xref: /titanic_51/usr/src/uts/common/io/ib/adapters/hermon/hermon_event.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 /*
23  * Copyright (c) 2008, 2010, Oracle and/or its affiliates. All rights reserved.
24  */
25 
26 /*
27  * hermon_event.c
28  *    Hermon Interrupt and Event Processing Routines
29  *
30  *    Implements all the routines necessary for allocating, freeing, and
31  *    handling all of the various event types that the Hermon hardware can
32  *    generate.
33  *    These routines include the main Hermon interrupt service routine
34  *    (hermon_isr()) as well as all the code necessary to setup and handle
35  *    events from each of the many event queues used by the Hermon device.
36  */
37 
38 #include <sys/types.h>
39 #include <sys/conf.h>
40 #include <sys/ddi.h>
41 #include <sys/sunddi.h>
42 #include <sys/modctl.h>
43 
44 #include <sys/ib/adapters/hermon/hermon.h>
45 
46 static void hermon_eq_poll(hermon_state_t *state, hermon_eqhdl_t eq);
47 static void hermon_eq_catastrophic(hermon_state_t *state);
48 static int hermon_eq_alloc(hermon_state_t *state, uint32_t log_eq_size,
49     uint_t intr, hermon_eqhdl_t *eqhdl);
50 static int hermon_eq_free(hermon_state_t *state, hermon_eqhdl_t *eqhdl);
51 static int hermon_eq_handler_init(hermon_state_t *state, hermon_eqhdl_t eq,
52     uint_t evt_type_mask, int (*eqfunc)(hermon_state_t *state,
53     hermon_eqhdl_t eq, hermon_hw_eqe_t *eqe));
54 static int hermon_eq_handler_fini(hermon_state_t *state, hermon_eqhdl_t eq);
55 static int hermon_port_state_change_handler(hermon_state_t *state,
56     hermon_eqhdl_t eq, hermon_hw_eqe_t *eqe);
57 static int hermon_comm_estbl_handler(hermon_state_t *state,
58     hermon_eqhdl_t eq, hermon_hw_eqe_t *eqe);
59 static int hermon_local_wq_cat_err_handler(hermon_state_t *state,
60     hermon_eqhdl_t eq, hermon_hw_eqe_t *eqe);
61 static int hermon_invreq_local_wq_err_handler(hermon_state_t *state,
62     hermon_eqhdl_t eq, hermon_hw_eqe_t *eqe);
63 static int hermon_local_acc_vio_wq_err_handler(hermon_state_t *state,
64     hermon_eqhdl_t eq, hermon_hw_eqe_t *eqe);
65 static int hermon_sendq_drained_handler(hermon_state_t *state,
66     hermon_eqhdl_t eq, hermon_hw_eqe_t *eqe);
67 static int hermon_path_mig_handler(hermon_state_t *state,
68     hermon_eqhdl_t eq, hermon_hw_eqe_t *eqe);
69 static int hermon_path_mig_err_handler(hermon_state_t *state,
70     hermon_eqhdl_t eq, hermon_hw_eqe_t *eqe);
71 static int hermon_catastrophic_handler(hermon_state_t *state,
72     hermon_eqhdl_t eq, hermon_hw_eqe_t *eqe);
73 static int hermon_srq_last_wqe_reached_handler(hermon_state_t *state,
74     hermon_eqhdl_t eq, hermon_hw_eqe_t *eqe);
75 static int hermon_fexch_error_handler(hermon_state_t *state,
76     hermon_eqhdl_t eq, hermon_hw_eqe_t *eqe);
77 static int hermon_no_eqhandler(hermon_state_t *state, hermon_eqhdl_t eq,
78     hermon_hw_eqe_t *eqe);
79 static int hermon_eq_demux(hermon_state_t *state, hermon_eqhdl_t eq,
80     hermon_hw_eqe_t *eqe);
81 
82 /*
83  * hermon_eq_init_all
84  *    Context: Only called from attach() path context
85  */
86 int
87 hermon_eq_init_all(hermon_state_t *state)
88 {
89 	uint_t		log_eq_size, intr_num;
90 	uint_t		num_eq, num_eq_init, num_eq_unmap, num_eq_rsvd;
91 	uint32_t	event_mask;	/* used for multiple event types */
92 	int		status, i, num_extra;
93 	struct hermon_sw_eq_s **eq;
94 	ddi_acc_handle_t uarhdl = hermon_get_uarhdl(state);
95 
96 	/* initialize the FMA retry loop */
97 	hermon_pio_init(fm_loop_cnt, fm_status, fm_test);
98 
99 	/*
100 	 * For now, all Event Queues default to the same size (pulled from
101 	 * the current configuration profile) and are all assigned to the
102 	 * same interrupt or MSI.  In the future we may support assigning
103 	 * EQs to specific interrupts or MSIs XXX
104 	 */
105 	log_eq_size = state->hs_cfg_profile->cp_log_eq_sz;
106 
107 	/*
108 	 * Total number of supported EQs is fixed.  Hermon hardware
109 	 * supports up to 512 EQs, though in theory they will one day be
110 	 * alloc'd to virtual HCA's.  We are currently using only 47 of them
111 	 * - that is, in Arbel and Tavor, before HERMON, where
112 	 * we had set aside the first 32 for use with Completion Queues (CQ)
113 	 * and reserved a few of the other 32 for each specific class of event
114 	 *
115 	 * However, with the coming of vitualization, we'll have only 4 per
116 	 * potential guest - so, we'll try alloc'ing them differntly
117 	 * (see below for more details).
118 	 */
119 	num_eq = HERMON_NUM_EQ_USED;
120 	num_eq_rsvd = state->hs_rsvd_eqs;
121 	eq = &state->hs_eqhdl[num_eq_rsvd];
122 
123 	/*
124 	 * If MSI is to be used, then set intr_num to the MSI number.
125 	 * Otherwise, for fixed (i.e. 'legacy') interrupts,
126 	 * it is what the card tells us in 'inta_pin'.
127 	 */
128 	if (state->hs_intr_type_chosen == DDI_INTR_TYPE_FIXED) {
129 		intr_num = state->hs_adapter.inta_pin;
130 		num_extra = 0;
131 	} else {
132 		/* If we have more than one MSI-X vector, init them. */
133 		for (i = 0; i + 1 < state->hs_intrmsi_allocd; i++) {
134 			status = hermon_eq_alloc(state, log_eq_size, i, &eq[i]);
135 			if (status != DDI_SUCCESS) {
136 				while (--i >= 0) {
137 					(void) hermon_eq_handler_fini(state,
138 					    eq[i]);
139 					(void) hermon_eq_free(state, &eq[i]);
140 				}
141 				return (DDI_FAILURE);
142 			}
143 
144 			(void) hermon_eq_handler_init(state, eq[i],
145 			    HERMON_EVT_NO_MASK, hermon_cq_handler);
146 		}
147 		intr_num = i;
148 		num_extra = i;
149 	}
150 
151 	/*
152 	 * Allocate and initialize the rest of the Event Queues to be used.
153 	 * If any of these EQ allocations fail then jump to the end, cleanup
154 	 * what had been successfully initialized, and return an error.
155 	 */
156 	for (i = 0; i < num_eq; i++) {
157 		status = hermon_eq_alloc(state, log_eq_size, intr_num,
158 		    &eq[num_extra + i]);
159 		if (status != DDI_SUCCESS) {
160 			num_eq_init = i;
161 			goto all_eq_init_fail;
162 		}
163 	}
164 	num_eq_init = num_eq;
165 	/*
166 	 * The "num_eq_unmap" variable is used in any possible failure
167 	 * cleanup (below) to indicate which events queues might require
168 	 * possible event class unmapping.
169 	 */
170 	num_eq_unmap = 0;
171 
172 	/*
173 	 * Setup EQ0 (first avail) for use with Completion Queues.  Note: We can
174 	 * cast the return value to void here because, when we use the
175 	 * HERMON_EVT_NO_MASK flag, it is not possible for
176 	 * hermon_eq_handler_init() to return an error.
177 	 */
178 	(void) hermon_eq_handler_init(state, eq[num_eq_unmap + num_extra],
179 	    HERMON_EVT_NO_MASK, hermon_cq_handler);
180 
181 	num_eq_unmap++;
182 
183 	/*
184 	 * Setup EQ1 for handling Completion Queue Error Events.
185 	 *
186 	 * These events include things like CQ overflow or CQ access
187 	 * violation errors.  If this setup fails for any reason (which, in
188 	 * general, it really never should), then jump to the end, cleanup
189 	 * everything that has been successfully initialized, and return an
190 	 * error.
191 	 */
192 	status = hermon_eq_handler_init(state, eq[num_eq_unmap + num_extra],
193 	    HERMON_EVT_MSK_CQ_ERRORS, hermon_cq_err_handler);
194 	if (status != DDI_SUCCESS) {
195 		goto all_eq_init_fail;
196 	}
197 	state->hs_cq_erreqnum = num_eq_unmap + num_extra + num_eq_rsvd;
198 	num_eq_unmap++;
199 
200 	/*
201 	 * Setup EQ2 for handling most other things including:
202 	 *
203 	 * Port State Change Events
204 	 *   These events include things like Port Up and Port Down events.
205 	 *
206 	 * Communication Established Events
207 	 *   These events correspond to the IB affiliated asynchronous events
208 	 *   that are used for connection management
209 	 *
210 	 * Path Migration Succeeded Events
211 	 *   These evens corresponid to the IB affiliated asynchronous events
212 	 *   that are used to indicate successful completion of a
213 	 *   Path Migration.
214 	 *
215 	 * Command Completion Events
216 	 *   These events correspond to the Arbel generated events that are used
217 	 *   to indicate Arbel firmware command completion.
