xref: /titanic_51/usr/src/uts/common/io/ib/ibtl/ibtl_chan.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  * ibtl_chan.c
27  *
28  * This file contains Transport API functions related to Channel Functions
29  * and internal Protection Domain and Address Handle Verbs functions.
30  */
31 
32 #include <sys/ib/ibtl/impl/ibtl.h>
33 #include <sys/ib/ibtl/impl/ibtl_cm.h>
34 #include <sys/ib/ib_pkt_hdrs.h>
35 
36 static char ibtl_chan[] = "ibtl_chan";
37 
38 /*
39  * RC Channel.
40  */
41 /*
42  * Function:
43  *	ibt_alloc_rc_channel
44  * Input:
45  *	hca_hdl		HCA Handle.
46  *	flags		Channel allocate flags.
47  *	args		A pointer to an ibt_rc_chan_alloc_args_t struct that
48  *			specifies required channel attributes.
49  * Output:
50  *	rc_chan_p	The returned RC Channel handle.
51  *	sizes		NULL or a pointer to ibt_chan_sizes_s struct where
52  *			new SendQ/RecvQ, and WR SGL sizes are returned.
53  * Returns:
54  *	IBT_SUCCESS
55  *	IBT_INVALID_PARAM
56  * Description:
57  *	Allocates a RC communication channels that satisfy the specified
58  *	channel attributes.
59  */
60 ibt_status_t
61 ibt_alloc_rc_channel(ibt_hca_hdl_t hca_hdl, ibt_chan_alloc_flags_t flags,
62     ibt_rc_chan_alloc_args_t *args, ibt_channel_hdl_t *rc_chan_p,
63     ibt_chan_sizes_t *sizes)
64 {
65 	ibt_status_t		retval;
66 	ibt_qp_alloc_attr_t	qp_attr;
67 	ibt_qp_info_t		qp_modify_attr;
68 	ibt_channel_hdl_t	chanp;
69 
70 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_alloc_rc_channel(%p, %x, %p, %p)",
71 	    hca_hdl, flags, args, sizes);
72 
73 	bzero(&qp_modify_attr, sizeof (ibt_qp_info_t));
74 
75 	qp_attr.qp_alloc_flags = IBT_QP_NO_FLAGS;
76 	if (flags & IBT_ACHAN_USER_MAP)
77 		qp_attr.qp_alloc_flags |= IBT_QP_USER_MAP;
78 
79 	if (flags & IBT_ACHAN_DEFER_ALLOC)
80 		qp_attr.qp_alloc_flags |= IBT_QP_DEFER_ALLOC;
81 
82 	if (flags & IBT_ACHAN_USES_SRQ) {
83 		if (args->rc_srq == NULL) {
84 			IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_rc_channel: "
85 			    "NULL SRQ Handle specified.");
86 			return (IBT_INVALID_PARAM);
87 		}
88 		qp_attr.qp_alloc_flags |= IBT_QP_USES_SRQ;
89 	}
90 
91 	/*
92 	 * Check if this request is to clone the channel, or to allocate a
93 	 * fresh one.
94 	 */
95 	if (flags & IBT_ACHAN_CLONE) {
96 
97 		ibt_rc_chan_query_attr_t	chan_attrs;
98 
99 		if (args->rc_clone_chan == NULL) {
100 			IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_rc_channel: "
101 			    "Clone Channel info not available.");
102 			return (IBT_INVALID_PARAM);
103 		} else if (args->rc_clone_chan->ch_qp.qp_hca != hca_hdl) {
104 			IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_rc_channel: "
105 			    "Clone Channel's & requested HCA Handle mismatch");
106 			return (IBT_INVALID_PARAM);
107 		}
108 
109 		IBTF_DPRINTF_L3(ibtl_chan, "ibt_alloc_rc_channel: "
110 		    "Clone <%p> - RC Channel", args->rc_clone_chan);
111 
112 		/*
113 		 * Query the source channel, to obtained the attributes
114 		 * so that the new channel share the same attributes.
115 		 */
116 		retval = ibt_query_rc_channel(args->rc_clone_chan, &chan_attrs);
117 		if (retval != IBT_SUCCESS) {
118 			IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_rc_channel: "
119 			    "Failed to query the source channel: %d", retval);
120 			return (retval);
121 		}
122 
123 		/* Setup QP alloc attributes. */
124 		qp_attr.qp_scq_hdl = chan_attrs.rc_scq;
125 		qp_attr.qp_rcq_hdl = chan_attrs.rc_rcq;
126 		qp_attr.qp_pd_hdl = chan_attrs.rc_pd;
127 		qp_attr.qp_flags = chan_attrs.rc_flags;
128 		qp_attr.qp_srq_hdl = chan_attrs.rc_srq;
129 
130 		bcopy(&chan_attrs.rc_chan_sizes, &qp_attr.qp_sizes,
131 		    sizeof (ibt_chan_sizes_t));
132 
133 		qp_modify_attr.qp_flags = chan_attrs.rc_control;
134 		qp_modify_attr.qp_transport.rc.rc_path.cep_hca_port_num =
135 		    chan_attrs.rc_prim_path.cep_hca_port_num;
136 		qp_modify_attr.qp_transport.rc.rc_path.cep_pkey_ix =
137 		    chan_attrs.rc_prim_path.cep_pkey_ix;
138 
139 	} else {
140 
141 		/* Setup QP alloc attributes. */
142 		qp_attr.qp_scq_hdl = args->rc_scq;
143 		qp_attr.qp_rcq_hdl = args->rc_rcq;
144 		qp_attr.qp_pd_hdl = args->rc_pd;
145 		qp_attr.qp_flags = args->rc_flags;
146 		qp_attr.qp_srq_hdl = args->rc_srq;
147 
148 		bcopy(&args->rc_sizes, &qp_attr.qp_sizes,
149 		    sizeof (ibt_chan_sizes_t));
150 
151 		qp_modify_attr.qp_flags = args->rc_control;
152 
153 		if ((args->rc_hca_port_num == 0) ||
154 		    (args->rc_hca_port_num > IBTL_HCA2NPORTS(hca_hdl))) {
155 			IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_rc_channel: "
156 			    "Invalid port_num %d, range is (1 to %d)",
157 			    args->rc_hca_port_num, IBTL_HCA2NPORTS(hca_hdl));
158 			return (IBT_HCA_PORT_INVALID);
159 		}
160 		qp_modify_attr.qp_transport.rc.rc_path.cep_hca_port_num =
161 		    args->rc_hca_port_num;
162 
163 		/*
164 		 * We allocate the Channel initially with the default PKey,
165 		 * and later client can update this when the channel is opened
166 		 * with the pkey returned from a path record lookup.
167 		 */
168 		mutex_enter(&ibtl_clnt_list_mutex);
169 		qp_modify_attr.qp_transport.rc.rc_path.cep_pkey_ix =
170 		    hca_hdl->ha_hca_devp->
171 		    hd_portinfop[args->rc_hca_port_num - 1].p_def_pkey_ix;
172 		mutex_exit(&ibtl_clnt_list_mutex);
173 	}
174 
175 	/* Allocate Channel and Initialize the channel. */
176 	retval = ibt_alloc_qp(hca_hdl, IBT_RC_RQP, &qp_attr, sizes, NULL,
177 	    &chanp);
178 	if (retval != IBT_SUCCESS) {
179 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_rc_channel: "
180 		    "Failed to allocate QP: %d", retval);
181 		*rc_chan_p = NULL;
182 		return (retval);
183 	}
184 
185 	qp_modify_attr.qp_trans = IBT_RC_SRV;
186 
187 	/* Initialize RC Channel by transitioning it to INIT State. */
188 	retval = ibt_initialize_qp(chanp, &qp_modify_attr);
189 	if (retval != IBT_SUCCESS) {
190 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_rc_channel: "
191 		    "Failed to Initialize QP: %d", retval);
192 
193 		/* Free the QP as we failed to initialize it. */
194 		(void) ibt_free_qp(chanp);
195 
196 		*rc_chan_p = NULL;
197 		return (retval);
198 	}
199 
200 	*rc_chan_p = chanp;
201 
202 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_alloc_rc_channel(%p): - SUCCESS (%p)",
203 	    hca_hdl, chanp);
204 
205 	return (IBT_SUCCESS);
206 }
207 
208 
209 /*
210  * Function:
211  *	ibt_query_rc_channel
212  * Input:
213  *	rc_chan		A previously allocated channel handle.
214  *	chan_attrs	A pointer to an ibt_rc_chan_query_args_t struct where
215  *			Channel's current attributes are returned.
216  * Output:
217  *	chan_attrs	A pointer to an ibt_rc_chan_query_args_t struct where
218  *			Channel's current attributes are returned.
219  * Returns:
220  *	IBT_SUCCESS
221  * Description:
222  *	Query an RC channel's attributes.
