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1
2/*
3
4 Linux Driver for BusLogic MultiMaster and FlashPoint SCSI Host Adapters
5
6 Copyright 1995-1998 by Leonard N. Zubkoff <lnz@dandelion.com>
7
8 This program is free software; you may redistribute and/or modify it under
9 the terms of the GNU General Public License Version 2 as published by the
10 Free Software Foundation.
11
12 This program is distributed in the hope that it will be useful, but
13 WITHOUT ANY WARRANTY, without even the implied warranty of MERCHANTABILITY
14 or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
15 for complete details.
16
17 The author respectfully requests that any modifications to this software be
18 sent directly to him for evaluation and testing.
19
20 Special thanks to Wayne Yen, Jin-Lon Hon, and Alex Win of BusLogic, whose
21 advice has been invaluable, to David Gentzel, for writing the original Linux
22 BusLogic driver, and to Paul Gortmaker, for being such a dedicated test site.
23
24 Finally, special thanks to Mylex/BusLogic for making the FlashPoint SCCB
25 Manager available as freely redistributable source code.
26
27*/
28
29#define BusLogic_DriverVersion "2.1.16"
30#define BusLogic_DriverDate "18 July 2002"
31
32#include <linux/module.h>
33#include <linux/init.h>
34#include <linux/interrupt.h>
35#include <linux/types.h>
36#include <linux/blkdev.h>
37#include <linux/delay.h>
38#include <linux/ioport.h>
39#include <linux/mm.h>
40#include <linux/stat.h>
41#include <linux/pci.h>
42#include <linux/spinlock.h>
43#include <linux/jiffies.h>
44#include <linux/dma-mapping.h>
45#include <linux/slab.h>
46#include <scsi/scsicam.h>
47
48#include <asm/dma.h>
49#include <asm/io.h>
50#include <asm/system.h>
51
52#include <scsi/scsi.h>
53#include <scsi/scsi_cmnd.h>
54#include <scsi/scsi_device.h>
55#include <scsi/scsi_host.h>
56#include <scsi/scsi_tcq.h>
57#include "BusLogic.h"
58#include "FlashPoint.c"
59
60#ifndef FAILURE
61#define FAILURE (-1)
62#endif
63
64static struct scsi_host_template Bus_Logic_template;
65
66/*
67 BusLogic_DriverOptionsCount is a count of the number of BusLogic Driver
68 Options specifications provided via the Linux Kernel Command Line or via
69 the Loadable Kernel Module Installation Facility.
70*/
71
72static int BusLogic_DriverOptionsCount;
73
74
75/*
76 BusLogic_DriverOptions is an array of Driver Options structures representing
77 BusLogic Driver Options specifications provided via the Linux Kernel Command
78 Line or via the Loadable Kernel Module Installation Facility.
79*/
80
81static struct BusLogic_DriverOptions BusLogic_DriverOptions[BusLogic_MaxHostAdapters];
82
83
84/*
85 BusLogic can be assigned a string by insmod.
86*/
87
88MODULE_LICENSE("GPL");
89#ifdef MODULE
90static char *BusLogic;
91module_param(BusLogic, charp, 0);
92#endif
93
94
95/*
96 BusLogic_ProbeOptions is a set of Probe Options to be applied across
97 all BusLogic Host Adapters.
98*/
99
100static struct BusLogic_ProbeOptions BusLogic_ProbeOptions;
101
102
103/*
104 BusLogic_GlobalOptions is a set of Global Options to be applied across
105 all BusLogic Host Adapters.
106*/
107
108static struct BusLogic_GlobalOptions BusLogic_GlobalOptions;
109
110static LIST_HEAD(BusLogic_host_list);
111
112/*
113 BusLogic_ProbeInfoCount is the number of entries in BusLogic_ProbeInfoList.
114*/
115
116static int BusLogic_ProbeInfoCount;
117
118
119/*
120 BusLogic_ProbeInfoList is the list of I/O Addresses and Bus Probe Information
121 to be checked for potential BusLogic Host Adapters. It is initialized by
122 interrogating the PCI Configuration Space on PCI machines as well as from the
123 list of standard BusLogic I/O Addresses.
124*/
125
126static struct BusLogic_ProbeInfo *BusLogic_ProbeInfoList;
127
128
129/*
130 BusLogic_CommandFailureReason holds a string identifying the reason why a
131 call to BusLogic_Command failed. It is only non-NULL when BusLogic_Command
132 returns a failure code.
133*/
134
135static char *BusLogic_CommandFailureReason;
136
137/*
138 BusLogic_AnnounceDriver announces the Driver Version and Date, Author's
139 Name, Copyright Notice, and Electronic Mail Address.
140*/
141
142static void BusLogic_AnnounceDriver(struct BusLogic_HostAdapter *HostAdapter)
143{
144 BusLogic_Announce("***** BusLogic SCSI Driver Version " BusLogic_DriverVersion " of " BusLogic_DriverDate " *****\n", HostAdapter);
145 BusLogic_Announce("Copyright 1995-1998 by Leonard N. Zubkoff " "<lnz@dandelion.com>\n", HostAdapter);
146}
147
148
149/*
150 BusLogic_DriverInfo returns the Host Adapter Name to identify this SCSI
151 Driver and Host Adapter.
152*/
153
154static const char *BusLogic_DriverInfo(struct Scsi_Host *Host)
155{
156 struct BusLogic_HostAdapter *HostAdapter = (struct BusLogic_HostAdapter *) Host->hostdata;
157 return HostAdapter->FullModelName;
158}
159
160/*
161 BusLogic_InitializeCCBs initializes a group of Command Control Blocks (CCBs)
162 for Host Adapter from the BlockSize bytes located at BlockPointer. The newly
163 created CCBs are added to Host Adapter's free list.
164*/
165
166static void BusLogic_InitializeCCBs(struct BusLogic_HostAdapter *HostAdapter, void *BlockPointer, int BlockSize, dma_addr_t BlockPointerHandle)
167{
168 struct BusLogic_CCB *CCB = (struct BusLogic_CCB *) BlockPointer;
169 unsigned int offset = 0;
170 memset(BlockPointer, 0, BlockSize);
171 CCB->AllocationGroupHead = BlockPointerHandle;
172 CCB->AllocationGroupSize = BlockSize;
173 while ((BlockSize -= sizeof(struct BusLogic_CCB)) >= 0) {
174 CCB->Status = BusLogic_CCB_Free;
175 CCB->HostAdapter = HostAdapter;
176 CCB->DMA_Handle = (u32) BlockPointerHandle + offset;
177 if (BusLogic_FlashPointHostAdapterP(HostAdapter)) {
178 CCB->CallbackFunction = BusLogic_QueueCompletedCCB;
179 CCB->BaseAddress = HostAdapter->FlashPointInfo.BaseAddress;
180 }
181 CCB->Next = HostAdapter->Free_CCBs;
182 CCB->NextAll = HostAdapter->All_CCBs;
183 HostAdapter->Free_CCBs = CCB;
184 HostAdapter->All_CCBs = CCB;
185 HostAdapter->AllocatedCCBs++;
186 CCB++;
187 offset += sizeof(struct BusLogic_CCB);
188 }
189}
190
191
192/*
193 BusLogic_CreateInitialCCBs allocates the initial CCBs for Host Adapter.
194*/
195
196static bool __init BusLogic_CreateInitialCCBs(struct BusLogic_HostAdapter *HostAdapter)
197{
198 int BlockSize = BusLogic_CCB_AllocationGroupSize * sizeof(struct BusLogic_CCB);
199 void *BlockPointer;
200 dma_addr_t BlockPointerHandle;
201 while (HostAdapter->AllocatedCCBs < HostAdapter->InitialCCBs) {
202 BlockPointer = pci_alloc_consistent(HostAdapter->PCI_Device, BlockSize, &BlockPointerHandle);
203 if (BlockPointer == NULL) {
204 BusLogic_Error("UNABLE TO ALLOCATE CCB GROUP - DETACHING\n", HostAdapter);
205 return false;
206 }
207 BusLogic_InitializeCCBs(HostAdapter, BlockPointer, BlockSize, BlockPointerHandle);
208 }
209 return true;
210}
211
212
213/*
214 BusLogic_DestroyCCBs deallocates the CCBs for Host Adapter.
215*/
216
217static void BusLogic_DestroyCCBs(struct BusLogic_HostAdapter *HostAdapter)
218{
219 struct BusLogic_CCB *NextCCB = HostAdapter->All_CCBs, *CCB, *Last_CCB = NULL;
220 HostAdapter->All_CCBs = NULL;
221 HostAdapter->Free_CCBs = NULL;
222 while ((CCB = NextCCB) != NULL) {
223 NextCCB = CCB->NextAll;
224 if (CCB->AllocationGroupHead) {
225 if (Last_CCB)
226 pci_free_consistent(HostAdapter->PCI_Device, Last_CCB->AllocationGroupSize, Last_CCB, Last_CCB->AllocationGroupHead);
227 Last_CCB = CCB;
228 }
229 }
230 if (Last_CCB)
231 pci_free_consistent(HostAdapter->PCI_Device, Last_CCB->AllocationGroupSize, Last_CCB, Last_CCB->AllocationGroupHead);
232}
233
234
235/*
236 BusLogic_CreateAdditionalCCBs allocates Additional CCBs for Host Adapter. If
237 allocation fails and there are no remaining CCBs available, the Driver Queue
238 Depth is decreased to a known safe value to avoid potential deadlocks when
239 multiple host adapters share the same IRQ Channel.
240*/
241
242static void BusLogic_CreateAdditionalCCBs(struct BusLogic_HostAdapter *HostAdapter, int AdditionalCCBs, bool SuccessMessageP)
243{
244 int BlockSize = BusLogic_CCB_AllocationGroupSize * sizeof(struct BusLogic_CCB);
245 int PreviouslyAllocated = HostAdapter->AllocatedCCBs;
246 void *BlockPointer;
247 dma_addr_t BlockPointerHandle;
248 if (AdditionalCCBs <= 0)
249 return;
250 while (HostAdapter->AllocatedCCBs - PreviouslyAllocated < AdditionalCCBs) {
251 BlockPointer = pci_alloc_consistent(HostAdapter->PCI_Device, BlockSize, &BlockPointerHandle);
252 if (BlockPointer == NULL)
253 break;
254 BusLogic_InitializeCCBs(HostAdapter, BlockPointer, BlockSize, BlockPointerHandle);
255 }
256 if (HostAdapter->AllocatedCCBs > PreviouslyAllocated) {
257 if (SuccessMessageP)
258 BusLogic_Notice("Allocated %d additional CCBs (total now %d)\n", HostAdapter, HostAdapter->AllocatedCCBs - PreviouslyAllocated, HostAdapter->AllocatedCCBs);
259 return;
260 }
261 BusLogic_Notice("Failed to allocate additional CCBs\n", HostAdapter);
262 if (HostAdapter->DriverQueueDepth > HostAdapter->AllocatedCCBs - HostAdapter->TargetDeviceCount) {
263 HostAdapter->DriverQueueDepth = HostAdapter->AllocatedCCBs - HostAdapter->TargetDeviceCount;
264 HostAdapter->SCSI_Host->can_queue = HostAdapter->DriverQueueDepth;
265 }
266}
267
268/*
269 BusLogic_AllocateCCB allocates a CCB from Host Adapter's free list,
270 allocating more memory from the Kernel if necessary. The Host Adapter's
271 Lock should already have been acquired by the caller.
272*/
273
274static struct BusLogic_CCB *BusLogic_AllocateCCB(struct BusLogic_HostAdapter
275 *HostAdapter)
276{
277 static unsigned long SerialNumber = 0;
278 struct BusLogic_CCB *CCB;
279 CCB = HostAdapter->Free_CCBs;
280 if (CCB != NULL) {
281 CCB->SerialNumber = ++SerialNumber;
282 HostAdapter->Free_CCBs = CCB->Next;
283 CCB->Next = NULL;
284 if (HostAdapter->Free_CCBs == NULL)
285 BusLogic_CreateAdditionalCCBs(HostAdapter, HostAdapter->IncrementalCCBs, true);
286 return CCB;
287 }
288 BusLogic_CreateAdditionalCCBs(HostAdapter, HostAdapter->IncrementalCCBs, true);
289 CCB = HostAdapter->Free_CCBs;
290 if (CCB == NULL)
291 return NULL;
292 CCB->SerialNumber = ++SerialNumber;
293 HostAdapter->Free_CCBs = CCB->Next;
294 CCB->Next = NULL;
295 return CCB;
296}
297
298
299/*
300 BusLogic_DeallocateCCB deallocates a CCB, returning it to the Host Adapter's
301 free list. The Host Adapter's Lock should already have been acquired by the
302 caller.
303*/
304
305static void BusLogic_DeallocateCCB(struct BusLogic_CCB *CCB)
306{
307 struct BusLogic_HostAdapter *HostAdapter = CCB->HostAdapter;
308
309 scsi_dma_unmap(CCB->Command);
310 pci_unmap_single(HostAdapter->PCI_Device, CCB->SenseDataPointer,
311 CCB->SenseDataLength, PCI_DMA_FROMDEVICE);
312
313 CCB->Command = NULL;
314 CCB->Status = BusLogic_CCB_Free;
315 CCB->Next = HostAdapter->Free_CCBs;
316 HostAdapter->Free_CCBs = CCB;
317}
318
319
320/*
321 BusLogic_Command sends the command OperationCode to HostAdapter, optionally
322 providing ParameterLength bytes of ParameterData and receiving at most
323 ReplyLength bytes of ReplyData; any excess reply data is received but
324 discarded.
325
326 On success, this function returns the number of reply bytes read from
327 the Host Adapter (including any discarded data); on failure, it returns
328 -1 if the command was invalid, or -2 if a timeout occurred.
329
330 BusLogic_Command is called exclusively during host adapter detection and
331 initialization, so performance and latency are not critical, and exclusive
332 access to the Host Adapter hardware is assumed. Once the host adapter and
333 driver are initialized, the only Host Adapter command that is issued is the
334 single byte Execute Mailbox Command operation code, which does not require
335 waiting for the Host Adapter Ready bit to be set in the Status Register.
336*/
337
338static int BusLogic_Command(struct BusLogic_HostAdapter *HostAdapter, enum BusLogic_OperationCode OperationCode, void *ParameterData, int ParameterLength, void *ReplyData, int ReplyLength)
339{
340 unsigned char *ParameterPointer = (unsigned char *) ParameterData;
341 unsigned char *ReplyPointer = (unsigned char *) ReplyData;
342 union BusLogic_StatusRegister StatusRegister;
343 union BusLogic_InterruptRegister InterruptRegister;
344 unsigned long ProcessorFlags = 0;
345 int ReplyBytes = 0, Result;
346 long TimeoutCounter;
347 /*
348 Clear out the Reply Data if provided.
349 */
350 if (ReplyLength > 0)
351 memset(ReplyData, 0, ReplyLength);
352 /*
353 If the IRQ Channel has not yet been acquired, then interrupts must be
354 disabled while issuing host adapter commands since a Command Complete
355 interrupt could occur if the IRQ Channel was previously enabled by another
356 BusLogic Host Adapter or another driver sharing the same IRQ Channel.
357 */
358 if (!HostAdapter->IRQ_ChannelAcquired)
359 local_irq_save(ProcessorFlags);
360 /*
361 Wait for the Host Adapter Ready bit to be set and the Command/Parameter
362 Register Busy bit to be reset in the Status Register.
363 */
364 TimeoutCounter = 10000;
365 while (--TimeoutCounter >= 0) {
366 StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
367 if (StatusRegister.sr.HostAdapterReady && !StatusRegister.sr.CommandParameterRegisterBusy)
368 break;
369 udelay(100);
370 }
371 if (TimeoutCounter < 0) {
372 BusLogic_CommandFailureReason = "Timeout waiting for Host Adapter Ready";
373 Result = -2;
374 goto Done;
375 }
376 /*
377 Write the OperationCode to the Command/Parameter Register.
378 */
379 HostAdapter->HostAdapterCommandCompleted = false;
380 BusLogic_WriteCommandParameterRegister(HostAdapter, OperationCode);
381 /*
382 Write any additional Parameter Bytes.
383 */
384 TimeoutCounter = 10000;
385 while (ParameterLength > 0 && --TimeoutCounter >= 0) {
386 /*
387 Wait 100 microseconds to give the Host Adapter enough time to determine
388 whether the last value written to the Command/Parameter Register was
389 valid or not. If the Command Complete bit is set in the Interrupt
390 Register, then the Command Invalid bit in the Status Register will be
391 reset if the Operation Code or Parameter was valid and the command
392 has completed, or set if the Operation Code or Parameter was invalid.
393 If the Data In Register Ready bit is set in the Status Register, then
394 the Operation Code was valid, and data is waiting to be read back
395 from the Host Adapter. Otherwise, wait for the Command/Parameter
396 Register Busy bit in the Status Register to be reset.
397 */
398 udelay(100);
399 InterruptRegister.All = BusLogic_ReadInterruptRegister(HostAdapter);
400 StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
401 if (InterruptRegister.ir.CommandComplete)
402 break;
403 if (HostAdapter->HostAdapterCommandCompleted)
404 break;
405 if (StatusRegister.sr.DataInRegisterReady)
406 break;
407 if (StatusRegister.sr.CommandParameterRegisterBusy)
408 continue;
409 BusLogic_WriteCommandParameterRegister(HostAdapter, *ParameterPointer++);
410 ParameterLength--;
411 }
412 if (TimeoutCounter < 0) {
413 BusLogic_CommandFailureReason = "Timeout waiting for Parameter Acceptance";
414 Result = -2;
415 goto Done;
416 }
417 /*
418 The Modify I/O Address command does not cause a Command Complete Interrupt.
419 */
420 if (OperationCode == BusLogic_ModifyIOAddress) {
421 StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
422 if (StatusRegister.sr.CommandInvalid) {
423 BusLogic_CommandFailureReason = "Modify I/O Address Invalid";
424 Result = -1;
425 goto Done;
426 }
427 if (BusLogic_GlobalOptions.TraceConfiguration)
428 BusLogic_Notice("BusLogic_Command(%02X) Status = %02X: " "(Modify I/O Address)\n", HostAdapter, OperationCode, StatusRegister.All);
429 Result = 0;
430 goto Done;
431 }
432 /*
433 Select an appropriate timeout value for awaiting command completion.
434 */
435 switch (OperationCode) {
436 case BusLogic_InquireInstalledDevicesID0to7:
437 case BusLogic_InquireInstalledDevicesID8to15:
438 case BusLogic_InquireTargetDevices:
439 /* Approximately 60 seconds. */
440 TimeoutCounter = 60 * 10000;
441 break;
442 default:
443 /* Approximately 1 second. */
444 TimeoutCounter = 10000;
445 break;
446 }
447 /*
448 Receive any Reply Bytes, waiting for either the Command Complete bit to
449 be set in the Interrupt Register, or for the Interrupt Handler to set the
450 Host Adapter Command Completed bit in the Host Adapter structure.
451 */
452 while (--TimeoutCounter >= 0) {
453 InterruptRegister.All = BusLogic_ReadInterruptRegister(HostAdapter);
454 StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
455 if (InterruptRegister.ir.CommandComplete)
456 break;
457 if (HostAdapter->HostAdapterCommandCompleted)
458 break;
459 if (StatusRegister.sr.DataInRegisterReady) {
460 if (++ReplyBytes <= ReplyLength)
461 *ReplyPointer++ = BusLogic_ReadDataInRegister(HostAdapter);
462 else
463 BusLogic_ReadDataInRegister(HostAdapter);
464 }
465 if (OperationCode == BusLogic_FetchHostAdapterLocalRAM && StatusRegister.sr.HostAdapterReady)
466 break;
467 udelay(100);
468 }
469 if (TimeoutCounter < 0) {
470 BusLogic_CommandFailureReason = "Timeout waiting for Command Complete";
471 Result = -2;
472 goto Done;
473 }
474 /*
475 Clear any pending Command Complete Interrupt.
476 */
477 BusLogic_InterruptReset(HostAdapter);
478 /*
479 Provide tracing information if requested.
480 */
481 if (BusLogic_GlobalOptions.TraceConfiguration) {
482 int i;
483 BusLogic_Notice("BusLogic_Command(%02X) Status = %02X: %2d ==> %2d:", HostAdapter, OperationCode, StatusRegister.All, ReplyLength, ReplyBytes);
484 if (ReplyLength > ReplyBytes)
485 ReplyLength = ReplyBytes;
486 for (i = 0; i < ReplyLength; i++)
487 BusLogic_Notice(" %02X", HostAdapter, ((unsigned char *) ReplyData)[i]);
488 BusLogic_Notice("\n", HostAdapter);
489 }
490 /*
491 Process Command Invalid conditions.
492 */
493 if (StatusRegister.sr.CommandInvalid) {
494 /*
495 Some early BusLogic Host Adapters may not recover properly from
496 a Command Invalid condition, so if this appears to be the case,
497 a Soft Reset is issued to the Host Adapter. Potentially invalid
498 commands are never attempted after Mailbox Initialization is
499 performed, so there should be no Host Adapter state lost by a
500 Soft Reset in response to a Command Invalid condition.
501 */
502 udelay(1000);
503 StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
504 if (StatusRegister.sr.CommandInvalid ||
505 StatusRegister.sr.Reserved ||
506 StatusRegister.sr.DataInRegisterReady ||
507 StatusRegister.sr.CommandParameterRegisterBusy || !StatusRegister.sr.HostAdapterReady || !StatusRegister.sr.InitializationRequired || StatusRegister.sr.DiagnosticActive || StatusRegister.sr.DiagnosticFailure) {
508 BusLogic_SoftReset(HostAdapter);
509 udelay(1000);
510 }
511 BusLogic_CommandFailureReason = "Command Invalid";
512 Result = -1;
513 goto Done;
514 }
515 /*
516 Handle Excess Parameters Supplied conditions.
517 */
518 if (ParameterLength > 0) {
519 BusLogic_CommandFailureReason = "Excess Parameters Supplied";
520 Result = -1;
521 goto Done;
522 }
523 /*
524 Indicate the command completed successfully.
525 */
526 BusLogic_CommandFailureReason = NULL;
527 Result = ReplyBytes;
528 /*
529 Restore the interrupt status if necessary and return.
530 */
531 Done:
532 if (!HostAdapter->IRQ_ChannelAcquired)
533 local_irq_restore(ProcessorFlags);
534 return Result;
535}
536
537
538/*
539 BusLogic_AppendProbeAddressISA appends a single ISA I/O Address to the list
540 of I/O Address and Bus Probe Information to be checked for potential BusLogic
541 Host Adapters.
542*/
543
544static void __init BusLogic_AppendProbeAddressISA(unsigned long IO_Address)
545{
546 struct BusLogic_ProbeInfo *ProbeInfo;
547 if (BusLogic_ProbeInfoCount >= BusLogic_MaxHostAdapters)
548 return;
549 ProbeInfo = &BusLogic_ProbeInfoList[BusLogic_ProbeInfoCount++];
550 ProbeInfo->HostAdapterType = BusLogic_MultiMaster;
551 ProbeInfo->HostAdapterBusType = BusLogic_ISA_Bus;
552 ProbeInfo->IO_Address = IO_Address;
553 ProbeInfo->PCI_Device = NULL;
554}
555
556
557/*
558 BusLogic_InitializeProbeInfoListISA initializes the list of I/O Address and
559 Bus Probe Information to be checked for potential BusLogic SCSI Host Adapters
560 only from the list of standard BusLogic MultiMaster ISA I/O Addresses.
561*/
562
563static void __init BusLogic_InitializeProbeInfoListISA(struct BusLogic_HostAdapter
564 *PrototypeHostAdapter)
565{
566 /*
567 If BusLogic Driver Options specifications requested that ISA Bus Probes
568 be inhibited, do not proceed further.
569 */
570 if (BusLogic_ProbeOptions.NoProbeISA)
571 return;
572 /*
573 Append the list of standard BusLogic MultiMaster ISA I/O Addresses.
574 */
575 if (!BusLogic_ProbeOptions.LimitedProbeISA || BusLogic_ProbeOptions.Probe330)
576 BusLogic_AppendProbeAddressISA(0x330);
577 if (!BusLogic_ProbeOptions.LimitedProbeISA || BusLogic_ProbeOptions.Probe334)
578 BusLogic_AppendProbeAddressISA(0x334);
579 if (!BusLogic_ProbeOptions.LimitedProbeISA || BusLogic_ProbeOptions.Probe230)
580 BusLogic_AppendProbeAddressISA(0x230);
581 if (!BusLogic_ProbeOptions.LimitedProbeISA || BusLogic_ProbeOptions.Probe234)
582 BusLogic_AppendProbeAddressISA(0x234);
583 if (!BusLogic_ProbeOptions.LimitedProbeISA || BusLogic_ProbeOptions.Probe130)
584 BusLogic_AppendProbeAddressISA(0x130);
585 if (!BusLogic_ProbeOptions.LimitedProbeISA || BusLogic_ProbeOptions.Probe134)
586 BusLogic_AppendProbeAddressISA(0x134);
587}
588
589
590#ifdef CONFIG_PCI
591
592
593/*
594 BusLogic_SortProbeInfo sorts a section of BusLogic_ProbeInfoList in order
595 of increasing PCI Bus and Device Number.
596*/
597
598static void __init BusLogic_SortProbeInfo(struct BusLogic_ProbeInfo *ProbeInfoList, int ProbeInfoCount)
599{
600 int LastInterchange = ProbeInfoCount - 1, Bound, j;
601 while (LastInterchange > 0) {
602 Bound = LastInterchange;
603 LastInterchange = 0;
604 for (j = 0; j < Bound; j++) {
605 struct BusLogic_ProbeInfo *ProbeInfo1 = &ProbeInfoList[j];
606 struct BusLogic_ProbeInfo *ProbeInfo2 = &ProbeInfoList[j + 1];
607 if (ProbeInfo1->Bus > ProbeInfo2->Bus || (ProbeInfo1->Bus == ProbeInfo2->Bus && (ProbeInfo1->Device > ProbeInfo2->Device))) {
608 struct BusLogic_ProbeInfo TempProbeInfo;
609 memcpy(&TempProbeInfo, ProbeInfo1, sizeof(struct BusLogic_ProbeInfo));
610 memcpy(ProbeInfo1, ProbeInfo2, sizeof(struct BusLogic_ProbeInfo));
611 memcpy(ProbeInfo2, &TempProbeInfo, sizeof(struct BusLogic_ProbeInfo));
612 LastInterchange = j;
613 }
614 }
615 }
616}
617
618
619/*
620 BusLogic_InitializeMultiMasterProbeInfo initializes the list of I/O Address
621 and Bus Probe Information to be checked for potential BusLogic MultiMaster
622 SCSI Host Adapters by interrogating the PCI Configuration Space on PCI
623 machines as well as from the list of standard BusLogic MultiMaster ISA
624 I/O Addresses. It returns the number of PCI MultiMaster Host Adapters found.
625*/
626
627static int __init BusLogic_InitializeMultiMasterProbeInfo(struct BusLogic_HostAdapter
628 *PrototypeHostAdapter)
629{
630 struct BusLogic_ProbeInfo *PrimaryProbeInfo = &BusLogic_ProbeInfoList[BusLogic_ProbeInfoCount];
631 int NonPrimaryPCIMultiMasterIndex = BusLogic_ProbeInfoCount + 1;
632 int NonPrimaryPCIMultiMasterCount = 0, PCIMultiMasterCount = 0;
633 bool ForceBusDeviceScanningOrder = false;
634 bool ForceBusDeviceScanningOrderChecked = false;
635 bool StandardAddressSeen[6];
636 struct pci_dev *PCI_Device = NULL;
637 int i;
638 if (BusLogic_ProbeInfoCount >= BusLogic_MaxHostAdapters)
639 return 0;
640 BusLogic_ProbeInfoCount++;
641 for (i = 0; i < 6; i++)
642 StandardAddressSeen[i] = false;
643 /*
644 Iterate over the MultiMaster PCI Host Adapters. For each enumerated host
645 adapter, determine whether its ISA Compatible I/O Port is enabled and if
646 so, whether it is assigned the Primary I/O Address. A host adapter that is
647 assigned the Primary I/O Address will always be the preferred boot device.
648 The MultiMaster BIOS will first recognize a host adapter at the Primary I/O
649 Address, then any other PCI host adapters, and finally any host adapters
650 located at the remaining standard ISA I/O Addresses. When a PCI host
651 adapter is found with its ISA Compatible I/O Port enabled, a command is
652 issued to disable the ISA Compatible I/O Port, and it is noted that the
653 particular standard ISA I/O Address need not be probed.
654 */
655 PrimaryProbeInfo->IO_Address = 0;
656 while ((PCI_Device = pci_get_device(PCI_VENDOR_ID_BUSLOGIC, PCI_DEVICE_ID_BUSLOGIC_MULTIMASTER, PCI_Device)) != NULL) {
657 struct BusLogic_HostAdapter *HostAdapter = PrototypeHostAdapter;
658 struct BusLogic_PCIHostAdapterInformation PCIHostAdapterInformation;
659 enum BusLogic_ISACompatibleIOPort ModifyIOAddressRequest;
660 unsigned char Bus;
661 unsigned char Device;
662 unsigned int IRQ_Channel;
663 unsigned long BaseAddress0;
664 unsigned long BaseAddress1;
665 unsigned long IO_Address;
666 unsigned long PCI_Address;
667
668 if (pci_enable_device(PCI_Device))
669 continue;
670
671 if (pci_set_dma_mask(PCI_Device, DMA_BIT_MASK(32) ))
672 continue;
673
674 Bus = PCI_Device->bus->number;
675 Device = PCI_Device->devfn >> 3;
676 IRQ_Channel = PCI_Device->irq;
677 IO_Address = BaseAddress0 = pci_resource_start(PCI_Device, 0);
678 PCI_Address = BaseAddress1 = pci_resource_start(PCI_Device, 1);
679
680 if (pci_resource_flags(PCI_Device, 0) & IORESOURCE_MEM) {
681 BusLogic_Error("BusLogic: Base Address0 0x%X not I/O for " "MultiMaster Host Adapter\n", NULL, BaseAddress0);
682 BusLogic_Error("at PCI Bus %d Device %d I/O Address 0x%X\n", NULL, Bus, Device, IO_Address);
683 continue;
684 }
685 if (pci_resource_flags(PCI_Device, 1) & IORESOURCE_IO) {
686 BusLogic_Error("BusLogic: Base Address1 0x%X not Memory for " "MultiMaster Host Adapter\n", NULL, BaseAddress1);
687 BusLogic_Error("at PCI Bus %d Device %d PCI Address 0x%X\n", NULL, Bus, Device, PCI_Address);
688 continue;
689 }
690 if (IRQ_Channel == 0) {
691 BusLogic_Error("BusLogic: IRQ Channel %d invalid for " "MultiMaster Host Adapter\n", NULL, IRQ_Channel);
692 BusLogic_Error("at PCI Bus %d Device %d I/O Address 0x%X\n", NULL, Bus, Device, IO_Address);
693 continue;
694 }
695 if (BusLogic_GlobalOptions.TraceProbe) {
696 BusLogic_Notice("BusLogic: PCI MultiMaster Host Adapter " "detected at\n", NULL);
697 BusLogic_Notice("BusLogic: PCI Bus %d Device %d I/O Address " "0x%X PCI Address 0x%X\n", NULL, Bus, Device, IO_Address, PCI_Address);
698 }
699 /*
700 Issue the Inquire PCI Host Adapter Information command to determine
701 the ISA Compatible I/O Port. If the ISA Compatible I/O Port is
702 known and enabled, note that the particular Standard ISA I/O
703 Address should not be probed.
704 */
705 HostAdapter->IO_Address = IO_Address;
706 BusLogic_InterruptReset(HostAdapter);
707 if (BusLogic_Command(HostAdapter, BusLogic_InquirePCIHostAdapterInformation, NULL, 0, &PCIHostAdapterInformation, sizeof(PCIHostAdapterInformation))
708 == sizeof(PCIHostAdapterInformation)) {
709 if (PCIHostAdapterInformation.ISACompatibleIOPort < 6)
710 StandardAddressSeen[PCIHostAdapterInformation.ISACompatibleIOPort] = true;
711 } else
712 PCIHostAdapterInformation.ISACompatibleIOPort = BusLogic_IO_Disable;
713 /*
714 * Issue the Modify I/O Address command to disable the ISA Compatible
715 * I/O Port. On PCI Host Adapters, the Modify I/O Address command
716 * allows modification of the ISA compatible I/O Address that the Host
717 * Adapter responds to; it does not affect the PCI compliant I/O Address
718 * assigned at system initialization.
719 */
720 ModifyIOAddressRequest = BusLogic_IO_Disable;
721 BusLogic_Command(HostAdapter, BusLogic_ModifyIOAddress, &ModifyIOAddressRequest, sizeof(ModifyIOAddressRequest), NULL, 0);
722 /*
723 For the first MultiMaster Host Adapter enumerated, issue the Fetch
724 Host Adapter Local RAM command to read byte 45 of the AutoSCSI area,
725 for the setting of the "Use Bus And Device # For PCI Scanning Seq."
726 option. Issue the Inquire Board ID command since this option is
727 only valid for the BT-948/958/958D.
728 */
729 if (!ForceBusDeviceScanningOrderChecked) {
730 struct BusLogic_FetchHostAdapterLocalRAMRequest FetchHostAdapterLocalRAMRequest;
731 struct BusLogic_AutoSCSIByte45 AutoSCSIByte45;
732 struct BusLogic_BoardID BoardID;
733 FetchHostAdapterLocalRAMRequest.ByteOffset = BusLogic_AutoSCSI_BaseOffset + 45;
734 FetchHostAdapterLocalRAMRequest.ByteCount = sizeof(AutoSCSIByte45);
735 BusLogic_Command(HostAdapter, BusLogic_FetchHostAdapterLocalRAM, &FetchHostAdapterLocalRAMRequest, sizeof(FetchHostAdapterLocalRAMRequest), &AutoSCSIByte45, sizeof(AutoSCSIByte45));
736 BusLogic_Command(HostAdapter, BusLogic_InquireBoardID, NULL, 0, &BoardID, sizeof(BoardID));
737 if (BoardID.FirmwareVersion1stDigit == '5')
738 ForceBusDeviceScanningOrder = AutoSCSIByte45.ForceBusDeviceScanningOrder;
739 ForceBusDeviceScanningOrderChecked = true;
740 }
741 /*
742 Determine whether this MultiMaster Host Adapter has its ISA
743 Compatible I/O Port enabled and is assigned the Primary I/O Address.
744 If it does, then it is the Primary MultiMaster Host Adapter and must
745 be recognized first. If it does not, then it is added to the list
746 for probing after any Primary MultiMaster Host Adapter is probed.
747 */
748 if (PCIHostAdapterInformation.ISACompatibleIOPort == BusLogic_IO_330) {
749 PrimaryProbeInfo->HostAdapterType = BusLogic_MultiMaster;
750 PrimaryProbeInfo->HostAdapterBusType = BusLogic_PCI_Bus;
751 PrimaryProbeInfo->IO_Address = IO_Address;
752 PrimaryProbeInfo->PCI_Address = PCI_Address;
753 PrimaryProbeInfo->Bus = Bus;
754 PrimaryProbeInfo->Device = Device;
755 PrimaryProbeInfo->IRQ_Channel = IRQ_Channel;
756 PrimaryProbeInfo->PCI_Device = pci_dev_get(PCI_Device);
757 PCIMultiMasterCount++;
758 } else if (BusLogic_ProbeInfoCount < BusLogic_MaxHostAdapters) {
759 struct BusLogic_ProbeInfo *ProbeInfo = &BusLogic_ProbeInfoList[BusLogic_ProbeInfoCount++];
760 ProbeInfo->HostAdapterType = BusLogic_MultiMaster;
761 ProbeInfo->HostAdapterBusType = BusLogic_PCI_Bus;
762 ProbeInfo->IO_Address = IO_Address;
763 ProbeInfo->PCI_Address = PCI_Address;
764 ProbeInfo->Bus = Bus;
765 ProbeInfo->Device = Device;
766 ProbeInfo->IRQ_Channel = IRQ_Channel;
767 ProbeInfo->PCI_Device = pci_dev_get(PCI_Device);
768 NonPrimaryPCIMultiMasterCount++;
769 PCIMultiMasterCount++;
770 } else
771 BusLogic_Warning("BusLogic: Too many Host Adapters " "detected\n", NULL);
772 }
773 /*
774 If the AutoSCSI "Use Bus And Device # For PCI Scanning Seq." option is ON
775 for the first enumerated MultiMaster Host Adapter, and if that host adapter
776 is a BT-948/958/958D, then the MultiMaster BIOS will recognize MultiMaster
777 Host Adapters in the order of increasing PCI Bus and Device Number. In
778 that case, sort the probe information into the same order the BIOS uses.
779 If this option is OFF, then the MultiMaster BIOS will recognize MultiMaster
780 Host Adapters in the order they are enumerated by the PCI BIOS, and hence
781 no sorting is necessary.
782 */
783 if (ForceBusDeviceScanningOrder)
784 BusLogic_SortProbeInfo(&BusLogic_ProbeInfoList[NonPrimaryPCIMultiMasterIndex], NonPrimaryPCIMultiMasterCount);
785 /*
786 If no PCI MultiMaster Host Adapter is assigned the Primary I/O Address,
787 then the Primary I/O Address must be probed explicitly before any PCI
788 host adapters are probed.
789 */
790 if (!BusLogic_ProbeOptions.NoProbeISA)
791 if (PrimaryProbeInfo->IO_Address == 0 &&
792 (!BusLogic_ProbeOptions.LimitedProbeISA ||
793 BusLogic_ProbeOptions.Probe330)) {
794 PrimaryProbeInfo->HostAdapterType = BusLogic_MultiMaster;
795 PrimaryProbeInfo->HostAdapterBusType = BusLogic_ISA_Bus;
796 PrimaryProbeInfo->IO_Address = 0x330;
797 }
798 /*
799 Append the list of standard BusLogic MultiMaster ISA I/O Addresses,
800 omitting the Primary I/O Address which has already been handled.
801 */
802 if (!BusLogic_ProbeOptions.NoProbeISA) {
803 if (!StandardAddressSeen[1] &&
804 (!BusLogic_ProbeOptions.LimitedProbeISA ||
805 BusLogic_ProbeOptions.Probe334))
806 BusLogic_AppendProbeAddressISA(0x334);
807 if (!StandardAddressSeen[2] &&
808 (!BusLogic_ProbeOptions.LimitedProbeISA ||
809 BusLogic_ProbeOptions.Probe230))
810 BusLogic_AppendProbeAddressISA(0x230);
811 if (!StandardAddressSeen[3] &&
812 (!BusLogic_ProbeOptions.LimitedProbeISA ||
813 BusLogic_ProbeOptions.Probe234))
814 BusLogic_AppendProbeAddressISA(0x234);
815 if (!StandardAddressSeen[4] &&
816 (!BusLogic_ProbeOptions.LimitedProbeISA ||
817 BusLogic_ProbeOptions.Probe130))
818 BusLogic_AppendProbeAddressISA(0x130);
819 if (!StandardAddressSeen[5] &&
820 (!BusLogic_ProbeOptions.LimitedProbeISA ||
821 BusLogic_ProbeOptions.Probe134))
822 BusLogic_AppendProbeAddressISA(0x134);
823 }
824 /*
825 Iterate over the older non-compliant MultiMaster PCI Host Adapters,
826 noting the PCI bus location and assigned IRQ Channel.
827 */
828 PCI_Device = NULL;
829 while ((PCI_Device = pci_get_device(PCI_VENDOR_ID_BUSLOGIC, PCI_DEVICE_ID_BUSLOGIC_MULTIMASTER_NC, PCI_Device)) != NULL) {
830 unsigned char Bus;
831 unsigned char Device;
832 unsigned int IRQ_Channel;
833 unsigned long IO_Address;
834
835 if (pci_enable_device(PCI_Device))
836 continue;
837
838 if (pci_set_dma_mask(PCI_Device, DMA_BIT_MASK(32)))
839 continue;
840
841 Bus = PCI_Device->bus->number;
842 Device = PCI_Device->devfn >> 3;
843 IRQ_Channel = PCI_Device->irq;
844 IO_Address = pci_resource_start(PCI_Device, 0);
845
846 if (IO_Address == 0 || IRQ_Channel == 0)
847 continue;
848 for (i = 0; i < BusLogic_ProbeInfoCount; i++) {
849 struct BusLogic_ProbeInfo *ProbeInfo = &BusLogic_ProbeInfoList[i];
850 if (ProbeInfo->IO_Address == IO_Address && ProbeInfo->HostAdapterType == BusLogic_MultiMaster) {
851 ProbeInfo->HostAdapterBusType = BusLogic_PCI_Bus;
852 ProbeInfo->PCI_Address = 0;
853 ProbeInfo->Bus = Bus;
854 ProbeInfo->Device = Device;
855 ProbeInfo->IRQ_Channel = IRQ_Channel;
856 ProbeInfo->PCI_Device = pci_dev_get(PCI_Device);
857 break;
858 }
859 }
860 }
861 return PCIMultiMasterCount;
862}
863
864
865/*
866 BusLogic_InitializeFlashPointProbeInfo initializes the list of I/O Address
867 and Bus Probe Information to be checked for potential BusLogic FlashPoint
868 Host Adapters by interrogating the PCI Configuration Space. It returns the
869 number of FlashPoint Host Adapters found.
870*/
871
872static int __init BusLogic_InitializeFlashPointProbeInfo(struct BusLogic_HostAdapter
873 *PrototypeHostAdapter)
874{
875 int FlashPointIndex = BusLogic_ProbeInfoCount, FlashPointCount = 0;
876 struct pci_dev *PCI_Device = NULL;
877 /*
878 Interrogate PCI Configuration Space for any FlashPoint Host Adapters.
879 */
880 while ((PCI_Device = pci_get_device(PCI_VENDOR_ID_BUSLOGIC, PCI_DEVICE_ID_BUSLOGIC_FLASHPOINT, PCI_Device)) != NULL) {
881 unsigned char Bus;
882 unsigned char Device;
883 unsigned int IRQ_Channel;
884 unsigned long BaseAddress0;
885 unsigned long BaseAddress1;
886 unsigned long IO_Address;
887 unsigned long PCI_Address;
888
889 if (pci_enable_device(PCI_Device))
890 continue;
891
892 if (pci_set_dma_mask(PCI_Device, DMA_BIT_MASK(32)))
893 continue;
894
895 Bus = PCI_Device->bus->number;
896 Device = PCI_Device->devfn >> 3;
897 IRQ_Channel = PCI_Device->irq;
898 IO_Address = BaseAddress0 = pci_resource_start(PCI_Device, 0);
899 PCI_Address = BaseAddress1 = pci_resource_start(PCI_Device, 1);
900#ifdef CONFIG_SCSI_FLASHPOINT
901 if (pci_resource_flags(PCI_Device, 0) & IORESOURCE_MEM) {
902 BusLogic_Error("BusLogic: Base Address0 0x%X not I/O for " "FlashPoint Host Adapter\n", NULL, BaseAddress0);
903 BusLogic_Error("at PCI Bus %d Device %d I/O Address 0x%X\n", NULL, Bus, Device, IO_Address);
904 continue;
905 }
906 if (pci_resource_flags(PCI_Device, 1) & IORESOURCE_IO) {
907 BusLogic_Error("BusLogic: Base Address1 0x%X not Memory for " "FlashPoint Host Adapter\n", NULL, BaseAddress1);
908 BusLogic_Error("at PCI Bus %d Device %d PCI Address 0x%X\n", NULL, Bus, Device, PCI_Address);
909 continue;
910 }
911 if (IRQ_Channel == 0) {
912 BusLogic_Error("BusLogic: IRQ Channel %d invalid for " "FlashPoint Host Adapter\n", NULL, IRQ_Channel);
913 BusLogic_Error("at PCI Bus %d Device %d I/O Address 0x%X\n", NULL, Bus, Device, IO_Address);
914 continue;
915 }
916 if (BusLogic_GlobalOptions.TraceProbe) {
917 BusLogic_Notice("BusLogic: FlashPoint Host Adapter " "detected at\n", NULL);
918 BusLogic_Notice("BusLogic: PCI Bus %d Device %d I/O Address " "0x%X PCI Address 0x%X\n", NULL, Bus, Device, IO_Address, PCI_Address);
919 }
920 if (BusLogic_ProbeInfoCount < BusLogic_MaxHostAdapters) {
921 struct BusLogic_ProbeInfo *ProbeInfo = &BusLogic_ProbeInfoList[BusLogic_ProbeInfoCount++];
922 ProbeInfo->HostAdapterType = BusLogic_FlashPoint;
923 ProbeInfo->HostAdapterBusType = BusLogic_PCI_Bus;
924 ProbeInfo->IO_Address = IO_Address;
925 ProbeInfo->PCI_Address = PCI_Address;
926 ProbeInfo->Bus = Bus;
927 ProbeInfo->Device = Device;
928 ProbeInfo->IRQ_Channel = IRQ_Channel;
929 ProbeInfo->PCI_Device = pci_dev_get(PCI_Device);
930 FlashPointCount++;
931 } else
932 BusLogic_Warning("BusLogic: Too many Host Adapters " "detected\n", NULL);
933#else
934 BusLogic_Error("BusLogic: FlashPoint Host Adapter detected at " "PCI Bus %d Device %d\n", NULL, Bus, Device);
935 BusLogic_Error("BusLogic: I/O Address 0x%X PCI Address 0x%X, irq %d, " "but FlashPoint\n", NULL, IO_Address, PCI_Address, IRQ_Channel);
936 BusLogic_Error("BusLogic: support was omitted in this kernel " "configuration.\n", NULL);
937#endif
938 }
939 /*
940 The FlashPoint BIOS will scan for FlashPoint Host Adapters in the order of
941 increasing PCI Bus and Device Number, so sort the probe information into
942 the same order the BIOS uses.