218 	 *
219 	 * Local WQ Catastrophic Error Events
220 	 * Invalid Req Local WQ Error Events
221 	 * Local Access Violation WQ Error Events
222 	 * SRQ Catastrophic Error Events
223 	 * SRQ Last WQE Reached Events
224 	 * ECC error detection events
225 	 *   These events also correspond to the similarly-named IB affiliated
226 	 *   asynchronous error type.
227 	 *
228 	 * Send Queue Drained Events
229 	 *   These events correspond to the IB affiliated asynchronous events
230 	 *   that are used to indicate completion of a Send Queue Drained QP
231 	 *   state transition.
232 	 *
233 	 * Path Migration Failed Events
234 	 *   These events correspond to the IB affiliated asynchronous events
235 	 *   that are used to indicate that path migration was not successful.
236 	 *
237 	 * Fibre Channel Error Event
238 	 *   This event is affiliated with an Fexch QP.
239 	 *
240 	 * NOTE: When an event fires on this EQ, it will demux the type and
241 	 * 	send it to the right specific handler routine
242 	 *
243 	 */
244 	event_mask =
245 	    HERMON_EVT_MSK_PORT_STATE_CHANGE |
246 	    HERMON_EVT_MSK_COMM_ESTABLISHED |
247 	    HERMON_EVT_MSK_COMMAND_INTF_COMP |
248 	    HERMON_EVT_MSK_LOCAL_WQ_CAT_ERROR |
249 	    HERMON_EVT_MSK_INV_REQ_LOCAL_WQ_ERROR |
250 	    HERMON_EVT_MSK_LOCAL_ACC_VIO_WQ_ERROR |
251 	    HERMON_EVT_MSK_SEND_QUEUE_DRAINED |
252 	    HERMON_EVT_MSK_PATH_MIGRATED |
253 	    HERMON_EVT_MSK_PATH_MIGRATE_FAILED |
254 	    HERMON_EVT_MSK_SRQ_CATASTROPHIC_ERROR |
255 	    HERMON_EVT_MSK_SRQ_LAST_WQE_REACHED |
256 	    HERMON_EVT_MSK_FEXCH_ERROR;
257 
258 	status = hermon_eq_handler_init(state, eq[num_eq_unmap + num_extra],
259 	    event_mask, hermon_eq_demux);
260 	if (status != DDI_SUCCESS) {
261 		goto all_eq_init_fail;
262 	}
263 	num_eq_unmap++;
264 
265 	/*
266 	 * Setup EQ3 to catch all other types of events.  Specifically, we
267 	 * do not catch the "Local EEC Catastrophic Error Event" because we
268 	 * should have no EEC (the Arbel driver does not support RD).  We also
269 	 * choose not to handle any of the address translation page fault
270 	 * event types.  Since we are not doing any page fault handling (and
271 	 * since the Arbel firmware does not currently support any such
272 	 * handling), we allow these events to go to the catch-all handler.
273 	 */
274 	status = hermon_eq_handler_init(state, eq[num_eq_unmap + num_extra],
275 	    HERMON_EVT_CATCHALL_MASK, hermon_no_eqhandler);
276 	if (status != DDI_SUCCESS) {
277 		goto all_eq_init_fail;
278 	}
279 	num_eq_unmap++;
280 
281 	/* the FMA retry loop starts. */
282 	hermon_pio_start(state, uarhdl, all_eq_init_fail, fm_loop_cnt,
283 	    fm_status, fm_test);
284 
285 	/*
286 	 * Run through and initialize the Consumer Index for each EQC.
287 	 */
288 	for (i = 0; i < num_eq + num_extra; i++) {
289 		ddi_put32(uarhdl, eq[i]->eq_doorbell, 0x0);
290 	}
291 
292 	/* the FMA retry loop ends. */
293 	hermon_pio_end(state, uarhdl, all_eq_init_fail, fm_loop_cnt,
294 	    fm_status, fm_test);
295 
296 	return (DDI_SUCCESS);
297 
298 all_eq_init_fail:
299 
300 	/* Unmap any of the partially mapped EQs from above */
301 	for (i = 0; i < num_eq_unmap + num_extra; i++) {
302 		(void) hermon_eq_handler_fini(state, eq[i]);
303 	}
304 
305 	/* Free up any of the partially allocated EQs from above */
306 	for (i = 0; i < num_eq_init + num_extra; i++) {
307 		(void) hermon_eq_free(state, &eq[i]);
308 	}
309 
310 	/* If a HW error happen during ddi_pio, return DDI_FAILURE */
311 	if (fm_status == HCA_PIO_PERSISTENT) {
312 		hermon_fm_ereport(state, HCA_SYS_ERR, HCA_ERR_NON_FATAL);
313 		status = DDI_FAILURE;
314 	}
315 
316 	return (status);
317 }
318 
319 
320 /*
321  * hermon_eq_fini_all
322  *    Context: Only called from attach() and/or detach() path contexts
323  */
324 int
325 hermon_eq_fini_all(hermon_state_t *state)
326 {
327 	uint_t		num_eq, num_eq_rsvd;
328 	int		status, i;
329 	struct hermon_sw_eq_s **eq;
330 
331 	/*
332 	 * Grab the total number of supported EQs again.  This is the same
333 	 * hardcoded value that was used above (during the event queue
334 	 * initialization.)
335 	 */
336 	num_eq = HERMON_NUM_EQ_USED + state->hs_intrmsi_allocd - 1;
337 	num_eq_rsvd = state->hs_rsvd_eqs;
338 	eq = &state->hs_eqhdl[num_eq_rsvd];
339 
340 	/*
341 	 * For each of the event queues that we initialized and mapped
342 	 * earlier, attempt to unmap the events from the EQ.
343 	 */
344 	for (i = 0; i < num_eq; i++) {
345 		status = hermon_eq_handler_fini(state, eq[i]);
346 		if (status != DDI_SUCCESS) {
347 			return (DDI_FAILURE);
348 		}
349 	}
350 
351 	/*
352 	 * Teardown and free up all the Event Queues that were allocated
353 	 * earlier.
354 	 */
355 	for (i = 0; i < num_eq; i++) {
356 		status = hermon_eq_free(state, &eq[i]);
357 		if (status != DDI_SUCCESS) {
358 			return (DDI_FAILURE);
359 		}
360 	}
361 
362 	return (DDI_SUCCESS);
363 }
364 
365 
366 /*
367  * hermon_eq_reset_uar_baseaddr
368  *    Context: Only called from attach()
369  */
370 void
371 hermon_eq_reset_uar_baseaddr(hermon_state_t *state)
372 {
373 	int i, num_eq;
374 	hermon_eqhdl_t eq, *eqh;
375 
376 	num_eq = HERMON_NUM_EQ_USED + state->hs_intrmsi_allocd - 1;
377 	eqh = &state->hs_eqhdl[state->hs_rsvd_eqs];
378 	for (i = 0; i < num_eq; i++) {
379 		eq = eqh[i];
380 		eq->eq_doorbell = (uint32_t *)
381 		    ((uintptr_t)state->hs_reg_uar_baseaddr +
382 		    (uint32_t)ARM_EQ_INDEX(eq->eq_eqnum));
383 	}
384 }
385 
386 
387 /*
388  * hermon_eq_arm_all
389  *    Context: Only called from attach() and/or detach() path contexts
390  */
391 int
392 hermon_eq_arm_all(hermon_state_t *state)
393 {
394 	uint_t		num_eq, num_eq_rsvd;
395 	uint64_t	offset;
396 	hermon_eqhdl_t	eq;
397 	uint32_t	eq_ci;
398 	int		i;
399 	ddi_acc_handle_t uarhdl = hermon_get_uarhdl(state);
400 
401 	/* initialize the FMA retry loop */
402 	hermon_pio_init(fm_loop_cnt, fm_status, fm_test);
403 
404 	num_eq = HERMON_NUM_EQ_USED + state->hs_intrmsi_allocd - 1;
405 	num_eq_rsvd = state->hs_rsvd_eqs;
406 
407 	/* the FMA retry loop starts. */
408 	hermon_pio_start(state, uarhdl, pio_error, fm_loop_cnt, fm_status,
409 	    fm_test);
410 
411 	for (i = 0; i < num_eq; i++) {
412 		offset = ARM_EQ_INDEX(i + num_eq_rsvd);
413 		eq = state->hs_eqhdl[i + num_eq_rsvd];
414 		eq_ci = (eq->eq_consindx & HERMON_EQ_CI_MASK) | EQ_ARM_BIT;
415 		ddi_put32(uarhdl,
416 		    (uint32_t *)((uintptr_t)state->hs_reg_uar_baseaddr +
417 		    (uint32_t)offset), eq_ci);
418 	}
419 
420 	/* the FMA retry loop ends. */
421 	hermon_pio_end(state, uarhdl, pio_error, fm_loop_cnt, fm_status,
422 	    fm_test);
423 
424 	return (DDI_SUCCESS);
425 
426 pio_error:
427 	hermon_fm_ereport(state, HCA_SYS_ERR, HCA_ERR_NON_FATAL);
428 	return (DDI_FAILURE);
429 }
430 
431 
432 /*
433  * hermon_isr()
434  *    Context: Only called from interrupt context (and during panic)
435  */
436 uint_t
437 hermon_isr(caddr_t arg1, caddr_t arg2)
438 {
439 	hermon_state_t	*state;
440 	int		i, r;
441 	int		intr;
442 
443 	/*
444 	 * Grab the Hermon softstate pointer from the input parameter
445 	 */
446 	state	= (hermon_state_t *)(void *)arg1;
447 
448 	/* Get the interrupt number */
449 	intr = (int)(uintptr_t)arg2;
450 
451 	/*
452 	 * Clear the interrupt.  Note: This is only needed for
453 	 * fixed interrupts as the framework does what is needed for
454 	 * MSI-X interrupts.
