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) 2009, 2010, Oracle and/or its affiliates. All rights reserved.
24 * Copyright 2016 Nexenta Systems, Inc. All rights reserved.
25 * Copyright (c) 2014, Joyent, Inc. All rights reserved.
26 * Copyright 2014 OmniTI Computer Consulting, Inc. All rights reserved.
27 * Copyright (c) 2014, Tegile Systems Inc. All rights reserved.
28 */
29
30 /*
31 * Copyright (c) 2000 to 2010, LSI Corporation.
32 * All rights reserved.
33 *
34 * Redistribution and use in source and binary forms of all code within
35 * this file that is exclusively owned by LSI, with or without
36 * modification, is permitted provided that, in addition to the CDDL 1.0
37 * License requirements, the following conditions are met:
38 *
39 * Neither the name of the author nor the names of its contributors may be
40 * used to endorse or promote products derived from this software without
41 * specific prior written permission.
42 *
43 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
44 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
45 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
46 * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
47 * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
48 * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
49 * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
50 * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
51 * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
52 * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
53 * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH
54 * DAMAGE.
55 */
56
57 /*
58 * mptsas - This is a driver based on LSI Logic's MPT2.0/2.5 interface.
59 *
60 */
61
62 #if defined(lint) || defined(DEBUG)
63 #define MPTSAS_DEBUG
64 #endif
65
66 /*
67 * standard header files.
68 */
69 #include <sys/note.h>
70 #include <sys/scsi/scsi.h>
71 #include <sys/pci.h>
72 #include <sys/file.h>
73 #include <sys/policy.h>
74 #include <sys/model.h>
75 #include <sys/sysevent.h>
76 #include <sys/sysevent/eventdefs.h>
77 #include <sys/sysevent/dr.h>
78 #include <sys/sata/sata_defs.h>
79 #include <sys/sata/sata_hba.h>
80 #include <sys/scsi/generic/sas.h>
81 #include <sys/scsi/impl/scsi_sas.h>
82
83 #pragma pack(1)
84 #include <sys/scsi/adapters/mpt_sas/mpi/mpi2_type.h>
85 #include <sys/scsi/adapters/mpt_sas/mpi/mpi2.h>
86 #include <sys/scsi/adapters/mpt_sas/mpi/mpi2_cnfg.h>
87 #include <sys/scsi/adapters/mpt_sas/mpi/mpi2_init.h>
88 #include <sys/scsi/adapters/mpt_sas/mpi/mpi2_ioc.h>
89 #include <sys/scsi/adapters/mpt_sas/mpi/mpi2_sas.h>
90 #include <sys/scsi/adapters/mpt_sas/mpi/mpi2_tool.h>
91 #include <sys/scsi/adapters/mpt_sas/mpi/mpi2_raid.h>
92 #pragma pack()
93
94 /*
95 * private header files.
96 *
97 */
98 #include <sys/scsi/impl/scsi_reset_notify.h>
99 #include <sys/scsi/adapters/mpt_sas/mptsas_var.h>
100 #include <sys/scsi/adapters/mpt_sas/mptsas_ioctl.h>
101 #include <sys/scsi/adapters/mpt_sas/mptsas_smhba.h>
102 #include <sys/scsi/adapters/mpt_sas/mptsas_hash.h>
103 #include <sys/raidioctl.h>
104
105 #include <sys/fs/dv_node.h> /* devfs_clean */
106
107 /*
108 * FMA header files
109 */
110 #include <sys/ddifm.h>
111 #include <sys/fm/protocol.h>
112 #include <sys/fm/util.h>
113 #include <sys/fm/io/ddi.h>
114
115 /*
116 * autoconfiguration data and routines.
117 */
118 static int mptsas_attach(dev_info_t *dip, ddi_attach_cmd_t cmd);
119 static int mptsas_detach(dev_info_t *devi, ddi_detach_cmd_t cmd);
120 static int mptsas_power(dev_info_t *dip, int component, int level);
121
122 /*
123 * cb_ops function
124 */
125 static int mptsas_ioctl(dev_t dev, int cmd, intptr_t data, int mode,
126 cred_t *credp, int *rval);
127 #ifdef __sparc
128 static int mptsas_reset(dev_info_t *devi, ddi_reset_cmd_t cmd);
129 #else /* __sparc */
130 static int mptsas_quiesce(dev_info_t *devi);
131 #endif /* __sparc */
132
133 /*
134 * Resource initilaization for hardware
135 */
136 static void mptsas_setup_cmd_reg(mptsas_t *mpt);
137 static void mptsas_disable_bus_master(mptsas_t *mpt);
138 static void mptsas_hba_fini(mptsas_t *mpt);
139 static void mptsas_cfg_fini(mptsas_t *mptsas_blkp);
140 static int mptsas_hba_setup(mptsas_t *mpt);
141 static void mptsas_hba_teardown(mptsas_t *mpt);
142 static int mptsas_config_space_init(mptsas_t *mpt);
143 static void mptsas_config_space_fini(mptsas_t *mpt);
144 static void mptsas_iport_register(mptsas_t *mpt);
145 static int mptsas_smp_setup(mptsas_t *mpt);
146 static void mptsas_smp_teardown(mptsas_t *mpt);
147 static int mptsas_cache_create(mptsas_t *mpt);
148 static void mptsas_cache_destroy(mptsas_t *mpt);
149 static int mptsas_alloc_request_frames(mptsas_t *mpt);
150 static int mptsas_alloc_sense_bufs(mptsas_t *mpt);
151 static int mptsas_alloc_reply_frames(mptsas_t *mpt);
152 static int mptsas_alloc_free_queue(mptsas_t *mpt);
153 static int mptsas_alloc_post_queue(mptsas_t *mpt);
154 static void mptsas_alloc_reply_args(mptsas_t *mpt);
155 static int mptsas_alloc_extra_sgl_frame(mptsas_t *mpt, mptsas_cmd_t *cmd);
156 static void mptsas_free_extra_sgl_frame(mptsas_t *mpt, mptsas_cmd_t *cmd);
157 static int mptsas_init_chip(mptsas_t *mpt, int first_time);
158
159 /*
160 * SCSA function prototypes
161 */
162 static int mptsas_scsi_start(struct scsi_address *ap, struct scsi_pkt *pkt);
163 static int mptsas_scsi_reset(struct scsi_address *ap, int level);
164 static int mptsas_scsi_abort(struct scsi_address *ap, struct scsi_pkt *pkt);
165 static int mptsas_scsi_getcap(struct scsi_address *ap, char *cap, int tgtonly);
166 static int mptsas_scsi_setcap(struct scsi_address *ap, char *cap, int value,
167 int tgtonly);
168 static void mptsas_scsi_dmafree(struct scsi_address *ap, struct scsi_pkt *pkt);
169 static struct scsi_pkt *mptsas_scsi_init_pkt(struct scsi_address *ap,
170 struct scsi_pkt *pkt, struct buf *bp, int cmdlen, int statuslen,
171 int tgtlen, int flags, int (*callback)(), caddr_t arg);
172 static void mptsas_scsi_sync_pkt(struct scsi_address *ap, struct scsi_pkt *pkt);
173 static void mptsas_scsi_destroy_pkt(struct scsi_address *ap,
174 struct scsi_pkt *pkt);
175 static int mptsas_scsi_tgt_init(dev_info_t *hba_dip, dev_info_t *tgt_dip,
176 scsi_hba_tran_t *hba_tran, struct scsi_device *sd);
177 static void mptsas_scsi_tgt_free(dev_info_t *hba_dip, dev_info_t *tgt_dip,
178 scsi_hba_tran_t *hba_tran, struct scsi_device *sd);
179 static int mptsas_scsi_reset_notify(struct scsi_address *ap, int flag,
180 void (*callback)(caddr_t), caddr_t arg);
181 static int mptsas_get_name(struct scsi_device *sd, char *name, int len);
182 static int mptsas_get_bus_addr(struct scsi_device *sd, char *name, int len);
183 static int mptsas_scsi_quiesce(dev_info_t *dip);
184 static int mptsas_scsi_unquiesce(dev_info_t *dip);
185 static int mptsas_bus_config(dev_info_t *pdip, uint_t flags,
186 ddi_bus_config_op_t op, void *arg, dev_info_t **childp);
187
188 /*
189 * SMP functions
190 */
191 static int mptsas_smp_start(struct smp_pkt *smp_pkt);
192
193 /*
194 * internal function prototypes.
195 */
196 static void mptsas_list_add(mptsas_t *mpt);
197 static void mptsas_list_del(mptsas_t *mpt);
198
199 static int mptsas_quiesce_bus(mptsas_t *mpt);
200 static int mptsas_unquiesce_bus(mptsas_t *mpt);
201
202 static int mptsas_alloc_handshake_msg(mptsas_t *mpt, size_t alloc_size);
203 static void mptsas_free_handshake_msg(mptsas_t *mpt);
204
205 static void mptsas_ncmds_checkdrain(void *arg);
206
207 static int mptsas_prepare_pkt(mptsas_cmd_t *cmd);
208 static int mptsas_accept_pkt(mptsas_t *mpt, mptsas_cmd_t *sp);
209 static int mptsas_accept_txwq_and_pkt(mptsas_t *mpt, mptsas_cmd_t *sp);
210 static void mptsas_accept_tx_waitq(mptsas_t *mpt);
211
212 static int mptsas_do_detach(dev_info_t *dev);
213 static int mptsas_do_scsi_reset(mptsas_t *mpt, uint16_t devhdl);
214 static int mptsas_do_scsi_abort(mptsas_t *mpt, int target, int lun,
215 struct scsi_pkt *pkt);
216 static int mptsas_scsi_capchk(char *cap, int tgtonly, int *cidxp);
217
218 static void mptsas_handle_qfull(mptsas_t *mpt, mptsas_cmd_t *cmd);
219 static void mptsas_handle_event(void *args);
220 static int mptsas_handle_event_sync(void *args);
221 static void mptsas_handle_dr(void *args);
222 static void mptsas_handle_topo_change(mptsas_topo_change_list_t *topo_node,
223 dev_info_t *pdip);
224
225 static void mptsas_restart_cmd(void *);
226
227 static void mptsas_flush_hba(mptsas_t *mpt);
228 static void mptsas_flush_target(mptsas_t *mpt, ushort_t target, int lun,
229 uint8_t tasktype);
230 static void mptsas_set_pkt_reason(mptsas_t *mpt, mptsas_cmd_t *cmd,
231 uchar_t reason, uint_t stat);
232
233 static uint_t mptsas_intr(caddr_t arg1, caddr_t arg2);
234 static void mptsas_process_intr(mptsas_t *mpt,
235 pMpi2ReplyDescriptorsUnion_t reply_desc_union);
236 static void mptsas_handle_scsi_io_success(mptsas_t *mpt,
237 pMpi2ReplyDescriptorsUnion_t reply_desc);
238 static void mptsas_handle_address_reply(mptsas_t *mpt,
239 pMpi2ReplyDescriptorsUnion_t reply_desc);
240 static int mptsas_wait_intr(mptsas_t *mpt, int polltime);
241 static void mptsas_sge_setup(mptsas_t *mpt, mptsas_cmd_t *cmd,
242 uint32_t *control, pMpi2SCSIIORequest_t frame, ddi_acc_handle_t acc_hdl);
243
244 static void mptsas_watch(void *arg);
245 static void mptsas_watchsubr(mptsas_t *mpt);
246 static void mptsas_cmd_timeout(mptsas_t *mpt, mptsas_target_t *ptgt);
247
248 static void mptsas_start_passthru(mptsas_t *mpt, mptsas_cmd_t *cmd);
249 static int mptsas_do_passthru(mptsas_t *mpt, uint8_t *request, uint8_t *reply,
250 uint8_t *data, uint32_t request_size, uint32_t reply_size,
251 uint32_t data_size, uint32_t direction, uint8_t *dataout,
252 uint32_t dataout_size, short timeout, int mode);
253 static int mptsas_free_devhdl(mptsas_t *mpt, uint16_t devhdl);
254
255 static uint8_t mptsas_get_fw_diag_buffer_number(mptsas_t *mpt,
256 uint32_t unique_id);
257 static void mptsas_start_diag(mptsas_t *mpt, mptsas_cmd_t *cmd);
258 static int mptsas_post_fw_diag_buffer(mptsas_t *mpt,
259 mptsas_fw_diagnostic_buffer_t *pBuffer, uint32_t *return_code);
260 static int mptsas_release_fw_diag_buffer(mptsas_t *mpt,
261 mptsas_fw_diagnostic_buffer_t *pBuffer, uint32_t *return_code,
262 uint32_t diag_type);
263 static int mptsas_diag_register(mptsas_t *mpt,
264 mptsas_fw_diag_register_t *diag_register, uint32_t *return_code);
265 static int mptsas_diag_unregister(mptsas_t *mpt,
266 mptsas_fw_diag_unregister_t *diag_unregister, uint32_t *return_code);
267 static int mptsas_diag_query(mptsas_t *mpt, mptsas_fw_diag_query_t *diag_query,
268 uint32_t *return_code);
269 static int mptsas_diag_read_buffer(mptsas_t *mpt,
270 mptsas_diag_read_buffer_t *diag_read_buffer, uint8_t *ioctl_buf,
271 uint32_t *return_code, int ioctl_mode);
272 static int mptsas_diag_release(mptsas_t *mpt,
273 mptsas_fw_diag_release_t *diag_release, uint32_t *return_code);
274 static int mptsas_do_diag_action(mptsas_t *mpt, uint32_t action,
275 uint8_t *diag_action, uint32_t length, uint32_t *return_code,
276 int ioctl_mode);
277 static int mptsas_diag_action(mptsas_t *mpt, mptsas_diag_action_t *data,
278 int mode);
279
280 static int mptsas_pkt_alloc_extern(mptsas_t *mpt, mptsas_cmd_t *cmd,
281 int cmdlen, int tgtlen, int statuslen, int kf);
282 static void mptsas_pkt_destroy_extern(mptsas_t *mpt, mptsas_cmd_t *cmd);
283
284 static int mptsas_kmem_cache_constructor(void *buf, void *cdrarg, int kmflags);
285 static void mptsas_kmem_cache_destructor(void *buf, void *cdrarg);
286
287 static int mptsas_cache_frames_constructor(void *buf, void *cdrarg,
288 int kmflags);
289 static void mptsas_cache_frames_destructor(void *buf, void *cdrarg);
290
291 static void mptsas_check_scsi_io_error(mptsas_t *mpt, pMpi2SCSIIOReply_t reply,
292 mptsas_cmd_t *cmd);
293 static void mptsas_check_task_mgt(mptsas_t *mpt,
294 pMpi2SCSIManagementReply_t reply, mptsas_cmd_t *cmd);
295 static int mptsas_send_scsi_cmd(mptsas_t *mpt, struct scsi_address *ap,
296 mptsas_target_t *ptgt, uchar_t *cdb, int cdblen, struct buf *data_bp,
297 int *resid);
298
299 static int mptsas_alloc_active_slots(mptsas_t *mpt, int flag);
300 static void mptsas_free_active_slots(mptsas_t *mpt);
301 static int mptsas_start_cmd(mptsas_t *mpt, mptsas_cmd_t *cmd);
302
303 static void mptsas_restart_hba(mptsas_t *mpt);
304 static void mptsas_restart_waitq(mptsas_t *mpt);
305
306 static void mptsas_deliver_doneq_thread(mptsas_t *mpt);
307 static void mptsas_doneq_add(mptsas_t *mpt, mptsas_cmd_t *cmd);
308 static void mptsas_doneq_mv(mptsas_t *mpt, uint64_t t);
309
310 static mptsas_cmd_t *mptsas_doneq_thread_rm(mptsas_t *mpt, uint64_t t);
311 static void mptsas_doneq_empty(mptsas_t *mpt);
312 static void mptsas_doneq_thread(mptsas_doneq_thread_arg_t *arg);
313
314 static mptsas_cmd_t *mptsas_waitq_rm(mptsas_t *mpt);
315 static void mptsas_waitq_delete(mptsas_t *mpt, mptsas_cmd_t *cmd);
316 static mptsas_cmd_t *mptsas_tx_waitq_rm(mptsas_t *mpt);
317 static void mptsas_tx_waitq_delete(mptsas_t *mpt, mptsas_cmd_t *cmd);
318
319
320 static void mptsas_start_watch_reset_delay();
321 static void mptsas_setup_bus_reset_delay(mptsas_t *mpt);
322 static void mptsas_watch_reset_delay(void *arg);
323 static int mptsas_watch_reset_delay_subr(mptsas_t *mpt);
324
325 /*
326 * helper functions
327 */
328 static void mptsas_dump_cmd(mptsas_t *mpt, mptsas_cmd_t *cmd);
329
330 static dev_info_t *mptsas_find_child(dev_info_t *pdip, char *name);
331 static dev_info_t *mptsas_find_child_phy(dev_info_t *pdip, uint8_t phy);
332 static dev_info_t *mptsas_find_child_addr(dev_info_t *pdip, uint64_t sasaddr,
333 int lun);
334 static mdi_pathinfo_t *mptsas_find_path_addr(dev_info_t *pdip, uint64_t sasaddr,
335 int lun);
336 static mdi_pathinfo_t *mptsas_find_path_phy(dev_info_t *pdip, uint8_t phy);
337 static dev_info_t *mptsas_find_smp_child(dev_info_t *pdip, char *str_wwn);
338
339 static int mptsas_parse_address(char *name, uint64_t *wwid, uint8_t *phy,
340 int *lun);
341 static int mptsas_parse_smp_name(char *name, uint64_t *wwn);
342
343 static mptsas_target_t *mptsas_phy_to_tgt(mptsas_t *mpt,
344 mptsas_phymask_t phymask, uint8_t phy);
345 static mptsas_target_t *mptsas_wwid_to_ptgt(mptsas_t *mpt,
346 mptsas_phymask_t phymask, uint64_t wwid);
347 static mptsas_smp_t *mptsas_wwid_to_psmp(mptsas_t *mpt,
348 mptsas_phymask_t phymask, uint64_t wwid);
349
350 static int mptsas_inquiry(mptsas_t *mpt, mptsas_target_t *ptgt, int lun,
351 uchar_t page, unsigned char *buf, int len, int *rlen, uchar_t evpd);
352
353 static int mptsas_get_target_device_info(mptsas_t *mpt, uint32_t page_address,
354 uint16_t *handle, mptsas_target_t **pptgt);
355 static void mptsas_update_phymask(mptsas_t *mpt);
356
357 static int mptsas_send_sep(mptsas_t *mpt, mptsas_target_t *ptgt,
358 uint32_t *status, uint8_t cmd);
359 static dev_info_t *mptsas_get_dip_from_dev(dev_t dev,
360 mptsas_phymask_t *phymask);
361 static mptsas_target_t *mptsas_addr_to_ptgt(mptsas_t *mpt, char *addr,
362 mptsas_phymask_t phymask);
363 static int mptsas_flush_led_status(mptsas_t *mpt, mptsas_target_t *ptgt);
364
365
366 /*
367 * Enumeration / DR functions
368 */
369 static void mptsas_config_all(dev_info_t *pdip);
370 static int mptsas_config_one_addr(dev_info_t *pdip, uint64_t sasaddr, int lun,
371 dev_info_t **lundip);
372 static int mptsas_config_one_phy(dev_info_t *pdip, uint8_t phy, int lun,
373 dev_info_t **lundip);
374
375 static int mptsas_config_target(dev_info_t *pdip, mptsas_target_t *ptgt);
376 static int mptsas_offline_target(dev_info_t *pdip, char *name);
377
378 static int mptsas_config_raid(dev_info_t *pdip, uint16_t target,
379 dev_info_t **dip);
380
381 static int mptsas_config_luns(dev_info_t *pdip, mptsas_target_t *ptgt);
382 static int mptsas_probe_lun(dev_info_t *pdip, int lun,
383 dev_info_t **dip, mptsas_target_t *ptgt);
384
385 static int mptsas_create_lun(dev_info_t *pdip, struct scsi_inquiry *sd_inq,
386 dev_info_t **dip, mptsas_target_t *ptgt, int lun);
387
388 static int mptsas_create_phys_lun(dev_info_t *pdip, struct scsi_inquiry *sd,
389 char *guid, dev_info_t **dip, mptsas_target_t *ptgt, int lun);
390 static int mptsas_create_virt_lun(dev_info_t *pdip, struct scsi_inquiry *sd,
391 char *guid, dev_info_t **dip, mdi_pathinfo_t **pip, mptsas_target_t *ptgt,
392 int lun);
393
394 static void mptsas_offline_missed_luns(dev_info_t *pdip,
395 uint16_t *repluns, int lun_cnt, mptsas_target_t *ptgt);
396 static int mptsas_offline_lun(dev_info_t *pdip, dev_info_t *rdip,
397 mdi_pathinfo_t *rpip, uint_t flags);
398
399 static int mptsas_config_smp(dev_info_t *pdip, uint64_t sas_wwn,
400 dev_info_t **smp_dip);
401 static int mptsas_offline_smp(dev_info_t *pdip, mptsas_smp_t *smp_node,
402 uint_t flags);
403
404 static int mptsas_event_query(mptsas_t *mpt, mptsas_event_query_t *data,
405 int mode, int *rval);
406 static int mptsas_event_enable(mptsas_t *mpt, mptsas_event_enable_t *data,
407 int mode, int *rval);
408 static int mptsas_event_report(mptsas_t *mpt, mptsas_event_report_t *data,
409 int mode, int *rval);
410 static void mptsas_record_event(void *args);
411 static int mptsas_reg_access(mptsas_t *mpt, mptsas_reg_access_t *data,
412 int mode);
413
414 mptsas_target_t *mptsas_tgt_alloc(refhash_t *, uint16_t, uint64_t,
415 uint32_t, mptsas_phymask_t, uint8_t);
416 static mptsas_smp_t *mptsas_smp_alloc(mptsas_t *, mptsas_smp_t *);
417 static int mptsas_online_smp(dev_info_t *pdip, mptsas_smp_t *smp_node,
418 dev_info_t **smp_dip);
419
420 /*
421 * Power management functions
422 */
423 static int mptsas_get_pci_cap(mptsas_t *mpt);
424 static int mptsas_init_pm(mptsas_t *mpt);
425
426 /*
427 * MPT MSI tunable:
428 *
429 * By default MSI is enabled on all supported platforms.
430 */
431 boolean_t mptsas_enable_msi = B_TRUE;
432 boolean_t mptsas_physical_bind_failed_page_83 = B_FALSE;
433
434 /*
435 * Global switch for use of MPI2.5 FAST PATH.
436 * We don't really know what FAST PATH actually does, so if it is suspected
437 * to cause problems it can be turned off by setting this variable to B_FALSE.
438 */
439 boolean_t mptsas_use_fastpath = B_TRUE;
440
441 static int mptsas_register_intrs(mptsas_t *);
442 static void mptsas_unregister_intrs(mptsas_t *);
443 static int mptsas_add_intrs(mptsas_t *, int);
444 static void mptsas_rem_intrs(mptsas_t *);
445
446 /*
447 * FMA Prototypes
448 */
449 static void mptsas_fm_init(mptsas_t *mpt);
450 static void mptsas_fm_fini(mptsas_t *mpt);
451 static int mptsas_fm_error_cb(dev_info_t *, ddi_fm_error_t *, const void *);
452
453 extern pri_t minclsyspri, maxclsyspri;
454
455 /*
456 * This device is created by the SCSI pseudo nexus driver (SCSI vHCI). It is
457 * under this device that the paths to a physical device are created when
458 * MPxIO is used.
459 */
460 extern dev_info_t *scsi_vhci_dip;
461
462 /*
463 * Tunable timeout value for Inquiry VPD page 0x83
464 * By default the value is 30 seconds.
465 */
466 int mptsas_inq83_retry_timeout = 30;
467
468 /*
469 * This is used to allocate memory for message frame storage, not for
470 * data I/O DMA. All message frames must be stored in the first 4G of
471 * physical memory.
472 */
473 ddi_dma_attr_t mptsas_dma_attrs = {
474 DMA_ATTR_V0, /* attribute layout version */
475 0x0ull, /* address low - should be 0 (longlong) */
476 0xffffffffull, /* address high - 32-bit max range */
477 0x00ffffffull, /* count max - max DMA object size */
478 4, /* allocation alignment requirements */
479 0x78, /* burstsizes - binary encoded values */
480 1, /* minxfer - gran. of DMA engine */
481 0x00ffffffull, /* maxxfer - gran. of DMA engine */
482 0xffffffffull, /* max segment size (DMA boundary) */
483 MPTSAS_MAX_DMA_SEGS, /* scatter/gather list length */
484 512, /* granularity - device transfer size */
485 0 /* flags, set to 0 */
486 };
487
488 /*
489 * This is used for data I/O DMA memory allocation. (full 64-bit DMA
490 * physical addresses are supported.)
491 */
492 ddi_dma_attr_t mptsas_dma_attrs64 = {
493 DMA_ATTR_V0, /* attribute layout version */
494 0x0ull, /* address low - should be 0 (longlong) */
495 0xffffffffffffffffull, /* address high - 64-bit max */
496 0x00ffffffull, /* count max - max DMA object size */
497 4, /* allocation alignment requirements */
498 0x78, /* burstsizes - binary encoded values */
499 1, /* minxfer - gran. of DMA engine */
500 0x00ffffffull, /* maxxfer - gran. of DMA engine */
501 0xffffffffull, /* max segment size (DMA boundary) */
502 MPTSAS_MAX_DMA_SEGS, /* scatter/gather list length */
503 512, /* granularity - device transfer size */
504 0 /* flags, set to 0 */
505 };
506
507 ddi_device_acc_attr_t mptsas_dev_attr = {
508 DDI_DEVICE_ATTR_V1,
509 DDI_STRUCTURE_LE_ACC,
510 DDI_STRICTORDER_ACC,
511 DDI_DEFAULT_ACC
512 };
513
514 static struct cb_ops mptsas_cb_ops = {
515 scsi_hba_open, /* open */
516 scsi_hba_close, /* close */
517 nodev, /* strategy */
518 nodev, /* print */
519 nodev, /* dump */
520 nodev, /* read */
521 nodev, /* write */
522 mptsas_ioctl, /* ioctl */
523 nodev, /* devmap */
524 nodev, /* mmap */
525 nodev, /* segmap */
526 nochpoll, /* chpoll */
527 ddi_prop_op, /* cb_prop_op */
528 NULL, /* streamtab */
529 D_MP, /* cb_flag */
530 CB_REV, /* rev */
531 nodev, /* aread */
532 nodev /* awrite */
533 };
534
535 static struct dev_ops mptsas_ops = {
536 DEVO_REV, /* devo_rev, */
537 0, /* refcnt */
538 ddi_no_info, /* info */
539 nulldev, /* identify */
540 nulldev, /* probe */
541 mptsas_attach, /* attach */
542 mptsas_detach, /* detach */
543 #ifdef __sparc
544 mptsas_reset,
545 #else
546 nodev, /* reset */
547 #endif /* __sparc */
548 &mptsas_cb_ops, /* driver operations */
549 NULL, /* bus operations */
550 mptsas_power, /* power management */
551 #ifdef __sparc
552 ddi_quiesce_not_needed
553 #else
554 mptsas_quiesce /* quiesce */
555 #endif /* __sparc */
556 };
557
558
559 #define MPTSAS_MOD_STRING "MPTSAS HBA Driver 00.00.00.24"
560
561 static struct modldrv modldrv = {
562 &mod_driverops, /* Type of module. This one is a driver */
563 MPTSAS_MOD_STRING, /* Name of the module. */
564 &mptsas_ops, /* driver ops */
565 };
566
567 static struct modlinkage modlinkage = {
568 MODREV_1, { &modldrv, NULL }
569 };
570 #define TARGET_PROP "target"
571 #define LUN_PROP "lun"
572 #define LUN64_PROP "lun64"
573 #define SAS_PROP "sas-mpt"
574 #define MDI_GUID "wwn"
575 #define NDI_GUID "guid"
576 #define MPTSAS_DEV_GONE "mptsas_dev_gone"
577
578 /*
579 * Local static data
580 */
581 #if defined(MPTSAS_DEBUG)
582 /*
583 * Flags to indicate which debug messages are to be printed and which go to the
584 * debug log ring buffer. Default is to not print anything, and to log
585 * everything except the watchsubr() output which normally happens every second.
586 */
587 uint32_t mptsas_debugprt_flags = 0x0;
588 uint32_t mptsas_debuglog_flags = ~(1U << 30);
589 #endif /* defined(MPTSAS_DEBUG) */
590 uint32_t mptsas_debug_resets = 0;
591
592 static kmutex_t mptsas_global_mutex;
593 static void *mptsas_state; /* soft state ptr */
594 static krwlock_t mptsas_global_rwlock;
595
596 static kmutex_t mptsas_log_mutex;
597 static char mptsas_log_buf[256];
598 _NOTE(MUTEX_PROTECTS_DATA(mptsas_log_mutex, mptsas_log_buf))
599
600 static mptsas_t *mptsas_head, *mptsas_tail;
601 static clock_t mptsas_scsi_watchdog_tick;
602 static clock_t mptsas_tick;
603 static timeout_id_t mptsas_reset_watch;
604 static timeout_id_t mptsas_timeout_id;
605 static int mptsas_timeouts_enabled = 0;
606
607 /*
608 * Default length for extended auto request sense buffers.
609 * All sense buffers need to be under the same alloc because there
610 * is only one common top 32bits (of 64bits) address register.
611 * Most requests only require 32 bytes, but some request >256.
612 * We use rmalloc()/rmfree() on this additional memory to manage the
613 * "extended" requests.
614 */
615 int mptsas_extreq_sense_bufsize = 256*64;
616
617 /*
618 * We believe that all software resrictions of having to run with DMA
619 * attributes to limit allocation to the first 4G are removed.
620 * However, this flag remains to enable quick switchback should suspicious
621 * problems emerge.
622 * Note that scsi_alloc_consistent_buf() does still adhere to allocating
623 * 32 bit addressable memory, but we can cope if that is changed now.
624 */
625 int mptsas_use_64bit_msgaddr = 1;
626
627 /*
628 * warlock directives
629 */
630 _NOTE(SCHEME_PROTECTS_DATA("unique per pkt", scsi_pkt \
631 mptsas_cmd NcrTableIndirect buf scsi_cdb scsi_status))
632 _NOTE(SCHEME_PROTECTS_DATA("unique per pkt", smp_pkt))
633 _NOTE(SCHEME_PROTECTS_DATA("stable data", scsi_device scsi_address))
634 _NOTE(SCHEME_PROTECTS_DATA("No Mutex Needed", mptsas_tgt_private))
635 _NOTE(SCHEME_PROTECTS_DATA("No Mutex Needed", scsi_hba_tran::tran_tgt_private))
636
637 /*
638 * SM - HBA statics
639 */
640 char *mptsas_driver_rev = MPTSAS_MOD_STRING;
641
642 #ifdef MPTSAS_DEBUG
643 void debug_enter(char *);
644 #endif
645
646 /*
647 * Notes:
648 * - scsi_hba_init(9F) initializes SCSI HBA modules
649 * - must call scsi_hba_fini(9F) if modload() fails
650 */
651 int
652 _init(void)
653 {
654 int status;
655 /* CONSTCOND */
656 ASSERT(NO_COMPETING_THREADS);
657
658 NDBG0(("_init"));
659
660 status = ddi_soft_state_init(&mptsas_state, MPTSAS_SIZE,
661 MPTSAS_INITIAL_SOFT_SPACE);
662 if (status != 0) {
663 return (status);
664 }
665
666 if ((status = scsi_hba_init(&modlinkage)) != 0) {
667 ddi_soft_state_fini(&mptsas_state);
668 return (status);
669 }
670
671 mutex_init(&mptsas_global_mutex, NULL, MUTEX_DRIVER, NULL);
672 rw_init(&mptsas_global_rwlock, NULL, RW_DRIVER, NULL);
673 mutex_init(&mptsas_log_mutex, NULL, MUTEX_DRIVER, NULL);
674
675 if ((status = mod_install(&modlinkage)) != 0) {
676 mutex_destroy(&mptsas_log_mutex);
677 rw_destroy(&mptsas_global_rwlock);
678 mutex_destroy(&mptsas_global_mutex);
679 ddi_soft_state_fini(&mptsas_state);
680 scsi_hba_fini(&modlinkage);
681 }
682
683 return (status);
684 }
685
686 /*
687 * Notes:
688 * - scsi_hba_fini(9F) uninitializes SCSI HBA modules
689 */
690 int
691 _fini(void)
692 {
693 int status;
694 /* CONSTCOND */
695 ASSERT(NO_COMPETING_THREADS);
696
697 NDBG0(("_fini"));
698
699 if ((status = mod_remove(&modlinkage)) == 0) {
700 ddi_soft_state_fini(&mptsas_state);
701 scsi_hba_fini(&modlinkage);
702 mutex_destroy(&mptsas_global_mutex);
703 rw_destroy(&mptsas_global_rwlock);
704 mutex_destroy(&mptsas_log_mutex);
705 }
706 return (status);
707 }
708
709 /*
710 * The loadable-module _info(9E) entry point
711 */
712 int
713 _info(struct modinfo *modinfop)
714 {
715 /* CONSTCOND */
716 ASSERT(NO_COMPETING_THREADS);
717 NDBG0(("mptsas _info"));
718
719 return (mod_info(&modlinkage, modinfop));
720 }
721
722 static int
723 mptsas_target_eval_devhdl(const void *op, void *arg)
724 {
725 uint16_t dh = *(uint16_t *)arg;
726 const mptsas_target_t *tp = op;
727
728 return ((int)tp->m_devhdl - (int)dh);
729 }
730
731 static int
732 mptsas_target_eval_slot(const void *op, void *arg)
733 {
734 mptsas_led_control_t *lcp = arg;
735 const mptsas_target_t *tp = op;
736
737 if (tp->m_enclosure != lcp->Enclosure)
738 return ((int)tp->m_enclosure - (int)lcp->Enclosure);
739
740 return ((int)tp->m_slot_num - (int)lcp->Slot);
741 }
742
743 static int
744 mptsas_target_eval_nowwn(const void *op, void *arg)
745 {
746 uint8_t phy = *(uint8_t *)arg;
747 const mptsas_target_t *tp = op;
748
749 if (tp->m_addr.mta_wwn != 0)
750 return (-1);
751
752 return ((int)tp->m_phynum - (int)phy);
753 }
754
755 static int
756 mptsas_smp_eval_devhdl(const void *op, void *arg)
757 {
758 uint16_t dh = *(uint16_t *)arg;
759 const mptsas_smp_t *sp = op;
760
761 return ((int)sp->m_devhdl - (int)dh);
762 }
763
764 static uint64_t
765 mptsas_target_addr_hash(const void *tp)
766 {
767 const mptsas_target_addr_t *tap = tp;
768
769 return ((tap->mta_wwn & 0xffffffffffffULL) |
770 ((uint64_t)tap->mta_phymask << 48));
771 }
772
773 static int
774 mptsas_target_addr_cmp(const void *a, const void *b)
775 {
776 const mptsas_target_addr_t *aap = a;
777 const mptsas_target_addr_t *bap = b;
778
779 if (aap->mta_wwn < bap->mta_wwn)
780 return (-1);
781 if (aap->mta_wwn > bap->mta_wwn)
782 return (1);
783 return ((int)bap->mta_phymask - (int)aap->mta_phymask);
784 }
785
786 static uint64_t
787 mptsas_tmp_target_hash(const void *tp)
788 {
789 return ((uint64_t)(uintptr_t)tp);
790 }
791
792 static int
793 mptsas_tmp_target_cmp(const void *a, const void *b)
794 {
795 if (a > b)
796 return (1);
797 if (b < a)
798 return (-1);
799
800 return (0);
801 }
802
803 static void
804 mptsas_target_free(void *op)
805 {
806 kmem_free(op, sizeof (mptsas_target_t));
807 }
808
809 static void
810 mptsas_smp_free(void *op)
811 {
812 kmem_free(op, sizeof (mptsas_smp_t));
813 }
814
815 static void
816 mptsas_destroy_hashes(mptsas_t *mpt)
817 {
818 mptsas_target_t *tp;
819 mptsas_smp_t *sp;
820
821 for (tp = refhash_first(mpt->m_targets); tp != NULL;
822 tp = refhash_next(mpt->m_targets, tp)) {
823 refhash_remove(mpt->m_targets, tp);
824 }
825 for (sp = refhash_first(mpt->m_smp_targets); sp != NULL;
826 sp = refhash_next(mpt->m_smp_targets, sp)) {
827 refhash_remove(mpt->m_smp_targets, sp);
828 }
829 refhash_destroy(mpt->m_tmp_targets);
830 refhash_destroy(mpt->m_targets);
831 refhash_destroy(mpt->m_smp_targets);
832 mpt->m_targets = NULL;
833 mpt->m_smp_targets = NULL;
834 }
835
836 static int
837 mptsas_iport_attach(dev_info_t *dip, ddi_attach_cmd_t cmd)
838 {
839 dev_info_t *pdip;
840 mptsas_t *mpt;
841 scsi_hba_tran_t *hba_tran;
842 char *iport = NULL;
843 char phymask[MPTSAS_MAX_PHYS];
844 mptsas_phymask_t phy_mask = 0;
845 int dynamic_port = 0;
846 uint32_t page_address;
847 char initiator_wwnstr[MPTSAS_WWN_STRLEN];
848 int rval = DDI_FAILURE;
849 int i = 0;
850 uint8_t numphys = 0;
851 uint8_t phy_id;
852 uint8_t phy_port = 0;
853 uint16_t attached_devhdl = 0;
854 uint32_t dev_info;
855 uint64_t attached_sas_wwn;
856 uint16_t dev_hdl;
857 uint16_t pdev_hdl;
858 uint16_t bay_num, enclosure, io_flags;
859 char attached_wwnstr[MPTSAS_WWN_STRLEN];
860
861 /* CONSTCOND */
862 ASSERT(NO_COMPETING_THREADS);
863
864 switch (cmd) {
865 case DDI_ATTACH:
866 break;
867
868 case DDI_RESUME:
869 /*
870 * If this a scsi-iport node, nothing to do here.
871 */
872 return (DDI_SUCCESS);
873
874 default:
875 return (DDI_FAILURE);
876 }
877
878 pdip = ddi_get_parent(dip);
879
880 if ((hba_tran = ndi_flavorv_get(pdip, SCSA_FLAVOR_SCSI_DEVICE)) ==
881 NULL) {
882 cmn_err(CE_WARN, "Failed attach iport because fail to "
883 "get tran vector for the HBA node");
884 return (DDI_FAILURE);
885 }
886
887 mpt = TRAN2MPT(hba_tran);
888 ASSERT(mpt != NULL);
889 if (mpt == NULL)
890 return (DDI_FAILURE);
891
892 if ((hba_tran = ndi_flavorv_get(dip, SCSA_FLAVOR_SCSI_DEVICE)) ==
893 NULL) {
894 mptsas_log(mpt, CE_WARN, "Failed attach iport because fail to "
895 "get tran vector for the iport node");
896 return (DDI_FAILURE);
897 }
898
899 /*
900 * Overwrite parent's tran_hba_private to iport's tran vector
901 */
902 hba_tran->tran_hba_private = mpt;
903
904 ddi_report_dev(dip);
905
906 /*
907 * Get SAS address for initiator port according dev_handle
908 */
909 iport = ddi_get_name_addr(dip);
910 if (iport && strncmp(iport, "v0", 2) == 0) {
911 if (ddi_prop_update_int(DDI_DEV_T_NONE, dip,
912 MPTSAS_VIRTUAL_PORT, 1) !=
913 DDI_PROP_SUCCESS) {
914 (void) ddi_prop_remove(DDI_DEV_T_NONE, dip,
915 MPTSAS_VIRTUAL_PORT);
916 mptsas_log(mpt, CE_WARN, "mptsas virtual port "
917 "prop update failed");
918 return (DDI_FAILURE);
919 }
920 return (DDI_SUCCESS);
921 }
922
923 mutex_enter(&mpt->m_mutex);
924 for (i = 0; i < MPTSAS_MAX_PHYS; i++) {
925 bzero(phymask, sizeof (phymask));
926 (void) sprintf(phymask,
927 "%x", mpt->m_phy_info[i].phy_mask);
928 if (strcmp(phymask, iport) == 0) {
929 break;
930 }
931 }
932
933 if (i == MPTSAS_MAX_PHYS) {
934 mptsas_log(mpt, CE_WARN, "Failed attach port %s because port"
935 "seems not exist", iport);
936 mutex_exit(&mpt->m_mutex);
937 return (DDI_FAILURE);
938 }
939
940 phy_mask = mpt->m_phy_info[i].phy_mask;
941
942 if (mpt->m_phy_info[i].port_flags & AUTO_PORT_CONFIGURATION)
943 dynamic_port = 1;
944 else
945 dynamic_port = 0;
946
947 /*
948 * Update PHY info for smhba
949 */
950 if (mptsas_smhba_phy_init(mpt)) {
951 mutex_exit(&mpt->m_mutex);
952 mptsas_log(mpt, CE_WARN, "mptsas phy update "
953 "failed");
954 return (DDI_FAILURE);
955 }
956
957 mutex_exit(&mpt->m_mutex);
958
959 numphys = 0;
960 for (i = 0; i < MPTSAS_MAX_PHYS; i++) {
961 if ((phy_mask >> i) & 0x01) {
962 numphys++;
963 }
964 }
965
966 bzero(initiator_wwnstr, sizeof (initiator_wwnstr));
967 (void) sprintf(initiator_wwnstr, "w%016"PRIx64,
968 mpt->un.m_base_wwid);
969
970 if (ddi_prop_update_string(DDI_DEV_T_NONE, dip,
971 SCSI_ADDR_PROP_INITIATOR_PORT, initiator_wwnstr) !=
972 DDI_PROP_SUCCESS) {
973 (void) ddi_prop_remove(DDI_DEV_T_NONE,
974 dip, SCSI_ADDR_PROP_INITIATOR_PORT);
975 mptsas_log(mpt, CE_WARN, "mptsas Initiator port "
976 "prop update failed");
977 return (DDI_FAILURE);
978 }
979 if (ddi_prop_update_int(DDI_DEV_T_NONE, dip,
980 MPTSAS_NUM_PHYS, numphys) !=
981 DDI_PROP_SUCCESS) {
982 (void) ddi_prop_remove(DDI_DEV_T_NONE, dip, MPTSAS_NUM_PHYS);
983 return (DDI_FAILURE);
984 }
985
986 if (ddi_prop_update_int(DDI_DEV_T_NONE, dip,
987 "phymask", phy_mask) !=
988 DDI_PROP_SUCCESS) {
989 (void) ddi_prop_remove(DDI_DEV_T_NONE, dip, "phymask");
990 mptsas_log(mpt, CE_WARN, "mptsas phy mask "
991 "prop update failed");
992 return (DDI_FAILURE);
993 }
994
995 if (ddi_prop_update_int(DDI_DEV_T_NONE, dip,
996 "dynamic-port", dynamic_port) !=
997 DDI_PROP_SUCCESS) {
998 (void) ddi_prop_remove(DDI_DEV_T_NONE, dip, "dynamic-port");
999 mptsas_log(mpt, CE_WARN, "mptsas dynamic port "
1000 "prop update failed");
1001 return (DDI_FAILURE);
1002 }
1003 if (ddi_prop_update_int(DDI_DEV_T_NONE, dip,
1004 MPTSAS_VIRTUAL_PORT, 0) !=
1005 DDI_PROP_SUCCESS) {
1006 (void) ddi_prop_remove(DDI_DEV_T_NONE, dip,
1007 MPTSAS_VIRTUAL_PORT);
1008 mptsas_log(mpt, CE_WARN, "mptsas virtual port "
1009 "prop update failed");
1010 return (DDI_FAILURE);
1011 }
1012 mptsas_smhba_set_all_phy_props(mpt, dip, numphys, phy_mask,
1013 &attached_devhdl);
1014
1015 mutex_enter(&mpt->m_mutex);
1016 page_address = (MPI2_SAS_DEVICE_PGAD_FORM_HANDLE &
1017 MPI2_SAS_DEVICE_PGAD_FORM_MASK) | (uint32_t)attached_devhdl;
1018 rval = mptsas_get_sas_device_page0(mpt, page_address, &dev_hdl,
1019 &attached_sas_wwn, &dev_info, &phy_port, &phy_id,
1020 &pdev_hdl, &bay_num, &enclosure, &io_flags);
1021 if (rval != DDI_SUCCESS) {
1022 mptsas_log(mpt, CE_WARN,
1023 "Failed to get device page0 for handle:%d",
1024 attached_devhdl);
1025 mutex_exit(&mpt->m_mutex);
1026 return (DDI_FAILURE);
1027 }
1028
1029 for (i = 0; i < MPTSAS_MAX_PHYS; i++) {
1030 bzero(phymask, sizeof (phymask));
1031 (void) sprintf(phymask, "%x", mpt->m_phy_info[i].phy_mask);
1032 if (strcmp(phymask, iport) == 0) {
1033 (void) sprintf(&mpt->m_phy_info[i].smhba_info.path[0],
1034 "%x",
1035 mpt->m_phy_info[i].phy_mask);
1036 }
1037 }
1038 mutex_exit(&mpt->m_mutex);
1039
1040 bzero(attached_wwnstr, sizeof (attached_wwnstr));
1041 (void) sprintf(attached_wwnstr, "w%016"PRIx64,
1042 attached_sas_wwn);
1043 if (ddi_prop_update_string(DDI_DEV_T_NONE, dip,
1044 SCSI_ADDR_PROP_ATTACHED_PORT, attached_wwnstr) !=
1045 DDI_PROP_SUCCESS) {
1046 (void) ddi_prop_remove(DDI_DEV_T_NONE,
1047 dip, SCSI_ADDR_PROP_ATTACHED_PORT);
1048 return (DDI_FAILURE);
1049 }
1050
1051 /* Create kstats for each phy on this iport */
1052
1053 mptsas_create_phy_stats(mpt, iport, dip);
1054
1055 /*
1056 * register sas hba iport with mdi (MPxIO/vhci)
1057 */
1058 if (mdi_phci_register(MDI_HCI_CLASS_SCSI,
1059 dip, 0) == MDI_SUCCESS) {
1060 mpt->m_mpxio_enable = TRUE;
1061 }
1062 return (DDI_SUCCESS);
1063 }
1064
1065 /*
1066 * Notes:
1067 * Set up all device state and allocate data structures,
1068 * mutexes, condition variables, etc. for device operation.
1069 * Add interrupts needed.
1070 * Return DDI_SUCCESS if device is ready, else return DDI_FAILURE.
1071 */
1072 static int
1073 mptsas_attach(dev_info_t *dip, ddi_attach_cmd_t cmd)
1074 {
1075 mptsas_t *mpt = NULL;
1076 int instance, i, j;
1077 int doneq_thread_num;
1078 char intr_added = 0;
1079 char map_setup = 0;
1080 char config_setup = 0;
1081 char hba_attach_setup = 0;
1082 char smp_attach_setup = 0;
1083 char mutex_init_done = 0;
1084 char event_taskq_create = 0;
1085 char dr_taskq_create = 0;
1086 char doneq_thread_create = 0;
1087 char added_watchdog = 0;
1088 scsi_hba_tran_t *hba_tran;
1089 uint_t mem_bar = MEM_SPACE;
1090 int rval = DDI_FAILURE;
1091
1092 /* CONSTCOND */
1093 ASSERT(NO_COMPETING_THREADS);
1094
1095 if (scsi_hba_iport_unit_address(dip)) {
1096 return (mptsas_iport_attach(dip, cmd));
1097 }
1098
1099 switch (cmd) {
1100 case DDI_ATTACH:
1101 break;
1102
1103 case DDI_RESUME:
1104 if ((hba_tran = ddi_get_driver_private(dip)) == NULL)
1105 return (DDI_FAILURE);
1106
1107 mpt = TRAN2MPT(hba_tran);
1108
1109 if (!mpt) {
1110 return (DDI_FAILURE);
1111 }
1112
1113 /*
1114 * Reset hardware and softc to "no outstanding commands"
1115 * Note that a check condition can result on first command
1116 * to a target.
1117 */
1118 mutex_enter(&mpt->m_mutex);
1119
1120 /*
1121 * raise power.
1122 */
1123 if (mpt->m_options & MPTSAS_OPT_PM) {
1124 mutex_exit(&mpt->m_mutex);
1125 (void) pm_busy_component(dip, 0);
1126 rval = pm_power_has_changed(dip, 0, PM_LEVEL_D0);
1127 if (rval == DDI_SUCCESS) {
1128 mutex_enter(&mpt->m_mutex);
1129 } else {
1130 /*
1131 * The pm_raise_power() call above failed,
1132 * and that can only occur if we were unable
1133 * to reset the hardware. This is probably
1134 * due to unhealty hardware, and because
1135 * important filesystems(such as the root
1136 * filesystem) could be on the attached disks,
1137 * it would not be a good idea to continue,
1138 * as we won't be entirely certain we are
1139 * writing correct data. So we panic() here
1140 * to not only prevent possible data corruption,
1141 * but to give developers or end users a hope
1142 * of identifying and correcting any problems.
1143 */
1144 fm_panic("mptsas could not reset hardware "
1145 "during resume");
1146 }
1147 }
1148
1149 mpt->m_suspended = 0;
1150
1151 /*
1152 * Reinitialize ioc
1153 */
1154 mpt->m_softstate |= MPTSAS_SS_MSG_UNIT_RESET;
1155 if (mptsas_init_chip(mpt, FALSE) == DDI_FAILURE) {
1156 mutex_exit(&mpt->m_mutex);
1157 if (mpt->m_options & MPTSAS_OPT_PM) {
1158 (void) pm_idle_component(dip, 0);
1159 }
1160 fm_panic("mptsas init chip fail during resume");
1161 }
1162 /*
1163 * mptsas_update_driver_data needs interrupts so enable them
1164 * first.
1165 */
1166 MPTSAS_ENABLE_INTR(mpt);
1167 mptsas_update_driver_data(mpt);
1168
1169 /* start requests, if possible */
1170 mptsas_restart_hba(mpt);
1171
1172 mutex_exit(&mpt->m_mutex);
1173
1174 /*
1175 * Restart watch thread
1176 */
1177 mutex_enter(&mptsas_global_mutex);
1178 if (mptsas_timeout_id == 0) {
1179 mptsas_timeout_id = timeout(mptsas_watch, NULL,
1180 mptsas_tick);
1181 mptsas_timeouts_enabled = 1;
1182 }
1183 mutex_exit(&mptsas_global_mutex);
1184
1185 /* report idle status to pm framework */
1186 if (mpt->m_options & MPTSAS_OPT_PM) {
1187 (void) pm_idle_component(dip, 0);
1188 }
1189
1190 return (DDI_SUCCESS);
1191
1192 default:
1193 return (DDI_FAILURE);
1194
1195 }
1196
1197 instance = ddi_get_instance(dip);
1198
1199 /*
1200 * Allocate softc information.
1201 */
1202 if (ddi_soft_state_zalloc(mptsas_state, instance) != DDI_SUCCESS) {
1203 mptsas_log(NULL, CE_WARN,
1204 "mptsas%d: cannot allocate soft state", instance);
1205 goto fail;
1206 }
1207
1208 mpt = ddi_get_soft_state(mptsas_state, instance);
1209
1210 if (mpt == NULL) {
1211 mptsas_log(NULL, CE_WARN,
1212 "mptsas%d: cannot get soft state", instance);
1213 goto fail;
1214 }
1215
1216 /* Indicate that we are 'sizeof (scsi_*(9S))' clean. */
1217 scsi_size_clean(dip);
1218
1219 mpt->m_dip = dip;
1220 mpt->m_instance = instance;
1221
1222 /* Make a per-instance copy of the structures */
1223 mpt->m_io_dma_attr = mptsas_dma_attrs64;
1224 if (mptsas_use_64bit_msgaddr) {
1225 mpt->m_msg_dma_attr = mptsas_dma_attrs64;
1226 } else {
1227 mpt->m_msg_dma_attr = mptsas_dma_attrs;
1228 }
1229 mpt->m_reg_acc_attr = mptsas_dev_attr;
1230 mpt->m_dev_acc_attr = mptsas_dev_attr;
1231
1232 /*
1233 * Size of individual request sense buffer
1234 */
1235 mpt->m_req_sense_size = EXTCMDS_STATUS_SIZE;
1236
1237 /*
1238 * Initialize FMA
1239 */
1240 mpt->m_fm_capabilities = ddi_getprop(DDI_DEV_T_ANY, mpt->m_dip,
1241 DDI_PROP_CANSLEEP | DDI_PROP_DONTPASS, "fm-capable",
1242 DDI_FM_EREPORT_CAPABLE | DDI_FM_ACCCHK_CAPABLE |
1243 DDI_FM_DMACHK_CAPABLE | DDI_FM_ERRCB_CAPABLE);
1244
1245 mptsas_fm_init(mpt);
1246
1247 if (mptsas_alloc_handshake_msg(mpt,
1248 sizeof (Mpi2SCSITaskManagementRequest_t)) == DDI_FAILURE) {
1249 mptsas_log(mpt, CE_WARN, "cannot initialize handshake msg.");
1250 goto fail;
1251 }
1252
1253 /*
1254 * Setup configuration space
1255 */
1256 if (mptsas_config_space_init(mpt) == FALSE) {
1257 mptsas_log(mpt, CE_WARN, "mptsas_config_space_init failed");
1258 goto fail;
1259 }
1260 config_setup++;
1261
1262 if (ddi_regs_map_setup(dip, mem_bar, (caddr_t *)&mpt->m_reg,
1263 0, 0, &mpt->m_reg_acc_attr, &mpt->m_datap) != DDI_SUCCESS) {
1264 mptsas_log(mpt, CE_WARN, "map setup failed");
1265 goto fail;
1266 }
1267 map_setup++;
1268
1269 /*
1270 * A taskq is created for dealing with the event handler
1271 */
1272 if ((mpt->m_event_taskq = ddi_taskq_create(dip, "mptsas_event_taskq",
1273 1, TASKQ_DEFAULTPRI, 0)) == NULL) {
1274 mptsas_log(mpt, CE_NOTE, "ddi_taskq_create failed");
1275 goto fail;
1276 }
1277 event_taskq_create++;
1278
1279 /*
1280 * A taskq is created for dealing with dr events
1281 */
1282 if ((mpt->m_dr_taskq = ddi_taskq_create(dip,
1283 "mptsas_dr_taskq",
1284 1, TASKQ_DEFAULTPRI, 0)) == NULL) {
1285 mptsas_log(mpt, CE_NOTE, "ddi_taskq_create for discovery "
1286 "failed");
1287 goto fail;
1288 }
1289 dr_taskq_create++;
1290
1291 mpt->m_doneq_thread_threshold = ddi_prop_get_int(DDI_DEV_T_ANY, dip,
1292 0, "mptsas_doneq_thread_threshold_prop", 10);
1293 mpt->m_doneq_length_threshold = ddi_prop_get_int(DDI_DEV_T_ANY, dip,
1294 0, "mptsas_doneq_length_threshold_prop", 8);
1295 mpt->m_doneq_thread_n = ddi_prop_get_int(DDI_DEV_T_ANY, dip,
1296 0, "mptsas_doneq_thread_n_prop", 8);
1297
1298 if (mpt->m_doneq_thread_n) {
1299 cv_init(&mpt->m_doneq_thread_cv, NULL, CV_DRIVER, NULL);
1300 mutex_init(&mpt->m_doneq_mutex, NULL, MUTEX_DRIVER, NULL);
1301
1302 mutex_enter(&mpt->m_doneq_mutex);
1303 mpt->m_doneq_thread_id =
1304 kmem_zalloc(sizeof (mptsas_doneq_thread_list_t)
1305 * mpt->m_doneq_thread_n, KM_SLEEP);
1306
1307 for (j = 0; j < mpt->m_doneq_thread_n; j++) {
1308 cv_init(&mpt->m_doneq_thread_id[j].cv, NULL,
1309 CV_DRIVER, NULL);
1310 mutex_init(&mpt->m_doneq_thread_id[j].mutex, NULL,
1311 MUTEX_DRIVER, NULL);
1312 mutex_enter(&mpt->m_doneq_thread_id[j].mutex);
1313 mpt->m_doneq_thread_id[j].flag |=
1314 MPTSAS_DONEQ_THREAD_ACTIVE;
1315 mpt->m_doneq_thread_id[j].arg.mpt = mpt;
1316 mpt->m_doneq_thread_id[j].arg.t = j;
1317 mpt->m_doneq_thread_id[j].threadp =
1318 thread_create(NULL, 0, mptsas_doneq_thread,
1319 &mpt->m_doneq_thread_id[j].arg,
1320 0, &p0, TS_RUN, minclsyspri);
1321 mpt->m_doneq_thread_id[j].donetail =
1322 &mpt->m_doneq_thread_id[j].doneq;
1323 mutex_exit(&mpt->m_doneq_thread_id[j].mutex);
1324 }
1325 mutex_exit(&mpt->m_doneq_mutex);
1326 doneq_thread_create++;
1327 }
1328
1329 /*
1330 * Disable hardware interrupt since we're not ready to
1331 * handle it yet.
1332 */
1333 MPTSAS_DISABLE_INTR(mpt);
1334 if (mptsas_register_intrs(mpt) == FALSE)
1335 goto fail;
1336 intr_added++;
1337
1338 /* Initialize mutex used in interrupt handler */
1339 mutex_init(&mpt->m_mutex, NULL, MUTEX_DRIVER,
1340 DDI_INTR_PRI(mpt->m_intr_pri));
1341 mutex_init(&mpt->m_passthru_mutex, NULL, MUTEX_DRIVER, NULL);
1342 mutex_init(&mpt->m_tx_waitq_mutex, NULL, MUTEX_DRIVER,
1343 DDI_INTR_PRI(mpt->m_intr_pri));
1344 for (i = 0; i < MPTSAS_MAX_PHYS; i++) {
1345 mutex_init(&mpt->m_phy_info[i].smhba_info.phy_mutex,
1346 NULL, MUTEX_DRIVER,
1347 DDI_INTR_PRI(mpt->m_intr_pri));
1348 }
1349
1350 cv_init(&mpt->m_cv, NULL, CV_DRIVER, NULL);
1351 cv_init(&mpt->m_passthru_cv, NULL, CV_DRIVER, NULL);
1352 cv_init(&mpt->m_fw_cv, NULL, CV_DRIVER, NULL);
1353 cv_init(&mpt->m_config_cv, NULL, CV_DRIVER, NULL);
1354 cv_init(&mpt->m_fw_diag_cv, NULL, CV_DRIVER, NULL);
1355 mutex_init_done++;
1356
1357 mutex_enter(&mpt->m_mutex);
1358 /*
1359 * Initialize power management component
1360 */
1361 if (mpt->m_options & MPTSAS_OPT_PM) {
1362 if (mptsas_init_pm(mpt)) {
1363 mutex_exit(&mpt->m_mutex);
1364 mptsas_log(mpt, CE_WARN, "mptsas pm initialization "
1365 "failed");
1366 goto fail;
1367 }
1368 }
1369
1370 /*
1371 * Initialize chip using Message Unit Reset, if allowed
1372 */
1373 mpt->m_softstate |= MPTSAS_SS_MSG_UNIT_RESET;
1374 if (mptsas_init_chip(mpt, TRUE) == DDI_FAILURE) {
1375 mutex_exit(&mpt->m_mutex);
1376 mptsas_log(mpt, CE_WARN, "mptsas chip initialization failed");
1377 goto fail;
1378 }
1379
1380 mpt->m_targets = refhash_create(MPTSAS_TARGET_BUCKET_COUNT,
1381 mptsas_target_addr_hash, mptsas_target_addr_cmp,
1382 mptsas_target_free, sizeof (mptsas_target_t),
1383 offsetof(mptsas_target_t, m_link),
1384 offsetof(mptsas_target_t, m_addr), KM_SLEEP);
1385
1386 /*
1387 * The refhash for temporary targets uses the address of the target
1388 * struct itself as tag, so the tag offset is 0. See the implementation
1389 * of mptsas_tmp_target_hash() and mptsas_tmp_target_cmp().
1390 */
1391 mpt->m_tmp_targets = refhash_create(MPTSAS_TMP_TARGET_BUCKET_COUNT,
1392 mptsas_tmp_target_hash, mptsas_tmp_target_cmp,
1393 mptsas_target_free, sizeof (mptsas_target_t),
1394 offsetof(mptsas_target_t, m_link), 0, KM_SLEEP);
1395
1396 /*
1397 * Fill in the phy_info structure and get the base WWID
1398 */
1399 if (mptsas_get_manufacture_page5(mpt) == DDI_FAILURE) {
1400 mptsas_log(mpt, CE_WARN,
1401 "mptsas_get_manufacture_page5 failed!");
1402 goto fail;
1403 }
1404
1405 if (mptsas_get_sas_io_unit_page_hndshk(mpt)) {
1406 mptsas_log(mpt, CE_WARN,
1407 "mptsas_get_sas_io_unit_page_hndshk failed!");
1408 goto fail;
1409 }
1410
1411 if (mptsas_get_manufacture_page0(mpt) == DDI_FAILURE) {
1412 mptsas_log(mpt, CE_WARN,
1413 "mptsas_get_manufacture_page0 failed!");
1414 goto fail;
1415 }
1416
1417 mutex_exit(&mpt->m_mutex);
1418
1419 /*
1420 * Register the iport for multiple port HBA
1421 */
1422 mptsas_iport_register(mpt);
1423
1424 /*
1425 * initialize SCSI HBA transport structure
1426 */
1427 if (mptsas_hba_setup(mpt) == FALSE)
1428 goto fail;
1429 hba_attach_setup++;
1430
1431 if (mptsas_smp_setup(mpt) == FALSE)
1432 goto fail;
1433 smp_attach_setup++;
1434
1435 if (mptsas_cache_create(mpt) == FALSE)
1436 goto fail;
1437
1438 mpt->m_scsi_reset_delay = ddi_prop_get_int(DDI_DEV_T_ANY,
1439 dip, 0, "scsi-reset-delay", SCSI_DEFAULT_RESET_DELAY);
1440 if (mpt->m_scsi_reset_delay == 0) {
1441 mptsas_log(mpt, CE_NOTE,
1442 "scsi_reset_delay of 0 is not recommended,"
1443 " resetting to SCSI_DEFAULT_RESET_DELAY\n");
1444 mpt->m_scsi_reset_delay = SCSI_DEFAULT_RESET_DELAY;
1445 }
1446
1447 /*
1448 * Initialize the wait and done FIFO queue
1449 */
1450 mpt->m_donetail = &mpt->m_doneq;
1451 mpt->m_waitqtail = &mpt->m_waitq;
1452 mpt->m_tx_waitqtail = &mpt->m_tx_waitq;
1453 mpt->m_tx_draining = 0;
1454
1455 /*
1456 * ioc cmd queue initialize
1457 */
1458 mpt->m_ioc_event_cmdtail = &mpt->m_ioc_event_cmdq;
1459 mpt->m_dev_handle = 0xFFFF;
1460
1461 MPTSAS_ENABLE_INTR(mpt);
1462
1463 /*
1464 * enable event notification
1465 */
1466 mutex_enter(&mpt->m_mutex);
1467 if (mptsas_ioc_enable_event_notification(mpt)) {
1468 mutex_exit(&mpt->m_mutex);
1469 goto fail;
1470 }
1471 mutex_exit(&mpt->m_mutex);
1472
1473 /*
1474 * used for mptsas_watch
1475 */
1476 mptsas_list_add(mpt);
1477
1478 mutex_enter(&mptsas_global_mutex);
1479 if (mptsas_timeouts_enabled == 0) {
1480 mptsas_scsi_watchdog_tick = ddi_prop_get_int(DDI_DEV_T_ANY,
1481 dip, 0, "scsi-watchdog-tick", DEFAULT_WD_TICK);
1482
1483 mptsas_tick = mptsas_scsi_watchdog_tick *
1484 drv_usectohz((clock_t)1000000);
1485
1486 mptsas_timeout_id = timeout(mptsas_watch, NULL, mptsas_tick);
1487 mptsas_timeouts_enabled = 1;
1488 }
1489 mutex_exit(&mptsas_global_mutex);
1490 added_watchdog++;
1491
1492 /*
1493 * Initialize PHY info for smhba.
1494 * This requires watchdog to be enabled otherwise if interrupts
1495 * don't work the system will hang.
1496 */
1497 if (mptsas_smhba_setup(mpt)) {
1498 mptsas_log(mpt, CE_WARN, "mptsas phy initialization "
1499 "failed");
1500 goto fail;
1501 }
1502
1503 /* Check all dma handles allocated in attach */
1504 if ((mptsas_check_dma_handle(mpt->m_dma_req_frame_hdl)
1505 != DDI_SUCCESS) ||
1506 (mptsas_check_dma_handle(mpt->m_dma_req_sense_hdl)
1507 != DDI_SUCCESS) ||
1508 (mptsas_check_dma_handle(mpt->m_dma_reply_frame_hdl)
1509 != DDI_SUCCESS) ||
1510 (mptsas_check_dma_handle(mpt->m_dma_free_queue_hdl)
1511 != DDI_SUCCESS) ||
1512 (mptsas_check_dma_handle(mpt->m_dma_post_queue_hdl)
1513 != DDI_SUCCESS) ||
1514 (mptsas_check_dma_handle(mpt->m_hshk_dma_hdl)
1515 != DDI_SUCCESS)) {
1516 goto fail;
1517 }
1518
1519 /* Check all acc handles allocated in attach */
1520 if ((mptsas_check_acc_handle(mpt->m_datap) != DDI_SUCCESS) ||
1521 (mptsas_check_acc_handle(mpt->m_acc_req_frame_hdl)
1522 != DDI_SUCCESS) ||
1523 (mptsas_check_acc_handle(mpt->m_acc_req_sense_hdl)
1524 != DDI_SUCCESS) ||
1525 (mptsas_check_acc_handle(mpt->m_acc_reply_frame_hdl)
1526 != DDI_SUCCESS) ||
1527 (mptsas_check_acc_handle(mpt->m_acc_free_queue_hdl)
1528 != DDI_SUCCESS) ||
1529 (mptsas_check_acc_handle(mpt->m_acc_post_queue_hdl)
1530 != DDI_SUCCESS) ||
1531 (mptsas_check_acc_handle(mpt->m_hshk_acc_hdl)
1532 != DDI_SUCCESS) ||
1533 (mptsas_check_acc_handle(mpt->m_config_handle)
1534 != DDI_SUCCESS)) {
1535 goto fail;
1536 }
1537
1538 /*
1539 * After this point, we are not going to fail the attach.
1540 */
1541
1542 /* Print message of HBA present */
1543 ddi_report_dev(dip);
1544
1545 /* report idle status to pm framework */
1546 if (mpt->m_options & MPTSAS_OPT_PM) {
1547 (void) pm_idle_component(dip, 0);
1548 }
1549
1550 return (DDI_SUCCESS);
1551
1552 fail:
1553 mptsas_log(mpt, CE_WARN, "attach failed");
1554 mptsas_fm_ereport(mpt, DDI_FM_DEVICE_NO_RESPONSE);
1555 ddi_fm_service_impact(mpt->m_dip, DDI_SERVICE_LOST);
1556 if (mpt) {
1557 /* deallocate in reverse order */
1558 if (added_watchdog) {
1559 mptsas_list_del(mpt);
1560 mutex_enter(&mptsas_global_mutex);
1561
1562 if (mptsas_timeout_id && (mptsas_head == NULL)) {
1563 timeout_id_t tid = mptsas_timeout_id;
1564 mptsas_timeouts_enabled = 0;
1565 mptsas_timeout_id = 0;
1566 mutex_exit(&mptsas_global_mutex);
1567 (void) untimeout(tid);
1568 mutex_enter(&mptsas_global_mutex);
1569 }
1570 mutex_exit(&mptsas_global_mutex);
1571 }
1572
1573 mptsas_cache_destroy(mpt);
1574
1575 if (smp_attach_setup) {
1576 mptsas_smp_teardown(mpt);
1577 }
1578 if (hba_attach_setup) {
1579 mptsas_hba_teardown(mpt);
1580 }
1581
1582 if (mpt->m_tmp_targets)
1583 refhash_destroy(mpt->m_tmp_targets);
1584 if (mpt->m_targets)
1585 refhash_destroy(mpt->m_targets);
1586 if (mpt->m_smp_targets)
1587 refhash_destroy(mpt->m_smp_targets);
1588
1589 if (mpt->m_active) {
1590 mptsas_free_active_slots(mpt);
1591 }
1592 if (intr_added) {
1593 mptsas_unregister_intrs(mpt);
1594 }
1595
1596 if (doneq_thread_create) {
1597 mutex_enter(&mpt->m_doneq_mutex);
1598 doneq_thread_num = mpt->m_doneq_thread_n;
1599 for (j = 0; j < mpt->m_doneq_thread_n; j++) {
1600 mutex_enter(&mpt->m_doneq_thread_id[j].mutex);
1601 mpt->m_doneq_thread_id[j].flag &=
1602 (~MPTSAS_DONEQ_THREAD_ACTIVE);
1603 cv_signal(&mpt->m_doneq_thread_id[j].cv);
1604 mutex_exit(&mpt->m_doneq_thread_id[j].mutex);
1605 }
1606 while (mpt->m_doneq_thread_n) {
1607 cv_wait(&mpt->m_doneq_thread_cv,
1608 &mpt->m_doneq_mutex);
1609 }
1610 for (j = 0; j < doneq_thread_num; j++) {
1611 cv_destroy(&mpt->m_doneq_thread_id[j].cv);
1612 mutex_destroy(&mpt->m_doneq_thread_id[j].mutex);
1613 }
1614 kmem_free(mpt->m_doneq_thread_id,
1615 sizeof (mptsas_doneq_thread_list_t)
1616 * doneq_thread_num);
1617 mutex_exit(&mpt->m_doneq_mutex);
1618 cv_destroy(&mpt->m_doneq_thread_cv);
1619 mutex_destroy(&mpt->m_doneq_mutex);
1620 }
1621 if (event_taskq_create) {
1622 ddi_taskq_destroy(mpt->m_event_taskq);
1623 }
1624 if (dr_taskq_create) {
1625 ddi_taskq_destroy(mpt->m_dr_taskq);
1626 }
1627 if (mutex_init_done) {
1628 mutex_destroy(&mpt->m_tx_waitq_mutex);
1629 mutex_destroy(&mpt->m_passthru_mutex);
1630 mutex_destroy(&mpt->m_mutex);
1631 for (i = 0; i < MPTSAS_MAX_PHYS; i++) {
1632 mutex_destroy(
1633 &mpt->m_phy_info[i].smhba_info.phy_mutex);
1634 }
1635 cv_destroy(&mpt->m_cv);
1636 cv_destroy(&mpt->m_passthru_cv);
1637 cv_destroy(&mpt->m_fw_cv);
1638 cv_destroy(&mpt->m_config_cv);
1639 cv_destroy(&mpt->m_fw_diag_cv);
1640 }
1641
1642 if (map_setup) {
1643 mptsas_cfg_fini(mpt);
1644 }
1645 if (config_setup) {
1646 mptsas_config_space_fini(mpt);
1647 }
1648 mptsas_free_handshake_msg(mpt);
1649 mptsas_hba_fini(mpt);
1650
1651 mptsas_fm_fini(mpt);
1652 ddi_soft_state_free(mptsas_state, instance);
1653 ddi_prop_remove_all(dip);
1654 }
1655 return (DDI_FAILURE);
1656 }
1657
1658 static int
1659 mptsas_suspend(dev_info_t *devi)
1660 {
1661 mptsas_t *mpt, *g;
1662 scsi_hba_tran_t *tran;
1663
1664 if (scsi_hba_iport_unit_address(devi)) {
1665 return (DDI_SUCCESS);
1666 }
1667
1668 if ((tran = ddi_get_driver_private(devi)) == NULL)
1669 return (DDI_SUCCESS);
1670
1671 mpt = TRAN2MPT(tran);
1672 if (!mpt) {
1673 return (DDI_SUCCESS);
1674 }
1675
1676 mutex_enter(&mpt->m_mutex);
1677
1678 if (mpt->m_suspended++) {
1679 mutex_exit(&mpt->m_mutex);
1680 return (DDI_SUCCESS);
1681 }
1682
1683 /*
1684 * Cancel timeout threads for this mpt
1685 */
1686 if (mpt->m_quiesce_timeid) {
1687 timeout_id_t tid = mpt->m_quiesce_timeid;
1688 mpt->m_quiesce_timeid = 0;
1689 mutex_exit(&mpt->m_mutex);
1690 (void) untimeout(tid);
1691 mutex_enter(&mpt->m_mutex);
1692 }
1693
1694 if (mpt->m_restart_cmd_timeid) {
1695 timeout_id_t tid = mpt->m_restart_cmd_timeid;
1696 mpt->m_restart_cmd_timeid = 0;
1697 mutex_exit(&mpt->m_mutex);
1698 (void) untimeout(tid);
1699 mutex_enter(&mpt->m_mutex);
1700 }
1701
1702 mutex_exit(&mpt->m_mutex);
1703
1704 (void) pm_idle_component(mpt->m_dip, 0);
1705
1706 /*
1707 * Cancel watch threads if all mpts suspended
1708 */
1709 rw_enter(&mptsas_global_rwlock, RW_WRITER);
1710 for (g = mptsas_head; g != NULL; g = g->m_next) {
1711 if (!g->m_suspended)
1712 break;
1713 }
1714 rw_exit(&mptsas_global_rwlock);
1715
1716 mutex_enter(&mptsas_global_mutex);
1717 if (g == NULL) {
1718 timeout_id_t tid;
1719
1720 mptsas_timeouts_enabled = 0;
1721 if (mptsas_timeout_id) {
1722 tid = mptsas_timeout_id;
1723 mptsas_timeout_id = 0;
1724 mutex_exit(&mptsas_global_mutex);
1725 (void) untimeout(tid);
1726 mutex_enter(&mptsas_global_mutex);
1727 }
1728 if (mptsas_reset_watch) {
1729 tid = mptsas_reset_watch;
1730 mptsas_reset_watch = 0;
1731 mutex_exit(&mptsas_global_mutex);
1732 (void) untimeout(tid);
1733 mutex_enter(&mptsas_global_mutex);
1734 }
1735 }
1736 mutex_exit(&mptsas_global_mutex);
1737
1738 mutex_enter(&mpt->m_mutex);
1739
1740 /*
1741 * If this mpt is not in full power(PM_LEVEL_D0), just return.
1742 */
1743 if ((mpt->m_options & MPTSAS_OPT_PM) &&
1744 (mpt->m_power_level != PM_LEVEL_D0)) {
1745 mutex_exit(&mpt->m_mutex);
1746 return (DDI_SUCCESS);
1747 }
1748
1749 /* Disable HBA interrupts in hardware */
1750 MPTSAS_DISABLE_INTR(mpt);
1751 /*
1752 * Send RAID action system shutdown to sync IR
1753 */
1754 mptsas_raid_action_system_shutdown(mpt);
1755
1756 mutex_exit(&mpt->m_mutex);
1757
1758 /* drain the taskq */
1759 ddi_taskq_wait(mpt->m_event_taskq);
1760 ddi_taskq_wait(mpt->m_dr_taskq);
1761
1762 return (DDI_SUCCESS);
1763 }
1764
1765 #ifdef __sparc
1766 /*ARGSUSED*/
1767 static int
1768 mptsas_reset(dev_info_t *devi, ddi_reset_cmd_t cmd)
1769 {
1770 mptsas_t *mpt;
1771 scsi_hba_tran_t *tran;
1772
1773 /*
1774 * If this call is for iport, just return.
1775 */
1776 if (scsi_hba_iport_unit_address(devi))
1777 return (DDI_SUCCESS);
1778
1779 if ((tran = ddi_get_driver_private(devi)) == NULL)
1780 return (DDI_SUCCESS);
1781
1782 if ((mpt = TRAN2MPT(tran)) == NULL)
1783 return (DDI_SUCCESS);
1784
1785 /*
1786 * Send RAID action system shutdown to sync IR. Disable HBA
1787 * interrupts in hardware first.
1788 */
1789 MPTSAS_DISABLE_INTR(mpt);
1790 mptsas_raid_action_system_shutdown(mpt);
1791
1792 return (DDI_SUCCESS);
1793 }
1794 #else /* __sparc */
1795 /*
1796 * quiesce(9E) entry point.
1797 *
1798 * This function is called when the system is single-threaded at high
1799 * PIL with preemption disabled. Therefore, this function must not be
1800 * blocked.
1801 *
1802 * This function returns DDI_SUCCESS on success, or DDI_FAILURE on failure.
1803 * DDI_FAILURE indicates an error condition and should almost never happen.
1804 */
1805 static int
1806 mptsas_quiesce(dev_info_t *devi)
1807 {
1808 mptsas_t *mpt;
1809 scsi_hba_tran_t *tran;
1810
1811 /*
1812 * If this call is for iport, just return.
1813 */
1814 if (scsi_hba_iport_unit_address(devi))
1815 return (DDI_SUCCESS);
1816
1817 if ((tran = ddi_get_driver_private(devi)) == NULL)
1818 return (DDI_SUCCESS);
1819
1820 if ((mpt = TRAN2MPT(tran)) == NULL)
1821 return (DDI_SUCCESS);
1822
1823 /* Disable HBA interrupts in hardware */
1824 MPTSAS_DISABLE_INTR(mpt);
1825 /* Send RAID action system shutdonw to sync IR */
1826 mptsas_raid_action_system_shutdown(mpt);
1827
1828 return (DDI_SUCCESS);
1829 }
1830 #endif /* __sparc */
1831
1832 /*
1833 * detach(9E). Remove all device allocations and system resources;
1834 * disable device interrupts.
1835 * Return DDI_SUCCESS if done; DDI_FAILURE if there's a problem.
1836 */
1837 static int
1838 mptsas_detach(dev_info_t *devi, ddi_detach_cmd_t cmd)
1839 {
1840 /* CONSTCOND */
1841 ASSERT(NO_COMPETING_THREADS);
1842 NDBG0(("mptsas_detach: dip=0x%p cmd=0x%p", (void *)devi, (void *)cmd));
1843
1844 switch (cmd) {
1845 case DDI_DETACH:
1846 return (mptsas_do_detach(devi));
1847
1848 case DDI_SUSPEND:
1849 return (mptsas_suspend(devi));
1850
1851 default:
1852 return (DDI_FAILURE);
1853 }
1854 /* NOTREACHED */
1855 }
1856
1857 static int
1858 mptsas_do_detach(dev_info_t *dip)
1859 {
1860 mptsas_t *mpt;
1861 scsi_hba_tran_t *tran;
1862 int circ = 0;
1863 int circ1 = 0;
1864 mdi_pathinfo_t *pip = NULL;
1865 int i;
1866 int doneq_thread_num = 0;
1867
1868 NDBG0(("mptsas_do_detach: dip=0x%p", (void *)dip));
1869
1870 if ((tran = ndi_flavorv_get(dip, SCSA_FLAVOR_SCSI_DEVICE)) == NULL)
1871 return (DDI_FAILURE);
1872
1873 mpt = TRAN2MPT(tran);
1874 if (!mpt) {
1875 return (DDI_FAILURE);
1876 }
1877 /*
1878 * Still have pathinfo child, should not detach mpt driver
1879 */
1880 if (scsi_hba_iport_unit_address(dip)) {
1881 if (mpt->m_mpxio_enable) {
1882 /*
1883 * MPxIO enabled for the iport
1884 */
1885 ndi_devi_enter(scsi_vhci_dip, &circ1);
1886 ndi_devi_enter(dip, &circ);
1887 while (pip = mdi_get_next_client_path(dip, NULL)) {
1888 if (mdi_pi_free(pip, 0) == MDI_SUCCESS) {
1889 continue;
1890 }
1891 ndi_devi_exit(dip, circ);
1892 ndi_devi_exit(scsi_vhci_dip, circ1);
1893 NDBG12(("detach failed because of "
1894 "outstanding path info"));
1895 return (DDI_FAILURE);
1896 }
1897 ndi_devi_exit(dip, circ);
1898 ndi_devi_exit(scsi_vhci_dip, circ1);
1899 (void) mdi_phci_unregister(dip, 0);
1900 }
1901
1902 ddi_prop_remove_all(dip);
1903
1904 return (DDI_SUCCESS);
1905 }
1906
1907 /* Make sure power level is D0 before accessing registers */
1908 if (mpt->m_options & MPTSAS_OPT_PM) {
1909 (void) pm_busy_component(dip, 0);
1910 if (mpt->m_power_level != PM_LEVEL_D0) {
1911 if (pm_raise_power(dip, 0, PM_LEVEL_D0) !=
1912 DDI_SUCCESS) {
1913 mptsas_log(mpt, CE_WARN,
1914 "mptsas%d: Raise power request failed.",
1915 mpt->m_instance);
1916 (void) pm_idle_component(dip, 0);
1917 return (DDI_FAILURE);
1918 }
1919 }
1920 }
1921
1922 /*
1923 * Send RAID action system shutdown to sync IR. After action, send a
1924 * Message Unit Reset. Since after that DMA resource will be freed,
1925 * set ioc to READY state will avoid HBA initiated DMA operation.
1926 */
1927 mutex_enter(&mpt->m_mutex);
1928 MPTSAS_DISABLE_INTR(mpt);
1929 mptsas_raid_action_system_shutdown(mpt);
1930 mpt->m_softstate |= MPTSAS_SS_MSG_UNIT_RESET;
1931 (void) mptsas_ioc_reset(mpt, FALSE);
1932 mutex_exit(&mpt->m_mutex);
1933 mptsas_rem_intrs(mpt);
1934 ddi_taskq_destroy(mpt->m_event_taskq);
1935 ddi_taskq_destroy(mpt->m_dr_taskq);
1936
1937 if (mpt->m_doneq_thread_n) {
1938 mutex_enter(&mpt->m_doneq_mutex);
1939 doneq_thread_num = mpt->m_doneq_thread_n;
1940 for (i = 0; i < mpt->m_doneq_thread_n; i++) {
1941 mutex_enter(&mpt->m_doneq_thread_id[i].mutex);
1942 mpt->m_doneq_thread_id[i].flag &=
1943 (~MPTSAS_DONEQ_THREAD_ACTIVE);
1944 cv_signal(&mpt->m_doneq_thread_id[i].cv);
1945 mutex_exit(&mpt->m_doneq_thread_id[i].mutex);
1946 }
1947 while (mpt->m_doneq_thread_n) {
1948 cv_wait(&mpt->m_doneq_thread_cv,
1949 &mpt->m_doneq_mutex);
1950 }
1951 for (i = 0; i < doneq_thread_num; i++) {
1952 cv_destroy(&mpt->m_doneq_thread_id[i].cv);
1953 mutex_destroy(&mpt->m_doneq_thread_id[i].mutex);
1954 }
1955 kmem_free(mpt->m_doneq_thread_id,
1956 sizeof (mptsas_doneq_thread_list_t)
1957 * doneq_thread_num);
1958 mutex_exit(&mpt->m_doneq_mutex);
1959 cv_destroy(&mpt->m_doneq_thread_cv);
1960 mutex_destroy(&mpt->m_doneq_mutex);
1961 }
1962
1963 scsi_hba_reset_notify_tear_down(mpt->m_reset_notify_listf);
1964
1965 mptsas_list_del(mpt);
1966
1967 /*
1968 * Cancel timeout threads for this mpt
1969 */
1970 mutex_enter(&mpt->m_mutex);
1971 if (mpt->m_quiesce_timeid) {
1972 timeout_id_t tid = mpt->m_quiesce_timeid;
1973 mpt->m_quiesce_timeid = 0;
1974 mutex_exit(&mpt->m_mutex);
1975 (void) untimeout(tid);
1976 mutex_enter(&mpt->m_mutex);
1977 }
1978
1979 if (mpt->m_restart_cmd_timeid) {
1980 timeout_id_t tid = mpt->m_restart_cmd_timeid;
1981 mpt->m_restart_cmd_timeid = 0;
1982 mutex_exit(&mpt->m_mutex);
1983 (void) untimeout(tid);
1984 mutex_enter(&mpt->m_mutex);
1985 }
1986
1987 mutex_exit(&mpt->m_mutex);
1988
1989 /*
1990 * last mpt? ... if active, CANCEL watch threads.
1991 */
1992 mutex_enter(&mptsas_global_mutex);
1993 if (mptsas_head == NULL) {
1994 timeout_id_t tid;
1995 /*
1996 * Clear mptsas_timeouts_enable so that the watch thread
1997 * gets restarted on DDI_ATTACH
1998 */
1999 mptsas_timeouts_enabled = 0;
2000 if (mptsas_timeout_id) {
2001 tid = mptsas_timeout_id;
2002 mptsas_timeout_id = 0;
2003 mutex_exit(&mptsas_global_mutex);
2004 (void) untimeout(tid);
2005 mutex_enter(&mptsas_global_mutex);
2006 }
2007 if (mptsas_reset_watch) {
2008 tid = mptsas_reset_watch;
2009 mptsas_reset_watch = 0;
2010 mutex_exit(&mptsas_global_mutex);
2011 (void) untimeout(tid);
2012 mutex_enter(&mptsas_global_mutex);
2013 }
2014 }
2015 mutex_exit(&mptsas_global_mutex);
2016
2017 /*
2018 * Delete Phy stats
2019 */
2020 mptsas_destroy_phy_stats(mpt);
2021
2022 mptsas_destroy_hashes(mpt);
2023
2024 /*
2025 * Delete nt_active.
