2 * Copyright (c) 2006 Oracle. All rights reserved.
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:
10 * Redistribution and use in source and binary forms, with or
11 * without modification, are permitted provided that the following
14 * - Redistributions of source code must retain the above
15 * copyright notice, this list of conditions and the following
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.
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
33 #include <linux/kernel.h>
34 #include <linux/slab.h>
35 #include <linux/ratelimit.h>
42 * This is stored as mr->r_trans_private.
45 struct rds_iw_device
*device
;
46 struct rds_iw_mr_pool
*pool
;
47 struct rdma_cm_id
*cm_id
;
50 struct ib_fast_reg_page_list
*page_list
;
52 struct rds_iw_mapping mapping
;
53 unsigned char remap_count
;
57 * Our own little MR pool
59 struct rds_iw_mr_pool
{
60 struct rds_iw_device
*device
; /* back ptr to the device that owns us */
62 struct mutex flush_lock
; /* serialize fmr invalidate */
63 struct work_struct flush_worker
; /* flush worker */
65 spinlock_t list_lock
; /* protect variables below */
66 atomic_t item_count
; /* total # of MRs */
67 atomic_t dirty_count
; /* # dirty of MRs */
68 struct list_head dirty_list
; /* dirty mappings */
69 struct list_head clean_list
; /* unused & unamapped MRs */
70 atomic_t free_pinned
; /* memory pinned by free MRs */
71 unsigned long max_message_size
; /* in pages */
72 unsigned long max_items
;
73 unsigned long max_items_soft
;
74 unsigned long max_free_pinned
;
78 static int rds_iw_flush_mr_pool(struct rds_iw_mr_pool
*pool
, int free_all
);
79 static void rds_iw_mr_pool_flush_worker(struct work_struct
*work
);
80 static int rds_iw_init_fastreg(struct rds_iw_mr_pool
*pool
, struct rds_iw_mr
*ibmr
);
81 static int rds_iw_map_fastreg(struct rds_iw_mr_pool
*pool
,
82 struct rds_iw_mr
*ibmr
,
83 struct scatterlist
*sg
, unsigned int nents
);
84 static void rds_iw_free_fastreg(struct rds_iw_mr_pool
*pool
, struct rds_iw_mr
*ibmr
);
85 static unsigned int rds_iw_unmap_fastreg_list(struct rds_iw_mr_pool
*pool
,
86 struct list_head
*unmap_list
,
87 struct list_head
*kill_list
,
89 static void rds_iw_destroy_fastreg(struct rds_iw_mr_pool
*pool
, struct rds_iw_mr
*ibmr
);
91 static int rds_iw_get_device(struct rds_sock
*rs
, struct rds_iw_device
**rds_iwdev
, struct rdma_cm_id
**cm_id
)
93 struct rds_iw_device
*iwdev
;
94 struct rds_iw_cm_id
*i_cm_id
;
99 list_for_each_entry(iwdev
, &rds_iw_devices
, list
) {
100 spin_lock_irq(&iwdev
->spinlock
);
101 list_for_each_entry(i_cm_id
, &iwdev
->cm_id_list
, list
) {
102 struct sockaddr_in
*src_addr
, *dst_addr
;
104 src_addr
= (struct sockaddr_in
*)&i_cm_id
->cm_id
->route
.addr
.src_addr
;
105 dst_addr
= (struct sockaddr_in
*)&i_cm_id
->cm_id
->route
.addr
.dst_addr
;
107 rdsdebug("local ipaddr = %x port %d, "
108 "remote ipaddr = %x port %d"
109 "..looking for %x port %d, "
110 "remote ipaddr = %x port %d\n",
111 src_addr
->sin_addr
.s_addr
,
113 dst_addr
->sin_addr
.s_addr
,
119 #ifdef WORKING_TUPLE_DETECTION
120 if (src_addr
->sin_addr
.s_addr
== rs
->rs_bound_addr
&&
121 src_addr
->sin_port
== rs
->rs_bound_port
&&
122 dst_addr
->sin_addr
.s_addr
== rs
->rs_conn_addr
&&
123 dst_addr
->sin_port
== rs
->rs_conn_port
) {
125 /* FIXME - needs to compare the local and remote
126 * ipaddr/port tuple, but the ipaddr is the only
127 * available information in the rds_sock (as the rest are
128 * zero'ed. It doesn't appear to be properly populated
129 * during connection setup...
