xref: /titanic_44/usr/src/uts/common/io/bnxe/bnxe_intr.c (revision a36f6bde69ea4d4ea2b0a475ce962b9c1c4ef323)
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 2014 QLogic Corporation
24  * The contents of this file are subject to the terms of the
25  * QLogic End User License (the "License").
26  * You may not use this file except in compliance with the License.
27  *
28  * You can obtain a copy of the License at
29  * http://www.qlogic.com/Resources/Documents/DriverDownloadHelp/
30  * QLogic_End_User_Software_License.txt
31  * See the License for the specific language governing permissions
32  * and limitations under the License.
33  */
34 
35 /*
36  * Copyright (c) 2002, 2011, Oracle and/or its affiliates. All rights reserved.
37  */
38 
39 #include "bnxe.h"
40 
41 /*
42  * The interrupt status bit vector is as follows:
43  *
44  *   bit 0: default interrupt
45  *
46  * Single Mode:
47  *
48  *   bits 1-16:  Function 1 (RSS 0-15)
49  *
50  * Multi-Function Mode:
51  *
52  *   bits 1-4:   Virtual Function 1 (RSS 0-3)
53  *   bits 5-8:   Virtual Function 2 (RSS 4-7)
54  *   bits 9-12:  Virtual Function 3 (RSS 8-11)
55  *   bits 13-16: Virtual Function 4 (RSS 12-15)
56  *
57  * While processing interrupts the programmatic index used for the default
58  * status block is 16 and the RSS status blocks are shifted down one (i.e.
59  * 0-15).
60  *
61  * Solaris defaults to 2 MSIX interrupts per function so only the default
62  * interrupt plus one RSS interrupt is used.  This default behavior can be
63  * modified via the /etc/system configuration file.
64  */
65 
66 
67 static inline char * BnxeIntrTypeName(int intrType)
68 {
69     return (intrType == DDI_INTR_TYPE_MSIX)  ? "MSIX"  :
70            (intrType == DDI_INTR_TYPE_MSI)   ? "MSI"   :
71            (intrType == DDI_INTR_TYPE_FIXED) ? "FIXED" :
72                                                "UNKNOWN";
73 }
74 
75 
76 static void BnxeFindDmaHandles(um_device_t * pUM)
77 {
78     lm_address_t physAddr;
79     BnxeMemDma * pTmp;
80     u32_t idx;
81 
82     BNXE_LOCK_ENTER_MEM(pUM);
83 
84     /* find the RSS status blocks */
85 
86     LM_FOREACH_SB_ID(&pUM->lm_dev, idx)
87     {
88         if (CHIP_IS_E1x(&pUM->lm_dev))
89         {
90             physAddr.as_u32.low =
91                 pUM->lm_dev.vars.status_blocks_arr[idx].hc_status_block_data.e1x_sb_data.common.host_sb_addr.lo;
92             physAddr.as_u32.high =
93                 pUM->lm_dev.vars.status_blocks_arr[idx].hc_status_block_data.e1x_sb_data.common.host_sb_addr.hi;
94         }
95         else
96         {
97             physAddr.as_u32.low =
98                 pUM->lm_dev.vars.status_blocks_arr[idx].hc_status_block_data.e2_sb_data.common.host_sb_addr.lo;
99             physAddr.as_u32.high =
100                 pUM->lm_dev.vars.status_blocks_arr[idx].hc_status_block_data.e2_sb_data.common.host_sb_addr.hi;
101         }
102 
103         pTmp = (BnxeMemDma *)d_list_peek_head(&pUM->memDmaList);
104         while (pTmp)
105         {
106             if (pTmp->physAddr.as_ptr == physAddr.as_ptr)
107             {
108                 break;
109             }
110 
111             pTmp = (BnxeMemDma *)d_list_next_entry(&pTmp->link);
112         }
113 
114         if (pTmp == NULL)
115         {
116             BnxeLogWarn(pUM, "Failed to find DMA handle for RSS status block %d", idx);
117         }
118 
119         pUM->statusBlocks[idx] = pTmp;
120     }
121 
122     /* find the default status block */
123 
124     pTmp = (BnxeMemDma *)d_list_peek_head(&pUM->memDmaList);
125     while (pTmp)
126     {
127         if (pTmp->physAddr.as_ptr ==
128             pUM->lm_dev.vars.gen_sp_status_block.blk_phy_address.as_ptr)
129         {
130             break;
131         }
132 
133         pTmp = (BnxeMemDma *)d_list_next_entry(&pTmp->link);
134     }
135 
136     if (pTmp == NULL)
137     {
138         BnxeLogWarn(pUM, "Failed to find DMA handle for default status block");
139     }
140 
141     pUM->statusBlocks[DEF_STATUS_BLOCK_IGU_INDEX] = pTmp;
142 
143     BNXE_LOCK_EXIT_MEM(pUM);
144 }
145 
146 
147 void BnxeIntrIguSbEnable(um_device_t * pUM,
148                          u32_t         idx,
149                          boolean_t     fromISR)
150 {
151     RxQueue * pRxQ = &pUM->rxq[idx];
152     u32_t igu_id = (FCOE_CID(&pUM->lm_dev) == idx) ?
153                        LM_NON_RSS_SB(&pUM->lm_dev) : idx;
154 
155     BNXE_LOCK_ENTER_INTR_FLIP(pUM, igu_id);
156 
157     if (fromISR)
158     {
159         /*
160          * If in an ISR and poll mode is ON then poll mode was flipped in the
161          * ISR which can occur during Rx processing.  If this is the case then
162          * don't do anything.  Only re-enable the IGU when poll mode is OFF.
163          */
164         if (!pRxQ->inPollMode)
165         {
166             lm_int_ack_sb_enable(&pUM->lm_dev, igu_id);
167         }
168     }
169     else
170     {
171         if (!pRxQ->inPollMode)
172         {
173             /* Why are intrs getting enabled on the ring twice...? */
174             cmn_err(CE_PANIC,
175                     "%s: Ring %d, enable intrs and NOT in poll mode!",
176                     BnxeDevName(pUM), igu_id);
177         }
178 
179         atomic_swap_32(&pRxQ->inPollMode, B_FALSE);
180         pRxQ->intrEnableCnt++;
181 
182         lm_int_ack_sb_enable(&pUM->lm_dev, igu_id);
183     }
184 
185     BNXE_LOCK_EXIT_INTR_FLIP(pUM, igu_id);
186 }
187 
188 
189 void BnxeIntrIguSbDisable(um_device_t * pUM,
190                           u32_t         idx,
191                           boolean_t     fromISR)
192 {
193     RxQueue * pRxQ = &pUM->rxq[idx];
194     u32_t igu_id = (FCOE_CID(&pUM->lm_dev) == idx) ?
