4600a1b3144e4de748d33fed54fb16849d9dc4bd
[dragonfly.git] / sys / dev / raid / asr / asr.c
1 /* $FreeBSD: src/sys/dev/asr/asr.c,v 1.3.2.2 2001/08/23 05:21:29 scottl Exp $ */
2 /* $DragonFly: src/sys/dev/raid/asr/asr.c,v 1.31 2007/12/23 07:00:56 pavalos Exp $ */
3 /*
4  * Copyright (c) 1996-2000 Distributed Processing Technology Corporation
5  * Copyright (c) 2000-2001 Adaptec Corporation
6  * All rights reserved.
7  *
8  * TERMS AND CONDITIONS OF USE
9  *
10  * Redistribution and use in source form, with or without modification, are
11  * permitted provided that redistributions of source code must retain the
12  * above copyright notice, this list of conditions and the following disclaimer.
13  *
14  * This software is provided `as is' by Adaptec and any express or implied
15  * warranties, including, but not limited to, the implied warranties of
16  * merchantability and fitness for a particular purpose, are disclaimed. In no
17  * event shall Adaptec be liable for any direct, indirect, incidental, special,
18  * exemplary or consequential damages (including, but not limited to,
19  * procurement of substitute goods or services; loss of use, data, or profits;
20  * or business interruptions) however caused and on any theory of liability,
21  * whether in contract, strict liability, or tort (including negligence or
22  * otherwise) arising in any way out of the use of this driver software, even
23  * if advised of the possibility of such damage.
24  *
25  * SCSI I2O host adapter driver
26  *
27  *      V1.08 2001/08/21 Mark_Salyzyn@adaptec.com
28  *              - The 2000S and 2005S do not initialize on some machines,
29  *                increased timeout to 255ms from 50ms for the StatusGet
30  *                command.
31  *      V1.07 2001/05/22 Mark_Salyzyn@adaptec.com
32  *              - I knew this one was too good to be true. The error return
33  *                on ioctl commands needs to be compared to CAM_REQ_CMP, not
34  *                to the bit masked status.
35  *      V1.06 2001/05/08 Mark_Salyzyn@adaptec.com
36  *              - The 2005S that was supported is affectionately called the
37  *                Conjoined BAR Firmware. In order to support RAID-5 in a
38  *                16MB low-cost configuration, Firmware was forced to go
39  *                to a Split BAR Firmware. This requires a separate IOP and
40  *                Messaging base address.
41  *      V1.05 2001/04/25 Mark_Salyzyn@adaptec.com
42  *              - Handle support for 2005S Zero Channel RAID solution.
43  *              - System locked up if the Adapter locked up. Do not try
44  *                to send other commands if the resetIOP command fails. The
45  *                fail outstanding command discovery loop was flawed as the
46  *                removal of the command from the list prevented discovering
47  *                all the commands.
48  *              - Comment changes to clarify driver.
49  *              - SysInfo searched for an EATA SmartROM, not an I2O SmartROM.
50  *              - We do not use the AC_FOUND_DEV event because of I2O.
51  *                Removed asr_async.
52  *      V1.04 2000/09/22 Mark_Salyzyn@adaptec.com, msmith@freebsd.org,
53  *                       lampa@fee.vutbr.cz and Scott_Long@adaptec.com.
54  *              - Removed support for PM1554, PM2554 and PM2654 in Mode-0
55  *                mode as this is confused with competitor adapters in run
56  *                mode.
57  *              - critical locking needed in ASR_ccbAdd and ASR_ccbRemove
58  *                to prevent operating system panic.
59  *              - moved default major number to 154 from 97.
60  *      V1.03 2000/07/12 Mark_Salyzyn@adaptec.com
61  *              - The controller is not actually an ASR (Adaptec SCSI RAID)
62  *                series that is visible, it's more of an internal code name.
63  *                remove any visible references within reason for now.
64  *              - bus_ptr->LUN was not correctly zeroed when initially
65  *                allocated causing a possible panic of the operating system
66  *                during boot.
67  *      V1.02 2000/06/26 Mark_Salyzyn@adaptec.com
68  *              - Code always fails for ASR_getTid affecting performance.
69  *              - initiated a set of changes that resulted from a formal
70  *                code inspection by Mark_Salyzyn@adaptec.com,
71  *                George_Dake@adaptec.com, Jeff_Zeak@adaptec.com,
72  *                Martin_Wilson@adaptec.com and Vincent_Trandoan@adaptec.com.
73  *                Their findings were focussed on the LCT & TID handler, and
74  *                all resulting changes were to improve code readability,
75  *                consistency or have a positive effect on performance.
76  *      V1.01 2000/06/14 Mark_Salyzyn@adaptec.com
77  *              - Passthrough returned an incorrect error.
78  *              - Passthrough did not migrate the intrinsic scsi layer wakeup
79  *                on command completion.
80  *              - generate control device nodes using make_dev and delete_dev.
81  *              - Performance affected by TID caching reallocing.
82  *              - Made suggested changes by Justin_Gibbs@adaptec.com
83  *                      - use splcam instead of splbio.
84  *                      - use u_int8_t instead of u_char.
85  *                      - use u_int16_t instead of u_short.
86  *                      - use u_int32_t instead of u_long where appropriate.
87  *                      - use 64 bit context handler instead of 32 bit.
88  *                      - create_ccb should only allocate the worst case
89  *                        requirements for the driver since CAM may evolve
90  *                        making union ccb much larger than needed here.
91  *                        renamed create_ccb to asr_alloc_ccb.
92  *                      - go nutz justifying all debug prints as macros
93  *                        defined at the top and remove unsightly ifdefs.
94  *                      - INLINE STATIC viewed as confusing. Historically
95  *                        utilized to affect code performance and debug
96  *                        issues in OS, Compiler or OEM specific situations.
97  *      V1.00 2000/05/31 Mark_Salyzyn@adaptec.com
98  *              - Ported from FreeBSD 2.2.X DPT I2O driver.
99  *                      changed struct scsi_xfer to union ccb/struct ccb_hdr
100  *                      changed variable name xs to ccb
101  *                      changed struct scsi_link to struct cam_path
102  *                      changed struct scsibus_data to struct cam_sim
103  *                      stopped using fordriver for holding on to the TID
104  *                      use proprietary packet creation instead of scsi_inquire
105  *                      CAM layer sends synchronize commands.
106  */
107
108 #define ASR_VERSION     1
109 #define ASR_REVISION    '0'
110 #define ASR_SUBREVISION '8'
111 #define ASR_MONTH       8
112 #define ASR_DAY         21
113 #define ASR_YEAR        2001 - 1980
114
115 /*
116  *      Debug macros to reduce the unsightly ifdefs
117  */
118 #if (defined(DEBUG_ASR) || defined(DEBUG_ASR_USR_CMD) || defined(DEBUG_ASR_CMD))
119 # define debug_asr_message(message)                                            \
120         {                                                                      \
121                 u_int32_t * pointer = (u_int32_t *)message;                    \
122                 u_int32_t   length = I2O_MESSAGE_FRAME_getMessageSize(message);\
123                 u_int32_t   counter = 0;                                       \
124                                                                                \
125                 while (length--) {                                             \
126                         kprintf ("%08lx%c", (u_long)*(pointer++),               \
127                           (((++counter & 7) == 0) || (length == 0))            \
128                             ? '\n'                                             \
129                             : ' ');                                            \
130                 }                                                              \
131         }
132 #endif /* DEBUG_ASR || DEBUG_ASR_USR_CMD || DEBUG_ASR_CMD */
133
134 #if (defined(DEBUG_ASR))
135   /* Breaks on none STDC based compilers :-( */
136 # define debug_asr_printf(fmt,args...)   kprintf(fmt, ##args)
137 # define debug_asr_dump_message(message) debug_asr_message(message)
138 # define debug_asr_print_path(ccb)       xpt_print_path(ccb->ccb_h.path);
139   /* None fatal version of the ASSERT macro */
140 # if (defined(__STDC__))
141 #  define ASSERT(phrase) if(!(phrase))kprintf(#phrase " at line %d file %s\n",__LINE__,__FILE__)
142 # else
143 #  define ASSERT(phrase) if(!(phrase))kprintf("phrase" " at line %d file %s\n",__LINE__,__FILE__)
144 # endif
145 #else /* DEBUG_ASR */
146 # define debug_asr_printf(fmt,args...)
147 # define debug_asr_dump_message(message)
148 # define debug_asr_print_path(ccb)
149 # define ASSERT(x)
150 #endif /* DEBUG_ASR */
151
152 /*
153  *      If DEBUG_ASR_CMD is defined:
154  *              0 - Display incoming SCSI commands
155  *              1 - add in a quick character before queueing.
156  *              2 - add in outgoing message frames.
157  */
158 #if (defined(DEBUG_ASR_CMD))
159 # define debug_asr_cmd_printf(fmt,args...)     kprintf(fmt,##args)
160 # define debug_asr_dump_ccb(ccb)                                      \
161         {                                                             \
162                 u_int8_t * cp = (unsigned char *)&(ccb->csio.cdb_io); \
163                 int        len = ccb->csio.cdb_len;                   \
164                                                                       \
165                 while (len) {                                         \
166                         debug_asr_cmd_printf (" %02x", *(cp++));      \
167                         --len;                                        \
168                 }                                                     \
169         }
170 # if (DEBUG_ASR_CMD > 0)
171 #  define debug_asr_cmd1_printf                debug_asr_cmd_printf
172 # else
173 #  define debug_asr_cmd1_printf(fmt,args...)
174 # endif
175 # if (DEBUG_ASR_CMD > 1)
176 #  define debug_asr_cmd2_printf                debug_asr_cmd_printf
177 #  define debug_asr_cmd2_dump_message(message) debug_asr_message(message)
178 # else
179 #  define debug_asr_cmd2_printf(fmt,args...)
180 #  define debug_asr_cmd2_dump_message(message)
181 # endif
182 #else /* DEBUG_ASR_CMD */
183 # define debug_asr_cmd_printf(fmt,args...)
184 # define debug_asr_cmd_dump_ccb(ccb)
185 # define debug_asr_cmd1_printf(fmt,args...)
186 # define debug_asr_cmd2_printf(fmt,args...)
187 # define debug_asr_cmd2_dump_message(message)
188 #endif /* DEBUG_ASR_CMD */
189
190 #if (defined(DEBUG_ASR_USR_CMD))
191 # define debug_usr_cmd_printf(fmt,args...)   kprintf(fmt,##args)
192 # define debug_usr_cmd_dump_message(message) debug_usr_message(message)
193 #else /* DEBUG_ASR_USR_CMD */
194 # define debug_usr_cmd_printf(fmt,args...)
195 # define debug_usr_cmd_dump_message(message)
196 #endif /* DEBUG_ASR_USR_CMD */
197
198 #define dsDescription_size 46   /* Snug as a bug in a rug */
199 #include "dptsig.h"
200
201 static dpt_sig_S ASR_sig = {
202         { 'd', 'P', 't', 'S', 'i', 'G'}, SIG_VERSION, PROC_INTEL,
203         PROC_386 | PROC_486 | PROC_PENTIUM | PROC_SEXIUM, FT_HBADRVR, 0,
204         OEM_DPT, OS_FREE_BSD, CAP_ABOVE16MB, DEV_ALL,
205         ADF_ALL_SC5,
206         0, 0, ASR_VERSION, ASR_REVISION, ASR_SUBREVISION,
207         ASR_MONTH, ASR_DAY, ASR_YEAR,
208 /*       01234567890123456789012345678901234567890123456789     < 50 chars */
209         "Adaptec FreeBSD 4.0.0 Unix SCSI I2O HBA Driver"
210         /*               ^^^^^ asr_attach alters these to match OS */
211 };
212
213 #include <sys/param.h>  /* TRUE=1 and FALSE=0 defined here */
214 #include <sys/kernel.h>
215 #include <sys/systm.h>
216 #include <sys/malloc.h>
217 #include <sys/proc.h>
218 #include <sys/conf.h>
219 #include <sys/bus.h>
220 #include <sys/rman.h>
221 #include <sys/stat.h>
222 #include <sys/device.h>
223 #include <sys/thread2.h>
224 #include <sys/ioccom.h>
225
226 #include <bus/cam/cam.h>
227 #include <bus/cam/cam_ccb.h>
228 #include <bus/cam/cam_sim.h>
229 #include <bus/cam/cam_xpt_sim.h>
230 #include <bus/cam/cam_xpt_periph.h>
231
232 #include <bus/cam/scsi/scsi_all.h>
233 #include <bus/cam/scsi/scsi_message.h>
234
235 #include <vm/vm.h>
236 #include <vm/pmap.h>
237 #include <machine/cputypes.h>
238 #include <machine/clock.h>
239 #include <machine/vmparam.h>
240
241 #include <bus/pci/pcivar.h>
242 #include <bus/pci/pcireg.h>
243
244 #define STATIC static
245 #define INLINE
246
247 #if (defined(DEBUG_ASR) && (DEBUG_ASR > 0))
248 # undef STATIC
249 # define STATIC
250 # undef INLINE
251 # define INLINE
252 #endif
253 #define IN
254 #define OUT
255 #define INOUT
256
257 #define osdSwap4(x) ((u_long)ntohl((u_long)(x)))
258 #define KVTOPHYS(x) vtophys(x)
259 #include        "dptalign.h"
260 #include        "i2oexec.h"
261 #include        "i2obscsi.h"
262 #include        "i2odpt.h"
263 #include        "i2oadptr.h"
264 #include        "sys_info.h"
265
266 /* Configuration Definitions */
267
268 #define SG_SIZE          58     /* Scatter Gather list Size              */
269 #define MAX_TARGET_ID    126    /* Maximum Target ID supported           */
270 #define MAX_LUN          255    /* Maximum LUN Supported                 */
271 #define MAX_CHANNEL      7      /* Maximum Channel # Supported by driver */
272 #define MAX_INBOUND      2000   /* Max CCBs, Also Max Queue Size         */
273 #define MAX_OUTBOUND     256    /* Maximum outbound frames/adapter       */
274 #define MAX_INBOUND_SIZE 512    /* Maximum inbound frame size            */
275 #define MAX_MAP          4194304L /* Maximum mapping size of IOP         */
276                                 /* Also serves as the minimum map for    */
277                                 /* the 2005S zero channel RAID product   */
278
279 /**************************************************************************
280 ** ASR Host Adapter structure - One Structure For Each Host Adapter That **
281 **  Is Configured Into The System.  The Structure Supplies Configuration **
282 **  Information, Status Info, Queue Info And An Active CCB List Pointer. **
283 ***************************************************************************/
284
285 /* I2O register set */
286 typedef struct {
287         U8           Address[0x30];
288         volatile U32 Status;
289         volatile U32 Mask;
290 #               define Mask_InterruptsDisabled 0x08
291         U32          x[2];
292         volatile U32 ToFIFO;    /* In Bound FIFO  */
293         volatile U32 FromFIFO;  /* Out Bound FIFO */
294 } i2oRegs_t;
295
296 /*
297  * A MIX of performance and space considerations for TID lookups
298  */
299 typedef u_int16_t tid_t;
300
301 typedef struct {
302         u_int32_t size;         /* up to MAX_LUN    */
303         tid_t     TID[1];
304 } lun2tid_t;
305
306 typedef struct {
307         u_int32_t   size;       /* up to MAX_TARGET */
308         lun2tid_t * LUN[1];
309 } target2lun_t;
310
311 /*
312  *      To ensure that we only allocate and use the worst case ccb here, lets
313  *      make our own local ccb union. If asr_alloc_ccb is utilized for another
314  *      ccb type, ensure that you add the additional structures into our local
315  *      ccb union. To ensure strict type checking, we will utilize the local
316  *      ccb definition wherever possible.
317  */
318 union asr_ccb {
319         struct ccb_hdr      ccb_h;  /* For convenience */
320         struct ccb_scsiio   csio;
321         struct ccb_setasync csa;
322 };
323
324 typedef struct Asr_softc {
325         u_int16_t               ha_irq;
326         void                  * ha_Base;       /* base port for each board */
327         u_int8_t     * volatile ha_blinkLED;
328         i2oRegs_t             * ha_Virt;       /* Base address of IOP      */
329         U8                    * ha_Fvirt;      /* Base address of Frames   */
330         I2O_IOP_ENTRY           ha_SystemTable;
331         LIST_HEAD(,ccb_hdr)     ha_ccb;        /* ccbs in use              */
332         struct cam_path       * ha_path[MAX_CHANNEL+1];
333         struct cam_sim        * ha_sim[MAX_CHANNEL+1];
334         struct resource       * ha_mem_res;
335         struct resource       * ha_mes_res;
336         struct resource       * ha_irq_res;
337         void                  * ha_intr;
338         PI2O_LCT                ha_LCT;        /* Complete list of devices */
339 #                define le_type   IdentityTag[0]
340 #                        define I2O_BSA     0x20
341 #                        define I2O_FCA     0x40
342 #                        define I2O_SCSI    0x00
343 #                        define I2O_PORT    0x80
344 #                        define I2O_UNKNOWN 0x7F
345 #                define le_bus    IdentityTag[1]
346 #                define le_target IdentityTag[2]
347 #                define le_lun    IdentityTag[3]
348         target2lun_t          * ha_targets[MAX_CHANNEL+1];
349         PI2O_SCSI_ERROR_REPLY_MESSAGE_FRAME ha_Msgs;
350         u_long                  ha_Msgs_Phys;
351
352         u_int8_t                ha_in_reset;
353 #               define HA_OPERATIONAL       0
354 #               define HA_IN_RESET          1
355 #               define HA_OFF_LINE          2
356 #               define HA_OFF_LINE_RECOVERY 3
357         /* Configuration information */
358         /* The target id maximums we take     */
359         u_int8_t                ha_MaxBus;     /* Maximum bus              */
360         u_int8_t                ha_MaxId;      /* Maximum target ID        */
361         u_int8_t                ha_MaxLun;     /* Maximum target LUN            */
362         u_int8_t                ha_SgSize;     /* Max SG elements          */
363         u_int8_t                ha_pciBusNum;
364         u_int8_t                ha_pciDeviceNum;
365         u_int8_t                ha_adapter_target[MAX_CHANNEL+1];
366         u_int16_t               ha_QueueSize;  /* Max outstanding commands */
367         u_int16_t               ha_Msgs_Count;
368
369         /* Links into other parents and HBAs */
370         struct Asr_softc      * ha_next;       /* HBA list                 */
371 } Asr_softc_t;
372
373 STATIC Asr_softc_t * Asr_softc;
374
375 /*
376  *      Prototypes of the routines we have in this object.
377  */
378
379 /* Externally callable routines */
380 #define PROBE_ARGS  IN device_t tag
381 #define PROBE_RET   int
382 #define PROBE_SET() u_long id = (pci_get_device(tag)<<16)|pci_get_vendor(tag)
383 #define PROBE_RETURN(retval) if(retval){device_set_desc(tag,retval);return(0);}else{return(ENXIO);}
384 #define ATTACH_ARGS IN device_t tag
385 #define ATTACH_RET  int
386 #define ATTACH_SET() int unit = device_get_unit(tag)
387 #define ATTACH_RETURN(retval) return(retval)
388 /* I2O HDM interface */
389 STATIC PROBE_RET      asr_probe (PROBE_ARGS);
390 STATIC ATTACH_RET     asr_attach (ATTACH_ARGS);
391 /* DOMINO placeholder */
392 STATIC PROBE_RET      domino_probe (PROBE_ARGS);
393 STATIC ATTACH_RET     domino_attach (ATTACH_ARGS);
394 /* MODE0 adapter placeholder */
395 STATIC PROBE_RET      mode0_probe (PROBE_ARGS);
396 STATIC ATTACH_RET     mode0_attach (ATTACH_ARGS);
397
398 STATIC Asr_softc_t  * ASR_get_sc (cdev_t dev);
399 STATIC d_ioctl_t asr_ioctl;
400 STATIC d_open_t asr_open;
401 STATIC d_close_t asr_close;
402 STATIC int            asr_intr (IN Asr_softc_t *sc);
403 STATIC void           asr_timeout (INOUT void *arg);
404 STATIC int            ASR_init (IN Asr_softc_t *sc);
405 STATIC INLINE int     ASR_acquireLct (INOUT Asr_softc_t *sc);
406 STATIC INLINE int     ASR_acquireHrt (INOUT Asr_softc_t *sc);
407 STATIC void           asr_action (IN struct cam_sim *sim,
408                                   IN union ccb *ccb);
409 STATIC void           asr_poll (IN struct cam_sim * sim);
410
411 /*
412  *      Here is the auto-probe structure used to nest our tests appropriately
413  *      during the startup phase of the operating system.
414  */
415 STATIC device_method_t asr_methods[] = {
416         DEVMETHOD(device_probe,  asr_probe),
417         DEVMETHOD(device_attach, asr_attach),
418         { 0, 0 }
419 };
420
421 STATIC driver_t asr_driver = {
422         "asr",
423         asr_methods,
424         sizeof(Asr_softc_t)
425 };
426
427 STATIC devclass_t asr_devclass;
428
429 DECLARE_DUMMY_MODULE(asr);
430 DRIVER_MODULE(asr, pci, asr_driver, asr_devclass, 0, 0);
431
432 STATIC device_method_t domino_methods[] = {
433         DEVMETHOD(device_probe,  domino_probe),
434         DEVMETHOD(device_attach, domino_attach),
435         { 0, 0 }
436 };
437
438 STATIC driver_t domino_driver = {
439         "domino",
440         domino_methods,
441         0
442 };
443
444 STATIC devclass_t domino_devclass;
445
446 DRIVER_MODULE(domino, pci, domino_driver, domino_devclass, 0, 0);
447
448 STATIC device_method_t mode0_methods[] = {
449         DEVMETHOD(device_probe,  mode0_probe),
450         DEVMETHOD(device_attach, mode0_attach),
451         { 0, 0 }
452 };
453
454 STATIC driver_t mode0_driver = {
455         "mode0",
456         mode0_methods,
457         0
458 };
459
460 STATIC devclass_t mode0_devclass;
461
462 DRIVER_MODULE(mode0, pci, mode0_driver, mode0_devclass, 0, 0);
463
464 /*
465  * devsw for asr hba driver
466  *
467  * only ioctl is used. the sd driver provides all other access.
