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 #ifndef BNXE_H
40 #define BNXE_H
41
42 #include <sys/types.h>
43 #include <sys/stream.h>
44 #include <sys/stropts.h>
45 #include <sys/errno.h>
46 #include <sys/cred.h>
47 #include <sys/poll.h>
48 #include <sys/modctl.h>
49 #include <sys/mac.h>
50 #include <sys/mac_provider.h>
51 #include <sys/stat.h>
52 #include <sys/ddi.h>
53 #include <sys/sunddi.h>
54 #include <sys/sunndi.h>
55 #include <sys/ddifm.h>
56 #include <sys/fm/protocol.h>
57 #include <sys/fm/util.h>
58 #include <sys/fm/io/ddi.h>
59 #include <sys/pattr.h>
60 #include <sys/sysmacros.h>
61 #include <sys/ethernet.h>
62 //#include <sys/vlan.h>
63 #include <sys/strsun.h>
64 #include <sys/ksynch.h>
65 #include <sys/kstat.h>
66 #include <netinet/in.h>
67 #include <netinet/ip.h>
68 #include <netinet/udp.h>
69 #include <netinet/tcp.h>
70 #include <inet/common.h>
71 #include <inet/ip.h>
72 #include <inet/ip_if.h>
73 #include <sys/strsubr.h>
74 #include <sys/pci.h>
75 #include <sys/gld.h>
76 #include <sys/mac_ether.h>
77
78 /*
79 * This really ticks me off! We use 'u' for naming unions
80 * within structures. Why is 'u' a reserved word!?!?!?
81 * http://bugs.opensolaris.org/view_bug.do?bug_id=4340073
82 * This undef has been moved to bnxe_debug.h.
83 */
84 //#undef u
85
86 #include "version.h"
87 #include "debug.h"
88 #include "bcmtype.h"
89 #include "lm_defs.h"
90 #include "listq.h"
91 #include "lm5710.h"
92 #include "lm.h"
93 #include "bd_chain.h"
94 #if !defined(__SunOS_MDB)
95 #include "command.h"
96 #endif
97 #include "bnxe_binding.h"
98 #if !defined(DBG) && !defined(__SunOS_MDB)
99 #include "bnxe_debug.h" /* wasn't included by debug.h */
100 #endif
101
102 #ifndef VLAN_TAGSZ
103 #define VLAN_TAGSZ 4
104 #endif
105
106 #define BNXE_RINGS
107 #define RSS_ID_NONE -1
108
109 #define USER_OPTION_CKSUM_NONE 0x0
110 #define USER_OPTION_CKSUM_L3 0x1
111 #define USER_OPTION_CKSUM_L3_L4 0x2
112 #define USER_OPTION_CKSUM_DEFAULT USER_OPTION_CKSUM_L3_L4
113
114 #define USER_OPTION_MTU_MIN 60
115 #define USER_OPTION_MTU_MAX 9216
116 #define USER_OPTION_MTU_DEFAULT 1500
117
118 #define USER_OPTION_NUM_RINGS_MIN 0
119 #define USER_OPTION_NUM_RINGS_MAX MAX_RSS_CHAINS
120 #define USER_OPTION_NUM_RINGS_DEFAULT_MF 1
121 #define USER_OPTION_NUM_RINGS_DEFAULT_SF 4
122 #define USER_OPTION_NUM_RINGS_DEFAULT 0
123
124 #define USER_OPTION_RX_RING_GROUPS_MIN 1
125 #define USER_OPTION_RX_RING_GROUPS_MAX 1
126 #define USER_OPTION_RX_RING_GROUPS_DEFAULT 1
127
128 #define USER_OPTION_BDS_MIN 1
129 #define USER_OPTION_BDS_MAX 32767
130 #define USER_OPTION_RX_BDS_DEFAULT 1024
131 #define USER_OPTION_TX_BDS_DEFAULT 1024
132 #define USER_OPTION_MF_BDS_DIVISOR 4
133
134 #define USER_OPTION_INTR_COALESCE_MIN 10 /* usecs */
135 #define USER_OPTION_INTR_COALESCE_MAX 1000
136 #define USER_OPTION_INTR_COALESCE_RX_DEFAULT 20
137 #define USER_OPTION_INTR_COALESCE_TX_DEFAULT 40
138
139 #define USER_OPTION_TX_MAX_FREE_DEFAULT 32
140 #define USER_OPTION_RX_MAX_FREE_DEFAULT 32
141
142 //#define USER_OPTION_RX_DCOPY_THRESH_DEFAULT 0xffffffff
143 #define USER_OPTION_RX_DCOPY_THRESH_DEFAULT 128
144
145 //#define USER_OPTION_TX_DCOPY_THRESH_DEFAULT 0
146 #define USER_OPTION_TX_DCOPY_THRESH_DEFAULT 512
147
148 //#define BNXE_IP_MAXLEN 65535
149 #define BNXE_IP_MAXLEN 32768 /* 32768 = PAGESIZE * (BNXE_MAX_DMA_FRAGS_PER_PKT - 2 ) */
150 #define BNXE_OPTION_LEN 80 /* room for IP/TCP options (max 40 bytes each) */
151 #define BNXE_PKTHDR_LEN (sizeof(struct ether_vlan_header) + sizeof(struct ip) + sizeof(struct tcphdr) + BNXE_OPTION_LEN)
152 #define BNXE_LSO_MAXLEN (BNXE_IP_MAXLEN + sizeof(struct ether_vlan_header) - BNXE_PKTHDR_LEN) /* maximum payload */
153
154 #define BNXE_MAGIC 0x0feedead
155 #define BNXE_MEM_CHECK_LEN 16
156 #define BNXE_STR_SIZE 32
157
158 #define BNXEF_NAME "bnxef"
159
160 #define BNXE_FCOE(dev) ((um_device_t *)(dev))->do_fcoe
161
162 #ifdef __sparc
163 #define BNXE_DMA_ALIGNMENT 0x2000UL
164 #else
165 #define BNXE_DMA_ALIGNMENT 0x1000UL
166 #endif
167
168 /*
169 * Adding a two byte offset to the receive buffer aligns the IP header on a
170 * 16 byte boundary and it would put the TCP payload (assuming a 20 byte IP
171 * header and 20 byte TCP header) on an 8 byte boundary.
172 */
173 #define BNXE_DMA_RX_OFFSET 2
174
175 /*
176 * The following two defines are used for defining limits on Tx packets.