455 	 */
456 	if (state->hs_intr_type_chosen == DDI_INTR_TYPE_FIXED) {
457 		ddi_acc_handle_t cmdhdl = hermon_get_cmdhdl(state);
458 
459 		/* initialize the FMA retry loop */
460 		hermon_pio_init(fm_loop_cnt, fm_status, fm_test);
461 
462 		/* the FMA retry loop starts. */
463 		hermon_pio_start(state, cmdhdl, pio_error, fm_loop_cnt,
464 		    fm_status, fm_test);
465 
466 		ddi_put64(cmdhdl, state->hs_cmd_regs.clr_intr,
467 		    (uint64_t)1 << state->hs_adapter.inta_pin);
468 
469 		/* the FMA retry loop ends. */
470 		hermon_pio_end(state, cmdhdl, pio_error, fm_loop_cnt, fm_status,
471 		    fm_test);
472 	}
473 
474 	/*
475 	 * Loop through all the EQs looking for ones that have "fired".
476 	 * To determine if an EQ is fired, the ownership will be the SW
477 	 * (the HW will set the owner appropriately). Update the Consumer Index
478 	 * of the Event Queue Entry (EQE) and pass it to HW by writing it
479 	 * to the respective Set CI DB Register.
480 	 *
481 	 * The "else" case handles the extra EQs used only for completion
482 	 * events, whereas the "if" case deals with the required interrupt
483 	 * vector that is used for all classes of events.
484 	 */
485 	r = state->hs_rsvd_eqs;
486 
487 	if (intr + 1 == state->hs_intrmsi_allocd) {	/* last intr */
488 		r += state->hs_intrmsi_allocd - 1;
489 		for (i = 0; i < HERMON_NUM_EQ_USED; i++) {
490 			hermon_eq_poll(state, state->hs_eqhdl[i + r]);
491 		}
492 	} else {	/* only poll the one EQ */
493 		hermon_eq_poll(state, state->hs_eqhdl[intr + r]);
494 	}
495 
496 	return (DDI_INTR_CLAIMED);
497 
498 pio_error:
499 	hermon_fm_ereport(state, HCA_SYS_ERR, HCA_ERR_FATAL);
500 	return (DDI_INTR_UNCLAIMED);
501 }
502 
503 
504 /*
505  * hermon_eq_poll
506  *    Context: Only called from interrupt context (and during panic)
507  */
508 static void
509 hermon_eq_poll(hermon_state_t *state, hermon_eqhdl_t eq)
510 {
511 	hermon_hw_eqe_t	*eqe;
512 	int		polled_some;
513 	uint32_t	cons_indx, wrap_around_mask, shift;
514 	int (*eqfunction)(hermon_state_t *state, hermon_eqhdl_t eq,
515 	    hermon_hw_eqe_t *eqe);
516 	ddi_acc_handle_t uarhdl = hermon_get_uarhdl(state);
517 
518 	/* initialize the FMA retry loop */
519 	hermon_pio_init(fm_loop_cnt, fm_status, fm_test);
520 
521 	_NOTE(NOW_INVISIBLE_TO_OTHER_THREADS(*eq))
522 
523 	/* Get the consumer pointer index */
524 	cons_indx = eq->eq_consindx;
525 	shift = eq->eq_log_eqsz - HERMON_EQE_OWNER_SHIFT;
526 
527 	/*
528 	 * Calculate the wrap around mask.  Note: This operation only works
529 	 * because all Hermon event queues have power-of-2 sizes
530 	 */
531 	wrap_around_mask = (eq->eq_bufsz - 1);
532 
533 	/* Calculate the pointer to the first EQ entry */
534 	eqe = &eq->eq_buf[(cons_indx & wrap_around_mask)];
535 
536 
537 	_NOTE(NOW_INVISIBLE_TO_OTHER_THREADS(*eqe))
538 
539 	/*
540 	 * Pull the handler function for this EQ from the Hermon Event Queue
541 	 * handle
542 	 */
543 	eqfunction = eq->eq_func;
544 
545 	for (;;) {
546 		polled_some = 0;
547 		while (HERMON_EQE_OWNER_IS_SW(eq, eqe, cons_indx, shift)) {
548 
549 			/*
550 			 * Call the EQ handler function.  But only call if we
551 			 * are not in polled I/O mode (i.e. not processing
552 			 * because of a system panic).  Note: We don't call
553 			 * the EQ handling functions from a system panic
554 			 * because we are primarily concerned only with
555 			 * ensuring that the event queues do not overflow (or,
556 			 * more specifically, the event queue associated with
557 			 * the CQ that is being used in the sync/dump process).
558 			 * Also, we don't want to make any upcalls (to the
559 			 * IBTF) because we can't guarantee when/if those
560 			 * calls would ever return.  And, if we're in panic,
561 			 * then we reached here through a PollCQ() call (from
562 			 * hermon_cq_poll()), and we need to ensure that we
563 			 * successfully return any work completions to the
564 			 * caller.
565 			 */
566 			if (ddi_in_panic() == 0) {
567 				eqfunction(state, eq, eqe);
568 			}
569 
570 			/* Reset to hardware ownership is implicit */
571 
572 			/* Increment the consumer index */
573 			cons_indx++;
574 
575 			/* Update the pointer to the next EQ entry */
576 			eqe = &eq->eq_buf[(cons_indx & wrap_around_mask)];
577 
578 			polled_some = 1;
579 		}
580 
581 		/*
582 		 * write consumer index via EQ set CI Doorbell, to keep overflow
583 		 * from occuring during poll
584 		 */
585 
586 		eq->eq_consindx = cons_indx;
587 
588 		/* the FMA retry loop starts. */
589 		hermon_pio_start(state, uarhdl, pio_error, fm_loop_cnt,
590 		    fm_status, fm_test);
591 
592 		ddi_put32(uarhdl, eq->eq_doorbell,
593 		    (cons_indx & HERMON_EQ_CI_MASK) | EQ_ARM_BIT);
594 
595 		/* the FMA retry loop starts. */
596 		hermon_pio_end(state, uarhdl, pio_error, fm_loop_cnt,
597 		    fm_status, fm_test);
598 
599 		if (polled_some == 0)
600 			break;
601 	};
602 	return;
603 
604 pio_error:
605 	hermon_fm_ereport(state, HCA_SYS_ERR, HCA_ERR_FATAL);
606 }
607 
608 
609 /*
610  * hermon_eq_catastrophic
611  *    Context: Only called from interrupt context (and during panic)
612  */
613 static void
614 hermon_eq_catastrophic(hermon_state_t *state)
615 {
616 	ddi_acc_handle_t	cmdhdl = hermon_get_cmdhdl(state);
617 	ibt_async_code_t	type;
618 	ibc_async_event_t	event;
619 	uint32_t		*base_addr;
620 	uint32_t		buf_size;
621 	uint32_t		word;
622 	uint8_t			err_type;
623 	uint32_t		err_buf;
624 	int			i;
625 
626 	/* initialize the FMA retry loop */
627 	hermon_pio_init(fm_loop_cnt, fm_status, fm_test);
628 
629 	bzero(&event, sizeof (ibc_async_event_t));
630 	base_addr = state->hs_cmd_regs.fw_err_buf;
631 
632 	buf_size = state->hs_fw.error_buf_sz;	/* in #dwords */
633 
634 	/* the FMA retry loop starts. */
635 	hermon_pio_start(state, cmdhdl, pio_error, fm_loop_cnt, fm_status,
636 	    fm_test);
637 
638 	word = ddi_get32(cmdhdl, base_addr);
639 
640 	/* the FMA retry loop ends. */
641 	hermon_pio_end(state, cmdhdl, pio_error, fm_loop_cnt, fm_status,
642 	    fm_test);
643 
644 	err_type = (word & 0xFF000000) >> 24;
645 	type	 = IBT_ERROR_LOCAL_CATASTROPHIC;
646 
647 	switch (err_type) {
648 	case HERMON_CATASTROPHIC_INTERNAL_ERROR:
649 		cmn_err(CE_WARN, "Catastrophic Internal Error: 0x%02x",
650 		    err_type);
651 
652 		break;
653 
654 	case HERMON_CATASTROPHIC_UPLINK_BUS_ERROR:
655 		cmn_err(CE_WARN, "Catastrophic Uplink Bus Error: 0x%02x",
656 		    err_type);
657 
658 		break;
659 
660 	case HERMON_CATASTROPHIC_DDR_DATA_ERROR:
661 		cmn_err(CE_WARN, "Catastrophic DDR Data Error: 0x%02x",
662 		    err_type);
663 
664 		break;
665 
666 	case HERMON_CATASTROPHIC_INTERNAL_PARITY_ERROR:
667 		cmn_err(CE_WARN, "Catastrophic Internal Parity Error: 0x%02x",
668 		    err_type);
669 
670 		break;
671 
672 	default:
673 		/* Unknown type of Catastrophic error */
674 		cmn_err(CE_WARN, "Catastrophic Unknown Error: 0x%02x",
675 		    err_type);
676 
677 		break;
678 	}
679 
680 	/* the FMA retry loop starts. */
681 	hermon_pio_start(state, cmdhdl, pio_error, fm_loop_cnt, fm_status,
682 	    fm_test);
683 
684 	/*
685 	 * Read in the catastrophic error buffer from the hardware.
