1 /*++
2
3 Copyright (C) Microsoft Corporation, 1991 - 1999
4
5 Module Name:
6
7 floppy.c
8
9 Abstract:
10
11 SCSI floppy class driver
12
13 Author:
14
15 Jeff Havens (jhavens)
16
17 Environment:
18
19 kernel mode only
20
21 Notes:
22
23 Revision History:
24 02/28/96 georgioc Merged this code with code developed by compaq in
25 parallel with microsoft, for 120MB floppy support.
26
27 01/17/96 georgioc Made code PNP aware (uses the new \storage\classpnp/scsiport)
28
29 --*/
30
31 #if !defined(__REACTOS__) || defined(_MSC_VER)
32 #pragma warning(disable:4214) // nonstandard extension used : bit field types other than int
33 #pragma warning(disable:4201) // nonstandard extension used : nameless struct/union
34 #endif
35
36 #include <stddef.h>
37 #include <ntddk.h>
38 #ifndef __REACTOS__
39 #include <winerror.h>
40 #endif
41 #include <scsi.h>
42 #include <classpnp.h>
43 #include <initguid.h>
44 #include <ntddstor.h>
45
46 #include <ntstrsafe.h>
47 #include <intsafe.h>
48
49 #ifdef __REACTOS__
50 // Downgrade unsupported NT6.2+ features.
51 #define NonPagedPoolNx NonPagedPool
52 #define NonPagedPoolNxCacheAligned NonPagedPoolCacheAligned
53 #endif
54
55 #define MODE_DATA_SIZE 192
56 #define SCSI_FLOPPY_TIMEOUT 20
57 #define SFLOPPY_SRB_LIST_SIZE 4
58 //
59 // Define all possible drive/media combinations, given drives listed above
60 // and media types in ntdddisk.h.
61 //
62 // These values are used to index the DriveMediaConstants table.
63 //
64
65 #define NUMBER_OF_DRIVE_TYPES 7
66 #define DRIVE_TYPE_120M 4 //120MB Floptical
67 #define DRIVE_TYPE_NONE NUMBER_OF_DRIVE_TYPES
68
69 //
70 // This array describes all media types we support.
71 // It should be arranged in the increasing order of density
72 //
73 // For a given drive, we list all the mediatypes that will
74 // work with that drive. For instance, a 120MB drive will
75 // take 720KB media, 1.44MB media, and 120MB media.
76 //
77 // Note that, DriveMediaConstants given below is grouped
78 // as drive and media combination
79 //
80 typedef enum _DRIVE_MEDIA_TYPE {
81 Drive360Media160, // 5.25" 360k drive; 160k media
82 Drive360Media180, // 5.25" 360k drive; 180k media
83 Drive360Media320, // 5.25" 360k drive; 320k media
84 Drive360Media32X, // 5.25" 360k drive; 320k 1k secs
85 Drive360Media360, // 5.25" 360k drive; 360k media
86 Drive720Media720, // 3.5" 720k drive; 720k media
87 Drive120Media160, // 5.25" 1.2Mb drive; 160k media
88 Drive120Media180, // 5.25" 1.2Mb drive; 180k media
89 Drive120Media320, // 5.25" 1.2Mb drive; 320k media
90 Drive120Media32X, // 5.25" 1.2Mb drive; 320k 1k secs
91 Drive120Media360, // 5.25" 1.2Mb drive; 360k media
92 Drive120Media120, // 5.25" 1.2Mb drive; 1.2Mb media
93 Drive144Media720, // 3.5" 1.44Mb drive; 720k media
94 Drive144Media144, // 3.5" 1.44Mb drive; 1.44Mb media
95 Drive288Media720, // 3.5" 2.88Mb drive; 720k media
96 Drive288Media144, // 3.5" 2.88Mb drive; 1.44Mb media
97 Drive288Media288, // 3.5" 2.88Mb drive; 2.88Mb media
98 Drive2080Media720, // 3.5" 20.8Mb drive; 720k media
99 Drive2080Media144, // 3.5" 20.8Mb drive; 1.44Mb media
100 Drive2080Media2080, // 3.5" 20.8Mb drive; 20.8Mb media
101 Drive32MMedia32M, // 3.5" 32Mb drive; 32MB media
102 Drive120MMedia720, // 3.5" 120Mb drive; 720k media
103 Drive120MMedia144, // 3.5" 120Mb drive; 1.44Mb media
104 Drive120MMedia120M, // 3.5" 120Mb drive; 120Mb media
105 Drive240MMedia144M, // 3.5" 240Mb drive; 1.44Mb media
106 Drive240MMedia120M, // 3.5" 240Mb drive; 120Mb media
107 Drive240MMedia240M // 3.5" 240Mb drive; 240Mb media
108 } DRIVE_MEDIA_TYPE;
109
110 //
111 // When we want to determine the media type in a drive, we will first
112 // guess that the media with highest possible density is in the drive,
113 // and keep trying lower densities until we can successfully read from
114 // the drive.
115 //
116 // These values are used to select a DRIVE_MEDIA_TYPE value.
117 //
118 // The following table defines ranges that apply to the DRIVE_MEDIA_TYPE
119 // enumerated values when trying media types for a particular drive type.
120 // Note that for this to work, the DRIVE_MEDIA_TYPE values must be sorted
121 // by ascending densities within drive types. Also, for maximum track
122 // size to be determined properly, the drive types must be in ascending
123 // order.
124 //
125
126 typedef struct _DRIVE_MEDIA_LIMITS {
127 DRIVE_MEDIA_TYPE HighestDriveMediaType;
128 DRIVE_MEDIA_TYPE LowestDriveMediaType;
129 } DRIVE_MEDIA_LIMITS, *PDRIVE_MEDIA_LIMITS;
130
131 #if 0
132 DRIVE_MEDIA_LIMITS DriveMediaLimits[NUMBER_OF_DRIVE_TYPES] = {
133
134 { Drive360Media360, Drive360Media160 }, // DRIVE_TYPE_0360
135 { Drive120Media120, Drive120Media160 }, // DRIVE_TYPE_1200
136 { Drive720Media720, Drive720Media720 }, // DRIVE_TYPE_0720
137 { Drive144Media144, Drive144Media720 }, // DRIVE_TYPE_1440
138 { Drive288Media288, Drive288Media720 }, // DRIVE_TYPE_2880
139 { Drive2080Media2080, Drive2080Media720 }
140 };
141 #else
142 DRIVE_MEDIA_LIMITS DriveMediaLimits[NUMBER_OF_DRIVE_TYPES] = {
143
144 { Drive720Media720, Drive720Media720 }, // DRIVE_TYPE_0720
145 { Drive144Media144, Drive144Media720}, // DRIVE_TYPE_1440
146 { Drive288Media288, Drive288Media720}, // DRIVE_TYPE_2880
147 { Drive2080Media2080, Drive2080Media720 },
148 { Drive32MMedia32M, Drive32MMedia32M }, // DRIVE_TYPE_32M
149 { Drive120MMedia120M, Drive120MMedia720 }, // DRIVE_TYPE_120M
150 { Drive240MMedia240M, Drive240MMedia144M } // DRIVE_TYPE_240M
151 };
152
153 #endif
154 //
155 // For each drive/media combination, define important constants.
156 //
157
158 typedef struct _DRIVE_MEDIA_CONSTANTS {
159 MEDIA_TYPE MediaType;
160 USHORT BytesPerSector;
161 UCHAR SectorsPerTrack;
162 USHORT MaximumTrack;
163 UCHAR NumberOfHeads;
164 } DRIVE_MEDIA_CONSTANTS, *PDRIVE_MEDIA_CONSTANTS;
165
166 //
167 // Magic value to add to the SectorLengthCode to use it as a shift value
168 // to determine the sector size.
169 //
170
171 #define SECTORLENGTHCODE_TO_BYTESHIFT 7
172
173 //
174 // The following values were gleaned from many different sources, which
175 // often disagreed with each other. Where numbers were in conflict, I
176 // chose the more conservative or most-often-selected value.
177 //
178
179 DRIVE_MEDIA_CONSTANTS DriveMediaConstants[] =
180 {
181
182 { F5_160_512, 0x200, 0x08, 0x27, 0x1 },
183 { F5_180_512, 0x200, 0x09, 0x27, 0x1 },
184 { F5_320_1024, 0x400, 0x04, 0x27, 0x2 },
185 { F5_320_512, 0x200, 0x08, 0x27, 0x2 },
186 { F5_360_512, 0x200, 0x09, 0x27, 0x2 },
187
188 { F3_720_512, 0x200, 0x09, 0x4f, 0x2 },
189
190 { F5_160_512, 0x200, 0x08, 0x27, 0x1 },
191 { F5_180_512, 0x200, 0x09, 0x27, 0x1 },
192 { F5_320_1024, 0x400, 0x04, 0x27, 0x2 },
193 { F5_320_512, 0x200, 0x08, 0x27, 0x2 },
194 { F5_360_512, 0x200, 0x09, 0x27, 0x2 },
195 { F5_1Pt2_512, 0x200, 0x0f, 0x4f, 0x2 },
196
197 { F3_720_512, 0x200, 0x09, 0x4f, 0x2 },
198 { F3_1Pt44_512, 0x200, 0x12, 0x4f, 0x2 },
199
200 { F3_720_512, 0x200, 0x09, 0x4f, 0x2 },
201 { F3_1Pt44_512, 0x200, 0x12, 0x4f, 0x2 },
202 { F3_2Pt88_512, 0x200, 0x24, 0x4f, 0x2 },
203
204 { F3_720_512, 0x200, 0x09, 0x4f, 0x2 },
205 { F3_1Pt44_512, 0x200, 0x12, 0x4f, 0x2 },
206 { F3_20Pt8_512, 0x200, 0x1b, 0xfa, 0x6 },
207
208 { F3_32M_512, 0x200, 0x20, 0x3ff,0x2},
209
210 { F3_720_512, 0x200, 0x09, 0x4f, 0x2 },
211 { F3_1Pt44_512, 0x200, 0x12, 0x4f, 0x2 },
212 { F3_120M_512, 0x200, 0x20, 0x3c2,0x8 },
213
214 { F3_1Pt44_512, 0x200, 0x12, 0x4f, 0x2 },
215 { F3_120M_512, 0x200, 0x20, 0x3c2,0x8 },
216 { F3_240M_512, 0x200, 0x38, 0x105,0x20}
217 };
218
219
220 #define NUMBER_OF_DRIVE_MEDIA_COMBINATIONS sizeof(DriveMediaConstants)/sizeof(DRIVE_MEDIA_CONSTANTS)
221
222 //
223 // floppy device data
224 //
225
226 typedef struct _DISK_DATA {
227 ULONG DriveType;
228 BOOLEAN IsDMF;
229 // BOOLEAN EnableDMF;
230 UNICODE_STRING FloppyInterfaceString;
231 } DISK_DATA, *PDISK_DATA;
232
233 //
234 // The FloppyCapacities and FloppyGeometries arrays are used by the
235 // USBFlopGetMediaTypes() and USBFlopFormatTracks() routines.
236
237 // The FloppyCapacities and FloppyGeometries arrays must be kept in 1:1 sync,
238 // i.e. each FloppyGeometries[i] must correspond to each FloppyCapacities[i].
239
240 // Also, the arrays must be kept in sorted ascending order so that they
241 // are returned in sorted ascending order by IOCTL_DISK_GET_MEDIA_TYPES.