2026 */
2027 mutex_enter(&mpt->m_mutex);
2028 mptsas_free_active_slots(mpt);
2029 mutex_exit(&mpt->m_mutex);
2030
2031 /* deallocate everything that was allocated in mptsas_attach */
2032 mptsas_cache_destroy(mpt);
2033
2034 mptsas_hba_fini(mpt);
2035 mptsas_cfg_fini(mpt);
2036
2037 /* Lower the power informing PM Framework */
2038 if (mpt->m_options & MPTSAS_OPT_PM) {
2039 if (pm_lower_power(dip, 0, PM_LEVEL_D3) != DDI_SUCCESS)
2040 mptsas_log(mpt, CE_WARN,
2041 "!mptsas%d: Lower power request failed "
2042 "during detach, ignoring.",
2043 mpt->m_instance);
2044 }
2045
2046 mutex_destroy(&mpt->m_tx_waitq_mutex);
2047 mutex_destroy(&mpt->m_passthru_mutex);
2048 mutex_destroy(&mpt->m_mutex);
2049 for (i = 0; i < MPTSAS_MAX_PHYS; i++) {
2050 mutex_destroy(&mpt->m_phy_info[i].smhba_info.phy_mutex);
2051 }
2052 cv_destroy(&mpt->m_cv);
2053 cv_destroy(&mpt->m_passthru_cv);
2054 cv_destroy(&mpt->m_fw_cv);
2055 cv_destroy(&mpt->m_config_cv);
2056 cv_destroy(&mpt->m_fw_diag_cv);
2057
2058
2059 mptsas_smp_teardown(mpt);
2060 mptsas_hba_teardown(mpt);
2061
2062 mptsas_config_space_fini(mpt);
2063
2064 mptsas_free_handshake_msg(mpt);
2065
2066 mptsas_fm_fini(mpt);
2067 ddi_soft_state_free(mptsas_state, ddi_get_instance(dip));
2068 ddi_prop_remove_all(dip);
2069
2070 return (DDI_SUCCESS);
2071 }
2072
2073 static void
2074 mptsas_list_add(mptsas_t *mpt)
2075 {
2076 rw_enter(&mptsas_global_rwlock, RW_WRITER);
2077
2078 if (mptsas_head == NULL) {
2079 mptsas_head = mpt;
2080 } else {
2081 mptsas_tail->m_next = mpt;
2082 }
2083 mptsas_tail = mpt;
2084 rw_exit(&mptsas_global_rwlock);
2085 }
2086
2087 static void
2088 mptsas_list_del(mptsas_t *mpt)
2089 {
2090 mptsas_t *m;
2091 /*
2092 * Remove device instance from the global linked list
2093 */
2094 rw_enter(&mptsas_global_rwlock, RW_WRITER);
2095 if (mptsas_head == mpt) {
2096 m = mptsas_head = mpt->m_next;
2097 } else {
2098 for (m = mptsas_head; m != NULL; m = m->m_next) {
2099 if (m->m_next == mpt) {
2100 m->m_next = mpt->m_next;
2101 break;
2102 }
2103 }
2104 if (m == NULL) {
2105 mptsas_log(mpt, CE_PANIC, "Not in softc list!");
2106 }
2107 }
2108
2109 if (mptsas_tail == mpt) {
2110 mptsas_tail = m;
2111 }
2112 rw_exit(&mptsas_global_rwlock);
2113 }
2114
2115 static int
2116 mptsas_alloc_handshake_msg(mptsas_t *mpt, size_t alloc_size)
2117 {
2118 ddi_dma_attr_t task_dma_attrs;
2119
2120 mpt->m_hshk_dma_size = 0;
2121 task_dma_attrs = mpt->m_msg_dma_attr;
2122 task_dma_attrs.dma_attr_sgllen = 1;
2123 task_dma_attrs.dma_attr_granular = (uint32_t)(alloc_size);
2124
2125 /* allocate Task Management ddi_dma resources */
2126 if (mptsas_dma_addr_create(mpt, task_dma_attrs,
2127 &mpt->m_hshk_dma_hdl, &mpt->m_hshk_acc_hdl, &mpt->m_hshk_memp,
2128 alloc_size, NULL) == FALSE) {
2129 return (DDI_FAILURE);
2130 }
2131 mpt->m_hshk_dma_size = alloc_size;
2132
2133 return (DDI_SUCCESS);
2134 }
2135
2136 static void
2137 mptsas_free_handshake_msg(mptsas_t *mpt)
2138 {
2139 if (mpt->m_hshk_dma_size == 0)
2140 return;
2141 mptsas_dma_addr_destroy(&mpt->m_hshk_dma_hdl, &mpt->m_hshk_acc_hdl);
2142 mpt->m_hshk_dma_size = 0;
2143 }
2144
2145 static int
2146 mptsas_hba_setup(mptsas_t *mpt)
2147 {
2148 scsi_hba_tran_t *hba_tran;
2149 int tran_flags;
2150
2151 /* Allocate a transport structure */
2152 hba_tran = mpt->m_tran = scsi_hba_tran_alloc(mpt->m_dip,
2153 SCSI_HBA_CANSLEEP);
2154 ASSERT(mpt->m_tran != NULL);
2155
2156 hba_tran->tran_hba_private = mpt;
2157 hba_tran->tran_tgt_private = NULL;
2158
2159 hba_tran->tran_tgt_init = mptsas_scsi_tgt_init;
2160 hba_tran->tran_tgt_free = mptsas_scsi_tgt_free;
2161
2162 hba_tran->tran_start = mptsas_scsi_start;
2163 hba_tran->tran_reset = mptsas_scsi_reset;
2164 hba_tran->tran_abort = mptsas_scsi_abort;
2165 hba_tran->tran_getcap = mptsas_scsi_getcap;
2166 hba_tran->tran_setcap = mptsas_scsi_setcap;
2167 hba_tran->tran_init_pkt = mptsas_scsi_init_pkt;
2168 hba_tran->tran_destroy_pkt = mptsas_scsi_destroy_pkt;
2169
2170 hba_tran->tran_dmafree = mptsas_scsi_dmafree;
2171 hba_tran->tran_sync_pkt = mptsas_scsi_sync_pkt;
2172 hba_tran->tran_reset_notify = mptsas_scsi_reset_notify;
2173
2174 hba_tran->tran_get_bus_addr = mptsas_get_bus_addr;
2175 hba_tran->tran_get_name = mptsas_get_name;
2176
2177 hba_tran->tran_quiesce = mptsas_scsi_quiesce;
2178 hba_tran->tran_unquiesce = mptsas_scsi_unquiesce;
2179 hba_tran->tran_bus_reset = NULL;
2180
2181 hba_tran->tran_add_eventcall = NULL;
2182 hba_tran->tran_get_eventcookie = NULL;
2183 hba_tran->tran_post_event = NULL;
2184 hba_tran->tran_remove_eventcall = NULL;
2185
2186 hba_tran->tran_bus_config = mptsas_bus_config;
2187
2188 hba_tran->tran_interconnect_type = INTERCONNECT_SAS;
2189
2190 /*
2191 * All children of the HBA are iports. We need tran was cloned.
2192 * So we pass the flags to SCSA. SCSI_HBA_TRAN_CLONE will be
2193 * inherited to iport's tran vector.
2194 */
2195 tran_flags = (SCSI_HBA_HBA | SCSI_HBA_TRAN_CLONE);
2196
2197 if (scsi_hba_attach_setup(mpt->m_dip, &mpt->m_msg_dma_attr,
2198 hba_tran, tran_flags) != DDI_SUCCESS) {
2199 mptsas_log(mpt, CE_WARN, "hba attach setup failed");
2200 scsi_hba_tran_free(hba_tran);
2201 mpt->m_tran = NULL;
2202 return (FALSE);
2203 }
2204 return (TRUE);
2205 }
2206
2207 static void
2208 mptsas_hba_teardown(mptsas_t *mpt)
2209 {
2210 (void) scsi_hba_detach(mpt->m_dip);
2211 if (mpt->m_tran != NULL) {
2212 scsi_hba_tran_free(mpt->m_tran);
2213 mpt->m_tran = NULL;
2214 }
2215 }
2216
2217 static void
2218 mptsas_iport_register(mptsas_t *mpt)
2219 {
2220 int i, j;
2221 mptsas_phymask_t mask = 0x0;
2222 /*
2223 * initial value of mask is 0
2224 */
2225 mutex_enter(&mpt->m_mutex);
2226 for (i = 0; i < mpt->m_num_phys; i++) {
2227 mptsas_phymask_t phy_mask = 0x0;
2228 char phy_mask_name[MPTSAS_MAX_PHYS];
2229 uint8_t current_port;
2230
2231 if (mpt->m_phy_info[i].attached_devhdl == 0)
2232 continue;
2233
2234 bzero(phy_mask_name, sizeof (phy_mask_name));
2235
2236 current_port = mpt->m_phy_info[i].port_num;
2237
2238 if ((mask & (1 << i)) != 0)
2239 continue;
2240
2241 for (j = 0; j < mpt->m_num_phys; j++) {
2242 if (mpt->m_phy_info[j].attached_devhdl &&
2243 (mpt->m_phy_info[j].port_num == current_port)) {
2244 phy_mask |= (1 << j);
2245 }
2246 }
2247 mask = mask | phy_mask;
2248
2249 for (j = 0; j < mpt->m_num_phys; j++) {
2250 if ((phy_mask >> j) & 0x01) {
2251 mpt->m_phy_info[j].phy_mask = phy_mask;
2252 }
2253 }
2254
2255 (void) sprintf(phy_mask_name, "%x", phy_mask);
2256
2257 mutex_exit(&mpt->m_mutex);
2258 /*
2259 * register a iport
2260 */
2261 (void) scsi_hba_iport_register(mpt->m_dip, phy_mask_name);
2262 mutex_enter(&mpt->m_mutex);
2263 }
2264 mutex_exit(&mpt->m_mutex);
2265 /*
2266 * register a virtual port for RAID volume always
2267 */
2268 (void) scsi_hba_iport_register(mpt->m_dip, "v0");
2269
2270 }
2271
2272 static int
2273 mptsas_smp_setup(mptsas_t *mpt)
2274 {
2275 mpt->m_smptran = smp_hba_tran_alloc(mpt->m_dip);
2276 ASSERT(mpt->m_smptran != NULL);
2277 mpt->m_smptran->smp_tran_hba_private = mpt;
2278 mpt->m_smptran->smp_tran_start = mptsas_smp_start;
2279 if (smp_hba_attach_setup(mpt->m_dip, mpt->m_smptran) != DDI_SUCCESS) {
2280 mptsas_log(mpt, CE_WARN, "smp attach setup failed");
2281 smp_hba_tran_free(mpt->m_smptran);
2282 mpt->m_smptran = NULL;
2283 return (FALSE);
2284 }
2285 /*
2286 * Initialize smp hash table
2287 */
2288 mpt->m_smp_targets = refhash_create(MPTSAS_SMP_BUCKET_COUNT,
2289 mptsas_target_addr_hash, mptsas_target_addr_cmp,
2290 mptsas_smp_free, sizeof (mptsas_smp_t),
2291 offsetof(mptsas_smp_t, m_link), offsetof(mptsas_smp_t, m_addr),
2292 KM_SLEEP);
2293 mpt->m_smp_devhdl = 0xFFFF;
2294
2295 return (TRUE);
2296 }
2297
2298 static void
2299 mptsas_smp_teardown(mptsas_t *mpt)
2300 {
2301 (void) smp_hba_detach(mpt->m_dip);
2302 if (mpt->m_smptran != NULL) {
2303 smp_hba_tran_free(mpt->m_smptran);
2304 mpt->m_smptran = NULL;
2305 }
2306 mpt->m_smp_devhdl = 0;
2307 }
2308
2309 static int
2310 mptsas_cache_create(mptsas_t *mpt)
2311 {
2312 int instance = mpt->m_instance;
2313 char buf[64];
2314
2315 /*
2316 * create kmem cache for packets
2317 */
2318 (void) sprintf(buf, "mptsas%d_cache", instance);
2319 mpt->m_kmem_cache = kmem_cache_create(buf,
2320 sizeof (struct mptsas_cmd) + scsi_pkt_size(), 8,
2321 mptsas_kmem_cache_constructor, mptsas_kmem_cache_destructor,
2322 NULL, (void *)mpt, NULL, 0);
2323
2324 if (mpt->m_kmem_cache == NULL) {
2325 mptsas_log(mpt, CE_WARN, "creating kmem cache failed");
2326 return (FALSE);
2327 }
2328
2329 /*
2330 * create kmem cache for extra SGL frames if SGL cannot
2331 * be accomodated into main request frame.
2332 */
2333 (void) sprintf(buf, "mptsas%d_cache_frames", instance);
2334 mpt->m_cache_frames = kmem_cache_create(buf,
2335 sizeof (mptsas_cache_frames_t), 8,
2336 mptsas_cache_frames_constructor, mptsas_cache_frames_destructor,
2337 NULL, (void *)mpt, NULL, 0);
2338
2339 if (mpt->m_cache_frames == NULL) {
2340 mptsas_log(mpt, CE_WARN, "creating cache for frames failed");
2341 return (FALSE);
2342 }
2343
2344 return (TRUE);
2345 }
2346
2347 static void
2348 mptsas_cache_destroy(mptsas_t *mpt)
2349 {
2350 /* deallocate in reverse order */
2351 if (mpt->m_cache_frames) {
2352 kmem_cache_destroy(mpt->m_cache_frames);
2353 mpt->m_cache_frames = NULL;
2354 }
2355 if (mpt->m_kmem_cache) {
2356 kmem_cache_destroy(mpt->m_kmem_cache);
2357 mpt->m_kmem_cache = NULL;
2358 }
2359 }
2360
2361 static int
2362 mptsas_power(dev_info_t *dip, int component, int level)
2363 {
2364 #ifndef __lock_lint
2365 _NOTE(ARGUNUSED(component))
2366 #endif
2367 mptsas_t *mpt;
2368 int rval = DDI_SUCCESS;
2369 int polls = 0;
2370 uint32_t ioc_status;
2371
2372 if (scsi_hba_iport_unit_address(dip) != 0)
2373 return (DDI_SUCCESS);
2374
2375 mpt = ddi_get_soft_state(mptsas_state, ddi_get_instance(dip));
2376 if (mpt == NULL) {
2377 return (DDI_FAILURE);
2378 }
2379
2380 mutex_enter(&mpt->m_mutex);
2381
2382 /*
2383 * If the device is busy, don't lower its power level
2384 */
2385 if (mpt->m_busy && (mpt->m_power_level > level)) {
2386 mutex_exit(&mpt->m_mutex);
2387 return (DDI_FAILURE);
2388 }
2389 switch (level) {
2390 case PM_LEVEL_D0:
2391 NDBG11(("mptsas%d: turning power ON.", mpt->m_instance));
2392 MPTSAS_POWER_ON(mpt);
2393 /*
2394 * Wait up to 30 seconds for IOC to come out of reset.
2395 */
2396 while (((ioc_status = ddi_get32(mpt->m_datap,
2397 &mpt->m_reg->Doorbell)) &
2398 MPI2_IOC_STATE_MASK) == MPI2_IOC_STATE_RESET) {
2399 if (polls++ > 3000) {
2400 break;
2401 }
2402 delay(drv_usectohz(10000));
2403 }
2404 /*
2405 * If IOC is not in operational state, try to hard reset it.
2406 */
2407 if ((ioc_status & MPI2_IOC_STATE_MASK) !=
2408 MPI2_IOC_STATE_OPERATIONAL) {
2409 mpt->m_softstate &= ~MPTSAS_SS_MSG_UNIT_RESET;
2410 if (mptsas_restart_ioc(mpt) == DDI_FAILURE) {
2411 mptsas_log(mpt, CE_WARN,
2412 "mptsas_power: hard reset failed");
2413 mutex_exit(&mpt->m_mutex);
2414 return (DDI_FAILURE);
2415 }
2416 }
2417 mpt->m_power_level = PM_LEVEL_D0;
2418 break;
2419 case PM_LEVEL_D3:
2420 NDBG11(("mptsas%d: turning power OFF.", mpt->m_instance));
2421 MPTSAS_POWER_OFF(mpt);
2422 break;
2423 default:
2424 mptsas_log(mpt, CE_WARN, "mptsas%d: unknown power level <%x>.",
2425 mpt->m_instance, level);
2426 rval = DDI_FAILURE;
2427 break;
2428 }
2429 mutex_exit(&mpt->m_mutex);
2430 return (rval);
2431 }
2432
2433 /*
2434 * Initialize configuration space and figure out which
2435 * chip and revison of the chip the mpt driver is using.
2436 */
2437 static int
2438 mptsas_config_space_init(mptsas_t *mpt)
2439 {
2440 NDBG0(("mptsas_config_space_init"));
2441
2442 if (mpt->m_config_handle != NULL)
2443 return (TRUE);
2444
2445 if (pci_config_setup(mpt->m_dip,
2446 &mpt->m_config_handle) != DDI_SUCCESS) {
2447 mptsas_log(mpt, CE_WARN, "cannot map configuration space.");
2448 return (FALSE);
2449 }
2450
2451 /*
2452 * This is a workaround for a XMITS ASIC bug which does not
2453 * drive the CBE upper bits.
2454 */
2455 if (pci_config_get16(mpt->m_config_handle, PCI_CONF_STAT) &
2456 PCI_STAT_PERROR) {
2457 pci_config_put16(mpt->m_config_handle, PCI_CONF_STAT,
2458 PCI_STAT_PERROR);
2459 }
2460
2461 mptsas_setup_cmd_reg(mpt);
2462
2463 /*
2464 * Get the chip device id:
2465 */
2466 mpt->m_devid = pci_config_get16(mpt->m_config_handle, PCI_CONF_DEVID);
2467
2468 /*
2469 * Save the revision.
2470 */
2471 mpt->m_revid = pci_config_get8(mpt->m_config_handle, PCI_CONF_REVID);
2472
2473 /*
2474 * Save the SubSystem Vendor and Device IDs
2475 */
2476 mpt->m_svid = pci_config_get16(mpt->m_config_handle, PCI_CONF_SUBVENID);
2477 mpt->m_ssid = pci_config_get16(mpt->m_config_handle, PCI_CONF_SUBSYSID);
2478
2479 /*
2480 * Set the latency timer to 0x40 as specified by the upa -> pci
2481 * bridge chip design team. This may be done by the sparc pci
2482 * bus nexus driver, but the driver should make sure the latency
2483 * timer is correct for performance reasons.
2484 */
2485 pci_config_put8(mpt->m_config_handle, PCI_CONF_LATENCY_TIMER,
2486 MPTSAS_LATENCY_TIMER);
2487
2488 (void) mptsas_get_pci_cap(mpt);
2489 return (TRUE);
2490 }
2491
2492 static void
2493 mptsas_config_space_fini(mptsas_t *mpt)
2494 {
2495 if (mpt->m_config_handle != NULL) {
2496 mptsas_disable_bus_master(mpt);
2497 pci_config_teardown(&mpt->m_config_handle);
2498 mpt->m_config_handle = NULL;
2499 }
2500 }
2501
2502 static void
2503 mptsas_setup_cmd_reg(mptsas_t *mpt)
2504 {
2505 ushort_t cmdreg;
2506
2507 /*
2508 * Set the command register to the needed values.
2509 */
2510 cmdreg = pci_config_get16(mpt->m_config_handle, PCI_CONF_COMM);
2511 cmdreg |= (PCI_COMM_ME | PCI_COMM_SERR_ENABLE |
2512 PCI_COMM_PARITY_DETECT | PCI_COMM_MAE);
2513 cmdreg &= ~PCI_COMM_IO;
2514 pci_config_put16(mpt->m_config_handle, PCI_CONF_COMM, cmdreg);
2515 }
2516
2517 static void
2518 mptsas_disable_bus_master(mptsas_t *mpt)
2519 {
2520 ushort_t cmdreg;
2521
2522 /*
2523 * Clear the master enable bit in the PCI command register.
2524 * This prevents any bus mastering activity like DMA.
2525 */
2526 cmdreg = pci_config_get16(mpt->m_config_handle, PCI_CONF_COMM);
2527 cmdreg &= ~PCI_COMM_ME;
2528 pci_config_put16(mpt->m_config_handle, PCI_CONF_COMM, cmdreg);
2529 }
2530
2531 int
2532 mptsas_dma_alloc(mptsas_t *mpt, mptsas_dma_alloc_state_t *dma_statep)
2533 {
2534 ddi_dma_attr_t attrs;
2535
2536 attrs = mpt->m_io_dma_attr;
2537 attrs.dma_attr_sgllen = 1;
2538
2539 ASSERT(dma_statep != NULL);
2540
2541 if (mptsas_dma_addr_create(mpt, attrs, &dma_statep->handle,
2542 &dma_statep->accessp, &dma_statep->memp, dma_statep->size,
2543 &dma_statep->cookie) == FALSE) {
2544 return (DDI_FAILURE);
2545 }
2546
2547 return (DDI_SUCCESS);
2548 }
2549
2550 void
2551 mptsas_dma_free(mptsas_dma_alloc_state_t *dma_statep)
2552 {
2553 ASSERT(dma_statep != NULL);
2554 mptsas_dma_addr_destroy(&dma_statep->handle, &dma_statep->accessp);
2555 dma_statep->size = 0;
2556 }
2557
2558 int
2559 mptsas_do_dma(mptsas_t *mpt, uint32_t size, int var, int (*callback)())
2560 {
2561 ddi_dma_attr_t attrs;
2562 ddi_dma_handle_t dma_handle;
2563 caddr_t memp;
2564 ddi_acc_handle_t accessp;
2565 int rval;
2566
2567 ASSERT(mutex_owned(&mpt->m_mutex));
2568
2569 attrs = mpt->m_msg_dma_attr;
2570 attrs.dma_attr_sgllen = 1;
2571 attrs.dma_attr_granular = size;
2572
2573 if (mptsas_dma_addr_create(mpt, attrs, &dma_handle,
2574 &accessp, &memp, size, NULL) == FALSE) {
2575 return (DDI_FAILURE);
2576 }
2577
2578 rval = (*callback) (mpt, memp, var, accessp);
2579
2580 if ((mptsas_check_dma_handle(dma_handle) != DDI_SUCCESS) ||
2581 (mptsas_check_acc_handle(accessp) != DDI_SUCCESS)) {
2582 ddi_fm_service_impact(mpt->m_dip, DDI_SERVICE_UNAFFECTED);
2583 rval = DDI_FAILURE;
2584 }
2585
2586 mptsas_dma_addr_destroy(&dma_handle, &accessp);
2587 return (rval);
2588
2589 }
2590
2591 static int
2592 mptsas_alloc_request_frames(mptsas_t *mpt)
2593 {
2594 ddi_dma_attr_t frame_dma_attrs;
2595 caddr_t memp;
2596 ddi_dma_cookie_t cookie;
2597 size_t mem_size;
2598
2599 /*
2600 * re-alloc when it has already alloced
2601 */
2602 if (mpt->m_dma_req_frame_hdl)
2603 mptsas_dma_addr_destroy(&mpt->m_dma_req_frame_hdl,
2604 &mpt->m_acc_req_frame_hdl);
2605
2606 /*
2607 * The size of the request frame pool is:
2608 * Number of Request Frames * Request Frame Size
2609 */
2610 mem_size = mpt->m_max_requests * mpt->m_req_frame_size;
2611
2612 /*
2613 * set the DMA attributes. System Request Message Frames must be
2614 * aligned on a 16-byte boundry.
2615 */
2616 frame_dma_attrs = mpt->m_msg_dma_attr;
2617 frame_dma_attrs.dma_attr_align = 16;
2618 frame_dma_attrs.dma_attr_sgllen = 1;
2619
2620 /*
2621 * allocate the request frame pool.
2622 */
2623 if (mptsas_dma_addr_create(mpt, frame_dma_attrs,
2624 &mpt->m_dma_req_frame_hdl, &mpt->m_acc_req_frame_hdl, &memp,
2625 mem_size, &cookie) == FALSE) {
2626 return (DDI_FAILURE);
2627 }
2628
2629 /*
2630 * Store the request frame memory address. This chip uses this
2631 * address to dma to and from the driver's frame. The second
2632 * address is the address mpt uses to fill in the frame.
2633 */
2634 mpt->m_req_frame_dma_addr = cookie.dmac_laddress;
2635 mpt->m_req_frame = memp;
2636
2637 /*
2638 * Clear the request frame pool.
2639 */
2640 bzero(mpt->m_req_frame, mem_size);
2641
2642 return (DDI_SUCCESS);
2643 }
2644
2645 static int
2646 mptsas_alloc_sense_bufs(mptsas_t *mpt)
2647 {
2648 ddi_dma_attr_t sense_dma_attrs;
2649 caddr_t memp;
2650 ddi_dma_cookie_t cookie;
2651 size_t mem_size;
2652 int num_extrqsense_bufs;
2653
2654 /*
2655 * re-alloc when it has already alloced
2656 */
2657 if (mpt->m_dma_req_sense_hdl) {
2658 rmfreemap(mpt->m_erqsense_map);
2659 mptsas_dma_addr_destroy(&mpt->m_dma_req_sense_hdl,
2660 &mpt->m_acc_req_sense_hdl);
2661 }
2662
2663 /*
2664 * The size of the request sense pool is:
2665 * (Number of Request Frames - 2 ) * Request Sense Size +
2666 * extra memory for extended sense requests.
2667 */
2668 mem_size = ((mpt->m_max_requests - 2) * mpt->m_req_sense_size) +
2669 mptsas_extreq_sense_bufsize;
2670
2671 /*
2672 * set the DMA attributes. ARQ buffers
2673 * aligned on a 16-byte boundry.
2674 */
2675 sense_dma_attrs = mpt->m_msg_dma_attr;
2676 sense_dma_attrs.dma_attr_align = 16;
2677 sense_dma_attrs.dma_attr_sgllen = 1;
2678
2679 /*
2680 * allocate the request sense buffer pool.
2681 */
2682 if (mptsas_dma_addr_create(mpt, sense_dma_attrs,
2683 &mpt->m_dma_req_sense_hdl, &mpt->m_acc_req_sense_hdl, &memp,
2684 mem_size, &cookie) == FALSE) {
2685 return (DDI_FAILURE);
2686 }
2687
2688 /*
2689 * Store the request sense base memory address. This chip uses this
2690 * address to dma the request sense data. The second
2691 * address is the address mpt uses to access the data.
2692 * The third is the base for the extended rqsense buffers.
2693 */
2694 mpt->m_req_sense_dma_addr = cookie.dmac_laddress;
2695 mpt->m_req_sense = memp;
2696 memp += (mpt->m_max_requests - 2) * mpt->m_req_sense_size;
2697 mpt->m_extreq_sense = memp;
2698
2699 /*
2700 * The extra memory is divided up into multiples of the base
2701 * buffer size in order to allocate via rmalloc().
2702 * Note that the rmallocmap cannot start at zero!
2703 */
2704 num_extrqsense_bufs = mptsas_extreq_sense_bufsize /
2705 mpt->m_req_sense_size;
2706 mpt->m_erqsense_map = rmallocmap_wait(num_extrqsense_bufs);
2707 rmfree(mpt->m_erqsense_map, num_extrqsense_bufs, 1);
2708
2709 /*
2710 * Clear the pool.
2711 */
2712 bzero(mpt->m_req_sense, mem_size);
2713
2714 return (DDI_SUCCESS);
2715 }
2716
2717 static int
2718 mptsas_alloc_reply_frames(mptsas_t *mpt)
2719 {
2720 ddi_dma_attr_t frame_dma_attrs;
2721 caddr_t memp;
2722 ddi_dma_cookie_t cookie;
2723 size_t mem_size;
2724
2725 /*
2726 * re-alloc when it has already alloced
2727 */
2728 if (mpt->m_dma_reply_frame_hdl) {
2729 mptsas_dma_addr_destroy(&mpt->m_dma_reply_frame_hdl,
2730 &mpt->m_acc_reply_frame_hdl);
2731 }
2732
2733 /*
2734 * The size of the reply frame pool is:
2735 * Number of Reply Frames * Reply Frame Size
2736 */
2737 mem_size = mpt->m_max_replies * mpt->m_reply_frame_size;
2738
2739 /*
2740 * set the DMA attributes. System Reply Message Frames must be
2741 * aligned on a 4-byte boundry. This is the default.
2742 */
2743 frame_dma_attrs = mpt->m_msg_dma_attr;
2744 frame_dma_attrs.dma_attr_sgllen = 1;
2745
2746 /*
2747 * allocate the reply frame pool
2748 */
2749 if (mptsas_dma_addr_create(mpt, frame_dma_attrs,
2750 &mpt->m_dma_reply_frame_hdl, &mpt->m_acc_reply_frame_hdl, &memp,
2751 mem_size, &cookie) == FALSE) {
2752 return (DDI_FAILURE);
2753 }
2754
2755 /*
2756 * Store the reply frame memory address. This chip uses this
2757 * address to dma to and from the driver's frame. The second
2758 * address is the address mpt uses to process the frame.
2759 */
2760 mpt->m_reply_frame_dma_addr = cookie.dmac_laddress;
2761 mpt->m_reply_frame = memp;
2762
2763 /*
2764 * Clear the reply frame pool.
2765 */
2766 bzero(mpt->m_reply_frame, mem_size);
2767
2768 return (DDI_SUCCESS);
2769 }
2770
2771 static int
2772 mptsas_alloc_free_queue(mptsas_t *mpt)
2773 {
2774 ddi_dma_attr_t frame_dma_attrs;
2775 caddr_t memp;
2776 ddi_dma_cookie_t cookie;
2777 size_t mem_size;
2778
2779 /*
2780 * re-alloc when it has already alloced
2781 */
2782 if (mpt->m_dma_free_queue_hdl) {
2783 mptsas_dma_addr_destroy(&mpt->m_dma_free_queue_hdl,
2784 &mpt->m_acc_free_queue_hdl);
2785 }
2786
2787 /*
2788 * The reply free queue size is:
2789 * Reply Free Queue Depth * 4
2790 * The "4" is the size of one 32 bit address (low part of 64-bit
2791 * address)
2792 */
2793 mem_size = mpt->m_free_queue_depth * 4;
2794
2795 /*
2796 * set the DMA attributes The Reply Free Queue must be aligned on a
2797 * 16-byte boundry.
2798 */
2799 frame_dma_attrs = mpt->m_msg_dma_attr;
2800 frame_dma_attrs.dma_attr_align = 16;
2801 frame_dma_attrs.dma_attr_sgllen = 1;
2802
2803 /*
2804 * allocate the reply free queue
2805 */
2806 if (mptsas_dma_addr_create(mpt, frame_dma_attrs,
2807 &mpt->m_dma_free_queue_hdl, &mpt->m_acc_free_queue_hdl, &memp,
2808 mem_size, &cookie) == FALSE) {
2809 return (DDI_FAILURE);
2810 }
2811
2812 /*
2813 * Store the reply free queue memory address. This chip uses this
2814 * address to read from the reply free queue. The second address
2815 * is the address mpt uses to manage the queue.
2816 */
2817 mpt->m_free_queue_dma_addr = cookie.dmac_laddress;
2818 mpt->m_free_queue = memp;
2819
2820 /*
2821 * Clear the reply free queue memory.
2822 */
2823 bzero(mpt->m_free_queue, mem_size);
2824
2825 return (DDI_SUCCESS);
2826 }
2827
2828 static int
2829 mptsas_alloc_post_queue(mptsas_t *mpt)
2830 {
2831 ddi_dma_attr_t frame_dma_attrs;
2832 caddr_t memp;
2833 ddi_dma_cookie_t cookie;
2834 size_t mem_size;
2835
2836 /*
2837 * re-alloc when it has already alloced
2838 */
2839 if (mpt->m_dma_post_queue_hdl) {
2840 mptsas_dma_addr_destroy(&mpt->m_dma_post_queue_hdl,
2841 &mpt->m_acc_post_queue_hdl);
2842 }
2843
2844 /*
2845 * The reply descriptor post queue size is:
2846 * Reply Descriptor Post Queue Depth * 8
2847 * The "8" is the size of each descriptor (8 bytes or 64 bits).
2848 */
2849 mem_size = mpt->m_post_queue_depth * 8;
2850
2851 /*
2852 * set the DMA attributes. The Reply Descriptor Post Queue must be
2853 * aligned on a 16-byte boundry.
2854 */
2855 frame_dma_attrs = mpt->m_msg_dma_attr;
2856 frame_dma_attrs.dma_attr_align = 16;
2857 frame_dma_attrs.dma_attr_sgllen = 1;
2858
2859 /*
2860 * allocate the reply post queue
2861 */
2862 if (mptsas_dma_addr_create(mpt, frame_dma_attrs,
2863 &mpt->m_dma_post_queue_hdl, &mpt->m_acc_post_queue_hdl, &memp,
2864 mem_size, &cookie) == FALSE) {
2865 return (DDI_FAILURE);
2866 }
2867
2868 /*
2869 * Store the reply descriptor post queue memory address. This chip
2870 * uses this address to write to the reply descriptor post queue. The
2871 * second address is the address mpt uses to manage the queue.
2872 */
2873 mpt->m_post_queue_dma_addr = cookie.dmac_laddress;
2874 mpt->m_post_queue = memp;
2875
2876 /*
2877 * Clear the reply post queue memory.
2878 */
2879 bzero(mpt->m_post_queue, mem_size);
2880
2881 return (DDI_SUCCESS);
2882 }
2883
2884 static void
2885 mptsas_alloc_reply_args(mptsas_t *mpt)
2886 {
2887 if (mpt->m_replyh_args == NULL) {
2888 mpt->m_replyh_args = kmem_zalloc(sizeof (m_replyh_arg_t) *
2889 mpt->m_max_replies, KM_SLEEP);
2890 }
2891 }
2892
2893 static int
2894 mptsas_alloc_extra_sgl_frame(mptsas_t *mpt, mptsas_cmd_t *cmd)
2895 {
2896 mptsas_cache_frames_t *frames = NULL;
2897 if (cmd->cmd_extra_frames == NULL) {
2898 frames = kmem_cache_alloc(mpt->m_cache_frames, KM_NOSLEEP);
2899 if (frames == NULL) {
2900 return (DDI_FAILURE);
2901 }
2902 cmd->cmd_extra_frames = frames;
2903 }
2904 return (DDI_SUCCESS);
2905 }
2906
2907 static void
2908 mptsas_free_extra_sgl_frame(mptsas_t *mpt, mptsas_cmd_t *cmd)
2909 {
2910 if (cmd->cmd_extra_frames) {
2911 kmem_cache_free(mpt->m_cache_frames,
2912 (void *)cmd->cmd_extra_frames);
2913 cmd->cmd_extra_frames = NULL;
2914 }
2915 }
2916
2917 static void
2918 mptsas_cfg_fini(mptsas_t *mpt)
2919 {
2920 NDBG0(("mptsas_cfg_fini"));
2921 ddi_regs_map_free(&mpt->m_datap);
2922 }
2923
2924 static void
2925 mptsas_hba_fini(mptsas_t *mpt)
2926 {
2927 NDBG0(("mptsas_hba_fini"));
2928
2929 /*
2930 * Free up any allocated memory
2931 */
2932 if (mpt->m_dma_req_frame_hdl) {
2933 mptsas_dma_addr_destroy(&mpt->m_dma_req_frame_hdl,
2934 &mpt->m_acc_req_frame_hdl);
2935 }
2936
2937 if (mpt->m_dma_req_sense_hdl) {
2938 rmfreemap(mpt->m_erqsense_map);
2939 mptsas_dma_addr_destroy(&mpt->m_dma_req_sense_hdl,
2940 &mpt->m_acc_req_sense_hdl);
2941 }
2942
2943 if (mpt->m_dma_reply_frame_hdl) {
2944 mptsas_dma_addr_destroy(&mpt->m_dma_reply_frame_hdl,
2945 &mpt->m_acc_reply_frame_hdl);
2946 }
2947
2948 if (mpt->m_dma_free_queue_hdl) {
2949 mptsas_dma_addr_destroy(&mpt->m_dma_free_queue_hdl,
2950 &mpt->m_acc_free_queue_hdl);
2951 }
2952
2953 if (mpt->m_dma_post_queue_hdl) {
2954 mptsas_dma_addr_destroy(&mpt->m_dma_post_queue_hdl,
2955 &mpt->m_acc_post_queue_hdl);
2956 }
2957
2958 if (mpt->m_replyh_args != NULL) {
2959 kmem_free(mpt->m_replyh_args, sizeof (m_replyh_arg_t)
2960 * mpt->m_max_replies);
2961 }
2962 }
2963
2964 static int
2965 mptsas_name_child(dev_info_t *lun_dip, char *name, int len)
2966 {
2967 int lun = 0;
2968 char *sas_wwn = NULL;
2969 int phynum = -1;
2970 int reallen = 0;
2971
2972 /* Get the target num */
2973 lun = ddi_prop_get_int(DDI_DEV_T_ANY, lun_dip, DDI_PROP_DONTPASS,
2974 LUN_PROP, 0);
2975
2976 if ((phynum = ddi_prop_get_int(DDI_DEV_T_ANY, lun_dip,
2977 DDI_PROP_DONTPASS, "sata-phy", -1)) != -1) {
2978 /*
2979 * Stick in the address of form "pPHY,LUN"
2980 */
2981 reallen = snprintf(name, len, "p%x,%x", phynum, lun);
2982 } else if (ddi_prop_lookup_string(DDI_DEV_T_ANY, lun_dip,
2983 DDI_PROP_DONTPASS, SCSI_ADDR_PROP_TARGET_PORT, &sas_wwn)
2984 == DDI_PROP_SUCCESS) {
2985 /*
2986 * Stick in the address of the form "wWWN,LUN"
2987 */
2988 reallen = snprintf(name, len, "%s,%x", sas_wwn, lun);
2989 ddi_prop_free(sas_wwn);
2990 } else {
2991 return (DDI_FAILURE);
2992 }
2993
2994 ASSERT(reallen < len);
2995 if (reallen >= len) {
2996 mptsas_log(0, CE_WARN, "!mptsas_get_name: name parameter "
2997 "length too small, it needs to be %d bytes", reallen + 1);
2998 }
2999 return (DDI_SUCCESS);
3000 }
3001
3002 /*
3003 * tran_tgt_init(9E) - target device instance initialization
3004 */
3005 static int
3006 mptsas_scsi_tgt_init(dev_info_t *hba_dip, dev_info_t *tgt_dip,
3007 scsi_hba_tran_t *hba_tran, struct scsi_device *sd)
3008 {
3009 #ifndef __lock_lint
3010 _NOTE(ARGUNUSED(hba_tran))
3011 #endif
3012
3013 /*
3014 * At this point, the scsi_device structure already exists
3015 * and has been initialized.
3016 *
3017 * Use this function to allocate target-private data structures,
3018 * if needed by this HBA. Add revised flow-control and queue
3019 * properties for child here, if desired and if you can tell they
3020 * support tagged queueing by now.
3021 */
3022 mptsas_t *mpt;
3023 int lun = sd->sd_address.a_lun;
3024 mdi_pathinfo_t *pip = NULL;
3025 mptsas_tgt_private_t *tgt_private = NULL;
3026 mptsas_target_t *ptgt = NULL;
3027 char *psas_wwn = NULL;
3028 mptsas_phymask_t phymask = 0;
3029 uint64_t sas_wwn = 0;
3030 mptsas_target_addr_t addr;
3031 mpt = SDEV2MPT(sd);
3032
3033 ASSERT(scsi_hba_iport_unit_address(hba_dip) != 0);
3034
3035 NDBG0(("mptsas_scsi_tgt_init: hbadip=0x%p tgtdip=0x%p lun=%d",
3036 (void *)hba_dip, (void *)tgt_dip, lun));
3037
3038 if (ndi_dev_is_persistent_node(tgt_dip) == 0) {
3039 (void) ndi_merge_node(tgt_dip, mptsas_name_child);
3040 ddi_set_name_addr(tgt_dip, NULL);
3041 return (DDI_FAILURE);
3042 }
3043 /*
3044 * phymask is 0 means the virtual port for RAID
3045 */
3046 phymask = (mptsas_phymask_t)ddi_prop_get_int(DDI_DEV_T_ANY, hba_dip, 0,
3047 "phymask", 0);
3048 if (mdi_component_is_client(tgt_dip, NULL) == MDI_SUCCESS) {
3049 if ((pip = (void *)(sd->sd_private)) == NULL) {
3050 /*
3051 * Very bad news if this occurs. Somehow scsi_vhci has
3052 * lost the pathinfo node for this target.
3053 */
3054 return (DDI_NOT_WELL_FORMED);
3055 }
3056
3057 if (mdi_prop_lookup_int(pip, LUN_PROP, &lun) !=
3058 DDI_PROP_SUCCESS) {
3059 mptsas_log(mpt, CE_WARN, "Get lun property failed\n");
3060 return (DDI_FAILURE);
3061 }
3062
3063 if (mdi_prop_lookup_string(pip, SCSI_ADDR_PROP_TARGET_PORT,
3064 &psas_wwn) == MDI_SUCCESS) {
3065 if (scsi_wwnstr_to_wwn(psas_wwn, &sas_wwn)) {
3066 sas_wwn = 0;
3067 }
3068 (void) mdi_prop_free(psas_wwn);
3069 }
3070 } else {
3071 lun = ddi_prop_get_int(DDI_DEV_T_ANY, tgt_dip,
3072 DDI_PROP_DONTPASS, LUN_PROP, 0);
3073 if (ddi_prop_lookup_string(DDI_DEV_T_ANY, tgt_dip,
3074 DDI_PROP_DONTPASS, SCSI_ADDR_PROP_TARGET_PORT, &psas_wwn) ==
3075 DDI_PROP_SUCCESS) {
3076 if (scsi_wwnstr_to_wwn(psas_wwn, &sas_wwn)) {
3077 sas_wwn = 0;
3078 }
3079 ddi_prop_free(psas_wwn);
3080 } else {
3081 sas_wwn = 0;
3082 }
3083 }
3084
3085 ASSERT((sas_wwn != 0) || (phymask != 0));
3086 addr.mta_wwn = sas_wwn;
3087 addr.mta_phymask = phymask;
3088 mutex_enter(&mpt->m_mutex);
3089 ptgt = refhash_lookup(mpt->m_targets, &addr);
3090 mutex_exit(&mpt->m_mutex);
3091 if (ptgt == NULL) {
3092 mptsas_log(mpt, CE_WARN, "!tgt_init: target doesn't exist or "
3093 "gone already! phymask:%x, saswwn %"PRIx64, phymask,
3094 sas_wwn);
3095 return (DDI_FAILURE);
3096 }
3097 if (hba_tran->tran_tgt_private == NULL) {
3098 tgt_private = kmem_zalloc(sizeof (mptsas_tgt_private_t),
3099 KM_SLEEP);
3100 tgt_private->t_lun = lun;
3101 tgt_private->t_private = ptgt;
3102 hba_tran->tran_tgt_private = tgt_private;
3103 }
3104
3105 if (mdi_component_is_client(tgt_dip, NULL) == MDI_SUCCESS) {
3106 return (DDI_SUCCESS);
3107 }
3108 mutex_enter(&mpt->m_mutex);
3109
3110 if (ptgt->m_deviceinfo &
3111 (MPI2_SAS_DEVICE_INFO_SATA_DEVICE |
3112 MPI2_SAS_DEVICE_INFO_ATAPI_DEVICE)) {
3113 uchar_t *inq89 = NULL;
3114 int inq89_len = 0x238;
3115 int reallen = 0;
3116 int rval = 0;
3117 struct sata_id *sid = NULL;
3118 char model[SATA_ID_MODEL_LEN + 1];
3119 char fw[SATA_ID_FW_LEN + 1];
3120 char *vid, *pid;
3121
3122 mutex_exit(&mpt->m_mutex);
3123 /*
3124 * According SCSI/ATA Translation -2 (SAT-2) revision 01a
3125 * chapter 12.4.2 VPD page 89h includes 512 bytes ATA IDENTIFY
3126 * DEVICE data or ATA IDENTIFY PACKET DEVICE data.
3127 */
3128 inq89 = kmem_zalloc(inq89_len, KM_SLEEP);
3129 rval = mptsas_inquiry(mpt, ptgt, 0, 0x89,
3130 inq89, inq89_len, &reallen, 1);
3131
3132 if (rval != 0) {
3133 if (inq89 != NULL) {
3134 kmem_free(inq89, inq89_len);
3135 }
3136
3137 mptsas_log(mpt, CE_WARN, "!mptsas request inquiry page "
3138 "0x89 for SATA target:%x failed!", ptgt->m_devhdl);
3139 return (DDI_SUCCESS);
3140 }
3141 sid = (void *)(&inq89[60]);
3142
3143 swab(sid->ai_model, model, SATA_ID_MODEL_LEN);
3144 swab(sid->ai_fw, fw, SATA_ID_FW_LEN);
3145
3146 model[SATA_ID_MODEL_LEN] = 0;
3147 fw[SATA_ID_FW_LEN] = 0;
3148
3149 sata_split_model(model, &vid, &pid);
3150
3151 /*
3152 * override SCSA "inquiry-*" properties
3153 */
3154 if (vid)
3155 (void) scsi_device_prop_update_inqstring(sd,
3156 INQUIRY_VENDOR_ID, vid, strlen(vid));
3157 if (pid)
3158 (void) scsi_device_prop_update_inqstring(sd,
3159 INQUIRY_PRODUCT_ID, pid, strlen(pid));
3160 (void) scsi_device_prop_update_inqstring(sd,
3161 INQUIRY_REVISION_ID, fw, strlen(fw));
3162
3163 if (inq89 != NULL) {
3164 kmem_free(inq89, inq89_len);
3165 }
3166 } else {
3167 mutex_exit(&mpt->m_mutex);
3168 }
3169
3170 return (DDI_SUCCESS);
3171 }
3172 /*
3173 * tran_tgt_free(9E) - target device instance deallocation
3174 */
3175 static void
3176 mptsas_scsi_tgt_free(dev_info_t *hba_dip, dev_info_t *tgt_dip,
3177 scsi_hba_tran_t *hba_tran, struct scsi_device *sd)
3178 {
3179 #ifndef __lock_lint
3180 _NOTE(ARGUNUSED(hba_dip, tgt_dip, hba_tran, sd))
3181 #endif
3182
3183 mptsas_tgt_private_t *tgt_private = hba_tran->tran_tgt_private;
3184
3185 if (tgt_private != NULL) {
3186 kmem_free(tgt_private, sizeof (mptsas_tgt_private_t));
3187 hba_tran->tran_tgt_private = NULL;
3188 }
3189 }
3190
3191 /*
3192 * scsi_pkt handling
3193 *
3194 * Visible to the external world via the transport structure.
3195 */
3196
3197 /*
3198 * Notes:
3199 * - transport the command to the addressed SCSI target/lun device
3200 * - normal operation is to schedule the command to be transported,
3201 * and return TRAN_ACCEPT if this is successful.
3202 * - if NO_INTR, tran_start must poll device for command completion
3203 */
3204 static int
3205 mptsas_scsi_start(struct scsi_address *ap, struct scsi_pkt *pkt)
3206 {
3207 #ifndef __lock_lint
3208 _NOTE(ARGUNUSED(ap))
3209 #endif
3210 mptsas_t *mpt = PKT2MPT(pkt);
3211 mptsas_cmd_t *cmd = PKT2CMD(pkt);
3212 int rval;
3213 mptsas_target_t *ptgt = cmd->cmd_tgt_addr;
3214
3215 NDBG1(("mptsas_scsi_start: pkt=0x%p", (void *)pkt));
3216 ASSERT(ptgt);
3217 if (ptgt == NULL)
3218 return (TRAN_FATAL_ERROR);
3219
3220 /*
3221 * prepare the pkt before taking mutex.
3222 */
3223 rval = mptsas_prepare_pkt(cmd);
3224 if (rval != TRAN_ACCEPT) {
3225 return (rval);
3226 }
3227
3228 /*
3229 * Send the command to target/lun, however your HBA requires it.
3230 * If busy, return TRAN_BUSY; if there's some other formatting error
3231 * in the packet, return TRAN_BADPKT; otherwise, fall through to the
3232 * return of TRAN_ACCEPT.
3233 *
3234 * Remember that access to shared resources, including the mptsas_t
3235 * data structure and the HBA hardware registers, must be protected
3236 * with mutexes, here and everywhere.
3237 *
3238 * Also remember that at interrupt time, you'll get an argument
3239 * to the interrupt handler which is a pointer to your mptsas_t
3240 * structure; you'll have to remember which commands are outstanding
3241 * and which scsi_pkt is the currently-running command so the
3242 * interrupt handler can refer to the pkt to set completion
3243 * status, call the target driver back through pkt_comp, etc.
3244 *
3245 * If the instance lock is held by other thread, don't spin to wait
3246 * for it. Instead, queue the cmd and next time when the instance lock
3247 * is not held, accept all the queued cmd. A extra tx_waitq is
3248 * introduced to protect the queue.
3249 *
3250 * The polled cmd will not be queud and accepted as usual.
3251 *
3252 * Under the tx_waitq mutex, record whether a thread is draining
3253 * the tx_waitq. An IO requesting thread that finds the instance
3254 * mutex contended appends to the tx_waitq and while holding the
3255 * tx_wait mutex, if the draining flag is not set, sets it and then
3256 * proceeds to spin for the instance mutex. This scheme ensures that
3257 * the last cmd in a burst be processed.
3258 *
3259 * we enable this feature only when the helper threads are enabled,
3260 * at which we think the loads are heavy.
3261 *
3262 * per instance mutex m_tx_waitq_mutex is introduced to protect the
3263 * m_tx_waitqtail, m_tx_waitq, m_tx_draining.
3264 */
3265
3266 if (mpt->m_doneq_thread_n) {
3267 if (mutex_tryenter(&mpt->m_mutex) != 0) {
3268 rval = mptsas_accept_txwq_and_pkt(mpt, cmd);
3269 mutex_exit(&mpt->m_mutex);
3270 } else if (cmd->cmd_pkt_flags & FLAG_NOINTR) {
3271 mutex_enter(&mpt->m_mutex);
3272 rval = mptsas_accept_txwq_and_pkt(mpt, cmd);
3273 mutex_exit(&mpt->m_mutex);
3274 } else {
3275 mutex_enter(&mpt->m_tx_waitq_mutex);
3276 /*
3277 * ptgt->m_dr_flag is protected by m_mutex or
3278 * m_tx_waitq_mutex. In this case, m_tx_waitq_mutex
3279 * is acquired.
3280 */
3281 if (ptgt->m_dr_flag == MPTSAS_DR_INTRANSITION) {
3282 if (cmd->cmd_pkt_flags & FLAG_NOQUEUE) {
3283 /*
3284 * The command should be allowed to
3285 * retry by returning TRAN_BUSY to
3286 * to stall the I/O's which come from
3287 * scsi_vhci since the device/path is
3288 * in unstable state now.
3289 */
3290 mutex_exit(&mpt->m_tx_waitq_mutex);
3291 return (TRAN_BUSY);
3292 } else {
3293 /*
3294 * The device is offline, just fail the
3295 * command by returning
3296 * TRAN_FATAL_ERROR.
3297 */
3298 mutex_exit(&mpt->m_tx_waitq_mutex);
3299 return (TRAN_FATAL_ERROR);
3300 }
3301 }
3302 if (mpt->m_tx_draining) {
3303 cmd->cmd_flags |= CFLAG_TXQ;
3304 *mpt->m_tx_waitqtail = cmd;
3305 mpt->m_tx_waitqtail = &cmd->cmd_linkp;
3306 mutex_exit(&mpt->m_tx_waitq_mutex);
3307 } else { /* drain the queue */
3308 mpt->m_tx_draining = 1;
3309 mutex_exit(&mpt->m_tx_waitq_mutex);
3310 mutex_enter(&mpt->m_mutex);
3311 rval = mptsas_accept_txwq_and_pkt(mpt, cmd);
3312 mutex_exit(&mpt->m_mutex);
3313 }
3314 }
3315 } else {
3316 mutex_enter(&mpt->m_mutex);
3317 /*
3318 * ptgt->m_dr_flag is protected by m_mutex or m_tx_waitq_mutex
3319 * in this case, m_mutex is acquired.
3320 */
3321 if (ptgt->m_dr_flag == MPTSAS_DR_INTRANSITION) {
3322 if (cmd->cmd_pkt_flags & FLAG_NOQUEUE) {
3323 /*
3324 * commands should be allowed to retry by
3325 * returning TRAN_BUSY to stall the I/O's
3326 * which come from scsi_vhci since the device/
3327 * path is in unstable state now.
3328 */
3329 mutex_exit(&mpt->m_mutex);
3330 return (TRAN_BUSY);
3331 } else {
3332 /*
3333 * The device is offline, just fail the
3334 * command by returning TRAN_FATAL_ERROR.
3335 */
3336 mutex_exit(&mpt->m_mutex);
3337 return (TRAN_FATAL_ERROR);
3338 }
3339 }
3340 rval = mptsas_accept_pkt(mpt, cmd);
3341 mutex_exit(&mpt->m_mutex);
3342 }
3343
3344 return (rval);
3345 }
3346
3347 /*
3348 * Accept all the queued cmds(if any) before accept the current one.
3349 */
3350 static int
3351 mptsas_accept_txwq_and_pkt(mptsas_t *mpt, mptsas_cmd_t *cmd)
3352 {
3353 int rval;
3354 mptsas_target_t *ptgt = cmd->cmd_tgt_addr;
3355
3356 ASSERT(mutex_owned(&mpt->m_mutex));
3357 /*
3358 * The call to mptsas_accept_tx_waitq() must always be performed
3359 * because that is where mpt->m_tx_draining is cleared.
3360 */
3361 mutex_enter(&mpt->m_tx_waitq_mutex);
3362 mptsas_accept_tx_waitq(mpt);
3363 mutex_exit(&mpt->m_tx_waitq_mutex);
3364 /*
3365 * ptgt->m_dr_flag is protected by m_mutex or m_tx_waitq_mutex
3366 * in this case, m_mutex is acquired.
3367 */
3368 if (ptgt->m_dr_flag == MPTSAS_DR_INTRANSITION) {
3369 if (cmd->cmd_pkt_flags & FLAG_NOQUEUE) {
3370 /*
3371 * The command should be allowed to retry by returning
3372 * TRAN_BUSY to stall the I/O's which come from
3373 * scsi_vhci since the device/path is in unstable state
3374 * now.
3375 */
3376 return (TRAN_BUSY);
3377 } else {
3378 /*
3379 * The device is offline, just fail the command by
3380 * return TRAN_FATAL_ERROR.
3381 */
3382 return (TRAN_FATAL_ERROR);
3383 }
3384 }
3385 rval = mptsas_accept_pkt(mpt, cmd);
3386
3387 return (rval);
3388 }
3389
3390 static int
3391 mptsas_accept_pkt(mptsas_t *mpt, mptsas_cmd_t *cmd)
3392 {
3393 int rval = TRAN_ACCEPT;
3394 mptsas_target_t *ptgt = cmd->cmd_tgt_addr;
3395
3396 NDBG1(("mptsas_accept_pkt: cmd=0x%p", (void *)cmd));
3397
3398 ASSERT(mutex_owned(&mpt->m_mutex));
3399
3400 if ((cmd->cmd_flags & CFLAG_PREPARED) == 0) {
3401 rval = mptsas_prepare_pkt(cmd);
3402 if (rval != TRAN_ACCEPT) {
3403 cmd->cmd_flags &= ~CFLAG_TRANFLAG;
3404 return (rval);
3405 }
3406 }
3407
3408 /*
3409 * reset the throttle if we were draining
3410 */
3411 if ((ptgt->m_t_ncmds == 0) &&
3412 (ptgt->m_t_throttle == DRAIN_THROTTLE)) {
3413 NDBG23(("reset throttle"));
3414 ASSERT(ptgt->m_reset_delay == 0);
3415 mptsas_set_throttle(mpt, ptgt, MAX_THROTTLE);
3416 }
3417
3418 /*
3419 * If HBA is being reset, the DevHandles are being re-initialized,
3420 * which means that they could be invalid even if the target is still
3421 * attached. Check if being reset and if DevHandle is being
3422 * re-initialized. If this is the case, return BUSY so the I/O can be
3423 * retried later.
3424 */
3425 if ((ptgt->m_devhdl == MPTSAS_INVALID_DEVHDL) && mpt->m_in_reset) {
3426 mptsas_set_pkt_reason(mpt, cmd, CMD_RESET, STAT_BUS_RESET);
3427 if (cmd->cmd_flags & CFLAG_TXQ) {
3428 mptsas_doneq_add(mpt, cmd);
3429 mptsas_doneq_empty(mpt);
3430 return (rval);
3431 } else {
3432 return (TRAN_BUSY);
3433 }
3434 }
3435
3436 /*
3437 * If device handle has already been invalidated, just
3438 * fail the command. In theory, command from scsi_vhci
3439 * client is impossible send down command with invalid
3440 * devhdl since devhdl is set after path offline, target
3441 * driver is not suppose to select a offlined path.
3442 */
3443 if (ptgt->m_devhdl == MPTSAS_INVALID_DEVHDL) {
3444 NDBG3(("rejecting command, it might because invalid devhdl "
3445 "request."));
3446 mptsas_set_pkt_reason(mpt, cmd, CMD_DEV_GONE, STAT_TERMINATED);
3447 if (cmd->cmd_flags & CFLAG_TXQ) {
3448 mptsas_doneq_add(mpt, cmd);
3449 mptsas_doneq_empty(mpt);
3450 return (rval);
3451 } else {
3452 return (TRAN_FATAL_ERROR);
3453 }
3454 }
3455 /*
3456 * The first case is the normal case. mpt gets a command from the
3457 * target driver and starts it.
3458 * Since SMID 0 is reserved and the TM slot is reserved, the actual max
3459 * commands is m_max_requests - 2.
3460 */
3461 if ((mpt->m_ncmds <= (mpt->m_max_requests - 2)) &&
3462 (ptgt->m_t_throttle > HOLD_THROTTLE) &&
3463 (ptgt->m_t_ncmds < ptgt->m_t_throttle) &&
3464 (ptgt->m_reset_delay == 0) &&
3465 (ptgt->m_t_nwait == 0) &&
3466 ((cmd->cmd_pkt_flags & FLAG_NOINTR) == 0)) {
3467 if (mptsas_save_cmd(mpt, cmd) == TRUE) {
3468 (void) mptsas_start_cmd(mpt, cmd);
3469 } else {
3470 mptsas_waitq_add(mpt, cmd);
3471 }
3472 } else {
3473 /*
3474 * Add this pkt to the work queue
3475 */
3476 mptsas_waitq_add(mpt, cmd);
3477
3478 if (cmd->cmd_pkt_flags & FLAG_NOINTR) {
3479 (void) mptsas_poll(mpt, cmd, MPTSAS_POLL_TIME);
3480
3481 /*
3482 * Only flush the doneq if this is not a TM
3483 * cmd. For TM cmds the flushing of the
3484 * doneq will be done in those routines.
3485 */
3486 if ((cmd->cmd_flags & CFLAG_TM_CMD) == 0) {
3487 mptsas_doneq_empty(mpt);
3488 }
3489 }
3490 }
3491 return (rval);
3492 }
3493
3494 int
3495 mptsas_save_cmd(mptsas_t *mpt, mptsas_cmd_t *cmd)
3496 {
3497 mptsas_slots_t *slots = mpt->m_active;
3498 uint_t slot, start_rotor;
3499 mptsas_target_t *ptgt = cmd->cmd_tgt_addr;
3500
3501 ASSERT(MUTEX_HELD(&mpt->m_mutex));
3502
3503 /*
3504 * Account for reserved TM request slot and reserved SMID of 0.
3505 */
3506 ASSERT(slots->m_n_normal == (mpt->m_max_requests - 2));
3507
3508 /*
3509 * Find the next available slot, beginning at m_rotor. If no slot is
3510 * available, we'll return FALSE to indicate that. This mechanism
3511 * considers only the normal slots, not the reserved slot 0 nor the
3512 * task management slot m_n_normal + 1. The rotor is left to point to
3513 * the normal slot after the one we select, unless we select the last
3514 * normal slot in which case it returns to slot 1.
3515 */
3516 start_rotor = slots->m_rotor;
3517 do {
3518 slot = slots->m_rotor++;
3519 if (slots->m_rotor > slots->m_n_normal)
3520 slots->m_rotor = 1;
3521
3522 if (slots->m_rotor == start_rotor)
3523 break;
3524 } while (slots->m_slot[slot] != NULL);
3525
3526 if (slots->m_slot[slot] != NULL)
3527 return (FALSE);
3528
3529 ASSERT(slot != 0 && slot <= slots->m_n_normal);
3530
3531 cmd->cmd_slot = slot;
3532 slots->m_slot[slot] = cmd;
3533 mpt->m_ncmds++;
3534
3535 /*
3536 * only increment per target ncmds if this is not a
3537 * command that has no target associated with it (i.e. a
3538 * event acknoledgment)
3539 */
3540 if ((cmd->cmd_flags & CFLAG_CMDIOC) == 0) {
3541 /*
3542 * Expiration time is set in mptsas_start_cmd
3543 */
3544 ptgt->m_t_ncmds++;
3545 cmd->cmd_active_expiration = 0;
3546 } else {
3547 /*
3548 * Initialize expiration time for passthrough commands,
3549 */
3550 cmd->cmd_active_expiration = gethrtime() +
3551 (hrtime_t)cmd->cmd_pkt->pkt_time * NANOSEC;
3552 }
3553 return (TRUE);
3554 }
3555
3556 /*
3557 * prepare the pkt:
3558 * the pkt may have been resubmitted or just reused so
3559 * initialize some fields and do some checks.
3560 */
3561 static int
3562 mptsas_prepare_pkt(mptsas_cmd_t *cmd)
3563 {
3564 struct scsi_pkt *pkt = CMD2PKT(cmd);
3565
3566 NDBG1(("mptsas_prepare_pkt: cmd=0x%p", (void *)cmd));
3567
3568 /*
3569 * Reinitialize some fields that need it; the packet may
3570 * have been resubmitted
3571 */
3572 pkt->pkt_reason = CMD_CMPLT;
3573 pkt->pkt_state = 0;
3574 pkt->pkt_statistics = 0;
3575 pkt->pkt_resid = 0;
3576 cmd->cmd_age = 0;
3577 cmd->cmd_pkt_flags = pkt->pkt_flags;
3578
3579 /*
3580 * zero status byte.
3581 */
3582 *(pkt->pkt_scbp) = 0;
3583
3584 if (cmd->cmd_flags & CFLAG_DMAVALID) {
3585 pkt->pkt_resid = cmd->cmd_dmacount;
3586
3587 /*
3588 * consistent packets need to be sync'ed first
3589 * (only for data going out)
3590 */
3591 if ((cmd->cmd_flags & CFLAG_CMDIOPB) &&
3592 (cmd->cmd_flags & CFLAG_DMASEND)) {
3593 (void) ddi_dma_sync(cmd->cmd_dmahandle, 0, 0,
3594 DDI_DMA_SYNC_FORDEV);
3595 }
3596 }
3597
3598 cmd->cmd_flags =
3599 (cmd->cmd_flags & ~(CFLAG_TRANFLAG)) |
3600 CFLAG_PREPARED | CFLAG_IN_TRANSPORT;
3601
3602 return (TRAN_ACCEPT);
3603 }
3604
3605 /*
3606 * tran_init_pkt(9E) - allocate scsi_pkt(9S) for command
3607 *
3608 * One of three possibilities:
3609 * - allocate scsi_pkt
3610 * - allocate scsi_pkt and DMA resources
3611 * - allocate DMA resources to an already-allocated pkt
3612 */
3613 static struct scsi_pkt *
3614 mptsas_scsi_init_pkt(struct scsi_address *ap, struct scsi_pkt *pkt,
3615 struct buf *bp, int cmdlen, int statuslen, int tgtlen, int flags,
3616 int (*callback)(), caddr_t arg)
3617 {
3618 mptsas_cmd_t *cmd, *new_cmd;
3619 mptsas_t *mpt = ADDR2MPT(ap);
3620 int failure = 1;
3621 uint_t oldcookiec;
3622 mptsas_target_t *ptgt = NULL;
3623 int rval;
3624 mptsas_tgt_private_t *tgt_private;
3625 int kf;
3626
3627 kf = (callback == SLEEP_FUNC)? KM_SLEEP: KM_NOSLEEP;
3628
3629 tgt_private = (mptsas_tgt_private_t *)ap->a_hba_tran->
3630 tran_tgt_private;
3631 ASSERT(tgt_private != NULL);
3632 if (tgt_private == NULL) {
3633 return (NULL);
3634 }
3635 ptgt = tgt_private->t_private;
3636 ASSERT(ptgt != NULL);
3637 if (ptgt == NULL)
3638 return (NULL);
3639 ap->a_target = ptgt->m_devhdl;
3640 ap->a_lun = tgt_private->t_lun;
3641
3642 ASSERT(callback == NULL_FUNC || callback == SLEEP_FUNC);
3643 #ifdef MPTSAS_TEST_EXTRN_ALLOC
3644 statuslen *= 100; tgtlen *= 4;
3645 #endif
3646 NDBG3(("mptsas_scsi_init_pkt:\n"
3647 "\ttgt=%d in=0x%p bp=0x%p clen=%d slen=%d tlen=%d flags=%x",
3648 ap->a_target, (void *)pkt, (void *)bp,
3649 cmdlen, statuslen, tgtlen, flags));
3650
3651 /*
3652 * Allocate the new packet.
3653 */
3654 if (pkt == NULL) {
3655 ddi_dma_handle_t save_dma_handle;
3656
3657 cmd = kmem_cache_alloc(mpt->m_kmem_cache, kf);
3658
3659 if (cmd) {
3660 save_dma_handle = cmd->cmd_dmahandle;
3661 bzero(cmd, sizeof (*cmd) + scsi_pkt_size());
3662 cmd->cmd_dmahandle = save_dma_handle;
3663
3664 pkt = (void *)((uchar_t *)cmd +
3665 sizeof (struct mptsas_cmd));
3666 pkt->pkt_ha_private = (opaque_t)cmd;
3667 pkt->pkt_address = *ap;
3668 pkt->pkt_private = (opaque_t)cmd->cmd_pkt_private;
3669 pkt->pkt_scbp = (opaque_t)&cmd->cmd_scb;
3670 pkt->pkt_cdbp = (opaque_t)&cmd->cmd_cdb;
3671 cmd->cmd_pkt = (struct scsi_pkt *)pkt;
3672 cmd->cmd_cdblen = (uchar_t)cmdlen;
3673 cmd->cmd_scblen = statuslen;
3674 cmd->cmd_rqslen = SENSE_LENGTH;
3675 cmd->cmd_tgt_addr = ptgt;
3676 failure = 0;
3677 }
3678
3679 if (failure || (cmdlen > sizeof (cmd->cmd_cdb)) ||
3680 (tgtlen > PKT_PRIV_LEN) ||
3681 (statuslen > EXTCMDS_STATUS_SIZE)) {
3682 if (failure == 0) {
3683 /*
3684 * if extern alloc fails, all will be
3685 * deallocated, including cmd
3686 */
3687 failure = mptsas_pkt_alloc_extern(mpt, cmd,
3688 cmdlen, tgtlen, statuslen, kf);
3689 }
3690 if (failure) {
3691 /*
3692 * if extern allocation fails, it will
3693 * deallocate the new pkt as well
3694 */
3695 return (NULL);
3696 }
3697 }
3698 new_cmd = cmd;
3699
3700 } else {
3701 cmd = PKT2CMD(pkt);
3702 new_cmd = NULL;
3703 }
3704
3705
3706 /* grab cmd->cmd_cookiec here as oldcookiec */
3707
3708 oldcookiec = cmd->cmd_cookiec;
3709
3710 /*
3711 * If the dma was broken up into PARTIAL transfers cmd_nwin will be
3712 * greater than 0 and we'll need to grab the next dma window
3713 */
3714 /*
3715 * SLM-not doing extra command frame right now; may add later
3716 */
3717
3718 if (cmd->cmd_nwin > 0) {
3719
3720 /*
3721 * Make sure we havn't gone past the the total number
3722 * of windows
3723 */
3724 if (++cmd->cmd_winindex >= cmd->cmd_nwin) {
3725 return (NULL);
3726 }
3727 if (ddi_dma_getwin(cmd->cmd_dmahandle, cmd->cmd_winindex,
3728 &cmd->cmd_dma_offset, &cmd->cmd_dma_len,
3729 &cmd->cmd_cookie, &cmd->cmd_cookiec) == DDI_FAILURE) {
3730 return (NULL);
3731 }
3732 goto get_dma_cookies;
3733 }
3734
3735
3736 if (flags & PKT_XARQ) {
3737 cmd->cmd_flags |= CFLAG_XARQ;
3738 }
3739
3740 /*
3741 * DMA resource allocation. This version assumes your
3742 * HBA has some sort of bus-mastering or onboard DMA capability, with a
3743 * scatter-gather list of length MPTSAS_MAX_DMA_SEGS, as given in the
3744 * ddi_dma_attr_t structure and passed to scsi_impl_dmaget.
3745 */
3746 if (bp && (bp->b_bcount != 0) &&
3747 (cmd->cmd_flags & CFLAG_DMAVALID) == 0) {
3748
3749 int cnt, dma_flags;
3750 mptti_t *dmap; /* ptr to the S/G list */
3751
3752 /*
3753 * Set up DMA memory and position to the next DMA segment.
3754 */
3755 ASSERT(cmd->cmd_dmahandle != NULL);
3756
3757 if (bp->b_flags & B_READ) {
3758 dma_flags = DDI_DMA_READ;
3759 cmd->cmd_flags &= ~CFLAG_DMASEND;
3760 } else {
3761 dma_flags = DDI_DMA_WRITE;
3762 cmd->cmd_flags |= CFLAG_DMASEND;
3763 }
3764 if (flags & PKT_CONSISTENT) {
3765 cmd->cmd_flags |= CFLAG_CMDIOPB;
3766 dma_flags |= DDI_DMA_CONSISTENT;
3767 }
3768
3769 if (flags & PKT_DMA_PARTIAL) {
3770 dma_flags |= DDI_DMA_PARTIAL;
3771 }
3772
3773 /*
3774 * workaround for byte hole issue on psycho and
3775 * schizo pre 2.1
3776 */
3777 if ((bp->b_flags & B_READ) && ((bp->b_flags &
3778 (B_PAGEIO|B_REMAPPED)) != B_PAGEIO) &&
3779 ((uintptr_t)bp->b_un.b_addr & 0x7)) {
3780 dma_flags |= DDI_DMA_CONSISTENT;
3781 }
3782
3783 rval = ddi_dma_buf_bind_handle(cmd->cmd_dmahandle, bp,
3784 dma_flags, callback, arg,
3785 &cmd->cmd_cookie, &cmd->cmd_cookiec);
3786 if (rval == DDI_DMA_PARTIAL_MAP) {
3787 (void) ddi_dma_numwin(cmd->cmd_dmahandle,
3788 &cmd->cmd_nwin);
3789 cmd->cmd_winindex = 0;
3790 (void) ddi_dma_getwin(cmd->cmd_dmahandle,
3791 cmd->cmd_winindex, &cmd->cmd_dma_offset,
3792 &cmd->cmd_dma_len, &cmd->cmd_cookie,
3793 &cmd->cmd_cookiec);
3794 } else if (rval && (rval != DDI_DMA_MAPPED)) {
3795 switch (rval) {
3796 case DDI_DMA_NORESOURCES:
3797 bioerror(bp, 0);
3798 break;
3799 case DDI_DMA_BADATTR:
3800 case DDI_DMA_NOMAPPING:
3801 bioerror(bp, EFAULT);
3802 break;
3803 case DDI_DMA_TOOBIG:
3804 default:
3805 bioerror(bp, EINVAL);
3806 break;
3807 }
3808 cmd->cmd_flags &= ~CFLAG_DMAVALID;
3809 if (new_cmd) {
3810 mptsas_scsi_destroy_pkt(ap, pkt);
3811 }
3812 return ((struct scsi_pkt *)NULL);
3813 }
3814
3815 get_dma_cookies:
3816 cmd->cmd_flags |= CFLAG_DMAVALID;
3817 ASSERT(cmd->cmd_cookiec > 0);
3818
3819 if (cmd->cmd_cookiec > MPTSAS_MAX_CMD_SEGS) {
3820 mptsas_log(mpt, CE_NOTE, "large cookiec received %d\n",
3821 cmd->cmd_cookiec);
3822 bioerror(bp, EINVAL);
3823 if (new_cmd) {
3824 mptsas_scsi_destroy_pkt(ap, pkt);
3825 }
3826 return ((struct scsi_pkt *)NULL);
3827 }
3828
3829 /*
3830 * Allocate extra SGL buffer if needed.
3831 */
3832 if ((cmd->cmd_cookiec > MPTSAS_MAX_FRAME_SGES64(mpt)) &&
3833 (cmd->cmd_extra_frames == NULL)) {
3834 if (mptsas_alloc_extra_sgl_frame(mpt, cmd) ==
3835 DDI_FAILURE) {
3836 mptsas_log(mpt, CE_WARN, "MPT SGL mem alloc "
3837 "failed");
3838 bioerror(bp, ENOMEM);
3839 if (new_cmd) {
3840 mptsas_scsi_destroy_pkt(ap, pkt);
3841 }
3842 return ((struct scsi_pkt *)NULL);
3843 }
3844 }
3845
3846 /*
3847 * Always use scatter-gather transfer
3848 * Use the loop below to store physical addresses of
3849 * DMA segments, from the DMA cookies, into your HBA's
3850 * scatter-gather list.
3851 * We need to ensure we have enough kmem alloc'd
3852 * for the sg entries since we are no longer using an
3853 * array inside mptsas_cmd_t.
3854 *
3855 * We check cmd->cmd_cookiec against oldcookiec so
3856 * the scatter-gather list is correctly allocated
3857 */
3858
3859 if (oldcookiec != cmd->cmd_cookiec) {
3860 if (cmd->cmd_sg != (mptti_t *)NULL) {
3861 kmem_free(cmd->cmd_sg, sizeof (mptti_t) *
3862 oldcookiec);
3863 cmd->cmd_sg = NULL;
3864 }
3865 }
3866
3867 if (cmd->cmd_sg == (mptti_t *)NULL) {
3868 cmd->cmd_sg = kmem_alloc((size_t)(sizeof (mptti_t)*
3869 cmd->cmd_cookiec), kf);
3870
3871 if (cmd->cmd_sg == (mptti_t *)NULL) {
3872 mptsas_log(mpt, CE_WARN,
3873 "unable to kmem_alloc enough memory "
3874 "for scatter/gather list");
3875 /*
3876 * if we have an ENOMEM condition we need to behave
3877 * the same way as the rest of this routine
3878 */
3879
3880 bioerror(bp, ENOMEM);
3881 if (new_cmd) {
3882 mptsas_scsi_destroy_pkt(ap, pkt);
3883 }
3884 return ((struct scsi_pkt *)NULL);
3885 }
3886 }
3887
3888 dmap = cmd->cmd_sg;
3889
3890 ASSERT(cmd->cmd_cookie.dmac_size != 0);
3891
3892 /*
3893 * store the first segment into the S/G list
3894 */
3895 dmap->count = cmd->cmd_cookie.dmac_size;
3896 dmap->addr.address64.Low = (uint32_t)
3897 (cmd->cmd_cookie.dmac_laddress & 0xffffffffull);
3898 dmap->addr.address64.High = (uint32_t)
3899 (cmd->cmd_cookie.dmac_laddress >> 32);
3900
3901 /*
3902 * dmacount counts the size of the dma for this window
3903 * (if partial dma is being used). totaldmacount
3904 * keeps track of the total amount of dma we have
3905 * transferred for all the windows (needed to calculate
3906 * the resid value below).
3907 */
3908 cmd->cmd_dmacount = cmd->cmd_cookie.dmac_size;
3909 cmd->cmd_totaldmacount += cmd->cmd_cookie.dmac_size;
3910
3911 /*
3912 * We already stored the first DMA scatter gather segment,
3913 * start at 1 if we need to store more.
3914 */
3915 for (cnt = 1; cnt < cmd->cmd_cookiec; cnt++) {
3916 /*
3917 * Get next DMA cookie
3918 */
3919 ddi_dma_nextcookie(cmd->cmd_dmahandle,
3920 &cmd->cmd_cookie);
3921 dmap++;
3922
3923 cmd->cmd_dmacount += cmd->cmd_cookie.dmac_size;
3924 cmd->cmd_totaldmacount += cmd->cmd_cookie.dmac_size;
3925
3926 /*
3927 * store the segment parms into the S/G list
3928 */
3929 dmap->count = cmd->cmd_cookie.dmac_size;
3930 dmap->addr.address64.Low = (uint32_t)
3931 (cmd->cmd_cookie.dmac_laddress & 0xffffffffull);
3932 dmap->addr.address64.High = (uint32_t)
3933 (cmd->cmd_cookie.dmac_laddress >> 32);
3934 }
3935
3936 /*
3937 * If this was partially allocated we set the resid
3938 * the amount of data NOT transferred in this window
3939 * If there is only one window, the resid will be 0
3940 */
3941 pkt->pkt_resid = (bp->b_bcount - cmd->cmd_totaldmacount);
3942 NDBG3(("mptsas_scsi_init_pkt: cmd_dmacount=%d.",
3943 cmd->cmd_dmacount));
3944 }
3945 return (pkt);
3946 }
3947
3948 /*
3949 * tran_destroy_pkt(9E) - scsi_pkt(9s) deallocation
3950 *
3951 * Notes:
3952 * - also frees DMA resources if allocated
3953 * - implicit DMA synchonization
3954 */
3955 static void
3956 mptsas_scsi_destroy_pkt(struct scsi_address *ap, struct scsi_pkt *pkt)
3957 {
3958 mptsas_cmd_t *cmd = PKT2CMD(pkt);
3959 mptsas_t *mpt = ADDR2MPT(ap);
3960
3961 NDBG3(("mptsas_scsi_destroy_pkt: target=%d pkt=0x%p",
3962 ap->a_target, (void *)pkt));
3963
3964 if (cmd->cmd_flags & CFLAG_DMAVALID) {
3965 (void) ddi_dma_unbind_handle(cmd->cmd_dmahandle);
3966 cmd->cmd_flags &= ~CFLAG_DMAVALID;
3967 }
3968
3969 if (cmd->cmd_sg) {
3970 kmem_free(cmd->cmd_sg, sizeof (mptti_t) * cmd->cmd_cookiec);
3971 cmd->cmd_sg = NULL;
3972 }
3973
3974 mptsas_free_extra_sgl_frame(mpt, cmd);
3975
3976 if ((cmd->cmd_flags &
3977 (CFLAG_FREE | CFLAG_CDBEXTERN | CFLAG_PRIVEXTERN |
3978 CFLAG_SCBEXTERN)) == 0) {
3979 cmd->cmd_flags = CFLAG_FREE;
3980 kmem_cache_free(mpt->m_kmem_cache, (void *)cmd);
3981 } else {
3982 mptsas_pkt_destroy_extern(mpt, cmd);
3983 }
3984 }
3985
3986 /*
3987 * kmem cache constructor and destructor:
3988 * When constructing, we bzero the cmd and allocate the dma handle
3989 * When destructing, just free the dma handle
3990 */
3991 static int
3992 mptsas_kmem_cache_constructor(void *buf, void *cdrarg, int kmflags)
3993 {
3994 mptsas_cmd_t *cmd = buf;
3995 mptsas_t *mpt = cdrarg;
3996 int (*callback)(caddr_t);
3997
3998 callback = (kmflags == KM_SLEEP)? DDI_DMA_SLEEP: DDI_DMA_DONTWAIT;
3999
4000 NDBG4(("mptsas_kmem_cache_constructor"));
4001
4002 /*
4003 * allocate a dma handle
4004 */
4005 if ((ddi_dma_alloc_handle(mpt->m_dip, &mpt->m_io_dma_attr, callback,
4006 NULL, &cmd->cmd_dmahandle)) != DDI_SUCCESS) {
4007 cmd->cmd_dmahandle = NULL;
4008 return (-1);
4009 }
4010 return (0);
4011 }
4012
4013 static void
4014 mptsas_kmem_cache_destructor(void *buf, void *cdrarg)
4015 {
4016 #ifndef __lock_lint
4017 _NOTE(ARGUNUSED(cdrarg))
4018 #endif
4019 mptsas_cmd_t *cmd = buf;
4020
4021 NDBG4(("mptsas_kmem_cache_destructor"));
4022
4023 if (cmd->cmd_dmahandle) {
4024 ddi_dma_free_handle(&cmd->cmd_dmahandle);
4025 cmd->cmd_dmahandle = NULL;
4026 }
4027 }
4028
4029 static int
4030 mptsas_cache_frames_constructor(void *buf, void *cdrarg, int kmflags)
4031 {
4032 mptsas_cache_frames_t *p = buf;
4033 mptsas_t *mpt = cdrarg;
4034 ddi_dma_attr_t frame_dma_attr;
4035 size_t mem_size, alloc_len;
4036 ddi_dma_cookie_t cookie;
4037 uint_t ncookie;
4038 int (*callback)(caddr_t) = (kmflags == KM_SLEEP)
4039 ? DDI_DMA_SLEEP: DDI_DMA_DONTWAIT;
4040
4041 frame_dma_attr = mpt->m_msg_dma_attr;
4042 frame_dma_attr.dma_attr_align = 0x10;
4043 frame_dma_attr.dma_attr_sgllen = 1;
4044
4045 if (ddi_dma_alloc_handle(mpt->m_dip, &frame_dma_attr, callback, NULL,
4046 &p->m_dma_hdl) != DDI_SUCCESS) {
4047 mptsas_log(mpt, CE_WARN, "Unable to allocate dma handle for"
4048 " extra SGL.");
4049 return (DDI_FAILURE);
4050 }
4051
4052 mem_size = (mpt->m_max_request_frames - 1) * mpt->m_req_frame_size;
4053
4054 if (ddi_dma_mem_alloc(p->m_dma_hdl, mem_size, &mpt->m_dev_acc_attr,
4055 DDI_DMA_CONSISTENT, callback, NULL, (caddr_t *)&p->m_frames_addr,
4056 &alloc_len, &p->m_acc_hdl) != DDI_SUCCESS) {
4057 ddi_dma_free_handle(&p->m_dma_hdl);
4058 p->m_dma_hdl = NULL;
4059 mptsas_log(mpt, CE_WARN, "Unable to allocate dma memory for"
4060 " extra SGL.");
4061 return (DDI_FAILURE);
4062 }
4063
4064 if (ddi_dma_addr_bind_handle(p->m_dma_hdl, NULL, p->m_frames_addr,
4065 alloc_len, DDI_DMA_RDWR | DDI_DMA_CONSISTENT, callback, NULL,
4066 &cookie, &ncookie) != DDI_DMA_MAPPED) {
4067 (void) ddi_dma_mem_free(&p->m_acc_hdl);
4068 ddi_dma_free_handle(&p->m_dma_hdl);
4069 p->m_dma_hdl = NULL;
4070 mptsas_log(mpt, CE_WARN, "Unable to bind DMA resources for"
4071 " extra SGL");
4072 return (DDI_FAILURE);
4073 }
4074
4075 /*
4076 * Store the SGL memory address. This chip uses this
4077 * address to dma to and from the driver. The second
4078 * address is the address mpt uses to fill in the SGL.
4079 */
4080 p->m_phys_addr = cookie.dmac_laddress;
4081
4082 return (DDI_SUCCESS);
4083 }
4084
4085 static void
4086 mptsas_cache_frames_destructor(void *buf, void *cdrarg)
4087 {
4088 #ifndef __lock_lint
4089 _NOTE(ARGUNUSED(cdrarg))
4090 #endif
4091 mptsas_cache_frames_t *p = buf;
4092 if (p->m_dma_hdl != NULL) {
4093 (void) ddi_dma_unbind_handle(p->m_dma_hdl);
4094 (void) ddi_dma_mem_free(&p->m_acc_hdl);
4095 ddi_dma_free_handle(&p->m_dma_hdl);
4096 p->m_phys_addr = NULL;
4097 p->m_frames_addr = NULL;
4098 p->m_dma_hdl = NULL;
4099 p->m_acc_hdl = NULL;
4100 }
4101
4102 }
4103
4104 /*
4105 * Figure out if we need to use a different method for the request
4106 * sense buffer and allocate from the map if necessary.
4107 */
4108 static boolean_t
4109 mptsas_cmdarqsize(mptsas_t *mpt, mptsas_cmd_t *cmd, size_t senselength, int kf)
4110 {
4111 if (senselength > mpt->m_req_sense_size) {
4112 unsigned long i;
4113
4114 /* Sense length is limited to an 8 bit value in MPI Spec. */
4115 if (senselength > 255)
4116 senselength = 255;
4117 cmd->cmd_extrqschunks = (senselength +
4118 (mpt->m_req_sense_size - 1))/mpt->m_req_sense_size;
4119 i = (kf == KM_SLEEP ? rmalloc_wait : rmalloc)
4120 (mpt->m_erqsense_map, cmd->cmd_extrqschunks);
4121
4122 if (i == 0)
4123 return (B_FALSE);
4124
4125 cmd->cmd_extrqslen = (uint16_t)senselength;
4126 cmd->cmd_extrqsidx = i - 1;
4127 cmd->cmd_arq_buf = mpt->m_extreq_sense +
4128 (cmd->cmd_extrqsidx * mpt->m_req_sense_size);
4129 } else {
4130 cmd->cmd_rqslen = (uchar_t)senselength;
4131 }
4132
4133 return (B_TRUE);
4134 }
4135
4136 /*
4137 * allocate and deallocate external pkt space (ie. not part of mptsas_cmd)
4138 * for non-standard length cdb, pkt_private, status areas
4139 * if allocation fails, then deallocate all external space and the pkt
4140 */
4141 /* ARGSUSED */
4142 static int
4143 mptsas_pkt_alloc_extern(mptsas_t *mpt, mptsas_cmd_t *cmd,
4144 int cmdlen, int tgtlen, int statuslen, int kf)
4145 {
4146 caddr_t cdbp, scbp, tgt;
4147
4148 NDBG3(("mptsas_pkt_alloc_extern: "
4149 "cmd=0x%p cmdlen=%d tgtlen=%d statuslen=%d kf=%x",
4150 (void *)cmd, cmdlen, tgtlen, statuslen, kf));
4151
4152 tgt = cdbp = scbp = NULL;
4153 cmd->cmd_scblen = statuslen;
4154 cmd->cmd_privlen = (uchar_t)tgtlen;
4155
4156 if (cmdlen > sizeof (cmd->cmd_cdb)) {
4157 if ((cdbp = kmem_zalloc((size_t)cmdlen, kf)) == NULL) {
4158 goto fail;
4159 }
4160 cmd->cmd_pkt->pkt_cdbp = (opaque_t)cdbp;
4161 cmd->cmd_flags |= CFLAG_CDBEXTERN;
4162 }
4163 if (tgtlen > PKT_PRIV_LEN) {
4164 if ((tgt = kmem_zalloc((size_t)tgtlen, kf)) == NULL) {
4165 goto fail;
4166 }
4167 cmd->cmd_flags |= CFLAG_PRIVEXTERN;
4168 cmd->cmd_pkt->pkt_private = tgt;
4169 }
4170 if (statuslen > EXTCMDS_STATUS_SIZE) {
4171 if ((scbp = kmem_zalloc((size_t)statuslen, kf)) == NULL) {
4172 goto fail;
4173 }
4174 cmd->cmd_flags |= CFLAG_SCBEXTERN;
4175 cmd->cmd_pkt->pkt_scbp = (opaque_t)scbp;
4176
4177 /* allocate sense data buf for DMA */
4178 if (mptsas_cmdarqsize(mpt, cmd, statuslen -
4179 MPTSAS_GET_ITEM_OFF(struct scsi_arq_status, sts_sensedata),
4180 kf) == B_FALSE)
4181 goto fail;
4182 }
4183 return (0);
4184 fail:
4185 mptsas_pkt_destroy_extern(mpt, cmd);
4186 return (1);
4187 }
4188
4189 /*
4190 * deallocate external pkt space and deallocate the pkt
4191 */
4192 static void
4193 mptsas_pkt_destroy_extern(mptsas_t *mpt, mptsas_cmd_t *cmd)
4194 {
4195 NDBG3(("mptsas_pkt_destroy_extern: cmd=0x%p", (void *)cmd));
4196
4197 if (cmd->cmd_flags & CFLAG_FREE) {
4198 mptsas_log(mpt, CE_PANIC,
4199 "mptsas_pkt_destroy_extern: freeing free packet");
4200 _NOTE(NOT_REACHED)
4201 /* NOTREACHED */
4202 }
4203 if (cmd->cmd_extrqslen != 0) {
4204 rmfree(mpt->m_erqsense_map, cmd->cmd_extrqschunks,
4205 cmd->cmd_extrqsidx + 1);
4206 }
4207 if (cmd->cmd_flags & CFLAG_CDBEXTERN) {
4208 kmem_free(cmd->cmd_pkt->pkt_cdbp, (size_t)cmd->cmd_cdblen);
4209 }
4210 if (cmd->cmd_flags & CFLAG_SCBEXTERN) {
4211 kmem_free(cmd->cmd_pkt->pkt_scbp, (size_t)cmd->cmd_scblen);
4212 }
4213 if (cmd->cmd_flags & CFLAG_PRIVEXTERN) {
4214 kmem_free(cmd->cmd_pkt->pkt_private, (size_t)cmd->cmd_privlen);
4215 }
4216 cmd->cmd_flags = CFLAG_FREE;
4217 kmem_cache_free(mpt->m_kmem_cache, (void *)cmd);
4218 }
4219
4220 /*
4221 * tran_sync_pkt(9E) - explicit DMA synchronization
4222 */
4223 /*ARGSUSED*/
4224 static void
4225 mptsas_scsi_sync_pkt(struct scsi_address *ap, struct scsi_pkt *pkt)
4226 {
4227 mptsas_cmd_t *cmd = PKT2CMD(pkt);
4228
4229 NDBG3(("mptsas_scsi_sync_pkt: target=%d, pkt=0x%p",
4230 ap->a_target, (void *)pkt));
4231
4232 if (cmd->cmd_dmahandle) {
4233 (void) ddi_dma_sync(cmd->cmd_dmahandle, 0, 0,
4234 (cmd->cmd_flags & CFLAG_DMASEND) ?
