xref: /titanic_51/usr/src/uts/common/io/ib/ibtl/ibtl_mem.c (revision 17a2b317610f531d565bf4e940433aab2d9e6985)
1 /*
2  * CDDL HEADER START
3  *
4  * The contents of this file are subject to the terms of the
5  * Common Development and Distribution License (the "License").
6  * You may not use this file except in compliance with the License.
7  *
8  * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9  * or http://www.opensolaris.org/os/licensing.
10  * See the License for the specific language governing permissions
11  * and limitations under the License.
12  *
13  * When distributing Covered Code, include this CDDL HEADER in each
14  * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15  * If applicable, add the following below this CDDL HEADER, with the
16  * fields enclosed by brackets "[]" replaced with your own identifying
17  * information: Portions Copyright [yyyy] [name of copyright owner]
18  *
19  * CDDL HEADER END
20  */
21 /*
22  * Copyright (c) 2003, 2010, Oracle and/or its affiliates. All rights reserved.
23  */
24 
25 
26 #include <sys/ib/ibtl/impl/ibtl.h>
27 
28 /*
29  * ibtl_mem.c
30  *    These routines implement all of the Memory Region verbs and the alloc/
31  *    query/free Memory Window verbs at the TI interface.
32  */
33 
34 static char ibtl_mem[] = "ibtl_mem";
35 
36 /*
37  * Function:
38  *	ibt_register_mr()
39  * Input:
40  *	hca_hdl   - HCA Handle.
41  *	pd        - Protection Domain Handle.
42  *	mem_attr  - Requested memory region attributes.
43  * Output:
44  *	mr_hdl_p  - The returned IBT memory region handle.
45  *	mem_desc  - Returned memory descriptor.
46  * Returns:
47  *      IBT_SUCCESS
48  *	IBT_CHAN_HDL_INVALID
49  *	IBT_MR_VA_INVALID
50  *	IBT_MR_LEN_INVALID
51  *	IBT_MR_ACCESS_REQ_INVALID
52  *	IBT_PD_HDL_INVALID
53  *	IBT_INSUFF_RESOURCE
54  * Description:
55  *    Prepares a virtually addressed memory region for use by a HCA. A
56  *    description of the registered memory suitable for use in Work Requests
57  *    (WRs) is returned in the ibt_mr_desc_t parameter.
58  */
59 ibt_status_t
60 ibt_register_mr(ibt_hca_hdl_t hca_hdl, ibt_pd_hdl_t pd, ibt_mr_attr_t *mem_attr,
61     ibt_mr_hdl_t *mr_hdl_p, ibt_mr_desc_t *mem_desc)
62 {
63 	ib_vaddr_t 	vaddr;
64 	ibt_status_t 	status;
65 
66 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_register_mr(%p, %p, %p)",
67 	    hca_hdl, pd, mem_attr);
68 
69 	vaddr = mem_attr->mr_vaddr;
70 
71 	status = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_register_mr(
72 	    IBTL_HCA2CIHCA(hca_hdl), pd, mem_attr, IBTL_HCA2CLNT(hca_hdl),
73 	    mr_hdl_p, mem_desc);
74 	if (status == IBT_SUCCESS) {
75 		mem_desc->md_vaddr = vaddr;
76 		atomic_inc_32(&hca_hdl->ha_mr_cnt);
77 	}
78 
79 	return (status);
80 }
81 
82 
83 /*
84  * Function:
85  *	ibt_register_buf()
86  * Input:
87  *	hca_hdl		HCA Handle.
88  *	pd		Protection Domain Handle.
89  *	mem_bpattr	Memory Registration attributes (IOVA and flags).
90  *	bp		A pointer to a buf(9S) struct.
91  * Output:
92  *	mr_hdl_p	The returned IBT memory region handle.
93  *	mem_desc	Returned memory descriptor.
94  * Returns:
95  *      IBT_SUCCESS
96  *	IBT_CHAN_HDL_INVALID
97  *	IBT_MR_VA_INVALID
98  *	IBT_MR_LEN_INVALID
99  *	IBT_MR_ACCESS_REQ_INVALID
100  *	IBT_PD_HDL_INVALID
101  *	IBT_INSUFF_RESOURCE
102  * Description:
103  *	Prepares a memory region described by a buf(9S) struct for use by a HCA.
104  *	A description of the registered memory suitable for use in
105  *	Work Requests (WRs) is returned in the ibt_mr_desc_t parameter.