242 //
243
244 typedef struct _FORMATTED_CAPACITY
245 {
246 ULONG NumberOfBlocks;
247
248 ULONG BlockLength;
249
250 BOOLEAN CanFormat; // return for IOCTL_DISK_GET_MEDIA_TYPES ?
251
252 } FORMATTED_CAPACITY, *PFORMATTED_CAPACITY;
253
254
255 FORMATTED_CAPACITY FloppyCapacities[] =
256 {
257 // Blocks BlockLen CanFormat H T B/S S/T
258 {0x000500, 0x0200, TRUE}, // 2 80 512 8 640 KB F5_640_512
259 {0x0005A0, 0x0200, TRUE}, // 2 80 512 9 720 KB F3_720_512
260 {0x000960, 0x0200, TRUE}, // 2 80 512 15 1.20 MB F3_1Pt2_512 (Toshiba)
261 {0x0004D0, 0x0400, TRUE}, // 2 77 1024 8 1.23 MB F3_1Pt23_1024 (NEC)
262 {0x000B40, 0x0200, TRUE}, // 2 80 512 18 1.44 MB F3_1Pt44_512
263 {0x000D20, 0x0200, FALSE}, // 2 80 512 21 1.70 MB DMF
264 {0x010000, 0x0200, TRUE}, // 2 1024 512 32 32 MB F3_32M_512
265 {0x03C300, 0x0200, TRUE}, // 8 963 512 32 120 MB F3_120M_512
266 {0x0600A4, 0x0200, TRUE}, // 13 890 512 34 200 MB F3_200Mb_512 (HiFD)
267 {0x072A00, 0x0200, TRUE} // 32 262 512 56 240 MB F3_240M_512
268 };
269
270 DISK_GEOMETRY FloppyGeometries[] =
271 {
272 // Cyl MediaType Trk/Cyl Sec/Trk Bytes/Sec
273 #ifndef __REACTOS__
274 {{80,0}, F3_640_512, 2, 8, 512},
275 {{80,0}, F3_720_512, 2, 9, 512},
276 {{80,0}, F3_1Pt2_512, 2, 15, 512},
277 {{77,0}, F3_1Pt23_1024, 2, 8, 1024},
278 {{80,0}, F3_1Pt44_512, 2, 18, 512},
279 {{80,0}, F3_1Pt44_512, 2, 21, 512}, // DMF -> F3_1Pt44_512
280 {{1024,0}, F3_32M_512, 2, 32, 512},
281 {{963,0}, F3_120M_512, 8, 32, 512},
282 {{890,0}, F3_200Mb_512, 13, 34, 512},
283 {{262,0}, F3_240M_512, 32, 56, 512}
284 #else
285 {{{80,0}}, F3_640_512, 2, 8, 512},
286 {{{80,0}}, F3_720_512, 2, 9, 512},
287 {{{80,0}}, F3_1Pt2_512, 2, 15, 512},
288 {{{77,0}}, F3_1Pt23_1024, 2, 8, 1024},
289 {{{80,0}}, F3_1Pt44_512, 2, 18, 512},
290 {{{80,0}}, F3_1Pt44_512, 2, 21, 512}, // DMF -> F3_1Pt44_512
291 {{{1024,0}}, F3_32M_512, 2, 32, 512},
292 {{{963,0}}, F3_120M_512, 8, 32, 512},
293 {{{890,0}}, F3_200Mb_512, 13, 34, 512},
294 {{{262,0}}, F3_240M_512, 32, 56, 512}
295 #endif
296 };
297
298 #define FLOPPY_CAPACITIES (sizeof(FloppyCapacities)/sizeof(FloppyCapacities[0]))
299
300 C_ASSERT((sizeof(FloppyGeometries)/sizeof(FloppyGeometries[0])) == FLOPPY_CAPACITIES);
301
302 //
303 // The following structures are used by USBFlopFormatTracks()
304 //
305
306 #pragma pack (push, 1)
307
308 typedef struct _CDB12FORMAT
309 {
310 UCHAR OperationCode;
311 UCHAR DefectListFormat : 3;
312 UCHAR CmpList : 1;
313 UCHAR FmtData : 1;
314 UCHAR LogicalUnitNumber : 3;
315 UCHAR TrackNumber;
316 UCHAR InterleaveMsb;
317 UCHAR InterleaveLsb;
318 UCHAR Reserved1[2];
319 UCHAR ParameterListLengthMsb;
320 UCHAR ParameterListLengthLsb;
321 UCHAR Reserved2[3];
322 } CDB12FORMAT, *PCDB12FORMAT;
323
324
325 typedef struct _DEFECT_LIST_HEADER
326 {
327 UCHAR Reserved1;
328 UCHAR Side : 1;
329 UCHAR Immediate : 1;
330 UCHAR Reserved2 : 2;
331 UCHAR SingleTrack : 1;
332 UCHAR DisableCert : 1;
333 UCHAR Reserved3 : 1;
334 UCHAR FormatOptionsValid : 1;
335 UCHAR DefectListLengthMsb;
336 UCHAR DefectListLengthLsb;
337 } DEFECT_LIST_HEADER, *PDEFECT_LIST_HEADER;
338
339 typedef struct _FORMAT_UNIT_PARAMETER_LIST
340 {
341 DEFECT_LIST_HEADER DefectListHeader;
342 FORMATTED_CAPACITY_DESCRIPTOR FormatDescriptor;
343 } FORMAT_UNIT_PARAMETER_LIST, *PFORMAT_UNIT_PARAMETER_LIST;
344
345 #pragma pack (pop)
346
347 DRIVER_INITIALIZE DriverEntry;
348
349 DRIVER_UNLOAD ScsiFlopUnload;
350
351 DRIVER_ADD_DEVICE ScsiFlopAddDevice;
352
353 NTSTATUS
354 #ifdef __REACTOS__
355 NTAPI
356 #endif
357 ScsiFlopInitDevice(
358 IN PDEVICE_OBJECT Fdo
359 );
360
361 NTSTATUS
362 #ifdef __REACTOS__
363 NTAPI
364 #endif
365 ScsiFlopStartDevice(
366 IN PDEVICE_OBJECT Fdo
367 );
368
369 NTSTATUS
370 #ifdef __REACTOS__
371 NTAPI
372 #endif
373 ScsiFlopRemoveDevice(
374 IN PDEVICE_OBJECT Fdo,
375 IN UCHAR Type
376 );
377
378 NTSTATUS
379 #ifdef __REACTOS__
380 NTAPI
381 #endif
382 ScsiFlopStopDevice(
383 IN PDEVICE_OBJECT Fdo,
384 IN UCHAR Type
385 );
386
387 BOOLEAN
388 FindScsiFlops(
389 IN PDRIVER_OBJECT DriverObject,
390 IN PUNICODE_STRING RegistryPath,
391 IN PCLASS_INIT_DATA InitializationData,
392 IN PDEVICE_OBJECT PortDeviceObject,
393 IN ULONG PortNumber
394 );
395
396 NTSTATUS
397 #ifdef __REACTOS__
398 NTAPI
399 #endif
400 ScsiFlopReadWriteVerification(
401 IN PDEVICE_OBJECT DeviceObject,
402 IN PIRP Irp
403 );
404
405 NTSTATUS
406 #ifdef __REACTOS__
407 NTAPI
408 #endif
409 ScsiFlopDeviceControl(
410 IN PDEVICE_OBJECT DeviceObject,
411 IN PIRP Irp
412 );
413
414 BOOLEAN
415 IsFloppyDevice(
416 PDEVICE_OBJECT DeviceObject
417 );
418
419 NTSTATUS
420 CreateFlopDeviceObject(
421 IN PDRIVER_OBJECT DriverObject,
422 IN PDEVICE_OBJECT PortDeviceObject,
423 IN ULONG DeviceCount
424 );
425
426 NTSTATUS
427 DetermineMediaType(
428 PDEVICE_OBJECT DeviceObject
429 );
430
431 ULONG
432 DetermineDriveType(
433 PDEVICE_OBJECT DeviceObject
434 );
435
436 BOOLEAN
437 FlCheckFormatParameters(
438 IN PDEVICE_OBJECT DeviceObject,
439 IN PFORMAT_PARAMETERS FormatParameters
440 );
441
442 NTSTATUS
443 FormatMedia(
444 PDEVICE_OBJECT DeviceObject,
445 MEDIA_TYPE MediaType
446 );
447
448 NTSTATUS
449 FlopticalFormatMedia(
450 PDEVICE_OBJECT DeviceObject,
451 PFORMAT_PARAMETERS Format
452 );
453
454 VOID
455 #ifdef __REACTOS__
456 NTAPI
457 #endif
458 ScsiFlopProcessError(
459 PDEVICE_OBJECT DeviceObject,
460 PSCSI_REQUEST_BLOCK Srb,
461 NTSTATUS *Status,
462 BOOLEAN *Retry
463 );
464
465 NTSTATUS
466 USBFlopGetMediaTypes(
467 IN PDEVICE_OBJECT DeviceObject,
468 IN PIRP Irp
469 );
470
471 NTSTATUS
472 USBFlopFormatTracks(
473 IN PDEVICE_OBJECT DeviceObject,
474 IN PIRP Irp
475 );
476
477 #ifdef ALLOC_PRAGMA
478 #pragma alloc_text(INIT, DriverEntry)
479
480 #pragma alloc_text(PAGE, ScsiFlopUnload)
481 #pragma alloc_text(PAGE, ScsiFlopAddDevice)
482 #pragma alloc_text(PAGE, CreateFlopDeviceObject)
483 #pragma alloc_text(PAGE, ScsiFlopStartDevice)
484 #pragma alloc_text(PAGE, ScsiFlopRemoveDevice)
485 #pragma alloc_text(PAGE, IsFloppyDevice)
486 #pragma alloc_text(PAGE, DetermineMediaType)
487 #pragma alloc_text(PAGE, DetermineDriveType)
488 #pragma alloc_text(PAGE, FlCheckFormatParameters)
489 #pragma alloc_text(PAGE, FormatMedia)
490 #pragma alloc_text(PAGE, FlopticalFormatMedia)
491 #pragma alloc_text(PAGE, USBFlopGetMediaTypes)
492 #pragma alloc_text(PAGE, USBFlopFormatTracks)
493
494 #endif
495
496
497 NTSTATUS
498 #ifdef __REACTOS__
499 NTAPI
500 #endif
DriverEntry(IN PDRIVER_OBJECT DriverObject,IN PUNICODE_STRING RegistryPath)501 DriverEntry(
502 IN PDRIVER_OBJECT DriverObject,
503 IN PUNICODE_STRING RegistryPath
504 )
505 /*++
506
507 Routine Description:
508
509 This is the system initialization routine for installable drivers.
510 It calls the SCSI class driver initialization routine.
511
512 Arguments:
513
514 DriverObject - Pointer to driver object created by system.
515
516 Return Value:
517
518 NTSTATUS
519
520 --*/
521
522 {
523 CLASS_INIT_DATA InitializationData;
524
525 //
526 // Zero InitData
527 //
528
529 RtlZeroMemory (&InitializationData, sizeof(CLASS_INIT_DATA));
530
531 //
532 // Set sizes
533 //
534
535 InitializationData.InitializationDataSize = sizeof(CLASS_INIT_DATA);
536 InitializationData.FdoData.DeviceExtensionSize =
537 sizeof(FUNCTIONAL_DEVICE_EXTENSION) + sizeof(DISK_DATA);
538
539 InitializationData.FdoData.DeviceType = FILE_DEVICE_DISK;
540 InitializationData.FdoData.DeviceCharacteristics = FILE_REMOVABLE_MEDIA | FILE_FLOPPY_DISKETTE;
541
542 //
543 // Set entry points
544 //
545
546 InitializationData.FdoData.ClassInitDevice = ScsiFlopInitDevice;
547 InitializationData.FdoData.ClassStartDevice = ScsiFlopStartDevice;
548 InitializationData.FdoData.ClassStopDevice = ScsiFlopStopDevice;
549 InitializationData.FdoData.ClassRemoveDevice = ScsiFlopRemoveDevice;
550
551 InitializationData.FdoData.ClassReadWriteVerification = ScsiFlopReadWriteVerification;
552 InitializationData.FdoData.ClassDeviceControl = ScsiFlopDeviceControl;
553
554 InitializationData.FdoData.ClassShutdownFlush = NULL;
555 InitializationData.FdoData.ClassCreateClose = NULL;
556 InitializationData.FdoData.ClassError = ScsiFlopProcessError;
557 InitializationData.ClassStartIo = NULL;
558
559 InitializationData.ClassAddDevice = ScsiFlopAddDevice;
560 InitializationData.ClassUnload = ScsiFlopUnload;
561 //
562 // Call the class init routine
563 //
564
565 return ClassInitialize( DriverObject, RegistryPath, &InitializationData);
566
567
568 } // end DriverEntry()
569
570 VOID
571 #ifdef __REACTOS__
572 NTAPI
573 #endif
ScsiFlopUnload(IN PDRIVER_OBJECT DriverObject)574 ScsiFlopUnload(
575 IN PDRIVER_OBJECT DriverObject
576 )
577 {
578 PAGED_CODE();
579 UNREFERENCED_PARAMETER(DriverObject);
580 return;
581 }
582
583 //
584 // AddDevice operation is performed in CreateFlopDeviceObject function which
585 // is called by ScsiFlopAddDevice (The AddDevice routine for sfloppy.sys).