195                        LM_NON_RSS_SB(&pUM->lm_dev) : idx;
196 
197     BNXE_LOCK_ENTER_INTR_FLIP(pUM, igu_id);
198 
199     if (fromISR)
200     {
201         /* we should never get here when in poll mode... */
202         ASSERT(pRxQ->inPollMode == B_FALSE);
203         lm_int_ack_sb_disable(&pUM->lm_dev, igu_id);
204     }
205     else
206     {
207         if (pRxQ->inPollMode)
208         {
209             /* Why are intrs getting disabled on the ring twice...? */
210             cmn_err(CE_PANIC,
211                     "%s: Ring %d, disable intrs and ALREADY in poll mode!",
212                     BnxeDevName(pUM), igu_id);
213         }
214 
215         /*
216          * Note here that the interrupt can already be disabled if GLDv3
217          * is disabling the interrupt under the context of an ISR.  This is
218          * OK as the inPollMode flag will tell the ISR not to re-enable the
219          * interrupt upon return.
220          */
221 
222         lm_int_ack_sb_disable(&pUM->lm_dev, igu_id);
223 
224         atomic_swap_32(&pRxQ->inPollMode, B_TRUE);
225         pRxQ->intrDisableCnt++;
226     }
227 
228     BNXE_LOCK_EXIT_INTR_FLIP(pUM, igu_id);
229 }
230 
231 
232 static void BnxeServiceDefSbIntr(um_device_t * pUM,
233                                  boolean_t *   pPktsRxed,
234                                  boolean_t *   pPktsTxed)
235 {
236     lm_device_t * pLM = (lm_device_t *)pUM;
237     u32_t         activity_flg         = 0;
238     u16_t         lcl_attn_bits        = 0;
239     u16_t         lcl_attn_ack         = 0;
240     u16_t         asserted_proc_grps   = 0;
241     u16_t         deasserted_proc_grps = 0;
242 
243     *pPktsRxed = B_FALSE;
244     *pPktsTxed = B_FALSE;
245 
246     BnxeLogDbg(pUM, "Default INTR: Handling default status block %d", DEF_STATUS_BLOCK_INDEX);
247 
248     ddi_dma_sync(pUM->statusBlocks[DEF_STATUS_BLOCK_IGU_INDEX]->dmaHandle,
249                  0, 0, DDI_DMA_SYNC_FORKERNEL);
250 
251     if (pUM->fmCapabilities &&
252         BnxeCheckDmaHandle(pUM->statusBlocks[DEF_STATUS_BLOCK_IGU_INDEX]->dmaHandle) != DDI_FM_OK)
253     {
254         ddi_fm_service_impact(pUM->pDev, DDI_SERVICE_DEGRADED);
255     }
256 
257     pUM->intrSbCnt[DEF_STATUS_BLOCK_IGU_INDEX]++;
258 
259     if (lm_is_def_sb_updated(pLM) == 0)
260     {
261         BnxeLogDbg(pUM, "Default INTR: No change in default status index so bail!");
262         pUM->intrSbNoChangeCnt[DEF_STATUS_BLOCK_IGU_INDEX]++;
263 
264         if (pUM->fmCapabilities &&
265             BnxeCheckAccHandle(pLM->vars.reg_handle[BAR_0]) != DDI_FM_OK)
266         {
267             ddi_fm_service_impact(pUM->pDev, DDI_SERVICE_DEGRADED);
268         }
269 
270         return;
271     }
272 
273     /* get a local copy of the indices from the status block */
274     lm_update_def_hc_indices(pLM, DEF_STATUS_BLOCK_INDEX, &activity_flg);
275 
276     BnxeDbgBreakIfFastPath(pUM, !(activity_flg & LM_DEF_EVENT_MASK));
277 
278     BnxeLogDbg(pUM, "Default INTR: processing events on sb: %x, events: 0x%x",
279                DEF_STATUS_BLOCK_INDEX, activity_flg);
280 
281     if (activity_flg & LM_DEF_ATTN_ACTIVE)
282     {
283         /* Attentions! Usually these are bad things we don't want to see */
284 
285         lm_get_attn_info(pLM, &lcl_attn_bits, &lcl_attn_ack);
286 
287         // NOTE: in case the status index of the attention has changed
288         // already (while processing), we could override with it our local
289         // copy. However, this is not a must, since it will be caught at the
290         // end of the loop with the call to lm_is_sb_updated(). In case the
291         // dpc_loop_cnt has exhausted, no worry, since will get an interrupt
292         // for that at a later time.
293 
294         // find out which lines are asserted/deasserted with account to
295         // their states, ASSERT if necessary.
296         GET_ATTN_CHNG_GROUPS(pLM, lcl_attn_bits, lcl_attn_ack,
297                              &asserted_proc_grps, &deasserted_proc_grps);
298 
299         BnxeLogDbg(pUM, "Default INTR: asserted_proc_grps: 0x%x, deasserted_proc_grps:0x%x",
300                    asserted_proc_grps, deasserted_proc_grps);
301 
302         if (asserted_proc_grps)
303         {
304             lm_handle_assertion_processing(pLM, asserted_proc_grps);
305 
306             if (pUM->fmCapabilities &&
307                 BnxeCheckAccHandle(pLM->vars.reg_handle[BAR_0]) != DDI_FM_OK)
308             {
309                 ddi_fm_service_impact(pUM->pDev, DDI_SERVICE_DEGRADED);
310             }
311         }
312 
313         // keep in mind that in the same round, it is possible that this
314         // func will have processing to do regarding deassertion on bits
315         // that are different than the ones processed earlier for assertion
316         // processing.
317 
318         if (deasserted_proc_grps)
319         {
320             lm_handle_deassertion_processing(pLM, deasserted_proc_grps);
321 
322             if (pUM->fmCapabilities &&
323                 BnxeCheckAccHandle(pLM->vars.reg_handle[BAR_0]) != DDI_FM_OK)
324             {
325                 ddi_fm_service_impact(pUM->pDev, DDI_SERVICE_DEGRADED);
326             }
327         }
328     }
329 
330     if (activity_flg & LM_DEF_USTORM_ACTIVE)
331     {
332         /* Check for L4 TOE/iSCSI/FCoE Rx completions. */
333 
334         if (lm_is_rx_completion(pLM, ISCSI_CID(pLM)))
335         {
336             BnxeDbgBreakMsg(pUM, "Unknown iSCSI Rx completion!");
337         }
338 
339         if (lm_is_rx_completion(pLM, FCOE_CID(pLM)))
340         {
341             *pPktsRxed = B_TRUE;
342         }
343     }
344 
345     if (activity_flg & LM_DEF_CSTORM_ACTIVE)
346     {
347         if (lm_is_eq_completion(pLM))
348         {
349             lm_service_eq_intr(pLM);
350         }
351 
352         if (lm_is_tx_completion(pLM, FWD_CID(pLM)))
353         {
354             /* XXX Possible? */
355             *pPktsTxed = B_TRUE;
356         }
357 
358         if (lm_is_tx_completion(pLM, ISCSI_CID(pLM)))
359         {
360             /* XXX iSCSI Tx. NO! */
361             BnxeDbgBreakMsg(pUM, "Unknown iSCSI Tx completion!");
362         }
363 
364         if (lm_is_tx_completion(pLM, FCOE_CID(pLM)))
365         {
366             *pPktsTxed = B_TRUE;
367         }
368     }
369 }
370 
371 
372 /*
373  * This is the polling path for an individual Rx Ring.  Here we simply pull
374  * any pending packets out of the hardware and put them into the wait queue.