106  */
107 ibt_status_t
108 ibt_register_buf(ibt_hca_hdl_t hca_hdl, ibt_pd_hdl_t pd,
109     ibt_smr_attr_t *mem_bpattr, struct buf *bp, ibt_mr_hdl_t *mr_hdl_p,
110     ibt_mr_desc_t *mem_desc)
111 {
112 	ibt_status_t 	status;
113 
114 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_register_buf(%p, %p, %p, %p)",
115 	    hca_hdl, pd, mem_bpattr, bp);
116 
117 	status = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_register_buf(
118 	    IBTL_HCA2CIHCA(hca_hdl), pd, mem_bpattr, bp, IBTL_HCA2CLNT(hca_hdl),
119 	    mr_hdl_p, mem_desc);
120 	if (status == IBT_SUCCESS) {
121 		atomic_inc_32(&hca_hdl->ha_mr_cnt);
122 	}
123 
124 	return (status);
125 }
126 
127 
128 /*
129  * Function:
130  *	ibt_query_mr()
131  * Input:
132  *	hca_hdl   - HCA Handle.
133  *	mr_hdl    - The IBT Memory Region handle.
134  * Output:
135  *      attr      - The pointer to Memory region attributes structure.
136  * Returns:
137  *      IBT_SUCCESS
138  *	IBT_CHAN_HDL_INVALID
139  *	IBT_MR_HDL_INVALID
140  * Description:
141  *    Retrieves information about a specified memory region.
142  */
143 ibt_status_t
144 ibt_query_mr(ibt_hca_hdl_t hca_hdl, ibt_mr_hdl_t mr_hdl,
145     ibt_mr_query_attr_t *attr)
146 {
147 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_query_mr(%p, %p)", hca_hdl, mr_hdl);
148 
149 	return (IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_query_mr(
150 	    IBTL_HCA2CIHCA(hca_hdl), mr_hdl, attr));
151 }
152 
153 
154 /*
155  * Function:
156  *	ibt_deregister_mr()
157  * Input:
158  *	hca_hdl   - HCA Handle.
159  *	mr_hdl    - The IBT Memory Region handle.
160  * Output:
161  *      none.
162  * Returns:
163  *      IBT_SUCCESS
164  *	IBT_CHAN_HDL_INVALID
165  *	IBT_MR_HDL_INVALID
166  *	IBT_MR_IN_USE
167  * Description:
168  *    De-register the registered memory region. Remove a memory region from a
169  *    HCA translation table, and free all resources associated with the
170  *    memory region.
171  */
172 ibt_status_t
173 ibt_deregister_mr(ibt_hca_hdl_t hca_hdl, ibt_mr_hdl_t mr_hdl)
174 {
175 	ibt_status_t 	status;
176 
177 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_deregister_mr(%p, %p)", hca_hdl, mr_hdl);
178 
179 	status = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_deregister_mr(
180 	    IBTL_HCA2CIHCA(hca_hdl), mr_hdl);
181 	if (status == IBT_SUCCESS) {
182 		atomic_dec_32(&hca_hdl->ha_mr_cnt);
183 	}
184 	return (status);
185 }
186 
187 
188 /*
189  * Function:
190  *	ibt_reregister_mr()
191  * Input:
192  *	hca_hdl   - HCA Handle.
193  *	mr_hdl    - The IBT Memory Region handle.
194  *	pd        - Optional Protection Domain Handle.
195  *	mem_attr  - Requested memory region attributes.
196  * Output:
197  *	mr_hdl_p  - The reregistered IBT memory region handle.
198  *	mem_desc  - Returned memory descriptor for the new memory region.
199  * Returns:
200  *      IBT_SUCCESS
201  *	IBT_CHAN_HDL_INVALID
202  *	IBT_MR_HDL_INVALID
203  *	IBT_MR_VA_INVALID
204  *	IBT_MR_LEN_INVALID
205  *	IBT_MR_ACCESS_REQ_INVALID
206  *	IBT_PD_HDL_INVALID
207  *	IBT_INSUFF_RESOURCE
208  *	IBT_MR_IN_USE
209  * Description:
210  *    Modify the attributes of an existing memory region.
211  */
212 ibt_status_t
213 ibt_reregister_mr(ibt_hca_hdl_t hca_hdl, ibt_mr_hdl_t mr_hdl, ibt_pd_hdl_t pd,
214     ibt_mr_attr_t *mem_attr, ibt_mr_hdl_t *mr_hdl_p, ibt_mr_desc_t *mem_desc)
215 {
216 	ibt_status_t 	status;
217 	ib_vaddr_t 	vaddr = mem_attr->mr_vaddr;
218 
219 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_reregister_mr(%p, %p, %p, %p)",
220 	    hca_hdl, mr_hdl, pd, mem_attr);
221 
222 	status = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_reregister_mr(
223 	    IBTL_HCA2CIHCA(hca_hdl), mr_hdl, pd, mem_attr,
224 	    IBTL_HCA2CLNT(hca_hdl), mr_hdl_p, mem_desc);
225 
226 	if (status == IBT_SUCCESS)
227 		mem_desc->md_vaddr = vaddr;
228 	else if (!(status == IBT_MR_IN_USE || status == IBT_HCA_HDL_INVALID ||
229 	    status == IBT_MR_HDL_INVALID)) {
230 
231 		IBTF_DPRINTF_L2(ibtl_mem, "ibt_reregister_mr: "
232 		    "Re-registration Failed: %d", status);
233 
234 		/* we lost one memory region resource */
235 		atomic_dec_32(&hca_hdl->ha_mr_cnt);
236 	}
237 
238 	return (status);
239 }
240 
241 
242 /*
243  * Function:
244  *	ibt_reregister_buf()
245  * Input:
246  *	hca_hdl		HCA Handle.