4235 DDI_DMA_SYNC_FORDEV : DDI_DMA_SYNC_FORCPU);
4236 }
4237 }
4238
4239 /*
4240 * tran_dmafree(9E) - deallocate DMA resources allocated for command
4241 */
4242 /*ARGSUSED*/
4243 static void
4244 mptsas_scsi_dmafree(struct scsi_address *ap, struct scsi_pkt *pkt)
4245 {
4246 mptsas_cmd_t *cmd = PKT2CMD(pkt);
4247 mptsas_t *mpt = ADDR2MPT(ap);
4248
4249 NDBG3(("mptsas_scsi_dmafree: target=%d pkt=0x%p",
4250 ap->a_target, (void *)pkt));
4251
4252 if (cmd->cmd_flags & CFLAG_DMAVALID) {
4253 (void) ddi_dma_unbind_handle(cmd->cmd_dmahandle);
4254 cmd->cmd_flags &= ~CFLAG_DMAVALID;
4255 }
4256
4257 mptsas_free_extra_sgl_frame(mpt, cmd);
4258 }
4259
4260 static void
4261 mptsas_pkt_comp(struct scsi_pkt *pkt, mptsas_cmd_t *cmd)
4262 {
4263 if ((cmd->cmd_flags & CFLAG_CMDIOPB) &&
4264 (!(cmd->cmd_flags & CFLAG_DMASEND))) {
4265 (void) ddi_dma_sync(cmd->cmd_dmahandle, 0, 0,
4266 DDI_DMA_SYNC_FORCPU);
4267 }
4268 (*pkt->pkt_comp)(pkt);
4269 }
4270
4271 static void
4272 mptsas_sge_mainframe(mptsas_cmd_t *cmd, pMpi2SCSIIORequest_t frame,
4273 ddi_acc_handle_t acc_hdl, uint_t cookiec, uint32_t end_flags)
4274 {
4275 pMpi2SGESimple64_t sge;
4276 mptti_t *dmap;
4277 uint32_t flags;
4278
4279 dmap = cmd->cmd_sg;
4280
4281 sge = (pMpi2SGESimple64_t)(&frame->SGL);
4282 while (cookiec--) {
4283 ddi_put32(acc_hdl,
4284 &sge->Address.Low, dmap->addr.address64.Low);
4285 ddi_put32(acc_hdl,
4286 &sge->Address.High, dmap->addr.address64.High);
4287 ddi_put32(acc_hdl, &sge->FlagsLength,
4288 dmap->count);
4289 flags = ddi_get32(acc_hdl, &sge->FlagsLength);
4290 flags |= ((uint32_t)
4291 (MPI2_SGE_FLAGS_SIMPLE_ELEMENT |
4292 MPI2_SGE_FLAGS_SYSTEM_ADDRESS |
4293 MPI2_SGE_FLAGS_64_BIT_ADDRESSING) <<
4294 MPI2_SGE_FLAGS_SHIFT);
4295
4296 /*
4297 * If this is the last cookie, we set the flags
4298 * to indicate so
4299 */
4300 if (cookiec == 0) {
4301 flags |= end_flags;
4302 }
4303 if (cmd->cmd_flags & CFLAG_DMASEND) {
4304 flags |= (MPI2_SGE_FLAGS_HOST_TO_IOC <<
4305 MPI2_SGE_FLAGS_SHIFT);
4306 } else {
4307 flags |= (MPI2_SGE_FLAGS_IOC_TO_HOST <<
4308 MPI2_SGE_FLAGS_SHIFT);
4309 }
4310 ddi_put32(acc_hdl, &sge->FlagsLength, flags);
4311 dmap++;
4312 sge++;
4313 }
4314 }
4315
4316 static void
4317 mptsas_sge_chain(mptsas_t *mpt, mptsas_cmd_t *cmd,
4318 pMpi2SCSIIORequest_t frame, ddi_acc_handle_t acc_hdl)
4319 {
4320 pMpi2SGESimple64_t sge;
4321 pMpi2SGEChain64_t sgechain;
4322 uint64_t nframe_phys_addr;
4323 uint_t cookiec;
4324 mptti_t *dmap;
4325 uint32_t flags;
4326
4327 /*
4328 * Save the number of entries in the DMA
4329 * Scatter/Gather list
4330 */
4331 cookiec = cmd->cmd_cookiec;
4332
4333 /*
4334 * Hereby we start to deal with multiple frames.
4335 * The process is as follows:
4336 * 1. Determine how many frames are needed for SGL element
4337 * storage; Note that all frames are stored in contiguous
4338 * memory space and in 64-bit DMA mode each element is
4339 * 3 double-words (12 bytes) long.
4340 * 2. Fill up the main frame. We need to do this separately
4341 * since it contains the SCSI IO request header and needs
4342 * dedicated processing. Note that the last 4 double-words
4343 * of the SCSI IO header is for SGL element storage
4344 * (MPI2_SGE_IO_UNION).
4345 * 3. Fill the chain element in the main frame, so the DMA
4346 * engine can use the following frames.
4347 * 4. Enter a loop to fill the remaining frames. Note that the
4348 * last frame contains no chain element. The remaining
4349 * frames go into the mpt SGL buffer allocated on the fly,
4350 * not immediately following the main message frame, as in
4351 * Gen1.
4352 * Some restrictions:
4353 * 1. For 64-bit DMA, the simple element and chain element
4354 * are both of 3 double-words (12 bytes) in size, even
4355 * though all frames are stored in the first 4G of mem
4356 * range and the higher 32-bits of the address are always 0.
4357 * 2. On some controllers (like the 1064/1068), a frame can
4358 * hold SGL elements with the last 1 or 2 double-words
4359 * (4 or 8 bytes) un-used. On these controllers, we should
4360 * recognize that there's not enough room for another SGL
4361 * element and move the sge pointer to the next frame.
4362 */
4363 int i, j, k, l, frames, sgemax;
4364 int temp;
4365 uint8_t chainflags;
4366 uint16_t chainlength;
4367 mptsas_cache_frames_t *p;
4368
4369 /*
4370 * Sgemax is the number of SGE's that will fit
4371 * each extra frame and frames is total
4372 * number of frames we'll need. 1 sge entry per
4373 * frame is reseverd for the chain element thus the -1 below.
4374 */
4375 sgemax = ((mpt->m_req_frame_size / sizeof (MPI2_SGE_SIMPLE64))
4376 - 1);
4377 temp = (cookiec - (MPTSAS_MAX_FRAME_SGES64(mpt) - 1)) / sgemax;
4378
4379 /*
4380 * A little check to see if we need to round up the number
4381 * of frames we need
4382 */
4383 if ((cookiec - (MPTSAS_MAX_FRAME_SGES64(mpt) - 1)) - (temp *
4384 sgemax) > 1) {
4385 frames = (temp + 1);
4386 } else {
4387 frames = temp;
4388 }
4389 dmap = cmd->cmd_sg;
4390 sge = (pMpi2SGESimple64_t)(&frame->SGL);
4391
4392 /*
4393 * First fill in the main frame
4394 */
4395 j = MPTSAS_MAX_FRAME_SGES64(mpt) - 1;
4396 mptsas_sge_mainframe(cmd, frame, acc_hdl, j,
4397 ((uint32_t)(MPI2_SGE_FLAGS_LAST_ELEMENT) <<
4398 MPI2_SGE_FLAGS_SHIFT));
4399 dmap += j;
4400 sge += j;
4401 j++;
4402
4403 /*
4404 * Fill in the chain element in the main frame.
4405 * About calculation on ChainOffset:
4406 * 1. Struct msg_scsi_io_request has 4 double-words (16 bytes)
4407 * in the end reserved for SGL element storage
4408 * (MPI2_SGE_IO_UNION); we should count it in our
4409 * calculation. See its definition in the header file.
4410 * 2. Constant j is the counter of the current SGL element
4411 * that will be processed, and (j - 1) is the number of
4412 * SGL elements that have been processed (stored in the
4413 * main frame).
4414 * 3. ChainOffset value should be in units of double-words (4
4415 * bytes) so the last value should be divided by 4.
4416 */
4417 ddi_put8(acc_hdl, &frame->ChainOffset,
4418 (sizeof (MPI2_SCSI_IO_REQUEST) -
4419 sizeof (MPI2_SGE_IO_UNION) +
4420 (j - 1) * sizeof (MPI2_SGE_SIMPLE64)) >> 2);
4421 sgechain = (pMpi2SGEChain64_t)sge;
4422 chainflags = (MPI2_SGE_FLAGS_CHAIN_ELEMENT |
4423 MPI2_SGE_FLAGS_SYSTEM_ADDRESS |
4424 MPI2_SGE_FLAGS_64_BIT_ADDRESSING);
4425 ddi_put8(acc_hdl, &sgechain->Flags, chainflags);
4426
4427 /*
4428 * The size of the next frame is the accurate size of space
4429 * (in bytes) used to store the SGL elements. j is the counter
4430 * of SGL elements. (j - 1) is the number of SGL elements that
4431 * have been processed (stored in frames).
4432 */
4433 if (frames >= 2) {
4434 ASSERT(mpt->m_req_frame_size >= sizeof (MPI2_SGE_SIMPLE64));
4435 chainlength = mpt->m_req_frame_size /
4436 sizeof (MPI2_SGE_SIMPLE64) *
4437 sizeof (MPI2_SGE_SIMPLE64);
4438 } else {
4439 chainlength = ((cookiec - (j - 1)) *
4440 sizeof (MPI2_SGE_SIMPLE64));
4441 }
4442
4443 p = cmd->cmd_extra_frames;
4444
4445 ddi_put16(acc_hdl, &sgechain->Length, chainlength);
4446 ddi_put32(acc_hdl, &sgechain->Address.Low, p->m_phys_addr);
4447 ddi_put32(acc_hdl, &sgechain->Address.High, p->m_phys_addr >> 32);
4448
4449 /*
4450 * If there are more than 2 frames left we have to
4451 * fill in the next chain offset to the location of
4452 * the chain element in the next frame.
4453 * sgemax is the number of simple elements in an extra
4454 * frame. Note that the value NextChainOffset should be
4455 * in double-words (4 bytes).
4456 */
4457 if (frames >= 2) {
4458 ddi_put8(acc_hdl, &sgechain->NextChainOffset,
4459 (sgemax * sizeof (MPI2_SGE_SIMPLE64)) >> 2);
4460 } else {
4461 ddi_put8(acc_hdl, &sgechain->NextChainOffset, 0);
4462 }
4463
4464 /*
4465 * Jump to next frame;
4466 * Starting here, chain buffers go into the per command SGL.
4467 * This buffer is allocated when chain buffers are needed.
4468 */
4469 sge = (pMpi2SGESimple64_t)p->m_frames_addr;
4470 i = cookiec;
4471
4472 /*
4473 * Start filling in frames with SGE's. If we
4474 * reach the end of frame and still have SGE's
4475 * to fill we need to add a chain element and
4476 * use another frame. j will be our counter
4477 * for what cookie we are at and i will be
4478 * the total cookiec. k is the current frame
4479 */
4480 for (k = 1; k <= frames; k++) {
4481 for (l = 1; (l <= (sgemax + 1)) && (j <= i); j++, l++) {
4482
4483 /*
4484 * If we have reached the end of frame
4485 * and we have more SGE's to fill in
4486 * we have to fill the final entry
4487 * with a chain element and then
4488 * continue to the next frame
4489 */
4490 if ((l == (sgemax + 1)) && (k != frames)) {
4491 sgechain = (pMpi2SGEChain64_t)sge;
4492 j--;
4493 chainflags = (
4494 MPI2_SGE_FLAGS_CHAIN_ELEMENT |
4495 MPI2_SGE_FLAGS_SYSTEM_ADDRESS |
4496 MPI2_SGE_FLAGS_64_BIT_ADDRESSING);
4497 ddi_put8(p->m_acc_hdl,
4498 &sgechain->Flags, chainflags);
4499 /*
4500 * k is the frame counter and (k + 1)
4501 * is the number of the next frame.
4502 * Note that frames are in contiguous
4503 * memory space.
4504 */
4505 nframe_phys_addr = p->m_phys_addr +
4506 (mpt->m_req_frame_size * k);
4507 ddi_put32(p->m_acc_hdl,
4508 &sgechain->Address.Low,
4509 nframe_phys_addr);
4510 ddi_put32(p->m_acc_hdl,
4511 &sgechain->Address.High,
4512 nframe_phys_addr >> 32);
4513
4514 /*
4515 * If there are more than 2 frames left
4516 * we have to next chain offset to
4517 * the location of the chain element
4518 * in the next frame and fill in the
4519 * length of the next chain
4520 */
4521 if ((frames - k) >= 2) {
4522 ddi_put8(p->m_acc_hdl,
4523 &sgechain->NextChainOffset,
4524 (sgemax *
4525 sizeof (MPI2_SGE_SIMPLE64))
4526 >> 2);
4527 ddi_put16(p->m_acc_hdl,
4528 &sgechain->Length,
4529 mpt->m_req_frame_size /
4530 sizeof (MPI2_SGE_SIMPLE64) *
4531 sizeof (MPI2_SGE_SIMPLE64));
4532 } else {
4533 /*
4534 * This is the last frame. Set
4535 * the NextChainOffset to 0 and
4536 * Length is the total size of
4537 * all remaining simple elements
4538 */
4539 ddi_put8(p->m_acc_hdl,
4540 &sgechain->NextChainOffset,
4541 0);
4542 ddi_put16(p->m_acc_hdl,
4543 &sgechain->Length,
4544 (cookiec - j) *
4545 sizeof (MPI2_SGE_SIMPLE64));
4546 }
4547
4548 /* Jump to the next frame */
4549 sge = (pMpi2SGESimple64_t)
4550 ((char *)p->m_frames_addr +
4551 (int)mpt->m_req_frame_size * k);
4552
4553 continue;
4554 }
4555
4556 ddi_put32(p->m_acc_hdl,
4557 &sge->Address.Low,
4558 dmap->addr.address64.Low);
4559 ddi_put32(p->m_acc_hdl,
4560 &sge->Address.High,
4561 dmap->addr.address64.High);
4562 ddi_put32(p->m_acc_hdl,
4563 &sge->FlagsLength, dmap->count);
4564 flags = ddi_get32(p->m_acc_hdl,
4565 &sge->FlagsLength);
4566 flags |= ((uint32_t)(
4567 MPI2_SGE_FLAGS_SIMPLE_ELEMENT |
4568 MPI2_SGE_FLAGS_SYSTEM_ADDRESS |
4569 MPI2_SGE_FLAGS_64_BIT_ADDRESSING) <<
4570 MPI2_SGE_FLAGS_SHIFT);
4571
4572 /*
4573 * If we are at the end of the frame and
4574 * there is another frame to fill in
4575 * we set the last simple element as last
4576 * element
4577 */
4578 if ((l == sgemax) && (k != frames)) {
4579 flags |= ((uint32_t)
4580 (MPI2_SGE_FLAGS_LAST_ELEMENT) <<
4581 MPI2_SGE_FLAGS_SHIFT);
4582 }
4583
4584 /*
4585 * If this is the final cookie we
4586 * indicate it by setting the flags
4587 */
4588 if (j == i) {
4589 flags |= ((uint32_t)
4590 (MPI2_SGE_FLAGS_LAST_ELEMENT |
4591 MPI2_SGE_FLAGS_END_OF_BUFFER |
4592 MPI2_SGE_FLAGS_END_OF_LIST) <<
4593 MPI2_SGE_FLAGS_SHIFT);
4594 }
4595 if (cmd->cmd_flags & CFLAG_DMASEND) {
4596 flags |=
4597 (MPI2_SGE_FLAGS_HOST_TO_IOC <<
4598 MPI2_SGE_FLAGS_SHIFT);
4599 } else {
4600 flags |=
4601 (MPI2_SGE_FLAGS_IOC_TO_HOST <<
4602 MPI2_SGE_FLAGS_SHIFT);
4603 }
4604 ddi_put32(p->m_acc_hdl,
4605 &sge->FlagsLength, flags);
4606 dmap++;
4607 sge++;
4608 }
4609 }
4610
4611 /*
4612 * Sync DMA with the chain buffers that were just created
4613 */
4614 (void) ddi_dma_sync(p->m_dma_hdl, 0, 0, DDI_DMA_SYNC_FORDEV);
4615 }
4616
4617 static void
4618 mptsas_ieee_sge_mainframe(mptsas_cmd_t *cmd, pMpi2SCSIIORequest_t frame,
4619 ddi_acc_handle_t acc_hdl, uint_t cookiec, uint8_t end_flag)
4620 {
4621 pMpi2IeeeSgeSimple64_t ieeesge;
4622 mptti_t *dmap;
4623 uint8_t flags;
4624
4625 dmap = cmd->cmd_sg;
4626
4627 NDBG1(("mptsas_ieee_sge_mainframe: cookiec=%d, %s", cookiec,
4628 cmd->cmd_flags & CFLAG_DMASEND?"Out":"In"));
4629
4630 ieeesge = (pMpi2IeeeSgeSimple64_t)(&frame->SGL);
4631 while (cookiec--) {
4632 ddi_put32(acc_hdl,
4633 &ieeesge->Address.Low, dmap->addr.address64.Low);
4634 ddi_put32(acc_hdl,
4635 &ieeesge->Address.High, dmap->addr.address64.High);
4636 ddi_put32(acc_hdl, &ieeesge->Length,
4637 dmap->count);
4638 NDBG1(("mptsas_ieee_sge_mainframe: len=%d", dmap->count));
4639 flags = (MPI2_IEEE_SGE_FLAGS_SIMPLE_ELEMENT |
4640 MPI2_IEEE_SGE_FLAGS_SYSTEM_ADDR);
4641
4642 /*
4643 * If this is the last cookie, we set the flags
4644 * to indicate so
4645 */
4646 if (cookiec == 0) {
4647 flags |= end_flag;
4648 }
4649
4650 ddi_put8(acc_hdl, &ieeesge->Flags, flags);
4651 dmap++;
4652 ieeesge++;
4653 }
4654 }
4655
4656 static void
4657 mptsas_ieee_sge_chain(mptsas_t *mpt, mptsas_cmd_t *cmd,
4658 pMpi2SCSIIORequest_t frame, ddi_acc_handle_t acc_hdl)
4659 {
4660 pMpi2IeeeSgeSimple64_t ieeesge;
4661 pMpi25IeeeSgeChain64_t ieeesgechain;
4662 uint64_t nframe_phys_addr;
4663 uint_t cookiec;
4664 mptti_t *dmap;
4665 uint8_t flags;
4666
4667 /*
4668 * Save the number of entries in the DMA
4669 * Scatter/Gather list
4670 */
4671 cookiec = cmd->cmd_cookiec;
4672
4673 NDBG1(("mptsas_ieee_sge_chain: cookiec=%d", cookiec));
4674
4675 /*
4676 * Hereby we start to deal with multiple frames.
4677 * The process is as follows:
4678 * 1. Determine how many frames are needed for SGL element
4679 * storage; Note that all frames are stored in contiguous
4680 * memory space and in 64-bit DMA mode each element is
4681 * 4 double-words (16 bytes) long.
4682 * 2. Fill up the main frame. We need to do this separately
4683 * since it contains the SCSI IO request header and needs
4684 * dedicated processing. Note that the last 4 double-words
4685 * of the SCSI IO header is for SGL element storage
4686 * (MPI2_SGE_IO_UNION).
4687 * 3. Fill the chain element in the main frame, so the DMA
4688 * engine can use the following frames.
4689 * 4. Enter a loop to fill the remaining frames. Note that the
4690 * last frame contains no chain element. The remaining
4691 * frames go into the mpt SGL buffer allocated on the fly,
4692 * not immediately following the main message frame, as in
4693 * Gen1.
4694 * Restrictions:
4695 * For 64-bit DMA, the simple element and chain element
4696 * are both of 4 double-words (16 bytes) in size, even
4697 * though all frames are stored in the first 4G of mem
4698 * range and the higher 32-bits of the address are always 0.
4699 */
4700 int i, j, k, l, frames, sgemax;
4701 int temp;
4702 uint8_t chainflags;
4703 uint32_t chainlength;
4704 mptsas_cache_frames_t *p;
4705
4706 /*
4707 * Sgemax is the number of SGE's that will fit
4708 * each extra frame and frames is total
4709 * number of frames we'll need. 1 sge entry per
4710 * frame is reseverd for the chain element thus the -1 below.
4711 */
4712 sgemax = ((mpt->m_req_frame_size / sizeof (MPI2_IEEE_SGE_SIMPLE64))
4713 - 1);
4714 temp = (cookiec - (MPTSAS_MAX_FRAME_SGES64(mpt) - 1)) / sgemax;
4715
4716 /*
4717 * A little check to see if we need to round up the number
4718 * of frames we need
4719 */
4720 if ((cookiec - (MPTSAS_MAX_FRAME_SGES64(mpt) - 1)) - (temp *
4721 sgemax) > 1) {
4722 frames = (temp + 1);
4723 } else {
4724 frames = temp;
4725 }
4726 NDBG1(("mptsas_ieee_sge_chain: temp=%d, frames=%d", temp, frames));
4727 dmap = cmd->cmd_sg;
4728 ieeesge = (pMpi2IeeeSgeSimple64_t)(&frame->SGL);
4729
4730 /*
4731 * First fill in the main frame
4732 */
4733 j = MPTSAS_MAX_FRAME_SGES64(mpt) - 1;
4734 mptsas_ieee_sge_mainframe(cmd, frame, acc_hdl, j, 0);
4735 dmap += j;
4736 ieeesge += j;
4737 j++;
4738
4739 /*
4740 * Fill in the chain element in the main frame.
4741 * About calculation on ChainOffset:
4742 * 1. Struct msg_scsi_io_request has 4 double-words (16 bytes)
4743 * in the end reserved for SGL element storage
4744 * (MPI2_SGE_IO_UNION); we should count it in our
4745 * calculation. See its definition in the header file.
4746 * 2. Constant j is the counter of the current SGL element
4747 * that will be processed, and (j - 1) is the number of
4748 * SGL elements that have been processed (stored in the
4749 * main frame).
4750 * 3. ChainOffset value should be in units of quad-words (16
4751 * bytes) so the last value should be divided by 16.
4752 */
4753 ddi_put8(acc_hdl, &frame->ChainOffset,
4754 (sizeof (MPI2_SCSI_IO_REQUEST) -
4755 sizeof (MPI2_SGE_IO_UNION) +
4756 (j - 1) * sizeof (MPI2_IEEE_SGE_SIMPLE64)) >> 4);
4757 ieeesgechain = (pMpi25IeeeSgeChain64_t)ieeesge;
4758 chainflags = (MPI2_IEEE_SGE_FLAGS_CHAIN_ELEMENT |
4759 MPI2_IEEE_SGE_FLAGS_SYSTEM_ADDR);
4760 ddi_put8(acc_hdl, &ieeesgechain->Flags, chainflags);
4761
4762 /*
4763 * The size of the next frame is the accurate size of space
4764 * (in bytes) used to store the SGL elements. j is the counter
4765 * of SGL elements. (j - 1) is the number of SGL elements that
4766 * have been processed (stored in frames).
4767 */
4768 if (frames >= 2) {
4769 ASSERT(mpt->m_req_frame_size >=
4770 sizeof (MPI2_IEEE_SGE_SIMPLE64));
4771 chainlength = mpt->m_req_frame_size /
4772 sizeof (MPI2_IEEE_SGE_SIMPLE64) *
4773 sizeof (MPI2_IEEE_SGE_SIMPLE64);
4774 } else {
4775 chainlength = ((cookiec - (j - 1)) *
4776 sizeof (MPI2_IEEE_SGE_SIMPLE64));
4777 }
4778
4779 p = cmd->cmd_extra_frames;
4780
4781 ddi_put32(acc_hdl, &ieeesgechain->Length, chainlength);
4782 ddi_put32(acc_hdl, &ieeesgechain->Address.Low, p->m_phys_addr);
4783 ddi_put32(acc_hdl, &ieeesgechain->Address.High, p->m_phys_addr >> 32);
4784
4785 /*
4786 * If there are more than 2 frames left we have to
4787 * fill in the next chain offset to the location of
4788 * the chain element in the next frame.
4789 * sgemax is the number of simple elements in an extra
4790 * frame. Note that the value NextChainOffset should be
4791 * in double-words (4 bytes).
4792 */
4793 if (frames >= 2) {
4794 ddi_put8(acc_hdl, &ieeesgechain->NextChainOffset,
4795 (sgemax * sizeof (MPI2_IEEE_SGE_SIMPLE64)) >> 4);
4796 } else {
4797 ddi_put8(acc_hdl, &ieeesgechain->NextChainOffset, 0);
4798 }
4799
4800 /*
4801 * Jump to next frame;
4802 * Starting here, chain buffers go into the per command SGL.
4803 * This buffer is allocated when chain buffers are needed.
4804 */
4805 ieeesge = (pMpi2IeeeSgeSimple64_t)p->m_frames_addr;
4806 i = cookiec;
4807
4808 /*
4809 * Start filling in frames with SGE's. If we
4810 * reach the end of frame and still have SGE's
4811 * to fill we need to add a chain element and
4812 * use another frame. j will be our counter
4813 * for what cookie we are at and i will be
4814 * the total cookiec. k is the current frame
4815 */
4816 for (k = 1; k <= frames; k++) {
4817 for (l = 1; (l <= (sgemax + 1)) && (j <= i); j++, l++) {
4818
4819 /*
4820 * If we have reached the end of frame
4821 * and we have more SGE's to fill in
4822 * we have to fill the final entry
4823 * with a chain element and then
4824 * continue to the next frame
4825 */
4826 if ((l == (sgemax + 1)) && (k != frames)) {
4827 ieeesgechain = (pMpi25IeeeSgeChain64_t)ieeesge;
4828 j--;
4829 chainflags =
4830 MPI2_IEEE_SGE_FLAGS_CHAIN_ELEMENT |
4831 MPI2_IEEE_SGE_FLAGS_SYSTEM_ADDR;
4832 ddi_put8(p->m_acc_hdl,
4833 &ieeesgechain->Flags, chainflags);
4834 /*
4835 * k is the frame counter and (k + 1)
4836 * is the number of the next frame.
4837 * Note that frames are in contiguous
4838 * memory space.
4839 */
4840 nframe_phys_addr = p->m_phys_addr +
4841 (mpt->m_req_frame_size * k);
4842 ddi_put32(p->m_acc_hdl,
4843 &ieeesgechain->Address.Low,
4844 nframe_phys_addr);
4845 ddi_put32(p->m_acc_hdl,
4846 &ieeesgechain->Address.High,
4847 nframe_phys_addr >> 32);
4848
4849 /*
4850 * If there are more than 2 frames left
4851 * we have to next chain offset to
4852 * the location of the chain element
4853 * in the next frame and fill in the
4854 * length of the next chain
4855 */
4856 if ((frames - k) >= 2) {
4857 ddi_put8(p->m_acc_hdl,
4858 &ieeesgechain->NextChainOffset,
4859 (sgemax *
4860 sizeof (MPI2_IEEE_SGE_SIMPLE64))
4861 >> 4);
4862 ASSERT(mpt->m_req_frame_size >=
4863 sizeof (MPI2_IEEE_SGE_SIMPLE64));
4864 ddi_put32(p->m_acc_hdl,
4865 &ieeesgechain->Length,
4866 mpt->m_req_frame_size /
4867 sizeof (MPI2_IEEE_SGE_SIMPLE64) *
4868 sizeof (MPI2_IEEE_SGE_SIMPLE64));
4869 } else {
4870 /*
4871 * This is the last frame. Set
4872 * the NextChainOffset to 0 and
4873 * Length is the total size of
4874 * all remaining simple elements
4875 */
4876 ddi_put8(p->m_acc_hdl,
4877 &ieeesgechain->NextChainOffset,
4878 0);
4879 ddi_put32(p->m_acc_hdl,
4880 &ieeesgechain->Length,
4881 (cookiec - j) *
4882 sizeof (MPI2_IEEE_SGE_SIMPLE64));
4883 }
4884
4885 /* Jump to the next frame */
4886 ieeesge = (pMpi2IeeeSgeSimple64_t)
4887 ((char *)p->m_frames_addr +
4888 (int)mpt->m_req_frame_size * k);
4889
4890 continue;
4891 }
4892
4893 ddi_put32(p->m_acc_hdl,
4894 &ieeesge->Address.Low,
4895 dmap->addr.address64.Low);
4896 ddi_put32(p->m_acc_hdl,
4897 &ieeesge->Address.High,
4898 dmap->addr.address64.High);
4899 ddi_put32(p->m_acc_hdl,
4900 &ieeesge->Length, dmap->count);
4901 flags = (MPI2_IEEE_SGE_FLAGS_SIMPLE_ELEMENT |
4902 MPI2_IEEE_SGE_FLAGS_SYSTEM_ADDR);
4903
4904 /*
4905 * If we are at the end of the frame and
4906 * there is another frame to fill in
4907 * do we need to do anything?
4908 * if ((l == sgemax) && (k != frames)) {
4909 * }
4910 */
4911
4912 /*
4913 * If this is the final cookie set end of list.
4914 */
4915 if (j == i) {
4916 flags |= MPI25_IEEE_SGE_FLAGS_END_OF_LIST;
4917 }
4918
4919 ddi_put8(p->m_acc_hdl, &ieeesge->Flags, flags);
4920 dmap++;
4921 ieeesge++;
4922 }
4923 }
4924
4925 /*
4926 * Sync DMA with the chain buffers that were just created
4927 */
4928 (void) ddi_dma_sync(p->m_dma_hdl, 0, 0, DDI_DMA_SYNC_FORDEV);
4929 }
4930
4931 static void
4932 mptsas_sge_setup(mptsas_t *mpt, mptsas_cmd_t *cmd, uint32_t *control,
4933 pMpi2SCSIIORequest_t frame, ddi_acc_handle_t acc_hdl)
4934 {
4935 ASSERT(cmd->cmd_flags & CFLAG_DMAVALID);
4936
4937 NDBG1(("mptsas_sge_setup: cookiec=%d", cmd->cmd_cookiec));
4938
4939 /*
4940 * Set read/write bit in control.
4941 */
4942 if (cmd->cmd_flags & CFLAG_DMASEND) {
4943 *control |= MPI2_SCSIIO_CONTROL_WRITE;
4944 } else {
4945 *control |= MPI2_SCSIIO_CONTROL_READ;
4946 }
4947
4948 ddi_put32(acc_hdl, &frame->DataLength, cmd->cmd_dmacount);
4949
4950 /*
4951 * We have 4 cases here. First where we can fit all the
4952 * SG elements into the main frame, and the case
4953 * where we can't. The SG element is also different when using
4954 * MPI2.5 interface.
4955 * If we have more cookies than we can attach to a frame
4956 * we will need to use a chain element to point
4957 * a location of memory where the rest of the S/G
4958 * elements reside.
4959 */
4960 if (cmd->cmd_cookiec <= MPTSAS_MAX_FRAME_SGES64(mpt)) {
4961 if (mpt->m_MPI25) {
4962 mptsas_ieee_sge_mainframe(cmd, frame, acc_hdl,
4963 cmd->cmd_cookiec,
4964 MPI25_IEEE_SGE_FLAGS_END_OF_LIST);
4965 } else {
4966 mptsas_sge_mainframe(cmd, frame, acc_hdl,
4967 cmd->cmd_cookiec,
4968 ((uint32_t)(MPI2_SGE_FLAGS_LAST_ELEMENT
4969 | MPI2_SGE_FLAGS_END_OF_BUFFER
4970 | MPI2_SGE_FLAGS_END_OF_LIST) <<
4971 MPI2_SGE_FLAGS_SHIFT));
4972 }
4973 } else {
4974 if (mpt->m_MPI25) {
4975 mptsas_ieee_sge_chain(mpt, cmd, frame, acc_hdl);
4976 } else {
4977 mptsas_sge_chain(mpt, cmd, frame, acc_hdl);
4978 }
4979 }
4980 }
4981
4982 /*
4983 * Interrupt handling
4984 * Utility routine. Poll for status of a command sent to HBA
4985 * without interrupts (a FLAG_NOINTR command).
4986 */
4987 int
4988 mptsas_poll(mptsas_t *mpt, mptsas_cmd_t *poll_cmd, int polltime)
4989 {
4990 int rval = TRUE;
4991
4992 NDBG5(("mptsas_poll: cmd=0x%p", (void *)poll_cmd));
4993
4994 if ((poll_cmd->cmd_flags & CFLAG_TM_CMD) == 0) {
4995 mptsas_restart_hba(mpt);
4996 }
4997
4998 /*
4999 * Wait, using drv_usecwait(), long enough for the command to
5000 * reasonably return from the target if the target isn't
5001 * "dead". A polled command may well be sent from scsi_poll, and
5002 * there are retries built in to scsi_poll if the transport
5003 * accepted the packet (TRAN_ACCEPT). scsi_poll waits 1 second
5004 * and retries the transport up to scsi_poll_busycnt times
5005 * (currently 60) if
5006 * 1. pkt_reason is CMD_INCOMPLETE and pkt_state is 0, or
5007 * 2. pkt_reason is CMD_CMPLT and *pkt_scbp has STATUS_BUSY
5008 *
5009 * limit the waiting to avoid a hang in the event that the
5010 * cmd never gets started but we are still receiving interrupts
5011 */
5012 while (!(poll_cmd->cmd_flags & CFLAG_FINISHED)) {
5013 if (mptsas_wait_intr(mpt, polltime) == FALSE) {
5014 NDBG5(("mptsas_poll: command incomplete"));
5015 rval = FALSE;
5016 break;
5017 }
5018 }
5019
5020 if (rval == FALSE) {
5021
5022 /*
5023 * this isn't supposed to happen, the hba must be wedged
5024 * Mark this cmd as a timeout.
5025 */
5026 mptsas_set_pkt_reason(mpt, poll_cmd, CMD_TIMEOUT,
5027 (STAT_TIMEOUT|STAT_ABORTED));
5028
5029 if (poll_cmd->cmd_queued == FALSE) {
5030
5031 NDBG5(("mptsas_poll: not on waitq"));
5032
5033 poll_cmd->cmd_pkt->pkt_state |=
5034 (STATE_GOT_BUS|STATE_GOT_TARGET|STATE_SENT_CMD);
5035 } else {
5036
5037 /* find and remove it from the waitq */
5038 NDBG5(("mptsas_poll: delete from waitq"));
5039 mptsas_waitq_delete(mpt, poll_cmd);
5040 }
5041
5042 }
5043 mptsas_fma_check(mpt, poll_cmd);
5044 NDBG5(("mptsas_poll: done"));
5045 return (rval);
5046 }
5047
5048 /*
5049 * Used for polling cmds and TM function
5050 */
5051 static int
5052 mptsas_wait_intr(mptsas_t *mpt, int polltime)
5053 {
5054 int cnt;
5055 pMpi2ReplyDescriptorsUnion_t reply_desc_union;
5056 uint32_t int_mask;
5057
5058 NDBG5(("mptsas_wait_intr"));
5059
5060 mpt->m_polled_intr = 1;
5061
5062 /*
5063 * Get the current interrupt mask and disable interrupts. When
5064 * re-enabling ints, set mask to saved value.
5065 */
5066 int_mask = ddi_get32(mpt->m_datap, &mpt->m_reg->HostInterruptMask);
5067 MPTSAS_DISABLE_INTR(mpt);
5068
5069 /*
5070 * Keep polling for at least (polltime * 1000) seconds
5071 */
5072 for (cnt = 0; cnt < polltime; cnt++) {
5073 (void) ddi_dma_sync(mpt->m_dma_post_queue_hdl, 0, 0,
5074 DDI_DMA_SYNC_FORCPU);
5075
5076 reply_desc_union = (pMpi2ReplyDescriptorsUnion_t)
5077 MPTSAS_GET_NEXT_REPLY(mpt, mpt->m_post_index);
5078
5079 if (ddi_get32(mpt->m_acc_post_queue_hdl,
5080 &reply_desc_union->Words.Low) == 0xFFFFFFFF ||
5081 ddi_get32(mpt->m_acc_post_queue_hdl,
5082 &reply_desc_union->Words.High) == 0xFFFFFFFF) {
5083 drv_usecwait(1000);
5084 continue;
5085 }
5086
5087 /*
5088 * The reply is valid, process it according to its
5089 * type.
5090 */
5091 mptsas_process_intr(mpt, reply_desc_union);
5092
5093 if (++mpt->m_post_index == mpt->m_post_queue_depth) {
5094 mpt->m_post_index = 0;
5095 }
5096
5097 /*
5098 * Update the global reply index
5099 */
5100 ddi_put32(mpt->m_datap,
5101 &mpt->m_reg->ReplyPostHostIndex, mpt->m_post_index);
5102 mpt->m_polled_intr = 0;
5103
5104 /*
5105 * Re-enable interrupts and quit.
5106 */
5107 ddi_put32(mpt->m_datap, &mpt->m_reg->HostInterruptMask,
5108 int_mask);
5109 return (TRUE);
5110
5111 }
5112
5113 /*
5114 * Clear polling flag, re-enable interrupts and quit.
5115 */
5116 mpt->m_polled_intr = 0;
5117 ddi_put32(mpt->m_datap, &mpt->m_reg->HostInterruptMask, int_mask);
5118 return (FALSE);
5119 }
5120
5121 static void
5122 mptsas_handle_scsi_io_success(mptsas_t *mpt,
5123 pMpi2ReplyDescriptorsUnion_t reply_desc)
5124 {
5125 pMpi2SCSIIOSuccessReplyDescriptor_t scsi_io_success;
5126 uint16_t SMID;
5127 mptsas_slots_t *slots = mpt->m_active;
5128 mptsas_cmd_t *cmd = NULL;
5129 struct scsi_pkt *pkt;
5130
5131 ASSERT(mutex_owned(&mpt->m_mutex));
5132
5133 scsi_io_success = (pMpi2SCSIIOSuccessReplyDescriptor_t)reply_desc;
5134 SMID = ddi_get16(mpt->m_acc_post_queue_hdl, &scsi_io_success->SMID);
5135
5136 /*
5137 * This is a success reply so just complete the IO. First, do a sanity
5138 * check on the SMID. The final slot is used for TM requests, which
5139 * would not come into this reply handler.
5140 */
5141 if ((SMID == 0) || (SMID > slots->m_n_normal)) {
5142 mptsas_log(mpt, CE_WARN, "?Received invalid SMID of %d\n",
5143 SMID);
5144 ddi_fm_service_impact(mpt->m_dip, DDI_SERVICE_UNAFFECTED);
5145 return;
5146 }
5147
5148 cmd = slots->m_slot[SMID];
5149
5150 /*
5151 * print warning and return if the slot is empty
5152 */
5153 if (cmd == NULL) {
5154 mptsas_log(mpt, CE_WARN, "?NULL command for successful SCSI IO "
5155 "in slot %d", SMID);
5156 return;
5157 }
5158
5159 pkt = CMD2PKT(cmd);
5160 pkt->pkt_state |= (STATE_GOT_BUS | STATE_GOT_TARGET | STATE_SENT_CMD |
5161 STATE_GOT_STATUS);
5162 if (cmd->cmd_flags & CFLAG_DMAVALID) {
5163 pkt->pkt_state |= STATE_XFERRED_DATA;
5164 }
5165 pkt->pkt_resid = 0;
5166
5167 if (cmd->cmd_flags & CFLAG_PASSTHRU) {
5168 cmd->cmd_flags |= CFLAG_FINISHED;
5169 cv_broadcast(&mpt->m_passthru_cv);
5170 return;
5171 } else {
5172 mptsas_remove_cmd(mpt, cmd);
5173 }
5174
5175 if (cmd->cmd_flags & CFLAG_RETRY) {
5176 /*
5177 * The target returned QFULL or busy, do not add tihs
5178 * pkt to the doneq since the hba will retry
5179 * this cmd.
5180 *
5181 * The pkt has already been resubmitted in
5182 * mptsas_handle_qfull() or in mptsas_check_scsi_io_error().
5183 * Remove this cmd_flag here.
5184 */
5185 cmd->cmd_flags &= ~CFLAG_RETRY;
5186 } else {
5187 mptsas_doneq_add(mpt, cmd);
5188 }
5189 }
5190
5191 static void
5192 mptsas_handle_address_reply(mptsas_t *mpt,
5193 pMpi2ReplyDescriptorsUnion_t reply_desc)
5194 {
5195 pMpi2AddressReplyDescriptor_t address_reply;
5196 pMPI2DefaultReply_t reply;
5197 mptsas_fw_diagnostic_buffer_t *pBuffer;
5198 uint32_t reply_addr, reply_frame_dma_baseaddr;
5199 uint16_t SMID, iocstatus;
5200 mptsas_slots_t *slots = mpt->m_active;
5201 mptsas_cmd_t *cmd = NULL;
5202 uint8_t function, buffer_type;
5203 m_replyh_arg_t *args;
5204 int reply_frame_no;
5205
5206 ASSERT(mutex_owned(&mpt->m_mutex));
5207
5208 address_reply = (pMpi2AddressReplyDescriptor_t)reply_desc;
5209 reply_addr = ddi_get32(mpt->m_acc_post_queue_hdl,
5210 &address_reply->ReplyFrameAddress);
5211 SMID = ddi_get16(mpt->m_acc_post_queue_hdl, &address_reply->SMID);
5212
5213 /*
5214 * If reply frame is not in the proper range we should ignore this
5215 * message and exit the interrupt handler.
5216 */
5217 reply_frame_dma_baseaddr = mpt->m_reply_frame_dma_addr & 0xffffffffu;
5218 if ((reply_addr < reply_frame_dma_baseaddr) ||
5219 (reply_addr >= (reply_frame_dma_baseaddr +
5220 (mpt->m_reply_frame_size * mpt->m_max_replies))) ||
5221 ((reply_addr - reply_frame_dma_baseaddr) %
5222 mpt->m_reply_frame_size != 0)) {
5223 mptsas_log(mpt, CE_WARN, "?Received invalid reply frame "
5224 "address 0x%x\n", reply_addr);
5225 ddi_fm_service_impact(mpt->m_dip, DDI_SERVICE_UNAFFECTED);
5226 return;
5227 }
5228
5229 (void) ddi_dma_sync(mpt->m_dma_reply_frame_hdl, 0, 0,
5230 DDI_DMA_SYNC_FORCPU);
5231 reply = (pMPI2DefaultReply_t)(mpt->m_reply_frame + (reply_addr -
5232 reply_frame_dma_baseaddr));
5233 function = ddi_get8(mpt->m_acc_reply_frame_hdl, &reply->Function);
5234
5235 NDBG31(("mptsas_handle_address_reply: function 0x%x, reply_addr=0x%x",
5236 function, reply_addr));
5237
5238 /*
5239 * don't get slot information and command for events since these values
5240 * don't exist
5241 */
5242 if ((function != MPI2_FUNCTION_EVENT_NOTIFICATION) &&
5243 (function != MPI2_FUNCTION_DIAG_BUFFER_POST)) {
5244 /*
5245 * This could be a TM reply, which use the last allocated SMID,
5246 * so allow for that.
5247 */
5248 if ((SMID == 0) || (SMID > (slots->m_n_normal + 1))) {
5249 mptsas_log(mpt, CE_WARN, "?Received invalid SMID of "
5250 "%d\n", SMID);
5251 ddi_fm_service_impact(mpt->m_dip,
5252 DDI_SERVICE_UNAFFECTED);
5253 return;
5254 }
5255
5256 cmd = slots->m_slot[SMID];
5257
5258 /*
5259 * print warning and return if the slot is empty
5260 */
5261 if (cmd == NULL) {
5262 mptsas_log(mpt, CE_WARN, "?NULL command for address "
5263 "reply in slot %d", SMID);
5264 return;
5265 }
5266 if ((cmd->cmd_flags &
5267 (CFLAG_PASSTHRU | CFLAG_CONFIG | CFLAG_FW_DIAG))) {
5268 cmd->cmd_rfm = reply_addr;
5269 cmd->cmd_flags |= CFLAG_FINISHED;
5270 cv_broadcast(&mpt->m_passthru_cv);
5271 cv_broadcast(&mpt->m_config_cv);
5272 cv_broadcast(&mpt->m_fw_diag_cv);
5273 return;
5274 } else if (!(cmd->cmd_flags & CFLAG_FW_CMD)) {
5275 mptsas_remove_cmd(mpt, cmd);
5276 }
5277 NDBG31(("\t\tmptsas_process_intr: slot=%d", SMID));
5278 }
5279 /*
5280 * Depending on the function, we need to handle
5281 * the reply frame (and cmd) differently.
5282 */
5283 switch (function) {
5284 case MPI2_FUNCTION_SCSI_IO_REQUEST:
5285 mptsas_check_scsi_io_error(mpt, (pMpi2SCSIIOReply_t)reply, cmd);
5286 break;
5287 case MPI2_FUNCTION_SCSI_TASK_MGMT:
5288 cmd->cmd_rfm = reply_addr;
5289 mptsas_check_task_mgt(mpt, (pMpi2SCSIManagementReply_t)reply,
5290 cmd);
5291 break;
5292 case MPI2_FUNCTION_FW_DOWNLOAD:
5293 cmd->cmd_flags |= CFLAG_FINISHED;
5294 cv_signal(&mpt->m_fw_cv);
5295 break;
5296 case MPI2_FUNCTION_EVENT_NOTIFICATION:
5297 reply_frame_no = (reply_addr - reply_frame_dma_baseaddr) /
5298 mpt->m_reply_frame_size;
5299 args = &mpt->m_replyh_args[reply_frame_no];
5300 args->mpt = (void *)mpt;
5301 args->rfm = reply_addr;
5302
5303 /*
5304 * Record the event if its type is enabled in
5305 * this mpt instance by ioctl.
5306 */
5307 mptsas_record_event(args);
5308
5309 /*
5310 * Handle time critical events
5311 * NOT_RESPONDING/ADDED only now
5312 */
5313 if (mptsas_handle_event_sync(args) == DDI_SUCCESS) {
5314 /*
5315 * Would not return main process,
5316 * just let taskq resolve ack action
5317 * and ack would be sent in taskq thread
5318 */
5319 NDBG20(("send mptsas_handle_event_sync success"));
5320 }
5321
5322 if (mpt->m_in_reset) {
5323 NDBG20(("dropping event received during reset"));
5324 return;
5325 }
5326
5327 if ((ddi_taskq_dispatch(mpt->m_event_taskq, mptsas_handle_event,
5328 (void *)args, DDI_NOSLEEP)) != DDI_SUCCESS) {
5329 mptsas_log(mpt, CE_WARN, "No memory available"
5330 "for dispatch taskq");
5331 /*
5332 * Return the reply frame to the free queue.
5333 */
5334 ddi_put32(mpt->m_acc_free_queue_hdl,
5335 &((uint32_t *)(void *)
5336 mpt->m_free_queue)[mpt->m_free_index], reply_addr);
5337 (void) ddi_dma_sync(mpt->m_dma_free_queue_hdl, 0, 0,
5338 DDI_DMA_SYNC_FORDEV);
5339 if (++mpt->m_free_index == mpt->m_free_queue_depth) {
5340 mpt->m_free_index = 0;
5341 }
5342
5343 ddi_put32(mpt->m_datap,
5344 &mpt->m_reg->ReplyFreeHostIndex, mpt->m_free_index);
5345 }
5346 return;
5347 case MPI2_FUNCTION_DIAG_BUFFER_POST:
5348 /*
5349 * If SMID is 0, this implies that the reply is due to a
5350 * release function with a status that the buffer has been
5351 * released. Set the buffer flags accordingly.
5352 */
5353 if (SMID == 0) {
5354 iocstatus = ddi_get16(mpt->m_acc_reply_frame_hdl,
5355 &reply->IOCStatus);
5356 buffer_type = ddi_get8(mpt->m_acc_reply_frame_hdl,
5357 &(((pMpi2DiagBufferPostReply_t)reply)->BufferType));
5358 if (iocstatus == MPI2_IOCSTATUS_DIAGNOSTIC_RELEASED) {
5359 pBuffer =
5360 &mpt->m_fw_diag_buffer_list[buffer_type];
5361 pBuffer->valid_data = TRUE;
5362 pBuffer->owned_by_firmware = FALSE;
5363 pBuffer->immediate = FALSE;
5364 }
5365 } else {
5366 /*
5367 * Normal handling of diag post reply with SMID.
5368 */
5369 cmd = slots->m_slot[SMID];
5370
5371 /*
5372 * print warning and return if the slot is empty
5373 */
5374 if (cmd == NULL) {
5375 mptsas_log(mpt, CE_WARN, "?NULL command for "
5376 "address reply in slot %d", SMID);
5377 return;
5378 }
5379 cmd->cmd_rfm = reply_addr;
5380 cmd->cmd_flags |= CFLAG_FINISHED;
5381 cv_broadcast(&mpt->m_fw_diag_cv);
5382 }
5383 return;
5384 default:
5385 mptsas_log(mpt, CE_WARN, "Unknown function 0x%x ", function);
5386 break;
5387 }
5388
5389 /*
5390 * Return the reply frame to the free queue.
5391 */
5392 ddi_put32(mpt->m_acc_free_queue_hdl,
5393 &((uint32_t *)(void *)mpt->m_free_queue)[mpt->m_free_index],
5394 reply_addr);
5395 (void) ddi_dma_sync(mpt->m_dma_free_queue_hdl, 0, 0,
5396 DDI_DMA_SYNC_FORDEV);
5397 if (++mpt->m_free_index == mpt->m_free_queue_depth) {
5398 mpt->m_free_index = 0;
5399 }
5400 ddi_put32(mpt->m_datap, &mpt->m_reg->ReplyFreeHostIndex,
5401 mpt->m_free_index);
5402
5403 if (cmd->cmd_flags & CFLAG_FW_CMD)
5404 return;
5405
5406 if (cmd->cmd_flags & CFLAG_RETRY) {
5407 /*
5408 * The target returned QFULL or busy, do not add this
5409 * pkt to the doneq since the hba will retry
5410 * this cmd.
5411 *
5412 * The pkt has already been resubmitted in
5413 * mptsas_handle_qfull() or in mptsas_check_scsi_io_error().
5414 * Remove this cmd_flag here.
5415 */
5416 cmd->cmd_flags &= ~CFLAG_RETRY;
5417 } else {
5418 mptsas_doneq_add(mpt, cmd);
5419 }
5420 }
5421
5422 #ifdef MPTSAS_DEBUG
5423 static uint8_t mptsas_last_sense[256];
5424 #endif
5425
5426 static void
5427 mptsas_check_scsi_io_error(mptsas_t *mpt, pMpi2SCSIIOReply_t reply,
5428 mptsas_cmd_t *cmd)
5429 {
5430 uint8_t scsi_status, scsi_state;
5431 uint16_t ioc_status, cmd_rqs_len;
5432 uint32_t xferred, sensecount, responsedata, loginfo = 0;
5433 struct scsi_pkt *pkt;
5434 struct scsi_arq_status *arqstat;
5435 mptsas_target_t *ptgt = cmd->cmd_tgt_addr;
5436 uint8_t *sensedata = NULL;
5437 uint64_t sas_wwn;
5438 uint8_t phy;
5439 char wwn_str[MPTSAS_WWN_STRLEN];
5440
5441 scsi_status = ddi_get8(mpt->m_acc_reply_frame_hdl, &reply->SCSIStatus);
5442 ioc_status = ddi_get16(mpt->m_acc_reply_frame_hdl, &reply->IOCStatus);
5443 scsi_state = ddi_get8(mpt->m_acc_reply_frame_hdl, &reply->SCSIState);
5444 xferred = ddi_get32(mpt->m_acc_reply_frame_hdl, &reply->TransferCount);
5445 sensecount = ddi_get32(mpt->m_acc_reply_frame_hdl, &reply->SenseCount);
5446 responsedata = ddi_get32(mpt->m_acc_reply_frame_hdl,
5447 &reply->ResponseInfo);
5448
5449 if (ioc_status & MPI2_IOCSTATUS_FLAG_LOG_INFO_AVAILABLE) {
5450 sas_wwn = ptgt->m_addr.mta_wwn;
5451 phy = ptgt->m_phynum;
5452 if (sas_wwn == 0) {
5453 (void) sprintf(wwn_str, "p%x", phy);
5454 } else {
5455 (void) sprintf(wwn_str, "w%016"PRIx64, sas_wwn);
5456 }
5457 loginfo = ddi_get32(mpt->m_acc_reply_frame_hdl,
5458 &reply->IOCLogInfo);
5459 mptsas_log(mpt, CE_NOTE,
5460 "?Log info 0x%x received for target %d %s.\n"
5461 "\tscsi_status=0x%x, ioc_status=0x%x, scsi_state=0x%x",
5462 loginfo, Tgt(cmd), wwn_str, scsi_status, ioc_status,
5463 scsi_state);
5464 }
5465
5466 NDBG31(("\t\tscsi_status=0x%x, ioc_status=0x%x, scsi_state=0x%x",
5467 scsi_status, ioc_status, scsi_state));
5468
5469 pkt = CMD2PKT(cmd);
5470 *(pkt->pkt_scbp) = scsi_status;
5471
5472 if (loginfo == 0x31170000) {
5473 /*
5474 * if loginfo PL_LOGINFO_CODE_IO_DEVICE_MISSING_DELAY_RETRY
5475 * 0x31170000 comes, that means the device missing delay
5476 * is in progressing, the command need retry later.
5477 */
5478 *(pkt->pkt_scbp) = STATUS_BUSY;
5479 return;
5480 }
5481
5482 if ((scsi_state & MPI2_SCSI_STATE_NO_SCSI_STATUS) &&
5483 ((ioc_status & MPI2_IOCSTATUS_MASK) ==
5484 MPI2_IOCSTATUS_SCSI_DEVICE_NOT_THERE)) {
5485 pkt->pkt_reason = CMD_INCOMPLETE;
5486 pkt->pkt_state |= STATE_GOT_BUS;
5487 if (ptgt->m_reset_delay == 0) {
5488 mptsas_set_throttle(mpt, ptgt,
5489 DRAIN_THROTTLE);
5490 }
5491 return;
5492 }
5493
5494 if (scsi_state & MPI2_SCSI_STATE_RESPONSE_INFO_VALID) {
5495 responsedata &= 0x000000FF;
5496 if (responsedata & MPTSAS_SCSI_RESPONSE_CODE_TLR_OFF) {
5497 mptsas_log(mpt, CE_NOTE, "Do not support the TLR\n");
5498 pkt->pkt_reason = CMD_TLR_OFF;
5499 return;
5500 }
5501 }
5502
5503
5504 switch (scsi_status) {
5505 case MPI2_SCSI_STATUS_CHECK_CONDITION:
5506 pkt->pkt_resid = (cmd->cmd_dmacount - xferred);
5507 arqstat = (void*)(pkt->pkt_scbp);
5508 arqstat->sts_rqpkt_status = *((struct scsi_status *)
5509 (pkt->pkt_scbp));
5510 pkt->pkt_state |= (STATE_GOT_BUS | STATE_GOT_TARGET |
5511 STATE_SENT_CMD | STATE_GOT_STATUS | STATE_ARQ_DONE);
5512 if (cmd->cmd_flags & CFLAG_XARQ) {
5513 pkt->pkt_state |= STATE_XARQ_DONE;
5514 }
5515 if (pkt->pkt_resid != cmd->cmd_dmacount) {
5516 pkt->pkt_state |= STATE_XFERRED_DATA;
5517 }
5518 arqstat->sts_rqpkt_reason = pkt->pkt_reason;
5519 arqstat->sts_rqpkt_state = pkt->pkt_state;
5520 arqstat->sts_rqpkt_state |= STATE_XFERRED_DATA;
5521 arqstat->sts_rqpkt_statistics = pkt->pkt_statistics;
5522 sensedata = (uint8_t *)&arqstat->sts_sensedata;
5523 cmd_rqs_len = cmd->cmd_extrqslen ?
5524 cmd->cmd_extrqslen : cmd->cmd_rqslen;
5525 (void) ddi_dma_sync(mpt->m_dma_req_sense_hdl, 0, 0,
5526 DDI_DMA_SYNC_FORKERNEL);
5527 #ifdef MPTSAS_DEBUG
5528 bcopy(cmd->cmd_arq_buf, mptsas_last_sense,
5529 ((cmd_rqs_len >= sizeof (mptsas_last_sense)) ?
5530 sizeof (mptsas_last_sense):cmd_rqs_len));
5531 #endif
5532 bcopy((uchar_t *)cmd->cmd_arq_buf, sensedata,
5533 ((cmd_rqs_len >= sensecount) ? sensecount :
5534 cmd_rqs_len));
5535 arqstat->sts_rqpkt_resid = (cmd_rqs_len - sensecount);
5536 cmd->cmd_flags |= CFLAG_CMDARQ;
5537 /*
5538 * Set proper status for pkt if autosense was valid
5539 */
5540 if (scsi_state & MPI2_SCSI_STATE_AUTOSENSE_VALID) {
5541 struct scsi_status zero_status = { 0 };
5542 arqstat->sts_rqpkt_status = zero_status;
5543 }
5544
5545 /*
5546 * ASC=0x47 is parity error
5547 * ASC=0x48 is initiator detected error received
5548 */
5549 if ((scsi_sense_key(sensedata) == KEY_ABORTED_COMMAND) &&
5550 ((scsi_sense_asc(sensedata) == 0x47) ||
5551 (scsi_sense_asc(sensedata) == 0x48))) {
5552 mptsas_log(mpt, CE_NOTE, "Aborted_command!");
5553 }
5554
5555 /*
5556 * ASC/ASCQ=0x3F/0x0E means report_luns data changed
5557 * ASC/ASCQ=0x25/0x00 means invalid lun
5558 */
5559 if (((scsi_sense_key(sensedata) == KEY_UNIT_ATTENTION) &&
5560 (scsi_sense_asc(sensedata) == 0x3F) &&
5561 (scsi_sense_ascq(sensedata) == 0x0E)) ||
5562 ((scsi_sense_key(sensedata) == KEY_ILLEGAL_REQUEST) &&
5563 (scsi_sense_asc(sensedata) == 0x25) &&
5564 (scsi_sense_ascq(sensedata) == 0x00))) {
5565 mptsas_topo_change_list_t *topo_node = NULL;
5566
5567 topo_node = kmem_zalloc(
5568 sizeof (mptsas_topo_change_list_t),
5569 KM_NOSLEEP);
5570 if (topo_node == NULL) {
5571 mptsas_log(mpt, CE_NOTE, "No memory"
5572 "resource for handle SAS dynamic"
5573 "reconfigure.\n");
5574 break;
5575 }
5576 topo_node->mpt = mpt;
5577 topo_node->event = MPTSAS_DR_EVENT_RECONFIG_TARGET;
5578 topo_node->un.phymask = ptgt->m_addr.mta_phymask;
5579 topo_node->devhdl = ptgt->m_devhdl;
5580 topo_node->object = (void *)ptgt;
5581 topo_node->flags = MPTSAS_TOPO_FLAG_LUN_ASSOCIATED;
5582
5583 if ((ddi_taskq_dispatch(mpt->m_dr_taskq,
5584 mptsas_handle_dr,
5585 (void *)topo_node,
5586 DDI_NOSLEEP)) != DDI_SUCCESS) {
5587 kmem_free(topo_node,
5588 sizeof (mptsas_topo_change_list_t));
5589 mptsas_log(mpt, CE_NOTE, "mptsas start taskq"
5590 "for handle SAS dynamic reconfigure"
5591 "failed. \n");
5592 }
5593 }
5594 break;
5595 case MPI2_SCSI_STATUS_GOOD:
5596 switch (ioc_status & MPI2_IOCSTATUS_MASK) {
5597 case MPI2_IOCSTATUS_SCSI_DEVICE_NOT_THERE:
5598 pkt->pkt_reason = CMD_DEV_GONE;
5599 pkt->pkt_state |= STATE_GOT_BUS;
5600 if (ptgt->m_reset_delay == 0) {
5601 mptsas_set_throttle(mpt, ptgt, DRAIN_THROTTLE);
5602 }
5603 NDBG31(("lost disk for target%d, command:%x",
5604 Tgt(cmd), pkt->pkt_cdbp[0]));
5605 break;
5606 case MPI2_IOCSTATUS_SCSI_DATA_OVERRUN:
5607 NDBG31(("data overrun: xferred=%d", xferred));
5608 NDBG31(("dmacount=%d", cmd->cmd_dmacount));
5609 pkt->pkt_reason = CMD_DATA_OVR;
5610 pkt->pkt_state |= (STATE_GOT_BUS | STATE_GOT_TARGET
5611 | STATE_SENT_CMD | STATE_GOT_STATUS
5612 | STATE_XFERRED_DATA);
5613 pkt->pkt_resid = 0;
5614 break;
5615 case MPI2_IOCSTATUS_SCSI_RESIDUAL_MISMATCH:
5616 case MPI2_IOCSTATUS_SCSI_DATA_UNDERRUN:
5617 NDBG31(("data underrun: xferred=%d", xferred));
5618 NDBG31(("dmacount=%d", cmd->cmd_dmacount));
5619 pkt->pkt_state |= (STATE_GOT_BUS | STATE_GOT_TARGET
5620 | STATE_SENT_CMD | STATE_GOT_STATUS);
5621 pkt->pkt_resid = (cmd->cmd_dmacount - xferred);
5622 if (pkt->pkt_resid != cmd->cmd_dmacount) {
5623 pkt->pkt_state |= STATE_XFERRED_DATA;
5624 }
5625 break;
5626 case MPI2_IOCSTATUS_SCSI_TASK_TERMINATED:
5627 if (cmd->cmd_active_expiration <= gethrtime()) {
5628 /*
5629 * When timeout requested, propagate
5630 * proper reason and statistics to
5631 * target drivers.
5632 */
5633 mptsas_set_pkt_reason(mpt, cmd, CMD_TIMEOUT,
5634 STAT_BUS_RESET | STAT_TIMEOUT);
5635 } else {
5636 mptsas_set_pkt_reason(mpt, cmd, CMD_RESET,
5637 STAT_BUS_RESET);
5638 }
5639 break;
5640 case MPI2_IOCSTATUS_SCSI_IOC_TERMINATED:
5641 case MPI2_IOCSTATUS_SCSI_EXT_TERMINATED:
5642 mptsas_set_pkt_reason(mpt,
5643 cmd, CMD_RESET, STAT_DEV_RESET);
5644 break;
5645 case MPI2_IOCSTATUS_SCSI_IO_DATA_ERROR:
5646 case MPI2_IOCSTATUS_SCSI_PROTOCOL_ERROR:
5647 pkt->pkt_state |= (STATE_GOT_BUS | STATE_GOT_TARGET);
5648 mptsas_set_pkt_reason(mpt,
5649 cmd, CMD_TERMINATED, STAT_TERMINATED);
5650 break;
5651 case MPI2_IOCSTATUS_INSUFFICIENT_RESOURCES:
5652 case MPI2_IOCSTATUS_BUSY:
5653 /*
5654 * set throttles to drain
5655 */
5656 for (ptgt = refhash_first(mpt->m_targets); ptgt != NULL;
5657 ptgt = refhash_next(mpt->m_targets, ptgt)) {
5658 mptsas_set_throttle(mpt, ptgt, DRAIN_THROTTLE);
5659 }
5660
5661 /*
5662 * retry command
5663 */
5664 cmd->cmd_flags |= CFLAG_RETRY;
5665 cmd->cmd_pkt_flags |= FLAG_HEAD;
5666
5667 (void) mptsas_accept_pkt(mpt, cmd);
5668 break;
5669 default:
5670 mptsas_log(mpt, CE_WARN,
5671 "unknown ioc_status = %x\n", ioc_status);
5672 mptsas_log(mpt, CE_CONT, "scsi_state = %x, transfer "
5673 "count = %x, scsi_status = %x", scsi_state,
5674 xferred, scsi_status);
5675 break;
5676 }
5677 break;
5678 case MPI2_SCSI_STATUS_TASK_SET_FULL:
5679 mptsas_handle_qfull(mpt, cmd);
5680 break;
5681 case MPI2_SCSI_STATUS_BUSY:
5682 NDBG31(("scsi_status busy received"));
5683 break;
5684 case MPI2_SCSI_STATUS_RESERVATION_CONFLICT:
5685 NDBG31(("scsi_status reservation conflict received"));
5686 break;
5687 default:
5688 mptsas_log(mpt, CE_WARN, "scsi_status=%x, ioc_status=%x\n",
5689 scsi_status, ioc_status);
5690 mptsas_log(mpt, CE_WARN,
5691 "mptsas_process_intr: invalid scsi status\n");
5692 break;
5693 }
5694 }
5695
5696 static void
5697 mptsas_check_task_mgt(mptsas_t *mpt, pMpi2SCSIManagementReply_t reply,
5698 mptsas_cmd_t *cmd)
5699 {
5700 uint8_t task_type;
5701 uint16_t ioc_status;
5702 uint32_t log_info;
5703 uint16_t dev_handle;
5704 struct scsi_pkt *pkt = CMD2PKT(cmd);
5705
5706 task_type = ddi_get8(mpt->m_acc_reply_frame_hdl, &reply->TaskType);
5707 ioc_status = ddi_get16(mpt->m_acc_reply_frame_hdl, &reply->IOCStatus);
5708 log_info = ddi_get32(mpt->m_acc_reply_frame_hdl, &reply->IOCLogInfo);
5709 dev_handle = ddi_get16(mpt->m_acc_reply_frame_hdl, &reply->DevHandle);
5710
5711 if (ioc_status != MPI2_IOCSTATUS_SUCCESS) {
5712 mptsas_log(mpt, CE_WARN, "mptsas_check_task_mgt: Task 0x%x "
5713 "failed. IOCStatus=0x%x IOCLogInfo=0x%x target=%d\n",
5714 task_type, ioc_status, log_info, dev_handle);
5715 pkt->pkt_reason = CMD_INCOMPLETE;
5716 return;
5717 }
5718
5719 switch (task_type) {
5720 case MPI2_SCSITASKMGMT_TASKTYPE_ABORT_TASK:
5721 case MPI2_SCSITASKMGMT_TASKTYPE_CLEAR_TASK_SET:
5722 case MPI2_SCSITASKMGMT_TASKTYPE_QUERY_TASK:
5723 case MPI2_SCSITASKMGMT_TASKTYPE_CLR_ACA:
5724 case MPI2_SCSITASKMGMT_TASKTYPE_QRY_TASK_SET:
5725 case MPI2_SCSITASKMGMT_TASKTYPE_QRY_UNIT_ATTENTION:
5726 break;
5727 case MPI2_SCSITASKMGMT_TASKTYPE_ABRT_TASK_SET:
5728 case MPI2_SCSITASKMGMT_TASKTYPE_LOGICAL_UNIT_RESET:
5729 case MPI2_SCSITASKMGMT_TASKTYPE_TARGET_RESET:
5730 /*
5731 * Check for invalid DevHandle of 0 in case application
5732 * sends bad command. DevHandle of 0 could cause problems.
5733 */
5734 if (dev_handle == 0) {
5735 mptsas_log(mpt, CE_WARN, "!Can't flush target with"
5736 " DevHandle of 0.");
5737 } else {
5738 mptsas_flush_target(mpt, dev_handle, Lun(cmd),
5739 task_type);
5740 }
5741 break;
5742 default:
5743 mptsas_log(mpt, CE_WARN, "Unknown task management type %d.",
5744 task_type);
5745 mptsas_log(mpt, CE_WARN, "ioc status = %x", ioc_status);
5746 break;
5747 }
5748 }
5749
5750 static void
5751 mptsas_doneq_thread(mptsas_doneq_thread_arg_t *arg)
5752 {
5753 mptsas_t *mpt = arg->mpt;
5754 uint64_t t = arg->t;
5755 mptsas_cmd_t *cmd;
5756 struct scsi_pkt *pkt;
5757 mptsas_doneq_thread_list_t *item = &mpt->m_doneq_thread_id[t];
5758
5759 mutex_enter(&item->mutex);
5760 while (item->flag & MPTSAS_DONEQ_THREAD_ACTIVE) {
5761 if (!item->doneq) {
5762 cv_wait(&item->cv, &item->mutex);
5763 }
5764 pkt = NULL;
5765 if ((cmd = mptsas_doneq_thread_rm(mpt, t)) != NULL) {
5766 cmd->cmd_flags |= CFLAG_COMPLETED;
5767 pkt = CMD2PKT(cmd);
5768 }
5769 mutex_exit(&item->mutex);
5770 if (pkt) {
5771 mptsas_pkt_comp(pkt, cmd);
5772 }
5773 mutex_enter(&item->mutex);
5774 }
5775 mutex_exit(&item->mutex);
5776 mutex_enter(&mpt->m_doneq_mutex);
5777 mpt->m_doneq_thread_n--;
5778 cv_broadcast(&mpt->m_doneq_thread_cv);
5779 mutex_exit(&mpt->m_doneq_mutex);
5780 }
5781
5782
5783 /*
5784 * mpt interrupt handler.
5785 */
5786 static uint_t
5787 mptsas_intr(caddr_t arg1, caddr_t arg2)
5788 {
5789 mptsas_t *mpt = (void *)arg1;
5790 pMpi2ReplyDescriptorsUnion_t reply_desc_union;
5791 uchar_t did_reply = FALSE;
5792
5793 NDBG1(("mptsas_intr: arg1 0x%p arg2 0x%p", (void *)arg1, (void *)arg2));
5794
5795 mutex_enter(&mpt->m_mutex);
5796
5797 /*
5798 * If interrupts are shared by two channels then check whether this
5799 * interrupt is genuinely for this channel by making sure first the
5800 * chip is in high power state.
5801 */
5802 if ((mpt->m_options & MPTSAS_OPT_PM) &&
5803 (mpt->m_power_level != PM_LEVEL_D0)) {
5804 mutex_exit(&mpt->m_mutex);
5805 return (DDI_INTR_UNCLAIMED);
5806 }
5807
5808 /*
5809 * If polling, interrupt was triggered by some shared interrupt because
5810 * IOC interrupts are disabled during polling, so polling routine will
5811 * handle any replies. Considering this, if polling is happening,
5812 * return with interrupt unclaimed.
5813 */
5814 if (mpt->m_polled_intr) {
5815 mutex_exit(&mpt->m_mutex);
5816 mptsas_log(mpt, CE_WARN, "mpt_sas: Unclaimed interrupt");
5817 return (DDI_INTR_UNCLAIMED);
5818 }
5819
5820 /*
5821 * Read the istat register.
5822 */
5823 if ((INTPENDING(mpt)) != 0) {
5824 /*
5825 * read fifo until empty.
5826 */
5827 #ifndef __lock_lint
5828 _NOTE(CONSTCOND)
5829 #endif
5830 while (TRUE) {
5831 (void) ddi_dma_sync(mpt->m_dma_post_queue_hdl, 0, 0,
5832 DDI_DMA_SYNC_FORCPU);
5833 reply_desc_union = (pMpi2ReplyDescriptorsUnion_t)
5834 MPTSAS_GET_NEXT_REPLY(mpt, mpt->m_post_index);
5835
5836 if (ddi_get32(mpt->m_acc_post_queue_hdl,
5837 &reply_desc_union->Words.Low) == 0xFFFFFFFF ||
5838 ddi_get32(mpt->m_acc_post_queue_hdl,
5839 &reply_desc_union->Words.High) == 0xFFFFFFFF) {
5840 break;
5841 }
5842
5843 /*
5844 * The reply is valid, process it according to its
5845 * type. Also, set a flag for updating the reply index
5846 * after they've all been processed.
5847 */
5848 did_reply = TRUE;
5849
5850 mptsas_process_intr(mpt, reply_desc_union);
5851
5852 /*
5853 * Increment post index and roll over if needed.
5854 */
5855 if (++mpt->m_post_index == mpt->m_post_queue_depth) {
5856 mpt->m_post_index = 0;
5857 }
5858 }
5859
5860 /*
5861 * Update the global reply index if at least one reply was
5862 * processed.
5863 */
5864 if (did_reply) {
5865 ddi_put32(mpt->m_datap,
5866 &mpt->m_reg->ReplyPostHostIndex, mpt->m_post_index);
5867 }
5868 } else {
5869 mutex_exit(&mpt->m_mutex);
5870 return (DDI_INTR_UNCLAIMED);
5871 }
5872 NDBG1(("mptsas_intr complete"));
5873
5874 /*
5875 * If no helper threads are created, process the doneq in ISR. If
5876 * helpers are created, use the doneq length as a metric to measure the
5877 * load on the interrupt CPU. If it is long enough, which indicates the
5878 * load is heavy, then we deliver the IO completions to the helpers.
5879 * This measurement has some limitations, although it is simple and
5880 * straightforward and works well for most of the cases at present.
5881 */
5882 if (!mpt->m_doneq_thread_n ||
5883 (mpt->m_doneq_len <= mpt->m_doneq_length_threshold)) {
5884 mptsas_doneq_empty(mpt);
5885 } else {
5886 mptsas_deliver_doneq_thread(mpt);
5887 }
5888
5889 /*
5890 * If there are queued cmd, start them now.
5891 */
5892 if (mpt->m_waitq != NULL) {
5893 mptsas_restart_waitq(mpt);
5894 }
5895
5896 mutex_exit(&mpt->m_mutex);
5897 return (DDI_INTR_CLAIMED);
5898 }
5899
5900 static void
5901 mptsas_process_intr(mptsas_t *mpt,
5902 pMpi2ReplyDescriptorsUnion_t reply_desc_union)
5903 {
5904 uint8_t reply_type;
5905
5906 ASSERT(mutex_owned(&mpt->m_mutex));
5907
5908 /*
5909 * The reply is valid, process it according to its
5910 * type. Also, set a flag for updated the reply index
5911 * after they've all been processed.
5912 */
5913 reply_type = ddi_get8(mpt->m_acc_post_queue_hdl,
5914 &reply_desc_union->Default.ReplyFlags);
5915 reply_type &= MPI2_RPY_DESCRIPT_FLAGS_TYPE_MASK;
5916 if (reply_type == MPI2_RPY_DESCRIPT_FLAGS_SCSI_IO_SUCCESS ||
5917 reply_type == MPI25_RPY_DESCRIPT_FLAGS_FAST_PATH_SCSI_IO_SUCCESS) {
5918 mptsas_handle_scsi_io_success(mpt, reply_desc_union);
5919 } else if (reply_type == MPI2_RPY_DESCRIPT_FLAGS_ADDRESS_REPLY) {
5920 mptsas_handle_address_reply(mpt, reply_desc_union);
5921 } else {
5922 mptsas_log(mpt, CE_WARN, "?Bad reply type %x", reply_type);
5923 ddi_fm_service_impact(mpt->m_dip, DDI_SERVICE_UNAFFECTED);
5924 }
5925
5926 /*
5927 * Clear the reply descriptor for re-use and increment
5928 * index.
5929 */
5930 ddi_put64(mpt->m_acc_post_queue_hdl,
5931 &((uint64_t *)(void *)mpt->m_post_queue)[mpt->m_post_index],
5932 0xFFFFFFFFFFFFFFFF);
5933 (void) ddi_dma_sync(mpt->m_dma_post_queue_hdl, 0, 0,
5934 DDI_DMA_SYNC_FORDEV);
5935 }
5936
5937 /*
5938 * handle qfull condition
5939 */
5940 static void
5941 mptsas_handle_qfull(mptsas_t *mpt, mptsas_cmd_t *cmd)
5942 {
5943 mptsas_target_t *ptgt = cmd->cmd_tgt_addr;
5944
5945 if ((++cmd->cmd_qfull_retries > ptgt->m_qfull_retries) ||
5946 (ptgt->m_qfull_retries == 0)) {
5947 /*
5948 * We have exhausted the retries on QFULL, or,
5949 * the target driver has indicated that it
5950 * wants to handle QFULL itself by setting
5951 * qfull-retries capability to 0. In either case
5952 * we want the target driver's QFULL handling
5953 * to kick in. We do this by having pkt_reason
5954 * as CMD_CMPLT and pkt_scbp as STATUS_QFULL.
5955 */
5956 mptsas_set_throttle(mpt, ptgt, DRAIN_THROTTLE);
5957 } else {
5958 if (ptgt->m_reset_delay == 0) {
5959 ptgt->m_t_throttle =
5960 max((ptgt->m_t_ncmds - 2), 0);
5961 }
5962
5963 cmd->cmd_pkt_flags |= FLAG_HEAD;
5964 cmd->cmd_flags &= ~(CFLAG_TRANFLAG);
5965 cmd->cmd_flags |= CFLAG_RETRY;
5966
5967 (void) mptsas_accept_pkt(mpt, cmd);
5968
5969 /*
5970 * when target gives queue full status with no commands
5971 * outstanding (m_t_ncmds == 0), throttle is set to 0
5972 * (HOLD_THROTTLE), and the queue full handling start
5973 * (see psarc/1994/313); if there are commands outstanding,
5974 * throttle is set to (m_t_ncmds - 2)
5975 */
5976 if (ptgt->m_t_throttle == HOLD_THROTTLE) {
5977 /*
5978 * By setting throttle to QFULL_THROTTLE, we
5979 * avoid submitting new commands and in
5980 * mptsas_restart_cmd find out slots which need
5981 * their throttles to be cleared.
5982 */
5983 mptsas_set_throttle(mpt, ptgt, QFULL_THROTTLE);
5984 if (mpt->m_restart_cmd_timeid == 0) {
5985 mpt->m_restart_cmd_timeid =
5986 timeout(mptsas_restart_cmd, mpt,
5987 ptgt->m_qfull_retry_interval);
5988 }
5989 }
5990 }
5991 }
5992
5993 mptsas_phymask_t
5994 mptsas_physport_to_phymask(mptsas_t *mpt, uint8_t physport)
5995 {
5996 mptsas_phymask_t phy_mask = 0;
5997 uint8_t i = 0;
5998
5999 NDBG20(("mptsas%d physport_to_phymask enter", mpt->m_instance));
6000
6001 ASSERT(mutex_owned(&mpt->m_mutex));
6002
6003 /*
6004 * If physport is 0xFF, this is a RAID volume. Use phymask of 0.
6005 */
6006 if (physport == 0xFF) {
6007 return (0);
6008 }
6009
6010 for (i = 0; i < MPTSAS_MAX_PHYS; i++) {
6011 if (mpt->m_phy_info[i].attached_devhdl &&
6012 (mpt->m_phy_info[i].phy_mask != 0) &&
6013 (mpt->m_phy_info[i].port_num == physport)) {
6014 phy_mask = mpt->m_phy_info[i].phy_mask;
6015 break;
6016 }
6017 }
6018 NDBG20(("mptsas%d physport_to_phymask:physport :%x phymask :%x, ",
6019 mpt->m_instance, physport, phy_mask));
6020 return (phy_mask);
6021 }
6022
6023 /*
6024 * mpt free device handle after device gone, by use of passthrough
6025 */
6026 static int
6027 mptsas_free_devhdl(mptsas_t *mpt, uint16_t devhdl)
6028 {
6029 Mpi2SasIoUnitControlRequest_t req;
6030 Mpi2SasIoUnitControlReply_t rep;
6031 int ret;
6032
6033 ASSERT(mutex_owned(&mpt->m_mutex));
6034
6035 /*
6036 * Need to compose a SAS IO Unit Control request message
6037 * and call mptsas_do_passthru() function
6038 */
6039 bzero(&req, sizeof (req));
6040 bzero(&rep, sizeof (rep));
6041
6042 req.Function = MPI2_FUNCTION_SAS_IO_UNIT_CONTROL;
6043 req.Operation = MPI2_SAS_OP_REMOVE_DEVICE;
6044 req.DevHandle = LE_16(devhdl);
6045
6046 ret = mptsas_do_passthru(mpt, (uint8_t *)&req, (uint8_t *)&rep, NULL,
6047 sizeof (req), sizeof (rep), NULL, 0, NULL, 0, 60, FKIOCTL);
6048 if (ret != 0) {
6049 cmn_err(CE_WARN, "mptsas_free_devhdl: passthru SAS IO Unit "
6050 "Control error %d", ret);
6051 return (DDI_FAILURE);
6052 }
6053
6054 /* do passthrough success, check the ioc status */
6055 if (LE_16(rep.IOCStatus) != MPI2_IOCSTATUS_SUCCESS) {
6056 cmn_err(CE_WARN, "mptsas_free_devhdl: passthru SAS IO Unit "
6057 "Control IOCStatus %d", LE_16(rep.IOCStatus));
6058 return (DDI_FAILURE);
6059 }
6060
6061 return (DDI_SUCCESS);
6062 }
6063
6064 static void
6065 mptsas_update_phymask(mptsas_t *mpt)
6066 {
6067 mptsas_phymask_t mask = 0, phy_mask;
6068 char *phy_mask_name;
6069 uint8_t current_port;
6070 int i, j;
6071
6072 NDBG20(("mptsas%d update phymask ", mpt->m_instance));
6073
6074 ASSERT(mutex_owned(&mpt->m_mutex));
6075
6076 (void) mptsas_get_sas_io_unit_page(mpt);
6077
6078 phy_mask_name = kmem_zalloc(MPTSAS_MAX_PHYS, KM_SLEEP);
6079
6080 for (i = 0; i < mpt->m_num_phys; i++) {
6081 phy_mask = 0x00;
6082
6083 if (mpt->m_phy_info[i].attached_devhdl == 0)
6084 continue;
6085
6086 bzero(phy_mask_name, sizeof (phy_mask_name));
6087
6088 current_port = mpt->m_phy_info[i].port_num;
6089
6090 if ((mask & (1 << i)) != 0)
6091 continue;
6092
6093 for (j = 0; j < mpt->m_num_phys; j++) {
6094 if (mpt->m_phy_info[j].attached_devhdl &&
6095 (mpt->m_phy_info[j].port_num == current_port)) {
6096 phy_mask |= (1 << j);
6097 }
6098 }
6099 mask = mask | phy_mask;
6100
6101 for (j = 0; j < mpt->m_num_phys; j++) {
6102 if ((phy_mask >> j) & 0x01) {
6103 mpt->m_phy_info[j].phy_mask = phy_mask;
6104 }
6105 }
6106
6107 (void) sprintf(phy_mask_name, "%x", phy_mask);
6108
6109 mutex_exit(&mpt->m_mutex);
6110 /*
6111 * register a iport, if the port has already been existed
6112 * SCSA will do nothing and just return.
6113 */
6114 (void) scsi_hba_iport_register(mpt->m_dip, phy_mask_name);
6115 mutex_enter(&mpt->m_mutex);
6116 }
6117 kmem_free(phy_mask_name, MPTSAS_MAX_PHYS);
6118 NDBG20(("mptsas%d update phymask return", mpt->m_instance));
6119 }
6120
6121 /*
6122 * mptsas_handle_dr is a task handler for DR, the DR action includes:
6123 * 1. Directly attched Device Added/Removed.
6124 * 2. Expander Device Added/Removed.
6125 * 3. Indirectly Attached Device Added/Expander.
6126 * 4. LUNs of a existing device status change.
6127 * 5. RAID volume created/deleted.
6128 * 6. Member of RAID volume is released because of RAID deletion.
6129 * 7. Physical disks are removed because of RAID creation.
6130 */
6131 static void
6132 mptsas_handle_dr(void *args) {
6133 mptsas_topo_change_list_t *topo_node = NULL;
6134 mptsas_topo_change_list_t *save_node = NULL;
6135 mptsas_t *mpt;
6136 dev_info_t *parent = NULL;
6137 mptsas_phymask_t phymask = 0;
6138 char *phy_mask_name;
6139 uint8_t flags = 0, physport = 0xff;
6140 uint8_t port_update = 0;
6141 uint_t event;
6142
6143 topo_node = (mptsas_topo_change_list_t *)args;
6144
6145 mpt = topo_node->mpt;
6146 event = topo_node->event;
6147 flags = topo_node->flags;
6148
6149 phy_mask_name = kmem_zalloc(MPTSAS_MAX_PHYS, KM_SLEEP);
6150
6151 NDBG20(("mptsas%d handle_dr enter", mpt->m_instance));
6152
6153 switch (event) {
6154 case MPTSAS_DR_EVENT_RECONFIG_TARGET:
6155 if ((flags == MPTSAS_TOPO_FLAG_DIRECT_ATTACHED_DEVICE) ||
6156 (flags == MPTSAS_TOPO_FLAG_EXPANDER_ATTACHED_DEVICE) ||
6157 (flags == MPTSAS_TOPO_FLAG_RAID_PHYSDRV_ASSOCIATED)) {
6158 /*
6159 * Direct attached or expander attached device added
6160 * into system or a Phys Disk that is being unhidden.
6161 */
6162 port_update = 1;
6163 }
6164 break;
6165 case MPTSAS_DR_EVENT_RECONFIG_SMP:
6166 /*
6167 * New expander added into system, it must be the head
6168 * of topo_change_list_t
6169 */
6170 port_update = 1;
6171 break;
6172 default:
6173 port_update = 0;
6174 break;
6175 }
6176 /*
6177 * All cases port_update == 1 may cause initiator port form change
6178 */
6179 mutex_enter(&mpt->m_mutex);
6180 if (mpt->m_port_chng && port_update) {
6181 /*
6182 * mpt->m_port_chng flag indicates some PHYs of initiator
6183 * port have changed to online. So when expander added or
6184 * directly attached device online event come, we force to
6185 * update port information by issueing SAS IO Unit Page and
6186 * update PHYMASKs.
6187 */
6188 (void) mptsas_update_phymask(mpt);
6189 mpt->m_port_chng = 0;
6190
6191 }
6192 mutex_exit(&mpt->m_mutex);
6193 while (topo_node) {
6194 phymask = 0;
6195 if (parent == NULL) {
6196 physport = topo_node->un.physport;
6197 event = topo_node->event;
6198 flags = topo_node->flags;
6199 if (event & (MPTSAS_DR_EVENT_OFFLINE_TARGET |
6200 MPTSAS_DR_EVENT_OFFLINE_SMP)) {
6201 /*
6202 * For all offline events, phymask is known
6203 */
6204 phymask = topo_node->un.phymask;
6205 goto find_parent;
6206 }
6207 if (event & MPTSAS_TOPO_FLAG_REMOVE_HANDLE) {
6208 goto handle_topo_change;
6209 }
6210 if (flags & MPTSAS_TOPO_FLAG_LUN_ASSOCIATED) {
6211 phymask = topo_node->un.phymask;
6212 goto find_parent;
6213 }
6214
6215 if ((flags ==
6216 MPTSAS_TOPO_FLAG_RAID_PHYSDRV_ASSOCIATED) &&
6217 (event == MPTSAS_DR_EVENT_RECONFIG_TARGET)) {
6218 /*
6219 * There is no any field in IR_CONFIG_CHANGE
6220 * event indicate physport/phynum, let's get
6221 * parent after SAS Device Page0 request.