375  * Note that there might already be packets in the wait queue which is OK as
376  * the caller will call BnxeRxRingProcess() next to process the queue.
377  */
378 void BnxePollRxRing(um_device_t * pUM,
379                     u32_t         idx,
380                     boolean_t *   pPktsRxed,
381                     boolean_t *   pPktsTxed)
382 {
383     lm_device_t * pLM = (lm_device_t *)pUM;
384     u32_t         activity_flg = 0;
385     u8_t          drv_rss_id = (u8_t)idx;
386 
387     *pPktsRxed = B_FALSE;
388     *pPktsTxed = B_FALSE;
389 
390     BnxeLogDbg(pUM, "Ring Poll: Handling status block sb_id:%d drv_rss_id:%d",
391                idx, drv_rss_id);
392 
393     /* use drv_rss_id for mapping into status block array (from LM) */
394     ddi_dma_sync(pUM->statusBlocks[drv_rss_id]->dmaHandle,
395                  0, 0, DDI_DMA_SYNC_FORKERNEL);
396 
397     if (pUM->fmCapabilities &&
398         BnxeCheckDmaHandle(pUM->statusBlocks[drv_rss_id]->dmaHandle) != DDI_FM_OK)
399     {
400         ddi_fm_service_impact(pUM->pDev, DDI_SERVICE_DEGRADED);
401     }
402 
403     pUM->intrSbPollCnt[drv_rss_id]++;
404 
405     if (lm_is_sb_updated(pLM, drv_rss_id) == 0)
406     {
407         BnxeLogDbg(pUM, "Ring Poll: No change in status index so bail!");
408         pUM->intrSbPollNoChangeCnt[drv_rss_id]++;
409         return;
410     }
411 
412     /* get a local copy of the indices from the status block */
413     lm_update_fp_hc_indices(pLM, drv_rss_id, &activity_flg, &drv_rss_id);
414 
415     BnxeDbgBreakIf(pUM, !(activity_flg & LM_NON_DEF_EVENT_MASK));
416 
417     BnxeLogDbg(pUM, "Ring Poll: processing events on sb: %x, events: 0x%x",
418                drv_rss_id, activity_flg);
419 
420     if (activity_flg & LM_NON_DEF_USTORM_ACTIVE)
421     {
422         /* Rx Completions */
423         if (lm_is_rx_completion(pLM, drv_rss_id))
424         {
425             *pPktsRxed = B_TRUE;
426         }
427 
428         /* XXX Check for L4 TOE/FCoE Rx completions. NO! */
429     }
430 
431     if (activity_flg & LM_NON_DEF_CSTORM_ACTIVE)
432     {
433         /* Tx completions */
434         if (lm_is_tx_completion(pLM, drv_rss_id))
435         {
436             *pPktsTxed = B_TRUE;
437         }
438 
439         /* XXX Check for L4 Tx and L5 EQ completions. NO! */
440     }
441 }
442 
443 
444 /*
445  * This is the polling path for the FCoE Ring.  Here we don't pull any
446  * pending packets out of the hardware.  We only care about FCoE Fast Path
447  * completions.  FCoE slow path L2 packets are processed via the default
448  * status block not the LM_NON_RSS_SB.  In this path we're assuming that
449  * the FCoE driver is performing a crashdump.
450  */
451 void BnxePollRxRingFCOE(um_device_t * pUM)
452 {
453     lm_device_t * pLM = (lm_device_t *)pUM;
454     u32_t         activity_flg = 0;
455 
456     u8_t sb_id = LM_NON_RSS_SB(pLM);
457     u8_t drv_rss_id = FCOE_CID(pLM);
458 
459     BnxeLogDbg(pUM, "Ring Poll FCoE: Handling status block sb_id:%d drv_rss_id:%d",
460                sb_id, drv_rss_id);
461 
462     /* use sb_id for mapping into status block array (from LM) */
463     ddi_dma_sync(pUM->statusBlocks[sb_id]->dmaHandle,
464                  0, 0, DDI_DMA_SYNC_FORKERNEL);
465 
466     if (pUM->fmCapabilities &&
467         BnxeCheckDmaHandle(pUM->statusBlocks[sb_id]->dmaHandle) != DDI_FM_OK)
468     {
469         ddi_fm_service_impact(pUM->pDev, DDI_SERVICE_DEGRADED);
470     }
471 
472     pUM->intrSbPollCnt[sb_id]++;
473 
474     if (lm_is_sb_updated(pLM, sb_id) == 0)
475     {
476         BnxeLogDbg(pUM, "Ring Poll FCoE: No change in status index so bail!");
477         pUM->intrSbPollNoChangeCnt[sb_id]++;
478         return;
479     }
480 
481     /* get a local copy of the indices from the status block */
482     lm_update_fp_hc_indices(pLM, sb_id, &activity_flg, &drv_rss_id);
483 
484     BnxeDbgBreakIf(pUM, !(activity_flg & LM_NON_DEF_EVENT_MASK));
485 
486     BnxeLogDbg(pUM, "Ring Poll FCoE: processing events on sb: %x, events: 0x%x",
487                sb_id, activity_flg);
488 
489     if (activity_flg & LM_NON_DEF_USTORM_ACTIVE)
490     {
491         if (lm_fc_is_eq_completion(pLM, drv_rss_id))
492         {
493             lm_fc_service_eq_intr(pLM, drv_rss_id);
494         }
495     }
496 }
497 
498 
499 static void BnxeServiceSbIntr(um_device_t * pUM,
500                               u8_t          sb_id,
501                               boolean_t *   pPktsRxed,
502                               boolean_t *   pPktsTxed)
503 {
504     lm_device_t * pLM = (lm_device_t *)pUM;
505     u32_t         activity_flg = 0;
506     u8_t          drv_rss_id;
507 
508     *pPktsRxed = B_FALSE;
509     *pPktsTxed = B_FALSE;
510 
511     drv_rss_id = lm_map_igu_sb_id_to_drv_rss(pLM, sb_id);
512 
513     BnxeLogDbg(pUM, "Ring INTR: Handling status block sb_id:%d drv_rss_id:%d",
514                sb_id, drv_rss_id);
515 
516     /* use sb_id for mapping into status block array (from LM) */
517     ddi_dma_sync(pUM->statusBlocks[sb_id]->dmaHandle,
518                  0, 0, DDI_DMA_SYNC_FORKERNEL);
519 
520     if (pUM->fmCapabilities &&
521         BnxeCheckDmaHandle(pUM->statusBlocks[sb_id]->dmaHandle) != DDI_FM_OK)
522     {
523         ddi_fm_service_impact(pUM->pDev, DDI_SERVICE_DEGRADED);
524     }
525 
526     pUM->intrSbCnt[sb_id]++;
527 
528     if (lm_is_sb_updated(pLM, sb_id) == 0)
529     {
530         BnxeLogDbg(pUM, "Ring INTR: No change in status index so bail!");
531         pUM->intrSbNoChangeCnt[sb_id]++;
532         return;
533     }
534 
535     /*
536      * get a local copy of the indices from the status block
537      * XXX note that here drv_rss_id is assigned to the sb_id
538      */
539     lm_update_fp_hc_indices(pLM, sb_id, &activity_flg, &drv_rss_id);
540 
541     BnxeDbgBreakIf(pUM, !(activity_flg & LM_NON_DEF_EVENT_MASK));
542 