247  *	mr_hdl		The IBT Memory Region handle.
248  *	pd		Optional Protection Domain Handle.
249  *	mem_bpattr	Memory Registration attributes (IOVA and flags).
250  *	bp		A pointer to a buf(9S) struct.
251  * Output:
252  *	mr_hdl_p	The reregistered IBT memory region handle.
253  *	mem_desc	Returned memory descriptor for the new memory region.
254  * Returns:
255  *      IBT_SUCCESS
256  *	IBT_CHAN_HDL_INVALID
257  *	IBT_MR_HDL_INVALID
258  *	IBT_MR_VA_INVALID
259  *	IBT_MR_LEN_INVALID
260  *	IBT_MR_ACCESS_REQ_INVALID
261  *	IBT_PD_HDL_INVALID
262  *	IBT_INSUFF_RESOURCE
263  *	IBT_MR_IN_USE
264  * Description:
265  *	Modify the attributes of an existing memory region as described by a
266  *	buf(9S) struct for use by a HCA.  A description of the registered
267  *	memory suitable for use in Work Requests (WRs) is returned in the
268  *	ibt_mr_desc_t parameter.
269  */
270 ibt_status_t
271 ibt_reregister_buf(ibt_hca_hdl_t hca_hdl, ibt_mr_hdl_t mr_hdl,
272     ibt_pd_hdl_t pd, ibt_smr_attr_t *mem_bpattr, struct buf *bp,
273     ibt_mr_hdl_t *mr_hdl_p, ibt_mr_desc_t *mem_desc)
274 {
275 	ibt_status_t 		status;
276 
277 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_reregister_buf(%p, %p, %p, %p, %p)",
278 	    hca_hdl, mr_hdl, pd, mem_bpattr, bp);
279 
280 	status = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_reregister_buf(
281 	    IBTL_HCA2CIHCA(hca_hdl), mr_hdl, pd, mem_bpattr, bp,
282 	    IBTL_HCA2CLNT(hca_hdl), mr_hdl_p, mem_desc);
283 
284 	if (!(status == IBT_SUCCESS || status == IBT_MR_IN_USE ||
285 	    status == IBT_HCA_HDL_INVALID || status == IBT_MR_HDL_INVALID)) {
286 
287 		IBTF_DPRINTF_L2(ibtl_mem, "ibt_reregister_buf: "
288 		    "Re-registration Mem Failed: %d", status);
289 
290 		/* we lost one memory region resource */
291 		atomic_dec_32(&hca_hdl->ha_mr_cnt);
292 	}
293 	return (status);
294 }
295 
296 
297 /*
298  * Function:
299  *	ibt_register_shared_mr()
300  * Input:
301  *	hca_hdl   - HCA Handle.
302  *	mr_hdl    - The IBT Memory Region handle.
303  *	pd        - Protection Domain Handle.
304  *	mem_sattr - Requested memory region shared attributes.
305  * Output:
306  *	mr_hdl_p  - The reregistered IBT memory region handle.
307  *	mem_desc  - Returned memory descriptor for the new memory region.
308  * Returns:
309  *      IBT_SUCCESS
310  *	IBT_INSUFF_RESOURCE
311  *	IBT_CHAN_HDL_INVALID
312  *	IBT_MR_HDL_INVALID
313  *	IBT_PD_HDL_INVALID
314  *	IBT_MR_ACCESS_REQ_INVALID
315  * Description:
316  *    Given an existing memory region, a new memory region associated with
317  *    the same physical locations is created.
318  */
319 ibt_status_t
320 ibt_register_shared_mr(ibt_hca_hdl_t hca_hdl, ibt_mr_hdl_t mr_hdl,
321     ibt_pd_hdl_t pd, ibt_smr_attr_t *mem_sattr, ibt_mr_hdl_t *mr_hdl_p,
322     ibt_mr_desc_t *mem_desc)
323 {
324 	ibt_status_t		status;
325 
326 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_register_shared_mr(%p, %p, %p, %p)",
327 	    hca_hdl, mr_hdl, pd, mem_sattr);
328 
329 	status = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_register_shared_mr(
330 	    IBTL_HCA2CIHCA(hca_hdl), mr_hdl, pd, mem_sattr,
331 	    IBTL_HCA2CLNT(hca_hdl), mr_hdl_p, mem_desc);
332 	if (status == IBT_SUCCESS) {
333 		atomic_inc_32(&hca_hdl->ha_mr_cnt);
334 	}
335 	return (status);
336 }
337 
338 /*
339  * Function:
340  *	ibt_sync_mr()
341  * Input:
342  *	hca_hdl		- HCA Handle.