6222 */
6223 goto handle_topo_change;
6224 }
6225
6226 mutex_enter(&mpt->m_mutex);
6227 if (flags == MPTSAS_TOPO_FLAG_DIRECT_ATTACHED_DEVICE) {
6228 /*
6229 * If the direct attached device added or a
6230 * phys disk is being unhidden, argument
6231 * physport actually is PHY#, so we have to get
6232 * phymask according PHY#.
6233 */
6234 physport = mpt->m_phy_info[physport].port_num;
6235 }
6236
6237 /*
6238 * Translate physport to phymask so that we can search
6239 * parent dip.
6240 */
6241 phymask = mptsas_physport_to_phymask(mpt,
6242 physport);
6243 mutex_exit(&mpt->m_mutex);
6244
6245 find_parent:
6246 bzero(phy_mask_name, MPTSAS_MAX_PHYS);
6247 /*
6248 * For RAID topology change node, write the iport name
6249 * as v0.
6250 */
6251 if (flags & MPTSAS_TOPO_FLAG_RAID_ASSOCIATED) {
6252 (void) sprintf(phy_mask_name, "v0");
6253 } else {
6254 /*
6255 * phymask can bo 0 if the drive has been
6256 * pulled by the time an add event is
6257 * processed. If phymask is 0, just skip this
6258 * event and continue.
6259 */
6260 if (phymask == 0) {
6261 mutex_enter(&mpt->m_mutex);
6262 save_node = topo_node;
6263 topo_node = topo_node->next;
6264 ASSERT(save_node);
6265 kmem_free(save_node,
6266 sizeof (mptsas_topo_change_list_t));
6267 mutex_exit(&mpt->m_mutex);
6268
6269 parent = NULL;
6270 continue;
6271 }
6272 (void) sprintf(phy_mask_name, "%x", phymask);
6273 }
6274 parent = scsi_hba_iport_find(mpt->m_dip,
6275 phy_mask_name);
6276 if (parent == NULL) {
6277 mptsas_log(mpt, CE_WARN, "Failed to find an "
6278 "iport, should not happen!");
6279 goto out;
6280 }
6281
6282 }
6283 ASSERT(parent);
6284 handle_topo_change:
6285
6286 mutex_enter(&mpt->m_mutex);
6287 /*
6288 * If HBA is being reset, don't perform operations depending
6289 * on the IOC. We must free the topo list, however.
6290 */
6291 if (!mpt->m_in_reset)
6292 mptsas_handle_topo_change(topo_node, parent);
6293 else
6294 NDBG20(("skipping topo change received during reset"));
6295 save_node = topo_node;
6296 topo_node = topo_node->next;
6297 ASSERT(save_node);
6298 kmem_free(save_node, sizeof (mptsas_topo_change_list_t));
6299 mutex_exit(&mpt->m_mutex);
6300
6301 if ((flags == MPTSAS_TOPO_FLAG_DIRECT_ATTACHED_DEVICE) ||
6302 (flags == MPTSAS_TOPO_FLAG_RAID_PHYSDRV_ASSOCIATED) ||
6303 (flags == MPTSAS_TOPO_FLAG_RAID_ASSOCIATED)) {
6304 /*
6305 * If direct attached device associated, make sure
6306 * reset the parent before start the next one. But
6307 * all devices associated with expander shares the
6308 * parent. Also, reset parent if this is for RAID.
6309 */
6310 parent = NULL;
6311 }
6312 }
6313 out:
6314 kmem_free(phy_mask_name, MPTSAS_MAX_PHYS);
6315 }
6316
6317 static void
6318 mptsas_handle_topo_change(mptsas_topo_change_list_t *topo_node,
6319 dev_info_t *parent)
6320 {
6321 mptsas_target_t *ptgt = NULL;
6322 mptsas_smp_t *psmp = NULL;
6323 mptsas_t *mpt = (void *)topo_node->mpt;
6324 uint16_t devhdl;
6325 uint16_t attached_devhdl;
6326 uint64_t sas_wwn = 0;
6327 int rval = 0;
6328 uint32_t page_address;
6329 uint8_t phy, flags;
6330 char *addr = NULL;
6331 dev_info_t *lundip;
6332 int circ = 0, circ1 = 0;
6333 char attached_wwnstr[MPTSAS_WWN_STRLEN];
6334
6335 NDBG20(("mptsas%d handle_topo_change enter, devhdl 0x%x,"
6336 "event 0x%x, flags 0x%x", mpt->m_instance, topo_node->devhdl,
6337 topo_node->event, topo_node->flags));
6338
6339 ASSERT(mutex_owned(&mpt->m_mutex));
6340
6341 switch (topo_node->event) {
6342 case MPTSAS_DR_EVENT_RECONFIG_TARGET:
6343 {
6344 char *phy_mask_name;
6345 mptsas_phymask_t phymask = 0;
6346
6347 if (topo_node->flags == MPTSAS_TOPO_FLAG_RAID_ASSOCIATED) {
6348 /*
6349 * Get latest RAID info.
6350 */
6351 (void) mptsas_get_raid_info(mpt);
6352 ptgt = refhash_linear_search(mpt->m_targets,
6353 mptsas_target_eval_devhdl, &topo_node->devhdl);
6354 if (ptgt == NULL)
6355 break;
6356 } else {
6357 ptgt = (void *)topo_node->object;
6358 }
6359
6360 if (ptgt == NULL) {
6361 /*
6362 * If a Phys Disk was deleted, RAID info needs to be
6363 * updated to reflect the new topology.
6364 */
6365 (void) mptsas_get_raid_info(mpt);
6366
6367 /*
6368 * Get sas device page 0 by DevHandle to make sure if
6369 * SSP/SATA end device exist.
6370 */
6371 page_address = (MPI2_SAS_DEVICE_PGAD_FORM_HANDLE &
6372 MPI2_SAS_DEVICE_PGAD_FORM_MASK) |
6373 topo_node->devhdl;
6374
6375 rval = mptsas_get_target_device_info(mpt, page_address,
6376 &devhdl, &ptgt);
6377 if (rval == DEV_INFO_WRONG_DEVICE_TYPE) {
6378 mptsas_log(mpt, CE_NOTE,
6379 "mptsas_handle_topo_change: target %d is "
6380 "not a SAS/SATA device. \n",
6381 topo_node->devhdl);
6382 } else if (rval == DEV_INFO_FAIL_ALLOC) {
6383 mptsas_log(mpt, CE_NOTE,
6384 "mptsas_handle_topo_change: could not "
6385 "allocate memory. \n");
6386 } else if (rval == DEV_INFO_FAIL_GUID) {
6387 mptsas_log(mpt, CE_NOTE,
6388 "mptsas_handle_topo_change: could not "
6389 "get SATA GUID for target %d. \n",
6390 topo_node->devhdl);
6391 }
6392 /*
6393 * If rval is DEV_INFO_PHYS_DISK or indicates failure
6394 * then there is nothing else to do, just leave.
6395 */
6396 if (rval != DEV_INFO_SUCCESS) {
6397 return;
6398 }
6399 }
6400
6401 ASSERT(ptgt->m_devhdl == topo_node->devhdl);
6402
6403 mutex_exit(&mpt->m_mutex);
6404 flags = topo_node->flags;
6405
6406 if (flags == MPTSAS_TOPO_FLAG_RAID_PHYSDRV_ASSOCIATED) {
6407 phymask = ptgt->m_addr.mta_phymask;
6408 phy_mask_name = kmem_zalloc(MPTSAS_MAX_PHYS, KM_SLEEP);
6409 (void) sprintf(phy_mask_name, "%x", phymask);
6410 parent = scsi_hba_iport_find(mpt->m_dip,
6411 phy_mask_name);
6412 kmem_free(phy_mask_name, MPTSAS_MAX_PHYS);
6413 if (parent == NULL) {
6414 mptsas_log(mpt, CE_WARN, "Failed to find a "
6415 "iport for PD, should not happen!");
6416 mutex_enter(&mpt->m_mutex);
6417 break;
6418 }
6419 }
6420
6421 if (flags == MPTSAS_TOPO_FLAG_RAID_ASSOCIATED) {
6422 ndi_devi_enter(parent, &circ1);
6423 (void) mptsas_config_raid(parent, topo_node->devhdl,
6424 &lundip);
6425 ndi_devi_exit(parent, circ1);
6426 } else {
6427 /*
6428 * hold nexus for bus configure
6429 */
6430 ndi_devi_enter(scsi_vhci_dip, &circ);
6431 ndi_devi_enter(parent, &circ1);
6432 rval = mptsas_config_target(parent, ptgt);
6433 /*
6434 * release nexus for bus configure
6435 */
6436 ndi_devi_exit(parent, circ1);
6437 ndi_devi_exit(scsi_vhci_dip, circ);
6438
6439 /*
6440 * Add parent's props for SMHBA support
6441 */
6442 if (flags == MPTSAS_TOPO_FLAG_DIRECT_ATTACHED_DEVICE) {
6443 bzero(attached_wwnstr,
6444 sizeof (attached_wwnstr));
6445 (void) sprintf(attached_wwnstr, "w%016"PRIx64,
6446 ptgt->m_addr.mta_wwn);
6447 if (ddi_prop_update_string(DDI_DEV_T_NONE,
6448 parent,
6449 SCSI_ADDR_PROP_ATTACHED_PORT,
6450 attached_wwnstr)
6451 != DDI_PROP_SUCCESS) {
6452 (void) ddi_prop_remove(DDI_DEV_T_NONE,
6453 parent,
6454 SCSI_ADDR_PROP_ATTACHED_PORT);
6455 mptsas_log(mpt, CE_WARN, "Failed to"
6456 "attached-port props");
6457 return;
6458 }
6459 if (ddi_prop_update_int(DDI_DEV_T_NONE, parent,
6460 MPTSAS_NUM_PHYS, 1) !=
6461 DDI_PROP_SUCCESS) {
6462 (void) ddi_prop_remove(DDI_DEV_T_NONE,
6463 parent, MPTSAS_NUM_PHYS);
6464 mptsas_log(mpt, CE_WARN, "Failed to"
6465 " create num-phys props");
6466 return;
6467 }
6468
6469 /*
6470 * Update PHY info for smhba
6471 */
6472 mutex_enter(&mpt->m_mutex);
6473 if (mptsas_smhba_phy_init(mpt)) {
6474 mutex_exit(&mpt->m_mutex);
6475 mptsas_log(mpt, CE_WARN, "mptsas phy"
6476 " update failed");
6477 return;
6478 }
6479 mutex_exit(&mpt->m_mutex);
6480
6481 /*
6482 * topo_node->un.physport is really the PHY#
6483 * for direct attached devices
6484 */
6485 mptsas_smhba_set_one_phy_props(mpt, parent,
6486 topo_node->un.physport, &attached_devhdl);
6487
6488 if (ddi_prop_update_int(DDI_DEV_T_NONE, parent,
6489 MPTSAS_VIRTUAL_PORT, 0) !=
6490 DDI_PROP_SUCCESS) {
6491 (void) ddi_prop_remove(DDI_DEV_T_NONE,
6492 parent, MPTSAS_VIRTUAL_PORT);
6493 mptsas_log(mpt, CE_WARN,
6494 "mptsas virtual-port"
6495 "port prop update failed");
6496 return;
6497 }
6498 }
6499 }
6500 mutex_enter(&mpt->m_mutex);
6501
6502 NDBG20(("mptsas%d handle_topo_change to online devhdl:%x, "
6503 "phymask:%x.", mpt->m_instance, ptgt->m_devhdl,
6504 ptgt->m_addr.mta_phymask));
6505 break;
6506 }
6507 case MPTSAS_DR_EVENT_OFFLINE_TARGET:
6508 {
6509 devhdl = topo_node->devhdl;
6510 ptgt = refhash_linear_search(mpt->m_targets,
6511 mptsas_target_eval_devhdl, &devhdl);
6512 if (ptgt == NULL)
6513 break;
6514
6515 sas_wwn = ptgt->m_addr.mta_wwn;
6516 phy = ptgt->m_phynum;
6517
6518 addr = kmem_zalloc(SCSI_MAXNAMELEN, KM_SLEEP);
6519
6520 if (sas_wwn) {
6521 (void) sprintf(addr, "w%016"PRIx64, sas_wwn);
6522 } else {
6523 (void) sprintf(addr, "p%x", phy);
6524 }
6525 ASSERT(ptgt->m_devhdl == devhdl);
6526
6527 if ((topo_node->flags == MPTSAS_TOPO_FLAG_RAID_ASSOCIATED) ||
6528 (topo_node->flags ==
6529 MPTSAS_TOPO_FLAG_RAID_PHYSDRV_ASSOCIATED)) {
6530 /*
6531 * Get latest RAID info if RAID volume status changes
6532 * or Phys Disk status changes
6533 */
6534 (void) mptsas_get_raid_info(mpt);
6535 }
6536 /*
6537 * Abort all outstanding command on the device
6538 */
6539 rval = mptsas_do_scsi_reset(mpt, devhdl);
6540 if (rval) {
6541 NDBG20(("mptsas%d handle_topo_change to reset target "
6542 "before offline devhdl:%x, phymask:%x, rval:%x",
6543 mpt->m_instance, ptgt->m_devhdl,
6544 ptgt->m_addr.mta_phymask, rval));
6545 }
6546
6547 mutex_exit(&mpt->m_mutex);
6548
6549 ndi_devi_enter(scsi_vhci_dip, &circ);
6550 ndi_devi_enter(parent, &circ1);
6551 rval = mptsas_offline_target(parent, addr);
6552 ndi_devi_exit(parent, circ1);
6553 ndi_devi_exit(scsi_vhci_dip, circ);
6554 NDBG20(("mptsas%d handle_topo_change to offline devhdl:%x, "
6555 "phymask:%x, rval:%x", mpt->m_instance,
6556 ptgt->m_devhdl, ptgt->m_addr.mta_phymask, rval));
6557
6558 kmem_free(addr, SCSI_MAXNAMELEN);
6559
6560 /*
6561 * Clear parent's props for SMHBA support
6562 */
6563 flags = topo_node->flags;
6564 if (flags == MPTSAS_TOPO_FLAG_DIRECT_ATTACHED_DEVICE) {
6565 bzero(attached_wwnstr, sizeof (attached_wwnstr));
6566 if (ddi_prop_update_string(DDI_DEV_T_NONE, parent,
6567 SCSI_ADDR_PROP_ATTACHED_PORT, attached_wwnstr) !=
6568 DDI_PROP_SUCCESS) {
6569 (void) ddi_prop_remove(DDI_DEV_T_NONE, parent,
6570 SCSI_ADDR_PROP_ATTACHED_PORT);
6571 mptsas_log(mpt, CE_WARN, "mptsas attached port "
6572 "prop update failed");
6573 break;
6574 }
6575 if (ddi_prop_update_int(DDI_DEV_T_NONE, parent,
6576 MPTSAS_NUM_PHYS, 0) !=
6577 DDI_PROP_SUCCESS) {
6578 (void) ddi_prop_remove(DDI_DEV_T_NONE, parent,
6579 MPTSAS_NUM_PHYS);
6580 mptsas_log(mpt, CE_WARN, "mptsas num phys "
6581 "prop update failed");
6582 break;
6583 }
6584 if (ddi_prop_update_int(DDI_DEV_T_NONE, parent,
6585 MPTSAS_VIRTUAL_PORT, 1) !=
6586 DDI_PROP_SUCCESS) {
6587 (void) ddi_prop_remove(DDI_DEV_T_NONE, parent,
6588 MPTSAS_VIRTUAL_PORT);
6589 mptsas_log(mpt, CE_WARN, "mptsas virtual port "
6590 "prop update failed");
6591 break;
6592 }
6593 }
6594
6595 mutex_enter(&mpt->m_mutex);
6596 ptgt->m_led_status = 0;
6597 (void) mptsas_flush_led_status(mpt, ptgt);
6598 if (rval == DDI_SUCCESS) {
6599 refhash_remove(mpt->m_targets, ptgt);
6600 ptgt = NULL;
6601 } else {
6602 /*
6603 * clean DR_INTRANSITION flag to allow I/O down to
6604 * PHCI driver since failover finished.
6605 * Invalidate the devhdl
6606 */
6607 ptgt->m_devhdl = MPTSAS_INVALID_DEVHDL;
6608 ptgt->m_tgt_unconfigured = 0;
6609 mutex_enter(&mpt->m_tx_waitq_mutex);
6610 ptgt->m_dr_flag = MPTSAS_DR_INACTIVE;
6611 mutex_exit(&mpt->m_tx_waitq_mutex);
6612 }
6613
6614 /*
6615 * Send SAS IO Unit Control to free the dev handle
6616 */
6617 if ((flags == MPTSAS_TOPO_FLAG_DIRECT_ATTACHED_DEVICE) ||
6618 (flags == MPTSAS_TOPO_FLAG_EXPANDER_ATTACHED_DEVICE)) {
6619 rval = mptsas_free_devhdl(mpt, devhdl);
6620
6621 NDBG20(("mptsas%d handle_topo_change to remove "
6622 "devhdl:%x, rval:%x", mpt->m_instance, devhdl,
6623 rval));
6624 }
6625
6626 break;
6627 }
6628 case MPTSAS_TOPO_FLAG_REMOVE_HANDLE:
6629 {
6630 devhdl = topo_node->devhdl;
6631 /*
6632 * If this is the remove handle event, do a reset first.
6633 */
6634 if (topo_node->event == MPTSAS_TOPO_FLAG_REMOVE_HANDLE) {
6635 rval = mptsas_do_scsi_reset(mpt, devhdl);
6636 if (rval) {
6637 NDBG20(("mpt%d reset target before remove "
6638 "devhdl:%x, rval:%x", mpt->m_instance,
6639 devhdl, rval));
6640 }
6641 }
6642
6643 /*
6644 * Send SAS IO Unit Control to free the dev handle
6645 */
6646 rval = mptsas_free_devhdl(mpt, devhdl);
6647 NDBG20(("mptsas%d handle_topo_change to remove "
6648 "devhdl:%x, rval:%x", mpt->m_instance, devhdl,
6649 rval));
6650 break;
6651 }
6652 case MPTSAS_DR_EVENT_RECONFIG_SMP:
6653 {
6654 mptsas_smp_t smp;
6655 dev_info_t *smpdip;
6656
6657 devhdl = topo_node->devhdl;
6658
6659 page_address = (MPI2_SAS_EXPAND_PGAD_FORM_HNDL &
6660 MPI2_SAS_EXPAND_PGAD_FORM_MASK) | (uint32_t)devhdl;
6661 rval = mptsas_get_sas_expander_page0(mpt, page_address, &smp);
6662 if (rval != DDI_SUCCESS) {
6663 mptsas_log(mpt, CE_WARN, "failed to online smp, "
6664 "handle %x", devhdl);
6665 return;
6666 }
6667
6668 psmp = mptsas_smp_alloc(mpt, &smp);
6669 if (psmp == NULL) {
6670 return;
6671 }
6672
6673 mutex_exit(&mpt->m_mutex);
6674 ndi_devi_enter(parent, &circ1);
6675 (void) mptsas_online_smp(parent, psmp, &smpdip);
6676 ndi_devi_exit(parent, circ1);
6677
6678 mutex_enter(&mpt->m_mutex);
6679 break;
6680 }
6681 case MPTSAS_DR_EVENT_OFFLINE_SMP:
6682 {
6683 devhdl = topo_node->devhdl;
6684 uint32_t dev_info;
6685
6686 psmp = refhash_linear_search(mpt->m_smp_targets,
6687 mptsas_smp_eval_devhdl, &devhdl);
6688 if (psmp == NULL)
6689 break;
6690 /*
6691 * The mptsas_smp_t data is released only if the dip is offlined
6692 * successfully.
6693 */
6694 mutex_exit(&mpt->m_mutex);
6695
6696 ndi_devi_enter(parent, &circ1);
6697 rval = mptsas_offline_smp(parent, psmp, NDI_DEVI_REMOVE);
6698 ndi_devi_exit(parent, circ1);
6699
6700 dev_info = psmp->m_deviceinfo;
6701 if ((dev_info & DEVINFO_DIRECT_ATTACHED) ==
6702 DEVINFO_DIRECT_ATTACHED) {
6703 if (ddi_prop_update_int(DDI_DEV_T_NONE, parent,
6704 MPTSAS_VIRTUAL_PORT, 1) !=
6705 DDI_PROP_SUCCESS) {
6706 (void) ddi_prop_remove(DDI_DEV_T_NONE, parent,
6707 MPTSAS_VIRTUAL_PORT);
6708 mptsas_log(mpt, CE_WARN, "mptsas virtual port "
6709 "prop update failed");
6710 return;
6711 }
6712 /*
6713 * Check whether the smp connected to the iport,
6714 */
6715 if (ddi_prop_update_int(DDI_DEV_T_NONE, parent,
6716 MPTSAS_NUM_PHYS, 0) !=
6717 DDI_PROP_SUCCESS) {
6718 (void) ddi_prop_remove(DDI_DEV_T_NONE, parent,
6719 MPTSAS_NUM_PHYS);
6720 mptsas_log(mpt, CE_WARN, "mptsas num phys"
6721 "prop update failed");
6722 return;
6723 }
6724 /*
6725 * Clear parent's attached-port props
6726 */
6727 bzero(attached_wwnstr, sizeof (attached_wwnstr));
6728 if (ddi_prop_update_string(DDI_DEV_T_NONE, parent,
6729 SCSI_ADDR_PROP_ATTACHED_PORT, attached_wwnstr) !=
6730 DDI_PROP_SUCCESS) {
6731 (void) ddi_prop_remove(DDI_DEV_T_NONE, parent,
6732 SCSI_ADDR_PROP_ATTACHED_PORT);
6733 mptsas_log(mpt, CE_WARN, "mptsas attached port "
6734 "prop update failed");
6735 return;
6736 }
6737 }
6738
6739 mutex_enter(&mpt->m_mutex);
6740 NDBG20(("mptsas%d handle_topo_change to remove devhdl:%x, "
6741 "rval:%x", mpt->m_instance, psmp->m_devhdl, rval));
6742 if (rval == DDI_SUCCESS) {
6743 refhash_remove(mpt->m_smp_targets, psmp);
6744 } else {
6745 psmp->m_devhdl = MPTSAS_INVALID_DEVHDL;
6746 }
6747
6748 bzero(attached_wwnstr, sizeof (attached_wwnstr));
6749
6750 break;
6751 }
6752 default:
6753 return;
6754 }
6755 }
6756
6757 /*
6758 * Record the event if its type is enabled in mpt instance by ioctl.
6759 */
6760 static void
6761 mptsas_record_event(void *args)
6762 {
6763 m_replyh_arg_t *replyh_arg;
6764 pMpi2EventNotificationReply_t eventreply;
6765 uint32_t event, rfm;
6766 mptsas_t *mpt;
6767 int i, j;
6768 uint16_t event_data_len;
6769 boolean_t sendAEN = FALSE;
6770
6771 replyh_arg = (m_replyh_arg_t *)args;
6772 rfm = replyh_arg->rfm;
6773 mpt = replyh_arg->mpt;
6774
6775 eventreply = (pMpi2EventNotificationReply_t)
6776 (mpt->m_reply_frame + (rfm -
6777 (mpt->m_reply_frame_dma_addr & 0xffffffffu)));
6778 event = ddi_get16(mpt->m_acc_reply_frame_hdl, &eventreply->Event);
6779
6780
6781 /*
6782 * Generate a system event to let anyone who cares know that a
6783 * LOG_ENTRY_ADDED event has occurred. This is sent no matter what the
6784 * event mask is set to.
6785 */
6786 if (event == MPI2_EVENT_LOG_ENTRY_ADDED) {
6787 sendAEN = TRUE;
6788 }
6789
6790 /*
6791 * Record the event only if it is not masked. Determine which dword
6792 * and bit of event mask to test.
6793 */
6794 i = (uint8_t)(event / 32);
6795 j = (uint8_t)(event % 32);
6796 if ((i < 4) && ((1 << j) & mpt->m_event_mask[i])) {
6797 i = mpt->m_event_index;
6798 mpt->m_events[i].Type = event;
6799 mpt->m_events[i].Number = ++mpt->m_event_number;
6800 bzero(mpt->m_events[i].Data, MPTSAS_MAX_EVENT_DATA_LENGTH * 4);
6801 event_data_len = ddi_get16(mpt->m_acc_reply_frame_hdl,
6802 &eventreply->EventDataLength);
6803
6804 if (event_data_len > 0) {
6805 /*
6806 * Limit data to size in m_event entry
6807 */
6808 if (event_data_len > MPTSAS_MAX_EVENT_DATA_LENGTH) {
6809 event_data_len = MPTSAS_MAX_EVENT_DATA_LENGTH;
6810 }
6811 for (j = 0; j < event_data_len; j++) {
6812 mpt->m_events[i].Data[j] =
6813 ddi_get32(mpt->m_acc_reply_frame_hdl,
6814 &(eventreply->EventData[j]));
6815 }
6816
6817 /*
6818 * check for index wrap-around
6819 */
6820 if (++i == MPTSAS_EVENT_QUEUE_SIZE) {
6821 i = 0;
6822 }
6823 mpt->m_event_index = (uint8_t)i;
6824
6825 /*
6826 * Set flag to send the event.
6827 */
6828 sendAEN = TRUE;
6829 }
6830 }
6831
6832 /*
6833 * Generate a system event if flag is set to let anyone who cares know
6834 * that an event has occurred.
6835 */
6836 if (sendAEN) {
6837 (void) ddi_log_sysevent(mpt->m_dip, DDI_VENDOR_LSI, "MPT_SAS",
6838 "SAS", NULL, NULL, DDI_NOSLEEP);
6839 }
6840 }
6841
6842 #define SMP_RESET_IN_PROGRESS MPI2_EVENT_SAS_TOPO_LR_SMP_RESET_IN_PROGRESS
6843 /*
6844 * handle sync events from ioc in interrupt
6845 * return value:
6846 * DDI_SUCCESS: The event is handled by this func
6847 * DDI_FAILURE: Event is not handled
6848 */
6849 static int
6850 mptsas_handle_event_sync(void *args)
6851 {
6852 m_replyh_arg_t *replyh_arg;
6853 pMpi2EventNotificationReply_t eventreply;
6854 uint32_t event, rfm;
6855 mptsas_t *mpt;
6856 uint_t iocstatus;
6857
6858 replyh_arg = (m_replyh_arg_t *)args;
6859 rfm = replyh_arg->rfm;
6860 mpt = replyh_arg->mpt;
6861
6862 ASSERT(mutex_owned(&mpt->m_mutex));
6863
6864 eventreply = (pMpi2EventNotificationReply_t)
6865 (mpt->m_reply_frame + (rfm -
6866 (mpt->m_reply_frame_dma_addr & 0xffffffffu)));
6867 event = ddi_get16(mpt->m_acc_reply_frame_hdl, &eventreply->Event);
6868
6869 if (iocstatus = ddi_get16(mpt->m_acc_reply_frame_hdl,
6870 &eventreply->IOCStatus)) {
6871 if (iocstatus == MPI2_IOCSTATUS_FLAG_LOG_INFO_AVAILABLE) {
6872 mptsas_log(mpt, CE_WARN,
6873 "!mptsas_handle_event_sync: event 0x%x, "
6874 "IOCStatus=0x%x, "
6875 "IOCLogInfo=0x%x", event, iocstatus,
6876 ddi_get32(mpt->m_acc_reply_frame_hdl,
6877 &eventreply->IOCLogInfo));
6878 } else {
6879 mptsas_log(mpt, CE_WARN,
6880 "mptsas_handle_event_sync: event 0x%x, "
6881 "IOCStatus=0x%x, "
6882 "(IOCLogInfo=0x%x)", event, iocstatus,
6883 ddi_get32(mpt->m_acc_reply_frame_hdl,
6884 &eventreply->IOCLogInfo));
6885 }
6886 }
6887
6888 /*
6889 * figure out what kind of event we got and handle accordingly
6890 */
6891 switch (event) {
6892 case MPI2_EVENT_SAS_TOPOLOGY_CHANGE_LIST:
6893 {
6894 pMpi2EventDataSasTopologyChangeList_t sas_topo_change_list;
6895 uint8_t num_entries, expstatus, phy;
6896 uint8_t phystatus, physport, state, i;
6897 uint8_t start_phy_num, link_rate;
6898 uint16_t dev_handle, reason_code;
6899 uint16_t enc_handle, expd_handle;
6900 char string[80], curr[80], prev[80];
6901 mptsas_topo_change_list_t *topo_head = NULL;
6902 mptsas_topo_change_list_t *topo_tail = NULL;
6903 mptsas_topo_change_list_t *topo_node = NULL;
6904 mptsas_target_t *ptgt;
6905 mptsas_smp_t *psmp;
6906 uint8_t flags = 0, exp_flag;
6907 smhba_info_t *pSmhba = NULL;
6908
6909 NDBG20(("mptsas_handle_event_sync: SAS topology change"));
6910
6911 sas_topo_change_list = (pMpi2EventDataSasTopologyChangeList_t)
6912 eventreply->EventData;
6913
6914 enc_handle = ddi_get16(mpt->m_acc_reply_frame_hdl,
6915 &sas_topo_change_list->EnclosureHandle);
6916 expd_handle = ddi_get16(mpt->m_acc_reply_frame_hdl,
6917 &sas_topo_change_list->ExpanderDevHandle);
6918 num_entries = ddi_get8(mpt->m_acc_reply_frame_hdl,
6919 &sas_topo_change_list->NumEntries);
6920 start_phy_num = ddi_get8(mpt->m_acc_reply_frame_hdl,
6921 &sas_topo_change_list->StartPhyNum);
6922 expstatus = ddi_get8(mpt->m_acc_reply_frame_hdl,
6923 &sas_topo_change_list->ExpStatus);
6924 physport = ddi_get8(mpt->m_acc_reply_frame_hdl,
6925 &sas_topo_change_list->PhysicalPort);
6926
6927 string[0] = 0;
6928 if (expd_handle) {
6929 flags = MPTSAS_TOPO_FLAG_EXPANDER_ASSOCIATED;
6930 switch (expstatus) {
6931 case MPI2_EVENT_SAS_TOPO_ES_ADDED:
6932 (void) sprintf(string, " added");
6933 /*
6934 * New expander device added
6935 */
6936 mpt->m_port_chng = 1;
6937 topo_node = kmem_zalloc(
6938 sizeof (mptsas_topo_change_list_t),
6939 KM_SLEEP);
6940 topo_node->mpt = mpt;
6941 topo_node->event = MPTSAS_DR_EVENT_RECONFIG_SMP;
6942 topo_node->un.physport = physport;
6943 topo_node->devhdl = expd_handle;
6944 topo_node->flags = flags;
6945 topo_node->object = NULL;
6946 if (topo_head == NULL) {
6947 topo_head = topo_tail = topo_node;
6948 } else {
6949 topo_tail->next = topo_node;
6950 topo_tail = topo_node;
6951 }
6952 break;
6953 case MPI2_EVENT_SAS_TOPO_ES_NOT_RESPONDING:
6954 (void) sprintf(string, " not responding, "
6955 "removed");
6956 psmp = refhash_linear_search(mpt->m_smp_targets,
6957 mptsas_smp_eval_devhdl, &expd_handle);
6958 if (psmp == NULL)
6959 break;
6960
6961 topo_node = kmem_zalloc(
6962 sizeof (mptsas_topo_change_list_t),
6963 KM_SLEEP);
6964 topo_node->mpt = mpt;
6965 topo_node->un.phymask =
6966 psmp->m_addr.mta_phymask;
6967 topo_node->event = MPTSAS_DR_EVENT_OFFLINE_SMP;
6968 topo_node->devhdl = expd_handle;
6969 topo_node->flags = flags;
6970 topo_node->object = NULL;
6971 if (topo_head == NULL) {
6972 topo_head = topo_tail = topo_node;
6973 } else {
6974 topo_tail->next = topo_node;
6975 topo_tail = topo_node;
6976 }
6977 break;
6978 case MPI2_EVENT_SAS_TOPO_ES_RESPONDING:
6979 break;
6980 case MPI2_EVENT_SAS_TOPO_ES_DELAY_NOT_RESPONDING:
6981 (void) sprintf(string, " not responding, "
6982 "delaying removal");
6983 break;
6984 default:
6985 break;
6986 }
6987 } else {
6988 flags = MPTSAS_TOPO_FLAG_DIRECT_ATTACHED_DEVICE;
6989 }
6990
6991 NDBG20(("SAS TOPOLOGY CHANGE for enclosure %x expander %x%s\n",
6992 enc_handle, expd_handle, string));
6993 for (i = 0; i < num_entries; i++) {
6994 phy = i + start_phy_num;
6995 phystatus = ddi_get8(mpt->m_acc_reply_frame_hdl,
6996 &sas_topo_change_list->PHY[i].PhyStatus);
6997 dev_handle = ddi_get16(mpt->m_acc_reply_frame_hdl,
6998 &sas_topo_change_list->PHY[i].AttachedDevHandle);
6999 reason_code = phystatus & MPI2_EVENT_SAS_TOPO_RC_MASK;
7000 /*
7001 * Filter out processing of Phy Vacant Status unless
7002 * the reason code is "Not Responding". Process all
7003 * other combinations of Phy Status and Reason Codes.
7004 */
7005 if ((phystatus &
7006 MPI2_EVENT_SAS_TOPO_PHYSTATUS_VACANT) &&
7007 (reason_code !=
7008 MPI2_EVENT_SAS_TOPO_RC_TARG_NOT_RESPONDING)) {
7009 continue;
7010 }
7011 curr[0] = 0;
7012 prev[0] = 0;
7013 string[0] = 0;
7014 switch (reason_code) {
7015 case MPI2_EVENT_SAS_TOPO_RC_TARG_ADDED:
7016 {
7017 NDBG20(("mptsas%d phy %d physical_port %d "
7018 "dev_handle %d added", mpt->m_instance, phy,
7019 physport, dev_handle));
7020 link_rate = ddi_get8(mpt->m_acc_reply_frame_hdl,
7021 &sas_topo_change_list->PHY[i].LinkRate);
7022 state = (link_rate &
7023 MPI2_EVENT_SAS_TOPO_LR_CURRENT_MASK) >>
7024 MPI2_EVENT_SAS_TOPO_LR_CURRENT_SHIFT;
7025 switch (state) {
7026 case MPI2_EVENT_SAS_TOPO_LR_PHY_DISABLED:
7027 (void) sprintf(curr, "is disabled");
7028 break;
7029 case MPI2_EVENT_SAS_TOPO_LR_NEGOTIATION_FAILED:
7030 (void) sprintf(curr, "is offline, "
7031 "failed speed negotiation");
7032 break;
7033 case MPI2_EVENT_SAS_TOPO_LR_SATA_OOB_COMPLETE:
7034 (void) sprintf(curr, "SATA OOB "
7035 "complete");
7036 break;
7037 case SMP_RESET_IN_PROGRESS:
7038 (void) sprintf(curr, "SMP reset in "
7039 "progress");
7040 break;
7041 case MPI2_EVENT_SAS_TOPO_LR_RATE_1_5:
7042 (void) sprintf(curr, "is online at "
7043 "1.5 Gbps");
7044 break;
7045 case MPI2_EVENT_SAS_TOPO_LR_RATE_3_0:
7046 (void) sprintf(curr, "is online at 3.0 "
7047 "Gbps");
7048 break;
7049 case MPI2_EVENT_SAS_TOPO_LR_RATE_6_0:
7050 (void) sprintf(curr, "is online at 6.0 "
7051 "Gbps");
7052 break;
7053 case MPI25_EVENT_SAS_TOPO_LR_RATE_12_0:
7054 (void) sprintf(curr,
7055 "is online at 12.0 Gbps");
7056 break;
7057 default:
7058 (void) sprintf(curr, "state is "
7059 "unknown");
7060 break;
7061 }
7062 /*
7063 * New target device added into the system.
7064 * Set association flag according to if an
7065 * expander is used or not.
7066 */
7067 exp_flag =
7068 MPTSAS_TOPO_FLAG_EXPANDER_ATTACHED_DEVICE;
7069 if (flags ==
7070 MPTSAS_TOPO_FLAG_EXPANDER_ASSOCIATED) {
7071 flags = exp_flag;
7072 }
7073 topo_node = kmem_zalloc(
7074 sizeof (mptsas_topo_change_list_t),
7075 KM_SLEEP);
7076 topo_node->mpt = mpt;
7077 topo_node->event =
7078 MPTSAS_DR_EVENT_RECONFIG_TARGET;
7079 if (expd_handle == 0) {
7080 /*
7081 * Per MPI 2, if expander dev handle
7082 * is 0, it's a directly attached
7083 * device. So driver use PHY to decide
7084 * which iport is associated
7085 */
7086 physport = phy;
7087 mpt->m_port_chng = 1;
7088 }
7089 topo_node->un.physport = physport;
7090 topo_node->devhdl = dev_handle;
7091 topo_node->flags = flags;
7092 topo_node->object = NULL;
7093 if (topo_head == NULL) {
7094 topo_head = topo_tail = topo_node;
7095 } else {
7096 topo_tail->next = topo_node;
7097 topo_tail = topo_node;
7098 }
7099 break;
7100 }
7101 case MPI2_EVENT_SAS_TOPO_RC_TARG_NOT_RESPONDING:
7102 {
7103 NDBG20(("mptsas%d phy %d physical_port %d "
7104 "dev_handle %d removed", mpt->m_instance,
7105 phy, physport, dev_handle));
7106 /*
7107 * Set association flag according to if an
7108 * expander is used or not.
7109 */
7110 exp_flag =
7111 MPTSAS_TOPO_FLAG_EXPANDER_ATTACHED_DEVICE;
7112 if (flags ==
7113 MPTSAS_TOPO_FLAG_EXPANDER_ASSOCIATED) {
7114 flags = exp_flag;
7115 }
7116 /*
7117 * Target device is removed from the system
7118 * Before the device is really offline from
7119 * from system.
7120 */
7121 ptgt = refhash_linear_search(mpt->m_targets,
7122 mptsas_target_eval_devhdl, &dev_handle);
7123 /*
7124 * If ptgt is NULL here, it means that the
7125 * DevHandle is not in the hash table. This is
7126 * reasonable sometimes. For example, if a
7127 * disk was pulled, then added, then pulled
7128 * again, the disk will not have been put into
7129 * the hash table because the add event will
7130 * have an invalid phymask. BUT, this does not
7131 * mean that the DevHandle is invalid. The
7132 * controller will still have a valid DevHandle
7133 * that must be removed. To do this, use the
7134 * MPTSAS_TOPO_FLAG_REMOVE_HANDLE event.
7135 */
7136 if (ptgt == NULL) {
7137 topo_node = kmem_zalloc(
7138 sizeof (mptsas_topo_change_list_t),
7139 KM_SLEEP);
7140 topo_node->mpt = mpt;
7141 topo_node->un.phymask = 0;
7142 topo_node->event =
7143 MPTSAS_TOPO_FLAG_REMOVE_HANDLE;
7144 topo_node->devhdl = dev_handle;
7145 topo_node->flags = flags;
7146 topo_node->object = NULL;
7147 if (topo_head == NULL) {
7148 topo_head = topo_tail =
7149 topo_node;
7150 } else {
7151 topo_tail->next = topo_node;
7152 topo_tail = topo_node;
7153 }
7154 break;
7155 }
7156
7157 /*
7158 * Update DR flag immediately avoid I/O failure
7159 * before failover finish. Pay attention to the
7160 * mutex protect, we need grab m_tx_waitq_mutex
7161 * during set m_dr_flag because we won't add
7162 * the following command into waitq, instead,
7163 * we need return TRAN_BUSY in the tran_start
7164 * context.
7165 */
7166 mutex_enter(&mpt->m_tx_waitq_mutex);
7167 ptgt->m_dr_flag = MPTSAS_DR_INTRANSITION;
7168 mutex_exit(&mpt->m_tx_waitq_mutex);
7169
7170 topo_node = kmem_zalloc(
7171 sizeof (mptsas_topo_change_list_t),
7172 KM_SLEEP);
7173 topo_node->mpt = mpt;
7174 topo_node->un.phymask =
7175 ptgt->m_addr.mta_phymask;
7176 topo_node->event =
7177 MPTSAS_DR_EVENT_OFFLINE_TARGET;
7178 topo_node->devhdl = dev_handle;
7179 topo_node->flags = flags;
7180 topo_node->object = NULL;
7181 if (topo_head == NULL) {
7182 topo_head = topo_tail = topo_node;
7183 } else {
7184 topo_tail->next = topo_node;
7185 topo_tail = topo_node;
7186 }
7187 break;
7188 }
7189 case MPI2_EVENT_SAS_TOPO_RC_PHY_CHANGED:
7190 link_rate = ddi_get8(mpt->m_acc_reply_frame_hdl,
7191 &sas_topo_change_list->PHY[i].LinkRate);
7192 state = (link_rate &
7193 MPI2_EVENT_SAS_TOPO_LR_CURRENT_MASK) >>
7194 MPI2_EVENT_SAS_TOPO_LR_CURRENT_SHIFT;
7195 pSmhba = &mpt->m_phy_info[i].smhba_info;
7196 pSmhba->negotiated_link_rate = state;
7197 switch (state) {
7198 case MPI2_EVENT_SAS_TOPO_LR_PHY_DISABLED:
7199 (void) sprintf(curr, "is disabled");
7200 mptsas_smhba_log_sysevent(mpt,
7201 ESC_SAS_PHY_EVENT,
7202 SAS_PHY_REMOVE,
7203 &mpt->m_phy_info[i].smhba_info);
7204 mpt->m_phy_info[i].smhba_info.
7205 negotiated_link_rate
7206 = 0x1;
7207 break;
7208 case MPI2_EVENT_SAS_TOPO_LR_NEGOTIATION_FAILED:
7209 (void) sprintf(curr, "is offline, "
7210 "failed speed negotiation");
7211 mptsas_smhba_log_sysevent(mpt,
7212 ESC_SAS_PHY_EVENT,
7213 SAS_PHY_OFFLINE,
7214 &mpt->m_phy_info[i].smhba_info);
7215 break;
7216 case MPI2_EVENT_SAS_TOPO_LR_SATA_OOB_COMPLETE:
7217 (void) sprintf(curr, "SATA OOB "
7218 "complete");
7219 break;
7220 case SMP_RESET_IN_PROGRESS:
7221 (void) sprintf(curr, "SMP reset in "
7222 "progress");
7223 break;
7224 case MPI2_EVENT_SAS_TOPO_LR_RATE_1_5:
7225 (void) sprintf(curr, "is online at "
7226 "1.5 Gbps");
7227 if ((expd_handle == 0) &&
7228 (enc_handle == 1)) {
7229 mpt->m_port_chng = 1;
7230 }
7231 mptsas_smhba_log_sysevent(mpt,
7232 ESC_SAS_PHY_EVENT,
7233 SAS_PHY_ONLINE,
7234 &mpt->m_phy_info[i].smhba_info);
7235 break;
7236 case MPI2_EVENT_SAS_TOPO_LR_RATE_3_0:
7237 (void) sprintf(curr, "is online at 3.0 "
7238 "Gbps");
7239 if ((expd_handle == 0) &&
7240 (enc_handle == 1)) {
7241 mpt->m_port_chng = 1;
7242 }
7243 mptsas_smhba_log_sysevent(mpt,
7244 ESC_SAS_PHY_EVENT,
7245 SAS_PHY_ONLINE,
7246 &mpt->m_phy_info[i].smhba_info);
7247 break;
7248 case MPI2_EVENT_SAS_TOPO_LR_RATE_6_0:
7249 (void) sprintf(curr, "is online at "
7250 "6.0 Gbps");
7251 if ((expd_handle == 0) &&
7252 (enc_handle == 1)) {
7253 mpt->m_port_chng = 1;
7254 }
7255 mptsas_smhba_log_sysevent(mpt,
7256 ESC_SAS_PHY_EVENT,
7257 SAS_PHY_ONLINE,
7258 &mpt->m_phy_info[i].smhba_info);
7259 break;
7260 case MPI25_EVENT_SAS_TOPO_LR_RATE_12_0:
7261 (void) sprintf(curr, "is online at "
7262 "12.0 Gbps");
7263 if ((expd_handle == 0) &&
7264 (enc_handle == 1)) {
7265 mpt->m_port_chng = 1;
7266 }
7267 mptsas_smhba_log_sysevent(mpt,
7268 ESC_SAS_PHY_EVENT,
7269 SAS_PHY_ONLINE,
7270 &mpt->m_phy_info[i].smhba_info);
7271 break;
7272 default:
7273 (void) sprintf(curr, "state is "
7274 "unknown");
7275 break;
7276 }
7277
7278 state = (link_rate &
7279 MPI2_EVENT_SAS_TOPO_LR_PREV_MASK) >>
7280 MPI2_EVENT_SAS_TOPO_LR_PREV_SHIFT;
7281 switch (state) {
7282 case MPI2_EVENT_SAS_TOPO_LR_PHY_DISABLED:
7283 (void) sprintf(prev, ", was disabled");
7284 break;
7285 case MPI2_EVENT_SAS_TOPO_LR_NEGOTIATION_FAILED:
7286 (void) sprintf(prev, ", was offline, "
7287 "failed speed negotiation");
7288 break;
7289 case MPI2_EVENT_SAS_TOPO_LR_SATA_OOB_COMPLETE:
7290 (void) sprintf(prev, ", was SATA OOB "
7291 "complete");
7292 break;
7293 case SMP_RESET_IN_PROGRESS:
7294 (void) sprintf(prev, ", was SMP reset "
7295 "in progress");
7296 break;
7297 case MPI2_EVENT_SAS_TOPO_LR_RATE_1_5:
7298 (void) sprintf(prev, ", was online at "
7299 "1.5 Gbps");
7300 break;
7301 case MPI2_EVENT_SAS_TOPO_LR_RATE_3_0:
7302 (void) sprintf(prev, ", was online at "
7303 "3.0 Gbps");
7304 break;
7305 case MPI2_EVENT_SAS_TOPO_LR_RATE_6_0:
7306 (void) sprintf(prev, ", was online at "
7307 "6.0 Gbps");
7308 break;
7309 case MPI25_EVENT_SAS_TOPO_LR_RATE_12_0:
7310 (void) sprintf(prev, ", was online at "
7311 "12.0 Gbps");
7312 break;
7313 default:
7314 break;
7315 }
7316 (void) sprintf(&string[strlen(string)], "link "
7317 "changed, ");
7318 break;
7319 case MPI2_EVENT_SAS_TOPO_RC_NO_CHANGE:
7320 continue;
7321 case MPI2_EVENT_SAS_TOPO_RC_DELAY_NOT_RESPONDING:
7322 (void) sprintf(&string[strlen(string)],
7323 "target not responding, delaying "
7324 "removal");
7325 break;
7326 }
7327 NDBG20(("mptsas%d phy %d DevHandle %x, %s%s%s\n",
7328 mpt->m_instance, phy, dev_handle, string, curr,
7329 prev));
7330 }
7331 if (topo_head != NULL) {
7332 /*
7333 * Launch DR taskq to handle topology change
7334 */
7335 if ((ddi_taskq_dispatch(mpt->m_dr_taskq,
7336 mptsas_handle_dr, (void *)topo_head,
7337 DDI_NOSLEEP)) != DDI_SUCCESS) {
7338 while (topo_head != NULL) {
7339 topo_node = topo_head;
7340 topo_head = topo_head->next;
7341 kmem_free(topo_node,
7342 sizeof (mptsas_topo_change_list_t));
7343 }
7344 mptsas_log(mpt, CE_NOTE, "mptsas start taskq "
7345 "for handle SAS DR event failed. \n");
7346 }
7347 }
7348 break;
7349 }
7350 case MPI2_EVENT_IR_CONFIGURATION_CHANGE_LIST:
7351 {
7352 Mpi2EventDataIrConfigChangeList_t *irChangeList;
7353 mptsas_topo_change_list_t *topo_head = NULL;
7354 mptsas_topo_change_list_t *topo_tail = NULL;
7355 mptsas_topo_change_list_t *topo_node = NULL;
7356 mptsas_target_t *ptgt;
7357 uint8_t num_entries, i, reason;
7358 uint16_t volhandle, diskhandle;
7359
7360 irChangeList = (pMpi2EventDataIrConfigChangeList_t)
7361 eventreply->EventData;
7362 num_entries = ddi_get8(mpt->m_acc_reply_frame_hdl,
7363 &irChangeList->NumElements);
7364
7365 NDBG20(("mptsas%d IR_CONFIGURATION_CHANGE_LIST event received",
7366 mpt->m_instance));
7367
7368 for (i = 0; i < num_entries; i++) {
7369 reason = ddi_get8(mpt->m_acc_reply_frame_hdl,
7370 &irChangeList->ConfigElement[i].ReasonCode);
7371 volhandle = ddi_get16(mpt->m_acc_reply_frame_hdl,
7372 &irChangeList->ConfigElement[i].VolDevHandle);
7373 diskhandle = ddi_get16(mpt->m_acc_reply_frame_hdl,
7374 &irChangeList->ConfigElement[i].PhysDiskDevHandle);
7375
7376 switch (reason) {
7377 case MPI2_EVENT_IR_CHANGE_RC_ADDED:
7378 case MPI2_EVENT_IR_CHANGE_RC_VOLUME_CREATED:
7379 {
7380 NDBG20(("mptsas %d volume added\n",
7381 mpt->m_instance));
7382
7383 topo_node = kmem_zalloc(
7384 sizeof (mptsas_topo_change_list_t),
7385 KM_SLEEP);
7386
7387 topo_node->mpt = mpt;
7388 topo_node->event =
7389 MPTSAS_DR_EVENT_RECONFIG_TARGET;
7390 topo_node->un.physport = 0xff;
7391 topo_node->devhdl = volhandle;
7392 topo_node->flags =
7393 MPTSAS_TOPO_FLAG_RAID_ASSOCIATED;
7394 topo_node->object = NULL;
7395 if (topo_head == NULL) {
7396 topo_head = topo_tail = topo_node;
7397 } else {
7398 topo_tail->next = topo_node;
7399 topo_tail = topo_node;
7400 }
7401 break;
7402 }
7403 case MPI2_EVENT_IR_CHANGE_RC_REMOVED:
7404 case MPI2_EVENT_IR_CHANGE_RC_VOLUME_DELETED:
7405 {
7406 NDBG20(("mptsas %d volume deleted\n",
7407 mpt->m_instance));
7408 ptgt = refhash_linear_search(mpt->m_targets,
7409 mptsas_target_eval_devhdl, &volhandle);
7410 if (ptgt == NULL)
7411 break;
7412
7413 /*
7414 * Clear any flags related to volume
7415 */
7416 (void) mptsas_delete_volume(mpt, volhandle);
7417
7418 /*
7419 * Update DR flag immediately avoid I/O failure
7420 */
7421 mutex_enter(&mpt->m_tx_waitq_mutex);
7422 ptgt->m_dr_flag = MPTSAS_DR_INTRANSITION;
7423 mutex_exit(&mpt->m_tx_waitq_mutex);
7424
7425 topo_node = kmem_zalloc(
7426 sizeof (mptsas_topo_change_list_t),
7427 KM_SLEEP);
7428 topo_node->mpt = mpt;
7429 topo_node->un.phymask =
7430 ptgt->m_addr.mta_phymask;
7431 topo_node->event =
7432 MPTSAS_DR_EVENT_OFFLINE_TARGET;
7433 topo_node->devhdl = volhandle;
7434 topo_node->flags =
7435 MPTSAS_TOPO_FLAG_RAID_ASSOCIATED;
7436 topo_node->object = (void *)ptgt;
7437 if (topo_head == NULL) {
7438 topo_head = topo_tail = topo_node;
7439 } else {
7440 topo_tail->next = topo_node;
7441 topo_tail = topo_node;
7442 }
7443 break;
7444 }
7445 case MPI2_EVENT_IR_CHANGE_RC_PD_CREATED:
7446 case MPI2_EVENT_IR_CHANGE_RC_HIDE:
7447 {
7448 ptgt = refhash_linear_search(mpt->m_targets,
7449 mptsas_target_eval_devhdl, &diskhandle);
7450 if (ptgt == NULL)
7451 break;
7452
7453 /*
7454 * Update DR flag immediately avoid I/O failure
7455 */
7456 mutex_enter(&mpt->m_tx_waitq_mutex);
7457 ptgt->m_dr_flag = MPTSAS_DR_INTRANSITION;
7458 mutex_exit(&mpt->m_tx_waitq_mutex);
7459
7460 topo_node = kmem_zalloc(
7461 sizeof (mptsas_topo_change_list_t),
7462 KM_SLEEP);
7463 topo_node->mpt = mpt;
7464 topo_node->un.phymask =
7465 ptgt->m_addr.mta_phymask;
7466 topo_node->event =
7467 MPTSAS_DR_EVENT_OFFLINE_TARGET;
7468 topo_node->devhdl = diskhandle;
7469 topo_node->flags =
7470 MPTSAS_TOPO_FLAG_RAID_PHYSDRV_ASSOCIATED;
7471 topo_node->object = (void *)ptgt;
7472 if (topo_head == NULL) {
7473 topo_head = topo_tail = topo_node;
7474 } else {
7475 topo_tail->next = topo_node;
7476 topo_tail = topo_node;
7477 }
7478 break;
7479 }
7480 case MPI2_EVENT_IR_CHANGE_RC_UNHIDE:
7481 case MPI2_EVENT_IR_CHANGE_RC_PD_DELETED:
7482 {
7483 /*
7484 * The physical drive is released by a IR
7485 * volume. But we cannot get the the physport
7486 * or phynum from the event data, so we only
7487 * can get the physport/phynum after SAS
7488 * Device Page0 request for the devhdl.
7489 */
7490 topo_node = kmem_zalloc(
7491 sizeof (mptsas_topo_change_list_t),
7492 KM_SLEEP);
7493 topo_node->mpt = mpt;
7494 topo_node->un.phymask = 0;
7495 topo_node->event =
7496 MPTSAS_DR_EVENT_RECONFIG_TARGET;
7497 topo_node->devhdl = diskhandle;
7498 topo_node->flags =
7499 MPTSAS_TOPO_FLAG_RAID_PHYSDRV_ASSOCIATED;
7500 topo_node->object = NULL;
7501 mpt->m_port_chng = 1;
7502 if (topo_head == NULL) {
7503 topo_head = topo_tail = topo_node;
7504 } else {
7505 topo_tail->next = topo_node;
7506 topo_tail = topo_node;
7507 }
7508 break;
7509 }
7510 default:
7511 break;
7512 }
7513 }
7514
7515 if (topo_head != NULL) {
7516 /*
7517 * Launch DR taskq to handle topology change
7518 */
7519 if ((ddi_taskq_dispatch(mpt->m_dr_taskq,
7520 mptsas_handle_dr, (void *)topo_head,
7521 DDI_NOSLEEP)) != DDI_SUCCESS) {
7522 while (topo_head != NULL) {
7523 topo_node = topo_head;
7524 topo_head = topo_head->next;
7525 kmem_free(topo_node,
7526 sizeof (mptsas_topo_change_list_t));
7527 }
7528 mptsas_log(mpt, CE_NOTE, "mptsas start taskq "
7529 "for handle SAS DR event failed. \n");
7530 }
7531 }
7532 break;
7533 }
7534 default:
7535 return (DDI_FAILURE);
7536 }
7537
7538 return (DDI_SUCCESS);
7539 }
7540
7541 /*
7542 * handle events from ioc
7543 */
7544 static void
7545 mptsas_handle_event(void *args)
7546 {
7547 m_replyh_arg_t *replyh_arg;
7548 pMpi2EventNotificationReply_t eventreply;
7549 uint32_t event, iocloginfo, rfm;
7550 uint32_t status;
7551 uint8_t port;
7552 mptsas_t *mpt;
7553 uint_t iocstatus;
7554
7555 replyh_arg = (m_replyh_arg_t *)args;
7556 rfm = replyh_arg->rfm;
7557 mpt = replyh_arg->mpt;
7558
7559 mutex_enter(&mpt->m_mutex);
7560 /*
7561 * If HBA is being reset, drop incoming event.
7562 */
7563 if (mpt->m_in_reset) {
7564 NDBG20(("dropping event received prior to reset"));
7565 mutex_exit(&mpt->m_mutex);
7566 return;
7567 }
7568
7569 eventreply = (pMpi2EventNotificationReply_t)
7570 (mpt->m_reply_frame + (rfm -
7571 (mpt->m_reply_frame_dma_addr & 0xffffffffu)));
7572 event = ddi_get16(mpt->m_acc_reply_frame_hdl, &eventreply->Event);
7573
7574 if (iocstatus = ddi_get16(mpt->m_acc_reply_frame_hdl,
7575 &eventreply->IOCStatus)) {
7576 if (iocstatus == MPI2_IOCSTATUS_FLAG_LOG_INFO_AVAILABLE) {
7577 mptsas_log(mpt, CE_WARN,
7578 "!mptsas_handle_event: IOCStatus=0x%x, "
7579 "IOCLogInfo=0x%x", iocstatus,
7580 ddi_get32(mpt->m_acc_reply_frame_hdl,
7581 &eventreply->IOCLogInfo));
7582 } else {
7583 mptsas_log(mpt, CE_WARN,
7584 "mptsas_handle_event: IOCStatus=0x%x, "
7585 "IOCLogInfo=0x%x", iocstatus,
7586 ddi_get32(mpt->m_acc_reply_frame_hdl,
7587 &eventreply->IOCLogInfo));
7588 }
7589 }
7590
7591 /*
7592 * figure out what kind of event we got and handle accordingly
7593 */
7594 switch (event) {
7595 case MPI2_EVENT_LOG_ENTRY_ADDED:
7596 break;
7597 case MPI2_EVENT_LOG_DATA:
7598 iocloginfo = ddi_get32(mpt->m_acc_reply_frame_hdl,
7599 &eventreply->IOCLogInfo);
7600 NDBG20(("mptsas %d log info %x received.\n", mpt->m_instance,
7601 iocloginfo));
7602 break;
7603 case MPI2_EVENT_STATE_CHANGE:
7604 NDBG20(("mptsas%d state change.", mpt->m_instance));
7605 break;
7606 case MPI2_EVENT_HARD_RESET_RECEIVED:
7607 NDBG20(("mptsas%d event change.", mpt->m_instance));
7608 break;
7609 case MPI2_EVENT_SAS_DISCOVERY:
7610 {
7611 MPI2_EVENT_DATA_SAS_DISCOVERY *sasdiscovery;
7612 char string[80];
7613 uint8_t rc;
7614
7615 sasdiscovery =
7616 (pMpi2EventDataSasDiscovery_t)eventreply->EventData;
7617
7618 rc = ddi_get8(mpt->m_acc_reply_frame_hdl,
7619 &sasdiscovery->ReasonCode);
7620 port = ddi_get8(mpt->m_acc_reply_frame_hdl,
7621 &sasdiscovery->PhysicalPort);
7622 status = ddi_get32(mpt->m_acc_reply_frame_hdl,
7623 &sasdiscovery->DiscoveryStatus);
7624
7625 string[0] = 0;
7626 switch (rc) {
7627 case MPI2_EVENT_SAS_DISC_RC_STARTED:
7628 (void) sprintf(string, "STARTING");
7629 break;
7630 case MPI2_EVENT_SAS_DISC_RC_COMPLETED:
7631 (void) sprintf(string, "COMPLETED");
7632 break;
7633 default:
7634 (void) sprintf(string, "UNKNOWN");
7635 break;
7636 }
7637
7638 NDBG20(("SAS DISCOVERY is %s for port %d, status %x", string,
7639 port, status));
7640
7641 break;
7642 }
7643 case MPI2_EVENT_EVENT_CHANGE:
7644 NDBG20(("mptsas%d event change.", mpt->m_instance));
7645 break;
7646 case MPI2_EVENT_TASK_SET_FULL:
7647 {
7648 pMpi2EventDataTaskSetFull_t taskfull;
7649
7650 taskfull = (pMpi2EventDataTaskSetFull_t)eventreply->EventData;
7651
7652 NDBG20(("TASK_SET_FULL received for mptsas%d, depth %d\n",
7653 mpt->m_instance, ddi_get16(mpt->m_acc_reply_frame_hdl,
7654 &taskfull->CurrentDepth)));
7655 break;
7656 }
7657 case MPI2_EVENT_SAS_TOPOLOGY_CHANGE_LIST:
7658 {
7659 /*
7660 * SAS TOPOLOGY CHANGE LIST Event has already been handled
7661 * in mptsas_handle_event_sync() of interrupt context
7662 */
7663 break;
7664 }
7665 case MPI2_EVENT_SAS_ENCL_DEVICE_STATUS_CHANGE:
7666 {
7667 pMpi2EventDataSasEnclDevStatusChange_t encstatus;
7668 uint8_t rc;
7669 char string[80];
7670
7671 encstatus = (pMpi2EventDataSasEnclDevStatusChange_t)
7672 eventreply->EventData;
7673
7674 rc = ddi_get8(mpt->m_acc_reply_frame_hdl,
7675 &encstatus->ReasonCode);
7676 switch (rc) {
7677 case MPI2_EVENT_SAS_ENCL_RC_ADDED:
7678 (void) sprintf(string, "added");
7679 break;
7680 case MPI2_EVENT_SAS_ENCL_RC_NOT_RESPONDING:
7681 (void) sprintf(string, ", not responding");
7682 break;
7683 default:
7684 break;
7685 }
7686 NDBG20(("mptsas%d ENCLOSURE STATUS CHANGE for enclosure "
7687 "%x%s\n", mpt->m_instance,
7688 ddi_get16(mpt->m_acc_reply_frame_hdl,
7689 &encstatus->EnclosureHandle), string));
7690 break;
7691 }
7692
7693 /*
7694 * MPI2_EVENT_SAS_DEVICE_STATUS_CHANGE is handled by
7695 * mptsas_handle_event_sync,in here just send ack message.
7696 */
7697 case MPI2_EVENT_SAS_DEVICE_STATUS_CHANGE:
7698 {
7699 pMpi2EventDataSasDeviceStatusChange_t statuschange;
7700 uint8_t rc;
7701 uint16_t devhdl;
7702 uint64_t wwn = 0;
7703 uint32_t wwn_lo, wwn_hi;
7704
7705 statuschange = (pMpi2EventDataSasDeviceStatusChange_t)
7706 eventreply->EventData;
7707 rc = ddi_get8(mpt->m_acc_reply_frame_hdl,
7708 &statuschange->ReasonCode);
7709 wwn_lo = ddi_get32(mpt->m_acc_reply_frame_hdl,
7710 (uint32_t *)(void *)&statuschange->SASAddress);
7711 wwn_hi = ddi_get32(mpt->m_acc_reply_frame_hdl,
7712 (uint32_t *)(void *)&statuschange->SASAddress + 1);
7713 wwn = ((uint64_t)wwn_hi << 32) | wwn_lo;
7714 devhdl = ddi_get16(mpt->m_acc_reply_frame_hdl,
7715 &statuschange->DevHandle);
7716
7717 NDBG13(("MPI2_EVENT_SAS_DEVICE_STATUS_CHANGE wwn is %"PRIx64,
7718 wwn));
7719
7720 switch (rc) {
7721 case MPI2_EVENT_SAS_DEV_STAT_RC_SMART_DATA:
7722 NDBG20(("SMART data received, ASC/ASCQ = %02x/%02x",
7723 ddi_get8(mpt->m_acc_reply_frame_hdl,
7724 &statuschange->ASC),
7725 ddi_get8(mpt->m_acc_reply_frame_hdl,
7726 &statuschange->ASCQ)));
7727 break;
7728
7729 case MPI2_EVENT_SAS_DEV_STAT_RC_UNSUPPORTED:
7730 NDBG20(("Device not supported"));
7731 break;
7732
7733 case MPI2_EVENT_SAS_DEV_STAT_RC_INTERNAL_DEVICE_RESET:
7734 NDBG20(("IOC internally generated the Target Reset "
7735 "for devhdl:%x", devhdl));
7736 break;
7737
7738 case MPI2_EVENT_SAS_DEV_STAT_RC_CMP_INTERNAL_DEV_RESET:
7739 NDBG20(("IOC's internally generated Target Reset "
7740 "completed for devhdl:%x", devhdl));
7741 break;
7742
7743 case MPI2_EVENT_SAS_DEV_STAT_RC_TASK_ABORT_INTERNAL:
7744 NDBG20(("IOC internally generated Abort Task"));
7745 break;
7746
7747 case MPI2_EVENT_SAS_DEV_STAT_RC_CMP_TASK_ABORT_INTERNAL:
7748 NDBG20(("IOC's internally generated Abort Task "
7749 "completed"));
7750 break;
7751
7752 case MPI2_EVENT_SAS_DEV_STAT_RC_ABORT_TASK_SET_INTERNAL:
7753 NDBG20(("IOC internally generated Abort Task Set"));
7754 break;
7755
7756 case MPI2_EVENT_SAS_DEV_STAT_RC_CLEAR_TASK_SET_INTERNAL:
7757 NDBG20(("IOC internally generated Clear Task Set"));
7758 break;
7759
7760 case MPI2_EVENT_SAS_DEV_STAT_RC_QUERY_TASK_INTERNAL:
7761 NDBG20(("IOC internally generated Query Task"));
7762 break;
7763
7764 case MPI2_EVENT_SAS_DEV_STAT_RC_ASYNC_NOTIFICATION:
7765 NDBG20(("Device sent an Asynchronous Notification"));
7766 break;
7767
7768 default:
7769 break;
7770 }
7771 break;
7772 }
7773 case MPI2_EVENT_IR_CONFIGURATION_CHANGE_LIST:
7774 {
7775 /*
7776 * IR TOPOLOGY CHANGE LIST Event has already been handled
7777 * in mpt_handle_event_sync() of interrupt context
7778 */
7779 break;
7780 }
7781 case MPI2_EVENT_IR_OPERATION_STATUS:
7782 {
7783 Mpi2EventDataIrOperationStatus_t *irOpStatus;
7784 char reason_str[80];
7785 uint8_t rc, percent;
7786 uint16_t handle;
7787
7788 irOpStatus = (pMpi2EventDataIrOperationStatus_t)
7789 eventreply->EventData;
7790 rc = ddi_get8(mpt->m_acc_reply_frame_hdl,
7791 &irOpStatus->RAIDOperation);
7792 percent = ddi_get8(mpt->m_acc_reply_frame_hdl,
7793 &irOpStatus->PercentComplete);
7794 handle = ddi_get16(mpt->m_acc_reply_frame_hdl,
7795 &irOpStatus->VolDevHandle);
7796
7797 switch (rc) {
7798 case MPI2_EVENT_IR_RAIDOP_RESYNC:
7799 (void) sprintf(reason_str, "resync");
7800 break;
7801 case MPI2_EVENT_IR_RAIDOP_ONLINE_CAP_EXPANSION:
7802 (void) sprintf(reason_str, "online capacity "
7803 "expansion");
7804 break;
7805 case MPI2_EVENT_IR_RAIDOP_CONSISTENCY_CHECK:
7806 (void) sprintf(reason_str, "consistency check");
7807 break;
7808 default:
7809 (void) sprintf(reason_str, "unknown reason %x",
7810 rc);
7811 }
7812
7813 NDBG20(("mptsas%d raid operational status: (%s)"
7814 "\thandle(0x%04x), percent complete(%d)\n",
7815 mpt->m_instance, reason_str, handle, percent));
7816 break;
7817 }
7818 case MPI2_EVENT_SAS_BROADCAST_PRIMITIVE:
7819 {
7820 pMpi2EventDataSasBroadcastPrimitive_t sas_broadcast;
7821 uint8_t phy_num;
7822 uint8_t primitive;
7823
7824 sas_broadcast = (pMpi2EventDataSasBroadcastPrimitive_t)
7825 eventreply->EventData;
7826
7827 phy_num = ddi_get8(mpt->m_acc_reply_frame_hdl,
7828 &sas_broadcast->PhyNum);
7829 primitive = ddi_get8(mpt->m_acc_reply_frame_hdl,
7830 &sas_broadcast->Primitive);
7831
7832 switch (primitive) {
7833 case MPI2_EVENT_PRIMITIVE_CHANGE:
7834 mptsas_smhba_log_sysevent(mpt,
7835 ESC_SAS_HBA_PORT_BROADCAST,
7836 SAS_PORT_BROADCAST_CHANGE,
7837 &mpt->m_phy_info[phy_num].smhba_info);
7838 break;
7839 case MPI2_EVENT_PRIMITIVE_SES:
7840 mptsas_smhba_log_sysevent(mpt,
7841 ESC_SAS_HBA_PORT_BROADCAST,
7842 SAS_PORT_BROADCAST_SES,
7843 &mpt->m_phy_info[phy_num].smhba_info);
7844 break;
7845 case MPI2_EVENT_PRIMITIVE_EXPANDER:
7846 mptsas_smhba_log_sysevent(mpt,
7847 ESC_SAS_HBA_PORT_BROADCAST,
7848 SAS_PORT_BROADCAST_D01_4,
7849 &mpt->m_phy_info[phy_num].smhba_info);
7850 break;
7851 case MPI2_EVENT_PRIMITIVE_ASYNCHRONOUS_EVENT:
7852 mptsas_smhba_log_sysevent(mpt,
7853 ESC_SAS_HBA_PORT_BROADCAST,
7854 SAS_PORT_BROADCAST_D04_7,
7855 &mpt->m_phy_info[phy_num].smhba_info);
7856 break;
7857 case MPI2_EVENT_PRIMITIVE_RESERVED3:
7858 mptsas_smhba_log_sysevent(mpt,
7859 ESC_SAS_HBA_PORT_BROADCAST,
7860 SAS_PORT_BROADCAST_D16_7,
7861 &mpt->m_phy_info[phy_num].smhba_info);
7862 break;
7863 case MPI2_EVENT_PRIMITIVE_RESERVED4:
7864 mptsas_smhba_log_sysevent(mpt,
7865 ESC_SAS_HBA_PORT_BROADCAST,
7866 SAS_PORT_BROADCAST_D29_7,
7867 &mpt->m_phy_info[phy_num].smhba_info);
7868 break;
7869 case MPI2_EVENT_PRIMITIVE_CHANGE0_RESERVED:
7870 mptsas_smhba_log_sysevent(mpt,
7871 ESC_SAS_HBA_PORT_BROADCAST,
7872 SAS_PORT_BROADCAST_D24_0,
7873 &mpt->m_phy_info[phy_num].smhba_info);
7874 break;
7875 case MPI2_EVENT_PRIMITIVE_CHANGE1_RESERVED:
7876 mptsas_smhba_log_sysevent(mpt,
7877 ESC_SAS_HBA_PORT_BROADCAST,
7878 SAS_PORT_BROADCAST_D27_4,
7879 &mpt->m_phy_info[phy_num].smhba_info);
7880 break;
7881 default:
7882 NDBG16(("mptsas%d: unknown BROADCAST PRIMITIVE"
7883 " %x received",
7884 mpt->m_instance, primitive));
7885 break;
7886 }
7887 NDBG16(("mptsas%d sas broadcast primitive: "
7888 "\tprimitive(0x%04x), phy(%d) complete\n",
7889 mpt->m_instance, primitive, phy_num));
7890 break;
7891 }
7892 case MPI2_EVENT_IR_VOLUME:
7893 {
7894 Mpi2EventDataIrVolume_t *irVolume;
7895 uint16_t devhandle;
7896 uint32_t state;
7897 int config, vol;
7898 uint8_t found = FALSE;
7899
7900 irVolume = (pMpi2EventDataIrVolume_t)eventreply->EventData;
7901 state = ddi_get32(mpt->m_acc_reply_frame_hdl,
7902 &irVolume->NewValue);
7903 devhandle = ddi_get16(mpt->m_acc_reply_frame_hdl,
7904 &irVolume->VolDevHandle);
7905
7906 NDBG20(("EVENT_IR_VOLUME event is received"));
7907
7908 /*
7909 * Get latest RAID info and then find the DevHandle for this
7910 * event in the configuration. If the DevHandle is not found
7911 * just exit the event.
7912 */
7913 (void) mptsas_get_raid_info(mpt);
7914 for (config = 0; (config < mpt->m_num_raid_configs) &&
7915 (!found); config++) {
7916 for (vol = 0; vol < MPTSAS_MAX_RAIDVOLS; vol++) {
7917 if (mpt->m_raidconfig[config].m_raidvol[vol].
7918 m_raidhandle == devhandle) {
7919 found = TRUE;
7920 break;
7921 }
7922 }
7923 }
7924 if (!found) {
7925 break;
7926 }
7927
7928 switch (irVolume->ReasonCode) {
7929 case MPI2_EVENT_IR_VOLUME_RC_SETTINGS_CHANGED:
7930 {
7931 uint32_t i;
7932 mpt->m_raidconfig[config].m_raidvol[vol].m_settings =
7933 state;
7934
7935 i = state & MPI2_RAIDVOL0_SETTING_MASK_WRITE_CACHING;
7936 mptsas_log(mpt, CE_NOTE, " Volume %d settings changed"
7937 ", auto-config of hot-swap drives is %s"
7938 ", write caching is %s"
7939 ", hot-spare pool mask is %02x\n",
7940 vol, state &
7941 MPI2_RAIDVOL0_SETTING_AUTO_CONFIG_HSWAP_DISABLE
7942 ? "disabled" : "enabled",
7943 i == MPI2_RAIDVOL0_SETTING_UNCHANGED
7944 ? "controlled by member disks" :
7945 i == MPI2_RAIDVOL0_SETTING_DISABLE_WRITE_CACHING
7946 ? "disabled" :
7947 i == MPI2_RAIDVOL0_SETTING_ENABLE_WRITE_CACHING
7948 ? "enabled" :
7949 "incorrectly set",
7950 (state >> 16) & 0xff);
7951 break;
7952 }
7953 case MPI2_EVENT_IR_VOLUME_RC_STATE_CHANGED:
7954 {
7955 mpt->m_raidconfig[config].m_raidvol[vol].m_state =
7956 (uint8_t)state;
7957
7958 mptsas_log(mpt, CE_NOTE,
7959 "Volume %d is now %s\n", vol,
7960 state == MPI2_RAID_VOL_STATE_OPTIMAL
7961 ? "optimal" :
7962 state == MPI2_RAID_VOL_STATE_DEGRADED
7963 ? "degraded" :
7964 state == MPI2_RAID_VOL_STATE_ONLINE
7965 ? "online" :
7966 state == MPI2_RAID_VOL_STATE_INITIALIZING
7967 ? "initializing" :
7968 state == MPI2_RAID_VOL_STATE_FAILED
7969 ? "failed" :
7970 state == MPI2_RAID_VOL_STATE_MISSING
7971 ? "missing" :
7972 "state unknown");
7973 break;
7974 }
7975 case MPI2_EVENT_IR_VOLUME_RC_STATUS_FLAGS_CHANGED:
7976 {
7977 mpt->m_raidconfig[config].m_raidvol[vol].
7978 m_statusflags = state;
7979
7980 mptsas_log(mpt, CE_NOTE,
7981 " Volume %d is now %s%s%s%s%s%s%s%s%s\n",
7982 vol,
7983 state & MPI2_RAIDVOL0_STATUS_FLAG_ENABLED
7984 ? ", enabled" : ", disabled",
7985 state & MPI2_RAIDVOL0_STATUS_FLAG_QUIESCED
7986 ? ", quiesced" : "",
7987 state & MPI2_RAIDVOL0_STATUS_FLAG_VOLUME_INACTIVE
7988 ? ", inactive" : ", active",
7989 state &
7990 MPI2_RAIDVOL0_STATUS_FLAG_BAD_BLOCK_TABLE_FULL
7991 ? ", bad block table is full" : "",
7992 state &
7993 MPI2_RAIDVOL0_STATUS_FLAG_RESYNC_IN_PROGRESS
7994 ? ", resync in progress" : "",
7995 state & MPI2_RAIDVOL0_STATUS_FLAG_BACKGROUND_INIT
7996 ? ", background initialization in progress" : "",
7997 state &
7998 MPI2_RAIDVOL0_STATUS_FLAG_CAPACITY_EXPANSION
7999 ? ", capacity expansion in progress" : "",
8000 state &
8001 MPI2_RAIDVOL0_STATUS_FLAG_CONSISTENCY_CHECK
8002 ? ", consistency check in progress" : "",
8003 state & MPI2_RAIDVOL0_STATUS_FLAG_DATA_SCRUB
8004 ? ", data scrub in progress" : "");
8005 break;
8006 }
8007 default:
8008 break;
8009 }
8010 break;
8011 }
8012 case MPI2_EVENT_IR_PHYSICAL_DISK:
8013 {
8014 Mpi2EventDataIrPhysicalDisk_t *irPhysDisk;
8015 uint16_t devhandle, enchandle, slot;
8016 uint32_t status, state;
8017 uint8_t physdisknum, reason;
8018
8019 irPhysDisk = (Mpi2EventDataIrPhysicalDisk_t *)
8020 eventreply->EventData;
8021 physdisknum = ddi_get8(mpt->m_acc_reply_frame_hdl,
8022 &irPhysDisk->PhysDiskNum);
8023 devhandle = ddi_get16(mpt->m_acc_reply_frame_hdl,
8024 &irPhysDisk->PhysDiskDevHandle);
8025 enchandle = ddi_get16(mpt->m_acc_reply_frame_hdl,
8026 &irPhysDisk->EnclosureHandle);
8027 slot = ddi_get16(mpt->m_acc_reply_frame_hdl,
8028 &irPhysDisk->Slot);
8029 state = ddi_get32(mpt->m_acc_reply_frame_hdl,
8030 &irPhysDisk->NewValue);
8031 reason = ddi_get8(mpt->m_acc_reply_frame_hdl,
8032 &irPhysDisk->ReasonCode);
8033
8034 NDBG20(("EVENT_IR_PHYSICAL_DISK event is received"));
8035
8036 switch (reason) {
8037 case MPI2_EVENT_IR_PHYSDISK_RC_SETTINGS_CHANGED:
8038 mptsas_log(mpt, CE_NOTE,
8039 " PhysDiskNum %d with DevHandle 0x%x in slot %d "
8040 "for enclosure with handle 0x%x is now in hot "
8041 "spare pool %d",
8042 physdisknum, devhandle, slot, enchandle,
8043 (state >> 16) & 0xff);
8044 break;
8045
8046 case MPI2_EVENT_IR_PHYSDISK_RC_STATUS_FLAGS_CHANGED:
8047 status = state;
8048 mptsas_log(mpt, CE_NOTE,
8049 " PhysDiskNum %d with DevHandle 0x%x in slot %d "
8050 "for enclosure with handle 0x%x is now "
8051 "%s%s%s%s%s\n", physdisknum, devhandle, slot,
8052 enchandle,
8053 status & MPI2_PHYSDISK0_STATUS_FLAG_INACTIVE_VOLUME
8054 ? ", inactive" : ", active",
8055 status & MPI2_PHYSDISK0_STATUS_FLAG_OUT_OF_SYNC
8056 ? ", out of sync" : "",
8057 status & MPI2_PHYSDISK0_STATUS_FLAG_QUIESCED
8058 ? ", quiesced" : "",
8059 status &
8060 MPI2_PHYSDISK0_STATUS_FLAG_WRITE_CACHE_ENABLED
8061 ? ", write cache enabled" : "",
8062 status & MPI2_PHYSDISK0_STATUS_FLAG_OCE_TARGET
8063 ? ", capacity expansion target" : "");
8064 break;
8065
8066 case MPI2_EVENT_IR_PHYSDISK_RC_STATE_CHANGED:
8067 mptsas_log(mpt, CE_NOTE,
8068 " PhysDiskNum %d with DevHandle 0x%x in slot %d "
8069 "for enclosure with handle 0x%x is now %s\n",
8070 physdisknum, devhandle, slot, enchandle,
8071 state == MPI2_RAID_PD_STATE_OPTIMAL
8072 ? "optimal" :
8073 state == MPI2_RAID_PD_STATE_REBUILDING
8074 ? "rebuilding" :
8075 state == MPI2_RAID_PD_STATE_DEGRADED
8076 ? "degraded" :
8077 state == MPI2_RAID_PD_STATE_HOT_SPARE
8078 ? "a hot spare" :
8079 state == MPI2_RAID_PD_STATE_ONLINE
8080 ? "online" :
8081 state == MPI2_RAID_PD_STATE_OFFLINE
8082 ? "offline" :
8083 state == MPI2_RAID_PD_STATE_NOT_COMPATIBLE
8084 ? "not compatible" :
8085 state == MPI2_RAID_PD_STATE_NOT_CONFIGURED
8086 ? "not configured" :
8087 "state unknown");
8088 break;
8089 }
8090 break;
8091 }
8092 default:
8093 NDBG20(("mptsas%d: unknown event %x received",
8094 mpt->m_instance, event));
8095 break;
8096 }
8097
8098 /*
8099 * Return the reply frame to the free queue.
8100 */
8101 ddi_put32(mpt->m_acc_free_queue_hdl,
8102 &((uint32_t *)(void *)mpt->m_free_queue)[mpt->m_free_index], rfm);
8103 (void) ddi_dma_sync(mpt->m_dma_free_queue_hdl, 0, 0,
8104 DDI_DMA_SYNC_FORDEV);
8105 if (++mpt->m_free_index == mpt->m_free_queue_depth) {
8106 mpt->m_free_index = 0;
8107 }
8108 ddi_put32(mpt->m_datap, &mpt->m_reg->ReplyFreeHostIndex,
8109 mpt->m_free_index);
8110 mutex_exit(&mpt->m_mutex);
8111 }
8112
8113 /*
8114 * invoked from timeout() to restart qfull cmds with throttle == 0
8115 */
8116 static void
8117 mptsas_restart_cmd(void *arg)
8118 {
8119 mptsas_t *mpt = arg;
8120 mptsas_target_t *ptgt = NULL;
8121
8122 mutex_enter(&mpt->m_mutex);
8123
8124 mpt->m_restart_cmd_timeid = 0;
8125
8126 for (ptgt = refhash_first(mpt->m_targets); ptgt != NULL;
8127 ptgt = refhash_next(mpt->m_targets, ptgt)) {
8128 if (ptgt->m_reset_delay == 0) {
8129 if (ptgt->m_t_throttle == QFULL_THROTTLE) {
8130 mptsas_set_throttle(mpt, ptgt,
8131 MAX_THROTTLE);
8132 }
8133 }
8134 }
8135 mptsas_restart_hba(mpt);
8136 mutex_exit(&mpt->m_mutex);
8137 }
8138
8139 void
8140 mptsas_remove_cmd(mptsas_t *mpt, mptsas_cmd_t *cmd)
8141 {
8142 int slot;
8143 mptsas_slots_t *slots = mpt->m_active;
8144 mptsas_target_t *ptgt = cmd->cmd_tgt_addr;
8145
8146 ASSERT(cmd != NULL);
8147 ASSERT(cmd->cmd_queued == FALSE);
8148
8149 /*
8150 * Task Management cmds are removed in their own routines. Also,
8151 * we don't want to modify timeout based on TM cmds.
8152 */
8153 if (cmd->cmd_flags & CFLAG_TM_CMD) {
8154 return;
8155 }
8156
8157 slot = cmd->cmd_slot;
8158
8159 /*
8160 * remove the cmd.
8161 */
8162 if (cmd == slots->m_slot[slot]) {
8163 NDBG31(("mptsas_remove_cmd: removing cmd=0x%p, flags "
8164 "0x%x", (void *)cmd, cmd->cmd_flags));
8165 slots->m_slot[slot] = NULL;
8166 mpt->m_ncmds--;
8167
8168 /*
8169 * only decrement per target ncmds if command
8170 * has a target associated with it.
8171 */
8172 if ((cmd->cmd_flags & CFLAG_CMDIOC) == 0) {
8173 ptgt->m_t_ncmds--;
8174 /*
8175 * reset throttle if we just ran an untagged command
8176 * to a tagged target
8177 */
8178 if ((ptgt->m_t_ncmds == 0) &&
8179 ((cmd->cmd_pkt_flags & FLAG_TAGMASK) == 0)) {
8180 mptsas_set_throttle(mpt, ptgt, MAX_THROTTLE);
8181 }
8182
8183 /*
8184 * Remove this command from the active queue.
8185 */
8186 if (cmd->cmd_active_expiration != 0) {
8187 TAILQ_REMOVE(&ptgt->m_active_cmdq, cmd,
8188 cmd_active_link);
8189 cmd->cmd_active_expiration = 0;
8190 }
8191 }
8192 }
8193
8194 /*
8195 * This is all we need to do for ioc commands.
8196 */
8197 if (cmd->cmd_flags & CFLAG_CMDIOC) {
8198 mptsas_return_to_pool(mpt, cmd);
8199 return;
8200 }
8201
8202 ASSERT(cmd != slots->m_slot[cmd->cmd_slot]);
8203 }
8204
8205 /*
8206 * accept all cmds on the tx_waitq if any and then
8207 * start a fresh request from the top of the device queue.
8208 *
8209 * since there are always cmds queued on the tx_waitq, and rare cmds on
8210 * the instance waitq, so this function should not be invoked in the ISR,
8211 * the mptsas_restart_waitq() is invoked in the ISR instead. otherwise, the
8212 * burden belongs to the IO dispatch CPUs is moved the interrupt CPU.
8213 */
8214 static void
8215 mptsas_restart_hba(mptsas_t *mpt)
8216 {
8217 ASSERT(mutex_owned(&mpt->m_mutex));
8218
8219 mutex_enter(&mpt->m_tx_waitq_mutex);
8220 if (mpt->m_tx_waitq) {
8221 mptsas_accept_tx_waitq(mpt);
8222 }
8223 mutex_exit(&mpt->m_tx_waitq_mutex);
8224 mptsas_restart_waitq(mpt);
8225 }
8226
8227 /*
8228 * start a fresh request from the top of the device queue
8229 */
8230 static void
8231 mptsas_restart_waitq(mptsas_t *mpt)
8232 {
8233 mptsas_cmd_t *cmd, *next_cmd;
8234 mptsas_target_t *ptgt = NULL;
8235
8236 NDBG1(("mptsas_restart_waitq: mpt=0x%p", (void *)mpt));
8237
8238 ASSERT(mutex_owned(&mpt->m_mutex));
8239
8240 /*
8241 * If there is a reset delay, don't start any cmds. Otherwise, start
8242 * as many cmds as possible.
8243 * Since SMID 0 is reserved and the TM slot is reserved, the actual max
8244 * commands is m_max_requests - 2.
8245 */
8246 cmd = mpt->m_waitq;
8247
8248 while (cmd != NULL) {
8249 next_cmd = cmd->cmd_linkp;
8250 if (cmd->cmd_flags & CFLAG_PASSTHRU) {
8251 if (mptsas_save_cmd(mpt, cmd) == TRUE) {
8252 /*
8253 * passthru command get slot need
8254 * set CFLAG_PREPARED.