223  */
224 ibt_status_t
225 ibt_query_rc_channel(ibt_channel_hdl_t rc_chan,
226     ibt_rc_chan_query_attr_t *chan_attrs)
227 {
228 	ibt_status_t		retval;
229 	ibt_qp_query_attr_t	qp_attr;
230 
231 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_query_rc_channel(%p, %p)",
232 	    rc_chan, chan_attrs);
233 
234 	if (rc_chan->ch_qp.qp_type != IBT_RC_SRV) {
235 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_query_rc_channel: "
236 		    "type of channel (%d) is not RC", rc_chan->ch_qp.qp_type);
237 		return (IBT_CHAN_SRV_TYPE_INVALID);
238 	}
239 
240 	bzero(&qp_attr, sizeof (ibt_qp_query_attr_t));
241 
242 	/* Query the channel (QP) */
243 	retval = ibt_query_qp(rc_chan, &qp_attr);
244 	if (retval != IBT_SUCCESS) {
245 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_query_rc_channel: "
246 		    "ibt_query_qp failed on QP %p: %d", rc_chan, retval);
247 		return (retval);
248 	}
249 
250 	chan_attrs->rc_hca_guid = IBTL_HCA2HCAGUID(IBTL_CHAN2HCA(rc_chan));
251 
252 	chan_attrs->rc_scq = qp_attr.qp_sq_cq;
253 	chan_attrs->rc_rcq = qp_attr.qp_rq_cq;
254 	chan_attrs->rc_pd = rc_chan->ch_qp.qp_pd_hdl;
255 	chan_attrs->rc_state = qp_attr.qp_info.qp_state;
256 	chan_attrs->rc_path_mtu = qp_attr.qp_info.qp_transport.rc.rc_path_mtu;
257 	chan_attrs->rc_path_retry_cnt =
258 	    qp_attr.qp_info.qp_transport.rc.rc_retry_cnt;
259 	chan_attrs->rc_path_rnr_retry_cnt =
260 	    qp_attr.qp_info.qp_transport.rc.rc_rnr_retry_cnt;
261 	chan_attrs->rc_min_rnr_nak =
262 	    qp_attr.qp_info.qp_transport.rc.rc_min_rnr_nak;
263 
264 	chan_attrs->rc_prim_path = qp_attr.qp_info.qp_transport.rc.rc_path;
265 	chan_attrs->rc_alt_path = qp_attr.qp_info.qp_transport.rc.rc_alt_path;
266 
267 	chan_attrs->rc_chan_sizes.cs_sq = qp_attr.qp_info.qp_sq_sz;
268 	chan_attrs->rc_chan_sizes.cs_rq = qp_attr.qp_info.qp_rq_sz;
269 	chan_attrs->rc_chan_sizes.cs_sq_sgl = qp_attr.qp_sq_sgl;
270 	chan_attrs->rc_chan_sizes.cs_rq_sgl = qp_attr.qp_rq_sgl;
271 	chan_attrs->rc_srq = qp_attr.qp_srq;
272 
273 	chan_attrs->rc_rdma_ra_out =
274 	    qp_attr.qp_info.qp_transport.rc.rc_rdma_ra_out;
275 	chan_attrs->rc_rdma_ra_in =
276 	    qp_attr.qp_info.qp_transport.rc.rc_rdma_ra_in;
277 
278 	chan_attrs->rc_flags = rc_chan->ch_qp.qp_flags;
279 	chan_attrs->rc_control = qp_attr.qp_info.qp_flags;
280 	chan_attrs->rc_mig_state = qp_attr.qp_info.qp_transport.rc.rc_mig_state;
281 
282 	chan_attrs->rc_qpn = qp_attr.qp_qpn & IB_QPN_MASK;
283 	chan_attrs->rc_dst_qpn =
284 	    qp_attr.qp_info.qp_transport.rc.rc_dst_qpn & IB_QPN_MASK;
285 
286 	return (retval);
287 }
288 
289 
290 /*
291  * Function:
292  *	ibt_modify_rc_channel
293  * Input:
294  *	rc_chan		A previously allocated channel handle.
295  *	flags		Specifies which attributes in ibt_rc_chan_modify_attr_t
296  *			are to be modified.
297  *	attrs		Attributes to be modified.
298  * Output:
299  *	actual_sz	On return contains the new send and receive queue sizes.
300  * Returns:
301  *	IBT_SUCCESS
302  * Description:
303  *	Modifies an RC channel's attributes, as specified by a
304  *	ibt_cep_modify_flags_t parameter to those specified in the
305  *	ibt_rc_chan_modify_attr_t structure.
306  */
307 ibt_status_t
308 ibt_modify_rc_channel(ibt_channel_hdl_t rc_chan, ibt_cep_modify_flags_t flags,
309     ibt_rc_chan_modify_attr_t *attrs, ibt_queue_sizes_t *actual_sz)
310 {
311 	ibt_status_t		retval;
312 	ibt_qp_info_t		qp_info;
313 	int			retries = 1;
314 
315 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_modify_rc_channel(%p, %x, %p, %p)",
316 	    rc_chan, flags, attrs, actual_sz);
317 
318 	if (rc_chan->ch_qp.qp_type != IBT_RC_SRV) {
319 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_modify_rc_channel: "
320 		    "type of channel (%d) is not RC", rc_chan->ch_qp.qp_type);
321 		return (IBT_CHAN_SRV_TYPE_INVALID);
322 	}
323 
324 retry:
325 	bzero(&qp_info, sizeof (ibt_qp_info_t));
326 
327 	if (flags & IBT_CEP_SET_ADDS_VECT) {
328 		bcopy(&attrs->rc_prim_adds_vect,
329 		    &qp_info.qp_transport.rc.rc_path.cep_adds_vect,
330 		    sizeof (ibt_adds_vect_t));
331 	}
332 
333 	qp_info.qp_trans = IBT_RC_SRV;
334 	qp_info.qp_transport.rc.rc_path.cep_hca_port_num =
335 	    attrs->rc_prim_port_num;
336 	qp_info.qp_transport.rc.rc_retry_cnt = attrs->rc_path_retry_cnt;
337 	qp_info.qp_transport.rc.rc_rnr_retry_cnt =
338 	    attrs->rc_path_rnr_retry_cnt;
339 	qp_info.qp_transport.rc.rc_rdma_ra_out = attrs->rc_rdma_ra_out;
340 	qp_info.qp_transport.rc.rc_rdma_ra_in = attrs->rc_rdma_ra_in;
341 
342 	/* Current channel state must be either SQD or RTS. */
343 	qp_info.qp_current_state = rc_chan->ch_current_state;
344 	qp_info.qp_state = rc_chan->ch_current_state;	/* No Change in State */
345 
346 	qp_info.qp_flags = attrs->rc_control;
347 	qp_info.qp_sq_sz = attrs->rc_sq_sz;
348 	qp_info.qp_rq_sz = attrs->rc_rq_sz;
349 	qp_info.qp_transport.rc.rc_min_rnr_nak = attrs->rc_min_rnr_nak;
350 
351 	if (flags & IBT_CEP_SET_ALT_PATH) {
352 		bcopy(&attrs->rc_alt_adds_vect,
353 		    &qp_info.qp_transport.rc.rc_alt_path.cep_adds_vect,
354 		    sizeof (ibt_adds_vect_t));
355 		qp_info.qp_transport.rc.rc_alt_path.cep_hca_port_num =
356 		    attrs->rc_alt_port_num;
357 	}
358 
359 	flags |= IBT_CEP_SET_STATE;
360 
361 	retval = ibt_modify_qp(rc_chan, flags, &qp_info, actual_sz);
362 	if (retval != IBT_SUCCESS) {
363 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_modify_rc_channel: "
364 		    "ibt_modify_qp failed on QP %p: %d", rc_chan, retval);
365 		/* give it one more shot if the old current state was stale */
366 		if (qp_info.qp_current_state != rc_chan->ch_current_state &&
367 		    --retries >= 0 &&
368 		    (qp_info.qp_current_state == IBT_STATE_RTS ||
369 		    qp_info.qp_current_state == IBT_STATE_SQD))
370 			goto retry;
371 	}
372 
373 	return (retval);
374 }
375 
376 
377 /*
378  * UD Channel.
379  */
380 /*
381  * Function:
382  *	ibt_alloc_ud_channel
383  * Input:
384  *	hca_hdl		HCA Handle.
385  *	flags		Channel allocate flags.
386  *	args		A pointer to an ibt_ud_chan_alloc_args_t struct that
387  *			specifies required channel attributes.
388  * Output:
389  *	ud_chan_p	The returned UD Channel handle.
390  *	sizes		NULL or a pointer to ibt_chan_sizes_s struct where
391  *			new SendQ/RecvQ, and WR SGL sizes are returned.
392  * Returns:
393  *	IBT_SUCCESS
394  *	IBT_INVALID_PARAM
395  * Description:
396  *	Allocate UD channels that satisfy the specified channel attributes.