343  *	mr_segments	- A pointer to an array of ibt_mr_sync_t that describes
344  *			  the memory regions to sync.
345  *	num_segments	- The length of the mr_segments array.
346  * Output:
347  *	NONE
348  * Returns:
349  *      IBT_SUCCESS
350  *	IBT_HCA_HDL_INVALID
351  *	IBT_MR_HDL_INVALID
352  *	IBT_INVALID_PARAM
353  *	IBT_MR_VA_INVALID
354  *	IBT_MR_LEN_INVALID
355  * Description:
356  *	Make memory changes visible to incoming RDMA reads, or make the affects
357  *	of an incoming RDMA writes visible to the consumer.
358  */
359 ibt_status_t
360 ibt_sync_mr(ibt_hca_hdl_t hca_hdl, ibt_mr_sync_t *mr_segments,
361     size_t num_segments)
362 
363 {
364 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_sync_mr(%p, %p, %d)", hca_hdl,
365 	    mr_segments, num_segments);
366 
367 	return (IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_sync_mr(
368 	    IBTL_HCA2CIHCA(hca_hdl), mr_segments, num_segments));
369 }
370 
371 
372 /*
373  * Function:
374  *	ibt_alloc_mw()
375  * Input:
376  *	hca_hdl   - HCA Handle.
377  *	pd        - Protection Domain Handle.
378  *	flags     - Memory Window alloc flags.
379  * Output:
380  *	mw_hdl_p  - The returned IBT Memory Window handle.
381  *	rkey      - The IBT R_Key handle.
382  * Returns:
383  *      IBT_SUCCESS
384  *	IBT_INSUFF_RESOURCE
385  *	IBT_CHAN_HDL_INVALID
386  *	IBT_PD_HDL_INVALID
387  * Description:
388  *    Allocate a memory window from the HCA.
389  */
390 ibt_status_t
391 ibt_alloc_mw(ibt_hca_hdl_t hca_hdl, ibt_pd_hdl_t pd, ibt_mw_flags_t flags,
392     ibt_mw_hdl_t *mw_hdl_p, ibt_rkey_t *rkey)
393 {
394 	ibt_status_t		status;
395 
396 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_alloc_mw(%p, %p, 0x%x)",
397 	    hca_hdl, pd, flags);
398 
399 	status = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_alloc_mw(
400 	    IBTL_HCA2CIHCA(hca_hdl), pd, flags, mw_hdl_p, rkey);
401 
402 	/*
403 	 * XXX - We should be able to allocate state and have a IBTF Memory
404 	 * Window Handle. Memory Windows are meant to be rebound on the fly
405 	 * (using a post) to make them fast. It is expected that alloc memory
406 	 * window will be done in a relatively static manner. But, we don't have
407 	 * a good reason to have local MW state at this point, so we won't.
408 	 */
409 	if (status == IBT_SUCCESS) {
410 		atomic_inc_32(&hca_hdl->ha_mw_cnt);
411 	}
412 	return (status);
413 }
414 
415 
416 /*
417  * Function:
418  *	ibt_query_mw()
419  * Input:
420  *	hca_hdl   - HCA Handle.
421  *	mw_hdl    - The IBT Memory Window handle.
422  * Output:
423  *	pd        - Protection Domain Handle.
424  *	rkey      - The IBT R_Key handle.
425  * Returns:
426  *      IBT_SUCCESS
427  *	IBT_CHAN_HDL_INVALID
428  *	IBT_MW_HDL_INVALID
429  * Description:
430  *    Retrieves information about a specified memory region.
431  */
432 ibt_status_t
433 ibt_query_mw(ibt_hca_hdl_t hca_hdl, ibt_mw_hdl_t mw_hdl,
434     ibt_mw_query_attr_t *mw_attr_p)
435 {
436 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_query_mw(%p, %p)", hca_hdl, mw_hdl);
437 
438 	return (IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_query_mw(
439 	    IBTL_HCA2CIHCA(hca_hdl), mw_hdl, mw_attr_p));
440 }
441 
442 
443 /*
444  * Function:
445  *	ibt_free_mw()
446  * Input:
447  *      hca_hdl   - HCA Handle
448  *	mw_hdl    - The IBT Memory Window handle.
449  * Output:
450  *	none.
451  * Returns:
452  *      IBT_SUCCESS
453  *	IBT_CHAN_HDL_INVALID
454  *	IBT_MW_HDL_INVALID
455  * Description:
456  *    De-allocate the Memory Window.