586 // DO_DEVICE_INITIALIZING flag is cleard upon successfully processing AddDevice
587 // operation in CreateFlopDeviceObject. But PREFAST is currently unable to
588 // detect that DO_DEVICE_INITIALIZING is indeed cleard in CreateFlopDeviceObject
589 // and it raises Warning 28152 (The return from an AddDevice-like function
590 // unexpectedly did not clear DO_DEVICE_INITIALIZING). Suppress that warning
591 // using #pragma.
592 //
593
594 #if !defined(__REACTOS__) || defined(_MSC_VER)
595 #pragma warning(push)
596 #pragma warning(disable:28152)
597 #endif
598
599 NTSTATUS
600 #ifdef __REACTOS__
601 NTAPI
602 #endif
ScsiFlopAddDevice(IN PDRIVER_OBJECT DriverObject,IN PDEVICE_OBJECT Pdo)603 ScsiFlopAddDevice (
604 IN PDRIVER_OBJECT DriverObject,
605 IN PDEVICE_OBJECT Pdo
606 )
607 /*++
608
609 Routine Description:
610
611 This routine creates and initializes a new FDO for the corresponding
612 PDO. It may perform property queries on the FDO but cannot do any
613 media access operations.
614
615 Arguments:
616
617 DriverObject - Scsiscan class driver object.
618
619 Pdo - the physical device object we are being added to
620
621 Return Value:
622
623 status
624
625 --*/
626 {
627 NTSTATUS status;
628 ULONG floppyCount = IoGetConfigurationInformation()->FloppyCount;
629
630 PAGED_CODE();
631
632 //
633 // Get the number of disks already initialized.
634 //
635
636 status = CreateFlopDeviceObject(DriverObject, Pdo, floppyCount);
637
638 if (NT_SUCCESS(status)) {
639
640 //
641 // Increment system floppy device count.
642 //
643
644 IoGetConfigurationInformation()->FloppyCount++;
645 }
646
647 return status;
648 }
649
650 NTSTATUS
CreateFlopDeviceObject(IN PDRIVER_OBJECT DriverObject,IN PDEVICE_OBJECT Pdo,IN ULONG DeviceCount)651 CreateFlopDeviceObject(
652 IN PDRIVER_OBJECT DriverObject,
653 IN PDEVICE_OBJECT Pdo,
654 IN ULONG DeviceCount
655 )
656
657 /*++
658
659 Routine Description:
660
661 This routine creates an object for the device and then calls the
662 SCSI port driver for media capacity and sector size.
663
664 Arguments:
665
666 DriverObject - Pointer to driver object created by system.
667 PortDeviceObject - to connect to SCSI port driver.
668 DeviceCount - Number of previously installed Floppys.
669 AdapterDescriptor - Pointer to structure returned by SCSI port
670 driver describing adapter capabilites (and limitations).
671 DeviceDescriptor - Pointer to configuration information for this device.
672
673 Return Value:
674
675 --*/
676 {
677 NTSTATUS status;
678 PDEVICE_OBJECT deviceObject = NULL;
679 PFUNCTIONAL_DEVICE_EXTENSION fdoExtension = NULL;
680 PDISK_DATA diskData;
681
682 PAGED_CODE();
683
684 DebugPrint((3,"CreateFlopDeviceObject: Enter routine\n"));
685
686 //
687 // Try to claim the device.
688 //
689
690 status = ClassClaimDevice(Pdo,FALSE);
691
692 if (!NT_SUCCESS(status)) {
693 return(status);
694 }
695
696 DeviceCount--;
697
698 do {
699 UCHAR name[256];
700
701 //
702 // Create device object for this device.
703 //
704
705 DeviceCount++;
706
707 status = RtlStringCbPrintfA((PCCHAR) name,
708 sizeof(name),
709 "\\Device\\Floppy%u",
710 DeviceCount);
711 if (NT_SUCCESS(status)) {
712
713 status = ClassCreateDeviceObject(DriverObject,
714 (PCCHAR) name,
715 Pdo,
716 TRUE,
717 &deviceObject);
718 }
719 } while ((status == STATUS_OBJECT_NAME_COLLISION) ||
720 (status == STATUS_OBJECT_NAME_EXISTS));
721
722 if (!NT_SUCCESS(status)) {
723 DebugPrint((1,"CreateFlopDeviceObjects: Can not create device\n"));
724 goto CreateFlopDeviceObjectExit;
725 }
726
727 //
728 // Indicate that IRPs should include MDLs.
729 //
730
731 deviceObject->Flags |= DO_DIRECT_IO;
732
733 fdoExtension = deviceObject->DeviceExtension;
734
735 //
736 // Back pointer to device object.
737 //
738
739 fdoExtension->CommonExtension.DeviceObject = deviceObject;
740
741 //
742 // This is the physical device.
743 //
744
745 fdoExtension->CommonExtension.PartitionZeroExtension = fdoExtension;
746
747 //
748 // Reset the drive type.
749 //
750
751 diskData = (PDISK_DATA) fdoExtension->CommonExtension.DriverData;
752 diskData->DriveType = DRIVE_TYPE_NONE;
753 diskData->IsDMF = FALSE;
754 // diskData->EnableDMF = TRUE;
755
756 //
757 // Initialize lock count to zero. The lock count is used to
758 // disable the ejection mechanism when media is mounted.
759 //
760
761 fdoExtension->LockCount = 0;
762
763 //
764 // Save system floppy number
765 //
766
767 fdoExtension->DeviceNumber = DeviceCount;
768
769 //
770 // Set the alignment requirements for the device based on the
771 // host adapter requirements
772 //
773
774 if (Pdo->AlignmentRequirement > deviceObject->AlignmentRequirement) {
775 deviceObject->AlignmentRequirement = Pdo->AlignmentRequirement;
776 }
777
778 //
779 // Clear the SrbFlags and disable synchronous transfers
780 //
781
782 fdoExtension->SrbFlags = SRB_FLAGS_DISABLE_SYNCH_TRANSFER;
783
784 //
785 // Finally, attach to the PDO
786 //
787
788 fdoExtension->LowerPdo = Pdo;
789
790 fdoExtension->CommonExtension.LowerDeviceObject =
791 IoAttachDeviceToDeviceStack(deviceObject, Pdo);
792
793 if(fdoExtension->CommonExtension.LowerDeviceObject == NULL) {
794
795 status = STATUS_UNSUCCESSFUL;
796 goto CreateFlopDeviceObjectExit;
797 }
798
799 deviceObject->StackSize++;
800
801 //
802 // The device is initialized properly - mark it as such.
803 //
804
805 deviceObject->Flags &= ~DO_DEVICE_INITIALIZING;
806
807 return STATUS_SUCCESS;
808
809 CreateFlopDeviceObjectExit:
810
811 if (deviceObject != NULL) {
812 IoDeleteDevice(deviceObject);
813 }
814
815 return status;
816
817 } // end CreateFlopDeviceObject()
818 #if !defined(__REACTOS__) || defined(_MSC_VER)
819 #pragma warning(pop)
820 #endif
821
822 NTSTATUS
823 #ifdef __REACTOS__
824 NTAPI
825 #endif
ScsiFlopInitDevice(IN PDEVICE_OBJECT Fdo)826 ScsiFlopInitDevice(
827 IN PDEVICE_OBJECT Fdo
828 )
829 {
830 PFUNCTIONAL_DEVICE_EXTENSION fdoExtension = Fdo->DeviceExtension;
831 PCOMMON_DEVICE_EXTENSION commonExtension = Fdo->DeviceExtension;
832 PDISK_DATA diskData = commonExtension->DriverData;
833
834 PVOID senseData = NULL;
835 ULONG timeOut;
836
837 NTSTATUS status = STATUS_SUCCESS;
838
839 //
840 // Allocate request sense buffer.
841 //
842
843 senseData = ExAllocatePool(NonPagedPoolNxCacheAligned, SENSE_BUFFER_SIZE);
844
845 if (senseData == NULL) {
846
847 //
848 // The buffer cannot be allocated.
849 //
850
851 status = STATUS_INSUFFICIENT_RESOURCES;
852 return status;
853 }
854
855 //
856 // Set the sense data pointer in the device extension.
857 //
858
859 fdoExtension->SenseData = senseData;
860
861 //
862 // Build the lookaside list for srb's for this device.
863 //
864
865 ClassInitializeSrbLookasideList((PCOMMON_DEVICE_EXTENSION)fdoExtension,
866 SFLOPPY_SRB_LIST_SIZE);
867
868 //
869 // Register for media change notification
870 //
871 ClassInitializeMediaChangeDetection(fdoExtension,
872 (PUCHAR) "SFloppy");
873
874 //
875 // Set timeout value in seconds.
876 //
877
878 timeOut = ClassQueryTimeOutRegistryValue(Fdo);
879 if (timeOut) {
880 fdoExtension->TimeOutValue = timeOut;
881 } else {
882 fdoExtension->TimeOutValue = SCSI_FLOPPY_TIMEOUT;
883 }
884
885 //
886 // Floppies are not partitionable so starting offset is 0.
887 //
888
889 fdoExtension->CommonExtension.StartingOffset.QuadPart = (LONGLONG)0;
890
891 #if 0
892 if (!IsFloppyDevice(Fdo) ||
893 !(Fdo->Characteristics & FILE_REMOVABLE_MEDIA) ||
894 (fdoExtension->DeviceDescriptor->DeviceType != DIRECT_ACCESS_DEVICE)) {
895
896 ExFreePool(senseData);
897 status = STATUS_NO_SUCH_DEVICE;
898 return status;
899 }
900 #endif
901
902 RtlZeroMemory(&(fdoExtension->DiskGeometry),
903 sizeof(DISK_GEOMETRY));
904
905 //
906 // Determine the media type if possible. Set the current media type to
907 // Unknown so that determine media type will check the media.
908 //
909
910 fdoExtension->DiskGeometry.MediaType = Unknown;
911
912 //
913 // Register interfaces for this device.