397  */
398 ibt_status_t
399 ibt_alloc_ud_channel(ibt_hca_hdl_t hca_hdl, ibt_chan_alloc_flags_t flags,
400     ibt_ud_chan_alloc_args_t *args, ibt_channel_hdl_t *ud_chan_p,
401     ibt_chan_sizes_t *sizes)
402 {
403 	ibt_status_t		retval;
404 	ibt_qp_alloc_attr_t	qp_attr;
405 	ibt_qp_info_t		qp_modify_attr;
406 	ibt_channel_hdl_t	chanp;
407 	ibt_chan_alloc_flags_t	variant_flags;
408 
409 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_alloc_ud_channel(%p, %x, %p, %p)",
410 	    hca_hdl, flags, args, sizes);
411 
412 	if (flags & IBT_ACHAN_USES_FEXCH) {
413 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ud_channel: "
414 		    "FEXCH QPs are allocated by ibt_alloc_ud_channel_range()");
415 		return (IBT_CHAN_SRV_TYPE_INVALID);
416 	}
417 
418 	bzero(&qp_modify_attr, sizeof (ibt_qp_info_t));
419 	bzero(&qp_attr, sizeof (ibt_qp_alloc_attr_t));
420 	qp_attr.qp_alloc_flags = IBT_QP_NO_FLAGS;
421 
422 	/* allow at most one of these flags */
423 	variant_flags = flags & (IBT_ACHAN_USER_MAP | IBT_ACHAN_USES_RSS |
424 	    IBT_ACHAN_USES_RFCI | IBT_ACHAN_USES_FCMD | IBT_ACHAN_CLONE);
425 	switch (variant_flags) {
426 	case IBT_ACHAN_USER_MAP:
427 		qp_attr.qp_alloc_flags |= IBT_QP_USER_MAP;
428 		break;
429 	case IBT_ACHAN_USES_RSS:
430 		qp_attr.qp_alloc_flags |= IBT_QP_USES_RSS;
431 		qp_modify_attr.qp_transport.ud.ud_rss = args->ud_rss;
432 		break;
433 	case IBT_ACHAN_USES_RFCI:
434 		qp_attr.qp_alloc_flags |= IBT_QP_USES_RFCI;
435 		qp_modify_attr.qp_transport.ud.ud_fc = qp_attr.qp_fc =
436 		    args->ud_fc;
437 		break;
438 	case IBT_ACHAN_USES_FCMD:
439 		qp_attr.qp_alloc_flags |= IBT_QP_USES_FCMD;
440 		qp_modify_attr.qp_transport.ud.ud_fc = qp_attr.qp_fc =
441 		    args->ud_fc;
442 		break;
443 	case IBT_ACHAN_CLONE:
444 	case 0:
445 		break;
446 	default:
447 		return (IBT_INVALID_PARAM);
448 	}
449 
450 	if (flags & IBT_ACHAN_DEFER_ALLOC)
451 		qp_attr.qp_alloc_flags |= IBT_QP_DEFER_ALLOC;
452 
453 	if (flags & IBT_ACHAN_USES_SRQ) {
454 		if (args->ud_srq == NULL) {
455 			IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ud_channel: "
456 			    "NULL SRQ Handle specified.");
457 			return (IBT_INVALID_PARAM);
458 		}
459 		if (flags & IBT_ACHAN_USES_RSS) {
460 			IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ud_channel: "
461 			    "SRQ not allowed with RSS.");
462 			return (IBT_INVALID_PARAM);
463 		}
464 		qp_attr.qp_alloc_flags |= IBT_QP_USES_SRQ;
465 	}
466 
467 	/*
468 	 * Check if this request is to clone the channel, or to allocate a
469 	 * fresh one.
470 	 */
471 	if (flags & IBT_ACHAN_CLONE) {
472 
473 		ibt_ud_chan_query_attr_t	chan_attrs;
474 
475 		if (args->ud_clone_chan == NULL) {
476 			IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ud_channel: "
477 			    "Clone Channel info not available.");
478 			return (IBT_INVALID_PARAM);
479 		} else if (args->ud_clone_chan->ch_qp.qp_hca != hca_hdl) {
480 			IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ud_channel: "
481 			    "Clone Channel and HCA Handle mismatch");
482 			return (IBT_INVALID_PARAM);
483 		}
484 
485 		IBTF_DPRINTF_L3(ibtl_chan, "ibt_alloc_ud_channel: "
486 		    "Clone <%p> - UD Channel", args->ud_clone_chan);
487 
488 		retval = ibt_query_ud_channel(args->ud_clone_chan, &chan_attrs);
489 		if (retval != IBT_SUCCESS) {
490 			IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ud_channel: "
491 			    "Failed to Query the source channel: %d", retval);
492 			return (retval);
493 		}
494 
495 		/* Setup QP alloc attributes. */
496 		qp_attr.qp_scq_hdl = chan_attrs.ud_scq;
497 		qp_attr.qp_rcq_hdl = chan_attrs.ud_rcq;
498 		qp_attr.qp_pd_hdl = chan_attrs.ud_pd;
499 		qp_attr.qp_flags = chan_attrs.ud_flags;
500 		qp_attr.qp_srq_hdl = chan_attrs.ud_srq;
501 
502 		bcopy(&chan_attrs.ud_chan_sizes, &qp_attr.qp_sizes,
503 		    sizeof (ibt_chan_sizes_t));
504 
505 		qp_modify_attr.qp_transport.ud.ud_port =
506 		    chan_attrs.ud_hca_port_num;
507 		qp_modify_attr.qp_transport.ud.ud_qkey = chan_attrs.ud_qkey;
508 		qp_modify_attr.qp_transport.ud.ud_pkey_ix =
509 		    chan_attrs.ud_pkey_ix;
510 	} else {
511 		ib_pkey_t	tmp_pkey;
512 
513 		/* Setup QP alloc attributes. */
514 		qp_attr.qp_scq_hdl = args->ud_scq;
515 		qp_attr.qp_rcq_hdl = args->ud_rcq;
516 		qp_attr.qp_pd_hdl = args->ud_pd;
517 		qp_attr.qp_flags = args->ud_flags;
518 		qp_attr.qp_srq_hdl = args->ud_srq;
519 
520 		bcopy(&args->ud_sizes, &qp_attr.qp_sizes,
521 		    sizeof (ibt_chan_sizes_t));
522 
523 		qp_modify_attr.qp_transport.ud.ud_port = args->ud_hca_port_num;
524 		qp_modify_attr.qp_transport.ud.ud_qkey = args->ud_qkey;
525 
526 		/* Validate input hca_port_num and pkey_ix values. */
527 		if ((retval = ibt_index2pkey(hca_hdl, args->ud_hca_port_num,
528 		    args->ud_pkey_ix, &tmp_pkey)) != IBT_SUCCESS) {
529 			IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ud_channel: "
530 			    "ibt_index2pkey failed, status: %d", retval);
531 			*ud_chan_p = NULL;
532 			return (retval);
533 		}
534 		qp_modify_attr.qp_transport.ud.ud_pkey_ix = args->ud_pkey_ix;
535 	}
536 
537 	/* Allocate Channel and Initialize the channel. */
538 	retval = ibt_alloc_qp(hca_hdl, IBT_UD_RQP, &qp_attr, sizes, NULL,
539 	    &chanp);
540 	if (retval != IBT_SUCCESS) {
541 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ud_channel: "
542 		    "Failed to allocate QP: %d", retval);
543 		*ud_chan_p = NULL;
544 		return (retval);
545 	}
546 
547 	/* Initialize UD Channel by transitioning it to RTS State. */
548 	qp_modify_attr.qp_trans = IBT_UD_SRV;
549 	qp_modify_attr.qp_flags = IBT_CEP_NO_FLAGS;
550 	qp_modify_attr.qp_transport.ud.ud_sq_psn = 0;
551 
552 	retval = ibt_initialize_qp(chanp, &qp_modify_attr);
553 	if (retval != IBT_SUCCESS) {
554 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ud_channel: "
555 		    "Failed to Initialize QP: %d", retval);
556 
557 		/* Free the QP as we failed to initialize it. */
558 		(void) ibt_free_qp(chanp);
559 
560 		*ud_chan_p = NULL;
561 		return (retval);
562 	}
563 
564 	*ud_chan_p = chanp;
565 
566 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_alloc_ud_channel(%p): - SUCCESS (%p)",
567 	    hca_hdl, chanp);
568 
569 	return (IBT_SUCCESS);
570 }
571 
572 
573 /*
574  * Function:
575  *	ibt_alloc_ud_channel_range
576  * Input:
577  *	hca_hdl		HCA Handle.
578  *	log2		Log (base 2) of the number of QPs to allocate.
579  *	flags		Channel allocate flags.
580  *	args		A pointer to an ibt_ud_chan_alloc_args_t struct that
581  *			specifies required channel attributes.
582  *	send_cq		A pointer to an array of CQ handles.
583  *	recv_cq		A pointer to an array of CQ handles.
584  * Output:
585  *	base_qpn_p	The returned QP number of the base QP.
586  *	ud_chan_p	The returned UD Channel handle.
587  *	sizes		NULL or a pointer to ibt_chan_sizes_s struct where
588  *			new SendQ/RecvQ, and WR SGL sizes are returned.
589  * Returns:
590  *	IBT_SUCCESS
591  *	IBT_INVALID_PARAM
592  * Description:
593  *	Allocate UD channels that satisfy the specified channel attributes.