457  */
458 ibt_status_t
459 ibt_free_mw(ibt_hca_hdl_t hca_hdl, ibt_mw_hdl_t mw_hdl)
460 {
461 	ibt_status_t		status;
462 
463 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_free_mw(%p, %p)", hca_hdl, mw_hdl);
464 
465 	status = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_free_mw(
466 	    IBTL_HCA2CIHCA(hca_hdl), mw_hdl);
467 
468 	if (status == IBT_SUCCESS) {
469 		atomic_dec_32(&hca_hdl->ha_mw_cnt);
470 	}
471 	return (status);
472 }
473 
474 
475 /*
476  * Function:
477  *	ibt_map_mem_area()
478  * Input:
479  *      hca_hdl		HCA Handle
480  *	va_attrs	A pointer to an ibt_va_attr_t that describes the
481  *			VA to be translated.
482  *	paddr_list_len	The number of entries in the 'paddr_list_p' array.
483  * Output:
484  *	paddr_list_p	Array of ibt_phys_buf_t (allocated by the caller),
485  *			in which the physical buffers that map the virtual
486  *			buffer are returned.
487  *	num_paddr_p	The actual number of ibt_phys_buf_t that were
488  *			returned in the 'paddr_list_p' array.
489  *	ma_hdl_p	Memory Area Handle.
490  * Returns:
491  *      IBT_SUCCESS
492  * Description:
493  * 	Translate a kernel virtual address range into HCA physical addresses.
494  *	A set of physical addresses, that can be used with "Reserved L_Key",
495  *	register physical,  and "Fast Registration Work Request" operations
496  *	is returned.
497  */
498 ibt_status_t
499 ibt_map_mem_area(ibt_hca_hdl_t hca_hdl, ibt_va_attr_t *va_attrs,
500     uint_t paddr_list_len, ibt_reg_req_t *reg_req, ibt_ma_hdl_t *ma_hdl_p)
501 {
502 	ibt_status_t	status;
503 
504 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_map_mem_area(%p, %p, %d)",
505 	    hca_hdl, va_attrs, paddr_list_len);
506 
507 	status = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_map_mem_area(
508 	    IBTL_HCA2CIHCA(hca_hdl), va_attrs,
509 	    NULL, /* IBTL_HCA2MODI_P(hca_hdl)->mi_reserved */
510 	    paddr_list_len, reg_req, ma_hdl_p);
511 	/* Not doing reference counting, which adversely effects performance */
512 
513 	return (status);
514 }
515 
516 
517 /*
518  * Function:
519  *	ibt_unmap_mem_area()
520  * Input:
521  *      hca_hdl		HCA Handle
522  *	ma_hdl		Memory Area Handle.
523  * Output:
524  *	None.
525  * Returns:
526  *      IBT_SUCCESS
527  * Description:
528  * 	Un pin physical pages pinned during an ibt_map_mem_area() call.
529  */
530 ibt_status_t
531 ibt_unmap_mem_area(ibt_hca_hdl_t hca_hdl, ibt_ma_hdl_t ma_hdl)
532 {
533 	ibt_status_t 	status;
534 
535 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_unmap_mem_area(%p, %p)",
536 	    hca_hdl, ma_hdl);
537 
538 	status = (IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_unmap_mem_area(
539 	    IBTL_HCA2CIHCA(hca_hdl), ma_hdl));
540 	/* Not doing reference counting, which adversely effects performance */
541 
542 	return (status);
543 }
544 
545 /*
546  * Function:
547  *	ibt_map_mem_iov()
548  * Input:
549  *      hca_hdl		HCA Handle
550  *	iov_attr	A pointer to an ibt_iov_attr_t that describes the
551  *			virtual ranges to be translated.
552  * Output:
553  *	wr		A pointer to the work request where the output
554  *			sgl (reserved_lkey, size, paddr) will be written.
555  *	mi_hdl_p	Memory IOV Handle.
556  * Returns:
557  *      IBT_SUCCESS
558  * Description:
559  * 	Translate an array of virtual address ranges into HCA physical
560  *	addresses, sizes, and reserved_lkey.
561  */
562 ibt_status_t
563 ibt_map_mem_iov(ibt_hca_hdl_t hca_hdl, ibt_iov_attr_t *iov_attr,
564     ibt_all_wr_t *wr, ibt_mi_hdl_t *mi_hdl_p)
565 {
566 	ibt_status_t 	status;
567 
568 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_map_mem_iov(%p, %p, %p)",
569 	    hca_hdl, iov_attr, wr);
570 
571 	status = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_map_mem_iov(
572 	    IBTL_HCA2CIHCA(hca_hdl), iov_attr, wr, mi_hdl_p);
573 	/* Not doing reference counting, which adversely effects performance */
574 
575 	return (status);
576 }
577 
578 
579 /*
580  * Function:
581  *	ibt_unmap_mem_iov()
582  * Input:
583  *      hca_hdl		HCA Handle
584  *	mi_hdl		Memory IOV Handle.