543     BnxeLogDbg(pUM, "Ring INTR: processing events on sb: %x, events: 0x%x",
544                drv_rss_id, activity_flg);
545 
546     if (activity_flg & LM_NON_DEF_USTORM_ACTIVE)
547     {
548         /* Rx Completions */
549         if (lm_is_rx_completion(pLM, drv_rss_id))
550         {
551             *pPktsRxed = B_TRUE;
552         }
553 
554         if (lm_fc_is_eq_completion(pLM, drv_rss_id))
555         {
556             lm_fc_service_eq_intr(pLM, drv_rss_id);
557         }
558 
559         /* XXX Check for ISCSI-OOO and L4 TOE Rx completions. NO! */
560     }
561 
562     if (activity_flg & LM_NON_DEF_CSTORM_ACTIVE)
563     {
564         /* Tx completions */
565         if (lm_is_tx_completion(pLM, drv_rss_id))
566         {
567             *pPktsTxed = B_TRUE;
568         }
569 
570         /* XXX Check for L4 Tx and L5 EQ completions. NO! */
571 
572         /* L4 Tx completions */
573         if (lm_toe_is_tx_completion(pLM, drv_rss_id))
574         {
575             BnxeDbgBreakMsg(pUM, "Unknown TOE Tx completion!");
576         }
577 
578         /* L5 EQ completions */
579         if (lm_sc_is_eq_completion(pLM, drv_rss_id))
580         {
581             BnxeDbgBreakMsg(pUM, "Unknown iSCSI EQ completion!");
582             //lm_sc_service_eq_intr(pLM, drv_rss_id);
583         }
584     }
585 }
586 
587 
588 uint_t BnxeIntrISR(caddr_t arg1, caddr_t arg2)
589 {
590     um_device_t *         pUM = (um_device_t *)arg1;
591     lm_device_t *         pLM = &pUM->lm_dev;
592     lm_interrupt_status_t intrStatus = 0;
593     boolean_t             pktsRxed   = 0;
594     boolean_t             pktsTxed   = 0;
595     u32_t                 rss_id     = 0;
596     int                   idx        = (int)(uintptr_t)arg2;
597 
598     BNXE_LOCK_ENTER_INTR(pUM, idx);
599 
600     if (!pUM->intrEnabled)
601     {
602         pLM->vars.dbg_intr_in_wrong_state++;
603 
604         BNXE_LOCK_EXIT_INTR(pUM, idx);
605         return DDI_INTR_UNCLAIMED;
606     }
607 
608     BnxeLogDbg(pUM, "-> BNXE INTA Interrupt <-");
609 
610     if (pLM->vars.enable_intr)
611     {
612         intrStatus = lm_get_interrupt_status(pLM);
613 
614         if (pUM->fmCapabilities &&
615             BnxeCheckAccHandle(pLM->vars.reg_handle[BAR_0]) != DDI_FM_OK)
616         {
617             ddi_fm_service_impact(pUM->pDev, DDI_SERVICE_DEGRADED);
618         }
619 
620         if (intrStatus == 0)
621         {
622             pLM->vars.dbg_intr_zero_status++;
623 
624             BNXE_LOCK_EXIT_INTR(pUM, idx);
625             return DDI_INTR_UNCLAIMED;
626         }
627     }
628     else
629     {
630         pLM->vars.dbg_intr_in_disabled++;
631         BnxeLogDbg(pUM, "INTA INTR: we got an interrupt when disabled");
632 
633         BNXE_LOCK_EXIT_INTR(pUM, idx);
634         return DDI_INTR_CLAIMED;
635     }
636 
637     atomic_add_64((volatile uint64_t *)&pUM->intrFired, 1);
638 
639     while (intrStatus)
640     {
641         if (intrStatus & 0x1)
642         {
643             if (rss_id == 0)
644             {
645                 lm_int_ack_def_sb_disable(pLM);
646 
647                 BnxeServiceDefSbIntr(pUM, &pktsRxed, &pktsTxed);
648 
649                 /*
650                  * Default sb only handles FCoE only right now.  If this changes
651                  * BnxeServiceDefSbIntr will have to change to return which CIDs
652                  * have packets pending.
653                  */
654 
655                 if (pktsTxed) BnxeTxRingProcess(pUM, FCOE_CID(pLM));
656                 if (pktsRxed) BnxeRxRingProcess(pUM, FCOE_CID(pLM), B_FALSE, 0);
657 
658                 lm_sq_post_pending(pLM);
659 
660                 lm_int_ack_def_sb_enable(pLM);
661             }
662             else
663             {
664                 /*
665                  * (rss_id - 1) is used because the non-default sbs are located
666                  * in lm_device at indices 0-15.
667                  */
668 
669                 lm_int_ack_sb_disable(pLM, (rss_id - 1));
670 
671                 BnxeServiceSbIntr(pUM, (rss_id - 1), &pktsRxed, &pktsTxed);
672 
673                 if (pktsTxed) BnxeTxRingProcess(pUM, (rss_id - 1));
674                 if (pktsRxed) BnxeRxRingProcess(pUM, (rss_id - 1), B_FALSE, 0);
675 
676                 lm_sq_post_pending(pLM);
677 
678                 lm_int_ack_sb_enable(pLM, (rss_id - 1));
679             }
680         }
681 
682         intrStatus >>= 1;
683         rss_id++;
684     }
685 
686     BNXE_LOCK_EXIT_INTR(pUM, idx);
687 
688     return DDI_INTR_CLAIMED;
689 }
690 
691 
692 uint_t BnxeIntrMISR(caddr_t arg1, caddr_t arg2)
693 {
694     um_device_t * pUM = (um_device_t *)arg1;
695     lm_device_t * pLM = &pUM->lm_dev;
696     boolean_t     pktsRxed = 0;
697     boolean_t     pktsTxed = 0;
698     int           sb_id    = (int)(uintptr_t)arg2;
699     u32_t         idx;
700 
701     BNXE_LOCK_ENTER_INTR(pUM, sb_id);
702 
703     if (!pUM->intrEnabled)
704     {
705         pLM->vars.dbg_intr_in_wrong_state++;
706 
707         BNXE_LOCK_EXIT_INTR(pUM, sb_id);
708         return DDI_INTR_UNCLAIMED;
709     }
710 
711     BnxeLogDbg(pUM, "-> BNXE MSIX Interrupt SB %d <-", sb_id);
712 
713     if (!pLM->vars.enable_intr)
714     {
715         pLM->vars.dbg_intr_in_disabled++;
716         BnxeLogDbg(pUM, "MISR INTR: we got an interrupt when disabled");
717 
718         BNXE_LOCK_EXIT_INTR(pUM, sb_id);
719         return DDI_INTR_CLAIMED;
720     }
721 
722     atomic_add_64((volatile uint64_t *)&pUM->intrFired, 1);
723 
724     if (sb_id == DEF_STATUS_BLOCK_IGU_INDEX)
725     {
726         lm_int_ack_def_sb_disable(pLM);
727 
728         BnxeServiceDefSbIntr(pUM, &pktsRxed, &pktsTxed);
729 
730         /*
731          * Default sb only handles FCoE only right now.  If this changes
732          * BnxeServiceDefSbIntr will have to change to return which CIDs
733          * have packets pending.