594  */
595 ibt_status_t
596 ibt_alloc_ud_channel_range(ibt_hca_hdl_t hca_hdl, uint_t log2,
597     ibt_chan_alloc_flags_t flags, ibt_ud_chan_alloc_args_t *args,
598     ibt_cq_hdl_t *send_cq, ibt_cq_hdl_t *recv_cq, ib_qpn_t *base_qpn_p,
599     ibt_channel_hdl_t *ud_chan_p, ibt_chan_sizes_t *sizes)
600 {
601 	ibt_status_t		retval;
602 	ibt_qp_alloc_attr_t	qp_attr;
603 	ibt_qp_info_t		qp_modify_attr;
604 	ibtl_channel_t		*chanp;
605 	ibt_cq_hdl_t		ibt_cq_hdl;
606 	ibc_cq_hdl_t		*ibc_send_cq, *ibc_recv_cq;
607 	ibc_qp_hdl_t		*ibc_qp_hdl_p;
608 	int			i, n = 1 << log2;
609 	ib_pkey_t		tmp_pkey;
610 
611 
612 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_alloc_ud_channel_range(%p, %x, %p, %p)",
613 	    hca_hdl, flags, args, sizes);
614 
615 	bzero(&qp_modify_attr, sizeof (ibt_qp_info_t));
616 
617 	qp_attr.qp_alloc_flags = IBT_QP_NO_FLAGS;
618 
619 	if (flags & IBT_ACHAN_CLONE)
620 		return (IBT_INVALID_PARAM);
621 
622 	if (flags & IBT_ACHAN_USER_MAP)
623 		qp_attr.qp_alloc_flags |= IBT_QP_USER_MAP;
624 
625 	if (flags & IBT_ACHAN_DEFER_ALLOC)
626 		qp_attr.qp_alloc_flags |= IBT_QP_DEFER_ALLOC;
627 
628 	if (flags & IBT_ACHAN_USES_SRQ) {
629 		if (args->ud_srq == NULL) {
630 			IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ud_channel: "
631 			    "NULL SRQ Handle specified.");
632 			return (IBT_INVALID_PARAM);
633 		}
634 		qp_attr.qp_alloc_flags |= IBT_QP_USES_SRQ;
635 	}
636 
637 	if (flags & IBT_ACHAN_USES_FEXCH) {
638 		qp_attr.qp_alloc_flags |= IBT_QP_USES_FEXCH;
639 		qp_attr.qp_fc = args->ud_fc;
640 		qp_modify_attr.qp_transport.ud.ud_fc = qp_attr.qp_fc =
641 		    args->ud_fc;
642 	}
643 	if (flags & IBT_ACHAN_USES_RSS) {
644 		if (log2 >
645 		    hca_hdl->ha_hca_devp->hd_hca_attr->hca_rss_max_log2_table)
646 			return (IBT_INSUFF_RESOURCE);
647 		qp_attr.qp_alloc_flags |= IBT_QP_USES_RSS;
648 	}
649 
650 	ibc_send_cq = kmem_alloc(sizeof (ibc_cq_hdl_t) << log2, KM_SLEEP);
651 	ibc_recv_cq = kmem_alloc(sizeof (ibc_cq_hdl_t) << log2, KM_SLEEP);
652 	ibc_qp_hdl_p = kmem_alloc(sizeof (ibc_qp_hdl_t) << log2, KM_SLEEP);
653 
654 	for (i = 0; i < 1 << log2; i++) {
655 		ud_chan_p[i] = kmem_zalloc(sizeof (ibtl_channel_t), KM_SLEEP);
656 		ibt_cq_hdl = send_cq[i];
657 		ibc_send_cq[i] = ibt_cq_hdl ? ibt_cq_hdl->cq_ibc_cq_hdl : NULL;
658 		ibt_cq_hdl = recv_cq[i];
659 		ibc_recv_cq[i] = ibt_cq_hdl ? ibt_cq_hdl->cq_ibc_cq_hdl : NULL;
660 	}
661 
662 	/* Setup QP alloc attributes. */
663 	qp_attr.qp_pd_hdl = args->ud_pd;
664 	qp_attr.qp_flags = args->ud_flags;
665 	qp_attr.qp_srq_hdl = args->ud_srq;
666 
667 	bcopy(&args->ud_sizes, &qp_attr.qp_sizes,
668 	    sizeof (ibt_chan_sizes_t));
669 
670 	qp_modify_attr.qp_transport.ud.ud_port = args->ud_hca_port_num;
671 	qp_modify_attr.qp_transport.ud.ud_qkey = args->ud_qkey;
672 
673 	/* Validate input hca_port_num and pkey_ix values. */
674 	if ((retval = ibt_index2pkey(hca_hdl, args->ud_hca_port_num,
675 	    args->ud_pkey_ix, &tmp_pkey)) != IBT_SUCCESS) {
676 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ud_channel_range:"
677 		    " ibt_index2pkey failed, status: %d", retval);
678 		goto fail;
679 	}
680 	qp_modify_attr.qp_transport.ud.ud_pkey_ix = args->ud_pkey_ix;
681 
682 	/* Allocate Channel and Initialize the channel. */
683 	retval = (IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_alloc_qp_range)(
684 	    IBTL_HCA2CIHCA(hca_hdl), log2, (ibtl_qp_hdl_t *)ud_chan_p,
685 	    IBT_UD_RQP, &qp_attr, sizes, ibc_send_cq, ibc_recv_cq,
686 	    base_qpn_p, ibc_qp_hdl_p);
687 	if (retval != IBT_SUCCESS) {
688 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ud_channel_range: "
689 		    "Failed to allocate QPs: %d", retval);
690 		goto fail;
691 	}
692 
693 	/* Initialize UD Channel by transitioning it to RTS State. */
694 	qp_modify_attr.qp_trans = IBT_UD_SRV;
695 	qp_modify_attr.qp_flags = IBT_CEP_NO_FLAGS;
696 	qp_modify_attr.qp_transport.ud.ud_sq_psn = 0;
697 
698 	for (i = 0; i < n; i++) {
699 		/* Initialize the internal QP struct. */
700 		chanp = ud_chan_p[i];
701 		chanp->ch_qp.qp_type = IBT_UD_SRV;
702 		chanp->ch_qp.qp_hca = hca_hdl;
703 		chanp->ch_qp.qp_ibc_qp_hdl = ibc_qp_hdl_p[i];
704 		chanp->ch_qp.qp_send_cq = send_cq[i];
705 		chanp->ch_qp.qp_recv_cq = recv_cq[i];
706 		chanp->ch_current_state = IBT_STATE_RESET;
707 		mutex_init(&chanp->ch_cm_mutex, NULL, MUTEX_DEFAULT, NULL);
708 		cv_init(&chanp->ch_cm_cv, NULL, CV_DEFAULT, NULL);
709 
710 		retval = ibt_initialize_qp(chanp, &qp_modify_attr);
711 		if (retval != IBT_SUCCESS) {
712 			int j;
713 
714 			IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ud_channel_range:"
715 			    " Failed to Initialize QP: %d", retval);
716 
717 			/* Free the QP as we failed to initialize it. */
718 			(void) ibt_free_qp(chanp);
719 			for (j = 0; j < i; j++) {
720 				chanp = ud_chan_p[j];
721 				(void) ibt_free_qp(chanp);
722 			}
723 			goto fail;
724 		}
725 
726 		/*
727 		 * The IBTA spec does not include the signal type or PD on a QP
728 		 * query operation. In order to implement the "CLONE" feature
729 		 * we need to cache these values.
730 		 */
731 		chanp->ch_qp.qp_flags = qp_attr.qp_flags;
732 		chanp->ch_qp.qp_pd_hdl = qp_attr.qp_pd_hdl;
733 	}
734 
735 
736 	IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ud_channel_range(%p): SUCCESS");
737 
738 	atomic_add_32(&hca_hdl->ha_qp_cnt, n);
739 
740 	retval = IBT_SUCCESS;
741 
742 fail:
743 	kmem_free(ibc_send_cq, sizeof (ibc_cq_hdl_t) << log2);
744 	kmem_free(ibc_recv_cq, sizeof (ibc_cq_hdl_t) << log2);
745 	kmem_free(ibc_qp_hdl_p, sizeof (ibc_qp_hdl_t) << log2);
746 	if (retval != IBT_SUCCESS) {
747 		for (i = 0; i < 1 << log2; i++) {
748 			kmem_free(ud_chan_p[i], sizeof (ibtl_channel_t));
749 			ud_chan_p[i] = NULL;
750 		}
751 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ud_channel_range(%p): "
752 		    "failed: %d", retval);
753 	}
754 	return (retval);
755 }
756 
757 
758 /*
759  * Function:
760  *	ibt_query_ud_channel
761  * Input:
762  *	ud_chan		A previously allocated UD channel handle.
763  * Output:
764  *	chan_attrs	Channel's current attributes.
765  * Returns:
766  *	IBT_SUCCESS
767  * Description:
768  *	Query a UD channel's attributes.