177 * BNXE_MAX_DMA_HANDLES_PER_PKT is the maximum number of DMA handles that are
178 * pre-allocated for every Tx buffer descriptor. These DMA handles are used
179 * for mapping each mblk in the chain when not double copying the packet data
180 * into the copy buffer. BNXE_MAX_DMA_FRAGS_PER_PKT is based on the hardware
181 * and represents the maximum number of fragments an outgoing packet can have.
182 * Note that a single DMA handle can be comprised of multiple fragments which
183 * is very likely with LSO.
184 *
185 * As seen below BNXE_MAX_DMA_FRAGS_PER_PKT is set to 10. The actual firmware
186 * limit is 13 but 10 is chosen specifically for the case of LSO packets that
187 * are broken up across a long mblk chain. The firmware utilizes a sliding
188 * window on a packet's assigned buffer descriptors for LSO. The window is 10
189 * bds and each window (i.e. bds 1-10, 2-11, 3-12, etc), except the window
190 * containing the last bd, must contains at least MSS bytes. There are 'rare'
191 * cases where a packet sent down by the stack will not satisfy this window
192 * size requirement. Therefore, setting the frag limit to 10 results in any
193 * long chained packet (i.e. greater than 10 mblks), the trailing mblks will
194 * get double copied into a single copy buffer and will be pointed to by the
195 * last bd. This simple change will ensure the sliding window requirement is
196 * always satisfied. Note, LSO packets with long mblk chains are a rare
197 * occurance (nicdrv test01 can trigger it).
198 */
199 #define BNXE_MAX_DMA_HANDLES_PER_PKT 11 /* go easy on DMA resources */
200 #define BNXE_MAX_DMA_FRAGS_PER_PKT 10 /* set BNXE_IP_MAXLEN above accordingly */
201 #define BNXE_MAX_DMA_SGLLEN 20 /* for partial dma mapping */
202
203 #define BNXE_PDWM_THRESHOLD 8
204
205 #define BNXE_TX_RESOURCES_NO_CREDIT 0x01
206 #define BNXE_TX_RESOURCES_NO_DESC 0x02
207 #define BNXE_TX_RESOURCES_NO_DRV_DMA_RES 0x04 /* Out of Tx DMA handles */
208 #define BNXE_TX_RESOURCES_NO_OS_DMA_RES 0x08 /* Unable to allocate DMA resources. (e.g. bind error) */
209 #define BNXE_TX_RESOURCES_TOO_MANY_FRAGS 0x10
210
211 #define BNXE_TX_GOODXMIT 0
212 #define BNXE_TX_LINKDOWN 1
213 #define BNXE_TX_DEFERPKT 2
214 #define BNXE_TX_HDWRFULL 3
215 #define BNXE_TX_PKTERROR 4
216
217 #define BNXE_ROUTE_RING_NONE 0
218 #define BNXE_ROUTE_RING_TCPUDP 1
219 #define BNXE_ROUTE_RING_DEST_MAC 2
220 #define BNXE_ROUTE_RING_MSG_PRIO 3
221
222 #undef BNXE_DEBUG_DMA_LIST
223
224 extern ddi_device_acc_attr_t bnxeAccessAttribBAR;
225 extern ddi_device_acc_attr_t bnxeAccessAttribBUF;
226
227 typedef struct _BnxeDevParams
228 {
229 u32_t fw_ver;
230
231 u32_t mtu[LM_CLI_IDX_MAX];
232
233 u32_t routeTxRingPolicy;
234 u32_t numRings; /* number of rings */
235 u32_t numRxDesc[LM_CLI_IDX_MAX]; /* number of RX descriptors */
236 u32_t numTxDesc[LM_CLI_IDX_MAX]; /* number of TX descriptors */
237 u32_t maxRxFree; /* max free allowed before posting back */
238 u32_t maxTxFree; /* max free allowed before posting back */
239
240 boolean_t intrCoalesce;
241 u32_t intrRxPerSec;
242 u32_t intrTxPerSec;
243 boolean_t disableMsix;
244
245 boolean_t l2_fw_flow_ctrl;
246 boolean_t autogreeenEnable;
247
248 u32_t rxCopyThreshold;
249 u32_t txCopyThreshold;
250
251 lm_rx_mask_t rx_filter_mask[LM_CLI_IDX_MAX];
252
253 int checksum;
254 lm_offload_t enabled_oflds;
255
256 boolean_t lsoEnable;
257
258 boolean_t logEnable;
259
260 boolean_t fcoeEnable;
261
262 boolean_t linkRemoteFaultDetect;
263
264 lm_status_t lastIndLink;
265 lm_medium_t lastIndMedium;
266
267 uint32_t debug_level;
268 } BnxeDevParams;
269
270
271 typedef struct _BnxeLinkCfg
272 {
273 boolean_t link_autoneg;
274 boolean_t param_20000fdx;
275 boolean_t param_10000fdx;
276 boolean_t param_2500fdx;
277 boolean_t param_1000fdx;
278 boolean_t param_100fdx;
279 boolean_t param_100hdx;
280 boolean_t param_10fdx;
281 boolean_t param_10hdx;
282 boolean_t param_txpause;
283 boolean_t param_rxpause;
284 } BnxeLinkCfg;
285
286
287 typedef struct _BnxePhyCfg
288 {
289 BnxeLinkCfg lnkcfg;
290 boolean_t flow_autoneg;
291 u32_t supported[ELINK_LINK_CONFIG_SIZE];
292 u32_t phy_cfg_size;
293 } BnxePhyCfg;
294
295