943 */
944 BusLogic_SortProbeInfo(&BusLogic_ProbeInfoList[FlashPointIndex], FlashPointCount);
945 return FlashPointCount;
946}
947
948
949/*
950 BusLogic_InitializeProbeInfoList initializes the list of I/O Address and Bus
951 Probe Information to be checked for potential BusLogic SCSI Host Adapters by
952 interrogating the PCI Configuration Space on PCI machines as well as from the
953 list of standard BusLogic MultiMaster ISA I/O Addresses. By default, if both
954 FlashPoint and PCI MultiMaster Host Adapters are present, this driver will
955 probe for FlashPoint Host Adapters first unless the BIOS primary disk is
956 controlled by the first PCI MultiMaster Host Adapter, in which case
957 MultiMaster Host Adapters will be probed first. The BusLogic Driver Options
958 specifications "MultiMasterFirst" and "FlashPointFirst" can be used to force
959 a particular probe order.
960*/
961
962static void __init BusLogic_InitializeProbeInfoList(struct BusLogic_HostAdapter
963 *PrototypeHostAdapter)
964{
965 /*
966 If a PCI BIOS is present, interrogate it for MultiMaster and FlashPoint
967 Host Adapters; otherwise, default to the standard ISA MultiMaster probe.
968 */
969 if (!BusLogic_ProbeOptions.NoProbePCI) {
970 if (BusLogic_ProbeOptions.MultiMasterFirst) {
971 BusLogic_InitializeMultiMasterProbeInfo(PrototypeHostAdapter);
972 BusLogic_InitializeFlashPointProbeInfo(PrototypeHostAdapter);
973 } else if (BusLogic_ProbeOptions.FlashPointFirst) {
974 BusLogic_InitializeFlashPointProbeInfo(PrototypeHostAdapter);
975 BusLogic_InitializeMultiMasterProbeInfo(PrototypeHostAdapter);
976 } else {
977 int FlashPointCount = BusLogic_InitializeFlashPointProbeInfo(PrototypeHostAdapter);
978 int PCIMultiMasterCount = BusLogic_InitializeMultiMasterProbeInfo(PrototypeHostAdapter);
979 if (FlashPointCount > 0 && PCIMultiMasterCount > 0) {
980 struct BusLogic_ProbeInfo *ProbeInfo = &BusLogic_ProbeInfoList[FlashPointCount];
981 struct BusLogic_HostAdapter *HostAdapter = PrototypeHostAdapter;
982 struct BusLogic_FetchHostAdapterLocalRAMRequest FetchHostAdapterLocalRAMRequest;
983 struct BusLogic_BIOSDriveMapByte Drive0MapByte;
984 while (ProbeInfo->HostAdapterBusType != BusLogic_PCI_Bus)
985 ProbeInfo++;
986 HostAdapter->IO_Address = ProbeInfo->IO_Address;
987 FetchHostAdapterLocalRAMRequest.ByteOffset = BusLogic_BIOS_BaseOffset + BusLogic_BIOS_DriveMapOffset + 0;
988 FetchHostAdapterLocalRAMRequest.ByteCount = sizeof(Drive0MapByte);
989 BusLogic_Command(HostAdapter, BusLogic_FetchHostAdapterLocalRAM, &FetchHostAdapterLocalRAMRequest, sizeof(FetchHostAdapterLocalRAMRequest), &Drive0MapByte, sizeof(Drive0MapByte));
990 /*
991 If the Map Byte for BIOS Drive 0 indicates that BIOS Drive 0
992 is controlled by this PCI MultiMaster Host Adapter, then
993 reverse the probe order so that MultiMaster Host Adapters are
994 probed before FlashPoint Host Adapters.
995 */
996 if (Drive0MapByte.DiskGeometry != BusLogic_BIOS_Disk_Not_Installed) {
997 struct BusLogic_ProbeInfo SavedProbeInfo[BusLogic_MaxHostAdapters];
998 int MultiMasterCount = BusLogic_ProbeInfoCount - FlashPointCount;
999 memcpy(SavedProbeInfo, BusLogic_ProbeInfoList, BusLogic_ProbeInfoCount * sizeof(struct BusLogic_ProbeInfo));
1000 memcpy(&BusLogic_ProbeInfoList[0], &SavedProbeInfo[FlashPointCount], MultiMasterCount * sizeof(struct BusLogic_ProbeInfo));
1001 memcpy(&BusLogic_ProbeInfoList[MultiMasterCount], &SavedProbeInfo[0], FlashPointCount * sizeof(struct BusLogic_ProbeInfo));
1002 }
1003 }
1004 }
1005 } else
1006 BusLogic_InitializeProbeInfoListISA(PrototypeHostAdapter);
1007}
1008
1009
1010#else
1011#define BusLogic_InitializeProbeInfoList(adapter) \
1012 BusLogic_InitializeProbeInfoListISA(adapter)
1013#endif /* CONFIG_PCI */
1014
1015
1016/*
1017 BusLogic_Failure prints a standardized error message, and then returns false.
1018*/
1019
1020static bool BusLogic_Failure(struct BusLogic_HostAdapter *HostAdapter, char *ErrorMessage)
1021{
1022 BusLogic_AnnounceDriver(HostAdapter);
1023 if (HostAdapter->HostAdapterBusType == BusLogic_PCI_Bus) {
1024 BusLogic_Error("While configuring BusLogic PCI Host Adapter at\n", HostAdapter);
1025 BusLogic_Error("Bus %d Device %d I/O Address 0x%X PCI Address 0x%X:\n", HostAdapter, HostAdapter->Bus, HostAdapter->Device, HostAdapter->IO_Address, HostAdapter->PCI_Address);
1026 } else
1027 BusLogic_Error("While configuring BusLogic Host Adapter at " "I/O Address 0x%X:\n", HostAdapter, HostAdapter->IO_Address);
1028 BusLogic_Error("%s FAILED - DETACHING\n", HostAdapter, ErrorMessage);
1029 if (BusLogic_CommandFailureReason != NULL)
1030 BusLogic_Error("ADDITIONAL FAILURE INFO - %s\n", HostAdapter, BusLogic_CommandFailureReason);
1031 return false;
1032}
1033
1034
1035/*
1036 BusLogic_ProbeHostAdapter probes for a BusLogic Host Adapter.
1037*/
1038
1039static bool __init BusLogic_ProbeHostAdapter(struct BusLogic_HostAdapter *HostAdapter)
1040{
1041 union BusLogic_StatusRegister StatusRegister;
1042 union BusLogic_InterruptRegister InterruptRegister;
1043 union BusLogic_GeometryRegister GeometryRegister;
1044 /*
1045 FlashPoint Host Adapters are Probed by the FlashPoint SCCB Manager.
1046 */
1047 if (BusLogic_FlashPointHostAdapterP(HostAdapter)) {
1048 struct FlashPoint_Info *FlashPointInfo = &HostAdapter->FlashPointInfo;
1049 FlashPointInfo->BaseAddress = (u32) HostAdapter->IO_Address;
1050 FlashPointInfo->IRQ_Channel = HostAdapter->IRQ_Channel;
1051 FlashPointInfo->Present = false;
1052 if (!(FlashPoint_ProbeHostAdapter(FlashPointInfo) == 0 && FlashPointInfo->Present)) {
1053 BusLogic_Error("BusLogic: FlashPoint Host Adapter detected at " "PCI Bus %d Device %d\n", HostAdapter, HostAdapter->Bus, HostAdapter->Device);
1054 BusLogic_Error("BusLogic: I/O Address 0x%X PCI Address 0x%X, " "but FlashPoint\n", HostAdapter, HostAdapter->IO_Address, HostAdapter->PCI_Address);
1055 BusLogic_Error("BusLogic: Probe Function failed to validate it.\n", HostAdapter);
1056 return false;
1057 }
1058 if (BusLogic_GlobalOptions.TraceProbe)
1059 BusLogic_Notice("BusLogic_Probe(0x%X): FlashPoint Found\n", HostAdapter, HostAdapter->IO_Address);
1060 /*
1061 Indicate the Host Adapter Probe completed successfully.
1062 */
1063 return true;
1064 }
1065 /*
1066 Read the Status, Interrupt, and Geometry Registers to test if there are I/O
1067 ports that respond, and to check the values to determine if they are from a
1068 BusLogic Host Adapter. A nonexistent I/O port will return 0xFF, in which
1069 case there is definitely no BusLogic Host Adapter at this base I/O Address.
1070 The test here is a subset of that used by the BusLogic Host Adapter BIOS.
1071 */
1072 StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
1073 InterruptRegister.All = BusLogic_ReadInterruptRegister(HostAdapter);
1074 GeometryRegister.All = BusLogic_ReadGeometryRegister(HostAdapter);
1075 if (BusLogic_GlobalOptions.TraceProbe)
1076 BusLogic_Notice("BusLogic_Probe(0x%X): Status 0x%02X, Interrupt 0x%02X, " "Geometry 0x%02X\n", HostAdapter, HostAdapter->IO_Address, StatusRegister.All, InterruptRegister.All, GeometryRegister.All);
1077 if (StatusRegister.All == 0 || StatusRegister.sr.DiagnosticActive || StatusRegister.sr.CommandParameterRegisterBusy || StatusRegister.sr.Reserved || StatusRegister.sr.CommandInvalid || InterruptRegister.ir.Reserved != 0)
1078 return false;
1079 /*
1080 Check the undocumented Geometry Register to test if there is an I/O port
1081 that responded. Adaptec Host Adapters do not implement the Geometry
1082 Register, so this test helps serve to avoid incorrectly recognizing an
1083 Adaptec 1542A or 1542B as a BusLogic. Unfortunately, the Adaptec 1542C
1084 series does respond to the Geometry Register I/O port, but it will be
1085 rejected later when the Inquire Extended Setup Information command is
1086 issued in BusLogic_CheckHostAdapter. The AMI FastDisk Host Adapter is a
1087 BusLogic clone that implements the same interface as earlier BusLogic
1088 Host Adapters, including the undocumented commands, and is therefore
1089 supported by this driver. However, the AMI FastDisk always returns 0x00
1090 upon reading the Geometry Register, so the extended translation option
1091 should always be left disabled on the AMI FastDisk.
1092 */
1093 if (GeometryRegister.All == 0xFF)
1094 return false;
1095 /*
1096 Indicate the Host Adapter Probe completed successfully.
1097 */
1098 return true;
1099}
1100
1101
1102/*
1103 BusLogic_HardwareResetHostAdapter issues a Hardware Reset to the Host Adapter
1104 and waits for Host Adapter Diagnostics to complete. If HardReset is true, a
1105 Hard Reset is performed which also initiates a SCSI Bus Reset. Otherwise, a
1106 Soft Reset is performed which only resets the Host Adapter without forcing a
1107 SCSI Bus Reset.
1108*/
1109
1110static bool BusLogic_HardwareResetHostAdapter(struct BusLogic_HostAdapter
1111 *HostAdapter, bool HardReset)
1112{
1113 union BusLogic_StatusRegister StatusRegister;
1114 int TimeoutCounter;
1115 /*
1116 FlashPoint Host Adapters are Hard Reset by the FlashPoint SCCB Manager.
1117 */
1118 if (BusLogic_FlashPointHostAdapterP(HostAdapter)) {
1119 struct FlashPoint_Info *FlashPointInfo = &HostAdapter->FlashPointInfo;
1120 FlashPointInfo->HostSoftReset = !HardReset;
1121 FlashPointInfo->ReportDataUnderrun = true;
1122 HostAdapter->CardHandle = FlashPoint_HardwareResetHostAdapter(FlashPointInfo);
1123 if (HostAdapter->CardHandle == FlashPoint_BadCardHandle)
1124 return false;
1125 /*
1126 Indicate the Host Adapter Hard Reset completed successfully.
1127 */
1128 return true;
1129 }
1130 /*
1131 Issue a Hard Reset or Soft Reset Command to the Host Adapter. The Host
1132 Adapter should respond by setting Diagnostic Active in the Status Register.
1133 */
1134 if (HardReset)
1135 BusLogic_HardReset(HostAdapter);
1136 else
1137 BusLogic_SoftReset(HostAdapter);
1138 /*
1139 Wait until Diagnostic Active is set in the Status Register.
1140 */
1141 TimeoutCounter = 5 * 10000;
1142 while (--TimeoutCounter >= 0) {
1143 StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
1144 if (StatusRegister.sr.DiagnosticActive)
1145 break;
1146 udelay(100);
1147 }
1148 if (BusLogic_GlobalOptions.TraceHardwareReset)
1149 BusLogic_Notice("BusLogic_HardwareReset(0x%X): Diagnostic Active, " "Status 0x%02X\n", HostAdapter, HostAdapter->IO_Address, StatusRegister.All);
1150 if (TimeoutCounter < 0)
1151 return false;
1152 /*
1153 Wait 100 microseconds to allow completion of any initial diagnostic
1154 activity which might leave the contents of the Status Register
1155 unpredictable.
1156 */
1157 udelay(100);
1158 /*
1159 Wait until Diagnostic Active is reset in the Status Register.
1160 */
1161 TimeoutCounter = 10 * 10000;
1162 while (--TimeoutCounter >= 0) {
1163 StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
1164 if (!StatusRegister.sr.DiagnosticActive)
1165 break;
1166 udelay(100);
1167 }
1168 if (BusLogic_GlobalOptions.TraceHardwareReset)
1169 BusLogic_Notice("BusLogic_HardwareReset(0x%X): Diagnostic Completed, " "Status 0x%02X\n", HostAdapter, HostAdapter->IO_Address, StatusRegister.All);
1170 if (TimeoutCounter < 0)
1171 return false;
1172 /*
1173 Wait until at least one of the Diagnostic Failure, Host Adapter Ready,
1174 or Data In Register Ready bits is set in the Status Register.
1175 */
1176 TimeoutCounter = 10000;
1177 while (--TimeoutCounter >= 0) {
1178 StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
1179 if (StatusRegister.sr.DiagnosticFailure || StatusRegister.sr.HostAdapterReady || StatusRegister.sr.DataInRegisterReady)
1180 break;
1181 udelay(100);
1182 }
1183 if (BusLogic_GlobalOptions.TraceHardwareReset)
1184 BusLogic_Notice("BusLogic_HardwareReset(0x%X): Host Adapter Ready, " "Status 0x%02X\n", HostAdapter, HostAdapter->IO_Address, StatusRegister.All);
1185 if (TimeoutCounter < 0)
1186 return false;
1187 /*
1188 If Diagnostic Failure is set or Host Adapter Ready is reset, then an
1189 error occurred during the Host Adapter diagnostics. If Data In Register
1190 Ready is set, then there is an Error Code available.
1191 */
1192 if (StatusRegister.sr.DiagnosticFailure || !StatusRegister.sr.HostAdapterReady) {
1193 BusLogic_CommandFailureReason = NULL;
1194 BusLogic_Failure(HostAdapter, "HARD RESET DIAGNOSTICS");
1195 BusLogic_Error("HOST ADAPTER STATUS REGISTER = %02X\n", HostAdapter, StatusRegister.All);
1196 if (StatusRegister.sr.DataInRegisterReady) {
1197 unsigned char ErrorCode = BusLogic_ReadDataInRegister(HostAdapter);
1198 BusLogic_Error("HOST ADAPTER ERROR CODE = %d\n", HostAdapter, ErrorCode);
1199 }
1200 return false;
1201 }
1202 /*
1203 Indicate the Host Adapter Hard Reset completed successfully.
1204 */
1205 return true;
1206}
1207
1208
1209/*
1210 BusLogic_CheckHostAdapter checks to be sure this really is a BusLogic
1211 Host Adapter.
1212*/
1213
1214static bool __init BusLogic_CheckHostAdapter(struct BusLogic_HostAdapter *HostAdapter)
1215{
1216 struct BusLogic_ExtendedSetupInformation ExtendedSetupInformation;
1217 unsigned char RequestedReplyLength;
1218 bool Result = true;
1219 /*
1220 FlashPoint Host Adapters do not require this protection.
1221 */
1222 if (BusLogic_FlashPointHostAdapterP(HostAdapter))
1223 return true;
1224 /*
1225 Issue the Inquire Extended Setup Information command. Only genuine
1226 BusLogic Host Adapters and true clones support this command. Adaptec 1542C
1227 series Host Adapters that respond to the Geometry Register I/O port will
1228 fail this command.
1229 */
1230 RequestedReplyLength = sizeof(ExtendedSetupInformation);
1231 if (BusLogic_Command(HostAdapter, BusLogic_InquireExtendedSetupInformation, &RequestedReplyLength, sizeof(RequestedReplyLength), &ExtendedSetupInformation, sizeof(ExtendedSetupInformation))
1232 != sizeof(ExtendedSetupInformation))
1233 Result = false;
1234 /*
1235 Provide tracing information if requested and return.
1236 */
1237 if (BusLogic_GlobalOptions.TraceProbe)
1238 BusLogic_Notice("BusLogic_Check(0x%X): MultiMaster %s\n", HostAdapter, HostAdapter->IO_Address, (Result ? "Found" : "Not Found"));
1239 return Result;
1240}
1241
1242
1243/*
1244 BusLogic_ReadHostAdapterConfiguration reads the Configuration Information
1245 from Host Adapter and initializes the Host Adapter structure.
1246*/
1247
1248static bool __init BusLogic_ReadHostAdapterConfiguration(struct BusLogic_HostAdapter
1249 *HostAdapter)
1250{
1251 struct BusLogic_BoardID BoardID;
1252 struct BusLogic_Configuration Configuration;
1253 struct BusLogic_SetupInformation SetupInformation;
1254 struct BusLogic_ExtendedSetupInformation ExtendedSetupInformation;
1255 unsigned char HostAdapterModelNumber[5];
1256 unsigned char FirmwareVersion3rdDigit;
1257 unsigned char FirmwareVersionLetter;
1258 struct BusLogic_PCIHostAdapterInformation PCIHostAdapterInformation;
1259 struct BusLogic_FetchHostAdapterLocalRAMRequest FetchHostAdapterLocalRAMRequest;
1260 struct BusLogic_AutoSCSIData AutoSCSIData;
1261 union BusLogic_GeometryRegister GeometryRegister;
1262 unsigned char RequestedReplyLength;
1263 unsigned char *TargetPointer, Character;
1264 int TargetID, i;
1265 /*
1266 Configuration Information for FlashPoint Host Adapters is provided in the
1267 FlashPoint_Info structure by the FlashPoint SCCB Manager's Probe Function.
1268 Initialize fields in the Host Adapter structure from the FlashPoint_Info
1269 structure.
1270 */
1271 if (BusLogic_FlashPointHostAdapterP(HostAdapter)) {
1272 struct FlashPoint_Info *FlashPointInfo = &HostAdapter->FlashPointInfo;
1273 TargetPointer = HostAdapter->ModelName;
1274 *TargetPointer++ = 'B';
1275 *TargetPointer++ = 'T';
1276 *TargetPointer++ = '-';
1277 for (i = 0; i < sizeof(FlashPointInfo->ModelNumber); i++)
1278 *TargetPointer++ = FlashPointInfo->ModelNumber[i];
1279 *TargetPointer++ = '\0';
1280 strcpy(HostAdapter->FirmwareVersion, FlashPoint_FirmwareVersion);
1281 HostAdapter->SCSI_ID = FlashPointInfo->SCSI_ID;
1282 HostAdapter->ExtendedTranslationEnabled = FlashPointInfo->ExtendedTranslationEnabled;
1283 HostAdapter->ParityCheckingEnabled = FlashPointInfo->ParityCheckingEnabled;
1284 HostAdapter->BusResetEnabled = !FlashPointInfo->HostSoftReset;
1285 HostAdapter->LevelSensitiveInterrupt = true;
1286 HostAdapter->HostWideSCSI = FlashPointInfo->HostWideSCSI;
1287 HostAdapter->HostDifferentialSCSI = false;
1288 HostAdapter->HostSupportsSCAM = true;
1289 HostAdapter->HostUltraSCSI = true;
1290 HostAdapter->ExtendedLUNSupport = true;
1291 HostAdapter->TerminationInfoValid = true;
1292 HostAdapter->LowByteTerminated = FlashPointInfo->LowByteTerminated;
1293 HostAdapter->HighByteTerminated = FlashPointInfo->HighByteTerminated;
1294 HostAdapter->SCAM_Enabled = FlashPointInfo->SCAM_Enabled;
1295 HostAdapter->SCAM_Level2 = FlashPointInfo->SCAM_Level2;
1296 HostAdapter->DriverScatterGatherLimit = BusLogic_ScatterGatherLimit;
1297 HostAdapter->MaxTargetDevices = (HostAdapter->HostWideSCSI ? 16 : 8);
1298 HostAdapter->MaxLogicalUnits = 32;
1299 HostAdapter->InitialCCBs = 4 * BusLogic_CCB_AllocationGroupSize;
1300 HostAdapter->IncrementalCCBs = BusLogic_CCB_AllocationGroupSize;
1301 HostAdapter->DriverQueueDepth = 255;
1302 HostAdapter->HostAdapterQueueDepth = HostAdapter->DriverQueueDepth;
1303 HostAdapter->SynchronousPermitted = FlashPointInfo->SynchronousPermitted;
1304 HostAdapter->FastPermitted = FlashPointInfo->FastPermitted;
1305 HostAdapter->UltraPermitted = FlashPointInfo->UltraPermitted;
1306 HostAdapter->WidePermitted = FlashPointInfo->WidePermitted;
1307 HostAdapter->DisconnectPermitted = FlashPointInfo->DisconnectPermitted;
1308 HostAdapter->TaggedQueuingPermitted = 0xFFFF;
1309 goto Common;
1310 }
1311 /*
1312 Issue the Inquire Board ID command.
1313 */
1314 if (BusLogic_Command(HostAdapter, BusLogic_InquireBoardID, NULL, 0, &BoardID, sizeof(BoardID)) != sizeof(BoardID))
1315 return BusLogic_Failure(HostAdapter, "INQUIRE BOARD ID");
1316 /*
1317 Issue the Inquire Configuration command.
1318 */
1319 if (BusLogic_Command(HostAdapter, BusLogic_InquireConfiguration, NULL, 0, &Configuration, sizeof(Configuration))
1320 != sizeof(Configuration))
1321 return BusLogic_Failure(HostAdapter, "INQUIRE CONFIGURATION");
1322 /*
1323 Issue the Inquire Setup Information command.
1324 */
1325 RequestedReplyLength = sizeof(SetupInformation);
1326 if (BusLogic_Command(HostAdapter, BusLogic_InquireSetupInformation, &RequestedReplyLength, sizeof(RequestedReplyLength), &SetupInformation, sizeof(SetupInformation))
1327 != sizeof(SetupInformation))
1328 return BusLogic_Failure(HostAdapter, "INQUIRE SETUP INFORMATION");
1329 /*
1330 Issue the Inquire Extended Setup Information command.
1331 */
1332 RequestedReplyLength = sizeof(ExtendedSetupInformation);
1333 if (BusLogic_Command(HostAdapter, BusLogic_InquireExtendedSetupInformation, &RequestedReplyLength, sizeof(RequestedReplyLength), &ExtendedSetupInformation, sizeof(ExtendedSetupInformation))
1334 != sizeof(ExtendedSetupInformation))
1335 return BusLogic_Failure(HostAdapter, "INQUIRE EXTENDED SETUP INFORMATION");
1336 /*
1337 Issue the Inquire Firmware Version 3rd Digit command.
1338 */
1339 FirmwareVersion3rdDigit = '\0';
1340 if (BoardID.FirmwareVersion1stDigit > '0')
1341 if (BusLogic_Command(HostAdapter, BusLogic_InquireFirmwareVersion3rdDigit, NULL, 0, &FirmwareVersion3rdDigit, sizeof(FirmwareVersion3rdDigit))
1342 != sizeof(FirmwareVersion3rdDigit))
1343 return BusLogic_Failure(HostAdapter, "INQUIRE FIRMWARE 3RD DIGIT");
1344 /*
1345 Issue the Inquire Host Adapter Model Number command.
1346 */
1347 if (ExtendedSetupInformation.BusType == 'A' && BoardID.FirmwareVersion1stDigit == '2')
1348 /* BusLogic BT-542B ISA 2.xx */
1349 strcpy(HostAdapterModelNumber, "542B");
1350 else if (ExtendedSetupInformation.BusType == 'E' && BoardID.FirmwareVersion1stDigit == '2' && (BoardID.FirmwareVersion2ndDigit <= '1' || (BoardID.FirmwareVersion2ndDigit == '2' && FirmwareVersion3rdDigit == '0')))
1351 /* BusLogic BT-742A EISA 2.1x or 2.20 */
1352 strcpy(HostAdapterModelNumber, "742A");
1353 else if (ExtendedSetupInformation.BusType == 'E' && BoardID.FirmwareVersion1stDigit == '0')
1354 /* AMI FastDisk EISA Series 441 0.x */
1355 strcpy(HostAdapterModelNumber, "747A");
1356 else {
1357 RequestedReplyLength = sizeof(HostAdapterModelNumber);
1358 if (BusLogic_Command(HostAdapter, BusLogic_InquireHostAdapterModelNumber, &RequestedReplyLength, sizeof(RequestedReplyLength), &HostAdapterModelNumber, sizeof(HostAdapterModelNumber))
1359 != sizeof(HostAdapterModelNumber))
1360 return BusLogic_Failure(HostAdapter, "INQUIRE HOST ADAPTER MODEL NUMBER");
1361 }
1362 /*
1363 BusLogic MultiMaster Host Adapters can be identified by their model number
1364 and the major version number of their firmware as follows:
1365
1366 5.xx BusLogic "W" Series Host Adapters:
1367 BT-948/958/958D
1368 4.xx BusLogic "C" Series Host Adapters:
1369 BT-946C/956C/956CD/747C/757C/757CD/445C/545C/540CF
1370 3.xx BusLogic "S" Series Host Adapters:
1371 BT-747S/747D/757S/757D/445S/545S/542D
1372 BT-542B/742A (revision H)
1373 2.xx BusLogic "A" Series Host Adapters:
1374 BT-542B/742A (revision G and below)
1375 0.xx AMI FastDisk VLB/EISA BusLogic Clone Host Adapter
1376 */
1377 /*
1378 Save the Model Name and Host Adapter Name in the Host Adapter structure.
1379 */
1380 TargetPointer = HostAdapter->ModelName;
1381 *TargetPointer++ = 'B';
1382 *TargetPointer++ = 'T';
1383 *TargetPointer++ = '-';
1384 for (i = 0; i < sizeof(HostAdapterModelNumber); i++) {
1385 Character = HostAdapterModelNumber[i];
1386 if (Character == ' ' || Character == '\0')
1387 break;
1388 *TargetPointer++ = Character;
1389 }
1390 *TargetPointer++ = '\0';
1391 /*
1392 Save the Firmware Version in the Host Adapter structure.
1393 */
1394 TargetPointer = HostAdapter->FirmwareVersion;
1395 *TargetPointer++ = BoardID.FirmwareVersion1stDigit;
1396 *TargetPointer++ = '.';
1397 *TargetPointer++ = BoardID.FirmwareVersion2ndDigit;
1398 if (FirmwareVersion3rdDigit != ' ' && FirmwareVersion3rdDigit != '\0')
1399 *TargetPointer++ = FirmwareVersion3rdDigit;
1400 *TargetPointer = '\0';
1401 /*
1402 Issue the Inquire Firmware Version Letter command.
1403 */
1404 if (strcmp(HostAdapter->FirmwareVersion, "3.3") >= 0) {
1405 if (BusLogic_Command(HostAdapter, BusLogic_InquireFirmwareVersionLetter, NULL, 0, &FirmwareVersionLetter, sizeof(FirmwareVersionLetter))
1406 != sizeof(FirmwareVersionLetter))
1407 return BusLogic_Failure(HostAdapter, "INQUIRE FIRMWARE VERSION LETTER");
1408 if (FirmwareVersionLetter != ' ' && FirmwareVersionLetter != '\0')
1409 *TargetPointer++ = FirmwareVersionLetter;
1410 *TargetPointer = '\0';
1411 }
1412 /*
1413 Save the Host Adapter SCSI ID in the Host Adapter structure.
1414 */
1415 HostAdapter->SCSI_ID = Configuration.HostAdapterID;
1416 /*
1417 Determine the Bus Type and save it in the Host Adapter structure, determine
1418 and save the IRQ Channel if necessary, and determine and save the DMA
1419 Channel for ISA Host Adapters.
1420 */
1421 HostAdapter->HostAdapterBusType = BusLogic_HostAdapterBusTypes[HostAdapter->ModelName[3] - '4'];
1422 if (HostAdapter->IRQ_Channel == 0) {
1423 if (Configuration.IRQ_Channel9)
1424 HostAdapter->IRQ_Channel = 9;
1425 else if (Configuration.IRQ_Channel10)
1426 HostAdapter->IRQ_Channel = 10;
1427 else if (Configuration.IRQ_Channel11)
1428 HostAdapter->IRQ_Channel = 11;
1429 else if (Configuration.IRQ_Channel12)
1430 HostAdapter->IRQ_Channel = 12;
1431 else if (Configuration.IRQ_Channel14)
1432 HostAdapter->IRQ_Channel = 14;
1433 else if (Configuration.IRQ_Channel15)
1434 HostAdapter->IRQ_Channel = 15;
1435 }
1436 if (HostAdapter->HostAdapterBusType == BusLogic_ISA_Bus) {
1437 if (Configuration.DMA_Channel5)
1438 HostAdapter->DMA_Channel = 5;
1439 else if (Configuration.DMA_Channel6)
1440 HostAdapter->DMA_Channel = 6;
1441 else if (Configuration.DMA_Channel7)
1442 HostAdapter->DMA_Channel = 7;
1443 }
1444 /*
1445 Determine whether Extended Translation is enabled and save it in
1446 the Host Adapter structure.
1447 */
1448 GeometryRegister.All = BusLogic_ReadGeometryRegister(HostAdapter);
1449 HostAdapter->ExtendedTranslationEnabled = GeometryRegister.gr.ExtendedTranslationEnabled;
1450 /*
1451 Save the Scatter Gather Limits, Level Sensitive Interrupt flag, Wide
1452 SCSI flag, Differential SCSI flag, SCAM Supported flag, and
1453 Ultra SCSI flag in the Host Adapter structure.
1454 */
1455 HostAdapter->HostAdapterScatterGatherLimit = ExtendedSetupInformation.ScatterGatherLimit;
1456 HostAdapter->DriverScatterGatherLimit = HostAdapter->HostAdapterScatterGatherLimit;
1457 if (HostAdapter->HostAdapterScatterGatherLimit > BusLogic_ScatterGatherLimit)
1458 HostAdapter->DriverScatterGatherLimit = BusLogic_ScatterGatherLimit;
1459 if (ExtendedSetupInformation.Misc.LevelSensitiveInterrupt)
1460 HostAdapter->LevelSensitiveInterrupt = true;
1461 HostAdapter->HostWideSCSI = ExtendedSetupInformation.HostWideSCSI;
1462 HostAdapter->HostDifferentialSCSI = ExtendedSetupInformation.HostDifferentialSCSI;
1463 HostAdapter->HostSupportsSCAM = ExtendedSetupInformation.HostSupportsSCAM;
1464 HostAdapter->HostUltraSCSI = ExtendedSetupInformation.HostUltraSCSI;
1465 /*
1466 Determine whether Extended LUN Format CCBs are supported and save the
1467 information in the Host Adapter structure.
1468 */
1469 if (HostAdapter->FirmwareVersion[0] == '5' || (HostAdapter->FirmwareVersion[0] == '4' && HostAdapter->HostWideSCSI))
1470 HostAdapter->ExtendedLUNSupport = true;
1471 /*
1472 Issue the Inquire PCI Host Adapter Information command to read the
1473 Termination Information from "W" series MultiMaster Host Adapters.
1474 */
1475 if (HostAdapter->FirmwareVersion[0] == '5') {
1476 if (BusLogic_Command(HostAdapter, BusLogic_InquirePCIHostAdapterInformation, NULL, 0, &PCIHostAdapterInformation, sizeof(PCIHostAdapterInformation))
1477 != sizeof(PCIHostAdapterInformation))
1478 return BusLogic_Failure(HostAdapter, "INQUIRE PCI HOST ADAPTER INFORMATION");
1479 /*
1480 Save the Termination Information in the Host Adapter structure.
1481 */
1482 if (PCIHostAdapterInformation.GenericInfoValid) {
1483 HostAdapter->TerminationInfoValid = true;
1484 HostAdapter->LowByteTerminated = PCIHostAdapterInformation.LowByteTerminated;
1485 HostAdapter->HighByteTerminated = PCIHostAdapterInformation.HighByteTerminated;
1486 }
1487 }
1488 /*
1489 Issue the Fetch Host Adapter Local RAM command to read the AutoSCSI data
1490 from "W" and "C" series MultiMaster Host Adapters.
1491 */
1492 if (HostAdapter->FirmwareVersion[0] >= '4') {
1493 FetchHostAdapterLocalRAMRequest.ByteOffset = BusLogic_AutoSCSI_BaseOffset;
1494 FetchHostAdapterLocalRAMRequest.ByteCount = sizeof(AutoSCSIData);
1495 if (BusLogic_Command(HostAdapter, BusLogic_FetchHostAdapterLocalRAM, &FetchHostAdapterLocalRAMRequest, sizeof(FetchHostAdapterLocalRAMRequest), &AutoSCSIData, sizeof(AutoSCSIData))
1496 != sizeof(AutoSCSIData))
1497 return BusLogic_Failure(HostAdapter, "FETCH HOST ADAPTER LOCAL RAM");
1498 /*
1499 Save the Parity Checking Enabled, Bus Reset Enabled, and Termination
1500 Information in the Host Adapter structure.
1501 */
1502 HostAdapter->ParityCheckingEnabled = AutoSCSIData.ParityCheckingEnabled;
1503 HostAdapter->BusResetEnabled = AutoSCSIData.BusResetEnabled;
1504 if (HostAdapter->FirmwareVersion[0] == '4') {
1505 HostAdapter->TerminationInfoValid = true;
1506 HostAdapter->LowByteTerminated = AutoSCSIData.LowByteTerminated;
1507 HostAdapter->HighByteTerminated = AutoSCSIData.HighByteTerminated;
1508 }
1509 /*
1510 Save the Wide Permitted, Fast Permitted, Synchronous Permitted,
1511 Disconnect Permitted, Ultra Permitted, and SCAM Information in the
1512 Host Adapter structure.
1513 */
1514 HostAdapter->WidePermitted = AutoSCSIData.WidePermitted;
1515 HostAdapter->FastPermitted = AutoSCSIData.FastPermitted;
1516 HostAdapter->SynchronousPermitted = AutoSCSIData.SynchronousPermitted;
1517 HostAdapter->DisconnectPermitted = AutoSCSIData.DisconnectPermitted;
1518 if (HostAdapter->HostUltraSCSI)
1519 HostAdapter->UltraPermitted = AutoSCSIData.UltraPermitted;
1520 if (HostAdapter->HostSupportsSCAM) {
1521 HostAdapter->SCAM_Enabled = AutoSCSIData.SCAM_Enabled;
1522 HostAdapter->SCAM_Level2 = AutoSCSIData.SCAM_Level2;
1523 }
1524 }
1525 /*
1526 Initialize fields in the Host Adapter structure for "S" and "A" series
1527 MultiMaster Host Adapters.
1528 */
1529 if (HostAdapter->FirmwareVersion[0] < '4') {
1530 if (SetupInformation.SynchronousInitiationEnabled) {
1531 HostAdapter->SynchronousPermitted = 0xFF;
1532 if (HostAdapter->HostAdapterBusType == BusLogic_EISA_Bus) {
1533 if (ExtendedSetupInformation.Misc.FastOnEISA)
1534 HostAdapter->FastPermitted = 0xFF;
1535 if (strcmp(HostAdapter->ModelName, "BT-757") == 0)
1536 HostAdapter->WidePermitted = 0xFF;
1537 }
1538 }
1539 HostAdapter->DisconnectPermitted = 0xFF;
1540 HostAdapter->ParityCheckingEnabled = SetupInformation.ParityCheckingEnabled;
1541 HostAdapter->BusResetEnabled = true;
1542 }
1543 /*
1544 Determine the maximum number of Target IDs and Logical Units supported by
1545 this driver for Wide and Narrow Host Adapters.
1546 */
1547 HostAdapter->MaxTargetDevices = (HostAdapter->HostWideSCSI ? 16 : 8);
1548 HostAdapter->MaxLogicalUnits = (HostAdapter->ExtendedLUNSupport ? 32 : 8);
1549 /*
1550 Select appropriate values for the Mailbox Count, Driver Queue Depth,
1551 Initial CCBs, and Incremental CCBs variables based on whether or not Strict
1552 Round Robin Mode is supported. If Strict Round Robin Mode is supported,
1553 then there is no performance degradation in using the maximum possible
1554 number of Outgoing and Incoming Mailboxes and allowing the Tagged and
1555 Untagged Queue Depths to determine the actual utilization. If Strict Round
1556 Robin Mode is not supported, then the Host Adapter must scan all the
1557 Outgoing Mailboxes whenever an Outgoing Mailbox entry is made, which can
1558 cause a substantial performance penalty. The host adapters actually have
1559 room to store the following number of CCBs internally; that is, they can
1560 internally queue and manage this many active commands on the SCSI bus
1561 simultaneously. Performance measurements demonstrate that the Driver Queue
1562 Depth should be set to the Mailbox Count, rather than the Host Adapter
1563 Queue Depth (internal CCB capacity), as it is more efficient to have the
1564 queued commands waiting in Outgoing Mailboxes if necessary than to block
1565 the process in the higher levels of the SCSI Subsystem.
1566
1567 192 BT-948/958/958D
1568 100 BT-946C/956C/956CD/747C/757C/757CD/445C
1569 50 BT-545C/540CF
1570 30 BT-747S/747D/757S/757D/445S/545S/542D/542B/742A
1571 */
1572 if (HostAdapter->FirmwareVersion[0] == '5')
1573 HostAdapter->HostAdapterQueueDepth = 192;
1574 else if (HostAdapter->FirmwareVersion[0] == '4')
1575 HostAdapter->HostAdapterQueueDepth = (HostAdapter->HostAdapterBusType != BusLogic_ISA_Bus ? 100 : 50);
1576 else
1577 HostAdapter->HostAdapterQueueDepth = 30;
1578 if (strcmp(HostAdapter->FirmwareVersion, "3.31") >= 0) {
1579 HostAdapter->StrictRoundRobinModeSupport = true;
1580 HostAdapter->MailboxCount = BusLogic_MaxMailboxes;
1581 } else {
1582 HostAdapter->StrictRoundRobinModeSupport = false;
1583 HostAdapter->MailboxCount = 32;
1584 }
1585 HostAdapter->DriverQueueDepth = HostAdapter->MailboxCount;
1586 HostAdapter->InitialCCBs = 4 * BusLogic_CCB_AllocationGroupSize;
1587 HostAdapter->IncrementalCCBs = BusLogic_CCB_AllocationGroupSize;
1588 /*
1589 Tagged Queuing support is available and operates properly on all "W" series
1590 MultiMaster Host Adapters, on "C" series MultiMaster Host Adapters with
1591 firmware version 4.22 and above, and on "S" series MultiMaster Host
1592 Adapters with firmware version 3.35 and above.
1593 */
1594 HostAdapter->TaggedQueuingPermitted = 0;
1595 switch (HostAdapter->FirmwareVersion[0]) {
1596 case '5':
1597 HostAdapter->TaggedQueuingPermitted = 0xFFFF;
1598 break;
1599 case '4':
1600 if (strcmp(HostAdapter->FirmwareVersion, "4.22") >= 0)
1601 HostAdapter->TaggedQueuingPermitted = 0xFFFF;
1602 break;
1603 case '3':
1604 if (strcmp(HostAdapter->FirmwareVersion, "3.35") >= 0)
1605 HostAdapter->TaggedQueuingPermitted = 0xFFFF;
1606 break;
1607 }
1608 /*
1609 Determine the Host Adapter BIOS Address if the BIOS is enabled and
1610 save it in the Host Adapter structure. The BIOS is disabled if the
1611 BIOS_Address is 0.
1612 */
1613 HostAdapter->BIOS_Address = ExtendedSetupInformation.BIOS_Address << 12;
1614 /*
1615 ISA Host Adapters require Bounce Buffers if there is more than 16MB memory.
1616 */
1617 if (HostAdapter->HostAdapterBusType == BusLogic_ISA_Bus && (void *) high_memory > (void *) MAX_DMA_ADDRESS)
1618 HostAdapter->BounceBuffersRequired = true;
1619 /*
1620 BusLogic BT-445S Host Adapters prior to board revision E have a hardware
1621 bug whereby when the BIOS is enabled, transfers to/from the same address
1622 range the BIOS occupies modulo 16MB are handled incorrectly. Only properly
1623 functioning BT-445S Host Adapters have firmware version 3.37, so require
1624 that ISA Bounce Buffers be used for the buggy BT-445S models if there is
1625 more than 16MB memory.
1626 */
1627 if (HostAdapter->BIOS_Address > 0 && strcmp(HostAdapter->ModelName, "BT-445S") == 0 && strcmp(HostAdapter->FirmwareVersion, "3.37") < 0 && (void *) high_memory > (void *) MAX_DMA_ADDRESS)
1628 HostAdapter->BounceBuffersRequired = true;
1629 /*
1630 Initialize parameters common to MultiMaster and FlashPoint Host Adapters.
1631 */
1632 Common:
1633 /*
1634 Initialize the Host Adapter Full Model Name from the Model Name.
1635 */
1636 strcpy(HostAdapter->FullModelName, "BusLogic ");
1637 strcat(HostAdapter->FullModelName, HostAdapter->ModelName);
1638 /*
1639 Select an appropriate value for the Tagged Queue Depth either from a
1640 BusLogic Driver Options specification, or based on whether this Host
1641 Adapter requires that ISA Bounce Buffers be used. The Tagged Queue Depth
1642 is left at 0 for automatic determination in BusLogic_SelectQueueDepths.