468  */
469 STATIC struct dev_ops asr_ops = {
470         { "asr", -1, 0 },
471         .d_open =       asr_open,
472         .d_close =      asr_close, 
473         .d_ioctl =      asr_ioctl,
474 };
475
476 /*
477  * Initialize the dynamic dev_ops hooks.
478  */
479 STATIC void
480 asr_drvinit (void * unused)
481 {
482         static int asr_devsw_installed = 0;
483
484         if (asr_devsw_installed) {
485                 return;
486         }
487         asr_devsw_installed++;
488
489         /*
490          * Adding the ops will dynamically assign a major number.
491          */
492         dev_ops_add(&asr_ops, 0, 0);
493 } /* asr_drvinit */
494
495 /* XXX Must initialize before CAM layer picks up our HBA driver */
496 SYSINIT(asrdev,SI_SUB_DRIVERS,SI_ORDER_MIDDLE,asr_drvinit,NULL)
497
498 /* I2O support routines */
499 #define defAlignLong(STRUCT,NAME) char NAME[sizeof(STRUCT)]
500 #define getAlignLong(STRUCT,NAME) ((STRUCT *)(NAME))
501
502 /*
503  *      Fill message with default.
504  */
505 STATIC PI2O_MESSAGE_FRAME
506 ASR_fillMessage (
507         IN char              * Message,
508         IN u_int16_t           size)
509 {
510         OUT PI2O_MESSAGE_FRAME Message_Ptr;
511
512         Message_Ptr = getAlignLong(I2O_MESSAGE_FRAME, Message);
513         bzero ((void *)Message_Ptr, size);
514         I2O_MESSAGE_FRAME_setVersionOffset(Message_Ptr, I2O_VERSION_11);
515         I2O_MESSAGE_FRAME_setMessageSize(Message_Ptr,
516           (size + sizeof(U32) - 1) >> 2);
517         I2O_MESSAGE_FRAME_setInitiatorAddress (Message_Ptr, 1);
518         return (Message_Ptr);
519 } /* ASR_fillMessage */
520
521 #define EMPTY_QUEUE ((U32)-1L)
522
523 STATIC INLINE U32
524 ASR_getMessage(
525         IN i2oRegs_t * virt)
526 {
527         OUT U32        MessageOffset;
528
529         if ((MessageOffset = virt->ToFIFO) == EMPTY_QUEUE) {
530                 MessageOffset = virt->ToFIFO;
531         }
532         return (MessageOffset);
533 } /* ASR_getMessage */
534
535 /* Issue a polled command */
536 STATIC U32
537 ASR_initiateCp (
538         INOUT i2oRegs_t     * virt,
539         INOUT U8            * fvirt,
540         IN PI2O_MESSAGE_FRAME Message)
541 {
542         OUT U32               Mask = -1L;
543         U32                   MessageOffset;
544         u_int                 Delay = 1500;
545
546         /*
547          * ASR_initiateCp is only used for synchronous commands and will
548          * be made more resiliant to adapter delays since commands like
549          * resetIOP can cause the adapter to be deaf for a little time.
550          */
551         while (((MessageOffset = ASR_getMessage(virt)) == EMPTY_QUEUE)
552          && (--Delay != 0)) {
553                 DELAY (10000);
554         }
555         if (MessageOffset != EMPTY_QUEUE) {
556                 bcopy (Message, fvirt + MessageOffset,
557                   I2O_MESSAGE_FRAME_getMessageSize(Message) << 2);
558                 /*
559                  *      Disable the Interrupts
560                  */
561                 virt->Mask = (Mask = virt->Mask) | Mask_InterruptsDisabled;
562                 virt->ToFIFO = MessageOffset;
563         }
564         return (Mask);
565 } /* ASR_initiateCp */
566
567 /*
568  *      Reset the adapter.
569  */
570 STATIC U32
571 ASR_resetIOP (
572         INOUT i2oRegs_t                * virt,
573         INOUT U8                       * fvirt)
574 {
575         struct resetMessage {
576                 I2O_EXEC_IOP_RESET_MESSAGE M;
577                 U32                        R;
578         };
579         defAlignLong(struct resetMessage,Message);
580         PI2O_EXEC_IOP_RESET_MESSAGE      Message_Ptr;
581         OUT U32               * volatile Reply_Ptr;
582         U32                              Old;
583
584         /*
585          *  Build up our copy of the Message.
586          */
587         Message_Ptr = (PI2O_EXEC_IOP_RESET_MESSAGE)ASR_fillMessage(Message,
588           sizeof(I2O_EXEC_IOP_RESET_MESSAGE));
589         I2O_EXEC_IOP_RESET_MESSAGE_setFunction(Message_Ptr, I2O_EXEC_IOP_RESET);
590         /*
591          *  Reset the Reply Status
592          */
593         *(Reply_Ptr = (U32 *)((char *)Message_Ptr
594           + sizeof(I2O_EXEC_IOP_RESET_MESSAGE))) = 0;
595         I2O_EXEC_IOP_RESET_MESSAGE_setStatusWordLowAddress(Message_Ptr,
596           KVTOPHYS((void *)Reply_Ptr));
597         /*
598          *      Send the Message out
599          */
600         if ((Old = ASR_initiateCp (virt, fvirt, (PI2O_MESSAGE_FRAME)Message_Ptr)) != (U32)-1L) {
601                 /*
602                  *      Wait for a response (Poll), timeouts are dangerous if
603                  * the card is truly responsive. We assume response in 2s.
604                  */
605                 u_int8_t Delay = 200;
606
607                 while ((*Reply_Ptr == 0) && (--Delay != 0)) {
608                         DELAY (10000);
609                 }
610                 /*
611                  *      Re-enable the interrupts.
612                  */
613                 virt->Mask = Old;
614                 ASSERT (*Reply_Ptr);
615                 return (*Reply_Ptr);
616         }
617         ASSERT (Old != (U32)-1L);
618         return (0);
619 } /* ASR_resetIOP */
620
621 /*
622  *      Get the curent state of the adapter
623  */
624 STATIC INLINE PI2O_EXEC_STATUS_GET_REPLY
625 ASR_getStatus (
626         INOUT i2oRegs_t *                        virt,
627         INOUT U8 *                               fvirt,
628         OUT PI2O_EXEC_STATUS_GET_REPLY           buffer)
629 {
630         defAlignLong(I2O_EXEC_STATUS_GET_MESSAGE,Message);
631         PI2O_EXEC_STATUS_GET_MESSAGE             Message_Ptr;
632         U32                                      Old;
633
634         /*
635          *  Build up our copy of the Message.
636          */
637         Message_Ptr = (PI2O_EXEC_STATUS_GET_MESSAGE)ASR_fillMessage(Message,
638           sizeof(I2O_EXEC_STATUS_GET_MESSAGE));
639         I2O_EXEC_STATUS_GET_MESSAGE_setFunction(Message_Ptr,
640           I2O_EXEC_STATUS_GET);
641         I2O_EXEC_STATUS_GET_MESSAGE_setReplyBufferAddressLow(Message_Ptr,
642           KVTOPHYS((void *)buffer));
643         /* This one is a Byte Count */
644         I2O_EXEC_STATUS_GET_MESSAGE_setReplyBufferLength(Message_Ptr,
645           sizeof(I2O_EXEC_STATUS_GET_REPLY));
646         /*
647          *  Reset the Reply Status
648          */
649         bzero ((void *)buffer, sizeof(I2O_EXEC_STATUS_GET_REPLY));
650         /*
651          *      Send the Message out
652          */
653         if ((Old = ASR_initiateCp (virt, fvirt, (PI2O_MESSAGE_FRAME)Message_Ptr)) != (U32)-1L) {
654                 /*
655                  *      Wait for a response (Poll), timeouts are dangerous if
656                  * the card is truly responsive. We assume response in 50ms.
657                  */
658                 u_int8_t Delay = 255;
659
660                 while (*((U8 * volatile)&(buffer->SyncByte)) == 0) {
661                         if (--Delay == 0) {
662                                 buffer = (PI2O_EXEC_STATUS_GET_REPLY)NULL;
663                                 break;
664                         }
665                         DELAY (1000);
666                 }
667                 /*
668                  *      Re-enable the interrupts.
669                  */
670                 virt->Mask = Old;
671                 return (buffer);
672         }
673         return ((PI2O_EXEC_STATUS_GET_REPLY)NULL);
674 } /* ASR_getStatus */
675
676 /*
677  *      Check if the device is a SCSI I2O HBA, and add it to the list.
678  */
679
680 /*
681  * Probe for ASR controller.  If we find it, we will use it.
682  * virtual adapters.
683  */
684 STATIC PROBE_RET
685 asr_probe(PROBE_ARGS)
686 {
687         PROBE_SET();
688         if ((id == 0xA5011044) || (id == 0xA5111044)) {
689                 PROBE_RETURN ("Adaptec Caching SCSI RAID");
690         }
691         PROBE_RETURN (NULL);
692 } /* asr_probe */
693
694 /*
695  * Probe/Attach for DOMINO chipset.
696  */
697 STATIC PROBE_RET
698 domino_probe(PROBE_ARGS)
699 {
700         PROBE_SET();
701         if (id == 0x10121044) {
702                 PROBE_RETURN ("Adaptec Caching Memory Controller");
703         }
704         PROBE_RETURN (NULL);
705 } /* domino_probe */
706
707 STATIC ATTACH_RET
708 domino_attach (ATTACH_ARGS)
709 {
710         ATTACH_RETURN (0);
711 } /* domino_attach */
712
713 /*
714  * Probe/Attach for MODE0 adapters.
715  */
716 STATIC PROBE_RET
717 mode0_probe(PROBE_ARGS)
718 {
719         PROBE_SET();
720
721         /*
722          *      If/When we can get a business case to commit to a
723          * Mode0 driver here, we can make all these tests more
724          * specific and robust. Mode0 adapters have their processors
725          * turned off, this the chips are in a raw state.
726          */
727
728         /* This is a PLX9054 */
729         if (id == 0x905410B5) {
730                 PROBE_RETURN ("Adaptec Mode0 PM3757");
731         }
732         /* This is a PLX9080 */
733         if (id == 0x908010B5) {
734                 PROBE_RETURN ("Adaptec Mode0 PM3754/PM3755");
735         }
736         /* This is a ZION 80303 */
737         if (id == 0x53098086) {
738                 PROBE_RETURN ("Adaptec Mode0 3010S");
739         }
740         /* This is an i960RS */
741         if (id == 0x39628086) {
742                 PROBE_RETURN ("Adaptec Mode0 2100S");
743         }
744         /* This is an i960RN */
745         if (id == 0x19648086) {
746                 PROBE_RETURN ("Adaptec Mode0 PM2865/2400A/3200S/3400S");
747         }
748 #if 0   /* this would match any generic i960 -- mjs */
749         /* This is an i960RP (typically also on Motherboards) */
750         if (id == 0x19608086) {
751                 PROBE_RETURN ("Adaptec Mode0 PM2554/PM1554/PM2654");
752         }
753 #endif
754         PROBE_RETURN (NULL);
755 } /* mode0_probe */
756
757 STATIC ATTACH_RET
758 mode0_attach (ATTACH_ARGS)
759 {
760         ATTACH_RETURN (0);
761 } /* mode0_attach */
762
763 STATIC INLINE union asr_ccb *
764 asr_alloc_ccb (
765         IN Asr_softc_t    * sc)
766 {
767         OUT union asr_ccb * new_ccb;
768
769         if ((new_ccb = (union asr_ccb *)kmalloc(sizeof(*new_ccb),
770           M_DEVBUF, M_WAITOK)) != (union asr_ccb *)NULL) {
771                 bzero (new_ccb, sizeof(*new_ccb));
772                 new_ccb->ccb_h.pinfo.priority = 1;
773                 new_ccb->ccb_h.pinfo.index = CAM_UNQUEUED_INDEX;
774                 new_ccb->ccb_h.spriv_ptr0 = sc;
775         }
776         return (new_ccb);
777 } /* asr_alloc_ccb */
778
779 STATIC INLINE void
780 asr_free_ccb (
781         IN union asr_ccb * free_ccb)
782 {
783         kfree(free_ccb, M_DEVBUF);
784 } /* asr_free_ccb */
785
786 /*
787  *      Print inquiry data `carefully'
788  */
789 STATIC void
790 ASR_prstring (
791         u_int8_t * s,
792         int        len)
793 {
794         while ((--len >= 0) && (*s) && (*s != ' ') && (*s != '-')) {
795                 kprintf ("%c", *(s++));
796         }
797 } /* ASR_prstring */
798
799 /*
800  * Prototypes
801  */
802 STATIC INLINE int ASR_queue (
803         IN Asr_softc_t             * sc,
804         IN PI2O_MESSAGE_FRAME Message);
805 /*
806  *      Send a message synchronously and without Interrupt to a ccb.
807  */
808 STATIC int
809 ASR_queue_s (
810         INOUT union asr_ccb * ccb,
811         IN PI2O_MESSAGE_FRAME Message)
812 {
813         U32                   Mask;
814         Asr_softc_t         * sc = (Asr_softc_t *)(ccb->ccb_h.spriv_ptr0);
815
816         /*
817          * We do not need any (optional byteswapping) method access to
818          * the Initiator context field.
819          */
820         I2O_MESSAGE_FRAME_setInitiatorContext64(Message, (long)ccb);
821
822         /* Prevent interrupt service */
823         crit_enter();
824         sc->ha_Virt->Mask = (Mask = sc->ha_Virt->Mask)
825           | Mask_InterruptsDisabled;
826
827         if (ASR_queue (sc, Message) == EMPTY_QUEUE) {
828                 ccb->ccb_h.status &= ~CAM_STATUS_MASK;
829                 ccb->ccb_h.status |= CAM_REQUEUE_REQ;
830         }
831
832         /*
833          * Wait for this board to report a finished instruction.
834          */
835         while ((ccb->ccb_h.status & CAM_STATUS_MASK) == CAM_REQ_INPROG) {
836                 (void)asr_intr (sc);
837         }
838
839         /* Re-enable Interrupts */
840         sc->ha_Virt->Mask = Mask;
841         crit_exit();
842
843         return (ccb->ccb_h.status);
844 } /* ASR_queue_s */
845
846 /*
847  *      Send a message synchronously to a Asr_softc_t
848  */
849 STATIC int
850 ASR_queue_c (
851         IN Asr_softc_t      * sc,
852         IN PI2O_MESSAGE_FRAME Message)
853 {
854         union asr_ccb       * ccb;
855         OUT int               status;
856
857         if ((ccb = asr_alloc_ccb (sc)) == (union asr_ccb *)NULL) {
858                 return (CAM_REQUEUE_REQ);
859         }
860
861         status = ASR_queue_s (ccb, Message);
862
863         asr_free_ccb(ccb);
864
865         return (status);
866 } /* ASR_queue_c */
867
868 /*
869  *      Add the specified ccb to the active queue
870  */
871 STATIC INLINE void
872 ASR_ccbAdd (
873         IN Asr_softc_t      * sc,
874         INOUT union asr_ccb * ccb)
875 {
876         crit_enter();
877         LIST_INSERT_HEAD(&(sc->ha_ccb), &(ccb->ccb_h), sim_links.le);
878         if (ccb->ccb_h.timeout != CAM_TIME_INFINITY) {
879                 if (ccb->ccb_h.timeout == CAM_TIME_DEFAULT) {
880                         /*
881                          * RAID systems can take considerable time to
882                          * complete some commands given the large cache
883                          * flashes switching from write back to write thru.
884                          */
885                         ccb->ccb_h.timeout = 6 * 60 * 1000;
886                 }
887                 callout_reset(&ccb->ccb_h.timeout_ch,
888                     (ccb->ccb_h.timeout * hz) / 1000, asr_timeout, ccb);
889         }
890         crit_exit();
891 } /* ASR_ccbAdd */
892
893 /*
894  *      Remove the specified ccb from the active queue.
895  */
896 STATIC INLINE void
897 ASR_ccbRemove (
898         IN Asr_softc_t      * sc,
899         INOUT union asr_ccb * ccb)
900 {
901         crit_enter();
902         callout_stop(&ccb->ccb_h.timeout_ch);
903         LIST_REMOVE(&(ccb->ccb_h), sim_links.le);
904         crit_exit();
905 } /* ASR_ccbRemove */
906
907 /*
908  *      Fail all the active commands, so they get re-issued by the operating
909  *      system.
910  */
911 STATIC INLINE void
912 ASR_failActiveCommands (
913         IN Asr_softc_t                         * sc)
914 {
915         struct ccb_hdr                         * ccb;
916
917 #if 0 /* Currently handled by callers, unnecessary paranoia currently */
918       /* Left in for historical perspective. */
919         defAlignLong(I2O_EXEC_LCT_NOTIFY_MESSAGE,Message);
920         PI2O_EXEC_LCT_NOTIFY_MESSAGE             Message_Ptr;
921
922         /* Send a blind LCT command to wait for the enableSys to complete */
923         Message_Ptr = (PI2O_EXEC_LCT_NOTIFY_MESSAGE)ASR_fillMessage(Message,
924           sizeof(I2O_EXEC_LCT_NOTIFY_MESSAGE) - sizeof(I2O_SG_ELEMENT));
925         I2O_MESSAGE_FRAME_setFunction(&(Message_Ptr->StdMessageFrame),
926           I2O_EXEC_LCT_NOTIFY);
927         I2O_EXEC_LCT_NOTIFY_MESSAGE_setClassIdentifier(Message_Ptr,
928           I2O_CLASS_MATCH_ANYCLASS);
929         (void)ASR_queue_c(sc, (PI2O_MESSAGE_FRAME)Message_Ptr);
930 #endif
931
932         crit_enter();
933         /*
934          *      We do not need to inform the CAM layer that we had a bus
935          * reset since we manage it on our own, this also prevents the
936          * SCSI_DELAY settling that would be required on other systems.
937          * The `SCSI_DELAY' has already been handled by the card via the
938          * acquisition of the LCT table while we are at CAM priority level.
939          *  for (int bus = 0; bus <= sc->ha_MaxBus; ++bus) {
940          *      xpt_async (AC_BUS_RESET, sc->ha_path[bus], NULL);
941          *  }
942          */
943         while ((ccb = LIST_FIRST(&(sc->ha_ccb))) != (struct ccb_hdr *)NULL) {
944                 ASR_ccbRemove (sc, (union asr_ccb *)ccb);
945
946                 ccb->status &= ~CAM_STATUS_MASK;
947                 ccb->status |= CAM_REQUEUE_REQ;
948                 /* Nothing Transfered */
949                 ((struct ccb_scsiio *)ccb)->resid
950                   = ((struct ccb_scsiio *)ccb)->dxfer_len;
951
952                 if (ccb->path) {
953                         xpt_done ((union ccb *)ccb);
954                 } else {
955                         wakeup ((caddr_t)ccb);
956                 }
957         }
958         crit_exit();
959 } /* ASR_failActiveCommands */
960
961 /*
962  *      The following command causes the HBA to reset the specific bus
963  */
964 STATIC INLINE void
965 ASR_resetBus(
966         IN Asr_softc_t                       * sc,
967         IN int                                 bus)
968 {
969         defAlignLong(I2O_HBA_BUS_RESET_MESSAGE,Message);
970         I2O_HBA_BUS_RESET_MESSAGE            * Message_Ptr;
971         PI2O_LCT_ENTRY                         Device;
972
973         Message_Ptr = (I2O_HBA_BUS_RESET_MESSAGE *)ASR_fillMessage(Message,
974           sizeof(I2O_HBA_BUS_RESET_MESSAGE));
975         I2O_MESSAGE_FRAME_setFunction(&Message_Ptr->StdMessageFrame,
976           I2O_HBA_BUS_RESET);
977         for (Device = sc->ha_LCT->LCTEntry; Device < (PI2O_LCT_ENTRY)
978           (((U32 *)sc->ha_LCT)+I2O_LCT_getTableSize(sc->ha_LCT));
979           ++Device) {
980                 if (((Device->le_type & I2O_PORT) != 0)
981                  && (Device->le_bus == bus)) {
982                         I2O_MESSAGE_FRAME_setTargetAddress(
983                           &Message_Ptr->StdMessageFrame,
984                           I2O_LCT_ENTRY_getLocalTID(Device));
985                         /* Asynchronous command, with no expectations */
986                         (void)ASR_queue(sc, (PI2O_MESSAGE_FRAME)Message_Ptr);
987                         break;
988                 }
989         }
990 } /* ASR_resetBus */
991
992 STATIC INLINE int
993 ASR_getBlinkLedCode (
994         IN Asr_softc_t * sc)
995 {
996         if ((sc != (Asr_softc_t *)NULL)
997          && (sc->ha_blinkLED != (u_int8_t *)NULL)
998          && (sc->ha_blinkLED[1] == 0xBC)) {
999                 return (sc->ha_blinkLED[0]);
1000         }
1001         return (0);
1002 } /* ASR_getBlinkCode */
1003
1004 /*
1005  *      Determine the address of an TID lookup. Must be done at high priority
1006  *      since the address can be changed by other threads of execution.
1007  *
1008  *      Returns NULL pointer if not indexible (but will attempt to generate
1009  *      an index if `new_entry' flag is set to TRUE).
1010  *
1011  *      All addressible entries are to be guaranteed zero if never initialized.
1012  */
1013 STATIC INLINE tid_t *
1014 ASR_getTidAddress(
1015         INOUT Asr_softc_t * sc,
1016         IN int              bus,
1017         IN int              target,
1018         IN int              lun,
1019         IN int              new_entry)
1020 {
1021         target2lun_t      * bus_ptr;
1022         lun2tid_t         * target_ptr;
1023         unsigned            new_size;
1024
1025         /*
1026          *      Validity checking of incoming parameters. More of a bound
1027          * expansion limit than an issue with the code dealing with the
1028          * values.