686 	 */
687 	for (i = 0; i < buf_size; i++) {
688 		base_addr =
689 		    (state->hs_cmd_regs.fw_err_buf + i);
690 		err_buf = ddi_get32(cmdhdl, base_addr);
691 		cmn_err(CE_NOTE, "hermon%d: catastrophic_error[%02x]: %08X",
692 		    state->hs_instance, i, err_buf);
693 	}
694 
695 	/* the FMA retry loop ends. */
696 	hermon_pio_end(state, cmdhdl, pio_error, fm_loop_cnt, fm_status,
697 	    fm_test);
698 
699 	/*
700 	 * We also call the IBTF here to inform it of the catastrophic error.
701 	 * Note: Since no event information (i.e. QP handles, CQ handles,
702 	 * etc.) is necessary, we pass a NULL pointer instead of a pointer to
703 	 * an empty ibc_async_event_t struct.
704 	 *
705 	 * But we also check if "hs_ibtfpriv" is NULL.  If it is then it
706 	 * means that we've have either received this event before we
707 	 * finished attaching to the IBTF or we've received it while we
708 	 * are in the process of detaching.
709 	 */
710 	if (state->hs_ibtfpriv != NULL) {
711 		HERMON_DO_IBTF_ASYNC_CALLB(state, type, &event);
712 	}
713 
714 pio_error:
715 	/* ignore these errors but log them because they're harmless. */
716 	hermon_fm_ereport(state, HCA_SYS_ERR, HCA_ERR_NON_FATAL);
717 }
718 
719 
720 /*
721  * hermon_eq_alloc()
722  *    Context: Only called from attach() path context
723  */
724 static int
725 hermon_eq_alloc(hermon_state_t *state, uint32_t log_eq_size, uint_t intr,
726     hermon_eqhdl_t *eqhdl)
727 {
728 	hermon_rsrc_t		*eqc, *rsrc;
729 	hermon_hw_eqc_t		eqc_entry;
730 	hermon_eqhdl_t		eq;
731 	ibt_mr_attr_t		mr_attr;
732 	hermon_mr_options_t	op;
733 	hermon_pdhdl_t		pd;
734 	hermon_mrhdl_t		mr;
735 	hermon_hw_eqe_t		*buf;
736 	int			status;
737 
738 	/* Use the internal protection domain (PD) for setting up EQs */
739 	pd = state->hs_pdhdl_internal;
740 
741 	/* Increment the reference count on the protection domain (PD) */
742 	hermon_pd_refcnt_inc(pd);
743 
744 	/*
745 	 * Allocate an EQ context entry.  This will be filled in with all
746 	 * the necessary parameters to define the Event Queue.  And then
747 	 * ownership will be passed to the hardware in the final step
748 	 * below.  If we fail here, we must undo the protection domain
749 	 * reference count.
750 	 */
751 	status = hermon_rsrc_alloc(state, HERMON_EQC, 1, HERMON_SLEEP, &eqc);
752 	if (status != DDI_SUCCESS) {
753 		status = DDI_FAILURE;
754 		goto eqalloc_fail1;
755 	}
756 
757 	/*
758 	 * Allocate the software structure for tracking the event queue (i.e.
759 	 * the Hermon Event Queue handle).  If we fail here, we must undo the
760 	 * protection domain reference count and the previous resource
761 	 * allocation.
762 	 */
763 	status = hermon_rsrc_alloc(state, HERMON_EQHDL, 1, HERMON_SLEEP, &rsrc);
764 	if (status != DDI_SUCCESS) {
765 		status = DDI_FAILURE;
766 		goto eqalloc_fail2;
767 	}
768 
769 	eq = (hermon_eqhdl_t)rsrc->hr_addr;
770 
771 	/*
772 	 * Allocate the memory for Event Queue.
773 	 */
774 	eq->eq_eqinfo.qa_size = (1 << log_eq_size) * sizeof (hermon_hw_eqe_t);
775 	eq->eq_eqinfo.qa_alloc_align = eq->eq_eqinfo.qa_bind_align = PAGESIZE;
776 
777 	eq->eq_eqinfo.qa_location = HERMON_QUEUE_LOCATION_NORMAL;
778 	status = hermon_queue_alloc(state, &eq->eq_eqinfo, HERMON_SLEEP);
779 	if (status != DDI_SUCCESS) {
780 		status = DDI_FAILURE;
781 		goto eqalloc_fail3;
782 	}
783 
784 	buf = (hermon_hw_eqe_t *)eq->eq_eqinfo.qa_buf_aligned;
785 	/*
786 	 * Initializing each of the Event Queue Entries (EQE) by setting their
787 	 * ownership to hardware ("owner" bit set to HW) is now done by HW
788 	 * when the transfer of ownership (below) of the
789 	 * EQ context itself is done.
790 	 */
791 
792 	/*
793 	 * Register the memory for the EQ.
794 	 *
795 	 * Because we are in the attach path we use NOSLEEP here so that we
796 	 * SPIN in the HCR since the event queues are not setup yet, and we
797 	 * cannot NOSPIN at this point in time.
798 	 */
799 
800 	mr_attr.mr_vaddr = (uint64_t)(uintptr_t)buf;
801 	mr_attr.mr_len	 = eq->eq_eqinfo.qa_size;
802 	mr_attr.mr_as	 = NULL;
803 	mr_attr.mr_flags = IBT_MR_NOSLEEP | IBT_MR_ENABLE_LOCAL_WRITE;
804 	op.mro_bind_type   = state->hs_cfg_profile->cp_iommu_bypass;
805 	op.mro_bind_dmahdl = eq->eq_eqinfo.qa_dmahdl;
806 	op.mro_bind_override_addr = 0;
807 	status = hermon_mr_register(state, pd, &mr_attr, &mr, &op,
808 	    HERMON_EQ_CMPT);
809 	if (status != DDI_SUCCESS) {
810 		status = DDI_FAILURE;
811 		goto eqalloc_fail4;
812 	}
813 	_NOTE(NOW_INVISIBLE_TO_OTHER_THREADS(*mr))
814 
815 	/*
816 	 * Fill in the EQC entry.  This is the final step before passing
817 	 * ownership of the EQC entry to the Hermon hardware.  We use all of
818 	 * the information collected/calculated above to fill in the
819 	 * requisite portions of the EQC.  Note:  We create all EQs in the
820 	 * "fired" state.  We will arm them later (after our interrupt
821 	 * routine had been registered.)
822 	 */
823 	bzero(&eqc_entry, sizeof (hermon_hw_eqc_t));
824 	eqc_entry.state		= HERMON_EQ_ARMED;
825 	eqc_entry.log_eq_sz	= log_eq_size;
826 	eqc_entry.intr		= intr;
827 	eqc_entry.log2_pgsz	= mr->mr_log2_pgsz;
828 	eqc_entry.pg_offs	= eq->eq_eqinfo.qa_pgoffs >> 5;
829 	eqc_entry.mtt_base_addrh = (uint32_t)((mr->mr_mttaddr >> 32) & 0xFF);
830 	eqc_entry.mtt_base_addrl =  mr->mr_mttaddr >> 3;
831 	eqc_entry.cons_indx	= 0x0;
832 	eqc_entry.prod_indx	= 0x0;
833 
834 	/*
835 	 * Write the EQC entry to hardware.  Lastly, we pass ownership of
836 	 * the entry to the hardware (using the Hermon SW2HW_EQ firmware
837 	 * command).  Note: in general, this operation shouldn't fail.  But
838 	 * if it does, we have to undo everything we've done above before
839 	 * returning error.
840 	 */
841 	status = hermon_cmn_ownership_cmd_post(state, SW2HW_EQ, &eqc_entry,
842 	    sizeof (hermon_hw_eqc_t), eqc->hr_indx, HERMON_CMD_NOSLEEP_SPIN);
843 	if (status != HERMON_CMD_SUCCESS) {
844 		cmn_err(CE_NOTE, "hermon%d: SW2HW_EQ command failed: %08x\n",
845 		    state->hs_instance, status);
846 		if (status == HERMON_CMD_INVALID_STATUS) {
847 			hermon_fm_ereport(state, HCA_SYS_ERR, HCA_ERR_SRV_LOST);
848 		}
849 		status = ibc_get_ci_failure(0);
850 		goto eqalloc_fail5;
851 	}
852 
853 	/*
854 	 * Fill in the rest of the Hermon Event Queue handle.  Having
855 	 * successfully transferred ownership of the EQC, we can update the
856 	 * following fields for use in further operations on the EQ.
857 	 */
858 	eq->eq_eqcrsrcp	 = eqc;
859 	eq->eq_rsrcp	 = rsrc;
860 	eq->eq_consindx	 = 0;
861 	eq->eq_eqnum	 = eqc->hr_indx;
862 	eq->eq_buf	 = buf;
863 	eq->eq_bufsz	 = (1 << log_eq_size);
864 	eq->eq_log_eqsz	 = log_eq_size;
865 	eq->eq_mrhdl	 = mr;
866 	eq->eq_doorbell	 = (uint32_t *)((uintptr_t)state->hs_reg_uar_baseaddr +
867 	    (uint32_t)ARM_EQ_INDEX(eq->eq_eqnum));
868 	*eqhdl		 = eq;
869 
870 	return (DDI_SUCCESS);
871 
872 /*
873  * The following is cleanup for all possible failure cases in this routine
874  */
875 eqalloc_fail5:
876 	if (hermon_mr_deregister(state, &mr, HERMON_MR_DEREG_ALL,
877 	    HERMON_NOSLEEP) != DDI_SUCCESS) {
878 		HERMON_WARNING(state, "failed to deregister EQ memory");
879 	}
880 eqalloc_fail4:
881 	hermon_queue_free(&eq->eq_eqinfo);
882 eqalloc_fail3:
883 	hermon_rsrc_free(state, &rsrc);
884 eqalloc_fail2:
885 	hermon_rsrc_free(state, &eqc);
886 eqalloc_fail1:
887 	hermon_pd_refcnt_dec(pd);
888 eqalloc_fail:
889 	return (status);
890 }
891 
892 
893 /*
894  * hermon_eq_free()
895  *    Context: Only called from attach() and/or detach() path contexts
896  */
897 static int
898 hermon_eq_free(hermon_state_t *state, hermon_eqhdl_t *eqhdl)
899 {
900 	hermon_rsrc_t		*eqc, *rsrc;
901 	hermon_hw_eqc_t		eqc_entry;
902 	hermon_pdhdl_t		pd;
903 	hermon_mrhdl_t		mr;
904 	hermon_eqhdl_t		eq;
905 	uint32_t		eqnum;
906 	int			status;
907 
908 	/*
909 	 * Pull all the necessary information from the Hermon Event Queue
910 	 * handle.  This is necessary here because the resource for the
911 	 * EQ handle is going to be freed up as part of this operation.