769  */
770 ibt_status_t
771 ibt_query_ud_channel(ibt_channel_hdl_t ud_chan,
772     ibt_ud_chan_query_attr_t *ud_chan_attrs)
773 {
774 	ibt_status_t		retval;
775 	ibt_qp_query_attr_t	qp_attr;
776 
777 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_query_ud_channel(%p, %p)",
778 	    ud_chan, ud_chan_attrs);
779 
780 	if (ud_chan->ch_qp.qp_type != IBT_UD_SRV) {
781 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_query_ud_channel: "
782 		    "type of channel (%d) is not UD", ud_chan->ch_qp.qp_type);
783 		return (IBT_CHAN_SRV_TYPE_INVALID);
784 	}
785 
786 	bzero(&qp_attr, sizeof (ibt_qp_query_attr_t));
787 
788 	/* Query the channel (QP) */
789 	retval = ibt_query_qp(ud_chan, &qp_attr);
790 	if (retval != IBT_SUCCESS) {
791 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_query_ud_channel: "
792 		    "ibt_query_qp failed on QP %p: %d", ud_chan, retval);
793 		return (retval);
794 	}
795 
796 	ud_chan_attrs->ud_qpn = qp_attr.qp_qpn & IB_QPN_MASK;
797 	ud_chan_attrs->ud_hca_guid = IBTL_HCA2HCAGUID(IBTL_CHAN2HCA(ud_chan));
798 
799 	ud_chan_attrs->ud_scq = qp_attr.qp_sq_cq;
800 	ud_chan_attrs->ud_rcq = qp_attr.qp_rq_cq;
801 	ud_chan_attrs->ud_pd = ud_chan->ch_qp.qp_pd_hdl;
802 
803 	ud_chan_attrs->ud_hca_port_num =
804 	    qp_attr.qp_info.qp_transport.ud.ud_port;
805 
806 	ud_chan_attrs->ud_state = qp_attr.qp_info.qp_state;
807 	ud_chan_attrs->ud_pkey_ix = qp_attr.qp_info.qp_transport.ud.ud_pkey_ix;
808 	ud_chan_attrs->ud_qkey = qp_attr.qp_info.qp_transport.ud.ud_qkey;
809 
810 	ud_chan_attrs->ud_chan_sizes.cs_sq = qp_attr.qp_info.qp_sq_sz;
811 	ud_chan_attrs->ud_chan_sizes.cs_rq = qp_attr.qp_info.qp_rq_sz;
812 	ud_chan_attrs->ud_chan_sizes.cs_sq_sgl = qp_attr.qp_sq_sgl;
813 	ud_chan_attrs->ud_chan_sizes.cs_rq_sgl = qp_attr.qp_rq_sgl;
814 	ud_chan_attrs->ud_srq = qp_attr.qp_srq;
815 
816 	ud_chan_attrs->ud_flags = ud_chan->ch_qp.qp_flags;
817 
818 	ud_chan_attrs->ud_query_fc = qp_attr.qp_query_fexch;
819 
820 	return (retval);
821 }
822 
823 
824 /*
825  * Function:
826  *	ibt_modify_ud_channel
827  * Input:
828  *	ud_chan		A previously allocated UD channel handle.
829  *	flags		Specifies which attributes in ibt_ud_chan_modify_attr_t
830  *			are to be modified.
831  *	attrs		Attributes to be modified.
832  * Output:
833  *	actual_sz	On return contains the new send and receive queue sizes.
834  * Returns:
835  *	IBT_SUCCESS
836  * Description:
837  *	Modifies an UD channel's attributes, as specified by a
838  *	ibt_cep_modify_flags_t parameter to those specified in the
839  *	ibt_ud_chan_modify_attr_t structure.
840  */
841 ibt_status_t
842 ibt_modify_ud_channel(ibt_channel_hdl_t ud_chan, ibt_cep_modify_flags_t flags,
843     ibt_ud_chan_modify_attr_t *attrs, ibt_queue_sizes_t *actual_sz)
844 {
845 	ibt_status_t		retval;
846 	ibt_qp_info_t		qp_info;
847 	ibt_cep_modify_flags_t	good_flags;
848 	int			retries = 1;
849 
850 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_modify_ud_channel(%p, %x, %p, %p)",
851 	    ud_chan, flags, attrs, actual_sz);
852 
853 	if (ud_chan->ch_qp.qp_type != IBT_UD_SRV) {
854 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_modify_ud_channel: "
855 		    "type of channel (%d) is not UD", ud_chan->ch_qp.qp_type);
856 		return (IBT_CHAN_SRV_TYPE_INVALID);
857 	}
858 
859 	good_flags = IBT_CEP_SET_SQ_SIZE | IBT_CEP_SET_RQ_SIZE |
860 	    IBT_CEP_SET_QKEY;
861 
862 	if (flags & ~good_flags) {
863 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_modify_ud_channel: "
864 		    "Invalid Modify Flags: %x", flags);
865 		return (IBT_INVALID_PARAM);
866 	}
867 
868 retry:
869 	bzero(&qp_info, sizeof (ibt_qp_info_t));
870 
871 	qp_info.qp_state = ud_chan->ch_current_state;	/* No Change in State */
872 	qp_info.qp_current_state = ud_chan->ch_current_state;
873 	qp_info.qp_flags = IBT_CEP_NO_FLAGS;
874 
875 	qp_info.qp_sq_sz = attrs->ud_sq_sz;
876 	qp_info.qp_rq_sz = attrs->ud_rq_sz;
877 	qp_info.qp_trans = IBT_UD_SRV;
878 	qp_info.qp_transport.ud.ud_qkey = attrs->ud_qkey;
879 
880 	flags |= IBT_CEP_SET_STATE;
881 
882 	retval = ibt_modify_qp(ud_chan, flags, &qp_info, actual_sz);
883 	if (retval != IBT_SUCCESS) {
884 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_modify_ud_channel: "
885 		    "ibt_modify_qp failed on QP %p: %d", ud_chan, retval);
886 		/* give it one more shot if the old current state was stale */
887 		if (qp_info.qp_current_state != ud_chan->ch_current_state &&
888 		    --retries >= 0 &&
889 		    (qp_info.qp_current_state == IBT_STATE_RTS ||
890 		    qp_info.qp_current_state == IBT_STATE_SQD))
891 			goto retry;
892 	}
893 
894 	return (retval);
895 }
896 
897 
898 /*
899  * Function:
900  *	ibt_recover_ud_channel
901  * Input:
902  *	ud_chan		An UD channel handle which is in SQError state.
903  * Output:
904  *	none.
905  * Returns:
906  *	IBT_SUCCESS
907  *	IBT_CHAN_HDL_INVALID
908  *	IBT_CHAN_SRV_TYPE_INVALID
909  *	IBT_CHAN_STATE_INVALID
910  * Description:
911  *	Recover an UD Channel which has transitioned to SQ Error state. The
912  *	ibt_recover_ud_channel() transitions the channel from SQ Error state
913  *	to Ready-To-Send channel state.
914  *
915  *	If a work request posted to a UD channel's send queue completes with
916  *	an error (see ibt_wc_status_t), the channel gets transitioned to SQ
917  *	Error state. In order to reuse this channel, ibt_recover_ud_channel()
918  *	can be used to recover the channel to a usable (Ready-to-Send) state.
919  */
920 ibt_status_t
921 ibt_recover_ud_channel(ibt_channel_hdl_t ud_chan)
922 {
923 	ibt_qp_info_t		modify_attr;
924 	ibt_status_t		retval;
925 
926 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_recover_ud_channel(%p)", ud_chan);
927 
928 	if (ud_chan->ch_qp.qp_type != IBT_UD_SRV) {
929 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_recover_ud_channel: "
930 		    "Called for non-UD channels<%d>", ud_chan->ch_qp.qp_type);
931 		return (IBT_CHAN_SRV_TYPE_INVALID);
932 	}
933 
934 	bzero(&modify_attr, sizeof (ibt_qp_info_t));
935 
936 	/* Set the channel state to RTS, to activate the send processing. */
937 	modify_attr.qp_state = IBT_STATE_RTS;
938 	modify_attr.qp_trans = ud_chan->ch_qp.qp_type;
939 	modify_attr.qp_current_state = IBT_STATE_SQE;
940 
941 	retval = ibt_modify_qp(ud_chan, IBT_CEP_SET_STATE, &modify_attr, NULL);
942 
943 	if (retval != IBT_SUCCESS)
944 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_recover_ud_channel: "
945 		    "ibt_modify_qp failed on qp %p: status = %d",
946 		    ud_chan, retval);
947 
948 	return (retval);
949 }
950 
951 
952 /*
953  * Function:
954  *	ibt_flush_channel
955  * Input:
956  *	chan		The opaque channel handle returned in a previous call
957  *			to ibt_alloc_ud_channel() or ibt_alloc_rc_channel().
958  * Output:
959  *	none.
960  * Returns:
961  *	IBT_SUCCESS
962  * Description:
963  *	Flush the specified channel. Outstanding work requests are flushed
964  *	so that the client can do the associated clean up. After that, the
965  *	client will usually deregister the previously registered memory,
966  *	then free the channel by calling ibt_free_channel().  This function
967  *	applies to UD channels, or to RC channels that have not successfully
968  *	been opened.
969  */
970 ibt_status_t
971 ibt_flush_channel(ibt_channel_hdl_t chan)
972 {
973 	ibt_status_t retval;
974 
975 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_flush_channel(%p)", chan);
976 
977 	retval = ibt_flush_qp(chan);
978 	if (retval != IBT_SUCCESS) {
979 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_flush_channel: "
980 		    "ibt_flush_qp failed on QP %p: %d", chan, retval);
981 	}
982 
983 	return (retval);
984 }
985 
986 
987 /*
988  * Function:
989  *	ibt_free_channel
990  * Input:
991  *	chan		The opaque channel handle returned in a previous
992  *			call to ibt_alloc_{ud,rc}_channel().
993  * Output:
994  *	none.
995  * Returns:
996  *	IBT_SUCCESS
997  * Description:
998  *	Releases the resources associated with the specified channel.
999  *	It is well assumed that channel has been closed before this.
1000  */
1001 ibt_status_t
1002 ibt_free_channel(ibt_channel_hdl_t chan)
1003 {
1004 	return (ibt_free_qp(chan));
1005 }
1006 
1007 
1008 /*
1009  * UD Destination.