8255 */
8256 cmd->cmd_flags |= CFLAG_PREPARED;
8257 mptsas_waitq_delete(mpt, cmd);
8258 mptsas_start_passthru(mpt, cmd);
8259 }
8260 cmd = next_cmd;
8261 continue;
8262 }
8263 if (cmd->cmd_flags & CFLAG_CONFIG) {
8264 if (mptsas_save_cmd(mpt, cmd) == TRUE) {
8265 /*
8266 * Send the config page request and delete it
8267 * from the waitq.
8268 */
8269 cmd->cmd_flags |= CFLAG_PREPARED;
8270 mptsas_waitq_delete(mpt, cmd);
8271 mptsas_start_config_page_access(mpt, cmd);
8272 }
8273 cmd = next_cmd;
8274 continue;
8275 }
8276 if (cmd->cmd_flags & CFLAG_FW_DIAG) {
8277 if (mptsas_save_cmd(mpt, cmd) == TRUE) {
8278 /*
8279 * Send the FW Diag request and delete if from
8280 * the waitq.
8281 */
8282 cmd->cmd_flags |= CFLAG_PREPARED;
8283 mptsas_waitq_delete(mpt, cmd);
8284 mptsas_start_diag(mpt, cmd);
8285 }
8286 cmd = next_cmd;
8287 continue;
8288 }
8289
8290 ptgt = cmd->cmd_tgt_addr;
8291 if (ptgt && (ptgt->m_t_throttle == DRAIN_THROTTLE) &&
8292 (ptgt->m_t_ncmds == 0)) {
8293 mptsas_set_throttle(mpt, ptgt, MAX_THROTTLE);
8294 }
8295 if ((mpt->m_ncmds <= (mpt->m_max_requests - 2)) &&
8296 (ptgt && (ptgt->m_reset_delay == 0)) &&
8297 (ptgt && (ptgt->m_t_ncmds <
8298 ptgt->m_t_throttle))) {
8299 if (mptsas_save_cmd(mpt, cmd) == TRUE) {
8300 mptsas_waitq_delete(mpt, cmd);
8301 (void) mptsas_start_cmd(mpt, cmd);
8302 }
8303 }
8304 cmd = next_cmd;
8305 }
8306 }
8307 /*
8308 * Cmds are queued if tran_start() doesn't get the m_mutexlock(no wait).
8309 * Accept all those queued cmds before new cmd is accept so that the
8310 * cmds are sent in order.
8311 */
8312 static void
8313 mptsas_accept_tx_waitq(mptsas_t *mpt)
8314 {
8315 mptsas_cmd_t *cmd;
8316
8317 ASSERT(mutex_owned(&mpt->m_mutex));
8318 ASSERT(mutex_owned(&mpt->m_tx_waitq_mutex));
8319
8320 /*
8321 * A Bus Reset could occur at any time and flush the tx_waitq,
8322 * so we cannot count on the tx_waitq to contain even one cmd.
8323 * And when the m_tx_waitq_mutex is released and run
8324 * mptsas_accept_pkt(), the tx_waitq may be flushed.
8325 */
8326 cmd = mpt->m_tx_waitq;
8327 for (;;) {
8328 if ((cmd = mpt->m_tx_waitq) == NULL) {
8329 mpt->m_tx_draining = 0;
8330 break;
8331 }
8332 if ((mpt->m_tx_waitq = cmd->cmd_linkp) == NULL) {
8333 mpt->m_tx_waitqtail = &mpt->m_tx_waitq;
8334 }
8335 cmd->cmd_linkp = NULL;
8336 mutex_exit(&mpt->m_tx_waitq_mutex);
8337 if (mptsas_accept_pkt(mpt, cmd) != TRAN_ACCEPT)
8338 cmn_err(CE_WARN, "mpt: mptsas_accept_tx_waitq: failed "
8339 "to accept cmd on queue\n");
8340 mutex_enter(&mpt->m_tx_waitq_mutex);
8341 }
8342 }
8343
8344
8345 /*
8346 * mpt tag type lookup
8347 */
8348 static char mptsas_tag_lookup[] =
8349 {0, MSG_HEAD_QTAG, MSG_ORDERED_QTAG, 0, MSG_SIMPLE_QTAG};
8350
8351 static int
8352 mptsas_start_cmd(mptsas_t *mpt, mptsas_cmd_t *cmd)
8353 {
8354 struct scsi_pkt *pkt = CMD2PKT(cmd);
8355 uint32_t control = 0;
8356 caddr_t mem, arsbuf;
8357 pMpi2SCSIIORequest_t io_request;
8358 ddi_dma_handle_t dma_hdl = mpt->m_dma_req_frame_hdl;
8359 ddi_acc_handle_t acc_hdl = mpt->m_acc_req_frame_hdl;
8360 mptsas_target_t *ptgt = cmd->cmd_tgt_addr;
8361 uint16_t SMID, io_flags = 0;
8362 uint8_t ars_size;
8363 uint64_t request_desc;
8364 uint32_t ars_dmaaddrlow;
8365 mptsas_cmd_t *c;
8366
8367 NDBG1(("mptsas_start_cmd: cmd=0x%p, flags 0x%x", (void *)cmd,
8368 cmd->cmd_flags));
8369
8370 /*
8371 * Set SMID and increment index. Rollover to 1 instead of 0 if index
8372 * is at the max. 0 is an invalid SMID, so we call the first index 1.
8373 */
8374 SMID = cmd->cmd_slot;
8375
8376 /*
8377 * It is possible for back to back device reset to
8378 * happen before the reset delay has expired. That's
8379 * ok, just let the device reset go out on the bus.
8380 */
8381 if ((cmd->cmd_pkt_flags & FLAG_NOINTR) == 0) {
8382 ASSERT(ptgt->m_reset_delay == 0);
8383 }
8384
8385 /*
8386 * if a non-tagged cmd is submitted to an active tagged target
8387 * then drain before submitting this cmd; SCSI-2 allows RQSENSE
8388 * to be untagged
8389 */
8390 if (((cmd->cmd_pkt_flags & FLAG_TAGMASK) == 0) &&
8391 (ptgt->m_t_ncmds > 1) &&
8392 ((cmd->cmd_flags & CFLAG_TM_CMD) == 0) &&
8393 (*(cmd->cmd_pkt->pkt_cdbp) != SCMD_REQUEST_SENSE)) {
8394 if ((cmd->cmd_pkt_flags & FLAG_NOINTR) == 0) {
8395 NDBG23(("target=%d, untagged cmd, start draining\n",
8396 ptgt->m_devhdl));
8397
8398 if (ptgt->m_reset_delay == 0) {
8399 mptsas_set_throttle(mpt, ptgt, DRAIN_THROTTLE);
8400 }
8401
8402 mptsas_remove_cmd(mpt, cmd);
8403 cmd->cmd_pkt_flags |= FLAG_HEAD;
8404 mptsas_waitq_add(mpt, cmd);
8405 }
8406 return (DDI_FAILURE);
8407 }
8408
8409 /*
8410 * Set correct tag bits.
8411 */
8412 if (cmd->cmd_pkt_flags & FLAG_TAGMASK) {
8413 switch (mptsas_tag_lookup[((cmd->cmd_pkt_flags &
8414 FLAG_TAGMASK) >> 12)]) {
8415 case MSG_SIMPLE_QTAG:
8416 control |= MPI2_SCSIIO_CONTROL_SIMPLEQ;
8417 break;
8418 case MSG_HEAD_QTAG:
8419 control |= MPI2_SCSIIO_CONTROL_HEADOFQ;
8420 break;
8421 case MSG_ORDERED_QTAG:
8422 control |= MPI2_SCSIIO_CONTROL_ORDEREDQ;
8423 break;
8424 default:
8425 mptsas_log(mpt, CE_WARN, "mpt: Invalid tag type\n");
8426 break;
8427 }
8428 } else {
8429 if (*(cmd->cmd_pkt->pkt_cdbp) != SCMD_REQUEST_SENSE) {
8430 ptgt->m_t_throttle = 1;
8431 }
8432 control |= MPI2_SCSIIO_CONTROL_SIMPLEQ;
8433 }
8434
8435 if (cmd->cmd_pkt_flags & FLAG_TLR) {
8436 control |= MPI2_SCSIIO_CONTROL_TLR_ON;
8437 }
8438
8439 mem = mpt->m_req_frame + (mpt->m_req_frame_size * SMID);
8440 io_request = (pMpi2SCSIIORequest_t)mem;
8441 if (cmd->cmd_extrqslen != 0) {
8442 /*
8443 * Mapping of the buffer was done in mptsas_pkt_alloc_extern().
8444 * Calculate the DMA address with the same offset.
8445 */
8446 arsbuf = cmd->cmd_arq_buf;
8447 ars_size = cmd->cmd_extrqslen;
8448 ars_dmaaddrlow = (mpt->m_req_sense_dma_addr +
8449 ((uintptr_t)arsbuf - (uintptr_t)mpt->m_req_sense)) &
8450 0xffffffffu;
8451 } else {
8452 arsbuf = mpt->m_req_sense + (mpt->m_req_sense_size * (SMID-1));
8453 cmd->cmd_arq_buf = arsbuf;
8454 ars_size = mpt->m_req_sense_size;
8455 ars_dmaaddrlow = (mpt->m_req_sense_dma_addr +
8456 (mpt->m_req_sense_size * (SMID-1))) &
8457 0xffffffffu;
8458 }
8459 bzero(io_request, sizeof (Mpi2SCSIIORequest_t));
8460 bzero(arsbuf, ars_size);
8461
8462 ddi_put8(acc_hdl, &io_request->SGLOffset0, offsetof
8463 (MPI2_SCSI_IO_REQUEST, SGL) / 4);
8464 mptsas_init_std_hdr(acc_hdl, io_request, ptgt->m_devhdl, Lun(cmd), 0,
8465 MPI2_FUNCTION_SCSI_IO_REQUEST);
8466
8467 (void) ddi_rep_put8(acc_hdl, (uint8_t *)pkt->pkt_cdbp,
8468 io_request->CDB.CDB32, cmd->cmd_cdblen, DDI_DEV_AUTOINCR);
8469
8470 io_flags = cmd->cmd_cdblen;
8471 if (mptsas_use_fastpath &&
8472 ptgt->m_io_flags & MPI25_SAS_DEVICE0_FLAGS_ENABLED_FAST_PATH) {
8473 io_flags |= MPI25_SCSIIO_IOFLAGS_FAST_PATH;
8474 request_desc = MPI25_REQ_DESCRIPT_FLAGS_FAST_PATH_SCSI_IO;
8475 } else {
8476 request_desc = MPI2_REQ_DESCRIPT_FLAGS_SCSI_IO;
8477 }
8478 ddi_put16(acc_hdl, &io_request->IoFlags, io_flags);
8479 /*
8480 * setup the Scatter/Gather DMA list for this request
8481 */
8482 if (cmd->cmd_cookiec > 0) {
8483 mptsas_sge_setup(mpt, cmd, &control, io_request, acc_hdl);
8484 } else {
8485 ddi_put32(acc_hdl, &io_request->SGL.MpiSimple.FlagsLength,
8486 ((uint32_t)MPI2_SGE_FLAGS_LAST_ELEMENT |
8487 MPI2_SGE_FLAGS_END_OF_BUFFER |
8488 MPI2_SGE_FLAGS_SIMPLE_ELEMENT |
8489 MPI2_SGE_FLAGS_END_OF_LIST) << MPI2_SGE_FLAGS_SHIFT);
8490 }
8491
8492 /*
8493 * save ARQ information
8494 */
8495 ddi_put8(acc_hdl, &io_request->SenseBufferLength, ars_size);
8496 ddi_put32(acc_hdl, &io_request->SenseBufferLowAddress, ars_dmaaddrlow);
8497
8498 ddi_put32(acc_hdl, &io_request->Control, control);
8499
8500 NDBG31(("starting message=%d(0x%p), with cmd=0x%p",
8501 SMID, (void *)io_request, (void *)cmd));
8502
8503 (void) ddi_dma_sync(dma_hdl, 0, 0, DDI_DMA_SYNC_FORDEV);
8504 (void) ddi_dma_sync(mpt->m_dma_req_sense_hdl, 0, 0,
8505 DDI_DMA_SYNC_FORDEV);
8506
8507 /*
8508 * Build request descriptor and write it to the request desc post reg.
8509 */
8510 request_desc |= (SMID << 16);
8511 request_desc |= (uint64_t)ptgt->m_devhdl << 48;
8512 MPTSAS_START_CMD(mpt, request_desc);
8513
8514 /*
8515 * Start timeout.
8516 */
8517 cmd->cmd_active_expiration =
8518 gethrtime() + (hrtime_t)pkt->pkt_time * NANOSEC;
8519 #ifdef MPTSAS_TEST
8520 /*
8521 * Force timeouts to happen immediately.
8522 */
8523 if (mptsas_test_timeouts)
8524 cmd->cmd_active_expiration = gethrtime();
8525 #endif
8526 c = TAILQ_FIRST(&ptgt->m_active_cmdq);
8527 if (c == NULL ||
8528 c->cmd_active_expiration < cmd->cmd_active_expiration) {
8529 /*
8530 * Common case is that this is the last pending expiration
8531 * (or queue is empty). Insert at head of the queue.
8532 */
8533 TAILQ_INSERT_HEAD(&ptgt->m_active_cmdq, cmd, cmd_active_link);
8534 } else {
8535 /*
8536 * Queue is not empty and first element expires later than
8537 * this command. Search for element expiring sooner.
8538 */
8539 while ((c = TAILQ_NEXT(c, cmd_active_link)) != NULL) {
8540 if (c->cmd_active_expiration <
8541 cmd->cmd_active_expiration) {
8542 TAILQ_INSERT_BEFORE(c, cmd, cmd_active_link);
8543 break;
8544 }
8545 }
8546 if (c == NULL) {
8547 /*
8548 * No element found expiring sooner, append to
8549 * non-empty queue.
8550 */
8551 TAILQ_INSERT_TAIL(&ptgt->m_active_cmdq, cmd,
8552 cmd_active_link);
8553 }
8554 }
8555
8556 if ((mptsas_check_dma_handle(dma_hdl) != DDI_SUCCESS) ||
8557 (mptsas_check_acc_handle(acc_hdl) != DDI_SUCCESS)) {
8558 ddi_fm_service_impact(mpt->m_dip, DDI_SERVICE_UNAFFECTED);
8559 return (DDI_FAILURE);
8560 }
8561 return (DDI_SUCCESS);
8562 }
8563
8564 /*
8565 * Select a helper thread to handle current doneq
8566 */
8567 static void
8568 mptsas_deliver_doneq_thread(mptsas_t *mpt)
8569 {
8570 uint64_t t, i;
8571 uint32_t min = 0xffffffff;
8572 mptsas_doneq_thread_list_t *item;
8573
8574 for (i = 0; i < mpt->m_doneq_thread_n; i++) {
8575 item = &mpt->m_doneq_thread_id[i];
8576 /*
8577 * If the completed command on help thread[i] less than
8578 * doneq_thread_threshold, then pick the thread[i]. Otherwise
8579 * pick a thread which has least completed command.
8580 */
8581
8582 mutex_enter(&item->mutex);
8583 if (item->len < mpt->m_doneq_thread_threshold) {
8584 t = i;
8585 mutex_exit(&item->mutex);
8586 break;
8587 }
8588 if (item->len < min) {
8589 min = item->len;
8590 t = i;
8591 }
8592 mutex_exit(&item->mutex);
8593 }
8594 mutex_enter(&mpt->m_doneq_thread_id[t].mutex);
8595 mptsas_doneq_mv(mpt, t);
8596 cv_signal(&mpt->m_doneq_thread_id[t].cv);
8597 mutex_exit(&mpt->m_doneq_thread_id[t].mutex);
8598 }
8599
8600 /*
8601 * move the current global doneq to the doneq of thead[t]
8602 */
8603 static void
8604 mptsas_doneq_mv(mptsas_t *mpt, uint64_t t)
8605 {
8606 mptsas_cmd_t *cmd;
8607 mptsas_doneq_thread_list_t *item = &mpt->m_doneq_thread_id[t];
8608
8609 ASSERT(mutex_owned(&item->mutex));
8610 while ((cmd = mpt->m_doneq) != NULL) {
8611 if ((mpt->m_doneq = cmd->cmd_linkp) == NULL) {
8612 mpt->m_donetail = &mpt->m_doneq;
8613 }
8614 cmd->cmd_linkp = NULL;
8615 *item->donetail = cmd;
8616 item->donetail = &cmd->cmd_linkp;
8617 mpt->m_doneq_len--;
8618 item->len++;
8619 }
8620 }
8621
8622 void
8623 mptsas_fma_check(mptsas_t *mpt, mptsas_cmd_t *cmd)
8624 {
8625 struct scsi_pkt *pkt = CMD2PKT(cmd);
8626
8627 /* Check all acc and dma handles */
8628 if ((mptsas_check_acc_handle(mpt->m_datap) !=
8629 DDI_SUCCESS) ||
8630 (mptsas_check_acc_handle(mpt->m_acc_req_frame_hdl) !=
8631 DDI_SUCCESS) ||
8632 (mptsas_check_acc_handle(mpt->m_acc_req_sense_hdl) !=
8633 DDI_SUCCESS) ||
8634 (mptsas_check_acc_handle(mpt->m_acc_reply_frame_hdl) !=
8635 DDI_SUCCESS) ||
8636 (mptsas_check_acc_handle(mpt->m_acc_free_queue_hdl) !=
8637 DDI_SUCCESS) ||
8638 (mptsas_check_acc_handle(mpt->m_acc_post_queue_hdl) !=
8639 DDI_SUCCESS) ||
8640 (mptsas_check_acc_handle(mpt->m_hshk_acc_hdl) !=
8641 DDI_SUCCESS) ||
8642 (mptsas_check_acc_handle(mpt->m_config_handle) !=
8643 DDI_SUCCESS)) {
8644 ddi_fm_service_impact(mpt->m_dip,
8645 DDI_SERVICE_UNAFFECTED);
8646 ddi_fm_acc_err_clear(mpt->m_config_handle,
8647 DDI_FME_VER0);
8648 pkt->pkt_reason = CMD_TRAN_ERR;
8649 pkt->pkt_statistics = 0;
8650 }
8651 if ((mptsas_check_dma_handle(mpt->m_dma_req_frame_hdl) !=
8652 DDI_SUCCESS) ||
8653 (mptsas_check_dma_handle(mpt->m_dma_req_sense_hdl) !=
8654 DDI_SUCCESS) ||
8655 (mptsas_check_dma_handle(mpt->m_dma_reply_frame_hdl) !=
8656 DDI_SUCCESS) ||
8657 (mptsas_check_dma_handle(mpt->m_dma_free_queue_hdl) !=
8658 DDI_SUCCESS) ||
8659 (mptsas_check_dma_handle(mpt->m_dma_post_queue_hdl) !=
8660 DDI_SUCCESS) ||
8661 (mptsas_check_dma_handle(mpt->m_hshk_dma_hdl) !=
8662 DDI_SUCCESS)) {
8663 ddi_fm_service_impact(mpt->m_dip,
8664 DDI_SERVICE_UNAFFECTED);
8665 pkt->pkt_reason = CMD_TRAN_ERR;
8666 pkt->pkt_statistics = 0;
8667 }
8668 if (cmd->cmd_dmahandle &&
8669 (mptsas_check_dma_handle(cmd->cmd_dmahandle) != DDI_SUCCESS)) {
8670 ddi_fm_service_impact(mpt->m_dip, DDI_SERVICE_UNAFFECTED);
8671 pkt->pkt_reason = CMD_TRAN_ERR;
8672 pkt->pkt_statistics = 0;
8673 }
8674 if ((cmd->cmd_extra_frames &&
8675 ((mptsas_check_dma_handle(cmd->cmd_extra_frames->m_dma_hdl) !=
8676 DDI_SUCCESS) ||
8677 (mptsas_check_acc_handle(cmd->cmd_extra_frames->m_acc_hdl) !=
8678 DDI_SUCCESS)))) {
8679 ddi_fm_service_impact(mpt->m_dip, DDI_SERVICE_UNAFFECTED);
8680 pkt->pkt_reason = CMD_TRAN_ERR;
8681 pkt->pkt_statistics = 0;
8682 }
8683 }
8684
8685 /*
8686 * These routines manipulate the queue of commands that
8687 * are waiting for their completion routines to be called.
8688 * The queue is usually in FIFO order but on an MP system
8689 * it's possible for the completion routines to get out
8690 * of order. If that's a problem you need to add a global
8691 * mutex around the code that calls the completion routine
8692 * in the interrupt handler.
8693 */
8694 static void
8695 mptsas_doneq_add(mptsas_t *mpt, mptsas_cmd_t *cmd)
8696 {
8697 struct scsi_pkt *pkt = CMD2PKT(cmd);
8698
8699 NDBG31(("mptsas_doneq_add: cmd=0x%p", (void *)cmd));
8700
8701 ASSERT((cmd->cmd_flags & CFLAG_COMPLETED) == 0);
8702 cmd->cmd_linkp = NULL;
8703 cmd->cmd_flags |= CFLAG_FINISHED;
8704 cmd->cmd_flags &= ~CFLAG_IN_TRANSPORT;
8705
8706 mptsas_fma_check(mpt, cmd);
8707
8708 /*
8709 * only add scsi pkts that have completion routines to
8710 * the doneq. no intr cmds do not have callbacks.
8711 */
8712 if (pkt && (pkt->pkt_comp)) {
8713 *mpt->m_donetail = cmd;
8714 mpt->m_donetail = &cmd->cmd_linkp;
8715 mpt->m_doneq_len++;
8716 }
8717 }
8718
8719 static mptsas_cmd_t *
8720 mptsas_doneq_thread_rm(mptsas_t *mpt, uint64_t t)
8721 {
8722 mptsas_cmd_t *cmd;
8723 mptsas_doneq_thread_list_t *item = &mpt->m_doneq_thread_id[t];
8724
8725 /* pop one off the done queue */
8726 if ((cmd = item->doneq) != NULL) {
8727 /* if the queue is now empty fix the tail pointer */
8728 NDBG31(("mptsas_doneq_thread_rm: cmd=0x%p", (void *)cmd));
8729 if ((item->doneq = cmd->cmd_linkp) == NULL) {
8730 item->donetail = &item->doneq;
8731 }
8732 cmd->cmd_linkp = NULL;
8733 item->len--;
8734 }
8735 return (cmd);
8736 }
8737
8738 static void
8739 mptsas_doneq_empty(mptsas_t *mpt)
8740 {
8741 if (mpt->m_doneq && !mpt->m_in_callback) {
8742 mptsas_cmd_t *cmd, *next;
8743 struct scsi_pkt *pkt;
8744
8745 mpt->m_in_callback = 1;
8746 cmd = mpt->m_doneq;
8747 mpt->m_doneq = NULL;
8748 mpt->m_donetail = &mpt->m_doneq;
8749 mpt->m_doneq_len = 0;
8750
8751 mutex_exit(&mpt->m_mutex);
8752 /*
8753 * run the completion routines of all the
8754 * completed commands
8755 */
8756 while (cmd != NULL) {
8757 next = cmd->cmd_linkp;
8758 cmd->cmd_linkp = NULL;
8759 /* run this command's completion routine */
8760 cmd->cmd_flags |= CFLAG_COMPLETED;
8761 pkt = CMD2PKT(cmd);
8762 mptsas_pkt_comp(pkt, cmd);
8763 cmd = next;
8764 }
8765 mutex_enter(&mpt->m_mutex);
8766 mpt->m_in_callback = 0;
8767 }
8768 }
8769
8770 /*
8771 * These routines manipulate the target's queue of pending requests
8772 */
8773 void
8774 mptsas_waitq_add(mptsas_t *mpt, mptsas_cmd_t *cmd)
8775 {
8776 NDBG7(("mptsas_waitq_add: cmd=0x%p", (void *)cmd));
8777 mptsas_target_t *ptgt = cmd->cmd_tgt_addr;
8778 cmd->cmd_queued = TRUE;
8779 if (ptgt)
8780 ptgt->m_t_nwait++;
8781 if (cmd->cmd_pkt_flags & FLAG_HEAD) {
8782 if ((cmd->cmd_linkp = mpt->m_waitq) == NULL) {
8783 mpt->m_waitqtail = &cmd->cmd_linkp;
8784 }
8785 mpt->m_waitq = cmd;
8786 } else {
8787 cmd->cmd_linkp = NULL;
8788 *(mpt->m_waitqtail) = cmd;
8789 mpt->m_waitqtail = &cmd->cmd_linkp;
8790 }
8791 }
8792
8793 static mptsas_cmd_t *
8794 mptsas_waitq_rm(mptsas_t *mpt)
8795 {
8796 mptsas_cmd_t *cmd;
8797 mptsas_target_t *ptgt;
8798 NDBG7(("mptsas_waitq_rm"));
8799
8800 MPTSAS_WAITQ_RM(mpt, cmd);
8801
8802 NDBG7(("mptsas_waitq_rm: cmd=0x%p", (void *)cmd));
8803 if (cmd) {
8804 ptgt = cmd->cmd_tgt_addr;
8805 if (ptgt) {
8806 ptgt->m_t_nwait--;
8807 ASSERT(ptgt->m_t_nwait >= 0);
8808 }
8809 }
8810 return (cmd);
8811 }
8812
8813 /*
8814 * remove specified cmd from the middle of the wait queue.
8815 */
8816 static void
8817 mptsas_waitq_delete(mptsas_t *mpt, mptsas_cmd_t *cmd)
8818 {
8819 mptsas_cmd_t *prevp = mpt->m_waitq;
8820 mptsas_target_t *ptgt = cmd->cmd_tgt_addr;
8821
8822 NDBG7(("mptsas_waitq_delete: mpt=0x%p cmd=0x%p",
8823 (void *)mpt, (void *)cmd));
8824 if (ptgt) {
8825 ptgt->m_t_nwait--;
8826 ASSERT(ptgt->m_t_nwait >= 0);
8827 }
8828
8829 if (prevp == cmd) {
8830 if ((mpt->m_waitq = cmd->cmd_linkp) == NULL)
8831 mpt->m_waitqtail = &mpt->m_waitq;
8832
8833 cmd->cmd_linkp = NULL;
8834 cmd->cmd_queued = FALSE;
8835 NDBG7(("mptsas_waitq_delete: mpt=0x%p cmd=0x%p",
8836 (void *)mpt, (void *)cmd));
8837 return;
8838 }
8839
8840 while (prevp != NULL) {
8841 if (prevp->cmd_linkp == cmd) {
8842 if ((prevp->cmd_linkp = cmd->cmd_linkp) == NULL)
8843 mpt->m_waitqtail = &prevp->cmd_linkp;
8844
8845 cmd->cmd_linkp = NULL;
8846 cmd->cmd_queued = FALSE;
8847 NDBG7(("mptsas_waitq_delete: mpt=0x%p cmd=0x%p",
8848 (void *)mpt, (void *)cmd));
8849 return;
8850 }
8851 prevp = prevp->cmd_linkp;
8852 }
8853 cmn_err(CE_PANIC, "mpt: mptsas_waitq_delete: queue botch");
8854 }
8855
8856 static mptsas_cmd_t *
8857 mptsas_tx_waitq_rm(mptsas_t *mpt)
8858 {
8859 mptsas_cmd_t *cmd;
8860 NDBG7(("mptsas_tx_waitq_rm"));
8861
8862 MPTSAS_TX_WAITQ_RM(mpt, cmd);
8863
8864 NDBG7(("mptsas_tx_waitq_rm: cmd=0x%p", (void *)cmd));
8865
8866 return (cmd);
8867 }
8868
8869 /*
8870 * remove specified cmd from the middle of the tx_waitq.
8871 */
8872 static void
8873 mptsas_tx_waitq_delete(mptsas_t *mpt, mptsas_cmd_t *cmd)
8874 {
8875 mptsas_cmd_t *prevp = mpt->m_tx_waitq;
8876
8877 NDBG7(("mptsas_tx_waitq_delete: mpt=0x%p cmd=0x%p",
8878 (void *)mpt, (void *)cmd));
8879
8880 if (prevp == cmd) {
8881 if ((mpt->m_tx_waitq = cmd->cmd_linkp) == NULL)
8882 mpt->m_tx_waitqtail = &mpt->m_tx_waitq;
8883
8884 cmd->cmd_linkp = NULL;
8885 cmd->cmd_queued = FALSE;
8886 NDBG7(("mptsas_tx_waitq_delete: mpt=0x%p cmd=0x%p",
8887 (void *)mpt, (void *)cmd));
8888 return;
8889 }
8890
8891 while (prevp != NULL) {
8892 if (prevp->cmd_linkp == cmd) {
8893 if ((prevp->cmd_linkp = cmd->cmd_linkp) == NULL)
8894 mpt->m_tx_waitqtail = &prevp->cmd_linkp;
8895
8896 cmd->cmd_linkp = NULL;
8897 cmd->cmd_queued = FALSE;
8898 NDBG7(("mptsas_tx_waitq_delete: mpt=0x%p cmd=0x%p",
8899 (void *)mpt, (void *)cmd));
8900 return;
8901 }
8902 prevp = prevp->cmd_linkp;
8903 }
8904 cmn_err(CE_PANIC, "mpt: mptsas_tx_waitq_delete: queue botch");
8905 }
8906
8907 /*
8908 * device and bus reset handling
8909 *
8910 * Notes:
8911 * - RESET_ALL: reset the controller
8912 * - RESET_TARGET: reset the target specified in scsi_address
8913 */
8914 static int
8915 mptsas_scsi_reset(struct scsi_address *ap, int level)
8916 {
8917 mptsas_t *mpt = ADDR2MPT(ap);
8918 int rval;
8919 mptsas_tgt_private_t *tgt_private;
8920 mptsas_target_t *ptgt = NULL;
8921
8922 tgt_private = (mptsas_tgt_private_t *)ap->a_hba_tran->tran_tgt_private;
8923 ptgt = tgt_private->t_private;
8924 if (ptgt == NULL) {
8925 return (FALSE);
8926 }
8927 NDBG22(("mptsas_scsi_reset: target=%d level=%d", ptgt->m_devhdl,
8928 level));
8929
8930 mutex_enter(&mpt->m_mutex);
8931 /*
8932 * if we are not in panic set up a reset delay for this target
8933 */
8934 if (!ddi_in_panic()) {
8935 mptsas_setup_bus_reset_delay(mpt);
8936 } else {
8937 drv_usecwait(mpt->m_scsi_reset_delay * 1000);
8938 }
8939 rval = mptsas_do_scsi_reset(mpt, ptgt->m_devhdl);
8940 mutex_exit(&mpt->m_mutex);
8941
8942 /*
8943 * The transport layer expect to only see TRUE and
8944 * FALSE. Therefore, we will adjust the return value
8945 * if mptsas_do_scsi_reset returns FAILED.
8946 */
8947 if (rval == FAILED)
8948 rval = FALSE;
8949 return (rval);
8950 }
8951
8952 static int
8953 mptsas_do_scsi_reset(mptsas_t *mpt, uint16_t devhdl)
8954 {
8955 int rval = FALSE;
8956 uint8_t config, disk;
8957
8958 ASSERT(mutex_owned(&mpt->m_mutex));
8959
8960 if (mptsas_debug_resets) {
8961 mptsas_log(mpt, CE_WARN, "mptsas_do_scsi_reset: target=%d",
8962 devhdl);
8963 }
8964
8965 /*
8966 * Issue a Target Reset message to the target specified but not to a
8967 * disk making up a raid volume. Just look through the RAID config
8968 * Phys Disk list of DevHandles. If the target's DevHandle is in this
8969 * list, then don't reset this target.
8970 */
8971 for (config = 0; config < mpt->m_num_raid_configs; config++) {
8972 for (disk = 0; disk < MPTSAS_MAX_DISKS_IN_CONFIG; disk++) {
8973 if (devhdl == mpt->m_raidconfig[config].
8974 m_physdisk_devhdl[disk]) {
8975 return (TRUE);
8976 }
8977 }
8978 }
8979
8980 rval = mptsas_ioc_task_management(mpt,
8981 MPI2_SCSITASKMGMT_TASKTYPE_TARGET_RESET, devhdl, 0, NULL, 0, 0);
8982
8983 mptsas_doneq_empty(mpt);
8984 return (rval);
8985 }
8986
8987 static int
8988 mptsas_scsi_reset_notify(struct scsi_address *ap, int flag,
8989 void (*callback)(caddr_t), caddr_t arg)
8990 {
8991 mptsas_t *mpt = ADDR2MPT(ap);
8992
8993 NDBG22(("mptsas_scsi_reset_notify: tgt=%d", ap->a_target));
8994
8995 return (scsi_hba_reset_notify_setup(ap, flag, callback, arg,
8996 &mpt->m_mutex, &mpt->m_reset_notify_listf));
8997 }
8998
8999 static int
9000 mptsas_get_name(struct scsi_device *sd, char *name, int len)
9001 {
9002 dev_info_t *lun_dip = NULL;
9003
9004 ASSERT(sd != NULL);
9005 ASSERT(name != NULL);
9006 lun_dip = sd->sd_dev;
9007 ASSERT(lun_dip != NULL);
9008
9009 if (mptsas_name_child(lun_dip, name, len) == DDI_SUCCESS) {
9010 return (1);
9011 } else {
9012 return (0);
9013 }
9014 }
9015
9016 static int
9017 mptsas_get_bus_addr(struct scsi_device *sd, char *name, int len)
9018 {
9019 return (mptsas_get_name(sd, name, len));
9020 }
9021
9022 void
9023 mptsas_set_throttle(mptsas_t *mpt, mptsas_target_t *ptgt, int what)
9024 {
9025
9026 NDBG25(("mptsas_set_throttle: throttle=%x", what));
9027
9028 /*
9029 * if the bus is draining/quiesced, no changes to the throttles
9030 * are allowed. Not allowing change of throttles during draining
9031 * limits error recovery but will reduce draining time
9032 *
9033 * all throttles should have been set to HOLD_THROTTLE
9034 */
9035 if (mpt->m_softstate & (MPTSAS_SS_QUIESCED | MPTSAS_SS_DRAINING)) {
9036 return;
9037 }
9038
9039 if (what == HOLD_THROTTLE) {
9040 ptgt->m_t_throttle = HOLD_THROTTLE;
9041 } else if (ptgt->m_reset_delay == 0) {
9042 ptgt->m_t_throttle = what;
9043 }
9044 }
9045
9046 /*
9047 * Clean up from a device reset.
9048 * For the case of target reset, this function clears the waitq of all
9049 * commands for a particular target. For the case of abort task set, this
9050 * function clears the waitq of all commonds for a particular target/lun.
9051 */
9052 static void
9053 mptsas_flush_target(mptsas_t *mpt, ushort_t target, int lun, uint8_t tasktype)
9054 {
9055 mptsas_slots_t *slots = mpt->m_active;
9056 mptsas_cmd_t *cmd, *next_cmd;
9057 int slot;
9058 uchar_t reason;
9059 uint_t stat;
9060 hrtime_t timestamp;
9061
9062 NDBG25(("mptsas_flush_target: target=%d lun=%d", target, lun));
9063
9064 timestamp = gethrtime();
9065
9066 /*
9067 * Make sure the I/O Controller has flushed all cmds
9068 * that are associated with this target for a target reset
9069 * and target/lun for abort task set.
9070 * Account for TM requests, which use the last SMID.
9071 */
9072 for (slot = 0; slot <= mpt->m_active->m_n_normal; slot++) {
9073 if ((cmd = slots->m_slot[slot]) == NULL)
9074 continue;
9075 reason = CMD_RESET;
9076 stat = STAT_DEV_RESET;
9077 switch (tasktype) {
9078 case MPI2_SCSITASKMGMT_TASKTYPE_TARGET_RESET:
9079 if (Tgt(cmd) == target) {
9080 if (cmd->cmd_active_expiration <= timestamp) {
9081 /*
9082 * When timeout requested, propagate
9083 * proper reason and statistics to
9084 * target drivers.
9085 */
9086 reason = CMD_TIMEOUT;
9087 stat |= STAT_TIMEOUT;
9088 }
9089 NDBG25(("mptsas_flush_target discovered non-"
9090 "NULL cmd in slot %d, tasktype 0x%x", slot,
9091 tasktype));
9092 mptsas_dump_cmd(mpt, cmd);
9093 mptsas_remove_cmd(mpt, cmd);
9094 mptsas_set_pkt_reason(mpt, cmd, reason, stat);
9095 mptsas_doneq_add(mpt, cmd);
9096 }
9097 break;
9098 case MPI2_SCSITASKMGMT_TASKTYPE_ABRT_TASK_SET:
9099 reason = CMD_ABORTED;
9100 stat = STAT_ABORTED;
9101 /*FALLTHROUGH*/
9102 case MPI2_SCSITASKMGMT_TASKTYPE_LOGICAL_UNIT_RESET:
9103 if ((Tgt(cmd) == target) && (Lun(cmd) == lun)) {
9104
9105 NDBG25(("mptsas_flush_target discovered non-"
9106 "NULL cmd in slot %d, tasktype 0x%x", slot,
9107 tasktype));
9108 mptsas_dump_cmd(mpt, cmd);
9109 mptsas_remove_cmd(mpt, cmd);
9110 mptsas_set_pkt_reason(mpt, cmd, reason,
9111 stat);
9112 mptsas_doneq_add(mpt, cmd);
9113 }
9114 break;
9115 default:
9116 break;
9117 }
9118 }
9119
9120 /*
9121 * Flush the waitq and tx_waitq of this target's cmds
9122 */
9123 cmd = mpt->m_waitq;
9124
9125 reason = CMD_RESET;
9126 stat = STAT_DEV_RESET;
9127
9128 switch (tasktype) {
9129 case MPI2_SCSITASKMGMT_TASKTYPE_TARGET_RESET:
9130 while (cmd != NULL) {
9131 next_cmd = cmd->cmd_linkp;
9132 if (Tgt(cmd) == target) {
9133 mptsas_waitq_delete(mpt, cmd);
9134 mptsas_set_pkt_reason(mpt, cmd,
9135 reason, stat);
9136 mptsas_doneq_add(mpt, cmd);
9137 }
9138 cmd = next_cmd;
9139 }
9140 mutex_enter(&mpt->m_tx_waitq_mutex);
9141 cmd = mpt->m_tx_waitq;
9142 while (cmd != NULL) {
9143 next_cmd = cmd->cmd_linkp;
9144 if (Tgt(cmd) == target) {
9145 mptsas_tx_waitq_delete(mpt, cmd);
9146 mutex_exit(&mpt->m_tx_waitq_mutex);
9147 mptsas_set_pkt_reason(mpt, cmd,
9148 reason, stat);
9149 mptsas_doneq_add(mpt, cmd);
9150 mutex_enter(&mpt->m_tx_waitq_mutex);
9151 }
9152 cmd = next_cmd;
9153 }
9154 mutex_exit(&mpt->m_tx_waitq_mutex);
9155 break;
9156 case MPI2_SCSITASKMGMT_TASKTYPE_ABRT_TASK_SET:
9157 reason = CMD_ABORTED;
9158 stat = STAT_ABORTED;
9159 /*FALLTHROUGH*/
9160 case MPI2_SCSITASKMGMT_TASKTYPE_LOGICAL_UNIT_RESET:
9161 while (cmd != NULL) {
9162 next_cmd = cmd->cmd_linkp;
9163 if ((Tgt(cmd) == target) && (Lun(cmd) == lun)) {
9164 mptsas_waitq_delete(mpt, cmd);
9165 mptsas_set_pkt_reason(mpt, cmd,
9166 reason, stat);
9167 mptsas_doneq_add(mpt, cmd);
9168 }
9169 cmd = next_cmd;
9170 }
9171 mutex_enter(&mpt->m_tx_waitq_mutex);
9172 cmd = mpt->m_tx_waitq;
9173 while (cmd != NULL) {
9174 next_cmd = cmd->cmd_linkp;
9175 if ((Tgt(cmd) == target) && (Lun(cmd) == lun)) {
9176 mptsas_tx_waitq_delete(mpt, cmd);
9177 mutex_exit(&mpt->m_tx_waitq_mutex);
9178 mptsas_set_pkt_reason(mpt, cmd,
9179 reason, stat);
9180 mptsas_doneq_add(mpt, cmd);
9181 mutex_enter(&mpt->m_tx_waitq_mutex);
9182 }
9183 cmd = next_cmd;
9184 }
9185 mutex_exit(&mpt->m_tx_waitq_mutex);
9186 break;
9187 default:
9188 mptsas_log(mpt, CE_WARN, "Unknown task management type %d.",
9189 tasktype);
9190 break;
9191 }
9192 }
9193
9194 /*
9195 * Clean up hba state, abort all outstanding command and commands in waitq
9196 * reset timeout of all targets.
9197 */
9198 static void
9199 mptsas_flush_hba(mptsas_t *mpt)
9200 {
9201 mptsas_slots_t *slots = mpt->m_active;
9202 mptsas_cmd_t *cmd;
9203 int slot;
9204
9205 NDBG25(("mptsas_flush_hba"));
9206
9207 /*
9208 * The I/O Controller should have already sent back
9209 * all commands via the scsi I/O reply frame. Make
9210 * sure all commands have been flushed.
9211 * Account for TM request, which use the last SMID.
9212 */
9213 for (slot = 0; slot <= mpt->m_active->m_n_normal; slot++) {
9214 if ((cmd = slots->m_slot[slot]) == NULL)
9215 continue;
9216
9217 if (cmd->cmd_flags & CFLAG_CMDIOC) {
9218 /*
9219 * Need to make sure to tell everyone that might be
9220 * waiting on this command that it's going to fail. If
9221 * we get here, this command will never timeout because
9222 * the active command table is going to be re-allocated,
9223 * so there will be nothing to check against a time out.
9224 * Instead, mark the command as failed due to reset.
9225 */
9226 mptsas_set_pkt_reason(mpt, cmd, CMD_RESET,
9227 STAT_BUS_RESET);
9228 if ((cmd->cmd_flags &
9229 (CFLAG_PASSTHRU | CFLAG_CONFIG | CFLAG_FW_DIAG))) {
9230 cmd->cmd_flags |= CFLAG_FINISHED;
9231 cv_broadcast(&mpt->m_passthru_cv);
9232 cv_broadcast(&mpt->m_config_cv);
9233 cv_broadcast(&mpt->m_fw_diag_cv);
9234 }
9235 continue;
9236 }
9237
9238 NDBG25(("mptsas_flush_hba discovered non-NULL cmd in slot %d",
9239 slot));
9240 mptsas_dump_cmd(mpt, cmd);
9241
9242 mptsas_remove_cmd(mpt, cmd);
9243 mptsas_set_pkt_reason(mpt, cmd, CMD_RESET, STAT_BUS_RESET);
9244 mptsas_doneq_add(mpt, cmd);
9245 }
9246
9247 /*
9248 * Flush the waitq.
9249 */
9250 while ((cmd = mptsas_waitq_rm(mpt)) != NULL) {
9251 mptsas_set_pkt_reason(mpt, cmd, CMD_RESET, STAT_BUS_RESET);
9252 if ((cmd->cmd_flags & CFLAG_PASSTHRU) ||
9253 (cmd->cmd_flags & CFLAG_CONFIG) ||
9254 (cmd->cmd_flags & CFLAG_FW_DIAG)) {
9255 cmd->cmd_flags |= CFLAG_FINISHED;
9256 cv_broadcast(&mpt->m_passthru_cv);
9257 cv_broadcast(&mpt->m_config_cv);
9258 cv_broadcast(&mpt->m_fw_diag_cv);
9259 } else {
9260 mptsas_doneq_add(mpt, cmd);
9261 }
9262 }
9263
9264 /*
9265 * Flush the tx_waitq
9266 */
9267 mutex_enter(&mpt->m_tx_waitq_mutex);
9268 while ((cmd = mptsas_tx_waitq_rm(mpt)) != NULL) {
9269 mutex_exit(&mpt->m_tx_waitq_mutex);
9270 mptsas_set_pkt_reason(mpt, cmd, CMD_RESET, STAT_BUS_RESET);
9271 mptsas_doneq_add(mpt, cmd);
9272 mutex_enter(&mpt->m_tx_waitq_mutex);
9273 }
9274 mutex_exit(&mpt->m_tx_waitq_mutex);
9275
9276 /*
9277 * Drain the taskqs prior to reallocating resources. The thread
9278 * passing through here could be launched from either (dr)
9279 * or (event) taskqs so only wait on the 'other' queue since
9280 * waiting on 'this' queue is a deadlock condition.
9281 */
9282 mutex_exit(&mpt->m_mutex);
9283 if (!taskq_member((taskq_t *)mpt->m_event_taskq, curthread))
9284 ddi_taskq_wait(mpt->m_event_taskq);
9285 if (!taskq_member((taskq_t *)mpt->m_dr_taskq, curthread))
9286 ddi_taskq_wait(mpt->m_dr_taskq);
9287
9288 mutex_enter(&mpt->m_mutex);
9289 }
9290
9291 /*
9292 * set pkt_reason and OR in pkt_statistics flag
9293 */
9294 static void
9295 mptsas_set_pkt_reason(mptsas_t *mpt, mptsas_cmd_t *cmd, uchar_t reason,
9296 uint_t stat)
9297 {
9298 #ifndef __lock_lint
9299 _NOTE(ARGUNUSED(mpt))
9300 #endif
9301
9302 NDBG25(("mptsas_set_pkt_reason: cmd=0x%p reason=%x stat=%x",
9303 (void *)cmd, reason, stat));
9304
9305 if (cmd) {
9306 if (cmd->cmd_pkt->pkt_reason == CMD_CMPLT) {
9307 cmd->cmd_pkt->pkt_reason = reason;
9308 }
9309 cmd->cmd_pkt->pkt_statistics |= stat;
9310 }
9311 }
9312
9313 static void
9314 mptsas_start_watch_reset_delay()
9315 {
9316 NDBG22(("mptsas_start_watch_reset_delay"));
9317
9318 mutex_enter(&mptsas_global_mutex);
9319 if (mptsas_reset_watch == NULL && mptsas_timeouts_enabled) {
9320 mptsas_reset_watch = timeout(mptsas_watch_reset_delay, NULL,
9321 drv_usectohz((clock_t)
9322 MPTSAS_WATCH_RESET_DELAY_TICK * 1000));
9323 ASSERT(mptsas_reset_watch != NULL);
9324 }
9325 mutex_exit(&mptsas_global_mutex);
9326 }
9327
9328 static void
9329 mptsas_setup_bus_reset_delay(mptsas_t *mpt)
9330 {
9331 mptsas_target_t *ptgt = NULL;
9332
9333 ASSERT(MUTEX_HELD(&mpt->m_mutex));
9334
9335 NDBG22(("mptsas_setup_bus_reset_delay"));
9336 for (ptgt = refhash_first(mpt->m_targets); ptgt != NULL;
9337 ptgt = refhash_next(mpt->m_targets, ptgt)) {
9338 mptsas_set_throttle(mpt, ptgt, HOLD_THROTTLE);
9339 ptgt->m_reset_delay = mpt->m_scsi_reset_delay;
9340 }
9341
9342 mptsas_start_watch_reset_delay();
9343 }
9344
9345 /*
9346 * mptsas_watch_reset_delay(_subr) is invoked by timeout() and checks every
9347 * mpt instance for active reset delays
9348 */
9349 static void
9350 mptsas_watch_reset_delay(void *arg)
9351 {
9352 #ifndef __lock_lint
9353 _NOTE(ARGUNUSED(arg))
9354 #endif
9355
9356 mptsas_t *mpt;
9357 int not_done = 0;
9358
9359 NDBG22(("mptsas_watch_reset_delay"));
9360
9361 mutex_enter(&mptsas_global_mutex);
9362 mptsas_reset_watch = 0;
9363 mutex_exit(&mptsas_global_mutex);
9364 rw_enter(&mptsas_global_rwlock, RW_READER);
9365 for (mpt = mptsas_head; mpt != NULL; mpt = mpt->m_next) {
9366 if (mpt->m_tran == 0) {
9367 continue;
9368 }
9369 mutex_enter(&mpt->m_mutex);
9370 not_done += mptsas_watch_reset_delay_subr(mpt);
9371 mutex_exit(&mpt->m_mutex);
9372 }
9373 rw_exit(&mptsas_global_rwlock);
9374
9375 if (not_done) {
9376 mptsas_start_watch_reset_delay();
9377 }
9378 }
9379
9380 static int
9381 mptsas_watch_reset_delay_subr(mptsas_t *mpt)
9382 {
9383 int done = 0;
9384 int restart = 0;
9385 mptsas_target_t *ptgt = NULL;
9386
9387 NDBG22(("mptsas_watch_reset_delay_subr: mpt=0x%p", (void *)mpt));
9388
9389 ASSERT(mutex_owned(&mpt->m_mutex));
9390
9391 for (ptgt = refhash_first(mpt->m_targets); ptgt != NULL;
9392 ptgt = refhash_next(mpt->m_targets, ptgt)) {
9393 if (ptgt->m_reset_delay != 0) {
9394 ptgt->m_reset_delay -=
9395 MPTSAS_WATCH_RESET_DELAY_TICK;
9396 if (ptgt->m_reset_delay <= 0) {
9397 ptgt->m_reset_delay = 0;
9398 mptsas_set_throttle(mpt, ptgt,
9399 MAX_THROTTLE);
9400 restart++;
9401 } else {
9402 done = -1;
9403 }
9404 }
9405 }
9406
9407 if (restart > 0) {
9408 mptsas_restart_hba(mpt);
9409 }
9410 return (done);
9411 }
9412
9413 #ifdef MPTSAS_TEST
9414 static void
9415 mptsas_test_reset(mptsas_t *mpt, int target)
9416 {
9417 mptsas_target_t *ptgt = NULL;
9418
9419 if (mptsas_rtest == target) {
9420 if (mptsas_do_scsi_reset(mpt, target) == TRUE) {
9421 mptsas_rtest = -1;
9422 }
9423 if (mptsas_rtest == -1) {
9424 NDBG22(("mptsas_test_reset success"));
9425 }
9426 }
9427 }
9428 #endif
9429
9430 /*
9431 * abort handling:
9432 *
9433 * Notes:
9434 * - if pkt is not NULL, abort just that command
9435 * - if pkt is NULL, abort all outstanding commands for target
9436 */
9437 static int
9438 mptsas_scsi_abort(struct scsi_address *ap, struct scsi_pkt *pkt)
9439 {
9440 mptsas_t *mpt = ADDR2MPT(ap);
9441 int rval;
9442 mptsas_tgt_private_t *tgt_private;
9443 int target, lun;
9444
9445 tgt_private = (mptsas_tgt_private_t *)ap->a_hba_tran->
9446 tran_tgt_private;
9447 ASSERT(tgt_private != NULL);
9448 target = tgt_private->t_private->m_devhdl;
9449 lun = tgt_private->t_lun;
9450
9451 NDBG23(("mptsas_scsi_abort: target=%d.%d", target, lun));
9452
9453 mutex_enter(&mpt->m_mutex);
9454 rval = mptsas_do_scsi_abort(mpt, target, lun, pkt);
9455 mutex_exit(&mpt->m_mutex);
9456 return (rval);
9457 }
9458
9459 static int
9460 mptsas_do_scsi_abort(mptsas_t *mpt, int target, int lun, struct scsi_pkt *pkt)
9461 {
9462 mptsas_cmd_t *sp = NULL;
9463 mptsas_slots_t *slots = mpt->m_active;
9464 int rval = FALSE;
9465
9466 ASSERT(mutex_owned(&mpt->m_mutex));
9467
9468 /*
9469 * Abort the command pkt on the target/lun in ap. If pkt is
9470 * NULL, abort all outstanding commands on that target/lun.
9471 * If you can abort them, return 1, else return 0.
9472 * Each packet that's aborted should be sent back to the target
9473 * driver through the callback routine, with pkt_reason set to
9474 * CMD_ABORTED.
9475 *
9476 * abort cmd pkt on HBA hardware; clean out of outstanding
9477 * command lists, etc.
9478 */
9479 if (pkt != NULL) {
9480 /* abort the specified packet */
9481 sp = PKT2CMD(pkt);
9482
9483 if (sp->cmd_queued) {
9484 NDBG23(("mptsas_do_scsi_abort: queued sp=0x%p aborted",
9485 (void *)sp));
9486 mptsas_waitq_delete(mpt, sp);
9487 mptsas_set_pkt_reason(mpt, sp, CMD_ABORTED,
9488 STAT_ABORTED);
9489 mptsas_doneq_add(mpt, sp);
9490 rval = TRUE;
9491 goto done;
9492 }
9493
9494 /*
9495 * Have mpt firmware abort this command
9496 */
9497
9498 if (slots->m_slot[sp->cmd_slot] != NULL) {
9499 rval = mptsas_ioc_task_management(mpt,
9500 MPI2_SCSITASKMGMT_TASKTYPE_ABORT_TASK, target,
9501 lun, NULL, 0, 0);
9502
9503 /*
9504 * The transport layer expects only TRUE and FALSE.
9505 * Therefore, if mptsas_ioc_task_management returns
9506 * FAILED we will return FALSE.
9507 */
9508 if (rval == FAILED)
9509 rval = FALSE;
9510 goto done;
9511 }
9512 }
9513
9514 /*
9515 * If pkt is NULL then abort task set
9516 */
9517 rval = mptsas_ioc_task_management(mpt,
9518 MPI2_SCSITASKMGMT_TASKTYPE_ABRT_TASK_SET, target, lun, NULL, 0, 0);
9519
9520 /*
9521 * The transport layer expects only TRUE and FALSE.
9522 * Therefore, if mptsas_ioc_task_management returns
9523 * FAILED we will return FALSE.
9524 */
9525 if (rval == FAILED)
9526 rval = FALSE;
9527
9528 #ifdef MPTSAS_TEST
9529 if (rval && mptsas_test_stop) {
9530 debug_enter("mptsas_do_scsi_abort");
9531 }
9532 #endif
9533
9534 done:
9535 mptsas_doneq_empty(mpt);
9536 return (rval);
9537 }
9538
9539 /*
9540 * capability handling:
9541 * (*tran_getcap). Get the capability named, and return its value.
9542 */
9543 static int
9544 mptsas_scsi_getcap(struct scsi_address *ap, char *cap, int tgtonly)
9545 {
9546 mptsas_t *mpt = ADDR2MPT(ap);
9547 int ckey;
9548 int rval = FALSE;
9549
9550 NDBG24(("mptsas_scsi_getcap: target=%d, cap=%s tgtonly=%x",
9551 ap->a_target, cap, tgtonly));
9552
9553 mutex_enter(&mpt->m_mutex);
9554
9555 if ((mptsas_scsi_capchk(cap, tgtonly, &ckey)) != TRUE) {
9556 mutex_exit(&mpt->m_mutex);
9557 return (UNDEFINED);
9558 }
9559
9560 switch (ckey) {
9561 case SCSI_CAP_DMA_MAX:
9562 rval = (int)mpt->m_msg_dma_attr.dma_attr_maxxfer;
9563 break;
9564 case SCSI_CAP_ARQ:
9565 rval = TRUE;
9566 break;
9567 case SCSI_CAP_MSG_OUT:
9568 case SCSI_CAP_PARITY:
9569 case SCSI_CAP_UNTAGGED_QING:
9570 rval = TRUE;
9571 break;
9572 case SCSI_CAP_TAGGED_QING:
9573 rval = TRUE;
9574 break;
9575 case SCSI_CAP_RESET_NOTIFICATION:
9576 rval = TRUE;
9577 break;
9578 case SCSI_CAP_LINKED_CMDS:
9579 rval = FALSE;
9580 break;
9581 case SCSI_CAP_QFULL_RETRIES:
9582 rval = ((mptsas_tgt_private_t *)(ap->a_hba_tran->
9583 tran_tgt_private))->t_private->m_qfull_retries;
9584 break;
9585 case SCSI_CAP_QFULL_RETRY_INTERVAL:
9586 rval = drv_hztousec(((mptsas_tgt_private_t *)
9587 (ap->a_hba_tran->tran_tgt_private))->
9588 t_private->m_qfull_retry_interval) / 1000;
9589 break;
9590 case SCSI_CAP_CDB_LEN:
9591 rval = CDB_GROUP4;
9592 break;
9593 case SCSI_CAP_INTERCONNECT_TYPE:
9594 rval = INTERCONNECT_SAS;
9595 break;
9596 case SCSI_CAP_TRAN_LAYER_RETRIES:
9597 if (mpt->m_ioc_capabilities &
9598 MPI2_IOCFACTS_CAPABILITY_TLR)
9599 rval = TRUE;
9600 else
9601 rval = FALSE;
9602 break;
9603 default:
9604 rval = UNDEFINED;
9605 break;
9606 }
9607
9608 NDBG24(("mptsas_scsi_getcap: %s, rval=%x", cap, rval));
9609
9610 mutex_exit(&mpt->m_mutex);
9611 return (rval);
9612 }
9613
9614 /*
9615 * (*tran_setcap). Set the capability named to the value given.
9616 */
9617 static int
9618 mptsas_scsi_setcap(struct scsi_address *ap, char *cap, int value, int tgtonly)
9619 {
9620 mptsas_t *mpt = ADDR2MPT(ap);
9621 int ckey;
9622 int rval = FALSE;
9623
9624 NDBG24(("mptsas_scsi_setcap: target=%d, cap=%s value=%x tgtonly=%x",
9625 ap->a_target, cap, value, tgtonly));
9626
9627 if (!tgtonly) {
9628 return (rval);
9629 }
9630
9631 mutex_enter(&mpt->m_mutex);
9632
9633 if ((mptsas_scsi_capchk(cap, tgtonly, &ckey)) != TRUE) {
9634 mutex_exit(&mpt->m_mutex);
9635 return (UNDEFINED);
9636 }
9637
9638 switch (ckey) {
9639 case SCSI_CAP_DMA_MAX:
9640 case SCSI_CAP_MSG_OUT:
9641 case SCSI_CAP_PARITY:
9642 case SCSI_CAP_INITIATOR_ID:
9643 case SCSI_CAP_LINKED_CMDS:
9644 case SCSI_CAP_UNTAGGED_QING:
9645 case SCSI_CAP_RESET_NOTIFICATION:
9646 /*
9647 * None of these are settable via
9648 * the capability interface.
9649 */
9650 break;
9651 case SCSI_CAP_ARQ:
9652 /*
9653 * We cannot turn off arq so return false if asked to
9654 */
9655 if (value) {
9656 rval = TRUE;
9657 } else {
9658 rval = FALSE;
9659 }
9660 break;
9661 case SCSI_CAP_TAGGED_QING:
9662 mptsas_set_throttle(mpt, ((mptsas_tgt_private_t *)
9663 (ap->a_hba_tran->tran_tgt_private))->t_private,
9664 MAX_THROTTLE);
9665 rval = TRUE;
9666 break;
9667 case SCSI_CAP_QFULL_RETRIES:
9668 ((mptsas_tgt_private_t *)(ap->a_hba_tran->tran_tgt_private))->
9669 t_private->m_qfull_retries = (uchar_t)value;
9670 rval = TRUE;
9671 break;
9672 case SCSI_CAP_QFULL_RETRY_INTERVAL:
9673 ((mptsas_tgt_private_t *)(ap->a_hba_tran->tran_tgt_private))->
9674 t_private->m_qfull_retry_interval =
9675 drv_usectohz(value * 1000);
9676 rval = TRUE;
9677 break;
9678 default:
9679 rval = UNDEFINED;
9680 break;
9681 }
9682 mutex_exit(&mpt->m_mutex);
9683 return (rval);
9684 }
9685
9686 /*
9687 * Utility routine for mptsas_ifsetcap/ifgetcap
9688 */
9689 /*ARGSUSED*/
9690 static int
9691 mptsas_scsi_capchk(char *cap, int tgtonly, int *cidxp)
9692 {
9693 NDBG24(("mptsas_scsi_capchk: cap=%s", cap));
9694
9695 if (!cap)
9696 return (FALSE);
9697
9698 *cidxp = scsi_hba_lookup_capstr(cap);
9699 return (TRUE);
9700 }
9701
9702 static int
9703 mptsas_alloc_active_slots(mptsas_t *mpt, int flag)
9704 {
9705 mptsas_slots_t *old_active = mpt->m_active;
9706 mptsas_slots_t *new_active;
9707 size_t size;
9708
9709 /*
9710 * if there are active commands, then we cannot
9711 * change size of active slots array.
9712 */
9713 ASSERT(mpt->m_ncmds == 0);
9714
9715 size = MPTSAS_SLOTS_SIZE(mpt);
9716 new_active = kmem_zalloc(size, flag);
9717 if (new_active == NULL) {
9718 NDBG1(("new active alloc failed"));
9719 return (-1);
9720 }
9721 /*
9722 * Since SMID 0 is reserved and the TM slot is reserved, the
9723 * number of slots that can be used at any one time is
9724 * m_max_requests - 2.
9725 */
9726 new_active->m_n_normal = (mpt->m_max_requests - 2);
9727 new_active->m_size = size;
9728 new_active->m_rotor = 1;
9729 if (old_active)
9730 mptsas_free_active_slots(mpt);
9731 mpt->m_active = new_active;
9732
9733 return (0);
9734 }
9735
9736 static void
9737 mptsas_free_active_slots(mptsas_t *mpt)
9738 {
9739 mptsas_slots_t *active = mpt->m_active;
9740 size_t size;
9741
9742 if (active == NULL)
9743 return;
9744 size = active->m_size;
9745 kmem_free(active, size);
9746 mpt->m_active = NULL;
9747 }
9748
9749 /*
9750 * Error logging, printing, and debug print routines.
9751 */
9752 static char *mptsas_label = "mpt_sas";
9753
9754 /*PRINTFLIKE3*/
9755 void
9756 mptsas_log(mptsas_t *mpt, int level, char *fmt, ...)
9757 {
9758 dev_info_t *dev;
9759 va_list ap;
9760
9761 if (mpt) {
9762 dev = mpt->m_dip;
9763 } else {
9764 dev = 0;
9765 }
9766
9767 mutex_enter(&mptsas_log_mutex);
9768
9769 va_start(ap, fmt);
9770 (void) vsprintf(mptsas_log_buf, fmt, ap);
9771 va_end(ap);
9772
9773 if (level == CE_CONT) {
9774 scsi_log(dev, mptsas_label, level, "%s\n", mptsas_log_buf);
9775 } else {
9776 scsi_log(dev, mptsas_label, level, "%s", mptsas_log_buf);
9777 }
9778
9779 mutex_exit(&mptsas_log_mutex);
9780 }
9781
9782 #ifdef MPTSAS_DEBUG
9783 /*
9784 * Use a circular buffer to log messages to private memory.
9785 * Increment idx atomically to minimize risk to miss lines.
9786 * It's fast and does not hold up the proceedings too much.
9787 */
9788 static const size_t mptsas_dbglog_linecnt = MPTSAS_DBGLOG_LINECNT;
9789 static const size_t mptsas_dbglog_linelen = MPTSAS_DBGLOG_LINELEN;
9790 static char mptsas_dbglog_bufs[MPTSAS_DBGLOG_LINECNT][MPTSAS_DBGLOG_LINELEN];
9791 static uint32_t mptsas_dbglog_idx = 0;
9792
9793 /*PRINTFLIKE1*/
9794 void
9795 mptsas_debug_log(char *fmt, ...)
9796 {
9797 va_list ap;
9798 uint32_t idx;
9799
9800 idx = atomic_inc_32_nv(&mptsas_dbglog_idx) &
9801 (mptsas_dbglog_linecnt - 1);
9802
9803 va_start(ap, fmt);
9804 (void) vsnprintf(mptsas_dbglog_bufs[idx],
9805 mptsas_dbglog_linelen, fmt, ap);
9806 va_end(ap);
9807 }
9808
9809 /*PRINTFLIKE1*/
9810 void
9811 mptsas_printf(char *fmt, ...)
9812 {
9813 dev_info_t *dev = 0;
9814 va_list ap;
9815
9816 mutex_enter(&mptsas_log_mutex);
9817
9818 va_start(ap, fmt);
9819 (void) vsprintf(mptsas_log_buf, fmt, ap);
9820 va_end(ap);
9821
9822 #ifdef PROM_PRINTF
9823 prom_printf("%s:\t%s\n", mptsas_label, mptsas_log_buf);
9824 #else
9825 scsi_log(dev, mptsas_label, CE_CONT, "!%s\n", mptsas_log_buf);
9826 #endif
9827 mutex_exit(&mptsas_log_mutex);
9828 }
9829 #endif
9830
9831 /*
9832 * timeout handling
9833 */
9834 static void
9835 mptsas_watch(void *arg)
9836 {
9837 #ifndef __lock_lint
9838 _NOTE(ARGUNUSED(arg))
9839 #endif
9840
9841 mptsas_t *mpt;
9842 uint32_t doorbell;
9843
9844 NDBG30(("mptsas_watch"));
9845
9846 rw_enter(&mptsas_global_rwlock, RW_READER);
9847 for (mpt = mptsas_head; mpt != (mptsas_t *)NULL; mpt = mpt->m_next) {
9848
9849 mutex_enter(&mpt->m_mutex);
9850
9851 /* Skip device if not powered on */
9852 if (mpt->m_options & MPTSAS_OPT_PM) {
9853 if (mpt->m_power_level == PM_LEVEL_D0) {
9854 (void) pm_busy_component(mpt->m_dip, 0);
9855 mpt->m_busy = 1;
9856 } else {
9857 mutex_exit(&mpt->m_mutex);
9858 continue;
9859 }
9860 }
9861
9862 /*
9863 * Check if controller is in a FAULT state. If so, reset it.
9864 */
9865 doorbell = ddi_get32(mpt->m_datap, &mpt->m_reg->Doorbell);
9866 if ((doorbell & MPI2_IOC_STATE_MASK) == MPI2_IOC_STATE_FAULT) {
9867 doorbell &= MPI2_DOORBELL_DATA_MASK;
9868 mptsas_log(mpt, CE_WARN, "MPT Firmware Fault, "
9869 "code: %04x", doorbell);
9870 mpt->m_softstate &= ~MPTSAS_SS_MSG_UNIT_RESET;
9871 if ((mptsas_restart_ioc(mpt)) == DDI_FAILURE) {
9872 mptsas_log(mpt, CE_WARN, "Reset failed"
9873 "after fault was detected");
9874 }
9875 }
9876
9877 /*
9878 * For now, always call mptsas_watchsubr.
9879 */
9880 mptsas_watchsubr(mpt);
9881
9882 if (mpt->m_options & MPTSAS_OPT_PM) {
9883 mpt->m_busy = 0;
9884 (void) pm_idle_component(mpt->m_dip, 0);
9885 }
9886
9887 mutex_exit(&mpt->m_mutex);
9888 }
9889 rw_exit(&mptsas_global_rwlock);
9890
9891 mutex_enter(&mptsas_global_mutex);
9892 if (mptsas_timeouts_enabled)
9893 mptsas_timeout_id = timeout(mptsas_watch, NULL, mptsas_tick);
9894 mutex_exit(&mptsas_global_mutex);
9895 }
9896
9897 static void
9898 mptsas_watchsubr_tgt(mptsas_t *mpt, mptsas_target_t *ptgt, hrtime_t timestamp)
9899 {
9900 mptsas_cmd_t *cmd;
9901
9902 /*
9903 * If we were draining due to a qfull condition,
9904 * go back to full throttle.
9905 */
9906 if ((ptgt->m_t_throttle < MAX_THROTTLE) &&
9907 (ptgt->m_t_throttle > HOLD_THROTTLE) &&
9908 (ptgt->m_t_ncmds < ptgt->m_t_throttle)) {
9909 mptsas_set_throttle(mpt, ptgt, MAX_THROTTLE);
9910 mptsas_restart_hba(mpt);
9911 }
9912
9913 cmd = TAILQ_LAST(&ptgt->m_active_cmdq, mptsas_active_cmdq);
9914 if (cmd == NULL)
9915 return;
9916
9917 if (cmd->cmd_active_expiration <= timestamp) {
9918 /*
9919 * Earliest command timeout expired. Drain throttle.
9920 */
9921 mptsas_set_throttle(mpt, ptgt, DRAIN_THROTTLE);
9922
9923 /*
9924 * Check for remaining commands.
9925 */
9926 cmd = TAILQ_FIRST(&ptgt->m_active_cmdq);
9927 if (cmd->cmd_active_expiration > timestamp) {
9928 /*
9929 * Wait for remaining commands to complete or
9930 * time out.
9931 */
9932 NDBG23(("command timed out, pending drain"));
9933 return;
9934 }
9935
9936 /*
9937 * All command timeouts expired.
9938 */
9939 mptsas_log(mpt, CE_NOTE, "Timeout of %d seconds "
9940 "expired with %d commands on target %d lun %d.",
9941 cmd->cmd_pkt->pkt_time, ptgt->m_t_ncmds,
9942 ptgt->m_devhdl, Lun(cmd));
9943
9944 mptsas_cmd_timeout(mpt, ptgt);
9945 } else if (cmd->cmd_active_expiration <=
9946 timestamp + (hrtime_t)mptsas_scsi_watchdog_tick * NANOSEC) {
9947 NDBG23(("pending timeout"));
9948 mptsas_set_throttle(mpt, ptgt, DRAIN_THROTTLE);
9949 }
9950 }
9951
9952 static void
9953 mptsas_watchsubr(mptsas_t *mpt)
9954 {
9955 int i;
9956 mptsas_cmd_t *cmd;
9957 mptsas_target_t *ptgt = NULL;
9958 hrtime_t timestamp = gethrtime();
9959
9960 ASSERT(MUTEX_HELD(&mpt->m_mutex));
9961
9962 NDBG30(("mptsas_watchsubr: mpt=0x%p", (void *)mpt));
9963
9964 #ifdef MPTSAS_TEST
9965 if (mptsas_enable_untagged) {
9966 mptsas_test_untagged++;
9967 }
9968 #endif
9969
9970 /*
9971 * Check for commands stuck in active slot
9972 * Account for TM requests, which use the last SMID.
9973 */
9974 for (i = 0; i <= mpt->m_active->m_n_normal; i++) {
9975 if ((cmd = mpt->m_active->m_slot[i]) != NULL) {
9976 if (cmd->cmd_active_expiration <= timestamp) {
9977 if ((cmd->cmd_flags & CFLAG_CMDIOC) == 0) {
9978 /*
9979 * There seems to be a command stuck
9980 * in the active slot. Drain throttle.
9981 */
9982 mptsas_set_throttle(mpt,
9983 cmd->cmd_tgt_addr,
9984 DRAIN_THROTTLE);
9985 } else if (cmd->cmd_flags &
9986 (CFLAG_PASSTHRU | CFLAG_CONFIG |
9987 CFLAG_FW_DIAG)) {
9988 /*
9989 * passthrough command timeout
9990 */
9991 cmd->cmd_flags |= (CFLAG_FINISHED |
9992 CFLAG_TIMEOUT);
9993 cv_broadcast(&mpt->m_passthru_cv);
9994 cv_broadcast(&mpt->m_config_cv);
9995 cv_broadcast(&mpt->m_fw_diag_cv);
9996 }
9997 }
9998 }
9999 }
10000
10001 for (ptgt = refhash_first(mpt->m_targets); ptgt != NULL;
10002 ptgt = refhash_next(mpt->m_targets, ptgt)) {
10003 mptsas_watchsubr_tgt(mpt, ptgt, timestamp);
10004 }
10005
10006 for (ptgt = refhash_first(mpt->m_tmp_targets); ptgt != NULL;
10007 ptgt = refhash_next(mpt->m_tmp_targets, ptgt)) {
10008 mptsas_watchsubr_tgt(mpt, ptgt, timestamp);
10009 }
10010 }
10011
10012 /*
10013 * timeout recovery
10014 */
10015 static void
10016 mptsas_cmd_timeout(mptsas_t *mpt, mptsas_target_t *ptgt)
10017 {
10018 uint16_t devhdl;
10019 uint64_t sas_wwn;
10020 uint8_t phy;
10021 char wwn_str[MPTSAS_WWN_STRLEN];
10022
10023 devhdl = ptgt->m_devhdl;
10024 sas_wwn = ptgt->m_addr.mta_wwn;
10025 phy = ptgt->m_phynum;
10026 if (sas_wwn == 0) {
10027 (void) sprintf(wwn_str, "p%x", phy);
10028 } else {
10029 (void) sprintf(wwn_str, "w%016"PRIx64, sas_wwn);
10030 }
10031
10032 NDBG29(("mptsas_cmd_timeout: target=%d", devhdl));
10033 mptsas_log(mpt, CE_WARN, "Disconnected command timeout for "
10034 "target %d %s, enclosure %u", devhdl, wwn_str,
10035 ptgt->m_enclosure);
10036
10037 /*
10038 * Abort all outstanding commands on the device.
10039 */
10040 NDBG29(("mptsas_cmd_timeout: device reset"));
10041 if (mptsas_do_scsi_reset(mpt, devhdl) != TRUE) {
10042 mptsas_log(mpt, CE_WARN, "Target %d reset for command timeout "
10043 "recovery failed!", devhdl);
10044 }
10045 }
10046
10047 /*
10048 * Device / Hotplug control
10049 */
10050 static int
10051 mptsas_scsi_quiesce(dev_info_t *dip)
10052 {
10053 mptsas_t *mpt;
10054 scsi_hba_tran_t *tran;
10055
10056 tran = ddi_get_driver_private(dip);
10057 if (tran == NULL || (mpt = TRAN2MPT(tran)) == NULL)
10058 return (-1);
10059
10060 return (mptsas_quiesce_bus(mpt));
10061 }
10062
10063 static int
10064 mptsas_scsi_unquiesce(dev_info_t *dip)
10065 {
10066 mptsas_t *mpt;
10067 scsi_hba_tran_t *tran;
10068
10069 tran = ddi_get_driver_private(dip);
10070 if (tran == NULL || (mpt = TRAN2MPT(tran)) == NULL)
10071 return (-1);
10072
10073 return (mptsas_unquiesce_bus(mpt));
10074 }
10075
10076 static int
10077 mptsas_quiesce_bus(mptsas_t *mpt)
10078 {
10079 mptsas_target_t *ptgt = NULL;
10080
10081 NDBG28(("mptsas_quiesce_bus"));
10082 mutex_enter(&mpt->m_mutex);
10083
10084 /* Set all the throttles to zero */
10085 for (ptgt = refhash_first(mpt->m_targets); ptgt != NULL;
10086 ptgt = refhash_next(mpt->m_targets, ptgt)) {
10087 mptsas_set_throttle(mpt, ptgt, HOLD_THROTTLE);
10088 }
10089
10090 /* If there are any outstanding commands in the queue */
10091 if (mpt->m_ncmds) {
10092 mpt->m_softstate |= MPTSAS_SS_DRAINING;
10093 mpt->m_quiesce_timeid = timeout(mptsas_ncmds_checkdrain,
10094 mpt, (MPTSAS_QUIESCE_TIMEOUT * drv_usectohz(1000000)));
10095 if (cv_wait_sig(&mpt->m_cv, &mpt->m_mutex) == 0) {
10096 /*
10097 * Quiesce has been interrupted
10098 */
10099 mpt->m_softstate &= ~MPTSAS_SS_DRAINING;
10100 for (ptgt = refhash_first(mpt->m_targets); ptgt != NULL;
10101 ptgt = refhash_next(mpt->m_targets, ptgt)) {
10102 mptsas_set_throttle(mpt, ptgt, MAX_THROTTLE);
10103 }
10104 mptsas_restart_hba(mpt);
10105 if (mpt->m_quiesce_timeid != 0) {
10106 timeout_id_t tid = mpt->m_quiesce_timeid;
10107 mpt->m_quiesce_timeid = 0;
10108 mutex_exit(&mpt->m_mutex);
10109 (void) untimeout(tid);
10110 return (-1);
10111 }
10112 mutex_exit(&mpt->m_mutex);
10113 return (-1);
10114 } else {
10115 /* Bus has been quiesced */
10116 ASSERT(mpt->m_quiesce_timeid == 0);
10117 mpt->m_softstate &= ~MPTSAS_SS_DRAINING;
10118 mpt->m_softstate |= MPTSAS_SS_QUIESCED;
10119 mutex_exit(&mpt->m_mutex);
10120 return (0);
10121 }
10122 }
10123 /* Bus was not busy - QUIESCED */
10124 mutex_exit(&mpt->m_mutex);
10125
10126 return (0);
10127 }
10128
10129 static int
10130 mptsas_unquiesce_bus(mptsas_t *mpt)
10131 {
10132 mptsas_target_t *ptgt = NULL;
10133
10134 NDBG28(("mptsas_unquiesce_bus"));
10135 mutex_enter(&mpt->m_mutex);
10136 mpt->m_softstate &= ~MPTSAS_SS_QUIESCED;
10137 for (ptgt = refhash_first(mpt->m_targets); ptgt != NULL;
10138 ptgt = refhash_next(mpt->m_targets, ptgt)) {
10139 mptsas_set_throttle(mpt, ptgt, MAX_THROTTLE);
10140 }
10141 mptsas_restart_hba(mpt);
10142 mutex_exit(&mpt->m_mutex);
10143 return (0);
10144 }
10145
10146 static void
10147 mptsas_ncmds_checkdrain(void *arg)
10148 {
10149 mptsas_t *mpt = arg;
10150 mptsas_target_t *ptgt = NULL;
10151
10152 mutex_enter(&mpt->m_mutex);
10153 if (mpt->m_softstate & MPTSAS_SS_DRAINING) {
10154 mpt->m_quiesce_timeid = 0;
10155 if (mpt->m_ncmds == 0) {
10156 /* Command queue has been drained */
10157 cv_signal(&mpt->m_cv);
10158 } else {
10159 /*
10160 * The throttle may have been reset because
10161 * of a SCSI bus reset
10162 */
10163 for (ptgt = refhash_first(mpt->m_targets); ptgt != NULL;
10164 ptgt = refhash_next(mpt->m_targets, ptgt)) {
10165 mptsas_set_throttle(mpt, ptgt, HOLD_THROTTLE);
10166 }
10167
10168 mpt->m_quiesce_timeid = timeout(mptsas_ncmds_checkdrain,
10169 mpt, (MPTSAS_QUIESCE_TIMEOUT *
10170 drv_usectohz(1000000)));
10171 }
10172 }
10173 mutex_exit(&mpt->m_mutex);
10174 }
10175
10176 /*ARGSUSED*/
10177 static void
10178 mptsas_dump_cmd(mptsas_t *mpt, mptsas_cmd_t *cmd)
10179 {
10180 int i;
10181 uint8_t *cp = (uchar_t *)cmd->cmd_pkt->pkt_cdbp;
10182 char buf[128];
10183
10184 buf[0] = '\0';
10185 NDBG25(("?Cmd (0x%p) dump for Target %d Lun %d:\n", (void *)cmd,
10186 Tgt(cmd), Lun(cmd)));
10187 (void) sprintf(&buf[0], "\tcdb=[");
10188 for (i = 0; i < (int)cmd->cmd_cdblen; i++) {
10189 (void) sprintf(&buf[strlen(buf)], " 0x%x", *cp++);
10190 }
10191 (void) sprintf(&buf[strlen(buf)], " ]");
10192 NDBG25(("?%s\n", buf));
10193 NDBG25(("?pkt_flags=0x%x pkt_statistics=0x%x pkt_state=0x%x\n",
10194 cmd->cmd_pkt->pkt_flags, cmd->cmd_pkt->pkt_statistics,
10195 cmd->cmd_pkt->pkt_state));
10196 NDBG25(("?pkt_scbp=0x%x cmd_flags=0x%x\n", cmd->cmd_pkt->pkt_scbp ?
10197 *(cmd->cmd_pkt->pkt_scbp) : 0, cmd->cmd_flags));
10198 }
10199
10200 static void
10201 mptsas_passthru_sge(ddi_acc_handle_t acc_hdl, mptsas_pt_request_t *pt,
10202 pMpi2SGESimple64_t sgep)
10203 {
10204 uint32_t sge_flags;
10205 uint32_t data_size, dataout_size;
10206 ddi_dma_cookie_t data_cookie;
10207 ddi_dma_cookie_t dataout_cookie;
10208
10209 data_size = pt->data_size;
10210 dataout_size = pt->dataout_size;
10211 data_cookie = pt->data_cookie;
10212 dataout_cookie = pt->dataout_cookie;
10213
10214 if (dataout_size) {
10215 sge_flags = dataout_size |
10216 ((uint32_t)(MPI2_SGE_FLAGS_SIMPLE_ELEMENT |
10217 MPI2_SGE_FLAGS_END_OF_BUFFER |
10218 MPI2_SGE_FLAGS_HOST_TO_IOC |
10219 MPI2_SGE_FLAGS_64_BIT_ADDRESSING) <<
10220 MPI2_SGE_FLAGS_SHIFT);
10221 ddi_put32(acc_hdl, &sgep->FlagsLength, sge_flags);
10222 ddi_put32(acc_hdl, &sgep->Address.Low,
10223 (uint32_t)(dataout_cookie.dmac_laddress &
10224 0xffffffffull));
10225 ddi_put32(acc_hdl, &sgep->Address.High,
10226 (uint32_t)(dataout_cookie.dmac_laddress
10227 >> 32));
10228 sgep++;
10229 }
10230 sge_flags = data_size;
10231 sge_flags |= ((uint32_t)(MPI2_SGE_FLAGS_SIMPLE_ELEMENT |
10232 MPI2_SGE_FLAGS_LAST_ELEMENT |
10233 MPI2_SGE_FLAGS_END_OF_BUFFER |
10234 MPI2_SGE_FLAGS_END_OF_LIST |
10235 MPI2_SGE_FLAGS_64_BIT_ADDRESSING) <<
10236 MPI2_SGE_FLAGS_SHIFT);
10237 if (pt->direction == MPTSAS_PASS_THRU_DIRECTION_WRITE) {
10238 sge_flags |= ((uint32_t)(MPI2_SGE_FLAGS_HOST_TO_IOC) <<
10239 MPI2_SGE_FLAGS_SHIFT);
10240 } else {
10241 sge_flags |= ((uint32_t)(MPI2_SGE_FLAGS_IOC_TO_HOST) <<
10242 MPI2_SGE_FLAGS_SHIFT);
10243 }
10244 ddi_put32(acc_hdl, &sgep->FlagsLength,
10245 sge_flags);
10246 ddi_put32(acc_hdl, &sgep->Address.Low,
10247 (uint32_t)(data_cookie.dmac_laddress &
10248 0xffffffffull));
10249 ddi_put32(acc_hdl, &sgep->Address.High,
10250 (uint32_t)(data_cookie.dmac_laddress >> 32));
10251 }
10252
10253 static void
10254 mptsas_passthru_ieee_sge(ddi_acc_handle_t acc_hdl, mptsas_pt_request_t *pt,
10255 pMpi2IeeeSgeSimple64_t ieeesgep)
10256 {
10257 uint8_t sge_flags;
10258 uint32_t data_size, dataout_size;
10259 ddi_dma_cookie_t data_cookie;
10260 ddi_dma_cookie_t dataout_cookie;
10261
10262 data_size = pt->data_size;
10263 dataout_size = pt->dataout_size;
10264 data_cookie = pt->data_cookie;
10265 dataout_cookie = pt->dataout_cookie;
10266
10267 sge_flags = (MPI2_IEEE_SGE_FLAGS_SIMPLE_ELEMENT |
10268 MPI2_IEEE_SGE_FLAGS_SYSTEM_ADDR);
10269 if (dataout_size) {
10270 ddi_put32(acc_hdl, &ieeesgep->Length, dataout_size);
10271 ddi_put32(acc_hdl, &ieeesgep->Address.Low,
10272 (uint32_t)(dataout_cookie.dmac_laddress &
10273 0xffffffffull));
10274 ddi_put32(acc_hdl, &ieeesgep->Address.High,
10275 (uint32_t)(dataout_cookie.dmac_laddress >> 32));
10276 ddi_put8(acc_hdl, &ieeesgep->Flags, sge_flags);
10277 ieeesgep++;
10278 }
10279 sge_flags |= MPI25_IEEE_SGE_FLAGS_END_OF_LIST;
10280 ddi_put32(acc_hdl, &ieeesgep->Length, data_size);
10281 ddi_put32(acc_hdl, &ieeesgep->Address.Low,
10282 (uint32_t)(data_cookie.dmac_laddress & 0xffffffffull));
10283 ddi_put32(acc_hdl, &ieeesgep->Address.High,
10284 (uint32_t)(data_cookie.dmac_laddress >> 32));
10285 ddi_put8(acc_hdl, &ieeesgep->Flags, sge_flags);
10286 }
10287
10288 static void
10289 mptsas_start_passthru(mptsas_t *mpt, mptsas_cmd_t *cmd)
10290 {
10291 caddr_t memp;
10292 pMPI2RequestHeader_t request_hdrp;
10293 struct scsi_pkt *pkt = cmd->cmd_pkt;
10294 mptsas_pt_request_t *pt = pkt->pkt_ha_private;
10295 uint32_t request_size;
10296 uint32_t i;
10297 uint64_t request_desc = 0;
10298 uint8_t desc_type;
10299 uint16_t SMID;
10300 uint8_t *request, function;
10301 ddi_dma_handle_t dma_hdl = mpt->m_dma_req_frame_hdl;
10302 ddi_acc_handle_t acc_hdl = mpt->m_acc_req_frame_hdl;
10303
10304 desc_type = MPI2_REQ_DESCRIPT_FLAGS_DEFAULT_TYPE;
10305
10306 request = pt->request;
10307 request_size = pt->request_size;
10308
10309 SMID = cmd->cmd_slot;
10310
10311 /*
10312 * Store the passthrough message in memory location
10313 * corresponding to our slot number
10314 */
10315 memp = mpt->m_req_frame + (mpt->m_req_frame_size * SMID);
10316 request_hdrp = (pMPI2RequestHeader_t)memp;
10317 bzero(memp, mpt->m_req_frame_size);
10318
10319 for (i = 0; i < request_size; i++) {
10320 bcopy(request + i, memp + i, 1);
10321 }
10322
10323 NDBG15(("mptsas_start_passthru: Func 0x%x, MsgFlags 0x%x, "
10324 "size=%d, in %d, out %d, SMID %d", request_hdrp->Function,
10325 request_hdrp->MsgFlags, request_size,
10326 pt->data_size, pt->dataout_size, SMID));
10327
10328 /*
10329 * Add an SGE, even if the length is zero.
10330 */
10331 if (mpt->m_MPI25 && pt->simple == 0) {
10332 mptsas_passthru_ieee_sge(acc_hdl, pt,
10333 (pMpi2IeeeSgeSimple64_t)
10334 ((uint8_t *)request_hdrp + pt->sgl_offset));
10335 } else {
10336 mptsas_passthru_sge(acc_hdl, pt,
10337 (pMpi2SGESimple64_t)
10338 ((uint8_t *)request_hdrp + pt->sgl_offset));
10339 }
10340
10341 function = request_hdrp->Function;
10342 if ((function == MPI2_FUNCTION_SCSI_IO_REQUEST) ||
10343 (function == MPI2_FUNCTION_RAID_SCSI_IO_PASSTHROUGH)) {
10344 pMpi2SCSIIORequest_t scsi_io_req;
10345 caddr_t arsbuf;
10346 uint8_t ars_size;
10347 uint32_t ars_dmaaddrlow;
10348
10349 NDBG15(("mptsas_start_passthru: Is SCSI IO Req"));
10350 scsi_io_req = (pMpi2SCSIIORequest_t)request_hdrp;
10351
10352 if (cmd->cmd_extrqslen != 0) {
10353 /*
10354 * Mapping of the buffer was done in
10355 * mptsas_do_passthru().