296 typedef struct _BnxeProps
297 {
298 u32_t link_speed;
299 boolean_t link_duplex;
300 boolean_t link_txpause;
301 boolean_t link_rxpause;
302 time_t uptime;
303 } BnxeProps;
304
305
306 typedef struct _BnxeMemBlock
307 {
308 d_list_entry_t link;
309 u32_t size;
310 void * pBuf;
311 char fileName[128];
312 u32_t fileLine;
313 } BnxeMemBlock;
314
315
316 typedef struct _BnxeMemDma
317 {
318 d_list_entry_t link;
319 u32_t size;
320 void * pDmaVirt;
321 ddi_dma_handle_t dmaHandle;
322 ddi_acc_handle_t dmaAccHandle;
323 lm_address_t physAddr;
324 char fileName[128];
325 u32_t fileLine;
326 } BnxeMemDma;
327
328
329 typedef struct _BnxeMemRegion
330 {
331 d_list_entry_t link;
332 lm_address_t baseAddr;
333 u32_t regNumber;
334 offset_t offset;
335 u32_t size;
336 ddi_acc_handle_t regAccess;
337 caddr_t pRegAddr;
338 } BnxeMemRegion;
339
340
341 typedef struct _um_txpacket_t
342 {
343 lm_packet_t lm_pkt; /* must be the first entry */
344 lm_pkt_tx_info_t tx_info;
345
346 mblk_t * pMblk;
347
348 ddi_dma_handle_t cbDmaHandle; /* cb = copy buffer */
349 ddi_acc_handle_t cbDmaAccHandle;
350 caddr_t pCbBuf;
351 lm_address_t cbPhysAddr;
352
353 u32_t cbLength;
354 u32_t num_handles; /* number of handles used for pkt */
355 ddi_dma_handle_t dmaHandles[BNXE_MAX_DMA_HANDLES_PER_PKT];
356
357 lm_frag_list_t frag_list;
358 lm_frag_t frag_list_buffer[BNXE_MAX_DMA_FRAGS_PER_PKT];
359 } um_txpacket_t;
360
361
362 typedef struct _TxQueue
363 {
364 void * pUM; /* backpointer to um_device_t */
365 u32_t idx; /* this ring's index */
366
367 mac_ring_handle_t ringHandle;
368
369 u32_t desc_cnt; /* number of Tx descriptors */
370
371 u32_t txFailed;
372 u32_t txDiscards;
373 u32_t txRecycle;
374 u32_t txCopied;
375 u32_t txBlocked;
376 u32_t txWait;
377 u32_t txLowWater;
378
379 u32_t thresh_pdwm; /* low resource water marks */
380
381 kmutex_t txMutex;
382
383 s_list_t sentTxQ; /* bds that have been sent and are ready to be freed */
384
385 kmutex_t freeTxDescMutex;
386 s_list_t freeTxDescQ; /* bds that are free for use */
387
388 s_list_t waitTxDescQ; /* bds that are setup and waiting for tx (lock w/ tx mutex) */
389
390 u32_t noTxCredits;
391 } TxQueue;
392
393
394 typedef struct _um_rxpacket_t
395 {
396 lm_packet_t lm_pkt; /* must be first entry */
397 lm_pkt_rx_info_t rx_info;
398 u32_t hash_value;
399
400 frtn_t freeRtn;
401 void * pUM; /* backpointer to um_device_t for free routine */
402 int idx; /* chain index used by the free routine */
403
404 u32_t signature;
405
406 ddi_dma_handle_t dmaHandle;
407 ddi_acc_handle_t dmaAccHandle;
408 } um_rxpacket_t;
409
410
411 typedef struct _RxQueue
412 {
413 void * pUM; /* backpointer to um_device_t */
414 u32_t idx; /* this ring's index */
415
416 mac_ring_handle_t ringHandle;
417 uint64_t genNumber; /* set by mac and passed up in mac_ring_rx */
418
419 volatile u32_t inPollMode;
420 u8_t intrDisableCnt;
421 u8_t intrEnableCnt;
422 u8_t pollCnt;
423
424 u32_t rxDiscards;
425 u32_t rxCopied;
426 u32_t rxLowWater;
427 u32_t rxBufUpInStack;
428
429 kmutex_t rxMutex;
430
431 kmutex_t doneRxMutex;
432 s_list_t doneRxQ; /* free bds that are ready to be posted */
433
434 s_list_t waitRxQ; /* packet waiting to be sent up */
435 } RxQueue;
436
437
438 typedef struct _RxQueueGroup
439 {
440 void * pUM; /* backpointer to um_device_t */
441 u32_t idx; /* this group's index */
442 mac_group_handle_t groupHandle;
443 } RxQueueGroup;
444
445
446 typedef struct _KstatRingMap
447 {
448 u32_t idx; /* ring index */
449 void * pUM; /* reference back to um_device_t */
450 } KstatRingMap;
451
452
453 typedef struct _BnxeFcoeState
454 {
455 lm_fcoe_state_t lm_fcoe;
456 } BnxeFcoeState;
457
458
459 typedef struct _BnxeClientStats
460 {
461 u32_t initWqeTx;
462 u32_t initWqeTxErr;
463 u32_t initCqeRx;
464 u32_t initCqeRxErr;
465 u32_t offloadConnWqeTx;
466 u32_t offloadConnWqeTxErr;
467 u32_t offloadConnCqeRx;
468 u32_t offloadConnCqeRxErr;
469 u32_t enableConnWqeTx;
470 u32_t enableConnWqeTxErr;
471 u32_t enableConnCqeRx;
472 u32_t enableConnCqeRxErr;
473 u32_t disableConnWqeTx;
474 u32_t disableConnWqeTxErr;
475 u32_t disableConnCqeRx;
476 u32_t disableConnCqeRxErr;
477 u32_t destroyConnWqeTx;