912 	 */
913 	eq	= *eqhdl;
914 	eqc	= eq->eq_eqcrsrcp;
915 	rsrc	= eq->eq_rsrcp;
916 	pd	= state->hs_pdhdl_internal;
917 	mr	= eq->eq_mrhdl;
918 	eqnum	= eq->eq_eqnum;
919 
920 	/*
921 	 * Reclaim EQC entry from hardware (using the Hermon HW2SW_EQ
922 	 * firmware command).  If the ownership transfer fails for any reason,
923 	 * then it is an indication that something (either in HW or SW) has
924 	 * gone seriously wrong.
925 	 */
926 	status = hermon_cmn_ownership_cmd_post(state, HW2SW_EQ, &eqc_entry,
927 	    sizeof (hermon_hw_eqc_t), eqnum, HERMON_CMD_NOSLEEP_SPIN);
928 	if (status != HERMON_CMD_SUCCESS) {
929 		HERMON_WARNING(state, "failed to reclaim EQC ownership");
930 		cmn_err(CE_CONT, "Hermon: HW2SW_EQ command failed: %08x\n",
931 		    status);
932 		return (DDI_FAILURE);
933 	}
934 
935 	/*
936 	 * Deregister the memory for the Event Queue.  If this fails
937 	 * for any reason, then it is an indication that something (either
938 	 * in HW or SW) has gone seriously wrong.  So we print a warning
939 	 * message and continue.
940 	 */
941 	status = hermon_mr_deregister(state, &mr, HERMON_MR_DEREG_ALL,
942 	    HERMON_NOSLEEP);
943 	if (status != DDI_SUCCESS) {
944 		HERMON_WARNING(state, "failed to deregister EQ memory");
945 	}
946 
947 	/* Free the memory for the EQ */
948 	hermon_queue_free(&eq->eq_eqinfo);
949 
950 	/* Free the Hermon Event Queue handle */
951 	hermon_rsrc_free(state, &rsrc);
952 
953 	/* Free up the EQC entry resource */
954 	hermon_rsrc_free(state, &eqc);
955 
956 	/* Decrement the reference count on the protection domain (PD) */
957 	hermon_pd_refcnt_dec(pd);
958 
959 	/* Set the eqhdl pointer to NULL and return success */
960 	*eqhdl = NULL;
961 
962 	return (DDI_SUCCESS);
963 }
964 
965 
966 /*
967  * hermon_eq_handler_init
968  *    Context: Only called from attach() path context
969  */
970 static int
971 hermon_eq_handler_init(hermon_state_t *state, hermon_eqhdl_t eq,
972     uint_t evt_type_mask, int (*eq_func)(hermon_state_t *state,
973     hermon_eqhdl_t eq, hermon_hw_eqe_t *eqe))
974 {
975 	int		status;
976 
977 	/*
978 	 * Save away the EQ handler function and the event type mask.  These
979 	 * will be used later during interrupt and event queue processing.
980 	 */
981 	eq->eq_func	   = eq_func;
982 	eq->eq_evttypemask = evt_type_mask;
983 
984 	/*
985 	 * Map the EQ to a specific class of event (or events) depending
986 	 * on the mask value passed in.  The HERMON_EVT_NO_MASK means not
987 	 * to attempt associating the EQ with any specific class of event.
988 	 * This is particularly useful when initializing the events queues
989 	 * used for CQ events.   The mapping is done using the Hermon MAP_EQ
990 	 * firmware command.  Note: This command should not, in general, fail.
991 	 * If it does, then something (probably HW related) has gone seriously
992 	 * wrong.
993 	 */
994 	if (evt_type_mask != HERMON_EVT_NO_MASK) {
995 		status = hermon_map_eq_cmd_post(state,
996 		    HERMON_CMD_MAP_EQ_EVT_MAP, eq->eq_eqnum, evt_type_mask,
997 		    HERMON_CMD_NOSLEEP_SPIN);
998 		if (status != HERMON_CMD_SUCCESS) {
999 			cmn_err(CE_NOTE, "hermon%d: MAP_EQ command failed: "
1000 			    "%08x\n", state->hs_instance, status);
1001 			return (DDI_FAILURE);
1002 		}
1003 	}
1004 
1005 	return (DDI_SUCCESS);
1006 }
1007 
1008 
1009 /*
1010  * hermon_eq_handler_fini
1011  *    Context: Only called from attach() and/or detach() path contexts
1012  */
1013 static int
1014 hermon_eq_handler_fini(hermon_state_t *state, hermon_eqhdl_t eq)
1015 {
1016 	int			status;
1017 
1018 	/*
1019 	 * Unmap the EQ from the event class to which it had been previously
1020 	 * mapped.  The unmapping is done using the Hermon MAP_EQ (in much
1021 	 * the same way that the initial mapping was done).  The difference,
1022 	 * however, is in the HERMON_EQ_EVT_UNMAP flag that is passed to the
1023 	 * MAP_EQ firmware command.  The HERMON_EVT_NO_MASK (which may have
1024 	 * been passed in at init time) still means that no association has
1025 	 * been made between the EQ and any specific class of event (and,
1026 	 * hence, no unmapping is necessary).  Note: This command should not,
1027 	 * in general, fail.  If it does, then something (probably HW related)
1028 	 * has gone seriously wrong.
1029 	 */
1030 	if (eq->eq_evttypemask != HERMON_EVT_NO_MASK) {
1031 		status = hermon_map_eq_cmd_post(state,
1032 		    HERMON_CMD_MAP_EQ_EVT_UNMAP, eq->eq_eqnum,
1033 		    eq->eq_evttypemask, HERMON_CMD_NOSLEEP_SPIN);
1034 		if (status != HERMON_CMD_SUCCESS) {
1035 			cmn_err(CE_NOTE, "hermon%d: MAP_EQ command failed: "
1036 			    "%08x\n", state->hs_instance, status);
1037 			return (DDI_FAILURE);
1038 		}
1039 	}
1040 
1041 	return (DDI_SUCCESS);
1042 }
1043 
1044 
1045 /*
1046  * hermon_eq_demux()
1047  *	Context: Called only from interrupt context
1048  *	Usage:  to demux the various type reported on one EQ
1049  */
1050 static int
1051 hermon_eq_demux(hermon_state_t *state, hermon_eqhdl_t eq,
1052     hermon_hw_eqe_t *eqe)
1053 {
1054 	uint_t			eqe_evttype;
1055 	int			status = DDI_FAILURE;
1056 
1057 	eqe_evttype = HERMON_EQE_EVTTYPE_GET(eq, eqe);
1058 
1059 	switch (eqe_evttype) {
1060 
1061 	case HERMON_EVT_PORT_STATE_CHANGE:
1062 		status = hermon_port_state_change_handler(state, eq, eqe);
1063 		break;
1064 
1065 	case HERMON_EVT_COMM_ESTABLISHED:
1066 		status = hermon_comm_estbl_handler(state, eq, eqe);
1067 		break;
1068 
1069 	case HERMON_EVT_COMMAND_INTF_COMP:
1070 		status = hermon_cmd_complete_handler(state, eq, eqe);
1071 		break;
1072 
1073 	case HERMON_EVT_LOCAL_WQ_CAT_ERROR:
1074 		HERMON_WARNING(state, HERMON_FMA_LOCCAT);
1075 		status = hermon_local_wq_cat_err_handler(state, eq, eqe);
1076 		break;
1077 
1078 	case HERMON_EVT_INV_REQ_LOCAL_WQ_ERROR:
1079 		HERMON_WARNING(state, HERMON_FMA_LOCINV);
1080 		status = hermon_invreq_local_wq_err_handler(state, eq, eqe);
1081 		break;
1082 
1083 	case HERMON_EVT_LOCAL_ACC_VIO_WQ_ERROR:
1084 		HERMON_WARNING(state, HERMON_FMA_LOCACEQ);
1085 		IBTF_DPRINTF_L2("async", HERMON_FMA_LOCACEQ);
1086 		status = hermon_local_acc_vio_wq_err_handler(state, eq, eqe);
1087 		break;
1088 	case HERMON_EVT_SEND_QUEUE_DRAINED:
1089 		status = hermon_sendq_drained_handler(state, eq, eqe);
1090 		break;
1091 
1092 	case HERMON_EVT_PATH_MIGRATED:
1093 		status = hermon_path_mig_handler(state, eq, eqe);
1094 		break;
1095 
1096 	case HERMON_EVT_PATH_MIGRATE_FAILED:
1097 		HERMON_WARNING(state, HERMON_FMA_PATHMIG);
1098 		status = hermon_path_mig_err_handler(state, eq, eqe);
1099 		break;
1100 
1101 	case HERMON_EVT_SRQ_CATASTROPHIC_ERROR:
1102 		HERMON_WARNING(state, HERMON_FMA_SRQCAT);
1103 		status = hermon_catastrophic_handler(state, eq, eqe);
1104 		break;
1105 
1106 	case HERMON_EVT_SRQ_LAST_WQE_REACHED:
1107 		status = hermon_srq_last_wqe_reached_handler(state, eq, eqe);
1108 		break;
1109 
1110 	case HERMON_EVT_FEXCH_ERROR:
1111 		status = hermon_fexch_error_handler(state, eq, eqe);
1112 		break;
1113 
1114 	default:
1115 		break;
1116 	}
1117 	return (status);
1118 }
1119 
1120 /*
1121  * hermon_port_state_change_handler()
1122  *    Context: Only called from interrupt context
1123  */
1124 /* ARGSUSED */
1125 static int
1126 hermon_port_state_change_handler(hermon_state_t *state, hermon_eqhdl_t eq,
1127     hermon_hw_eqe_t *eqe)
1128 {
1129 	ibc_async_event_t	event;
1130 	ibt_async_code_t	type;
1131 	uint_t			subtype;
1132 	uint8_t			port;
1133 	char			link_msg[24];
1134 
1135 	/*
1136 	 * Depending on the type of Port State Change event, pass the
1137 	 * appropriate asynch event to the IBTF.