1029          *
1030          *      sc must be valid before it gets here, so that check could be
1031          * dropped if speed a critical issue.
1032          */
1033         if ((sc == (Asr_softc_t *)NULL)
1034          || (bus > MAX_CHANNEL)
1035          || (target > sc->ha_MaxId)
1036          || (lun > sc->ha_MaxLun)) {
1037                 debug_asr_printf("(%lx,%d,%d,%d) target out of range\n",
1038                   (u_long)sc, bus, target, lun);
1039                 return ((tid_t *)NULL);
1040         }
1041         /*
1042          *      See if there is an associated bus list.
1043          *
1044          *      for performance, allocate in size of BUS_CHUNK chunks.
1045          *      BUS_CHUNK must be a power of two. This is to reduce
1046          *      fragmentation effects on the allocations.
1047          */
1048 #       define BUS_CHUNK 8
1049         new_size = ((target + BUS_CHUNK - 1) & ~(BUS_CHUNK - 1));
1050         if ((bus_ptr = sc->ha_targets[bus]) == (target2lun_t *)NULL) {
1051                 /*
1052                  *      Allocate a new structure?
1053                  *              Since one element in structure, the +1
1054                  *              needed for size has been abstracted.
1055                  */
1056                 if ((new_entry == FALSE)
1057                  || ((sc->ha_targets[bus] = bus_ptr = (target2lun_t *)kmalloc (
1058                     sizeof(*bus_ptr) + (sizeof(bus_ptr->LUN) * new_size),
1059                     M_TEMP, M_WAITOK))
1060                    == (target2lun_t *)NULL)) {
1061                         debug_asr_printf("failed to allocate bus list\n");
1062                         return ((tid_t *)NULL);
1063                 }
1064                 bzero (bus_ptr, sizeof(*bus_ptr)
1065                   + (sizeof(bus_ptr->LUN) * new_size));
1066                 bus_ptr->size = new_size + 1;
1067         } else if (bus_ptr->size <= new_size) {
1068                 target2lun_t * new_bus_ptr;
1069
1070                 /*
1071                  *      Reallocate a new structure?
1072                  *              Since one element in structure, the +1
1073                  *              needed for size has been abstracted.
1074                  */
1075                 if ((new_entry == FALSE)
1076                  || ((new_bus_ptr = (target2lun_t *)kmalloc (
1077                     sizeof(*bus_ptr) + (sizeof(bus_ptr->LUN) * new_size),
1078                     M_TEMP, M_WAITOK))
1079                    == (target2lun_t *)NULL)) {
1080                         debug_asr_printf("failed to reallocate bus list\n");
1081                         return ((tid_t *)NULL);
1082                 }
1083                 /*
1084                  *      Zero and copy the whole thing, safer, simpler coding
1085                  * and not really performance critical at this point.
1086                  */
1087                 bzero (new_bus_ptr, sizeof(*bus_ptr)
1088                   + (sizeof(bus_ptr->LUN) * new_size));
1089                 bcopy (bus_ptr, new_bus_ptr, sizeof(*bus_ptr)
1090                   + (sizeof(bus_ptr->LUN) * (bus_ptr->size - 1)));
1091                 sc->ha_targets[bus] = new_bus_ptr;
1092                 kfree (bus_ptr, M_TEMP);
1093                 bus_ptr = new_bus_ptr;
1094                 bus_ptr->size = new_size + 1;
1095         }
1096         /*
1097          *      We now have the bus list, lets get to the target list.
1098          *      Since most systems have only *one* lun, we do not allocate
1099          *      in chunks as above, here we allow one, then in chunk sizes.
1100          *      TARGET_CHUNK must be a power of two. This is to reduce
1101          *      fragmentation effects on the allocations.
1102          */
1103 #       define TARGET_CHUNK 8
1104         if ((new_size = lun) != 0) {
1105                 new_size = ((lun + TARGET_CHUNK - 1) & ~(TARGET_CHUNK - 1));
1106         }
1107         if ((target_ptr = bus_ptr->LUN[target]) == (lun2tid_t *)NULL) {
1108                 /*
1109                  *      Allocate a new structure?
1110                  *              Since one element in structure, the +1
1111                  *              needed for size has been abstracted.
1112                  */
1113                 if ((new_entry == FALSE)
1114                  || ((bus_ptr->LUN[target] = target_ptr = (lun2tid_t *)kmalloc (
1115                     sizeof(*target_ptr) + (sizeof(target_ptr->TID) * new_size),
1116                     M_TEMP, M_WAITOK))
1117                    == (lun2tid_t *)NULL)) {
1118                         debug_asr_printf("failed to allocate target list\n");
1119                         return ((tid_t *)NULL);
1120                 }
1121                 bzero (target_ptr, sizeof(*target_ptr)
1122                   + (sizeof(target_ptr->TID) * new_size));
1123                 target_ptr->size = new_size + 1;
1124         } else if (target_ptr->size <= new_size) {
1125                 lun2tid_t * new_target_ptr;
1126
1127                 /*
1128                  *      Reallocate a new structure?
1129                  *              Since one element in structure, the +1
1130                  *              needed for size has been abstracted.
1131                  */
1132                 if ((new_entry == FALSE)
1133                  || ((new_target_ptr = (lun2tid_t *)kmalloc (
1134                     sizeof(*target_ptr) + (sizeof(target_ptr->TID) * new_size),
1135                     M_TEMP, M_WAITOK))
1136                    == (lun2tid_t *)NULL)) {
1137                         debug_asr_printf("failed to reallocate target list\n");
1138                         return ((tid_t *)NULL);
1139                 }
1140                 /*
1141                  *      Zero and copy the whole thing, safer, simpler coding
1142                  * and not really performance critical at this point.
1143                  */
1144                 bzero (new_target_ptr, sizeof(*target_ptr)
1145                   + (sizeof(target_ptr->TID) * new_size));
1146                 bcopy (target_ptr, new_target_ptr,
1147                   sizeof(*target_ptr)
1148                   + (sizeof(target_ptr->TID) * (target_ptr->size - 1)));
1149                 bus_ptr->LUN[target] = new_target_ptr;
1150                 kfree (target_ptr, M_TEMP);
1151                 target_ptr = new_target_ptr;
1152                 target_ptr->size = new_size + 1;
1153         }
1154         /*
1155          *      Now, acquire the TID address from the LUN indexed list.
1156          */
1157         return (&(target_ptr->TID[lun]));
1158 } /* ASR_getTidAddress */
1159
1160 /*
1161  *      Get a pre-existing TID relationship.
1162  *
1163  *      If the TID was never set, return (tid_t)-1.
1164  *
1165  *      should use mutex rather than spl.
1166  */
1167 STATIC INLINE tid_t
1168 ASR_getTid (
1169         IN Asr_softc_t * sc,
1170         IN int           bus,
1171         IN int           target,
1172         IN int           lun)
1173 {
1174         tid_t          * tid_ptr;
1175         OUT tid_t        retval;
1176
1177         crit_enter();
1178         if (((tid_ptr = ASR_getTidAddress (sc, bus, target, lun, FALSE))
1179           == (tid_t *)NULL)
1180         /* (tid_t)0 or (tid_t)-1 indicate no TID */
1181          || (*tid_ptr == (tid_t)0)) {
1182                 crit_exit();
1183                 return ((tid_t)-1);
1184         }
1185         retval = *tid_ptr;
1186         crit_exit();
1187         return (retval);
1188 } /* ASR_getTid */
1189
1190 /*
1191  *      Set a TID relationship.
1192  *
1193  *      If the TID was not set, return (tid_t)-1.
1194  *
1195  *      should use mutex rather than spl.
1196  */
1197 STATIC INLINE tid_t
1198 ASR_setTid (
1199         INOUT Asr_softc_t * sc,
1200         IN int              bus,
1201         IN int              target,
1202         IN int              lun,
1203         INOUT tid_t         TID)
1204 {
1205         tid_t             * tid_ptr;
1206
1207         if (TID != (tid_t)-1) {
1208                 if (TID == 0) {
1209                         return ((tid_t)-1);
1210                 }
1211                 crit_enter();
1212                 if ((tid_ptr = ASR_getTidAddress (sc, bus, target, lun, TRUE))
1213                  == (tid_t *)NULL) {
1214                         crit_exit();
1215                         return ((tid_t)-1);
1216                 }
1217                 *tid_ptr = TID;
1218                 crit_exit();
1219         }
1220         return (TID);
1221 } /* ASR_setTid */
1222
1223 /*-------------------------------------------------------------------------*/
1224 /*                    Function ASR_rescan                                  */
1225 /*-------------------------------------------------------------------------*/
1226 /* The Parameters Passed To This Function Are :                            */
1227 /*     Asr_softc_t *     : HBA miniport driver's adapter data storage.     */
1228 /*                                                                         */
1229 /* This Function Will rescan the adapter and resynchronize any data        */
1230 /*                                                                         */
1231 /* Return : 0 For OK, Error Code Otherwise                                 */
1232 /*-------------------------------------------------------------------------*/
1233
1234 STATIC INLINE int
1235 ASR_rescan(
1236         IN Asr_softc_t * sc)
1237 {
1238         int              bus;
1239         OUT int          error;
1240
1241         /*
1242          * Re-acquire the LCT table and synchronize us to the adapter.
1243          */
1244         if ((error = ASR_acquireLct(sc)) == 0) {
1245                 error = ASR_acquireHrt(sc);
1246         }
1247
1248         if (error != 0) {
1249                 return error;
1250         }
1251
1252         bus = sc->ha_MaxBus;
1253         /* Reset all existing cached TID lookups */
1254         do {
1255                 int target, event = 0;
1256
1257                 /*
1258                  *      Scan for all targets on this bus to see if they
1259                  * got affected by the rescan.
1260                  */
1261                 for (target = 0; target <= sc->ha_MaxId; ++target) {
1262                         int lun;
1263
1264                         /* Stay away from the controller ID */
1265                         if (target == sc->ha_adapter_target[bus]) {
1266                                 continue;
1267                         }
1268                         for (lun = 0; lun <= sc->ha_MaxLun; ++lun) {
1269                                 PI2O_LCT_ENTRY Device;
1270                                 tid_t          TID = (tid_t)-1;
1271                                 tid_t          LastTID;
1272
1273                                 /*
1274                                  * See if the cached TID changed. Search for
1275                                  * the device in our new LCT.
1276                                  */
1277                                 for (Device = sc->ha_LCT->LCTEntry;
1278                                   Device < (PI2O_LCT_ENTRY)(((U32 *)sc->ha_LCT)
1279                                    + I2O_LCT_getTableSize(sc->ha_LCT));
1280                                   ++Device) {
1281                                         if ((Device->le_type != I2O_UNKNOWN)
1282                                          && (Device->le_bus == bus)
1283                                          && (Device->le_target == target)
1284                                          && (Device->le_lun == lun)
1285                                          && (I2O_LCT_ENTRY_getUserTID(Device)
1286                                           == 0xFFF)) {
1287                                                 TID = I2O_LCT_ENTRY_getLocalTID(
1288                                                   Device);
1289                                                 break;
1290                                         }
1291                                 }
1292                                 /*
1293                                  * Indicate to the OS that the label needs
1294                                  * to be recalculated, or that the specific
1295                                  * open device is no longer valid (Merde)
1296                                  * because the cached TID changed.
1297                                  */
1298                                 LastTID = ASR_getTid (sc, bus, target, lun);
1299                                 if (LastTID != TID) {
1300                                         struct cam_path * path;
1301
1302                                         if (xpt_create_path(&path,
1303                                           /*periph*/NULL,
1304                                           cam_sim_path(sc->ha_sim[bus]),
1305                                           target, lun) != CAM_REQ_CMP) {
1306                                                 if (TID == (tid_t)-1) {
1307                                                         event |= AC_LOST_DEVICE;
1308                                                 } else {
1309                                                         event |= AC_INQ_CHANGED
1310                                                                | AC_GETDEV_CHANGED;
1311                                                 }
1312                                         } else {
1313                                                 if (TID == (tid_t)-1) {
1314                                                         xpt_async(
1315                                                           AC_LOST_DEVICE,
1316                                                           path, NULL);
1317                                                 } else if (LastTID == (tid_t)-1) {
1318                                                         struct ccb_getdev ccb;
1319
1320                                                         xpt_setup_ccb(
1321                                                           &(ccb.ccb_h),
1322                                                           path, /*priority*/5);
1323                                                         xpt_async(
1324                                                           AC_FOUND_DEVICE,
1325                                                           path,
1326                                                           &ccb);
1327                                                 } else {
1328                                                         xpt_async(
1329                                                           AC_INQ_CHANGED,
1330                                                           path, NULL);
1331                                                         xpt_async(
1332                                                           AC_GETDEV_CHANGED,
1333                                                           path, NULL);
1334                                                 }
1335                                         }
1336                                 }
1337                                 /*
1338                                  *      We have the option of clearing the
1339                                  * cached TID for it to be rescanned, or to
1340                                  * set it now even if the device never got
1341                                  * accessed. We chose the later since we
1342                                  * currently do not use the condition that
1343                                  * the TID ever got cached.
1344                                  */
1345                                 ASR_setTid (sc, bus, target, lun, TID);
1346                         }
1347                 }
1348                 /*
1349                  *      The xpt layer can not handle multiple events at the
1350                  * same call.
1351                  */
1352                 if (event & AC_LOST_DEVICE) {
1353                         xpt_async(AC_LOST_DEVICE, sc->ha_path[bus], NULL);
1354                 }
1355                 if (event & AC_INQ_CHANGED) {
1356                         xpt_async(AC_INQ_CHANGED, sc->ha_path[bus], NULL);
1357                 }
1358                 if (event & AC_GETDEV_CHANGED) {
1359                         xpt_async(AC_GETDEV_CHANGED, sc->ha_path[bus], NULL);
1360                 }
1361         } while (--bus >= 0);
1362         return (error);
1363 } /* ASR_rescan */
1364
1365 /*-------------------------------------------------------------------------*/
1366 /*                    Function ASR_reset                                   */
1367 /*-------------------------------------------------------------------------*/
1368 /* The Parameters Passed To This Function Are :                            */
1369 /*     Asr_softc_t *      : HBA miniport driver's adapter data storage.    */
1370 /*                                                                         */
1371 /* This Function Will reset the adapter and resynchronize any data         */
1372 /*                                                                         */
1373 /* Return : None                                                           */
1374 /*-------------------------------------------------------------------------*/
1375
1376 STATIC INLINE int
1377 ASR_reset(
1378         IN Asr_softc_t * sc)
1379 {
1380         int              retVal;
1381
1382         crit_enter();
1383         if ((sc->ha_in_reset == HA_IN_RESET)
1384          || (sc->ha_in_reset == HA_OFF_LINE_RECOVERY)) {
1385                 crit_exit();
1386                 return (EBUSY);
1387         }
1388         /*
1389          *      Promotes HA_OPERATIONAL to HA_IN_RESET,
1390          * or HA_OFF_LINE to HA_OFF_LINE_RECOVERY.
1391          */
1392         ++(sc->ha_in_reset);
1393         if (ASR_resetIOP (sc->ha_Virt, sc->ha_Fvirt) == 0) {
1394                 debug_asr_printf ("ASR_resetIOP failed\n");
1395                 /*
1396                  *      We really need to take this card off-line, easier said
1397                  * than make sense. Better to keep retrying for now since if a
1398                  * UART cable is connected the blinkLEDs the adapter is now in
1399                  * a hard state requiring action from the monitor commands to
1400                  * the HBA to continue. For debugging waiting forever is a
1401                  * good thing. In a production system, however, one may wish
1402                  * to instead take the card off-line ...
1403                  */
1404 #               if 0 && (defined(HA_OFF_LINE))
1405                         /*
1406                          * Take adapter off-line.
1407                          */
1408                         kprintf ("asr%d: Taking adapter off-line\n",
1409                           sc->ha_path[0]
1410                             ? cam_sim_unit(xpt_path_sim(sc->ha_path[0]))
1411                             : 0);
1412                         sc->ha_in_reset = HA_OFF_LINE;
1413                         crit_exit();
1414                         return (ENXIO);
1415 #               else
1416                         /* Wait Forever */
1417                         while (ASR_resetIOP (sc->ha_Virt, sc->ha_Fvirt) == 0);
1418 #               endif
1419         }
1420         retVal = ASR_init (sc);
1421         crit_exit();
1422         if (retVal != 0) {
1423                 debug_asr_printf ("ASR_init failed\n");
1424                 sc->ha_in_reset = HA_OFF_LINE;
1425                 return (ENXIO);
1426         }
1427         if (ASR_rescan (sc) != 0) {
1428                 debug_asr_printf ("ASR_rescan failed\n");
1429         }
1430         ASR_failActiveCommands (sc);
1431         if (sc->ha_in_reset == HA_OFF_LINE_RECOVERY) {
1432                 kprintf ("asr%d: Brining adapter back on-line\n",
1433                   sc->ha_path[0]
1434                     ? cam_sim_unit(xpt_path_sim(sc->ha_path[0]))
1435                     : 0);
1436         }
1437         sc->ha_in_reset = HA_OPERATIONAL;
1438         return (0);
1439 } /* ASR_reset */
1440
1441 /*
1442  *      Device timeout handler.
1443  */
1444 STATIC void
1445 asr_timeout(
1446         INOUT void  * arg)
1447 {
1448         union asr_ccb * ccb = (union asr_ccb *)arg;
1449         Asr_softc_t   * sc = (Asr_softc_t *)(ccb->ccb_h.spriv_ptr0);
1450         int             s;
1451
1452         debug_asr_print_path(ccb);
1453         debug_asr_printf("timed out");
1454
1455         /*
1456          *      Check if the adapter has locked up?
1457          */
1458         if ((s = ASR_getBlinkLedCode(sc)) != 0) {
1459                 /* Reset Adapter */
1460                 kprintf ("asr%d: Blink LED 0x%x resetting adapter\n",
1461                   cam_sim_unit(xpt_path_sim(ccb->ccb_h.path)), s);
1462                 if (ASR_reset (sc) == ENXIO) {
1463                         /* Try again later */
1464                         callout_reset(&ccb->ccb_h.timeout_ch,
1465                             (ccb->ccb_h.timeout * hz) / 1000, asr_timeout, ccb);
1466                 }
1467                 return;
1468         }
1469         /*
1470          *      Abort does not function on the ASR card!!! Walking away from
1471          * the SCSI command is also *very* dangerous. A SCSI BUS reset is
1472          * our best bet, followed by a complete adapter reset if that fails.
1473          */
1474         crit_enter();
1475         /* Check if we already timed out once to raise the issue */
1476         if ((ccb->ccb_h.status & CAM_STATUS_MASK) == CAM_CMD_TIMEOUT) {
1477                 debug_asr_printf (" AGAIN\nreinitializing adapter\n");
1478                 if (ASR_reset (sc) == ENXIO) {
1479                         callout_reset(&ccb->ccb_h.timeout_ch,
1480                             (ccb->ccb_h.timeout * hz) / 1000, asr_timeout, ccb);
1481                 }
1482                 crit_exit();
1483                 return;
1484         }
1485         debug_asr_printf ("\nresetting bus\n");
1486         /* If the BUS reset does not take, then an adapter reset is next! */
1487         ccb->ccb_h.status &= ~CAM_STATUS_MASK;
1488         ccb->ccb_h.status |= CAM_CMD_TIMEOUT;
1489         callout_reset(&ccb->ccb_h.timeout_ch, (ccb->ccb_h.timeout * hz) / 1000,
1490                       asr_timeout, ccb);
1491         ASR_resetBus (sc, cam_sim_bus(xpt_path_sim(ccb->ccb_h.path)));
1492         xpt_async (AC_BUS_RESET, ccb->ccb_h.path, NULL);
1493         crit_exit();
1494 } /* asr_timeout */
1495
1496 /*
1497  * send a message asynchronously
1498  */
1499 STATIC INLINE int
1500 ASR_queue(
1501         IN Asr_softc_t      * sc,
1502         IN PI2O_MESSAGE_FRAME Message)
1503 {
1504         OUT U32               MessageOffset;
1505         union asr_ccb       * ccb;
1506
1507         debug_asr_printf ("Host Command Dump:\n");
1508         debug_asr_dump_message (Message);
1509
1510         ccb = (union asr_ccb *)(long)
1511           I2O_MESSAGE_FRAME_getInitiatorContext64(Message);
1512
1513         if ((MessageOffset = ASR_getMessage(sc->ha_Virt)) != EMPTY_QUEUE) {
1514                 bcopy (Message, sc->ha_Fvirt + MessageOffset,
1515                   I2O_MESSAGE_FRAME_getMessageSize(Message) << 2);
1516                 if (ccb) {
1517                         ASR_ccbAdd (sc, ccb);
1518                 }
1519                 /* Post the command */
1520                 sc->ha_Virt->ToFIFO = MessageOffset;
1521         } else {
1522                 if (ASR_getBlinkLedCode(sc)) {
1523                         /*
1524                          *      Unlikely we can do anything if we can't grab a
1525                          * message frame :-(, but lets give it a try.
1526                          */
1527                         (void)ASR_reset (sc);
1528                 }
1529         }
1530         return (MessageOffset);
1531 } /* ASR_queue */
1532
1533
1534 /* Simple Scatter Gather elements */
1535 #define SG(SGL,Index,Flags,Buffer,Size)                            \
1536         I2O_FLAGS_COUNT_setCount(                                  \
1537           &(((PI2O_SG_ELEMENT)(SGL))->u.Simple[Index].FlagsCount), \
1538           Size);                                                   \
1539         I2O_FLAGS_COUNT_setFlags(                                  \
1540           &(((PI2O_SG_ELEMENT)(SGL))->u.Simple[Index].FlagsCount), \
1541           I2O_SGL_FLAGS_SIMPLE_ADDRESS_ELEMENT | (Flags));         \
1542         I2O_SGE_SIMPLE_ELEMENT_setPhysicalAddress(                 \
1543           &(((PI2O_SG_ELEMENT)(SGL))->u.Simple[Index]),            \
1544           (Buffer == NULL) ? NULL : KVTOPHYS(Buffer))
1545
1546 /*
1547  *      Retrieve Parameter Group.