10356 * Calculate the DMA address with the same offset.
10357 */
10358 arsbuf = cmd->cmd_arq_buf;
10359 ars_size = cmd->cmd_extrqslen;
10360 ars_dmaaddrlow = (mpt->m_req_sense_dma_addr +
10361 ((uintptr_t)arsbuf - (uintptr_t)mpt->m_req_sense)) &
10362 0xffffffffu;
10363 } else {
10364 arsbuf = mpt->m_req_sense +
10365 (mpt->m_req_sense_size * (SMID-1));
10366 cmd->cmd_arq_buf = arsbuf;
10367 ars_size = mpt->m_req_sense_size;
10368 ars_dmaaddrlow = (mpt->m_req_sense_dma_addr +
10369 (mpt->m_req_sense_size * (SMID-1))) &
10370 0xffffffffu;
10371 }
10372 bzero(arsbuf, ars_size);
10373
10374 ddi_put8(acc_hdl, &scsi_io_req->SenseBufferLength, ars_size);
10375 ddi_put32(acc_hdl, &scsi_io_req->SenseBufferLowAddress,
10376 ars_dmaaddrlow);
10377
10378 /*
10379 * Put SGE for data and data_out buffer at the end of
10380 * scsi_io_request message header.(64 bytes in total)
10381 * Set SGLOffset0 value
10382 */
10383 ddi_put8(acc_hdl, &scsi_io_req->SGLOffset0,
10384 offsetof(MPI2_SCSI_IO_REQUEST, SGL) / 4);
10385
10386 /*
10387 * Setup descriptor info. RAID passthrough must use the
10388 * default request descriptor which is already set, so if this
10389 * is a SCSI IO request, change the descriptor to SCSI IO.
10390 */
10391 if (function == MPI2_FUNCTION_SCSI_IO_REQUEST) {
10392 desc_type = MPI2_REQ_DESCRIPT_FLAGS_SCSI_IO;
10393 request_desc = ((uint64_t)ddi_get16(acc_hdl,
10394 &scsi_io_req->DevHandle) << 48);
10395 }
10396 (void) ddi_dma_sync(mpt->m_dma_req_sense_hdl, 0, 0,
10397 DDI_DMA_SYNC_FORDEV);
10398 }
10399
10400 /*
10401 * We must wait till the message has been completed before
10402 * beginning the next message so we wait for this one to
10403 * finish.
10404 */
10405 (void) ddi_dma_sync(dma_hdl, 0, 0, DDI_DMA_SYNC_FORDEV);
10406 request_desc |= (SMID << 16) + desc_type;
10407 cmd->cmd_rfm = NULL;
10408 MPTSAS_START_CMD(mpt, request_desc);
10409 if ((mptsas_check_dma_handle(dma_hdl) != DDI_SUCCESS) ||
10410 (mptsas_check_acc_handle(acc_hdl) != DDI_SUCCESS)) {
10411 ddi_fm_service_impact(mpt->m_dip, DDI_SERVICE_UNAFFECTED);
10412 }
10413 }
10414
10415 typedef void (mptsas_pre_f)(mptsas_t *, mptsas_pt_request_t *);
10416 static mptsas_pre_f mpi_pre_ioc_facts;
10417 static mptsas_pre_f mpi_pre_port_facts;
10418 static mptsas_pre_f mpi_pre_fw_download;
10419 static mptsas_pre_f mpi_pre_fw_25_download;
10420 static mptsas_pre_f mpi_pre_fw_upload;
10421 static mptsas_pre_f mpi_pre_fw_25_upload;
10422 static mptsas_pre_f mpi_pre_sata_passthrough;
10423 static mptsas_pre_f mpi_pre_smp_passthrough;
10424 static mptsas_pre_f mpi_pre_config;
10425 static mptsas_pre_f mpi_pre_sas_io_unit_control;
10426 static mptsas_pre_f mpi_pre_scsi_io_req;
10427
10428 /*
10429 * Prepare the pt for a SAS2 FW_DOWNLOAD request.
10430 */
10431 static void
10432 mpi_pre_fw_download(mptsas_t *mpt, mptsas_pt_request_t *pt)
10433 {
10434 pMpi2FWDownloadTCSGE_t tcsge;
10435 pMpi2FWDownloadRequest req;
10436
10437 /*
10438 * If SAS3, call separate function.
10439 */
10440 if (mpt->m_MPI25) {
10441 mpi_pre_fw_25_download(mpt, pt);
10442 return;
10443 }
10444
10445 /*
10446 * User requests should come in with the Transaction
10447 * context element where the SGL will go. Putting the
10448 * SGL after that seems to work, but don't really know
10449 * why. Other drivers tend to create an extra SGL and
10450 * refer to the TCE through that.
10451 */
10452 req = (pMpi2FWDownloadRequest)pt->request;
10453 tcsge = (pMpi2FWDownloadTCSGE_t)&req->SGL;
10454 if (tcsge->ContextSize != 0 || tcsge->DetailsLength != 12 ||
10455 tcsge->Flags != MPI2_SGE_FLAGS_TRANSACTION_ELEMENT) {
10456 mptsas_log(mpt, CE_WARN, "FW Download tce invalid!");
10457 }
10458
10459 pt->sgl_offset = offsetof(MPI2_FW_DOWNLOAD_REQUEST, SGL) +
10460 sizeof (*tcsge);
10461 if (pt->request_size != pt->sgl_offset)
10462 NDBG15(("mpi_pre_fw_download(): Incorrect req size, "
10463 "0x%x, should be 0x%x, dataoutsz 0x%x",
10464 (int)pt->request_size, (int)pt->sgl_offset,
10465 (int)pt->dataout_size));
10466 if (pt->data_size < sizeof (MPI2_FW_DOWNLOAD_REPLY))
10467 NDBG15(("mpi_pre_fw_download(): Incorrect rep size, "
10468 "0x%x, should be 0x%x", pt->data_size,
10469 (int)sizeof (MPI2_FW_DOWNLOAD_REPLY)));
10470 }
10471
10472 /*
10473 * Prepare the pt for a SAS3 FW_DOWNLOAD request.
10474 */
10475 static void
10476 mpi_pre_fw_25_download(mptsas_t *mpt, mptsas_pt_request_t *pt)
10477 {
10478 pMpi2FWDownloadTCSGE_t tcsge;
10479 pMpi2FWDownloadRequest req2;
10480 pMpi25FWDownloadRequest req25;
10481
10482 /*
10483 * User requests should come in with the Transaction
10484 * context element where the SGL will go. The new firmware
10485 * Doesn't use TCE and has space in the main request for
10486 * this information. So move to the right place.
10487 */
10488 req2 = (pMpi2FWDownloadRequest)pt->request;
10489 req25 = (pMpi25FWDownloadRequest)pt->request;
10490 tcsge = (pMpi2FWDownloadTCSGE_t)&req2->SGL;
10491 if (tcsge->ContextSize != 0 || tcsge->DetailsLength != 12 ||
10492 tcsge->Flags != MPI2_SGE_FLAGS_TRANSACTION_ELEMENT) {
10493 mptsas_log(mpt, CE_WARN, "FW Download tce invalid!");
10494 }
10495 req25->ImageOffset = tcsge->ImageOffset;
10496 req25->ImageSize = tcsge->ImageSize;
10497
10498 pt->sgl_offset = offsetof(MPI25_FW_DOWNLOAD_REQUEST, SGL);
10499 if (pt->request_size != pt->sgl_offset)
10500 NDBG15(("mpi_pre_fw_25_download(): Incorrect req size, "
10501 "0x%x, should be 0x%x, dataoutsz 0x%x",
10502 pt->request_size, pt->sgl_offset,
10503 pt->dataout_size));
10504 if (pt->data_size < sizeof (MPI2_FW_DOWNLOAD_REPLY))
10505 NDBG15(("mpi_pre_fw_25_download(): Incorrect rep size, "
10506 "0x%x, should be 0x%x", pt->data_size,
10507 (int)sizeof (MPI2_FW_UPLOAD_REPLY)));
10508 }
10509
10510 /*
10511 * Prepare the pt for a SAS2 FW_UPLOAD request.
10512 */
10513 static void
10514 mpi_pre_fw_upload(mptsas_t *mpt, mptsas_pt_request_t *pt)
10515 {
10516 pMpi2FWUploadTCSGE_t tcsge;
10517 pMpi2FWUploadRequest_t req;
10518
10519 /*
10520 * If SAS3, call separate function.
10521 */
10522 if (mpt->m_MPI25) {
10523 mpi_pre_fw_25_upload(mpt, pt);
10524 return;
10525 }
10526
10527 /*
10528 * User requests should come in with the Transaction
10529 * context element where the SGL will go. Putting the
10530 * SGL after that seems to work, but don't really know
10531 * why. Other drivers tend to create an extra SGL and
10532 * refer to the TCE through that.
10533 */
10534 req = (pMpi2FWUploadRequest_t)pt->request;
10535 tcsge = (pMpi2FWUploadTCSGE_t)&req->SGL;
10536 if (tcsge->ContextSize != 0 || tcsge->DetailsLength != 12 ||
10537 tcsge->Flags != MPI2_SGE_FLAGS_TRANSACTION_ELEMENT) {
10538 mptsas_log(mpt, CE_WARN, "FW Upload tce invalid!");
10539 }
10540
10541 pt->sgl_offset = offsetof(MPI2_FW_UPLOAD_REQUEST, SGL) +
10542 sizeof (*tcsge);
10543 if (pt->request_size != pt->sgl_offset)
10544 NDBG15(("mpi_pre_fw_upload(): Incorrect req size, "
10545 "0x%x, should be 0x%x, dataoutsz 0x%x",
10546 pt->request_size, pt->sgl_offset,
10547 pt->dataout_size));
10548 if (pt->data_size < sizeof (MPI2_FW_UPLOAD_REPLY))
10549 NDBG15(("mpi_pre_fw_upload(): Incorrect rep size, "
10550 "0x%x, should be 0x%x", pt->data_size,
10551 (int)sizeof (MPI2_FW_UPLOAD_REPLY)));
10552 }
10553
10554 /*
10555 * Prepare the pt a SAS3 FW_UPLOAD request.
10556 */
10557 static void
10558 mpi_pre_fw_25_upload(mptsas_t *mpt, mptsas_pt_request_t *pt)
10559 {
10560 pMpi2FWUploadTCSGE_t tcsge;
10561 pMpi2FWUploadRequest_t req2;
10562 pMpi25FWUploadRequest_t req25;
10563
10564 /*
10565 * User requests should come in with the Transaction
10566 * context element where the SGL will go. The new firmware
10567 * Doesn't use TCE and has space in the main request for
10568 * this information. So move to the right place.
10569 */
10570 req2 = (pMpi2FWUploadRequest_t)pt->request;
10571 req25 = (pMpi25FWUploadRequest_t)pt->request;
10572 tcsge = (pMpi2FWUploadTCSGE_t)&req2->SGL;
10573 if (tcsge->ContextSize != 0 || tcsge->DetailsLength != 12 ||
10574 tcsge->Flags != MPI2_SGE_FLAGS_TRANSACTION_ELEMENT) {
10575 mptsas_log(mpt, CE_WARN, "FW Upload tce invalid!");
10576 }
10577 req25->ImageOffset = tcsge->ImageOffset;
10578 req25->ImageSize = tcsge->ImageSize;
10579
10580 pt->sgl_offset = offsetof(MPI25_FW_UPLOAD_REQUEST, SGL);
10581 if (pt->request_size != pt->sgl_offset)
10582 NDBG15(("mpi_pre_fw_25_upload(): Incorrect req size, "
10583 "0x%x, should be 0x%x, dataoutsz 0x%x",
10584 pt->request_size, pt->sgl_offset,
10585 pt->dataout_size));
10586 if (pt->data_size < sizeof (MPI2_FW_UPLOAD_REPLY))
10587 NDBG15(("mpi_pre_fw_25_upload(): Incorrect rep size, "
10588 "0x%x, should be 0x%x", pt->data_size,
10589 (int)sizeof (MPI2_FW_UPLOAD_REPLY)));
10590 }
10591
10592 /*
10593 * Prepare the pt for an IOC_FACTS request.
10594 */
10595 static void
10596 mpi_pre_ioc_facts(mptsas_t *mpt, mptsas_pt_request_t *pt)
10597 {
10598 #ifndef __lock_lint
10599 _NOTE(ARGUNUSED(mpt))
10600 #endif
10601 if (pt->request_size != sizeof (MPI2_IOC_FACTS_REQUEST))
10602 NDBG15(("mpi_pre_ioc_facts(): Incorrect req size, "
10603 "0x%x, should be 0x%x, dataoutsz 0x%x",
10604 pt->request_size,
10605 (int)sizeof (MPI2_IOC_FACTS_REQUEST),
10606 pt->dataout_size));
10607 if (pt->data_size != sizeof (MPI2_IOC_FACTS_REPLY))
10608 NDBG15(("mpi_pre_ioc_facts(): Incorrect rep size, "
10609 "0x%x, should be 0x%x", pt->data_size,
10610 (int)sizeof (MPI2_IOC_FACTS_REPLY)));
10611 pt->sgl_offset = (uint16_t)pt->request_size;
10612 }
10613
10614 /*
10615 * Prepare the pt for a PORT_FACTS request.
10616 */
10617 static void
10618 mpi_pre_port_facts(mptsas_t *mpt, mptsas_pt_request_t *pt)
10619 {
10620 #ifndef __lock_lint
10621 _NOTE(ARGUNUSED(mpt))
10622 #endif
10623 if (pt->request_size != sizeof (MPI2_PORT_FACTS_REQUEST))
10624 NDBG15(("mpi_pre_port_facts(): Incorrect req size, "
10625 "0x%x, should be 0x%x, dataoutsz 0x%x",
10626 pt->request_size,
10627 (int)sizeof (MPI2_PORT_FACTS_REQUEST),
10628 pt->dataout_size));
10629 if (pt->data_size != sizeof (MPI2_PORT_FACTS_REPLY))
10630 NDBG15(("mpi_pre_port_facts(): Incorrect rep size, "
10631 "0x%x, should be 0x%x", pt->data_size,
10632 (int)sizeof (MPI2_PORT_FACTS_REPLY)));
10633 pt->sgl_offset = (uint16_t)pt->request_size;
10634 }
10635
10636 /*
10637 * Prepare pt for a SATA_PASSTHROUGH request.
10638 */
10639 static void
10640 mpi_pre_sata_passthrough(mptsas_t *mpt, mptsas_pt_request_t *pt)
10641 {
10642 #ifndef __lock_lint
10643 _NOTE(ARGUNUSED(mpt))
10644 #endif
10645 pt->sgl_offset = offsetof(MPI2_SATA_PASSTHROUGH_REQUEST, SGL);
10646 if (pt->request_size != pt->sgl_offset)
10647 NDBG15(("mpi_pre_sata_passthrough(): Incorrect req size, "
10648 "0x%x, should be 0x%x, dataoutsz 0x%x",
10649 pt->request_size, pt->sgl_offset,
10650 pt->dataout_size));
10651 if (pt->data_size != sizeof (MPI2_SATA_PASSTHROUGH_REPLY))
10652 NDBG15(("mpi_pre_sata_passthrough(): Incorrect rep size, "
10653 "0x%x, should be 0x%x", pt->data_size,
10654 (int)sizeof (MPI2_SATA_PASSTHROUGH_REPLY)));
10655 }
10656
10657 static void
10658 mpi_pre_smp_passthrough(mptsas_t *mpt, mptsas_pt_request_t *pt)
10659 {
10660 #ifndef __lock_lint
10661 _NOTE(ARGUNUSED(mpt))
10662 #endif
10663 pt->sgl_offset = offsetof(MPI2_SMP_PASSTHROUGH_REQUEST, SGL);
10664 if (pt->request_size != pt->sgl_offset)
10665 NDBG15(("mpi_pre_smp_passthrough(): Incorrect req size, "
10666 "0x%x, should be 0x%x, dataoutsz 0x%x",
10667 pt->request_size, pt->sgl_offset,
10668 pt->dataout_size));
10669 if (pt->data_size != sizeof (MPI2_SMP_PASSTHROUGH_REPLY))
10670 NDBG15(("mpi_pre_smp_passthrough(): Incorrect rep size, "
10671 "0x%x, should be 0x%x", pt->data_size,
10672 (int)sizeof (MPI2_SMP_PASSTHROUGH_REPLY)));
10673 }
10674
10675 /*
10676 * Prepare pt for a CONFIG request.
10677 */
10678 static void
10679 mpi_pre_config(mptsas_t *mpt, mptsas_pt_request_t *pt)
10680 {
10681 #ifndef __lock_lint
10682 _NOTE(ARGUNUSED(mpt))
10683 #endif
10684 pt->sgl_offset = offsetof(MPI2_CONFIG_REQUEST, PageBufferSGE);
10685 if (pt->request_size != pt->sgl_offset)
10686 NDBG15(("mpi_pre_config(): Incorrect req size, 0x%x, "
10687 "should be 0x%x, dataoutsz 0x%x", pt->request_size,
10688 pt->sgl_offset, pt->dataout_size));
10689 if (pt->data_size != sizeof (MPI2_CONFIG_REPLY))
10690 NDBG15(("mpi_pre_config(): Incorrect rep size, 0x%x, "
10691 "should be 0x%x", pt->data_size,
10692 (int)sizeof (MPI2_CONFIG_REPLY)));
10693 pt->simple = 1;
10694 }
10695
10696 /*
10697 * Prepare pt for a SCSI_IO_REQ request.
10698 */
10699 static void
10700 mpi_pre_scsi_io_req(mptsas_t *mpt, mptsas_pt_request_t *pt)
10701 {
10702 #ifndef __lock_lint
10703 _NOTE(ARGUNUSED(mpt))
10704 #endif
10705 pt->sgl_offset = offsetof(MPI2_SCSI_IO_REQUEST, SGL);
10706 if (pt->request_size != pt->sgl_offset)
10707 NDBG15(("mpi_pre_config(): Incorrect req size, 0x%x, "
10708 "should be 0x%x, dataoutsz 0x%x", pt->request_size,
10709 pt->sgl_offset,
10710 pt->dataout_size));
10711 if (pt->data_size != sizeof (MPI2_SCSI_IO_REPLY))
10712 NDBG15(("mpi_pre_config(): Incorrect rep size, 0x%x, "
10713 "should be 0x%x", pt->data_size,
10714 (int)sizeof (MPI2_SCSI_IO_REPLY)));
10715 }
10716
10717 /*
10718 * Prepare the mptsas_cmd for a SAS_IO_UNIT_CONTROL request.
10719 */
10720 static void
10721 mpi_pre_sas_io_unit_control(mptsas_t *mpt, mptsas_pt_request_t *pt)
10722 {
10723 #ifndef __lock_lint
10724 _NOTE(ARGUNUSED(mpt))
10725 #endif
10726 pt->sgl_offset = (uint16_t)pt->request_size;
10727 }
10728
10729 /*
10730 * A set of functions to prepare an mptsas_cmd for the various
10731 * supported requests.
10732 */
10733 static struct mptsas_func {
10734 U8 Function;
10735 char *Name;
10736 mptsas_pre_f *f_pre;
10737 } mptsas_func_list[] = {
10738 { MPI2_FUNCTION_IOC_FACTS, "IOC_FACTS", mpi_pre_ioc_facts },
10739 { MPI2_FUNCTION_PORT_FACTS, "PORT_FACTS", mpi_pre_port_facts },
10740 { MPI2_FUNCTION_FW_DOWNLOAD, "FW_DOWNLOAD", mpi_pre_fw_download },
10741 { MPI2_FUNCTION_FW_UPLOAD, "FW_UPLOAD", mpi_pre_fw_upload },
10742 { MPI2_FUNCTION_SATA_PASSTHROUGH, "SATA_PASSTHROUGH",
10743 mpi_pre_sata_passthrough },
10744 { MPI2_FUNCTION_SMP_PASSTHROUGH, "SMP_PASSTHROUGH",
10745 mpi_pre_smp_passthrough},
10746 { MPI2_FUNCTION_SCSI_IO_REQUEST, "SCSI_IO_REQUEST",
10747 mpi_pre_scsi_io_req},
10748 { MPI2_FUNCTION_CONFIG, "CONFIG", mpi_pre_config},
10749 { MPI2_FUNCTION_SAS_IO_UNIT_CONTROL, "SAS_IO_UNIT_CONTROL",
10750 mpi_pre_sas_io_unit_control },
10751 { 0xFF, NULL, NULL } /* list end */
10752 };
10753
10754 static void
10755 mptsas_prep_sgl_offset(mptsas_t *mpt, mptsas_pt_request_t *pt)
10756 {
10757 pMPI2RequestHeader_t hdr;
10758 struct mptsas_func *f;
10759
10760 hdr = (pMPI2RequestHeader_t)pt->request;
10761
10762 for (f = mptsas_func_list; f->f_pre != NULL; f++) {
10763 if (hdr->Function == f->Function) {
10764 f->f_pre(mpt, pt);
10765 NDBG15(("mptsas_prep_sgl_offset: Function %s,"
10766 " sgl_offset 0x%x", f->Name,
10767 pt->sgl_offset));
10768 return;
10769 }
10770 }
10771 NDBG15(("mptsas_prep_sgl_offset: Unknown Function 0x%02x,"
10772 " returning req_size 0x%x for sgl_offset",
10773 hdr->Function, pt->request_size));
10774 pt->sgl_offset = (uint16_t)pt->request_size;
10775 }
10776
10777
10778 static int
10779 mptsas_do_passthru(mptsas_t *mpt, uint8_t *request, uint8_t *reply,
10780 uint8_t *data, uint32_t request_size, uint32_t reply_size,
10781 uint32_t data_size, uint32_t direction, uint8_t *dataout,
10782 uint32_t dataout_size, short timeout, int mode)
10783 {
10784 mptsas_pt_request_t pt;
10785 mptsas_dma_alloc_state_t data_dma_state;
10786 mptsas_dma_alloc_state_t dataout_dma_state;
10787 caddr_t memp;
10788 mptsas_cmd_t *cmd = NULL;
10789 struct scsi_pkt *pkt;
10790 uint32_t reply_len = 0, sense_len = 0;
10791 pMPI2RequestHeader_t request_hdrp;
10792 pMPI2RequestHeader_t request_msg;
10793 pMPI2DefaultReply_t reply_msg;
10794 Mpi2SCSIIOReply_t rep_msg;
10795 int rvalue;
10796 int i, status = 0, pt_flags = 0, rv = 0;
10797 uint8_t function;
10798
10799 ASSERT(mutex_owned(&mpt->m_mutex));
10800
10801 reply_msg = (pMPI2DefaultReply_t)(&rep_msg);
10802 bzero(reply_msg, sizeof (MPI2_DEFAULT_REPLY));
10803 request_msg = kmem_zalloc(request_size, KM_SLEEP);
10804
10805 mutex_exit(&mpt->m_mutex);
10806 /*
10807 * copy in the request buffer since it could be used by
10808 * another thread when the pt request into waitq
10809 */
10810 if (ddi_copyin(request, request_msg, request_size, mode)) {
10811 mutex_enter(&mpt->m_mutex);
10812 status = EFAULT;
10813 mptsas_log(mpt, CE_WARN, "failed to copy request data");
10814 goto out;
10815 }
10816 NDBG27(("mptsas_do_passthru: mode 0x%x, size 0x%x, Func 0x%x",
10817 mode, request_size, request_msg->Function));
10818 mutex_enter(&mpt->m_mutex);
10819
10820 function = request_msg->Function;
10821 if (function == MPI2_FUNCTION_SCSI_TASK_MGMT) {
10822 pMpi2SCSITaskManagementRequest_t task;
10823 task = (pMpi2SCSITaskManagementRequest_t)request_msg;
10824 mptsas_setup_bus_reset_delay(mpt);
10825 rv = mptsas_ioc_task_management(mpt, task->TaskType,
10826 task->DevHandle, (int)task->LUN[1], reply, reply_size,
10827 mode);
10828
10829 if (rv != TRUE) {
10830 status = EIO;
10831 mptsas_log(mpt, CE_WARN, "task management failed");
10832 }
10833 goto out;
10834 }
10835
10836 if (data_size != 0) {
10837 data_dma_state.size = data_size;
10838 if (mptsas_dma_alloc(mpt, &data_dma_state) != DDI_SUCCESS) {
10839 status = ENOMEM;
10840 mptsas_log(mpt, CE_WARN, "failed to alloc DMA "
10841 "resource");
10842 goto out;
10843 }
10844 pt_flags |= MPTSAS_DATA_ALLOCATED;
10845 if (direction == MPTSAS_PASS_THRU_DIRECTION_WRITE) {
10846 mutex_exit(&mpt->m_mutex);
10847 for (i = 0; i < data_size; i++) {
10848 if (ddi_copyin(data + i, (uint8_t *)
10849 data_dma_state.memp + i, 1, mode)) {
10850 mutex_enter(&mpt->m_mutex);
10851 status = EFAULT;
10852 mptsas_log(mpt, CE_WARN, "failed to "
10853 "copy read data");
10854 goto out;
10855 }
10856 }
10857 mutex_enter(&mpt->m_mutex);
10858 }
10859 } else {
10860 bzero(&data_dma_state, sizeof (data_dma_state));
10861 }
10862
10863 if (dataout_size != 0) {
10864 dataout_dma_state.size = dataout_size;
10865 if (mptsas_dma_alloc(mpt, &dataout_dma_state) != DDI_SUCCESS) {
10866 status = ENOMEM;
10867 mptsas_log(mpt, CE_WARN, "failed to alloc DMA "
10868 "resource");
10869 goto out;
10870 }
10871 pt_flags |= MPTSAS_DATAOUT_ALLOCATED;
10872 mutex_exit(&mpt->m_mutex);
10873 for (i = 0; i < dataout_size; i++) {
10874 if (ddi_copyin(dataout + i, (uint8_t *)
10875 dataout_dma_state.memp + i, 1, mode)) {
10876 mutex_enter(&mpt->m_mutex);
10877 mptsas_log(mpt, CE_WARN, "failed to copy out"
10878 " data");
10879 status = EFAULT;
10880 goto out;
10881 }
10882 }
10883 mutex_enter(&mpt->m_mutex);
10884 } else {
10885 bzero(&dataout_dma_state, sizeof (dataout_dma_state));
10886 }
10887
10888 if ((rvalue = (mptsas_request_from_pool(mpt, &cmd, &pkt))) == -1) {
10889 status = EAGAIN;
10890 mptsas_log(mpt, CE_NOTE, "event ack command pool is full");
10891 goto out;
10892 }
10893 pt_flags |= MPTSAS_REQUEST_POOL_CMD;
10894
10895 bzero((caddr_t)cmd, sizeof (*cmd));
10896 bzero((caddr_t)pkt, scsi_pkt_size());
10897 bzero((caddr_t)&pt, sizeof (pt));
10898
10899 cmd->ioc_cmd_slot = (uint32_t)(rvalue);
10900
10901 pt.request = (uint8_t *)request_msg;
10902 pt.direction = direction;
10903 pt.simple = 0;
10904 pt.request_size = request_size;
10905 pt.data_size = data_size;
10906 pt.dataout_size = dataout_size;
10907 pt.data_cookie = data_dma_state.cookie;
10908 pt.dataout_cookie = dataout_dma_state.cookie;
10909 mptsas_prep_sgl_offset(mpt, &pt);
10910
10911 /*
10912 * Form a blank cmd/pkt to store the acknowledgement message
10913 */
10914 pkt->pkt_cdbp = (opaque_t)&cmd->cmd_cdb[0];
10915 pkt->pkt_scbp = (opaque_t)&cmd->cmd_scb;
10916 pkt->pkt_ha_private = (opaque_t)&pt;
10917 pkt->pkt_flags = FLAG_HEAD;
10918 pkt->pkt_time = timeout;
10919 cmd->cmd_pkt = pkt;
10920 cmd->cmd_flags = CFLAG_CMDIOC | CFLAG_PASSTHRU;
10921
10922 if ((function == MPI2_FUNCTION_SCSI_IO_REQUEST) ||
10923 (function == MPI2_FUNCTION_RAID_SCSI_IO_PASSTHROUGH)) {
10924 uint8_t com, cdb_group_id;
10925 boolean_t ret;
10926
10927 pkt->pkt_cdbp = ((pMpi2SCSIIORequest_t)request_msg)->CDB.CDB32;
10928 com = pkt->pkt_cdbp[0];
10929 cdb_group_id = CDB_GROUPID(com);
10930 switch (cdb_group_id) {
10931 case CDB_GROUPID_0: cmd->cmd_cdblen = CDB_GROUP0; break;
10932 case CDB_GROUPID_1: cmd->cmd_cdblen = CDB_GROUP1; break;
10933 case CDB_GROUPID_2: cmd->cmd_cdblen = CDB_GROUP2; break;
10934 case CDB_GROUPID_4: cmd->cmd_cdblen = CDB_GROUP4; break;
10935 case CDB_GROUPID_5: cmd->cmd_cdblen = CDB_GROUP5; break;
10936 default:
10937 NDBG27(("mptsas_do_passthru: SCSI_IO, reserved "
10938 "CDBGROUP 0x%x requested!", cdb_group_id));
10939 break;
10940 }
10941
10942 reply_len = sizeof (MPI2_SCSI_IO_REPLY);
10943 sense_len = reply_size - reply_len;
10944 ret = mptsas_cmdarqsize(mpt, cmd, sense_len, KM_SLEEP);
10945 VERIFY(ret == B_TRUE);
10946 } else {
10947 reply_len = reply_size;
10948 sense_len = 0;
10949 }
10950
10951 NDBG27(("mptsas_do_passthru: %s, dsz 0x%x, dosz 0x%x, replen 0x%x, "
10952 "snslen 0x%x",
10953 (direction == MPTSAS_PASS_THRU_DIRECTION_WRITE)?"Write":"Read",
10954 data_size, dataout_size, reply_len, sense_len));
10955
10956 /*
10957 * Save the command in a slot
10958 */
10959 if (mptsas_save_cmd(mpt, cmd) == TRUE) {
10960 /*
10961 * Once passthru command get slot, set cmd_flags
10962 * CFLAG_PREPARED.
10963 */
10964 cmd->cmd_flags |= CFLAG_PREPARED;
10965 mptsas_start_passthru(mpt, cmd);
10966 } else {
10967 mptsas_waitq_add(mpt, cmd);
10968 }
10969
10970 while ((cmd->cmd_flags & CFLAG_FINISHED) == 0) {
10971 cv_wait(&mpt->m_passthru_cv, &mpt->m_mutex);
10972 }
10973
10974 NDBG27(("mptsas_do_passthru: Cmd complete, flags 0x%x, rfm 0x%x "
10975 "pktreason 0x%x", cmd->cmd_flags, cmd->cmd_rfm,
10976 pkt->pkt_reason));
10977
10978 if (cmd->cmd_flags & CFLAG_PREPARED) {
10979 memp = mpt->m_req_frame + (mpt->m_req_frame_size *
10980 cmd->cmd_slot);
10981 request_hdrp = (pMPI2RequestHeader_t)memp;
10982 }
10983
10984 if (cmd->cmd_flags & CFLAG_TIMEOUT) {
10985 status = ETIMEDOUT;
10986 mptsas_log(mpt, CE_WARN, "passthrough command timeout");
10987 pt_flags |= MPTSAS_CMD_TIMEOUT;
10988 goto out;
10989 }
10990
10991 if (cmd->cmd_rfm) {
10992 /*
10993 * cmd_rfm is zero means the command reply is a CONTEXT
10994 * reply and no PCI Write to post the free reply SMFA
10995 * because no reply message frame is used.
10996 * cmd_rfm is non-zero means the reply is a ADDRESS
10997 * reply and reply message frame is used.
10998 */
10999 pt_flags |= MPTSAS_ADDRESS_REPLY;
11000 (void) ddi_dma_sync(mpt->m_dma_reply_frame_hdl, 0, 0,
11001 DDI_DMA_SYNC_FORCPU);
11002 reply_msg = (pMPI2DefaultReply_t)
11003 (mpt->m_reply_frame + (cmd->cmd_rfm -
11004 (mpt->m_reply_frame_dma_addr & 0xffffffffu)));
11005 }
11006
11007 mptsas_fma_check(mpt, cmd);
11008 if (pkt->pkt_reason == CMD_TRAN_ERR) {
11009 status = EAGAIN;
11010 mptsas_log(mpt, CE_WARN, "passthru fma error");
11011 goto out;
11012 }
11013 if (pkt->pkt_reason == CMD_RESET) {
11014 status = EAGAIN;
11015 mptsas_log(mpt, CE_WARN, "ioc reset abort passthru");
11016 goto out;
11017 }
11018
11019 if (pkt->pkt_reason == CMD_INCOMPLETE) {
11020 status = EIO;
11021 mptsas_log(mpt, CE_WARN, "passthrough command incomplete");
11022 goto out;
11023 }
11024
11025 mutex_exit(&mpt->m_mutex);
11026 if (cmd->cmd_flags & CFLAG_PREPARED) {
11027 function = request_hdrp->Function;
11028 if ((function == MPI2_FUNCTION_SCSI_IO_REQUEST) ||
11029 (function == MPI2_FUNCTION_RAID_SCSI_IO_PASSTHROUGH)) {
11030 reply_len = sizeof (MPI2_SCSI_IO_REPLY);
11031 sense_len = cmd->cmd_extrqslen ?
11032 min(sense_len, cmd->cmd_extrqslen) :
11033 min(sense_len, cmd->cmd_rqslen);
11034 } else {
11035 reply_len = reply_size;
11036 sense_len = 0;
11037 }
11038
11039 for (i = 0; i < reply_len; i++) {
11040 if (ddi_copyout((uint8_t *)reply_msg + i, reply + i, 1,
11041 mode)) {
11042 mutex_enter(&mpt->m_mutex);
11043 status = EFAULT;
11044 mptsas_log(mpt, CE_WARN, "failed to copy out "
11045 "reply data");
11046 goto out;
11047 }
11048 }
11049 for (i = 0; i < sense_len; i++) {
11050 if (ddi_copyout((uint8_t *)request_hdrp + 64 + i,
11051 reply + reply_len + i, 1, mode)) {
11052 mutex_enter(&mpt->m_mutex);
11053 status = EFAULT;
11054 mptsas_log(mpt, CE_WARN, "failed to copy out "
11055 "sense data");
11056 goto out;
11057 }
11058 }
11059 }
11060
11061 if (data_size) {
11062 if (direction != MPTSAS_PASS_THRU_DIRECTION_WRITE) {
11063 (void) ddi_dma_sync(data_dma_state.handle, 0, 0,
11064 DDI_DMA_SYNC_FORCPU);
11065 for (i = 0; i < data_size; i++) {
11066 if (ddi_copyout((uint8_t *)(
11067 data_dma_state.memp + i), data + i, 1,
11068 mode)) {
11069 mutex_enter(&mpt->m_mutex);
11070 status = EFAULT;
11071 mptsas_log(mpt, CE_WARN, "failed to "
11072 "copy out the reply data");
11073 goto out;
11074 }
11075 }
11076 }
11077 }
11078 mutex_enter(&mpt->m_mutex);
11079 out:
11080 /*
11081 * Put the reply frame back on the free queue, increment the free
11082 * index, and write the new index to the free index register. But only
11083 * if this reply is an ADDRESS reply.
11084 */
11085 if (pt_flags & MPTSAS_ADDRESS_REPLY) {
11086 ddi_put32(mpt->m_acc_free_queue_hdl,
11087 &((uint32_t *)(void *)mpt->m_free_queue)[mpt->m_free_index],
11088 cmd->cmd_rfm);
11089 (void) ddi_dma_sync(mpt->m_dma_free_queue_hdl, 0, 0,
11090 DDI_DMA_SYNC_FORDEV);
11091 if (++mpt->m_free_index == mpt->m_free_queue_depth) {
11092 mpt->m_free_index = 0;
11093 }
11094 ddi_put32(mpt->m_datap, &mpt->m_reg->ReplyFreeHostIndex,
11095 mpt->m_free_index);
11096 }
11097 if (cmd) {
11098 if (cmd->cmd_extrqslen != 0) {
11099 rmfree(mpt->m_erqsense_map, cmd->cmd_extrqschunks,
11100 cmd->cmd_extrqsidx + 1);
11101 }
11102 if (cmd->cmd_flags & CFLAG_PREPARED) {
11103 mptsas_remove_cmd(mpt, cmd);
11104 pt_flags &= (~MPTSAS_REQUEST_POOL_CMD);
11105 }
11106 }
11107 if (pt_flags & MPTSAS_REQUEST_POOL_CMD)
11108 mptsas_return_to_pool(mpt, cmd);
11109 if (pt_flags & MPTSAS_DATA_ALLOCATED) {
11110 if (mptsas_check_dma_handle(data_dma_state.handle) !=
11111 DDI_SUCCESS) {
11112 ddi_fm_service_impact(mpt->m_dip,
11113 DDI_SERVICE_UNAFFECTED);
11114 status = EFAULT;
11115 }
11116 mptsas_dma_free(&data_dma_state);
11117 }
11118 if (pt_flags & MPTSAS_DATAOUT_ALLOCATED) {
11119 if (mptsas_check_dma_handle(dataout_dma_state.handle) !=
11120 DDI_SUCCESS) {
11121 ddi_fm_service_impact(mpt->m_dip,
11122 DDI_SERVICE_UNAFFECTED);
11123 status = EFAULT;
11124 }
11125 mptsas_dma_free(&dataout_dma_state);
11126 }
11127 if (pt_flags & MPTSAS_CMD_TIMEOUT) {
11128 if ((mptsas_restart_ioc(mpt)) == DDI_FAILURE) {
11129 mptsas_log(mpt, CE_WARN, "mptsas_restart_ioc failed");
11130 }
11131 }
11132 if (request_msg)
11133 kmem_free(request_msg, request_size);
11134 NDBG27(("mptsas_do_passthru: Done status 0x%x", status));
11135
11136 return (status);
11137 }
11138
11139 static int
11140 mptsas_pass_thru(mptsas_t *mpt, mptsas_pass_thru_t *data, int mode)
11141 {
11142 /*
11143 * If timeout is 0, set timeout to default of 60 seconds.
11144 */
11145 if (data->Timeout == 0) {
11146 data->Timeout = MPTSAS_PASS_THRU_TIME_DEFAULT;
11147 }
11148
11149 if (((data->DataSize == 0) &&
11150 (data->DataDirection == MPTSAS_PASS_THRU_DIRECTION_NONE)) ||
11151 ((data->DataSize != 0) &&
11152 ((data->DataDirection == MPTSAS_PASS_THRU_DIRECTION_READ) ||
11153 (data->DataDirection == MPTSAS_PASS_THRU_DIRECTION_WRITE) ||
11154 ((data->DataDirection == MPTSAS_PASS_THRU_DIRECTION_BOTH) &&
11155 (data->DataOutSize != 0))))) {
11156 if (data->DataDirection == MPTSAS_PASS_THRU_DIRECTION_BOTH) {
11157 data->DataDirection = MPTSAS_PASS_THRU_DIRECTION_READ;
11158 } else {
11159 data->DataOutSize = 0;
11160 }
11161 /*
11162 * Send passthru request messages
11163 */
11164 return (mptsas_do_passthru(mpt,
11165 (uint8_t *)((uintptr_t)data->PtrRequest),
11166 (uint8_t *)((uintptr_t)data->PtrReply),
11167 (uint8_t *)((uintptr_t)data->PtrData),
11168 data->RequestSize, data->ReplySize,
11169 data->DataSize, data->DataDirection,
11170 (uint8_t *)((uintptr_t)data->PtrDataOut),
11171 data->DataOutSize, data->Timeout, mode));
11172 } else {
11173 return (EINVAL);
11174 }
11175 }
11176
11177 static uint8_t
11178 mptsas_get_fw_diag_buffer_number(mptsas_t *mpt, uint32_t unique_id)
11179 {
11180 uint8_t index;
11181
11182 for (index = 0; index < MPI2_DIAG_BUF_TYPE_COUNT; index++) {
11183 if (mpt->m_fw_diag_buffer_list[index].unique_id == unique_id) {
11184 return (index);
11185 }
11186 }
11187
11188 return (MPTSAS_FW_DIAGNOSTIC_UID_NOT_FOUND);
11189 }
11190
11191 static void
11192 mptsas_start_diag(mptsas_t *mpt, mptsas_cmd_t *cmd)
11193 {
11194 pMpi2DiagBufferPostRequest_t pDiag_post_msg;
11195 pMpi2DiagReleaseRequest_t pDiag_release_msg;
11196 struct scsi_pkt *pkt = cmd->cmd_pkt;
11197 mptsas_diag_request_t *diag = pkt->pkt_ha_private;
11198 uint32_t i;
11199 uint64_t request_desc;
11200
11201 ASSERT(mutex_owned(&mpt->m_mutex));
11202
11203 /*
11204 * Form the diag message depending on the post or release function.
11205 */
11206 if (diag->function == MPI2_FUNCTION_DIAG_BUFFER_POST) {
11207 pDiag_post_msg = (pMpi2DiagBufferPostRequest_t)
11208 (mpt->m_req_frame + (mpt->m_req_frame_size *
11209 cmd->cmd_slot));
11210 bzero(pDiag_post_msg, mpt->m_req_frame_size);
11211 ddi_put8(mpt->m_acc_req_frame_hdl, &pDiag_post_msg->Function,
11212 diag->function);
11213 ddi_put8(mpt->m_acc_req_frame_hdl, &pDiag_post_msg->BufferType,
11214 diag->pBuffer->buffer_type);
11215 ddi_put8(mpt->m_acc_req_frame_hdl,
11216 &pDiag_post_msg->ExtendedType,
11217 diag->pBuffer->extended_type);
11218 ddi_put32(mpt->m_acc_req_frame_hdl,
11219 &pDiag_post_msg->BufferLength,
11220 diag->pBuffer->buffer_data.size);
11221 for (i = 0; i < (sizeof (pDiag_post_msg->ProductSpecific) / 4);
11222 i++) {
11223 ddi_put32(mpt->m_acc_req_frame_hdl,
11224 &pDiag_post_msg->ProductSpecific[i],
11225 diag->pBuffer->product_specific[i]);
11226 }
11227 ddi_put32(mpt->m_acc_req_frame_hdl,
11228 &pDiag_post_msg->BufferAddress.Low,
11229 (uint32_t)(diag->pBuffer->buffer_data.cookie.dmac_laddress
11230 & 0xffffffffull));
11231 ddi_put32(mpt->m_acc_req_frame_hdl,
11232 &pDiag_post_msg->BufferAddress.High,
11233 (uint32_t)(diag->pBuffer->buffer_data.cookie.dmac_laddress
11234 >> 32));
11235 } else {
11236 pDiag_release_msg = (pMpi2DiagReleaseRequest_t)
11237 (mpt->m_req_frame + (mpt->m_req_frame_size *
11238 cmd->cmd_slot));
11239 bzero(pDiag_release_msg, mpt->m_req_frame_size);
11240 ddi_put8(mpt->m_acc_req_frame_hdl,
11241 &pDiag_release_msg->Function, diag->function);
11242 ddi_put8(mpt->m_acc_req_frame_hdl,
11243 &pDiag_release_msg->BufferType,
11244 diag->pBuffer->buffer_type);
11245 }
11246
11247 /*
11248 * Send the message
11249 */
11250 (void) ddi_dma_sync(mpt->m_dma_req_frame_hdl, 0, 0,
11251 DDI_DMA_SYNC_FORDEV);
11252 request_desc = (cmd->cmd_slot << 16) +
11253 MPI2_REQ_DESCRIPT_FLAGS_DEFAULT_TYPE;
11254 cmd->cmd_rfm = NULL;
11255 MPTSAS_START_CMD(mpt, request_desc);
11256 if ((mptsas_check_dma_handle(mpt->m_dma_req_frame_hdl) !=
11257 DDI_SUCCESS) ||
11258 (mptsas_check_acc_handle(mpt->m_acc_req_frame_hdl) !=
11259 DDI_SUCCESS)) {
11260 ddi_fm_service_impact(mpt->m_dip, DDI_SERVICE_UNAFFECTED);
11261 }
11262 }
11263
11264 static int
11265 mptsas_post_fw_diag_buffer(mptsas_t *mpt,
11266 mptsas_fw_diagnostic_buffer_t *pBuffer, uint32_t *return_code)
11267 {
11268 mptsas_diag_request_t diag;
11269 int status, slot_num, post_flags = 0;
11270 mptsas_cmd_t *cmd = NULL;
11271 struct scsi_pkt *pkt;
11272 pMpi2DiagBufferPostReply_t reply;
11273 uint16_t iocstatus;
11274 uint32_t iocloginfo, transfer_length;
11275
11276 /*
11277 * If buffer is not enabled, just leave.
11278 */
11279 *return_code = MPTSAS_FW_DIAG_ERROR_POST_FAILED;
11280 if (!pBuffer->enabled) {
11281 status = DDI_FAILURE;
11282 goto out;
11283 }
11284
11285 /*
11286 * Clear some flags initially.
11287 */
11288 pBuffer->force_release = FALSE;
11289 pBuffer->valid_data = FALSE;
11290 pBuffer->owned_by_firmware = FALSE;
11291
11292 /*
11293 * Get a cmd buffer from the cmd buffer pool
11294 */
11295 if ((slot_num = (mptsas_request_from_pool(mpt, &cmd, &pkt))) == -1) {
11296 status = DDI_FAILURE;
11297 mptsas_log(mpt, CE_NOTE, "command pool is full: Post FW Diag");
11298 goto out;
11299 }
11300 post_flags |= MPTSAS_REQUEST_POOL_CMD;
11301
11302 bzero((caddr_t)cmd, sizeof (*cmd));
11303 bzero((caddr_t)pkt, scsi_pkt_size());
11304
11305 cmd->ioc_cmd_slot = (uint32_t)(slot_num);
11306
11307 diag.pBuffer = pBuffer;
11308 diag.function = MPI2_FUNCTION_DIAG_BUFFER_POST;
11309
11310 /*
11311 * Form a blank cmd/pkt to store the acknowledgement message
11312 */
11313 pkt->pkt_ha_private = (opaque_t)&diag;
11314 pkt->pkt_flags = FLAG_HEAD;
11315 pkt->pkt_time = 60;
11316 cmd->cmd_pkt = pkt;
11317 cmd->cmd_flags = CFLAG_CMDIOC | CFLAG_FW_DIAG;
11318
11319 /*
11320 * Save the command in a slot
11321 */
11322 if (mptsas_save_cmd(mpt, cmd) == TRUE) {
11323 /*
11324 * Once passthru command get slot, set cmd_flags
11325 * CFLAG_PREPARED.
11326 */
11327 cmd->cmd_flags |= CFLAG_PREPARED;
11328 mptsas_start_diag(mpt, cmd);
11329 } else {
11330 mptsas_waitq_add(mpt, cmd);
11331 }
11332
11333 while ((cmd->cmd_flags & CFLAG_FINISHED) == 0) {
11334 cv_wait(&mpt->m_fw_diag_cv, &mpt->m_mutex);
11335 }
11336
11337 if (cmd->cmd_flags & CFLAG_TIMEOUT) {
11338 status = DDI_FAILURE;
11339 mptsas_log(mpt, CE_WARN, "Post FW Diag command timeout");
11340 goto out;
11341 }
11342
11343 /*
11344 * cmd_rfm points to the reply message if a reply was given. Check the
11345 * IOCStatus to make sure everything went OK with the FW diag request
11346 * and set buffer flags.
11347 */
11348 if (cmd->cmd_rfm) {
11349 post_flags |= MPTSAS_ADDRESS_REPLY;
11350 (void) ddi_dma_sync(mpt->m_dma_reply_frame_hdl, 0, 0,
11351 DDI_DMA_SYNC_FORCPU);
11352 reply = (pMpi2DiagBufferPostReply_t)(mpt->m_reply_frame +
11353 (cmd->cmd_rfm -
11354 (mpt->m_reply_frame_dma_addr & 0xffffffffu)));
11355
11356 /*
11357 * Get the reply message data
11358 */
11359 iocstatus = ddi_get16(mpt->m_acc_reply_frame_hdl,
11360 &reply->IOCStatus);
11361 iocloginfo = ddi_get32(mpt->m_acc_reply_frame_hdl,
11362 &reply->IOCLogInfo);
11363 transfer_length = ddi_get32(mpt->m_acc_reply_frame_hdl,
11364 &reply->TransferLength);
11365
11366 /*
11367 * If post failed quit.
11368 */
11369 if (iocstatus != MPI2_IOCSTATUS_SUCCESS) {
11370 status = DDI_FAILURE;
11371 NDBG13(("post FW Diag Buffer failed: IOCStatus=0x%x, "
11372 "IOCLogInfo=0x%x, TransferLength=0x%x", iocstatus,
11373 iocloginfo, transfer_length));
11374 goto out;
11375 }
11376
11377 /*
11378 * Post was successful.
11379 */
11380 pBuffer->valid_data = TRUE;
11381 pBuffer->owned_by_firmware = TRUE;
11382 *return_code = MPTSAS_FW_DIAG_ERROR_SUCCESS;
11383 status = DDI_SUCCESS;
11384 }
11385
11386 out:
11387 /*
11388 * Put the reply frame back on the free queue, increment the free
11389 * index, and write the new index to the free index register. But only
11390 * if this reply is an ADDRESS reply.
11391 */
11392 if (post_flags & MPTSAS_ADDRESS_REPLY) {
11393 ddi_put32(mpt->m_acc_free_queue_hdl,
11394 &((uint32_t *)(void *)mpt->m_free_queue)[mpt->m_free_index],
11395 cmd->cmd_rfm);
11396 (void) ddi_dma_sync(mpt->m_dma_free_queue_hdl, 0, 0,
11397 DDI_DMA_SYNC_FORDEV);
11398 if (++mpt->m_free_index == mpt->m_free_queue_depth) {
11399 mpt->m_free_index = 0;
11400 }
11401 ddi_put32(mpt->m_datap, &mpt->m_reg->ReplyFreeHostIndex,
11402 mpt->m_free_index);
11403 }
11404 if (cmd && (cmd->cmd_flags & CFLAG_PREPARED)) {
11405 mptsas_remove_cmd(mpt, cmd);
11406 post_flags &= (~MPTSAS_REQUEST_POOL_CMD);
11407 }
11408 if (post_flags & MPTSAS_REQUEST_POOL_CMD) {
11409 mptsas_return_to_pool(mpt, cmd);
11410 }
11411
11412 return (status);
11413 }
11414
11415 static int
11416 mptsas_release_fw_diag_buffer(mptsas_t *mpt,
11417 mptsas_fw_diagnostic_buffer_t *pBuffer, uint32_t *return_code,
11418 uint32_t diag_type)
11419 {
11420 mptsas_diag_request_t diag;
11421 int status, slot_num, rel_flags = 0;
11422 mptsas_cmd_t *cmd = NULL;
11423 struct scsi_pkt *pkt;
11424 pMpi2DiagReleaseReply_t reply;
11425 uint16_t iocstatus;
11426 uint32_t iocloginfo;
11427
11428 /*
11429 * If buffer is not enabled, just leave.
11430 */
11431 *return_code = MPTSAS_FW_DIAG_ERROR_RELEASE_FAILED;
11432 if (!pBuffer->enabled) {
11433 mptsas_log(mpt, CE_NOTE, "This buffer type is not supported "
11434 "by the IOC");
11435 status = DDI_FAILURE;
11436 goto out;
11437 }
11438
11439 /*
11440 * Clear some flags initially.
11441 */
11442 pBuffer->force_release = FALSE;
11443 pBuffer->valid_data = FALSE;
11444 pBuffer->owned_by_firmware = FALSE;
11445
11446 /*
11447 * Get a cmd buffer from the cmd buffer pool
11448 */
11449 if ((slot_num = (mptsas_request_from_pool(mpt, &cmd, &pkt))) == -1) {
11450 status = DDI_FAILURE;
11451 mptsas_log(mpt, CE_NOTE, "command pool is full: Release FW "
11452 "Diag");
11453 goto out;
11454 }
11455 rel_flags |= MPTSAS_REQUEST_POOL_CMD;
11456
11457 bzero((caddr_t)cmd, sizeof (*cmd));
11458 bzero((caddr_t)pkt, scsi_pkt_size());
11459
11460 cmd->ioc_cmd_slot = (uint32_t)(slot_num);
11461
11462 diag.pBuffer = pBuffer;
11463 diag.function = MPI2_FUNCTION_DIAG_RELEASE;
11464
11465 /*
11466 * Form a blank cmd/pkt to store the acknowledgement message
11467 */
11468 pkt->pkt_ha_private = (opaque_t)&diag;
11469 pkt->pkt_flags = FLAG_HEAD;
11470 pkt->pkt_time = 60;
11471 cmd->cmd_pkt = pkt;
11472 cmd->cmd_flags = CFLAG_CMDIOC | CFLAG_FW_DIAG;
11473
11474 /*
11475 * Save the command in a slot
11476 */
11477 if (mptsas_save_cmd(mpt, cmd) == TRUE) {
11478 /*
11479 * Once passthru command get slot, set cmd_flags
11480 * CFLAG_PREPARED.
11481 */
11482 cmd->cmd_flags |= CFLAG_PREPARED;
11483 mptsas_start_diag(mpt, cmd);
11484 } else {
11485 mptsas_waitq_add(mpt, cmd);
11486 }
11487
11488 while ((cmd->cmd_flags & CFLAG_FINISHED) == 0) {
11489 cv_wait(&mpt->m_fw_diag_cv, &mpt->m_mutex);
11490 }
11491
11492 if (cmd->cmd_flags & CFLAG_TIMEOUT) {
11493 status = DDI_FAILURE;
11494 mptsas_log(mpt, CE_WARN, "Release FW Diag command timeout");
11495 goto out;
11496 }
11497
11498 /*
11499 * cmd_rfm points to the reply message if a reply was given. Check the
11500 * IOCStatus to make sure everything went OK with the FW diag request
11501 * and set buffer flags.
11502 */
11503 if (cmd->cmd_rfm) {
11504 rel_flags |= MPTSAS_ADDRESS_REPLY;
11505 (void) ddi_dma_sync(mpt->m_dma_reply_frame_hdl, 0, 0,
11506 DDI_DMA_SYNC_FORCPU);
11507 reply = (pMpi2DiagReleaseReply_t)(mpt->m_reply_frame +
11508 (cmd->cmd_rfm -
11509 (mpt->m_reply_frame_dma_addr & 0xffffffffu)));
11510
11511 /*
11512 * Get the reply message data
11513 */
11514 iocstatus = ddi_get16(mpt->m_acc_reply_frame_hdl,
11515 &reply->IOCStatus);
11516 iocloginfo = ddi_get32(mpt->m_acc_reply_frame_hdl,
11517 &reply->IOCLogInfo);
11518
11519 /*
11520 * If release failed quit.
11521 */
11522 if ((iocstatus != MPI2_IOCSTATUS_SUCCESS) ||
11523 pBuffer->owned_by_firmware) {
11524 status = DDI_FAILURE;
11525 NDBG13(("release FW Diag Buffer failed: "
11526 "IOCStatus=0x%x, IOCLogInfo=0x%x", iocstatus,
11527 iocloginfo));
11528 goto out;
11529 }
11530
11531 /*
11532 * Release was successful.
11533 */
11534 *return_code = MPTSAS_FW_DIAG_ERROR_SUCCESS;
11535 status = DDI_SUCCESS;
11536
11537 /*
11538 * If this was for an UNREGISTER diag type command, clear the
11539 * unique ID.
11540 */
11541 if (diag_type == MPTSAS_FW_DIAG_TYPE_UNREGISTER) {
11542 pBuffer->unique_id = MPTSAS_FW_DIAG_INVALID_UID;
11543 }
11544 }
11545
11546 out:
11547 /*
11548 * Put the reply frame back on the free queue, increment the free
11549 * index, and write the new index to the free index register. But only
11550 * if this reply is an ADDRESS reply.
11551 */
11552 if (rel_flags & MPTSAS_ADDRESS_REPLY) {
11553 ddi_put32(mpt->m_acc_free_queue_hdl,
11554 &((uint32_t *)(void *)mpt->m_free_queue)[mpt->m_free_index],
11555 cmd->cmd_rfm);
11556 (void) ddi_dma_sync(mpt->m_dma_free_queue_hdl, 0, 0,
11557 DDI_DMA_SYNC_FORDEV);
11558 if (++mpt->m_free_index == mpt->m_free_queue_depth) {
11559 mpt->m_free_index = 0;
11560 }
11561 ddi_put32(mpt->m_datap, &mpt->m_reg->ReplyFreeHostIndex,
11562 mpt->m_free_index);
11563 }
11564 if (cmd && (cmd->cmd_flags & CFLAG_PREPARED)) {
11565 mptsas_remove_cmd(mpt, cmd);
11566 rel_flags &= (~MPTSAS_REQUEST_POOL_CMD);
11567 }
11568 if (rel_flags & MPTSAS_REQUEST_POOL_CMD) {
11569 mptsas_return_to_pool(mpt, cmd);
11570 }
11571
11572 return (status);
11573 }
11574
11575 static int
11576 mptsas_diag_register(mptsas_t *mpt, mptsas_fw_diag_register_t *diag_register,
11577 uint32_t *return_code)
11578 {
11579 mptsas_fw_diagnostic_buffer_t *pBuffer;
11580 uint8_t extended_type, buffer_type, i;
11581 uint32_t buffer_size;
11582 uint32_t unique_id;
11583 int status;
11584
11585 ASSERT(mutex_owned(&mpt->m_mutex));
11586
11587 extended_type = diag_register->ExtendedType;
11588 buffer_type = diag_register->BufferType;
11589 buffer_size = diag_register->RequestedBufferSize;
11590 unique_id = diag_register->UniqueId;
11591
11592 /*
11593 * Check for valid buffer type
11594 */
11595 if (buffer_type >= MPI2_DIAG_BUF_TYPE_COUNT) {
11596 *return_code = MPTSAS_FW_DIAG_ERROR_INVALID_PARAMETER;
11597 return (DDI_FAILURE);
11598 }
11599
11600 /*
11601 * Get the current buffer and look up the unique ID. The unique ID
11602 * should not be found. If it is, the ID is already in use.
11603 */
11604 i = mptsas_get_fw_diag_buffer_number(mpt, unique_id);
11605 pBuffer = &mpt->m_fw_diag_buffer_list[buffer_type];
11606 if (i != MPTSAS_FW_DIAGNOSTIC_UID_NOT_FOUND) {
11607 *return_code = MPTSAS_FW_DIAG_ERROR_INVALID_UID;
11608 return (DDI_FAILURE);
11609 }
11610
11611 /*
11612 * The buffer's unique ID should not be registered yet, and the given
11613 * unique ID cannot be 0.
11614 */
11615 if ((pBuffer->unique_id != MPTSAS_FW_DIAG_INVALID_UID) ||
11616 (unique_id == MPTSAS_FW_DIAG_INVALID_UID)) {
11617 *return_code = MPTSAS_FW_DIAG_ERROR_INVALID_UID;
11618 return (DDI_FAILURE);
11619 }
11620
11621 /*
11622 * If this buffer is already posted as immediate, just change owner.
11623 */
11624 if (pBuffer->immediate && pBuffer->owned_by_firmware &&
11625 (pBuffer->unique_id == MPTSAS_FW_DIAG_INVALID_UID)) {
11626 pBuffer->immediate = FALSE;
11627 pBuffer->unique_id = unique_id;
11628 return (DDI_SUCCESS);
11629 }
11630
11631 /*
11632 * Post a new buffer after checking if it's enabled. The DMA buffer
11633 * that is allocated will be contiguous (sgl_len = 1).
11634 */
11635 if (!pBuffer->enabled) {
11636 *return_code = MPTSAS_FW_DIAG_ERROR_NO_BUFFER;
11637 return (DDI_FAILURE);
11638 }
11639 bzero(&pBuffer->buffer_data, sizeof (mptsas_dma_alloc_state_t));
11640 pBuffer->buffer_data.size = buffer_size;
11641 if (mptsas_dma_alloc(mpt, &pBuffer->buffer_data) != DDI_SUCCESS) {
11642 mptsas_log(mpt, CE_WARN, "failed to alloc DMA resource for "
11643 "diag buffer: size = %d bytes", buffer_size);
11644 *return_code = MPTSAS_FW_DIAG_ERROR_NO_BUFFER;
11645 return (DDI_FAILURE);
11646 }
11647
11648 /*
11649 * Copy the given info to the diag buffer and post the buffer.
11650 */
11651 pBuffer->buffer_type = buffer_type;
11652 pBuffer->immediate = FALSE;
11653 if (buffer_type == MPI2_DIAG_BUF_TYPE_TRACE) {
11654 for (i = 0; i < (sizeof (pBuffer->product_specific) / 4);
11655 i++) {
11656 pBuffer->product_specific[i] =
11657 diag_register->ProductSpecific[i];
11658 }
11659 }
11660 pBuffer->extended_type = extended_type;
11661 pBuffer->unique_id = unique_id;
11662 status = mptsas_post_fw_diag_buffer(mpt, pBuffer, return_code);
11663
11664 if (mptsas_check_dma_handle(pBuffer->buffer_data.handle) !=
11665 DDI_SUCCESS) {
11666 mptsas_log(mpt, CE_WARN, "Check of DMA handle failed in "
11667 "mptsas_diag_register.");
11668 ddi_fm_service_impact(mpt->m_dip, DDI_SERVICE_UNAFFECTED);
11669 status = DDI_FAILURE;
11670 }
11671
11672 /*
11673 * In case there was a failure, free the DMA buffer.
11674 */
11675 if (status == DDI_FAILURE) {
11676 mptsas_dma_free(&pBuffer->buffer_data);
11677 }
11678
11679 return (status);
11680 }
11681
11682 static int
11683 mptsas_diag_unregister(mptsas_t *mpt,
11684 mptsas_fw_diag_unregister_t *diag_unregister, uint32_t *return_code)
11685 {
11686 mptsas_fw_diagnostic_buffer_t *pBuffer;
11687 uint8_t i;
11688 uint32_t unique_id;
11689 int status;
11690
11691 ASSERT(mutex_owned(&mpt->m_mutex));
11692
11693 unique_id = diag_unregister->UniqueId;
11694
11695 /*
11696 * Get the current buffer and look up the unique ID. The unique ID
11697 * should be there.
11698 */
11699 i = mptsas_get_fw_diag_buffer_number(mpt, unique_id);
11700 if (i == MPTSAS_FW_DIAGNOSTIC_UID_NOT_FOUND) {
11701 *return_code = MPTSAS_FW_DIAG_ERROR_INVALID_UID;
11702 return (DDI_FAILURE);
11703 }
11704
11705 pBuffer = &mpt->m_fw_diag_buffer_list[i];
11706
11707 /*
11708 * Try to release the buffer from FW before freeing it. If release
11709 * fails, don't free the DMA buffer in case FW tries to access it
11710 * later. If buffer is not owned by firmware, can't release it.
11711 */
11712 if (!pBuffer->owned_by_firmware) {
11713 status = DDI_SUCCESS;
11714 } else {
11715 status = mptsas_release_fw_diag_buffer(mpt, pBuffer,
11716 return_code, MPTSAS_FW_DIAG_TYPE_UNREGISTER);
11717 }
11718
11719 /*
11720 * At this point, return the current status no matter what happens with
11721 * the DMA buffer.
11722 */
11723 pBuffer->unique_id = MPTSAS_FW_DIAG_INVALID_UID;
11724 if (status == DDI_SUCCESS) {
11725 if (mptsas_check_dma_handle(pBuffer->buffer_data.handle) !=
11726 DDI_SUCCESS) {
11727 mptsas_log(mpt, CE_WARN, "Check of DMA handle failed "
11728 "in mptsas_diag_unregister.");
11729 ddi_fm_service_impact(mpt->m_dip,
11730 DDI_SERVICE_UNAFFECTED);
11731 }
11732 mptsas_dma_free(&pBuffer->buffer_data);
11733 }
11734
11735 return (status);
11736 }
11737
11738 static int
11739 mptsas_diag_query(mptsas_t *mpt, mptsas_fw_diag_query_t *diag_query,
11740 uint32_t *return_code)
11741 {
11742 mptsas_fw_diagnostic_buffer_t *pBuffer;
11743 uint8_t i;
11744 uint32_t unique_id;
11745
11746 ASSERT(mutex_owned(&mpt->m_mutex));
11747
11748 unique_id = diag_query->UniqueId;
11749
11750 /*
11751 * If ID is valid, query on ID.
11752 * If ID is invalid, query on buffer type.
11753 */
11754 if (unique_id == MPTSAS_FW_DIAG_INVALID_UID) {
11755 i = diag_query->BufferType;
11756 if (i >= MPI2_DIAG_BUF_TYPE_COUNT) {
11757 *return_code = MPTSAS_FW_DIAG_ERROR_INVALID_UID;
11758 return (DDI_FAILURE);
11759 }
11760 } else {
11761 i = mptsas_get_fw_diag_buffer_number(mpt, unique_id);
11762 if (i == MPTSAS_FW_DIAGNOSTIC_UID_NOT_FOUND) {
11763 *return_code = MPTSAS_FW_DIAG_ERROR_INVALID_UID;
11764 return (DDI_FAILURE);
11765 }
11766 }
11767
11768 /*
11769 * Fill query structure with the diag buffer info.
11770 */
11771 pBuffer = &mpt->m_fw_diag_buffer_list[i];
11772 diag_query->BufferType = pBuffer->buffer_type;
11773 diag_query->ExtendedType = pBuffer->extended_type;
11774 if (diag_query->BufferType == MPI2_DIAG_BUF_TYPE_TRACE) {
11775 for (i = 0; i < (sizeof (diag_query->ProductSpecific) / 4);
11776 i++) {
11777 diag_query->ProductSpecific[i] =
11778 pBuffer->product_specific[i];
11779 }
11780 }
11781 diag_query->TotalBufferSize = pBuffer->buffer_data.size;
11782 diag_query->DriverAddedBufferSize = 0;
11783 diag_query->UniqueId = pBuffer->unique_id;
11784 diag_query->ApplicationFlags = 0;
11785 diag_query->DiagnosticFlags = 0;
11786
11787 /*
11788 * Set/Clear application flags
11789 */
11790 if (pBuffer->immediate) {
11791 diag_query->ApplicationFlags &= ~MPTSAS_FW_DIAG_FLAG_APP_OWNED;
11792 } else {
11793 diag_query->ApplicationFlags |= MPTSAS_FW_DIAG_FLAG_APP_OWNED;
11794 }
11795 if (pBuffer->valid_data || pBuffer->owned_by_firmware) {
11796 diag_query->ApplicationFlags |=
11797 MPTSAS_FW_DIAG_FLAG_BUFFER_VALID;
11798 } else {
11799 diag_query->ApplicationFlags &=
11800 ~MPTSAS_FW_DIAG_FLAG_BUFFER_VALID;
11801 }
11802 if (pBuffer->owned_by_firmware) {
11803 diag_query->ApplicationFlags |=
11804 MPTSAS_FW_DIAG_FLAG_FW_BUFFER_ACCESS;
11805 } else {
11806 diag_query->ApplicationFlags &=
11807 ~MPTSAS_FW_DIAG_FLAG_FW_BUFFER_ACCESS;
11808 }
11809
11810 return (DDI_SUCCESS);
11811 }
11812
11813 static int
11814 mptsas_diag_read_buffer(mptsas_t *mpt,
11815 mptsas_diag_read_buffer_t *diag_read_buffer, uint8_t *ioctl_buf,
11816 uint32_t *return_code, int ioctl_mode)
11817 {
11818 mptsas_fw_diagnostic_buffer_t *pBuffer;
11819 uint8_t i, *pData;
11820 uint32_t unique_id, byte;
11821 int status;
11822
11823 ASSERT(mutex_owned(&mpt->m_mutex));
11824
11825 unique_id = diag_read_buffer->UniqueId;
11826
11827 /*
11828 * Get the current buffer and look up the unique ID. The unique ID
11829 * should be there.
11830 */
11831 i = mptsas_get_fw_diag_buffer_number(mpt, unique_id);
11832 if (i == MPTSAS_FW_DIAGNOSTIC_UID_NOT_FOUND) {
11833 *return_code = MPTSAS_FW_DIAG_ERROR_INVALID_UID;
11834 return (DDI_FAILURE);
11835 }
11836
11837 pBuffer = &mpt->m_fw_diag_buffer_list[i];
11838
11839 /*
11840 * Make sure requested read is within limits
11841 */
11842 if (diag_read_buffer->StartingOffset + diag_read_buffer->BytesToRead >
11843 pBuffer->buffer_data.size) {
11844 *return_code = MPTSAS_FW_DIAG_ERROR_INVALID_PARAMETER;
11845 return (DDI_FAILURE);
11846 }
11847
11848 /*
11849 * Copy the requested data from DMA to the diag_read_buffer. The DMA
11850 * buffer that was allocated is one contiguous buffer.
11851 */
11852 pData = (uint8_t *)(pBuffer->buffer_data.memp +
11853 diag_read_buffer->StartingOffset);
11854 (void) ddi_dma_sync(pBuffer->buffer_data.handle, 0, 0,
11855 DDI_DMA_SYNC_FORCPU);
11856 for (byte = 0; byte < diag_read_buffer->BytesToRead; byte++) {
11857 if (ddi_copyout(pData + byte, ioctl_buf + byte, 1, ioctl_mode)
11858 != 0) {
11859 return (DDI_FAILURE);
11860 }
11861 }
11862 diag_read_buffer->Status = 0;
11863
11864 /*
11865 * Set or clear the Force Release flag.
11866 */
11867 if (pBuffer->force_release) {
11868 diag_read_buffer->Flags |= MPTSAS_FW_DIAG_FLAG_FORCE_RELEASE;
11869 } else {
11870 diag_read_buffer->Flags &= ~MPTSAS_FW_DIAG_FLAG_FORCE_RELEASE;
11871 }
11872
11873 /*
11874 * If buffer is to be reregistered, make sure it's not already owned by
11875 * firmware first.
11876 */
11877 status = DDI_SUCCESS;
11878 if (!pBuffer->owned_by_firmware) {
11879 if (diag_read_buffer->Flags & MPTSAS_FW_DIAG_FLAG_REREGISTER) {
11880 status = mptsas_post_fw_diag_buffer(mpt, pBuffer,
11881 return_code);
11882 }
11883 }
11884
11885 return (status);
11886 }
11887
11888 static int
11889 mptsas_diag_release(mptsas_t *mpt, mptsas_fw_diag_release_t *diag_release,
11890 uint32_t *return_code)
11891 {
11892 mptsas_fw_diagnostic_buffer_t *pBuffer;
11893 uint8_t i;
11894 uint32_t unique_id;
11895 int status;
11896
11897 ASSERT(mutex_owned(&mpt->m_mutex));
11898
11899 unique_id = diag_release->UniqueId;
11900
11901 /*
11902 * Get the current buffer and look up the unique ID. The unique ID
11903 * should be there.
11904 */
11905 i = mptsas_get_fw_diag_buffer_number(mpt, unique_id);
11906 if (i == MPTSAS_FW_DIAGNOSTIC_UID_NOT_FOUND) {
11907 *return_code = MPTSAS_FW_DIAG_ERROR_INVALID_UID;
11908 return (DDI_FAILURE);
11909 }
11910
11911 pBuffer = &mpt->m_fw_diag_buffer_list[i];
11912
11913 /*
11914 * If buffer is not owned by firmware, it's already been released.
11915 */
11916 if (!pBuffer->owned_by_firmware) {
11917 *return_code = MPTSAS_FW_DIAG_ERROR_ALREADY_RELEASED;
11918 return (DDI_FAILURE);
11919 }
11920
11921 /*
11922 * Release the buffer.
11923 */
11924 status = mptsas_release_fw_diag_buffer(mpt, pBuffer, return_code,
11925 MPTSAS_FW_DIAG_TYPE_RELEASE);
11926 return (status);
11927 }
11928
11929 static int
11930 mptsas_do_diag_action(mptsas_t *mpt, uint32_t action, uint8_t *diag_action,
11931 uint32_t length, uint32_t *return_code, int ioctl_mode)
11932 {
11933 mptsas_fw_diag_register_t diag_register;
11934 mptsas_fw_diag_unregister_t diag_unregister;
11935 mptsas_fw_diag_query_t diag_query;
11936 mptsas_diag_read_buffer_t diag_read_buffer;
11937 mptsas_fw_diag_release_t diag_release;
11938 int status = DDI_SUCCESS;
11939 uint32_t original_return_code, read_buf_len;
11940
11941 ASSERT(mutex_owned(&mpt->m_mutex));
11942
11943 original_return_code = *return_code;
11944 *return_code = MPTSAS_FW_DIAG_ERROR_SUCCESS;
11945
11946 switch (action) {
11947 case MPTSAS_FW_DIAG_TYPE_REGISTER:
11948 if (!length) {
11949 *return_code =
11950 MPTSAS_FW_DIAG_ERROR_INVALID_PARAMETER;
11951 status = DDI_FAILURE;
11952 break;
11953 }
11954 if (ddi_copyin(diag_action, &diag_register,
11955 sizeof (diag_register), ioctl_mode) != 0) {
11956 return (DDI_FAILURE);
11957 }
11958 status = mptsas_diag_register(mpt, &diag_register,
11959 return_code);
11960 break;
11961
11962 case MPTSAS_FW_DIAG_TYPE_UNREGISTER:
11963 if (length < sizeof (diag_unregister)) {
11964 *return_code =
11965 MPTSAS_FW_DIAG_ERROR_INVALID_PARAMETER;
11966 status = DDI_FAILURE;
11967 break;
11968 }
11969 if (ddi_copyin(diag_action, &diag_unregister,
11970 sizeof (diag_unregister), ioctl_mode) != 0) {
11971 return (DDI_FAILURE);
11972 }
11973 status = mptsas_diag_unregister(mpt, &diag_unregister,
11974 return_code);
11975 break;
11976
11977 case MPTSAS_FW_DIAG_TYPE_QUERY:
11978 if (length < sizeof (diag_query)) {
11979 *return_code =
11980 MPTSAS_FW_DIAG_ERROR_INVALID_PARAMETER;
11981 status = DDI_FAILURE;
11982 break;
11983 }
11984 if (ddi_copyin(diag_action, &diag_query,
11985 sizeof (diag_query), ioctl_mode) != 0) {
11986 return (DDI_FAILURE);
11987 }
11988 status = mptsas_diag_query(mpt, &diag_query,
11989 return_code);
11990 if (status == DDI_SUCCESS) {
11991 if (ddi_copyout(&diag_query, diag_action,
11992 sizeof (diag_query), ioctl_mode) != 0) {
11993 return (DDI_FAILURE);
11994 }
11995 }
11996 break;
11997
11998 case MPTSAS_FW_DIAG_TYPE_READ_BUFFER:
11999 if (ddi_copyin(diag_action, &diag_read_buffer,
12000 sizeof (diag_read_buffer) - 4, ioctl_mode) != 0) {
12001 return (DDI_FAILURE);
12002 }
12003 read_buf_len = sizeof (diag_read_buffer) -
12004 sizeof (diag_read_buffer.DataBuffer) +
12005 diag_read_buffer.BytesToRead;
12006 if (length < read_buf_len) {
12007 *return_code =
12008 MPTSAS_FW_DIAG_ERROR_INVALID_PARAMETER;
12009 status = DDI_FAILURE;
12010 break;
12011 }
12012 status = mptsas_diag_read_buffer(mpt,
12013 &diag_read_buffer, diag_action +
12014 sizeof (diag_read_buffer) - 4, return_code,
12015 ioctl_mode);
12016 if (status == DDI_SUCCESS) {
12017 if (ddi_copyout(&diag_read_buffer, diag_action,
12018 sizeof (diag_read_buffer) - 4, ioctl_mode)
12019 != 0) {
12020 return (DDI_FAILURE);
12021 }
12022 }
12023 break;
12024
12025 case MPTSAS_FW_DIAG_TYPE_RELEASE:
12026 if (length < sizeof (diag_release)) {
12027 *return_code =
12028 MPTSAS_FW_DIAG_ERROR_INVALID_PARAMETER;
12029 status = DDI_FAILURE;
12030 break;
12031 }
12032 if (ddi_copyin(diag_action, &diag_release,
12033 sizeof (diag_release), ioctl_mode) != 0) {
12034 return (DDI_FAILURE);
12035 }
12036 status = mptsas_diag_release(mpt, &diag_release,
12037 return_code);
12038 break;
12039
12040 default:
12041 *return_code = MPTSAS_FW_DIAG_ERROR_INVALID_PARAMETER;
12042 status = DDI_FAILURE;
12043 break;
12044 }
12045
12046 if ((status == DDI_FAILURE) &&
12047 (original_return_code == MPTSAS_FW_DIAG_NEW) &&
12048 (*return_code != MPTSAS_FW_DIAG_ERROR_SUCCESS)) {
12049 status = DDI_SUCCESS;
12050 }
12051
12052 return (status);
12053 }
12054
12055 static int
12056 mptsas_diag_action(mptsas_t *mpt, mptsas_diag_action_t *user_data, int mode)
12057 {
12058 int status;
12059 mptsas_diag_action_t driver_data;
12060
12061 ASSERT(mutex_owned(&mpt->m_mutex));
12062
12063 /*
12064 * Copy the user data to a driver data buffer.
12065 */
12066 if (ddi_copyin(user_data, &driver_data, sizeof (mptsas_diag_action_t),
12067 mode) == 0) {
12068 /*
12069 * Send diag action request if Action is valid
12070 */
12071 if (driver_data.Action == MPTSAS_FW_DIAG_TYPE_REGISTER ||
12072 driver_data.Action == MPTSAS_FW_DIAG_TYPE_UNREGISTER ||
12073 driver_data.Action == MPTSAS_FW_DIAG_TYPE_QUERY ||
12074 driver_data.Action == MPTSAS_FW_DIAG_TYPE_READ_BUFFER ||
12075 driver_data.Action == MPTSAS_FW_DIAG_TYPE_RELEASE) {
12076 status = mptsas_do_diag_action(mpt, driver_data.Action,
12077 (void *)(uintptr_t)driver_data.PtrDiagAction,
12078 driver_data.Length, &driver_data.ReturnCode,
12079 mode);
12080 if (status == DDI_SUCCESS) {
12081 if (ddi_copyout(&driver_data.ReturnCode,
12082 &user_data->ReturnCode,
12083 sizeof (user_data->ReturnCode), mode)
12084 != 0) {
12085 status = EFAULT;
12086 } else {
12087 status = 0;
12088 }
12089 } else {
12090 status = EIO;
12091 }
12092 } else {
12093 status = EINVAL;
12094 }
12095 } else {
12096 status = EFAULT;
12097 }
12098
12099 return (status);
12100 }
12101
12102 /*
12103 * This routine handles the "event query" ioctl.
12104 */
12105 static int
12106 mptsas_event_query(mptsas_t *mpt, mptsas_event_query_t *data, int mode,
12107 int *rval)
12108 {
12109 int status;
12110 mptsas_event_query_t driverdata;
12111 uint8_t i;
12112
12113 driverdata.Entries = MPTSAS_EVENT_QUEUE_SIZE;
12114
12115 mutex_enter(&mpt->m_mutex);
12116 for (i = 0; i < 4; i++) {
12117 driverdata.Types[i] = mpt->m_event_mask[i];
12118 }
12119 mutex_exit(&mpt->m_mutex);
12120
12121 if (ddi_copyout(&driverdata, data, sizeof (driverdata), mode) != 0) {
12122 status = EFAULT;
12123 } else {
12124 *rval = MPTIOCTL_STATUS_GOOD;
12125 status = 0;
12126 }
12127
12128 return (status);
12129 }
12130
12131 /*
12132 * This routine handles the "event enable" ioctl.
12133 */
12134 static int
12135 mptsas_event_enable(mptsas_t *mpt, mptsas_event_enable_t *data, int mode,
12136 int *rval)
12137 {
12138 int status;
12139 mptsas_event_enable_t driverdata;
12140 uint8_t i;
12141
12142 if (ddi_copyin(data, &driverdata, sizeof (driverdata), mode) == 0) {
12143 mutex_enter(&mpt->m_mutex);
12144 for (i = 0; i < 4; i++) {
12145 mpt->m_event_mask[i] = driverdata.Types[i];
12146 }
12147 mutex_exit(&mpt->m_mutex);
12148
12149 *rval = MPTIOCTL_STATUS_GOOD;
12150 status = 0;
12151 } else {
12152 status = EFAULT;
12153 }
12154 return (status);
12155 }
12156
12157 /*
12158 * This routine handles the "event report" ioctl.
12159 */
12160 static int
12161 mptsas_event_report(mptsas_t *mpt, mptsas_event_report_t *data, int mode,
12162 int *rval)
12163 {
12164 int status;
12165 mptsas_event_report_t driverdata;
12166
12167 mutex_enter(&mpt->m_mutex);
12168
12169 if (ddi_copyin(&data->Size, &driverdata.Size, sizeof (driverdata.Size),
12170 mode) == 0) {
12171 if (driverdata.Size >= sizeof (mpt->m_events)) {
12172 if (ddi_copyout(mpt->m_events, data->Events,
12173 sizeof (mpt->m_events), mode) != 0) {
12174 status = EFAULT;
12175 } else {
12176 if (driverdata.Size > sizeof (mpt->m_events)) {
12177 driverdata.Size =
12178 sizeof (mpt->m_events);
12179 if (ddi_copyout(&driverdata.Size,
12180 &data->Size,
12181 sizeof (driverdata.Size),
12182 mode) != 0) {
12183 status = EFAULT;
12184 } else {
12185 *rval = MPTIOCTL_STATUS_GOOD;
12186 status = 0;
12187 }
12188 } else {
12189 *rval = MPTIOCTL_STATUS_GOOD;
12190 status = 0;
12191 }
12192 }
12193 } else {
12194 *rval = MPTIOCTL_STATUS_LEN_TOO_SHORT;
12195 status = 0;
12196 }
12197 } else {
12198 status = EFAULT;
12199 }
12200
12201 mutex_exit(&mpt->m_mutex);
12202 return (status);
12203 }
12204
12205 static void
12206 mptsas_lookup_pci_data(mptsas_t *mpt, mptsas_adapter_data_t *adapter_data)
12207 {
12208 int *reg_data;
12209 uint_t reglen;
12210
12211 /*
12212 * Lookup the 'reg' property and extract the other data
12213 */
12214 if (ddi_prop_lookup_int_array(DDI_DEV_T_ANY, mpt->m_dip,
12215 DDI_PROP_DONTPASS, "reg", ®_data, ®len) ==
12216 DDI_PROP_SUCCESS) {
12217 /*
12218 * Extract the PCI data from the 'reg' property first DWORD.
12219 * The entry looks like the following:
12220 * First DWORD:
12221 * Bits 0 - 7 8-bit Register number
12222 * Bits 8 - 10 3-bit Function number
12223 * Bits 11 - 15 5-bit Device number
12224 * Bits 16 - 23 8-bit Bus number
12225 * Bits 24 - 25 2-bit Address Space type identifier
12226 *
12227 */
12228 adapter_data->PciInformation.u.bits.BusNumber =
12229 (reg_data[0] & 0x00FF0000) >> 16;
12230 adapter_data->PciInformation.u.bits.DeviceNumber =
12231 (reg_data[0] & 0x0000F800) >> 11;
12232 adapter_data->PciInformation.u.bits.FunctionNumber =
12233 (reg_data[0] & 0x00000700) >> 8;
12234 ddi_prop_free((void *)reg_data);
12235 } else {
12236 /*
12237 * If we can't determine the PCI data then we fill in FF's for
12238 * the data to indicate this.
12239 */
12240 adapter_data->PCIDeviceHwId = 0xFFFFFFFF;
12241 adapter_data->MpiPortNumber = 0xFFFFFFFF;
12242 adapter_data->PciInformation.u.AsDWORD = 0xFFFFFFFF;
12243 }
12244
12245 /*
12246 * Saved in the mpt->m_fwversion
12247 */
12248 adapter_data->MpiFirmwareVersion = mpt->m_fwversion;
12249 }
12250
12251 static void
12252 mptsas_read_adapter_data(mptsas_t *mpt, mptsas_adapter_data_t *adapter_data)
12253 {
12254 char *driver_verstr = MPTSAS_MOD_STRING;
12255
12256 mptsas_lookup_pci_data(mpt, adapter_data);
12257 adapter_data->AdapterType = mpt->m_MPI25 ?
12258 MPTIOCTL_ADAPTER_TYPE_SAS3 :
12259 MPTIOCTL_ADAPTER_TYPE_SAS2;
12260 adapter_data->PCIDeviceHwId = (uint32_t)mpt->m_devid;
12261 adapter_data->PCIDeviceHwRev = (uint32_t)mpt->m_revid;
12262 adapter_data->SubSystemId = (uint32_t)mpt->m_ssid;
12263 adapter_data->SubsystemVendorId = (uint32_t)mpt->m_svid;
12264 (void) strcpy((char *)&adapter_data->DriverVersion[0], driver_verstr);
12265 adapter_data->BiosVersion = 0;
12266 (void) mptsas_get_bios_page3(mpt, &adapter_data->BiosVersion);
12267 }
12268
12269 static void
12270 mptsas_read_pci_info(mptsas_t *mpt, mptsas_pci_info_t *pci_info)
12271 {
12272 int *reg_data, i;
12273 uint_t reglen;
12274
12275 /*
12276 * Lookup the 'reg' property and extract the other data
12277 */
12278 if (ddi_prop_lookup_int_array(DDI_DEV_T_ANY, mpt->m_dip,
12279 DDI_PROP_DONTPASS, "reg", ®_data, ®len) ==
12280 DDI_PROP_SUCCESS) {
12281 /*
12282 * Extract the PCI data from the 'reg' property first DWORD.
12283 * The entry looks like the following:
12284 * First DWORD:
12285 * Bits 8 - 10 3-bit Function number
12286 * Bits 11 - 15 5-bit Device number
12287 * Bits 16 - 23 8-bit Bus number
12288 */
12289 pci_info->BusNumber = (reg_data[0] & 0x00FF0000) >> 16;
12290 pci_info->DeviceNumber = (reg_data[0] & 0x0000F800) >> 11;
12291 pci_info->FunctionNumber = (reg_data[0] & 0x00000700) >> 8;
12292 ddi_prop_free((void *)reg_data);
12293 } else {
12294 /*
12295 * If we can't determine the PCI info then we fill in FF's for
12296 * the data to indicate this.
12297 */
12298 pci_info->BusNumber = 0xFFFFFFFF;
12299 pci_info->DeviceNumber = 0xFF;
12300 pci_info->FunctionNumber = 0xFF;
12301 }
12302
12303 /*
12304 * Now get the interrupt vector and the pci header. The vector can
12305 * only be 0 right now. The header is the first 256 bytes of config
12306 * space.