585  * Output:
586  *	None.
587  * Returns:
588  *      IBT_SUCCESS
589  * Description:
590  * 	Un pin physical pages pinned during an ibt_map_mem_iov() call.
591  */
592 ibt_status_t
593 ibt_unmap_mem_iov(ibt_hca_hdl_t hca_hdl, ibt_mi_hdl_t mi_hdl)
594 {
595 	ibt_status_t 	status;
596 
597 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_unmap_mem_iov(%p, %p)",
598 	    hca_hdl, mi_hdl);
599 
600 	status = (IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_unmap_mem_iov(
601 	    IBTL_HCA2CIHCA(hca_hdl), mi_hdl));
602 	/* Not doing reference counting, which adversely effects performance */
603 
604 	return (status);
605 }
606 
607 /*
608  * Function:
609  *	ibt_alloc_io_mem()
610  * Input:
611  *      hca_hdl		HCA Handle
612  *	size		Number of bytes to allocate
613  *	mr_flag		Possible values: IBT_MR_SLEEP, IBT_MR_NONCOHERENT
614  * Output:
615  *     	kaddrp 		Contains pointer to the virtual address of the
616  *			memory allocated by this call.  (Set to NULL if
617  *			memory allocation fails).
618  *	mem_alloc_hdl	Memory access handle returned by ibt_mem_alloc()
619  *
620  * Returns:
621  *      IBT_SUCCESS
622  *	IBT_INSUFF_RESOURCE
623  * 	IBT_HCA_HDL_INVALID
624  *	IBT_MR_ACCESS_REQ_INVALID
625  *	IBT_INVALID_PARAM
626  * Description:
627  *	Wrapper for ddi_dma_mem_alloc()
628  */
629 ibt_status_t
630 ibt_alloc_io_mem(ibt_hca_hdl_t hca_hdl, size_t size, ibt_mr_flags_t mr_flag,
631     caddr_t *kaddrp, ibt_mem_alloc_hdl_t *mem_alloc_hdl)
632 {
633 	return (IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_alloc_io_mem(
634 	    IBTL_HCA2CIHCA(hca_hdl), size, mr_flag, kaddrp,
635 	    (ibc_mem_alloc_hdl_t *)mem_alloc_hdl));
636 }
637 
638 /*
639  * Function:
640  *	ibt_free_io_mem()
641  * Input:
642  *      hca_hdl		HCA Handle
643  *	mem_alloc_hdl	Memory access handle returned by ibt_mem_alloc()
644  * Output:
645  *	None
646  *
647  * Returns:
648  *      IBT_SUCCESS
649  * Description:
650  *	Wrapper for ddi_dma_mem_free()
651  */
652 ibt_status_t
653 ibt_free_io_mem(ibt_hca_hdl_t hca_hdl, ibt_mem_alloc_hdl_t mem_alloc_hdl)
654 {
655 	return (IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_free_io_mem(
656 	    IBTL_HCA2CIHCA(hca_hdl), (ibc_mem_alloc_hdl_t)mem_alloc_hdl));
657 }
658 
659 /*
660  * Function:
661  *	ibt_alloc_lkey()
662  * Input:
663  *      hca_hdl			HCA Handle
664  *	pd			A protection domain handle.
665  *	flags			Access control.
666  *	phys_buf_list_sz	Requested size of Physical Buffer List (PBL)
667  *				resources to be allocated.
668  * Output:
669  *	mr_hdl_p		The returned IBT memory region handle.
670  *	mem_desc_p		Returned memory descriptor.
671  * Returns:
672  *      IBT_SUCCESS
673  * Description:
674  * 	Allocates physical buffer list resources for use in memory
675  *	registrations.
676  */
677 ibt_status_t
678 ibt_alloc_lkey(ibt_hca_hdl_t hca_hdl, ibt_pd_hdl_t pd, ibt_lkey_flags_t flags,
679     uint_t phys_buf_list_sz, ibt_mr_hdl_t *mr_hdl_p,
680     ibt_pmr_desc_t *mem_desc_p)
681 {
682 	ibt_status_t 	status;
683 
684 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_alloc_lkey(%p, %p, 0x%X, %d)",
685 	    hca_hdl, pd, flags, phys_buf_list_sz);
686 
687 	status = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_alloc_lkey(
688 	    IBTL_HCA2CIHCA(hca_hdl), pd, flags, phys_buf_list_sz, mr_hdl_p,
689 	    mem_desc_p);
690 	if (status == IBT_SUCCESS) {
691 		atomic_inc_32(&hca_hdl->ha_mr_cnt);
692 	}
693 
694 	return (status);
695 }
696 
697 
698 /*
699  * Function:
700  *	ibt_register_phys_mr()
701  * Input:
702  *      hca_hdl		HCA Handle
703  *	pd		A protection domain handle.
704  *	mem_pattr	Requested memory region physical attributes.