1643 Initialize the Untagged Queue Depth.
1644 */
1645 for (TargetID = 0; TargetID < BusLogic_MaxTargetDevices; TargetID++) {
1646 unsigned char QueueDepth = 0;
1647 if (HostAdapter->DriverOptions != NULL && HostAdapter->DriverOptions->QueueDepth[TargetID] > 0)
1648 QueueDepth = HostAdapter->DriverOptions->QueueDepth[TargetID];
1649 else if (HostAdapter->BounceBuffersRequired)
1650 QueueDepth = BusLogic_TaggedQueueDepthBB;
1651 HostAdapter->QueueDepth[TargetID] = QueueDepth;
1652 }
1653 if (HostAdapter->BounceBuffersRequired)
1654 HostAdapter->UntaggedQueueDepth = BusLogic_UntaggedQueueDepthBB;
1655 else
1656 HostAdapter->UntaggedQueueDepth = BusLogic_UntaggedQueueDepth;
1657 if (HostAdapter->DriverOptions != NULL)
1658 HostAdapter->CommonQueueDepth = HostAdapter->DriverOptions->CommonQueueDepth;
1659 if (HostAdapter->CommonQueueDepth > 0 && HostAdapter->CommonQueueDepth < HostAdapter->UntaggedQueueDepth)
1660 HostAdapter->UntaggedQueueDepth = HostAdapter->CommonQueueDepth;
1661 /*
1662 Tagged Queuing is only allowed if Disconnect/Reconnect is permitted.
1663 Therefore, mask the Tagged Queuing Permitted Default bits with the
1664 Disconnect/Reconnect Permitted bits.
1665 */
1666 HostAdapter->TaggedQueuingPermitted &= HostAdapter->DisconnectPermitted;
1667 /*
1668 Combine the default Tagged Queuing Permitted bits with any BusLogic Driver
1669 Options Tagged Queuing specification.
1670 */
1671 if (HostAdapter->DriverOptions != NULL)
1672 HostAdapter->TaggedQueuingPermitted =
1673 (HostAdapter->DriverOptions->TaggedQueuingPermitted & HostAdapter->DriverOptions->TaggedQueuingPermittedMask) | (HostAdapter->TaggedQueuingPermitted & ~HostAdapter->DriverOptions->TaggedQueuingPermittedMask);
1674
1675 /*
1676 Select an appropriate value for Bus Settle Time either from a BusLogic
1677 Driver Options specification, or from BusLogic_DefaultBusSettleTime.
1678 */
1679 if (HostAdapter->DriverOptions != NULL && HostAdapter->DriverOptions->BusSettleTime > 0)
1680 HostAdapter->BusSettleTime = HostAdapter->DriverOptions->BusSettleTime;
1681 else
1682 HostAdapter->BusSettleTime = BusLogic_DefaultBusSettleTime;
1683 /*
1684 Indicate reading the Host Adapter Configuration completed successfully.
1685 */
1686 return true;
1687}
1688
1689
1690/*
1691 BusLogic_ReportHostAdapterConfiguration reports the configuration of
1692 Host Adapter.
1693*/
1694
1695static bool __init BusLogic_ReportHostAdapterConfiguration(struct BusLogic_HostAdapter
1696 *HostAdapter)
1697{
1698 unsigned short AllTargetsMask = (1 << HostAdapter->MaxTargetDevices) - 1;
1699 unsigned short SynchronousPermitted, FastPermitted;
1700 unsigned short UltraPermitted, WidePermitted;
1701 unsigned short DisconnectPermitted, TaggedQueuingPermitted;
1702 bool CommonSynchronousNegotiation, CommonTaggedQueueDepth;
1703 char SynchronousString[BusLogic_MaxTargetDevices + 1];
1704 char WideString[BusLogic_MaxTargetDevices + 1];
1705 char DisconnectString[BusLogic_MaxTargetDevices + 1];
1706 char TaggedQueuingString[BusLogic_MaxTargetDevices + 1];
1707 char *SynchronousMessage = SynchronousString;
1708 char *WideMessage = WideString;
1709 char *DisconnectMessage = DisconnectString;
1710 char *TaggedQueuingMessage = TaggedQueuingString;
1711 int TargetID;
1712 BusLogic_Info("Configuring BusLogic Model %s %s%s%s%s SCSI Host Adapter\n",
1713 HostAdapter, HostAdapter->ModelName,
1714 BusLogic_HostAdapterBusNames[HostAdapter->HostAdapterBusType], (HostAdapter->HostWideSCSI ? " Wide" : ""), (HostAdapter->HostDifferentialSCSI ? " Differential" : ""), (HostAdapter->HostUltraSCSI ? " Ultra" : ""));
1715 BusLogic_Info(" Firmware Version: %s, I/O Address: 0x%X, " "IRQ Channel: %d/%s\n", HostAdapter, HostAdapter->FirmwareVersion, HostAdapter->IO_Address, HostAdapter->IRQ_Channel, (HostAdapter->LevelSensitiveInterrupt ? "Level" : "Edge"));
1716 if (HostAdapter->HostAdapterBusType != BusLogic_PCI_Bus) {
1717 BusLogic_Info(" DMA Channel: ", HostAdapter);
1718 if (HostAdapter->DMA_Channel > 0)
1719 BusLogic_Info("%d, ", HostAdapter, HostAdapter->DMA_Channel);
1720 else
1721 BusLogic_Info("None, ", HostAdapter);
1722 if (HostAdapter->BIOS_Address > 0)
1723 BusLogic_Info("BIOS Address: 0x%X, ", HostAdapter, HostAdapter->BIOS_Address);
1724 else
1725 BusLogic_Info("BIOS Address: None, ", HostAdapter);
1726 } else {
1727 BusLogic_Info(" PCI Bus: %d, Device: %d, Address: ", HostAdapter, HostAdapter->Bus, HostAdapter->Device);
1728 if (HostAdapter->PCI_Address > 0)
1729 BusLogic_Info("0x%X, ", HostAdapter, HostAdapter->PCI_Address);
1730 else
1731 BusLogic_Info("Unassigned, ", HostAdapter);
1732 }
1733 BusLogic_Info("Host Adapter SCSI ID: %d\n", HostAdapter, HostAdapter->SCSI_ID);
1734 BusLogic_Info(" Parity Checking: %s, Extended Translation: %s\n", HostAdapter, (HostAdapter->ParityCheckingEnabled ? "Enabled" : "Disabled"), (HostAdapter->ExtendedTranslationEnabled ? "Enabled" : "Disabled"));
1735 AllTargetsMask &= ~(1 << HostAdapter->SCSI_ID);
1736 SynchronousPermitted = HostAdapter->SynchronousPermitted & AllTargetsMask;
1737 FastPermitted = HostAdapter->FastPermitted & AllTargetsMask;
1738 UltraPermitted = HostAdapter->UltraPermitted & AllTargetsMask;
1739 if ((BusLogic_MultiMasterHostAdapterP(HostAdapter) && (HostAdapter->FirmwareVersion[0] >= '4' || HostAdapter->HostAdapterBusType == BusLogic_EISA_Bus)) || BusLogic_FlashPointHostAdapterP(HostAdapter)) {
1740 CommonSynchronousNegotiation = false;
1741 if (SynchronousPermitted == 0) {
1742 SynchronousMessage = "Disabled";
1743 CommonSynchronousNegotiation = true;
1744 } else if (SynchronousPermitted == AllTargetsMask) {
1745 if (FastPermitted == 0) {
1746 SynchronousMessage = "Slow";
1747 CommonSynchronousNegotiation = true;
1748 } else if (FastPermitted == AllTargetsMask) {
1749 if (UltraPermitted == 0) {
1750 SynchronousMessage = "Fast";
1751 CommonSynchronousNegotiation = true;
1752 } else if (UltraPermitted == AllTargetsMask) {
1753 SynchronousMessage = "Ultra";
1754 CommonSynchronousNegotiation = true;
1755 }
1756 }
1757 }
1758 if (!CommonSynchronousNegotiation) {
1759 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++)
1760 SynchronousString[TargetID] = ((!(SynchronousPermitted & (1 << TargetID))) ? 'N' : (!(FastPermitted & (1 << TargetID)) ? 'S' : (!(UltraPermitted & (1 << TargetID)) ? 'F' : 'U')));
1761 SynchronousString[HostAdapter->SCSI_ID] = '#';
1762 SynchronousString[HostAdapter->MaxTargetDevices] = '\0';
1763 }
1764 } else
1765 SynchronousMessage = (SynchronousPermitted == 0 ? "Disabled" : "Enabled");
1766 WidePermitted = HostAdapter->WidePermitted & AllTargetsMask;
1767 if (WidePermitted == 0)
1768 WideMessage = "Disabled";
1769 else if (WidePermitted == AllTargetsMask)
1770 WideMessage = "Enabled";
1771 else {
1772 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++)
1773 WideString[TargetID] = ((WidePermitted & (1 << TargetID)) ? 'Y' : 'N');
1774 WideString[HostAdapter->SCSI_ID] = '#';
1775 WideString[HostAdapter->MaxTargetDevices] = '\0';
1776 }
1777 DisconnectPermitted = HostAdapter->DisconnectPermitted & AllTargetsMask;
1778 if (DisconnectPermitted == 0)
1779 DisconnectMessage = "Disabled";
1780 else if (DisconnectPermitted == AllTargetsMask)
1781 DisconnectMessage = "Enabled";
1782 else {
1783 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++)
1784 DisconnectString[TargetID] = ((DisconnectPermitted & (1 << TargetID)) ? 'Y' : 'N');
1785 DisconnectString[HostAdapter->SCSI_ID] = '#';
1786 DisconnectString[HostAdapter->MaxTargetDevices] = '\0';
1787 }
1788 TaggedQueuingPermitted = HostAdapter->TaggedQueuingPermitted & AllTargetsMask;
1789 if (TaggedQueuingPermitted == 0)
1790 TaggedQueuingMessage = "Disabled";
1791 else if (TaggedQueuingPermitted == AllTargetsMask)
1792 TaggedQueuingMessage = "Enabled";
1793 else {
1794 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++)
1795 TaggedQueuingString[TargetID] = ((TaggedQueuingPermitted & (1 << TargetID)) ? 'Y' : 'N');
1796 TaggedQueuingString[HostAdapter->SCSI_ID] = '#';
1797 TaggedQueuingString[HostAdapter->MaxTargetDevices] = '\0';
1798 }
1799 BusLogic_Info(" Synchronous Negotiation: %s, Wide Negotiation: %s\n", HostAdapter, SynchronousMessage, WideMessage);
1800 BusLogic_Info(" Disconnect/Reconnect: %s, Tagged Queuing: %s\n", HostAdapter, DisconnectMessage, TaggedQueuingMessage);
1801 if (BusLogic_MultiMasterHostAdapterP(HostAdapter)) {
1802 BusLogic_Info(" Scatter/Gather Limit: %d of %d segments, " "Mailboxes: %d\n", HostAdapter, HostAdapter->DriverScatterGatherLimit, HostAdapter->HostAdapterScatterGatherLimit, HostAdapter->MailboxCount);
1803 BusLogic_Info(" Driver Queue Depth: %d, " "Host Adapter Queue Depth: %d\n", HostAdapter, HostAdapter->DriverQueueDepth, HostAdapter->HostAdapterQueueDepth);
1804 } else
1805 BusLogic_Info(" Driver Queue Depth: %d, " "Scatter/Gather Limit: %d segments\n", HostAdapter, HostAdapter->DriverQueueDepth, HostAdapter->DriverScatterGatherLimit);
1806 BusLogic_Info(" Tagged Queue Depth: ", HostAdapter);
1807 CommonTaggedQueueDepth = true;
1808 for (TargetID = 1; TargetID < HostAdapter->MaxTargetDevices; TargetID++)
1809 if (HostAdapter->QueueDepth[TargetID] != HostAdapter->QueueDepth[0]) {
1810 CommonTaggedQueueDepth = false;
1811 break;
1812 }
1813 if (CommonTaggedQueueDepth) {
1814 if (HostAdapter->QueueDepth[0] > 0)
1815 BusLogic_Info("%d", HostAdapter, HostAdapter->QueueDepth[0]);
1816 else
1817 BusLogic_Info("Automatic", HostAdapter);
1818 } else
1819 BusLogic_Info("Individual", HostAdapter);
1820 BusLogic_Info(", Untagged Queue Depth: %d\n", HostAdapter, HostAdapter->UntaggedQueueDepth);
1821 if (HostAdapter->TerminationInfoValid) {
1822 if (HostAdapter->HostWideSCSI)
1823 BusLogic_Info(" SCSI Bus Termination: %s", HostAdapter, (HostAdapter->LowByteTerminated ? (HostAdapter->HighByteTerminated ? "Both Enabled" : "Low Enabled")
1824 : (HostAdapter->HighByteTerminated ? "High Enabled" : "Both Disabled")));
1825 else
1826 BusLogic_Info(" SCSI Bus Termination: %s", HostAdapter, (HostAdapter->LowByteTerminated ? "Enabled" : "Disabled"));
1827 if (HostAdapter->HostSupportsSCAM)
1828 BusLogic_Info(", SCAM: %s", HostAdapter, (HostAdapter->SCAM_Enabled ? (HostAdapter->SCAM_Level2 ? "Enabled, Level 2" : "Enabled, Level 1")
1829 : "Disabled"));
1830 BusLogic_Info("\n", HostAdapter);
1831 }
1832 /*
1833 Indicate reporting the Host Adapter configuration completed successfully.
1834 */
1835 return true;
1836}
1837
1838
1839/*
1840 BusLogic_AcquireResources acquires the system resources necessary to use
1841 Host Adapter.
1842*/
1843
1844static bool __init BusLogic_AcquireResources(struct BusLogic_HostAdapter *HostAdapter)
1845{
1846 if (HostAdapter->IRQ_Channel == 0) {
1847 BusLogic_Error("NO LEGAL INTERRUPT CHANNEL ASSIGNED - DETACHING\n", HostAdapter);
1848 return false;
1849 }
1850 /*
1851 Acquire shared access to the IRQ Channel.
1852 */
1853 if (request_irq(HostAdapter->IRQ_Channel, BusLogic_InterruptHandler, IRQF_SHARED, HostAdapter->FullModelName, HostAdapter) < 0) {
1854 BusLogic_Error("UNABLE TO ACQUIRE IRQ CHANNEL %d - DETACHING\n", HostAdapter, HostAdapter->IRQ_Channel);
1855 return false;
1856 }
1857 HostAdapter->IRQ_ChannelAcquired = true;
1858 /*
1859 Acquire exclusive access to the DMA Channel.
1860 */
1861 if (HostAdapter->DMA_Channel > 0) {
1862 if (request_dma(HostAdapter->DMA_Channel, HostAdapter->FullModelName) < 0) {
1863 BusLogic_Error("UNABLE TO ACQUIRE DMA CHANNEL %d - DETACHING\n", HostAdapter, HostAdapter->DMA_Channel);
1864 return false;
1865 }
1866 set_dma_mode(HostAdapter->DMA_Channel, DMA_MODE_CASCADE);
1867 enable_dma(HostAdapter->DMA_Channel);
1868 HostAdapter->DMA_ChannelAcquired = true;
1869 }
1870 /*
1871 Indicate the System Resource Acquisition completed successfully,
1872 */
1873 return true;
1874}
1875
1876
1877/*
1878 BusLogic_ReleaseResources releases any system resources previously acquired
1879 by BusLogic_AcquireResources.
1880*/
1881
1882static void BusLogic_ReleaseResources(struct BusLogic_HostAdapter *HostAdapter)
1883{
1884 /*
1885 Release shared access to the IRQ Channel.
1886 */
1887 if (HostAdapter->IRQ_ChannelAcquired)
1888 free_irq(HostAdapter->IRQ_Channel, HostAdapter);
1889 /*
1890 Release exclusive access to the DMA Channel.
1891 */
1892 if (HostAdapter->DMA_ChannelAcquired)
1893 free_dma(HostAdapter->DMA_Channel);
1894 /*
1895 Release any allocated memory structs not released elsewhere
1896 */
1897 if (HostAdapter->MailboxSpace)
1898 pci_free_consistent(HostAdapter->PCI_Device, HostAdapter->MailboxSize, HostAdapter->MailboxSpace, HostAdapter->MailboxSpaceHandle);
1899 pci_dev_put(HostAdapter->PCI_Device);
1900 HostAdapter->MailboxSpace = NULL;
1901 HostAdapter->MailboxSpaceHandle = 0;
1902 HostAdapter->MailboxSize = 0;
1903}
1904
1905
1906/*
1907 BusLogic_InitializeHostAdapter initializes Host Adapter. This is the only
1908 function called during SCSI Host Adapter detection which modifies the state
1909 of the Host Adapter from its initial power on or hard reset state.
1910*/
1911
1912static bool BusLogic_InitializeHostAdapter(struct BusLogic_HostAdapter
1913 *HostAdapter)
1914{
1915 struct BusLogic_ExtendedMailboxRequest ExtendedMailboxRequest;
1916 enum BusLogic_RoundRobinModeRequest RoundRobinModeRequest;
1917 enum BusLogic_SetCCBFormatRequest SetCCBFormatRequest;
1918 int TargetID;
1919 /*
1920 Initialize the pointers to the first and last CCBs that are queued for
1921 completion processing.
1922 */
1923 HostAdapter->FirstCompletedCCB = NULL;
1924 HostAdapter->LastCompletedCCB = NULL;
1925 /*
1926 Initialize the Bus Device Reset Pending CCB, Tagged Queuing Active,
1927 Command Successful Flag, Active Commands, and Commands Since Reset
1928 for each Target Device.
1929 */
1930 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++) {
1931 HostAdapter->BusDeviceResetPendingCCB[TargetID] = NULL;
1932 HostAdapter->TargetFlags[TargetID].TaggedQueuingActive = false;
1933 HostAdapter->TargetFlags[TargetID].CommandSuccessfulFlag = false;
1934 HostAdapter->ActiveCommands[TargetID] = 0;
1935 HostAdapter->CommandsSinceReset[TargetID] = 0;
1936 }
1937 /*
1938 FlashPoint Host Adapters do not use Outgoing and Incoming Mailboxes.
1939 */
1940 if (BusLogic_FlashPointHostAdapterP(HostAdapter))
1941 goto Done;
1942 /*
1943 Initialize the Outgoing and Incoming Mailbox pointers.
1944 */
1945 HostAdapter->MailboxSize = HostAdapter->MailboxCount * (sizeof(struct BusLogic_OutgoingMailbox) + sizeof(struct BusLogic_IncomingMailbox));
1946 HostAdapter->MailboxSpace = pci_alloc_consistent(HostAdapter->PCI_Device, HostAdapter->MailboxSize, &HostAdapter->MailboxSpaceHandle);
1947 if (HostAdapter->MailboxSpace == NULL)
1948 return BusLogic_Failure(HostAdapter, "MAILBOX ALLOCATION");
1949 HostAdapter->FirstOutgoingMailbox = (struct BusLogic_OutgoingMailbox *) HostAdapter->MailboxSpace;
1950 HostAdapter->LastOutgoingMailbox = HostAdapter->FirstOutgoingMailbox + HostAdapter->MailboxCount - 1;
1951 HostAdapter->NextOutgoingMailbox = HostAdapter->FirstOutgoingMailbox;
1952 HostAdapter->FirstIncomingMailbox = (struct BusLogic_IncomingMailbox *) (HostAdapter->LastOutgoingMailbox + 1);
1953 HostAdapter->LastIncomingMailbox = HostAdapter->FirstIncomingMailbox + HostAdapter->MailboxCount - 1;
1954 HostAdapter->NextIncomingMailbox = HostAdapter->FirstIncomingMailbox;
1955
1956 /*
1957 Initialize the Outgoing and Incoming Mailbox structures.
1958 */
1959 memset(HostAdapter->FirstOutgoingMailbox, 0, HostAdapter->MailboxCount * sizeof(struct BusLogic_OutgoingMailbox));
1960 memset(HostAdapter->FirstIncomingMailbox, 0, HostAdapter->MailboxCount * sizeof(struct BusLogic_IncomingMailbox));
1961 /*
1962 Initialize the Host Adapter's Pointer to the Outgoing/Incoming Mailboxes.
1963 */
1964 ExtendedMailboxRequest.MailboxCount = HostAdapter->MailboxCount;
1965 ExtendedMailboxRequest.BaseMailboxAddress = (u32) HostAdapter->MailboxSpaceHandle;
1966 if (BusLogic_Command(HostAdapter, BusLogic_InitializeExtendedMailbox, &ExtendedMailboxRequest, sizeof(ExtendedMailboxRequest), NULL, 0) < 0)
1967 return BusLogic_Failure(HostAdapter, "MAILBOX INITIALIZATION");
1968 /*
1969 Enable Strict Round Robin Mode if supported by the Host Adapter. In
1970 Strict Round Robin Mode, the Host Adapter only looks at the next Outgoing
1971 Mailbox for each new command, rather than scanning through all the
1972 Outgoing Mailboxes to find any that have new commands in them. Strict
1973 Round Robin Mode is significantly more efficient.
1974 */
1975 if (HostAdapter->StrictRoundRobinModeSupport) {
1976 RoundRobinModeRequest = BusLogic_StrictRoundRobinMode;
1977 if (BusLogic_Command(HostAdapter, BusLogic_EnableStrictRoundRobinMode, &RoundRobinModeRequest, sizeof(RoundRobinModeRequest), NULL, 0) < 0)
1978 return BusLogic_Failure(HostAdapter, "ENABLE STRICT ROUND ROBIN MODE");
1979 }
1980 /*
1981 For Host Adapters that support Extended LUN Format CCBs, issue the Set CCB
1982 Format command to allow 32 Logical Units per Target Device.
1983 */
1984 if (HostAdapter->ExtendedLUNSupport) {
1985 SetCCBFormatRequest = BusLogic_ExtendedLUNFormatCCB;
1986 if (BusLogic_Command(HostAdapter, BusLogic_SetCCBFormat, &SetCCBFormatRequest, sizeof(SetCCBFormatRequest), NULL, 0) < 0)
1987 return BusLogic_Failure(HostAdapter, "SET CCB FORMAT");
1988 }
1989 /*
1990 Announce Successful Initialization.
1991 */
1992 Done:
1993 if (!HostAdapter->HostAdapterInitialized) {
1994 BusLogic_Info("*** %s Initialized Successfully ***\n", HostAdapter, HostAdapter->FullModelName);
1995 BusLogic_Info("\n", HostAdapter);
1996 } else
1997 BusLogic_Warning("*** %s Initialized Successfully ***\n", HostAdapter, HostAdapter->FullModelName);
1998 HostAdapter->HostAdapterInitialized = true;
1999 /*
2000 Indicate the Host Adapter Initialization completed successfully.
2001 */
2002 return true;
2003}
2004
2005
2006/*
2007 BusLogic_TargetDeviceInquiry inquires about the Target Devices accessible
2008 through Host Adapter.
2009*/
2010
2011static bool __init BusLogic_TargetDeviceInquiry(struct BusLogic_HostAdapter
2012 *HostAdapter)
2013{
2014 u16 InstalledDevices;
2015 u8 InstalledDevicesID0to7[8];
2016 struct BusLogic_SetupInformation SetupInformation;
2017 u8 SynchronousPeriod[BusLogic_MaxTargetDevices];
2018 unsigned char RequestedReplyLength;
2019 int TargetID;
2020 /*
2021 Wait a few seconds between the Host Adapter Hard Reset which initiates
2022 a SCSI Bus Reset and issuing any SCSI Commands. Some SCSI devices get
2023 confused if they receive SCSI Commands too soon after a SCSI Bus Reset.
2024 */
2025 BusLogic_Delay(HostAdapter->BusSettleTime);
2026 /*
2027 FlashPoint Host Adapters do not provide for Target Device Inquiry.
2028 */
2029 if (BusLogic_FlashPointHostAdapterP(HostAdapter))
2030 return true;
2031 /*
2032 Inhibit the Target Device Inquiry if requested.
2033 */
2034 if (HostAdapter->DriverOptions != NULL && HostAdapter->DriverOptions->LocalOptions.InhibitTargetInquiry)
2035 return true;
2036 /*
2037 Issue the Inquire Target Devices command for host adapters with firmware
2038 version 4.25 or later, or the Inquire Installed Devices ID 0 to 7 command
2039 for older host adapters. This is necessary to force Synchronous Transfer
2040 Negotiation so that the Inquire Setup Information and Inquire Synchronous
2041 Period commands will return valid data. The Inquire Target Devices command
2042 is preferable to Inquire Installed Devices ID 0 to 7 since it only probes
2043 Logical Unit 0 of each Target Device.
2044 */
2045 if (strcmp(HostAdapter->FirmwareVersion, "4.25") >= 0) {
2046
2047 /*
2048 * Issue a Inquire Target Devices command. Inquire Target Devices only
2049 * tests Logical Unit 0 of each Target Device unlike the Inquire Installed
2050 * Devices commands which test Logical Units 0 - 7. Two bytes are
2051 * returned, where byte 0 bit 0 set indicates that Target Device 0 exists,
2052 * and so on.
2053 */
2054
2055 if (BusLogic_Command(HostAdapter, BusLogic_InquireTargetDevices, NULL, 0, &InstalledDevices, sizeof(InstalledDevices))
2056 != sizeof(InstalledDevices))
2057 return BusLogic_Failure(HostAdapter, "INQUIRE TARGET DEVICES");
2058 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++)
2059 HostAdapter->TargetFlags[TargetID].TargetExists = (InstalledDevices & (1 << TargetID) ? true : false);
2060 } else {
2061
2062 /*
2063 * Issue an Inquire Installed Devices command. For each Target Device,
2064 * a byte is returned where bit 0 set indicates that Logical Unit 0
2065 * exists, bit 1 set indicates that Logical Unit 1 exists, and so on.
2066 */
2067
2068 if (BusLogic_Command(HostAdapter, BusLogic_InquireInstalledDevicesID0to7, NULL, 0, &InstalledDevicesID0to7, sizeof(InstalledDevicesID0to7))
2069 != sizeof(InstalledDevicesID0to7))
2070 return BusLogic_Failure(HostAdapter, "INQUIRE INSTALLED DEVICES ID 0 TO 7");
2071 for (TargetID = 0; TargetID < 8; TargetID++)
2072 HostAdapter->TargetFlags[TargetID].TargetExists = (InstalledDevicesID0to7[TargetID] != 0 ? true : false);
2073 }
2074 /*
2075 Issue the Inquire Setup Information command.
2076 */
2077 RequestedReplyLength = sizeof(SetupInformation);
2078 if (BusLogic_Command(HostAdapter, BusLogic_InquireSetupInformation, &RequestedReplyLength, sizeof(RequestedReplyLength), &SetupInformation, sizeof(SetupInformation))
2079 != sizeof(SetupInformation))
2080 return BusLogic_Failure(HostAdapter, "INQUIRE SETUP INFORMATION");
2081 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++)
2082 HostAdapter->SynchronousOffset[TargetID] = (TargetID < 8 ? SetupInformation.SynchronousValuesID0to7[TargetID].Offset : SetupInformation.SynchronousValuesID8to15[TargetID - 8].Offset);
2083 if (strcmp(HostAdapter->FirmwareVersion, "5.06L") >= 0)
2084 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++)
2085 HostAdapter->TargetFlags[TargetID].WideTransfersActive = (TargetID < 8 ? (SetupInformation.WideTransfersActiveID0to7 & (1 << TargetID)
2086 ? true : false)
2087 : (SetupInformation.WideTransfersActiveID8to15 & (1 << (TargetID - 8))
2088 ? true : false));
2089 /*
2090 Issue the Inquire Synchronous Period command.
2091 */
2092 if (HostAdapter->FirmwareVersion[0] >= '3') {
2093
2094 /* Issue a Inquire Synchronous Period command. For each Target Device,
2095 * a byte is returned which represents the Synchronous Transfer Period
2096 * in units of 10 nanoseconds.
2097 */
2098
2099 RequestedReplyLength = sizeof(SynchronousPeriod);
2100 if (BusLogic_Command(HostAdapter, BusLogic_InquireSynchronousPeriod, &RequestedReplyLength, sizeof(RequestedReplyLength), &SynchronousPeriod, sizeof(SynchronousPeriod))
2101 != sizeof(SynchronousPeriod))
2102 return BusLogic_Failure(HostAdapter, "INQUIRE SYNCHRONOUS PERIOD");
2103 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++)
2104 HostAdapter->SynchronousPeriod[TargetID] = SynchronousPeriod[TargetID];
2105 } else
2106 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++)
2107 if (SetupInformation.SynchronousValuesID0to7[TargetID].Offset > 0)
2108 HostAdapter->SynchronousPeriod[TargetID] = 20 + 5 * SetupInformation.SynchronousValuesID0to7[TargetID]
2109 .TransferPeriod;
2110 /*
2111 Indicate the Target Device Inquiry completed successfully.
2112 */
2113 return true;
2114}
2115
2116/*
2117 BusLogic_InitializeHostStructure initializes the fields in the SCSI Host
2118 structure. The base, io_port, n_io_ports, irq, and dma_channel fields in the
2119 SCSI Host structure are intentionally left uninitialized, as this driver
2120 handles acquisition and release of these resources explicitly, as well as
2121 ensuring exclusive access to the Host Adapter hardware and data structures
2122 through explicit acquisition and release of the Host Adapter's Lock.
2123*/
2124
2125static void __init BusLogic_InitializeHostStructure(struct BusLogic_HostAdapter
2126 *HostAdapter, struct Scsi_Host *Host)
2127{
2128 Host->max_id = HostAdapter->MaxTargetDevices;
2129 Host->max_lun = HostAdapter->MaxLogicalUnits;
2130 Host->max_channel = 0;
2131 Host->unique_id = HostAdapter->IO_Address;
2132 Host->this_id = HostAdapter->SCSI_ID;
2133 Host->can_queue = HostAdapter->DriverQueueDepth;
2134 Host->sg_tablesize = HostAdapter->DriverScatterGatherLimit;
2135 Host->unchecked_isa_dma = HostAdapter->BounceBuffersRequired;
2136 Host->cmd_per_lun = HostAdapter->UntaggedQueueDepth;
2137}
2138
2139/*
2140 BusLogic_SlaveConfigure will actually set the queue depth on individual
2141 scsi devices as they are permanently added to the device chain. We
2142 shamelessly rip off the SelectQueueDepths code to make this work mostly
2143 like it used to. Since we don't get called once at the end of the scan
2144 but instead get called for each device, we have to do things a bit
2145 differently.
2146*/
2147static int BusLogic_SlaveConfigure(struct scsi_device *Device)
2148{
2149 struct BusLogic_HostAdapter *HostAdapter = (struct BusLogic_HostAdapter *) Device->host->hostdata;
2150 int TargetID = Device->id;
2151 int QueueDepth = HostAdapter->QueueDepth[TargetID];
2152
2153 if (HostAdapter->TargetFlags[TargetID].TaggedQueuingSupported && (HostAdapter->TaggedQueuingPermitted & (1 << TargetID))) {
2154 if (QueueDepth == 0)
2155 QueueDepth = BusLogic_MaxAutomaticTaggedQueueDepth;
2156 HostAdapter->QueueDepth[TargetID] = QueueDepth;
2157 scsi_adjust_queue_depth(Device, MSG_SIMPLE_TAG, QueueDepth);
2158 } else {
2159 HostAdapter->TaggedQueuingPermitted &= ~(1 << TargetID);
2160 QueueDepth = HostAdapter->UntaggedQueueDepth;
2161 HostAdapter->QueueDepth[TargetID] = QueueDepth;
2162 scsi_adjust_queue_depth(Device, 0, QueueDepth);
2163 }
2164 QueueDepth = 0;
2165 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++)
2166 if (HostAdapter->TargetFlags[TargetID].TargetExists) {
2167 QueueDepth += HostAdapter->QueueDepth[TargetID];
2168 }
2169 if (QueueDepth > HostAdapter->AllocatedCCBs)
2170 BusLogic_CreateAdditionalCCBs(HostAdapter, QueueDepth - HostAdapter->AllocatedCCBs, false);
2171 return 0;
2172}
2173
2174/*
2175 BusLogic_DetectHostAdapter probes for BusLogic Host Adapters at the standard
2176 I/O Addresses where they may be located, initializing, registering, and
2177 reporting the configuration of each BusLogic Host Adapter it finds. It
2178 returns the number of BusLogic Host Adapters successfully initialized and
2179 registered.
2180*/
2181
2182static int __init BusLogic_init(void)
2183{
2184 int BusLogicHostAdapterCount = 0, DriverOptionsIndex = 0, ProbeIndex;
2185 struct BusLogic_HostAdapter *PrototypeHostAdapter;
2186 int ret = 0;
2187
2188#ifdef MODULE
2189 if (BusLogic)
2190 BusLogic_Setup(BusLogic);
2191#endif
2192
2193 if (BusLogic_ProbeOptions.NoProbe)
2194 return -ENODEV;
2195 BusLogic_ProbeInfoList =
2196 kzalloc(BusLogic_MaxHostAdapters * sizeof(struct BusLogic_ProbeInfo), GFP_KERNEL);
2197 if (BusLogic_ProbeInfoList == NULL) {
2198 BusLogic_Error("BusLogic: Unable to allocate Probe Info List\n", NULL);
2199 return -ENOMEM;
2200 }
2201
2202 PrototypeHostAdapter =
2203 kzalloc(sizeof(struct BusLogic_HostAdapter), GFP_KERNEL);
2204 if (PrototypeHostAdapter == NULL) {
2205 kfree(BusLogic_ProbeInfoList);
2206 BusLogic_Error("BusLogic: Unable to allocate Prototype " "Host Adapter\n", NULL);
2207 return -ENOMEM;
2208 }
2209
2210#ifdef MODULE
2211 if (BusLogic != NULL)
2212 BusLogic_Setup(BusLogic);
2213#endif
2214 BusLogic_InitializeProbeInfoList(PrototypeHostAdapter);
2215 for (ProbeIndex = 0; ProbeIndex < BusLogic_ProbeInfoCount; ProbeIndex++) {
2216 struct BusLogic_ProbeInfo *ProbeInfo = &BusLogic_ProbeInfoList[ProbeIndex];
2217 struct BusLogic_HostAdapter *HostAdapter = PrototypeHostAdapter;
2218 struct Scsi_Host *Host;
2219 if (ProbeInfo->IO_Address == 0)
2220 continue;
2221 memset(HostAdapter, 0, sizeof(struct BusLogic_HostAdapter));
2222 HostAdapter->HostAdapterType = ProbeInfo->HostAdapterType;
2223 HostAdapter->HostAdapterBusType = ProbeInfo->HostAdapterBusType;
2224 HostAdapter->IO_Address = ProbeInfo->IO_Address;
2225 HostAdapter->PCI_Address = ProbeInfo->PCI_Address;
2226 HostAdapter->Bus = ProbeInfo->Bus;
2227 HostAdapter->Device = ProbeInfo->Device;
2228 HostAdapter->PCI_Device = ProbeInfo->PCI_Device;
2229 HostAdapter->IRQ_Channel = ProbeInfo->IRQ_Channel;
2230 HostAdapter->AddressCount = BusLogic_HostAdapterAddressCount[HostAdapter->HostAdapterType];
2231
2232 /*
2233 Make sure region is free prior to probing.
2234 */
2235 if (!request_region(HostAdapter->IO_Address, HostAdapter->AddressCount,
2236 "BusLogic"))
2237 continue;
2238 /*
2239 Probe the Host Adapter. If unsuccessful, abort further initialization.
2240 */
2241 if (!BusLogic_ProbeHostAdapter(HostAdapter)) {
2242 release_region(HostAdapter->IO_Address, HostAdapter->AddressCount);
2243 continue;
2244 }
2245 /*
2246 Hard Reset the Host Adapter. If unsuccessful, abort further
2247 initialization.
2248 */
2249 if (!BusLogic_HardwareResetHostAdapter(HostAdapter, true)) {
2250 release_region(HostAdapter->IO_Address, HostAdapter->AddressCount);
2251 continue;
2252 }
2253 /*
2254 Check the Host Adapter. If unsuccessful, abort further initialization.
2255 */
2256 if (!BusLogic_CheckHostAdapter(HostAdapter)) {
2257 release_region(HostAdapter->IO_Address, HostAdapter->AddressCount);
2258 continue;
2259 }
2260 /*
2261 Initialize the Driver Options field if provided.
2262 */
2263 if (DriverOptionsIndex < BusLogic_DriverOptionsCount)
2264 HostAdapter->DriverOptions = &BusLogic_DriverOptions[DriverOptionsIndex++];
2265 /*
2266 Announce the Driver Version and Date, Author's Name, Copyright Notice,
2267 and Electronic Mail Address.
2268 */
2269 BusLogic_AnnounceDriver(HostAdapter);
2270 /*
2271 Register the SCSI Host structure.
2272 */
2273
2274 Host = scsi_host_alloc(&Bus_Logic_template, sizeof(struct BusLogic_HostAdapter));
2275 if (Host == NULL) {
2276 release_region(HostAdapter->IO_Address, HostAdapter->AddressCount);
2277 continue;
2278 }
2279 HostAdapter = (struct BusLogic_HostAdapter *) Host->hostdata;
2280 memcpy(HostAdapter, PrototypeHostAdapter, sizeof(struct BusLogic_HostAdapter));
2281 HostAdapter->SCSI_Host = Host;
2282 HostAdapter->HostNumber = Host->host_no;
2283 /*
2284 Add Host Adapter to the end of the list of registered BusLogic
2285 Host Adapters.
2286 */
2287 list_add_tail(&HostAdapter->host_list, &BusLogic_host_list);
2288
2289 /*
2290 Read the Host Adapter Configuration, Configure the Host Adapter,
2291 Acquire the System Resources necessary to use the Host Adapter, then
2292 Create the Initial CCBs, Initialize the Host Adapter, and finally
2293 perform Target Device Inquiry.
2294
2295 From this point onward, any failure will be assumed to be due to a
2296 problem with the Host Adapter, rather than due to having mistakenly
2297 identified this port as belonging to a BusLogic Host Adapter. The
2298 I/O Address range will not be released, thereby preventing it from
2299 being incorrectly identified as any other type of Host Adapter.
2300 */
2301 if (BusLogic_ReadHostAdapterConfiguration(HostAdapter) &&
2302 BusLogic_ReportHostAdapterConfiguration(HostAdapter) &&
2303 BusLogic_AcquireResources(HostAdapter) &&
2304 BusLogic_CreateInitialCCBs(HostAdapter) &&
2305 BusLogic_InitializeHostAdapter(HostAdapter) &&
2306 BusLogic_TargetDeviceInquiry(HostAdapter)) {
2307 /*
2308 Initialization has been completed successfully. Release and
2309 re-register usage of the I/O Address range so that the Model
2310 Name of the Host Adapter will appear, and initialize the SCSI
2311 Host structure.
2312 */
2313 release_region(HostAdapter->IO_Address,
2314 HostAdapter->AddressCount);
2315 if (!request_region(HostAdapter->IO_Address,
2316 HostAdapter->AddressCount,
2317 HostAdapter->FullModelName)) {
2318 printk(KERN_WARNING
2319 "BusLogic: Release and re-register of "
2320 "port 0x%04lx failed \n",
2321 (unsigned long)HostAdapter->IO_Address);
2322 BusLogic_DestroyCCBs(HostAdapter);
2323 BusLogic_ReleaseResources(HostAdapter);
2324 list_del(&HostAdapter->host_list);
2325 scsi_host_put(Host);
2326 ret = -ENOMEM;
2327 } else {
2328 BusLogic_InitializeHostStructure(HostAdapter,
2329 Host);
2330 if (scsi_add_host(Host, HostAdapter->PCI_Device
2331 ? &HostAdapter->PCI_Device->dev
2332 : NULL)) {
2333 printk(KERN_WARNING
2334 "BusLogic: scsi_add_host()"
2335 "failed!\n");
2336 BusLogic_DestroyCCBs(HostAdapter);
2337 BusLogic_ReleaseResources(HostAdapter);
2338 list_del(&HostAdapter->host_list);
2339 scsi_host_put(Host);
2340 ret = -ENODEV;
2341 } else {
2342 scsi_scan_host(Host);
2343 BusLogicHostAdapterCount++;
2344 }
2345 }
2346 } else {
2347 /*
2348 An error occurred during Host Adapter Configuration Querying, Host
2349 Adapter Configuration, Resource Acquisition, CCB Creation, Host
2350 Adapter Initialization, or Target Device Inquiry, so remove Host
2351 Adapter from the list of registered BusLogic Host Adapters, destroy
2352 the CCBs, Release the System Resources, and Unregister the SCSI
2353 Host.
2354 */
2355 BusLogic_DestroyCCBs(HostAdapter);
2356 BusLogic_ReleaseResources(HostAdapter);
2357 list_del(&HostAdapter->host_list);
2358 scsi_host_put(Host);
2359 ret = -ENODEV;
2360 }
2361 }
2362 kfree(PrototypeHostAdapter);
2363 kfree(BusLogic_ProbeInfoList);
2364 BusLogic_ProbeInfoList = NULL;
2365 return ret;
2366}
2367
2368
2369/*
2370 BusLogic_ReleaseHostAdapter releases all resources previously acquired to
2371 support a specific Host Adapter, including the I/O Address range, and
2372 unregisters the BusLogic Host Adapter.
2373*/
2374
2375static int __exit BusLogic_ReleaseHostAdapter(struct BusLogic_HostAdapter *HostAdapter)
2376{
2377 struct Scsi_Host *Host = HostAdapter->SCSI_Host;
2378
2379 scsi_remove_host(Host);
2380
2381 /*
2382 FlashPoint Host Adapters must first be released by the FlashPoint
2383 SCCB Manager.
2384 */
2385 if (BusLogic_FlashPointHostAdapterP(HostAdapter))
2386 FlashPoint_ReleaseHostAdapter(HostAdapter->CardHandle);
2387 /*
2388 Destroy the CCBs and release any system resources acquired to
2389 support Host Adapter.
2390 */
2391 BusLogic_DestroyCCBs(HostAdapter);
2392 BusLogic_ReleaseResources(HostAdapter);
2393 /*
2394 Release usage of the I/O Address range.
2395 */
2396 release_region(HostAdapter->IO_Address, HostAdapter->AddressCount);
2397 /*
2398 Remove Host Adapter from the list of registered BusLogic Host Adapters.
2399 */
2400 list_del(&HostAdapter->host_list);
2401
2402 scsi_host_put(Host);
2403 return 0;
2404}
2405
2406
2407/*
2408 BusLogic_QueueCompletedCCB queues CCB for completion processing.
2409*/
2410
2411static void BusLogic_QueueCompletedCCB(struct BusLogic_CCB *CCB)
2412{
2413 struct BusLogic_HostAdapter *HostAdapter = CCB->HostAdapter;
2414 CCB->Status = BusLogic_CCB_Completed;
2415 CCB->Next = NULL;
2416 if (HostAdapter->FirstCompletedCCB == NULL) {
2417 HostAdapter->FirstCompletedCCB = CCB;
2418 HostAdapter->LastCompletedCCB = CCB;
2419 } else {
2420 HostAdapter->LastCompletedCCB->Next = CCB;
2421 HostAdapter->LastCompletedCCB = CCB;
2422 }
2423 HostAdapter->ActiveCommands[CCB->TargetID]--;
2424}
2425
2426
2427/*
2428 BusLogic_ComputeResultCode computes a SCSI Subsystem Result Code from
2429 the Host Adapter Status and Target Device Status.
2430*/
2431
2432static int BusLogic_ComputeResultCode(struct BusLogic_HostAdapter *HostAdapter, enum BusLogic_HostAdapterStatus HostAdapterStatus, enum BusLogic_TargetDeviceStatus TargetDeviceStatus)
2433{
2434 int HostStatus;
2435 switch (HostAdapterStatus) {
2436 case BusLogic_CommandCompletedNormally:
2437 case BusLogic_LinkedCommandCompleted:
2438 case BusLogic_LinkedCommandCompletedWithFlag:
2439 HostStatus = DID_OK;
2440 break;
2441 case BusLogic_SCSISelectionTimeout:
2442 HostStatus = DID_TIME_OUT;
2443 break;
2444 case BusLogic_InvalidOutgoingMailboxActionCode:
2445 case BusLogic_InvalidCommandOperationCode:
2446 case BusLogic_InvalidCommandParameter:
2447 BusLogic_Warning("BusLogic Driver Protocol Error 0x%02X\n", HostAdapter, HostAdapterStatus);
2448 case BusLogic_DataUnderRun:
2449 case BusLogic_DataOverRun:
2450 case BusLogic_UnexpectedBusFree:
2451 case BusLogic_LinkedCCBhasInvalidLUN:
2452 case BusLogic_AutoRequestSenseFailed:
2453 case BusLogic_TaggedQueuingMessageRejected:
2454 case BusLogic_UnsupportedMessageReceived:
2455 case BusLogic_HostAdapterHardwareFailed:
2456 case BusLogic_TargetDeviceReconnectedImproperly:
2457 case BusLogic_AbortQueueGenerated:
2458 case BusLogic_HostAdapterSoftwareError:
2459 case BusLogic_HostAdapterHardwareTimeoutError:
2460 case BusLogic_SCSIParityErrorDetected:
2461 HostStatus = DID_ERROR;
2462 break;
2463 case BusLogic_InvalidBusPhaseRequested:
2464 case BusLogic_TargetFailedResponseToATN:
2465 case BusLogic_HostAdapterAssertedRST:
2466 case BusLogic_OtherDeviceAssertedRST:
2467 case BusLogic_HostAdapterAssertedBusDeviceReset:
2468 HostStatus = DID_RESET;
2469 break;
2470 default:
2471 BusLogic_Warning("Unknown Host Adapter Status 0x%02X\n", HostAdapter, HostAdapterStatus);
2472 HostStatus = DID_ERROR;
2473 break;
2474 }
2475 return (HostStatus << 16) | TargetDeviceStatus;
2476}
2477
2478
2479/*
2480 BusLogic_ScanIncomingMailboxes scans the Incoming Mailboxes saving any
2481 Incoming Mailbox entries for completion processing.
2482*/
2483
2484static void BusLogic_ScanIncomingMailboxes(struct BusLogic_HostAdapter *HostAdapter)
2485{
2486 /*
2487 Scan through the Incoming Mailboxes in Strict Round Robin fashion, saving
2488 any completed CCBs for further processing. It is essential that for each
2489 CCB and SCSI Command issued, command completion processing is performed
2490 exactly once. Therefore, only Incoming Mailboxes with completion code
2491 Command Completed Without Error, Command Completed With Error, or Command
2492 Aborted At Host Request are saved for completion processing. When an
2493 Incoming Mailbox has a completion code of Aborted Command Not Found, the
2494 CCB had already completed or been aborted before the current Abort request
2495 was processed, and so completion processing has already occurred and no
2496 further action should be taken.
2497 */
2498 struct BusLogic_IncomingMailbox *NextIncomingMailbox = HostAdapter->NextIncomingMailbox;
2499 enum BusLogic_CompletionCode CompletionCode;
2500 while ((CompletionCode = NextIncomingMailbox->CompletionCode) != BusLogic_IncomingMailboxFree) {
2501 /*
2502 We are only allowed to do this because we limit our architectures we
2503 run on to machines where bus_to_virt() actually works. There *needs*
2504 to be a dma_addr_to_virt() in the new PCI DMA mapping interface to
2505 replace bus_to_virt() or else this code is going to become very
2506 innefficient.
2507 */
2508 struct BusLogic_CCB *CCB = (struct BusLogic_CCB *) Bus_to_Virtual(NextIncomingMailbox->CCB);
2509 if (CompletionCode != BusLogic_AbortedCommandNotFound) {
2510 if (CCB->Status == BusLogic_CCB_Active || CCB->Status == BusLogic_CCB_Reset) {
2511 /*
2512 Save the Completion Code for this CCB and queue the CCB
2513 for completion processing.