1010  */
1011 /*
1012  * Function:
1013  *	ibt_alloc_ud_dest
1014  * Input:
1015  *	hca_hdl		HCA Handle.
1016  *	pd		Protection Domain
1017  * Output:
1018  *	ud_dest_p	Address to store the returned UD destination handle.
1019  * Returns:
1020  *	IBT_SUCCESS
1021  * Description:
1022  *	Allocate a UD destination handle. The returned UD destination handle
1023  *	has no useful contents, but is usable after calling ibt_modify_ud_dest,
1024  *	ibt_modify_reply_ud_dest, or ibt_open_ud_dest.
1025  */
1026 ibt_status_t
1027 ibt_alloc_ud_dest(ibt_hca_hdl_t hca_hdl, ibt_ud_dest_flags_t flags,
1028     ibt_pd_hdl_t pd, ibt_ud_dest_hdl_t *ud_dest_p)
1029 {
1030 	ibt_status_t	retval;
1031 	ibt_ud_dest_t	*ud_destp;
1032 	ibt_ah_hdl_t	ah;
1033 	ibt_adds_vect_t adds_vect;
1034 
1035 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_alloc_ud_dest(%p, %x, %p)",
1036 	    hca_hdl, flags, pd);
1037 
1038 	bzero(&adds_vect, sizeof (adds_vect));
1039 	adds_vect.av_port_num = 1;
1040 	adds_vect.av_srate = IBT_SRATE_1X;	/* assume the minimum */
1041 	retval = ibt_alloc_ah(hca_hdl, flags, pd, &adds_vect, &ah);
1042 	if (retval != IBT_SUCCESS) {
1043 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ud_dest: "
1044 		    "Address Handle Allocation failed: %d", retval);
1045 		*ud_dest_p = NULL;
1046 		return (retval);
1047 	}
1048 	ud_destp = kmem_alloc(sizeof (*ud_destp), KM_SLEEP);
1049 	ud_destp->ud_ah = ah;
1050 	ud_destp->ud_dest_hca = hca_hdl;
1051 	ud_destp->ud_dst_qpn = 0;
1052 	ud_destp->ud_qkey = 0;
1053 	*ud_dest_p = ud_destp;
1054 	return (IBT_SUCCESS);
1055 }
1056 
1057 /*
1058  * Function:
1059  *	ibt_query_ud_dest
1060  * Input:
1061  *	ud_dest		A previously allocated UD destination handle.
1062  * Output:
1063  *	dest_attrs	UD destination's current attributes.
1064  * Returns:
1065  *	IBT_SUCCESS
1066  * Description:
1067  *	Query a UD destination's attributes.
1068  */
1069 ibt_status_t
1070 ibt_query_ud_dest(ibt_ud_dest_hdl_t ud_dest,
1071     ibt_ud_dest_query_attr_t *dest_attrs)
1072 {
1073 	ibt_status_t	retval;
1074 
1075 	ASSERT(dest_attrs != NULL);
1076 
1077 	/* Query Address Handle */
1078 	retval = ibt_query_ah(ud_dest->ud_dest_hca, ud_dest->ud_ah,
1079 	    &dest_attrs->ud_pd, &dest_attrs->ud_addr_vect);
1080 
1081 	if (retval != IBT_SUCCESS) {
1082 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_query_ud_dest: "
1083 		    "Failed to Query Address Handle: %d", retval);
1084 		return (retval);
1085 	}
1086 
1087 	/* Update the return struct. */
1088 	dest_attrs->ud_hca_hdl = ud_dest->ud_dest_hca;
1089 	dest_attrs->ud_dst_qpn = ud_dest->ud_dst_qpn;
1090 	dest_attrs->ud_qkey = ud_dest->ud_qkey;
1091 
1092 	return (retval);
1093 }
1094 
1095 /*
1096  * Function:
1097  *	ibt_modify_ud_dest
1098  * Input:
1099  *	ud_dest		A previously allocated UD destination handle
1100  *			as returned by ibt_alloc_ud_dest().
1101  *	qkey		QKey of the destination.
1102  *	dest_qpn	QPN of the destination.
1103  *	adds_vect	NULL or Address Vector for the destination.
1104  *
1105  * Output:
1106  *	none.
1107  * Returns:
1108  *	IBT_SUCCESS
1109  * Description:
1110  *	Modify a previously allocated UD destination handle from the
1111  *	arguments supplied by the caller.
1112  */
1113 ibt_status_t
1114 ibt_modify_ud_dest(ibt_ud_dest_hdl_t ud_dest, ib_qkey_t qkey,
1115     ib_qpn_t dest_qpn, ibt_adds_vect_t *adds_vect)
1116 {
1117 	ibt_status_t	retval;
1118 
1119 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_modify_ud_dest(%p, %x, %x, %p) ",
1120 	    ud_dest, qkey, dest_qpn, adds_vect);
1121 
1122 	if ((adds_vect != NULL) &&
1123 	    (retval = ibt_modify_ah(ud_dest->ud_dest_hca, ud_dest->ud_ah,
1124 	    adds_vect)) != IBT_SUCCESS) {
1125 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_modify_ud_dest: "
1126 		    "ibt_modify_ah() failed: status = %d", retval);
1127 		return (retval);
1128 	}
1129 	ud_dest->ud_dst_qpn = dest_qpn;
1130 	ud_dest->ud_qkey = qkey;
1131 	return (IBT_SUCCESS);
1132 }
1133 
1134 /*
1135  * Function:
1136  *	ibt_free_ud_dest
1137  * Input:
1138  *	ud_dest		The opaque destination handle returned in a previous
1139  *			call to ibt_alloc_ud_dest() or ibt_alloc_mcg_dest().
1140  * Output:
1141  *	none.
1142  * Returns:
1143  *	IBT_SUCCESS
1144  * Description:
1145  *	Releases the resources associated with the specified destination
1146  *	handle.
1147  */
1148 ibt_status_t
1149 ibt_free_ud_dest(ibt_ud_dest_hdl_t ud_dest)
1150 {
1151 	ibt_status_t	retval;
1152 
1153 	retval = ibt_free_ah(ud_dest->ud_dest_hca, ud_dest->ud_ah);
1154 	if (retval != IBT_SUCCESS) {
1155 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_free_ud_dest: "
1156 		    "Address Handle free failed: %d", retval);
1157 		return (retval);
1158 	}
1159 	kmem_free(ud_dest, sizeof (*ud_dest));
1160 	return (IBT_SUCCESS);
1161 }
1162 
1163 static ibt_status_t
1164 ibtl_find_sgid_ix(ib_gid_t *sgid, ibt_channel_hdl_t ud_chan, uint8_t port,
1165     uint_t *sgid_ix_p)
1166 {
1167 	ibtl_hca_devinfo_t *hca_devp = ud_chan->ch_qp.qp_hca->ha_hca_devp;
1168 	ib_gid_t *sgidp;
1169 	uint_t i;
1170 	uint_t sgid_tbl_sz;
1171 
1172 	if (port == 0 || port > hca_devp->hd_hca_attr->hca_nports ||
1173 	    sgid->gid_prefix == 0 || sgid->gid_guid == 0) {
1174 		*sgid_ix_p = 0;
1175 		return (IBT_INVALID_PARAM);
1176 	}
1177 	mutex_enter(&ibtl_clnt_list_mutex);
1178 	sgidp = &hca_devp->hd_portinfop[port - 1].p_sgid_tbl[0];
1179 	sgid_tbl_sz = hca_devp->hd_portinfop[port - 1].p_sgid_tbl_sz;
1180 	for (i = 0; i < sgid_tbl_sz; i++, sgidp++) {
1181 		if ((sgid->gid_guid != sgidp->gid_guid) ||
1182 		    (sgid->gid_prefix != sgidp->gid_prefix))
1183 			continue;
1184 		mutex_exit(&ibtl_clnt_list_mutex);
1185 		*sgid_ix_p = i;
1186 		return (IBT_SUCCESS);
1187 	}
1188 	mutex_exit(&ibtl_clnt_list_mutex);
1189 	*sgid_ix_p = 0;
1190 	return (IBT_INVALID_PARAM);
1191 }
1192 
1193 /*
1194  * Function:
1195  *	ibt_modify_reply_ud_dest
1196  * Input:
1197  *	ud_dest		A previously allocated UD reply destination handle
1198  *			as returned by ibt_alloc_ud_dest().
1199  *	qkey		Qkey.  0 means "not specified", so use the Q_Key
1200  *			in the QP context.
1201  *	recv_buf	Pointer to the first data buffer associated with the
1202  *			receive work request.
1203  * Output:
1204  * Returns:
1205  *	IBT_SUCCESS
1206  * Description:
1207  *	Modify a previously allocated UD destination handle, so that it
1208  *	can be used to reply to the sender of the datagram contained in the
1209  *	specified work request completion.  If the qkey is not supplied (0),
1210  *	then use the qkey in the QP (we just set qkey to a privileged QKEY).