131 if (src_addr
->sin_addr
.s_addr
== rs
->rs_bound_addr
) {
133 spin_unlock_irq(&iwdev
->spinlock
);
135 *cm_id
= i_cm_id
->cm_id
;
139 spin_unlock_irq(&iwdev
->spinlock
);
145 static int rds_iw_add_cm_id(struct rds_iw_device
*rds_iwdev
, struct rdma_cm_id
*cm_id
)
147 struct rds_iw_cm_id
*i_cm_id
;
149 i_cm_id
= kmalloc(sizeof *i_cm_id
, GFP_KERNEL
);
153 i_cm_id
->cm_id
= cm_id
;
155 spin_lock_irq(&rds_iwdev
->spinlock
);
156 list_add_tail(&i_cm_id
->list
, &rds_iwdev
->cm_id_list
);
157 spin_unlock_irq(&rds_iwdev
->spinlock
);
162 static void rds_iw_remove_cm_id(struct rds_iw_device
*rds_iwdev
,
163 struct rdma_cm_id
*cm_id
)
165 struct rds_iw_cm_id
*i_cm_id
;
167 spin_lock_irq(&rds_iwdev
->spinlock
);
168 list_for_each_entry(i_cm_id
, &rds_iwdev
->cm_id_list
, list
) {
169 if (i_cm_id
->cm_id
== cm_id
) {
170 list_del(&i_cm_id
->list
);
175 spin_unlock_irq(&rds_iwdev
->spinlock
);
179 int rds_iw_update_cm_id(struct rds_iw_device
*rds_iwdev
, struct rdma_cm_id
*cm_id
)
181 struct sockaddr_in
*src_addr
, *dst_addr
;
182 struct rds_iw_device
*rds_iwdev_old
;
184 struct rdma_cm_id
*pcm_id
;
187 src_addr
= (struct sockaddr_in
*)&cm_id
->route
.addr
.src_addr
;
188 dst_addr
= (struct sockaddr_in
*)&cm_id
->route
.addr
.dst_addr
;
190 rs
.rs_bound_addr
= src_addr
->sin_addr
.s_addr
;
191 rs
.rs_bound_port
= src_addr
->sin_port
;
192 rs
.rs_conn_addr
= dst_addr
->sin_addr
.s_addr
;
193 rs
.rs_conn_port
= dst_addr
->sin_port
;
195 rc
= rds_iw_get_device(&rs
, &rds_iwdev_old
, &pcm_id
);
197 rds_iw_remove_cm_id(rds_iwdev
, cm_id
);
199 return rds_iw_add_cm_id(rds_iwdev
, cm_id
);
202 void rds_iw_add_conn(struct rds_iw_device
*rds_iwdev
, struct rds_connection
*conn
)
204 struct rds_iw_connection
*ic
= conn
->c_transport_data
;
206 /* conn was previously on the nodev_conns_list */
207 spin_lock_irq(&iw_nodev_conns_lock
);
208 BUG_ON(list_empty(&iw_nodev_conns
));
209 BUG_ON(list_empty(&ic
->iw_node
));
210 list_del(&ic
->iw_node
);
212 spin_lock(&rds_iwdev
->spinlock
);
213 list_add_tail(&ic
->iw_node
, &rds_iwdev
->conn_list
);
214 spin_unlock(&rds_iwdev
->spinlock
);
215 spin_unlock_irq(&iw_nodev_conns_lock
);
217 ic
->rds_iwdev
= rds_iwdev
;
220 void rds_iw_remove_conn(struct rds_iw_device
*rds_iwdev
, struct rds_connection
*conn
)
222 struct rds_iw_connection
*ic
= conn
->c_transport_data
;
224 /* place conn on nodev_conns_list */
225 spin_lock(&iw_nodev_conns_lock
);
227 spin_lock_irq(&rds_iwdev
->spinlock
);
228 BUG_ON(list_empty(&ic
->iw_node
));
229 list_del(&ic
->iw_node
);
230 spin_unlock_irq(&rds_iwdev
->spinlock
);
232 list_add_tail(&ic
->iw_node
, &iw_nodev_conns
);
234 spin_unlock(&iw_nodev_conns_lock
);
236 rds_iw_remove_cm_id(ic
->rds_iwdev
, ic
->i_cm_id
);
237 ic
->rds_iwdev
= NULL
;
240 void __rds_iw_destroy_conns(struct list_head