478 u32_t destroyConnWqeTxErr;
479 u32_t destroyConnCqeRx;
480 u32_t destroyConnCqeRxErr;
481 u32_t destroyWqeTx;
482 u32_t destroyWqeTxErr;
483 u32_t destroyCqeRx;
484 u32_t destroyCqeRxErr;
485 u32_t compRequestCqeRx;
486 u32_t compRequestCqeRxErr;
487 u32_t statWqeTx;
488 u32_t statWqeTxErr;
489 u32_t statCqeRx;
490 u32_t statCqeRxErr;
491 } BnxeClientStats;
492
493
494 typedef struct _BnxeFcoeData
495 {
496 dev_info_t * pDev;
497 BnxeBinding bind;
498 BnxeClientStats stats;
499 BnxeWwnInfo wwn;
500 } BnxeFcoeData;
501
502
503 typedef struct _BnxeIntrBlock
504 {
505 int intrCount;
506 int intrCapability;
507 u32_t intrPriority;
508 u32_t intrHandleBlockSize;
509 ddi_intr_handle_t * pIntrHandleBlockAlloc;
510 ddi_intr_handle_t * pIntrHandleBlock;
511 } BnxeIntrBlock;
512
513
514 typedef struct _BnxeWorkQueueInstance
515 {
516 void * pUM;
517
518 char taskqName[BNXE_STR_SIZE];
519 ddi_taskq_t * pTaskq;
520 kmutex_t workQueueMutex;
521 s_list_t workQueue;
522
523 u32_t workItemQueued;
524 u32_t workItemError;
525 u32_t workItemComplete;
526 u32_t highWater;
527 } BnxeWorkQueueInstance;
528
529
530 typedef struct _BnxeWorkQueues
531 {
532 BnxeWorkQueueInstance instq; /* instant, single thread serialized */
533 BnxeWorkQueueInstance delayq; /* delayed, multi thread not serialized */
534 } BnxeWorkQueues;
535
536
537 /* the following are used against the clientState variable in um_device_t */
538
539 #define CLIENT_FLG_DEVI 0x001
540 #define CLIENT_FLG_BIND 0x002
541 #define CLIENT_FLG_HW 0x004
542
543 #define CLIENT_DEVI(pUM, client) \
544 ((pUM)->clientState[(client)] & CLIENT_FLG_DEVI)
545
546 #define CLIENT_HW(pUM, client) \
547 ((pUM)->clientState[(client)] & CLIENT_FLG_HW)
548
549 #define CLIENT_BOUND(pUM, client) \
550 (((client) == LM_CLI_IDX_NDIS) ? \
551 ((pUM)->clientState[(client)] & CLIENT_FLG_HW) : \
552 ((pUM)->clientState[(client)] & CLIENT_FLG_BIND))
553
554 #define CLIENT_DEVI_SET(pUM, client) \
555 ((pUM)->clientState[(client)] |= CLIENT_FLG_DEVI)
556
557 #define CLIENT_DEVI_RESET(pUM, client) \
558 ((pUM)->clientState[(client)] &= ~CLIENT_FLG_DEVI)
559
560 #define CLIENT_BIND_SET(pUM, client) \
561 ((pUM)->clientState[(client)] |= CLIENT_FLG_BIND)
562
563 #define CLIENT_BIND_RESET(pUM, client) \
564 ((pUM)->clientState[(client)] &= ~CLIENT_FLG_BIND)
565
566 #define CLIENT_HW_SET(pUM, client) \
567 ((pUM)->clientState[(client)] |= CLIENT_FLG_HW)
568
569 #define CLIENT_HW_RESET(pUM, client) \
570 ((pUM)->clientState[(client)] &= ~CLIENT_FLG_HW)
571
572
573 typedef struct _um_device
574 {
575 lm_device_t lm_dev; /* must be the first element */
576
577 u32_t magic;
578 dev_info_t * pDev;
579
580 u32_t hwInitDone;
581 u32_t chipStarted;
582 u32_t clientState[LM_CLI_IDX_MAX];
583
584 d_list_t memBlockList;
585 d_list_t memDmaList;
586 d_list_t memRegionList;
587 #ifdef BNXE_DEBUG_DMA_LIST
588 d_list_t memDmaListSaved;
589 #endif
590
591 int instance;
592 char devName[BNXE_STR_SIZE];
593 char version[BNXE_STR_SIZE];
594 char versionLM[BNXE_STR_SIZE];
595 char versionFW[BNXE_STR_SIZE];
596 char versionBC[BNXE_STR_SIZE];
597 char chipName[BNXE_STR_SIZE];
598 char chipID[BNXE_STR_SIZE];
599 char intrAlloc[BNXE_STR_SIZE];
600 char bus_dev_func[BNXE_STR_SIZE];
601 char vendor_device[BNXE_STR_SIZE];
602
603 volatile u32_t plumbed;
604
605 ddi_acc_handle_t pPciCfg;
606
607 kmutex_t intrMutex[MAX_RSS_CHAINS + 1];
608 kmutex_t intrFlipMutex[MAX_RSS_CHAINS + 1];
609 kmutex_t sbMutex[MAX_RSS_CHAINS + 1];
610 kmutex_t ethConMutex;
611 kmutex_t mcpMutex;
612 kmutex_t phyMutex;
613 kmutex_t indMutex;
614 kmutex_t cidMutex;
615 kmutex_t spqMutex; /* slow path queue lock */
616 kmutex_t spReqMutex; /* slow path request manager lock */
617 kmutex_t rrReqMutex; /* ramrod request */
618 kmutex_t islesCtrlMutex;
619 kmutex_t toeMutex;
620 kmutex_t memMutex;
621 kmutex_t offloadMutex;
622 kmutex_t hwInitMutex;
623 kmutex_t gldMutex;
624 krwlock_t gldTxMutex;
625
626 kmutex_t timerMutex;
627 volatile u32_t timerEnabled;
628 timeout_id_t timerID;
629
630 BnxeWorkQueues workqs;
631
632 BnxeMemDma * statusBlocks[MAX_RSS_CHAINS + 1];
633 volatile u32_t intrEnabled;
634 u64_t intrFired;
635 /* the arrays below = LM_SB_CNT() + 1 = 17 */