2514 */
2515 CCB->CompletionCode = CompletionCode;
2516 BusLogic_QueueCompletedCCB(CCB);
2517 } else {
2518 /*
2519 If a CCB ever appears in an Incoming Mailbox and is not marked
2520 as status Active or Reset, then there is most likely a bug in
2521 the Host Adapter firmware.
2522 */
2523 BusLogic_Warning("Illegal CCB #%ld status %d in " "Incoming Mailbox\n", HostAdapter, CCB->SerialNumber, CCB->Status);
2524 }
2525 }
2526 NextIncomingMailbox->CompletionCode = BusLogic_IncomingMailboxFree;
2527 if (++NextIncomingMailbox > HostAdapter->LastIncomingMailbox)
2528 NextIncomingMailbox = HostAdapter->FirstIncomingMailbox;
2529 }
2530 HostAdapter->NextIncomingMailbox = NextIncomingMailbox;
2531}
2532
2533
2534/*
2535 BusLogic_ProcessCompletedCCBs iterates over the completed CCBs for Host
2536 Adapter setting the SCSI Command Result Codes, deallocating the CCBs, and
2537 calling the SCSI Subsystem Completion Routines. The Host Adapter's Lock
2538 should already have been acquired by the caller.
2539*/
2540
2541static void BusLogic_ProcessCompletedCCBs(struct BusLogic_HostAdapter *HostAdapter)
2542{
2543 if (HostAdapter->ProcessCompletedCCBsActive)
2544 return;
2545 HostAdapter->ProcessCompletedCCBsActive = true;
2546 while (HostAdapter->FirstCompletedCCB != NULL) {
2547 struct BusLogic_CCB *CCB = HostAdapter->FirstCompletedCCB;
2548 struct scsi_cmnd *Command = CCB->Command;
2549 HostAdapter->FirstCompletedCCB = CCB->Next;
2550 if (HostAdapter->FirstCompletedCCB == NULL)
2551 HostAdapter->LastCompletedCCB = NULL;
2552 /*
2553 Process the Completed CCB.
2554 */
2555 if (CCB->Opcode == BusLogic_BusDeviceReset) {
2556 int TargetID = CCB->TargetID;
2557 BusLogic_Warning("Bus Device Reset CCB #%ld to Target " "%d Completed\n", HostAdapter, CCB->SerialNumber, TargetID);
2558 BusLogic_IncrementErrorCounter(&HostAdapter->TargetStatistics[TargetID].BusDeviceResetsCompleted);
2559 HostAdapter->TargetFlags[TargetID].TaggedQueuingActive = false;
2560 HostAdapter->CommandsSinceReset[TargetID] = 0;
2561 HostAdapter->LastResetCompleted[TargetID] = jiffies;
2562 /*
2563 Place CCB back on the Host Adapter's free list.
2564 */
2565 BusLogic_DeallocateCCB(CCB);
2566#if 0 /* this needs to be redone different for new EH */
2567 /*
2568 Bus Device Reset CCBs have the Command field non-NULL only when a
2569 Bus Device Reset was requested for a Command that did not have a
2570 currently active CCB in the Host Adapter (i.e., a Synchronous
2571 Bus Device Reset), and hence would not have its Completion Routine
2572 called otherwise.
2573 */
2574 while (Command != NULL) {
2575 struct scsi_cmnd *NextCommand = Command->reset_chain;
2576 Command->reset_chain = NULL;
2577 Command->result = DID_RESET << 16;
2578 Command->scsi_done(Command);
2579 Command = NextCommand;
2580 }
2581#endif
2582 /*
2583 Iterate over the CCBs for this Host Adapter performing completion
2584 processing for any CCBs marked as Reset for this Target.
2585 */
2586 for (CCB = HostAdapter->All_CCBs; CCB != NULL; CCB = CCB->NextAll)
2587 if (CCB->Status == BusLogic_CCB_Reset && CCB->TargetID == TargetID) {
2588 Command = CCB->Command;
2589 BusLogic_DeallocateCCB(CCB);
2590 HostAdapter->ActiveCommands[TargetID]--;
2591 Command->result = DID_RESET << 16;
2592 Command->scsi_done(Command);
2593 }
2594 HostAdapter->BusDeviceResetPendingCCB[TargetID] = NULL;
2595 } else {
2596 /*
2597 Translate the Completion Code, Host Adapter Status, and Target
2598 Device Status into a SCSI Subsystem Result Code.
2599 */
2600 switch (CCB->CompletionCode) {
2601 case BusLogic_IncomingMailboxFree:
2602 case BusLogic_AbortedCommandNotFound:
2603 case BusLogic_InvalidCCB:
2604 BusLogic_Warning("CCB #%ld to Target %d Impossible State\n", HostAdapter, CCB->SerialNumber, CCB->TargetID);
2605 break;
2606 case BusLogic_CommandCompletedWithoutError:
2607 HostAdapter->TargetStatistics[CCB->TargetID]
2608 .CommandsCompleted++;
2609 HostAdapter->TargetFlags[CCB->TargetID]
2610 .CommandSuccessfulFlag = true;
2611 Command->result = DID_OK << 16;
2612 break;
2613 case BusLogic_CommandAbortedAtHostRequest:
2614 BusLogic_Warning("CCB #%ld to Target %d Aborted\n", HostAdapter, CCB->SerialNumber, CCB->TargetID);
2615 BusLogic_IncrementErrorCounter(&HostAdapter->TargetStatistics[CCB->TargetID]
2616 .CommandAbortsCompleted);
2617 Command->result = DID_ABORT << 16;
2618 break;
2619 case BusLogic_CommandCompletedWithError:
2620 Command->result = BusLogic_ComputeResultCode(HostAdapter, CCB->HostAdapterStatus, CCB->TargetDeviceStatus);
2621 if (CCB->HostAdapterStatus != BusLogic_SCSISelectionTimeout) {
2622 HostAdapter->TargetStatistics[CCB->TargetID]
2623 .CommandsCompleted++;
2624 if (BusLogic_GlobalOptions.TraceErrors) {
2625 int i;
2626 BusLogic_Notice("CCB #%ld Target %d: Result %X Host "
2627 "Adapter Status %02X " "Target Status %02X\n", HostAdapter, CCB->SerialNumber, CCB->TargetID, Command->result, CCB->HostAdapterStatus, CCB->TargetDeviceStatus);
2628 BusLogic_Notice("CDB ", HostAdapter);
2629 for (i = 0; i < CCB->CDB_Length; i++)
2630 BusLogic_Notice(" %02X", HostAdapter, CCB->CDB[i]);
2631 BusLogic_Notice("\n", HostAdapter);
2632 BusLogic_Notice("Sense ", HostAdapter);
2633 for (i = 0; i < CCB->SenseDataLength; i++)
2634 BusLogic_Notice(" %02X", HostAdapter, Command->sense_buffer[i]);
2635 BusLogic_Notice("\n", HostAdapter);
2636 }
2637 }
2638 break;
2639 }
2640 /*
2641 When an INQUIRY command completes normally, save the
2642 CmdQue (Tagged Queuing Supported) and WBus16 (16 Bit
2643 Wide Data Transfers Supported) bits.
2644 */
2645 if (CCB->CDB[0] == INQUIRY && CCB->CDB[1] == 0 && CCB->HostAdapterStatus == BusLogic_CommandCompletedNormally) {
2646 struct BusLogic_TargetFlags *TargetFlags = &HostAdapter->TargetFlags[CCB->TargetID];
2647 struct SCSI_Inquiry *InquiryResult =
2648 (struct SCSI_Inquiry *) scsi_sglist(Command);
2649 TargetFlags->TargetExists = true;
2650 TargetFlags->TaggedQueuingSupported = InquiryResult->CmdQue;
2651 TargetFlags->WideTransfersSupported = InquiryResult->WBus16;
2652 }
2653 /*
2654 Place CCB back on the Host Adapter's free list.
2655 */
2656 BusLogic_DeallocateCCB(CCB);
2657 /*
2658 Call the SCSI Command Completion Routine.
2659 */
2660 Command->scsi_done(Command);
2661 }
2662 }
2663 HostAdapter->ProcessCompletedCCBsActive = false;
2664}
2665
2666
2667/*
2668 BusLogic_InterruptHandler handles hardware interrupts from BusLogic Host
2669 Adapters.
2670*/
2671
2672static irqreturn_t BusLogic_InterruptHandler(int IRQ_Channel, void *DeviceIdentifier)
2673{
2674 struct BusLogic_HostAdapter *HostAdapter = (struct BusLogic_HostAdapter *) DeviceIdentifier;
2675 unsigned long ProcessorFlags;
2676 /*
2677 Acquire exclusive access to Host Adapter.
2678 */
2679 spin_lock_irqsave(HostAdapter->SCSI_Host->host_lock, ProcessorFlags);
2680 /*
2681 Handle Interrupts appropriately for each Host Adapter type.
2682 */
2683 if (BusLogic_MultiMasterHostAdapterP(HostAdapter)) {
2684 union BusLogic_InterruptRegister InterruptRegister;
2685 /*
2686 Read the Host Adapter Interrupt Register.
2687 */
2688 InterruptRegister.All = BusLogic_ReadInterruptRegister(HostAdapter);
2689 if (InterruptRegister.ir.InterruptValid) {
2690 /*
2691 Acknowledge the interrupt and reset the Host Adapter
2692 Interrupt Register.
2693 */
2694 BusLogic_InterruptReset(HostAdapter);
2695 /*
2696 Process valid External SCSI Bus Reset and Incoming Mailbox
2697 Loaded Interrupts. Command Complete Interrupts are noted,
2698 and Outgoing Mailbox Available Interrupts are ignored, as
2699 they are never enabled.
2700 */
2701 if (InterruptRegister.ir.ExternalBusReset)
2702 HostAdapter->HostAdapterExternalReset = true;
2703 else if (InterruptRegister.ir.IncomingMailboxLoaded)
2704 BusLogic_ScanIncomingMailboxes(HostAdapter);
2705 else if (InterruptRegister.ir.CommandComplete)
2706 HostAdapter->HostAdapterCommandCompleted = true;
2707 }
2708 } else {
2709 /*
2710 Check if there is a pending interrupt for this Host Adapter.
2711 */
2712 if (FlashPoint_InterruptPending(HostAdapter->CardHandle))
2713 switch (FlashPoint_HandleInterrupt(HostAdapter->CardHandle)) {
2714 case FlashPoint_NormalInterrupt:
2715 break;
2716 case FlashPoint_ExternalBusReset:
2717 HostAdapter->HostAdapterExternalReset = true;
2718 break;
2719 case FlashPoint_InternalError:
2720 BusLogic_Warning("Internal FlashPoint Error detected" " - Resetting Host Adapter\n", HostAdapter);
2721 HostAdapter->HostAdapterInternalError = true;
2722 break;
2723 }
2724 }
2725 /*
2726 Process any completed CCBs.
2727 */
2728 if (HostAdapter->FirstCompletedCCB != NULL)
2729 BusLogic_ProcessCompletedCCBs(HostAdapter);
2730 /*
2731 Reset the Host Adapter if requested.
2732 */
2733 if (HostAdapter->HostAdapterExternalReset) {
2734 BusLogic_Warning("Resetting %s due to External SCSI Bus Reset\n", HostAdapter, HostAdapter->FullModelName);
2735 BusLogic_IncrementErrorCounter(&HostAdapter->ExternalHostAdapterResets);
2736 BusLogic_ResetHostAdapter(HostAdapter, false);
2737 HostAdapter->HostAdapterExternalReset = false;
2738 } else if (HostAdapter->HostAdapterInternalError) {
2739 BusLogic_Warning("Resetting %s due to Host Adapter Internal Error\n", HostAdapter, HostAdapter->FullModelName);
2740 BusLogic_IncrementErrorCounter(&HostAdapter->HostAdapterInternalErrors);
2741 BusLogic_ResetHostAdapter(HostAdapter, true);
2742 HostAdapter->HostAdapterInternalError = false;
2743 }
2744 /*
2745 Release exclusive access to Host Adapter.
2746 */
2747 spin_unlock_irqrestore(HostAdapter->SCSI_Host->host_lock, ProcessorFlags);
2748 return IRQ_HANDLED;
2749}
2750
2751
2752/*
2753 BusLogic_WriteOutgoingMailbox places CCB and Action Code into an Outgoing
2754 Mailbox for execution by Host Adapter. The Host Adapter's Lock should
2755 already have been acquired by the caller.
2756*/
2757
2758static bool BusLogic_WriteOutgoingMailbox(struct BusLogic_HostAdapter
2759 *HostAdapter, enum BusLogic_ActionCode ActionCode, struct BusLogic_CCB *CCB)
2760{
2761 struct BusLogic_OutgoingMailbox *NextOutgoingMailbox;
2762 NextOutgoingMailbox = HostAdapter->NextOutgoingMailbox;
2763 if (NextOutgoingMailbox->ActionCode == BusLogic_OutgoingMailboxFree) {
2764 CCB->Status = BusLogic_CCB_Active;
2765 /*
2766 The CCB field must be written before the Action Code field since
2767 the Host Adapter is operating asynchronously and the locking code
2768 does not protect against simultaneous access by the Host Adapter.
2769 */
2770 NextOutgoingMailbox->CCB = CCB->DMA_Handle;
2771 NextOutgoingMailbox->ActionCode = ActionCode;
2772 BusLogic_StartMailboxCommand(HostAdapter);
2773 if (++NextOutgoingMailbox > HostAdapter->LastOutgoingMailbox)
2774 NextOutgoingMailbox = HostAdapter->FirstOutgoingMailbox;
2775 HostAdapter->NextOutgoingMailbox = NextOutgoingMailbox;
2776 if (ActionCode == BusLogic_MailboxStartCommand) {
2777 HostAdapter->ActiveCommands[CCB->TargetID]++;
2778 if (CCB->Opcode != BusLogic_BusDeviceReset)
2779 HostAdapter->TargetStatistics[CCB->TargetID].CommandsAttempted++;
2780 }
2781 return true;
2782 }
2783 return false;
2784}
2785
2786/* Error Handling (EH) support */
2787
2788static int BusLogic_host_reset(struct scsi_cmnd * SCpnt)
2789{
2790 struct BusLogic_HostAdapter *HostAdapter = (struct BusLogic_HostAdapter *) SCpnt->device->host->hostdata;
2791
2792 unsigned int id = SCpnt->device->id;
2793 struct BusLogic_TargetStatistics *stats = &HostAdapter->TargetStatistics[id];
2794 int rc;
2795
2796 spin_lock_irq(SCpnt->device->host->host_lock);
2797
2798 BusLogic_IncrementErrorCounter(&stats->HostAdapterResetsRequested);
2799
2800 rc = BusLogic_ResetHostAdapter(HostAdapter, false);
2801 spin_unlock_irq(SCpnt->device->host->host_lock);
2802 return rc;
2803}
2804
2805/*
2806 BusLogic_QueueCommand creates a CCB for Command and places it into an
2807 Outgoing Mailbox for execution by the associated Host Adapter.
2808*/
2809
2810static int BusLogic_QueueCommand_lck(struct scsi_cmnd *Command, void (*CompletionRoutine) (struct scsi_cmnd *))
2811{
2812 struct BusLogic_HostAdapter *HostAdapter = (struct BusLogic_HostAdapter *) Command->device->host->hostdata;
2813 struct BusLogic_TargetFlags *TargetFlags = &HostAdapter->TargetFlags[Command->device->id];
2814 struct BusLogic_TargetStatistics *TargetStatistics = HostAdapter->TargetStatistics;
2815 unsigned char *CDB = Command->cmnd;
2816 int CDB_Length = Command->cmd_len;
2817 int TargetID = Command->device->id;
2818 int LogicalUnit = Command->device->lun;
2819 int BufferLength = scsi_bufflen(Command);
2820 int Count;
2821 struct BusLogic_CCB *CCB;
2822 /*
2823 SCSI REQUEST_SENSE commands will be executed automatically by the Host
2824 Adapter for any errors, so they should not be executed explicitly unless
2825 the Sense Data is zero indicating that no error occurred.
2826 */
2827 if (CDB[0] == REQUEST_SENSE && Command->sense_buffer[0] != 0) {
2828 Command->result = DID_OK << 16;
2829 CompletionRoutine(Command);
2830 return 0;
2831 }
2832 /*
2833 Allocate a CCB from the Host Adapter's free list. In the unlikely event
2834 that there are none available and memory allocation fails, wait 1 second
2835 and try again. If that fails, the Host Adapter is probably hung so signal
2836 an error as a Host Adapter Hard Reset should be initiated soon.
2837 */
2838 CCB = BusLogic_AllocateCCB(HostAdapter);
2839 if (CCB == NULL) {
2840 spin_unlock_irq(HostAdapter->SCSI_Host->host_lock);
2841 BusLogic_Delay(1);
2842 spin_lock_irq(HostAdapter->SCSI_Host->host_lock);
2843 CCB = BusLogic_AllocateCCB(HostAdapter);
2844 if (CCB == NULL) {
2845 Command->result = DID_ERROR << 16;
2846 CompletionRoutine(Command);
2847 return 0;
2848 }
2849 }
2850
2851 /*
2852 Initialize the fields in the BusLogic Command Control Block (CCB).
2853 */
2854 Count = scsi_dma_map(Command);
2855 BUG_ON(Count < 0);
2856 if (Count) {
2857 struct scatterlist *sg;
2858 int i;
2859
2860 CCB->Opcode = BusLogic_InitiatorCCB_ScatterGather;
2861 CCB->DataLength = Count * sizeof(struct BusLogic_ScatterGatherSegment);
2862 if (BusLogic_MultiMasterHostAdapterP(HostAdapter))
2863 CCB->DataPointer = (unsigned int) CCB->DMA_Handle + ((unsigned long) &CCB->ScatterGatherList - (unsigned long) CCB);
2864 else
2865 CCB->DataPointer = Virtual_to_32Bit_Virtual(CCB->ScatterGatherList);
2866
2867 scsi_for_each_sg(Command, sg, Count, i) {
2868 CCB->ScatterGatherList[i].SegmentByteCount =
2869 sg_dma_len(sg);
2870 CCB->ScatterGatherList[i].SegmentDataPointer =
2871 sg_dma_address(sg);
2872 }
2873 } else if (!Count) {
2874 CCB->Opcode = BusLogic_InitiatorCCB;
2875 CCB->DataLength = BufferLength;
2876 CCB->DataPointer = 0;
2877 }
2878
2879 switch (CDB[0]) {
2880 case READ_6:
2881 case READ_10:
2882 CCB->DataDirection = BusLogic_DataInLengthChecked;
2883 TargetStatistics[TargetID].ReadCommands++;
2884 BusLogic_IncrementByteCounter(&TargetStatistics[TargetID].TotalBytesRead, BufferLength);
2885 BusLogic_IncrementSizeBucket(TargetStatistics[TargetID].ReadCommandSizeBuckets, BufferLength);
2886 break;
2887 case WRITE_6:
2888 case WRITE_10:
2889 CCB->DataDirection = BusLogic_DataOutLengthChecked;
2890 TargetStatistics[TargetID].WriteCommands++;
2891 BusLogic_IncrementByteCounter(&TargetStatistics[TargetID].TotalBytesWritten, BufferLength);
2892 BusLogic_IncrementSizeBucket(TargetStatistics[TargetID].WriteCommandSizeBuckets, BufferLength);
2893 break;
2894 default:
2895 CCB->DataDirection = BusLogic_UncheckedDataTransfer;
2896 break;
2897 }
2898 CCB->CDB_Length = CDB_Length;
2899 CCB->HostAdapterStatus = 0;
2900 CCB->TargetDeviceStatus = 0;
2901 CCB->TargetID = TargetID;
2902 CCB->LogicalUnit = LogicalUnit;
2903 CCB->TagEnable = false;
2904 CCB->LegacyTagEnable = false;
2905 /*
2906 BusLogic recommends that after a Reset the first couple of commands that
2907 are sent to a Target Device be sent in a non Tagged Queue fashion so that
2908 the Host Adapter and Target Device can establish Synchronous and Wide
2909 Transfer before Queue Tag messages can interfere with the Synchronous and
2910 Wide Negotiation messages. By waiting to enable Tagged Queuing until after
2911 the first BusLogic_MaxTaggedQueueDepth commands have been queued, it is
2912 assured that after a Reset any pending commands are requeued before Tagged
2913 Queuing is enabled and that the Tagged Queuing message will not occur while
2914 the partition table is being printed. In addition, some devices do not
2915 properly handle the transition from non-tagged to tagged commands, so it is
2916 necessary to wait until there are no pending commands for a target device
2917 before queuing tagged commands.
2918 */
2919 if (HostAdapter->CommandsSinceReset[TargetID]++ >=
2920 BusLogic_MaxTaggedQueueDepth && !TargetFlags->TaggedQueuingActive && HostAdapter->ActiveCommands[TargetID] == 0 && TargetFlags->TaggedQueuingSupported && (HostAdapter->TaggedQueuingPermitted & (1 << TargetID))) {
2921 TargetFlags->TaggedQueuingActive = true;
2922 BusLogic_Notice("Tagged Queuing now active for Target %d\n", HostAdapter, TargetID);
2923 }
2924 if (TargetFlags->TaggedQueuingActive) {
2925 enum BusLogic_QueueTag QueueTag = BusLogic_SimpleQueueTag;
2926 /*
2927 When using Tagged Queuing with Simple Queue Tags, it appears that disk
2928 drive controllers do not guarantee that a queued command will not
2929 remain in a disconnected state indefinitely if commands that read or
2930 write nearer the head position continue to arrive without interruption.
2931 Therefore, for each Target Device this driver keeps track of the last
2932 time either the queue was empty or an Ordered Queue Tag was issued. If
2933 more than 4 seconds (one fifth of the 20 second disk timeout) have
2934 elapsed since this last sequence point, this command will be issued
2935 with an Ordered Queue Tag rather than a Simple Queue Tag, which forces
2936 the Target Device to complete all previously queued commands before
2937 this command may be executed.
2938 */
2939 if (HostAdapter->ActiveCommands[TargetID] == 0)
2940 HostAdapter->LastSequencePoint[TargetID] = jiffies;
2941 else if (time_after(jiffies, HostAdapter->LastSequencePoint[TargetID] + 4 * HZ)) {
2942 HostAdapter->LastSequencePoint[TargetID] = jiffies;
2943 QueueTag = BusLogic_OrderedQueueTag;
2944 }
2945 if (HostAdapter->ExtendedLUNSupport) {
2946 CCB->TagEnable = true;
2947 CCB->QueueTag = QueueTag;
2948 } else {
2949 CCB->LegacyTagEnable = true;
2950 CCB->LegacyQueueTag = QueueTag;
2951 }
2952 }
2953 memcpy(CCB->CDB, CDB, CDB_Length);
2954 CCB->SenseDataLength = SCSI_SENSE_BUFFERSIZE;
2955 CCB->SenseDataPointer = pci_map_single(HostAdapter->PCI_Device, Command->sense_buffer, CCB->SenseDataLength, PCI_DMA_FROMDEVICE);
2956 CCB->Command = Command;
2957 Command->scsi_done = CompletionRoutine;
2958 if (BusLogic_MultiMasterHostAdapterP(HostAdapter)) {
2959 /*
2960 Place the CCB in an Outgoing Mailbox. The higher levels of the SCSI
2961 Subsystem should not attempt to queue more commands than can be placed
2962 in Outgoing Mailboxes, so there should always be one free. In the
2963 unlikely event that there are none available, wait 1 second and try
2964 again. If that fails, the Host Adapter is probably hung so signal an
2965 error as a Host Adapter Hard Reset should be initiated soon.
2966 */
2967 if (!BusLogic_WriteOutgoingMailbox(HostAdapter, BusLogic_MailboxStartCommand, CCB)) {
2968 spin_unlock_irq(HostAdapter->SCSI_Host->host_lock);
2969 BusLogic_Warning("Unable to write Outgoing Mailbox - " "Pausing for 1 second\n", HostAdapter);
2970 BusLogic_Delay(1);
2971 spin_lock_irq(HostAdapter->SCSI_Host->host_lock);
2972 if (!BusLogic_WriteOutgoingMailbox(HostAdapter, BusLogic_MailboxStartCommand, CCB)) {
2973 BusLogic_Warning("Still unable to write Outgoing Mailbox - " "Host Adapter Dead?\n", HostAdapter);
2974 BusLogic_DeallocateCCB(CCB);
2975 Command->result = DID_ERROR << 16;
2976 Command->scsi_done(Command);
2977 }
2978 }
2979 } else {
2980 /*
2981 Call the FlashPoint SCCB Manager to start execution of the CCB.
2982 */
2983 CCB->Status = BusLogic_CCB_Active;
2984 HostAdapter->ActiveCommands[TargetID]++;
2985 TargetStatistics[TargetID].CommandsAttempted++;
2986 FlashPoint_StartCCB(HostAdapter->CardHandle, CCB);
2987 /*
2988 The Command may have already completed and BusLogic_QueueCompletedCCB
2989 been called, or it may still be pending.
2990 */
2991 if (CCB->Status == BusLogic_CCB_Completed)
2992 BusLogic_ProcessCompletedCCBs(HostAdapter);
2993 }
2994 return 0;
2995}
2996
2997static DEF_SCSI_QCMD(BusLogic_QueueCommand)
2998
2999#if 0
3000/*
3001 BusLogic_AbortCommand aborts Command if possible.
3002*/
3003
3004static int BusLogic_AbortCommand(struct scsi_cmnd *Command)
3005{
3006 struct BusLogic_HostAdapter *HostAdapter = (struct BusLogic_HostAdapter *) Command->device->host->hostdata;
3007
3008 int TargetID = Command->device->id;
3009 struct BusLogic_CCB *CCB;
3010 BusLogic_IncrementErrorCounter(&HostAdapter->TargetStatistics[TargetID].CommandAbortsRequested);
3011 /*
3012 Attempt to find an Active CCB for this Command. If no Active CCB for this
3013 Command is found, then no Abort is necessary.
3014 */
3015 for (CCB = HostAdapter->All_CCBs; CCB != NULL; CCB = CCB->NextAll)
3016 if (CCB->Command == Command)
3017 break;
3018 if (CCB == NULL) {
3019 BusLogic_Warning("Unable to Abort Command to Target %d - " "No CCB Found\n", HostAdapter, TargetID);
3020 return SUCCESS;
3021 } else if (CCB->Status == BusLogic_CCB_Completed) {
3022 BusLogic_Warning("Unable to Abort Command to Target %d - " "CCB Completed\n", HostAdapter, TargetID);
3023 return SUCCESS;
3024 } else if (CCB->Status == BusLogic_CCB_Reset) {
3025 BusLogic_Warning("Unable to Abort Command to Target %d - " "CCB Reset\n", HostAdapter, TargetID);
3026 return SUCCESS;
3027 }
3028 if (BusLogic_MultiMasterHostAdapterP(HostAdapter)) {
3029 /*
3030 Attempt to Abort this CCB. MultiMaster Firmware versions prior to 5.xx
3031 do not generate Abort Tag messages, but only generate the non-tagged
3032 Abort message. Since non-tagged commands are not sent by the Host
3033 Adapter until the queue of outstanding tagged commands has completed,
3034 and the Abort message is treated as a non-tagged command, it is
3035 effectively impossible to abort commands when Tagged Queuing is active.
3036 Firmware version 5.xx does generate Abort Tag messages, so it is
3037 possible to abort commands when Tagged Queuing is active.
3038 */
3039 if (HostAdapter->TargetFlags[TargetID].TaggedQueuingActive && HostAdapter->FirmwareVersion[0] < '5') {
3040 BusLogic_Warning("Unable to Abort CCB #%ld to Target %d - " "Abort Tag Not Supported\n", HostAdapter, CCB->SerialNumber, TargetID);
3041 return FAILURE;
3042 } else if (BusLogic_WriteOutgoingMailbox(HostAdapter, BusLogic_MailboxAbortCommand, CCB)) {
3043 BusLogic_Warning("Aborting CCB #%ld to Target %d\n", HostAdapter, CCB->SerialNumber, TargetID);
3044 BusLogic_IncrementErrorCounter(&HostAdapter->TargetStatistics[TargetID].CommandAbortsAttempted);
3045 return SUCCESS;
3046 } else {
3047 BusLogic_Warning("Unable to Abort CCB #%ld to Target %d - " "No Outgoing Mailboxes\n", HostAdapter, CCB->SerialNumber, TargetID);
3048 return FAILURE;
3049 }
3050 } else {
3051 /*
3052 Call the FlashPoint SCCB Manager to abort execution of the CCB.
3053 */
3054 BusLogic_Warning("Aborting CCB #%ld to Target %d\n", HostAdapter, CCB->SerialNumber, TargetID);
3055 BusLogic_IncrementErrorCounter(&HostAdapter->TargetStatistics[TargetID].CommandAbortsAttempted);
3056 FlashPoint_AbortCCB(HostAdapter->CardHandle, CCB);
3057 /*
3058 The Abort may have already been completed and
3059 BusLogic_QueueCompletedCCB been called, or it
3060 may still be pending.
3061 */
3062 if (CCB->Status == BusLogic_CCB_Completed) {
3063 BusLogic_ProcessCompletedCCBs(HostAdapter);
3064 }
3065 return SUCCESS;
3066 }
3067 return SUCCESS;
3068}
3069
3070#endif
3071/*
3072 BusLogic_ResetHostAdapter resets Host Adapter if possible, marking all
3073 currently executing SCSI Commands as having been Reset.
3074*/
3075
3076static int BusLogic_ResetHostAdapter(struct BusLogic_HostAdapter *HostAdapter, bool HardReset)
3077{
3078 struct BusLogic_CCB *CCB;
3079 int TargetID;
3080
3081 /*
3082 * Attempt to Reset and Reinitialize the Host Adapter.
3083 */
3084
3085 if (!(BusLogic_HardwareResetHostAdapter(HostAdapter, HardReset) && BusLogic_InitializeHostAdapter(HostAdapter))) {
3086 BusLogic_Error("Resetting %s Failed\n", HostAdapter, HostAdapter->FullModelName);
3087 return FAILURE;
3088 }
3089
3090 /*
3091 * Deallocate all currently executing CCBs.
3092 */
3093
3094 for (CCB = HostAdapter->All_CCBs; CCB != NULL; CCB = CCB->NextAll)
3095 if (CCB->Status == BusLogic_CCB_Active)
3096 BusLogic_DeallocateCCB(CCB);
3097 /*
3098 * Wait a few seconds between the Host Adapter Hard Reset which
3099 * initiates a SCSI Bus Reset and issuing any SCSI Commands. Some
3100 * SCSI devices get confused if they receive SCSI Commands too soon
3101 * after a SCSI Bus Reset.
3102 */
3103
3104 if (HardReset) {
3105 spin_unlock_irq(HostAdapter->SCSI_Host->host_lock);
3106 BusLogic_Delay(HostAdapter->BusSettleTime);
3107 spin_lock_irq(HostAdapter->SCSI_Host->host_lock);
3108 }
3109
3110 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++) {
3111 HostAdapter->LastResetAttempted[TargetID] = jiffies;
3112 HostAdapter->LastResetCompleted[TargetID] = jiffies;
3113 }
3114 return SUCCESS;
3115}
3116
3117/*
3118 BusLogic_BIOSDiskParameters returns the Heads/Sectors/Cylinders BIOS Disk
3119 Parameters for Disk. The default disk geometry is 64 heads, 32 sectors, and
3120 the appropriate number of cylinders so as not to exceed drive capacity. In
3121 order for disks equal to or larger than 1 GB to be addressable by the BIOS
3122 without exceeding the BIOS limitation of 1024 cylinders, Extended Translation
3123 may be enabled in AutoSCSI on FlashPoint Host Adapters and on "W" and "C"
3124 series MultiMaster Host Adapters, or by a dip switch setting on "S" and "A"
3125 series MultiMaster Host Adapters. With Extended Translation enabled, drives
3126 between 1 GB inclusive and 2 GB exclusive are given a disk geometry of 128
3127 heads and 32 sectors, and drives above 2 GB inclusive are given a disk
3128 geometry of 255 heads and 63 sectors. However, if the BIOS detects that the
3129 Extended Translation setting does not match the geometry in the partition
3130 table, then the translation inferred from the partition table will be used by
3131 the BIOS, and a warning may be displayed.
3132*/
3133
3134static int BusLogic_BIOSDiskParameters(struct scsi_device *sdev, struct block_device *Device, sector_t capacity, int *Parameters)
3135{
3136 struct BusLogic_HostAdapter *HostAdapter = (struct BusLogic_HostAdapter *) sdev->host->hostdata;
3137 struct BIOS_DiskParameters *DiskParameters = (struct BIOS_DiskParameters *) Parameters;
3138 unsigned char *buf;
3139 if (HostAdapter->ExtendedTranslationEnabled && capacity >= 2 * 1024 * 1024 /* 1 GB in 512 byte sectors */ ) {
3140 if (capacity >= 4 * 1024 * 1024 /* 2 GB in 512 byte sectors */ ) {
3141 DiskParameters->Heads = 255;
3142 DiskParameters->Sectors = 63;
3143 } else {
3144 DiskParameters->Heads = 128;
3145 DiskParameters->Sectors = 32;
3146 }
3147 } else {
3148 DiskParameters->Heads = 64;
3149 DiskParameters->Sectors = 32;
3150 }
3151 DiskParameters->Cylinders = (unsigned long) capacity / (DiskParameters->Heads * DiskParameters->Sectors);
3152 buf = scsi_bios_ptable(Device);
3153 if (buf == NULL)
3154 return 0;
3155 /*
3156 If the boot sector partition table flag is valid, search for a partition
3157 table entry whose end_head matches one of the standard BusLogic geometry
3158 translations (64/32, 128/32, or 255/63).
3159 */
3160 if (*(unsigned short *) (buf + 64) == 0xAA55) {
3161 struct partition *FirstPartitionEntry = (struct partition *) buf;
3162 struct partition *PartitionEntry = FirstPartitionEntry;
3163 int SavedCylinders = DiskParameters->Cylinders, PartitionNumber;
3164 unsigned char PartitionEntryEndHead = 0, PartitionEntryEndSector = 0;
3165 for (PartitionNumber = 0; PartitionNumber < 4; PartitionNumber++) {
3166 PartitionEntryEndHead = PartitionEntry->end_head;
3167 PartitionEntryEndSector = PartitionEntry->end_sector & 0x3F;
3168 if (PartitionEntryEndHead == 64 - 1) {
3169 DiskParameters->Heads = 64;
3170 DiskParameters->Sectors = 32;
3171 break;
3172 } else if (PartitionEntryEndHead == 128 - 1) {
3173 DiskParameters->Heads = 128;
3174 DiskParameters->Sectors = 32;
3175 break;
3176 } else if (PartitionEntryEndHead == 255 - 1) {
3177 DiskParameters->Heads = 255;
3178 DiskParameters->Sectors = 63;
3179 break;
3180 }
3181 PartitionEntry++;
3182 }
3183 if (PartitionNumber == 4) {
3184 PartitionEntryEndHead = FirstPartitionEntry->end_head;
3185 PartitionEntryEndSector = FirstPartitionEntry->end_sector & 0x3F;
3186 }
3187 DiskParameters->Cylinders = (unsigned long) capacity / (DiskParameters->Heads * DiskParameters->Sectors);
3188 if (PartitionNumber < 4 && PartitionEntryEndSector == DiskParameters->Sectors) {
3189 if (DiskParameters->Cylinders != SavedCylinders)
3190 BusLogic_Warning("Adopting Geometry %d/%d from Partition Table\n", HostAdapter, DiskParameters->Heads, DiskParameters->Sectors);
3191 } else if (PartitionEntryEndHead > 0 || PartitionEntryEndSector > 0) {
3192 BusLogic_Warning("Warning: Partition Table appears to " "have Geometry %d/%d which is\n", HostAdapter, PartitionEntryEndHead + 1, PartitionEntryEndSector);
3193 BusLogic_Warning("not compatible with current BusLogic " "Host Adapter Geometry %d/%d\n", HostAdapter, DiskParameters->Heads, DiskParameters->Sectors);
3194 }
3195 }
3196 kfree(buf);
3197 return 0;
3198}
3199
3200
3201/*
3202 BugLogic_ProcDirectoryInfo implements /proc/scsi/BusLogic/<N>.
3203*/
3204
3205static int BusLogic_ProcDirectoryInfo(struct Scsi_Host *shost, char *ProcBuffer, char **StartPointer, off_t Offset, int BytesAvailable, int WriteFlag)
3206{
3207 struct BusLogic_HostAdapter *HostAdapter = (struct BusLogic_HostAdapter *) shost->hostdata;
3208 struct BusLogic_TargetStatistics *TargetStatistics;
3209 int TargetID, Length;
3210 char *Buffer;
3211
3212 TargetStatistics = HostAdapter->TargetStatistics;
3213 if (WriteFlag) {
3214 HostAdapter->ExternalHostAdapterResets = 0;
3215 HostAdapter->HostAdapterInternalErrors = 0;
3216 memset(TargetStatistics, 0, BusLogic_MaxTargetDevices * sizeof(struct BusLogic_TargetStatistics));
3217 return 0;
3218 }
3219 Buffer = HostAdapter->MessageBuffer;
3220 Length = HostAdapter->MessageBufferLength;
3221 Length += sprintf(&Buffer[Length], "\n\
3222Current Driver Queue Depth: %d\n\
3223Currently Allocated CCBs: %d\n", HostAdapter->DriverQueueDepth, HostAdapter->AllocatedCCBs);
3224 Length += sprintf(&Buffer[Length], "\n\n\
3225 DATA TRANSFER STATISTICS\n\
3226\n\
3227Target Tagged Queuing Queue Depth Active Attempted Completed\n\
3228====== ============== =========== ====== ========= =========\n");
3229 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++) {
3230 struct BusLogic_TargetFlags *TargetFlags = &HostAdapter->TargetFlags[TargetID];
3231 if (!TargetFlags->TargetExists)
3232 continue;
3233 Length += sprintf(&Buffer[Length], " %2d %s", TargetID, (TargetFlags->TaggedQueuingSupported ? (TargetFlags->TaggedQueuingActive ? " Active" : (HostAdapter->TaggedQueuingPermitted & (1 << TargetID)
3234 ? " Permitted" : " Disabled"))
3235 : "Not Supported"));
3236 Length += sprintf(&Buffer[Length],
3237 " %3d %3u %9u %9u\n", HostAdapter->QueueDepth[TargetID], HostAdapter->ActiveCommands[TargetID], TargetStatistics[TargetID].CommandsAttempted, TargetStatistics[TargetID].CommandsCompleted);
3238 }
3239 Length += sprintf(&Buffer[Length], "\n\
3240Target Read Commands Write Commands Total Bytes Read Total Bytes Written\n\
3241====== ============= ============== =================== ===================\n");
3242 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++) {
3243 struct BusLogic_TargetFlags *TargetFlags = &HostAdapter->TargetFlags[TargetID];
3244 if (!TargetFlags->TargetExists)
3245 continue;
3246 Length += sprintf(&Buffer[Length], " %2d %9u %9u", TargetID, TargetStatistics[TargetID].ReadCommands, TargetStatistics[TargetID].WriteCommands);
3247 if (TargetStatistics[TargetID].TotalBytesRead.Billions > 0)
3248 Length += sprintf(&Buffer[Length], " %9u%09u", TargetStatistics[TargetID].TotalBytesRead.Billions, TargetStatistics[TargetID].TotalBytesRead.Units);
3249 else
3250 Length += sprintf(&Buffer[Length], " %9u", TargetStatistics[TargetID].TotalBytesRead.Units);
3251 if (TargetStatistics[TargetID].TotalBytesWritten.Billions > 0)
3252 Length += sprintf(&Buffer[Length], " %9u%09u\n", TargetStatistics[TargetID].TotalBytesWritten.Billions, TargetStatistics[TargetID].TotalBytesWritten.Units);
3253 else
3254 Length += sprintf(&Buffer[Length], " %9u\n", TargetStatistics[TargetID].TotalBytesWritten.Units);
3255 }
3256 Length += sprintf(&Buffer[Length], "\n\
3257Target Command 0-1KB 1-2KB 2-4KB 4-8KB 8-16KB\n\
3258====== ======= ========= ========= ========= ========= =========\n");
3259 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++) {
3260 struct BusLogic_TargetFlags *TargetFlags = &HostAdapter->TargetFlags[TargetID];
3261 if (!TargetFlags->TargetExists)
3262 continue;
3263 Length +=
3264 sprintf(&Buffer[Length],
3265 " %2d Read %9u %9u %9u %9u %9u\n", TargetID,
3266 TargetStatistics[TargetID].ReadCommandSizeBuckets[0],
3267 TargetStatistics[TargetID].ReadCommandSizeBuckets[1], TargetStatistics[TargetID].ReadCommandSizeBuckets[2], TargetStatistics[TargetID].ReadCommandSizeBuckets[3], TargetStatistics[TargetID].ReadCommandSizeBuckets[4]);
3268 Length +=
3269 sprintf(&Buffer[Length],
3270 " %2d Write %9u %9u %9u %9u %9u\n", TargetID,
3271 TargetStatistics[TargetID].WriteCommandSizeBuckets[0],
3272 TargetStatistics[TargetID].WriteCommandSizeBuckets[1], TargetStatistics[TargetID].WriteCommandSizeBuckets[2], TargetStatistics[TargetID].WriteCommandSizeBuckets[3], TargetStatistics[TargetID].WriteCommandSizeBuckets[4]);
3273 }
3274 Length += sprintf(&Buffer[Length], "\n\
3275Target Command 16-32KB 32-64KB 64-128KB 128-256KB 256KB+\n\
3276====== ======= ========= ========= ========= ========= =========\n");
3277 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++) {
3278 struct BusLogic_TargetFlags *TargetFlags = &HostAdapter->TargetFlags[TargetID];
3279 if (!TargetFlags->TargetExists)
3280 continue;
3281 Length +=
3282 sprintf(&Buffer[Length],
3283 " %2d Read %9u %9u %9u %9u %9u\n", TargetID,
3284 TargetStatistics[TargetID].ReadCommandSizeBuckets[5],
3285 TargetStatistics[TargetID].ReadCommandSizeBuckets[6], TargetStatistics[TargetID].ReadCommandSizeBuckets[7], TargetStatistics[TargetID].ReadCommandSizeBuckets[8], TargetStatistics[TargetID].ReadCommandSizeBuckets[9]);
3286 Length +=
3287 sprintf(&Buffer[Length],
3288 " %2d Write %9u %9u %9u %9u %9u\n", TargetID,
3289 TargetStatistics[TargetID].WriteCommandSizeBuckets[5],
3290 TargetStatistics[TargetID].WriteCommandSizeBuckets[6], TargetStatistics[TargetID].WriteCommandSizeBuckets[7], TargetStatistics[TargetID].WriteCommandSizeBuckets[8], TargetStatistics[TargetID].WriteCommandSizeBuckets[9]);
3291 }
3292 Length += sprintf(&Buffer[Length], "\n\n\
3293 ERROR RECOVERY STATISTICS\n\
3294\n\
3295 Command Aborts Bus Device Resets Host Adapter Resets\n\
3296Target Requested Completed Requested Completed Requested Completed\n\
3297 ID \\\\\\\\ Attempted //// \\\\\\\\ Attempted //// \\\\\\\\ Attempted ////\n\
3298====== ===== ===== ===== ===== ===== ===== ===== ===== =====\n");
3299 for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++) {
3300 struct BusLogic_TargetFlags *TargetFlags = &HostAdapter->TargetFlags[TargetID];
3301 if (!TargetFlags->TargetExists)
3302 continue;
3303 Length += sprintf(&Buffer[Length], "\
3304 %2d %5d %5d %5d %5d %5d %5d %5d %5d %5d\n", TargetID, TargetStatistics[TargetID].CommandAbortsRequested, TargetStatistics[TargetID].CommandAbortsAttempted, TargetStatistics[TargetID].CommandAbortsCompleted, TargetStatistics[TargetID].BusDeviceResetsRequested, TargetStatistics[TargetID].BusDeviceResetsAttempted, TargetStatistics[TargetID].BusDeviceResetsCompleted, TargetStatistics[TargetID].HostAdapterResetsRequested, TargetStatistics[TargetID].HostAdapterResetsAttempted, TargetStatistics[TargetID].HostAdapterResetsCompleted);
3305 }
3306 Length += sprintf(&Buffer[Length], "\nExternal Host Adapter Resets: %d\n", HostAdapter->ExternalHostAdapterResets);
3307 Length += sprintf(&Buffer[Length], "Host Adapter Internal Errors: %d\n", HostAdapter->HostAdapterInternalErrors);
3308 if (Length >= BusLogic_MessageBufferSize)
3309 BusLogic_Error("Message Buffer length %d exceeds size %d\n", HostAdapter, Length, BusLogic_MessageBufferSize);
3310 if ((Length -= Offset) <= 0)
3311 return 0;
3312 if (Length >= BytesAvailable)
3313 Length = BytesAvailable;
3314 memcpy(ProcBuffer, HostAdapter->MessageBuffer + Offset, Length);
3315 *StartPointer = ProcBuffer;
3316 return Length;
3317}
3318
3319
3320/*
3321 BusLogic_Message prints Driver Messages.
3322*/
3323
3324static void BusLogic_Message(enum BusLogic_MessageLevel MessageLevel, char *Format, struct BusLogic_HostAdapter *HostAdapter, ...)