734          */
735 
736         if (pktsTxed) BnxeTxRingProcess(pUM, FCOE_CID(pLM));
737 	if (pktsRxed) BnxeRxRingProcess(pUM, FCOE_CID(pLM), FALSE, 0);
738 
739         lm_sq_post_pending(pLM);
740 
741         lm_int_ack_def_sb_enable(pLM);
742     }
743     else
744     {
745         /*
746          * Note that polling is not allowed by GLDv3 on the LM_NON_RSS_SB when
747          * overlapped with FCoE. This is enforced by the BnxeRxRingIntrEnable
748          * and BnxeRxRingIntrDisable routines. The FCoE driver IS ALLOWED to
749          * put the SB into poll mode. FCoE trumps GLDv3/L2 and it's assumed
750          * the FCoE driver is performing a crashdump in this case.
751          */
752 
753         idx = ((sb_id == LM_NON_RSS_SB(pLM)) &&
754                CLIENT_BOUND(pUM, LM_CLI_IDX_FCOE) &&
755                (pUM->rssIntr.intrCount == LM_MAX_RSS_CHAINS(&pUM->lm_dev))) ?
756                    FCOE_CID(pLM) : sb_id;
757 
758         if (pUM->rxq[idx].inPollMode)
759         {
760             /* Shouldn't be here! */
761             cmn_err(CE_PANIC,
762                     "%s: Interupt on RSS/MSIX ring %d when in poll mode!",
763                     BnxeDevName(pUM), idx);
764         }
765 
766         /* accounts for poll mode */
767         BnxeIntrIguSbDisable(pUM, idx, B_TRUE);
768 
769         BnxeServiceSbIntr(pUM, sb_id, &pktsRxed, &pktsTxed);
770 
771         if (pktsTxed) BnxeTxRingProcess(pUM, sb_id);
772         if (pktsRxed) BnxeRxRingProcess(pUM, sb_id, B_FALSE, 0);
773 
774         lm_sq_post_pending(pLM);
775 
776         /* accounts for poll mode */
777         BnxeIntrIguSbEnable(pUM, idx, B_TRUE);
778     }
779 
780     BNXE_LOCK_EXIT_INTR(pUM, sb_id);
781 
782     return DDI_INTR_CLAIMED;
783 }
784 
785 
786 static int BnxeGetInterruptCount(dev_info_t * pDev, int type, int intrTypes)
787 {
788     int nintrs = 0;
789 
790     if (intrTypes & type)
791     {
792         return (ddi_intr_get_nintrs(pDev, type, &nintrs) != DDI_SUCCESS) ?
793                -1 : nintrs;
794     }
795 
796     return -1;
797 }
798 
799 
800 static boolean_t BnxeIntrBlockAlloc(um_device_t *   pUM,
801                                     int             intrInum,
802                                     int             intrCnt,
803                                     BnxeIntrBlock * pBlock)
804 
805 {
806     dev_info_t * pDev = pUM->pDev;
807     int intrRequest;
808     int intrActual;
809     int rc, i;
810 
811     if ((pUM->intrType == DDI_INTR_TYPE_FIXED) && (intrCnt != 1))
812     {
813         return B_FALSE;
814     }
815 
816     intrRequest = intrCnt;
817     intrActual  = 0;
818 
819     /*
820      * We need to allocate an interrupt block array of maximum size which is
821      * MAX_RSS_CHAINS plus one for the default interrupt.  Even though we
822      * won't allocate all of those handlers the "inum" value passed to
823      * ddi_intr_alloc() determines the starting index where the handlers
824      * will be allocated.  See the multi-function block offset documentation
825      * at the top of this file.
826      */
827     pBlock->intrHandleBlockSize =
828         ((MAX_RSS_CHAINS + 1) * sizeof(ddi_intr_handle_t));
829 
830     if ((pBlock->pIntrHandleBlockAlloc =
831          (ddi_intr_handle_t *)kmem_zalloc(pBlock->intrHandleBlockSize,
832                                           KM_SLEEP)) == NULL)
833     {
834         BnxeLogWarn(pUM, "Memory alloc failed for isr handle block (inum=%d)!",
835                     intrInum);
836         return B_FALSE;
837     }
838 
839     if ((rc = ddi_intr_alloc(pDev,
840                              pBlock->pIntrHandleBlockAlloc,
841                              pUM->intrType,
842                              intrInum,
843                              intrRequest,
844                              &intrActual,
845                              DDI_INTR_ALLOC_NORMAL)) != DDI_SUCCESS)
846     {
847         BnxeLogWarn(pUM, "Failed to allocate isr handle block (%d) (inum=%d cnt=%d)!",
848                     rc, intrInum, intrRequest);
849         kmem_free(pBlock->pIntrHandleBlockAlloc, pBlock->intrHandleBlockSize);
850         return B_FALSE;
851     }
852 
853     /*
854      * Point 'pIntrHandleBlock' to the starting interrupt index in the
855      * allocated interrupt block array.  This is done so we can easily enable,
856      * disable, free, etc the interrupts.  For 10u8 and beyond the inum value
857      * is also used as an index into the interrupt block so we point
858      * pIntrHandleBlock to the inum'th index.  For 10u7 and below all
859      * interrupt allocations start at index 0 per block.