1548  *              Buffer must be allocated using defAlignLong macro.
1549  */
1550 STATIC void *
1551 ASR_getParams(
1552         IN Asr_softc_t                     * sc,
1553         IN tid_t                             TID,
1554         IN int                               Group,
1555         OUT void                           * Buffer,
1556         IN unsigned                          BufferSize)
1557 {
1558         struct paramGetMessage {
1559                 I2O_UTIL_PARAMS_GET_MESSAGE M;
1560                 char                         F[
1561                   sizeof(I2O_SGE_SIMPLE_ELEMENT)*2 - sizeof(I2O_SG_ELEMENT)];
1562                 struct Operations {
1563                         I2O_PARAM_OPERATIONS_LIST_HEADER Header;
1564                         I2O_PARAM_OPERATION_ALL_TEMPLATE Template[1];
1565                 }                            O;
1566         };
1567         defAlignLong(struct paramGetMessage, Message);
1568         struct Operations                  * Operations_Ptr;
1569         I2O_UTIL_PARAMS_GET_MESSAGE        * Message_Ptr;
1570         struct ParamBuffer {
1571                 I2O_PARAM_RESULTS_LIST_HEADER       Header;
1572                 I2O_PARAM_READ_OPERATION_RESULT     Read;
1573                 char                                Info[1];
1574         }                                  * Buffer_Ptr;
1575
1576         Message_Ptr = (I2O_UTIL_PARAMS_GET_MESSAGE *)ASR_fillMessage(Message,
1577           sizeof(I2O_UTIL_PARAMS_GET_MESSAGE)
1578             + sizeof(I2O_SGE_SIMPLE_ELEMENT)*2 - sizeof(I2O_SG_ELEMENT));
1579         Operations_Ptr = (struct Operations *)((char *)Message_Ptr
1580           + sizeof(I2O_UTIL_PARAMS_GET_MESSAGE)
1581           + sizeof(I2O_SGE_SIMPLE_ELEMENT)*2 - sizeof(I2O_SG_ELEMENT));
1582         bzero ((void *)Operations_Ptr, sizeof(struct Operations));
1583         I2O_PARAM_OPERATIONS_LIST_HEADER_setOperationCount(
1584           &(Operations_Ptr->Header), 1);
1585         I2O_PARAM_OPERATION_ALL_TEMPLATE_setOperation(
1586           &(Operations_Ptr->Template[0]), I2O_PARAMS_OPERATION_FIELD_GET);
1587         I2O_PARAM_OPERATION_ALL_TEMPLATE_setFieldCount(
1588           &(Operations_Ptr->Template[0]), 0xFFFF);
1589         I2O_PARAM_OPERATION_ALL_TEMPLATE_setGroupNumber(
1590           &(Operations_Ptr->Template[0]), Group);
1591         bzero ((void *)(Buffer_Ptr = getAlignLong(struct ParamBuffer, Buffer)),
1592           BufferSize);
1593
1594         I2O_MESSAGE_FRAME_setVersionOffset(&(Message_Ptr->StdMessageFrame),
1595           I2O_VERSION_11
1596           + (((sizeof(I2O_UTIL_PARAMS_GET_MESSAGE) - sizeof(I2O_SG_ELEMENT))
1597             / sizeof(U32)) << 4));
1598         I2O_MESSAGE_FRAME_setTargetAddress (&(Message_Ptr->StdMessageFrame),
1599           TID);
1600         I2O_MESSAGE_FRAME_setFunction (&(Message_Ptr->StdMessageFrame),
1601           I2O_UTIL_PARAMS_GET);
1602         /*
1603          *  Set up the buffers as scatter gather elements.
1604          */
1605         SG(&(Message_Ptr->SGL), 0,
1606           I2O_SGL_FLAGS_DIR | I2O_SGL_FLAGS_END_OF_BUFFER,
1607           Operations_Ptr, sizeof(struct Operations));
1608         SG(&(Message_Ptr->SGL), 1,
1609           I2O_SGL_FLAGS_LAST_ELEMENT | I2O_SGL_FLAGS_END_OF_BUFFER,
1610           Buffer_Ptr, BufferSize);
1611
1612         if ((ASR_queue_c(sc, (PI2O_MESSAGE_FRAME)Message_Ptr) == CAM_REQ_CMP)
1613          && (Buffer_Ptr->Header.ResultCount)) {
1614                 return ((void *)(Buffer_Ptr->Info));
1615         }
1616         return ((void *)NULL);
1617 } /* ASR_getParams */
1618
1619 /*
1620  *      Acquire the LCT information.
1621  */
1622 STATIC INLINE int
1623 ASR_acquireLct (
1624         INOUT Asr_softc_t          * sc)
1625 {
1626         PI2O_EXEC_LCT_NOTIFY_MESSAGE Message_Ptr;
1627         PI2O_SGE_SIMPLE_ELEMENT      sg;
1628         int                          MessageSizeInBytes;
1629         caddr_t                      v;
1630         int                          len;
1631         I2O_LCT                      Table;
1632         PI2O_LCT_ENTRY               Entry;
1633
1634         /*
1635          *      sc value assumed valid
1636          */
1637         MessageSizeInBytes = sizeof(I2O_EXEC_LCT_NOTIFY_MESSAGE)
1638           - sizeof(I2O_SG_ELEMENT) + sizeof(I2O_SGE_SIMPLE_ELEMENT);
1639         if ((Message_Ptr = (PI2O_EXEC_LCT_NOTIFY_MESSAGE)kmalloc (
1640           MessageSizeInBytes, M_TEMP, M_WAITOK))
1641           == (PI2O_EXEC_LCT_NOTIFY_MESSAGE)NULL) {
1642                 return (ENOMEM);
1643         }
1644         (void)ASR_fillMessage((char *)Message_Ptr, MessageSizeInBytes);
1645         I2O_MESSAGE_FRAME_setVersionOffset(&(Message_Ptr->StdMessageFrame),
1646           (I2O_VERSION_11 +
1647           (((sizeof(I2O_EXEC_LCT_NOTIFY_MESSAGE) - sizeof(I2O_SG_ELEMENT))
1648                         / sizeof(U32)) << 4)));
1649         I2O_MESSAGE_FRAME_setFunction(&(Message_Ptr->StdMessageFrame),
1650           I2O_EXEC_LCT_NOTIFY);
1651         I2O_EXEC_LCT_NOTIFY_MESSAGE_setClassIdentifier(Message_Ptr,
1652           I2O_CLASS_MATCH_ANYCLASS);
1653         /*
1654          *      Call the LCT table to determine the number of device entries
1655          * to reserve space for.
1656          */
1657         SG(&(Message_Ptr->SGL), 0,
1658           I2O_SGL_FLAGS_LAST_ELEMENT | I2O_SGL_FLAGS_END_OF_BUFFER, &Table,
1659           sizeof(I2O_LCT));
1660         /*
1661          *      since this code is reused in several systems, code efficiency
1662          * is greater by using a shift operation rather than a divide by
1663          * sizeof(u_int32_t).
1664          */
1665         I2O_LCT_setTableSize(&Table,
1666           (sizeof(I2O_LCT) - sizeof(I2O_LCT_ENTRY)) >> 2);
1667         (void)ASR_queue_c(sc, (PI2O_MESSAGE_FRAME)Message_Ptr);
1668         /*
1669          *      Determine the size of the LCT table.
1670          */
1671         if (sc->ha_LCT) {
1672                 kfree (sc->ha_LCT, M_TEMP);
1673         }
1674         /*
1675          *      kmalloc only generates contiguous memory when less than a
1676          * page is expected. We must break the request up into an SG list ...
1677          */
1678         if (((len = (I2O_LCT_getTableSize(&Table) << 2)) <=
1679           (sizeof(I2O_LCT) - sizeof(I2O_LCT_ENTRY)))
1680          || (len > (128 * 1024))) {     /* Arbitrary */
1681                 kfree (Message_Ptr, M_TEMP);
1682                 return (EINVAL);
1683         }
1684         if ((sc->ha_LCT = (PI2O_LCT)kmalloc (len, M_TEMP, M_WAITOK))
1685           == (PI2O_LCT)NULL) {
1686                 kfree (Message_Ptr, M_TEMP);
1687                 return (ENOMEM);
1688         }
1689         /*
1690          *      since this code is reused in several systems, code efficiency
1691          * is greater by using a shift operation rather than a divide by
1692          * sizeof(u_int32_t).
1693          */
1694         I2O_LCT_setTableSize(sc->ha_LCT,
1695           (sizeof(I2O_LCT) - sizeof(I2O_LCT_ENTRY)) >> 2);
1696         /*
1697          *      Convert the access to the LCT table into a SG list.
1698          */
1699         sg = Message_Ptr->SGL.u.Simple;
1700         v = (caddr_t)(sc->ha_LCT);
1701         for (;;) {
1702                 int next, base, span;
1703
1704                 span = 0;
1705                 next = base = KVTOPHYS(v);
1706                 I2O_SGE_SIMPLE_ELEMENT_setPhysicalAddress(sg, base);
1707
1708                 /* How far can we go contiguously */
1709                 while ((len > 0) && (base == next)) {
1710                         int size;
1711
1712                         next = trunc_page(base) + PAGE_SIZE;
1713                         size = next - base;
1714                         if (size > len) {
1715                                 size = len;
1716                         }
1717                         span += size;
1718                         v += size;
1719                         len -= size;
1720                         base = KVTOPHYS(v);
1721                 }
1722
1723                 /* Construct the Flags */
1724                 I2O_FLAGS_COUNT_setCount(&(sg->FlagsCount), span);
1725                 {
1726                         int rw = I2O_SGL_FLAGS_SIMPLE_ADDRESS_ELEMENT;
1727                         if (len <= 0) {
1728                                 rw = (I2O_SGL_FLAGS_SIMPLE_ADDRESS_ELEMENT
1729                                     | I2O_SGL_FLAGS_LAST_ELEMENT
1730                                     | I2O_SGL_FLAGS_END_OF_BUFFER);
1731                         }
1732                         I2O_FLAGS_COUNT_setFlags(&(sg->FlagsCount), rw);
1733                 }
1734
1735                 if (len <= 0) {
1736                         break;
1737                 }
1738
1739                 /*
1740                  * Incrementing requires resizing of the packet.
1741                  */
1742                 ++sg;
1743                 MessageSizeInBytes += sizeof(*sg);
1744                 I2O_MESSAGE_FRAME_setMessageSize(
1745                   &(Message_Ptr->StdMessageFrame),
1746                   I2O_MESSAGE_FRAME_getMessageSize(
1747                     &(Message_Ptr->StdMessageFrame))
1748                   + (sizeof(*sg) / sizeof(U32)));
1749                 {
1750                         PI2O_EXEC_LCT_NOTIFY_MESSAGE NewMessage_Ptr;
1751
1752                         if ((NewMessage_Ptr = (PI2O_EXEC_LCT_NOTIFY_MESSAGE)
1753                             kmalloc (MessageSizeInBytes, M_TEMP, M_WAITOK))
1754                             == (PI2O_EXEC_LCT_NOTIFY_MESSAGE)NULL) {
1755                                 kfree (sc->ha_LCT, M_TEMP);
1756                                 sc->ha_LCT = (PI2O_LCT)NULL;
1757                                 kfree (Message_Ptr, M_TEMP);
1758                                 return (ENOMEM);
1759                         }
1760                         span = ((caddr_t)sg) - (caddr_t)Message_Ptr;
1761                         bcopy ((caddr_t)Message_Ptr,
1762                           (caddr_t)NewMessage_Ptr, span);
1763                         kfree (Message_Ptr, M_TEMP);
1764                         sg = (PI2O_SGE_SIMPLE_ELEMENT)
1765                           (((caddr_t)NewMessage_Ptr) + span);
1766                         Message_Ptr = NewMessage_Ptr;
1767                 }
1768         }
1769         {       int retval;
1770
1771                 retval = ASR_queue_c(sc, (PI2O_MESSAGE_FRAME)Message_Ptr);
1772                 kfree (Message_Ptr, M_TEMP);
1773                 if (retval != CAM_REQ_CMP) {
1774                         return (ENODEV);
1775                 }
1776         }
1777         /* If the LCT table grew, lets truncate accesses */
1778         if (I2O_LCT_getTableSize(&Table) < I2O_LCT_getTableSize(sc->ha_LCT)) {
1779                 I2O_LCT_setTableSize(sc->ha_LCT, I2O_LCT_getTableSize(&Table));
1780         }
1781         for (Entry = sc->ha_LCT->LCTEntry; Entry < (PI2O_LCT_ENTRY)
1782           (((U32 *)sc->ha_LCT)+I2O_LCT_getTableSize(sc->ha_LCT));
1783           ++Entry) {
1784                 Entry->le_type = I2O_UNKNOWN;
1785                 switch (I2O_CLASS_ID_getClass(&(Entry->ClassID))) {
1786
1787                 case I2O_CLASS_RANDOM_BLOCK_STORAGE:
1788                         Entry->le_type = I2O_BSA;
1789                         break;
1790
1791                 case I2O_CLASS_SCSI_PERIPHERAL:
1792                         Entry->le_type = I2O_SCSI;
1793                         break;
1794
1795                 case I2O_CLASS_FIBRE_CHANNEL_PERIPHERAL:
1796                         Entry->le_type = I2O_FCA;
1797                         break;
1798
1799                 case I2O_CLASS_BUS_ADAPTER_PORT:
1800                         Entry->le_type = I2O_PORT | I2O_SCSI;
1801                         /* FALLTHRU */
1802                 case I2O_CLASS_FIBRE_CHANNEL_PORT:
1803                         if (I2O_CLASS_ID_getClass(&(Entry->ClassID)) ==
1804                           I2O_CLASS_FIBRE_CHANNEL_PORT) {
1805                                 Entry->le_type = I2O_PORT | I2O_FCA;
1806                         }
1807                 {       struct ControllerInfo {
1808                                 I2O_PARAM_RESULTS_LIST_HEADER       Header;
1809                                 I2O_PARAM_READ_OPERATION_RESULT     Read;
1810                                 I2O_HBA_SCSI_CONTROLLER_INFO_SCALAR Info;
1811                         };
1812                         defAlignLong(struct ControllerInfo, Buffer);
1813                         PI2O_HBA_SCSI_CONTROLLER_INFO_SCALAR Info;
1814
1815                         Entry->le_bus = 0xff;
1816                         Entry->le_target = 0xff;
1817                         Entry->le_lun = 0xff;
1818
1819                         if ((Info = (PI2O_HBA_SCSI_CONTROLLER_INFO_SCALAR)
1820                           ASR_getParams(sc,
1821                             I2O_LCT_ENTRY_getLocalTID(Entry),
1822                             I2O_HBA_SCSI_CONTROLLER_INFO_GROUP_NO,
1823                             Buffer, sizeof(struct ControllerInfo)))
1824                         == (PI2O_HBA_SCSI_CONTROLLER_INFO_SCALAR)NULL) {
1825                                 continue;
1826                         }
1827                         Entry->le_target
1828                           = I2O_HBA_SCSI_CONTROLLER_INFO_SCALAR_getInitiatorID(
1829                             Info);
1830                         Entry->le_lun = 0;
1831                 }       /* FALLTHRU */
1832                 default:
1833                         continue;
1834                 }
1835                 {       struct DeviceInfo {
1836                                 I2O_PARAM_RESULTS_LIST_HEADER   Header;
1837                                 I2O_PARAM_READ_OPERATION_RESULT Read;
1838                                 I2O_DPT_DEVICE_INFO_SCALAR      Info;
1839                         };
1840                         defAlignLong (struct DeviceInfo, Buffer);
1841                         PI2O_DPT_DEVICE_INFO_SCALAR      Info;
1842
1843                         Entry->le_bus = 0xff;
1844                         Entry->le_target = 0xff;
1845                         Entry->le_lun = 0xff;
1846
1847                         if ((Info = (PI2O_DPT_DEVICE_INFO_SCALAR)
1848                           ASR_getParams(sc,
1849                             I2O_LCT_ENTRY_getLocalTID(Entry),
1850                             I2O_DPT_DEVICE_INFO_GROUP_NO,
1851                             Buffer, sizeof(struct DeviceInfo)))
1852                         == (PI2O_DPT_DEVICE_INFO_SCALAR)NULL) {
1853                                 continue;
1854                         }
1855                         Entry->le_type
1856                           |= I2O_DPT_DEVICE_INFO_SCALAR_getDeviceType(Info);
1857                         Entry->le_bus
1858                           = I2O_DPT_DEVICE_INFO_SCALAR_getBus(Info);
1859                         if ((Entry->le_bus > sc->ha_MaxBus)
1860                          && (Entry->le_bus <= MAX_CHANNEL)) {
1861                                 sc->ha_MaxBus = Entry->le_bus;
1862                         }
1863                         Entry->le_target
1864                           = I2O_DPT_DEVICE_INFO_SCALAR_getIdentifier(Info);
1865                         Entry->le_lun
1866                           = I2O_DPT_DEVICE_INFO_SCALAR_getLunInfo(Info);
1867                 }
1868         }
1869         /*
1870          *      A zero return value indicates success.
1871          */
1872         return (0);
1873 } /* ASR_acquireLct */
1874
1875 /*
1876  * Initialize a message frame.
1877  * We assume that the CDB has already been set up, so all we do here is
1878  * generate the Scatter Gather list.
1879  */
1880 STATIC INLINE PI2O_MESSAGE_FRAME
1881 ASR_init_message(
1882         IN union asr_ccb      * ccb,
1883         OUT PI2O_MESSAGE_FRAME  Message)
1884 {
1885         int                     next, span, base, rw;
1886         OUT PI2O_MESSAGE_FRAME  Message_Ptr;
1887         Asr_softc_t           * sc = (Asr_softc_t *)(ccb->ccb_h.spriv_ptr0);
1888         PI2O_SGE_SIMPLE_ELEMENT sg;
1889         caddr_t                 v;
1890         vm_size_t               size, len;
1891         U32                     MessageSize;
1892
1893         /* We only need to zero out the PRIVATE_SCSI_SCB_EXECUTE_MESSAGE */
1894         bzero (Message_Ptr = getAlignLong(I2O_MESSAGE_FRAME, Message),
1895           (sizeof(PRIVATE_SCSI_SCB_EXECUTE_MESSAGE) - sizeof(I2O_SG_ELEMENT)));
1896
1897         {
1898                 int   target = ccb->ccb_h.target_id;
1899                 int   lun = ccb->ccb_h.target_lun;
1900                 int   bus = cam_sim_bus(xpt_path_sim(ccb->ccb_h.path));
1901                 tid_t TID;
1902
1903                 if ((TID = ASR_getTid (sc, bus, target, lun)) == (tid_t)-1) {
1904                         PI2O_LCT_ENTRY Device;
1905
1906                         TID = (tid_t)0;
1907                         for (Device = sc->ha_LCT->LCTEntry; Device < (PI2O_LCT_ENTRY)
1908                           (((U32 *)sc->ha_LCT)+I2O_LCT_getTableSize(sc->ha_LCT));
1909                           ++Device) {
1910                                 if ((Device->le_type != I2O_UNKNOWN)
1911                                  && (Device->le_bus == bus)
1912                                  && (Device->le_target == target)
1913                                  && (Device->le_lun == lun)
1914                                  && (I2O_LCT_ENTRY_getUserTID(Device) == 0xFFF)) {
1915                                         TID = I2O_LCT_ENTRY_getLocalTID(Device);
1916                                         ASR_setTid (sc, Device->le_bus,
1917                                           Device->le_target, Device->le_lun,
1918                                           TID);
1919                                         break;
1920                                 }
1921                         }
1922                 }
1923                 if (TID == (tid_t)0) {
1924                         return ((PI2O_MESSAGE_FRAME)NULL);
1925                 }
1926                 I2O_MESSAGE_FRAME_setTargetAddress(Message_Ptr, TID);
1927                 PRIVATE_SCSI_SCB_EXECUTE_MESSAGE_setTID(
1928                   (PPRIVATE_SCSI_SCB_EXECUTE_MESSAGE)Message_Ptr, TID);
1929         }
1930         I2O_MESSAGE_FRAME_setVersionOffset(Message_Ptr, I2O_VERSION_11 |
1931           (((sizeof(PRIVATE_SCSI_SCB_EXECUTE_MESSAGE) - sizeof(I2O_SG_ELEMENT))
1932                 / sizeof(U32)) << 4));
1933         I2O_MESSAGE_FRAME_setMessageSize(Message_Ptr,
1934           (sizeof(PRIVATE_SCSI_SCB_EXECUTE_MESSAGE)
1935           - sizeof(I2O_SG_ELEMENT)) / sizeof(U32));
1936         I2O_MESSAGE_FRAME_setInitiatorAddress (Message_Ptr, 1);
1937         I2O_MESSAGE_FRAME_setFunction(Message_Ptr, I2O_PRIVATE_MESSAGE);
1938         I2O_PRIVATE_MESSAGE_FRAME_setXFunctionCode (
1939           (PI2O_PRIVATE_MESSAGE_FRAME)Message_Ptr, I2O_SCSI_SCB_EXEC);
1940         PRIVATE_SCSI_SCB_EXECUTE_MESSAGE_setSCBFlags (
1941           (PPRIVATE_SCSI_SCB_EXECUTE_MESSAGE)Message_Ptr,
1942             I2O_SCB_FLAG_ENABLE_DISCONNECT
1943           | I2O_SCB_FLAG_SIMPLE_QUEUE_TAG
1944           | I2O_SCB_FLAG_SENSE_DATA_IN_BUFFER);
1945         /*
1946          * We do not need any (optional byteswapping) method access to
1947          * the Initiator & Transaction context field.