3325{
3326 static char Buffer[BusLogic_LineBufferSize];
3327 static bool BeginningOfLine = true;
3328 va_list Arguments;
3329 int Length = 0;
3330 va_start(Arguments, HostAdapter);
3331 Length = vsprintf(Buffer, Format, Arguments);
3332 va_end(Arguments);
3333 if (MessageLevel == BusLogic_AnnounceLevel) {
3334 static int AnnouncementLines = 0;
3335 strcpy(&HostAdapter->MessageBuffer[HostAdapter->MessageBufferLength], Buffer);
3336 HostAdapter->MessageBufferLength += Length;
3337 if (++AnnouncementLines <= 2)
3338 printk("%sscsi: %s", BusLogic_MessageLevelMap[MessageLevel], Buffer);
3339 } else if (MessageLevel == BusLogic_InfoLevel) {
3340 strcpy(&HostAdapter->MessageBuffer[HostAdapter->MessageBufferLength], Buffer);
3341 HostAdapter->MessageBufferLength += Length;
3342 if (BeginningOfLine) {
3343 if (Buffer[0] != '\n' || Length > 1)
3344 printk("%sscsi%d: %s", BusLogic_MessageLevelMap[MessageLevel], HostAdapter->HostNumber, Buffer);
3345 } else
3346 printk("%s", Buffer);
3347 } else {
3348 if (BeginningOfLine) {
3349 if (HostAdapter != NULL && HostAdapter->HostAdapterInitialized)
3350 printk("%sscsi%d: %s", BusLogic_MessageLevelMap[MessageLevel], HostAdapter->HostNumber, Buffer);
3351 else
3352 printk("%s%s", BusLogic_MessageLevelMap[MessageLevel], Buffer);
3353 } else
3354 printk("%s", Buffer);
3355 }
3356 BeginningOfLine = (Buffer[Length - 1] == '\n');
3357}
3358
3359
3360/*
3361 BusLogic_ParseKeyword parses an individual option keyword. It returns true
3362 and updates the pointer if the keyword is recognized and false otherwise.
3363*/
3364
3365static bool __init BusLogic_ParseKeyword(char **StringPointer, char *Keyword)
3366{
3367 char *Pointer = *StringPointer;
3368 while (*Keyword != '\0') {
3369 char StringChar = *Pointer++;
3370 char KeywordChar = *Keyword++;
3371 if (StringChar >= 'A' && StringChar <= 'Z')
3372 StringChar += 'a' - 'Z';
3373 if (KeywordChar >= 'A' && KeywordChar <= 'Z')
3374 KeywordChar += 'a' - 'Z';
3375 if (StringChar != KeywordChar)
3376 return false;
3377 }
3378 *StringPointer = Pointer;
3379 return true;
3380}
3381
3382
3383/*
3384 BusLogic_ParseDriverOptions handles processing of BusLogic Driver Options
3385 specifications.
3386
3387 BusLogic Driver Options may be specified either via the Linux Kernel Command
3388 Line or via the Loadable Kernel Module Installation Facility. Driver Options
3389 for multiple host adapters may be specified either by separating the option
3390 strings by a semicolon, or by specifying multiple "BusLogic=" strings on the
3391 command line. Individual option specifications for a single host adapter are
3392 separated by commas. The Probing and Debugging Options apply to all host
3393 adapters whereas the remaining options apply individually only to the
3394 selected host adapter.
3395
3396 The BusLogic Driver Probing Options are described in
3397 <file:Documentation/scsi/BusLogic.txt>.
3398*/
3399
3400static int __init BusLogic_ParseDriverOptions(char *OptionsString)
3401{
3402 while (true) {
3403 struct BusLogic_DriverOptions *DriverOptions = &BusLogic_DriverOptions[BusLogic_DriverOptionsCount++];
3404 int TargetID;
3405 memset(DriverOptions, 0, sizeof(struct BusLogic_DriverOptions));
3406 while (*OptionsString != '\0' && *OptionsString != ';') {
3407 /* Probing Options. */
3408 if (BusLogic_ParseKeyword(&OptionsString, "IO:")) {
3409 unsigned long IO_Address = simple_strtoul(OptionsString, &OptionsString, 0);
3410 BusLogic_ProbeOptions.LimitedProbeISA = true;
3411 switch (IO_Address) {
3412 case 0x330:
3413 BusLogic_ProbeOptions.Probe330 = true;
3414 break;
3415 case 0x334:
3416 BusLogic_ProbeOptions.Probe334 = true;
3417 break;
3418 case 0x230:
3419 BusLogic_ProbeOptions.Probe230 = true;
3420 break;
3421 case 0x234:
3422 BusLogic_ProbeOptions.Probe234 = true;
3423 break;
3424 case 0x130:
3425 BusLogic_ProbeOptions.Probe130 = true;
3426 break;
3427 case 0x134:
3428 BusLogic_ProbeOptions.Probe134 = true;
3429 break;
3430 default:
3431 BusLogic_Error("BusLogic: Invalid Driver Options " "(invalid I/O Address 0x%X)\n", NULL, IO_Address);
3432 return 0;
3433 }
3434 } else if (BusLogic_ParseKeyword(&OptionsString, "NoProbeISA"))
3435 BusLogic_ProbeOptions.NoProbeISA = true;
3436 else if (BusLogic_ParseKeyword(&OptionsString, "NoProbePCI"))
3437 BusLogic_ProbeOptions.NoProbePCI = true;
3438 else if (BusLogic_ParseKeyword(&OptionsString, "NoProbe"))
3439 BusLogic_ProbeOptions.NoProbe = true;
3440 else if (BusLogic_ParseKeyword(&OptionsString, "NoSortPCI"))
3441 BusLogic_ProbeOptions.NoSortPCI = true;
3442 else if (BusLogic_ParseKeyword(&OptionsString, "MultiMasterFirst"))
3443 BusLogic_ProbeOptions.MultiMasterFirst = true;
3444 else if (BusLogic_ParseKeyword(&OptionsString, "FlashPointFirst"))
3445 BusLogic_ProbeOptions.FlashPointFirst = true;
3446 /* Tagged Queuing Options. */
3447 else if (BusLogic_ParseKeyword(&OptionsString, "QueueDepth:[") || BusLogic_ParseKeyword(&OptionsString, "QD:[")) {
3448 for (TargetID = 0; TargetID < BusLogic_MaxTargetDevices; TargetID++) {
3449 unsigned short QueueDepth = simple_strtoul(OptionsString, &OptionsString, 0);
3450 if (QueueDepth > BusLogic_MaxTaggedQueueDepth) {
3451 BusLogic_Error("BusLogic: Invalid Driver Options " "(invalid Queue Depth %d)\n", NULL, QueueDepth);
3452 return 0;
3453 }
3454 DriverOptions->QueueDepth[TargetID] = QueueDepth;
3455 if (*OptionsString == ',')
3456 OptionsString++;
3457 else if (*OptionsString == ']')
3458 break;
3459 else {
3460 BusLogic_Error("BusLogic: Invalid Driver Options " "(',' or ']' expected at '%s')\n", NULL, OptionsString);
3461 return 0;
3462 }
3463 }
3464 if (*OptionsString != ']') {
3465 BusLogic_Error("BusLogic: Invalid Driver Options " "(']' expected at '%s')\n", NULL, OptionsString);
3466 return 0;
3467 } else
3468 OptionsString++;
3469 } else if (BusLogic_ParseKeyword(&OptionsString, "QueueDepth:") || BusLogic_ParseKeyword(&OptionsString, "QD:")) {
3470 unsigned short QueueDepth = simple_strtoul(OptionsString, &OptionsString, 0);
3471 if (QueueDepth == 0 || QueueDepth > BusLogic_MaxTaggedQueueDepth) {
3472 BusLogic_Error("BusLogic: Invalid Driver Options " "(invalid Queue Depth %d)\n", NULL, QueueDepth);
3473 return 0;
3474 }
3475 DriverOptions->CommonQueueDepth = QueueDepth;
3476 for (TargetID = 0; TargetID < BusLogic_MaxTargetDevices; TargetID++)
3477 DriverOptions->QueueDepth[TargetID] = QueueDepth;
3478 } else if (BusLogic_ParseKeyword(&OptionsString, "TaggedQueuing:") || BusLogic_ParseKeyword(&OptionsString, "TQ:")) {
3479 if (BusLogic_ParseKeyword(&OptionsString, "Default")) {
3480 DriverOptions->TaggedQueuingPermitted = 0x0000;
3481 DriverOptions->TaggedQueuingPermittedMask = 0x0000;
3482 } else if (BusLogic_ParseKeyword(&OptionsString, "Enable")) {
3483 DriverOptions->TaggedQueuingPermitted = 0xFFFF;
3484 DriverOptions->TaggedQueuingPermittedMask = 0xFFFF;
3485 } else if (BusLogic_ParseKeyword(&OptionsString, "Disable")) {
3486 DriverOptions->TaggedQueuingPermitted = 0x0000;
3487 DriverOptions->TaggedQueuingPermittedMask = 0xFFFF;
3488 } else {
3489 unsigned short TargetBit;
3490 for (TargetID = 0, TargetBit = 1; TargetID < BusLogic_MaxTargetDevices; TargetID++, TargetBit <<= 1)
3491 switch (*OptionsString++) {
3492 case 'Y':
3493 DriverOptions->TaggedQueuingPermitted |= TargetBit;
3494 DriverOptions->TaggedQueuingPermittedMask |= TargetBit;
3495 break;
3496 case 'N':
3497 DriverOptions->TaggedQueuingPermitted &= ~TargetBit;
3498 DriverOptions->TaggedQueuingPermittedMask |= TargetBit;
3499 break;
3500 case 'X':
3501 break;
3502 default:
3503 OptionsString--;
3504 TargetID = BusLogic_MaxTargetDevices;
3505 break;
3506 }
3507 }
3508 }
3509 /* Miscellaneous Options. */
3510 else if (BusLogic_ParseKeyword(&OptionsString, "BusSettleTime:") || BusLogic_ParseKeyword(&OptionsString, "BST:")) {
3511 unsigned short BusSettleTime = simple_strtoul(OptionsString, &OptionsString, 0);
3512 if (BusSettleTime > 5 * 60) {
3513 BusLogic_Error("BusLogic: Invalid Driver Options " "(invalid Bus Settle Time %d)\n", NULL, BusSettleTime);
3514 return 0;
3515 }
3516 DriverOptions->BusSettleTime = BusSettleTime;
3517 } else if (BusLogic_ParseKeyword(&OptionsString, "InhibitTargetInquiry"))
3518 DriverOptions->LocalOptions.InhibitTargetInquiry = true;
3519 /* Debugging Options. */
3520 else if (BusLogic_ParseKeyword(&OptionsString, "TraceProbe"))
3521 BusLogic_GlobalOptions.TraceProbe = true;
3522 else if (BusLogic_ParseKeyword(&OptionsString, "TraceHardwareReset"))
3523 BusLogic_GlobalOptions.TraceHardwareReset = true;
3524 else if (BusLogic_ParseKeyword(&OptionsString, "TraceConfiguration"))
3525 BusLogic_GlobalOptions.TraceConfiguration = true;
3526 else if (BusLogic_ParseKeyword(&OptionsString, "TraceErrors"))
3527 BusLogic_GlobalOptions.TraceErrors = true;
3528 else if (BusLogic_ParseKeyword(&OptionsString, "Debug")) {
3529 BusLogic_GlobalOptions.TraceProbe = true;
3530 BusLogic_GlobalOptions.TraceHardwareReset = true;
3531 BusLogic_GlobalOptions.TraceConfiguration = true;
3532 BusLogic_GlobalOptions.TraceErrors = true;
3533 }
3534 if (*OptionsString == ',')
3535 OptionsString++;
3536 else if (*OptionsString != ';' && *OptionsString != '\0') {
3537 BusLogic_Error("BusLogic: Unexpected Driver Option '%s' " "ignored\n", NULL, OptionsString);
3538 *OptionsString = '\0';
3539 }
3540 }
3541 if (!(BusLogic_DriverOptionsCount == 0 || BusLogic_ProbeInfoCount == 0 || BusLogic_DriverOptionsCount == BusLogic_ProbeInfoCount)) {
3542 BusLogic_Error("BusLogic: Invalid Driver Options " "(all or no I/O Addresses must be specified)\n", NULL);
3543 return 0;
3544 }
3545 /*
3546 Tagged Queuing is disabled when the Queue Depth is 1 since queuing
3547 multiple commands is not possible.
3548 */
3549 for (TargetID = 0; TargetID < BusLogic_MaxTargetDevices; TargetID++)
3550 if (DriverOptions->QueueDepth[TargetID] == 1) {
3551 unsigned short TargetBit = 1 << TargetID;
3552 DriverOptions->TaggedQueuingPermitted &= ~TargetBit;
3553 DriverOptions->TaggedQueuingPermittedMask |= TargetBit;
3554 }
3555 if (*OptionsString == ';')
3556 OptionsString++;
3557 if (*OptionsString == '\0')
3558 return 0;
3559 }
3560 return 1;
3561}
3562
3563/*
3564 Get it all started
3565*/
3566
3567static struct scsi_host_template Bus_Logic_template = {
3568 .module = THIS_MODULE,
3569 .proc_name = "BusLogic",
3570 .proc_info = BusLogic_ProcDirectoryInfo,
3571 .name = "BusLogic",
3572 .info = BusLogic_DriverInfo,
3573 .queuecommand = BusLogic_QueueCommand,
3574 .slave_configure = BusLogic_SlaveConfigure,
3575 .bios_param = BusLogic_BIOSDiskParameters,
3576 .eh_host_reset_handler = BusLogic_host_reset,
3577#if 0
3578 .eh_abort_handler = BusLogic_AbortCommand,
3579#endif
3580 .unchecked_isa_dma = 1,
3581 .max_sectors = 128,
3582 .use_clustering = ENABLE_CLUSTERING,
3583};
3584
3585/*
3586 BusLogic_Setup handles processing of Kernel Command Line Arguments.
3587*/
3588
3589static int __init BusLogic_Setup(char *str)
3590{
3591 int ints[3];
3592
3593 (void) get_options(str, ARRAY_SIZE(ints), ints);
3594
3595 if (ints[0] != 0) {
3596 BusLogic_Error("BusLogic: Obsolete Command Line Entry " "Format Ignored\n", NULL);
3597 return 0;
3598 }
3599 if (str == NULL || *str == '\0')
3600 return 0;
3601 return BusLogic_ParseDriverOptions(str);
3602}
3603
3604/*
3605 * Exit function. Deletes all hosts associated with this driver.
3606 */
3607
3608static void __exit BusLogic_exit(void)
3609{
3610 struct BusLogic_HostAdapter *ha, *next;
3611
3612 list_for_each_entry_safe(ha, next, &BusLogic_host_list, host_list)
3613 BusLogic_ReleaseHostAdapter(ha);
3614}
3615
3616__setup("BusLogic=", BusLogic_Setup);
3617
3618#ifdef MODULE
3619static struct pci_device_id BusLogic_pci_tbl[] __devinitdata = {
3620 { PCI_VENDOR_ID_BUSLOGIC, PCI_DEVICE_ID_BUSLOGIC_MULTIMASTER,
3621 PCI_ANY_ID, PCI_ANY_ID, 0, 0, 0},
3622 { PCI_VENDOR_ID_BUSLOGIC, PCI_DEVICE_ID_BUSLOGIC_MULTIMASTER_NC,
3623 PCI_ANY_ID, PCI_ANY_ID, 0, 0, 0},
3624 { PCI_VENDOR_ID_BUSLOGIC, PCI_DEVICE_ID_BUSLOGIC_FLASHPOINT,
3625 PCI_ANY_ID, PCI_ANY_ID, 0, 0, 0},
3626 { }
3627};
3628#endif
3629MODULE_DEVICE_TABLE(pci, BusLogic_pci_tbl);
3630
3631module_init(BusLogic_init);
3632module_exit(BusLogic_exit);
1// SPDX-License-Identifier: GPL-2.0-only
2
3/*
4
5 Linux Driver for BusLogic MultiMaster and FlashPoint SCSI Host Adapters
6
7 Copyright 1995-1998 by Leonard N. Zubkoff <lnz@dandelion.com>
8
9
10 The author respectfully requests that any modifications to this software be
11 sent directly to him for evaluation and testing.
12
13 Special thanks to Wayne Yen, Jin-Lon Hon, and Alex Win of BusLogic, whose
14 advice has been invaluable, to David Gentzel, for writing the original Linux
15 BusLogic driver, and to Paul Gortmaker, for being such a dedicated test site.
16
17 Finally, special thanks to Mylex/BusLogic for making the FlashPoint SCCB
18 Manager available as freely redistributable source code.
19
20*/
21
22#define blogic_drvr_version "2.1.17"
23#define blogic_drvr_date "12 September 2013"
24
25#include <linux/module.h>
26#include <linux/init.h>
27#include <linux/interrupt.h>
28#include <linux/types.h>
29#include <linux/blkdev.h>
30#include <linux/delay.h>
31#include <linux/ioport.h>
32#include <linux/mm.h>
33#include <linux/stat.h>
34#include <linux/pci.h>
35#include <linux/spinlock.h>
36#include <linux/jiffies.h>
37#include <linux/dma-mapping.h>
38#include <linux/slab.h>
39#include <linux/msdos_partition.h>
40#include <scsi/scsicam.h>
41
42#include <asm/dma.h>
43#include <asm/io.h>
44
45#include <scsi/scsi.h>
46#include <scsi/scsi_cmnd.h>
47#include <scsi/scsi_device.h>
48#include <scsi/scsi_host.h>
49#include <scsi/scsi_tcq.h>
50#include "BusLogic.h"
51#include "FlashPoint.c"
52
53#ifndef FAILURE
54#define FAILURE (-1)
55#endif
56
57static const struct scsi_host_template blogic_template;
58
59/*
60 blogic_drvr_options_count is a count of the number of BusLogic Driver
61 Options specifications provided via the Linux Kernel Command Line or via
62 the Loadable Kernel Module Installation Facility.
63*/
64
65static int blogic_drvr_options_count;
66
67
68/*
69 blogic_drvr_options is an array of Driver Options structures representing
70 BusLogic Driver Options specifications provided via the Linux Kernel Command
71 Line or via the Loadable Kernel Module Installation Facility.
72*/
73
74static struct blogic_drvr_options blogic_drvr_options[BLOGIC_MAX_ADAPTERS];
75
76
77/*
78 BusLogic can be assigned a string by insmod.
79*/
80
81MODULE_DESCRIPTION("BusLogic MultiMaster and FlashPoint SCSI Host Adapter driver");
82MODULE_LICENSE("GPL");
83#ifdef MODULE
84static char *BusLogic;
85module_param(BusLogic, charp, 0);
86#endif
87
88
89/*
90 blogic_probe_options is a set of Probe Options to be applied across
91 all BusLogic Host Adapters.
92*/
93
94static struct blogic_probe_options blogic_probe_options;
95
96
97/*
98 blogic_global_options is a set of Global Options to be applied across
99 all BusLogic Host Adapters.
100*/
101
102static struct blogic_global_options blogic_global_options;
103
104static LIST_HEAD(blogic_host_list);
105
106/*
107 blogic_probeinfo_count is the number of entries in blogic_probeinfo_list.
108*/
109
110static int blogic_probeinfo_count;
111
112
113/*
114 blogic_probeinfo_list is the list of I/O Addresses and Bus Probe Information
115 to be checked for potential BusLogic Host Adapters. It is initialized by
116 interrogating the PCI Configuration Space on PCI machines as well as from the
117 list of standard BusLogic I/O Addresses.
118*/
119
120static struct blogic_probeinfo *blogic_probeinfo_list;
121
122
123/*
124 blogic_cmd_failure_reason holds a string identifying the reason why a
125 call to blogic_cmd failed. It is only non-NULL when blogic_cmd
126 returns a failure code.
127*/
128
129static char *blogic_cmd_failure_reason;
130
131/*
132 blogic_announce_drvr announces the Driver Version and Date, Author's
133 Name, Copyright Notice, and Electronic Mail Address.
134*/
135
136static void blogic_announce_drvr(struct blogic_adapter *adapter)
137{
138 blogic_announce("***** BusLogic SCSI Driver Version " blogic_drvr_version " of " blogic_drvr_date " *****\n", adapter);
139 blogic_announce("Copyright 1995-1998 by Leonard N. Zubkoff <lnz@dandelion.com>\n", adapter);
140}
141
142
143/*
144 blogic_drvr_info returns the Host Adapter Name to identify this SCSI
145 Driver and Host Adapter.
146*/
147
148static const char *blogic_drvr_info(struct Scsi_Host *host)
149{
150 struct blogic_adapter *adapter =
151 (struct blogic_adapter *) host->hostdata;
152 return adapter->full_model;
153}
154
155/*
156 blogic_init_ccbs initializes a group of Command Control Blocks (CCBs)
157 for Host Adapter from the blk_size bytes located at blk_pointer. The newly
158 created CCBs are added to Host Adapter's free list.
159*/
160
161static void blogic_init_ccbs(struct blogic_adapter *adapter, void *blk_pointer,
162 int blk_size, dma_addr_t blkp)
163{
164 struct blogic_ccb *ccb = (struct blogic_ccb *) blk_pointer;
165 unsigned int offset = 0;
166 memset(blk_pointer, 0, blk_size);
167 ccb->allocgrp_head = blkp;
168 ccb->allocgrp_size = blk_size;
169 while ((blk_size -= sizeof(struct blogic_ccb)) >= 0) {
170 ccb->status = BLOGIC_CCB_FREE;
171 ccb->adapter = adapter;
172 ccb->dma_handle = (u32) blkp + offset;
173 if (blogic_flashpoint_type(adapter)) {
174 ccb->callback = blogic_qcompleted_ccb;
175 ccb->base_addr = adapter->fpinfo.base_addr;
176 }
177 ccb->next = adapter->free_ccbs;
178 ccb->next_all = adapter->all_ccbs;
179 adapter->free_ccbs = ccb;
180 adapter->all_ccbs = ccb;
181 adapter->alloc_ccbs++;
182 ccb++;
183 offset += sizeof(struct blogic_ccb);
184 }
185}
186
187
188/*
189 blogic_create_initccbs allocates the initial CCBs for Host Adapter.
190*/
191
192static bool __init blogic_create_initccbs(struct blogic_adapter *adapter)
193{
194 int blk_size = BLOGIC_CCB_GRP_ALLOCSIZE * sizeof(struct blogic_ccb);
195 void *blk_pointer;
196 dma_addr_t blkp;
197
198 while (adapter->alloc_ccbs < adapter->initccbs) {
199 blk_pointer = dma_alloc_coherent(&adapter->pci_device->dev,
200 blk_size, &blkp, GFP_KERNEL);
201 if (blk_pointer == NULL) {
202 blogic_err("UNABLE TO ALLOCATE CCB GROUP - DETACHING\n",
203 adapter);
204 return false;
205 }
206 blogic_init_ccbs(adapter, blk_pointer, blk_size, blkp);
207 }
208 return true;
209}
210
211
212/*
213 blogic_destroy_ccbs deallocates the CCBs for Host Adapter.
214*/
215
216static void blogic_destroy_ccbs(struct blogic_adapter *adapter)
217{
218 struct blogic_ccb *next_ccb = adapter->all_ccbs, *ccb, *lastccb = NULL;
219 adapter->all_ccbs = NULL;
220 adapter->free_ccbs = NULL;
221 while ((ccb = next_ccb) != NULL) {
222 next_ccb = ccb->next_all;
223 if (ccb->allocgrp_head) {
224 if (lastccb)
225 dma_free_coherent(&adapter->pci_device->dev,
226 lastccb->allocgrp_size, lastccb,
227 lastccb->allocgrp_head);
228 lastccb = ccb;
229 }
230 }
231 if (lastccb)
232 dma_free_coherent(&adapter->pci_device->dev,
233 lastccb->allocgrp_size, lastccb,
234 lastccb->allocgrp_head);
235}
236
237
238/*
239 blogic_create_addlccbs allocates Additional CCBs for Host Adapter. If
240 allocation fails and there are no remaining CCBs available, the Driver Queue
241 Depth is decreased to a known safe value to avoid potential deadlocks when
242 multiple host adapters share the same IRQ Channel.
243*/
244
245static void blogic_create_addlccbs(struct blogic_adapter *adapter,
246 int addl_ccbs, bool print_success)
247{
248 int blk_size = BLOGIC_CCB_GRP_ALLOCSIZE * sizeof(struct blogic_ccb);
249 int prev_alloc = adapter->alloc_ccbs;
250 void *blk_pointer;
251 dma_addr_t blkp;
252 if (addl_ccbs <= 0)
253 return;
254 while (adapter->alloc_ccbs - prev_alloc < addl_ccbs) {
255 blk_pointer = dma_alloc_coherent(&adapter->pci_device->dev,
256 blk_size, &blkp, GFP_KERNEL);
257 if (blk_pointer == NULL)
258 break;
259 blogic_init_ccbs(adapter, blk_pointer, blk_size, blkp);
260 }
261 if (adapter->alloc_ccbs > prev_alloc) {
262 if (print_success)
263 blogic_notice("Allocated %d additional CCBs (total now %d)\n", adapter, adapter->alloc_ccbs - prev_alloc, adapter->alloc_ccbs);
264 return;
265 }
266 blogic_notice("Failed to allocate additional CCBs\n", adapter);
267 if (adapter->drvr_qdepth > adapter->alloc_ccbs - adapter->tgt_count) {
268 adapter->drvr_qdepth = adapter->alloc_ccbs - adapter->tgt_count;
269 adapter->scsi_host->can_queue = adapter->drvr_qdepth;
270 }
271}
272
273/*
274 blogic_alloc_ccb allocates a CCB from Host Adapter's free list,
275 allocating more memory from the Kernel if necessary. The Host Adapter's
276 Lock should already have been acquired by the caller.
277*/
278
279static struct blogic_ccb *blogic_alloc_ccb(struct blogic_adapter *adapter)
280{
281 static unsigned long serial;
282 struct blogic_ccb *ccb;
283 ccb = adapter->free_ccbs;
284 if (ccb != NULL) {
285 ccb->serial = ++serial;
286 adapter->free_ccbs = ccb->next;
287 ccb->next = NULL;
288 if (adapter->free_ccbs == NULL)
289 blogic_create_addlccbs(adapter, adapter->inc_ccbs,
290 true);
291 return ccb;
292 }
293 blogic_create_addlccbs(adapter, adapter->inc_ccbs, true);
294 ccb = adapter->free_ccbs;
295 if (ccb == NULL)
296 return NULL;
297 ccb->serial = ++serial;
298 adapter->free_ccbs = ccb->next;
299 ccb->next = NULL;
300 return ccb;
301}
302
303
304/*
305 blogic_dealloc_ccb deallocates a CCB, returning it to the Host Adapter's
306 free list. The Host Adapter's Lock should already have been acquired by the
307 caller.
308*/
309
310static void blogic_dealloc_ccb(struct blogic_ccb *ccb, int dma_unmap)
311{
312 struct blogic_adapter *adapter = ccb->adapter;
313
314 if (ccb->command != NULL)
315 scsi_dma_unmap(ccb->command);
316 if (dma_unmap)
317 dma_unmap_single(&adapter->pci_device->dev, ccb->sensedata,
318 ccb->sense_datalen, DMA_FROM_DEVICE);
319
320 ccb->command = NULL;
321 ccb->status = BLOGIC_CCB_FREE;
322 ccb->next = adapter->free_ccbs;
323 adapter->free_ccbs = ccb;
324}
325
326
327/*
328 blogic_cmd sends the command opcode to adapter, optionally
329 providing paramlen bytes of param and receiving at most
330 replylen bytes of reply; any excess reply data is received but
331 discarded.
332
333 On success, this function returns the number of reply bytes read from
334 the Host Adapter (including any discarded data); on failure, it returns
335 -1 if the command was invalid, or -2 if a timeout occurred.
336
337 blogic_cmd is called exclusively during host adapter detection and
338 initialization, so performance and latency are not critical, and exclusive
339 access to the Host Adapter hardware is assumed. Once the host adapter and
340 driver are initialized, the only Host Adapter command that is issued is the
341 single byte Execute Mailbox Command operation code, which does not require
342 waiting for the Host Adapter Ready bit to be set in the Status Register.
343*/
344
345static int blogic_cmd(struct blogic_adapter *adapter, enum blogic_opcode opcode,
346 void *param, int paramlen, void *reply, int replylen)
347{
348 unsigned char *param_p = (unsigned char *) param;
349 unsigned char *reply_p = (unsigned char *) reply;
350 union blogic_stat_reg statusreg;
351 union blogic_int_reg intreg;
352 unsigned long processor_flag = 0;
353 int reply_b = 0, result;
354 long timeout;
355 /*
356 Clear out the Reply Data if provided.
357 */
358 if (replylen > 0)
359 memset(reply, 0, replylen);
360 /*
361 If the IRQ Channel has not yet been acquired, then interrupts
362 must be disabled while issuing host adapter commands since a
363 Command Complete interrupt could occur if the IRQ Channel was
364 previously enabled by another BusLogic Host Adapter or another
365 driver sharing the same IRQ Channel.
366 */
367 if (!adapter->irq_acquired)
368 local_irq_save(processor_flag);
369 /*
370 Wait for the Host Adapter Ready bit to be set and the
371 Command/Parameter Register Busy bit to be reset in the Status
372 Register.
373 */
374 timeout = 10000;
375 while (--timeout >= 0) {
376 statusreg.all = blogic_rdstatus(adapter);
377 if (statusreg.sr.adapter_ready && !statusreg.sr.cmd_param_busy)
378 break;
379 udelay(100);
380 }
381 if (timeout < 0) {
382 blogic_cmd_failure_reason =
383 "Timeout waiting for Host Adapter Ready";
384 result = -2;
385 goto done;
386 }
387 /*
388 Write the opcode to the Command/Parameter Register.
389 */
390 adapter->adapter_cmd_complete = false;
391 blogic_setcmdparam(adapter, opcode);
392 /*
393 Write any additional Parameter Bytes.
394 */
395 timeout = 10000;
396 while (paramlen > 0 && --timeout >= 0) {
397 /*
398 Wait 100 microseconds to give the Host Adapter enough
399 time to determine whether the last value written to the
400 Command/Parameter Register was valid or not. If the
401 Command Complete bit is set in the Interrupt Register,
402 then the Command Invalid bit in the Status Register will
403 be reset if the Operation Code or Parameter was valid
404 and the command has completed, or set if the Operation
405 Code or Parameter was invalid. If the Data In Register
406 Ready bit is set in the Status Register, then the
407 Operation Code was valid, and data is waiting to be read
408 back from the Host Adapter. Otherwise, wait for the
409 Command/Parameter Register Busy bit in the Status
410 Register to be reset.
411 */
412 udelay(100);
413 intreg.all = blogic_rdint(adapter);
414 statusreg.all = blogic_rdstatus(adapter);
415 if (intreg.ir.cmd_complete)
416 break;
417 if (adapter->adapter_cmd_complete)
418 break;
419 if (statusreg.sr.datain_ready)
420 break;
421 if (statusreg.sr.cmd_param_busy)
422 continue;
423 blogic_setcmdparam(adapter, *param_p++);
424 paramlen--;
425 }
426 if (timeout < 0) {
427 blogic_cmd_failure_reason =
428 "Timeout waiting for Parameter Acceptance";
429 result = -2;
430 goto done;
431 }
432 /*
433 The Modify I/O Address command does not cause a Command Complete
434 Interrupt.
435 */
436 if (opcode == BLOGIC_MOD_IOADDR) {
437 statusreg.all = blogic_rdstatus(adapter);
438 if (statusreg.sr.cmd_invalid) {
439 blogic_cmd_failure_reason =
440 "Modify I/O Address Invalid";
441 result = -1;
442 goto done;
443 }
444 if (blogic_global_options.trace_config)
445 blogic_notice("blogic_cmd(%02X) Status = %02X: (Modify I/O Address)\n", adapter, opcode, statusreg.all);
446 result = 0;
447 goto done;
448 }
449 /*
450 Select an appropriate timeout value for awaiting command completion.
451 */
452 switch (opcode) {
453 case BLOGIC_INQ_DEV0TO7:
454 case BLOGIC_INQ_DEV8TO15:
455 case BLOGIC_INQ_DEV:
456 /* Approximately 60 seconds. */
457 timeout = 60 * 10000;
458 break;
459 default:
460 /* Approximately 1 second. */
461 timeout = 10000;
462 break;
463 }
464 /*
465 Receive any Reply Bytes, waiting for either the Command
466 Complete bit to be set in the Interrupt Register, or for the
467 Interrupt Handler to set the Host Adapter Command Completed
468 bit in the Host Adapter structure.
469 */
470 while (--timeout >= 0) {
471 intreg.all = blogic_rdint(adapter);
472 statusreg.all = blogic_rdstatus(adapter);
473 if (intreg.ir.cmd_complete)
474 break;
475 if (adapter->adapter_cmd_complete)
476 break;
477 if (statusreg.sr.datain_ready) {
478 if (++reply_b <= replylen)
479 *reply_p++ = blogic_rddatain(adapter);
480 else
481 blogic_rddatain(adapter);
482 }
483 if (opcode == BLOGIC_FETCH_LOCALRAM &&
484 statusreg.sr.adapter_ready)
485 break;
486 udelay(100);
487 }
488 if (timeout < 0) {
489 blogic_cmd_failure_reason =
490 "Timeout waiting for Command Complete";
491 result = -2;
492 goto done;
493 }
494 /*
495 Clear any pending Command Complete Interrupt.
496 */
497 blogic_intreset(adapter);
498 /*
499 Provide tracing information if requested.
500 */
501 if (blogic_global_options.trace_config) {
502 int i;
503 blogic_notice("blogic_cmd(%02X) Status = %02X: %2d ==> %2d:",
504 adapter, opcode, statusreg.all, replylen,
505 reply_b);
506 if (replylen > reply_b)
507 replylen = reply_b;
508 for (i = 0; i < replylen; i++)
509 blogic_notice(" %02X", adapter,
510 ((unsigned char *) reply)[i]);
511 blogic_notice("\n", adapter);
512 }
513 /*
514 Process Command Invalid conditions.
515 */
516 if (statusreg.sr.cmd_invalid) {
517 /*
518 Some early BusLogic Host Adapters may not recover
519 properly from a Command Invalid condition, so if this
520 appears to be the case, a Soft Reset is issued to the
521 Host Adapter. Potentially invalid commands are never
522 attempted after Mailbox Initialization is performed,
523 so there should be no Host Adapter state lost by a
524 Soft Reset in response to a Command Invalid condition.
525 */
526 udelay(1000);
527 statusreg.all = blogic_rdstatus(adapter);
528 if (statusreg.sr.cmd_invalid || statusreg.sr.rsvd ||
529 statusreg.sr.datain_ready ||
530 statusreg.sr.cmd_param_busy ||
531 !statusreg.sr.adapter_ready ||
532 !statusreg.sr.init_reqd ||
533 statusreg.sr.diag_active ||
534 statusreg.sr.diag_failed) {
535 blogic_softreset(adapter);
536 udelay(1000);
537 }
538 blogic_cmd_failure_reason = "Command Invalid";
539 result = -1;
540 goto done;
541 }
542 /*
543 Handle Excess Parameters Supplied conditions.
544 */
545 if (paramlen > 0) {
546 blogic_cmd_failure_reason = "Excess Parameters Supplied";
547 result = -1;
548 goto done;
549 }
550 /*
551 Indicate the command completed successfully.
552 */
553 blogic_cmd_failure_reason = NULL;
554 result = reply_b;
555 /*
556 Restore the interrupt status if necessary and return.
557 */
558done:
559 if (!adapter->irq_acquired)
560 local_irq_restore(processor_flag);
561 return result;
562}
563
564
565/*
566 blogic_sort_probeinfo sorts a section of blogic_probeinfo_list in order
567 of increasing PCI Bus and Device Number.
568*/
569
570static void __init blogic_sort_probeinfo(struct blogic_probeinfo
571 *probeinfo_list, int probeinfo_cnt)
572{
573 int last_exchange = probeinfo_cnt - 1, bound, j;
574
575 while (last_exchange > 0) {
576 bound = last_exchange;
577 last_exchange = 0;
578 for (j = 0; j < bound; j++) {
579 struct blogic_probeinfo *probeinfo1 =
580 &probeinfo_list[j];
581 struct blogic_probeinfo *probeinfo2 =
582 &probeinfo_list[j + 1];
583 if (probeinfo1->bus > probeinfo2->bus ||
584 (probeinfo1->bus == probeinfo2->bus &&
585 (probeinfo1->dev > probeinfo2->dev))) {
586 struct blogic_probeinfo tmp_probeinfo;
587
588 memcpy(&tmp_probeinfo, probeinfo1,
589 sizeof(struct blogic_probeinfo));
590 memcpy(probeinfo1, probeinfo2,
591 sizeof(struct blogic_probeinfo));
592 memcpy(probeinfo2, &tmp_probeinfo,
593 sizeof(struct blogic_probeinfo));
594 last_exchange = j;
595 }
596 }
597 }
598}
599
600
601/*
602 blogic_init_mm_probeinfo initializes the list of I/O Address
603 and Bus Probe Information to be checked for potential BusLogic MultiMaster
604 SCSI Host Adapters by interrogating the PCI Configuration Space on PCI
605 machines as well as from the list of standard BusLogic MultiMaster ISA
606 I/O Addresses. It returns the number of PCI MultiMaster Host Adapters found.
607*/
608
609static int __init blogic_init_mm_probeinfo(struct blogic_adapter *adapter)
610{
611 struct blogic_probeinfo *pr_probeinfo =
612 &blogic_probeinfo_list[blogic_probeinfo_count];
613 int nonpr_mmindex = blogic_probeinfo_count + 1;
614 int nonpr_mmcount = 0, mmcount = 0;
615 bool force_scan_order = false;
616 bool force_scan_order_checked = false;
617 struct pci_dev *pci_device = NULL;
618 int i;
619 if (blogic_probeinfo_count >= BLOGIC_MAX_ADAPTERS)
620 return 0;
621 blogic_probeinfo_count++;
622 /*
623 Iterate over the MultiMaster PCI Host Adapters. For each
624 enumerated host adapter, determine whether its ISA Compatible
625 I/O Port is enabled and if so, whether it is assigned the
626 Primary I/O Address. A host adapter that is assigned the
627 Primary I/O Address will always be the preferred boot device.
628 The MultiMaster BIOS will first recognize a host adapter at
629 the Primary I/O Address, then any other PCI host adapters,
630 and finally any host adapters located at the remaining
631 standard ISA I/O Addresses. When a PCI host adapter is found
632 with its ISA Compatible I/O Port enabled, a command is issued
633 to disable the ISA Compatible I/O Port, and it is noted that the
634 particular standard ISA I/O Address need not be probed.
635 */
636 pr_probeinfo->io_addr = 0;
637 while ((pci_device = pci_get_device(PCI_VENDOR_ID_BUSLOGIC,
638 PCI_DEVICE_ID_BUSLOGIC_MULTIMASTER,
639 pci_device)) != NULL) {
640 struct blogic_adapter *host_adapter = adapter;
641 struct blogic_adapter_info adapter_info;
642 enum blogic_isa_ioport mod_ioaddr_req;
643 unsigned char bus;
644 unsigned char device;
645 unsigned int irq_ch;
646 unsigned long base_addr0;
647 unsigned long base_addr1;
648 unsigned long io_addr;
649 unsigned long pci_addr;
650
651 if (pci_enable_device(pci_device))
652 continue;
653
654 if (dma_set_mask(&pci_device->dev, DMA_BIT_MASK(32)))
655 continue;
656
657 bus = pci_device->bus->number;
658 device = pci_device->devfn >> 3;
659 irq_ch = pci_device->irq;
660 io_addr = base_addr0 = pci_resource_start(pci_device, 0);
661 pci_addr = base_addr1 = pci_resource_start(pci_device, 1);
662
663 if (pci_resource_flags(pci_device, 0) & IORESOURCE_MEM) {
664 blogic_err("BusLogic: Base Address0 0x%lX not I/O for MultiMaster Host Adapter\n", NULL, base_addr0);
665 blogic_err("at PCI Bus %d Device %d I/O Address 0x%lX\n", NULL, bus, device, io_addr);
666 continue;
667 }
668 if (pci_resource_flags(pci_device, 1) & IORESOURCE_IO) {
669 blogic_err("BusLogic: Base Address1 0x%lX not Memory for MultiMaster Host Adapter\n", NULL, base_addr1);
670 blogic_err("at PCI Bus %d Device %d PCI Address 0x%lX\n", NULL, bus, device, pci_addr);
671 continue;
672 }
673 if (irq_ch == 0) {
674 blogic_err("BusLogic: IRQ Channel %d invalid for MultiMaster Host Adapter\n", NULL, irq_ch);
675 blogic_err("at PCI Bus %d Device %d I/O Address 0x%lX\n", NULL, bus, device, io_addr);
676 continue;
677 }
678 if (blogic_global_options.trace_probe) {
679 blogic_notice("BusLogic: PCI MultiMaster Host Adapter detected at\n", NULL);
680 blogic_notice("BusLogic: PCI Bus %d Device %d I/O Address 0x%lX PCI Address 0x%lX\n", NULL, bus, device, io_addr, pci_addr);
681 }
682 /*
683 Issue the Inquire PCI Host Adapter Information command to determine
684 the ISA Compatible I/O Port. If the ISA Compatible I/O Port is
685 known and enabled, note that the particular Standard ISA I/O
686 Address should not be probed.
687 */
688 host_adapter->io_addr = io_addr;
689 blogic_intreset(host_adapter);
690 if (blogic_cmd(host_adapter, BLOGIC_INQ_PCI_INFO, NULL, 0,
691 &adapter_info, sizeof(adapter_info)) !=
692 sizeof(adapter_info))
693 adapter_info.isa_port = BLOGIC_IO_DISABLE;
694 /*
695 Issue the Modify I/O Address command to disable the
696 ISA Compatible I/O Port. On PCI Host Adapters, the
697 Modify I/O Address command allows modification of the
698 ISA compatible I/O Address that the Host Adapter
699 responds to; it does not affect the PCI compliant
700 I/O Address assigned at system initialization.
701 */
702 mod_ioaddr_req = BLOGIC_IO_DISABLE;
703 blogic_cmd(host_adapter, BLOGIC_MOD_IOADDR, &mod_ioaddr_req,
704 sizeof(mod_ioaddr_req), NULL, 0);
705 /*
706 For the first MultiMaster Host Adapter enumerated,
707 issue the Fetch Host Adapter Local RAM command to read
708 byte 45 of the AutoSCSI area, for the setting of the
709 "Use Bus And Device # For PCI Scanning Seq." option.
710 Issue the Inquire Board ID command since this option is
711 only valid for the BT-948/958/958D.
712 */
713 if (!force_scan_order_checked) {
714 struct blogic_fetch_localram fetch_localram;
715 struct blogic_autoscsi_byte45 autoscsi_byte45;
716 struct blogic_board_id id;
717
718 fetch_localram.offset = BLOGIC_AUTOSCSI_BASE + 45;
719 fetch_localram.count = sizeof(autoscsi_byte45);
720 blogic_cmd(host_adapter, BLOGIC_FETCH_LOCALRAM,
721 &fetch_localram, sizeof(fetch_localram),
722 &autoscsi_byte45,
723 sizeof(autoscsi_byte45));
724 blogic_cmd(host_adapter, BLOGIC_GET_BOARD_ID, NULL, 0,
725 &id, sizeof(id));
726 if (id.fw_ver_digit1 == '5')
727 force_scan_order =
728 autoscsi_byte45.force_scan_order;
729 force_scan_order_checked = true;
730 }
731 /*
732 Determine whether this MultiMaster Host Adapter has its
733 ISA Compatible I/O Port enabled and is assigned the
734 Primary I/O Address. If it does, then it is the Primary
735 MultiMaster Host Adapter and must be recognized first.
736 If it does not, then it is added to the list for probing
737 after any Primary MultiMaster Host Adapter is probed.
738 */
739 if (adapter_info.isa_port == BLOGIC_IO_330) {
740 pr_probeinfo->adapter_type = BLOGIC_MULTIMASTER;
741 pr_probeinfo->adapter_bus_type = BLOGIC_PCI_BUS;
742 pr_probeinfo->io_addr = io_addr;
743 pr_probeinfo->pci_addr = pci_addr;
744 pr_probeinfo->bus = bus;
745 pr_probeinfo->dev = device;
746 pr_probeinfo->irq_ch = irq_ch;
747 pr_probeinfo->pci_device = pci_dev_get(pci_device);
748 mmcount++;
749 } else if (blogic_probeinfo_count < BLOGIC_MAX_ADAPTERS) {
750 struct blogic_probeinfo *probeinfo =
751 &blogic_probeinfo_list[blogic_probeinfo_count++];
752 probeinfo->adapter_type = BLOGIC_MULTIMASTER;
753 probeinfo->adapter_bus_type = BLOGIC_PCI_BUS;
754 probeinfo->io_addr = io_addr;
755 probeinfo->pci_addr = pci_addr;
756 probeinfo->bus = bus;
757 probeinfo->dev = device;
758 probeinfo->irq_ch = irq_ch;
759 probeinfo->pci_device = pci_dev_get(pci_device);
760 nonpr_mmcount++;
761 mmcount++;
762 } else
763 blogic_warn("BusLogic: Too many Host Adapters detected\n", NULL);
764 }
765 /*
766 If the AutoSCSI "Use Bus And Device # For PCI Scanning Seq."
767 option is ON for the first enumerated MultiMaster Host Adapter,
768 and if that host adapter is a BT-948/958/958D, then the
769 MultiMaster BIOS will recognize MultiMaster Host Adapters in
770 the order of increasing PCI Bus and Device Number. In that case,
771 sort the probe information into the same order the BIOS uses.