1138 	 */
1139 	port = (uint8_t)HERMON_EQE_PORTNUM_GET(eq, eqe);
1140 
1141 	/* Check for valid port number in event */
1142 	if ((port == 0) || (port > state->hs_cfg_profile->cp_num_ports)) {
1143 		HERMON_WARNING(state, "Unexpected port number in port state "
1144 		    "change event");
1145 		cmn_err(CE_CONT, "  Port number: %02x\n", port);
1146 		return (DDI_FAILURE);
1147 	}
1148 
1149 	subtype = HERMON_EQE_EVTSUBTYPE_GET(eq, eqe);
1150 	if (subtype == HERMON_PORT_LINK_ACTIVE) {
1151 		event.ev_port 	= port;
1152 		type		= IBT_EVENT_PORT_UP;
1153 
1154 		(void) snprintf(link_msg, 23, "port %d up", port);
1155 		ddi_dev_report_fault(state->hs_dip, DDI_SERVICE_RESTORED,
1156 		    DDI_EXTERNAL_FAULT, link_msg);
1157 	} else if (subtype == HERMON_PORT_LINK_DOWN) {
1158 		event.ev_port	= port;
1159 		type		= IBT_ERROR_PORT_DOWN;
1160 
1161 		(void) snprintf(link_msg, 23, "port %d down", port);
1162 		ddi_dev_report_fault(state->hs_dip, DDI_SERVICE_LOST,
1163 		    DDI_EXTERNAL_FAULT, link_msg);
1164 	} else {
1165 		HERMON_WARNING(state, "Unexpected subtype in port state change "
1166 		    "event");
1167 		cmn_err(CE_CONT, "  Event type: %02x, subtype: %02x\n",
1168 		    HERMON_EQE_EVTTYPE_GET(eq, eqe), subtype);
1169 		return (DDI_FAILURE);
1170 	}
1171 
1172 	/*
1173 	 * Deliver the event to the IBTF.  Note: If "hs_ibtfpriv" is NULL,
1174 	 * then we have either received this event before we finished
1175 	 * attaching to the IBTF or we've received it while we are in the
1176 	 * process of detaching.
1177 	 */
1178 	if (state->hs_ibtfpriv != NULL) {
1179 		HERMON_DO_IBTF_ASYNC_CALLB(state, type, &event);
1180 	}
1181 
1182 	return (DDI_SUCCESS);
1183 }
1184 
1185 
1186 /*
1187  * hermon_comm_estbl_handler()
1188  *    Context: Only called from interrupt context
1189  */
1190 /* ARGSUSED */
1191 static int
1192 hermon_comm_estbl_handler(hermon_state_t *state, hermon_eqhdl_t eq,
1193     hermon_hw_eqe_t *eqe)
1194 {
1195 	hermon_qphdl_t		qp;
1196 	uint_t			qpnum;
1197 	ibc_async_event_t	event;
1198 	ibt_async_code_t	type;
1199 
1200 	/* Get the QP handle from QP number in event descriptor */
1201 	qpnum = HERMON_EQE_QPNUM_GET(eq, eqe);
1202 	qp = hermon_qphdl_from_qpnum(state, qpnum);
1203 
1204 	/*
1205 	 * If the QP handle is NULL, this is probably an indication
1206 	 * that the QP has been freed already.  In which case, we
1207 	 * should not deliver this event.
1208 	 *
1209 	 * We also check that the QP number in the handle is the
1210 	 * same as the QP number in the event queue entry.  This
1211 	 * extra check allows us to handle the case where a QP was
1212 	 * freed and then allocated again in the time it took to
1213 	 * handle the event queue processing.  By constantly incrementing
1214 	 * the non-constrained portion of the QP number every time
1215 	 * a new QP is allocated, we mitigate (somewhat) the chance
1216 	 * that a stale event could be passed to the client's QP
1217 	 * handler.
1218 	 *
1219 	 * Lastly, we check if "hs_ibtfpriv" is NULL.  If it is then it
1220 	 * means that we've have either received this event before we
1221 	 * finished attaching to the IBTF or we've received it while we
1222 	 * are in the process of detaching.
1223 	 */
1224 	if ((qp != NULL) && (qp->qp_qpnum == qpnum) &&
1225 	    (state->hs_ibtfpriv != NULL)) {
1226 		event.ev_qp_hdl = (ibtl_qp_hdl_t)qp->qp_hdlrarg;
1227 		type		= IBT_EVENT_COM_EST_QP;
1228 
1229 		HERMON_DO_IBTF_ASYNC_CALLB(state, type, &event);
1230 	}
1231 
1232 	return (DDI_SUCCESS);
1233 }
1234 
1235 
1236 /*
1237  * hermon_local_wq_cat_err_handler()
1238  *    Context: Only called from interrupt context
1239  */
1240 /* ARGSUSED */
1241 static int
1242 hermon_local_wq_cat_err_handler(hermon_state_t *state, hermon_eqhdl_t eq,
1243     hermon_hw_eqe_t *eqe)
1244 {
1245 	hermon_qphdl_t		qp;
1246 	uint_t			qpnum;
1247 	ibc_async_event_t	event;
1248 	ibt_async_code_t	type;
1249 
1250 	/* Get the QP handle from QP number in event descriptor */
1251 	qpnum = HERMON_EQE_QPNUM_GET(eq, eqe);
1252 	qp = hermon_qphdl_from_qpnum(state, qpnum);
1253 
1254 	/*
1255 	 * If the QP handle is NULL, this is probably an indication
1256 	 * that the QP has been freed already.  In which case, we
1257 	 * should not deliver this event.
1258 	 *
1259 	 * We also check that the QP number in the handle is the
1260 	 * same as the QP number in the event queue entry.  This
1261 	 * extra check allows us to handle the case where a QP was
1262 	 * freed and then allocated again in the time it took to
1263 	 * handle the event queue processing.  By constantly incrementing
1264 	 * the non-constrained portion of the QP number every time
1265 	 * a new QP is allocated, we mitigate (somewhat) the chance
1266 	 * that a stale event could be passed to the client's QP
1267 	 * handler.
1268 	 *
1269 	 * Lastly, we check if "hs_ibtfpriv" is NULL.  If it is then it
1270 	 * means that we've have either received this event before we
1271 	 * finished attaching to the IBTF or we've received it while we
1272 	 * are in the process of detaching.
1273 	 */
1274 	if ((qp != NULL) && (qp->qp_qpnum == qpnum) &&
1275 	    (state->hs_ibtfpriv != NULL)) {
1276 		event.ev_qp_hdl = (ibtl_qp_hdl_t)qp->qp_hdlrarg;
1277 		type		= IBT_ERROR_CATASTROPHIC_QP;
1278 
1279 		HERMON_DO_IBTF_ASYNC_CALLB(state, type, &event);
1280 	}
1281 
1282 	return (DDI_SUCCESS);
1283 }
1284 
1285 
1286 /*
1287  * hermon_invreq_local_wq_err_handler()
1288  *    Context: Only called from interrupt context
1289  */
1290 /* ARGSUSED */
1291 static int
1292 hermon_invreq_local_wq_err_handler(hermon_state_t *state, hermon_eqhdl_t eq,
1293     hermon_hw_eqe_t *eqe)
1294 {
1295 	hermon_qphdl_t		qp;
1296 	uint_t			qpnum;
1297 	ibc_async_event_t	event;
1298 	ibt_async_code_t	type;
1299 
1300 	/* Get the QP handle from QP number in event descriptor */
1301 	qpnum = HERMON_EQE_QPNUM_GET(eq, eqe);
1302 	qp = hermon_qphdl_from_qpnum(state, qpnum);
1303 
1304 	/*
1305 	 * If the QP handle is NULL, this is probably an indication
1306 	 * that the QP has been freed already.  In which case, we
1307 	 * should not deliver this event.
1308 	 *
1309 	 * We also check that the QP number in the handle is the
1310 	 * same as the QP number in the event queue entry.  This
1311 	 * extra check allows us to handle the case where a QP was
1312 	 * freed and then allocated again in the time it took to
1313 	 * handle the event queue processing.  By constantly incrementing
1314 	 * the non-constrained portion of the QP number every time
1315 	 * a new QP is allocated, we mitigate (somewhat) the chance
1316 	 * that a stale event could be passed to the client's QP
1317 	 * handler.
1318 	 *
1319 	 * Lastly, we check if "hs_ibtfpriv" is NULL.  If it is then it
1320 	 * means that we've have either received this event before we
1321 	 * finished attaching to the IBTF or we've received it while we
1322 	 * are in the process of detaching.