*list
, spinlock_t
*list_lock
)
242 struct rds_iw_connection
*ic
, *_ic
;
245 /* avoid calling conn_destroy with irqs off */
246 spin_lock_irq(list_lock
);
247 list_splice(list
, &tmp_list
);
248 INIT_LIST_HEAD(list
);
249 spin_unlock_irq(list_lock
);
251 list_for_each_entry_safe(ic
, _ic
, &tmp_list
, iw_node
)
252 rds_conn_destroy(ic
->conn
);
255 static void rds_iw_set_scatterlist(struct rds_iw_scatterlist
*sg
,
256 struct scatterlist
*list
, unsigned int sg_len
)
265 static u64
*rds_iw_map_scatterlist(struct rds_iw_device
*rds_iwdev
,
266 struct rds_iw_scatterlist
*sg
)
268 struct ib_device
*dev
= rds_iwdev
->dev
;
269 u64
*dma_pages
= NULL
;
272 WARN_ON(sg
->dma_len
);
274 sg
->dma_len
= ib_dma_map_sg(dev
, sg
->list
, sg
->len
, DMA_BIDIRECTIONAL
);
275 if (unlikely(!sg
->dma_len
)) {
276 printk(KERN_WARNING
"RDS/IW: dma_map_sg failed!\n");
277 return ERR_PTR(-EBUSY
);
284 for (i
= 0; i
< sg
->dma_len
; ++i
) {
285 unsigned int dma_len
= ib_sg_dma_len(dev
, &sg
->list
[i
]);
286 u64 dma_addr
= ib_sg_dma_address(dev
, &sg
->list
[i
]);
289 sg
->bytes
+= dma_len
;
291 end_addr
= dma_addr
+ dma_len
;
292 if (dma_addr
& PAGE_MASK
) {
295 dma_addr
&= ~PAGE_MASK
;
297 if (end_addr
& PAGE_MASK
) {
298 if (i
< sg
->dma_len
- 1)
300 end_addr
= (end_addr
+ PAGE_MASK
) & ~PAGE_MASK
;
303 sg
->dma_npages
+= (end_addr
- dma_addr
) >> PAGE_SHIFT
;
306 /* Now gather the dma addrs into one list */
307 if (sg
->dma_npages
> fastreg_message_size
)
310 dma_pages
= kmalloc(sizeof(u64
) * sg
->dma_npages
, GFP_ATOMIC
);
316 for (i
= j
= 0; i
< sg
->dma_len
; ++i
) {
317 unsigned int dma_len
= ib_sg_dma_len(dev
, &sg
->list
[i
]);
318 u64 dma_addr
= ib_sg_dma_address(dev
, &sg
->list
[i
]);
321 end_addr
= dma_addr
+ dma_len
;
322 dma_addr
&= ~PAGE_MASK
;
323 for (; dma_addr
< end_addr
; dma_addr
+= PAGE_SIZE
)
324 dma_pages
[j
++] = dma_addr
;
325 BUG_ON(j
> sg
->dma_npages
);
331 ib_dma_unmap_sg(rds_iwdev
->dev
, sg
->list
, sg
->len
, DMA_BIDIRECTIONAL
);
338 struct rds_iw_mr_pool
*rds_iw_create_mr_pool(struct rds_iw_device
*rds_iwdev
)
340 struct rds_iw_mr_pool
*pool
;
342 pool
= kzalloc(sizeof(*pool
), GFP_KERNEL
);
344 printk(KERN_WARNING
"RDS/IW: rds_iw_create_mr_pool alloc error\n");
345 return ERR_PTR(-ENOMEM
);
348 pool
->device
= rds_iwdev
;
349 INIT_LIST_HEAD(&pool
->dirty_list
);
350 INIT_LIST_HEAD(&pool
->clean_list
);
351 mutex_init(&pool
->flush_lock
);
352 spin_lock_init(&pool
->list_lock
);
353 INIT_WORK(&pool
->flush_worker
, rds_iw_mr_pool_flush_worker
);
355 pool
->max_message_size
= fastreg_message_size
;
356 pool
->max_items
= fastreg_pool_size
;
357 pool
->max_free_pinned
= pool
->max_items
* pool
->max_message_size
/ 4;
358 pool
->max_pages
= fastreg_message_size
;
360 /* We never allow more than max_items MRs to be allocated.