772 If this option is OFF, then the MultiMaster BIOS will recognize
773 MultiMaster Host Adapters in the order they are enumerated by
774 the PCI BIOS, and hence no sorting is necessary.
775 */
776 if (force_scan_order)
777 blogic_sort_probeinfo(&blogic_probeinfo_list[nonpr_mmindex],
778 nonpr_mmcount);
779 /*
780 Iterate over the older non-compliant MultiMaster PCI Host Adapters,
781 noting the PCI bus location and assigned IRQ Channel.
782 */
783 pci_device = NULL;
784 while ((pci_device = pci_get_device(PCI_VENDOR_ID_BUSLOGIC,
785 PCI_DEVICE_ID_BUSLOGIC_MULTIMASTER_NC,
786 pci_device)) != NULL) {
787 unsigned char bus;
788 unsigned char device;
789 unsigned int irq_ch;
790 unsigned long io_addr;
791
792 if (pci_enable_device(pci_device))
793 continue;
794
795 if (dma_set_mask(&pci_device->dev, DMA_BIT_MASK(32)))
796 continue;
797
798 bus = pci_device->bus->number;
799 device = pci_device->devfn >> 3;
800 irq_ch = pci_device->irq;
801 io_addr = pci_resource_start(pci_device, 0);
802
803 if (io_addr == 0 || irq_ch == 0)
804 continue;
805 for (i = 0; i < blogic_probeinfo_count; i++) {
806 struct blogic_probeinfo *probeinfo =
807 &blogic_probeinfo_list[i];
808 if (probeinfo->io_addr == io_addr &&
809 probeinfo->adapter_type == BLOGIC_MULTIMASTER) {
810 probeinfo->adapter_bus_type = BLOGIC_PCI_BUS;
811 probeinfo->pci_addr = 0;
812 probeinfo->bus = bus;
813 probeinfo->dev = device;
814 probeinfo->irq_ch = irq_ch;
815 probeinfo->pci_device = pci_dev_get(pci_device);
816 break;
817 }
818 }
819 }
820 return mmcount;
821}
822
823
824/*
825 blogic_init_fp_probeinfo initializes the list of I/O Address
826 and Bus Probe Information to be checked for potential BusLogic FlashPoint
827 Host Adapters by interrogating the PCI Configuration Space. It returns the
828 number of FlashPoint Host Adapters found.
829*/
830
831static int __init blogic_init_fp_probeinfo(struct blogic_adapter *adapter)
832{
833 int fpindex = blogic_probeinfo_count, fpcount = 0;
834 struct pci_dev *pci_device = NULL;
835 /*
836 Interrogate PCI Configuration Space for any FlashPoint Host Adapters.
837 */
838 while ((pci_device = pci_get_device(PCI_VENDOR_ID_BUSLOGIC,
839 PCI_DEVICE_ID_BUSLOGIC_FLASHPOINT,
840 pci_device)) != NULL) {
841 unsigned char bus;
842 unsigned char device;
843 unsigned int irq_ch;
844 unsigned long base_addr0;
845 unsigned long base_addr1;
846 unsigned long io_addr;
847 unsigned long pci_addr;
848
849 if (pci_enable_device(pci_device))
850 continue;
851
852 if (dma_set_mask(&pci_device->dev, DMA_BIT_MASK(32)))
853 continue;
854
855 bus = pci_device->bus->number;
856 device = pci_device->devfn >> 3;
857 irq_ch = pci_device->irq;
858 io_addr = base_addr0 = pci_resource_start(pci_device, 0);
859 pci_addr = base_addr1 = pci_resource_start(pci_device, 1);
860#ifdef CONFIG_SCSI_FLASHPOINT
861 if (pci_resource_flags(pci_device, 0) & IORESOURCE_MEM) {
862 blogic_err("BusLogic: Base Address0 0x%lX not I/O for FlashPoint Host Adapter\n", NULL, base_addr0);
863 blogic_err("at PCI Bus %d Device %d I/O Address 0x%lX\n", NULL, bus, device, io_addr);
864 continue;
865 }
866 if (pci_resource_flags(pci_device, 1) & IORESOURCE_IO) {
867 blogic_err("BusLogic: Base Address1 0x%lX not Memory for FlashPoint Host Adapter\n", NULL, base_addr1);
868 blogic_err("at PCI Bus %d Device %d PCI Address 0x%lX\n", NULL, bus, device, pci_addr);
869 continue;
870 }
871 if (irq_ch == 0) {
872 blogic_err("BusLogic: IRQ Channel %d invalid for FlashPoint Host Adapter\n", NULL, irq_ch);
873 blogic_err("at PCI Bus %d Device %d I/O Address 0x%lX\n", NULL, bus, device, io_addr);
874 continue;
875 }
876 if (blogic_global_options.trace_probe) {
877 blogic_notice("BusLogic: FlashPoint Host Adapter detected at\n", NULL);
878 blogic_notice("BusLogic: PCI Bus %d Device %d I/O Address 0x%lX PCI Address 0x%lX\n", NULL, bus, device, io_addr, pci_addr);
879 }
880 if (blogic_probeinfo_count < BLOGIC_MAX_ADAPTERS) {
881 struct blogic_probeinfo *probeinfo =
882 &blogic_probeinfo_list[blogic_probeinfo_count++];
883 probeinfo->adapter_type = BLOGIC_FLASHPOINT;
884 probeinfo->adapter_bus_type = BLOGIC_PCI_BUS;
885 probeinfo->io_addr = io_addr;
886 probeinfo->pci_addr = pci_addr;
887 probeinfo->bus = bus;
888 probeinfo->dev = device;
889 probeinfo->irq_ch = irq_ch;
890 probeinfo->pci_device = pci_dev_get(pci_device);
891 fpcount++;
892 } else
893 blogic_warn("BusLogic: Too many Host Adapters detected\n", NULL);
894#else
895 blogic_err("BusLogic: FlashPoint Host Adapter detected at PCI Bus %d Device %d\n", NULL, bus, device);
896 blogic_err("BusLogic: I/O Address 0x%lX PCI Address 0x%lX, irq %d, but FlashPoint\n", NULL, io_addr, pci_addr, irq_ch);
897 blogic_err("BusLogic: support was omitted in this kernel configuration.\n", NULL);
898#endif
899 }
900 /*
901 The FlashPoint BIOS will scan for FlashPoint Host Adapters in the order of
902 increasing PCI Bus and Device Number, so sort the probe information into
903 the same order the BIOS uses.
904 */
905 blogic_sort_probeinfo(&blogic_probeinfo_list[fpindex], fpcount);
906 return fpcount;
907}
908
909
910/*
911 blogic_init_probeinfo_list initializes the list of I/O Address and Bus
912 Probe Information to be checked for potential BusLogic SCSI Host Adapters by
913 interrogating the PCI Configuration Space on PCI machines as well as from the
914 list of standard BusLogic MultiMaster ISA I/O Addresses. By default, if both
915 FlashPoint and PCI MultiMaster Host Adapters are present, this driver will
916 probe for FlashPoint Host Adapters first unless the BIOS primary disk is
917 controlled by the first PCI MultiMaster Host Adapter, in which case
918 MultiMaster Host Adapters will be probed first. The BusLogic Driver Options
919 specifications "MultiMasterFirst" and "FlashPointFirst" can be used to force
920 a particular probe order.
921*/
922
923static void __init blogic_init_probeinfo_list(struct blogic_adapter *adapter)
924{
925 /*
926 If a PCI BIOS is present, interrogate it for MultiMaster and
927 FlashPoint Host Adapters; otherwise, default to the standard
928 ISA MultiMaster probe.
929 */
930 if (!blogic_probe_options.noprobe_pci) {
931 if (blogic_probe_options.multimaster_first) {
932 blogic_init_mm_probeinfo(adapter);
933 blogic_init_fp_probeinfo(adapter);
934 } else if (blogic_probe_options.flashpoint_first) {
935 blogic_init_fp_probeinfo(adapter);
936 blogic_init_mm_probeinfo(adapter);
937 } else {
938 int fpcount = blogic_init_fp_probeinfo(adapter);
939 int mmcount = blogic_init_mm_probeinfo(adapter);
940 if (fpcount > 0 && mmcount > 0) {
941 struct blogic_probeinfo *probeinfo =
942 &blogic_probeinfo_list[fpcount];
943 struct blogic_adapter *myadapter = adapter;
944 struct blogic_fetch_localram fetch_localram;
945 struct blogic_bios_drvmap d0_mapbyte;
946
947 while (probeinfo->adapter_bus_type !=
948 BLOGIC_PCI_BUS)
949 probeinfo++;
950 myadapter->io_addr = probeinfo->io_addr;
951 fetch_localram.offset =
952 BLOGIC_BIOS_BASE + BLOGIC_BIOS_DRVMAP;
953 fetch_localram.count = sizeof(d0_mapbyte);
954 blogic_cmd(myadapter, BLOGIC_FETCH_LOCALRAM,
955 &fetch_localram,
956 sizeof(fetch_localram),
957 &d0_mapbyte,
958 sizeof(d0_mapbyte));
959 /*
960 If the Map Byte for BIOS Drive 0 indicates
961 that BIOS Drive 0 is controlled by this
962 PCI MultiMaster Host Adapter, then reverse
963 the probe order so that MultiMaster Host
964 Adapters are probed before FlashPoint Host
965 Adapters.
966 */
967 if (d0_mapbyte.diskgeom != BLOGIC_BIOS_NODISK) {
968 struct blogic_probeinfo saved_probeinfo[BLOGIC_MAX_ADAPTERS];
969 int mmcount = blogic_probeinfo_count - fpcount;
970
971 memcpy(saved_probeinfo,
972 blogic_probeinfo_list,
973 blogic_probeinfo_count * sizeof(struct blogic_probeinfo));
974 memcpy(&blogic_probeinfo_list[0],
975 &saved_probeinfo[fpcount],
976 mmcount * sizeof(struct blogic_probeinfo));
977 memcpy(&blogic_probeinfo_list[mmcount],
978 &saved_probeinfo[0],
979 fpcount * sizeof(struct blogic_probeinfo));
980 }
981 }
982 }
983 }
984}
985
986
987/*
988 blogic_failure prints a standardized error message, and then returns false.
989*/
990
991static bool blogic_failure(struct blogic_adapter *adapter, char *msg)
992{
993 blogic_announce_drvr(adapter);
994 if (adapter->adapter_bus_type == BLOGIC_PCI_BUS) {
995 blogic_err("While configuring BusLogic PCI Host Adapter at\n",
996 adapter);
997 blogic_err("Bus %d Device %d I/O Address 0x%lX PCI Address 0x%lX:\n", adapter, adapter->bus, adapter->dev, adapter->io_addr, adapter->pci_addr);
998 } else
999 blogic_err("While configuring BusLogic Host Adapter at I/O Address 0x%lX:\n", adapter, adapter->io_addr);
1000 blogic_err("%s FAILED - DETACHING\n", adapter, msg);
1001 if (blogic_cmd_failure_reason != NULL)
1002 blogic_err("ADDITIONAL FAILURE INFO - %s\n", adapter,
1003 blogic_cmd_failure_reason);
1004 return false;
1005}
1006
1007
1008/*
1009 blogic_probe probes for a BusLogic Host Adapter.
1010*/
1011
1012static bool __init blogic_probe(struct blogic_adapter *adapter)
1013{
1014 union blogic_stat_reg statusreg;
1015 union blogic_int_reg intreg;
1016 union blogic_geo_reg georeg;
1017 /*
1018 FlashPoint Host Adapters are Probed by the FlashPoint SCCB Manager.
1019 */
1020 if (blogic_flashpoint_type(adapter)) {
1021 struct fpoint_info *fpinfo = &adapter->fpinfo;
1022 fpinfo->base_addr = (u32) adapter->io_addr;
1023 fpinfo->irq_ch = adapter->irq_ch;
1024 fpinfo->present = false;
1025 if (!(FlashPoint_ProbeHostAdapter(fpinfo) == 0 &&
1026 fpinfo->present)) {
1027 blogic_err("BusLogic: FlashPoint Host Adapter detected at PCI Bus %d Device %d\n", adapter, adapter->bus, adapter->dev);
1028 blogic_err("BusLogic: I/O Address 0x%lX PCI Address 0x%lX, but FlashPoint\n", adapter, adapter->io_addr, adapter->pci_addr);
1029 blogic_err("BusLogic: Probe Function failed to validate it.\n", adapter);
1030 return false;
1031 }
1032 if (blogic_global_options.trace_probe)
1033 blogic_notice("BusLogic_Probe(0x%lX): FlashPoint Found\n", adapter, adapter->io_addr);
1034 /*
1035 Indicate the Host Adapter Probe completed successfully.
1036 */
1037 return true;
1038 }
1039 /*
1040 Read the Status, Interrupt, and Geometry Registers to test if there are I/O
1041 ports that respond, and to check the values to determine if they are from a
1042 BusLogic Host Adapter. A nonexistent I/O port will return 0xFF, in which
1043 case there is definitely no BusLogic Host Adapter at this base I/O Address.
1044 The test here is a subset of that used by the BusLogic Host Adapter BIOS.
1045 */
1046 statusreg.all = blogic_rdstatus(adapter);
1047 intreg.all = blogic_rdint(adapter);
1048 georeg.all = blogic_rdgeom(adapter);
1049 if (blogic_global_options.trace_probe)
1050 blogic_notice("BusLogic_Probe(0x%lX): Status 0x%02X, Interrupt 0x%02X, Geometry 0x%02X\n", adapter, adapter->io_addr, statusreg.all, intreg.all, georeg.all);
1051 if (statusreg.all == 0 || statusreg.sr.diag_active ||
1052 statusreg.sr.cmd_param_busy || statusreg.sr.rsvd ||
1053 statusreg.sr.cmd_invalid || intreg.ir.rsvd != 0)
1054 return false;
1055 /*
1056 Check the undocumented Geometry Register to test if there is
1057 an I/O port that responded. Adaptec Host Adapters do not
1058 implement the Geometry Register, so this test helps serve to
1059 avoid incorrectly recognizing an Adaptec 1542A or 1542B as a
1060 BusLogic. Unfortunately, the Adaptec 1542C series does respond
1061 to the Geometry Register I/O port, but it will be rejected
1062 later when the Inquire Extended Setup Information command is
1063 issued in blogic_checkadapter. The AMI FastDisk Host Adapter
1064 is a BusLogic clone that implements the same interface as
1065 earlier BusLogic Host Adapters, including the undocumented
1066 commands, and is therefore supported by this driver. However,
1067 the AMI FastDisk always returns 0x00 upon reading the Geometry
1068 Register, so the extended translation option should always be
1069 left disabled on the AMI FastDisk.
1070 */
1071 if (georeg.all == 0xFF)
1072 return false;
1073 /*
1074 Indicate the Host Adapter Probe completed successfully.
1075 */
1076 return true;
1077}
1078
1079
1080/*
1081 blogic_hwreset issues a Hardware Reset to the Host Adapter
1082 and waits for Host Adapter Diagnostics to complete. If hard_reset is true, a
1083 Hard Reset is performed which also initiates a SCSI Bus Reset. Otherwise, a
1084 Soft Reset is performed which only resets the Host Adapter without forcing a
1085 SCSI Bus Reset.
1086*/
1087
1088static bool blogic_hwreset(struct blogic_adapter *adapter, bool hard_reset)
1089{
1090 union blogic_stat_reg statusreg;
1091 int timeout;
1092 /*
1093 FlashPoint Host Adapters are Hard Reset by the FlashPoint
1094 SCCB Manager.
1095 */
1096 if (blogic_flashpoint_type(adapter)) {
1097 struct fpoint_info *fpinfo = &adapter->fpinfo;
1098 fpinfo->softreset = !hard_reset;
1099 fpinfo->report_underrun = true;
1100 adapter->cardhandle =
1101 FlashPoint_HardwareResetHostAdapter(fpinfo);
1102 if (adapter->cardhandle == (void *)FPOINT_BADCARD_HANDLE)
1103 return false;
1104 /*
1105 Indicate the Host Adapter Hard Reset completed successfully.
1106 */
1107 return true;
1108 }
1109 /*
1110 Issue a Hard Reset or Soft Reset Command to the Host Adapter.
1111 The Host Adapter should respond by setting Diagnostic Active in
1112 the Status Register.
1113 */
1114 if (hard_reset)
1115 blogic_hardreset(adapter);
1116 else
1117 blogic_softreset(adapter);
1118 /*
1119 Wait until Diagnostic Active is set in the Status Register.
1120 */
1121 timeout = 5 * 10000;
1122 while (--timeout >= 0) {
1123 statusreg.all = blogic_rdstatus(adapter);
1124 if (statusreg.sr.diag_active)
1125 break;
1126 udelay(100);
1127 }
1128 if (blogic_global_options.trace_hw_reset)
1129 blogic_notice("BusLogic_HardwareReset(0x%lX): Diagnostic Active, Status 0x%02X\n", adapter, adapter->io_addr, statusreg.all);
1130 if (timeout < 0)
1131 return false;
1132 /*
1133 Wait 100 microseconds to allow completion of any initial diagnostic
1134 activity which might leave the contents of the Status Register
1135 unpredictable.
1136 */
1137 udelay(100);
1138 /*
1139 Wait until Diagnostic Active is reset in the Status Register.
1140 */
1141 timeout = 10 * 10000;
1142 while (--timeout >= 0) {
1143 statusreg.all = blogic_rdstatus(adapter);
1144 if (!statusreg.sr.diag_active)
1145 break;
1146 udelay(100);
1147 }
1148 if (blogic_global_options.trace_hw_reset)
1149 blogic_notice("BusLogic_HardwareReset(0x%lX): Diagnostic Completed, Status 0x%02X\n", adapter, adapter->io_addr, statusreg.all);
1150 if (timeout < 0)
1151 return false;
1152 /*
1153 Wait until at least one of the Diagnostic Failure, Host Adapter
1154 Ready, or Data In Register Ready bits is set in the Status Register.
1155 */
1156 timeout = 10000;
1157 while (--timeout >= 0) {
1158 statusreg.all = blogic_rdstatus(adapter);
1159 if (statusreg.sr.diag_failed || statusreg.sr.adapter_ready ||
1160 statusreg.sr.datain_ready)
1161 break;
1162 udelay(100);
1163 }
1164 if (blogic_global_options.trace_hw_reset)
1165 blogic_notice("BusLogic_HardwareReset(0x%lX): Host Adapter Ready, Status 0x%02X\n", adapter, adapter->io_addr, statusreg.all);
1166 if (timeout < 0)
1167 return false;
1168 /*
1169 If Diagnostic Failure is set or Host Adapter Ready is reset,
1170 then an error occurred during the Host Adapter diagnostics.
1171 If Data In Register Ready is set, then there is an Error Code
1172 available.
1173 */
1174 if (statusreg.sr.diag_failed || !statusreg.sr.adapter_ready) {
1175 blogic_cmd_failure_reason = NULL;
1176 blogic_failure(adapter, "HARD RESET DIAGNOSTICS");
1177 blogic_err("HOST ADAPTER STATUS REGISTER = %02X\n", adapter,
1178 statusreg.all);
1179 if (statusreg.sr.datain_ready)
1180 blogic_err("HOST ADAPTER ERROR CODE = %d\n", adapter,
1181 blogic_rddatain(adapter));
1182 return false;
1183 }
1184 /*
1185 Indicate the Host Adapter Hard Reset completed successfully.
1186 */
1187 return true;
1188}
1189
1190
1191/*
1192 blogic_checkadapter checks to be sure this really is a BusLogic
1193 Host Adapter.
1194*/
1195
1196static bool __init blogic_checkadapter(struct blogic_adapter *adapter)
1197{
1198 struct blogic_ext_setup ext_setupinfo;
1199 unsigned char req_replylen;
1200 bool result = true;
1201 /*
1202 FlashPoint Host Adapters do not require this protection.
1203 */
1204 if (blogic_flashpoint_type(adapter))
1205 return true;
1206 /*
1207 Issue the Inquire Extended Setup Information command. Only genuine
1208 BusLogic Host Adapters and true clones support this command.
1209 Adaptec 1542C series Host Adapters that respond to the Geometry
1210 Register I/O port will fail this command.
1211 */
1212 req_replylen = sizeof(ext_setupinfo);
1213 if (blogic_cmd(adapter, BLOGIC_INQ_EXTSETUP, &req_replylen,
1214 sizeof(req_replylen), &ext_setupinfo,
1215 sizeof(ext_setupinfo)) != sizeof(ext_setupinfo))
1216 result = false;
1217 /*
1218 Provide tracing information if requested and return.
1219 */
1220 if (blogic_global_options.trace_probe)
1221 blogic_notice("BusLogic_Check(0x%lX): MultiMaster %s\n", adapter,
1222 adapter->io_addr,
1223 (result ? "Found" : "Not Found"));
1224 return result;
1225}
1226
1227
1228/*
1229 blogic_rdconfig reads the Configuration Information
1230 from Host Adapter and initializes the Host Adapter structure.
1231*/
1232
1233static bool __init blogic_rdconfig(struct blogic_adapter *adapter)
1234{
1235 struct blogic_board_id id;
1236 struct blogic_config config;
1237 struct blogic_setup_info setupinfo;
1238 struct blogic_ext_setup ext_setupinfo;
1239 unsigned char model[5];
1240 unsigned char fw_ver_digit3;
1241 unsigned char fw_ver_letter;
1242 struct blogic_adapter_info adapter_info;
1243 struct blogic_fetch_localram fetch_localram;
1244 struct blogic_autoscsi autoscsi;
1245 union blogic_geo_reg georeg;
1246 unsigned char req_replylen;
1247 unsigned char *tgt, ch;
1248 int tgt_id, i;
1249 /*
1250 Configuration Information for FlashPoint Host Adapters is
1251 provided in the fpoint_info structure by the FlashPoint
1252 SCCB Manager's Probe Function. Initialize fields in the
1253 Host Adapter structure from the fpoint_info structure.
1254 */
1255 if (blogic_flashpoint_type(adapter)) {
1256 struct fpoint_info *fpinfo = &adapter->fpinfo;
1257 tgt = adapter->model;
1258 *tgt++ = 'B';
1259 *tgt++ = 'T';
1260 *tgt++ = '-';
1261 for (i = 0; i < sizeof(fpinfo->model); i++)
1262 *tgt++ = fpinfo->model[i];
1263 *tgt++ = '\0';
1264 strcpy(adapter->fw_ver, FLASHPOINT_FW_VER);
1265 adapter->scsi_id = fpinfo->scsi_id;
1266 adapter->ext_trans_enable = fpinfo->ext_trans_enable;
1267 adapter->parity = fpinfo->parity;
1268 adapter->reset_enabled = !fpinfo->softreset;
1269 adapter->level_int = true;
1270 adapter->wide = fpinfo->wide;
1271 adapter->differential = false;
1272 adapter->scam = true;
1273 adapter->ultra = true;
1274 adapter->ext_lun = true;
1275 adapter->terminfo_valid = true;
1276 adapter->low_term = fpinfo->low_term;
1277 adapter->high_term = fpinfo->high_term;
1278 adapter->scam_enabled = fpinfo->scam_enabled;
1279 adapter->scam_lev2 = fpinfo->scam_lev2;
1280 adapter->drvr_sglimit = BLOGIC_SG_LIMIT;
1281 adapter->maxdev = (adapter->wide ? 16 : 8);
1282 adapter->maxlun = 32;
1283 adapter->initccbs = 4 * BLOGIC_CCB_GRP_ALLOCSIZE;
1284 adapter->inc_ccbs = BLOGIC_CCB_GRP_ALLOCSIZE;
1285 adapter->drvr_qdepth = 255;
1286 adapter->adapter_qdepth = adapter->drvr_qdepth;
1287 adapter->sync_ok = fpinfo->sync_ok;
1288 adapter->fast_ok = fpinfo->fast_ok;
1289 adapter->ultra_ok = fpinfo->ultra_ok;
1290 adapter->wide_ok = fpinfo->wide_ok;
1291 adapter->discon_ok = fpinfo->discon_ok;
1292 adapter->tagq_ok = 0xFFFF;
1293 goto common;
1294 }
1295 /*
1296 Issue the Inquire Board ID command.
1297 */
1298 if (blogic_cmd(adapter, BLOGIC_GET_BOARD_ID, NULL, 0, &id,
1299 sizeof(id)) != sizeof(id))
1300 return blogic_failure(adapter, "INQUIRE BOARD ID");
1301 /*
1302 Issue the Inquire Configuration command.
1303 */
1304 if (blogic_cmd(adapter, BLOGIC_INQ_CONFIG, NULL, 0, &config,
1305 sizeof(config))
1306 != sizeof(config))
1307 return blogic_failure(adapter, "INQUIRE CONFIGURATION");
1308 /*
1309 Issue the Inquire Setup Information command.
1310 */
1311 req_replylen = sizeof(setupinfo);
1312 if (blogic_cmd(adapter, BLOGIC_INQ_SETUPINFO, &req_replylen,
1313 sizeof(req_replylen), &setupinfo,
1314 sizeof(setupinfo)) != sizeof(setupinfo))
1315 return blogic_failure(adapter, "INQUIRE SETUP INFORMATION");
1316 /*
1317 Issue the Inquire Extended Setup Information command.
1318 */
1319 req_replylen = sizeof(ext_setupinfo);
1320 if (blogic_cmd(adapter, BLOGIC_INQ_EXTSETUP, &req_replylen,
1321 sizeof(req_replylen), &ext_setupinfo,
1322 sizeof(ext_setupinfo)) != sizeof(ext_setupinfo))
1323 return blogic_failure(adapter,
1324 "INQUIRE EXTENDED SETUP INFORMATION");
1325 /*
1326 Issue the Inquire Firmware Version 3rd Digit command.
1327 */
1328 fw_ver_digit3 = '\0';
1329 if (id.fw_ver_digit1 > '0')
1330 if (blogic_cmd(adapter, BLOGIC_INQ_FWVER_D3, NULL, 0,
1331 &fw_ver_digit3,
1332 sizeof(fw_ver_digit3)) != sizeof(fw_ver_digit3))
1333 return blogic_failure(adapter,
1334 "INQUIRE FIRMWARE 3RD DIGIT");
1335 /*
1336 Issue the Inquire Host Adapter Model Number command.
1337 */
1338 if (ext_setupinfo.bus_type == 'A' && id.fw_ver_digit1 == '2')
1339 /* BusLogic BT-542B ISA 2.xx */
1340 strcpy(model, "542B");
1341 else if (ext_setupinfo.bus_type == 'E' && id.fw_ver_digit1 == '2' &&
1342 (id.fw_ver_digit2 <= '1' || (id.fw_ver_digit2 == '2' &&
1343 fw_ver_digit3 == '0')))
1344 /* BusLogic BT-742A EISA 2.1x or 2.20 */
1345 strcpy(model, "742A");
1346 else if (ext_setupinfo.bus_type == 'E' && id.fw_ver_digit1 == '0')
1347 /* AMI FastDisk EISA Series 441 0.x */
1348 strcpy(model, "747A");
1349 else {
1350 req_replylen = sizeof(model);
1351 if (blogic_cmd(adapter, BLOGIC_INQ_MODELNO, &req_replylen,
1352 sizeof(req_replylen), &model,
1353 sizeof(model)) != sizeof(model))
1354 return blogic_failure(adapter,
1355 "INQUIRE HOST ADAPTER MODEL NUMBER");
1356 }
1357 /*
1358 BusLogic MultiMaster Host Adapters can be identified by their
1359 model number and the major version number of their firmware
1360 as follows:
1361
1362 5.xx BusLogic "W" Series Host Adapters:
1363 BT-948/958/958D
1364 4.xx BusLogic "C" Series Host Adapters:
1365 BT-946C/956C/956CD/747C/757C/757CD/445C/545C/540CF
1366 3.xx BusLogic "S" Series Host Adapters:
1367 BT-747S/747D/757S/757D/445S/545S/542D
1368 BT-542B/742A (revision H)
1369 2.xx BusLogic "A" Series Host Adapters:
1370 BT-542B/742A (revision G and below)
1371 0.xx AMI FastDisk VLB/EISA BusLogic Clone Host Adapter
1372 */
1373 /*
1374 Save the Model Name and Host Adapter Name in the Host Adapter
1375 structure.
1376 */
1377 tgt = adapter->model;
1378 *tgt++ = 'B';
1379 *tgt++ = 'T';
1380 *tgt++ = '-';
1381 for (i = 0; i < sizeof(model); i++) {
1382 ch = model[i];
1383 if (ch == ' ' || ch == '\0')
1384 break;
1385 *tgt++ = ch;
1386 }
1387 *tgt++ = '\0';
1388 /*
1389 Save the Firmware Version in the Host Adapter structure.
1390 */
1391 tgt = adapter->fw_ver;
1392 *tgt++ = id.fw_ver_digit1;
1393 *tgt++ = '.';
1394 *tgt++ = id.fw_ver_digit2;
1395 if (fw_ver_digit3 != ' ' && fw_ver_digit3 != '\0')
1396 *tgt++ = fw_ver_digit3;
1397 *tgt = '\0';
1398 /*
1399 Issue the Inquire Firmware Version Letter command.
1400 */
1401 if (strcmp(adapter->fw_ver, "3.3") >= 0) {
1402 if (blogic_cmd(adapter, BLOGIC_INQ_FWVER_LETTER, NULL, 0,
1403 &fw_ver_letter,
1404 sizeof(fw_ver_letter)) != sizeof(fw_ver_letter))
1405 return blogic_failure(adapter,
1406 "INQUIRE FIRMWARE VERSION LETTER");
1407 if (fw_ver_letter != ' ' && fw_ver_letter != '\0')
1408 *tgt++ = fw_ver_letter;
1409 *tgt = '\0';
1410 }
1411 /*
1412 Save the Host Adapter SCSI ID in the Host Adapter structure.
1413 */
1414 adapter->scsi_id = config.id;
1415 /*
1416 Determine the Bus Type and save it in the Host Adapter structure,
1417 determine and save the IRQ Channel if necessary, and determine
1418 and save the DMA Channel for ISA Host Adapters.
1419 */
1420 adapter->adapter_bus_type =
1421 blogic_adater_bus_types[adapter->model[3] - '4'];
1422 if (adapter->irq_ch == 0) {
1423 if (config.irq_ch9)
1424 adapter->irq_ch = 9;
1425 else if (config.irq_ch10)
1426 adapter->irq_ch = 10;
1427 else if (config.irq_ch11)
1428 adapter->irq_ch = 11;
1429 else if (config.irq_ch12)
1430 adapter->irq_ch = 12;
1431 else if (config.irq_ch14)
1432 adapter->irq_ch = 14;
1433 else if (config.irq_ch15)
1434 adapter->irq_ch = 15;
1435 }
1436 /*
1437 Determine whether Extended Translation is enabled and save it in
1438 the Host Adapter structure.
1439 */
1440 georeg.all = blogic_rdgeom(adapter);
1441 adapter->ext_trans_enable = georeg.gr.ext_trans_enable;
1442 /*
1443 Save the Scatter Gather Limits, Level Sensitive Interrupt flag, Wide
1444 SCSI flag, Differential SCSI flag, SCAM Supported flag, and
1445 Ultra SCSI flag in the Host Adapter structure.
1446 */
1447 adapter->adapter_sglimit = ext_setupinfo.sg_limit;
1448 adapter->drvr_sglimit = adapter->adapter_sglimit;
1449 if (adapter->adapter_sglimit > BLOGIC_SG_LIMIT)
1450 adapter->drvr_sglimit = BLOGIC_SG_LIMIT;
1451 if (ext_setupinfo.misc.level_int)
1452 adapter->level_int = true;
1453 adapter->wide = ext_setupinfo.wide;
1454 adapter->differential = ext_setupinfo.differential;
1455 adapter->scam = ext_setupinfo.scam;
1456 adapter->ultra = ext_setupinfo.ultra;
1457 /*
1458 Determine whether Extended LUN Format CCBs are supported and save the
1459 information in the Host Adapter structure.
1460 */
1461 if (adapter->fw_ver[0] == '5' || (adapter->fw_ver[0] == '4' &&
1462 adapter->wide))
1463 adapter->ext_lun = true;
1464 /*
1465 Issue the Inquire PCI Host Adapter Information command to read the
1466 Termination Information from "W" series MultiMaster Host Adapters.
1467 */
1468 if (adapter->fw_ver[0] == '5') {
1469 if (blogic_cmd(adapter, BLOGIC_INQ_PCI_INFO, NULL, 0,
1470 &adapter_info,
1471 sizeof(adapter_info)) != sizeof(adapter_info))
1472 return blogic_failure(adapter,
1473 "INQUIRE PCI HOST ADAPTER INFORMATION");
1474 /*
1475 Save the Termination Information in the Host Adapter
1476 structure.
1477 */
1478 if (adapter_info.genericinfo_valid) {
1479 adapter->terminfo_valid = true;
1480 adapter->low_term = adapter_info.low_term;
1481 adapter->high_term = adapter_info.high_term;
1482 }
1483 }
1484 /*
1485 Issue the Fetch Host Adapter Local RAM command to read the
1486 AutoSCSI data from "W" and "C" series MultiMaster Host Adapters.
1487 */
1488 if (adapter->fw_ver[0] >= '4') {
1489 fetch_localram.offset = BLOGIC_AUTOSCSI_BASE;
1490 fetch_localram.count = sizeof(autoscsi);
1491 if (blogic_cmd(adapter, BLOGIC_FETCH_LOCALRAM, &fetch_localram,
1492 sizeof(fetch_localram), &autoscsi,
1493 sizeof(autoscsi)) != sizeof(autoscsi))
1494 return blogic_failure(adapter,
1495 "FETCH HOST ADAPTER LOCAL RAM");
1496 /*
1497 Save the Parity Checking Enabled, Bus Reset Enabled,
1498 and Termination Information in the Host Adapter structure.
1499 */
1500 adapter->parity = autoscsi.parity;
1501 adapter->reset_enabled = autoscsi.reset_enabled;
1502 if (adapter->fw_ver[0] == '4') {
1503 adapter->terminfo_valid = true;
1504 adapter->low_term = autoscsi.low_term;
1505 adapter->high_term = autoscsi.high_term;
1506 }
1507 /*
1508 Save the Wide Permitted, Fast Permitted, Synchronous
1509 Permitted, Disconnect Permitted, Ultra Permitted, and
1510 SCAM Information in the Host Adapter structure.
1511 */
1512 adapter->wide_ok = autoscsi.wide_ok;
1513 adapter->fast_ok = autoscsi.fast_ok;
1514 adapter->sync_ok = autoscsi.sync_ok;
1515 adapter->discon_ok = autoscsi.discon_ok;
1516 if (adapter->ultra)
1517 adapter->ultra_ok = autoscsi.ultra_ok;
1518 if (adapter->scam) {
1519 adapter->scam_enabled = autoscsi.scam_enabled;
1520 adapter->scam_lev2 = autoscsi.scam_lev2;
1521 }
1522 }
1523 /*
1524 Initialize fields in the Host Adapter structure for "S" and "A"
1525 series MultiMaster Host Adapters.
1526 */
1527 if (adapter->fw_ver[0] < '4') {
1528 if (setupinfo.sync) {
1529 adapter->sync_ok = 0xFF;
1530 if (adapter->adapter_bus_type == BLOGIC_EISA_BUS) {
1531 if (ext_setupinfo.misc.fast_on_eisa)
1532 adapter->fast_ok = 0xFF;
1533 if (strcmp(adapter->model, "BT-757") == 0)
1534 adapter->wide_ok = 0xFF;
1535 }
1536 }
1537 adapter->discon_ok = 0xFF;
1538 adapter->parity = setupinfo.parity;
1539 adapter->reset_enabled = true;
1540 }
1541 /*
1542 Determine the maximum number of Target IDs and Logical Units
1543 supported by this driver for Wide and Narrow Host Adapters.
1544 */
1545 adapter->maxdev = (adapter->wide ? 16 : 8);
1546 adapter->maxlun = (adapter->ext_lun ? 32 : 8);
1547 /*
1548 Select appropriate values for the Mailbox Count, Driver Queue Depth,
1549 Initial CCBs, and Incremental CCBs variables based on whether
1550 or not Strict Round Robin Mode is supported. If Strict Round
1551 Robin Mode is supported, then there is no performance degradation
1552 in using the maximum possible number of Outgoing and Incoming
1553 Mailboxes and allowing the Tagged and Untagged Queue Depths to
1554 determine the actual utilization. If Strict Round Robin Mode is
1555 not supported, then the Host Adapter must scan all the Outgoing
1556 Mailboxes whenever an Outgoing Mailbox entry is made, which can
1557 cause a substantial performance penalty. The host adapters
1558 actually have room to store the following number of CCBs
1559 internally; that is, they can internally queue and manage this
1560 many active commands on the SCSI bus simultaneously. Performance
1561 measurements demonstrate that the Driver Queue Depth should be
1562 set to the Mailbox Count, rather than the Host Adapter Queue
1563 Depth (internal CCB capacity), as it is more efficient to have the
1564 queued commands waiting in Outgoing Mailboxes if necessary than
1565 to block the process in the higher levels of the SCSI Subsystem.
1566
1567 192 BT-948/958/958D
1568 100 BT-946C/956C/956CD/747C/757C/757CD/445C
1569 50 BT-545C/540CF
1570 30 BT-747S/747D/757S/757D/445S/545S/542D/542B/742A
1571 */
1572 if (adapter->fw_ver[0] == '5')
1573 adapter->adapter_qdepth = 192;
1574 else if (adapter->fw_ver[0] == '4')
1575 adapter->adapter_qdepth = 100;
1576 else
1577 adapter->adapter_qdepth = 30;
1578 if (strcmp(adapter->fw_ver, "3.31") >= 0) {
1579 adapter->strict_rr = true;
1580 adapter->mbox_count = BLOGIC_MAX_MAILBOX;
1581 } else {
1582 adapter->strict_rr = false;
1583 adapter->mbox_count = 32;
1584 }
1585 adapter->drvr_qdepth = adapter->mbox_count;
1586 adapter->initccbs = 4 * BLOGIC_CCB_GRP_ALLOCSIZE;
1587 adapter->inc_ccbs = BLOGIC_CCB_GRP_ALLOCSIZE;
1588 /*
1589 Tagged Queuing support is available and operates properly on
1590 all "W" series MultiMaster Host Adapters, on "C" series
1591 MultiMaster Host Adapters with firmware version 4.22 and above,
1592 and on "S" series MultiMaster Host Adapters with firmware version
1593 3.35 and above.
1594 */
1595 adapter->tagq_ok = 0;
1596 switch (adapter->fw_ver[0]) {
1597 case '5':
1598 adapter->tagq_ok = 0xFFFF;
1599 break;
1600 case '4':
1601 if (strcmp(adapter->fw_ver, "4.22") >= 0)
1602 adapter->tagq_ok = 0xFFFF;
1603 break;
1604 case '3':
1605 if (strcmp(adapter->fw_ver, "3.35") >= 0)
1606 adapter->tagq_ok = 0xFFFF;
1607 break;
1608 }
1609 /*
1610 Determine the Host Adapter BIOS Address if the BIOS is enabled and
1611 save it in the Host Adapter structure. The BIOS is disabled if the
1612 bios_addr is 0.
1613 */
1614 adapter->bios_addr = ext_setupinfo.bios_addr << 12;
1615 /*
1616 BusLogic BT-445S Host Adapters prior to board revision E have a
1617 hardware bug whereby when the BIOS is enabled, transfers to/from
1618 the same address range the BIOS occupies modulo 16MB are handled
1619 incorrectly. Only properly functioning BT-445S Host Adapters
1620 have firmware version 3.37.
1621 */
1622 if (adapter->bios_addr > 0 &&
1623 strcmp(adapter->model, "BT-445S") == 0 &&
1624 strcmp(adapter->fw_ver, "3.37") < 0)
1625 return blogic_failure(adapter, "Too old firmware");
1626 /*
1627 Initialize parameters common to MultiMaster and FlashPoint
1628 Host Adapters.
1629 */
1630common:
1631 /*
1632 Initialize the Host Adapter Full Model Name from the Model Name.
1633 */
1634 strcpy(adapter->full_model, "BusLogic ");
1635 strcat(adapter->full_model, adapter->model);
1636 /*
1637 Select an appropriate value for the Tagged Queue Depth either from a
1638 BusLogic Driver Options specification, or based on whether this Host
1639 Adapter requires that ISA Bounce Buffers be used. The Tagged Queue
1640 Depth is left at 0 for automatic determination in
1641 BusLogic_SelectQueueDepths. Initialize the Untagged Queue Depth.
1642 */
1643 for (tgt_id = 0; tgt_id < BLOGIC_MAXDEV; tgt_id++) {
1644 unsigned char qdepth = 0;
1645 if (adapter->drvr_opts != NULL &&
1646 adapter->drvr_opts->qdepth[tgt_id] > 0)
1647 qdepth = adapter->drvr_opts->qdepth[tgt_id];
1648 adapter->qdepth[tgt_id] = qdepth;
1649 }
1650 adapter->untag_qdepth = BLOGIC_UNTAG_DEPTH;
1651 if (adapter->drvr_opts != NULL)
1652 adapter->common_qdepth = adapter->drvr_opts->common_qdepth;
1653 if (adapter->common_qdepth > 0 &&
1654 adapter->common_qdepth < adapter->untag_qdepth)
1655 adapter->untag_qdepth = adapter->common_qdepth;
1656 /*
1657 Tagged Queuing is only allowed if Disconnect/Reconnect is permitted.
1658 Therefore, mask the Tagged Queuing Permitted Default bits with the
1659 Disconnect/Reconnect Permitted bits.
1660 */
1661 adapter->tagq_ok &= adapter->discon_ok;
1662 /*
1663 Combine the default Tagged Queuing Permitted bits with any
1664 BusLogic Driver Options Tagged Queuing specification.
1665 */
1666 if (adapter->drvr_opts != NULL)
1667 adapter->tagq_ok = (adapter->drvr_opts->tagq_ok &
1668 adapter->drvr_opts->tagq_ok_mask) |
1669 (adapter->tagq_ok & ~adapter->drvr_opts->tagq_ok_mask);
1670
1671 /*
1672 Select an appropriate value for Bus Settle Time either from a
1673 BusLogic Driver Options specification, or from
1674 BLOGIC_BUS_SETTLE_TIME.
1675 */
1676 if (adapter->drvr_opts != NULL &&
1677 adapter->drvr_opts->bus_settle_time > 0)
1678 adapter->bus_settle_time = adapter->drvr_opts->bus_settle_time;
1679 else
1680 adapter->bus_settle_time = BLOGIC_BUS_SETTLE_TIME;
1681 /*
1682 Indicate reading the Host Adapter Configuration completed
1683 successfully.
1684 */
1685 return true;
1686}
1687
1688
1689/*
1690 blogic_reportconfig reports the configuration of Host Adapter.