12307 */
12308 pci_info->InterruptVector = 0;
12309 for (i = 0; i < sizeof (pci_info->PciHeader); i++) {
12310 pci_info->PciHeader[i] = pci_config_get8(mpt->m_config_handle,
12311 i);
12312 }
12313 }
12314
12315 static int
12316 mptsas_reg_access(mptsas_t *mpt, mptsas_reg_access_t *data, int mode)
12317 {
12318 int status = 0;
12319 mptsas_reg_access_t driverdata;
12320
12321 mutex_enter(&mpt->m_mutex);
12322 if (ddi_copyin(data, &driverdata, sizeof (driverdata), mode) == 0) {
12323 switch (driverdata.Command) {
12324 /*
12325 * IO access is not supported.
12326 */
12327 case REG_IO_READ:
12328 case REG_IO_WRITE:
12329 mptsas_log(mpt, CE_WARN, "IO access is not "
12330 "supported. Use memory access.");
12331 status = EINVAL;
12332 break;
12333
12334 case REG_MEM_READ:
12335 driverdata.RegData = ddi_get32(mpt->m_datap,
12336 (uint32_t *)(void *)mpt->m_reg +
12337 driverdata.RegOffset);
12338 if (ddi_copyout(&driverdata.RegData,
12339 &data->RegData,
12340 sizeof (driverdata.RegData), mode) != 0) {
12341 mptsas_log(mpt, CE_WARN, "Register "
12342 "Read Failed");
12343 status = EFAULT;
12344 }
12345 break;
12346
12347 case REG_MEM_WRITE:
12348 ddi_put32(mpt->m_datap,
12349 (uint32_t *)(void *)mpt->m_reg +
12350 driverdata.RegOffset,
12351 driverdata.RegData);
12352 break;
12353
12354 default:
12355 status = EINVAL;
12356 break;
12357 }
12358 } else {
12359 status = EFAULT;
12360 }
12361
12362 mutex_exit(&mpt->m_mutex);
12363 return (status);
12364 }
12365
12366 static int
12367 led_control(mptsas_t *mpt, intptr_t data, int mode)
12368 {
12369 int ret = 0;
12370 mptsas_led_control_t lc;
12371 mptsas_target_t *ptgt;
12372
12373 if (ddi_copyin((void *)data, &lc, sizeof (lc), mode) != 0) {
12374 return (EFAULT);
12375 }
12376
12377 if ((lc.Command != MPTSAS_LEDCTL_FLAG_SET &&
12378 lc.Command != MPTSAS_LEDCTL_FLAG_GET) ||
12379 lc.Led < MPTSAS_LEDCTL_LED_MIN ||
12380 lc.Led > MPTSAS_LEDCTL_LED_MAX ||
12381 (lc.Command == MPTSAS_LEDCTL_FLAG_SET && lc.LedStatus != 0 &&
12382 lc.LedStatus != 1)) {
12383 return (EINVAL);
12384 }
12385
12386 if ((lc.Command == MPTSAS_LEDCTL_FLAG_SET && (mode & FWRITE) == 0) ||
12387 (lc.Command == MPTSAS_LEDCTL_FLAG_GET && (mode & FREAD) == 0))
12388 return (EACCES);
12389
12390 /* Locate the target we're interrogating... */
12391 mutex_enter(&mpt->m_mutex);
12392 ptgt = refhash_linear_search(mpt->m_targets,
12393 mptsas_target_eval_slot, &lc);
12394 if (ptgt == NULL) {
12395 /* We could not find a target for that enclosure/slot. */
12396 mutex_exit(&mpt->m_mutex);
12397 return (ENOENT);
12398 }
12399
12400 if (lc.Command == MPTSAS_LEDCTL_FLAG_SET) {
12401 /* Update our internal LED state. */
12402 ptgt->m_led_status &= ~(1 << (lc.Led - 1));
12403 ptgt->m_led_status |= lc.LedStatus << (lc.Led - 1);
12404
12405 /* Flush it to the controller. */
12406 ret = mptsas_flush_led_status(mpt, ptgt);
12407 mutex_exit(&mpt->m_mutex);
12408 return (ret);
12409 }
12410
12411 /* Return our internal LED state. */
12412 lc.LedStatus = (ptgt->m_led_status >> (lc.Led - 1)) & 1;
12413 mutex_exit(&mpt->m_mutex);
12414
12415 if (ddi_copyout(&lc, (void *)data, sizeof (lc), mode) != 0) {
12416 return (EFAULT);
12417 }
12418
12419 return (0);
12420 }
12421
12422 static int
12423 get_disk_info(mptsas_t *mpt, intptr_t data, int mode)
12424 {
12425 uint16_t i = 0;
12426 uint16_t count = 0;
12427 int ret = 0;
12428 mptsas_target_t *ptgt;
12429 mptsas_disk_info_t *di;
12430 STRUCT_DECL(mptsas_get_disk_info, gdi);
12431
12432 if ((mode & FREAD) == 0)
12433 return (EACCES);
12434
12435 STRUCT_INIT(gdi, get_udatamodel());
12436
12437 if (ddi_copyin((void *)data, STRUCT_BUF(gdi), STRUCT_SIZE(gdi),
12438 mode) != 0) {
12439 return (EFAULT);
12440 }
12441
12442 /* Find out how many targets there are. */
12443 mutex_enter(&mpt->m_mutex);
12444 for (ptgt = refhash_first(mpt->m_targets); ptgt != NULL;
12445 ptgt = refhash_next(mpt->m_targets, ptgt)) {
12446 count++;
12447 }
12448 mutex_exit(&mpt->m_mutex);
12449
12450 /*
12451 * If we haven't been asked to copy out information on each target,
12452 * then just return the count.
12453 */
12454 STRUCT_FSET(gdi, DiskCount, count);
12455 if (STRUCT_FGETP(gdi, PtrDiskInfoArray) == NULL)
12456 goto copy_out;
12457
12458 /*
12459 * If we haven't been given a large enough buffer to copy out into,
12460 * let the caller know.
12461 */
12462 if (STRUCT_FGET(gdi, DiskInfoArraySize) <
12463 count * sizeof (mptsas_disk_info_t)) {
12464 ret = ENOSPC;
12465 goto copy_out;
12466 }
12467
12468 di = kmem_zalloc(count * sizeof (mptsas_disk_info_t), KM_SLEEP);
12469
12470 mutex_enter(&mpt->m_mutex);
12471 for (ptgt = refhash_first(mpt->m_targets); ptgt != NULL;
12472 ptgt = refhash_next(mpt->m_targets, ptgt)) {
12473 if (i >= count) {
12474 /*
12475 * The number of targets changed while we weren't
12476 * looking, so give up.
12477 */
12478 refhash_rele(mpt->m_targets, ptgt);
12479 mutex_exit(&mpt->m_mutex);
12480 kmem_free(di, count * sizeof (mptsas_disk_info_t));
12481 return (EAGAIN);
12482 }
12483 di[i].Instance = mpt->m_instance;
12484 di[i].Enclosure = ptgt->m_enclosure;
12485 di[i].Slot = ptgt->m_slot_num;
12486 di[i].SasAddress = ptgt->m_addr.mta_wwn;
12487 i++;
12488 }
12489 mutex_exit(&mpt->m_mutex);
12490 STRUCT_FSET(gdi, DiskCount, i);
12491
12492 /* Copy out the disk information to the caller. */
12493 if (ddi_copyout((void *)di, STRUCT_FGETP(gdi, PtrDiskInfoArray),
12494 i * sizeof (mptsas_disk_info_t), mode) != 0) {
12495 ret = EFAULT;
12496 }
12497
12498 kmem_free(di, count * sizeof (mptsas_disk_info_t));
12499
12500 copy_out:
12501 if (ddi_copyout(STRUCT_BUF(gdi), (void *)data, STRUCT_SIZE(gdi),
12502 mode) != 0) {
12503 ret = EFAULT;
12504 }
12505
12506 return (ret);
12507 }
12508
12509 static int
12510 mptsas_ioctl(dev_t dev, int cmd, intptr_t data, int mode, cred_t *credp,
12511 int *rval)
12512 {
12513 int status = 0;
12514 mptsas_t *mpt;
12515 mptsas_update_flash_t flashdata;
12516 mptsas_pass_thru_t passthru_data;
12517 mptsas_adapter_data_t adapter_data;
12518 mptsas_pci_info_t pci_info;
12519 int copylen;
12520
12521 int iport_flag = 0;
12522 dev_info_t *dip = NULL;
12523 mptsas_phymask_t phymask = 0;
12524 struct devctl_iocdata *dcp = NULL;
12525 char *addr = NULL;
12526 mptsas_target_t *ptgt = NULL;
12527
12528 *rval = MPTIOCTL_STATUS_GOOD;
12529 if (secpolicy_sys_config(credp, B_FALSE) != 0) {
12530 return (EPERM);
12531 }
12532
12533 mpt = ddi_get_soft_state(mptsas_state, MINOR2INST(getminor(dev)));
12534 if (mpt == NULL) {
12535 /*
12536 * Called from iport node, get the states
12537 */
12538 iport_flag = 1;
12539 dip = mptsas_get_dip_from_dev(dev, &phymask);
12540 if (dip == NULL) {
12541 return (ENXIO);
12542 }
12543 mpt = DIP2MPT(dip);
12544 }
12545 /* Make sure power level is D0 before accessing registers */
12546 mutex_enter(&mpt->m_mutex);
12547 if (mpt->m_options & MPTSAS_OPT_PM) {
12548 (void) pm_busy_component(mpt->m_dip, 0);
12549 if (mpt->m_power_level != PM_LEVEL_D0) {
12550 mutex_exit(&mpt->m_mutex);
12551 if (pm_raise_power(mpt->m_dip, 0, PM_LEVEL_D0) !=
12552 DDI_SUCCESS) {
12553 mptsas_log(mpt, CE_WARN,
12554 "mptsas%d: mptsas_ioctl: Raise power "
12555 "request failed.", mpt->m_instance);
12556 (void) pm_idle_component(mpt->m_dip, 0);
12557 return (ENXIO);
12558 }
12559 } else {
12560 mutex_exit(&mpt->m_mutex);
12561 }
12562 } else {
12563 mutex_exit(&mpt->m_mutex);
12564 }
12565
12566 if (iport_flag) {
12567 status = scsi_hba_ioctl(dev, cmd, data, mode, credp, rval);
12568 if (status != 0) {
12569 goto out;
12570 }
12571 /*
12572 * The following code control the OK2RM LED, it doesn't affect
12573 * the ioctl return status.
12574 */
12575 if ((cmd == DEVCTL_DEVICE_ONLINE) ||
12576 (cmd == DEVCTL_DEVICE_OFFLINE)) {
12577 if (ndi_dc_allochdl((void *)data, &dcp) !=
12578 NDI_SUCCESS) {
12579 goto out;
12580 }
12581 addr = ndi_dc_getaddr(dcp);
12582 ptgt = mptsas_addr_to_ptgt(mpt, addr, phymask);
12583 if (ptgt == NULL) {
12584 NDBG14(("mptsas_ioctl led control: tgt %s not "
12585 "found", addr));
12586 ndi_dc_freehdl(dcp);
12587 goto out;
12588 }
12589 mutex_enter(&mpt->m_mutex);
12590 if (cmd == DEVCTL_DEVICE_ONLINE) {
12591 ptgt->m_tgt_unconfigured = 0;
12592 } else if (cmd == DEVCTL_DEVICE_OFFLINE) {
12593 ptgt->m_tgt_unconfigured = 1;
12594 }
12595 if (cmd == DEVCTL_DEVICE_OFFLINE) {
12596 ptgt->m_led_status |=
12597 (1 << (MPTSAS_LEDCTL_LED_OK2RM - 1));
12598 } else {
12599 ptgt->m_led_status &=
12600 ~(1 << (MPTSAS_LEDCTL_LED_OK2RM - 1));
12601 }
12602 (void) mptsas_flush_led_status(mpt, ptgt);
12603 mutex_exit(&mpt->m_mutex);
12604 ndi_dc_freehdl(dcp);
12605 }
12606 goto out;
12607 }
12608 switch (cmd) {
12609 case MPTIOCTL_GET_DISK_INFO:
12610 status = get_disk_info(mpt, data, mode);
12611 break;
12612 case MPTIOCTL_LED_CONTROL:
12613 status = led_control(mpt, data, mode);
12614 break;
12615 case MPTIOCTL_UPDATE_FLASH:
12616 if (ddi_copyin((void *)data, &flashdata,
12617 sizeof (struct mptsas_update_flash), mode)) {
12618 status = EFAULT;
12619 break;
12620 }
12621
12622 mutex_enter(&mpt->m_mutex);
12623 if (mptsas_update_flash(mpt,
12624 (caddr_t)(long)flashdata.PtrBuffer,
12625 flashdata.ImageSize, flashdata.ImageType, mode)) {
12626 status = EFAULT;
12627 }
12628
12629 /*
12630 * Reset the chip to start using the new
12631 * firmware. Reset if failed also.
12632 */
12633 mpt->m_softstate &= ~MPTSAS_SS_MSG_UNIT_RESET;
12634 if (mptsas_restart_ioc(mpt) == DDI_FAILURE) {
12635 status = EFAULT;
12636 }
12637 mutex_exit(&mpt->m_mutex);
12638 break;
12639 case MPTIOCTL_PASS_THRU:
12640 /*
12641 * The user has requested to pass through a command to
12642 * be executed by the MPT firmware. Call our routine
12643 * which does this. Only allow one passthru IOCTL at
12644 * one time. Other threads will block on
12645 * m_passthru_mutex, which is of adaptive variant.
12646 */
12647 if (ddi_copyin((void *)data, &passthru_data,
12648 sizeof (mptsas_pass_thru_t), mode)) {
12649 status = EFAULT;
12650 break;
12651 }
12652 mutex_enter(&mpt->m_passthru_mutex);
12653 mutex_enter(&mpt->m_mutex);
12654 status = mptsas_pass_thru(mpt, &passthru_data, mode);
12655 mutex_exit(&mpt->m_mutex);
12656 mutex_exit(&mpt->m_passthru_mutex);
12657
12658 break;
12659 case MPTIOCTL_GET_ADAPTER_DATA:
12660 /*
12661 * The user has requested to read adapter data. Call
12662 * our routine which does this.
12663 */
12664 bzero(&adapter_data, sizeof (mptsas_adapter_data_t));
12665 if (ddi_copyin((void *)data, (void *)&adapter_data,
12666 sizeof (mptsas_adapter_data_t), mode)) {
12667 status = EFAULT;
12668 break;
12669 }
12670 if (adapter_data.StructureLength >=
12671 sizeof (mptsas_adapter_data_t)) {
12672 adapter_data.StructureLength = (uint32_t)
12673 sizeof (mptsas_adapter_data_t);
12674 copylen = sizeof (mptsas_adapter_data_t);
12675 mutex_enter(&mpt->m_mutex);
12676 mptsas_read_adapter_data(mpt, &adapter_data);
12677 mutex_exit(&mpt->m_mutex);
12678 } else {
12679 adapter_data.StructureLength = (uint32_t)
12680 sizeof (mptsas_adapter_data_t);
12681 copylen = sizeof (adapter_data.StructureLength);
12682 *rval = MPTIOCTL_STATUS_LEN_TOO_SHORT;
12683 }
12684 if (ddi_copyout((void *)(&adapter_data), (void *)data,
12685 copylen, mode) != 0) {
12686 status = EFAULT;
12687 }
12688 break;
12689 case MPTIOCTL_GET_PCI_INFO:
12690 /*
12691 * The user has requested to read pci info. Call
12692 * our routine which does this.
12693 */
12694 bzero(&pci_info, sizeof (mptsas_pci_info_t));
12695 mutex_enter(&mpt->m_mutex);
12696 mptsas_read_pci_info(mpt, &pci_info);
12697 mutex_exit(&mpt->m_mutex);
12698 if (ddi_copyout((void *)(&pci_info), (void *)data,
12699 sizeof (mptsas_pci_info_t), mode) != 0) {
12700 status = EFAULT;
12701 }
12702 break;
12703 case MPTIOCTL_RESET_ADAPTER:
12704 mutex_enter(&mpt->m_mutex);
12705 mpt->m_softstate &= ~MPTSAS_SS_MSG_UNIT_RESET;
12706 if ((mptsas_restart_ioc(mpt)) == DDI_FAILURE) {
12707 mptsas_log(mpt, CE_WARN, "reset adapter IOCTL "
12708 "failed");
12709 status = EFAULT;
12710 }
12711 mutex_exit(&mpt->m_mutex);
12712 break;
12713 case MPTIOCTL_DIAG_ACTION:
12714 /*
12715 * The user has done a diag buffer action. Call our
12716 * routine which does this. Only allow one diag action
12717 * at one time.
12718 */
12719 mutex_enter(&mpt->m_mutex);
12720 if (mpt->m_diag_action_in_progress) {
12721 mutex_exit(&mpt->m_mutex);
12722 return (EBUSY);
12723 }
12724 mpt->m_diag_action_in_progress = 1;
12725 status = mptsas_diag_action(mpt,
12726 (mptsas_diag_action_t *)data, mode);
12727 mpt->m_diag_action_in_progress = 0;
12728 mutex_exit(&mpt->m_mutex);
12729 break;
12730 case MPTIOCTL_EVENT_QUERY:
12731 /*
12732 * The user has done an event query. Call our routine
12733 * which does this.
12734 */
12735 status = mptsas_event_query(mpt,
12736 (mptsas_event_query_t *)data, mode, rval);
12737 break;
12738 case MPTIOCTL_EVENT_ENABLE:
12739 /*
12740 * The user has done an event enable. Call our routine
12741 * which does this.
12742 */
12743 status = mptsas_event_enable(mpt,
12744 (mptsas_event_enable_t *)data, mode, rval);
12745 break;
12746 case MPTIOCTL_EVENT_REPORT:
12747 /*
12748 * The user has done an event report. Call our routine
12749 * which does this.
12750 */
12751 status = mptsas_event_report(mpt,
12752 (mptsas_event_report_t *)data, mode, rval);
12753 break;
12754 case MPTIOCTL_REG_ACCESS:
12755 /*
12756 * The user has requested register access. Call our
12757 * routine which does this.
12758 */
12759 status = mptsas_reg_access(mpt,
12760 (mptsas_reg_access_t *)data, mode);
12761 break;
12762 default:
12763 status = scsi_hba_ioctl(dev, cmd, data, mode, credp,
12764 rval);
12765 break;
12766 }
12767
12768 out:
12769 return (status);
12770 }
12771
12772 int
12773 mptsas_restart_ioc(mptsas_t *mpt)
12774 {
12775 int rval = DDI_SUCCESS;
12776 mptsas_target_t *ptgt = NULL;
12777
12778 ASSERT(mutex_owned(&mpt->m_mutex));
12779
12780 /*
12781 * Set a flag telling I/O path that we're processing a reset. This is
12782 * needed because after the reset is complete, the hash table still
12783 * needs to be rebuilt. If I/Os are started before the hash table is
12784 * rebuilt, I/O errors will occur. This flag allows I/Os to be marked
12785 * so that they can be retried.
12786 */
12787 mpt->m_in_reset = TRUE;
12788
12789 /*
12790 * Set all throttles to HOLD
12791 */
12792 for (ptgt = refhash_first(mpt->m_targets); ptgt != NULL;
12793 ptgt = refhash_next(mpt->m_targets, ptgt)) {
12794 mptsas_set_throttle(mpt, ptgt, HOLD_THROTTLE);
12795 }
12796
12797 /*
12798 * Disable interrupts
12799 */
12800 MPTSAS_DISABLE_INTR(mpt);
12801
12802 /*
12803 * Abort all commands: outstanding commands, commands in waitq and
12804 * tx_waitq.
12805 */
12806 mptsas_flush_hba(mpt);
12807
12808 /*
12809 * Reinitialize the chip.
12810 */
12811 if (mptsas_init_chip(mpt, FALSE) == DDI_FAILURE) {
12812 rval = DDI_FAILURE;
12813 }
12814
12815 /*
12816 * Enable interrupts again
12817 */
12818 MPTSAS_ENABLE_INTR(mpt);
12819
12820 /*
12821 * If mptsas_init_chip was successful, update the driver data.
12822 */
12823 if (rval == DDI_SUCCESS) {
12824 mptsas_update_driver_data(mpt);
12825 }
12826
12827 /*
12828 * Reset the throttles
12829 */
12830 for (ptgt = refhash_first(mpt->m_targets); ptgt != NULL;
12831 ptgt = refhash_next(mpt->m_targets, ptgt)) {
12832 mptsas_set_throttle(mpt, ptgt, MAX_THROTTLE);
12833 }
12834
12835 mptsas_doneq_empty(mpt);
12836 mptsas_restart_hba(mpt);
12837
12838 if (rval != DDI_SUCCESS) {
12839 mptsas_fm_ereport(mpt, DDI_FM_DEVICE_NO_RESPONSE);
12840 ddi_fm_service_impact(mpt->m_dip, DDI_SERVICE_LOST);
12841 }
12842
12843 /*
12844 * Clear the reset flag so that I/Os can continue.
12845 */
12846 mpt->m_in_reset = FALSE;
12847
12848 return (rval);
12849 }
12850
12851 static int
12852 mptsas_init_chip(mptsas_t *mpt, int first_time)
12853 {
12854 ddi_dma_cookie_t cookie;
12855 uint32_t i;
12856 int rval;
12857
12858 /*
12859 * Check to see if the firmware image is valid
12860 */
12861 if (ddi_get32(mpt->m_datap, &mpt->m_reg->HostDiagnostic) &
12862 MPI2_DIAG_FLASH_BAD_SIG) {
12863 mptsas_log(mpt, CE_WARN, "mptsas bad flash signature!");
12864 goto fail;
12865 }
12866
12867 /*
12868 * Reset the chip
12869 */
12870 rval = mptsas_ioc_reset(mpt, first_time);
12871 if (rval == MPTSAS_RESET_FAIL) {
12872 mptsas_log(mpt, CE_WARN, "hard reset failed!");
12873 goto fail;
12874 }
12875
12876 if ((rval == MPTSAS_SUCCESS_MUR) && (!first_time)) {
12877 goto mur;
12878 }
12879 /*
12880 * Setup configuration space
12881 */
12882 if (mptsas_config_space_init(mpt) == FALSE) {
12883 mptsas_log(mpt, CE_WARN, "mptsas_config_space_init "
12884 "failed!");
12885 goto fail;
12886 }
12887
12888 /*
12889 * IOC facts can change after a diag reset so all buffers that are
12890 * based on these numbers must be de-allocated and re-allocated. Get
12891 * new IOC facts each time chip is initialized.
12892 */
12893 if (mptsas_ioc_get_facts(mpt) == DDI_FAILURE) {
12894 mptsas_log(mpt, CE_WARN, "mptsas_ioc_get_facts failed");
12895 goto fail;
12896 }
12897
12898 if (mptsas_alloc_active_slots(mpt, KM_SLEEP)) {
12899 goto fail;
12900 }
12901 /*
12902 * Allocate request message frames, reply free queue, reply descriptor
12903 * post queue, and reply message frames using latest IOC facts.
12904 */
12905 if (mptsas_alloc_request_frames(mpt) == DDI_FAILURE) {
12906 mptsas_log(mpt, CE_WARN, "mptsas_alloc_request_frames failed");
12907 goto fail;
12908 }
12909 if (mptsas_alloc_sense_bufs(mpt) == DDI_FAILURE) {
12910 mptsas_log(mpt, CE_WARN, "mptsas_alloc_sense_bufs failed");
12911 goto fail;
12912 }
12913 if (mptsas_alloc_free_queue(mpt) == DDI_FAILURE) {
12914 mptsas_log(mpt, CE_WARN, "mptsas_alloc_free_queue failed!");
12915 goto fail;
12916 }
12917 if (mptsas_alloc_post_queue(mpt) == DDI_FAILURE) {
12918 mptsas_log(mpt, CE_WARN, "mptsas_alloc_post_queue failed!");
12919 goto fail;
12920 }
12921 if (mptsas_alloc_reply_frames(mpt) == DDI_FAILURE) {
12922 mptsas_log(mpt, CE_WARN, "mptsas_alloc_reply_frames failed!");
12923 goto fail;
12924 }
12925
12926 mur:
12927 /*
12928 * Re-Initialize ioc to operational state
12929 */
12930 if (mptsas_ioc_init(mpt) == DDI_FAILURE) {
12931 mptsas_log(mpt, CE_WARN, "mptsas_ioc_init failed");
12932 goto fail;
12933 }
12934
12935 mptsas_alloc_reply_args(mpt);
12936
12937 /*
12938 * Initialize reply post index. Reply free index is initialized after
12939 * the next loop.
12940 */
12941 mpt->m_post_index = 0;
12942
12943 /*
12944 * Initialize the Reply Free Queue with the physical addresses of our
12945 * reply frames.
12946 */
12947 cookie.dmac_address = mpt->m_reply_frame_dma_addr & 0xffffffffu;
12948 for (i = 0; i < mpt->m_max_replies; i++) {
12949 ddi_put32(mpt->m_acc_free_queue_hdl,
12950 &((uint32_t *)(void *)mpt->m_free_queue)[i],
12951 cookie.dmac_address);
12952 cookie.dmac_address += mpt->m_reply_frame_size;
12953 }
12954 (void) ddi_dma_sync(mpt->m_dma_free_queue_hdl, 0, 0,
12955 DDI_DMA_SYNC_FORDEV);
12956
12957 /*
12958 * Initialize the reply free index to one past the last frame on the
12959 * queue. This will signify that the queue is empty to start with.
12960 */
12961 mpt->m_free_index = i;
12962 ddi_put32(mpt->m_datap, &mpt->m_reg->ReplyFreeHostIndex, i);
12963
12964 /*
12965 * Initialize the reply post queue to 0xFFFFFFFF,0xFFFFFFFF's.
12966 */
12967 for (i = 0; i < mpt->m_post_queue_depth; i++) {
12968 ddi_put64(mpt->m_acc_post_queue_hdl,
12969 &((uint64_t *)(void *)mpt->m_post_queue)[i],
12970 0xFFFFFFFFFFFFFFFF);
12971 }
12972 (void) ddi_dma_sync(mpt->m_dma_post_queue_hdl, 0, 0,
12973 DDI_DMA_SYNC_FORDEV);
12974
12975 /*
12976 * Enable ports
12977 */
12978 if (mptsas_ioc_enable_port(mpt) == DDI_FAILURE) {
12979 mptsas_log(mpt, CE_WARN, "mptsas_ioc_enable_port failed");
12980 goto fail;
12981 }
12982
12983 /*
12984 * enable events
12985 */
12986 if (mptsas_ioc_enable_event_notification(mpt)) {
12987 mptsas_log(mpt, CE_WARN,
12988 "mptsas_ioc_enable_event_notification failed");
12989 goto fail;
12990 }
12991
12992 /*
12993 * We need checks in attach and these.
12994 * chip_init is called in mult. places
12995 */
12996
12997 if ((mptsas_check_dma_handle(mpt->m_dma_req_frame_hdl) !=
12998 DDI_SUCCESS) ||
12999 (mptsas_check_dma_handle(mpt->m_dma_req_sense_hdl) !=
13000 DDI_SUCCESS) ||
13001 (mptsas_check_dma_handle(mpt->m_dma_reply_frame_hdl) !=
13002 DDI_SUCCESS) ||
13003 (mptsas_check_dma_handle(mpt->m_dma_free_queue_hdl) !=
13004 DDI_SUCCESS) ||
13005 (mptsas_check_dma_handle(mpt->m_dma_post_queue_hdl) !=
13006 DDI_SUCCESS) ||
13007 (mptsas_check_dma_handle(mpt->m_hshk_dma_hdl) !=
13008 DDI_SUCCESS)) {
13009 ddi_fm_service_impact(mpt->m_dip, DDI_SERVICE_UNAFFECTED);
13010 goto fail;
13011 }
13012
13013 /* Check all acc handles */
13014 if ((mptsas_check_acc_handle(mpt->m_datap) != DDI_SUCCESS) ||
13015 (mptsas_check_acc_handle(mpt->m_acc_req_frame_hdl) !=
13016 DDI_SUCCESS) ||
13017 (mptsas_check_acc_handle(mpt->m_acc_req_sense_hdl) !=
13018 DDI_SUCCESS) ||
13019 (mptsas_check_acc_handle(mpt->m_acc_reply_frame_hdl) !=
13020 DDI_SUCCESS) ||
13021 (mptsas_check_acc_handle(mpt->m_acc_free_queue_hdl) !=
13022 DDI_SUCCESS) ||
13023 (mptsas_check_acc_handle(mpt->m_acc_post_queue_hdl) !=
13024 DDI_SUCCESS) ||
13025 (mptsas_check_acc_handle(mpt->m_hshk_acc_hdl) !=
13026 DDI_SUCCESS) ||
13027 (mptsas_check_acc_handle(mpt->m_config_handle) !=
13028 DDI_SUCCESS)) {
13029 ddi_fm_service_impact(mpt->m_dip, DDI_SERVICE_UNAFFECTED);
13030 goto fail;
13031 }
13032
13033 return (DDI_SUCCESS);
13034
13035 fail:
13036 return (DDI_FAILURE);
13037 }
13038
13039 static int
13040 mptsas_get_pci_cap(mptsas_t *mpt)
13041 {
13042 ushort_t caps_ptr, cap, cap_count;
13043
13044 if (mpt->m_config_handle == NULL)
13045 return (FALSE);
13046 /*
13047 * Check if capabilities list is supported and if so,
13048 * get initial capabilities pointer and clear bits 0,1.
13049 */
13050 if (pci_config_get16(mpt->m_config_handle, PCI_CONF_STAT)
13051 & PCI_STAT_CAP) {
13052 caps_ptr = P2ALIGN(pci_config_get8(mpt->m_config_handle,
13053 PCI_CONF_CAP_PTR), 4);
13054 } else {
13055 caps_ptr = PCI_CAP_NEXT_PTR_NULL;
13056 }
13057
13058 /*
13059 * Walk capabilities if supported.
13060 */
13061 for (cap_count = 0; caps_ptr != PCI_CAP_NEXT_PTR_NULL; ) {
13062
13063 /*
13064 * Check that we haven't exceeded the maximum number of
13065 * capabilities and that the pointer is in a valid range.
13066 */
13067 if (++cap_count > 48) {
13068 mptsas_log(mpt, CE_WARN,
13069 "too many device capabilities.\n");
13070 break;
13071 }
13072 if (caps_ptr < 64) {
13073 mptsas_log(mpt, CE_WARN,
13074 "capabilities pointer 0x%x out of range.\n",
13075 caps_ptr);
13076 break;
13077 }
13078
13079 /*
13080 * Get next capability and check that it is valid.
13081 * For now, we only support power management.
13082 */
13083 cap = pci_config_get8(mpt->m_config_handle, caps_ptr);
13084 switch (cap) {
13085 case PCI_CAP_ID_PM:
13086 mptsas_log(mpt, CE_NOTE,
13087 "?mptsas%d supports power management.\n",
13088 mpt->m_instance);
13089 mpt->m_options |= MPTSAS_OPT_PM;
13090
13091 /* Save PMCSR offset */
13092 mpt->m_pmcsr_offset = caps_ptr + PCI_PMCSR;
13093 break;
13094 /*
13095 * The following capabilities are valid. Any others
13096 * will cause a message to be logged.
13097 */
13098 case PCI_CAP_ID_VPD:
13099 case PCI_CAP_ID_MSI:
13100 case PCI_CAP_ID_PCIX:
13101 case PCI_CAP_ID_PCI_E:
13102 case PCI_CAP_ID_MSI_X:
13103 break;
13104 default:
13105 mptsas_log(mpt, CE_NOTE,
13106 "?mptsas%d unrecognized capability "
13107 "0x%x.\n", mpt->m_instance, cap);
13108 break;
13109 }
13110
13111 /*
13112 * Get next capabilities pointer and clear bits 0,1.
13113 */
13114 caps_ptr = P2ALIGN(pci_config_get8(mpt->m_config_handle,
13115 (caps_ptr + PCI_CAP_NEXT_PTR)), 4);
13116 }
13117 return (TRUE);
13118 }
13119
13120 static int
13121 mptsas_init_pm(mptsas_t *mpt)
13122 {
13123 char pmc_name[16];
13124 char *pmc[] = {
13125 NULL,
13126 "0=Off (PCI D3 State)",
13127 "3=On (PCI D0 State)",
13128 NULL
13129 };
13130 uint16_t pmcsr_stat;
13131
13132 if (mptsas_get_pci_cap(mpt) == FALSE) {
13133 return (DDI_FAILURE);
13134 }
13135 /*
13136 * If PCI's capability does not support PM, then don't need
13137 * to registe the pm-components
13138 */
13139 if (!(mpt->m_options & MPTSAS_OPT_PM))
13140 return (DDI_SUCCESS);
13141 /*
13142 * If power management is supported by this chip, create
13143 * pm-components property for the power management framework
13144 */
13145 (void) sprintf(pmc_name, "NAME=mptsas%d", mpt->m_instance);
13146 pmc[0] = pmc_name;
13147 if (ddi_prop_update_string_array(DDI_DEV_T_NONE, mpt->m_dip,
13148 "pm-components", pmc, 3) != DDI_PROP_SUCCESS) {
13149 mpt->m_options &= ~MPTSAS_OPT_PM;
13150 mptsas_log(mpt, CE_WARN,
13151 "mptsas%d: pm-component property creation failed.",
13152 mpt->m_instance);
13153 return (DDI_FAILURE);
13154 }
13155
13156 /*
13157 * Power on device.
13158 */
13159 (void) pm_busy_component(mpt->m_dip, 0);
13160 pmcsr_stat = pci_config_get16(mpt->m_config_handle,
13161 mpt->m_pmcsr_offset);
13162 if ((pmcsr_stat & PCI_PMCSR_STATE_MASK) != PCI_PMCSR_D0) {
13163 mptsas_log(mpt, CE_WARN, "mptsas%d: Power up the device",
13164 mpt->m_instance);
13165 pci_config_put16(mpt->m_config_handle, mpt->m_pmcsr_offset,
13166 PCI_PMCSR_D0);
13167 }
13168 if (pm_power_has_changed(mpt->m_dip, 0, PM_LEVEL_D0) != DDI_SUCCESS) {
13169 mptsas_log(mpt, CE_WARN, "pm_power_has_changed failed");
13170 return (DDI_FAILURE);
13171 }
13172 mpt->m_power_level = PM_LEVEL_D0;
13173 /*
13174 * Set pm idle delay.
13175 */
13176 mpt->m_pm_idle_delay = ddi_prop_get_int(DDI_DEV_T_ANY,
13177 mpt->m_dip, 0, "mptsas-pm-idle-delay", MPTSAS_PM_IDLE_TIMEOUT);
13178
13179 return (DDI_SUCCESS);
13180 }
13181
13182 static int
13183 mptsas_register_intrs(mptsas_t *mpt)
13184 {
13185 dev_info_t *dip;
13186 int intr_types;
13187
13188 dip = mpt->m_dip;
13189
13190 /* Get supported interrupt types */
13191 if (ddi_intr_get_supported_types(dip, &intr_types) != DDI_SUCCESS) {
13192 mptsas_log(mpt, CE_WARN, "ddi_intr_get_supported_types "
13193 "failed\n");
13194 return (FALSE);
13195 }
13196
13197 NDBG6(("ddi_intr_get_supported_types() returned: 0x%x", intr_types));
13198
13199 /*
13200 * Try MSI, but fall back to FIXED
13201 */
13202 if (mptsas_enable_msi && (intr_types & DDI_INTR_TYPE_MSI)) {
13203 if (mptsas_add_intrs(mpt, DDI_INTR_TYPE_MSI) == DDI_SUCCESS) {
13204 NDBG0(("Using MSI interrupt type"));
13205 mpt->m_intr_type = DDI_INTR_TYPE_MSI;
13206 return (TRUE);
13207 }
13208 }
13209 if (intr_types & DDI_INTR_TYPE_FIXED) {
13210 if (mptsas_add_intrs(mpt, DDI_INTR_TYPE_FIXED) == DDI_SUCCESS) {
13211 NDBG0(("Using FIXED interrupt type"));
13212 mpt->m_intr_type = DDI_INTR_TYPE_FIXED;
13213 return (TRUE);
13214 } else {
13215 NDBG0(("FIXED interrupt registration failed"));
13216 return (FALSE);
13217 }
13218 }
13219
13220 return (FALSE);
13221 }
13222
13223 static void
13224 mptsas_unregister_intrs(mptsas_t *mpt)
13225 {
13226 mptsas_rem_intrs(mpt);
13227 }
13228
13229 /*
13230 * mptsas_add_intrs:
13231 *
13232 * Register FIXED or MSI interrupts.
13233 */
13234 static int
13235 mptsas_add_intrs(mptsas_t *mpt, int intr_type)
13236 {
13237 dev_info_t *dip = mpt->m_dip;
13238 int avail, actual, count = 0;
13239 int i, flag, ret;
13240
13241 NDBG6(("mptsas_add_intrs:interrupt type 0x%x", intr_type));
13242
13243 /* Get number of interrupts */
13244 ret = ddi_intr_get_nintrs(dip, intr_type, &count);
13245 if ((ret != DDI_SUCCESS) || (count <= 0)) {
13246 mptsas_log(mpt, CE_WARN, "ddi_intr_get_nintrs() failed, "
13247 "ret %d count %d\n", ret, count);
13248
13249 return (DDI_FAILURE);
13250 }
13251
13252 /* Get number of available interrupts */
13253 ret = ddi_intr_get_navail(dip, intr_type, &avail);
13254 if ((ret != DDI_SUCCESS) || (avail == 0)) {
13255 mptsas_log(mpt, CE_WARN, "ddi_intr_get_navail() failed, "
13256 "ret %d avail %d\n", ret, avail);
13257
13258 return (DDI_FAILURE);
13259 }
13260
13261 if (avail < count) {
13262 mptsas_log(mpt, CE_NOTE, "ddi_intr_get_nvail returned %d, "
13263 "navail() returned %d", count, avail);
13264 }
13265
13266 /* Mpt only have one interrupt routine */
13267 if ((intr_type == DDI_INTR_TYPE_MSI) && (count > 1)) {
13268 count = 1;
13269 }
13270
13271 /* Allocate an array of interrupt handles */
13272 mpt->m_intr_size = count * sizeof (ddi_intr_handle_t);
13273 mpt->m_htable = kmem_alloc(mpt->m_intr_size, KM_SLEEP);
13274
13275 flag = DDI_INTR_ALLOC_NORMAL;
13276
13277 /* call ddi_intr_alloc() */
13278 ret = ddi_intr_alloc(dip, mpt->m_htable, intr_type, 0,
13279 count, &actual, flag);
13280
13281 if ((ret != DDI_SUCCESS) || (actual == 0)) {
13282 mptsas_log(mpt, CE_WARN, "ddi_intr_alloc() failed, ret %d\n",
13283 ret);
13284 kmem_free(mpt->m_htable, mpt->m_intr_size);
13285 return (DDI_FAILURE);
13286 }
13287
13288 /* use interrupt count returned or abort? */
13289 if (actual < count) {
13290 mptsas_log(mpt, CE_NOTE, "Requested: %d, Received: %d\n",
13291 count, actual);
13292 }
13293
13294 mpt->m_intr_cnt = actual;
13295
13296 /*
13297 * Get priority for first msi, assume remaining are all the same
13298 */
13299 if ((ret = ddi_intr_get_pri(mpt->m_htable[0],
13300 &mpt->m_intr_pri)) != DDI_SUCCESS) {
13301 mptsas_log(mpt, CE_WARN, "ddi_intr_get_pri() failed %d\n", ret);
13302
13303 /* Free already allocated intr */
13304 for (i = 0; i < actual; i++) {
13305 (void) ddi_intr_free(mpt->m_htable[i]);
13306 }
13307
13308 kmem_free(mpt->m_htable, mpt->m_intr_size);
13309 return (DDI_FAILURE);
13310 }
13311
13312 /* Test for high level mutex */
13313 if (mpt->m_intr_pri >= ddi_intr_get_hilevel_pri()) {
13314 mptsas_log(mpt, CE_WARN, "mptsas_add_intrs: "
13315 "Hi level interrupt not supported\n");
13316
13317 /* Free already allocated intr */
13318 for (i = 0; i < actual; i++) {
13319 (void) ddi_intr_free(mpt->m_htable[i]);
13320 }
13321
13322 kmem_free(mpt->m_htable, mpt->m_intr_size);
13323 return (DDI_FAILURE);
13324 }
13325
13326 /* Call ddi_intr_add_handler() */
13327 for (i = 0; i < actual; i++) {
13328 if ((ret = ddi_intr_add_handler(mpt->m_htable[i], mptsas_intr,
13329 (caddr_t)mpt, (caddr_t)(uintptr_t)i)) != DDI_SUCCESS) {
13330 mptsas_log(mpt, CE_WARN, "ddi_intr_add_handler() "
13331 "failed %d\n", ret);
13332
13333 /* Free already allocated intr */
13334 for (i = 0; i < actual; i++) {
13335 (void) ddi_intr_free(mpt->m_htable[i]);
13336 }
13337
13338 kmem_free(mpt->m_htable, mpt->m_intr_size);
13339 return (DDI_FAILURE);
13340 }
13341 }
13342
13343 if ((ret = ddi_intr_get_cap(mpt->m_htable[0], &mpt->m_intr_cap))
13344 != DDI_SUCCESS) {
13345 mptsas_log(mpt, CE_WARN, "ddi_intr_get_cap() failed %d\n", ret);
13346
13347 /* Free already allocated intr */
13348 for (i = 0; i < actual; i++) {
13349 (void) ddi_intr_free(mpt->m_htable[i]);
13350 }
13351
13352 kmem_free(mpt->m_htable, mpt->m_intr_size);
13353 return (DDI_FAILURE);
13354 }
13355
13356 /*
13357 * Enable interrupts
13358 */
13359 if (mpt->m_intr_cap & DDI_INTR_FLAG_BLOCK) {
13360 /* Call ddi_intr_block_enable() for MSI interrupts */
13361 (void) ddi_intr_block_enable(mpt->m_htable, mpt->m_intr_cnt);
13362 } else {
13363 /* Call ddi_intr_enable for MSI or FIXED interrupts */
13364 for (i = 0; i < mpt->m_intr_cnt; i++) {
13365 (void) ddi_intr_enable(mpt->m_htable[i]);
13366 }
13367 }
13368 return (DDI_SUCCESS);
13369 }
13370
13371 /*
13372 * mptsas_rem_intrs:
13373 *
13374 * Unregister FIXED or MSI interrupts
13375 */
13376 static void
13377 mptsas_rem_intrs(mptsas_t *mpt)
13378 {
13379 int i;
13380
13381 NDBG6(("mptsas_rem_intrs"));
13382
13383 /* Disable all interrupts */
13384 if (mpt->m_intr_cap & DDI_INTR_FLAG_BLOCK) {
13385 /* Call ddi_intr_block_disable() */
13386 (void) ddi_intr_block_disable(mpt->m_htable, mpt->m_intr_cnt);
13387 } else {
13388 for (i = 0; i < mpt->m_intr_cnt; i++) {
13389 (void) ddi_intr_disable(mpt->m_htable[i]);
13390 }
13391 }
13392
13393 /* Call ddi_intr_remove_handler() */
13394 for (i = 0; i < mpt->m_intr_cnt; i++) {
13395 (void) ddi_intr_remove_handler(mpt->m_htable[i]);
13396 (void) ddi_intr_free(mpt->m_htable[i]);
13397 }
13398
13399 kmem_free(mpt->m_htable, mpt->m_intr_size);
13400 }
13401
13402 /*
13403 * The IO fault service error handling callback function
13404 */
13405 /*ARGSUSED*/
13406 static int
13407 mptsas_fm_error_cb(dev_info_t *dip, ddi_fm_error_t *err, const void *impl_data)
13408 {
13409 /*
13410 * as the driver can always deal with an error in any dma or
13411 * access handle, we can just return the fme_status value.
13412 */
13413 pci_ereport_post(dip, err, NULL);
13414 return (err->fme_status);
13415 }
13416
13417 /*
13418 * mptsas_fm_init - initialize fma capabilities and register with IO
13419 * fault services.
13420 */
13421 static void
13422 mptsas_fm_init(mptsas_t *mpt)
13423 {
13424 /*
13425 * Need to change iblock to priority for new MSI intr
13426 */
13427 ddi_iblock_cookie_t fm_ibc;
13428
13429 /* Only register with IO Fault Services if we have some capability */
13430 if (mpt->m_fm_capabilities) {
13431 /* Adjust access and dma attributes for FMA */
13432 mpt->m_reg_acc_attr.devacc_attr_access = DDI_FLAGERR_ACC;
13433 mpt->m_msg_dma_attr.dma_attr_flags |= DDI_DMA_FLAGERR;
13434 mpt->m_io_dma_attr.dma_attr_flags |= DDI_DMA_FLAGERR;
13435
13436 /*
13437 * Register capabilities with IO Fault Services.
13438 * mpt->m_fm_capabilities will be updated to indicate
13439 * capabilities actually supported (not requested.)
13440 */
13441 ddi_fm_init(mpt->m_dip, &mpt->m_fm_capabilities, &fm_ibc);
13442
13443 /*
13444 * Initialize pci ereport capabilities if ereport
13445 * capable (should always be.)
13446 */
13447 if (DDI_FM_EREPORT_CAP(mpt->m_fm_capabilities) ||
13448 DDI_FM_ERRCB_CAP(mpt->m_fm_capabilities)) {
13449 pci_ereport_setup(mpt->m_dip);
13450 }
13451
13452 /*
13453 * Register error callback if error callback capable.
13454 */
13455 if (DDI_FM_ERRCB_CAP(mpt->m_fm_capabilities)) {
13456 ddi_fm_handler_register(mpt->m_dip,
13457 mptsas_fm_error_cb, (void *) mpt);
13458 }
13459 }
13460 }
13461
13462 /*
13463 * mptsas_fm_fini - Releases fma capabilities and un-registers with IO
13464 * fault services.
13465 *
13466 */
13467 static void
13468 mptsas_fm_fini(mptsas_t *mpt)
13469 {
13470 /* Only unregister FMA capabilities if registered */
13471 if (mpt->m_fm_capabilities) {
13472
13473 /*
13474 * Un-register error callback if error callback capable.
13475 */
13476
13477 if (DDI_FM_ERRCB_CAP(mpt->m_fm_capabilities)) {
13478 ddi_fm_handler_unregister(mpt->m_dip);
13479 }
13480
13481 /*
13482 * Release any resources allocated by pci_ereport_setup()
13483 */
13484
13485 if (DDI_FM_EREPORT_CAP(mpt->m_fm_capabilities) ||
13486 DDI_FM_ERRCB_CAP(mpt->m_fm_capabilities)) {
13487 pci_ereport_teardown(mpt->m_dip);
13488 }
13489
13490 /* Unregister from IO Fault Services */
13491 ddi_fm_fini(mpt->m_dip);
13492
13493 /* Adjust access and dma attributes for FMA */
13494 mpt->m_reg_acc_attr.devacc_attr_access = DDI_DEFAULT_ACC;
13495 mpt->m_msg_dma_attr.dma_attr_flags &= ~DDI_DMA_FLAGERR;
13496 mpt->m_io_dma_attr.dma_attr_flags &= ~DDI_DMA_FLAGERR;
13497
13498 }
13499 }
13500
13501 int
13502 mptsas_check_acc_handle(ddi_acc_handle_t handle)
13503 {
13504 ddi_fm_error_t de;
13505
13506 if (handle == NULL)
13507 return (DDI_FAILURE);
13508 ddi_fm_acc_err_get(handle, &de, DDI_FME_VER0);
13509 return (de.fme_status);
13510 }
13511
13512 int
13513 mptsas_check_dma_handle(ddi_dma_handle_t handle)
13514 {
13515 ddi_fm_error_t de;
13516
13517 if (handle == NULL)
13518 return (DDI_FAILURE);
13519 ddi_fm_dma_err_get(handle, &de, DDI_FME_VER0);
13520 return (de.fme_status);
13521 }
13522
13523 void
13524 mptsas_fm_ereport(mptsas_t *mpt, char *detail)
13525 {
13526 uint64_t ena;
13527 char buf[FM_MAX_CLASS];
13528
13529 (void) snprintf(buf, FM_MAX_CLASS, "%s.%s", DDI_FM_DEVICE, detail);
13530 ena = fm_ena_generate(0, FM_ENA_FMT1);
13531 if (DDI_FM_EREPORT_CAP(mpt->m_fm_capabilities)) {
13532 ddi_fm_ereport_post(mpt->m_dip, buf, ena, DDI_NOSLEEP,
13533 FM_VERSION, DATA_TYPE_UINT8, FM_EREPORT_VERS0, NULL);
13534 }
13535 }
13536
13537 static int
13538 mptsas_get_target_device_info(mptsas_t *mpt, uint32_t page_address,
13539 uint16_t *dev_handle, mptsas_target_t **pptgt)
13540 {
13541 int rval;
13542 uint32_t dev_info;
13543 uint64_t sas_wwn;
13544 mptsas_phymask_t phymask;
13545 uint8_t physport, phynum, config, disk;
13546 uint64_t devicename;
13547 uint16_t pdev_hdl;
13548 mptsas_target_t *tmp_tgt = NULL;
13549 uint16_t bay_num, enclosure, io_flags;
13550
13551 ASSERT(*pptgt == NULL);
13552
13553 rval = mptsas_get_sas_device_page0(mpt, page_address, dev_handle,
13554 &sas_wwn, &dev_info, &physport, &phynum, &pdev_hdl,
13555 &bay_num, &enclosure, &io_flags);
13556 if (rval != DDI_SUCCESS) {
13557 rval = DEV_INFO_FAIL_PAGE0;
13558 return (rval);
13559 }
13560
13561 if ((dev_info & (MPI2_SAS_DEVICE_INFO_SSP_TARGET |
13562 MPI2_SAS_DEVICE_INFO_SATA_DEVICE |
13563 MPI2_SAS_DEVICE_INFO_ATAPI_DEVICE)) == NULL) {
13564 rval = DEV_INFO_WRONG_DEVICE_TYPE;
13565 return (rval);
13566 }
13567
13568 /*
13569 * Check if the dev handle is for a Phys Disk. If so, set return value
13570 * and exit. Don't add Phys Disks to hash.
13571 */
13572 for (config = 0; config < mpt->m_num_raid_configs; config++) {
13573 for (disk = 0; disk < MPTSAS_MAX_DISKS_IN_CONFIG; disk++) {
13574 if (*dev_handle == mpt->m_raidconfig[config].
13575 m_physdisk_devhdl[disk]) {
13576 rval = DEV_INFO_PHYS_DISK;
13577 return (rval);
13578 }
13579 }
13580 }
13581
13582 /*
13583 * Get SATA Device Name from SAS device page0 for
13584 * sata device, if device name doesn't exist, set mta_wwn to
13585 * 0 for direct attached SATA. For the device behind the expander
13586 * we still can use STP address assigned by expander.
13587 */
13588 if (dev_info & (MPI2_SAS_DEVICE_INFO_SATA_DEVICE |
13589 MPI2_SAS_DEVICE_INFO_ATAPI_DEVICE)) {
13590 /* alloc a temporary target to send the cmd to */
13591 tmp_tgt = mptsas_tgt_alloc(mpt->m_tmp_targets, *dev_handle,
13592 0, dev_info, 0, 0);
13593 mutex_exit(&mpt->m_mutex);
13594
13595 devicename = mptsas_get_sata_guid(mpt, tmp_tgt, 0);
13596
13597 if (devicename == -1) {
13598 mutex_enter(&mpt->m_mutex);
13599 refhash_remove(mpt->m_tmp_targets, tmp_tgt);
13600 rval = DEV_INFO_FAIL_GUID;
13601 return (rval);
13602 }
13603
13604 if (devicename != 0 && (((devicename >> 56) & 0xf0) == 0x50)) {
13605 sas_wwn = devicename;
13606 } else if (dev_info & MPI2_SAS_DEVICE_INFO_DIRECT_ATTACH) {
13607 sas_wwn = 0;
13608 }
13609
13610 mutex_enter(&mpt->m_mutex);
13611 refhash_remove(mpt->m_tmp_targets, tmp_tgt);
13612 }
13613
13614 phymask = mptsas_physport_to_phymask(mpt, physport);
13615 *pptgt = mptsas_tgt_alloc(mpt->m_targets, *dev_handle, sas_wwn,
13616 dev_info, phymask, phynum);
13617 if (*pptgt == NULL) {
13618 mptsas_log(mpt, CE_WARN, "Failed to allocated target"
13619 "structure!");
13620 rval = DEV_INFO_FAIL_ALLOC;
13621 return (rval);
13622 }
13623 (*pptgt)->m_io_flags = io_flags;
13624 (*pptgt)->m_enclosure = enclosure;
13625 (*pptgt)->m_slot_num = bay_num;
13626 return (DEV_INFO_SUCCESS);
13627 }
13628
13629 uint64_t
13630 mptsas_get_sata_guid(mptsas_t *mpt, mptsas_target_t *ptgt, int lun)
13631 {
13632 uint64_t sata_guid = 0, *pwwn = NULL;
13633 int target = ptgt->m_devhdl;
13634 uchar_t *inq83 = NULL;
13635 int inq83_len = 0xFF;
13636 uchar_t *dblk = NULL;
13637 int inq83_retry = 3;
13638 int rval = DDI_FAILURE;
13639
13640 inq83 = kmem_zalloc(inq83_len, KM_SLEEP);
13641
13642 inq83_retry:
13643 rval = mptsas_inquiry(mpt, ptgt, lun, 0x83, inq83,
13644 inq83_len, NULL, 1);
13645 if (rval != DDI_SUCCESS) {
13646 mptsas_log(mpt, CE_WARN, "!mptsas request inquiry page "
13647 "0x83 for target:%x, lun:%x failed!", target, lun);
13648 sata_guid = -1;
13649 goto out;
13650 }
13651 /* According to SAT2, the first descriptor is logic unit name */
13652 dblk = &inq83[4];
13653 if ((dblk[1] & 0x30) != 0) {
13654 mptsas_log(mpt, CE_WARN, "!Descriptor is not lun associated.");
13655 goto out;
13656 }
13657 pwwn = (uint64_t *)(void *)(&dblk[4]);
13658 if ((dblk[4] & 0xf0) == 0x50) {
13659 sata_guid = BE_64(*pwwn);
13660 goto out;
13661 } else if (dblk[4] == 'A') {
13662 NDBG20(("SATA drive has no NAA format GUID."));
13663 goto out;
13664 } else {
13665 /* The data is not ready, wait and retry */
13666 inq83_retry--;
13667 if (inq83_retry <= 0) {
13668 goto out;
13669 }
13670 NDBG20(("The GUID is not ready, retry..."));
13671 delay(1 * drv_usectohz(1000000));
13672 goto inq83_retry;
13673 }
13674 out:
13675 kmem_free(inq83, inq83_len);
13676 return (sata_guid);
13677 }
13678
13679 static int
13680 mptsas_inquiry(mptsas_t *mpt, mptsas_target_t *ptgt, int lun, uchar_t page,
13681 unsigned char *buf, int len, int *reallen, uchar_t evpd)
13682 {
13683 uchar_t cdb[CDB_GROUP0];
13684 struct scsi_address ap;
13685 struct buf *data_bp = NULL;
13686 int resid = 0;
13687 int ret = DDI_FAILURE;
13688
13689 ASSERT(len <= 0xffff);
13690
13691 ap.a_target = MPTSAS_INVALID_DEVHDL;
13692 ap.a_lun = (uchar_t)(lun);
13693 ap.a_hba_tran = mpt->m_tran;
13694
13695 data_bp = scsi_alloc_consistent_buf(&ap,
13696 (struct buf *)NULL, len, B_READ, NULL_FUNC, NULL);
13697 if (data_bp == NULL) {
13698 return (ret);
13699 }
13700 bzero(cdb, CDB_GROUP0);
13701 cdb[0] = SCMD_INQUIRY;
13702 cdb[1] = evpd;
13703 cdb[2] = page;
13704 cdb[3] = (len & 0xff00) >> 8;
13705 cdb[4] = (len & 0x00ff);
13706 cdb[5] = 0;
13707
13708 ret = mptsas_send_scsi_cmd(mpt, &ap, ptgt, &cdb[0], CDB_GROUP0, data_bp,
13709 &resid);
13710 if (ret == DDI_SUCCESS) {
13711 if (reallen) {
13712 *reallen = len - resid;
13713 }
13714 bcopy((caddr_t)data_bp->b_un.b_addr, buf, len);
13715 }
13716 if (data_bp) {
13717 scsi_free_consistent_buf(data_bp);
13718 }
13719 return (ret);
13720 }
13721
13722 static int
13723 mptsas_send_scsi_cmd(mptsas_t *mpt, struct scsi_address *ap,
13724 mptsas_target_t *ptgt, uchar_t *cdb, int cdblen, struct buf *data_bp,
13725 int *resid)
13726 {
13727 struct scsi_pkt *pktp = NULL;
13728 scsi_hba_tran_t *tran_clone = NULL;
13729 mptsas_tgt_private_t *tgt_private = NULL;
13730 int ret = DDI_FAILURE;
13731
13732 /*
13733 * scsi_hba_tran_t->tran_tgt_private is used to pass the address
13734 * information to scsi_init_pkt, allocate a scsi_hba_tran structure
13735 * to simulate the cmds from sd
13736 */
13737 tran_clone = kmem_alloc(
13738 sizeof (scsi_hba_tran_t), KM_SLEEP);
13739 if (tran_clone == NULL) {
13740 goto out;
13741 }
13742 bcopy((caddr_t)mpt->m_tran,
13743 (caddr_t)tran_clone, sizeof (scsi_hba_tran_t));
13744 tgt_private = kmem_alloc(
13745 sizeof (mptsas_tgt_private_t), KM_SLEEP);
13746 if (tgt_private == NULL) {
13747 goto out;
13748 }
13749 tgt_private->t_lun = ap->a_lun;
13750 tgt_private->t_private = ptgt;
13751 tran_clone->tran_tgt_private = tgt_private;
13752 ap->a_hba_tran = tran_clone;
13753
13754 pktp = scsi_init_pkt(ap, (struct scsi_pkt *)NULL,
13755 data_bp, cdblen, sizeof (struct scsi_arq_status),
13756 0, PKT_CONSISTENT, NULL, NULL);
13757 if (pktp == NULL) {
13758 goto out;
13759 }
13760 bcopy(cdb, pktp->pkt_cdbp, cdblen);
13761 pktp->pkt_flags = FLAG_NOPARITY;
13762 if (scsi_poll(pktp) < 0) {
13763 goto out;
13764 }
13765 if (((struct scsi_status *)pktp->pkt_scbp)->sts_chk) {
13766 goto out;
13767 }
13768 if (resid != NULL) {
13769 *resid = pktp->pkt_resid;
13770 }
13771
13772 ret = DDI_SUCCESS;
13773 out:
13774 if (pktp) {
13775 scsi_destroy_pkt(pktp);
13776 }
13777 if (tran_clone) {
13778 kmem_free(tran_clone, sizeof (scsi_hba_tran_t));
13779 }
13780 if (tgt_private) {
13781 kmem_free(tgt_private, sizeof (mptsas_tgt_private_t));
13782 }
13783 return (ret);
13784 }
13785 static int
13786 mptsas_parse_address(char *name, uint64_t *wwid, uint8_t *phy, int *lun)
13787 {
13788 char *cp = NULL;
13789 char *ptr = NULL;
13790 size_t s = 0;
13791 char *wwid_str = NULL;
13792 char *lun_str = NULL;
13793 long lunnum;
13794 long phyid = -1;
13795 int rc = DDI_FAILURE;
13796
13797 ptr = name;
13798 ASSERT(ptr[0] == 'w' || ptr[0] == 'p');
13799 ptr++;
13800 if ((cp = strchr(ptr, ',')) == NULL) {
13801 return (DDI_FAILURE);
13802 }
13803
13804 wwid_str = kmem_zalloc(SCSI_MAXNAMELEN, KM_SLEEP);
13805 s = (uintptr_t)cp - (uintptr_t)ptr;
13806
13807 bcopy(ptr, wwid_str, s);
13808 wwid_str[s] = '\0';
13809
13810 ptr = ++cp;
13811
13812 if ((cp = strchr(ptr, '\0')) == NULL) {
13813 goto out;
13814 }
13815 lun_str = kmem_zalloc(SCSI_MAXNAMELEN, KM_SLEEP);
13816 s = (uintptr_t)cp - (uintptr_t)ptr;
13817
13818 bcopy(ptr, lun_str, s);
13819 lun_str[s] = '\0';
13820
13821 if (name[0] == 'p') {
13822 rc = ddi_strtol(wwid_str, NULL, 0x10, &phyid);
13823 } else {
13824 rc = scsi_wwnstr_to_wwn(wwid_str, wwid);
13825 }
13826 if (rc != DDI_SUCCESS)
13827 goto out;
13828
13829 if (phyid != -1) {
13830 ASSERT(phyid < MPTSAS_MAX_PHYS);
13831 *phy = (uint8_t)phyid;
13832 }
13833 rc = ddi_strtol(lun_str, NULL, 0x10, &lunnum);
13834 if (rc != 0)
13835 goto out;
13836
13837 *lun = (int)lunnum;
13838 rc = DDI_SUCCESS;
13839 out:
13840 if (wwid_str)
13841 kmem_free(wwid_str, SCSI_MAXNAMELEN);
13842 if (lun_str)
13843 kmem_free(lun_str, SCSI_MAXNAMELEN);
13844
13845 return (rc);
13846 }
13847
13848 /*
13849 * mptsas_parse_smp_name() is to parse sas wwn string
13850 * which format is "wWWN"
13851 */
13852 static int
13853 mptsas_parse_smp_name(char *name, uint64_t *wwn)
13854 {
13855 char *ptr = name;
13856
13857 if (*ptr != 'w') {
13858 return (DDI_FAILURE);
13859 }
13860
13861 ptr++;
13862 if (scsi_wwnstr_to_wwn(ptr, wwn)) {
13863 return (DDI_FAILURE);
13864 }
13865 return (DDI_SUCCESS);
13866 }
13867
13868 static int
13869 mptsas_bus_config(dev_info_t *pdip, uint_t flag,
13870 ddi_bus_config_op_t op, void *arg, dev_info_t **childp)
13871 {
13872 int ret = NDI_FAILURE;
13873 int circ = 0;
13874 int circ1 = 0;
13875 mptsas_t *mpt;
13876 char *ptr = NULL;
13877 char *devnm = NULL;
13878 uint64_t wwid = 0;
13879 uint8_t phy = 0xFF;
13880 int lun = 0;
13881 uint_t mflags = flag;
13882 int bconfig = TRUE;
13883
13884 if (scsi_hba_iport_unit_address(pdip) == 0) {
13885 return (DDI_FAILURE);
13886 }
13887
13888 mpt = DIP2MPT(pdip);
13889 if (!mpt) {
13890 return (DDI_FAILURE);
13891 }
13892 /*
13893 * Hold the nexus across the bus_config
13894 */
13895 ndi_devi_enter(scsi_vhci_dip, &circ);
13896 ndi_devi_enter(pdip, &circ1);
13897 switch (op) {
13898 case BUS_CONFIG_ONE:
13899 /* parse wwid/target name out of name given */
13900 if ((ptr = strchr((char *)arg, '@')) == NULL) {
13901 ret = NDI_FAILURE;
13902 break;
13903 }
13904 ptr++;
13905 if (strncmp((char *)arg, "smp", 3) == 0) {
13906 /*
13907 * This is a SMP target device
13908 */
13909 ret = mptsas_parse_smp_name(ptr, &wwid);
13910 if (ret != DDI_SUCCESS) {
13911 ret = NDI_FAILURE;
13912 break;
13913 }
13914 ret = mptsas_config_smp(pdip, wwid, childp);
13915 } else if ((ptr[0] == 'w') || (ptr[0] == 'p')) {
13916 /*
13917 * OBP could pass down a non-canonical form
13918 * bootpath without LUN part when LUN is 0.
13919 * So driver need adjust the string.
13920 */
13921 if (strchr(ptr, ',') == NULL) {
13922 devnm = kmem_zalloc(SCSI_MAXNAMELEN, KM_SLEEP);
13923 (void) sprintf(devnm, "%s,0", (char *)arg);
13924 ptr = strchr(devnm, '@');
13925 ptr++;
13926 }
13927
13928 /*
13929 * The device path is wWWID format and the device
13930 * is not SMP target device.
13931 */
13932 ret = mptsas_parse_address(ptr, &wwid, &phy, &lun);
13933 if (ret != DDI_SUCCESS) {
13934 ret = NDI_FAILURE;
13935 break;
13936 }
13937 *childp = NULL;
13938 if (ptr[0] == 'w') {
13939 ret = mptsas_config_one_addr(pdip, wwid,
13940 lun, childp);
13941 } else if (ptr[0] == 'p') {
13942 ret = mptsas_config_one_phy(pdip, phy, lun,
13943 childp);
13944 }
13945
13946 /*
13947 * If this is CD/DVD device in OBP path, the
13948 * ndi_busop_bus_config can be skipped as config one
13949 * operation is done above.
13950 */
13951 if ((ret == NDI_SUCCESS) && (*childp != NULL) &&
13952 (strcmp(ddi_node_name(*childp), "cdrom") == 0) &&
13953 (strncmp((char *)arg, "disk", 4) == 0)) {
13954 bconfig = FALSE;
13955 ndi_hold_devi(*childp);
13956 }
13957 } else {
13958 ret = NDI_FAILURE;
13959 break;
13960 }
13961
13962 /*
13963 * DDI group instructed us to use this flag.
13964 */
13965 mflags |= NDI_MDI_FALLBACK;
13966 break;
13967 case BUS_CONFIG_DRIVER:
13968 case BUS_CONFIG_ALL:
13969 mptsas_config_all(pdip);
13970 ret = NDI_SUCCESS;
13971 break;
13972 }
13973
13974 if ((ret == NDI_SUCCESS) && bconfig) {
13975 ret = ndi_busop_bus_config(pdip, mflags, op,
13976 (devnm == NULL) ? arg : devnm, childp, 0);
13977 }
13978
13979 ndi_devi_exit(pdip, circ1);
13980 ndi_devi_exit(scsi_vhci_dip, circ);
13981 if (devnm != NULL)
13982 kmem_free(devnm, SCSI_MAXNAMELEN);
13983 return (ret);
13984 }
13985
13986 static int
13987 mptsas_probe_lun(dev_info_t *pdip, int lun, dev_info_t **dip,
13988 mptsas_target_t *ptgt)
13989 {
13990 int rval = DDI_FAILURE;
13991 struct scsi_inquiry *sd_inq = NULL;
13992 mptsas_t *mpt = DIP2MPT(pdip);
13993
13994 sd_inq = (struct scsi_inquiry *)kmem_alloc(SUN_INQSIZE, KM_SLEEP);
13995
13996 rval = mptsas_inquiry(mpt, ptgt, lun, 0, (uchar_t *)sd_inq,
13997 SUN_INQSIZE, 0, (uchar_t)0);
13998
13999 if ((rval == DDI_SUCCESS) && MPTSAS_VALID_LUN(sd_inq)) {
14000 rval = mptsas_create_lun(pdip, sd_inq, dip, ptgt, lun);
14001 } else {
14002 rval = DDI_FAILURE;
14003 }
14004
14005 kmem_free(sd_inq, SUN_INQSIZE);
14006 return (rval);
14007 }
14008
14009 static int
14010 mptsas_config_one_addr(dev_info_t *pdip, uint64_t sasaddr, int lun,
14011 dev_info_t **lundip)
14012 {
14013 int rval;
14014 mptsas_t *mpt = DIP2MPT(pdip);
14015 int phymask;
14016 mptsas_target_t *ptgt = NULL;
14017
14018 /*
14019 * Get the physical port associated to the iport
14020 */
14021 phymask = ddi_prop_get_int(DDI_DEV_T_ANY, pdip, 0,
14022 "phymask", 0);
14023
14024 ptgt = mptsas_wwid_to_ptgt(mpt, phymask, sasaddr);
14025 if (ptgt == NULL) {
14026 /*
14027 * didn't match any device by searching
14028 */
14029 return (DDI_FAILURE);
14030 }
14031 /*
14032 * If the LUN already exists and the status is online,
14033 * we just return the pointer to dev_info_t directly.
14034 * For the mdi_pathinfo node, we'll handle it in
14035 * mptsas_create_virt_lun()
14036 * TODO should be also in mptsas_handle_dr
14037 */
14038
14039 *lundip = mptsas_find_child_addr(pdip, sasaddr, lun);
14040 if (*lundip != NULL) {
14041 /*
14042 * TODO Another senario is, we hotplug the same disk
14043 * on the same slot, the devhdl changed, is this
14044 * possible?
14045 * tgt_private->t_private != ptgt
14046 */
14047 if (sasaddr != ptgt->m_addr.mta_wwn) {
14048 /*
14049 * The device has changed although the devhdl is the
14050 * same (Enclosure mapping mode, change drive on the
14051 * same slot)
14052 */
14053 return (DDI_FAILURE);
14054 }
14055 return (DDI_SUCCESS);
14056 }
14057
14058 if (phymask == 0) {
14059 /*
14060 * Configure IR volume
14061 */
14062 rval = mptsas_config_raid(pdip, ptgt->m_devhdl, lundip);
14063 return (rval);
14064 }
14065 rval = mptsas_probe_lun(pdip, lun, lundip, ptgt);
14066
14067 return (rval);
14068 }
14069
14070 static int
14071 mptsas_config_one_phy(dev_info_t *pdip, uint8_t phy, int lun,
14072 dev_info_t **lundip)
14073 {
14074 int rval;
14075 mptsas_t *mpt = DIP2MPT(pdip);
14076 mptsas_phymask_t phymask;
14077 mptsas_target_t *ptgt = NULL;
14078
14079 /*
14080 * Get the physical port associated to the iport
14081 */
14082 phymask = (mptsas_phymask_t)ddi_prop_get_int(DDI_DEV_T_ANY, pdip, 0,
14083 "phymask", 0);
14084
14085 ptgt = mptsas_phy_to_tgt(mpt, phymask, phy);
14086 if (ptgt == NULL) {
14087 /*
14088 * didn't match any device by searching
14089 */
14090 return (DDI_FAILURE);
14091 }
14092
14093 /*
14094 * If the LUN already exists and the status is online,
14095 * we just return the pointer to dev_info_t directly.
14096 * For the mdi_pathinfo node, we'll handle it in
14097 * mptsas_create_virt_lun().
14098 */
14099
14100 *lundip = mptsas_find_child_phy(pdip, phy);
14101 if (*lundip != NULL) {
14102 return (DDI_SUCCESS);
14103 }
14104
14105 rval = mptsas_probe_lun(pdip, lun, lundip, ptgt);
14106
14107 return (rval);
14108 }
14109
14110 static int
14111 mptsas_retrieve_lundata(int lun_cnt, uint8_t *buf, uint16_t *lun_num,
14112 uint8_t *lun_addr_type)
14113 {
14114 uint32_t lun_idx = 0;
14115
14116 ASSERT(lun_num != NULL);
14117 ASSERT(lun_addr_type != NULL);
14118
14119 lun_idx = (lun_cnt + 1) * MPTSAS_SCSI_REPORTLUNS_ADDRESS_SIZE;
14120 /* determine report luns addressing type */
14121 switch (buf[lun_idx] & MPTSAS_SCSI_REPORTLUNS_ADDRESS_MASK) {
14122 /*
14123 * Vendors in the field have been found to be concatenating
14124 * bus/target/lun to equal the complete lun value instead
14125 * of switching to flat space addressing
14126 */
14127 /* 00b - peripheral device addressing method */
14128 case MPTSAS_SCSI_REPORTLUNS_ADDRESS_PERIPHERAL:
14129 /* FALLTHRU */
14130 /* 10b - logical unit addressing method */
14131 case MPTSAS_SCSI_REPORTLUNS_ADDRESS_LOGICAL_UNIT:
14132 /* FALLTHRU */
14133 /* 01b - flat space addressing method */
14134 case MPTSAS_SCSI_REPORTLUNS_ADDRESS_FLAT_SPACE:
14135 /* byte0 bit0-5=msb lun byte1 bit0-7=lsb lun */
14136 *lun_addr_type = (buf[lun_idx] &
14137 MPTSAS_SCSI_REPORTLUNS_ADDRESS_MASK) >> 6;
14138 *lun_num = (buf[lun_idx] & 0x3F) << 8;
14139 *lun_num |= buf[lun_idx + 1];
14140 return (DDI_SUCCESS);
14141 default:
14142 return (DDI_FAILURE);
14143 }
14144 }
14145
14146 static int
14147 mptsas_config_luns(dev_info_t *pdip, mptsas_target_t *ptgt)
14148 {
14149 struct buf *repluns_bp = NULL;
14150 struct scsi_address ap;
14151 uchar_t cdb[CDB_GROUP5];
14152 int ret = DDI_FAILURE;
14153 int retry = 0;
14154 int lun_list_len = 0;
14155 uint16_t lun_num = 0;
14156 uint8_t lun_addr_type = 0;
14157 uint32_t lun_cnt = 0;
14158 uint32_t lun_total = 0;
14159 dev_info_t *cdip = NULL;
14160 uint16_t *saved_repluns = NULL;
14161 char *buffer = NULL;
14162 int buf_len = 128;
14163 mptsas_t *mpt = DIP2MPT(pdip);
14164 uint64_t sas_wwn = 0;
14165 uint8_t phy = 0xFF;
14166 uint32_t dev_info = 0;
14167
14168 mutex_enter(&mpt->m_mutex);
14169 sas_wwn = ptgt->m_addr.mta_wwn;
14170 phy = ptgt->m_phynum;
14171 dev_info = ptgt->m_deviceinfo;
14172 mutex_exit(&mpt->m_mutex);
14173
14174 if (sas_wwn == 0) {
14175 /*
14176 * It's a SATA without Device Name
14177 * So don't try multi-LUNs
14178 */
14179 if (mptsas_find_child_phy(pdip, phy)) {
14180 return (DDI_SUCCESS);
14181 } else {
14182 /*
14183 * need configure and create node
14184 */
14185 return (DDI_FAILURE);
14186 }
14187 }
14188
14189 /*
14190 * WWN (SAS address or Device Name exist)
14191 */
14192 if (dev_info & (MPI2_SAS_DEVICE_INFO_SATA_DEVICE |
14193 MPI2_SAS_DEVICE_INFO_ATAPI_DEVICE)) {
14194 /*
14195 * SATA device with Device Name
14196 * So don't try multi-LUNs
14197 */
14198 if (mptsas_find_child_addr(pdip, sas_wwn, 0)) {
14199 return (DDI_SUCCESS);
14200 } else {
14201 return (DDI_FAILURE);
14202 }
14203 }
14204
14205 do {
14206 ap.a_target = MPTSAS_INVALID_DEVHDL;
14207 ap.a_lun = 0;
14208 ap.a_hba_tran = mpt->m_tran;
14209 repluns_bp = scsi_alloc_consistent_buf(&ap,
14210 (struct buf *)NULL, buf_len, B_READ, NULL_FUNC, NULL);
14211 if (repluns_bp == NULL) {
14212 retry++;
14213 continue;
14214 }
14215 bzero(cdb, CDB_GROUP5);
14216 cdb[0] = SCMD_REPORT_LUNS;
14217 cdb[6] = (buf_len & 0xff000000) >> 24;
14218 cdb[7] = (buf_len & 0x00ff0000) >> 16;
14219 cdb[8] = (buf_len & 0x0000ff00) >> 8;
14220 cdb[9] = (buf_len & 0x000000ff);
14221
14222 ret = mptsas_send_scsi_cmd(mpt, &ap, ptgt, &cdb[0], CDB_GROUP5,
14223 repluns_bp, NULL);
14224 if (ret != DDI_SUCCESS) {
14225 scsi_free_consistent_buf(repluns_bp);
14226 retry++;
14227 continue;
14228 }
14229 lun_list_len = BE_32(*(int *)((void *)(
14230 repluns_bp->b_un.b_addr)));
14231 if (buf_len >= lun_list_len + 8) {
14232 ret = DDI_SUCCESS;
14233 break;
14234 }
14235 scsi_free_consistent_buf(repluns_bp);
14236 buf_len = lun_list_len + 8;
14237
14238 } while (retry < 3);
14239
14240 if (ret != DDI_SUCCESS)
14241 return (ret);
14242 buffer = (char *)repluns_bp->b_un.b_addr;
14243 /*
14244 * find out the number of luns returned by the SCSI ReportLun call
14245 * and allocate buffer space
14246 */
14247 lun_total = lun_list_len / MPTSAS_SCSI_REPORTLUNS_ADDRESS_SIZE;
14248 saved_repluns = kmem_zalloc(sizeof (uint16_t) * lun_total, KM_SLEEP);
14249 if (saved_repluns == NULL) {
14250 scsi_free_consistent_buf(repluns_bp);
14251 return (DDI_FAILURE);
14252 }
14253 for (lun_cnt = 0; lun_cnt < lun_total; lun_cnt++) {
14254 if (mptsas_retrieve_lundata(lun_cnt, (uint8_t *)(buffer),
14255 &lun_num, &lun_addr_type) != DDI_SUCCESS) {
14256 continue;
14257 }
14258 saved_repluns[lun_cnt] = lun_num;
14259 if (cdip = mptsas_find_child_addr(pdip, sas_wwn, lun_num))
14260 ret = DDI_SUCCESS;
14261 else
14262 ret = mptsas_probe_lun(pdip, lun_num, &cdip,
14263 ptgt);
14264 if ((ret == DDI_SUCCESS) && (cdip != NULL)) {
14265 (void) ndi_prop_remove(DDI_DEV_T_NONE, cdip,
14266 MPTSAS_DEV_GONE);
14267 }
14268 }
14269 mptsas_offline_missed_luns(pdip, saved_repluns, lun_total, ptgt);
14270 kmem_free(saved_repluns, sizeof (uint16_t) * lun_total);
14271 scsi_free_consistent_buf(repluns_bp);
14272 return (DDI_SUCCESS);
14273 }
14274
14275 static int
14276 mptsas_config_raid(dev_info_t *pdip, uint16_t target, dev_info_t **dip)
14277 {
14278 int rval = DDI_FAILURE;
14279 struct scsi_inquiry *sd_inq = NULL;
14280 mptsas_t *mpt = DIP2MPT(pdip);
14281 mptsas_target_t *ptgt = NULL;
14282
14283 mutex_enter(&mpt->m_mutex);
14284 ptgt = refhash_linear_search(mpt->m_targets,
14285 mptsas_target_eval_devhdl, &target);
14286 mutex_exit(&mpt->m_mutex);
14287 if (ptgt == NULL) {
14288 mptsas_log(mpt, CE_WARN, "Volume with VolDevHandle of 0x%x "
14289 "not found.", target);
14290 return (rval);
14291 }
14292
14293 sd_inq = (struct scsi_inquiry *)kmem_alloc(SUN_INQSIZE, KM_SLEEP);
14294 rval = mptsas_inquiry(mpt, ptgt, 0, 0, (uchar_t *)sd_inq,
14295 SUN_INQSIZE, 0, (uchar_t)0);
14296
14297 if ((rval == DDI_SUCCESS) && MPTSAS_VALID_LUN(sd_inq)) {
14298 rval = mptsas_create_phys_lun(pdip, sd_inq, NULL, dip, ptgt,
14299 0);
14300 } else {
14301 rval = DDI_FAILURE;
14302 }
14303
14304 kmem_free(sd_inq, SUN_INQSIZE);
14305 return (rval);
14306 }
14307
14308 /*
14309 * configure all RAID volumes for virtual iport
14310 */
14311 static void
14312 mptsas_config_all_viport(dev_info_t *pdip)
14313 {
14314 mptsas_t *mpt = DIP2MPT(pdip);
14315 int config, vol;
14316 int target;
14317 dev_info_t *lundip = NULL;
14318
14319 /*
14320 * Get latest RAID info and search for any Volume DevHandles. If any
14321 * are found, configure the volume.
14322 */
14323 mutex_enter(&mpt->m_mutex);
14324 for (config = 0; config < mpt->m_num_raid_configs; config++) {
14325 for (vol = 0; vol < MPTSAS_MAX_RAIDVOLS; vol++) {
14326 if (mpt->m_raidconfig[config].m_raidvol[vol].m_israid
14327 == 1) {
14328 target = mpt->m_raidconfig[config].
14329 m_raidvol[vol].m_raidhandle;
14330 mutex_exit(&mpt->m_mutex);
14331 (void) mptsas_config_raid(pdip, target,
14332 &lundip);
14333 mutex_enter(&mpt->m_mutex);
14334 }
14335 }
14336 }
14337 mutex_exit(&mpt->m_mutex);
14338 }
14339
14340 static void
14341 mptsas_offline_missed_luns(dev_info_t *pdip, uint16_t *repluns,
14342 int lun_cnt, mptsas_target_t *ptgt)
14343 {
14344 dev_info_t *child = NULL, *savechild = NULL;
14345 mdi_pathinfo_t *pip = NULL, *savepip = NULL;
14346 uint64_t sas_wwn, wwid;
14347 uint8_t phy;
14348 int lun;
14349 int i;
14350 int find;
14351 char *addr;
14352 char *nodename;
14353 mptsas_t *mpt = DIP2MPT(pdip);
14354
14355 mutex_enter(&mpt->m_mutex);
14356 wwid = ptgt->m_addr.mta_wwn;
14357 mutex_exit(&mpt->m_mutex);
14358
14359 child = ddi_get_child(pdip);
14360 while (child) {
14361 find = 0;
14362 savechild = child;
14363 child = ddi_get_next_sibling(child);
14364
14365 nodename = ddi_node_name(savechild);
14366 if (strcmp(nodename, "smp") == 0) {
14367 continue;
14368 }
14369
14370 addr = ddi_get_name_addr(savechild);
14371 if (addr == NULL) {
14372 continue;
14373 }
14374
14375 if (mptsas_parse_address(addr, &sas_wwn, &phy, &lun) !=
14376 DDI_SUCCESS) {
14377 continue;
14378 }
14379
14380 if (wwid == sas_wwn) {
14381 for (i = 0; i < lun_cnt; i++) {
14382 if (repluns[i] == lun) {
14383 find = 1;
14384 break;
14385 }
14386 }
14387 } else {
14388 continue;
14389 }
14390 if (find == 0) {
14391 /*
14392 * The lun has not been there already
14393 */
14394 (void) mptsas_offline_lun(pdip, savechild, NULL,
14395 NDI_DEVI_REMOVE);
14396 }
14397 }
14398
14399 pip = mdi_get_next_client_path(pdip, NULL);
14400 while (pip) {
14401 find = 0;
14402 savepip = pip;
14403 addr = MDI_PI(pip)->pi_addr;
14404
14405 pip = mdi_get_next_client_path(pdip, pip);
14406
14407 if (addr == NULL) {
14408 continue;
14409 }
14410
14411 if (mptsas_parse_address(addr, &sas_wwn, &phy,
14412 &lun) != DDI_SUCCESS) {
14413 continue;
14414 }
14415
14416 if (sas_wwn == wwid) {
14417 for (i = 0; i < lun_cnt; i++) {
14418 if (repluns[i] == lun) {
14419 find = 1;
14420 break;
14421 }
14422 }
14423 } else {
14424 continue;
14425 }
14426
14427 if (find == 0) {
14428 /*
14429 * The lun has not been there already
14430 */
14431 (void) mptsas_offline_lun(pdip, NULL, savepip,
14432 NDI_DEVI_REMOVE);
14433 }
14434 }
14435 }
14436
14437 void
14438 mptsas_update_hashtab(struct mptsas *mpt)
14439 {
14440 uint32_t page_address;
14441 int rval = 0;
14442 uint16_t dev_handle;
14443 mptsas_target_t *ptgt = NULL;
14444 mptsas_smp_t smp_node;
14445
14446 /*
14447 * Get latest RAID info.
14448 */
14449 (void) mptsas_get_raid_info(mpt);
14450
14451 dev_handle = mpt->m_smp_devhdl;
14452 for (; mpt->m_done_traverse_smp == 0; ) {
14453 page_address = (MPI2_SAS_EXPAND_PGAD_FORM_GET_NEXT_HNDL &
14454 MPI2_SAS_EXPAND_PGAD_FORM_MASK) | (uint32_t)dev_handle;
14455 if (mptsas_get_sas_expander_page0(mpt, page_address, &smp_node)
14456 != DDI_SUCCESS) {
14457 break;
14458 }
14459 mpt->m_smp_devhdl = dev_handle = smp_node.m_devhdl;
14460 (void) mptsas_smp_alloc(mpt, &smp_node);
14461 }
14462
14463 /*
14464 * Config target devices
14465 */
14466 dev_handle = mpt->m_dev_handle;
14467
14468 /*
14469 * Do loop to get sas device page 0 by GetNextHandle till the
14470 * the last handle. If the sas device is a SATA/SSP target,
14471 * we try to config it.
14472 */
14473 for (; mpt->m_done_traverse_dev == 0; ) {
14474 ptgt = NULL;
14475 page_address =
14476 (MPI2_SAS_DEVICE_PGAD_FORM_GET_NEXT_HANDLE &
14477 MPI2_SAS_DEVICE_PGAD_FORM_MASK) |
14478 (uint32_t)dev_handle;
14479 rval = mptsas_get_target_device_info(mpt, page_address,
14480 &dev_handle, &ptgt);
14481 if ((rval == DEV_INFO_FAIL_PAGE0) ||
14482 (rval == DEV_INFO_FAIL_ALLOC) ||
14483 (rval == DEV_INFO_FAIL_GUID)) {
14484 break;
14485 }
14486
14487 mpt->m_dev_handle = dev_handle;
14488 }
14489
14490 }
14491
14492 void
14493 mptsas_update_driver_data(struct mptsas *mpt)
14494 {
14495 mptsas_target_t *tp;
14496 mptsas_smp_t *sp;
14497
14498 ASSERT(MUTEX_HELD(&mpt->m_mutex));
14499
14500 /*
14501 * TODO after hard reset, update the driver data structures
14502 * 1. update port/phymask mapping table mpt->m_phy_info
14503 * 2. invalid all the entries in hash table
14504 * m_devhdl = 0xffff and m_deviceinfo = 0
14505 * 3. call sas_device_page/expander_page to update hash table
14506 */
14507 mptsas_update_phymask(mpt);
14508
14509 /*
14510 * Remove all the devhdls for existing entries but leave their
14511 * addresses alone. In update_hashtab() below, we'll find all
14512 * targets that are still present and reassociate them with
14513 * their potentially new devhdls. Leaving the targets around in
14514 * this fashion allows them to be used on the tx waitq even
14515 * while IOC reset is occurring.