361 * When we exceed more than max_items_soft, we start freeing
362 * items more aggressively.
363 * Make sure that max_items > max_items_soft > max_items / 2
365 pool
->max_items_soft
= pool
->max_items
* 3 / 4;
370 void rds_iw_get_mr_info(struct rds_iw_device
*rds_iwdev
, struct rds_info_rdma_connection
*iinfo
)
372 struct rds_iw_mr_pool
*pool
= rds_iwdev
->mr_pool
;
374 iinfo
->rdma_mr_max
= pool
->max_items
;
375 iinfo
->rdma_mr_size
= pool
->max_pages
;
378 void rds_iw_destroy_mr_pool(struct rds_iw_mr_pool
*pool
)
380 flush_workqueue(rds_wq
);
381 rds_iw_flush_mr_pool(pool
, 1);
382 BUG_ON(atomic_read(&pool
->item_count
));
383 BUG_ON(atomic_read(&pool
->free_pinned
));
387 static inline struct rds_iw_mr
*rds_iw_reuse_fmr(struct rds_iw_mr_pool
*pool
)
389 struct rds_iw_mr
*ibmr
= NULL
;
392 spin_lock_irqsave(&pool
->list_lock
, flags
);
393 if (!list_empty(&pool
->clean_list
)) {
394 ibmr
= list_entry(pool
->clean_list
.next
, struct rds_iw_mr
, mapping
.m_list
);
395 list_del_init(&ibmr
->mapping
.m_list
);
397 spin_unlock_irqrestore(&pool
->list_lock
, flags
);
402 static struct rds_iw_mr
*rds_iw_alloc_mr(struct rds_iw_device
*rds_iwdev
)
404 struct rds_iw_mr_pool
*pool
= rds_iwdev
->mr_pool
;
405 struct rds_iw_mr
*ibmr
= NULL
;
406 int err
= 0, iter
= 0;
409 ibmr
= rds_iw_reuse_fmr(pool
);
413 /* No clean MRs - now we have the choice of either
414 * allocating a fresh MR up to the limit imposed by the
415 * driver, or flush any dirty unused MRs.
416 * We try to avoid stalling in the send path if possible,
417 * so we allocate as long as we're allowed to.