1691*/
1692
1693static bool __init blogic_reportconfig(struct blogic_adapter *adapter)
1694{
1695 unsigned short alltgt_mask = (1 << adapter->maxdev) - 1;
1696 unsigned short sync_ok, fast_ok;
1697 unsigned short ultra_ok, wide_ok;
1698 unsigned short discon_ok, tagq_ok;
1699 bool common_syncneg, common_tagq_depth;
1700 char syncstr[BLOGIC_MAXDEV + 1];
1701 char widestr[BLOGIC_MAXDEV + 1];
1702 char discon_str[BLOGIC_MAXDEV + 1];
1703 char tagq_str[BLOGIC_MAXDEV + 1];
1704 char *syncmsg = syncstr;
1705 char *widemsg = widestr;
1706 char *discon_msg = discon_str;
1707 char *tagq_msg = tagq_str;
1708 int tgt_id;
1709
1710 blogic_info("Configuring BusLogic Model %s %s%s%s%s SCSI Host Adapter\n", adapter, adapter->model, blogic_adapter_busnames[adapter->adapter_bus_type], (adapter->wide ? " Wide" : ""), (adapter->differential ? " Differential" : ""), (adapter->ultra ? " Ultra" : ""));
1711 blogic_info(" Firmware Version: %s, I/O Address: 0x%lX, IRQ Channel: %d/%s\n", adapter, adapter->fw_ver, adapter->io_addr, adapter->irq_ch, (adapter->level_int ? "Level" : "Edge"));
1712 if (adapter->adapter_bus_type != BLOGIC_PCI_BUS) {
1713 blogic_info(" DMA Channel: None, ", adapter);
1714 if (adapter->bios_addr > 0)
1715 blogic_info("BIOS Address: 0x%X, ", adapter,
1716 adapter->bios_addr);
1717 else
1718 blogic_info("BIOS Address: None, ", adapter);
1719 } else {
1720 blogic_info(" PCI Bus: %d, Device: %d, Address: ", adapter,
1721 adapter->bus, adapter->dev);
1722 if (adapter->pci_addr > 0)
1723 blogic_info("0x%lX, ", adapter, adapter->pci_addr);
1724 else
1725 blogic_info("Unassigned, ", adapter);
1726 }
1727 blogic_info("Host Adapter SCSI ID: %d\n", adapter, adapter->scsi_id);
1728 blogic_info(" Parity Checking: %s, Extended Translation: %s\n",
1729 adapter, (adapter->parity ? "Enabled" : "Disabled"),
1730 (adapter->ext_trans_enable ? "Enabled" : "Disabled"));
1731 alltgt_mask &= ~(1 << adapter->scsi_id);
1732 sync_ok = adapter->sync_ok & alltgt_mask;
1733 fast_ok = adapter->fast_ok & alltgt_mask;
1734 ultra_ok = adapter->ultra_ok & alltgt_mask;
1735 if ((blogic_multimaster_type(adapter) &&
1736 (adapter->fw_ver[0] >= '4' ||
1737 adapter->adapter_bus_type == BLOGIC_EISA_BUS)) ||
1738 blogic_flashpoint_type(adapter)) {
1739 common_syncneg = false;
1740 if (sync_ok == 0) {
1741 syncmsg = "Disabled";
1742 common_syncneg = true;
1743 } else if (sync_ok == alltgt_mask) {
1744 if (fast_ok == 0) {
1745 syncmsg = "Slow";
1746 common_syncneg = true;
1747 } else if (fast_ok == alltgt_mask) {
1748 if (ultra_ok == 0) {
1749 syncmsg = "Fast";
1750 common_syncneg = true;
1751 } else if (ultra_ok == alltgt_mask) {
1752 syncmsg = "Ultra";
1753 common_syncneg = true;
1754 }
1755 }
1756 }
1757 if (!common_syncneg) {
1758 for (tgt_id = 0; tgt_id < adapter->maxdev; tgt_id++)
1759 syncstr[tgt_id] = ((!(sync_ok & (1 << tgt_id))) ? 'N' : (!(fast_ok & (1 << tgt_id)) ? 'S' : (!(ultra_ok & (1 << tgt_id)) ? 'F' : 'U')));
1760 syncstr[adapter->scsi_id] = '#';
1761 syncstr[adapter->maxdev] = '\0';
1762 }
1763 } else
1764 syncmsg = (sync_ok == 0 ? "Disabled" : "Enabled");
1765 wide_ok = adapter->wide_ok & alltgt_mask;
1766 if (wide_ok == 0)
1767 widemsg = "Disabled";
1768 else if (wide_ok == alltgt_mask)
1769 widemsg = "Enabled";
1770 else {
1771 for (tgt_id = 0; tgt_id < adapter->maxdev; tgt_id++)
1772 widestr[tgt_id] = ((wide_ok & (1 << tgt_id)) ? 'Y' : 'N');
1773 widestr[adapter->scsi_id] = '#';
1774 widestr[adapter->maxdev] = '\0';
1775 }
1776 discon_ok = adapter->discon_ok & alltgt_mask;
1777 if (discon_ok == 0)
1778 discon_msg = "Disabled";
1779 else if (discon_ok == alltgt_mask)
1780 discon_msg = "Enabled";
1781 else {
1782 for (tgt_id = 0; tgt_id < adapter->maxdev; tgt_id++)
1783 discon_str[tgt_id] = ((discon_ok & (1 << tgt_id)) ? 'Y' : 'N');
1784 discon_str[adapter->scsi_id] = '#';
1785 discon_str[adapter->maxdev] = '\0';
1786 }
1787 tagq_ok = adapter->tagq_ok & alltgt_mask;
1788 if (tagq_ok == 0)
1789 tagq_msg = "Disabled";
1790 else if (tagq_ok == alltgt_mask)
1791 tagq_msg = "Enabled";
1792 else {
1793 for (tgt_id = 0; tgt_id < adapter->maxdev; tgt_id++)
1794 tagq_str[tgt_id] = ((tagq_ok & (1 << tgt_id)) ? 'Y' : 'N');
1795 tagq_str[adapter->scsi_id] = '#';
1796 tagq_str[adapter->maxdev] = '\0';
1797 }
1798 blogic_info(" Synchronous Negotiation: %s, Wide Negotiation: %s\n",
1799 adapter, syncmsg, widemsg);
1800 blogic_info(" Disconnect/Reconnect: %s, Tagged Queuing: %s\n", adapter,
1801 discon_msg, tagq_msg);
1802 if (blogic_multimaster_type(adapter)) {
1803 blogic_info(" Scatter/Gather Limit: %d of %d segments, Mailboxes: %d\n", adapter, adapter->drvr_sglimit, adapter->adapter_sglimit, adapter->mbox_count);
1804 blogic_info(" Driver Queue Depth: %d, Host Adapter Queue Depth: %d\n", adapter, adapter->drvr_qdepth, adapter->adapter_qdepth);
1805 } else
1806 blogic_info(" Driver Queue Depth: %d, Scatter/Gather Limit: %d segments\n", adapter, adapter->drvr_qdepth, adapter->drvr_sglimit);
1807 blogic_info(" Tagged Queue Depth: ", adapter);
1808 common_tagq_depth = true;
1809 for (tgt_id = 1; tgt_id < adapter->maxdev; tgt_id++)
1810 if (adapter->qdepth[tgt_id] != adapter->qdepth[0]) {
1811 common_tagq_depth = false;
1812 break;
1813 }
1814 if (common_tagq_depth) {
1815 if (adapter->qdepth[0] > 0)
1816 blogic_info("%d", adapter, adapter->qdepth[0]);
1817 else
1818 blogic_info("Automatic", adapter);
1819 } else
1820 blogic_info("Individual", adapter);
1821 blogic_info(", Untagged Queue Depth: %d\n", adapter,
1822 adapter->untag_qdepth);
1823 if (adapter->terminfo_valid) {
1824 if (adapter->wide)
1825 blogic_info(" SCSI Bus Termination: %s", adapter,
1826 (adapter->low_term ? (adapter->high_term ? "Both Enabled" : "Low Enabled") : (adapter->high_term ? "High Enabled" : "Both Disabled")));
1827 else
1828 blogic_info(" SCSI Bus Termination: %s", adapter,
1829 (adapter->low_term ? "Enabled" : "Disabled"));
1830 if (adapter->scam)
1831 blogic_info(", SCAM: %s", adapter,
1832 (adapter->scam_enabled ? (adapter->scam_lev2 ? "Enabled, Level 2" : "Enabled, Level 1") : "Disabled"));
1833 blogic_info("\n", adapter);
1834 }
1835 /*
1836 Indicate reporting the Host Adapter configuration completed
1837 successfully.
1838 */
1839 return true;
1840}
1841
1842
1843/*
1844 blogic_getres acquires the system resources necessary to use
1845 Host Adapter.
1846*/
1847
1848static bool __init blogic_getres(struct blogic_adapter *adapter)
1849{
1850 if (adapter->irq_ch == 0) {
1851 blogic_err("NO LEGAL INTERRUPT CHANNEL ASSIGNED - DETACHING\n",
1852 adapter);
1853 return false;
1854 }
1855 /*
1856 Acquire shared access to the IRQ Channel.
1857 */
1858 if (request_irq(adapter->irq_ch, blogic_inthandler, IRQF_SHARED,
1859 adapter->full_model, adapter) < 0) {
1860 blogic_err("UNABLE TO ACQUIRE IRQ CHANNEL %d - DETACHING\n",
1861 adapter, adapter->irq_ch);
1862 return false;
1863 }
1864 adapter->irq_acquired = true;
1865 /*
1866 Indicate the System Resource Acquisition completed successfully,
1867 */
1868 return true;
1869}
1870
1871
1872/*
1873 blogic_relres releases any system resources previously acquired
1874 by blogic_getres.
1875*/
1876
1877static void blogic_relres(struct blogic_adapter *adapter)
1878{
1879 /*
1880 Release shared access to the IRQ Channel.
1881 */
1882 if (adapter->irq_acquired)
1883 free_irq(adapter->irq_ch, adapter);
1884 /*
1885 Release any allocated memory structs not released elsewhere
1886 */
1887 if (adapter->mbox_space)
1888 dma_free_coherent(&adapter->pci_device->dev, adapter->mbox_sz,
1889 adapter->mbox_space, adapter->mbox_space_handle);
1890 pci_dev_put(adapter->pci_device);
1891 adapter->mbox_space = NULL;
1892 adapter->mbox_space_handle = 0;
1893 adapter->mbox_sz = 0;
1894}
1895
1896
1897/*
1898 blogic_initadapter initializes Host Adapter. This is the only
1899 function called during SCSI Host Adapter detection which modifies the state
1900 of the Host Adapter from its initial power on or hard reset state.
1901*/
1902
1903static bool blogic_initadapter(struct blogic_adapter *adapter)
1904{
1905 struct blogic_extmbox_req extmbox_req;
1906 enum blogic_rr_req rr_req;
1907 enum blogic_setccb_fmt setccb_fmt;
1908 int tgt_id;
1909
1910 /*
1911 Initialize the pointers to the first and last CCBs that are
1912 queued for completion processing.
1913 */
1914 adapter->firstccb = NULL;
1915 adapter->lastccb = NULL;
1916
1917 /*
1918 Initialize the Bus Device Reset Pending CCB, Tagged Queuing Active,
1919 Command Successful Flag, Active Commands, and Commands Since Reset
1920 for each Target Device.
1921 */
1922 for (tgt_id = 0; tgt_id < adapter->maxdev; tgt_id++) {
1923 adapter->bdr_pend[tgt_id] = NULL;
1924 adapter->tgt_flags[tgt_id].tagq_active = false;
1925 adapter->tgt_flags[tgt_id].cmd_good = false;
1926 adapter->active_cmds[tgt_id] = 0;
1927 adapter->cmds_since_rst[tgt_id] = 0;
1928 }
1929
1930 /*
1931 FlashPoint Host Adapters do not use Outgoing and Incoming Mailboxes.
1932 */
1933 if (blogic_flashpoint_type(adapter))
1934 goto done;
1935
1936 /*
1937 Initialize the Outgoing and Incoming Mailbox pointers.
1938 */
1939 adapter->mbox_sz = adapter->mbox_count * (sizeof(struct blogic_outbox) + sizeof(struct blogic_inbox));
1940 adapter->mbox_space = dma_alloc_coherent(&adapter->pci_device->dev,
1941 adapter->mbox_sz, &adapter->mbox_space_handle,
1942 GFP_KERNEL);
1943 if (adapter->mbox_space == NULL)
1944 return blogic_failure(adapter, "MAILBOX ALLOCATION");
1945 adapter->first_outbox = (struct blogic_outbox *) adapter->mbox_space;
1946 adapter->last_outbox = adapter->first_outbox + adapter->mbox_count - 1;
1947 adapter->next_outbox = adapter->first_outbox;
1948 adapter->first_inbox = (struct blogic_inbox *) (adapter->last_outbox + 1);
1949 adapter->last_inbox = adapter->first_inbox + adapter->mbox_count - 1;
1950 adapter->next_inbox = adapter->first_inbox;
1951
1952 /*
1953 Initialize the Outgoing and Incoming Mailbox structures.
1954 */
1955 memset(adapter->first_outbox, 0,
1956 adapter->mbox_count * sizeof(struct blogic_outbox));
1957 memset(adapter->first_inbox, 0,
1958 adapter->mbox_count * sizeof(struct blogic_inbox));
1959
1960 /*
1961 Initialize the Host Adapter's Pointer to the Outgoing/Incoming
1962 Mailboxes.
1963 */
1964 extmbox_req.mbox_count = adapter->mbox_count;
1965 extmbox_req.base_mbox_addr = (u32) adapter->mbox_space_handle;
1966 if (blogic_cmd(adapter, BLOGIC_INIT_EXT_MBOX, &extmbox_req,
1967 sizeof(extmbox_req), NULL, 0) < 0)
1968 return blogic_failure(adapter, "MAILBOX INITIALIZATION");
1969 /*
1970 Enable Strict Round Robin Mode if supported by the Host Adapter. In
1971 Strict Round Robin Mode, the Host Adapter only looks at the next
1972 Outgoing Mailbox for each new command, rather than scanning
1973 through all the Outgoing Mailboxes to find any that have new
1974 commands in them. Strict Round Robin Mode is significantly more
1975 efficient.
1976 */
1977 if (adapter->strict_rr) {
1978 rr_req = BLOGIC_STRICT_RR_MODE;
1979 if (blogic_cmd(adapter, BLOGIC_STRICT_RR, &rr_req,
1980 sizeof(rr_req), NULL, 0) < 0)
1981 return blogic_failure(adapter,
1982 "ENABLE STRICT ROUND ROBIN MODE");
1983 }
1984
1985 /*
1986 For Host Adapters that support Extended LUN Format CCBs, issue the
1987 Set CCB Format command to allow 32 Logical Units per Target Device.
1988 */
1989 if (adapter->ext_lun) {
1990 setccb_fmt = BLOGIC_EXT_LUN_CCB;
1991 if (blogic_cmd(adapter, BLOGIC_SETCCB_FMT, &setccb_fmt,
1992 sizeof(setccb_fmt), NULL, 0) < 0)
1993 return blogic_failure(adapter, "SET CCB FORMAT");
1994 }
1995
1996 /*
1997 Announce Successful Initialization.
1998 */
1999done:
2000 if (!adapter->adapter_initd) {
2001 blogic_info("*** %s Initialized Successfully ***\n", adapter,
2002 adapter->full_model);
2003 blogic_info("\n", adapter);
2004 } else
2005 blogic_warn("*** %s Initialized Successfully ***\n", adapter,
2006 adapter->full_model);
2007 adapter->adapter_initd = true;
2008
2009 /*
2010 Indicate the Host Adapter Initialization completed successfully.
2011 */
2012 return true;
2013}
2014
2015
2016/*
2017 blogic_inquiry inquires about the Target Devices accessible
2018 through Host Adapter.
2019*/
2020
2021static bool __init blogic_inquiry(struct blogic_adapter *adapter)
2022{
2023 u16 installed_devs;
2024 u8 installed_devs0to7[8];
2025 struct blogic_setup_info setupinfo;
2026 u8 sync_period[BLOGIC_MAXDEV];
2027 unsigned char req_replylen;
2028 int tgt_id;
2029
2030 /*
2031 Wait a few seconds between the Host Adapter Hard Reset which
2032 initiates a SCSI Bus Reset and issuing any SCSI Commands. Some
2033 SCSI devices get confused if they receive SCSI Commands too soon
2034 after a SCSI Bus Reset.
2035 */
2036 blogic_delay(adapter->bus_settle_time);
2037 /*
2038 FlashPoint Host Adapters do not provide for Target Device Inquiry.
2039 */
2040 if (blogic_flashpoint_type(adapter))
2041 return true;
2042 /*
2043 Inhibit the Target Device Inquiry if requested.
2044 */
2045 if (adapter->drvr_opts != NULL && adapter->drvr_opts->stop_tgt_inquiry)
2046 return true;
2047 /*
2048 Issue the Inquire Target Devices command for host adapters with
2049 firmware version 4.25 or later, or the Inquire Installed Devices
2050 ID 0 to 7 command for older host adapters. This is necessary to
2051 force Synchronous Transfer Negotiation so that the Inquire Setup
2052 Information and Inquire Synchronous Period commands will return
2053 valid data. The Inquire Target Devices command is preferable to
2054 Inquire Installed Devices ID 0 to 7 since it only probes Logical
2055 Unit 0 of each Target Device.
2056 */
2057 if (strcmp(adapter->fw_ver, "4.25") >= 0) {
2058
2059 /*
2060 Issue a Inquire Target Devices command. Inquire Target
2061 Devices only tests Logical Unit 0 of each Target Device
2062 unlike the Inquire Installed Devices commands which test
2063 Logical Units 0 - 7. Two bytes are returned, where byte
2064 0 bit 0 set indicates that Target Device 0 exists, and so on.
2065 */
2066
2067 if (blogic_cmd(adapter, BLOGIC_INQ_DEV, NULL, 0,
2068 &installed_devs, sizeof(installed_devs))
2069 != sizeof(installed_devs))
2070 return blogic_failure(adapter, "INQUIRE TARGET DEVICES");
2071 for (tgt_id = 0; tgt_id < adapter->maxdev; tgt_id++)
2072 adapter->tgt_flags[tgt_id].tgt_exists =
2073 (installed_devs & (1 << tgt_id) ? true : false);
2074 } else {
2075
2076 /*
2077 Issue an Inquire Installed Devices command. For each
2078 Target Device, a byte is returned where bit 0 set
2079 indicates that Logical Unit 0 * exists, bit 1 set
2080 indicates that Logical Unit 1 exists, and so on.
2081 */
2082
2083 if (blogic_cmd(adapter, BLOGIC_INQ_DEV0TO7, NULL, 0,
2084 &installed_devs0to7, sizeof(installed_devs0to7))
2085 != sizeof(installed_devs0to7))
2086 return blogic_failure(adapter,
2087 "INQUIRE INSTALLED DEVICES ID 0 TO 7");
2088 for (tgt_id = 0; tgt_id < 8; tgt_id++)
2089 adapter->tgt_flags[tgt_id].tgt_exists =
2090 installed_devs0to7[tgt_id] != 0;
2091 }
2092 /*
2093 Issue the Inquire Setup Information command.
2094 */
2095 req_replylen = sizeof(setupinfo);
2096 if (blogic_cmd(adapter, BLOGIC_INQ_SETUPINFO, &req_replylen,
2097 sizeof(req_replylen), &setupinfo, sizeof(setupinfo))
2098 != sizeof(setupinfo))
2099 return blogic_failure(adapter, "INQUIRE SETUP INFORMATION");
2100 for (tgt_id = 0; tgt_id < adapter->maxdev; tgt_id++)
2101 adapter->sync_offset[tgt_id] = (tgt_id < 8 ? setupinfo.sync0to7[tgt_id].offset : setupinfo.sync8to15[tgt_id - 8].offset);
2102 if (strcmp(adapter->fw_ver, "5.06L") >= 0)
2103 for (tgt_id = 0; tgt_id < adapter->maxdev; tgt_id++)
2104 adapter->tgt_flags[tgt_id].wide_active = (tgt_id < 8 ? (setupinfo.wide_tx_active0to7 & (1 << tgt_id) ? true : false) : (setupinfo.wide_tx_active8to15 & (1 << (tgt_id - 8)) ? true : false));
2105 /*
2106 Issue the Inquire Synchronous Period command.
2107 */
2108 if (adapter->fw_ver[0] >= '3') {
2109
2110 /* Issue a Inquire Synchronous Period command. For each
2111 Target Device, a byte is returned which represents the
2112 Synchronous Transfer Period in units of 10 nanoseconds.
2113 */
2114
2115 req_replylen = sizeof(sync_period);
2116 if (blogic_cmd(adapter, BLOGIC_INQ_SYNC_PERIOD, &req_replylen,
2117 sizeof(req_replylen), &sync_period,
2118 sizeof(sync_period)) != sizeof(sync_period))
2119 return blogic_failure(adapter,
2120 "INQUIRE SYNCHRONOUS PERIOD");
2121 for (tgt_id = 0; tgt_id < adapter->maxdev; tgt_id++)
2122 adapter->sync_period[tgt_id] = sync_period[tgt_id];
2123 } else
2124 for (tgt_id = 0; tgt_id < adapter->maxdev; tgt_id++)
2125 if (setupinfo.sync0to7[tgt_id].offset > 0)
2126 adapter->sync_period[tgt_id] = 20 + 5 * setupinfo.sync0to7[tgt_id].tx_period;
2127 /*
2128 Indicate the Target Device Inquiry completed successfully.
2129 */
2130 return true;
2131}
2132
2133/*
2134 blogic_inithoststruct initializes the fields in the SCSI Host
2135 structure. The base, io_port, n_io_ports, irq, and dma_channel fields in the
2136 SCSI Host structure are intentionally left uninitialized, as this driver
2137 handles acquisition and release of these resources explicitly, as well as
2138 ensuring exclusive access to the Host Adapter hardware and data structures
2139 through explicit acquisition and release of the Host Adapter's Lock.
2140*/
2141
2142static void __init blogic_inithoststruct(struct blogic_adapter *adapter,
2143 struct Scsi_Host *host)
2144{
2145 host->max_id = adapter->maxdev;
2146 host->max_lun = adapter->maxlun;
2147 host->max_channel = 0;
2148 host->unique_id = adapter->io_addr;
2149 host->this_id = adapter->scsi_id;
2150 host->can_queue = adapter->drvr_qdepth;
2151 host->sg_tablesize = adapter->drvr_sglimit;
2152 host->cmd_per_lun = adapter->untag_qdepth;
2153}
2154
2155/*
2156 blogic_slaveconfig will actually set the queue depth on individual
2157 scsi devices as they are permanently added to the device chain. We
2158 shamelessly rip off the SelectQueueDepths code to make this work mostly
2159 like it used to. Since we don't get called once at the end of the scan
2160 but instead get called for each device, we have to do things a bit
2161 differently.
2162*/
2163static int blogic_slaveconfig(struct scsi_device *dev)
2164{
2165 struct blogic_adapter *adapter =
2166 (struct blogic_adapter *) dev->host->hostdata;
2167 int tgt_id = dev->id;
2168 int qdepth = adapter->qdepth[tgt_id];
2169
2170 if (adapter->tgt_flags[tgt_id].tagq_ok &&
2171 (adapter->tagq_ok & (1 << tgt_id))) {
2172 if (qdepth == 0)
2173 qdepth = BLOGIC_MAX_AUTO_TAG_DEPTH;
2174 adapter->qdepth[tgt_id] = qdepth;
2175 scsi_change_queue_depth(dev, qdepth);
2176 } else {
2177 adapter->tagq_ok &= ~(1 << tgt_id);
2178 qdepth = adapter->untag_qdepth;
2179 adapter->qdepth[tgt_id] = qdepth;
2180 scsi_change_queue_depth(dev, qdepth);
2181 }
2182 qdepth = 0;
2183 for (tgt_id = 0; tgt_id < adapter->maxdev; tgt_id++)
2184 if (adapter->tgt_flags[tgt_id].tgt_exists)
2185 qdepth += adapter->qdepth[tgt_id];
2186 if (qdepth > adapter->alloc_ccbs)
2187 blogic_create_addlccbs(adapter, qdepth - adapter->alloc_ccbs,
2188 false);
2189 return 0;
2190}
2191
2192/*
2193 blogic_init probes for BusLogic Host Adapters at the standard
2194 I/O Addresses where they may be located, initializing, registering, and
2195 reporting the configuration of each BusLogic Host Adapter it finds. It
2196 returns the number of BusLogic Host Adapters successfully initialized and
2197 registered.
2198*/
2199
2200static int __init blogic_init(void)
2201{
2202 int drvr_optindex = 0, probeindex;
2203 struct blogic_adapter *adapter;
2204 int ret = 0;
2205
2206#ifdef MODULE
2207 if (BusLogic)
2208 blogic_setup(BusLogic);
2209#endif
2210
2211 if (blogic_probe_options.noprobe)
2212 return -ENODEV;
2213 blogic_probeinfo_list =
2214 kcalloc(BLOGIC_MAX_ADAPTERS, sizeof(struct blogic_probeinfo),
2215 GFP_KERNEL);
2216 if (blogic_probeinfo_list == NULL) {
2217 blogic_err("BusLogic: Unable to allocate Probe Info List\n",
2218 NULL);
2219 return -ENOMEM;
2220 }
2221
2222 adapter = kzalloc(sizeof(struct blogic_adapter), GFP_KERNEL);
2223 if (adapter == NULL) {
2224 kfree(blogic_probeinfo_list);
2225 blogic_err("BusLogic: Unable to allocate Prototype Host Adapter\n", NULL);
2226 return -ENOMEM;
2227 }
2228
2229#ifdef MODULE
2230 if (BusLogic != NULL)
2231 blogic_setup(BusLogic);
2232#endif
2233 blogic_init_probeinfo_list(adapter);
2234 for (probeindex = 0; probeindex < blogic_probeinfo_count; probeindex++) {
2235 struct blogic_probeinfo *probeinfo =
2236 &blogic_probeinfo_list[probeindex];
2237 struct blogic_adapter *myadapter = adapter;
2238 struct Scsi_Host *host;
2239
2240 if (probeinfo->io_addr == 0)
2241 continue;
2242 memset(myadapter, 0, sizeof(struct blogic_adapter));
2243 myadapter->adapter_type = probeinfo->adapter_type;
2244 myadapter->adapter_bus_type = probeinfo->adapter_bus_type;
2245 myadapter->io_addr = probeinfo->io_addr;
2246 myadapter->pci_addr = probeinfo->pci_addr;
2247 myadapter->bus = probeinfo->bus;
2248 myadapter->dev = probeinfo->dev;
2249 myadapter->pci_device = probeinfo->pci_device;
2250 myadapter->irq_ch = probeinfo->irq_ch;
2251 myadapter->addr_count =
2252 blogic_adapter_addr_count[myadapter->adapter_type];
2253
2254 /*
2255 Make sure region is free prior to probing.
2256 */
2257 if (!request_region(myadapter->io_addr, myadapter->addr_count,
2258 "BusLogic"))
2259 continue;
2260 /*
2261 Probe the Host Adapter. If unsuccessful, abort further
2262 initialization.
2263 */
2264 if (!blogic_probe(myadapter)) {
2265 release_region(myadapter->io_addr,
2266 myadapter->addr_count);
2267 continue;
2268 }
2269 /*
2270 Hard Reset the Host Adapter. If unsuccessful, abort further
2271 initialization.
2272 */
2273 if (!blogic_hwreset(myadapter, true)) {
2274 release_region(myadapter->io_addr,
2275 myadapter->addr_count);
2276 continue;
2277 }
2278 /*
2279 Check the Host Adapter. If unsuccessful, abort further
2280 initialization.
2281 */
2282 if (!blogic_checkadapter(myadapter)) {
2283 release_region(myadapter->io_addr,
2284 myadapter->addr_count);
2285 continue;
2286 }
2287 /*
2288 Initialize the Driver Options field if provided.
2289 */
2290 if (drvr_optindex < blogic_drvr_options_count)
2291 myadapter->drvr_opts =
2292 &blogic_drvr_options[drvr_optindex++];
2293 /*
2294 Announce the Driver Version and Date, Author's Name,
2295 Copyright Notice, and Electronic Mail Address.
2296 */
2297 blogic_announce_drvr(myadapter);
2298 /*
2299 Register the SCSI Host structure.
2300 */
2301
2302 host = scsi_host_alloc(&blogic_template,
2303 sizeof(struct blogic_adapter));
2304 if (host == NULL) {
2305 release_region(myadapter->io_addr,
2306 myadapter->addr_count);
2307 continue;
2308 }
2309 myadapter = (struct blogic_adapter *) host->hostdata;
2310 memcpy(myadapter, adapter, sizeof(struct blogic_adapter));
2311 myadapter->scsi_host = host;
2312 myadapter->host_no = host->host_no;
2313 /*
2314 Add Host Adapter to the end of the list of registered
2315 BusLogic Host Adapters.
2316 */
2317 list_add_tail(&myadapter->host_list, &blogic_host_list);
2318
2319 /*
2320 Read the Host Adapter Configuration, Configure the Host
2321 Adapter, Acquire the System Resources necessary to use
2322 the Host Adapter, then Create the Initial CCBs, Initialize
2323 the Host Adapter, and finally perform Target Device
2324 Inquiry. From this point onward, any failure will be
2325 assumed to be due to a problem with the Host Adapter,
2326 rather than due to having mistakenly identified this port
2327 as belonging to a BusLogic Host Adapter. The I/O Address
2328 range will not be released, thereby preventing it from
2329 being incorrectly identified as any other type of Host
2330 Adapter.
2331 */
2332 if (blogic_rdconfig(myadapter) &&
2333 blogic_reportconfig(myadapter) &&
2334 blogic_getres(myadapter) &&
2335 blogic_create_initccbs(myadapter) &&
2336 blogic_initadapter(myadapter) &&
2337 blogic_inquiry(myadapter)) {
2338 /*
2339 Initialization has been completed successfully.
2340 Release and re-register usage of the I/O Address
2341 range so that the Model Name of the Host Adapter
2342 will appear, and initialize the SCSI Host structure.
2343 */
2344 release_region(myadapter->io_addr,
2345 myadapter->addr_count);
2346 if (!request_region(myadapter->io_addr,
2347 myadapter->addr_count,
2348 myadapter->full_model)) {
2349 printk(KERN_WARNING
2350 "BusLogic: Release and re-register of "
2351 "port 0x%04lx failed \n",
2352 (unsigned long)myadapter->io_addr);
2353 blogic_destroy_ccbs(myadapter);
2354 blogic_relres(myadapter);
2355 list_del(&myadapter->host_list);
2356 scsi_host_put(host);
2357 ret = -ENOMEM;
2358 } else {
2359 blogic_inithoststruct(myadapter,
2360 host);
2361 if (scsi_add_host(host, myadapter->pci_device
2362 ? &myadapter->pci_device->dev
2363 : NULL)) {
2364 printk(KERN_WARNING
2365 "BusLogic: scsi_add_host()"
2366 "failed!\n");
2367 blogic_destroy_ccbs(myadapter);
2368 blogic_relres(myadapter);
2369 list_del(&myadapter->host_list);
2370 scsi_host_put(host);
2371 ret = -ENODEV;
2372 } else
2373 scsi_scan_host(host);
2374 }
2375 } else {
2376 /*
2377 An error occurred during Host Adapter Configuration
2378 Querying, Host Adapter Configuration, Resource
2379 Acquisition, CCB Creation, Host Adapter
2380 Initialization, or Target Device Inquiry, so
2381 remove Host Adapter from the list of registered
2382 BusLogic Host Adapters, destroy the CCBs, Release
2383 the System Resources, and Unregister the SCSI
2384 Host.
2385 */
2386 blogic_destroy_ccbs(myadapter);
2387 blogic_relres(myadapter);
2388 list_del(&myadapter->host_list);
2389 scsi_host_put(host);
2390 ret = -ENODEV;
2391 }
2392 }
2393 kfree(adapter);
2394 kfree(blogic_probeinfo_list);
2395 blogic_probeinfo_list = NULL;
2396 return ret;
2397}
2398
2399
2400/*
2401 blogic_deladapter releases all resources previously acquired to
2402 support a specific Host Adapter, including the I/O Address range, and
2403 unregisters the BusLogic Host Adapter.
2404*/
2405
2406static int __exit blogic_deladapter(struct blogic_adapter *adapter)
2407{
2408 struct Scsi_Host *host = adapter->scsi_host;
2409
2410 scsi_remove_host(host);
2411
2412 /*
2413 FlashPoint Host Adapters must first be released by the FlashPoint
2414 SCCB Manager.
2415 */
2416 if (blogic_flashpoint_type(adapter))
2417 FlashPoint_ReleaseHostAdapter(adapter->cardhandle);
2418 /*
2419 Destroy the CCBs and release any system resources acquired to
2420 support Host Adapter.
2421 */
2422 blogic_destroy_ccbs(adapter);
2423 blogic_relres(adapter);
2424 /*
2425 Release usage of the I/O Address range.
2426 */
2427 release_region(adapter->io_addr, adapter->addr_count);
2428 /*
2429 Remove Host Adapter from the list of registered BusLogic
2430 Host Adapters.
2431 */
2432 list_del(&adapter->host_list);
2433
2434 scsi_host_put(host);
2435 return 0;
2436}
2437
2438
2439/*
2440 blogic_qcompleted_ccb queues CCB for completion processing.
2441*/
2442
2443static void blogic_qcompleted_ccb(struct blogic_ccb *ccb)
2444{
2445 struct blogic_adapter *adapter = ccb->adapter;
2446
2447 ccb->status = BLOGIC_CCB_COMPLETE;
2448 ccb->next = NULL;
2449 if (adapter->firstccb == NULL) {
2450 adapter->firstccb = ccb;
2451 adapter->lastccb = ccb;
2452 } else {
2453 adapter->lastccb->next = ccb;
2454 adapter->lastccb = ccb;
2455 }
2456 adapter->active_cmds[ccb->tgt_id]--;
2457}
2458
2459
2460/*
2461 blogic_resultcode computes a SCSI Subsystem Result Code from
2462 the Host Adapter Status and Target Device Status.
2463*/
2464
2465static int blogic_resultcode(struct blogic_adapter *adapter,
2466 enum blogic_adapter_status adapter_status,
2467 enum blogic_tgt_status tgt_status)
2468{
2469 int hoststatus;
2470
2471 switch (adapter_status) {
2472 case BLOGIC_CMD_CMPLT_NORMAL:
2473 case BLOGIC_LINK_CMD_CMPLT:
2474 case BLOGIC_LINK_CMD_CMPLT_FLAG:
2475 hoststatus = DID_OK;
2476 break;
2477 case BLOGIC_SELECT_TIMEOUT:
2478 hoststatus = DID_TIME_OUT;
2479 break;
2480 case BLOGIC_INVALID_OUTBOX_CODE:
2481 case BLOGIC_INVALID_CMD_CODE:
2482 case BLOGIC_BAD_CMD_PARAM:
2483 blogic_warn("BusLogic Driver Protocol Error 0x%02X\n",
2484 adapter, adapter_status);
2485 fallthrough;
2486 case BLOGIC_DATA_UNDERRUN:
2487 case BLOGIC_DATA_OVERRUN:
2488 case BLOGIC_NOEXPECT_BUSFREE:
2489 case BLOGIC_LINKCCB_BADLUN:
2490 case BLOGIC_AUTOREQSENSE_FAIL:
2491 case BLOGIC_TAGQUEUE_REJECT:
2492 case BLOGIC_BAD_MSG_RCVD:
2493 case BLOGIC_HW_FAIL:
2494 case BLOGIC_BAD_RECONNECT:
2495 case BLOGIC_ABRT_QUEUE:
2496 case BLOGIC_ADAPTER_SW_ERROR:
2497 case BLOGIC_HW_TIMEOUT:
2498 case BLOGIC_PARITY_ERR:
2499 hoststatus = DID_ERROR;
2500 break;
2501 case BLOGIC_INVALID_BUSPHASE:
2502 case BLOGIC_NORESPONSE_TO_ATN:
2503 case BLOGIC_HW_RESET:
2504 case BLOGIC_RST_FROM_OTHERDEV:
2505 case BLOGIC_HW_BDR:
2506 hoststatus = DID_RESET;
2507 break;
2508 default:
2509 blogic_warn("Unknown Host Adapter Status 0x%02X\n", adapter,
2510 adapter_status);
2511 hoststatus = DID_ERROR;
2512 break;
2513 }
2514 return (hoststatus << 16) | tgt_status;
2515}
2516
2517/*
2518 * turn the dma address from an inbox into a ccb pointer
2519 * This is rather inefficient.
2520 */
2521static struct blogic_ccb *
2522blogic_inbox_to_ccb(struct blogic_adapter *adapter, struct blogic_inbox *inbox)
2523{
2524 struct blogic_ccb *ccb;
2525
2526 for (ccb = adapter->all_ccbs; ccb; ccb = ccb->next_all)
2527 if (inbox->ccb == ccb->dma_handle)
2528 break;
2529
2530 return ccb;
2531}
2532
2533/*
2534 blogic_scan_inbox scans the Incoming Mailboxes saving any
2535 Incoming Mailbox entries for completion processing.
2536*/
2537static void blogic_scan_inbox(struct blogic_adapter *adapter)
2538{
2539 /*
2540 Scan through the Incoming Mailboxes in Strict Round Robin
2541 fashion, saving any completed CCBs for further processing. It
2542 is essential that for each CCB and SCSI Command issued, command
2543 completion processing is performed exactly once. Therefore,
2544 only Incoming Mailboxes with completion code Command Completed
2545 Without Error, Command Completed With Error, or Command Aborted
2546 At Host Request are saved for completion processing. When an
2547 Incoming Mailbox has a completion code of Aborted Command Not
2548 Found, the CCB had already completed or been aborted before the
2549 current Abort request was processed, and so completion processing
2550 has already occurred and no further action should be taken.
2551 */
2552 struct blogic_inbox *next_inbox = adapter->next_inbox;
2553 enum blogic_cmplt_code comp_code;
2554
2555 while ((comp_code = next_inbox->comp_code) != BLOGIC_INBOX_FREE) {
2556 struct blogic_ccb *ccb = blogic_inbox_to_ccb(adapter, next_inbox);
2557 if (!ccb) {
2558 /*
2559 * This should never happen, unless the CCB list is
2560 * corrupted in memory.
2561 */
2562 blogic_warn("Could not find CCB for dma address %x\n", adapter, next_inbox->ccb);
2563 } else if (comp_code != BLOGIC_CMD_NOTFOUND) {
2564 if (ccb->status == BLOGIC_CCB_ACTIVE ||
2565 ccb->status == BLOGIC_CCB_RESET) {
2566 /*
2567 Save the Completion Code for this CCB and
2568 queue the CCB for completion processing.
2569 */
2570 ccb->comp_code = comp_code;
2571 blogic_qcompleted_ccb(ccb);
2572 } else {
2573 /*
2574 If a CCB ever appears in an Incoming Mailbox
2575 and is not marked as status Active or Reset,
2576 then there is most likely a bug in
2577 the Host Adapter firmware.
2578 */
2579 blogic_warn("Illegal CCB #%ld status %d in Incoming Mailbox\n", adapter, ccb->serial, ccb->status);
2580 }
2581 }
2582 next_inbox->comp_code = BLOGIC_INBOX_FREE;
2583 if (++next_inbox > adapter->last_inbox)
2584 next_inbox = adapter->first_inbox;
2585 }
2586 adapter->next_inbox = next_inbox;
2587}
2588
2589
2590/*
2591 blogic_process_ccbs iterates over the completed CCBs for Host
2592 Adapter setting the SCSI Command Result Codes, deallocating the CCBs, and
2593 calling the SCSI Subsystem Completion Routines. The Host Adapter's Lock
2594 should already have been acquired by the caller.
2595*/
2596
2597static void blogic_process_ccbs(struct blogic_adapter *adapter)
2598{
2599 if (adapter->processing_ccbs)
2600 return;
2601 adapter->processing_ccbs = true;
2602 while (adapter->firstccb != NULL) {
2603 struct blogic_ccb *ccb = adapter->firstccb;
2604 struct scsi_cmnd *command = ccb->command;
2605 adapter->firstccb = ccb->next;
2606 if (adapter->firstccb == NULL)
2607 adapter->lastccb = NULL;
2608 /*
2609 Process the Completed CCB.
2610 */
2611 if (ccb->opcode == BLOGIC_BDR) {
2612 int tgt_id = ccb->tgt_id;
2613
2614 blogic_warn("Bus Device Reset CCB #%ld to Target %d Completed\n", adapter, ccb->serial, tgt_id);
2615 blogic_inc_count(&adapter->tgt_stats[tgt_id].bdr_done);
2616 adapter->tgt_flags[tgt_id].tagq_active = false;
2617 adapter->cmds_since_rst[tgt_id] = 0;
2618 adapter->last_resetdone[tgt_id] = jiffies;
2619 /*
2620 Place CCB back on the Host Adapter's free list.
2621 */
2622 blogic_dealloc_ccb(ccb, 1);
2623#if 0 /* this needs to be redone different for new EH */
2624 /*
2625 Bus Device Reset CCBs have the command field
2626 non-NULL only when a Bus Device Reset was requested
2627 for a command that did not have a currently active
2628 CCB in the Host Adapter (i.e., a Synchronous Bus
2629 Device Reset), and hence would not have its
2630 Completion Routine called otherwise.
2631 */
2632 while (command != NULL) {
2633 struct scsi_cmnd *nxt_cmd =
2634 command->reset_chain;
2635 command->reset_chain = NULL;
2636 command->result = DID_RESET << 16;
2637 scsi_done(command);
2638 command = nxt_cmd;
2639 }
2640#endif
2641 /*
2642 Iterate over the CCBs for this Host Adapter
2643 performing completion processing for any CCBs
2644 marked as Reset for this Target.
2645 */
2646 for (ccb = adapter->all_ccbs; ccb != NULL;
2647 ccb = ccb->next_all)
2648 if (ccb->status == BLOGIC_CCB_RESET &&
2649 ccb->tgt_id == tgt_id) {
2650 command = ccb->command;
2651 blogic_dealloc_ccb(ccb, 1);
2652 adapter->active_cmds[tgt_id]--;
2653 command->result = DID_RESET << 16;
2654 scsi_done(command);
2655 }
2656 adapter->bdr_pend[tgt_id] = NULL;
2657 } else {
2658 /*
2659 Translate the Completion Code, Host Adapter Status,
2660 and Target Device Status into a SCSI Subsystem
2661 Result Code.
2662 */
2663 switch (ccb->comp_code) {
2664 case BLOGIC_INBOX_FREE:
2665 case BLOGIC_CMD_NOTFOUND:
2666 case BLOGIC_INVALID_CCB:
2667 blogic_warn("CCB #%ld to Target %d Impossible State\n", adapter, ccb->serial, ccb->tgt_id);
2668 break;
2669 case BLOGIC_CMD_COMPLETE_GOOD:
2670 adapter->tgt_stats[ccb->tgt_id]
2671 .cmds_complete++;
2672 adapter->tgt_flags[ccb->tgt_id]
2673 .cmd_good = true;
2674 command->result = DID_OK << 16;
2675 break;
2676 case BLOGIC_CMD_ABORT_BY_HOST:
2677 blogic_warn("CCB #%ld to Target %d Aborted\n",
2678 adapter, ccb->serial, ccb->tgt_id);
2679 blogic_inc_count(&adapter->tgt_stats[ccb->tgt_id].aborts_done);
2680 command->result = DID_ABORT << 16;
2681 break;
2682 case BLOGIC_CMD_COMPLETE_ERROR:
2683 command->result = blogic_resultcode(adapter,
2684 ccb->adapter_status, ccb->tgt_status);
2685 if (ccb->adapter_status != BLOGIC_SELECT_TIMEOUT) {
2686 adapter->tgt_stats[ccb->tgt_id]
2687 .cmds_complete++;
2688 if (blogic_global_options.trace_err) {
2689 int i;
2690 blogic_notice("CCB #%ld Target %d: Result %X Host "
2691 "Adapter Status %02X Target Status %02X\n", adapter, ccb->serial, ccb->tgt_id, command->result, ccb->adapter_status, ccb->tgt_status);
2692 blogic_notice("CDB ", adapter);
2693 for (i = 0; i < ccb->cdblen; i++)
2694 blogic_notice(" %02X", adapter, ccb->cdb[i]);
2695 blogic_notice("\n", adapter);
2696 blogic_notice("Sense ", adapter);
2697 for (i = 0; i < ccb->sense_datalen; i++)
2698 blogic_notice(" %02X", adapter, command->sense_buffer[i]);
2699 blogic_notice("\n", adapter);
2700 }
2701 }
2702 break;
2703 }
2704 /*
2705 When an INQUIRY command completes normally, save the
2706 CmdQue (Tagged Queuing Supported) and WBus16 (16 Bit
2707 Wide Data Transfers Supported) bits.
2708 */
2709 if (ccb->cdb[0] == INQUIRY && ccb->cdb[1] == 0 &&
2710 ccb->adapter_status == BLOGIC_CMD_CMPLT_NORMAL) {
2711 struct blogic_tgt_flags *tgt_flags =
2712 &adapter->tgt_flags[ccb->tgt_id];
2713 struct scsi_inquiry *inquiry =
2714 (struct scsi_inquiry *) scsi_sglist(command);
2715 tgt_flags->tgt_exists = true;
2716 tgt_flags->tagq_ok = inquiry->CmdQue;
2717 tgt_flags->wide_ok = inquiry->WBus16;
2718 }
2719 /*
2720 Place CCB back on the Host Adapter's free list.
2721 */
2722 blogic_dealloc_ccb(ccb, 1);
2723 /*
2724 Call the SCSI Command Completion Routine.
2725 */
2726 scsi_done(command);
2727 }
2728 }
2729 adapter->processing_ccbs = false;
2730}
2731
2732
2733/*
2734 blogic_inthandler handles hardware interrupts from BusLogic Host
2735 Adapters.
2736*/
2737
2738static irqreturn_t blogic_inthandler(int irq_ch, void *devid)
2739{
2740 struct blogic_adapter *adapter = (struct blogic_adapter *) devid;
2741 unsigned long processor_flag;
2742 /*
2743 Acquire exclusive access to Host Adapter.
2744 */
2745 spin_lock_irqsave(adapter->scsi_host->host_lock, processor_flag);
2746 /*
2747 Handle Interrupts appropriately for each Host Adapter type.
2748 */
2749 if (blogic_multimaster_type(adapter)) {
2750 union blogic_int_reg intreg;
2751 /*
2752 Read the Host Adapter Interrupt Register.
2753 */
2754 intreg.all = blogic_rdint(adapter);
2755 if (intreg.ir.int_valid) {
2756 /*
2757 Acknowledge the interrupt and reset the Host Adapter
2758 Interrupt Register.
2759 */
2760 blogic_intreset(adapter);
2761 /*
2762 Process valid External SCSI Bus Reset and Incoming
2763 Mailbox Loaded Interrupts. Command Complete
2764 Interrupts are noted, and Outgoing Mailbox Available
2765 Interrupts are ignored, as they are never enabled.
2766 */
2767 if (intreg.ir.ext_busreset)
2768 adapter->adapter_extreset = true;
2769 else if (intreg.ir.mailin_loaded)
2770 blogic_scan_inbox(adapter);
2771 else if (intreg.ir.cmd_complete)
2772 adapter->adapter_cmd_complete = true;
2773 }
2774 } else {
2775 /*
2776 Check if there is a pending interrupt for this Host Adapter.
2777 */
2778 if (FlashPoint_InterruptPending(adapter->cardhandle))
2779 switch (FlashPoint_HandleInterrupt(adapter->cardhandle)) {
2780 case FPOINT_NORMAL_INT:
2781 break;
2782 case FPOINT_EXT_RESET:
2783 adapter->adapter_extreset = true;
2784 break;
2785 case FPOINT_INTERN_ERR:
2786 blogic_warn("Internal FlashPoint Error detected - Resetting Host Adapter\n", adapter);
2787 adapter->adapter_intern_err = true;
2788 break;
2789 }
2790 }
2791 /*
2792 Process any completed CCBs.
2793 */
2794 if (adapter->firstccb != NULL)
2795 blogic_process_ccbs(adapter);
2796 /*
2797 Reset the Host Adapter if requested.
2798 */
2799 if (adapter->adapter_extreset) {
2800 blogic_warn("Resetting %s due to External SCSI Bus Reset\n", adapter, adapter->full_model);
2801 blogic_inc_count(&adapter->ext_resets);
2802 blogic_resetadapter(adapter, false);
2803 adapter->adapter_extreset = false;
2804 } else if (adapter->adapter_intern_err) {
2805 blogic_warn("Resetting %s due to Host Adapter Internal Error\n", adapter, adapter->full_model);
2806 blogic_inc_count(&adapter->adapter_intern_errors);
2807 blogic_resetadapter(adapter, true);
2808 adapter->adapter_intern_err = false;
2809 }
2810 /*
2811 Release exclusive access to Host Adapter.
2812 */
2813 spin_unlock_irqrestore(adapter->scsi_host->host_lock, processor_flag);
2814 return IRQ_HANDLED;
2815}
2816
2817
2818/*
2819 blogic_write_outbox places CCB and Action Code into an Outgoing
2820 Mailbox for execution by Host Adapter. The Host Adapter's Lock should
2821 already have been acquired by the caller.