705  * Output:
706  *	mr_hdl_p	The returned IBT memory region handle.
707  *	mem_desc_p	Returned memory descriptor.
708  * Returns:
709  *      IBT_SUCCESS
710  * Description:
711  * 	Prepares a physically addressed memory region for use by a HCA.
712  */
713 ibt_status_t
714 ibt_register_phys_mr(ibt_hca_hdl_t hca_hdl, ibt_pd_hdl_t pd,
715     ibt_pmr_attr_t *mem_pattr, ibt_mr_hdl_t *mr_hdl_p,
716     ibt_pmr_desc_t *mem_desc_p)
717 {
718 	ibt_status_t 	status;
719 
720 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_register_phys_mr(%p, %p, %p)",
721 	    hca_hdl, pd, mem_pattr);
722 
723 	status = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_register_physical_mr(
724 	    IBTL_HCA2CIHCA(hca_hdl), pd, mem_pattr,
725 	    NULL, /* IBTL_HCA2MODI_P(hca_hdl)->mi_reserved */
726 	    mr_hdl_p, mem_desc_p);
727 	if (status == IBT_SUCCESS) {
728 		atomic_inc_32(&hca_hdl->ha_mr_cnt);
729 	}
730 
731 	return (status);
732 }
733 
734 
735 /*
736  * Function:
737  *	ibt_reregister_phys_mr()
738  * Input:
739  *      hca_hdl		HCA Handle
740  *	mr_hdl		The IBT memory region handle.
741  *	pd		A protection domain handle.
742  *	mem_pattr	Requested memory region physical attributes.
743  * Output:
744  *	mr_hdl_p	The returned IBT memory region handle.
745  *	mem_desc_p	Returned memory descriptor.
746  * Returns:
747  *      IBT_SUCCESS
748  * Description:
749  * 	Prepares a physically addressed memory region for use by a HCA.
750  */
751 ibt_status_t
752 ibt_reregister_phys_mr(ibt_hca_hdl_t hca_hdl, ibt_mr_hdl_t mr_hdl,
753     ibt_pd_hdl_t pd, ibt_pmr_attr_t *mem_pattr, ibt_mr_hdl_t *mr_hdl_p,
754     ibt_pmr_desc_t *mem_desc_p)
755 {
756 	ibt_status_t 	status;
757 
758 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_reregister_phys_mr(%p, %p, %p, %p)",
759 	    hca_hdl, mr_hdl, pd, mem_pattr);
760 
761 	status = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_reregister_physical_mr(
762 	    IBTL_HCA2CIHCA(hca_hdl), mr_hdl, pd, mem_pattr,
763 	    NULL, /* IBTL_HCA2MODI_P(hca_hdl)->mi_reserved */
764 	    mr_hdl_p, mem_desc_p);
765 
766 	if (!(status == IBT_SUCCESS || status == IBT_MR_IN_USE ||
767 	    status == IBT_HCA_HDL_INVALID || status == IBT_MR_HDL_INVALID)) {
768 		IBTF_DPRINTF_L2(ibtl_mem, "ibt_reregister_phys_mr: "
769 		    "Re-registration Mem Failed: %d", status);
770 
771 		/* we lost one memory region resource */
772 		atomic_dec_32(&hca_hdl->ha_mr_cnt);
773 
774 	}
775 	return (status);
776 }
777 
778 
779 /*
780  * Fast Memory Registration (FMR).
781  *
782  * ibt_create_fmr_pool
783  *      Not fast-path.
784  *      ibt_create_fmr_pool() verifies that the HCA supports FMR and allocates
785  *      and initializes an "FMR pool".  This pool contains state specific to
786  *      this registration, including the watermark setting to determine when
787  *      to sync, and the total number of FMR regions available within this pool.
788  *
789  */
790 ibt_status_t
791 ibt_create_fmr_pool(ibt_hca_hdl_t hca_hdl, ibt_pd_hdl_t pd,
792     ibt_fmr_pool_attr_t *fmr_params, ibt_fmr_pool_hdl_t *fmr_pool_p)
793 {
794 	ibt_status_t 		status;
795 
796 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_create_fmr_pool(%p, %p, %p)",
797 	    hca_hdl, pd, fmr_params);
798 
799 	status = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_create_fmr_pool(
800 	    IBTL_HCA2CIHCA(hca_hdl), pd, fmr_params, fmr_pool_p);
801 	if (status != IBT_SUCCESS) {
802 		*fmr_pool_p = NULL;
803 		return (status);
804 	}
805 
806 	/* Update the FMR resource count */
807 	atomic_inc_32(&hca_hdl->ha_fmr_pool_cnt);
808 
809 	return (status);
810 }
811 
812 
813 /*
814  * ibt_destroy_fmr_pool
815  *      ibt_destroy_fmr_pool() deallocates all of the FMR regions in a specific
816  *      pool.  All state and information regarding the pool are destroyed and
817  *      returned as free space once again.  No more use of FMR regions in this
818  *      pool are possible without a subsequent call to ibt_create_fmr_pool().