636 u64_t intrSbCnt[MAX_RSS_CHAINS + 1];
637 u64_t intrSbNoChangeCnt[MAX_RSS_CHAINS + 1];
638 u64_t intrSbPollCnt[MAX_RSS_CHAINS + 1];
639 u64_t intrSbPollNoChangeCnt[MAX_RSS_CHAINS + 1];
640
641 int intrType;
642 u32_t intrPriority;
643 BnxeIntrBlock defIntr;
644 BnxeIntrBlock rssIntr;
645 BnxeIntrBlock fcoeIntr;
646
647 BnxeDevParams devParams;
648 mac_handle_t pMac;
649 mac_resource_handle_t macRxResourceHandles[MAX_ETH_REG_CONS];
650 u8_t gldMac[ETHERNET_ADDRESS_SIZE];
651
652 d_list_t mcast_l2;
653 d_list_t mcast_fcoe;
654
655 u32_t ucastTableLen; /* number of ucast addrs in the table */
656 #ifndef LM_MAX_UC_TABLE_SIZE
657 #define LM_MAX_UC_TABLE_SIZE 1 /* for now, fix needed to support multiple ucast addr */
658 #endif
659
660 TxQueue txq[MAX_ETH_CONS];
661 RxQueue rxq[MAX_ETH_CONS];
662 RxQueueGroup rxqGroup[USER_OPTION_RX_RING_GROUPS_MAX];
663 u32_t rxBufSignature[LM_CLI_IDX_MAX];
664 u32_t txMsgPullUp;
665
666 BnxeProps props;
667 BnxePhyCfg hwinit; /* gathered by BnxeCfgInit */
668 BnxePhyCfg curcfg; /* initialized from hwinit by BnxeCfgReset */
669 BnxeLinkCfg remote;
670 u32_t phyInitialized;
671
672 kstat_t * kstats;
673 kstat_t * kstatsLink;
674 kstat_t * kstatsIntr;
675 kstat_t * kstatsL2Chip;
676 kstat_t * kstatsL2Driver;
677 kstat_t * kstatsL2Stats;
678 kstat_t * kstatsFcoe;
679 kstat_t * kstatsDcbx;
680 kstat_t * kstats_rxq[MAX_ETH_CONS];
681 KstatRingMap kstats_rxq_map[MAX_ETH_CONS];
682 kstat_t * kstats_txq[MAX_ETH_CONS];
683 KstatRingMap kstats_txq_map[MAX_ETH_CONS];
684 kmutex_t kstatMutex;
685
686 int fmCapabilities; /* FMA capabilities */
687
688 boolean_t do_fcoe;
689 BnxeFcoeData fcoe;
690 iscsi_info_block_hdr_t iscsiInfo;
691
692 } um_device_t;
693
694
695 /* mioc[ack|nak] return values from ioctl subroutines */
696 enum ioc_reply
697 {
698 IOC_INVAL = -1, /* bad, NAK with EINVAL */
699 IOC_DONE, /* OK, reply sent */
700 IOC_ACK, /* OK, just send ACK */
701 IOC_REPLY, /* OK, just send reply */
702 IOC_RESTART_ACK, /* OK, restart & ACK */
703 IOC_RESTART_REPLY /* OK, restart & reply */
704 };
705
706
707 #define BNXE_IOC_BASE ('X' << 8)
708 /* IOCTLs for get/set lldp and dcbx params */
709 #define GIOCBNXELLDP (BNXE_IOC_BASE + 0)
710 #define GIOCBNXEDCBX (BNXE_IOC_BASE + 1)
711 #define SIOCBNXEDCBX (BNXE_IOC_BASE + 2)
712 /* IOCTLs for edebug and firmware upgrade */
713 #define GIOCBNXEREG (BNXE_IOC_BASE + 3)
714 #define SIOCBNXEREG (BNXE_IOC_BASE + 4)
715 #define GIOCBNXENVRM (BNXE_IOC_BASE + 5)
716 #define SIOCBNXENVRM (BNXE_IOC_BASE + 6)
717 #define GIOCBNXEPCI (BNXE_IOC_BASE + 7)
718 #define GIOCBNXESTATS (BNXE_IOC_BASE + 8)
719
720 struct bnxe_reg_data
721 {
722 u32_t offset;
723 u32_t value;
724 };
725
726 struct bnxe_nvram_data
727 {
728 u32_t offset;
729 u32_t num_of_u32;
730 u32_t value[1]; /* variable */
731 };
732
733
734 /* bnxe_cfg.c */
735 void BnxeCfgInit(um_device_t * pUM);
736 void BnxeCfgReset(um_device_t * pUM);
737
738 /* bnxe_mm.c */
739 void BnxeInitBdCnts(um_device_t * pUM,
740 int cli_idx);
741
742 /* bnxe_gld.c */
743 boolean_t BnxeGldInit(um_device_t * pUM);
744 boolean_t BnxeGldFini(um_device_t * pUM);
745 void BnxeGldLink(um_device_t * pUM,
746 link_state_t state);
747
748 /* bnxe_hw.c */
749 boolean_t BnxeEstablishHwConn(um_device_t * pUM,
750 int cid);
751 int BnxeHwStartFCOE(um_device_t * pUM);
752 int BnxeHwStartL2(um_device_t * pUM);
753 int BnxeHwStartCore(um_device_t * pUM);
754 void BnxeHwStopFCOE(um_device_t * pUM);
755 void BnxeHwStopL2(um_device_t * pUM);
756 void BnxeHwStopCore(um_device_t * pUM);
757 void BnxeUpdatePhy(um_device_t * pUM);
758 int BnxeMacAddress(um_device_t * pUM,
759 int cliIdx,
760 boolean_t flag,
761 const uint8_t * pMacAddr);
762 int BnxeMulticast(um_device_t * pUM,
763 int cliIdx,
764 boolean_t flag,
765 const uint8_t * pMcastAddr,
766 boolean_t hwSet);
767 int BnxeRxMask(um_device_t * pUM,
768 int cliIdx,
769 lm_rx_mask_t mask);
770 int BnxeHwResume(um_device_t * pUM);
771 int BnxeHwSuspend(um_device_t * pUM);
772 #if (DEVO_REV > 3)
773 int BnxeHwQuiesce(um_device_t * pUM);
774 #endif
775
776 /* bnxe_intr.c */
777 void BnxeIntrIguSbEnable(um_device_t * pUM,
778 u32_t idx,
779 boolean_t fromISR);