2822*/
2823
2824static bool blogic_write_outbox(struct blogic_adapter *adapter,
2825 enum blogic_action action, struct blogic_ccb *ccb)
2826{
2827 struct blogic_outbox *next_outbox;
2828
2829 next_outbox = adapter->next_outbox;
2830 if (next_outbox->action == BLOGIC_OUTBOX_FREE) {
2831 ccb->status = BLOGIC_CCB_ACTIVE;
2832 /*
2833 The CCB field must be written before the Action Code field
2834 since the Host Adapter is operating asynchronously and the
2835 locking code does not protect against simultaneous access
2836 by the Host Adapter.
2837 */
2838 next_outbox->ccb = ccb->dma_handle;
2839 next_outbox->action = action;
2840 blogic_execmbox(adapter);
2841 if (++next_outbox > adapter->last_outbox)
2842 next_outbox = adapter->first_outbox;
2843 adapter->next_outbox = next_outbox;
2844 if (action == BLOGIC_MBOX_START) {
2845 adapter->active_cmds[ccb->tgt_id]++;
2846 if (ccb->opcode != BLOGIC_BDR)
2847 adapter->tgt_stats[ccb->tgt_id].cmds_tried++;
2848 }
2849 return true;
2850 }
2851 return false;
2852}
2853
2854/* Error Handling (EH) support */
2855
2856static int blogic_hostreset(struct scsi_cmnd *SCpnt)
2857{
2858 struct blogic_adapter *adapter =
2859 (struct blogic_adapter *) SCpnt->device->host->hostdata;
2860
2861 unsigned int id = SCpnt->device->id;
2862 struct blogic_tgt_stats *stats = &adapter->tgt_stats[id];
2863 int rc;
2864
2865 spin_lock_irq(SCpnt->device->host->host_lock);
2866
2867 blogic_inc_count(&stats->adapter_reset_req);
2868
2869 rc = blogic_resetadapter(adapter, false);
2870 spin_unlock_irq(SCpnt->device->host->host_lock);
2871 return rc;
2872}
2873
2874/*
2875 blogic_qcmd creates a CCB for Command and places it into an
2876 Outgoing Mailbox for execution by the associated Host Adapter.
2877*/
2878
2879static int blogic_qcmd_lck(struct scsi_cmnd *command)
2880{
2881 void (*comp_cb)(struct scsi_cmnd *) = scsi_done;
2882 struct blogic_adapter *adapter =
2883 (struct blogic_adapter *) command->device->host->hostdata;
2884 struct blogic_tgt_flags *tgt_flags =
2885 &adapter->tgt_flags[command->device->id];
2886 struct blogic_tgt_stats *tgt_stats = adapter->tgt_stats;
2887 unsigned char *cdb = command->cmnd;
2888 int cdblen = command->cmd_len;
2889 int tgt_id = command->device->id;
2890 int lun = command->device->lun;
2891 int buflen = scsi_bufflen(command);
2892 int count;
2893 struct blogic_ccb *ccb;
2894 dma_addr_t sense_buf;
2895
2896 /*
2897 SCSI REQUEST_SENSE commands will be executed automatically by the
2898 Host Adapter for any errors, so they should not be executed
2899 explicitly unless the Sense Data is zero indicating that no error
2900 occurred.
2901 */
2902 if (cdb[0] == REQUEST_SENSE && command->sense_buffer[0] != 0) {
2903 command->result = DID_OK << 16;
2904 comp_cb(command);
2905 return 0;
2906 }
2907 /*
2908 Allocate a CCB from the Host Adapter's free list. In the unlikely
2909 event that there are none available and memory allocation fails,
2910 wait 1 second and try again. If that fails, the Host Adapter is
2911 probably hung so signal an error as a Host Adapter Hard Reset
2912 should be initiated soon.
2913 */
2914 ccb = blogic_alloc_ccb(adapter);
2915 if (ccb == NULL) {
2916 spin_unlock_irq(adapter->scsi_host->host_lock);
2917 blogic_delay(1);
2918 spin_lock_irq(adapter->scsi_host->host_lock);
2919 ccb = blogic_alloc_ccb(adapter);
2920 if (ccb == NULL) {
2921 command->result = DID_ERROR << 16;
2922 comp_cb(command);
2923 return 0;
2924 }
2925 }
2926
2927 /*
2928 Initialize the fields in the BusLogic Command Control Block (CCB).
2929 */
2930 count = scsi_dma_map(command);
2931 BUG_ON(count < 0);
2932 if (count) {
2933 struct scatterlist *sg;
2934 int i;
2935
2936 ccb->opcode = BLOGIC_INITIATOR_CCB_SG;
2937 ccb->datalen = count * sizeof(struct blogic_sg_seg);
2938 if (blogic_multimaster_type(adapter))
2939 ccb->data = (unsigned int) ccb->dma_handle +
2940 ((unsigned long) &ccb->sglist -
2941 (unsigned long) ccb);
2942 else
2943 ccb->data = virt_to_32bit_virt(ccb->sglist);
2944
2945 scsi_for_each_sg(command, sg, count, i) {
2946 ccb->sglist[i].segbytes = sg_dma_len(sg);
2947 ccb->sglist[i].segdata = sg_dma_address(sg);
2948 }
2949 } else if (!count) {
2950 ccb->opcode = BLOGIC_INITIATOR_CCB;
2951 ccb->datalen = buflen;
2952 ccb->data = 0;
2953 }
2954
2955 switch (cdb[0]) {
2956 case READ_6:
2957 case READ_10:
2958 ccb->datadir = BLOGIC_DATAIN_CHECKED;
2959 tgt_stats[tgt_id].read_cmds++;
2960 blogic_addcount(&tgt_stats[tgt_id].bytesread, buflen);
2961 blogic_incszbucket(tgt_stats[tgt_id].read_sz_buckets, buflen);
2962 break;
2963 case WRITE_6:
2964 case WRITE_10:
2965 ccb->datadir = BLOGIC_DATAOUT_CHECKED;
2966 tgt_stats[tgt_id].write_cmds++;
2967 blogic_addcount(&tgt_stats[tgt_id].byteswritten, buflen);
2968 blogic_incszbucket(tgt_stats[tgt_id].write_sz_buckets, buflen);
2969 break;
2970 default:
2971 ccb->datadir = BLOGIC_UNCHECKED_TX;
2972 break;
2973 }
2974 ccb->cdblen = cdblen;
2975 ccb->adapter_status = 0;
2976 ccb->tgt_status = 0;
2977 ccb->tgt_id = tgt_id;
2978 ccb->lun = lun;
2979 ccb->tag_enable = false;
2980 ccb->legacytag_enable = false;
2981 /*
2982 BusLogic recommends that after a Reset the first couple of
2983 commands that are sent to a Target Device be sent in a non
2984 Tagged Queue fashion so that the Host Adapter and Target Device
2985 can establish Synchronous and Wide Transfer before Queue Tag
2986 messages can interfere with the Synchronous and Wide Negotiation
2987 messages. By waiting to enable Tagged Queuing until after the
2988 first BLOGIC_MAX_TAG_DEPTH commands have been queued, it is
2989 assured that after a Reset any pending commands are requeued
2990 before Tagged Queuing is enabled and that the Tagged Queuing
2991 message will not occur while the partition table is being printed.
2992 In addition, some devices do not properly handle the transition
2993 from non-tagged to tagged commands, so it is necessary to wait
2994 until there are no pending commands for a target device
2995 before queuing tagged commands.
2996 */
2997 if (adapter->cmds_since_rst[tgt_id]++ >= BLOGIC_MAX_TAG_DEPTH &&
2998 !tgt_flags->tagq_active &&
2999 adapter->active_cmds[tgt_id] == 0
3000 && tgt_flags->tagq_ok &&
3001 (adapter->tagq_ok & (1 << tgt_id))) {
3002 tgt_flags->tagq_active = true;
3003 blogic_notice("Tagged Queuing now active for Target %d\n",
3004 adapter, tgt_id);
3005 }
3006 if (tgt_flags->tagq_active) {
3007 enum blogic_queuetag queuetag = BLOGIC_SIMPLETAG;
3008 /*
3009 When using Tagged Queuing with Simple Queue Tags, it
3010 appears that disk drive controllers do not guarantee that
3011 a queued command will not remain in a disconnected state
3012 indefinitely if commands that read or write nearer the
3013 head position continue to arrive without interruption.
3014 Therefore, for each Target Device this driver keeps track
3015 of the last time either the queue was empty or an Ordered
3016 Queue Tag was issued. If more than 4 seconds (one fifth
3017 of the 20 second disk timeout) have elapsed since this
3018 last sequence point, this command will be issued with an
3019 Ordered Queue Tag rather than a Simple Queue Tag, which
3020 forces the Target Device to complete all previously
3021 queued commands before this command may be executed.
3022 */
3023 if (adapter->active_cmds[tgt_id] == 0)
3024 adapter->last_seqpoint[tgt_id] = jiffies;
3025 else if (time_after(jiffies,
3026 adapter->last_seqpoint[tgt_id] + 4 * HZ)) {
3027 adapter->last_seqpoint[tgt_id] = jiffies;
3028 queuetag = BLOGIC_ORDEREDTAG;
3029 }
3030 if (adapter->ext_lun) {
3031 ccb->tag_enable = true;
3032 ccb->queuetag = queuetag;
3033 } else {
3034 ccb->legacytag_enable = true;
3035 ccb->legacy_tag = queuetag;
3036 }
3037 }
3038 memcpy(ccb->cdb, cdb, cdblen);
3039 ccb->sense_datalen = SCSI_SENSE_BUFFERSIZE;
3040 ccb->command = command;
3041 sense_buf = dma_map_single(&adapter->pci_device->dev,
3042 command->sense_buffer, ccb->sense_datalen,
3043 DMA_FROM_DEVICE);
3044 if (dma_mapping_error(&adapter->pci_device->dev, sense_buf)) {
3045 blogic_err("DMA mapping for sense data buffer failed\n",
3046 adapter);
3047 blogic_dealloc_ccb(ccb, 0);
3048 return SCSI_MLQUEUE_HOST_BUSY;
3049 }
3050 ccb->sensedata = sense_buf;
3051 if (blogic_multimaster_type(adapter)) {
3052 /*
3053 Place the CCB in an Outgoing Mailbox. The higher levels
3054 of the SCSI Subsystem should not attempt to queue more
3055 commands than can be placed in Outgoing Mailboxes, so
3056 there should always be one free. In the unlikely event
3057 that there are none available, wait 1 second and try
3058 again. If that fails, the Host Adapter is probably hung
3059 so signal an error as a Host Adapter Hard Reset should
3060 be initiated soon.
3061 */
3062 if (!blogic_write_outbox(adapter, BLOGIC_MBOX_START, ccb)) {
3063 spin_unlock_irq(adapter->scsi_host->host_lock);
3064 blogic_warn("Unable to write Outgoing Mailbox - Pausing for 1 second\n", adapter);
3065 blogic_delay(1);
3066 spin_lock_irq(adapter->scsi_host->host_lock);
3067 if (!blogic_write_outbox(adapter, BLOGIC_MBOX_START,
3068 ccb)) {
3069 blogic_warn("Still unable to write Outgoing Mailbox - Host Adapter Dead?\n", adapter);
3070 blogic_dealloc_ccb(ccb, 1);
3071 command->result = DID_ERROR << 16;
3072 scsi_done(command);
3073 }
3074 }
3075 } else {
3076 /*
3077 Call the FlashPoint SCCB Manager to start execution of
3078 the CCB.
3079 */
3080 ccb->status = BLOGIC_CCB_ACTIVE;
3081 adapter->active_cmds[tgt_id]++;
3082 tgt_stats[tgt_id].cmds_tried++;
3083 FlashPoint_StartCCB(adapter->cardhandle, ccb);
3084 /*
3085 The Command may have already completed and
3086 blogic_qcompleted_ccb been called, or it may still be
3087 pending.
3088 */
3089 if (ccb->status == BLOGIC_CCB_COMPLETE)
3090 blogic_process_ccbs(adapter);
3091 }
3092 return 0;
3093}
3094
3095static DEF_SCSI_QCMD(blogic_qcmd)
3096
3097#if 0
3098/*
3099 blogic_abort aborts Command if possible.
3100*/
3101
3102static int blogic_abort(struct scsi_cmnd *command)
3103{
3104 struct blogic_adapter *adapter =
3105 (struct blogic_adapter *) command->device->host->hostdata;
3106
3107 int tgt_id = command->device->id;
3108 struct blogic_ccb *ccb;
3109 blogic_inc_count(&adapter->tgt_stats[tgt_id].aborts_request);
3110
3111 /*
3112 Attempt to find an Active CCB for this Command. If no Active
3113 CCB for this Command is found, then no Abort is necessary.
3114 */
3115 for (ccb = adapter->all_ccbs; ccb != NULL; ccb = ccb->next_all)
3116 if (ccb->command == command)
3117 break;
3118 if (ccb == NULL) {
3119 blogic_warn("Unable to Abort Command to Target %d - No CCB Found\n", adapter, tgt_id);
3120 return SUCCESS;
3121 } else if (ccb->status == BLOGIC_CCB_COMPLETE) {
3122 blogic_warn("Unable to Abort Command to Target %d - CCB Completed\n", adapter, tgt_id);
3123 return SUCCESS;
3124 } else if (ccb->status == BLOGIC_CCB_RESET) {
3125 blogic_warn("Unable to Abort Command to Target %d - CCB Reset\n", adapter, tgt_id);
3126 return SUCCESS;
3127 }
3128 if (blogic_multimaster_type(adapter)) {
3129 /*
3130 Attempt to Abort this CCB. MultiMaster Firmware versions
3131 prior to 5.xx do not generate Abort Tag messages, but only
3132 generate the non-tagged Abort message. Since non-tagged
3133 commands are not sent by the Host Adapter until the queue
3134 of outstanding tagged commands has completed, and the
3135 Abort message is treated as a non-tagged command, it is
3136 effectively impossible to abort commands when Tagged
3137 Queuing is active. Firmware version 5.xx does generate
3138 Abort Tag messages, so it is possible to abort commands
3139 when Tagged Queuing is active.
3140 */
3141 if (adapter->tgt_flags[tgt_id].tagq_active &&
3142 adapter->fw_ver[0] < '5') {
3143 blogic_warn("Unable to Abort CCB #%ld to Target %d - Abort Tag Not Supported\n", adapter, ccb->serial, tgt_id);
3144 return FAILURE;
3145 } else if (blogic_write_outbox(adapter, BLOGIC_MBOX_ABORT,
3146 ccb)) {
3147 blogic_warn("Aborting CCB #%ld to Target %d\n",
3148 adapter, ccb->serial, tgt_id);
3149 blogic_inc_count(&adapter->tgt_stats[tgt_id].aborts_tried);
3150 return SUCCESS;
3151 } else {
3152 blogic_warn("Unable to Abort CCB #%ld to Target %d - No Outgoing Mailboxes\n", adapter, ccb->serial, tgt_id);
3153 return FAILURE;
3154 }
3155 } else {
3156 /*
3157 Call the FlashPoint SCCB Manager to abort execution of
3158 the CCB.
3159 */
3160 blogic_warn("Aborting CCB #%ld to Target %d\n", adapter,
3161 ccb->serial, tgt_id);
3162 blogic_inc_count(&adapter->tgt_stats[tgt_id].aborts_tried);
3163 FlashPoint_AbortCCB(adapter->cardhandle, ccb);
3164 /*
3165 The Abort may have already been completed and
3166 blogic_qcompleted_ccb been called, or it
3167 may still be pending.
3168 */
3169 if (ccb->status == BLOGIC_CCB_COMPLETE)
3170 blogic_process_ccbs(adapter);
3171 return SUCCESS;
3172 }
3173 return SUCCESS;
3174}
3175
3176#endif
3177/*
3178 blogic_resetadapter resets Host Adapter if possible, marking all
3179 currently executing SCSI Commands as having been Reset.
3180*/
3181
3182static int blogic_resetadapter(struct blogic_adapter *adapter, bool hard_reset)
3183{
3184 struct blogic_ccb *ccb;
3185 int tgt_id;
3186
3187 /*
3188 * Attempt to Reset and Reinitialize the Host Adapter.
3189 */
3190
3191 if (!(blogic_hwreset(adapter, hard_reset) &&
3192 blogic_initadapter(adapter))) {
3193 blogic_err("Resetting %s Failed\n", adapter,
3194 adapter->full_model);
3195 return FAILURE;
3196 }
3197
3198 /*
3199 * Deallocate all currently executing CCBs.
3200 */
3201
3202 for (ccb = adapter->all_ccbs; ccb != NULL; ccb = ccb->next_all)
3203 if (ccb->status == BLOGIC_CCB_ACTIVE)
3204 blogic_dealloc_ccb(ccb, 1);
3205 /*
3206 * Wait a few seconds between the Host Adapter Hard Reset which
3207 * initiates a SCSI Bus Reset and issuing any SCSI Commands. Some
3208 * SCSI devices get confused if they receive SCSI Commands too soon
3209 * after a SCSI Bus Reset.
3210 */
3211
3212 if (hard_reset) {
3213 spin_unlock_irq(adapter->scsi_host->host_lock);
3214 blogic_delay(adapter->bus_settle_time);
3215 spin_lock_irq(adapter->scsi_host->host_lock);
3216 }
3217
3218 for (tgt_id = 0; tgt_id < adapter->maxdev; tgt_id++) {
3219 adapter->last_resettried[tgt_id] = jiffies;
3220 adapter->last_resetdone[tgt_id] = jiffies;
3221 }
3222 return SUCCESS;
3223}
3224
3225/*
3226 blogic_diskparam returns the Heads/Sectors/Cylinders BIOS Disk
3227 Parameters for Disk. The default disk geometry is 64 heads, 32 sectors, and
3228 the appropriate number of cylinders so as not to exceed drive capacity. In
3229 order for disks equal to or larger than 1 GB to be addressable by the BIOS
3230 without exceeding the BIOS limitation of 1024 cylinders, Extended Translation
3231 may be enabled in AutoSCSI on FlashPoint Host Adapters and on "W" and "C"
3232 series MultiMaster Host Adapters, or by a dip switch setting on "S" and "A"
3233 series MultiMaster Host Adapters. With Extended Translation enabled, drives
3234 between 1 GB inclusive and 2 GB exclusive are given a disk geometry of 128
3235 heads and 32 sectors, and drives above 2 GB inclusive are given a disk
3236 geometry of 255 heads and 63 sectors. However, if the BIOS detects that the
3237 Extended Translation setting does not match the geometry in the partition
3238 table, then the translation inferred from the partition table will be used by
3239 the BIOS, and a warning may be displayed.
3240*/
3241
3242static int blogic_diskparam(struct scsi_device *sdev, struct block_device *dev,
3243 sector_t capacity, int *params)
3244{
3245 struct blogic_adapter *adapter =
3246 (struct blogic_adapter *) sdev->host->hostdata;
3247 struct bios_diskparam *diskparam = (struct bios_diskparam *) params;
3248 unsigned char *buf;
3249
3250 if (adapter->ext_trans_enable && capacity >= 2 * 1024 * 1024 /* 1 GB in 512 byte sectors */) {
3251 if (capacity >= 4 * 1024 * 1024 /* 2 GB in 512 byte sectors */) {
3252 diskparam->heads = 255;
3253 diskparam->sectors = 63;
3254 } else {
3255 diskparam->heads = 128;
3256 diskparam->sectors = 32;
3257 }
3258 } else {
3259 diskparam->heads = 64;
3260 diskparam->sectors = 32;
3261 }
3262 diskparam->cylinders = (unsigned long) capacity / (diskparam->heads * diskparam->sectors);
3263 buf = scsi_bios_ptable(dev);
3264 if (buf == NULL)
3265 return 0;
3266 /*
3267 If the boot sector partition table flag is valid, search for
3268 a partition table entry whose end_head matches one of the
3269 standard BusLogic geometry translations (64/32, 128/32, or 255/63).
3270 */
3271 if (*(unsigned short *) (buf + 64) == MSDOS_LABEL_MAGIC) {
3272 struct msdos_partition *part1_entry =
3273 (struct msdos_partition *)buf;
3274 struct msdos_partition *part_entry = part1_entry;
3275 int saved_cyl = diskparam->cylinders, part_no;
3276 unsigned char part_end_head = 0, part_end_sector = 0;
3277
3278 for (part_no = 0; part_no < 4; part_no++) {
3279 part_end_head = part_entry->end_head;
3280 part_end_sector = part_entry->end_sector & 0x3F;
3281 if (part_end_head == 64 - 1) {
3282 diskparam->heads = 64;
3283 diskparam->sectors = 32;
3284 break;
3285 } else if (part_end_head == 128 - 1) {
3286 diskparam->heads = 128;
3287 diskparam->sectors = 32;
3288 break;
3289 } else if (part_end_head == 255 - 1) {
3290 diskparam->heads = 255;
3291 diskparam->sectors = 63;
3292 break;
3293 }
3294 part_entry++;
3295 }
3296 if (part_no == 4) {
3297 part_end_head = part1_entry->end_head;
3298 part_end_sector = part1_entry->end_sector & 0x3F;
3299 }
3300 diskparam->cylinders = (unsigned long) capacity / (diskparam->heads * diskparam->sectors);
3301 if (part_no < 4 && part_end_sector == diskparam->sectors) {
3302 if (diskparam->cylinders != saved_cyl)
3303 blogic_warn("Adopting Geometry %d/%d from Partition Table\n", adapter, diskparam->heads, diskparam->sectors);
3304 } else if (part_end_head > 0 || part_end_sector > 0) {
3305 blogic_warn("Warning: Partition Table appears to have Geometry %d/%d which is\n", adapter, part_end_head + 1, part_end_sector);
3306 blogic_warn("not compatible with current BusLogic Host Adapter Geometry %d/%d\n", adapter, diskparam->heads, diskparam->sectors);
3307 }
3308 }
3309 kfree(buf);
3310 return 0;
3311}
3312
3313
3314/*
3315 BugLogic_ProcDirectoryInfo implements /proc/scsi/BusLogic/<N>.
3316*/
3317
3318static int blogic_write_info(struct Scsi_Host *shost, char *procbuf,
3319 int bytes_avail)
3320{
3321 struct blogic_adapter *adapter =
3322 (struct blogic_adapter *) shost->hostdata;
3323 struct blogic_tgt_stats *tgt_stats;
3324
3325 tgt_stats = adapter->tgt_stats;
3326 adapter->ext_resets = 0;
3327 adapter->adapter_intern_errors = 0;
3328 memset(tgt_stats, 0, BLOGIC_MAXDEV * sizeof(struct blogic_tgt_stats));
3329 return 0;
3330}
3331
3332static int blogic_show_info(struct seq_file *m, struct Scsi_Host *shost)
3333{
3334 struct blogic_adapter *adapter = (struct blogic_adapter *) shost->hostdata;
3335 struct blogic_tgt_stats *tgt_stats;
3336 int tgt;
3337
3338 tgt_stats = adapter->tgt_stats;
3339 seq_write(m, adapter->msgbuf, adapter->msgbuflen);
3340 seq_printf(m, "\n\
3341Current Driver Queue Depth: %d\n\
3342Currently Allocated CCBs: %d\n", adapter->drvr_qdepth, adapter->alloc_ccbs);
3343 seq_puts(m, "\n\n\
3344 DATA TRANSFER STATISTICS\n\
3345\n\
3346Target Tagged Queuing Queue Depth Active Attempted Completed\n\
3347====== ============== =========== ====== ========= =========\n");
3348 for (tgt = 0; tgt < adapter->maxdev; tgt++) {
3349 struct blogic_tgt_flags *tgt_flags = &adapter->tgt_flags[tgt];
3350 if (!tgt_flags->tgt_exists)
3351 continue;
3352 seq_printf(m, " %2d %s", tgt, (tgt_flags->tagq_ok ? (tgt_flags->tagq_active ? " Active" : (adapter->tagq_ok & (1 << tgt)
3353 ? " Permitted" : " Disabled"))
3354 : "Not Supported"));
3355 seq_printf(m,
3356 " %3d %3u %9u %9u\n", adapter->qdepth[tgt], adapter->active_cmds[tgt], tgt_stats[tgt].cmds_tried, tgt_stats[tgt].cmds_complete);
3357 }
3358 seq_puts(m, "\n\
3359Target Read Commands Write Commands Total Bytes Read Total Bytes Written\n\
3360====== ============= ============== =================== ===================\n");
3361 for (tgt = 0; tgt < adapter->maxdev; tgt++) {
3362 struct blogic_tgt_flags *tgt_flags = &adapter->tgt_flags[tgt];
3363 if (!tgt_flags->tgt_exists)
3364 continue;
3365 seq_printf(m, " %2d %9u %9u", tgt, tgt_stats[tgt].read_cmds, tgt_stats[tgt].write_cmds);
3366 if (tgt_stats[tgt].bytesread.billions > 0)
3367 seq_printf(m, " %9u%09u", tgt_stats[tgt].bytesread.billions, tgt_stats[tgt].bytesread.units);
3368 else
3369 seq_printf(m, " %9u", tgt_stats[tgt].bytesread.units);
3370 if (tgt_stats[tgt].byteswritten.billions > 0)
3371 seq_printf(m, " %9u%09u\n", tgt_stats[tgt].byteswritten.billions, tgt_stats[tgt].byteswritten.units);
3372 else
3373 seq_printf(m, " %9u\n", tgt_stats[tgt].byteswritten.units);
3374 }
3375 seq_puts(m, "\n\
3376Target Command 0-1KB 1-2KB 2-4KB 4-8KB 8-16KB\n\
3377====== ======= ========= ========= ========= ========= =========\n");
3378 for (tgt = 0; tgt < adapter->maxdev; tgt++) {
3379 struct blogic_tgt_flags *tgt_flags = &adapter->tgt_flags[tgt];
3380 if (!tgt_flags->tgt_exists)
3381 continue;
3382 seq_printf(m,
3383 " %2d Read %9u %9u %9u %9u %9u\n", tgt,
3384 tgt_stats[tgt].read_sz_buckets[0],
3385 tgt_stats[tgt].read_sz_buckets[1], tgt_stats[tgt].read_sz_buckets[2], tgt_stats[tgt].read_sz_buckets[3], tgt_stats[tgt].read_sz_buckets[4]);
3386 seq_printf(m,
3387 " %2d Write %9u %9u %9u %9u %9u\n", tgt,
3388 tgt_stats[tgt].write_sz_buckets[0],
3389 tgt_stats[tgt].write_sz_buckets[1], tgt_stats[tgt].write_sz_buckets[2], tgt_stats[tgt].write_sz_buckets[3], tgt_stats[tgt].write_sz_buckets[4]);
3390 }
3391 seq_puts(m, "\n\
3392Target Command 16-32KB 32-64KB 64-128KB 128-256KB 256KB+\n\
3393====== ======= ========= ========= ========= ========= =========\n");
3394 for (tgt = 0; tgt < adapter->maxdev; tgt++) {
3395 struct blogic_tgt_flags *tgt_flags = &adapter->tgt_flags[tgt];
3396 if (!tgt_flags->tgt_exists)
3397 continue;
3398 seq_printf(m,
3399 " %2d Read %9u %9u %9u %9u %9u\n", tgt,
3400 tgt_stats[tgt].read_sz_buckets[5],
3401 tgt_stats[tgt].read_sz_buckets[6], tgt_stats[tgt].read_sz_buckets[7], tgt_stats[tgt].read_sz_buckets[8], tgt_stats[tgt].read_sz_buckets[9]);
3402 seq_printf(m,
3403 " %2d Write %9u %9u %9u %9u %9u\n", tgt,
3404 tgt_stats[tgt].write_sz_buckets[5],
3405 tgt_stats[tgt].write_sz_buckets[6], tgt_stats[tgt].write_sz_buckets[7], tgt_stats[tgt].write_sz_buckets[8], tgt_stats[tgt].write_sz_buckets[9]);
3406 }
3407 seq_puts(m, "\n\n\
3408 ERROR RECOVERY STATISTICS\n\
3409\n\
3410 Command Aborts Bus Device Resets Host Adapter Resets\n\
3411Target Requested Completed Requested Completed Requested Completed\n\
3412 ID \\\\\\\\ Attempted //// \\\\\\\\ Attempted //// \\\\\\\\ Attempted ////\n\
3413====== ===== ===== ===== ===== ===== ===== ===== ===== =====\n");
3414 for (tgt = 0; tgt < adapter->maxdev; tgt++) {
3415 struct blogic_tgt_flags *tgt_flags = &adapter->tgt_flags[tgt];
3416 if (!tgt_flags->tgt_exists)
3417 continue;
3418 seq_printf(m, " %2d %5d %5d %5d %5d %5d %5d %5d %5d %5d\n",
3419 tgt, tgt_stats[tgt].aborts_request,
3420 tgt_stats[tgt].aborts_tried,
3421 tgt_stats[tgt].aborts_done,
3422 tgt_stats[tgt].bdr_request,
3423 tgt_stats[tgt].bdr_tried,
3424 tgt_stats[tgt].bdr_done,
3425 tgt_stats[tgt].adapter_reset_req,
3426 tgt_stats[tgt].adapter_reset_attempt,
3427 tgt_stats[tgt].adapter_reset_done);
3428 }
3429 seq_printf(m, "\nExternal Host Adapter Resets: %d\n", adapter->ext_resets);
3430 seq_printf(m, "Host Adapter Internal Errors: %d\n", adapter->adapter_intern_errors);
3431 return 0;
3432}
3433
3434
3435/*
3436 blogic_msg prints Driver Messages.
3437*/
3438__printf(2, 4)
3439static void blogic_msg(enum blogic_msglevel msglevel, char *fmt,
3440 struct blogic_adapter *adapter, ...)
3441{
3442 static char buf[BLOGIC_LINEBUF_SIZE];
3443 static bool begin = true;
3444 va_list args;
3445 int len = 0;
3446
3447 va_start(args, adapter);
3448 len = vscnprintf(buf, sizeof(buf), fmt, args);
3449 va_end(args);
3450 if (msglevel == BLOGIC_ANNOUNCE_LEVEL) {
3451 static int msglines = 0;
3452 strcpy(&adapter->msgbuf[adapter->msgbuflen], buf);
3453 adapter->msgbuflen += len;
3454 if (++msglines <= 2)
3455 printk("%sscsi: %s", blogic_msglevelmap[msglevel], buf);
3456 } else if (msglevel == BLOGIC_INFO_LEVEL) {
3457 strcpy(&adapter->msgbuf[adapter->msgbuflen], buf);
3458 adapter->msgbuflen += len;
3459 if (begin) {
3460 if (buf[0] != '\n' || len > 1)
3461 printk("%sscsi%d: %s", blogic_msglevelmap[msglevel], adapter->host_no, buf);
3462 } else
3463 pr_cont("%s", buf);
3464 } else {
3465 if (begin) {
3466 if (adapter != NULL && adapter->adapter_initd)
3467 printk("%sscsi%d: %s", blogic_msglevelmap[msglevel], adapter->host_no, buf);
3468 else
3469 printk("%s%s", blogic_msglevelmap[msglevel], buf);
3470 } else
3471 pr_cont("%s", buf);
3472 }
3473 begin = (buf[len - 1] == '\n');
3474}
3475
3476
3477/*
3478 blogic_parse parses an individual option keyword. It returns true
3479 and updates the pointer if the keyword is recognized and false otherwise.
3480*/
3481
3482static bool __init blogic_parse(char **str, char *keyword)
3483{
3484 char *pointer = *str;
3485 while (*keyword != '\0') {
3486 char strch = *pointer++;
3487 char keywordch = *keyword++;
3488 if (strch >= 'A' && strch <= 'Z')
3489 strch += 'a' - 'Z';
3490 if (keywordch >= 'A' && keywordch <= 'Z')
3491 keywordch += 'a' - 'Z';
3492 if (strch != keywordch)
3493 return false;
3494 }
3495 *str = pointer;
3496 return true;
3497}
3498
3499
3500/*
3501 blogic_parseopts handles processing of BusLogic Driver Options
3502 specifications.
3503
3504 BusLogic Driver Options may be specified either via the Linux Kernel Command
3505 Line or via the Loadable Kernel Module Installation Facility. Driver Options
3506 for multiple host adapters may be specified either by separating the option
3507 strings by a semicolon, or by specifying multiple "BusLogic=" strings on the
3508 command line. Individual option specifications for a single host adapter are
3509 separated by commas. The Probing and Debugging Options apply to all host
3510 adapters whereas the remaining options apply individually only to the
3511 selected host adapter.
3512
3513 The BusLogic Driver Probing Options are described in
3514 <file:Documentation/scsi/BusLogic.rst>.
3515*/
3516
3517static int __init blogic_parseopts(char *options)
3518{
3519 while (true) {
3520 struct blogic_drvr_options *drvr_opts =
3521 &blogic_drvr_options[blogic_drvr_options_count++];
3522 int tgt_id;
3523
3524 memset(drvr_opts, 0, sizeof(struct blogic_drvr_options));
3525 while (*options != '\0' && *options != ';') {
3526 if (blogic_parse(&options, "NoProbePCI"))
3527 blogic_probe_options.noprobe_pci = true;
3528 else if (blogic_parse(&options, "NoProbe"))
3529 blogic_probe_options.noprobe = true;
3530 else if (blogic_parse(&options, "NoSortPCI"))
3531 blogic_probe_options.nosort_pci = true;
3532 else if (blogic_parse(&options, "MultiMasterFirst"))
3533 blogic_probe_options.multimaster_first = true;
3534 else if (blogic_parse(&options, "FlashPointFirst"))
3535 blogic_probe_options.flashpoint_first = true;
3536 /* Tagged Queuing Options. */
3537 else if (blogic_parse(&options, "QueueDepth:[") ||
3538 blogic_parse(&options, "QD:[")) {
3539 for (tgt_id = 0; tgt_id < BLOGIC_MAXDEV; tgt_id++) {
3540 unsigned short qdepth = simple_strtoul(options, &options, 0);
3541 if (qdepth > BLOGIC_MAX_TAG_DEPTH) {
3542 blogic_err("BusLogic: Invalid Driver Options (invalid Queue Depth %d)\n", NULL, qdepth);
3543 return 0;
3544 }
3545 drvr_opts->qdepth[tgt_id] = qdepth;
3546 if (*options == ',')
3547 options++;
3548 else if (*options == ']')
3549 break;
3550 else {
3551 blogic_err("BusLogic: Invalid Driver Options (',' or ']' expected at '%s')\n", NULL, options);
3552 return 0;
3553 }
3554 }
3555 if (*options != ']') {
3556 blogic_err("BusLogic: Invalid Driver Options (']' expected at '%s')\n", NULL, options);
3557 return 0;
3558 } else
3559 options++;
3560 } else if (blogic_parse(&options, "QueueDepth:") || blogic_parse(&options, "QD:")) {
3561 unsigned short qdepth = simple_strtoul(options, &options, 0);
3562 if (qdepth == 0 ||
3563 qdepth > BLOGIC_MAX_TAG_DEPTH) {
3564 blogic_err("BusLogic: Invalid Driver Options (invalid Queue Depth %d)\n", NULL, qdepth);
3565 return 0;
3566 }
3567 drvr_opts->common_qdepth = qdepth;
3568 for (tgt_id = 0; tgt_id < BLOGIC_MAXDEV; tgt_id++)
3569 drvr_opts->qdepth[tgt_id] = qdepth;
3570 } else if (blogic_parse(&options, "TaggedQueuing:") ||
3571 blogic_parse(&options, "TQ:")) {
3572 if (blogic_parse(&options, "Default")) {
3573 drvr_opts->tagq_ok = 0x0000;
3574 drvr_opts->tagq_ok_mask = 0x0000;
3575 } else if (blogic_parse(&options, "Enable")) {
3576 drvr_opts->tagq_ok = 0xFFFF;
3577 drvr_opts->tagq_ok_mask = 0xFFFF;
3578 } else if (blogic_parse(&options, "Disable")) {
3579 drvr_opts->tagq_ok = 0x0000;
3580 drvr_opts->tagq_ok_mask = 0xFFFF;
3581 } else {
3582 unsigned short tgt_bit;
3583 for (tgt_id = 0, tgt_bit = 1;
3584 tgt_id < BLOGIC_MAXDEV;
3585 tgt_id++, tgt_bit <<= 1)
3586 switch (*options++) {
3587 case 'Y':
3588 drvr_opts->tagq_ok |= tgt_bit;
3589 drvr_opts->tagq_ok_mask |= tgt_bit;
3590 break;
3591 case 'N':
3592 drvr_opts->tagq_ok &= ~tgt_bit;
3593 drvr_opts->tagq_ok_mask |= tgt_bit;
3594 break;
3595 case 'X':
3596 break;
3597 default:
3598 options--;
3599 tgt_id = BLOGIC_MAXDEV;
3600 break;
3601 }
3602 }
3603 }
3604 /* Miscellaneous Options. */
3605 else if (blogic_parse(&options, "BusSettleTime:") ||
3606 blogic_parse(&options, "BST:")) {
3607 unsigned short bus_settle_time =
3608 simple_strtoul(options, &options, 0);
3609 if (bus_settle_time > 5 * 60) {
3610 blogic_err("BusLogic: Invalid Driver Options (invalid Bus Settle Time %d)\n", NULL, bus_settle_time);
3611 return 0;
3612 }
3613 drvr_opts->bus_settle_time = bus_settle_time;
3614 } else if (blogic_parse(&options,
3615 "InhibitTargetInquiry"))
3616 drvr_opts->stop_tgt_inquiry = true;
3617 /* Debugging Options. */
3618 else if (blogic_parse(&options, "TraceProbe"))
3619 blogic_global_options.trace_probe = true;
3620 else if (blogic_parse(&options, "TraceHardwareReset"))
3621 blogic_global_options.trace_hw_reset = true;
3622 else if (blogic_parse(&options, "TraceConfiguration"))
3623 blogic_global_options.trace_config = true;
3624 else if (blogic_parse(&options, "TraceErrors"))
3625 blogic_global_options.trace_err = true;
3626 else if (blogic_parse(&options, "Debug")) {
3627 blogic_global_options.trace_probe = true;
3628 blogic_global_options.trace_hw_reset = true;
3629 blogic_global_options.trace_config = true;
3630 blogic_global_options.trace_err = true;
3631 }
3632 if (*options == ',')
3633 options++;
3634 else if (*options != ';' && *options != '\0') {
3635 blogic_err("BusLogic: Unexpected Driver Option '%s' ignored\n", NULL, options);
3636 *options = '\0';
3637 }
3638 }
3639 if (!(blogic_drvr_options_count == 0 ||
3640 blogic_probeinfo_count == 0 ||
3641 blogic_drvr_options_count == blogic_probeinfo_count)) {
3642 blogic_err("BusLogic: Invalid Driver Options (all or no I/O Addresses must be specified)\n", NULL);
3643 return 0;
3644 }
3645 /*
3646 Tagged Queuing is disabled when the Queue Depth is 1 since queuing
3647 multiple commands is not possible.
3648 */
3649 for (tgt_id = 0; tgt_id < BLOGIC_MAXDEV; tgt_id++)
3650 if (drvr_opts->qdepth[tgt_id] == 1) {
3651 unsigned short tgt_bit = 1 << tgt_id;
3652 drvr_opts->tagq_ok &= ~tgt_bit;
3653 drvr_opts->tagq_ok_mask |= tgt_bit;
3654 }
3655 if (*options == ';')
3656 options++;
3657 if (*options == '\0')
3658 return 0;
3659 }
3660 return 1;
3661}
3662
3663/*
3664 Get it all started
3665*/
3666
3667static const struct scsi_host_template blogic_template = {
3668 .module = THIS_MODULE,
3669 .proc_name = "BusLogic",
3670 .write_info = blogic_write_info,
3671 .show_info = blogic_show_info,
3672 .name = "BusLogic",
3673 .info = blogic_drvr_info,
3674 .queuecommand = blogic_qcmd,
3675 .slave_configure = blogic_slaveconfig,
3676 .bios_param = blogic_diskparam,
3677 .eh_host_reset_handler = blogic_hostreset,
3678#if 0
3679 .eh_abort_handler = blogic_abort,
3680#endif
3681 .max_sectors = 128,
3682};
3683
3684/*
3685 blogic_setup handles processing of Kernel Command Line Arguments.
3686*/
3687
3688static int __init blogic_setup(char *str)
3689{
3690 int ints[3];
3691
3692 (void) get_options(str, ARRAY_SIZE(ints), ints);
3693
3694 if (ints[0] != 0) {
3695 blogic_err("BusLogic: Obsolete Command Line Entry Format Ignored\n", NULL);
3696 return 0;
3697 }
3698 if (str == NULL || *str == '\0')
3699 return 0;
3700 return blogic_parseopts(str);
3701}
3702
3703/*
3704 * Exit function. Deletes all hosts associated with this driver.
3705 */
3706
3707static void __exit blogic_exit(void)
3708{
3709 struct blogic_adapter *ha, *next;
3710
3711 list_for_each_entry_safe(ha, next, &blogic_host_list, host_list)
3712 blogic_deladapter(ha);
3713}
3714
3715__setup("BusLogic=", blogic_setup);
3716
3717#ifdef MODULE
3718/*static struct pci_device_id blogic_pci_tbl[] = {
3719 { PCI_VENDOR_ID_BUSLOGIC, PCI_DEVICE_ID_BUSLOGIC_MULTIMASTER,
3720 PCI_ANY_ID, PCI_ANY_ID, 0, 0, 0},
3721 { PCI_VENDOR_ID_BUSLOGIC, PCI_DEVICE_ID_BUSLOGIC_MULTIMASTER_NC,
3722 PCI_ANY_ID, PCI_ANY_ID, 0, 0, 0},
3723 { PCI_VENDOR_ID_BUSLOGIC, PCI_DEVICE_ID_BUSLOGIC_FLASHPOINT,
3724 PCI_ANY_ID, PCI_ANY_ID, 0, 0, 0},
3725 { }
3726};*/
3727static const struct pci_device_id blogic_pci_tbl[] = {
3728 {PCI_DEVICE(PCI_VENDOR_ID_BUSLOGIC, PCI_DEVICE_ID_BUSLOGIC_MULTIMASTER)},
3729 {PCI_DEVICE(PCI_VENDOR_ID_BUSLOGIC, PCI_DEVICE_ID_BUSLOGIC_MULTIMASTER_NC)},
3730 {PCI_DEVICE(PCI_VENDOR_ID_BUSLOGIC, PCI_DEVICE_ID_BUSLOGIC_FLASHPOINT)},
3731 {0, },
3732};
3733#endif
3734MODULE_DEVICE_TABLE(pci, blogic_pci_tbl);
3735
3736module_init(blogic_init);
3737module_exit(blogic_exit);