860      */
861 #if 0
862 
863 #ifdef DDI_INTR_IRM
864     pBlock->pIntrHandleBlock =
865         &pBlock->pIntrHandleBlockAlloc[intrInum];
866 #else
867     pBlock->pIntrHandleBlock =
868         &pBlock->pIntrHandleBlockAlloc[0];
869 #endif
870 
871 #else
872 
873     if (pBlock->pIntrHandleBlockAlloc[0])
874     {
875         pBlock->pIntrHandleBlock =
876             &pBlock->pIntrHandleBlockAlloc[0];
877     }
878     else
879     {
880         pBlock->pIntrHandleBlock =
881             &pBlock->pIntrHandleBlockAlloc[intrInum];
882     }
883 
884 #endif
885 
886     if (intrRequest != intrActual)
887     {
888         BnxeLogWarn(pUM, "Failed to allocate desired isr count (%d/%d)!",
889                     intrActual, intrRequest);
890 
891 #if 0
892         for (i = 0; i < intrActual; i++)
893         {
894             ddi_intr_free(pBlock->pIntrHandleBlock[i]);
895         }
896 
897         kmem_free(pBlock->pIntrHandleBlockAlloc, pBlock->intrHandleBlockSize);
898         return B_FALSE;
899 #else
900         if (intrActual == 0)
901         {
902             kmem_free(pBlock->pIntrHandleBlockAlloc, pBlock->intrHandleBlockSize);
903             return B_FALSE;
904         }
905 #endif
906     }
907 
908     pBlock->intrCount = intrActual;
909 
910     if ((rc = ddi_intr_get_cap(pBlock->pIntrHandleBlock[0],
911                                &pBlock->intrCapability)) != DDI_SUCCESS)
912     {
913         BnxeLogWarn(pUM, "Failed to get isr capability (%d)!", rc);
914         goto BnxeIntrBlockAlloc_fail;
915     }
916 
917     if ((rc = ddi_intr_get_pri(pBlock->pIntrHandleBlock[0],
918                                &pBlock->intrPriority)) != DDI_SUCCESS)
919     {
920         BnxeLogWarn(pUM, "Failed to get isr priority (%d)!", rc);
921         goto BnxeIntrBlockAlloc_fail;
922     }
923 
924     if (pBlock->intrPriority >= ddi_intr_get_hilevel_pri())
925     {
926         BnxeLogWarn(pUM, "Interrupt priority is too high!");
927         goto BnxeIntrBlockAlloc_fail;
928     }
929 
930     return B_TRUE;
931 
932 BnxeIntrBlockAlloc_fail:
933 
934     for (i = 0; i < intrActual; i++)
935     {
936         ddi_intr_free(pBlock->pIntrHandleBlock[i]);
937     }
938 
939     kmem_free(pBlock->pIntrHandleBlockAlloc, pBlock->intrHandleBlockSize);
940 
941     memset(pBlock, 0, sizeof(BnxeIntrBlock));
942 
943     return B_FALSE;
944 }
945 
946 
947 static void BnxeIntrBlockFree(um_device_t *   pUM,
948                               BnxeIntrBlock * pBlock)
949 
950 {
951     int i;
952 
953     if (pBlock->intrCount == 0)
954     {
955         memset(pBlock, 0, sizeof(BnxeIntrBlock));
956         return;
957     }
958 
959     for (i = 0; i < pBlock->intrCount; i++)
960     {
961         ddi_intr_free(pBlock->pIntrHandleBlock[i]);
962     }
963 
964     kmem_free(pBlock->pIntrHandleBlockAlloc, pBlock->intrHandleBlockSize);
965 
966     memset(pBlock, 0, sizeof(BnxeIntrBlock));
967 }
968 
969 
970 static boolean_t BnxeIntrAddHandlers(um_device_t * pUM)
971 {
972     int rc, i, j;
973 
974     switch (pUM->intrType)
975     {
976     case DDI_INTR_TYPE_MSIX:
977 
978         if ((rc = ddi_intr_add_handler(
979                       pUM->defIntr.pIntrHandleBlock[0],
980                       BnxeIntrMISR,
981                       (caddr_t)pUM,
982                       (caddr_t)(uintptr_t)DEF_STATUS_BLOCK_IGU_INDEX)) !=
983             DDI_SUCCESS)
984         {
985             BnxeLogWarn(pUM, "Failed to add the MSIX default isr handler (%d)", rc);
986             return B_FALSE;
987         }
988 
989         for (i = 0; i < pUM->rssIntr.intrCount; i++)
990         {
991             if ((rc = ddi_intr_add_handler(
992                           pUM->rssIntr.pIntrHandleBlock[i],
993                           BnxeIntrMISR,
994                           (caddr_t)pUM,
995                           (caddr_t)(uintptr_t)i)) !=
996                 DDI_SUCCESS)
997             {
998                 BnxeLogWarn(pUM, "Failed to add the MSIX RSS isr handler %d (%d)",
999                             (i + NDIS_CID(&pUM->lm_dev)), rc);
1000 
1001                 ddi_intr_remove_handler(pUM->defIntr.pIntrHandleBlock[0]);
1002 
1003                 for (j = 0; j < i; j++) /* unwind */
1004                 {
1005                     ddi_intr_remove_handler(pUM->rssIntr.pIntrHandleBlock[j]);
1006                 }
1007 
1008                 return B_FALSE;
1009             }
1010         }
1011 
1012         /*
1013          * fcoeIntr.intrCount == 1 implies LM_NON_RSS_SB (last) status block
1014          * was allocated for FCoE and there was no overlap with the RSS
1015          * allocation.
1016          */
1017         if (pUM->fcoeIntr.intrCount == 1)
1018         {
1019             if ((rc = ddi_intr_add_handler(
1020                           pUM->fcoeIntr.pIntrHandleBlock[0],
1021                           BnxeIntrMISR,
1022                           (caddr_t)pUM,
1023                           (caddr_t)(uintptr_t)LM_NON_RSS_SB(&pUM->lm_dev))) !=
1024                 DDI_SUCCESS)
1025             {
1026                 BnxeLogWarn(pUM, "Failed to add the MSIX FCoE isr handler (%d)", rc);
1027 
1028                 ddi_intr_remove_handler(pUM->defIntr.pIntrHandleBlock[0]);
1029 
1030                 for (i = 0; i < pUM->rssIntr.intrCount; i++)
1031                 {
1032                     ddi_intr_remove_handler(pUM->rssIntr.pIntrHandleBlock[i]);
1033                 }
1034 
1035                 return B_FALSE;
1036             }
1037         }
1038 
1039         break;
1040 
1041     case DDI_INTR_TYPE_FIXED:
1042 
1043         if ((rc = ddi_intr_add_handler(
1044                                pUM->defIntr.pIntrHandleBlock[0],
1045                                BnxeIntrISR,
1046                                (caddr_t)pUM,
1047                                (caddr_t)(uintptr_t)DEF_STATUS_BLOCK_IGU_INDEX)) !=
1048             DDI_SUCCESS)
1049         {
1050             BnxeLogWarn(pUM, "Failed to add the fixed default isr handler (%d)", rc);
1051             return B_FALSE;
1052         }
1053 
1054         break;
1055 
1056     default:
1057 
1058         BnxeLogWarn(pUM, "Failed to add isr handler (unsupported type %d)!",
1059                     pUM->intrType);
1060         return B_FALSE;
1061     }
1062 
1063     return B_TRUE;
1064 }
1065 
1066 
1067 static void BnxeIntrBlockRemoveHandler(um_device_t *   pUM,