780 void BnxeIntrIguSbDisable(um_device_t * pUM,
781 u32_t idx,
782 boolean_t fromISR);
783 void BnxePollRxRing(um_device_t * pUM,
784 u32_t idx,
785 boolean_t * pPktsRxed,
786 boolean_t * pPktsTxed);
787 void BnxePollRxRingFCOE(um_device_t * pUM);
788 int BnxeIntrEnable(um_device_t * pUM);
789 void BnxeIntrDisable(um_device_t * pUM);
790 boolean_t BnxeIntrInit(um_device_t * pUM);
791 void BnxeIntrFini(um_device_t * pUM);
792
793 /* bnxe_kstat.c */
794 boolean_t BnxeKstatInit(um_device_t * pUM);
795 void BnxeKstatFini(um_device_t * pUM);
796
797 /* bnxe_rr.c */
798 int BnxeRouteTxRing(um_device_t * pUM,
799 mblk_t * pMblk);
800
801 /* bnxe_rx.c */
802 boolean_t BnxeWaitForPacketsFromClient(um_device_t * pUM,
803 int cliIdx);
804 mblk_t * BnxeRxRingProcess(um_device_t * pUM,
805 int idx,
806 boolean_t polling,
807 int numBytes);
808 void BnxeRxPktsAbort(um_device_t * pUM,
809 int cliIdx);
810 int BnxeRxPktsInitPostBuffers(um_device_t * pUM,
811 int cliIdx);
812 int BnxeRxPktsInit(um_device_t * pUM,
813 int cliIdx);
814 void BnxeRxPktsFini(um_device_t * pUM,
815 int cliIdx);
816
817 /* bnxe_tx.c */
818 void BnxeTxPktsReclaim(um_device_t * pUM,
819 int idx,
820 s_list_t * pPktList);
821 void BnxeTxRingProcess(um_device_t * pUM,
822 int idx);
823 int BnxeTxSendMblk(um_device_t * pUM,
824 int idx,
825 mblk_t * pMblk,
826 u32_t flags,
827 u16_t vlan_tag);
828 void BnxeTxPktsAbort(um_device_t * pUM,
829 int cliIdx);
830 int BnxeTxPktsInit(um_device_t * pUM,
831 int cliIdx);
832 void BnxeTxPktsFini(um_device_t * pUM,
833 int cliIdx);
834
835 /* bnxe_timer.c */
836 void BnxeTimerStart(um_device_t * pUM);
837 void BnxeTimerStop(um_device_t * pUM);
838
839 /* bnxe_workq.c */
840 boolean_t BnxeWorkQueueInit(um_device_t * pUM);
841 void BnxeWorkQueueWaitAndDestroy(um_device_t * pUM);
842 void BnxeWorkQueueStartPending(um_device_t * pUM);
843 boolean_t BnxeWorkQueueAdd(um_device_t * pUM,
844 void (*pWorkCbk)(um_device_t *, void *, u32_t),
845 void * pWorkData,
846 u32_t workDataLen);
847 boolean_t BnxeWorkQueueAddNoCopy(um_device_t * pUM,
848 void (*pWorkCbk)(um_device_t *, void *),
849 void * pWorkData);
850 boolean_t BnxeWorkQueueAddGeneric(um_device_t * pUM,
851 void (*pWorkCbkGeneric)(um_device_t *));
852 boolean_t BnxeWorkQueueAddDelay(um_device_t * pUM,
853 void (*pWorkCbk)(um_device_t *, void *, u32_t),
854 void * pWorkData,
855 u32_t workDataLen,
856 u32_t delayMs);
857 boolean_t BnxeWorkQueueAddDelayNoCopy(um_device_t * pUM,
858 void (*pWorkCbk)(um_device_t *, void *),
859 void * pWorkData,
860 u32_t delayMs);
861 boolean_t BnxeWorkQueueAddDelayGeneric(um_device_t * pUM,
862 void (*pWorkCbkGeneric)(um_device_t *),
863 u32_t delayMs);
864
865 /* bnxe_fcoe.c */
866 boolean_t BnxeFcoeInitCqe(um_device_t * pUM,
867 struct fcoe_kcqe * kcqe);
868 boolean_t BnxeFcoeOffloadConnCqe(um_device_t * pUM,
869 BnxeFcoeState * pFcoeState,
870 struct fcoe_kcqe * kcqe);
871 boolean_t BnxeFcoeEnableConnCqe(um_device_t * pUM,
872 BnxeFcoeState * pFcoeState,
873 struct fcoe_kcqe * kcqe);
874 boolean_t BnxeFcoeDisableConnCqe(um_device_t * pUM,
875 BnxeFcoeState * pFcoeState,
876 struct fcoe_kcqe * kcqe);
877 boolean_t BnxeFcoeDestroyConnCqe(um_device_t * pUM,
878 BnxeFcoeState * pFcoeState,
879 struct fcoe_kcqe * kcqe);
880 boolean_t BnxeFcoeDestroyCqe(um_device_t * pUM,
881 struct fcoe_kcqe * kcqe);
882 boolean_t BnxeFcoeStatCqe(um_device_t * pUM,
883 struct fcoe_kcqe * kcqe);
884 boolean_t BnxeFcoeCompRequestCqe(um_device_t * pUM,
885 struct fcoe_kcqe * kcqes,
886 u32_t num_kcqes);
887 boolean_t BnxeFcoePrvCtl(dev_info_t * pDev,
888 int cmd,
889 void * pData,
890 int dataLen);
891 mblk_t * BnxeFcoePrvTx(dev_info_t * pDev,
892 mblk_t * pMblk,
893 u32_t flags,
894 u16_t vlan_tag);
895 boolean_t BnxeFcoePrvPoll(dev_info_t * pDev);
896 boolean_t BnxeFcoePrvSendWqes(dev_info_t * pDev,
897 void * wqes[],
898 int wqeCnt);
899 boolean_t BnxeFcoePrvMapMailboxq(dev_info_t * pDev,
900 u32_t cid,
901 void ** ppMap,
902 ddi_acc_handle_t * pAccHandle);
903 boolean_t BnxeFcoePrvUnmapMailboxq(dev_info_t * pDev,
904 u32_t cid,
905 void * pMap,
906 ddi_acc_handle_t accHandle);
907 int BnxeFcoeInit(um_device_t * pUM);
908 int BnxeFcoeFini(um_device_t * pUM);