819  */
820 ibt_status_t
821 ibt_destroy_fmr_pool(ibt_hca_hdl_t hca_hdl, ibt_fmr_pool_hdl_t fmr_pool)
822 {
823 	ibt_status_t 	status;
824 
825 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_destroy_fmr_pool(%p, %p)",
826 	    hca_hdl, fmr_pool);
827 
828 	status = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_destroy_fmr_pool(
829 	    IBTL_HCA2CIHCA(hca_hdl), fmr_pool);
830 	if (status != IBT_SUCCESS) {
831 		IBTF_DPRINTF_L2(ibtl_mem, "ibt_destroy_fmr_pool: "
832 		    "CI FMR Pool destroy failed (%d)", status);
833 		return (status);
834 	}
835 
836 	atomic_dec_32(&hca_hdl->ha_fmr_pool_cnt);
837 
838 	return (status);
839 }
840 
841 /*
842  * ibt_flush_fmr_pool
843  *      ibt_flush_fmr_pool forces a flush to occur.  At the client's request,
844  *      any unmapped FMR regions (See 'ibt_deregister_mr())') are returned to
845  *      a free state.  This function allows for an asynchronous cleanup of
846  *      formerly used FMR regions.  Sync operation is also performed internally
847  *      by HCA driver, when 'watermark' settings for the number of free FMR
848  *      regions left in the "pool" is reached.
849  */
850 ibt_status_t
851 ibt_flush_fmr_pool(ibt_hca_hdl_t hca_hdl, ibt_fmr_pool_hdl_t fmr_pool)
852 {
853 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_flush_fmr_pool(%p, %p)",
854 	    hca_hdl, fmr_pool);
855 
856 	return (IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_flush_fmr_pool(
857 	    IBTL_HCA2CIHCA(hca_hdl), fmr_pool));
858 }
859 
860 /*
861  * ibt_register_physical_fmr
862  *      ibt_register_physical_fmr() assigns a "free" entry from the FMR Pool.
863  *      It first consults the "FMR cache" to see if this is a duplicate memory
864  *      registration to something already in use.  If not, then a free entry
865  *      in the "pool" is marked used.
866  */
867 ibt_status_t
868 ibt_register_physical_fmr(ibt_hca_hdl_t hca_hdl, ibt_fmr_pool_hdl_t fmr_pool,
869     ibt_pmr_attr_t *mem_pattr, ibt_mr_hdl_t *mr_hdl_p,
870     ibt_pmr_desc_t *mem_desc_p)
871 {
872 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_register_physical_fmr(%p, %p, %p, %p)",
873 	    hca_hdl, fmr_pool, mem_pattr, mem_desc_p);
874 
875 	return (IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_register_physical_fmr(
876 	    IBTL_HCA2CIHCA(hca_hdl), fmr_pool, mem_pattr,
877 	    NULL, /* IBTL_HCA2MODI_P(hca_hdl)->mi_reserved */
878 	    mr_hdl_p, mem_desc_p));
879 }
880 
881 /*
882  * ibt_deregister_fmr
883  *	The ibt_deregister_fmr un-maps the resources reserved from the FMR
884  *	pool by ibt_register_physical_fmr().   The ibt_deregister_fmr() will
885  *	mark the region as free in the FMR Pool.
886  */
887 ibt_status_t
888 ibt_deregister_fmr(ibt_hca_hdl_t hca, ibt_mr_hdl_t mr_hdl)
889 {
890 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_deregister_fmr(%p, %p)", hca, mr_hdl);
891 
892 	return (IBTL_HCA2CIHCAOPS_P(hca)->ibc_deregister_fmr(
893 	    IBTL_HCA2CIHCA(hca), mr_hdl));
894 }
895 
896 /*
897  * ibt_register_dma_mr
898  */
899 ibt_status_t
900 ibt_register_dma_mr(ibt_hca_hdl_t hca, ibt_pd_hdl_t pd,
901     ibt_dmr_attr_t *mem_attr, ibt_mr_hdl_t *mr_hdl_p, ibt_mr_desc_t *mem_desc)
902 {
903 	ibt_status_t 	status;
904 
905 	IBTF_DPRINTF_L3(ibtl_mem, "ibt_register_dma_mr(%p, %p, %p)",
906 	    hca, pd, mem_attr);
907 
908 	status = IBTL_HCA2CIHCAOPS_P(hca)->ibc_register_dma_mr(
909 	    IBTL_HCA2CIHCA(hca), pd, mem_attr, NULL, mr_hdl_p, mem_desc);
910 	if (status == IBT_SUCCESS) {
911 		atomic_inc_32(&hca->ha_mr_cnt);
912 	}
913 	return (status);
914 }
915