914 //
915
916 {
917 UNICODE_STRING interfaceName;
918
919 RtlInitUnicodeString(&interfaceName, NULL);
920
921 status = IoRegisterDeviceInterface(fdoExtension->LowerPdo,
922 (LPGUID) &GUID_DEVINTERFACE_FLOPPY,
923 NULL,
924 &interfaceName);
925
926 if(NT_SUCCESS(status)) {
927 diskData->FloppyInterfaceString = interfaceName;
928 } else {
929 RtlInitUnicodeString(&(diskData->FloppyInterfaceString), NULL);
930 DebugPrint((1, "ScsiFlopStartDevice: Unable to register device "
931 "interface for fdo %p [%08lx]\n",
932 Fdo, status));
933 }
934 }
935
936 return (STATUS_SUCCESS);
937 }
938
939 #if !defined(__REACTOS__) || defined(_MSC_VER)
940 #pragma warning(suppress:6262) // This function uses 1096 bytes of stack which exceed default value of 1024 bytes used by Code Analysis for flagging as warning
941 #endif
942 #ifdef __REACTOS__
ScsiFlopStartDevice(IN PDEVICE_OBJECT Fdo)943 NTSTATUS NTAPI ScsiFlopStartDevice(
944 #else
945 NTSTATUS ScsiFlopStartDevice(
946 #endif
947 IN PDEVICE_OBJECT Fdo
948 )
949 {
950 PFUNCTIONAL_DEVICE_EXTENSION fdoExtension = Fdo->DeviceExtension;
951 PCOMMON_DEVICE_EXTENSION commonExtension = Fdo->DeviceExtension;
952
953 PIRP irp;
954 IO_STATUS_BLOCK ioStatus;
955
956 SCSI_ADDRESS scsiAddress;
957
958 WCHAR ntNameBuffer[256];
959 UNICODE_STRING ntUnicodeString;
960
961 WCHAR arcNameBuffer[256];
962 UNICODE_STRING arcUnicodeString;
963
964 KEVENT event;
965
966 NTSTATUS status = STATUS_SUCCESS;
967
968 PAGED_CODE();
969
970 KeInitializeEvent(&event,SynchronizationEvent,FALSE);
971
972 DetermineMediaType(Fdo); // ignore unsuccessful here
973
974 //
975 // Create device object for this device.
976 //
977
978 RtlStringCbPrintfW(ntNameBuffer,
979 sizeof(ntNameBuffer),
980 L"\\Device\\Floppy%u",
981 fdoExtension->DeviceNumber);
982
983 //
984 // Create local copy of unicode string
985 //
986 RtlInitUnicodeString(&ntUnicodeString,ntNameBuffer);
987
988 //
989 // Create a symbolic link from the disk name to the corresponding
990 // ARC name, to be used if we're booting off the disk. This will
991 // fail if it's not system initialization time; that's fine. The
992 // ARC name looks something like \ArcName\scsi(0)Flop(0)fdisk(0).
993 // In order to get the address, we need to send a IOCTL_SCSI_GET_ADDRESS...
994 //
995
996 irp = IoBuildDeviceIoControlRequest(IOCTL_SCSI_GET_ADDRESS,
997 Fdo,
998 NULL,
999 0,
1000 &scsiAddress,
1001 sizeof(scsiAddress),
1002 FALSE,
1003 &event,
1004 &ioStatus);
1005
1006 if (irp == NULL) {
1007 return STATUS_INSUFFICIENT_RESOURCES;
1008 }
1009
1010 status = IoCallDriver(fdoExtension->CommonExtension.LowerDeviceObject, irp);
1011
1012 if (status == STATUS_PENDING) {
1013 KeWaitForSingleObject(&event, Executive, KernelMode, FALSE, NULL);
1014 status = ioStatus.Status;
1015 }
1016
1017 //
1018 // IOCTL_SCSI_GET_ADDRESS might not be supported by the port driver and
1019 // hence may fail. But it is not a fatal error. Do not fail PnP start
1020 // if this IOCTL fails.
1021 //
1022 if (NT_SUCCESS(status)) {
1023
1024 RtlStringCbPrintfW(arcNameBuffer,
1025 sizeof(arcNameBuffer),
1026 L"\\ArcName\\scsi(%u)disk(%u)fdisk(%u)",
1027 scsiAddress.PortNumber,
1028 scsiAddress.TargetId,
1029 scsiAddress.Lun);
1030
1031 RtlInitUnicodeString(&arcUnicodeString, arcNameBuffer);
1032
1033 IoAssignArcName(&arcUnicodeString, &ntUnicodeString);
1034 }
1035
1036 status = STATUS_SUCCESS;
1037
1038 //
1039 // Create the multi() arc name -- Create the "fake"
1040 // name of multi(0)disk(0)fdisk(#) to handle the case where the
1041 // SCSI floppy is the only floppy in the system. If this fails
1042 // it doesn't matter because the previous scsi() based ArcName
1043 // will work. This name is necessary for installation.
1044 //
1045
1046 RtlStringCbPrintfW(arcNameBuffer,
1047 sizeof(arcNameBuffer),
1048 L"\\ArcName\\multi(%u)disk(%u)fdisk(%u)",
1049 0,
1050 0,
1051 fdoExtension->DeviceNumber);
1052
1053 RtlInitUnicodeString(&arcUnicodeString, arcNameBuffer);
1054
1055 IoAssignArcName(&arcUnicodeString, &ntUnicodeString);
1056
1057 //
1058 // Set our interface state.
1059 //
1060
1061 {
1062 PDISK_DATA diskData = commonExtension->DriverData;
1063
1064 if(diskData->FloppyInterfaceString.Buffer != NULL) {
1065
1066 status = IoSetDeviceInterfaceState(
1067 &(diskData->FloppyInterfaceString),
1068 TRUE);
1069
1070 if(!NT_SUCCESS(status)) {
1071 DebugPrint((1, "ScsiFlopStartDevice: Unable to set device "
1072 "interface state to TRUE for fdo %p "
1073 "[%08lx]\n",
1074 Fdo, status));
1075 }
1076 }
1077 }
1078
1079 return STATUS_SUCCESS;
1080 }
1081
1082
1083 NTSTATUS
1084 #ifdef __REACTOS__
1085 NTAPI
1086 #endif
ScsiFlopReadWriteVerification(IN PDEVICE_OBJECT DeviceObject,IN PIRP Irp)1087 ScsiFlopReadWriteVerification(
1088 IN PDEVICE_OBJECT DeviceObject,
1089 IN PIRP Irp
1090 )
1091
1092 /*++
1093
1094 Routine Description:
1095
1096 Arguments:
1097
1098 Return Value:
1099
1100 NT Status
1101
1102 --*/
1103
1104 {
1105 PFUNCTIONAL_DEVICE_EXTENSION fdoExtension = DeviceObject->DeviceExtension;
1106 PIO_STACK_LOCATION irpSp = IoGetCurrentIrpStackLocation(Irp);
1107 NTSTATUS status = STATUS_SUCCESS;
1108
1109 //
1110 // Make sure that the number of bytes to transfer is a multiple of the sector size
1111 //
1112 if ((irpSp->Parameters.Read.Length & (fdoExtension->DiskGeometry.BytesPerSector - 1)) != 0)
1113 {
1114 status = STATUS_INVALID_PARAMETER;
1115 }
1116
1117 Irp->IoStatus.Status = status;
1118
1119 return status;
1120 }
1121
1122
1123 NTSTATUS
1124 #ifdef __REACTOS__
1125 NTAPI
1126 #endif
ScsiFlopDeviceControl(PDEVICE_OBJECT DeviceObject,PIRP Irp)1127 ScsiFlopDeviceControl(
1128 PDEVICE_OBJECT DeviceObject,
1129 PIRP Irp
1130 )
1131
1132 /*++
1133
1134 Routine Description:
1135
1136 Arguments:
1137
1138 Return Value:
1139
1140 Status is returned.
1141
1142 --*/
1143
1144 {
1145 KIRQL currentIrql;
1146 PIO_STACK_LOCATION irpStack = IoGetCurrentIrpStackLocation(Irp);
1147 PFUNCTIONAL_DEVICE_EXTENSION fdoExtension = DeviceObject->DeviceExtension;
1148 PSCSI_REQUEST_BLOCK srb;
1149 PCDB cdb;
1150 NTSTATUS status;
1151 PDISK_GEOMETRY outputBuffer;
1152 ULONG outputBufferLength;
1153 ULONG i;
1154 DRIVE_MEDIA_TYPE lowestDriveMediaType;
1155 DRIVE_MEDIA_TYPE highestDriveMediaType;
1156 PFORMAT_PARAMETERS formatParameters;
1157 PMODE_PARAMETER_HEADER modeData;
1158 ULONG length;
1159
1160 //
1161 // Initialize the information field
1162 //
1163 Irp->IoStatus.Information = 0;
1164
1165 srb = ExAllocatePool(NonPagedPoolNx, SCSI_REQUEST_BLOCK_SIZE);
1166
1167 if (srb == NULL) {
1168
1169 Irp->IoStatus.Status = STATUS_INSUFFICIENT_RESOURCES;
1170 if (IoIsErrorUserInduced(Irp->IoStatus.Status)) {
1171
1172 IoSetHardErrorOrVerifyDevice(Irp, DeviceObject);
1173 }
1174
1175 KeRaiseIrql(DISPATCH_LEVEL, ¤tIrql);
1176 ClassReleaseRemoveLock(DeviceObject, Irp);
1177 ClassCompleteRequest(DeviceObject, Irp, 0);
1178 KeLowerIrql(currentIrql);
1179
1180 return(STATUS_INSUFFICIENT_RESOURCES);
1181 }
1182
1183 //
1184 // Write zeros to Srb.
1185 //
1186
1187 RtlZeroMemory(srb, SCSI_REQUEST_BLOCK_SIZE);
1188
1189 cdb = (PCDB)srb->Cdb;
1190
1191 switch (irpStack->Parameters.DeviceIoControl.IoControlCode) {
1192
1193
1194 case IOCTL_DISK_VERIFY: {
1195
1196 PVERIFY_INFORMATION verifyInfo = Irp->AssociatedIrp.SystemBuffer;
1197 LARGE_INTEGER byteOffset;
1198 ULONG sectorOffset;
1199 USHORT sectorCount;
1200
1201 //
1202 // Validate buffer length.
1203 //
1204
1205 if (irpStack->Parameters.DeviceIoControl.InputBufferLength <
1206 sizeof(VERIFY_INFORMATION)) {
1207
1208 status = STATUS_INFO_LENGTH_MISMATCH;
1209 break;
1210 }
1211
1212 //
1213 // Perform a bounds check on the sector range
1214 //
1215 if ((verifyInfo->StartingOffset.QuadPart > fdoExtension->CommonExtension.PartitionLength.QuadPart) ||
1216 (verifyInfo->StartingOffset.QuadPart < 0))
1217 {
1218 status = STATUS_NONEXISTENT_SECTOR;
1219 break;
1220 }
1221 else
1222 {
1223 ULONGLONG bytesRemaining = fdoExtension->CommonExtension.PartitionLength.QuadPart - verifyInfo->StartingOffset.QuadPart;
1224
1225 if ((ULONGLONG)verifyInfo->Length > bytesRemaining)
1226 {
1227 status = STATUS_NONEXISTENT_SECTOR;
1228 break;
1229 }
1230 }
1231
1232 //
1233 // Verify sectors
1234 //
1235
1236 srb->CdbLength = 10;
1237
1238 cdb->CDB10.OperationCode = SCSIOP_VERIFY;
1239
1240 //
1241 // Add disk offset to starting sector.
1242 //
1243
1244 byteOffset.QuadPart = fdoExtension->CommonExtension.StartingOffset.QuadPart +
1245 verifyInfo->StartingOffset.QuadPart;
1246
1247 //
1248 // Convert byte offset to sector offset.
1249 //
1250
1251 sectorOffset = (ULONG)(byteOffset.QuadPart >> fdoExtension->SectorShift);
1252
1253 //
1254 // Convert ULONG byte count to USHORT sector count.
1255 //
1256
1257 sectorCount = (USHORT)(verifyInfo->Length >> fdoExtension->SectorShift);
1258
1259 //
1260 // Move little endian values into CDB in big endian format.