909 void BnxeFcoeStartStop(um_device_t * pUM);
910
911 /* bnxe_main.c */
912 u8_t BnxeInstance(void * pDev);
913 char * BnxeDevName(void * pDev);
914 boolean_t BnxeProtoSupport(um_device_t * pUM, int proto);
915 boolean_t BnxeProtoFcoeAfex(um_device_t * pUM);
916 int BnxeCheckAccHandle(ddi_acc_handle_t handle);
917 int BnxeCheckDmaHandle(ddi_dma_handle_t handle);
918 void BnxeFmErrorReport(um_device_t * pUM, char * detail);
919
920 /* bnxe_illumos.c */
921 extern boolean_t bnxe_fill_transceiver(um_device_t *, void *);
922 extern mac_ether_media_t bnxe_phy_to_media(um_device_t *);
923
924 extern kmutex_t bnxeLoaderMutex;
925 extern u32_t bnxeNumPlumbed;
926
927 extern BnxeLinkCfg bnxeLinkCfg;
928
929 /* undefine this to help with dtrace analysis */
930 #define BNXE_LOCKS_INLINE
931
932 #ifdef BNXE_LOCKS_INLINE
933
934 #define BNXE_LOCK_ENTER_INTR(pUM, idx) mutex_enter(&(pUM)->intrMutex[(idx)])
935 #define BNXE_LOCK_EXIT_INTR(pUM, idx) mutex_exit(&(pUM)->intrMutex[(idx)])
936 #define BNXE_LOCK_ENTER_INTR_FLIP(pUM, idx) mutex_enter(&(pUM)->intrFlipMutex[(idx)])
937 #define BNXE_LOCK_EXIT_INTR_FLIP(pUM, idx) mutex_exit(&(pUM)->intrFlipMutex[(idx)])
938 #define BNXE_LOCK_ENTER_TX(pUM, idx) mutex_enter(&(pUM)->txq[(idx)].txMutex)
939 #define BNXE_LOCK_EXIT_TX(pUM, idx) mutex_exit(&(pUM)->txq[(idx)].txMutex)
940 #define BNXE_LOCK_ENTER_FREETX(pUM, idx) mutex_enter(&(pUM)->txq[(idx)].freeTxDescMutex)
941 #define BNXE_LOCK_EXIT_FREETX(pUM, idx) mutex_exit(&(pUM)->txq[(idx)].freeTxDescMutex)
942 #define BNXE_LOCK_ENTER_RX(pUM, idx) mutex_enter(&(pUM)->rxq[(idx)].rxMutex)
943 #define BNXE_LOCK_EXIT_RX(pUM, idx) mutex_exit(&(pUM)->rxq[(idx)].rxMutex)
944 #define BNXE_LOCK_ENTER_DONERX(pUM, idx) mutex_enter(&(pUM)->rxq[(idx)].doneRxMutex)
945 #define BNXE_LOCK_EXIT_DONERX(pUM, idx) mutex_exit(&(pUM)->rxq[(idx)].doneRxMutex)
946 #define BNXE_LOCK_ENTER_SB(pUM, idx) mutex_enter(&(pUM)->sbMutex[(idx)])
947 #define BNXE_LOCK_EXIT_SB(pUM, idx) mutex_exit(&(pUM)->sbMutex[(idx)])
948 #define BNXE_LOCK_ENTER_ETH_CON(pUM) mutex_enter(&(pUM)->ethConMutex)
949 #define BNXE_LOCK_EXIT_ETH_CON(pUM) mutex_exit(&(pUM)->ethConMutex)
950 #define BNXE_LOCK_ENTER_MCP(pUM) mutex_enter(&(pUM)->mcpMutex)
951 #define BNXE_LOCK_EXIT_MCP(pUM) mutex_exit(&(pUM)->mcpMutex)
952 #define BNXE_LOCK_ENTER_PHY(pUM) mutex_enter(&(pUM)->phyMutex)
953 #define BNXE_LOCK_EXIT_PHY(pUM) mutex_exit(&(pUM)->phyMutex)
954 #define BNXE_LOCK_ENTER_IND(pUM) mutex_enter(&(pUM)->indMutex)
955 #define BNXE_LOCK_EXIT_IND(pUM) mutex_exit(&(pUM)->indMutex)
956 #define BNXE_LOCK_ENTER_CID(pUM) mutex_enter(&(pUM)->cidMutex)
957 #define BNXE_LOCK_EXIT_CID(pUM) mutex_exit(&(pUM)->cidMutex)
958 #define BNXE_LOCK_ENTER_SPQ(pUM) mutex_enter(&(pUM)->spqMutex)
959 #define BNXE_LOCK_EXIT_SPQ(pUM) mutex_exit(&(pUM)->spqMutex)
960 #define BNXE_LOCK_ENTER_SPREQ(pUM) mutex_enter(&(pUM)->spReqMutex)
961 #define BNXE_LOCK_EXIT_SPREQ(pUM) mutex_exit(&(pUM)->spReqMutex)
962 #define BNXE_LOCK_ENTER_RRREQ(pUM) mutex_enter(&(pUM)->rrReqMutex)
963 #define BNXE_LOCK_EXIT_RRREQ(pUM) mutex_exit(&(pUM)->rrReqMutex)
964 #define BNXE_LOCK_ENTER_ISLES_CONTROL(pUM) mutex_enter(&(pUM)->islesCtrlMutex)
965 #define BNXE_LOCK_EXIT_ISLES_CONTROL(pUM) mutex_exit(&(pUM)->islesCtrlMutex)
966 #define BNXE_LOCK_ENTER_TOE(pUM) mutex_enter(&(pUM)->toeMutex)
967 #define BNXE_LOCK_EXIT_TOE(pUM) mutex_exit(&(pUM)->toeMutex)
968 #define BNXE_LOCK_ENTER_MEM(pUM) mutex_enter(&(pUM)->memMutex)
969 #define BNXE_LOCK_EXIT_MEM(pUM) mutex_exit(&(pUM)->memMutex)
970 #define BNXE_LOCK_ENTER_OFFLOAD(pUM) mutex_enter(&(pUM)->offloadMutex)
971 #define BNXE_LOCK_EXIT_OFFLOAD(pUM) mutex_exit(&(pUM)->offloadMutex)
972 #define BNXE_LOCK_ENTER_HWINIT(pUM) mutex_enter(&(pUM)->hwInitMutex)
973 #define BNXE_LOCK_EXIT_HWINIT(pUM) mutex_exit(&(pUM)->hwInitMutex)
974 #define BNXE_LOCK_ENTER_GLD(pUM) mutex_enter(&(pUM)->gldMutex)
975 #define BNXE_LOCK_EXIT_GLD(pUM) mutex_exit(&(pUM)->gldMutex)
976 #define BNXE_LOCK_ENTER_GLDTX(pUM, rw) rw_enter(&(pUM)->gldTxMutex, (rw))
977 #define BNXE_LOCK_EXIT_GLDTX(pUM) rw_exit(&(pUM)->gldTxMutex)
978 #define BNXE_LOCK_ENTER_TIMER(pUM) mutex_enter(&(pUM)->timerMutex)
