don't.
999 */
1001 }
1002 }
1005 {
1019 }
1023 /* If we ever end up with a really empty receive ring, we're
1024 * in deep trouble, as the sender will definitely see RNR
1025 * timeouts. */
1031 }
1034 {
1043 }
1046 {
1050 /* Default to 30% of all available RAM for recv memory */
1065 else
1067 out:
1069 }
1072 {
1075 }