1261 //
1262
1263 cdb->CDB10.LogicalBlockByte0 = ((PFOUR_BYTE)§orOffset)->Byte3;
1264 cdb->CDB10.LogicalBlockByte1 = ((PFOUR_BYTE)§orOffset)->Byte2;
1265 cdb->CDB10.LogicalBlockByte2 = ((PFOUR_BYTE)§orOffset)->Byte1;
1266 cdb->CDB10.LogicalBlockByte3 = ((PFOUR_BYTE)§orOffset)->Byte0;
1267
1268 cdb->CDB10.TransferBlocksMsb = ((PFOUR_BYTE)§orCount)->Byte1;
1269 cdb->CDB10.TransferBlocksLsb = ((PFOUR_BYTE)§orCount)->Byte0;
1270
1271 //
1272 // The verify command is used by the NT FORMAT utility and
1273 // requests are sent down for 5% of the volume size. The
1274 // request timeout value is calculated based on the number of
1275 // sectors verified.
1276 //
1277
1278 srb->TimeOutValue = ((sectorCount + 0x7F) >> 7) *
1279 fdoExtension->TimeOutValue;
1280
1281 status = ClassSendSrbAsynchronous(DeviceObject,
1282 srb,
1283 Irp,
1284 NULL,
1285 0,
1286 FALSE);
1287 return(status);
1288
1289 }
1290
1291 case IOCTL_DISK_GET_PARTITION_INFO: {
1292
1293 if (fdoExtension->AdapterDescriptor->BusType == BusTypeUsb) {
1294
1295 USBFlopGetMediaTypes(DeviceObject, NULL);
1296
1297 // Don't need to propagate any error if one occurs
1298 //
1299 status = STATUS_SUCCESS;
1300
1301 } else {
1302
1303 status = DetermineMediaType(DeviceObject);
1304 }
1305
1306 if (!NT_SUCCESS(status)) {
1307 // so will propogate error
1308 NOTHING;
1309 } else if (fdoExtension->DiskGeometry.MediaType == F3_120M_512) {
1310 //so that the format code will not try to partition it.
1311 status = STATUS_INVALID_DEVICE_REQUEST;
1312 } else {
1313 //
1314 // Free the Srb, since it is not needed.
1315 //
1316
1317 ExFreePool(srb);
1318
1319 //
1320 // Pass the request to the common device control routine.
1321 //
1322
1323 return(ClassDeviceControl(DeviceObject, Irp));
1324 }
1325 break;
1326 }
1327
1328 case IOCTL_DISK_GET_DRIVE_GEOMETRY: {
1329
1330 DebugPrint((3,"ScsiDeviceIoControl: Get drive geometry\n"));
1331
1332 if (fdoExtension->AdapterDescriptor->BusType == BusTypeUsb)
1333 {
1334 status = USBFlopGetMediaTypes(DeviceObject,
1335 Irp);
1336 break;
1337 }
1338
1339 //
1340 // If there's not enough room to write the
1341 // data, then fail the request.
1342 //
1343
1344 if ( irpStack->Parameters.DeviceIoControl.OutputBufferLength <
1345 sizeof( DISK_GEOMETRY ) ) {
1346
1347 status = STATUS_INVALID_PARAMETER;
1348 break;
1349 }
1350
1351 status = DetermineMediaType(DeviceObject);
1352
1353 if (!NT_SUCCESS(status)) {
1354
1355 Irp->IoStatus.Information = 0;
1356 Irp->IoStatus.Status = status;
1357
1358 } else {
1359
1360 //
1361 // Copy drive geometry information from device extension.
1362 //
1363
1364 RtlMoveMemory(Irp->AssociatedIrp.SystemBuffer,
1365 &(fdoExtension->DiskGeometry),
1366 sizeof(DISK_GEOMETRY));
1367
1368 Irp->IoStatus.Information = sizeof(DISK_GEOMETRY);
1369 status = STATUS_SUCCESS;
1370
1371 }
1372
1373 break;
1374 }
1375
1376 case IOCTL_DISK_GET_MEDIA_TYPES: {
1377
1378 if (fdoExtension->AdapterDescriptor->BusType == BusTypeUsb)
1379 {
1380 status = USBFlopGetMediaTypes(DeviceObject,
1381 Irp);
1382 break;
1383 }
1384
1385 i = DetermineDriveType(DeviceObject);
1386
1387 if (i == DRIVE_TYPE_NONE) {
1388 status = STATUS_UNRECOGNIZED_MEDIA;
1389 break;
1390 }
1391
1392 lowestDriveMediaType = DriveMediaLimits[i].LowestDriveMediaType;
1393 highestDriveMediaType = DriveMediaLimits[i].HighestDriveMediaType;
1394
1395 outputBufferLength =
1396 irpStack->Parameters.DeviceIoControl.OutputBufferLength;
1397
1398 //
1399 // Make sure that the input buffer has enough room to return
1400 // at least one descriptions of a supported media type.
1401 //
1402
1403 if ( outputBufferLength < ( sizeof( DISK_GEOMETRY ) ) ) {
1404
1405 status = STATUS_BUFFER_TOO_SMALL;
1406 break;
1407 }
1408
1409 //
1410 // Assume success, although we might modify it to a buffer
1411 // overflow warning below (if the buffer isn't big enough
1412 // to hold ALL of the media descriptions).
1413 //
1414
1415 status = STATUS_SUCCESS;
1416
1417 if (outputBufferLength < ( sizeof( DISK_GEOMETRY ) *
1418 ( highestDriveMediaType - lowestDriveMediaType + 1 ) ) ) {
1419
1420 //
1421 // The buffer is too small for all of the descriptions;
1422 // calculate what CAN fit in the buffer.
1423 //
1424
1425 status = STATUS_BUFFER_OVERFLOW;
1426
1427 highestDriveMediaType = (DRIVE_MEDIA_TYPE)( ( lowestDriveMediaType - 1 ) +
1428 ( outputBufferLength /
1429 sizeof( DISK_GEOMETRY ) ) );
1430 }
1431
1432 outputBuffer = (PDISK_GEOMETRY) Irp->AssociatedIrp.SystemBuffer;
1433
1434 for (i = (UCHAR)lowestDriveMediaType;i <= (UCHAR)highestDriveMediaType;i++ ) {
1435
1436 outputBuffer->MediaType = DriveMediaConstants[i].MediaType;
1437 outputBuffer->Cylinders.LowPart =
1438 DriveMediaConstants[i].MaximumTrack + 1;
1439 outputBuffer->Cylinders.HighPart = 0;
1440 outputBuffer->TracksPerCylinder =
1441 DriveMediaConstants[i].NumberOfHeads;
1442 outputBuffer->SectorsPerTrack =
1443 DriveMediaConstants[i].SectorsPerTrack;
1444 outputBuffer->BytesPerSector =
1445 DriveMediaConstants[i].BytesPerSector;
1446 outputBuffer++;
1447
1448 Irp->IoStatus.Information += sizeof( DISK_GEOMETRY );
1449 }
1450
1451 break;
1452 }
1453
1454 case IOCTL_DISK_FORMAT_TRACKS: {
1455
1456 if (fdoExtension->AdapterDescriptor->BusType == BusTypeUsb)
1457 {
1458 status = USBFlopFormatTracks(DeviceObject,
1459 Irp);
1460 break;
1461 }
1462
1463 //
1464 // Make sure that we got all the necessary format parameters.
1465 //
1466
1467 if ( irpStack->Parameters.DeviceIoControl.InputBufferLength <sizeof( FORMAT_PARAMETERS ) ) {
1468
1469 status = STATUS_INVALID_PARAMETER;
1470 break;
1471 }
1472
1473 formatParameters = (PFORMAT_PARAMETERS) Irp->AssociatedIrp.SystemBuffer;
1474
1475 //
1476 // Make sure the parameters we got are reasonable.
1477 //
1478
1479 if ( !FlCheckFormatParameters(DeviceObject, formatParameters)) {
1480
1481 status = STATUS_INVALID_PARAMETER;
1482 break;
1483 }
1484
1485 //
1486 // If this request is for a 20.8 MB floppy then call a special
1487 // floppy format routine.
1488 //
1489
1490 if (formatParameters->MediaType == F3_20Pt8_512) {
1491 status = FlopticalFormatMedia(DeviceObject,
1492 formatParameters
1493 );
1494
1495 break;
1496 }
1497
1498 //
1499 // All the work is done in the pass. If this is not the first pass,
1500 // then complete the request and return;
1501 //
1502
1503 if (formatParameters->StartCylinderNumber != 0 || formatParameters->StartHeadNumber != 0) {
1504
1505 status = STATUS_SUCCESS;
1506 break;
1507 }
1508
1509 status = FormatMedia( DeviceObject, formatParameters->MediaType);
1510 break;
1511 }
1512
1513 case IOCTL_DISK_IS_WRITABLE: {
1514
1515 if ((fdoExtension->DiskGeometry.MediaType) == F3_32M_512) {
1516
1517 //
1518 // 32MB media is READ ONLY. Just return
1519 // STATUS_MEDIA_WRITE_PROTECTED
1520 //
1521
1522 status = STATUS_MEDIA_WRITE_PROTECTED;
1523
1524 break;
1525 }
1526
1527 //
1528 // Determine if the device is writable.
1529 //
1530
1531 modeData = ExAllocatePool(NonPagedPoolNxCacheAligned, MODE_DATA_SIZE);
1532
1533 if (modeData == NULL) {
1534 status = STATUS_INSUFFICIENT_RESOURCES;
1535 break;
1536 }
1537
1538 RtlZeroMemory(modeData, MODE_DATA_SIZE);
1539
1540 length = ClassModeSense(DeviceObject,
1541 (PCHAR) modeData,
1542 MODE_DATA_SIZE,
1543 MODE_SENSE_RETURN_ALL);
1544
1545 if (length < sizeof(MODE_PARAMETER_HEADER)) {
1546
1547 //
1548 // Retry the request in case of a check condition.
1549 //
1550
1551 length = ClassModeSense(DeviceObject,
1552 (PCHAR) modeData,
1553 MODE_DATA_SIZE,
1554 MODE_SENSE_RETURN_ALL);
1555
1556 if (length < sizeof(MODE_PARAMETER_HEADER)) {
1557 status = STATUS_IO_DEVICE_ERROR;
1558 ExFreePool(modeData);
1559 break;
1560 }
1561 }
1562
1563 if (modeData->DeviceSpecificParameter & MODE_DSP_WRITE_PROTECT) {
1564 status = STATUS_MEDIA_WRITE_PROTECTED;
1565 } else {
1566 status = STATUS_SUCCESS;
1567 }
1568
1569 DebugPrint((2,"IOCTL_DISK_IS_WRITABLE returns %08X\n", status));
1570
1571 ExFreePool(modeData);
1572 break;
1573 }
1574
1575 default: {
1576
1577 DebugPrint((3,"ScsiIoDeviceControl: Unsupported device IOCTL\n"));
1578
1579 //
1580 // Free the Srb, since it is not needed.
1581 //
1582
1583 ExFreePool(srb);
1584
1585 //
1586 // Pass the request to the common device control routine.
1587 //
1588
1589 return(ClassDeviceControl(DeviceObject, Irp));
1590
1591 break;
1592 }
1593
1594 } // end switch( ...
1595
1596 //
1597 // Check if SL_OVERRIDE_VERIFY_VOLUME flag is set in the IRP.
1598 // If so, do not return STATUS_VERIFY_REQUIRED
1599 //
1600 if ((status == STATUS_VERIFY_REQUIRED) &&
1601 (TEST_FLAG(irpStack->Flags, SL_OVERRIDE_VERIFY_VOLUME))) {
1602
1603 status = STATUS_IO_DEVICE_ERROR;
1604
1605 }
1606
1607 Irp->IoStatus.Status = status;
1608
1609 if (!NT_SUCCESS(status) && IoIsErrorUserInduced(status)) {
1610
1611 IoSetHardErrorOrVerifyDevice(Irp, DeviceObject);
1612 }
1613
1614 KeRaiseIrql(DISPATCH_LEVEL, ¤tIrql);
1615 ClassReleaseRemoveLock(DeviceObject, Irp);
1616 ClassCompleteRequest(DeviceObject, Irp, 0);
1617 KeLowerIrql(currentIrql);
1618
1619 ExFreePool(srb);
1620
1621 return status;
1622
1623 } // end ScsiFlopDeviceControl()
1624
1625 #if 0
1626
1627 BOOLEAN
1628 IsFloppyDevice(
1629 PDEVICE_OBJECT DeviceObject
1630 )
1631 /*++
1632
1633 Routine Description:
1634
1635 The routine performs the necessary funcitons to deterime if the device is
1636 really a floppy rather than a harddisk. This is done by a mode sense
1637 command. First a check is made to see if the medimum type is set. Second
1638 a check is made for the flexible parameters mode page.