1948          */
1949         I2O_MESSAGE_FRAME_setInitiatorContext64(Message, (long)ccb);
1950
1951         I2O_PRIVATE_MESSAGE_FRAME_setOrganizationID(
1952           (PI2O_PRIVATE_MESSAGE_FRAME)Message_Ptr, DPT_ORGANIZATION_ID);
1953         /*
1954          * copy the cdb over
1955          */
1956         PRIVATE_SCSI_SCB_EXECUTE_MESSAGE_setCDBLength(
1957           (PPRIVATE_SCSI_SCB_EXECUTE_MESSAGE)Message_Ptr, ccb->csio.cdb_len);
1958         bcopy (&(ccb->csio.cdb_io),
1959           ((PPRIVATE_SCSI_SCB_EXECUTE_MESSAGE)Message_Ptr)->CDB, ccb->csio.cdb_len);
1960
1961         /*
1962          * Given a buffer describing a transfer, set up a scatter/gather map
1963          * in a ccb to map that SCSI transfer.
1964          */
1965
1966         rw = (ccb->ccb_h.flags & CAM_DIR_IN) ? 0 : I2O_SGL_FLAGS_DIR;
1967
1968         PRIVATE_SCSI_SCB_EXECUTE_MESSAGE_setSCBFlags (
1969           (PPRIVATE_SCSI_SCB_EXECUTE_MESSAGE)Message_Ptr,
1970           (ccb->csio.dxfer_len)
1971             ? ((rw) ? (I2O_SCB_FLAG_XFER_TO_DEVICE
1972                      | I2O_SCB_FLAG_ENABLE_DISCONNECT
1973                      | I2O_SCB_FLAG_SIMPLE_QUEUE_TAG
1974                      | I2O_SCB_FLAG_SENSE_DATA_IN_BUFFER)
1975                     : (I2O_SCB_FLAG_XFER_FROM_DEVICE
1976                      | I2O_SCB_FLAG_ENABLE_DISCONNECT
1977                      | I2O_SCB_FLAG_SIMPLE_QUEUE_TAG
1978                      | I2O_SCB_FLAG_SENSE_DATA_IN_BUFFER))
1979             :         (I2O_SCB_FLAG_ENABLE_DISCONNECT
1980                      | I2O_SCB_FLAG_SIMPLE_QUEUE_TAG
1981                      | I2O_SCB_FLAG_SENSE_DATA_IN_BUFFER));
1982
1983         /*
1984          * Given a transfer described by a `data', fill in the SG list.
1985          */
1986         sg = &((PPRIVATE_SCSI_SCB_EXECUTE_MESSAGE)Message_Ptr)->SGL.u.Simple[0];
1987
1988         len = ccb->csio.dxfer_len;
1989         v = ccb->csio.data_ptr;
1990         ASSERT (ccb->csio.dxfer_len >= 0);
1991         MessageSize = I2O_MESSAGE_FRAME_getMessageSize(Message_Ptr);
1992         PRIVATE_SCSI_SCB_EXECUTE_MESSAGE_setByteCount(
1993           (PPRIVATE_SCSI_SCB_EXECUTE_MESSAGE)Message_Ptr, len);
1994         while ((len > 0) && (sg < &((PPRIVATE_SCSI_SCB_EXECUTE_MESSAGE)
1995           Message_Ptr)->SGL.u.Simple[SG_SIZE])) {
1996                 span = 0;
1997                 next = base = KVTOPHYS(v);
1998                 I2O_SGE_SIMPLE_ELEMENT_setPhysicalAddress(sg, base);
1999
2000                 /* How far can we go contiguously */
2001                 while ((len > 0) && (base == next)) {
2002                         next = trunc_page(base) + PAGE_SIZE;
2003                         size = next - base;
2004                         if (size > len) {
2005                                 size = len;
2006                         }
2007                         span += size;
2008                         v += size;
2009                         len -= size;
2010                         base = KVTOPHYS(v);
2011                 }
2012
2013                 I2O_FLAGS_COUNT_setCount(&(sg->FlagsCount), span);
2014                 if (len == 0) {
2015                         rw |= I2O_SGL_FLAGS_LAST_ELEMENT;
2016                 }
2017                 I2O_FLAGS_COUNT_setFlags(&(sg->FlagsCount),
2018                   I2O_SGL_FLAGS_SIMPLE_ADDRESS_ELEMENT | rw);
2019                 ++sg;
2020                 MessageSize += sizeof(*sg) / sizeof(U32);
2021         }
2022         /* We always do the request sense ... */
2023         if ((span = ccb->csio.sense_len) == 0) {
2024                 span = sizeof(ccb->csio.sense_data);
2025         }
2026         SG(sg, 0, I2O_SGL_FLAGS_LAST_ELEMENT | I2O_SGL_FLAGS_END_OF_BUFFER,
2027           &(ccb->csio.sense_data), span);
2028         I2O_MESSAGE_FRAME_setMessageSize(Message_Ptr,
2029           MessageSize + (sizeof(*sg) / sizeof(U32)));
2030         return (Message_Ptr);
2031 } /* ASR_init_message */
2032
2033 /*
2034  *      Reset the adapter.
2035  */
2036 STATIC INLINE U32
2037 ASR_initOutBound (
2038         INOUT Asr_softc_t                     * sc)
2039 {
2040         struct initOutBoundMessage {
2041                 I2O_EXEC_OUTBOUND_INIT_MESSAGE M;
2042                 U32                            R;
2043         };
2044         defAlignLong(struct initOutBoundMessage,Message);
2045         PI2O_EXEC_OUTBOUND_INIT_MESSAGE         Message_Ptr;
2046         OUT U32                      * volatile Reply_Ptr;
2047         U32                                     Old;
2048
2049         /*
2050          *  Build up our copy of the Message.
2051          */
2052         Message_Ptr = (PI2O_EXEC_OUTBOUND_INIT_MESSAGE)ASR_fillMessage(Message,
2053           sizeof(I2O_EXEC_OUTBOUND_INIT_MESSAGE));
2054         I2O_MESSAGE_FRAME_setFunction(&(Message_Ptr->StdMessageFrame),
2055           I2O_EXEC_OUTBOUND_INIT);
2056         I2O_EXEC_OUTBOUND_INIT_MESSAGE_setHostPageFrameSize(Message_Ptr, PAGE_SIZE);
2057         I2O_EXEC_OUTBOUND_INIT_MESSAGE_setOutboundMFrameSize(Message_Ptr,
2058           sizeof(I2O_SCSI_ERROR_REPLY_MESSAGE_FRAME));
2059         /*
2060          *  Reset the Reply Status
2061          */
2062         *(Reply_Ptr = (U32 *)((char *)Message_Ptr
2063           + sizeof(I2O_EXEC_OUTBOUND_INIT_MESSAGE))) = 0;
2064         SG (&(Message_Ptr->SGL), 0, I2O_SGL_FLAGS_LAST_ELEMENT, Reply_Ptr,
2065           sizeof(U32));
2066         /*
2067          *      Send the Message out
2068          */
2069         if ((Old = ASR_initiateCp (sc->ha_Virt, sc->ha_Fvirt, (PI2O_MESSAGE_FRAME)Message_Ptr)) != (U32)-1L) {
2070                 u_long size, addr;
2071
2072                 /*
2073                  *      Wait for a response (Poll).
2074                  */
2075                 while (*Reply_Ptr < I2O_EXEC_OUTBOUND_INIT_REJECTED);
2076                 /*
2077                  *      Re-enable the interrupts.
2078                  */
2079                 sc->ha_Virt->Mask = Old;
2080                 /*
2081                  *      Populate the outbound table.
2082                  */
2083                 if (sc->ha_Msgs == (PI2O_SCSI_ERROR_REPLY_MESSAGE_FRAME)NULL) {
2084
2085                         /* Allocate the reply frames */
2086                         size = sizeof(I2O_SCSI_ERROR_REPLY_MESSAGE_FRAME)
2087                           * sc->ha_Msgs_Count;
2088
2089                         /*
2090                          *      contigmalloc only works reliably at
2091                          * initialization time.
2092                          */
2093                         if ((sc->ha_Msgs = (PI2O_SCSI_ERROR_REPLY_MESSAGE_FRAME)
2094                           contigmalloc (size, M_DEVBUF, M_WAITOK, 0ul,
2095                             0xFFFFFFFFul, (u_long)sizeof(U32), 0ul))
2096                           != (PI2O_SCSI_ERROR_REPLY_MESSAGE_FRAME)NULL) {
2097                                 (void)bzero ((char *)sc->ha_Msgs, size);
2098                                 sc->ha_Msgs_Phys = KVTOPHYS(sc->ha_Msgs);
2099                         }
2100                 }
2101
2102                 /* Initialize the outbound FIFO */
2103                 if (sc->ha_Msgs != (PI2O_SCSI_ERROR_REPLY_MESSAGE_FRAME)NULL)
2104                 for (size = sc->ha_Msgs_Count, addr = sc->ha_Msgs_Phys;
2105                   size; --size) {
2106                         sc->ha_Virt->FromFIFO = addr;
2107                         addr += sizeof(I2O_SCSI_ERROR_REPLY_MESSAGE_FRAME);
2108                 }
2109                 return (*Reply_Ptr);
2110         }
2111         return (0);
2112 } /* ASR_initOutBound */
2113
2114 /*
2115  *      Set the system table
2116  */
2117 STATIC INLINE int
2118 ASR_setSysTab(
2119         IN Asr_softc_t              * sc)
2120 {
2121         PI2O_EXEC_SYS_TAB_SET_MESSAGE Message_Ptr;
2122         PI2O_SET_SYSTAB_HEADER        SystemTable;
2123         Asr_softc_t                 * ha;
2124         PI2O_SGE_SIMPLE_ELEMENT       sg;
2125         int                           retVal;
2126
2127         if ((SystemTable = (PI2O_SET_SYSTAB_HEADER)kmalloc (
2128           sizeof(I2O_SET_SYSTAB_HEADER), M_TEMP, M_WAITOK))
2129           == (PI2O_SET_SYSTAB_HEADER)NULL) {
2130                 return (ENOMEM);
2131         }
2132         bzero (SystemTable, sizeof(I2O_SET_SYSTAB_HEADER));
2133         for (ha = Asr_softc; ha; ha = ha->ha_next) {
2134                 ++SystemTable->NumberEntries;
2135         }
2136         if ((Message_Ptr = (PI2O_EXEC_SYS_TAB_SET_MESSAGE)kmalloc (
2137           sizeof(I2O_EXEC_SYS_TAB_SET_MESSAGE) - sizeof(I2O_SG_ELEMENT)
2138            + ((3+SystemTable->NumberEntries) * sizeof(I2O_SGE_SIMPLE_ELEMENT)),
2139           M_TEMP, M_WAITOK)) == (PI2O_EXEC_SYS_TAB_SET_MESSAGE)NULL) {
2140                 kfree (SystemTable, M_TEMP);
2141                 return (ENOMEM);
2142         }
2143         (void)ASR_fillMessage((char *)Message_Ptr,
2144           sizeof(I2O_EXEC_SYS_TAB_SET_MESSAGE) - sizeof(I2O_SG_ELEMENT)
2145            + ((3+SystemTable->NumberEntries) * sizeof(I2O_SGE_SIMPLE_ELEMENT)));
2146         I2O_MESSAGE_FRAME_setVersionOffset(&(Message_Ptr->StdMessageFrame),
2147           (I2O_VERSION_11 +
2148           (((sizeof(I2O_EXEC_SYS_TAB_SET_MESSAGE) - sizeof(I2O_SG_ELEMENT))
2149                         / sizeof(U32)) << 4)));
2150         I2O_MESSAGE_FRAME_setFunction(&(Message_Ptr->StdMessageFrame),
2151           I2O_EXEC_SYS_TAB_SET);
2152         /*
2153          *      Call the LCT table to determine the number of device entries
2154          * to reserve space for.
2155          *      since this code is reused in several systems, code efficiency
2156          * is greater by using a shift operation rather than a divide by
2157          * sizeof(u_int32_t).
2158          */
2159         sg = (PI2O_SGE_SIMPLE_ELEMENT)((char *)Message_Ptr
2160           + ((I2O_MESSAGE_FRAME_getVersionOffset(
2161               &(Message_Ptr->StdMessageFrame)) & 0xF0) >> 2));
2162         SG(sg, 0, I2O_SGL_FLAGS_DIR, SystemTable, sizeof(I2O_SET_SYSTAB_HEADER));
2163         ++sg;
2164         for (ha = Asr_softc; ha; ha = ha->ha_next) {
2165                 SG(sg, 0,
2166                   ((ha->ha_next)
2167                     ? (I2O_SGL_FLAGS_DIR)
2168                     : (I2O_SGL_FLAGS_DIR | I2O_SGL_FLAGS_END_OF_BUFFER)),
2169                   &(ha->ha_SystemTable), sizeof(ha->ha_SystemTable));
2170                 ++sg;
2171         }
2172         SG(sg, 0, I2O_SGL_FLAGS_DIR | I2O_SGL_FLAGS_END_OF_BUFFER, NULL, 0);
2173         SG(sg, 1, I2O_SGL_FLAGS_DIR | I2O_SGL_FLAGS_LAST_ELEMENT
2174             | I2O_SGL_FLAGS_END_OF_BUFFER, NULL, 0);
2175         retVal = ASR_queue_c(sc, (PI2O_MESSAGE_FRAME)Message_Ptr);
2176         kfree (Message_Ptr, M_TEMP);
2177         kfree (SystemTable, M_TEMP);
2178         return (retVal);
2179 } /* ASR_setSysTab */
2180
2181 STATIC INLINE int
2182 ASR_acquireHrt (
2183         INOUT Asr_softc_t                   * sc)
2184 {
2185         defAlignLong(I2O_EXEC_HRT_GET_MESSAGE,Message);
2186         I2O_EXEC_HRT_GET_MESSAGE *            Message_Ptr;
2187         struct {
2188                 I2O_HRT       Header;
2189                 I2O_HRT_ENTRY Entry[MAX_CHANNEL];
2190         }                                     Hrt;
2191         u_int8_t                              NumberOfEntries;
2192         PI2O_HRT_ENTRY                        Entry;
2193
2194         bzero ((void *)&Hrt, sizeof (Hrt));
2195         Message_Ptr = (I2O_EXEC_HRT_GET_MESSAGE *)ASR_fillMessage(Message,
2196           sizeof(I2O_EXEC_HRT_GET_MESSAGE) - sizeof(I2O_SG_ELEMENT)
2197           + sizeof(I2O_SGE_SIMPLE_ELEMENT));
2198         I2O_MESSAGE_FRAME_setVersionOffset(&(Message_Ptr->StdMessageFrame),
2199           (I2O_VERSION_11
2200           + (((sizeof(I2O_EXEC_HRT_GET_MESSAGE) - sizeof(I2O_SG_ELEMENT))
2201                    / sizeof(U32)) << 4)));
2202         I2O_MESSAGE_FRAME_setFunction (&(Message_Ptr->StdMessageFrame),
2203           I2O_EXEC_HRT_GET);
2204
2205         /*
2206          *  Set up the buffers as scatter gather elements.
2207          */
2208         SG(&(Message_Ptr->SGL), 0,
2209           I2O_SGL_FLAGS_LAST_ELEMENT | I2O_SGL_FLAGS_END_OF_BUFFER,
2210           &Hrt, sizeof(Hrt));
2211         if (ASR_queue_c(sc, (PI2O_MESSAGE_FRAME)Message_Ptr) != CAM_REQ_CMP) {
2212                 return (ENODEV);
2213         }
2214         if ((NumberOfEntries = I2O_HRT_getNumberEntries(&Hrt.Header))
2215           > (MAX_CHANNEL + 1)) {
2216                 NumberOfEntries = MAX_CHANNEL + 1;
2217         }
2218         for (Entry = Hrt.Header.HRTEntry;
2219           NumberOfEntries != 0;
2220           ++Entry, --NumberOfEntries) {
2221                 PI2O_LCT_ENTRY Device;
2222
2223                 for (Device = sc->ha_LCT->LCTEntry; Device < (PI2O_LCT_ENTRY)
2224                   (((U32 *)sc->ha_LCT)+I2O_LCT_getTableSize(sc->ha_LCT));
2225                   ++Device) {
2226                         if (I2O_LCT_ENTRY_getLocalTID(Device)
2227                           == (I2O_HRT_ENTRY_getAdapterID(Entry) & 0xFFF)) {
2228                                 Device->le_bus = I2O_HRT_ENTRY_getAdapterID(
2229                                   Entry) >> 16;
2230                                 if ((Device->le_bus > sc->ha_MaxBus)
2231                                  && (Device->le_bus <= MAX_CHANNEL)) {
2232                                         sc->ha_MaxBus = Device->le_bus;
2233                                 }
2234                         }
2235                 }
2236         }
2237         return (0);
2238 } /* ASR_acquireHrt */
2239
2240 /*
2241  *      Enable the adapter.
2242  */
2243 STATIC INLINE int
2244 ASR_enableSys (
2245         IN Asr_softc_t                         * sc)
2246 {
2247         defAlignLong(I2O_EXEC_SYS_ENABLE_MESSAGE,Message);
2248         PI2O_EXEC_SYS_ENABLE_MESSAGE             Message_Ptr;
2249
2250         Message_Ptr = (PI2O_EXEC_SYS_ENABLE_MESSAGE)ASR_fillMessage(Message,
2251           sizeof(I2O_EXEC_SYS_ENABLE_MESSAGE));
2252         I2O_MESSAGE_FRAME_setFunction(&(Message_Ptr->StdMessageFrame),
2253           I2O_EXEC_SYS_ENABLE);
2254         return (ASR_queue_c(sc, (PI2O_MESSAGE_FRAME)Message_Ptr) != 0);
2255 } /* ASR_enableSys */
2256
2257 /*
2258  *      Perform the stages necessary to initialize the adapter
2259  */
2260 STATIC int
2261 ASR_init(
2262         IN Asr_softc_t * sc)
2263 {
2264         return ((ASR_initOutBound(sc) == 0)
2265          || (ASR_setSysTab(sc) != CAM_REQ_CMP)
2266          || (ASR_enableSys(sc) != CAM_REQ_CMP));
2267 } /* ASR_init */
2268
2269 /*
2270  *      Send a Synchronize Cache command to the target device.
2271  */
2272 STATIC INLINE void
2273 ASR_sync (
2274         IN Asr_softc_t * sc,
2275         IN int           bus,
2276         IN int           target,
2277         IN int           lun)
2278 {
2279         tid_t            TID;
2280
2281         /*
2282          * We will not synchronize the device when there are outstanding
2283          * commands issued by the OS (this is due to a locked up device,
2284          * as the OS normally would flush all outstanding commands before
2285          * issuing a shutdown or an adapter reset).
2286          */
2287         if ((sc != (Asr_softc_t *)NULL)
2288          && (LIST_FIRST(&(sc->ha_ccb)) != (struct ccb_hdr *)NULL)
2289          && ((TID = ASR_getTid (sc, bus, target, lun)) != (tid_t)-1)
2290          && (TID != (tid_t)0)) {
2291                 defAlignLong(PRIVATE_SCSI_SCB_EXECUTE_MESSAGE,Message);
2292                 PPRIVATE_SCSI_SCB_EXECUTE_MESSAGE             Message_Ptr;
2293
2294                 bzero (Message_Ptr
2295                   = getAlignLong(PRIVATE_SCSI_SCB_EXECUTE_MESSAGE, Message),
2296                   sizeof(PRIVATE_SCSI_SCB_EXECUTE_MESSAGE)
2297                   - sizeof(I2O_SG_ELEMENT) + sizeof(I2O_SGE_SIMPLE_ELEMENT));
2298
2299                 I2O_MESSAGE_FRAME_setVersionOffset(
2300                   (PI2O_MESSAGE_FRAME)Message_Ptr,
2301                   I2O_VERSION_11
2302                     | (((sizeof(PRIVATE_SCSI_SCB_EXECUTE_MESSAGE)
2303                     - sizeof(I2O_SG_ELEMENT))
2304                         / sizeof(U32)) << 4));
2305                 I2O_MESSAGE_FRAME_setMessageSize(
2306                   (PI2O_MESSAGE_FRAME)Message_Ptr,
2307                   (sizeof(PRIVATE_SCSI_SCB_EXECUTE_MESSAGE)
2308                   - sizeof(I2O_SG_ELEMENT))
2309                         / sizeof(U32));
2310                 I2O_MESSAGE_FRAME_setInitiatorAddress (
2311                   (PI2O_MESSAGE_FRAME)Message_Ptr, 1);
2312                 I2O_MESSAGE_FRAME_setFunction(
2313                   (PI2O_MESSAGE_FRAME)Message_Ptr, I2O_PRIVATE_MESSAGE);
2314                 I2O_MESSAGE_FRAME_setTargetAddress(
2315                   (PI2O_MESSAGE_FRAME)Message_Ptr, TID);
2316                 I2O_PRIVATE_MESSAGE_FRAME_setXFunctionCode (
2317                   (PI2O_PRIVATE_MESSAGE_FRAME)Message_Ptr,
2318                   I2O_SCSI_SCB_EXEC);
2319                 PRIVATE_SCSI_SCB_EXECUTE_MESSAGE_setTID(Message_Ptr, TID);
2320                 PRIVATE_SCSI_SCB_EXECUTE_MESSAGE_setSCBFlags (Message_Ptr,
2321                     I2O_SCB_FLAG_ENABLE_DISCONNECT
2322                   | I2O_SCB_FLAG_SIMPLE_QUEUE_TAG
2323                   | I2O_SCB_FLAG_SENSE_DATA_IN_BUFFER);
2324                 I2O_PRIVATE_MESSAGE_FRAME_setOrganizationID(
2325                   (PI2O_PRIVATE_MESSAGE_FRAME)Message_Ptr,
2326                   DPT_ORGANIZATION_ID);
2327                 PRIVATE_SCSI_SCB_EXECUTE_MESSAGE_setCDBLength(Message_Ptr, 6);
2328                 Message_Ptr->CDB[0] = SYNCHRONIZE_CACHE;
2329                 Message_Ptr->CDB[1] = (lun << 5);
2330
2331                 PRIVATE_SCSI_SCB_EXECUTE_MESSAGE_setSCBFlags (Message_Ptr,
2332                   (I2O_SCB_FLAG_XFER_FROM_DEVICE
2333                     | I2O_SCB_FLAG_ENABLE_DISCONNECT
2334                     | I2O_SCB_FLAG_SIMPLE_QUEUE_TAG
2335                     | I2O_SCB_FLAG_SENSE_DATA_IN_BUFFER));
2336
2337                 (void)ASR_queue_c(sc, (PI2O_MESSAGE_FRAME)Message_Ptr);
2338
2339         }
2340 }
2341
2342 STATIC INLINE void
2343 ASR_synchronize (
2344         IN Asr_softc_t * sc)
2345 {
2346         int              bus, target, lun;
2347
2348         for (bus = 0; bus <= sc->ha_MaxBus; ++bus) {
2349                 for (target = 0; target <= sc->ha_MaxId; ++target) {
2350                         for (lun = 0; lun <= sc->ha_MaxLun; ++lun) {
2351                                 ASR_sync(sc,bus,target,lun);
2352                         }
2353                 }
2354         }
2355 }
2356
2357 /*
2358  *      Reset the HBA, targets and BUS.