419 * We're fussy with enforcing the FMR limit, though. If the driver
420 * tells us we can't use more than N fmrs, we shouldn't start
422 if (atomic_inc_return(&pool
->item_count
) <= pool
->max_items
)
425 atomic_dec(&pool
->item_count
);
428 rds_iw_stats_inc(s_iw_rdma_mr_pool_depleted
);
429 return ERR_PTR(-EAGAIN
);
432 /* We do have some empty MRs. Flush them out. */
433 rds_iw_stats_inc(s_iw_rdma_mr_pool_wait
);
434 rds_iw_flush_mr_pool(pool
, 0);
437 ibmr
= kzalloc(sizeof(*ibmr
), GFP_KERNEL
);
443 spin_lock_init(&ibmr
->mapping
.m_lock
);
444 INIT_LIST_HEAD(&ibmr
->mapping
.m_list
);
445 ibmr
->mapping
.m_mr
= ibmr
;
447 err
= rds_iw_init_fastreg(pool
, ibmr
);
451 rds_iw_stats_inc(s_iw_rdma_mr_alloc
);
456 rds_iw_destroy_fastreg(pool
, ibmr
);
459 atomic_dec(&pool
->item_count
);
463 void rds_iw_sync_mr(void *trans_private
, int direction
)
465 struct rds_iw_mr
*ibmr
= trans_private
;
466 struct rds_iw_device
*rds_iwdev
= ibmr
->device
;
469 case DMA_FROM_DEVICE
:
470 ib_dma_sync_sg_for_cpu(rds_iwdev
->dev
, ibmr
->mapping
.m_sg
.list
,
471 ibmr
->mapping
.m_sg
.dma_len
, DMA_BIDIRECTIONAL
);
474 ib_dma_sync_sg_for_device(rds_iwdev
->dev
, ibmr
->mapping
.m_sg
.list
,
475 ibmr
->mapping
.m_sg
.dma_len
, DMA_BIDIRECTIONAL
);
480 static inline unsigned int rds_iw_flush_goal(struct rds_iw_mr_pool
*pool
, int free_all
)
482 unsigned int item_count
;
484 item_count
= atomic_read(&pool
->item_count
);
492 * Flush our pool of MRs.
493 * At a minimum, all currently unused MRs are unmapped.
494 * If the number of MRs allocated exceeds the limit, we also try
495 * to free as many MRs as needed to get back to this limit.
497 static int rds_iw_flush_mr_pool(struct rds_iw_mr_pool
*pool
, int free_all
)
499 struct rds_iw_mr
*ibmr
, *next
;
500 LIST_HEAD(unmap_list
);
501 LIST_HEAD(kill_list
);
503 unsigned int nfreed
= 0, ncleaned
= 0, unpinned
= 0, free_goal
;
506 rds_iw_stats_inc(s_iw_rdma_mr_pool_flush
);
508 mutex_lock(&pool
->flush_lock
);
510 spin_lock_irqsave(&pool
->list_lock
, flags
);
511 /* Get the list of all mappings to be destroyed */
512 list_splice_init(&pool
->dirty_list
, &unmap_list
);
514 list_splice_init(&pool
->clean_list
, &kill_list
);
515 spin_unlock_irqrestore(&pool
->list_lock
, flags
);
517 free_goal
= rds_iw_flush_goal(pool
, free_all
);
519 /* Batched invalidate of dirty MRs.
520 * For FMR based MRs, the mappings on the unmap list are
521 * actually members of an ibmr (ibmr->mapping). They either
522 * migrate to the kill_list, or have been cleaned and should be
523 * moved to the clean_list.
524 * For fastregs, they will be dynamically allocated, and
525 * will be destroyed by the unmap function.