1211  */
1212 ibt_status_t
1213 ibt_modify_reply_ud_dest(ibt_channel_hdl_t ud_chan, ibt_ud_dest_hdl_t ud_dest,
1214     ib_qkey_t qkey, ibt_wc_t *wc, ib_vaddr_t recv_buf)
1215 {
1216 	ibt_status_t		retval;
1217 	ibt_adds_vect_t		adds_vect;
1218 	ib_grh_t		*grh;
1219 	uint8_t			port;
1220 	uint32_t		ver_tc_flow;
1221 
1222 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_modify_reply_ud_dest(%p, %p, %x, %p, "
1223 	    "%llx)", ud_chan, ud_dest, qkey, wc, recv_buf);
1224 
1225 	if (ud_chan->ch_qp.qp_type != IBT_UD_SRV) {
1226 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_modify_reply_ud_dest: "
1227 		    "type of channel (%d) is not UD",
1228 		    ud_chan->ch_qp.qp_type);
1229 		return (IBT_CHAN_SRV_TYPE_INVALID);
1230 	}
1231 	if (qkey == 0)
1232 		qkey = ud_chan->ch_transport.ud.ud_qkey;
1233 	port = ud_chan->ch_transport.ud.ud_port_num;
1234 
1235 	if (wc->wc_flags & IBT_WC_GRH_PRESENT) {
1236 		grh = (ib_grh_t *)(uintptr_t)recv_buf;
1237 		adds_vect.av_send_grh = B_TRUE;
1238 		adds_vect.av_dgid.gid_prefix = b2h64(grh->SGID.gid_prefix);
1239 		adds_vect.av_dgid.gid_guid = b2h64(grh->SGID.gid_guid);
1240 		adds_vect.av_sgid.gid_prefix = b2h64(grh->DGID.gid_prefix);
1241 		adds_vect.av_sgid.gid_guid = b2h64(grh->DGID.gid_guid);
1242 		(void) ibtl_find_sgid_ix(&adds_vect.av_sgid, ud_chan,
1243 		    port, &adds_vect.av_sgid_ix);
1244 		ver_tc_flow = b2h32(grh->IPVer_TC_Flow);
1245 		adds_vect.av_flow = ver_tc_flow & IB_GRH_FLOW_LABEL_MASK;
1246 		adds_vect.av_tclass = (ver_tc_flow & IB_GRH_TCLASS_MASK) >> 20;
1247 		adds_vect.av_hop = grh->HopLmt;
1248 	} else {
1249 		adds_vect.av_send_grh = B_FALSE;
1250 		adds_vect.av_dgid.gid_prefix = 0;
1251 		adds_vect.av_sgid.gid_prefix = 0;
1252 		adds_vect.av_dgid.gid_guid = 0;
1253 		adds_vect.av_sgid.gid_guid = 0;
1254 		adds_vect.av_sgid_ix = 0;
1255 		adds_vect.av_flow = 0;
1256 		adds_vect.av_tclass = 0;
1257 		adds_vect.av_hop = 0;
1258 	}
1259 
1260 	adds_vect.av_srate = IBT_SRATE_1X;	/* assume the minimum */
1261 	adds_vect.av_srvl = wc->wc_sl;
1262 	adds_vect.av_dlid = wc->wc_slid;
1263 	adds_vect.av_src_path = wc->wc_path_bits;
1264 	adds_vect.av_port_num = port;
1265 
1266 	if ((retval = ibt_modify_ah(ud_dest->ud_dest_hca, ud_dest->ud_ah,
1267 	    &adds_vect)) != IBT_SUCCESS) {
1268 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_modify_reply_ud_dest: "
1269 		    "ibt_alloc_ah() failed: status = %d", retval);
1270 		return (retval);
1271 	}
1272 	ud_dest->ud_dst_qpn = wc->wc_qpn & IB_QPN_MASK;
1273 	ud_dest->ud_qkey = qkey;
1274 
1275 	return (IBT_SUCCESS);
1276 }
1277 
1278 
1279 /*
1280  * Function:
1281  *	ibt_is_privileged_ud_dest
1282  * Input:
1283  *	ud_dest		A previously allocated destination handle.
1284  * Output:
1285  *	none
1286  * Returns:
1287  *	B_FALSE/B_TRUE
1288  * Description:
1289  *	Determine if a UD destination Handle is a privileged handle.
1290  */
1291 boolean_t
1292 ibt_is_privileged_ud_dest(ibt_ud_dest_hdl_t ud_dest)
1293 {
1294 	return ((ud_dest->ud_qkey & IB_PRIVILEGED_QKEY_BIT) ? B_TRUE : B_FALSE);
1295 }
1296 
1297 
1298 /*
1299  * Function:
1300  *	ibt_update_channel_qkey
1301  * Input:
1302  *	ud_chan		The UD channel handle, that is to be used to
1303  *			communicate with the specified destination.
1304  *
1305  *	ud_dest		A UD destination handle returned from
1306  *			ibt_alloc_ud_dest(9F).
1307  * Output:
1308  *	none
1309  * Returns:
1310  *	IBT_SUCCESS
1311  * Description:
1312  *   ibt_update_channel_qkey() sets the Q_Key in the specified channel context
1313  *   to the Q_Key in the specified destination handle. This function can be used
1314  *   to enable sends to a privileged destination. All posted send work requests
1315  *   that contain a privileged destination handle now use the Q_Key in the
1316  *   channel context.
1317  *
1318  *   ibt_update_channel_qkey() can also be used to enable the caller to receive
1319  *   from the specified remote destination on the specified channel.
1320  */
1321 ibt_status_t
1322 ibt_update_channel_qkey(ibt_channel_hdl_t ud_chan, ibt_ud_dest_hdl_t ud_dest)
1323 {
1324 	ibt_status_t		retval;
1325 	ibt_qp_info_t		qp_info;
1326 
1327 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_update_channel_qkey(%p, %p)",
1328 	    ud_chan, ud_dest);
1329 
1330 	if (ud_chan->ch_qp.qp_type != IBT_UD_SRV) {
1331 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_update_channel_qkey: "
1332 		    "type of channel (%d) is not UD",
1333 		    ud_chan->ch_qp.qp_type);
1334 		return (IBT_CHAN_SRV_TYPE_INVALID);
1335 	}
1336 	bzero(&qp_info, sizeof (ibt_qp_info_t));
1337 
1338 	qp_info.qp_trans = IBT_UD_SRV;
1339 	qp_info.qp_state = ud_chan->ch_current_state;
1340 	qp_info.qp_current_state = ud_chan->ch_current_state;
1341 	qp_info.qp_transport.ud.ud_qkey = ud_dest->ud_qkey;
1342 
1343 	retval = ibt_modify_qp(ud_chan, IBT_CEP_SET_QKEY | IBT_CEP_SET_STATE,
1344 	    &qp_info, NULL);
1345 	if (retval != IBT_SUCCESS) {
1346 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_update_channel_qkey: "
1347 		    "Failed to modify QP %p: status %d", ud_chan, retval);
1348 	} else {
1349 		ud_chan->ch_transport.ud.ud_qkey = ud_dest->ud_qkey;
1350 	}
1351 
1352 	return (retval);
1353 }
1354 
1355 
1356 /*
1357  * Function:
1358  *	ibt_set_chan_private
1359  * Input:
1360  *	chan		A previously allocated channel handle.
1361  *	clnt_private	The client private data.
1362  * Output:
1363  *	none.
1364  * Returns:
1365  *	none.
1366  * Description:
1367  *	Set the client private data.
1368  */
1369 void
1370 ibt_set_chan_private(ibt_channel_hdl_t chan, void *clnt_private)
1371 {
1372 	chan->ch_clnt_private = clnt_private;
1373 }
1374 
1375 
1376 /*
1377  * Function:
1378  *	ibt_get_chan_private
1379  * Input:
1380  *	chan		A previously allocated channel handle.
1381  * Output:
1382  *	A pointer to the client private data.
1383  * Returns:
1384  *	none.
1385  * Description:
1386  *	Get a pointer to client private data.
1387  */
1388 void *
1389 ibt_get_chan_private(ibt_channel_hdl_t chan)
1390 {
1391 	return (chan->ch_clnt_private);
1392 }
1393 
1394 /*
1395  * Function:
1396  *	ibt_channel_to_hca_guid
1397  * Input:
1398  *	chan		Channel Handle.
1399  * Output:
1400  *	none.
1401  * Returns:
1402  *	hca_guid	Returned HCA GUID on which the specified Channel is
1403  *			allocated. Valid if it is non-NULL on return.
1404  * Description:
1405  *	A helper function to retrieve HCA GUID for the specified Channel.
1406  */
1407 ib_guid_t
1408 ibt_channel_to_hca_guid(ibt_channel_hdl_t chan)
1409 {
1410 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_channel_to_hca_guid(%p)", chan);
1411 
1412 	return (IBTL_HCA2HCAGUID(IBTL_CHAN2HCA(chan)));
1413 }
1414 
1415 /*
1416  * Protection Domain Verbs Functions.
1417  */
1418 
1419 /*
1420  * Function:
1421  *	ibt_alloc_pd
1422  * Input:
1423  *	hca_hdl		The IBT HCA handle, the device on which we need
1424  *			to create the requested Protection Domain.
1425  *	flags		IBT_PD_NO_FLAGS, IBT_PD_USER_MAP or IBT_PD_DEFER_ALLOC
1426  * Output:
1427  *	pd		IBT Protection Domain Handle.
1428  * Returns:
1429  *	IBT_SUCCESS
1430  *	IBT_HCA_HDL_INVALID
1431  * Description:
1432  *	Allocate a Protection Domain.