2359  *              Currently this resets *all* the SCSI busses.
2360  */
2361 STATIC INLINE void
2362 asr_hbareset(
2363         IN Asr_softc_t * sc)
2364 {
2365         ASR_synchronize (sc);
2366         (void)ASR_reset (sc);
2367 } /* asr_hbareset */
2368
2369 /*
2370  *      A reduced copy of the real pci_map_mem, incorporating the MAX_MAP
2371  * limit and a reduction in error checking (in the pre 4.0 case).
2372  */
2373 STATIC int
2374 asr_pci_map_mem (
2375         IN device_t      tag,
2376         IN Asr_softc_t * sc)
2377 {
2378         int              rid;
2379         u_int32_t        p, l, s;
2380
2381         /*
2382          * I2O specification says we must find first *memory* mapped BAR
2383          */
2384         for (rid = PCIR_MAPS;
2385           rid < (PCIR_MAPS + 4 * sizeof(u_int32_t));
2386           rid += sizeof(u_int32_t)) {
2387                 p = pci_read_config(tag, rid, sizeof(p));
2388                 if ((p & 1) == 0) {
2389                         break;
2390                 }
2391         }
2392         /*
2393          *      Give up?
2394          */
2395         if (rid >= (PCIR_MAPS + 4 * sizeof(u_int32_t))) {
2396                 rid = PCIR_MAPS;
2397         }
2398         p = pci_read_config(tag, rid, sizeof(p));
2399         pci_write_config(tag, rid, -1, sizeof(p));
2400         l = 0 - (pci_read_config(tag, rid, sizeof(l)) & ~15);
2401         pci_write_config(tag, rid, p, sizeof(p));
2402         if (l > MAX_MAP) {
2403                 l = MAX_MAP;
2404         }
2405         /*
2406          * The 2005S Zero Channel RAID solution is not a perfect PCI
2407          * citizen. It asks for 4MB on BAR0, and 0MB on BAR1, once
2408          * enabled it rewrites the size of BAR0 to 2MB, sets BAR1 to
2409          * BAR0+2MB and sets it's size to 2MB. The IOP registers are
2410          * accessible via BAR0, the messaging registers are accessible
2411          * via BAR1. If the subdevice code is 50 to 59 decimal.
2412          */
2413         s = pci_read_config(tag, PCIR_DEVVENDOR, sizeof(s));
2414         if (s != 0xA5111044) {
2415                 s = pci_read_config(tag, PCIR_SUBVEND_0, sizeof(s));
2416                 if ((((ADPTDOMINATOR_SUB_ID_START ^ s) & 0xF000FFFF) == 0)
2417                  && (ADPTDOMINATOR_SUB_ID_START <= s)
2418                  && (s <= ADPTDOMINATOR_SUB_ID_END)) {
2419                         l = MAX_MAP; /* Conjoined BAR Raptor Daptor */
2420                 }
2421         }
2422         p &= ~15;
2423         sc->ha_mem_res = bus_alloc_resource(tag, SYS_RES_MEMORY, &rid,
2424           p, p + l, l, RF_ACTIVE);
2425         if (sc->ha_mem_res == (struct resource *)NULL) {
2426                 return (0);
2427         }
2428         sc->ha_Base = (void *)rman_get_start(sc->ha_mem_res);
2429         if (sc->ha_Base == (void *)NULL) {
2430                 return (0);
2431         }
2432         sc->ha_Virt = (i2oRegs_t *) rman_get_virtual(sc->ha_mem_res);
2433         if (s == 0xA5111044) { /* Split BAR Raptor Daptor */
2434                 if ((rid += sizeof(u_int32_t))
2435                   >= (PCIR_MAPS + 4 * sizeof(u_int32_t))) {
2436                         return (0);
2437                 }
2438                 p = pci_read_config(tag, rid, sizeof(p));
2439                 pci_write_config(tag, rid, -1, sizeof(p));
2440                 l = 0 - (pci_read_config(tag, rid, sizeof(l)) & ~15);
2441                 pci_write_config(tag, rid, p, sizeof(p));
2442                 if (l > MAX_MAP) {
2443                         l = MAX_MAP;
2444                 }
2445                 p &= ~15;
2446                 sc->ha_mes_res = bus_alloc_resource(tag, SYS_RES_MEMORY, &rid,
2447                   p, p + l, l, RF_ACTIVE);
2448                 if (sc->ha_mes_res == (struct resource *)NULL) {
2449                         return (0);
2450                 }
2451                 if ((void *)rman_get_start(sc->ha_mes_res) == (void *)NULL) {
2452                         return (0);
2453                 }
2454                 sc->ha_Fvirt = (U8 *) rman_get_virtual(sc->ha_mes_res);
2455         } else {
2456                 sc->ha_Fvirt = (U8 *)(sc->ha_Virt);
2457         }
2458         return (1);
2459 } /* asr_pci_map_mem */
2460
2461 /*
2462  *      A simplified copy of the real pci_map_int with additional
2463  * registration requirements.
2464  */
2465 STATIC int
2466 asr_pci_map_int (
2467         IN device_t      tag,
2468         IN Asr_softc_t * sc)
2469 {
2470         int rid = 0;
2471         int error;
2472
2473         sc->ha_irq_res = bus_alloc_resource(tag, SYS_RES_IRQ, &rid,
2474           0, ~0, 1, RF_ACTIVE | RF_SHAREABLE);
2475         if (sc->ha_irq_res == (struct resource *)NULL) {
2476                 return (0);
2477         }
2478         error = bus_setup_intr(tag, sc->ha_irq_res, 0,
2479                               (driver_intr_t *)asr_intr, (void *)sc, 
2480                               &(sc->ha_intr), NULL);
2481         if (error) {
2482                 return (0);
2483         }
2484         sc->ha_irq = pci_read_config(tag, PCIR_INTLINE, sizeof(char));
2485         return (1);
2486 } /* asr_pci_map_int */
2487
2488 /*
2489  *      Attach the devices, and virtual devices to the driver list.
2490  */
2491 STATIC ATTACH_RET
2492 asr_attach (ATTACH_ARGS)
2493 {
2494         Asr_softc_t              * sc;
2495         struct scsi_inquiry_data * iq;
2496         ATTACH_SET();
2497
2498         sc = kmalloc(sizeof(*sc), M_DEVBUF, M_INTWAIT);
2499         if (Asr_softc == (Asr_softc_t *)NULL) {
2500                 /*
2501                  *      Fixup the OS revision as saved in the dptsig for the
2502                  *      engine (dptioctl.h) to pick up.
2503                  */
2504                 bcopy (osrelease, &ASR_sig.dsDescription[16], 5);
2505                 kprintf ("asr%d: major=%d\n", unit, asr_ops.head.maj);
2506         }
2507         /*
2508          *      Initialize the software structure
2509          */
2510         bzero (sc, sizeof(*sc));
2511         LIST_INIT(&(sc->ha_ccb));
2512         /* Link us into the HA list */
2513         {
2514                 Asr_softc_t **ha;
2515
2516                 for (ha = &Asr_softc; *ha; ha = &((*ha)->ha_next));
2517                 *(ha) = sc;
2518         }
2519         {
2520                 PI2O_EXEC_STATUS_GET_REPLY status;
2521                 int size;
2522
2523                 /*
2524                  *      This is the real McCoy!
2525                  */
2526                 if (!asr_pci_map_mem(tag, sc)) {
2527                         kprintf ("asr%d: could not map memory\n", unit);
2528                         ATTACH_RETURN(ENXIO);
2529                 }
2530                 /* Enable if not formerly enabled */
2531                 pci_write_config (tag, PCIR_COMMAND,
2532                   pci_read_config (tag, PCIR_COMMAND, sizeof(char))
2533                   | PCIM_CMD_MEMEN | PCIM_CMD_BUSMASTEREN, sizeof(char));
2534                 /* Knowledge is power, responsibility is direct */
2535                 {
2536                         struct pci_devinfo {
2537                                 STAILQ_ENTRY(pci_devinfo) pci_links;
2538                                 struct resource_list      resources;
2539                                 pcicfgregs                cfg;
2540                         } * dinfo = device_get_ivars(tag);
2541                         sc->ha_pciBusNum = dinfo->cfg.bus;
2542                         sc->ha_pciDeviceNum = (dinfo->cfg.slot << 3)
2543                                             | dinfo->cfg.func;
2544                 }
2545                 /* Check if the device is there? */
2546                 if ((ASR_resetIOP(sc->ha_Virt, sc->ha_Fvirt) == 0)
2547                  || ((status = (PI2O_EXEC_STATUS_GET_REPLY)kmalloc (
2548                   sizeof(I2O_EXEC_STATUS_GET_REPLY), M_TEMP, M_WAITOK))
2549                   == (PI2O_EXEC_STATUS_GET_REPLY)NULL)
2550                  || (ASR_getStatus(sc->ha_Virt, sc->ha_Fvirt, status) == NULL)) {
2551                         kprintf ("asr%d: could not initialize hardware\n", unit);
2552                         ATTACH_RETURN(ENODEV);  /* Get next, maybe better luck */
2553                 }
2554                 sc->ha_SystemTable.OrganizationID = status->OrganizationID;
2555                 sc->ha_SystemTable.IOP_ID = status->IOP_ID;
2556                 sc->ha_SystemTable.I2oVersion = status->I2oVersion;
2557                 sc->ha_SystemTable.IopState = status->IopState;
2558                 sc->ha_SystemTable.MessengerType = status->MessengerType;
2559                 sc->ha_SystemTable.InboundMessageFrameSize
2560                   = status->InboundMFrameSize;
2561                 sc->ha_SystemTable.MessengerInfo.InboundMessagePortAddressLow
2562                   = (U32)(sc->ha_Base) + (U32)(&(((i2oRegs_t *)NULL)->ToFIFO));
2563
2564                 if (!asr_pci_map_int(tag, (void *)sc)) {
2565                         kprintf ("asr%d: could not map interrupt\n", unit);
2566                         ATTACH_RETURN(ENXIO);
2567                 }
2568
2569                 /* Adjust the maximim inbound count */
2570                 if (((sc->ha_QueueSize
2571                   = I2O_EXEC_STATUS_GET_REPLY_getMaxInboundMFrames(status))
2572                      > MAX_INBOUND)
2573                  || (sc->ha_QueueSize == 0)) {
2574                         sc->ha_QueueSize = MAX_INBOUND;
2575                 }
2576
2577                 /* Adjust the maximum outbound count */
2578                 if (((sc->ha_Msgs_Count
2579                   = I2O_EXEC_STATUS_GET_REPLY_getMaxOutboundMFrames(status))
2580                      > MAX_OUTBOUND)
2581                  || (sc->ha_Msgs_Count == 0)) {
2582                         sc->ha_Msgs_Count = MAX_OUTBOUND;
2583                 }
2584                 if (sc->ha_Msgs_Count > sc->ha_QueueSize) {
2585                         sc->ha_Msgs_Count = sc->ha_QueueSize;
2586                 }
2587
2588                 /* Adjust the maximum SG size to adapter */
2589                 if ((size = (I2O_EXEC_STATUS_GET_REPLY_getInboundMFrameSize(
2590                   status) << 2)) > MAX_INBOUND_SIZE) {
2591                         size = MAX_INBOUND_SIZE;
2592                 }
2593                 kfree (status, M_TEMP);
2594                 sc->ha_SgSize = (size - sizeof(PRIVATE_SCSI_SCB_EXECUTE_MESSAGE)
2595                   + sizeof(I2O_SG_ELEMENT)) / sizeof(I2O_SGE_SIMPLE_ELEMENT);
2596         }
2597
2598         /*
2599          *      Only do a bus/HBA reset on the first time through. On this
2600          * first time through, we do not send a flush to the devices.
2601          */
2602         if (ASR_init(sc) == 0) {
2603                 struct BufferInfo {
2604                         I2O_PARAM_RESULTS_LIST_HEADER       Header;
2605                         I2O_PARAM_READ_OPERATION_RESULT     Read;
2606                         I2O_DPT_EXEC_IOP_BUFFERS_SCALAR     Info;
2607                 };
2608                 defAlignLong (struct BufferInfo, Buffer);
2609                 PI2O_DPT_EXEC_IOP_BUFFERS_SCALAR Info;
2610 #                       define FW_DEBUG_BLED_OFFSET 8
2611
2612                 if ((Info = (PI2O_DPT_EXEC_IOP_BUFFERS_SCALAR)
2613                   ASR_getParams(sc, 0,
2614                     I2O_DPT_EXEC_IOP_BUFFERS_GROUP_NO,
2615                     Buffer, sizeof(struct BufferInfo)))
2616                 != (PI2O_DPT_EXEC_IOP_BUFFERS_SCALAR)NULL) {
2617                         sc->ha_blinkLED = sc->ha_Fvirt
2618                           + I2O_DPT_EXEC_IOP_BUFFERS_SCALAR_getSerialOutputOffset(Info)
2619                           + FW_DEBUG_BLED_OFFSET;
2620                 }
2621                 if (ASR_acquireLct(sc) == 0) {
2622                         (void)ASR_acquireHrt(sc);
2623                 }
2624         } else {
2625                 kprintf ("asr%d: failed to initialize\n", unit);
2626                 ATTACH_RETURN(ENXIO);
2627         }
2628         /*
2629          *      Add in additional probe responses for more channels. We
2630          * are reusing the variable `target' for a channel loop counter.
2631          * Done here because of we need both the acquireLct and
2632          * acquireHrt data.
2633          */
2634         {       PI2O_LCT_ENTRY Device;
2635
2636                 for (Device = sc->ha_LCT->LCTEntry; Device < (PI2O_LCT_ENTRY)
2637                   (((U32 *)sc->ha_LCT)+I2O_LCT_getTableSize(sc->ha_LCT));
2638                   ++Device) {
2639                         if (Device->le_type == I2O_UNKNOWN) {
2640                                 continue;
2641                         }
2642                         if (I2O_LCT_ENTRY_getUserTID(Device) == 0xFFF) {
2643                                 if (Device->le_target > sc->ha_MaxId) {
2644                                         sc->ha_MaxId = Device->le_target;
2645                                 }
2646                                 if (Device->le_lun > sc->ha_MaxLun) {
2647                                         sc->ha_MaxLun = Device->le_lun;
2648                                 }
2649                         }
2650                         if (((Device->le_type & I2O_PORT) != 0)
2651                          && (Device->le_bus <= MAX_CHANNEL)) {
2652                                 /* Do not increase MaxId for efficiency */
2653                                 sc->ha_adapter_target[Device->le_bus]
2654                                         = Device->le_target;
2655                         }
2656                 }
2657         }
2658
2659
2660         /*
2661          *      Print the HBA model number as inquired from the card.
2662          */
2663
2664         kprintf ("asr%d:", unit);
2665
2666         if ((iq = (struct scsi_inquiry_data *)kmalloc (
2667             sizeof(struct scsi_inquiry_data), M_TEMP, M_WAITOK))
2668           != (struct scsi_inquiry_data *)NULL) {
2669                 defAlignLong(PRIVATE_SCSI_SCB_EXECUTE_MESSAGE,Message);
2670                 PPRIVATE_SCSI_SCB_EXECUTE_MESSAGE             Message_Ptr;
2671                 int                                           posted = 0;
2672
2673                 bzero (iq, sizeof(struct scsi_inquiry_data));
2674                 bzero (Message_Ptr
2675                   = getAlignLong(PRIVATE_SCSI_SCB_EXECUTE_MESSAGE, Message),
2676                   sizeof(PRIVATE_SCSI_SCB_EXECUTE_MESSAGE)
2677                   - sizeof(I2O_SG_ELEMENT) + sizeof(I2O_SGE_SIMPLE_ELEMENT));
2678
2679                 I2O_MESSAGE_FRAME_setVersionOffset(
2680                   (PI2O_MESSAGE_FRAME)Message_Ptr,
2681                   I2O_VERSION_11
2682                     | (((sizeof(PRIVATE_SCSI_SCB_EXECUTE_MESSAGE)
2683                     - sizeof(I2O_SG_ELEMENT))
2684                         / sizeof(U32)) << 4));
2685                 I2O_MESSAGE_FRAME_setMessageSize(
2686                   (PI2O_MESSAGE_FRAME)Message_Ptr,
2687                   (sizeof(PRIVATE_SCSI_SCB_EXECUTE_MESSAGE)
2688                   - sizeof(I2O_SG_ELEMENT) + sizeof(I2O_SGE_SIMPLE_ELEMENT))
2689                         / sizeof(U32));
2690                 I2O_MESSAGE_FRAME_setInitiatorAddress (
2691                   (PI2O_MESSAGE_FRAME)Message_Ptr, 1);
2692                 I2O_MESSAGE_FRAME_setFunction(
2693                   (PI2O_MESSAGE_FRAME)Message_Ptr, I2O_PRIVATE_MESSAGE);
2694                 I2O_PRIVATE_MESSAGE_FRAME_setXFunctionCode (
2695                   (PI2O_PRIVATE_MESSAGE_FRAME)Message_Ptr,
2696                   I2O_SCSI_SCB_EXEC);
2697                 PRIVATE_SCSI_SCB_EXECUTE_MESSAGE_setSCBFlags (Message_Ptr,
2698                     I2O_SCB_FLAG_ENABLE_DISCONNECT
2699                   | I2O_SCB_FLAG_SIMPLE_QUEUE_TAG
2700                   | I2O_SCB_FLAG_SENSE_DATA_IN_BUFFER);
2701                 PRIVATE_SCSI_SCB_EXECUTE_MESSAGE_setInterpret(Message_Ptr, 1);
2702                 I2O_PRIVATE_MESSAGE_FRAME_setOrganizationID(
2703                   (PI2O_PRIVATE_MESSAGE_FRAME)Message_Ptr,
2704                   DPT_ORGANIZATION_ID);
2705                 PRIVATE_SCSI_SCB_EXECUTE_MESSAGE_setCDBLength(Message_Ptr, 6);
2706                 Message_Ptr->CDB[0] = INQUIRY;
2707                 Message_Ptr->CDB[4] = (unsigned char)sizeof(struct scsi_inquiry_data);
2708                 if (Message_Ptr->CDB[4] == 0) {
2709                         Message_Ptr->CDB[4] = 255;
2710                 }
2711
2712                 PRIVATE_SCSI_SCB_EXECUTE_MESSAGE_setSCBFlags (Message_Ptr,
2713                   (I2O_SCB_FLAG_XFER_FROM_DEVICE
2714                     | I2O_SCB_FLAG_ENABLE_DISCONNECT
2715                     | I2O_SCB_FLAG_SIMPLE_QUEUE_TAG
2716                     | I2O_SCB_FLAG_SENSE_DATA_IN_BUFFER));
2717
2718                 PRIVATE_SCSI_SCB_EXECUTE_MESSAGE_setByteCount(
2719                   (PPRIVATE_SCSI_SCB_EXECUTE_MESSAGE)Message_Ptr,
2720                   sizeof(struct scsi_inquiry_data));
2721                 SG(&(Message_Ptr->SGL), 0,
2722                   I2O_SGL_FLAGS_LAST_ELEMENT | I2O_SGL_FLAGS_END_OF_BUFFER,
2723                   iq, sizeof(struct scsi_inquiry_data));
2724                 (void)ASR_queue_c(sc, (PI2O_MESSAGE_FRAME)Message_Ptr);
2725
2726                 if (iq->vendor[0] && (iq->vendor[0] != ' ')) {
2727                         kprintf (" ");
2728                         ASR_prstring (iq->vendor, 8);
2729                         ++posted;
2730                 }
2731                 if (iq->product[0] && (iq->product[0] != ' ')) {
2732                         kprintf (" ");
2733                         ASR_prstring (iq->product, 16);
2734                         ++posted;
2735                 }
2736                 if (iq->revision[0] && (iq->revision[0] != ' ')) {
2737                         kprintf (" FW Rev. ");
2738                         ASR_prstring (iq->revision, 4);
2739                         ++posted;
2740                 }
2741                 kfree ((caddr_t)iq, M_TEMP);
2742                 if (posted) {
2743                         kprintf (",");
2744                 }
2745         }
2746         kprintf (" %d channel, %d CCBs, Protocol I2O\n", sc->ha_MaxBus + 1,
2747           (sc->ha_QueueSize > MAX_INBOUND) ? MAX_INBOUND : sc->ha_QueueSize);
2748
2749         /*
2750          * fill in the prototype cam_path.