527 if (!list_empty(&unmap_list
)) {
528 ncleaned
= rds_iw_unmap_fastreg_list(pool
, &unmap_list
,
529 &kill_list
, &unpinned
);
530 /* If we've been asked to destroy all MRs, move those
531 * that were simply cleaned to the kill list */
533 list_splice_init(&unmap_list
, &kill_list
);
536 /* Destroy any MRs that are past their best before date */
537 list_for_each_entry_safe(ibmr
, next
, &kill_list
, mapping
.m_list
) {
538 rds_iw_stats_inc(s_iw_rdma_mr_free
);
539 list_del(&ibmr
->mapping
.m_list
);
540 rds_iw_destroy_fastreg(pool
, ibmr
);
545 /* Anything that remains are laundered ibmrs, which we can add
546 * back to the clean list. */
547 if (!list_empty(&unmap_list
)) {
548 spin_lock_irqsave(&pool
->list_lock
, flags
);
549 list_splice(&unmap_list
, &pool
->clean_list
);
550 spin_unlock_irqrestore(&pool
->list_lock
, flags
);
553 atomic_sub(unpinned
, &pool
->free_pinned
);
554 atomic_sub(ncleaned
, &pool
->dirty_count
);
555 atomic_sub(nfreed
, &pool
->item_count
);
557 mutex_unlock(&pool
->flush_lock
);
561 static void rds_iw_mr_pool_flush_worker(struct work_struct
*work
)
563 struct rds_iw_mr_pool
*pool
= container_of(work
, struct rds_iw_mr_pool
, flush_worker
);
565 rds_iw_flush_mr_pool(pool
, 0);
568 void rds_iw_free_mr(void *trans_private
, int invalidate
)
570 struct rds_iw_mr
*ibmr
= trans_private
;
571 struct rds_iw_mr_pool
*pool
= ibmr
->device
->mr_pool
;
573 rdsdebug("RDS/IW: free_mr nents %u\n", ibmr
->mapping
.m_sg
.len
);
577 /* Return it to the pool's free list */
578 rds_iw_free_fastreg(pool
, ibmr
);
580 /* If we've pinned too many pages, request a flush */
581 if (atomic_read(&pool
->free_pinned
) >= pool
->max_free_pinned
||
582 atomic_read(&pool
->dirty_count
) >= pool
->max_items
/ 10)
583 queue_work(rds_wq
, &pool
->flush_worker
);
586 if (likely(!in_interrupt())) {
587 rds_iw_flush_mr_pool(pool
, 0);
589 /* We get here if the user created a MR marked
590 * as use_once and invalidate at the same time. */
591 queue_work(rds_wq
, &pool
->flush_worker
);
596 void rds_iw_flush_mrs(void)
598 struct rds_iw_device
*rds_iwdev
;
600 list_for_each_entry(rds_iwdev
, &rds_iw_devices
, list
) {
601 struct rds_iw_mr_pool
*pool
= rds_iwdev
->mr_pool
;
604 rds_iw_flush_mr_pool(pool
, 0);
608 void *rds_iw_get_mr(struct scatterlist
*sg
, unsigned long nents
,
609 struct rds_sock
*rs
, u32
*key_ret
)
611 struct rds_iw_device
*rds_iwdev
;
612 struct rds_iw_mr
*ibmr
= NULL
;
613 struct rdma_cm_id
*cm_id
;
616 ret
= rds_iw_get_device(rs
, &rds_iwdev
, &cm_id
);
622 if (!rds_iwdev
->mr_pool
) {
627 ibmr
= rds_iw_alloc_mr(rds_iwdev
);
632 ibmr
->device
= rds_iwdev
;
634 ret
= rds_iw_map_fastreg(rds_iwdev
->mr_pool
, ibmr
, sg
, nents
);
636 *key_ret
= ibmr
->mr
->rkey
;
638 printk(KERN_WARNING
"RDS/IW: failed to map mr (errno=%d)\n", ret
);
643 rds_iw_free_mr(ibmr
, 0);
650 * iWARP fastreg handling
652 * The life cycle of a fastreg registration is a bit different from
654 * The idea behind fastreg is to have one MR, to which we bind different
655 * mappings over time. To avoid stalling on the expensive map and invalidate
656 * operations, these operations are pipelined on the same send queue on
657 * which we want to send the message containing the r_key.
659 * This creates a bit of a problem for us, as we do not have the destination
660 * IP in GET_MR, so the connection must be setup prior to the GET_MR call for
661 * RDMA to be correctly setup. If a fastreg request is present, rds_iw_xmit
662 * will try to queue a LOCAL_INV (if needed) and a FAST_REG_MR work request
663 * before queuing the SEND. When completions for these arrive, they are
664 * dispatched to the MR has a bit set showing that RDMa can be performed.
666 * There is another interesting aspect that's related to invalidation.
667 * The application can request that a mapping is invalidated in FREE_MR.
668 * The expectation there is that this invalidation step includes ALL
669 * PREVIOUSLY FREED MRs.