1068                                        BnxeIntrBlock * pBlock)
1069 {
1070     int i;
1071 
1072     (void)pUM;
1073 
1074     if (pBlock->intrCount == 0)
1075     {
1076         return;
1077     }
1078 
1079     for (i = 0; i < pBlock->intrCount; i++)
1080     {
1081         ddi_intr_remove_handler(pBlock->pIntrHandleBlock[i]);
1082     }
1083 }
1084 
1085 
1086 static boolean_t BnxeIntrBlockEnable(um_device_t *   pUM,
1087                                      BnxeIntrBlock * pBlock)
1088 {
1089     int rc, i, j;
1090 
1091     if (pBlock->intrCount == 0)
1092     {
1093         return B_TRUE;
1094     }
1095 
1096     if (pBlock->intrCapability & DDI_INTR_FLAG_BLOCK)
1097     {
1098         if ((rc = ddi_intr_block_enable(pBlock->pIntrHandleBlock,
1099                                         pBlock->intrCount)) != DDI_SUCCESS)
1100         {
1101             BnxeLogWarn(pUM, "Failed to enable isr block (%d)", rc);
1102             return B_FALSE;
1103         }
1104     }
1105     else
1106     {
1107         for (i = 0; i < pBlock->intrCount; i++)
1108         {
1109             if ((rc = ddi_intr_enable(pBlock->pIntrHandleBlock[i])) !=
1110                 DDI_SUCCESS)
1111             {
1112                 BnxeLogWarn(pUM, "Failed to enable isr %d (%d)", i, rc);
1113 
1114                 for (j = 0; j < i; j++) /* unwind */
1115                 {
1116                     ddi_intr_disable(pBlock->pIntrHandleBlock[j]);
1117                 }
1118 
1119                 return B_FALSE;
1120             }
1121         }
1122     }
1123 
1124     return B_TRUE;
1125 }
1126 
1127 
1128 static void BnxeIntrBlockDisable(um_device_t *   pUM,
1129                                  BnxeIntrBlock * pBlock)
1130 {
1131     int i;
1132 
1133     if (pBlock->intrCount == 0)
1134     {
1135         return;
1136     }
1137 
1138     if (pBlock->intrCapability & DDI_INTR_FLAG_BLOCK)
1139     {
1140         ddi_intr_block_disable(pBlock->pIntrHandleBlock, pBlock->intrCount);
1141     }
1142     else
1143     {
1144         for (i = 0; i < pBlock->intrCount; i++)
1145         {
1146             ddi_intr_disable(pBlock->pIntrHandleBlock[i]);
1147         }
1148     }
1149 }
1150 
1151 
1152 int BnxeIntrEnable(um_device_t * pUM)
1153 {
1154     BnxeMemDma * pDma;
1155     int rc, i, j;
1156 
1157     atomic_swap_64((volatile uint64_t *)&pUM->intrFired, 0);
1158 
1159     for (i = 0; i < (MAX_RSS_CHAINS + 1); i++)
1160     {
1161         pUM->intrSbCnt[i]         = 0;
1162         pUM->intrSbNoChangeCnt[i] = 0;
1163     }
1164 
1165     /* get the DMA handles for quick access to the status blocks for sync */
1166     BnxeFindDmaHandles(pUM);
1167 
1168     /* Enable the default interrupt... */
1169 
1170     if (!BnxeIntrBlockEnable(pUM, &pUM->defIntr))
1171     {
1172         BnxeLogWarn(pUM, "Failed to enable the default interrupt");
1173         return -1;
1174     }
1175 
1176     /* Enable the FCoE interrupt... */
1177 
1178     if (!BnxeIntrBlockEnable(pUM, &pUM->fcoeIntr))
1179     {
1180         BnxeLogWarn(pUM, "Failed to enable the FCoE interrupt");
1181         BnxeIntrBlockDisable(pUM, &pUM->defIntr);
1182         return -1;
1183     }
1184 
1185     /* Enable the RSS interrupts... */
1186 
1187     if (!BnxeIntrBlockEnable(pUM, &pUM->rssIntr))
1188     {
1189         BnxeLogWarn(pUM, "Failed to enable the RSS interrupt");
1190         BnxeIntrBlockDisable(pUM, &pUM->defIntr);
1191         BnxeIntrBlockDisable(pUM, &pUM->fcoeIntr);
1192         return -1;
1193     }
1194 
1195     /* allow the hardware to generate interrupts */
1196     atomic_swap_32(&pUM->intrEnabled, B_TRUE);
1197     lm_enable_int(&pUM->lm_dev);
1198 
1199     if (pUM->fmCapabilities &&
1200         BnxeCheckAccHandle(pUM->lm_dev.vars.reg_handle[BAR_0]) != DDI_FM_OK)
1201     {
1202         ddi_fm_service_impact(pUM->pDev, DDI_SERVICE_DEGRADED);
1203     }
1204 
1205 /* XXX do not remove this... edavis */
1206 drv_usecwait(1000000); /* :-( */
1207 
1208     return 0;
1209 }
1210 
1211 
1212 void BnxeIntrDisable(um_device_t * pUM)
1213 {
1214     int rc, i;
1215 
1216     /* stop the device from generating any interrupts */
1217     lm_disable_int(&pUM->lm_dev);
1218 
1219     if (pUM->fmCapabilities &&
1220         BnxeCheckAccHandle(pUM->lm_dev.vars.reg_handle[BAR_0]) != DDI_FM_OK)
1221     {
1222         ddi_fm_service_impact(pUM->pDev, DDI_SERVICE_DEGRADED);
1223     }
1224 
1225     atomic_swap_32(&pUM->intrEnabled, B_FALSE);
1226 
1227     /*
1228      * Ensure the ISR no longer touches the hardware by making sure the ISR
1229      * is not running or the current run completes.   Since interrupts were
1230      * disabled before here and intrEnabled is FALSE, we can be sure
1231      * interrupts will no longer be processed.
1232      */
1233     for (i = 0; i < (MAX_RSS_CHAINS + 1); i++)
1234     {
1235         BNXE_LOCK_ENTER_INTR(pUM, i);
1236         BNXE_LOCK_EXIT_INTR(pUM, i);
1237     }
1238 
1239     /* Disable the default interrupt... */
1240 
1241     BnxeIntrBlockDisable(pUM, &pUM->defIntr);
1242 
1243     /* Disable the FCoE interrupt... */
1244 
1245     BnxeIntrBlockDisable(pUM, &pUM->fcoeIntr);
1246 
1247     /* Disable the RSS interrupts... */
1248 
1249     BnxeIntrBlockDisable(pUM, &pUM->rssIntr);
1250 }
1251 
1252 
1253 boolean_t BnxeIntrInit(um_device_t * pUM)
1254 {
1255     dev_info_t * pDev;
1256     int intrTypes = 0;
1257     int intrTotalAlloc = 0;
1258     int numMSIX, numMSI, numFIX;
1259     int rc, i;
1260 
1261     pDev = pUM->pDev;
1262 
1263     atomic_swap_32(&pUM->intrEnabled, B_FALSE);
1264 
1265     if ((rc = ddi_intr_get_supported_types(pDev, &intrTypes)) != DDI_SUCCESS)
1266     {
1267         BnxeLogWarn(pUM, "Failed to get supported interrupt types (%d)", rc);
1268         return B_FALSE;
1269     }
1270 
1271     numMSIX = BnxeGetInterruptCount(pDev, DDI_INTR_TYPE_MSIX, intrTypes);
1272     numMSI  = BnxeGetInterruptCount(pDev, DDI_INTR_TYPE_MSI, intrTypes);
1273     numFIX  = BnxeGetInterruptCount(pDev, DDI_INTR_TYPE_FIXED, intrTypes);
1274 
1275     if (numFIX <= 0)
1276     {
1277         BnxeLogWarn(pUM, "Fixed interrupt not supported!");
1278         return B_FALSE;
1279     }
1280 
1281     memset(&pUM->defIntr,  0, sizeof(BnxeIntrBlock));
1282     memset(&pUM->rssIntr,  0, sizeof(BnxeIntrBlock));
1283     memset(&pUM->fcoeIntr, 0, sizeof(BnxeIntrBlock));
1284 
1285     if (pUM->devParams.disableMsix)
1286     {