1639
1640 Arguments:
1641
1642 DeviceObject - Supplies the device object to be tested.
1643
1644 Return Value:
1645
1646 Return TRUE if the indicated device is a floppy.
1647
1648 --*/
1649 {
1650
1651 PVOID modeData;
1652 PUCHAR pageData;
1653 ULONG length;
1654
1655 modeData = ExAllocatePool(NonPagedPoolNxCacheAligned, MODE_DATA_SIZE);
1656
1657 if (modeData == NULL) {
1658 return(FALSE);
1659 }
1660
1661 RtlZeroMemory(modeData, MODE_DATA_SIZE);
1662
1663 length = ClassModeSense(DeviceObject, modeData, MODE_DATA_SIZE, MODE_SENSE_RETURN_ALL);
1664
1665 if (length < sizeof(MODE_PARAMETER_HEADER)) {
1666
1667 //
1668 // Retry the request in case of a check condition.
1669 //
1670
1671 length = ClassModeSense(DeviceObject,
1672 modeData,
1673 MODE_DATA_SIZE,
1674 MODE_SENSE_RETURN_ALL);
1675
1676 if (length < sizeof(MODE_PARAMETER_HEADER)) {
1677
1678 ExFreePool(modeData);
1679 return(FALSE);
1680
1681 }
1682 }
1683
1684 #if 0
1685 //
1686 // Some drives incorrectly report this. In particular the SONY RMO-S350
1687 // when in disk mode.
1688 //
1689
1690 if (((PMODE_PARAMETER_HEADER) modeData)->MediumType >= MODE_FD_SINGLE_SIDE
1691 && ((PMODE_PARAMETER_HEADER) modeData)->MediumType <= MODE_FD_MAXIMUM_TYPE) {
1692
1693 DebugPrint((1, "ScsiFlop: MediumType value %2x, This is a floppy.\n", ((PMODE_PARAMETER_HEADER) modeData)->MediumType));
1694 ExFreePool(modeData);
1695 return(TRUE);
1696 }
1697
1698 #endif
1699
1700 //
1701 // If the length is greater than length indiated by the mode data reset
1702 // the data to the mode data.
1703 //
1704 if (length > (ULONG)((PMODE_PARAMETER_HEADER) modeData)->ModeDataLength + 1) {
1705 length = (ULONG)((PMODE_PARAMETER_HEADER) modeData)->ModeDataLength + 1;
1706
1707 }
1708
1709 //
1710 // Look for the flexible disk mode page.
1711 //
1712
1713 pageData = ClassFindModePage( modeData, length, MODE_PAGE_FLEXIBILE, TRUE);
1714
1715 if (pageData != NULL) {
1716
1717 DebugPrint((1, "ScsiFlop: Flexible disk page found, This is a floppy.\n"));
1718
1719 //
1720 // As a special case for the floptical driver do a magic mode sense to
1721 // enable the drive.
1722 //
1723
1724 ClassModeSense(DeviceObject, modeData, 0x2a, 0x2e);
1725
1726 ExFreePool(modeData);
1727 return(TRUE);
1728
1729 }
1730
1731 ExFreePool(modeData);
1732 return(FALSE);
1733
1734 }
1735 #endif
1736
1737
1738 NTSTATUS
DetermineMediaType(PDEVICE_OBJECT DeviceObject)1739 DetermineMediaType(
1740 PDEVICE_OBJECT DeviceObject
1741 )
1742 /*++
1743
1744 Routine Description:
1745
1746 This routine determines the floppy media type based on the size of the
1747 device. The geometry information is set for the device object.
1748
1749 Arguments:
1750
1751 DeviceObject - Supplies the device object to be tested.
1752
1753 Return Value:
1754
1755 None
1756
1757 --*/
1758 {
1759 PFUNCTIONAL_DEVICE_EXTENSION fdoExtension = DeviceObject->DeviceExtension;
1760 PDISK_GEOMETRY geometry;
1761 LONG index;
1762 NTSTATUS status;
1763
1764 PAGED_CODE();
1765
1766 geometry = &(fdoExtension->DiskGeometry);
1767
1768 //
1769 // Issue ReadCapacity to update device extension
1770 // with information for current media.
1771 //
1772
1773 status = ClassReadDriveCapacity(DeviceObject);
1774
1775 if (!NT_SUCCESS(status)) {
1776
1777 //
1778 // Set the media type to unknow and zero the geometry information.
1779 //
1780
1781 geometry->MediaType = Unknown;
1782
1783 return status;
1784
1785 }
1786
1787 //
1788 // Look at the capcity of disk to determine its type.
1789 //
1790
1791 for (index = NUMBER_OF_DRIVE_MEDIA_COMBINATIONS - 1; index >= 0; index--) {
1792
1793 //
1794 // Walk the table backward untill the drive capacity holds all of the
1795 // data and the bytes per setor are equal
1796 //
1797
1798 if ((ULONG) (DriveMediaConstants[index].NumberOfHeads *
1799 (DriveMediaConstants[index].MaximumTrack + 1) *
1800 DriveMediaConstants[index].SectorsPerTrack *
1801 DriveMediaConstants[index].BytesPerSector) <=
1802 fdoExtension->CommonExtension.PartitionLength.LowPart &&
1803 DriveMediaConstants[index].BytesPerSector ==
1804 geometry->BytesPerSector) {
1805
1806 geometry->MediaType = DriveMediaConstants[index].MediaType;
1807 geometry->TracksPerCylinder = DriveMediaConstants[index].NumberOfHeads;
1808 geometry->SectorsPerTrack = DriveMediaConstants[index].SectorsPerTrack;
1809 geometry->Cylinders.LowPart = DriveMediaConstants[index].MaximumTrack+1;
1810 break;
1811 }
1812 }
1813
1814 if (index == -1) {
1815
1816 //
1817 // Set the media type to unknow and zero the geometry information.
1818 //
1819
1820 geometry->MediaType = Unknown;
1821
1822
1823 } else {
1824 //
1825 // DMF check breaks the insight SCSI floppy, so its disabled for that case
1826 //
1827 PDISK_DATA diskData = (PDISK_DATA) fdoExtension->CommonExtension.DriverData;
1828
1829 // if (diskData->EnableDMF == TRUE) {
1830
1831 //
1832 //check to see if DMF
1833 //
1834
1835 PSCSI_REQUEST_BLOCK srb;
1836 PVOID readData;
1837
1838 //
1839 // Allocate a Srb for the read command.
1840 //
1841
1842 readData = ExAllocatePool(NonPagedPoolNx, geometry->BytesPerSector);
1843 if (readData == NULL) {
1844 return STATUS_NO_MEMORY;
1845 }
1846
1847 srb = ExAllocatePool(NonPagedPoolNx, SCSI_REQUEST_BLOCK_SIZE);
1848
1849 if (srb == NULL) {
1850
1851 ExFreePool(readData);
1852 return STATUS_NO_MEMORY;
1853 }
1854
1855 RtlZeroMemory(readData, geometry->BytesPerSector);
1856 RtlZeroMemory(srb, SCSI_REQUEST_BLOCK_SIZE);
1857
1858 srb->CdbLength = 10;
1859 srb->Cdb[0] = SCSIOP_READ;
1860 srb->Cdb[5] = 0;
1861 srb->Cdb[8] = (UCHAR) 1;
1862
1863 //
1864 // Set timeout value.
1865 //
1866
1867 srb->TimeOutValue = fdoExtension->TimeOutValue;
1868
1869 //
1870 // Send the mode select data.
1871 //
1872
1873 status = ClassSendSrbSynchronous(DeviceObject,
1874 srb,
1875 readData,
1876 geometry->BytesPerSector,
1877 FALSE
1878 );
1879
1880 if (NT_SUCCESS(status)) {
1881 char *pchar = (char *)readData;
1882
1883 pchar += 3; //skip 3 bytes jump code
1884
1885 // If the MSDMF3. signature is there then mark it as DMF diskette
1886 if (RtlCompareMemory(pchar, "MSDMF3.", 7) == 7) {
1887 diskData->IsDMF = TRUE;
1888 }
1889
1890 }
1891 ExFreePool(readData);
1892 ExFreePool(srb);
1893 // }// else
1894 }
1895 return status;
1896 }
1897
1898 ULONG
DetermineDriveType(PDEVICE_OBJECT DeviceObject)1899 DetermineDriveType(
1900 PDEVICE_OBJECT DeviceObject
1901 )
1902 /*++
1903
1904 Routine Description:
1905
1906 The routine determines the device type so that the supported medias can be
1907 determined. It does a mode sense for the default parameters. This code
1908 assumes that the returned values are for the maximum device size.
1909
1910 Arguments:
1911
1912 DeviceObject - Supplies the device object to be tested.
1913
1914 Return Value:
1915
1916 None
1917
1918 --*/
1919 {
1920 PFUNCTIONAL_DEVICE_EXTENSION fdoExtension = DeviceObject->DeviceExtension;
1921 PVOID modeData;
1922 PDISK_DATA diskData = (PDISK_DATA) fdoExtension->CommonExtension.DriverData;
1923 PMODE_FLEXIBLE_DISK_PAGE pageData;
1924 ULONG length;
1925 LONG index;
1926 UCHAR numberOfHeads;
1927 UCHAR sectorsPerTrack;
1928 USHORT maximumTrack;
1929 BOOLEAN applyFix = FALSE;
1930
1931 PAGED_CODE();
1932
1933 if (diskData->DriveType != DRIVE_TYPE_NONE) {
1934 return(diskData->DriveType);
1935 }
1936
1937 modeData = ExAllocatePool(NonPagedPoolNxCacheAligned, MODE_DATA_SIZE);
1938
1939 if (modeData == NULL) {
1940 return(DRIVE_TYPE_NONE);
1941 }
1942
1943 RtlZeroMemory(modeData, MODE_DATA_SIZE);
1944
1945 length = ClassModeSense(DeviceObject,
1946 modeData,
1947 MODE_DATA_SIZE,
1948 MODE_PAGE_FLEXIBILE);
1949
1950 if (length < sizeof(MODE_PARAMETER_HEADER)) {
1951
1952 //
1953 // Retry the request one more time
1954 // in case of a check condition.
1955 //
1956 length = ClassModeSense(DeviceObject,
1957 modeData,
1958 MODE_DATA_SIZE,
1959 MODE_PAGE_FLEXIBILE);
1960
1961 if (length < sizeof(MODE_PARAMETER_HEADER)) {
1962
1963 ExFreePool(modeData);
1964 return(DRIVE_TYPE_NONE);
1965 }
1966 }
1967
1968 //
1969 // Look for the flexible disk mode page.
1970 //
1971
1972 pageData = ClassFindModePage( modeData,
1973 length,
1974 MODE_PAGE_FLEXIBILE,
1975 TRUE);
1976
1977 //
1978 // Make sure the page is returned and is large enough.
1979 //
1980
1981 if ((pageData != NULL) &&
1982 (pageData->PageLength + 2 >=
1983 (UCHAR)offsetof(MODE_FLEXIBLE_DISK_PAGE, StartWritePrecom))) {
1984
1985 //
1986 // Pull out the heads, cylinders, and sectors.
1987 //
1988
1989 numberOfHeads = pageData->NumberOfHeads;
1990 maximumTrack = pageData->NumberOfCylinders[1];
1991 maximumTrack |= pageData->NumberOfCylinders[0] << 8;
1992 sectorsPerTrack = pageData->SectorsPerTrack;
1993
1994
1995 //
1996 // Convert from number of cylinders to maximum track.