671 static int rds_iw_init_fastreg(struct rds_iw_mr_pool
*pool
,
672 struct rds_iw_mr
*ibmr
)
674 struct rds_iw_device
*rds_iwdev
= pool
->device
;
675 struct ib_fast_reg_page_list
*page_list
= NULL
;
679 mr
= ib_alloc_fast_reg_mr(rds_iwdev
->pd
, pool
->max_message_size
);
683 printk(KERN_WARNING
"RDS/IW: ib_alloc_fast_reg_mr failed (err=%d)\n", err
);
687 /* FIXME - this is overkill, but mapping->m_sg.dma_len/mapping->m_sg.dma_npages
690 page_list
= ib_alloc_fast_reg_page_list(rds_iwdev
->dev
, pool
->max_message_size
);
691 if (IS_ERR(page_list
)) {
692 err
= PTR_ERR(page_list
);
694 printk(KERN_WARNING
"RDS/IW: ib_alloc_fast_reg_page_list failed (err=%d)\n", err
);
699 ibmr
->page_list
= page_list
;
704 static int rds_iw_rdma_build_fastreg(struct rds_iw_mapping
*mapping
)
706 struct rds_iw_mr
*ibmr
= mapping
->m_mr
;
707 struct ib_send_wr f_wr
, *failed_wr
;
711 * Perform a WR for the fast_reg_mr. Each individual page
712 * in the sg list is added to the fast reg page list and placed
713 * inside the fast_reg_mr WR. The key used is a rolling 8bit
714 * counter, which should guarantee uniqueness.
716 ib_update_fast_reg_key(ibmr
->mr
, ibmr
->remap_count
++);
717 mapping
->m_rkey
= ibmr
->mr
->rkey
;
719 memset(&f_wr
, 0, sizeof(f_wr
));
720 f_wr
.wr_id
= RDS_IW_FAST_REG_WR_ID
;
721 f_wr
.opcode
= IB_WR_FAST_REG_MR
;
722 f_wr
.wr
.fast_reg
.length
= mapping
->m_sg
.bytes
;
723 f_wr
.wr
.fast_reg
.rkey
= mapping
->m_rkey
;
724 f_wr
.wr
.fast_reg
.page_list
= ibmr
->page_list
;
725 f_wr
.wr
.fast_reg
.page_list_len
= mapping
->m_sg
.dma_len
;
726 f_wr
.wr
.fast_reg
.page_shift
= PAGE_SHIFT
;
727 f_wr
.wr
.fast_reg
.access_flags
= IB_ACCESS_LOCAL_WRITE
|
728 IB_ACCESS_REMOTE_READ
|
729 IB_ACCESS_REMOTE_WRITE
;
730 f_wr
.wr
.fast_reg
.iova_start
= 0;
731 f_wr
.send_flags
= IB_SEND_SIGNALED
;
734 ret
= ib_post_send(ibmr
->cm_id
->qp
, &f_wr
, &failed_wr
);
735 BUG_ON(failed_wr
!= &f_wr
);
737 printk_ratelimited(KERN_WARNING
"RDS/IW: %s:%d ib_post_send returned %d\n",
738 __func__
, __LINE__
, ret
);
742 static int rds_iw_rdma_fastreg_inv(struct rds_iw_mr
*ibmr
)
744 struct ib_send_wr s_wr
, *failed_wr
;
747 if (!ibmr
->cm_id
->qp
|| !ibmr
->mr
)
750 memset(&s_wr
, 0, sizeof(s_wr
));
751 s_wr
.wr_id
= RDS_IW_LOCAL_INV_WR_ID
;
752 s_wr
.opcode
= IB_WR_LOCAL_INV
;
753 s_wr
.ex
.invalidate_rkey
= ibmr
->mr
->rkey
;
754 s_wr
.send_flags
= IB_SEND_SIGNALED
;
757 ret
= ib_post_send(ibmr
->cm_id
->qp
, &s_wr
, &failed_wr
);
759 printk_ratelimited(KERN_WARNING
"RDS/IW: %s:%d ib_post_send returned %d\n",
760 __func__
, __LINE__
, ret
);
767 static int rds_iw_map_fastreg(struct rds_iw_mr_pool
*pool
,
768 struct rds_iw_mr
*ibmr
,
769 struct scatterlist
*sg
,
772 struct rds_iw_device
*rds_iwdev
= pool
->device
;
773 struct rds_iw_mapping