14516 */
14517 for (tp = refhash_first(mpt->m_targets); tp != NULL;
14518 tp = refhash_next(mpt->m_targets, tp)) {
14519 tp->m_devhdl = MPTSAS_INVALID_DEVHDL;
14520 tp->m_deviceinfo = 0;
14521 tp->m_dr_flag = MPTSAS_DR_INACTIVE;
14522 }
14523 for (sp = refhash_first(mpt->m_smp_targets); sp != NULL;
14524 sp = refhash_next(mpt->m_smp_targets, sp)) {
14525 sp->m_devhdl = MPTSAS_INVALID_DEVHDL;
14526 sp->m_deviceinfo = 0;
14527 }
14528 mpt->m_done_traverse_dev = 0;
14529 mpt->m_done_traverse_smp = 0;
14530 mpt->m_dev_handle = mpt->m_smp_devhdl = MPTSAS_INVALID_DEVHDL;
14531 mptsas_update_hashtab(mpt);
14532 }
14533
14534 static void
14535 mptsas_config_all(dev_info_t *pdip)
14536 {
14537 dev_info_t *smpdip = NULL;
14538 mptsas_t *mpt = DIP2MPT(pdip);
14539 int phymask = 0;
14540 mptsas_phymask_t phy_mask;
14541 mptsas_target_t *ptgt = NULL;
14542 mptsas_smp_t *psmp;
14543
14544 /*
14545 * Get the phymask associated to the iport
14546 */
14547 phymask = ddi_prop_get_int(DDI_DEV_T_ANY, pdip, 0,
14548 "phymask", 0);
14549
14550 /*
14551 * Enumerate RAID volumes here (phymask == 0).
14552 */
14553 if (phymask == 0) {
14554 mptsas_config_all_viport(pdip);
14555 return;
14556 }
14557
14558 mutex_enter(&mpt->m_mutex);
14559
14560 if (!mpt->m_done_traverse_dev || !mpt->m_done_traverse_smp) {
14561 mptsas_update_hashtab(mpt);
14562 }
14563
14564 for (psmp = refhash_first(mpt->m_smp_targets); psmp != NULL;
14565 psmp = refhash_next(mpt->m_smp_targets, psmp)) {
14566 phy_mask = psmp->m_addr.mta_phymask;
14567 if (phy_mask == phymask) {
14568 smpdip = NULL;
14569 mutex_exit(&mpt->m_mutex);
14570 (void) mptsas_online_smp(pdip, psmp, &smpdip);
14571 mutex_enter(&mpt->m_mutex);
14572 }
14573 }
14574
14575 for (ptgt = refhash_first(mpt->m_targets); ptgt != NULL;
14576 ptgt = refhash_next(mpt->m_targets, ptgt)) {
14577 phy_mask = ptgt->m_addr.mta_phymask;
14578 if (phy_mask == phymask) {
14579 mutex_exit(&mpt->m_mutex);
14580 (void) mptsas_config_target(pdip, ptgt);
14581 mutex_enter(&mpt->m_mutex);
14582 }
14583 }
14584 mutex_exit(&mpt->m_mutex);
14585 }
14586
14587 static int
14588 mptsas_config_target(dev_info_t *pdip, mptsas_target_t *ptgt)
14589 {
14590 int rval = DDI_FAILURE;
14591 dev_info_t *tdip;
14592
14593 rval = mptsas_config_luns(pdip, ptgt);
14594 if (rval != DDI_SUCCESS) {
14595 /*
14596 * The return value means the SCMD_REPORT_LUNS
14597 * did not execute successfully. The target maybe
14598 * doesn't support such command.
14599 */
14600 rval = mptsas_probe_lun(pdip, 0, &tdip, ptgt);
14601 }
14602 return (rval);
14603 }
14604
14605 /*
14606 * Return fail if not all the childs/paths are freed.
14607 * if there is any path under the HBA, the return value will be always fail
14608 * because we didn't call mdi_pi_free for path
14609 */
14610 static int
14611 mptsas_offline_target(dev_info_t *pdip, char *name)
14612 {
14613 dev_info_t *child = NULL, *prechild = NULL;
14614 mdi_pathinfo_t *pip = NULL, *savepip = NULL;
14615 int tmp_rval, rval = DDI_SUCCESS;
14616 char *addr, *cp;
14617 size_t s;
14618 mptsas_t *mpt = DIP2MPT(pdip);
14619
14620 child = ddi_get_child(pdip);
14621 while (child) {
14622 addr = ddi_get_name_addr(child);
14623 prechild = child;
14624 child = ddi_get_next_sibling(child);
14625
14626 if (addr == NULL) {
14627 continue;
14628 }
14629 if ((cp = strchr(addr, ',')) == NULL) {
14630 continue;
14631 }
14632
14633 s = (uintptr_t)cp - (uintptr_t)addr;
14634
14635 if (strncmp(addr, name, s) != 0) {
14636 continue;
14637 }
14638
14639 tmp_rval = mptsas_offline_lun(pdip, prechild, NULL,
14640 NDI_DEVI_REMOVE);
14641 if (tmp_rval != DDI_SUCCESS) {
14642 rval = DDI_FAILURE;
14643 if (ndi_prop_create_boolean(DDI_DEV_T_NONE,
14644 prechild, MPTSAS_DEV_GONE) !=
14645 DDI_PROP_SUCCESS) {
14646 mptsas_log(mpt, CE_WARN, "mptsas driver "
14647 "unable to create property for "
14648 "SAS %s (MPTSAS_DEV_GONE)", addr);
14649 }
14650 }
14651 }
14652
14653 pip = mdi_get_next_client_path(pdip, NULL);
14654 while (pip) {
14655 addr = MDI_PI(pip)->pi_addr;
14656 savepip = pip;
14657 pip = mdi_get_next_client_path(pdip, pip);
14658 if (addr == NULL) {
14659 continue;
14660 }
14661
14662 if ((cp = strchr(addr, ',')) == NULL) {
14663 continue;
14664 }
14665
14666 s = (uintptr_t)cp - (uintptr_t)addr;
14667
14668 if (strncmp(addr, name, s) != 0) {
14669 continue;
14670 }
14671
14672 (void) mptsas_offline_lun(pdip, NULL, savepip,
14673 NDI_DEVI_REMOVE);
14674 /*
14675 * driver will not invoke mdi_pi_free, so path will not
14676 * be freed forever, return DDI_FAILURE.
14677 */
14678 rval = DDI_FAILURE;
14679 }
14680 return (rval);
14681 }
14682
14683 static int
14684 mptsas_offline_lun(dev_info_t *pdip, dev_info_t *rdip,
14685 mdi_pathinfo_t *rpip, uint_t flags)
14686 {
14687 int rval = DDI_FAILURE;
14688 char *devname;
14689 dev_info_t *cdip, *parent;
14690
14691 if (rpip != NULL) {
14692 parent = scsi_vhci_dip;
14693 cdip = mdi_pi_get_client(rpip);
14694 } else if (rdip != NULL) {
14695 parent = pdip;
14696 cdip = rdip;
14697 } else {
14698 return (DDI_FAILURE);
14699 }
14700
14701 /*
14702 * Make sure node is attached otherwise
14703 * it won't have related cache nodes to
14704 * clean up. i_ddi_devi_attached is
14705 * similiar to i_ddi_node_state(cdip) >=
14706 * DS_ATTACHED.
14707 */
14708 if (i_ddi_devi_attached(cdip)) {
14709
14710 /* Get full devname */
14711 devname = kmem_alloc(MAXNAMELEN + 1, KM_SLEEP);
14712 (void) ddi_deviname(cdip, devname);
14713 /* Clean cache */
14714 (void) devfs_clean(parent, devname + 1,
14715 DV_CLEAN_FORCE);
14716 kmem_free(devname, MAXNAMELEN + 1);
14717 }
14718 if (rpip != NULL) {
14719 if (MDI_PI_IS_OFFLINE(rpip)) {
14720 rval = DDI_SUCCESS;
14721 } else {
14722 rval = mdi_pi_offline(rpip, 0);
14723 }
14724 } else {
14725 rval = ndi_devi_offline(cdip, flags);
14726 }
14727
14728 return (rval);
14729 }
14730
14731 static dev_info_t *
14732 mptsas_find_smp_child(dev_info_t *parent, char *str_wwn)
14733 {
14734 dev_info_t *child = NULL;
14735 char *smp_wwn = NULL;
14736
14737 child = ddi_get_child(parent);
14738 while (child) {
14739 if (ddi_prop_lookup_string(DDI_DEV_T_ANY, child,
14740 DDI_PROP_DONTPASS, SMP_WWN, &smp_wwn)
14741 != DDI_SUCCESS) {
14742 child = ddi_get_next_sibling(child);
14743 continue;
14744 }
14745
14746 if (strcmp(smp_wwn, str_wwn) == 0) {
14747 ddi_prop_free(smp_wwn);
14748 break;
14749 }
14750 child = ddi_get_next_sibling(child);
14751 ddi_prop_free(smp_wwn);
14752 }
14753 return (child);
14754 }
14755
14756 static int
14757 mptsas_offline_smp(dev_info_t *pdip, mptsas_smp_t *smp_node, uint_t flags)
14758 {
14759 int rval = DDI_FAILURE;
14760 char *devname;
14761 char wwn_str[MPTSAS_WWN_STRLEN];
14762 dev_info_t *cdip;
14763
14764 (void) sprintf(wwn_str, "%"PRIx64, smp_node->m_addr.mta_wwn);
14765
14766 cdip = mptsas_find_smp_child(pdip, wwn_str);
14767
14768 if (cdip == NULL)
14769 return (DDI_SUCCESS);
14770
14771 /*
14772 * Make sure node is attached otherwise
14773 * it won't have related cache nodes to
14774 * clean up. i_ddi_devi_attached is
14775 * similiar to i_ddi_node_state(cdip) >=
14776 * DS_ATTACHED.
14777 */
14778 if (i_ddi_devi_attached(cdip)) {
14779
14780 /* Get full devname */
14781 devname = kmem_alloc(MAXNAMELEN + 1, KM_SLEEP);
14782 (void) ddi_deviname(cdip, devname);
14783 /* Clean cache */
14784 (void) devfs_clean(pdip, devname + 1,
14785 DV_CLEAN_FORCE);
14786 kmem_free(devname, MAXNAMELEN + 1);
14787 }
14788
14789 rval = ndi_devi_offline(cdip, flags);
14790
14791 return (rval);
14792 }
14793
14794 static dev_info_t *
14795 mptsas_find_child(dev_info_t *pdip, char *name)
14796 {
14797 dev_info_t *child = NULL;
14798 char *rname = NULL;
14799 int rval = DDI_FAILURE;
14800
14801 rname = kmem_zalloc(SCSI_MAXNAMELEN, KM_SLEEP);
14802
14803 child = ddi_get_child(pdip);
14804 while (child) {
14805 rval = mptsas_name_child(child, rname, SCSI_MAXNAMELEN);
14806 if (rval != DDI_SUCCESS) {
14807 child = ddi_get_next_sibling(child);
14808 bzero(rname, SCSI_MAXNAMELEN);
14809 continue;
14810 }
14811
14812 if (strcmp(rname, name) == 0) {
14813 break;
14814 }
14815 child = ddi_get_next_sibling(child);
14816 bzero(rname, SCSI_MAXNAMELEN);
14817 }
14818
14819 kmem_free(rname, SCSI_MAXNAMELEN);
14820
14821 return (child);
14822 }
14823
14824
14825 static dev_info_t *
14826 mptsas_find_child_addr(dev_info_t *pdip, uint64_t sasaddr, int lun)
14827 {
14828 dev_info_t *child = NULL;
14829 char *name = NULL;
14830 char *addr = NULL;
14831
14832 name = kmem_zalloc(SCSI_MAXNAMELEN, KM_SLEEP);
14833 addr = kmem_zalloc(SCSI_MAXNAMELEN, KM_SLEEP);
14834 (void) sprintf(name, "%016"PRIx64, sasaddr);
14835 (void) sprintf(addr, "w%s,%x", name, lun);
14836 child = mptsas_find_child(pdip, addr);
14837 kmem_free(name, SCSI_MAXNAMELEN);
14838 kmem_free(addr, SCSI_MAXNAMELEN);
14839 return (child);
14840 }
14841
14842 static dev_info_t *
14843 mptsas_find_child_phy(dev_info_t *pdip, uint8_t phy)
14844 {
14845 dev_info_t *child;
14846 char *addr;
14847
14848 addr = kmem_zalloc(SCSI_MAXNAMELEN, KM_SLEEP);
14849 (void) sprintf(addr, "p%x,0", phy);
14850 child = mptsas_find_child(pdip, addr);
14851 kmem_free(addr, SCSI_MAXNAMELEN);
14852 return (child);
14853 }
14854
14855 static mdi_pathinfo_t *
14856 mptsas_find_path_phy(dev_info_t *pdip, uint8_t phy)
14857 {
14858 mdi_pathinfo_t *path;
14859 char *addr = NULL;
14860
14861 addr = kmem_zalloc(SCSI_MAXNAMELEN, KM_SLEEP);
14862 (void) sprintf(addr, "p%x,0", phy);
14863 path = mdi_pi_find(pdip, NULL, addr);
14864 kmem_free(addr, SCSI_MAXNAMELEN);
14865 return (path);
14866 }
14867
14868 static mdi_pathinfo_t *
14869 mptsas_find_path_addr(dev_info_t *parent, uint64_t sasaddr, int lun)
14870 {
14871 mdi_pathinfo_t *path;
14872 char *name = NULL;
14873 char *addr = NULL;
14874
14875 name = kmem_zalloc(SCSI_MAXNAMELEN, KM_SLEEP);
14876 addr = kmem_zalloc(SCSI_MAXNAMELEN, KM_SLEEP);
14877 (void) sprintf(name, "%016"PRIx64, sasaddr);
14878 (void) sprintf(addr, "w%s,%x", name, lun);
14879 path = mdi_pi_find(parent, NULL, addr);
14880 kmem_free(name, SCSI_MAXNAMELEN);
14881 kmem_free(addr, SCSI_MAXNAMELEN);
14882
14883 return (path);
14884 }
14885
14886 static int
14887 mptsas_create_lun(dev_info_t *pdip, struct scsi_inquiry *sd_inq,
14888 dev_info_t **lun_dip, mptsas_target_t *ptgt, int lun)
14889 {
14890 int i = 0;
14891 uchar_t *inq83 = NULL;
14892 int inq83_len1 = 0xFF;
14893 int inq83_len = 0;
14894 int rval = DDI_FAILURE;
14895 ddi_devid_t devid;
14896 char *guid = NULL;
14897 int target = ptgt->m_devhdl;
14898 mdi_pathinfo_t *pip = NULL;
14899 mptsas_t *mpt = DIP2MPT(pdip);
14900
14901 /*
14902 * For DVD/CD ROM and tape devices and optical
14903 * devices, we won't try to enumerate them under
14904 * scsi_vhci, so no need to try page83
14905 */
14906 if (sd_inq && (sd_inq->inq_dtype == DTYPE_RODIRECT ||
14907 sd_inq->inq_dtype == DTYPE_OPTICAL ||
14908 sd_inq->inq_dtype == DTYPE_ESI))
14909 goto create_lun;
14910
14911 /*
14912 * The LCA returns good SCSI status, but corrupt page 83 data the first
14913 * time it is queried. The solution is to keep trying to request page83
14914 * and verify the GUID is not (DDI_NOT_WELL_FORMED) in
14915 * mptsas_inq83_retry_timeout seconds. If the timeout expires, driver
14916 * give up to get VPD page at this stage and fail the enumeration.
14917 */
14918
14919 inq83 = kmem_zalloc(inq83_len1, KM_SLEEP);
14920
14921 for (i = 0; i < mptsas_inq83_retry_timeout; i++) {
14922 rval = mptsas_inquiry(mpt, ptgt, lun, 0x83, inq83,
14923 inq83_len1, &inq83_len, 1);
14924 if (rval != 0) {
14925 mptsas_log(mpt, CE_WARN, "!mptsas request inquiry page "
14926 "0x83 for target:%x, lun:%x failed!", target, lun);
14927 if (mptsas_physical_bind_failed_page_83 != B_FALSE)
14928 goto create_lun;
14929 goto out;
14930 }
14931 /*
14932 * create DEVID from inquiry data
14933 */
14934 if ((rval = ddi_devid_scsi_encode(
14935 DEVID_SCSI_ENCODE_VERSION_LATEST, NULL, (uchar_t *)sd_inq,
14936 sizeof (struct scsi_inquiry), NULL, 0, inq83,
14937 (size_t)inq83_len, &devid)) == DDI_SUCCESS) {
14938 /*
14939 * extract GUID from DEVID
14940 */
14941 guid = ddi_devid_to_guid(devid);
14942
14943 /*
14944 * Do not enable MPXIO if the strlen(guid) is greater
14945 * than MPTSAS_MAX_GUID_LEN, this constrain would be
14946 * handled by framework later.
14947 */
14948 if (guid && (strlen(guid) > MPTSAS_MAX_GUID_LEN)) {
14949 ddi_devid_free_guid(guid);
14950 guid = NULL;
14951 if (mpt->m_mpxio_enable == TRUE) {
14952 mptsas_log(mpt, CE_NOTE, "!Target:%x, "
14953 "lun:%x doesn't have a valid GUID, "
14954 "multipathing for this drive is "
14955 "not enabled", target, lun);
14956 }
14957 }
14958
14959 /*
14960 * devid no longer needed
14961 */
14962 ddi_devid_free(devid);
14963 break;
14964 } else if (rval == DDI_NOT_WELL_FORMED) {
14965 /*
14966 * return value of ddi_devid_scsi_encode equal to
14967 * DDI_NOT_WELL_FORMED means DEVID_RETRY, it worth
14968 * to retry inquiry page 0x83 and get GUID.
14969 */
14970 NDBG20(("Not well formed devid, retry..."));
14971 delay(1 * drv_usectohz(1000000));
14972 continue;
14973 } else {
14974 mptsas_log(mpt, CE_WARN, "!Encode devid failed for "
14975 "path target:%x, lun:%x", target, lun);
14976 rval = DDI_FAILURE;
14977 goto create_lun;
14978 }
14979 }
14980
14981 if (i == mptsas_inq83_retry_timeout) {
14982 mptsas_log(mpt, CE_WARN, "!Repeated page83 requests timeout "
14983 "for path target:%x, lun:%x", target, lun);
14984 }
14985
14986 rval = DDI_FAILURE;
14987
14988 create_lun:
14989 if ((guid != NULL) && (mpt->m_mpxio_enable == TRUE)) {
14990 rval = mptsas_create_virt_lun(pdip, sd_inq, guid, lun_dip, &pip,
14991 ptgt, lun);
14992 }
14993 if (rval != DDI_SUCCESS) {
14994 rval = mptsas_create_phys_lun(pdip, sd_inq, guid, lun_dip,
14995 ptgt, lun);
14996
14997 }
14998 out:
14999 if (guid != NULL) {
15000 /*
15001 * guid no longer needed
15002 */
15003 ddi_devid_free_guid(guid);
15004 }
15005 if (inq83 != NULL)
15006 kmem_free(inq83, inq83_len1);
15007 return (rval);
15008 }
15009
15010 static int
15011 mptsas_create_virt_lun(dev_info_t *pdip, struct scsi_inquiry *inq, char *guid,
15012 dev_info_t **lun_dip, mdi_pathinfo_t **pip, mptsas_target_t *ptgt, int lun)
15013 {
15014 int target;
15015 char *nodename = NULL;
15016 char **compatible = NULL;
15017 int ncompatible = 0;
15018 int mdi_rtn = MDI_FAILURE;
15019 int rval = DDI_FAILURE;
15020 char *old_guid = NULL;
15021 mptsas_t *mpt = DIP2MPT(pdip);
15022 char *lun_addr = NULL;
15023 char *wwn_str = NULL;
15024 char *attached_wwn_str = NULL;
15025 char *component = NULL;
15026 uint8_t phy = 0xFF;
15027 uint64_t sas_wwn;
15028 int64_t lun64 = 0;
15029 uint32_t devinfo;
15030 uint16_t dev_hdl;
15031 uint16_t pdev_hdl;
15032 uint64_t dev_sas_wwn;
15033 uint64_t pdev_sas_wwn;
15034 uint32_t pdev_info;
15035 uint8_t physport;
15036 uint8_t phy_id;
15037 uint32_t page_address;
15038 uint16_t bay_num, enclosure, io_flags;
15039 char pdev_wwn_str[MPTSAS_WWN_STRLEN];
15040 uint32_t dev_info;
15041
15042 mutex_enter(&mpt->m_mutex);
15043 target = ptgt->m_devhdl;
15044 sas_wwn = ptgt->m_addr.mta_wwn;
15045 devinfo = ptgt->m_deviceinfo;
15046 phy = ptgt->m_phynum;
15047 mutex_exit(&mpt->m_mutex);
15048
15049 if (sas_wwn) {
15050 *pip = mptsas_find_path_addr(pdip, sas_wwn, lun);
15051 } else {
15052 *pip = mptsas_find_path_phy(pdip, phy);
15053 }
15054
15055 if (*pip != NULL) {
15056 *lun_dip = MDI_PI(*pip)->pi_client->ct_dip;
15057 ASSERT(*lun_dip != NULL);
15058 if (ddi_prop_lookup_string(DDI_DEV_T_ANY, *lun_dip,
15059 (DDI_PROP_DONTPASS | DDI_PROP_NOTPROM),
15060 MDI_CLIENT_GUID_PROP, &old_guid) == DDI_SUCCESS) {
15061 if (strncmp(guid, old_guid, strlen(guid)) == 0) {
15062 /*
15063 * Same path back online again.
15064 */
15065 (void) ddi_prop_free(old_guid);
15066 if ((!MDI_PI_IS_ONLINE(*pip)) &&
15067 (!MDI_PI_IS_STANDBY(*pip)) &&
15068 (ptgt->m_tgt_unconfigured == 0)) {
15069 rval = mdi_pi_online(*pip, 0);
15070 mutex_enter(&mpt->m_mutex);
15071 ptgt->m_led_status = 0;
15072 (void) mptsas_flush_led_status(mpt,
15073 ptgt);
15074 mutex_exit(&mpt->m_mutex);
15075 } else {
15076 rval = DDI_SUCCESS;
15077 }
15078 if (rval != DDI_SUCCESS) {
15079 mptsas_log(mpt, CE_WARN, "path:target: "
15080 "%x, lun:%x online failed!", target,
15081 lun);
15082 *pip = NULL;
15083 *lun_dip = NULL;
15084 }
15085 return (rval);
15086 } else {
15087 /*
15088 * The GUID of the LUN has changed which maybe
15089 * because customer mapped another volume to the
15090 * same LUN.
15091 */
15092 mptsas_log(mpt, CE_WARN, "The GUID of the "
15093 "target:%x, lun:%x was changed, maybe "
15094 "because someone mapped another volume "
15095 "to the same LUN", target, lun);
15096 (void) ddi_prop_free(old_guid);
15097 if (!MDI_PI_IS_OFFLINE(*pip)) {
15098 rval = mdi_pi_offline(*pip, 0);
15099 if (rval != MDI_SUCCESS) {
15100 mptsas_log(mpt, CE_WARN, "path:"
15101 "target:%x, lun:%x offline "
15102 "failed!", target, lun);
15103 *pip = NULL;
15104 *lun_dip = NULL;
15105 return (DDI_FAILURE);
15106 }
15107 }
15108 if (mdi_pi_free(*pip, 0) != MDI_SUCCESS) {
15109 mptsas_log(mpt, CE_WARN, "path:target:"
15110 "%x, lun:%x free failed!", target,
15111 lun);
15112 *pip = NULL;
15113 *lun_dip = NULL;
15114 return (DDI_FAILURE);
15115 }
15116 }
15117 } else {
15118 mptsas_log(mpt, CE_WARN, "Can't get client-guid "
15119 "property for path:target:%x, lun:%x", target, lun);
15120 *pip = NULL;
15121 *lun_dip = NULL;
15122 return (DDI_FAILURE);
15123 }
15124 }
15125 scsi_hba_nodename_compatible_get(inq, NULL,
15126 inq->inq_dtype, NULL, &nodename, &compatible, &ncompatible);
15127
15128 /*
15129 * if nodename can't be determined then print a message and skip it
15130 */
15131 if (nodename == NULL) {
15132 mptsas_log(mpt, CE_WARN, "mptsas driver found no compatible "
15133 "driver for target%d lun %d dtype:0x%02x", target, lun,
15134 inq->inq_dtype);
15135 return (DDI_FAILURE);
15136 }
15137
15138 wwn_str = kmem_zalloc(MPTSAS_WWN_STRLEN, KM_SLEEP);
15139 /* The property is needed by MPAPI */
15140 (void) sprintf(wwn_str, "%016"PRIx64, sas_wwn);
15141
15142 lun_addr = kmem_zalloc(SCSI_MAXNAMELEN, KM_SLEEP);
15143 if (guid) {
15144 (void) sprintf(lun_addr, "w%s,%x", wwn_str, lun);
15145 (void) sprintf(wwn_str, "w%016"PRIx64, sas_wwn);
15146 } else {
15147 (void) sprintf(lun_addr, "p%x,%x", phy, lun);
15148 (void) sprintf(wwn_str, "p%x", phy);
15149 }
15150
15151 mdi_rtn = mdi_pi_alloc_compatible(pdip, nodename,
15152 guid, lun_addr, compatible, ncompatible,
15153 0, pip);
15154 if (mdi_rtn == MDI_SUCCESS) {
15155
15156 if (mdi_prop_update_string(*pip, MDI_GUID,
15157 guid) != DDI_SUCCESS) {
15158 mptsas_log(mpt, CE_WARN, "mptsas driver unable to "
15159 "create prop for target %d lun %d (MDI_GUID)",
15160 target, lun);
15161 mdi_rtn = MDI_FAILURE;
15162 goto virt_create_done;
15163 }
15164
15165 if (mdi_prop_update_int(*pip, LUN_PROP,
15166 lun) != DDI_SUCCESS) {
15167 mptsas_log(mpt, CE_WARN, "mptsas driver unable to "
15168 "create prop for target %d lun %d (LUN_PROP)",
15169 target, lun);
15170 mdi_rtn = MDI_FAILURE;
15171 goto virt_create_done;
15172 }
15173 lun64 = (int64_t)lun;
15174 if (mdi_prop_update_int64(*pip, LUN64_PROP,
15175 lun64) != DDI_SUCCESS) {
15176 mptsas_log(mpt, CE_WARN, "mptsas driver unable to "
15177 "create prop for target %d (LUN64_PROP)",
15178 target);
15179 mdi_rtn = MDI_FAILURE;
15180 goto virt_create_done;
15181 }
15182 if (mdi_prop_update_string_array(*pip, "compatible",
15183 compatible, ncompatible) !=
15184 DDI_PROP_SUCCESS) {
15185 mptsas_log(mpt, CE_WARN, "mptsas driver unable to "
15186 "create prop for target %d lun %d (COMPATIBLE)",
15187 target, lun);
15188 mdi_rtn = MDI_FAILURE;
15189 goto virt_create_done;
15190 }
15191 if (sas_wwn && (mdi_prop_update_string(*pip,
15192 SCSI_ADDR_PROP_TARGET_PORT, wwn_str) != DDI_PROP_SUCCESS)) {
15193 mptsas_log(mpt, CE_WARN, "mptsas driver unable to "
15194 "create prop for target %d lun %d "
15195 "(target-port)", target, lun);
15196 mdi_rtn = MDI_FAILURE;
15197 goto virt_create_done;
15198 } else if ((sas_wwn == 0) && (mdi_prop_update_int(*pip,
15199 "sata-phy", phy) != DDI_PROP_SUCCESS)) {
15200 /*
15201 * Direct attached SATA device without DeviceName
15202 */
15203 mptsas_log(mpt, CE_WARN, "mptsas driver unable to "
15204 "create prop for SAS target %d lun %d "
15205 "(sata-phy)", target, lun);
15206 mdi_rtn = MDI_FAILURE;
15207 goto virt_create_done;
15208 }
15209 mutex_enter(&mpt->m_mutex);
15210
15211 page_address = (MPI2_SAS_DEVICE_PGAD_FORM_HANDLE &
15212 MPI2_SAS_DEVICE_PGAD_FORM_MASK) |
15213 (uint32_t)ptgt->m_devhdl;
15214 rval = mptsas_get_sas_device_page0(mpt, page_address,
15215 &dev_hdl, &dev_sas_wwn, &dev_info, &physport,
15216 &phy_id, &pdev_hdl, &bay_num, &enclosure, &io_flags);
15217 if (rval != DDI_SUCCESS) {
15218 mutex_exit(&mpt->m_mutex);
15219 mptsas_log(mpt, CE_WARN, "mptsas unable to get "
15220 "parent device for handle %d", page_address);
15221 mdi_rtn = MDI_FAILURE;
15222 goto virt_create_done;
15223 }
15224
15225 page_address = (MPI2_SAS_DEVICE_PGAD_FORM_HANDLE &
15226 MPI2_SAS_DEVICE_PGAD_FORM_MASK) | (uint32_t)pdev_hdl;
15227 rval = mptsas_get_sas_device_page0(mpt, page_address,
15228 &dev_hdl, &pdev_sas_wwn, &pdev_info, &physport,
15229 &phy_id, &pdev_hdl, &bay_num, &enclosure, &io_flags);
15230 if (rval != DDI_SUCCESS) {
15231 mutex_exit(&mpt->m_mutex);
15232 mptsas_log(mpt, CE_WARN, "mptsas unable to get"
15233 "device info for handle %d", page_address);
15234 mdi_rtn = MDI_FAILURE;
15235 goto virt_create_done;
15236 }
15237
15238 mutex_exit(&mpt->m_mutex);
15239
15240 /*
15241 * If this device direct attached to the controller
15242 * set the attached-port to the base wwid
15243 */
15244 if ((ptgt->m_deviceinfo & DEVINFO_DIRECT_ATTACHED)
15245 != DEVINFO_DIRECT_ATTACHED) {
15246 (void) sprintf(pdev_wwn_str, "w%016"PRIx64,
15247 pdev_sas_wwn);
15248 } else {
15249 /*
15250 * Update the iport's attached-port to guid
15251 */
15252 if (sas_wwn == 0) {
15253 (void) sprintf(wwn_str, "p%x", phy);
15254 } else {
15255 (void) sprintf(wwn_str, "w%016"PRIx64, sas_wwn);
15256 }
15257 if (ddi_prop_update_string(DDI_DEV_T_NONE,
15258 pdip, SCSI_ADDR_PROP_ATTACHED_PORT, wwn_str) !=
15259 DDI_PROP_SUCCESS) {
15260 mptsas_log(mpt, CE_WARN,
15261 "mptsas unable to create "
15262 "property for iport target-port"
15263 " %s (sas_wwn)",
15264 wwn_str);
15265 mdi_rtn = MDI_FAILURE;
15266 goto virt_create_done;
15267 }
15268
15269 (void) sprintf(pdev_wwn_str, "w%016"PRIx64,
15270 mpt->un.m_base_wwid);
15271 }
15272
15273 if (mdi_prop_update_string(*pip,
15274 SCSI_ADDR_PROP_ATTACHED_PORT, pdev_wwn_str) !=
15275 DDI_PROP_SUCCESS) {
15276 mptsas_log(mpt, CE_WARN, "mptsas unable to create "
15277 "property for iport attached-port %s (sas_wwn)",
15278 attached_wwn_str);
15279 mdi_rtn = MDI_FAILURE;
15280 goto virt_create_done;
15281 }
15282
15283
15284 if (inq->inq_dtype == 0) {
15285 component = kmem_zalloc(MAXPATHLEN, KM_SLEEP);
15286 /*
15287 * set obp path for pathinfo
15288 */
15289 (void) snprintf(component, MAXPATHLEN,
15290 "disk@%s", lun_addr);
15291
15292 if (mdi_pi_pathname_obp_set(*pip, component) !=
15293 DDI_SUCCESS) {
15294 mptsas_log(mpt, CE_WARN, "mpt_sas driver "
15295 "unable to set obp-path for object %s",
15296 component);
15297 mdi_rtn = MDI_FAILURE;
15298 goto virt_create_done;
15299 }
15300 }
15301
15302 *lun_dip = MDI_PI(*pip)->pi_client->ct_dip;
15303 if (devinfo & (MPI2_SAS_DEVICE_INFO_SATA_DEVICE |
15304 MPI2_SAS_DEVICE_INFO_ATAPI_DEVICE)) {
15305 if ((ndi_prop_update_int(DDI_DEV_T_NONE, *lun_dip,
15306 "pm-capable", 1)) !=
15307 DDI_PROP_SUCCESS) {
15308 mptsas_log(mpt, CE_WARN, "mptsas driver"
15309 "failed to create pm-capable "
15310 "property, target %d", target);
15311 mdi_rtn = MDI_FAILURE;
15312 goto virt_create_done;
15313 }
15314 }
15315 /*
15316 * Create the phy-num property
15317 */
15318 if (mdi_prop_update_int(*pip, "phy-num",
15319 ptgt->m_phynum) != DDI_SUCCESS) {
15320 mptsas_log(mpt, CE_WARN, "mptsas driver unable to "
15321 "create phy-num property for target %d lun %d",
15322 target, lun);
15323 mdi_rtn = MDI_FAILURE;
15324 goto virt_create_done;
15325 }
15326 NDBG20(("new path:%s onlining,", MDI_PI(*pip)->pi_addr));
15327 mdi_rtn = mdi_pi_online(*pip, 0);
15328 if (mdi_rtn == MDI_SUCCESS) {
15329 mutex_enter(&mpt->m_mutex);
15330 ptgt->m_led_status = 0;
15331 (void) mptsas_flush_led_status(mpt, ptgt);
15332 mutex_exit(&mpt->m_mutex);
15333 }
15334 if (mdi_rtn == MDI_NOT_SUPPORTED) {
15335 mdi_rtn = MDI_FAILURE;
15336 }
15337 virt_create_done:
15338 if (*pip && mdi_rtn != MDI_SUCCESS) {
15339 (void) mdi_pi_free(*pip, 0);
15340 *pip = NULL;
15341 *lun_dip = NULL;
15342 }
15343 }
15344
15345 scsi_hba_nodename_compatible_free(nodename, compatible);
15346 if (lun_addr != NULL) {
15347 kmem_free(lun_addr, SCSI_MAXNAMELEN);
15348 }
15349 if (wwn_str != NULL) {
15350 kmem_free(wwn_str, MPTSAS_WWN_STRLEN);
15351 }
15352 if (component != NULL) {
15353 kmem_free(component, MAXPATHLEN);
15354 }
15355
15356 return ((mdi_rtn == MDI_SUCCESS) ? DDI_SUCCESS : DDI_FAILURE);
15357 }
15358
15359 static int
15360 mptsas_create_phys_lun(dev_info_t *pdip, struct scsi_inquiry *inq,
15361 char *guid, dev_info_t **lun_dip, mptsas_target_t *ptgt, int lun)
15362 {
15363 int target;
15364 int rval;
15365 int ndi_rtn = NDI_FAILURE;
15366 uint64_t be_sas_wwn;
15367 char *nodename = NULL;
15368 char **compatible = NULL;
15369 int ncompatible = 0;
15370 int instance = 0;
15371 mptsas_t *mpt = DIP2MPT(pdip);
15372 char *wwn_str = NULL;
15373 char *component = NULL;
15374 char *attached_wwn_str = NULL;
15375 uint8_t phy = 0xFF;
15376 uint64_t sas_wwn;
15377 uint32_t devinfo;
15378 uint16_t dev_hdl;
15379 uint16_t pdev_hdl;
15380 uint64_t pdev_sas_wwn;
15381 uint64_t dev_sas_wwn;
15382 uint32_t pdev_info;
15383 uint8_t physport;
15384 uint8_t phy_id;
15385 uint32_t page_address;
15386 uint16_t bay_num, enclosure, io_flags;
15387 char pdev_wwn_str[MPTSAS_WWN_STRLEN];
15388 uint32_t dev_info;
15389 int64_t lun64 = 0;
15390
15391 mutex_enter(&mpt->m_mutex);
15392 target = ptgt->m_devhdl;
15393 sas_wwn = ptgt->m_addr.mta_wwn;
15394 devinfo = ptgt->m_deviceinfo;
15395 phy = ptgt->m_phynum;
15396 mutex_exit(&mpt->m_mutex);
15397
15398 /*
15399 * generate compatible property with binding-set "mpt"
15400 */
15401 scsi_hba_nodename_compatible_get(inq, NULL, inq->inq_dtype, NULL,
15402 &nodename, &compatible, &ncompatible);
15403
15404 /*
15405 * if nodename can't be determined then print a message and skip it
15406 */
15407 if (nodename == NULL) {
15408 mptsas_log(mpt, CE_WARN, "mptsas found no compatible driver "
15409 "for target %d lun %d", target, lun);
15410 return (DDI_FAILURE);
15411 }
15412
15413 ndi_rtn = ndi_devi_alloc(pdip, nodename,
15414 DEVI_SID_NODEID, lun_dip);
15415
15416 /*
15417 * if lun alloc success, set props
15418 */
15419 if (ndi_rtn == NDI_SUCCESS) {
15420
15421 if (ndi_prop_update_int(DDI_DEV_T_NONE,
15422 *lun_dip, LUN_PROP, lun) !=
15423 DDI_PROP_SUCCESS) {
15424 mptsas_log(mpt, CE_WARN, "mptsas unable to create "
15425 "property for target %d lun %d (LUN_PROP)",
15426 target, lun);
15427 ndi_rtn = NDI_FAILURE;
15428 goto phys_create_done;
15429 }
15430
15431 lun64 = (int64_t)lun;
15432 if (ndi_prop_update_int64(DDI_DEV_T_NONE,
15433 *lun_dip, LUN64_PROP, lun64) !=
15434 DDI_PROP_SUCCESS) {
15435 mptsas_log(mpt, CE_WARN, "mptsas unable to create "
15436 "property for target %d lun64 %d (LUN64_PROP)",
15437 target, lun);
15438 ndi_rtn = NDI_FAILURE;
15439 goto phys_create_done;
15440 }
15441 if (ndi_prop_update_string_array(DDI_DEV_T_NONE,
15442 *lun_dip, "compatible", compatible, ncompatible)
15443 != DDI_PROP_SUCCESS) {
15444 mptsas_log(mpt, CE_WARN, "mptsas unable to create "
15445 "property for target %d lun %d (COMPATIBLE)",
15446 target, lun);
15447 ndi_rtn = NDI_FAILURE;
15448 goto phys_create_done;
15449 }
15450
15451 /*
15452 * We need the SAS WWN for non-multipath devices, so
15453 * we'll use the same property as that multipathing
15454 * devices need to present for MPAPI. If we don't have
15455 * a WWN (e.g. parallel SCSI), don't create the prop.
15456 */
15457 wwn_str = kmem_zalloc(MPTSAS_WWN_STRLEN, KM_SLEEP);
15458 (void) sprintf(wwn_str, "w%016"PRIx64, sas_wwn);
15459 if (sas_wwn && ndi_prop_update_string(DDI_DEV_T_NONE,
15460 *lun_dip, SCSI_ADDR_PROP_TARGET_PORT, wwn_str)
15461 != DDI_PROP_SUCCESS) {
15462 mptsas_log(mpt, CE_WARN, "mptsas unable to "
15463 "create property for SAS target %d lun %d "
15464 "(target-port)", target, lun);
15465 ndi_rtn = NDI_FAILURE;
15466 goto phys_create_done;
15467 }
15468
15469 be_sas_wwn = BE_64(sas_wwn);
15470 if (sas_wwn && ndi_prop_update_byte_array(
15471 DDI_DEV_T_NONE, *lun_dip, "port-wwn",
15472 (uchar_t *)&be_sas_wwn, 8) != DDI_PROP_SUCCESS) {
15473 mptsas_log(mpt, CE_WARN, "mptsas unable to "
15474 "create property for SAS target %d lun %d "
15475 "(port-wwn)", target, lun);
15476 ndi_rtn = NDI_FAILURE;
15477 goto phys_create_done;
15478 } else if ((sas_wwn == 0) && (ndi_prop_update_int(
15479 DDI_DEV_T_NONE, *lun_dip, "sata-phy", phy) !=
15480 DDI_PROP_SUCCESS)) {
15481 /*
15482 * Direct attached SATA device without DeviceName
15483 */
15484 mptsas_log(mpt, CE_WARN, "mptsas unable to "
15485 "create property for SAS target %d lun %d "
15486 "(sata-phy)", target, lun);
15487 ndi_rtn = NDI_FAILURE;
15488 goto phys_create_done;
15489 }
15490
15491 if (ndi_prop_create_boolean(DDI_DEV_T_NONE,
15492 *lun_dip, SAS_PROP) != DDI_PROP_SUCCESS) {
15493 mptsas_log(mpt, CE_WARN, "mptsas unable to"
15494 "create property for SAS target %d lun %d"
15495 " (SAS_PROP)", target, lun);
15496 ndi_rtn = NDI_FAILURE;
15497 goto phys_create_done;
15498 }
15499 if (guid && (ndi_prop_update_string(DDI_DEV_T_NONE,
15500 *lun_dip, NDI_GUID, guid) != DDI_SUCCESS)) {
15501 mptsas_log(mpt, CE_WARN, "mptsas unable "
15502 "to create guid property for target %d "
15503 "lun %d", target, lun);
15504 ndi_rtn = NDI_FAILURE;
15505 goto phys_create_done;
15506 }
15507
15508 /*
15509 * The following code is to set properties for SM-HBA support,
15510 * it doesn't apply to RAID volumes
15511 */
15512 if (ptgt->m_addr.mta_phymask == 0)
15513 goto phys_raid_lun;
15514
15515 mutex_enter(&mpt->m_mutex);
15516
15517 page_address = (MPI2_SAS_DEVICE_PGAD_FORM_HANDLE &
15518 MPI2_SAS_DEVICE_PGAD_FORM_MASK) |
15519 (uint32_t)ptgt->m_devhdl;
15520 rval = mptsas_get_sas_device_page0(mpt, page_address,
15521 &dev_hdl, &dev_sas_wwn, &dev_info,
15522 &physport, &phy_id, &pdev_hdl,
15523 &bay_num, &enclosure, &io_flags);
15524 if (rval != DDI_SUCCESS) {
15525 mutex_exit(&mpt->m_mutex);
15526 mptsas_log(mpt, CE_WARN, "mptsas unable to get"
15527 "parent device for handle %d.", page_address);
15528 ndi_rtn = NDI_FAILURE;
15529 goto phys_create_done;
15530 }
15531
15532 page_address = (MPI2_SAS_DEVICE_PGAD_FORM_HANDLE &
15533 MPI2_SAS_DEVICE_PGAD_FORM_MASK) | (uint32_t)pdev_hdl;
15534 rval = mptsas_get_sas_device_page0(mpt, page_address,
15535 &dev_hdl, &pdev_sas_wwn, &pdev_info, &physport,
15536 &phy_id, &pdev_hdl, &bay_num, &enclosure, &io_flags);
15537 if (rval != DDI_SUCCESS) {
15538 mutex_exit(&mpt->m_mutex);
15539 mptsas_log(mpt, CE_WARN, "mptsas unable to create "
15540 "device for handle %d.", page_address);
15541 ndi_rtn = NDI_FAILURE;
15542 goto phys_create_done;
15543 }
15544
15545 mutex_exit(&mpt->m_mutex);
15546
15547 /*
15548 * If this device direct attached to the controller
15549 * set the attached-port to the base wwid
15550 */
15551 if ((ptgt->m_deviceinfo & DEVINFO_DIRECT_ATTACHED)
15552 != DEVINFO_DIRECT_ATTACHED) {
15553 (void) sprintf(pdev_wwn_str, "w%016"PRIx64,
15554 pdev_sas_wwn);
15555 } else {
15556 /*
15557 * Update the iport's attached-port to guid
15558 */
15559 if (sas_wwn == 0) {
15560 (void) sprintf(wwn_str, "p%x", phy);
15561 } else {
15562 (void) sprintf(wwn_str, "w%016"PRIx64, sas_wwn);
15563 }
15564 if (ddi_prop_update_string(DDI_DEV_T_NONE,
15565 pdip, SCSI_ADDR_PROP_ATTACHED_PORT, wwn_str) !=
15566 DDI_PROP_SUCCESS) {
15567 mptsas_log(mpt, CE_WARN,
15568 "mptsas unable to create "
15569 "property for iport target-port"
15570 " %s (sas_wwn)",
15571 wwn_str);
15572 ndi_rtn = NDI_FAILURE;
15573 goto phys_create_done;
15574 }
15575
15576 (void) sprintf(pdev_wwn_str, "w%016"PRIx64,
15577 mpt->un.m_base_wwid);
15578 }
15579
15580 if (ndi_prop_update_string(DDI_DEV_T_NONE,
15581 *lun_dip, SCSI_ADDR_PROP_ATTACHED_PORT, pdev_wwn_str) !=
15582 DDI_PROP_SUCCESS) {
15583 mptsas_log(mpt, CE_WARN,
15584 "mptsas unable to create "
15585 "property for iport attached-port %s (sas_wwn)",
15586 attached_wwn_str);
15587 ndi_rtn = NDI_FAILURE;
15588 goto phys_create_done;
15589 }
15590
15591 if (IS_SATA_DEVICE(dev_info)) {
15592 if (ndi_prop_update_string(DDI_DEV_T_NONE,
15593 *lun_dip, MPTSAS_VARIANT, "sata") !=
15594 DDI_PROP_SUCCESS) {
15595 mptsas_log(mpt, CE_WARN,
15596 "mptsas unable to create "
15597 "property for device variant ");
15598 ndi_rtn = NDI_FAILURE;
15599 goto phys_create_done;
15600 }
15601 }
15602
15603 if (IS_ATAPI_DEVICE(dev_info)) {
15604 if (ndi_prop_update_string(DDI_DEV_T_NONE,
15605 *lun_dip, MPTSAS_VARIANT, "atapi") !=
15606 DDI_PROP_SUCCESS) {
15607 mptsas_log(mpt, CE_WARN,
15608 "mptsas unable to create "
15609 "property for device variant ");
15610 ndi_rtn = NDI_FAILURE;
15611 goto phys_create_done;
15612 }
15613 }
15614
15615 phys_raid_lun:
15616 /*
15617 * if this is a SAS controller, and the target is a SATA
15618 * drive, set the 'pm-capable' property for sd and if on
15619 * an OPL platform, also check if this is an ATAPI
15620 * device.
15621 */
15622 instance = ddi_get_instance(mpt->m_dip);
15623 if (devinfo & (MPI2_SAS_DEVICE_INFO_SATA_DEVICE |
15624 MPI2_SAS_DEVICE_INFO_ATAPI_DEVICE)) {
15625 NDBG2(("mptsas%d: creating pm-capable property, "
15626 "target %d", instance, target));
15627
15628 if ((ndi_prop_update_int(DDI_DEV_T_NONE,
15629 *lun_dip, "pm-capable", 1)) !=
15630 DDI_PROP_SUCCESS) {
15631 mptsas_log(mpt, CE_WARN, "mptsas "
15632 "failed to create pm-capable "
15633 "property, target %d", target);
15634 ndi_rtn = NDI_FAILURE;
15635 goto phys_create_done;
15636 }
15637
15638 }
15639
15640 if ((inq->inq_dtype == 0) || (inq->inq_dtype == 5)) {
15641 /*
15642 * add 'obp-path' properties for devinfo
15643 */
15644 bzero(wwn_str, sizeof (wwn_str));
15645 (void) sprintf(wwn_str, "%016"PRIx64, sas_wwn);
15646 component = kmem_zalloc(MAXPATHLEN, KM_SLEEP);
15647 if (guid) {
15648 (void) snprintf(component, MAXPATHLEN,
15649 "disk@w%s,%x", wwn_str, lun);
15650 } else {
15651 (void) snprintf(component, MAXPATHLEN,
15652 "disk@p%x,%x", phy, lun);
15653 }
15654 if (ddi_pathname_obp_set(*lun_dip, component)
15655 != DDI_SUCCESS) {
15656 mptsas_log(mpt, CE_WARN, "mpt_sas driver "
15657 "unable to set obp-path for SAS "
15658 "object %s", component);
15659 ndi_rtn = NDI_FAILURE;
15660 goto phys_create_done;
15661 }
15662 }
15663 /*
15664 * Create the phy-num property for non-raid disk
15665 */
15666 if (ptgt->m_addr.mta_phymask != 0) {
15667 if (ndi_prop_update_int(DDI_DEV_T_NONE,
15668 *lun_dip, "phy-num", ptgt->m_phynum) !=
15669 DDI_PROP_SUCCESS) {
15670 mptsas_log(mpt, CE_WARN, "mptsas driver "
15671 "failed to create phy-num property for "
15672 "target %d", target);
15673 ndi_rtn = NDI_FAILURE;
15674 goto phys_create_done;
15675 }
15676 }
15677 phys_create_done:
15678 /*
15679 * If props were setup ok, online the lun
15680 */
15681 if (ndi_rtn == NDI_SUCCESS) {
15682 /*
15683 * Try to online the new node
15684 */
15685 ndi_rtn = ndi_devi_online(*lun_dip, NDI_ONLINE_ATTACH);
15686 }
15687 if (ndi_rtn == NDI_SUCCESS) {
15688 mutex_enter(&mpt->m_mutex);
15689 ptgt->m_led_status = 0;
15690 (void) mptsas_flush_led_status(mpt, ptgt);
15691 mutex_exit(&mpt->m_mutex);
15692 }
15693
15694 /*
15695 * If success set rtn flag, else unwire alloc'd lun
15696 */
15697 if (ndi_rtn != NDI_SUCCESS) {
15698 NDBG12(("mptsas driver unable to online "
15699 "target %d lun %d", target, lun));
15700 ndi_prop_remove_all(*lun_dip);
15701 (void) ndi_devi_free(*lun_dip);
15702 *lun_dip = NULL;
15703 }
15704 }
15705
15706 scsi_hba_nodename_compatible_free(nodename, compatible);
15707
15708 if (wwn_str != NULL) {
15709 kmem_free(wwn_str, MPTSAS_WWN_STRLEN);
15710 }
15711 if (component != NULL) {
15712 kmem_free(component, MAXPATHLEN);
15713 }
15714
15715
15716 return ((ndi_rtn == NDI_SUCCESS) ? DDI_SUCCESS : DDI_FAILURE);
15717 }
15718
15719 static int
15720 mptsas_probe_smp(dev_info_t *pdip, uint64_t wwn)
15721 {
15722 mptsas_t *mpt = DIP2MPT(pdip);
15723 struct smp_device smp_sd;
15724
15725 /* XXX An HBA driver should not be allocating an smp_device. */
15726 bzero(&smp_sd, sizeof (struct smp_device));
15727 smp_sd.smp_sd_address.smp_a_hba_tran = mpt->m_smptran;
15728 bcopy(&wwn, smp_sd.smp_sd_address.smp_a_wwn, SAS_WWN_BYTE_SIZE);
15729
15730 if (smp_probe(&smp_sd) != DDI_PROBE_SUCCESS)
15731 return (NDI_FAILURE);
15732 return (NDI_SUCCESS);
15733 }
15734
15735 static int
15736 mptsas_config_smp(dev_info_t *pdip, uint64_t sas_wwn, dev_info_t **smp_dip)
15737 {
15738 mptsas_t *mpt = DIP2MPT(pdip);
15739 mptsas_smp_t *psmp = NULL;
15740 int rval;
15741 int phymask;
15742
15743 /*
15744 * Get the physical port associated to the iport
15745 * PHYMASK TODO
15746 */
15747 phymask = ddi_prop_get_int(DDI_DEV_T_ANY, pdip, 0,
15748 "phymask", 0);
15749 /*
15750 * Find the smp node in hash table with specified sas address and
15751 * physical port
15752 */
15753 psmp = mptsas_wwid_to_psmp(mpt, phymask, sas_wwn);
15754 if (psmp == NULL) {
15755 return (DDI_FAILURE);
15756 }
15757
15758 rval = mptsas_online_smp(pdip, psmp, smp_dip);
15759
15760 return (rval);
15761 }
15762
15763 static int
15764 mptsas_online_smp(dev_info_t *pdip, mptsas_smp_t *smp_node,
15765 dev_info_t **smp_dip)
15766 {
15767 char wwn_str[MPTSAS_WWN_STRLEN];
15768 char attached_wwn_str[MPTSAS_WWN_STRLEN];
15769 int ndi_rtn = NDI_FAILURE;
15770 int rval = 0;
15771 mptsas_smp_t dev_info;
15772 uint32_t page_address;
15773 mptsas_t *mpt = DIP2MPT(pdip);
15774 uint16_t dev_hdl;
15775 uint64_t sas_wwn;
15776 uint64_t smp_sas_wwn;
15777 uint8_t physport;
15778 uint8_t phy_id;
15779 uint16_t pdev_hdl;
15780 uint8_t numphys = 0;
15781 uint16_t i = 0;
15782 char phymask[MPTSAS_MAX_PHYS];
15783 char *iport = NULL;
15784 mptsas_phymask_t phy_mask = 0;
15785 uint16_t attached_devhdl;
15786 uint16_t bay_num, enclosure, io_flags;
15787
15788 (void) sprintf(wwn_str, "%"PRIx64, smp_node->m_addr.mta_wwn);
15789
15790 /*
15791 * Probe smp device, prevent the node of removed device from being
15792 * configured succesfully
15793 */
15794 if (mptsas_probe_smp(pdip, smp_node->m_addr.mta_wwn) != NDI_SUCCESS) {
15795 return (DDI_FAILURE);
15796 }
15797
15798 if ((*smp_dip = mptsas_find_smp_child(pdip, wwn_str)) != NULL) {
15799 return (DDI_SUCCESS);
15800 }
15801
15802 ndi_rtn = ndi_devi_alloc(pdip, "smp", DEVI_SID_NODEID, smp_dip);
15803
15804 /*
15805 * if lun alloc success, set props
15806 */
15807 if (ndi_rtn == NDI_SUCCESS) {
15808 /*
15809 * Set the flavor of the child to be SMP flavored
15810 */
15811 ndi_flavor_set(*smp_dip, SCSA_FLAVOR_SMP);
15812
15813 if (ndi_prop_update_string(DDI_DEV_T_NONE,
15814 *smp_dip, SMP_WWN, wwn_str) !=
15815 DDI_PROP_SUCCESS) {
15816 mptsas_log(mpt, CE_WARN, "mptsas unable to create "
15817 "property for smp device %s (sas_wwn)",
15818 wwn_str);
15819 ndi_rtn = NDI_FAILURE;
15820 goto smp_create_done;
15821 }
15822 (void) sprintf(wwn_str, "w%"PRIx64, smp_node->m_addr.mta_wwn);
15823 if (ndi_prop_update_string(DDI_DEV_T_NONE,
15824 *smp_dip, SCSI_ADDR_PROP_TARGET_PORT, wwn_str) !=
15825 DDI_PROP_SUCCESS) {
15826 mptsas_log(mpt, CE_WARN, "mptsas unable to create "
15827 "property for iport target-port %s (sas_wwn)",
15828 wwn_str);
15829 ndi_rtn = NDI_FAILURE;
15830 goto smp_create_done;
15831 }
15832
15833 mutex_enter(&mpt->m_mutex);
15834
15835 page_address = (MPI2_SAS_EXPAND_PGAD_FORM_HNDL &
15836 MPI2_SAS_EXPAND_PGAD_FORM_MASK) | smp_node->m_devhdl;
15837 rval = mptsas_get_sas_expander_page0(mpt, page_address,
15838 &dev_info);
15839 if (rval != DDI_SUCCESS) {
15840 mutex_exit(&mpt->m_mutex);
15841 mptsas_log(mpt, CE_WARN,
15842 "mptsas unable to get expander "
15843 "parent device info for %x", page_address);
15844 ndi_rtn = NDI_FAILURE;
15845 goto smp_create_done;
15846 }
15847
15848 smp_node->m_pdevhdl = dev_info.m_pdevhdl;
15849 page_address = (MPI2_SAS_DEVICE_PGAD_FORM_HANDLE &
15850 MPI2_SAS_DEVICE_PGAD_FORM_MASK) |
15851 (uint32_t)dev_info.m_pdevhdl;
15852 rval = mptsas_get_sas_device_page0(mpt, page_address,
15853 &dev_hdl, &sas_wwn, &smp_node->m_pdevinfo, &physport,
15854 &phy_id, &pdev_hdl, &bay_num, &enclosure, &io_flags);
15855 if (rval != DDI_SUCCESS) {
15856 mutex_exit(&mpt->m_mutex);
15857 mptsas_log(mpt, CE_WARN, "mptsas unable to get "
15858 "device info for %x", page_address);
15859 ndi_rtn = NDI_FAILURE;
15860 goto smp_create_done;
15861 }
15862
15863 page_address = (MPI2_SAS_DEVICE_PGAD_FORM_HANDLE &
15864 MPI2_SAS_DEVICE_PGAD_FORM_MASK) |
15865 (uint32_t)dev_info.m_devhdl;
15866 rval = mptsas_get_sas_device_page0(mpt, page_address,
15867 &dev_hdl, &smp_sas_wwn, &smp_node->m_deviceinfo,
15868 &physport, &phy_id, &pdev_hdl, &bay_num, &enclosure,
15869 &io_flags);
15870 if (rval != DDI_SUCCESS) {
15871 mutex_exit(&mpt->m_mutex);
15872 mptsas_log(mpt, CE_WARN, "mptsas unable to get "
15873 "device info for %x", page_address);
15874 ndi_rtn = NDI_FAILURE;
15875 goto smp_create_done;
15876 }
15877 mutex_exit(&mpt->m_mutex);
15878
15879 /*
15880 * If this smp direct attached to the controller
15881 * set the attached-port to the base wwid
15882 */
15883 if ((smp_node->m_deviceinfo & DEVINFO_DIRECT_ATTACHED)
15884 != DEVINFO_DIRECT_ATTACHED) {
15885 (void) sprintf(attached_wwn_str, "w%016"PRIx64,
15886 sas_wwn);
15887 } else {
15888 (void) sprintf(attached_wwn_str, "w%016"PRIx64,
15889 mpt->un.m_base_wwid);
15890 }
15891
15892 if (ndi_prop_update_string(DDI_DEV_T_NONE,
15893 *smp_dip, SCSI_ADDR_PROP_ATTACHED_PORT, attached_wwn_str) !=
15894 DDI_PROP_SUCCESS) {
15895 mptsas_log(mpt, CE_WARN, "mptsas unable to create "
15896 "property for smp attached-port %s (sas_wwn)",
15897 attached_wwn_str);
15898 ndi_rtn = NDI_FAILURE;
15899 goto smp_create_done;
15900 }
15901
15902 if (ndi_prop_create_boolean(DDI_DEV_T_NONE,
15903 *smp_dip, SMP_PROP) != DDI_PROP_SUCCESS) {
15904 mptsas_log(mpt, CE_WARN, "mptsas unable to "
15905 "create property for SMP %s (SMP_PROP) ",
15906 wwn_str);
15907 ndi_rtn = NDI_FAILURE;
15908 goto smp_create_done;
15909 }
15910
15911 /*
15912 * check the smp to see whether it direct
15913 * attached to the controller
15914 */
15915 if ((smp_node->m_deviceinfo & DEVINFO_DIRECT_ATTACHED)
15916 != DEVINFO_DIRECT_ATTACHED) {
15917 goto smp_create_done;
15918 }
15919 numphys = ddi_prop_get_int(DDI_DEV_T_ANY, pdip,
15920 DDI_PROP_DONTPASS, MPTSAS_NUM_PHYS, -1);
15921 if (numphys > 0) {
15922 goto smp_create_done;
15923 }
15924 /*
15925 * this iport is an old iport, we need to
15926 * reconfig the props for it.
15927 */
15928 if (ddi_prop_update_int(DDI_DEV_T_NONE, pdip,
15929 MPTSAS_VIRTUAL_PORT, 0) !=
15930 DDI_PROP_SUCCESS) {
15931 (void) ddi_prop_remove(DDI_DEV_T_NONE, pdip,
15932 MPTSAS_VIRTUAL_PORT);
15933 mptsas_log(mpt, CE_WARN, "mptsas virtual port "
15934 "prop update failed");
15935 goto smp_create_done;
15936 }
15937
15938 mutex_enter(&mpt->m_mutex);
15939 numphys = 0;
15940 iport = ddi_get_name_addr(pdip);
15941 for (i = 0; i < MPTSAS_MAX_PHYS; i++) {
15942 bzero(phymask, sizeof (phymask));
15943 (void) sprintf(phymask,
15944 "%x", mpt->m_phy_info[i].phy_mask);
15945 if (strcmp(phymask, iport) == 0) {
15946 phy_mask = mpt->m_phy_info[i].phy_mask;
15947 break;
15948 }
15949 }
15950
15951 for (i = 0; i < MPTSAS_MAX_PHYS; i++) {
15952 if ((phy_mask >> i) & 0x01) {
15953 numphys++;
15954 }
15955 }
15956 /*
15957 * Update PHY info for smhba
15958 */
15959 if (mptsas_smhba_phy_init(mpt)) {
15960 mutex_exit(&mpt->m_mutex);
15961 mptsas_log(mpt, CE_WARN, "mptsas phy update "
15962 "failed");
15963 goto smp_create_done;
15964 }
15965 mutex_exit(&mpt->m_mutex);
15966
15967 mptsas_smhba_set_all_phy_props(mpt, pdip, numphys, phy_mask,
15968 &attached_devhdl);
15969
15970 if (ddi_prop_update_int(DDI_DEV_T_NONE, pdip,
15971 MPTSAS_NUM_PHYS, numphys) !=
15972 DDI_PROP_SUCCESS) {
15973 (void) ddi_prop_remove(DDI_DEV_T_NONE, pdip,
15974 MPTSAS_NUM_PHYS);
15975 mptsas_log(mpt, CE_WARN, "mptsas update "
15976 "num phys props failed");
15977 goto smp_create_done;
15978 }
15979 /*
15980 * Add parent's props for SMHBA support
15981 */
15982 if (ddi_prop_update_string(DDI_DEV_T_NONE, pdip,
15983 SCSI_ADDR_PROP_ATTACHED_PORT, wwn_str) !=
15984 DDI_PROP_SUCCESS) {
15985 (void) ddi_prop_remove(DDI_DEV_T_NONE, pdip,
15986 SCSI_ADDR_PROP_ATTACHED_PORT);
15987 mptsas_log(mpt, CE_WARN, "mptsas update iport"
15988 "attached-port failed");
15989 goto smp_create_done;
15990 }
15991
15992 smp_create_done:
15993 /*
15994 * If props were setup ok, online the lun
15995 */
15996 if (ndi_rtn == NDI_SUCCESS) {
15997 /*
15998 * Try to online the new node
15999 */
16000 ndi_rtn = ndi_devi_online(*smp_dip, NDI_ONLINE_ATTACH);
16001 }
16002
16003 /*
16004 * If success set rtn flag, else unwire alloc'd lun
16005 */
16006 if (ndi_rtn != NDI_SUCCESS) {
16007 NDBG12(("mptsas unable to online "
16008 "SMP target %s", wwn_str));
16009 ndi_prop_remove_all(*smp_dip);
16010 (void) ndi_devi_free(*smp_dip);
16011 }
16012 }
16013
16014 return ((ndi_rtn == NDI_SUCCESS) ? DDI_SUCCESS : DDI_FAILURE);
16015 }
16016
16017 /* smp transport routine */
16018 static int mptsas_smp_start(struct smp_pkt *smp_pkt)
16019 {
16020 uint64_t wwn;
16021 Mpi2SmpPassthroughRequest_t req;
16022 Mpi2SmpPassthroughReply_t rep;
16023 uint32_t direction = 0;
16024 mptsas_t *mpt;
16025 int ret;
16026 uint64_t tmp64;
16027
16028 mpt = (mptsas_t *)smp_pkt->smp_pkt_address->
16029 smp_a_hba_tran->smp_tran_hba_private;
16030
16031 bcopy(smp_pkt->smp_pkt_address->smp_a_wwn, &wwn, SAS_WWN_BYTE_SIZE);
16032 /*
16033 * Need to compose a SMP request message
16034 * and call mptsas_do_passthru() function
16035 */
16036 bzero(&req, sizeof (req));
16037 bzero(&rep, sizeof (rep));
16038 req.PassthroughFlags = 0;
16039 req.PhysicalPort = 0xff;
16040 req.ChainOffset = 0;
16041 req.Function = MPI2_FUNCTION_SMP_PASSTHROUGH;
16042
16043 if ((smp_pkt->smp_pkt_reqsize & 0xffff0000ul) != 0) {
16044 smp_pkt->smp_pkt_reason = ERANGE;
16045 return (DDI_FAILURE);
16046 }
16047 req.RequestDataLength = LE_16((uint16_t)(smp_pkt->smp_pkt_reqsize - 4));
16048
16049 req.MsgFlags = 0;
16050 tmp64 = LE_64(wwn);
16051 bcopy(&tmp64, &req.SASAddress, SAS_WWN_BYTE_SIZE);
16052 if (smp_pkt->smp_pkt_rspsize > 0) {
16053 direction |= MPTSAS_PASS_THRU_DIRECTION_READ;
16054 }
16055 if (smp_pkt->smp_pkt_reqsize > 0) {
16056 direction |= MPTSAS_PASS_THRU_DIRECTION_WRITE;
16057 }
16058
16059 mutex_enter(&mpt->m_mutex);
16060 ret = mptsas_do_passthru(mpt, (uint8_t *)&req, (uint8_t *)&rep,
16061 (uint8_t *)smp_pkt->smp_pkt_rsp,
16062 offsetof(Mpi2SmpPassthroughRequest_t, SGL), sizeof (rep),
16063 smp_pkt->smp_pkt_rspsize - 4, direction,
16064 (uint8_t *)smp_pkt->smp_pkt_req, smp_pkt->smp_pkt_reqsize - 4,
16065 smp_pkt->smp_pkt_timeout, FKIOCTL);
16066 mutex_exit(&mpt->m_mutex);
16067 if (ret != 0) {
16068 cmn_err(CE_WARN, "smp_start do passthru error %d", ret);
16069 smp_pkt->smp_pkt_reason = (uchar_t)(ret);
16070 return (DDI_FAILURE);
16071 }
16072 /* do passthrough success, check the smp status */
16073 if (LE_16(rep.IOCStatus) != MPI2_IOCSTATUS_SUCCESS) {
16074 switch (LE_16(rep.IOCStatus)) {
16075 case MPI2_IOCSTATUS_SCSI_DEVICE_NOT_THERE:
16076 smp_pkt->smp_pkt_reason = ENODEV;
16077 break;
16078 case MPI2_IOCSTATUS_SAS_SMP_DATA_OVERRUN:
16079 smp_pkt->smp_pkt_reason = EOVERFLOW;
16080 break;
16081 case MPI2_IOCSTATUS_SAS_SMP_REQUEST_FAILED:
16082 smp_pkt->smp_pkt_reason = EIO;
16083 break;
16084 default:
16085 mptsas_log(mpt, CE_NOTE, "smp_start: get unknown ioc"
16086 "status:%x", LE_16(rep.IOCStatus));
16087 smp_pkt->smp_pkt_reason = EIO;
16088 break;
16089 }
16090 return (DDI_FAILURE);
16091 }
16092 if (rep.SASStatus != MPI2_SASSTATUS_SUCCESS) {
16093 mptsas_log(mpt, CE_NOTE, "smp_start: get error SAS status:%x",
16094 rep.SASStatus);
16095 smp_pkt->smp_pkt_reason = EIO;
16096 return (DDI_FAILURE);
16097 }
16098
16099 return (DDI_SUCCESS);
16100 }
16101
16102 /*
16103 * If we didn't get a match, we need to get sas page0 for each device, and
16104 * untill we get a match. If failed, return NULL
16105 */
16106 static mptsas_target_t *
16107 mptsas_phy_to_tgt(mptsas_t *mpt, mptsas_phymask_t phymask, uint8_t phy)
16108 {
16109 int i, j = 0;
16110 int rval = 0;
16111 uint16_t cur_handle;
16112 uint32_t page_address;
16113 mptsas_target_t *ptgt = NULL;
16114
16115 /*
16116 * PHY named device must be direct attached and attaches to
16117 * narrow port, if the iport is not parent of the device which
16118 * we are looking for.
16119 */
16120 for (i = 0; i < MPTSAS_MAX_PHYS; i++) {
16121 if ((1 << i) & phymask)
16122 j++;
16123 }
16124
16125 if (j > 1)
16126 return (NULL);
16127
16128 /*
16129 * Must be a narrow port and single device attached to the narrow port
16130 * So the physical port num of device which is equal to the iport's
16131 * port num is the device what we are looking for.
16132 */
16133
16134 if (mpt->m_phy_info[phy].phy_mask != phymask)
16135 return (NULL);
16136
16137 mutex_enter(&mpt->m_mutex);
16138
16139 ptgt = refhash_linear_search(mpt->m_targets, mptsas_target_eval_nowwn,
16140 &phy);
16141 if (ptgt != NULL) {
16142 mutex_exit(&mpt->m_mutex);
16143 return (ptgt);
16144 }
16145
16146 if (mpt->m_done_traverse_dev) {
16147 mutex_exit(&mpt->m_mutex);
16148 return (NULL);
16149 }
16150
16151 /* If didn't get a match, come here */
16152 cur_handle = mpt->m_dev_handle;
16153 for (; ; ) {
16154 ptgt = NULL;
16155 page_address = (MPI2_SAS_DEVICE_PGAD_FORM_GET_NEXT_HANDLE &
16156 MPI2_SAS_DEVICE_PGAD_FORM_MASK) | (uint32_t)cur_handle;
16157 rval = mptsas_get_target_device_info(mpt, page_address,
16158 &cur_handle, &ptgt);
16159 if ((rval == DEV_INFO_FAIL_PAGE0) ||
16160 (rval == DEV_INFO_FAIL_ALLOC) ||
16161 (rval == DEV_INFO_FAIL_GUID)) {
16162 break;
16163 }
16164 if ((rval == DEV_INFO_WRONG_DEVICE_TYPE) ||
16165 (rval == DEV_INFO_PHYS_DISK)) {
16166 continue;
16167 }
16168 mpt->m_dev_handle = cur_handle;
16169
16170 if ((ptgt->m_addr.mta_wwn == 0) && (ptgt->m_phynum == phy)) {
16171 break;
16172 }
16173 }
16174
16175 mutex_exit(&mpt->m_mutex);
16176 return (ptgt);
16177 }
16178
16179 /*
16180 * The ptgt->m_addr.mta_wwn contains the wwid for each disk.
16181 * For Raid volumes, we need to check m_raidvol[x].m_raidwwid
16182 * If we didn't get a match, we need to get sas page0 for each device, and
16183 * untill we get a match
16184 * If failed, return NULL
16185 */
16186 static mptsas_target_t *
16187 mptsas_wwid_to_ptgt(mptsas_t *mpt, mptsas_phymask_t phymask, uint64_t wwid)
16188 {
16189 int rval = 0;
16190 uint16_t cur_handle;
16191 uint32_t page_address;
16192 mptsas_target_t *tmp_tgt = NULL;
16193 mptsas_target_addr_t addr;
16194
16195 addr.mta_wwn = wwid;
16196 addr.mta_phymask = phymask;
16197 mutex_enter(&mpt->m_mutex);
16198 tmp_tgt = refhash_lookup(mpt->m_targets, &addr);
16199 if (tmp_tgt != NULL) {
16200 mutex_exit(&mpt->m_mutex);
16201 return (tmp_tgt);
16202 }
16203
16204 if (phymask == 0) {
16205 /*
16206 * It's IR volume
16207 */
16208 rval = mptsas_get_raid_info(mpt);
16209 if (rval) {
16210 tmp_tgt = refhash_lookup(mpt->m_targets, &addr);
16211 }
16212 mutex_exit(&mpt->m_mutex);
16213 return (tmp_tgt);
16214 }
16215
16216 if (mpt->m_done_traverse_dev) {
16217 mutex_exit(&mpt->m_mutex);
16218 return (NULL);
16219 }
16220
16221 /* If didn't get a match, come here */
16222 cur_handle = mpt->m_dev_handle;
16223 for (;;) {
16224 tmp_tgt = NULL;
16225 page_address = (MPI2_SAS_DEVICE_PGAD_FORM_GET_NEXT_HANDLE &
16226 MPI2_SAS_DEVICE_PGAD_FORM_MASK) | cur_handle;
16227 rval = mptsas_get_target_device_info(mpt, page_address,
16228 &cur_handle, &tmp_tgt);
16229 if ((rval == DEV_INFO_FAIL_PAGE0) ||
16230 (rval == DEV_INFO_FAIL_ALLOC) ||
16231 (rval == DEV_INFO_FAIL_GUID)) {
16232 tmp_tgt = NULL;
16233 break;
16234 }
16235 if ((rval == DEV_INFO_WRONG_DEVICE_TYPE) ||
16236 (rval == DEV_INFO_PHYS_DISK)) {
16237 continue;
16238 }
16239 mpt->m_dev_handle = cur_handle;
16240 if ((tmp_tgt->m_addr.mta_wwn) &&
16241 (tmp_tgt->m_addr.mta_wwn == wwid) &&
16242 (tmp_tgt->m_addr.mta_phymask == phymask)) {
16243 break;
16244 }
16245 }
16246
16247 mutex_exit(&mpt->m_mutex);
16248 return (tmp_tgt);
16249 }
16250
16251 static mptsas_smp_t *
16252 mptsas_wwid_to_psmp(mptsas_t *mpt, mptsas_phymask_t phymask, uint64_t wwid)
16253 {
16254 int rval = 0;
16255 uint16_t cur_handle;
16256 uint32_t page_address;
16257 mptsas_smp_t smp_node, *psmp = NULL;
16258 mptsas_target_addr_t addr;
16259
16260 addr.mta_wwn = wwid;
16261 addr.mta_phymask = phymask;
16262 mutex_enter(&mpt->m_mutex);
16263 psmp = refhash_lookup(mpt->m_smp_targets, &addr);
16264 if (psmp != NULL) {
16265 mutex_exit(&mpt->m_mutex);
16266 return (psmp);
16267 }
16268
16269 if (mpt->m_done_traverse_smp) {
16270 mutex_exit(&mpt->m_mutex);
16271 return (NULL);
16272 }
16273
16274 /* If didn't get a match, come here */
16275 cur_handle = mpt->m_smp_devhdl;
16276 for (;;) {
16277 psmp = NULL;
16278 page_address = (MPI2_SAS_EXPAND_PGAD_FORM_GET_NEXT_HNDL &
16279 MPI2_SAS_EXPAND_PGAD_FORM_MASK) | (uint32_t)cur_handle;
16280 rval = mptsas_get_sas_expander_page0(mpt, page_address,
16281 &smp_node);
16282 if (rval != DDI_SUCCESS) {
16283 break;
16284 }
16285 mpt->m_smp_devhdl = cur_handle = smp_node.m_devhdl;
16286 psmp = mptsas_smp_alloc(mpt, &smp_node);
16287 ASSERT(psmp);
16288 if ((psmp->m_addr.mta_wwn) && (psmp->m_addr.mta_wwn == wwid) &&
16289 (psmp->m_addr.mta_phymask == phymask)) {
16290 break;
16291 }
16292 }
16293
16294 mutex_exit(&mpt->m_mutex);
16295 return (psmp);
16296 }
16297
16298 mptsas_target_t *
16299 mptsas_tgt_alloc(refhash_t *refhash, uint16_t devhdl, uint64_t wwid,
16300 uint32_t devinfo, mptsas_phymask_t phymask, uint8_t phynum)
16301 {
16302 mptsas_target_t *tmp_tgt = NULL;
16303 mptsas_target_addr_t addr;
16304
16305 addr.mta_wwn = wwid;
16306 addr.mta_phymask = phymask;
16307 tmp_tgt = refhash_lookup(refhash, &addr);
16308 if (tmp_tgt != NULL) {
16309 NDBG20(("Hash item already exist"));
16310 tmp_tgt->m_deviceinfo = devinfo;
16311 tmp_tgt->m_devhdl = devhdl; /* XXX - duplicate? */
16312 return (tmp_tgt);
16313 }
16314 tmp_tgt = kmem_zalloc(sizeof (struct mptsas_target), KM_SLEEP);
16315 if (tmp_tgt == NULL) {
16316 cmn_err(CE_WARN, "Fatal, allocated tgt failed");
16317 return (NULL);
16318 }
16319 tmp_tgt->m_devhdl = devhdl;
16320 tmp_tgt->m_addr.mta_wwn = wwid;
16321 tmp_tgt->m_deviceinfo = devinfo;
16322 tmp_tgt->m_addr.mta_phymask = phymask;
16323 tmp_tgt->m_phynum = phynum;
16324 /* Initialized the tgt structure */
16325 tmp_tgt->m_qfull_retries = QFULL_RETRIES;
16326 tmp_tgt->m_qfull_retry_interval =
16327 drv_usectohz(QFULL_RETRY_INTERVAL * 1000);
16328 tmp_tgt->m_t_throttle = MAX_THROTTLE;
16329 TAILQ_INIT(&tmp_tgt->m_active_cmdq);
16330
16331 refhash_insert(refhash, tmp_tgt);
16332
16333 return (tmp_tgt);
16334 }
16335
16336 static void
16337 mptsas_smp_target_copy(mptsas_smp_t *src, mptsas_smp_t *dst)
16338 {
16339 dst->m_devhdl = src->m_devhdl;
16340 dst->m_deviceinfo = src->m_deviceinfo;
16341 dst->m_pdevhdl = src->m_pdevhdl;
16342 dst->m_pdevinfo = src->m_pdevinfo;
16343 }
16344
16345 static mptsas_smp_t *
16346 mptsas_smp_alloc(mptsas_t *mpt, mptsas_smp_t *data)
16347 {
16348 mptsas_target_addr_t addr;
16349 mptsas_smp_t *ret_data;
16350
16351 addr.mta_wwn = data->m_addr.mta_wwn;
16352 addr.mta_phymask = data->m_addr.mta_phymask;
16353 ret_data = refhash_lookup(mpt->m_smp_targets, &addr);
16354 /*
16355 * If there's already a matching SMP target, update its fields
16356 * in place. Since the address is not changing, it's safe to do
16357 * this. We cannot just bcopy() here because the structure we've
16358 * been given has invalid hash links.
16359 */
16360 if (ret_data != NULL) {
16361 mptsas_smp_target_copy(data, ret_data);
16362 return (ret_data);
16363 }
16364
16365 ret_data = kmem_alloc(sizeof (mptsas_smp_t), KM_SLEEP);
16366 bcopy(data, ret_data, sizeof (mptsas_smp_t));
16367 refhash_insert(mpt->m_smp_targets, ret_data);
16368 return (ret_data);
16369 }
16370
16371 /*
16372 * Functions for SGPIO LED support
16373 */
16374 static dev_info_t *
16375 mptsas_get_dip_from_dev(dev_t dev, mptsas_phymask_t *phymask)
16376 {
16377 dev_info_t *dip;
16378 int prop;
16379 dip = e_ddi_hold_devi_by_dev(dev, 0);
16380 if (dip == NULL)
16381 return (dip);
16382 prop = ddi_prop_get_int(DDI_DEV_T_ANY, dip, 0,
16383 "phymask", 0);
16384 *phymask = (mptsas_phymask_t)prop;
16385 ddi_release_devi(dip);
16386 return (dip);
16387 }
16388 static mptsas_target_t *
16389 mptsas_addr_to_ptgt(mptsas_t *mpt, char *addr, mptsas_phymask_t phymask)
16390 {
16391 uint8_t phynum;
16392 uint64_t wwn;
16393 int lun;
16394 mptsas_target_t *ptgt = NULL;
16395
16396 if (mptsas_parse_address(addr, &wwn, &phynum, &lun) != DDI_SUCCESS) {
16397 return (NULL);
16398 }
16399 if (addr[0] == 'w') {
16400 ptgt = mptsas_wwid_to_ptgt(mpt, (int)phymask, wwn);
16401 } else {
16402 ptgt = mptsas_phy_to_tgt(mpt, (int)phymask, phynum);
16403 }
16404 return (ptgt);
16405 }
16406
16407 static int
16408 mptsas_flush_led_status(mptsas_t *mpt, mptsas_target_t *ptgt)
16409 {
16410 uint32_t slotstatus = 0;
16411
16412 /* Build an MPI2 Slot Status based on our view of the world */
16413 if (ptgt->m_led_status & (1 << (MPTSAS_LEDCTL_LED_IDENT - 1)))
16414 slotstatus |= MPI2_SEP_REQ_SLOTSTATUS_IDENTIFY_REQUEST;
16415 if (ptgt->m_led_status & (1 << (MPTSAS_LEDCTL_LED_FAIL - 1)))
16416 slotstatus |= MPI2_SEP_REQ_SLOTSTATUS_PREDICTED_FAULT;
16417 if (ptgt->m_led_status & (1 << (MPTSAS_LEDCTL_LED_OK2RM - 1)))
16418 slotstatus |= MPI2_SEP_REQ_SLOTSTATUS_REQUEST_REMOVE;
16419
16420 /* Write it to the controller */
16421 NDBG14(("mptsas_ioctl: set LED status %x for slot %x",
16422 slotstatus, ptgt->m_slot_num));
16423 return (mptsas_send_sep(mpt, ptgt, &slotstatus,
16424 MPI2_SEP_REQ_ACTION_WRITE_STATUS));
16425 }
16426
16427 /*
16428 * send sep request, use enclosure/slot addressing
16429 */
16430 static int
16431 mptsas_send_sep(mptsas_t *mpt, mptsas_target_t *ptgt,
16432 uint32_t *status, uint8_t act)
16433 {
16434 Mpi2SepRequest_t req;
16435 Mpi2SepReply_t rep;
16436 int ret;
16437
16438 ASSERT(mutex_owned(&mpt->m_mutex));
16439
16440 /*
16441 * We only support SEP control of directly-attached targets, in which
16442 * case the "SEP" we're talking to is a virtual one contained within
16443 * the HBA itself. This is necessary because DA targets typically have
16444 * no other mechanism for LED control. Targets for which a separate
16445 * enclosure service processor exists should be controlled via ses(7d)
16446 * or sgen(7d). Furthermore, since such requests can time out, they
16447 * should be made in user context rather than in response to
16448 * asynchronous fabric changes.
16449 *
16450 * In addition, we do not support this operation for RAID volumes,
16451 * since there is no slot associated with them.
16452 */
16453 if (!(ptgt->m_deviceinfo & DEVINFO_DIRECT_ATTACHED) ||
16454 ptgt->m_addr.mta_phymask == 0) {
16455 return (ENOTTY);
16456 }
16457
16458 bzero(&req, sizeof (req));
16459 bzero(&rep, sizeof (rep));
16460
16461 req.Function = MPI2_FUNCTION_SCSI_ENCLOSURE_PROCESSOR;
16462 req.Action = act;
16463 req.Flags = MPI2_SEP_REQ_FLAGS_ENCLOSURE_SLOT_ADDRESS;
16464 req.EnclosureHandle = LE_16(ptgt->m_enclosure);
16465 req.Slot = LE_16(ptgt->m_slot_num);
16466 if (act == MPI2_SEP_REQ_ACTION_WRITE_STATUS) {
16467 req.SlotStatus = LE_32(*status);
16468 }
16469 ret = mptsas_do_passthru(mpt, (uint8_t *)&req, (uint8_t *)&rep, NULL,
16470 sizeof (req), sizeof (rep), NULL, 0, NULL, 0, 60, FKIOCTL);
16471 if (ret != 0) {
16472 mptsas_log(mpt, CE_NOTE, "mptsas_send_sep: passthru SEP "
16473 "Processor Request message error %d", ret);
16474 return (ret);
16475 }
16476 /* do passthrough success, check the ioc status */
16477 if (LE_16(rep.IOCStatus) != MPI2_IOCSTATUS_SUCCESS) {
16478 mptsas_log(mpt, CE_NOTE, "send_sep act %x: ioc "
16479 "status:%x loginfo %x", act, LE_16(rep.IOCStatus),
16480 LE_32(rep.IOCLogInfo));
16481 switch (LE_16(rep.IOCStatus) & MPI2_IOCSTATUS_MASK) {
16482 case MPI2_IOCSTATUS_INVALID_FUNCTION:
16483 case MPI2_IOCSTATUS_INVALID_VPID:
16484 case MPI2_IOCSTATUS_INVALID_FIELD:
16485 case MPI2_IOCSTATUS_INVALID_STATE:
16486 case MPI2_IOCSTATUS_OP_STATE_NOT_SUPPORTED:
16487 case MPI2_IOCSTATUS_CONFIG_INVALID_ACTION:
16488 case MPI2_IOCSTATUS_CONFIG_INVALID_TYPE:
16489 case MPI2_IOCSTATUS_CONFIG_INVALID_PAGE:
16490 case MPI2_IOCSTATUS_CONFIG_INVALID_DATA:
16491 case MPI2_IOCSTATUS_CONFIG_NO_DEFAULTS:
16492 return (EINVAL);
16493 case MPI2_IOCSTATUS_BUSY:
16494 return (EBUSY);
16495 case MPI2_IOCSTATUS_INSUFFICIENT_RESOURCES:
16496 return (EAGAIN);
16497 case MPI2_IOCSTATUS_INVALID_SGL:
16498 case MPI2_IOCSTATUS_INTERNAL_ERROR:
16499 case MPI2_IOCSTATUS_CONFIG_CANT_COMMIT:
16500 default:
16501 return (EIO);
16502 }
16503 }
16504 if (act != MPI2_SEP_REQ_ACTION_WRITE_STATUS) {
16505 *status = LE_32(rep.SlotStatus);
16506 }
16507
16508 return (0);
16509 }
16510
16511 int
16512 mptsas_dma_addr_create(mptsas_t *mpt, ddi_dma_attr_t dma_attr,
16513 ddi_dma_handle_t *dma_hdp, ddi_acc_handle_t *acc_hdp, caddr_t *dma_memp,
16514 uint32_t alloc_size, ddi_dma_cookie_t *cookiep)
16515 {
16516 ddi_dma_cookie_t new_cookie;
16517 size_t alloc_len;
16518 uint_t ncookie;
16519
16520 if (cookiep == NULL)
16521 cookiep = &new_cookie;
16522
16523 if (ddi_dma_alloc_handle(mpt->m_dip, &dma_attr, DDI_DMA_SLEEP,
16524 NULL, dma_hdp) != DDI_SUCCESS) {
16525 return (FALSE);
16526 }
16527
16528 if (ddi_dma_mem_alloc(*dma_hdp, alloc_size, &mpt->m_dev_acc_attr,
16529 DDI_DMA_CONSISTENT, DDI_DMA_SLEEP, NULL, dma_memp, &alloc_len,
16530 acc_hdp) != DDI_SUCCESS) {
16531 ddi_dma_free_handle(dma_hdp);
16532 *dma_hdp = NULL;
16533 return (FALSE);
16534 }
16535
16536 if (ddi_dma_addr_bind_handle(*dma_hdp, NULL, *dma_memp, alloc_len,
16537 (DDI_DMA_RDWR | DDI_DMA_CONSISTENT), DDI_DMA_SLEEP, NULL,
16538 cookiep, &ncookie) != DDI_DMA_MAPPED) {
16539 (void) ddi_dma_mem_free(acc_hdp);
16540 ddi_dma_free_handle(dma_hdp);
16541 *dma_hdp = NULL;
16542 return (FALSE);
16543 }
16544
16545 return (TRUE);
16546 }
16547
16548 void
16549 mptsas_dma_addr_destroy(ddi_dma_handle_t *dma_hdp, ddi_acc_handle_t *acc_hdp)
16550 {
16551 if (*dma_hdp == NULL)
16552 return;
16553
16554 (void) ddi_dma_unbind_handle(*dma_hdp);
16555 (void) ddi_dma_mem_free(acc_hdp);
16556 ddi_dma_free_handle(dma_hdp);
16557 *dma_hdp = NULL;
16558 }