2751          */
2752         {
2753                 int             bus;
2754                 union asr_ccb * ccb;
2755
2756                 if ((ccb = asr_alloc_ccb (sc)) == (union asr_ccb *)NULL) {
2757                         kprintf ("asr%d: CAM could not be notified of asynchronous callback parameters\n", unit);
2758                         ATTACH_RETURN(ENOMEM);
2759                 }
2760                 for (bus = 0; bus <= sc->ha_MaxBus; ++bus) {
2761                         int                 QueueSize = sc->ha_QueueSize;
2762
2763                         if (QueueSize > MAX_INBOUND) {
2764                                 QueueSize = MAX_INBOUND;
2765                         }
2766
2767                         /*
2768                          *      Construct our first channel SIM entry
2769                          */
2770                         sc->ha_sim[bus] = cam_sim_alloc(
2771                           asr_action, asr_poll, "asr", sc,
2772                           unit, 1, QueueSize, NULL);
2773                         if (sc->ha_sim[bus] == NULL)
2774                                 continue;
2775
2776                         if (xpt_bus_register(sc->ha_sim[bus], bus)
2777                           != CAM_SUCCESS) {
2778                                 cam_sim_free(sc->ha_sim[bus]);
2779                                 sc->ha_sim[bus] = NULL;
2780                                 continue;
2781                         }
2782
2783                         if (xpt_create_path(&(sc->ha_path[bus]), /*periph*/NULL,
2784                           cam_sim_path(sc->ha_sim[bus]), CAM_TARGET_WILDCARD,
2785                           CAM_LUN_WILDCARD) != CAM_REQ_CMP) {
2786                                 xpt_bus_deregister(
2787                                   cam_sim_path(sc->ha_sim[bus]));
2788                                 cam_sim_free(sc->ha_sim[bus]);
2789                                 sc->ha_sim[bus] = NULL;
2790                                 continue;
2791                         }
2792                 }
2793                 asr_free_ccb (ccb);
2794         }
2795         /*
2796          *      Generate the device node information
2797          */
2798         make_dev(&asr_ops, unit, 0, 0, S_IRWXU, "rasr%d", unit);
2799         ATTACH_RETURN(0);
2800 } /* asr_attach */
2801
2802 STATIC void
2803 asr_poll(
2804         IN struct cam_sim *sim)
2805 {
2806         asr_intr(cam_sim_softc(sim));
2807 } /* asr_poll */
2808
2809 STATIC void
2810 asr_action(
2811         IN struct cam_sim * sim,
2812         IN union ccb      * ccb)
2813 {
2814         struct Asr_softc  * sc;
2815
2816         debug_asr_printf ("asr_action(%lx,%lx{%x})\n",
2817           (u_long)sim, (u_long)ccb, ccb->ccb_h.func_code);
2818
2819         CAM_DEBUG(ccb->ccb_h.path, CAM_DEBUG_TRACE, ("asr_action\n"));
2820
2821         ccb->ccb_h.spriv_ptr0 = sc = (struct Asr_softc *)cam_sim_softc(sim);
2822
2823         switch (ccb->ccb_h.func_code) {
2824
2825         /* Common cases first */
2826         case XPT_SCSI_IO:       /* Execute the requested I/O operation */
2827         {
2828                 struct Message {
2829                         char M[MAX_INBOUND_SIZE];
2830                 };
2831                 defAlignLong(struct Message,Message);
2832                 PI2O_MESSAGE_FRAME   Message_Ptr;
2833
2834                 /* Reject incoming commands while we are resetting the card */
2835                 if (sc->ha_in_reset != HA_OPERATIONAL) {
2836                         ccb->ccb_h.status &= ~CAM_STATUS_MASK;
2837                         if (sc->ha_in_reset >= HA_OFF_LINE) {
2838                                 /* HBA is now off-line */
2839                                 ccb->ccb_h.status |= CAM_UNREC_HBA_ERROR;
2840                         } else {
2841                                 /* HBA currently resetting, try again later. */
2842                                 ccb->ccb_h.status |= CAM_REQUEUE_REQ;
2843                         }
2844                         debug_asr_cmd_printf (" e\n");
2845                         xpt_done(ccb);
2846                         debug_asr_cmd_printf (" q\n");
2847                         break;
2848                 }
2849                 if ((ccb->ccb_h.status & CAM_STATUS_MASK) != CAM_REQ_INPROG) {
2850                         kprintf(
2851                           "asr%d WARNING: scsi_cmd(%x) already done on b%dt%du%d\n",
2852                           cam_sim_unit(xpt_path_sim(ccb->ccb_h.path)),
2853                           ccb->csio.cdb_io.cdb_bytes[0],
2854                           cam_sim_bus(sim),
2855                           ccb->ccb_h.target_id,
2856                           ccb->ccb_h.target_lun);
2857                 }
2858                 debug_asr_cmd_printf ("(%d,%d,%d,%d)",
2859                   cam_sim_unit(sim),
2860                   cam_sim_bus(sim),
2861                   ccb->ccb_h.target_id,
2862                   ccb->ccb_h.target_lun);
2863                 debug_asr_cmd_dump_ccb(ccb);
2864
2865                 if ((Message_Ptr = ASR_init_message ((union asr_ccb *)ccb,
2866                   (PI2O_MESSAGE_FRAME)Message)) != (PI2O_MESSAGE_FRAME)NULL) {
2867                         debug_asr_cmd2_printf ("TID=%x:\n",
2868                           PRIVATE_SCSI_SCB_EXECUTE_MESSAGE_getTID(
2869                             (PPRIVATE_SCSI_SCB_EXECUTE_MESSAGE)Message_Ptr));
2870                         debug_asr_cmd2_dump_message(Message_Ptr);
2871                         debug_asr_cmd1_printf (" q");
2872
2873                         if (ASR_queue (sc, Message_Ptr) == EMPTY_QUEUE) {
2874                                 ccb->ccb_h.status &= ~CAM_STATUS_MASK;
2875                                 ccb->ccb_h.status |= CAM_REQUEUE_REQ;
2876                                 debug_asr_cmd_printf (" E\n");
2877                                 xpt_done(ccb);
2878                         }
2879                         debug_asr_cmd_printf (" Q\n");
2880                         break;
2881                 }
2882                 /*
2883                  *      We will get here if there is no valid TID for the device
2884                  * referenced in the scsi command packet.
2885                  */
2886                 ccb->ccb_h.status &= ~CAM_STATUS_MASK;
2887                 ccb->ccb_h.status |= CAM_SEL_TIMEOUT;
2888                 debug_asr_cmd_printf (" B\n");
2889                 xpt_done(ccb);
2890                 break;
2891         }
2892
2893         case XPT_RESET_DEV:     /* Bus Device Reset the specified SCSI device */
2894                 /* Rese HBA device ... */
2895                 asr_hbareset (sc);
2896                 ccb->ccb_h.status = CAM_REQ_CMP;
2897                 xpt_done(ccb);
2898                 break;
2899
2900 #       if (defined(REPORT_LUNS))
2901         case REPORT_LUNS:
2902 #       endif
2903         case XPT_ABORT:                 /* Abort the specified CCB */
2904                 /* XXX Implement */
2905                 ccb->ccb_h.status = CAM_REQ_INVALID;
2906                 xpt_done(ccb);
2907                 break;
2908
2909         case XPT_SET_TRAN_SETTINGS:
2910                 /* XXX Implement */
2911                 ccb->ccb_h.status = CAM_FUNC_NOTAVAIL;
2912                 xpt_done(ccb);
2913                 break;
2914
2915         case XPT_GET_TRAN_SETTINGS:
2916         /* Get default/user set transfer settings for the target */
2917         {
2918                 struct  ccb_trans_settings *cts = &(ccb->cts);
2919 #ifdef  CAM_NEW_TRAN_CODE
2920                 struct ccb_trans_settings_scsi *scsi =
2921                     &cts->proto_specific.scsi;
2922                 struct ccb_trans_settings_spi *spi =
2923                     &cts->xport_specific.spi;
2924
2925                 if (cts->type == CTS_TYPE_USER_SETTINGS) {
2926                         cts->protocol = PROTO_SCSI;
2927                         cts->protocol_version = SCSI_REV_2;
2928                         cts->transport = XPORT_SPI;
2929                         cts->transport_version = 2;
2930
2931                         scsi->flags = CTS_SCSI_FLAGS_TAG_ENB;
2932                         spi->flags = CTS_SPI_FLAGS_DISC_ENB;
2933                         spi->bus_width = MSG_EXT_WDTR_BUS_16_BIT;
2934                         spi->sync_period = 6; /* 40MHz */
2935                         spi->sync_offset = 15;
2936                         spi->valid = CTS_SPI_VALID_SYNC_RATE
2937                                    | CTS_SPI_VALID_SYNC_OFFSET
2938                                    | CTS_SPI_VALID_BUS_WIDTH
2939                                    | CTS_SPI_VALID_DISC;
2940                         scsi->valid = CTS_SCSI_VALID_TQ;
2941
2942                         ccb->ccb_h.status = CAM_REQ_CMP;
2943                 } else {
2944                         ccb->ccb_h.status = CAM_FUNC_NOTAVAIL;
2945                 }
2946 #else
2947                 if ((cts->flags & CCB_TRANS_USER_SETTINGS) != 0) {
2948                         cts->flags = CCB_TRANS_DISC_ENB|CCB_TRANS_TAG_ENB;
2949                         cts->bus_width = MSG_EXT_WDTR_BUS_16_BIT;
2950                         cts->sync_period = 6; /* 40MHz */
2951                         cts->sync_offset = 15;
2952
2953                         cts->valid = CCB_TRANS_SYNC_RATE_VALID
2954                                    | CCB_TRANS_SYNC_OFFSET_VALID
2955                                    | CCB_TRANS_BUS_WIDTH_VALID
2956                                    | CCB_TRANS_DISC_VALID
2957                                    | CCB_TRANS_TQ_VALID;
2958                         ccb->ccb_h.status = CAM_REQ_CMP;
2959                 } else {
2960                         ccb->ccb_h.status = CAM_FUNC_NOTAVAIL;
2961                 }
2962 #endif
2963                 xpt_done(ccb);
2964                 break;
2965         }
2966
2967         case XPT_CALC_GEOMETRY:
2968         {
2969                 struct    ccb_calc_geometry *ccg;
2970                 u_int32_t size_mb;
2971                 u_int32_t secs_per_cylinder;
2972
2973                 ccg = &(ccb->ccg);
2974                 size_mb = ccg->volume_size
2975                         / ((1024L * 1024L) / ccg->block_size);
2976
2977                 if (size_mb > 4096) {
2978                         ccg->heads = 255;
2979                         ccg->secs_per_track = 63;
2980                 } else if (size_mb > 2048) {
2981                         ccg->heads = 128;
2982                         ccg->secs_per_track = 63;
2983                 } else if (size_mb > 1024) {
2984                         ccg->heads = 65;
2985                         ccg->secs_per_track = 63;
2986                 } else {
2987                         ccg->heads = 64;
2988                         ccg->secs_per_track = 32;
2989                 }
2990                 secs_per_cylinder = ccg->heads * ccg->secs_per_track;
2991                 ccg->cylinders = ccg->volume_size / secs_per_cylinder;
2992                 ccb->ccb_h.status = CAM_REQ_CMP;
2993                 xpt_done(ccb);
2994                 break;
2995         }
2996
2997         case XPT_RESET_BUS:             /* Reset the specified SCSI bus */
2998                 ASR_resetBus (sc, cam_sim_bus(sim));
2999                 ccb->ccb_h.status = CAM_REQ_CMP;
3000                 xpt_done(ccb);
3001                 break;
3002
3003         case XPT_TERM_IO:               /* Terminate the I/O process */
3004                 /* XXX Implement */
3005                 ccb->ccb_h.status = CAM_REQ_INVALID;
3006                 xpt_done(ccb);
3007                 break;
3008
3009         case XPT_PATH_INQ:              /* Path routing inquiry */
3010         {
3011                 struct ccb_pathinq *cpi = &(ccb->cpi);
3012
3013                 cpi->version_num = 1; /* XXX??? */
3014                 cpi->hba_inquiry = PI_SDTR_ABLE|PI_TAG_ABLE|PI_WIDE_16;
3015                 cpi->target_sprt = 0;
3016                 /* Not necessary to reset bus, done by HDM initialization */
3017                 cpi->hba_misc = PIM_NOBUSRESET;
3018                 cpi->hba_eng_cnt = 0;
3019                 cpi->max_target = sc->ha_MaxId;
3020                 cpi->max_lun = sc->ha_MaxLun;
3021                 cpi->initiator_id = sc->ha_adapter_target[cam_sim_bus(sim)];
3022                 cpi->bus_id = cam_sim_bus(sim);
3023                 cpi->base_transfer_speed = 3300;
3024                 strncpy(cpi->sim_vid, "FreeBSD", SIM_IDLEN);
3025                 strncpy(cpi->hba_vid, "Adaptec", HBA_IDLEN);
3026                 strncpy(cpi->dev_name, cam_sim_name(sim), DEV_IDLEN);
3027                 cpi->unit_number = cam_sim_unit(sim);
3028                 cpi->ccb_h.status = CAM_REQ_CMP;
3029 #ifdef  CAM_NEW_TRAN_CODE
3030                 cpi->transport = XPORT_SPI;
3031                 cpi->transport_version = 2;
3032                 cpi->protocol = PROTO_SCSI;
3033                 cpi->protocol_version = SCSI_REV_2;
3034 #endif
3035                 xpt_done(ccb);
3036                 break;
3037         }
3038         default:
3039                 ccb->ccb_h.status = CAM_REQ_INVALID;
3040                 xpt_done(ccb);
3041                 break;
3042         }
3043 } /* asr_action */
3044
3045
3046 /*
3047  * Handle processing of current CCB as pointed to by the Status.
3048  */
3049 STATIC int
3050 asr_intr (
3051         IN Asr_softc_t * sc)
3052 {
3053         OUT int          processed;
3054
3055         for (processed = 0;
3056           sc->ha_Virt->Status & Mask_InterruptsDisabled;
3057           processed = 1) {
3058                 union asr_ccb                     * ccb;
3059                 U32                                 ReplyOffset;
3060                 PI2O_SCSI_ERROR_REPLY_MESSAGE_FRAME Reply;
3061
3062                 if (((ReplyOffset = sc->ha_Virt->FromFIFO) == EMPTY_QUEUE)
3063                  && ((ReplyOffset = sc->ha_Virt->FromFIFO) == EMPTY_QUEUE)) {
3064                         break;
3065                 }
3066                 Reply = (PI2O_SCSI_ERROR_REPLY_MESSAGE_FRAME)(ReplyOffset
3067                   - sc->ha_Msgs_Phys + (char *)(sc->ha_Msgs));
3068                 /*
3069                  * We do not need any (optional byteswapping) method access to
3070                  * the Initiator context field.
3071                  */
3072                 ccb = (union asr_ccb *)(long)
3073                   I2O_MESSAGE_FRAME_getInitiatorContext64(
3074                     &(Reply->StdReplyFrame.StdMessageFrame));
3075                 if (I2O_MESSAGE_FRAME_getMsgFlags(
3076                   &(Reply->StdReplyFrame.StdMessageFrame))
3077                   & I2O_MESSAGE_FLAGS_FAIL) {
3078                         defAlignLong(I2O_UTIL_NOP_MESSAGE,Message);
3079                         PI2O_UTIL_NOP_MESSAGE             Message_Ptr;
3080                         U32                               MessageOffset;
3081
3082                         MessageOffset = (u_long)
3083                           I2O_FAILURE_REPLY_MESSAGE_FRAME_getPreservedMFA(
3084                             (PI2O_FAILURE_REPLY_MESSAGE_FRAME)Reply);
3085                         /*
3086                          *  Get the Original Message Frame's address, and get
3087                          * it's Transaction Context into our space. (Currently
3088                          * unused at original authorship, but better to be
3089                          * safe than sorry). Straight copy means that we
3090                          * need not concern ourselves with the (optional
3091                          * byteswapping) method access.
3092                          */
3093                         Reply->StdReplyFrame.TransactionContext
3094                           = ((PI2O_SINGLE_REPLY_MESSAGE_FRAME)
3095                             (sc->ha_Fvirt + MessageOffset))->TransactionContext;
3096                         /*
3097                          *      For 64 bit machines, we need to reconstruct the
3098                          * 64 bit context.
3099                          */
3100                         ccb = (union asr_ccb *)(long)
3101                           I2O_MESSAGE_FRAME_getInitiatorContext64(
3102                             &(Reply->StdReplyFrame.StdMessageFrame));
3103                         /*
3104                          * Unique error code for command failure.
3105                          */
3106                         I2O_SINGLE_REPLY_MESSAGE_FRAME_setDetailedStatusCode(
3107                           &(Reply->StdReplyFrame), (u_int16_t)-2);
3108                         /*
3109                          *  Modify the message frame to contain a NOP and
3110                          * re-issue it to the controller.
3111                          */
3112                         Message_Ptr = (PI2O_UTIL_NOP_MESSAGE)ASR_fillMessage(
3113                           Message, sizeof(I2O_UTIL_NOP_MESSAGE));
3114 #                       if (I2O_UTIL_NOP != 0)
3115                                 I2O_MESSAGE_FRAME_setFunction (
3116                                   &(Message_Ptr->StdMessageFrame),
3117                                   I2O_UTIL_NOP);
3118 #                       endif
3119                         /*
3120                          *  Copy the packet out to the Original Message
3121                          */
3122                         bcopy ((caddr_t)Message_Ptr,
3123                           sc->ha_Fvirt + MessageOffset,
3124                           sizeof(I2O_UTIL_NOP_MESSAGE));
3125                         /*
3126                          *  Issue the NOP
3127                          */
3128                         sc->ha_Virt->ToFIFO = MessageOffset;
3129                 }
3130
3131                 /*
3132                  *      Asynchronous command with no return requirements,
3133                  * and a generic handler for immunity against odd error
3134                  * returns from the adapter.
3135                  */
3136                 if (ccb == (union asr_ccb *)NULL) {
3137                         /*
3138                          * Return Reply so that it can be used for the
3139                          * next command
3140                          */
3141                         sc->ha_Virt->FromFIFO = ReplyOffset;
3142                         continue;
3143                 }
3144
3145                 /* Welease Wadjah! (and stop timeouts) */
3146                 ASR_ccbRemove (sc, ccb);
3147
3148                 switch (
3149                   I2O_SINGLE_REPLY_MESSAGE_FRAME_getDetailedStatusCode(
3150                     &(Reply->StdReplyFrame))) {
3151
3152                 case I2O_SCSI_DSC_SUCCESS:
3153                         ccb->ccb_h.status &= ~CAM_STATUS_MASK;
3154                         ccb->ccb_h.status |= CAM_REQ_CMP;
3155                         break;
3156
3157                 case I2O_SCSI_DSC_CHECK_CONDITION:
3158                         ccb->ccb_h.status &= ~CAM_STATUS_MASK;
3159                         ccb->ccb_h.status |= CAM_REQ_CMP|CAM_AUTOSNS_VALID;
3160                         break;
3161
3162                 case I2O_SCSI_DSC_BUSY:
3163                         /* FALLTHRU */
3164                 case I2O_SCSI_HBA_DSC_ADAPTER_BUSY:
3165                         /* FALLTHRU */
3166                 case I2O_SCSI_HBA_DSC_SCSI_BUS_RESET:
3167                         /* FALLTHRU */
3168                 case I2O_SCSI_HBA_DSC_BUS_BUSY:
3169                         ccb->ccb_h.status &= ~CAM_STATUS_MASK;
3170                         ccb->ccb_h.status |= CAM_SCSI_BUSY;
3171                         break;
3172
3173                 case I2O_SCSI_HBA_DSC_SELECTION_TIMEOUT:
3174                         ccb->ccb_h.status &= ~CAM_STATUS_MASK;
3175                         ccb->ccb_h.status |= CAM_SEL_TIMEOUT;
3176                         break;
3177
3178                 case I2O_SCSI_HBA_DSC_COMMAND_TIMEOUT:
3179                         /* FALLTHRU */
3180                 case I2O_SCSI_HBA_DSC_DEVICE_NOT_PRESENT:
3181                         /* FALLTHRU */
3182                 case I2O_SCSI_HBA_DSC_LUN_INVALID:
3183                         /* FALLTHRU */
3184                 case I2O_SCSI_HBA_DSC_SCSI_TID_INVALID:
3185                         ccb->ccb_h.status &= ~CAM_STATUS_MASK;
3186                         ccb->ccb_h.status |= CAM_CMD_TIMEOUT;
3187                         break;
3188
3189                 case I2O_SCSI_HBA_DSC_DATA_OVERRUN:
3190                         /* FALLTHRU */
3191                 case I2O_SCSI_HBA_DSC_REQUEST_LENGTH_ERROR:
3192                         ccb->ccb_h.status &= ~CAM_STATUS_MASK;
3193                         ccb->ccb_h.status |= CAM_DATA_RUN_ERR;
3194                         break;
3195
3196                 default:
3197                         ccb->ccb_h.status &= ~CAM_STATUS_MASK;
3198                         ccb->ccb_h.status |= CAM_REQUEUE_REQ;
3199                         break;
3200                 }
3201                 if ((ccb->csio.resid = ccb->csio.dxfer_len) != 0) {
3202                         ccb->csio.resid -=
3203                           I2O_SCSI_ERROR_REPLY_MESSAGE_FRAME_getTransferCount(
3204                             Reply);
3205                 }
3206
3207                 /* Sense data in reply packet */
3208                 if (ccb->ccb_h.status & CAM_AUTOSNS_VALID) {
3209                         u_int16_t size = I2O_SCSI_ERROR_REPLY_MESSAGE_FRAME_getAutoSenseTransferCount(Reply);
3210
3211                         if (size) {
3212                                 if (size > sizeof(ccb->csio.sense_data)) {
3213                                         size = sizeof(ccb->csio.sense_data);
3214                                 }
3215                                 if (size > I2O_SCSI_SENSE_DATA_SZ) {
3216                                         size = I2O_SCSI_SENSE_DATA_SZ;
3217                                 }
3218                                 if ((ccb->csio.sense_len)
3219                                  && (size > ccb->csio.sense_len)) {
3220                                         size = ccb->csio.sense_len;
3221                                 }
3222                                 bcopy ((caddr_t)Reply->SenseData,
3223                                   (caddr_t)&(ccb->csio.sense_data), size);
3224                         }
3225                 }
3226
3227                 /*
3228                  * Return Reply so that it can be used for the next command
3229                  * since we have no more need for it now
3230                  */
3231                 sc->ha_Virt->FromFIFO = ReplyOffset;
3232
3233                 if (ccb->ccb_h.path) {
3234                         xpt_done ((union ccb *)ccb);
3235                 } else {
3236                         wakeup ((caddr_t)ccb);
3237                 }
3238         }
3239         return (processed);
3240 } /* asr_intr */
3241
3242 #undef QueueSize        /* Grrrr */
3243 #undef SG_Size          /* Grrrr */
3244
3245 /*
3246  *      Meant to be included at the bottom of asr.c !!!