1287         BnxeLogInfo(pUM, "Forcing fixed level interrupts.");
1288         pUM->lm_dev.params.interrupt_mode = LM_INT_MODE_INTA;
1289         pUM->intrType                     = DDI_INTR_TYPE_FIXED;
1290     }
1291     else if (numMSIX > 0)
1292     {
1293         pUM->lm_dev.params.interrupt_mode = LM_INT_MODE_MIMD;
1294         pUM->intrType                     = DDI_INTR_TYPE_MSIX;
1295     }
1296     else /* numFIX */
1297     {
1298         pUM->lm_dev.params.interrupt_mode = LM_INT_MODE_INTA;
1299         pUM->intrType                     = DDI_INTR_TYPE_FIXED;
1300     }
1301 
1302     while (1)
1303     {
1304         /* allocate the default interrupt */
1305 
1306         if (!BnxeIntrBlockAlloc(pUM,
1307                                 0,
1308                                 1,
1309                                 &pUM->defIntr))
1310         {
1311             BnxeLogWarn(pUM, "Failed to allocate default %s interrupt!",
1312                         BnxeIntrTypeName(pUM->intrType));
1313             goto BnxeIntrInit_alloc_fail;
1314         }
1315 
1316         intrTotalAlloc++;
1317 
1318         if (pUM->intrType == DDI_INTR_TYPE_FIXED)
1319         {
1320             /* only one interrupt allocated for fixed (default) */
1321             break;
1322         }
1323 
1324         if (BnxeProtoFcoeAfex(pUM))
1325         {
1326             pUM->devParams.numRings = 0;
1327         }
1328         else
1329         {
1330             /* allocate the RSS interrupts */
1331 
1332             while (pUM->devParams.numRings > 0)
1333             {
1334                 if (!BnxeIntrBlockAlloc(pUM,
1335                                         (NDIS_CID(&pUM->lm_dev) + 1),
1336                                         pUM->devParams.numRings,
1337                                         &pUM->rssIntr))
1338                 {
1339                     BnxeLogWarn(pUM, "Failed to allocate %d RSS %s interrupts!",
1340                                 pUM->devParams.numRings,
1341                                 BnxeIntrTypeName(pUM->intrType));
1342                     pUM->devParams.numRings >>= 1;
1343                     continue;
1344                 }
1345 
1346                 break;
1347             }
1348 
1349             if (pUM->devParams.numRings == 0)
1350             {
1351                 BnxeIntrBlockFree(pUM, &pUM->defIntr);
1352                 goto BnxeIntrInit_alloc_fail;
1353             }
1354 
1355             BnxeLogInfo(pUM, "Allocated %d RSS %s interrupts.",
1356                         pUM->rssIntr.intrCount,
1357                         BnxeIntrTypeName(pUM->intrType));
1358 
1359             intrTotalAlloc += pUM->rssIntr.intrCount; /* intrCount <= numRings */
1360         }
1361 
1362         /*
1363          * Allocate the FCoE interrupt only if all available status blocks
1364          * were not taken up by the RSS chains.  If they were then the last
1365          * status block (LM_NON_RSS_SB) is overloaded for both RSS and FCoE.
1366          */
1367 
1368         if (BNXE_FCOE(pUM))
1369         {
1370             if (pUM->rssIntr.intrCount < LM_MAX_RSS_CHAINS(&pUM->lm_dev))
1371             {
1372                 if (!BnxeIntrBlockAlloc(pUM,
1373                                         (LM_NON_RSS_SB(&pUM->lm_dev) + 1),
1374                                         1,
1375                                         &pUM->fcoeIntr))
1376                 {
1377                     BnxeLogWarn(pUM, "Failed to allocate FCoE %s interrupt!",
1378                                 BnxeIntrTypeName(pUM->intrType));
1379                     BnxeIntrBlockFree(pUM, &pUM->defIntr);
1380                     BnxeIntrBlockFree(pUM, &pUM->rssIntr);
1381                     goto BnxeIntrInit_alloc_fail;
1382                 }
1383 
1384                 intrTotalAlloc++;
1385             }
1386             else
1387             {
1388                 /* to be safe, sets fcoeIntr.intrCount to 0 */
1389                 memset(&pUM->fcoeIntr, 0, sizeof(BnxeIntrBlock));
1390             }
1391         }
1392 
1393         break;
1394 
1395 BnxeIntrInit_alloc_fail:
1396 
1397         if (pUM->intrType == DDI_INTR_TYPE_FIXED)
1398         {
1399             return B_FALSE;
1400         }
1401 
1402         /* fall back to fixed a retry allocation */
1403         intrTotalAlloc = 0;
1404         pUM->lm_dev.params.interrupt_mode = LM_INT_MODE_INTA;
1405         pUM->intrType                     = DDI_INTR_TYPE_FIXED;
1406     }
1407 
1408     if (pUM->intrType == DDI_INTR_TYPE_MSIX)
1409     {
1410         pUM->devParams.numRings          = pUM->rssIntr.intrCount;
1411         pUM->lm_dev.params.rss_chain_cnt = pUM->rssIntr.intrCount;
1412         pUM->lm_dev.params.tss_chain_cnt = pUM->rssIntr.intrCount;
1413     }
1414     else
1415     {
1416         /* fixed level (no rings)... */
1417         pUM->devParams.numRings          = 0;
1418         pUM->lm_dev.params.rss_chain_cnt = 1;
1419         pUM->lm_dev.params.tss_chain_cnt = 1;
1420 
1421         BnxeLogWarn(pUM, "Using Fixed Level Interrupts! (set ddi_msix_alloc_limit in /etc/system)");
1422     }
1423 
1424     BnxeLogInfo(pUM, "Interrupts (Supported - %d Fixed / %d MSI / %d MSIX) (Allocated - %d %s)",
1425                 numFIX, numMSI, numMSIX, intrTotalAlloc, BnxeIntrTypeName(pUM->intrType));
1426 
1427     if (!BnxeIntrAddHandlers(pUM))
1428     {
1429         BnxeLogWarn(pUM, "Failed to add interrupts!");
1430         BnxeIntrBlockFree(pUM, &pUM->defIntr);
1431         BnxeIntrBlockFree(pUM, &pUM->fcoeIntr);
1432         BnxeIntrBlockFree(pUM, &pUM->rssIntr);
1433         return B_FALSE;
1434     }
1435 
1436     /* copy default priority and assume rest are the same (for mutex) */
1437     pUM->intrPriority = pUM->defIntr.intrPriority;
1438 
1439     return B_TRUE;
1440 }
1441 
1442 
1443 void BnxeIntrFini(um_device_t * pUM)
1444 {
1445     int i;
1446 
1447     BnxeIntrBlockDisable(pUM, &pUM->defIntr);
1448     BnxeIntrBlockRemoveHandler(pUM, &pUM->defIntr);
1449     BnxeIntrBlockFree(pUM, &pUM->defIntr);
1450 
1451     BnxeIntrBlockDisable(pUM, &pUM->fcoeIntr);
1452     BnxeIntrBlockRemoveHandler(pUM, &pUM->fcoeIntr);
1453     BnxeIntrBlockFree(pUM, &pUM->fcoeIntr);
1454 
1455     BnxeIntrBlockDisable(pUM, &pUM->rssIntr);
1456     BnxeIntrBlockRemoveHandler(pUM, &pUM->rssIntr);
1457     BnxeIntrBlockFree(pUM, &pUM->rssIntr);
1458 }
1459 
1460