1997 //
1998
1999 maximumTrack--;
2000
2001 //
2002 // Search for the maximum supported media. Based on the number of heads,
2003 // sectors per track and number of cylinders
2004 //
2005 for (index = 0; index < NUMBER_OF_DRIVE_MEDIA_COMBINATIONS; index++) {
2006
2007 //
2008 // Walk the table forward until the drive capacity holds all of the
2009 // data and the bytes per setor are equal
2010 //
2011
2012 if (DriveMediaConstants[index].NumberOfHeads == numberOfHeads &&
2013 DriveMediaConstants[index].MaximumTrack == maximumTrack &&
2014 DriveMediaConstants[index].SectorsPerTrack ==sectorsPerTrack) {
2015
2016 ExFreePool(modeData);
2017
2018 //
2019 // index is now a drive media combination. Compare this to
2020 // the maximum drive media type in the drive media table.
2021 //
2022
2023 for (length = 0; length < NUMBER_OF_DRIVE_TYPES; length++) {
2024
2025 if (DriveMediaLimits[length].HighestDriveMediaType == index) {
2026 return(length);
2027 }
2028 }
2029 return(DRIVE_TYPE_NONE);
2030 }
2031 }
2032
2033 // If the maximum track is greater than 8 bits then divide the
2034 // number of tracks by 3 and multiply the number of heads by 3.
2035 // This is a special case for the 20.8 MB floppy.
2036 //
2037
2038 if (!applyFix && maximumTrack >= 0x0100) {
2039 maximumTrack++;
2040 maximumTrack /= 3;
2041 maximumTrack--;
2042 numberOfHeads *= 3;
2043 } else {
2044 ExFreePool(modeData);
2045 return(DRIVE_TYPE_NONE);
2046 }
2047
2048 }
2049
2050 ExFreePool(modeData);
2051 return(DRIVE_TYPE_NONE);
2052 }
2053
2054
2055 BOOLEAN
FlCheckFormatParameters(IN PDEVICE_OBJECT DeviceObject,IN PFORMAT_PARAMETERS FormatParameters)2056 FlCheckFormatParameters(
2057 IN PDEVICE_OBJECT DeviceObject,
2058 IN PFORMAT_PARAMETERS FormatParameters
2059 )
2060
2061 /*++
2062
2063 Routine Description:
2064
2065 This routine checks the supplied format parameters to make sure that
2066 they'll work on the drive to be formatted.
2067
2068 Arguments:
2069
2070 DeviceObject - Pointer to the device object to be formated.
2071
2072 FormatParameters - a pointer to the caller's parameters for the FORMAT.
2073
2074 Return Value:
2075
2076 TRUE if parameters are OK.
2077 FALSE if the parameters are bad.
2078
2079 --*/
2080
2081 {
2082 PDRIVE_MEDIA_CONSTANTS driveMediaConstants;
2083 DRIVE_MEDIA_TYPE driveMediaType;
2084 ULONG index;
2085
2086 PAGED_CODE();
2087
2088 //
2089 // Get the device type.
2090 //
2091
2092 index = DetermineDriveType(DeviceObject);
2093
2094 if (index == DRIVE_TYPE_NONE) {
2095
2096 //
2097 // If the determine device type failed then just use the media type
2098 // and try the parameters.
2099 //
2100
2101 driveMediaType = Drive360Media160;
2102
2103 while (( DriveMediaConstants[driveMediaType].MediaType !=
2104 FormatParameters->MediaType ) &&
2105 ( driveMediaType < Drive288Media288) ) {
2106
2107 driveMediaType++;
2108 }
2109
2110 } else {
2111
2112 //
2113 // Figure out which entry in the DriveMediaConstants table to use.
2114 //
2115
2116 driveMediaType =
2117 DriveMediaLimits[index].HighestDriveMediaType;
2118
2119 while ( ( DriveMediaConstants[driveMediaType].MediaType !=
2120 FormatParameters->MediaType ) &&
2121 ( driveMediaType > DriveMediaLimits[index].
2122 LowestDriveMediaType ) ) {
2123
2124 driveMediaType--;
2125 }
2126
2127 }
2128
2129
2130 // driveMediaType is bounded below by DriveMediaLimits[].LowestDriveMediaType
2131 #if !defined(__REACTOS__) || defined(_MSC_VER)
2132 #pragma warning(push)
2133 #pragma warning(disable:33010) // 33010: Enum used as array index may be negative
2134 #endif
2135 if ( DriveMediaConstants[driveMediaType].MediaType !=
2136 FormatParameters->MediaType ) {
2137 return FALSE;
2138
2139 } else {
2140
2141 driveMediaConstants = &DriveMediaConstants[driveMediaType];
2142
2143 if ( ( FormatParameters->StartHeadNumber >
2144 (ULONG)( driveMediaConstants->NumberOfHeads - 1 ) ) ||
2145 ( FormatParameters->EndHeadNumber >
2146 (ULONG)( driveMediaConstants->NumberOfHeads - 1 ) ) ||
2147 ( FormatParameters->StartCylinderNumber >
2148 driveMediaConstants->MaximumTrack ) ||
2149 ( FormatParameters->EndCylinderNumber >
2150 driveMediaConstants->MaximumTrack ) ||
2151 ( FormatParameters->EndCylinderNumber <
2152 FormatParameters->StartCylinderNumber ) ) {
2153
2154 return FALSE;
2155
2156 } else {
2157
2158 return TRUE;
2159 }
2160 }
2161 #if !defined(__REACTOS__) || defined(_MSC_VER)
2162 #pragma warning(pop)
2163 #endif
2164 }
2165
2166 NTSTATUS
FormatMedia(PDEVICE_OBJECT DeviceObject,MEDIA_TYPE MediaType)2167 FormatMedia(
2168 PDEVICE_OBJECT DeviceObject,
2169 MEDIA_TYPE MediaType
2170 )
2171 /*++
2172
2173 Routine Description:
2174
2175 This routine formats the floppy disk. The entire floppy is formated in
2176 one shot.
2177
2178 Arguments:
2179
2180 DeviceObject - Supplies the device object to be tested.
2181
2182 Irp - Supplies a pointer to the requesting Irp.
2183
2184 MediaType - Supplies the media type format the device for.
2185
2186 Return Value:
2187
2188 Returns a status for the operation.
2189
2190 --*/
2191 {
2192 PVOID modeData;
2193 PSCSI_REQUEST_BLOCK srb;
2194 PMODE_FLEXIBLE_DISK_PAGE pageData;
2195 DRIVE_MEDIA_TYPE driveMediaType;
2196 PDRIVE_MEDIA_CONSTANTS driveMediaConstants;
2197 ULONG length;
2198 NTSTATUS status;
2199
2200 PAGED_CODE();
2201
2202 modeData = ExAllocatePool(NonPagedPoolNxCacheAligned, MODE_DATA_SIZE);
2203
2204 if (modeData == NULL) {
2205 return(STATUS_INSUFFICIENT_RESOURCES);
2206 }
2207
2208 RtlZeroMemory(modeData, MODE_DATA_SIZE);
2209
2210 length = ClassModeSense(DeviceObject,
2211 modeData,
2212 MODE_DATA_SIZE,
2213 MODE_PAGE_FLEXIBILE);
2214
2215 if (length < sizeof(MODE_PARAMETER_HEADER)) {
2216 ExFreePool(modeData);
2217 return(STATUS_INVALID_DEVICE_REQUEST);
2218 }
2219
2220 //
2221 // Look for the flexible disk mode page.
2222 //
2223
2224 pageData = ClassFindModePage( modeData, length, MODE_PAGE_FLEXIBILE, TRUE);
2225
2226 //
2227 // Make sure the page is returned and is large enough.
2228 //
2229
2230 if ((pageData == NULL) ||
2231 (pageData->PageLength + 2 <
2232 (UCHAR)offsetof(MODE_FLEXIBLE_DISK_PAGE, StartWritePrecom))) {
2233
2234 ExFreePool(modeData);
2235 return(STATUS_INVALID_DEVICE_REQUEST);
2236
2237 }
2238
2239 //
2240 // Look for a drive media type which matches the requested media type.
2241 //
2242 //
2243 //start from Drive120MMedia120M instead of Drive2080Media2080
2244 //
2245 for (driveMediaType = Drive120MMedia120M;
2246 DriveMediaConstants[driveMediaType].MediaType != MediaType;
2247 driveMediaType--) {
2248 if (driveMediaType == Drive360Media160) {
2249
2250 ExFreePool(modeData);
2251 return(STATUS_INVALID_PARAMETER);
2252
2253 }
2254 }
2255
2256 driveMediaConstants = &DriveMediaConstants[driveMediaType];
2257
2258 if ((pageData->NumberOfHeads != driveMediaConstants->NumberOfHeads) ||
2259 (pageData->SectorsPerTrack != driveMediaConstants->SectorsPerTrack) ||
2260 ((pageData->NumberOfCylinders[0] != (UCHAR)((driveMediaConstants->MaximumTrack+1) >> 8)) &&
2261 (pageData->NumberOfCylinders[1] != (UCHAR)driveMediaConstants->MaximumTrack+1)) ||
2262 (pageData->BytesPerSector[0] != driveMediaConstants->BytesPerSector >> 8 )) {
2263
2264 //
2265 // Update the flexible parameters page with the new parameters.
2266 //
2267
2268 pageData->NumberOfHeads = driveMediaConstants->NumberOfHeads;
2269 pageData->SectorsPerTrack = driveMediaConstants->SectorsPerTrack;
2270 pageData->NumberOfCylinders[0] = (UCHAR)((driveMediaConstants->MaximumTrack+1) >> 8);
2271 pageData->NumberOfCylinders[1] = (UCHAR)driveMediaConstants->MaximumTrack+1;
2272 pageData->BytesPerSector[0] = driveMediaConstants->BytesPerSector >> 8;
2273
2274 //
2275 // Clear the mode parameter header.
2276 //
2277
2278 RtlZeroMemory(modeData, sizeof(MODE_PARAMETER_HEADER));
2279
2280 //
2281 // Set the length equal to the length returned for the flexible page.
2282 //
2283
2284 length = pageData->PageLength + 2;
2285
2286 //
2287 // Copy the page after the mode parameter header.
2288 //
2289
2290 RtlMoveMemory((PCHAR) modeData + sizeof(MODE_PARAMETER_HEADER),
2291 pageData,
2292 length
2293 );
2294 length += sizeof(MODE_PARAMETER_HEADER);
2295
2296
2297 //
2298 // Allocate a Srb for the format command.
2299 //
2300
2301 srb = ExAllocatePool(NonPagedPoolNx, SCSI_REQUEST_BLOCK_SIZE);
2302
2303 if (srb == NULL) {
2304
2305 ExFreePool(modeData);
2306 return(STATUS_INSUFFICIENT_RESOURCES);
2307 }
2308
2309 RtlZeroMemory(srb, SCSI_REQUEST_BLOCK_SIZE);
2310
2311 srb->CdbLength = 6;
2312 srb->Cdb[0] = SCSIOP_MODE_SELECT;
2313 srb->Cdb[4] = (UCHAR) length;
2314
2315 //
2316 // Set the PF bit.
2317 //
2318
2319 srb->Cdb[1] |= 0x10;
2320
2321 //
2322 // Set timeout value.
2323 //
2324
2325 srb->TimeOutValue = 2;
2326
2327 //
2328 // Send the mode select data.
2329 //
2330
2331 status = ClassSendSrbSynchronous(DeviceObject,
2332 srb,
2333 modeData,
2334 length,
2335 TRUE
2336 );
2337
2338 //
2339 // The mode data not needed any more so free it.