1323 	 */
1324 	if ((qp != NULL) && (qp->qp_qpnum == qpnum) &&
1325 	    (state->hs_ibtfpriv != NULL)) {
1326 		event.ev_qp_hdl = (ibtl_qp_hdl_t)qp->qp_hdlrarg;
1327 		type		= IBT_ERROR_INVALID_REQUEST_QP;
1328 
1329 		HERMON_DO_IBTF_ASYNC_CALLB(state, type, &event);
1330 	}
1331 
1332 	return (DDI_SUCCESS);
1333 }
1334 
1335 
1336 /*
1337  * hermon_local_acc_vio_wq_err_handler()
1338  *    Context: Only called from interrupt context
1339  */
1340 /* ARGSUSED */
1341 static int
1342 hermon_local_acc_vio_wq_err_handler(hermon_state_t *state, hermon_eqhdl_t eq,
1343     hermon_hw_eqe_t *eqe)
1344 {
1345 	hermon_qphdl_t		qp;
1346 	uint_t			qpnum;
1347 	ibc_async_event_t	event;
1348 	ibt_async_code_t	type;
1349 
1350 	/* Get the QP handle from QP number in event descriptor */
1351 	qpnum = HERMON_EQE_QPNUM_GET(eq, eqe);
1352 	qp = hermon_qphdl_from_qpnum(state, qpnum);
1353 
1354 	/*
1355 	 * If the QP handle is NULL, this is probably an indication
1356 	 * that the QP has been freed already.  In which case, we
1357 	 * should not deliver this event.
1358 	 *
1359 	 * We also check that the QP number in the handle is the
1360 	 * same as the QP number in the event queue entry.  This
1361 	 * extra check allows us to handle the case where a QP was
1362 	 * freed and then allocated again in the time it took to
1363 	 * handle the event queue processing.  By constantly incrementing
1364 	 * the non-constrained portion of the QP number every time
1365 	 * a new QP is allocated, we mitigate (somewhat) the chance
1366 	 * that a stale event could be passed to the client's QP
1367 	 * handler.
1368 	 *
1369 	 * Lastly, we check if "hs_ibtfpriv" is NULL.  If it is then it
1370 	 * means that we've have either received this event before we
1371 	 * finished attaching to the IBTF or we've received it while we
1372 	 * are in the process of detaching.
1373 	 */
1374 	if ((qp != NULL) && (qp->qp_qpnum == qpnum) &&
1375 	    (state->hs_ibtfpriv != NULL)) {
1376 		event.ev_qp_hdl = (ibtl_qp_hdl_t)qp->qp_hdlrarg;
1377 		type		= IBT_ERROR_ACCESS_VIOLATION_QP;
1378 
1379 		HERMON_DO_IBTF_ASYNC_CALLB(state, type, &event);
1380 	}
1381 
1382 	return (DDI_SUCCESS);
1383 }
1384 
1385 
1386 /*
1387  * hermon_sendq_drained_handler()
1388  *    Context: Only called from interrupt context
1389  */
1390 /* ARGSUSED */
1391 static int
1392 hermon_sendq_drained_handler(hermon_state_t *state, hermon_eqhdl_t eq,
1393     hermon_hw_eqe_t *eqe)
1394 {
1395 	hermon_qphdl_t		qp;
1396 	uint_t			qpnum;
1397 	ibc_async_event_t	event;
1398 	uint_t			forward_sqd_event;
1399 	ibt_async_code_t	type;
1400 
1401 	/* Get the QP handle from QP number in event descriptor */
1402 	qpnum = HERMON_EQE_QPNUM_GET(eq, eqe);
1403 	qp = hermon_qphdl_from_qpnum(state, qpnum);
1404 
1405 	/*
1406 	 * If the QP handle is NULL, this is probably an indication
1407 	 * that the QP has been freed already.  In which case, we
1408 	 * should not deliver this event.
1409 	 *
1410 	 * We also check that the QP number in the handle is the
1411 	 * same as the QP number in the event queue entry.  This
1412 	 * extra check allows us to handle the case where a QP was
1413 	 * freed and then allocated again in the time it took to
1414 	 * handle the event queue processing.  By constantly incrementing
1415 	 * the non-constrained portion of the QP number every time
1416 	 * a new QP is allocated, we mitigate (somewhat) the chance
1417 	 * that a stale event could be passed to the client's QP
1418 	 * handler.
1419 	 *
1420 	 * And then we check if "hs_ibtfpriv" is NULL.  If it is then it
1421 	 * means that we've have either received this event before we
1422 	 * finished attaching to the IBTF or we've received it while we
1423 	 * are in the process of detaching.
1424 	 */
1425 	if ((qp != NULL) && (qp->qp_qpnum == qpnum) &&
1426 	    (state->hs_ibtfpriv != NULL)) {
1427 		event.ev_qp_hdl = (ibtl_qp_hdl_t)qp->qp_hdlrarg;
1428 		type		= IBT_EVENT_SQD;
1429 
1430 		/*
1431 		 * Grab the QP lock and update the QP state to reflect that
1432 		 * the Send Queue Drained event has arrived.  Also determine
1433 		 * whether the event is intended to be forwarded on to the
1434 		 * consumer or not.  This information is used below in
1435 		 * determining whether or not to call the IBTF.
1436 		 */
1437 		mutex_enter(&qp->qp_lock);
1438 		forward_sqd_event = qp->qp_forward_sqd_event;
1439 		qp->qp_forward_sqd_event  = 0;
1440 		qp->qp_sqd_still_draining = 0;
1441 		mutex_exit(&qp->qp_lock);
1442 
1443 		if (forward_sqd_event != 0) {
1444 			HERMON_DO_IBTF_ASYNC_CALLB(state, type, &event);
1445 		}
1446 	}
1447 
1448 	return (DDI_SUCCESS);
1449 }
1450 
1451 
1452 /*
1453  * hermon_path_mig_handler()
1454  *    Context: Only called from interrupt context
1455  */
1456 /* ARGSUSED */
1457 static int
1458 hermon_path_mig_handler(hermon_state_t *state, hermon_eqhdl_t eq,
1459     hermon_hw_eqe_t *eqe)
1460 {
1461 	hermon_qphdl_t		qp;
1462 	uint_t			qpnum;
1463 	ibc_async_event_t	event;
1464 	ibt_async_code_t	type;
1465 
1466 	/* Get the QP handle from QP number in event descriptor */
1467 	qpnum = HERMON_EQE_QPNUM_GET(eq, eqe);
1468 	qp = hermon_qphdl_from_qpnum(state, qpnum);
1469 
1470 	/*
1471 	 * If the QP handle is NULL, this is probably an indication
1472 	 * that the QP has been freed already.  In which case, we
1473 	 * should not deliver this event.
1474 	 *
1475 	 * We also check that the QP number in the handle is the
1476 	 * same as the QP number in the event queue entry.  This
1477 	 * extra check allows us to handle the case where a QP was
1478 	 * freed and then allocated again in the time it took to
1479 	 * handle the event queue processing.  By constantly incrementing
1480 	 * the non-constrained portion of the QP number every time
1481 	 * a new QP is allocated, we mitigate (somewhat) the chance
1482 	 * that a stale event could be passed to the client's QP
1483 	 * handler.
1484 	 *
1485 	 * Lastly, we check if "hs_ibtfpriv" is NULL.  If it is then it
1486 	 * means that we've have either received this event before we
1487 	 * finished attaching to the IBTF or we've received it while we
1488 	 * are in the process of detaching.
1489 	 */
1490 	if ((qp != NULL) && (qp->qp_qpnum == qpnum) &&
1491 	    (state->hs_ibtfpriv != NULL)) {
1492 		event.ev_qp_hdl = (ibtl_qp_hdl_t)qp->qp_hdlrarg;
1493 		type		= IBT_EVENT_PATH_MIGRATED_QP;
1494 
1495 		HERMON_DO_IBTF_ASYNC_CALLB(state, type, &event);
1496 	}
1497 
1498 	return (DDI_SUCCESS);
1499 }
1500 
1501 
1502 /*
1503  * hermon_path_mig_err_handler()
1504  *    Context: Only called from interrupt context
1505  */
1506 /* ARGSUSED */
1507 static int
1508 hermon_path_mig_err_handler(hermon_state_t *state, hermon_eqhdl_t eq,
1509     hermon_hw_eqe_t *eqe)
1510 {
1511 	hermon_qphdl_t		qp;
1512 	uint_t			qpnum;
1513 	ibc_async_event_t	event;
1514 	ibt_async_code_t	type;
1515 
1516 	/* Get the QP handle from QP number in event descriptor */
1517 	qpnum = HERMON_EQE_QPNUM_GET(eq, eqe);
1518 	qp = hermon_qphdl_from_qpnum(state, qpnum);
1519 
1520 	/*
1521 	 * If the QP handle is NULL, this is probably an indication
1522 	 * that the QP has been freed already.  In which case, we
1523 	 * should not deliver this event.
1524 	 *
1525 	 * We also check that the QP number in the handle is the
1526 	 * same as the QP number in the event queue entry.  This
1527 	 * extra check allows us to handle the case where a QP was
1528 	 * freed and then allocated again in the time it took to
1529 	 * handle the event queue processing.  By constantly incrementing
1530 	 * the non-constrained portion of the QP number every time
1531 	 * a new QP is allocated, we mitigate (somewhat) the chance
1532 	 * that a stale event could be passed to the client's QP
1533 	 * handler.
1534 	 *
1535 	 * Lastly, we check if "hs_ibtfpriv" is NULL.  If it is then it
1536 	 * means that we've have either received this event before we
1537 	 * finished attaching to the IBTF or we've received it while we
1538 	 * are in the process of detaching.