3247  */
3248
3249 /*
3250  *      Included here as hard coded. Done because other necessary include
3251  *      files utilize C++ comment structures which make them a nuisance to
3252  *      included here just to pick up these three typedefs.
3253  */
3254 typedef U32   DPT_TAG_T;
3255 typedef U32   DPT_MSG_T;
3256 typedef U32   DPT_RTN_T;
3257
3258 #undef SCSI_RESET       /* Conflicts with "scsi/scsiconf.h" defintion */
3259 #include        "osd_unix.h"
3260
3261 #define asr_unit(dev)     minor(dev)
3262
3263 STATIC INLINE Asr_softc_t *
3264 ASR_get_sc (
3265         IN cdev_t          dev)
3266 {
3267         int               unit = asr_unit(dev);
3268         OUT Asr_softc_t * sc = Asr_softc;
3269
3270         while (sc && sc->ha_sim[0] && (cam_sim_unit(sc->ha_sim[0]) != unit)) {
3271                 sc = sc->ha_next;
3272         }
3273         return (sc);
3274 } /* ASR_get_sc */
3275
3276 STATIC u_int8_t ASR_ctlr_held;
3277 #if (!defined(UNREFERENCED_PARAMETER))
3278 # define UNREFERENCED_PARAMETER(x) (void)(x)
3279 #endif
3280
3281 STATIC int
3282 asr_open(struct dev_open_args *ap)
3283 {
3284         cdev_t dev = ap->a_head.a_dev;
3285         OUT int error;
3286
3287         if (ASR_get_sc (dev) == (Asr_softc_t *)NULL) {
3288                 return (ENODEV);
3289         }
3290         crit_enter();
3291         if (ASR_ctlr_held) {
3292                 error = EBUSY;
3293         } else if ((error = suser_cred(ap->a_cred, 0)) == 0) {
3294                 ++ASR_ctlr_held;
3295         }
3296         crit_exit();
3297         return (error);
3298 } /* asr_open */
3299
3300 STATIC int
3301 asr_close(struct dev_close_args *ap)
3302 {
3303         ASR_ctlr_held = 0;
3304         return (0);
3305 } /* asr_close */
3306
3307
3308 /*-------------------------------------------------------------------------*/
3309 /*                    Function ASR_queue_i                                 */
3310 /*-------------------------------------------------------------------------*/
3311 /* The Parameters Passed To This Function Are :                            */
3312 /*     Asr_softc_t *      : HBA miniport driver's adapter data storage.    */
3313 /*     PI2O_MESSAGE_FRAME : Msg Structure Pointer For This Command         */
3314 /*      I2O_SCSI_ERROR_REPLY_MESSAGE_FRAME following the Msg Structure     */
3315 /*                                                                         */
3316 /* This Function Will Take The User Request Packet And Convert It To An    */
3317 /* I2O MSG And Send It Off To The Adapter.                                 */
3318 /*                                                                         */
3319 /* Return : 0 For OK, Error Code Otherwise                                 */
3320 /*-------------------------------------------------------------------------*/
3321 STATIC INLINE int
3322 ASR_queue_i(
3323         IN Asr_softc_t                             * sc,
3324         INOUT PI2O_MESSAGE_FRAME                     Packet)
3325 {
3326         union asr_ccb                              * ccb;
3327         PI2O_SCSI_ERROR_REPLY_MESSAGE_FRAME          Reply;
3328         PI2O_MESSAGE_FRAME                           Message_Ptr;
3329         PI2O_SCSI_ERROR_REPLY_MESSAGE_FRAME          Reply_Ptr;
3330         int                                          MessageSizeInBytes;
3331         int                                          ReplySizeInBytes;
3332         int                                          error;
3333         int                                          s;
3334         /* Scatter Gather buffer list */
3335         struct ioctlSgList_S {
3336                 SLIST_ENTRY(ioctlSgList_S) link;
3337                 caddr_t                    UserSpace;
3338                 I2O_FLAGS_COUNT            FlagsCount;
3339                 char                       KernelSpace[sizeof(long)];
3340         }                                          * elm;
3341         /* Generates a `first' entry */
3342         SLIST_HEAD(ioctlSgListHead_S, ioctlSgList_S) sgList;
3343
3344         if (ASR_getBlinkLedCode(sc)) {
3345                 debug_usr_cmd_printf ("Adapter currently in BlinkLed %x\n",
3346                   ASR_getBlinkLedCode(sc));
3347                 return (EIO);
3348         }
3349         /* Copy in the message into a local allocation */
3350         if ((Message_Ptr = (PI2O_MESSAGE_FRAME)kmalloc (
3351           sizeof(I2O_MESSAGE_FRAME), M_TEMP, M_WAITOK))
3352          == (PI2O_MESSAGE_FRAME)NULL) {
3353                 debug_usr_cmd_printf (
3354                   "Failed to acquire I2O_MESSAGE_FRAME memory\n");
3355                 return (ENOMEM);
3356         }
3357         if ((error = copyin ((caddr_t)Packet, (caddr_t)Message_Ptr,
3358           sizeof(I2O_MESSAGE_FRAME))) != 0) {
3359                 kfree (Message_Ptr, M_TEMP);
3360                 debug_usr_cmd_printf ("Can't copy in packet errno=%d\n", error);
3361                 return (error);
3362         }
3363         /* Acquire information to determine type of packet */
3364         MessageSizeInBytes = (I2O_MESSAGE_FRAME_getMessageSize(Message_Ptr)<<2);
3365         /* The offset of the reply information within the user packet */
3366         Reply = (PI2O_SCSI_ERROR_REPLY_MESSAGE_FRAME)((char *)Packet
3367           + MessageSizeInBytes);
3368
3369         /* Check if the message is a synchronous initialization command */
3370         s = I2O_MESSAGE_FRAME_getFunction(Message_Ptr);
3371         kfree (Message_Ptr, M_TEMP);
3372         switch (s) {
3373
3374         case I2O_EXEC_IOP_RESET:
3375         {       U32 status;
3376
3377                 status = ASR_resetIOP(sc->ha_Virt, sc->ha_Fvirt);
3378                 ReplySizeInBytes = sizeof(status);
3379                 debug_usr_cmd_printf ("resetIOP done\n");
3380                 return (copyout ((caddr_t)&status, (caddr_t)Reply,
3381                   ReplySizeInBytes));
3382         }
3383
3384         case I2O_EXEC_STATUS_GET:
3385         {       I2O_EXEC_STATUS_GET_REPLY status;
3386
3387                 if (ASR_getStatus (sc->ha_Virt, sc->ha_Fvirt, &status)
3388                   == (PI2O_EXEC_STATUS_GET_REPLY)NULL) {
3389                         debug_usr_cmd_printf ("getStatus failed\n");
3390                         return (ENXIO);
3391                 }
3392                 ReplySizeInBytes = sizeof(status);
3393                 debug_usr_cmd_printf ("getStatus done\n");
3394                 return (copyout ((caddr_t)&status, (caddr_t)Reply,
3395                   ReplySizeInBytes));
3396         }
3397
3398         case I2O_EXEC_OUTBOUND_INIT:
3399         {       U32 status;
3400
3401                 status = ASR_initOutBound(sc);
3402                 ReplySizeInBytes = sizeof(status);
3403                 debug_usr_cmd_printf ("intOutBound done\n");
3404                 return (copyout ((caddr_t)&status, (caddr_t)Reply,
3405                   ReplySizeInBytes));
3406         }
3407         }
3408
3409         /* Determine if the message size is valid */
3410         if ((MessageSizeInBytes < sizeof(I2O_MESSAGE_FRAME))
3411          || (MAX_INBOUND_SIZE < MessageSizeInBytes)) {
3412                 debug_usr_cmd_printf ("Packet size %d incorrect\n",
3413                   MessageSizeInBytes);
3414                 return (EINVAL);
3415         }
3416
3417         if ((Message_Ptr = (PI2O_MESSAGE_FRAME)kmalloc (MessageSizeInBytes,
3418           M_TEMP, M_WAITOK)) == (PI2O_MESSAGE_FRAME)NULL) {
3419                 debug_usr_cmd_printf ("Failed to acquire frame[%d] memory\n",
3420                   MessageSizeInBytes);
3421                 return (ENOMEM);
3422         }
3423         if ((error = copyin ((caddr_t)Packet, (caddr_t)Message_Ptr,
3424           MessageSizeInBytes)) != 0) {
3425                 kfree (Message_Ptr, M_TEMP);
3426                 debug_usr_cmd_printf ("Can't copy in packet[%d] errno=%d\n",
3427                   MessageSizeInBytes, error);
3428                 return (error);
3429         }
3430
3431         /* Check the size of the reply frame, and start constructing */
3432
3433         if ((Reply_Ptr = (PI2O_SCSI_ERROR_REPLY_MESSAGE_FRAME)kmalloc (
3434           sizeof(I2O_MESSAGE_FRAME), M_TEMP, M_WAITOK))
3435           == (PI2O_SCSI_ERROR_REPLY_MESSAGE_FRAME)NULL) {
3436                 kfree (Message_Ptr, M_TEMP);
3437                 debug_usr_cmd_printf (
3438                   "Failed to acquire I2O_MESSAGE_FRAME memory\n");
3439                 return (ENOMEM);
3440         }
3441         if ((error = copyin ((caddr_t)Reply, (caddr_t)Reply_Ptr,
3442           sizeof(I2O_MESSAGE_FRAME))) != 0) {
3443                 kfree (Reply_Ptr, M_TEMP);
3444                 kfree (Message_Ptr, M_TEMP);
3445                 debug_usr_cmd_printf (
3446                   "Failed to copy in reply frame, errno=%d\n",
3447                   error);
3448                 return (error);
3449         }
3450         ReplySizeInBytes = (I2O_MESSAGE_FRAME_getMessageSize(
3451           &(Reply_Ptr->StdReplyFrame.StdMessageFrame)) << 2);
3452         kfree (Reply_Ptr, M_TEMP);
3453         if (ReplySizeInBytes < sizeof(I2O_SINGLE_REPLY_MESSAGE_FRAME)) {
3454                 kfree (Message_Ptr, M_TEMP);
3455                 debug_usr_cmd_printf (
3456                   "Failed to copy in reply frame[%d], errno=%d\n",
3457                   ReplySizeInBytes, error);
3458                 return (EINVAL);
3459         }
3460
3461         if ((Reply_Ptr = (PI2O_SCSI_ERROR_REPLY_MESSAGE_FRAME)kmalloc (
3462           ((ReplySizeInBytes > sizeof(I2O_SCSI_ERROR_REPLY_MESSAGE_FRAME))
3463             ? ReplySizeInBytes
3464             : sizeof(I2O_SCSI_ERROR_REPLY_MESSAGE_FRAME)),
3465           M_TEMP, M_WAITOK)) == (PI2O_SCSI_ERROR_REPLY_MESSAGE_FRAME)NULL) {
3466                 kfree (Message_Ptr, M_TEMP);
3467                 debug_usr_cmd_printf ("Failed to acquire frame[%d] memory\n",
3468                   ReplySizeInBytes);
3469                 return (ENOMEM);
3470         }
3471         (void)ASR_fillMessage ((char *)Reply_Ptr, ReplySizeInBytes);
3472         Reply_Ptr->StdReplyFrame.StdMessageFrame.InitiatorContext
3473           = Message_Ptr->InitiatorContext;
3474         Reply_Ptr->StdReplyFrame.TransactionContext
3475           = ((PI2O_PRIVATE_MESSAGE_FRAME)Message_Ptr)->TransactionContext;
3476         I2O_MESSAGE_FRAME_setMsgFlags(
3477           &(Reply_Ptr->StdReplyFrame.StdMessageFrame),
3478           I2O_MESSAGE_FRAME_getMsgFlags(
3479             &(Reply_Ptr->StdReplyFrame.StdMessageFrame))
3480               | I2O_MESSAGE_FLAGS_REPLY);
3481
3482         /* Check if the message is a special case command */
3483         switch (I2O_MESSAGE_FRAME_getFunction(Message_Ptr)) {
3484         case I2O_EXEC_SYS_TAB_SET: /* Special Case of empty Scatter Gather */
3485                 if (MessageSizeInBytes == ((I2O_MESSAGE_FRAME_getVersionOffset(
3486                   Message_Ptr) & 0xF0) >> 2)) {
3487                         kfree (Message_Ptr, M_TEMP);
3488                         I2O_SINGLE_REPLY_MESSAGE_FRAME_setDetailedStatusCode(
3489                           &(Reply_Ptr->StdReplyFrame),
3490                           (ASR_setSysTab(sc) != CAM_REQ_CMP));
3491                         I2O_MESSAGE_FRAME_setMessageSize(
3492                           &(Reply_Ptr->StdReplyFrame.StdMessageFrame),
3493                           sizeof(I2O_SINGLE_REPLY_MESSAGE_FRAME));
3494                         error = copyout ((caddr_t)Reply_Ptr, (caddr_t)Reply,
3495                           ReplySizeInBytes);
3496                         kfree (Reply_Ptr, M_TEMP);
3497                         return (error);
3498                 }
3499         }
3500
3501         /* Deal in the general case */
3502         /* First allocate and optionally copy in each scatter gather element */
3503         SLIST_INIT(&sgList);
3504         if ((I2O_MESSAGE_FRAME_getVersionOffset(Message_Ptr) & 0xF0) != 0) {
3505                 PI2O_SGE_SIMPLE_ELEMENT sg;
3506
3507                 /*
3508                  *      since this code is reused in several systems, code
3509                  * efficiency is greater by using a shift operation rather
3510                  * than a divide by sizeof(u_int32_t).
3511                  */
3512                 sg = (PI2O_SGE_SIMPLE_ELEMENT)((char *)Message_Ptr
3513                   + ((I2O_MESSAGE_FRAME_getVersionOffset(Message_Ptr) & 0xF0)
3514                     >> 2));
3515                 while (sg < (PI2O_SGE_SIMPLE_ELEMENT)(((caddr_t)Message_Ptr)
3516                   + MessageSizeInBytes)) {
3517                         caddr_t v;
3518                         int     len;
3519
3520                         if ((I2O_FLAGS_COUNT_getFlags(&(sg->FlagsCount))
3521                          & I2O_SGL_FLAGS_SIMPLE_ADDRESS_ELEMENT) == 0) {
3522                                 error = EINVAL;
3523                                 break;
3524                         }
3525                         len = I2O_FLAGS_COUNT_getCount(&(sg->FlagsCount));
3526                         debug_usr_cmd_printf ("SG[%d] = %x[%d]\n",
3527                           sg - (PI2O_SGE_SIMPLE_ELEMENT)((char *)Message_Ptr
3528                           + ((I2O_MESSAGE_FRAME_getVersionOffset(
3529                                 Message_Ptr) & 0xF0) >> 2)),
3530                           I2O_SGE_SIMPLE_ELEMENT_getPhysicalAddress(sg), len);
3531
3532                         if ((elm = (struct ioctlSgList_S *)kmalloc (
3533                           sizeof(*elm) - sizeof(elm->KernelSpace) + len,
3534                           M_TEMP, M_WAITOK))
3535                           == (struct ioctlSgList_S *)NULL) {
3536                                 debug_usr_cmd_printf (
3537                                   "Failed to allocate SG[%d]\n", len);
3538                                 error = ENOMEM;
3539                                 break;
3540                         }
3541                         SLIST_INSERT_HEAD(&sgList, elm, link);
3542                         elm->FlagsCount = sg->FlagsCount;
3543                         elm->UserSpace = (caddr_t)
3544                           (I2O_SGE_SIMPLE_ELEMENT_getPhysicalAddress(sg));
3545                         v = elm->KernelSpace;
3546                         /* Copy in outgoing data (DIR bit could be invalid) */
3547                         if ((error = copyin (elm->UserSpace, (caddr_t)v, len))
3548                           != 0) {
3549                                 break;
3550                         }
3551                         /*
3552                          *      If the buffer is not contiguous, lets
3553                          * break up the scatter/gather entries.
3554                          */
3555                         while ((len > 0)
3556                          && (sg < (PI2O_SGE_SIMPLE_ELEMENT)
3557                           (((caddr_t)Message_Ptr) + MAX_INBOUND_SIZE))) {
3558                                 int next, base, span;
3559
3560                                 span = 0;
3561                                 next = base = KVTOPHYS(v);
3562                                 I2O_SGE_SIMPLE_ELEMENT_setPhysicalAddress(sg,
3563                                   base);
3564
3565                                 /* How far can we go physically contiguously */
3566                                 while ((len > 0) && (base == next)) {
3567                                         int size;
3568
3569                                         next = trunc_page(base) + PAGE_SIZE;
3570                                         size = next - base;
3571                                         if (size > len) {
3572                                                 size = len;
3573                                         }
3574                                         span += size;
3575                                         v += size;
3576                                         len -= size;
3577                                         base = KVTOPHYS(v);
3578                                 }
3579
3580                                 /* Construct the Flags */
3581                                 I2O_FLAGS_COUNT_setCount(&(sg->FlagsCount),
3582                                   span);
3583                                 {
3584                                         int flags = I2O_FLAGS_COUNT_getFlags(
3585                                           &(elm->FlagsCount));
3586                                         /* Any remaining length? */
3587                                         if (len > 0) {
3588                                             flags &=
3589                                                 ~(I2O_SGL_FLAGS_END_OF_BUFFER
3590                                                  | I2O_SGL_FLAGS_LAST_ELEMENT);
3591                                         }
3592                                         I2O_FLAGS_COUNT_setFlags(
3593                                           &(sg->FlagsCount), flags);
3594                                 }
3595
3596                                 debug_usr_cmd_printf ("sg[%d] = %x[%d]\n",
3597                                   sg - (PI2O_SGE_SIMPLE_ELEMENT)
3598                                     ((char *)Message_Ptr
3599                                   + ((I2O_MESSAGE_FRAME_getVersionOffset(
3600                                         Message_Ptr) & 0xF0) >> 2)),
3601                                   I2O_SGE_SIMPLE_ELEMENT_getPhysicalAddress(sg),
3602                                   span);
3603                                 if (len <= 0) {
3604                                         break;
3605                                 }
3606
3607                                 /*
3608                                  * Incrementing requires resizing of the
3609                                  * packet, and moving up the existing SG
3610                                  * elements.
3611                                  */
3612                                 ++sg;
3613                                 MessageSizeInBytes += sizeof(*sg);
3614                                 I2O_MESSAGE_FRAME_setMessageSize(Message_Ptr,
3615                                   I2O_MESSAGE_FRAME_getMessageSize(Message_Ptr)
3616                                   + (sizeof(*sg) / sizeof(U32)));
3617                                 {
3618                                         PI2O_MESSAGE_FRAME NewMessage_Ptr;
3619
3620                                         if ((NewMessage_Ptr
3621                                           = (PI2O_MESSAGE_FRAME)
3622                                             kmalloc (MessageSizeInBytes,
3623                                              M_TEMP, M_WAITOK))
3624                                             == (PI2O_MESSAGE_FRAME)NULL) {
3625                                                 debug_usr_cmd_printf (
3626                                                   "Failed to acquire frame[%d] memory\n",
3627                                                   MessageSizeInBytes);
3628                                                 error = ENOMEM;
3629                                                 break;
3630                                         }
3631                                         span = ((caddr_t)sg)
3632                                              - (caddr_t)Message_Ptr;
3633                                         bcopy ((caddr_t)Message_Ptr,
3634                                           (caddr_t)NewMessage_Ptr, span);
3635                                         bcopy ((caddr_t)(sg-1),
3636                                           ((caddr_t)NewMessage_Ptr) + span,
3637                                           MessageSizeInBytes - span);
3638                                         kfree (Message_Ptr, M_TEMP);
3639                                         sg = (PI2O_SGE_SIMPLE_ELEMENT)
3640                                           (((caddr_t)NewMessage_Ptr) + span);
3641                                         Message_Ptr = NewMessage_Ptr;
3642                                 }
3643                         }
3644                         if ((error)
3645                          || ((I2O_FLAGS_COUNT_getFlags(&(sg->FlagsCount))
3646                           & I2O_SGL_FLAGS_LAST_ELEMENT) != 0)) {
3647                                 break;
3648                         }
3649                         ++sg;
3650                 }
3651                 if (error) {
3652                         while ((elm = SLIST_FIRST(&sgList))
3653                           != (struct ioctlSgList_S *)NULL) {
3654                                 SLIST_REMOVE_HEAD(&sgList, link);
3655                                 kfree (elm, M_TEMP);
3656                         }
3657                         kfree (Reply_Ptr, M_TEMP);
3658                         kfree (Message_Ptr, M_TEMP);
3659                         return (error);
3660                 }
3661         }
3662
3663         debug_usr_cmd_printf ("Inbound: ");
3664         debug_usr_cmd_dump_message(Message_Ptr);
3665
3666         /* Send the command */
3667         if ((ccb = asr_alloc_ccb (sc)) == (union asr_ccb *)NULL) {
3668                 /* Free up in-kernel buffers */
3669                 while ((elm = SLIST_FIRST(&sgList))
3670                   != (struct ioctlSgList_S *)NULL) {
3671                         SLIST_REMOVE_HEAD(&sgList, link);
3672                         kfree (elm, M_TEMP);
3673                 }
3674                 kfree (Reply_Ptr, M_TEMP);
3675                 kfree (Message_Ptr, M_TEMP);
3676                 return (ENOMEM);
3677         }
3678
3679         /*
3680          * We do not need any (optional byteswapping) method access to
3681          * the&nb