*mapping
= &ibmr
->mapping
;
777 rds_iw_set_scatterlist(&mapping
->m_sg
, sg
, sg_len
);
779 dma_pages
= rds_iw_map_scatterlist(rds_iwdev
, &mapping
->m_sg
);
780 if (IS_ERR(dma_pages
)) {
781 ret
= PTR_ERR(dma_pages
);
786 if (mapping
->m_sg
.dma_len
> pool
->max_message_size
) {
791 for (i
= 0; i
< mapping
->m_sg
.dma_npages
; ++i
)
792 ibmr
->page_list
->page_list
[i
] = dma_pages
[i
];
794 ret
= rds_iw_rdma_build_fastreg(mapping
);
798 rds_iw_stats_inc(s_iw_rdma_mr_used
);
807 * "Free" a fastreg MR.
809 static void rds_iw_free_fastreg(struct rds_iw_mr_pool
*pool
,
810 struct rds_iw_mr
*ibmr
)
815 if (!ibmr
->mapping
.m_sg
.dma_len
)
818 ret
= rds_iw_rdma_fastreg_inv(ibmr
);
822 /* Try to post the LOCAL_INV WR to the queue. */
823 spin_lock_irqsave(&pool
->list_lock
, flags
);
825 list_add_tail(&ibmr
->mapping
.m_list
, &pool
->dirty_list
);
826 atomic_add(ibmr
->mapping
.m_sg
.len
, &pool
->free_pinned
);
827 atomic_inc(&pool
->dirty_count
);
829 spin_unlock_irqrestore(&pool
->list_lock
, flags
);
832 static unsigned int rds_iw_unmap_fastreg_list(struct rds_iw_mr_pool
*pool
,
833 struct list_head
*unmap_list
,
834 struct list_head
*kill_list
,
837 struct rds_iw_mapping
*mapping
, *next
;
838 unsigned int ncleaned
= 0;
839 LIST_HEAD(laundered
);
841 /* Batched invalidation of fastreg MRs.
842 * Why do we do it this way, even though we could pipeline unmap
843 * and remap? The reason is the application semantics - when the
844 * application requests an invalidation of MRs, it expects all
845 * previously released R_Keys to become invalid.
847 * If we implement MR reuse naively, we risk memory corruption
848 * (this has actually been observed). So the default behavior
849 * requires that a MR goes through an explicit unmap operation before
850 * we can reuse it again.
852 * We could probably improve on this a little, by allowing immediate
853 * reuse of a MR on the same socket (eg you could add small
854 * cache of unused MRs to strct rds_socket - GET_MR could grab one
855 * of these without requiring an explicit invalidate).
857 while (!list_empty(unmap_list
)) {
860 spin_lock_irqsave(&pool
->list_lock
, flags
);
861 list_for_each_entry_safe(mapping
, next
, unmap_list
, m_list
) {
862 *unpinned
+= mapping
->m_sg
.len
;
863 list_move(&mapping
->m_list
, &laundered
);
866 spin_unlock_irqrestore(&pool
->list_lock
, flags
);
869 /* Move all laundered mappings back to the unmap list.
870 * We do not kill any WRs right now - it doesn't seem the
871 * fastreg API has a max_remap limit. */
872 list_splice_init(&laundered
, unmap_list
);
877 static void rds_iw_destroy_fastreg(struct rds_iw_mr_pool
*pool
,
878 struct rds_iw_mr
*ibmr
)
881 ib_free_fast_reg_page_list(ibmr
->page_list
);
883 ib_dereg_mr(ibmr
->mr
);