1539 	 */
1540 	if ((qp != NULL) && (qp->qp_qpnum == qpnum) &&
1541 	    (state->hs_ibtfpriv != NULL)) {
1542 		event.ev_qp_hdl = (ibtl_qp_hdl_t)qp->qp_hdlrarg;
1543 		type		= IBT_ERROR_PATH_MIGRATE_REQ_QP;
1544 
1545 		HERMON_DO_IBTF_ASYNC_CALLB(state, type, &event);
1546 	}
1547 
1548 	return (DDI_SUCCESS);
1549 }
1550 
1551 
1552 /*
1553  * hermon_catastrophic_handler()
1554  *    Context: Only called from interrupt context
1555  */
1556 /* ARGSUSED */
1557 static int
1558 hermon_catastrophic_handler(hermon_state_t *state, hermon_eqhdl_t eq,
1559     hermon_hw_eqe_t *eqe)
1560 {
1561 	hermon_qphdl_t		qp;
1562 	uint_t			qpnum;
1563 	ibc_async_event_t	event;
1564 	ibt_async_code_t	type;
1565 
1566 	if (eq->eq_evttypemask == HERMON_EVT_MSK_LOCAL_CAT_ERROR) {
1567 		HERMON_FMANOTE(state, HERMON_FMA_INTERNAL);
1568 		hermon_eq_catastrophic(state);
1569 		return (DDI_SUCCESS);
1570 	}
1571 
1572 	/* Get the QP handle from QP number in event descriptor */
1573 	qpnum = HERMON_EQE_QPNUM_GET(eq, eqe);
1574 	qp = hermon_qphdl_from_qpnum(state, qpnum);
1575 
1576 	/*
1577 	 * If the QP handle is NULL, this is probably an indication
1578 	 * that the QP has been freed already.  In which case, we
1579 	 * should not deliver this event.
1580 	 *
1581 	 * We also check that the QP number in the handle is the
1582 	 * same as the QP number in the event queue entry.  This
1583 	 * extra check allows us to handle the case where a QP was
1584 	 * freed and then allocated again in the time it took to
1585 	 * handle the event queue processing.  By constantly incrementing
1586 	 * the non-constrained portion of the QP number every time
1587 	 * a new QP is allocated, we mitigate (somewhat) the chance
1588 	 * that a stale event could be passed to the client's QP
1589 	 * handler.
1590 	 *
1591 	 * Lastly, we check if "hs_ibtfpriv" is NULL.  If it is then it
1592 	 * means that we've have either received this event before we
1593 	 * finished attaching to the IBTF or we've received it while we
1594 	 * are in the process of detaching.
1595 	 */
1596 	if ((qp != NULL) && (qp->qp_qpnum == qpnum) &&
1597 	    (state->hs_ibtfpriv != NULL)) {
1598 		event.ev_srq_hdl = (ibt_srq_hdl_t)qp->qp_srqhdl->srq_hdlrarg;
1599 		type		= IBT_ERROR_CATASTROPHIC_SRQ;
1600 
1601 		mutex_enter(&qp->qp_srqhdl->srq_lock);
1602 		qp->qp_srqhdl->srq_state = HERMON_SRQ_STATE_ERROR;
1603 		mutex_exit(&qp->qp_srqhdl->srq_lock);
1604 
1605 		HERMON_DO_IBTF_ASYNC_CALLB(state, type, &event);
1606 	}
1607 
1608 	return (DDI_SUCCESS);
1609 }
1610 
1611 
1612 /*
1613  * hermon_srq_last_wqe_reached_handler()
1614  *    Context: Only called from interrupt context
1615  */
1616 /* ARGSUSED */
1617 static int
1618 hermon_srq_last_wqe_reached_handler(hermon_state_t *state, hermon_eqhdl_t eq,
1619     hermon_hw_eqe_t *eqe)
1620 {
1621 	hermon_qphdl_t		qp;
1622 	uint_t			qpnum;
1623 	ibc_async_event_t	event;
1624 	ibt_async_code_t	type;
1625 
1626 	/* Get the QP handle from QP number in event descriptor */
1627 	qpnum = HERMON_EQE_QPNUM_GET(eq, eqe);
1628 	qp = hermon_qphdl_from_qpnum(state, qpnum);
1629 
1630 	/*
1631 	 * If the QP handle is NULL, this is probably an indication
1632 	 * that the QP has been freed already.  In which case, we
1633 	 * should not deliver this event.
1634 	 *
1635 	 * We also check that the QP number in the handle is the
1636 	 * same as the QP number in the event queue entry.  This
1637 	 * extra check allows us to handle the case where a QP was
1638 	 * freed and then allocated again in the time it took to
1639 	 * handle the event queue processing.  By constantly incrementing
1640 	 * the non-constrained portion of the QP number every time
1641 	 * a new QP is allocated, we mitigate (somewhat) the chance
1642 	 * that a stale event could be passed to the client's QP
1643 	 * handler.
1644 	 *
1645 	 * Lastly, we check if "hs_ibtfpriv" is NULL.  If it is then it
1646 	 * means that we've have either received this event before we
1647 	 * finished attaching to the IBTF or we've received it while we
1648 	 * are in the process of detaching.
1649 	 */
1650 	if ((qp != NULL) && (qp->qp_qpnum == qpnum) &&
1651 	    (state->hs_ibtfpriv != NULL)) {
1652 		event.ev_qp_hdl = (ibtl_qp_hdl_t)qp->qp_hdlrarg;
1653 		type		= IBT_EVENT_EMPTY_CHAN;
1654 
1655 		HERMON_DO_IBTF_ASYNC_CALLB(state, type, &event);
1656 	}
1657 
1658 	return (DDI_SUCCESS);
1659 }
1660 
1661 
1662 /* ARGSUSED */
1663 static int hermon_fexch_error_handler(hermon_state_t *state,
1664     hermon_eqhdl_t eq, hermon_hw_eqe_t *eqe)
1665 {
1666 	hermon_qphdl_t		qp;
1667 	uint_t			qpnum;
1668 	ibc_async_event_t	event;
1669 	ibt_async_code_t	type;
1670 
1671 	/* Get the QP handle from QP number in event descriptor */
1672 	event.ev_port = HERMON_EQE_FEXCH_PORTNUM_GET(eq, eqe);
1673 	qpnum = hermon_fcoib_qpnum_from_fexch(state,
1674 	    event.ev_port, HERMON_EQE_FEXCH_FEXCH_GET(eq, eqe));
1675 	qp = hermon_qphdl_from_qpnum(state, qpnum);
1676 
1677 	event.ev_fc = HERMON_EQE_FEXCH_SYNDROME_GET(eq, eqe);
1678 
1679 	/*
1680 	 * If the QP handle is NULL, this is probably an indication
1681 	 * that the QP has been freed already.  In which case, we
1682 	 * should not deliver this event.
1683 	 *
1684 	 * We also check that the QP number in the handle is the
1685 	 * same as the QP number in the event queue entry.  This
1686 	 * extra check allows us to handle the case where a QP was
1687 	 * freed and then allocated again in the time it took to
1688 	 * handle the event queue processing.  By constantly incrementing
1689 	 * the non-constrained portion of the QP number every time
1690 	 * a new QP is allocated, we mitigate (somewhat) the chance
1691 	 * that a stale event could be passed to the client's QP
1692 	 * handler.
1693 	 *
1694 	 * Lastly, we check if "hs_ibtfpriv" is NULL.  If it is then it
1695 	 * means that we've have either received this event before we
1696 	 * finished attaching to the IBTF or we've received it while we
1697 	 * are in the process of detaching.
1698 	 */
1699 	if ((qp != NULL) && (qp->qp_qpnum == qpnum) &&
1700 	    (state->hs_ibtfpriv != NULL)) {
1701 		event.ev_qp_hdl = (ibtl_qp_hdl_t)qp->qp_hdlrarg;
1702 		type		= IBT_FEXCH_ERROR;
1703 
1704 		HERMON_DO_IBTF_ASYNC_CALLB(state, type, &event);
1705 	}
1706 
1707 	return (DDI_SUCCESS);
1708 }
1709 
1710 
1711 /*
1712  * hermon_no_eqhandler
1713  *    Context: Only called from interrupt context
1714  */
1715 /* ARGSUSED */
1716 static int
1717 hermon_no_eqhandler(hermon_state_t *state, hermon_eqhdl_t eq,
1718     hermon_hw_eqe_t *eqe)
1719 {
1720 	uint_t		data;
1721 	int		i;
1722 
1723 	/*
1724 	 * This "unexpected event" handler (or "catch-all" handler) will
1725 	 * receive all events for which no other handler has been registered.
1726 	 * If we end up here, then something has probably gone seriously wrong
1727 	 * with the Hermon hardware (or, perhaps, with the software... though
1728 	 * it's unlikely in this case).  The EQE provides all the information
1729 	 * about the event.  So we print a warning message here along with
1730 	 * the contents of the EQE.
1731 	 */
1732 	HERMON_WARNING(state, "Unexpected Event handler");
1733 	cmn_err(CE_CONT, "  Event type: %02x, subtype: %02x\n",
1734 	    HERMON_EQE_EVTTYPE_GET(eq, eqe),
1735 	    HERMON_EQE_EVTSUBTYPE_GET(eq, eqe));
1736 	for (i = 0; i < sizeof (hermon_hw_eqe_t) >> 2; i++) {
1737 		data = ((uint_t *)eqe)[i];
1738 		cmn_err(CE_CONT, "  EQE[%02x]: %08x\n", i, data);
1739 	}
1740 
1741 	return (DDI_SUCCESS);
1742 }
1743