979 #define BNXE_LOCK_EXIT_TIMER(pUM) mutex_exit(&(pUM)->timerMutex)
980 #define BNXE_LOCK_ENTER_STATS(pUM) mutex_enter(&(pUM)->kstatMutex)
981 #define BNXE_LOCK_EXIT_STATS(pUM) mutex_exit(&(pUM)->kstatMutex)
982
983 #else /* not BNXE_LOCKS_INLINE */
984
985 void BNXE_LOCK_ENTER_INTR(um_device_t * pUM, int idx);
986 void BNXE_LOCK_EXIT_INTR(um_device_t * pUM, int idx);
987 void BNXE_LOCK_ENTER_INTR_FLIP(um_device_t * pUM, int idx);
988 void BNXE_LOCK_EXIT_INTR_FLIP(um_device_t * pUM, int idx);
989 void BNXE_LOCK_ENTER_TX(um_device_t * pUM, int idx);
990 void BNXE_LOCK_EXIT_TX(um_device_t * pUM, int idx);
991 void BNXE_LOCK_ENTER_FREETX(um_device_t * pUM, int idx);
992 void BNXE_LOCK_EXIT_FREETX(um_device_t * pUM, int idx);
993 void BNXE_LOCK_ENTER_RX(um_device_t * pUM, int idx);
994 void BNXE_LOCK_EXIT_RX(um_device_t * pUM, int idx);
995 void BNXE_LOCK_ENTER_DONERX(um_device_t * pUM, int idx);
996 void BNXE_LOCK_EXIT_DONERX(um_device_t * pUM, int idx);
997 void BNXE_LOCK_ENTER_SB(um_device_t * pUM, int idx);
998 void BNXE_LOCK_EXIT_SB(um_device_t * pUM, int idx);
999 void BNXE_LOCK_ENTER_ETH_CON(um_device_t * pUM);
1000 void BNXE_LOCK_EXIT_ETH_CON(um_device_t * pUM);
1001 void BNXE_LOCK_ENTER_MCP(um_device_t * pUM);
1002 void BNXE_LOCK_EXIT_MCP(um_device_t * pUM);
1003 void BNXE_LOCK_ENTER_PHY(um_device_t * pUM);
1004 void BNXE_LOCK_EXIT_PHY(um_device_t * pUM);
1005 void BNXE_LOCK_ENTER_IND(um_device_t * pUM);
1006 void BNXE_LOCK_EXIT_IND(um_device_t * pUM);
1007 void BNXE_LOCK_ENTER_CID(um_device_t * pUM);
1008 void BNXE_LOCK_EXIT_CID(um_device_t * pUM);
1009 void BNXE_LOCK_ENTER_SPQ(um_device_t * pUM);
1010 void BNXE_LOCK_EXIT_SPQ(um_device_t * pUM);
1011 void BNXE_LOCK_ENTER_SPREQ(um_device_t * pUM);
1012 void BNXE_LOCK_EXIT_SPREQ(um_device_t * pUM);
1013 void BNXE_LOCK_ENTER_RRREQ(um_device_t * pUM);
1014 void BNXE_LOCK_EXIT_RRREQ(um_device_t * pUM);
1015 void BNXE_LOCK_ENTER_ISLES_CONTROL(um_device_t * pUM);
1016 void BNXE_LOCK_EXIT_ISLES_CONTROL(um_device_t * pUM);
1017 void BNXE_LOCK_ENTER_MEM(um_device_t * pUM);
1018 void BNXE_LOCK_EXIT_MEM(um_device_t * pUM);
1019 void BNXE_LOCK_ENTER_GLD(um_device_t * pUM);
1020 void BNXE_LOCK_EXIT_GLD(um_device_t * pUM);
1021 void BNXE_LOCK_ENTER_GLDTX(um_device_t * pUM, krw_t rw);
1022 void BNXE_LOCK_EXIT_GLDTX(um_device_t * pUM);
1023 void BNXE_LOCK_ENTER_TIMER(um_device_t * pUM);
1024 void BNXE_LOCK_EXIT_TIMER(um_device_t * pUM);
1025 void BNXE_LOCK_ENTER_STATS(um_device_t * pUM);
1026 void BNXE_LOCK_EXIT_STATS(um_device_t * pUM);
1027
1028 #endif /* BNXE_LOCKS_INLINE */
1029
1030 #define CATC_TRIGGER(lmdev, data) { \
1031 REG_WR((lmdev), 0x2000, (data)); \
1032 }
1033 #define CATC_TRIGGER_START(lmdev) CATC_TRIGGER((lmdev), 0xcafecafe)
1034
1035 void BnxeDumpMem(um_device_t * pUM,
1036 char * pTag,
1037 u8_t * pMem,
1038 u32_t len);
1039 void BnxeDumpPkt(um_device_t * pUM,
1040 char * pTag,
1041 mblk_t * pMblk,
1042 boolean_t contents);
1043
1044 /* XXX yuck (beware return strings lengths with kstat and mdb) */
1045
BnxeIsClientBound(um_device_t * pUM)1046 inline boolean_t BnxeIsClientBound(um_device_t * pUM)
1047 {
1048 return (CLIENT_HW(pUM, LM_CLI_IDX_NDIS) ||
1049 CLIENT_BOUND(pUM, LM_CLI_IDX_FCOE));
1050 }
1051
BnxeClientsHw(um_device_t * pUM)1052 inline char * BnxeClientsHw(um_device_t * pUM)
1053 {
1054 if (CLIENT_HW(pUM, LM_CLI_IDX_NDIS) &&
1055 CLIENT_HW(pUM, LM_CLI_IDX_FCOE)) { return "L2,FCoE"; }
1056 else if (CLIENT_HW(pUM, LM_CLI_IDX_NDIS)) { return "L2"; }
1057 else if (CLIENT_HW(pUM, LM_CLI_IDX_FCOE)) { return "FCoE"; }
1058 else { return "None"; }
1059 }
1060
BnxeClientsDevi(um_device_t * pUM)1061 inline char * BnxeClientsDevi(um_device_t * pUM)
1062 {
1063 if (CLIENT_DEVI(pUM, LM_CLI_IDX_FCOE)) { return "FCoE"; }
1064 else { return "None"; }
1065 }
1066
BnxeClientsBound(um_device_t * pUM)1067 inline char * BnxeClientsBound(um_device_t * pUM)
1068 {
1069 if (CLIENT_HW(pUM, LM_CLI_IDX_NDIS) &&
1070 CLIENT_BOUND(pUM, LM_CLI_IDX_FCOE)) { return "L2,FCoE"; }
1071 else if (CLIENT_HW(pUM, LM_CLI_IDX_NDIS)) { return "L2"; }
1072 else if (CLIENT_BOUND(pUM, LM_CLI_IDX_FCOE)) { return "FCoE"; }
1073 else { return "None"; }
1074 }
1075
1076 #endif /* BNXE_H */
1077
1078