1433  */
1434 ibt_status_t
1435 ibt_alloc_pd(ibt_hca_hdl_t hca_hdl, ibt_pd_flags_t flags, ibt_pd_hdl_t *pd)
1436 {
1437 	ibt_status_t	retval;
1438 
1439 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_alloc_pd(%p, %x)", hca_hdl, flags);
1440 
1441 	/* re-direct the call to CI's call */
1442 	ibtl_qp_flow_control_enter();
1443 	retval = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_alloc_pd(
1444 	    IBTL_HCA2CIHCA(hca_hdl), flags, pd);
1445 	ibtl_qp_flow_control_exit();
1446 	if (retval != IBT_SUCCESS) {
1447 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_pd: CI PD Alloc Err");
1448 		return (retval);
1449 	}
1450 
1451 	/* Update the PDs Resource Count per HCA Device. */
1452 	atomic_inc_32(&hca_hdl->ha_pd_cnt);
1453 
1454 	return (retval);
1455 }
1456 
1457 /*
1458  * Function:
1459  *	ibt_free_pd
1460  * Input:
1461  *	hca_hdl		The IBT HCA handle, the device on which we need
1462  *			to free the requested Protection Domain.
1463  *	pd		IBT Protection Domain Handle.
1464  * Output:
1465  *	none.
1466  * Returns:
1467  *	IBT_SUCCESS
1468  *	IBT_HCA_HDL_INVALID
1469  *	IBT_MEM_PD_HDL_INVALID
1470  *	IBT_MEM_PD_IN_USE
1471  * Description:
1472  *	Release/de-allocate a Protection Domain.
1473  */
1474 ibt_status_t
1475 ibt_free_pd(ibt_hca_hdl_t hca_hdl, ibt_pd_hdl_t pd)
1476 {
1477 	ibt_status_t	retval;
1478 
1479 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_free_pd(%p, %p)", hca_hdl, pd);
1480 
1481 	/* re-direct the call to CI's call */
1482 	retval = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_free_pd(
1483 	    IBTL_HCA2CIHCA(hca_hdl), pd);
1484 	if (retval != IBT_SUCCESS) {
1485 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_free_pd: CI Free PD Failed");
1486 		return (retval);
1487 	}
1488 
1489 	/* Update the PDs Resource Count per HCA Device. */
1490 	atomic_dec_32(&hca_hdl->ha_pd_cnt);
1491 
1492 	return (retval);
1493 }
1494 
1495 
1496 /*
1497  * Address Handle Verbs Functions.
1498  */
1499 
1500 /*
1501  * Function:
1502  *	ibt_alloc_ah
1503  * Input:
1504  *	hca_hdl		The IBT HCA Handle.
1505  *	pd		The IBT Protection Domain to associate with this handle.
1506  *	adds_vectp	Points to an ibt_adds_vect_t struct.
1507  * Output:
1508  *	ah		IBT Address Handle.
1509  * Returns:
1510  *	IBT_SUCCESS
1511  *	IBT_HCA_HDL_INVALID
1512  *	IBT_INSUFF_RESOURCE
1513  *	IBT_MEM_PD_HDL_INVALID
1514  * Description:
1515  *	Allocate and returns an Address Handle.
1516  */
1517 ibt_status_t
1518 ibt_alloc_ah(ibt_hca_hdl_t hca_hdl, ibt_ah_flags_t flags, ibt_pd_hdl_t pd,
1519     ibt_adds_vect_t *adds_vectp, ibt_ah_hdl_t *ah)
1520 {
1521 	ibt_status_t	retval;
1522 
1523 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_alloc_ah(%p, %x, %p, %p)",
1524 	    hca_hdl, flags, pd, adds_vectp);
1525 
1526 	/* XXX - if av_send_grh, need to compute av_sgid_ix from av_sgid */
1527 
1528 	/* re-direct the call to CI's call */
1529 	retval = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_alloc_ah(
1530 	    IBTL_HCA2CIHCA(hca_hdl), flags, pd, adds_vectp, ah);
1531 
1532 	if (retval != IBT_SUCCESS) {
1533 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_alloc_ah: "
1534 		    "ibc_alloc_ah failed: status = %d", retval);
1535 		return (retval);
1536 	}
1537 
1538 	/* Update the AHs Resource Count per HCA Device. */
1539 	atomic_inc_32(&hca_hdl->ha_ah_cnt);
1540 
1541 	return (retval);
1542 }
1543 
1544 
1545 /*
1546  * Function:
1547  *	ibt_free_ah
1548  * Input:
1549  *	hca_hdl		The IBT HCA Handle.
1550  *	ah		IBT Address Handle.
1551  * Output:
1552  *	none.
1553  * Returns:
1554  *	IBT_SUCCESS
1555  *	IBT_HCA_HDL_INVALID
1556  *	IBT_AH_HDL_INVALID
1557  * Description:
1558  *	Release/de-allocate the specified Address Handle.
1559  */
1560 ibt_status_t
1561 ibt_free_ah(ibt_hca_hdl_t hca_hdl, ibt_ah_hdl_t ah)
1562 {
1563 	ibt_status_t	retval;
1564 
1565 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_free_ah(%p, %p)", hca_hdl, ah);
1566 
1567 	/* re-direct the call to CI's call */
1568 	retval = IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_free_ah(
1569 	    IBTL_HCA2CIHCA(hca_hdl), ah);
1570 
1571 	if (retval != IBT_SUCCESS) {
1572 		IBTF_DPRINTF_L2(ibtl_chan, "ibt_free_ah: CI Free AH Failed");
1573 		return (retval);
1574 	}
1575 
1576 	/* Update the AHs Resource Count per HCA Device. */
1577 	atomic_dec_32(&hca_hdl->ha_ah_cnt);
1578 
1579 	return (retval);
1580 }
1581 
1582 
1583 /*
1584  * Function:
1585  *	ibt_query_ah
1586  * Input:
1587  *	hca_hdl		The IBT HCA Handle.
1588  *	ah		IBT Address Handle.
1589  * Output:
1590  *	pd		The Protection Domain Handle with which this
1591  *			Address Handle is associated.
1592  *	adds_vectp	Points to an ibt_adds_vect_t struct.
1593  * Returns:
1594  *	IBT_SUCCESS/IBT_HCA_HDL_INVALID/IBT_AH_HDL_INVALID
1595  * Description:
1596  *	Obtain the address vector information for the specified address handle.
1597  */
1598 ibt_status_t
1599 ibt_query_ah(ibt_hca_hdl_t hca_hdl, ibt_ah_hdl_t ah, ibt_pd_hdl_t *pd,
1600     ibt_adds_vect_t *adds_vectp)
1601 {
1602 	ibt_status_t	retval;
1603 
1604 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_query_ah(%p, %p)", hca_hdl, ah);
1605 
1606 	/* re-direct the call to CI's call */
1607 	retval = (IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_query_ah(
1608 	    IBTL_HCA2CIHCA(hca_hdl), ah, pd, adds_vectp));
1609 
1610 	/*
1611 	 * We need to fill in av_sgid, as the CI does only saves/restores
1612 	 * av_sgid_ix.
1613 	 */
1614 	if (retval == IBT_SUCCESS) {
1615 		ibtl_hca_devinfo_t *hca_devp = hca_hdl->ha_hca_devp;
1616 		uint8_t port = adds_vectp->av_port_num;
1617 
1618 		mutex_enter(&ibtl_clnt_list_mutex);
1619 		if (port > 0 && port <= hca_devp->hd_hca_attr->hca_nports &&
1620 		    adds_vectp->av_sgid_ix < IBTL_HDIP2SGIDTBLSZ(hca_devp)) {
1621 			ib_gid_t *sgidp;
1622 
1623 			sgidp = hca_devp->hd_portinfop[port-1].p_sgid_tbl;
1624 			adds_vectp->av_sgid = sgidp[adds_vectp->av_sgid_ix];
1625 		} else {
1626 			adds_vectp->av_sgid.gid_prefix = 0;
1627 			adds_vectp->av_sgid.gid_guid = 0;
1628 		}
1629 		mutex_exit(&ibtl_clnt_list_mutex);
1630 	}
1631 	return (retval);
1632 }
1633 
1634 
1635 /*
1636  * Function:
1637  *	ibt_modify_ah
1638  * Input:
1639  *	hca_hdl		The IBT HCA Handle.
1640  *	ah		IBT Address Handle.
1641  * Output:
1642  *	adds_vectp	Points to an ibt_adds_vect_t struct. The new address
1643  *			vector information is specified is returned in this
1644  *			structure.
1645  * Returns:
1646  *	IBT_SUCCESS/IBT_HCA_HDL_INVALID/IBT_AH_HDL_INVALID
1647  * Description:
1648  *	Modify the address vector information for the specified Address Handle.
1649  */
1650 ibt_status_t
1651 ibt_modify_ah(ibt_hca_hdl_t hca_hdl, ibt_ah_hdl_t ah,
1652     ibt_adds_vect_t *adds_vectp)
1653 {
1654 	IBTF_DPRINTF_L3(ibtl_chan, "ibt_modify_ah(%p, %p)", hca_hdl, ah);
1655 
1656 	/* XXX - if av_send_grh, need to compute av_sgid_ix from av_sgid */
1657 
1658 	/* re-direct the call to CI's call */
1659 	return (IBTL_HCA2CIHCAOPS_P(hca_hdl)->ibc_modify_ah(
1660 	    IBTL_HCA2CIHCA(hca_hdl), ah, adds_vectp));
1661 }
1662