2340 //
2341
2342 ExFreePool(modeData);
2343
2344 if (!NT_SUCCESS(status)) {
2345 ExFreePool(srb);
2346 return(status);
2347 }
2348
2349 } else {
2350
2351 //
2352 // The mode data not needed any more so free it.
2353 //
2354
2355 ExFreePool(modeData);
2356
2357 //
2358 // Allocate a Srb for the format command.
2359 //
2360
2361 srb = ExAllocatePool(NonPagedPoolNx, SCSI_REQUEST_BLOCK_SIZE);
2362
2363 if (srb == NULL) {
2364 return(STATUS_INSUFFICIENT_RESOURCES);
2365 }
2366
2367 }
2368
2369 RtlZeroMemory(srb, SCSI_REQUEST_BLOCK_SIZE);
2370
2371 srb->CdbLength = 6;
2372
2373 srb->Cdb[0] = SCSIOP_FORMAT_UNIT;
2374
2375 //
2376 // Set timeout value.
2377 //
2378
2379 srb->TimeOutValue = 10 * 60;
2380
2381 status = ClassSendSrbSynchronous(DeviceObject,
2382 srb,
2383 NULL,
2384 0,
2385 FALSE
2386 );
2387 ExFreePool(srb);
2388
2389 return(status);
2390
2391 }
2392
2393 VOID
2394 #ifdef __REACTOS__
2395 NTAPI
2396 #endif
ScsiFlopProcessError(PDEVICE_OBJECT DeviceObject,PSCSI_REQUEST_BLOCK Srb,NTSTATUS * Status,BOOLEAN * Retry)2397 ScsiFlopProcessError(
2398 PDEVICE_OBJECT DeviceObject,
2399 PSCSI_REQUEST_BLOCK Srb,
2400 NTSTATUS *Status,
2401 BOOLEAN *Retry
2402 )
2403 /*++
2404
2405 Routine Description:
2406
2407 This routine checks the type of error. If the error indicate the floppy
2408 controller needs to be reinitialize a command is made to do it.
2409
2410 Arguments:
2411
2412 DeviceObject - Supplies a pointer to the device object.
2413
2414 Srb - Supplies a pointer to the failing Srb.
2415
2416 Status - Status with which the IRP will be completed.
2417
2418 Retry - Indication of whether the request will be retried.
2419
2420 Return Value:
2421
2422 None.
2423
2424 --*/
2425
2426 {
2427 PFUNCTIONAL_DEVICE_EXTENSION fdoExtension = DeviceObject->DeviceExtension;
2428 PDISK_DATA diskData = (PDISK_DATA) fdoExtension->CommonExtension.DriverData;
2429 PSENSE_DATA senseBuffer = Srb->SenseInfoBuffer;
2430 PIO_STACK_LOCATION irpStack;
2431 PIRP irp;
2432 PSCSI_REQUEST_BLOCK srb;
2433 LARGE_INTEGER largeInt;
2434 PCOMPLETION_CONTEXT context;
2435 PCDB cdb;
2436 ULONG_PTR alignment;
2437 ULONG majorFunction;
2438
2439 UNREFERENCED_PARAMETER(Status);
2440 UNREFERENCED_PARAMETER(Retry);
2441
2442 largeInt.QuadPart = 1;
2443
2444 //
2445 // Check the status. The initialization command only needs to be sent
2446 // if UNIT ATTENTION or LUN NOT READY is returned.
2447 //
2448
2449 if (!(Srb->SrbStatus & SRB_STATUS_AUTOSENSE_VALID)) {
2450
2451 //
2452 // The drive does not require reinitialization.
2453 //
2454
2455 return;
2456 }
2457
2458 //
2459 // Reset the drive type.
2460 //
2461
2462 diskData->DriveType = DRIVE_TYPE_NONE;
2463 diskData->IsDMF = FALSE;
2464
2465 fdoExtension->DiskGeometry.MediaType = Unknown;
2466
2467 if (fdoExtension->AdapterDescriptor->BusType == BusTypeUsb) {
2468
2469 // FLPYDISK.SYS never returns a non-zero value for the ChangeCount
2470 // on an IOCTL_DISK_CHECK_VERIFY. Some things seem to work better
2471 // if we do the same. In particular, FatVerifyVolume() can exit between
2472 // the IOCTL_DISK_CHECK_VERIFY and the IOCTL_DISK_GET_DRIVE_GEOMETRY
2473 // if a non-zero ChangeCount is returned, and this appears to cause
2474 // issues formatting unformatted media in some situations.
2475 //
2476 // This is something that should probably be revisited at some point.
2477 //
2478 fdoExtension->MediaChangeCount = 0;
2479
2480 if (((senseBuffer->SenseKey & 0xf) == SCSI_SENSE_UNIT_ATTENTION) &&
2481 (senseBuffer->AdditionalSenseCode == SCSI_ADSENSE_MEDIUM_CHANGED)) {
2482
2483 struct _START_STOP *startStopCdb;
2484
2485 DebugPrint((2,"Sending SCSIOP_START_STOP_UNIT\n"));
2486
2487 context = ExAllocatePool(NonPagedPoolNx,
2488 sizeof(COMPLETION_CONTEXT));
2489
2490 if (context == NULL) {
2491
2492 return;
2493 }
2494 #if (NTDDI_VERSION >= NTDDI_WIN8)
2495 srb = &context->Srb.Srb;
2496 #else
2497 srb = &context->Srb;
2498 #endif
2499
2500 RtlZeroMemory(srb, SCSI_REQUEST_BLOCK_SIZE);
2501
2502 srb->SrbFlags = SRB_FLAGS_DISABLE_AUTOSENSE;
2503
2504 srb->CdbLength = 6;
2505
2506 startStopCdb = (struct _START_STOP *)srb->Cdb;
2507
2508 startStopCdb->OperationCode = SCSIOP_START_STOP_UNIT;
2509 startStopCdb->Start = 1;
2510
2511 // A Start Stop Unit request has no transfer buffer.
2512 // Set the request to IRP_MJ_FLUSH_BUFFERS when calling
2513 // IoBuildAsynchronousFsdRequest() so that it ignores
2514 // the buffer pointer and buffer length parameters.
2515 //
2516 majorFunction = IRP_MJ_FLUSH_BUFFERS;
2517
2518 } else if ((senseBuffer->SenseKey & 0xf) == SCSI_SENSE_MEDIUM_ERROR) {
2519
2520 // Return ERROR_UNRECOGNIZED_MEDIA instead of
2521 // STATUS_DEVICE_DATA_ERROR to make shell happy.
2522 //
2523 *Status = STATUS_UNRECOGNIZED_MEDIA;
2524 return;
2525
2526 } else {
2527
2528 return;
2529 }
2530
2531 #ifndef __REACTOS__
2532 } else if (((senseBuffer->SenseKey & 0xf) == SCSI_SENSE_NOT_READY) &&
2533 senseBuffer->AdditionalSenseCodeQualifier == SCSI_SENSEQ_INIT_COMMAND_REQUIRED ||
2534 (senseBuffer->SenseKey & 0xf) == SCSI_SENSE_UNIT_ATTENTION) {
2535 #else
2536 } else if ((((senseBuffer->SenseKey & 0xf) == SCSI_SENSE_NOT_READY) &&
2537 senseBuffer->AdditionalSenseCodeQualifier == SCSI_SENSEQ_INIT_COMMAND_REQUIRED) ||
2538 (senseBuffer->SenseKey & 0xf) == SCSI_SENSE_UNIT_ATTENTION) {
2539 #endif
2540
2541 ULONG sizeNeeded;
2542 ULONG tmpSize;
2543 BOOLEAN overFlow;
2544
2545 DebugPrint((1, "ScsiFlopProcessError: Reinitializing the floppy.\n"));
2546
2547 //
2548 // Send the special mode sense command to enable writes on the
2549 // floptical drive.
2550 //
2551
2552 alignment = DeviceObject->AlignmentRequirement ?
2553 DeviceObject->AlignmentRequirement : 1;
2554
2555 sizeNeeded = 0;
2556 overFlow = TRUE;
2557 if (SUCCEEDED(ULongAdd(sizeof(COMPLETION_CONTEXT), 0x2a, &tmpSize))) {
2558
2559 if (SUCCEEDED(ULongAdd(tmpSize, (ULONG) alignment, &sizeNeeded))) {
2560 overFlow = FALSE;
2561 }
2562 }
2563
2564 context = NULL;
2565
2566 if (!overFlow) {
2567 context = ExAllocatePool(NonPagedPoolNx, sizeNeeded);
2568 }
2569
2570 if (context == NULL) {
2571
2572 //
2573 // If there is not enough memory to fulfill this request,
2574 // simply return. A subsequent retry will fail and another
2575 // chance to start the unit.
2576 //
2577
2578 return;
2579 }
2580
2581 #if (NTDDI_VERSION >= NTDDI_WIN8)
2582 srb = &context->Srb.Srb;
2583 #else
2584 srb = &context->Srb;
2585 #endif
2586
2587 RtlZeroMemory(srb, SCSI_REQUEST_BLOCK_SIZE);
2588
2589 //
2590 // Set the transfer length.
2591 //
2592
2593 srb->DataTransferLength = 0x2a;
2594 srb->SrbFlags = SRB_FLAGS_DATA_IN | SRB_FLAGS_DISABLE_AUTOSENSE | SRB_FLAGS_DISABLE_SYNCH_TRANSFER;
2595
2596 //
2597 // The data buffer must be aligned.
2598 //
2599
2600 srb->DataBuffer = (PVOID) (((ULONG_PTR) (context + 1) + (alignment - 1)) &
2601 ~(alignment - 1));
2602
2603
2604 //
2605 // Build the start unit CDB.
2606 //
2607
2608 srb->CdbLength = 6;
2609 cdb = (PCDB)srb->Cdb;
2610 cdb->MODE_SENSE.OperationCode = SCSIOP_MODE_SENSE;
2611 cdb->MODE_SENSE.PageCode = 0x2e;
2612 cdb->MODE_SENSE.AllocationLength = 0x2a;
2613
2614 majorFunction = IRP_MJ_READ;
2615
2616 } else {
2617
2618 return;
2619 }
2620
2621 context->DeviceObject = DeviceObject;
2622
2623 //
2624 // Write length to SRB.
2625 //
2626
2627 srb->Length = SCSI_REQUEST_BLOCK_SIZE;
2628
2629 srb->Function = SRB_FUNCTION_EXECUTE_SCSI;
2630 srb->TimeOutValue = fdoExtension->TimeOutValue;
2631
2632 //
2633 // Build the asynchronous request
2634 // to be sent to the port driver.
2635 //
2636
2637 irp = IoBuildAsynchronousFsdRequest(majorFunction,
2638 DeviceObject,
2639 srb->DataBuffer,
2640 srb->DataTransferLength,
2641 &largeInt,
2642 NULL);
2643
2644 if(irp == NULL) {
2645 ExFreePool(context);
2646 return;
2647 }
2648
2649
2650 IoSetCompletionRoutine(irp,
2651 (PIO_COMPLETION_ROUTINE)ClassAsynchronousCompletion,
2652 context,
2653 TRUE,
2654 TRUE,
2655 TRUE);
2656
2657 ClassAcquireRemoveLock(DeviceObject, irp);
2658
2659 irpStack = IoGetNextIrpStackLocation(irp);
2660
2661 irpStack->MajorFunction = IRP_MJ_SCSI;
2662
2663 srb->OriginalRequest = irp;
2664
2665 //
2666 // Save SRB address in next stack for port driver.
2667 //
2668
2669 irpStack->Parameters.Others.Argument1 = (PVOID)srb;
2670
2671 //
2672 // Can't release the remove lock yet - let ClassAsynchronousCompletion
2673 // take care of that for us.
2674 //
2675
2676 (VOID)IoCallDriver(fdoExtension->CommonExtension.LowerDeviceObject, irp);
2677
2678 return;
2679 }
2680
2681 NTSTATUS
FlopticalFormatMedia(PDEVICE_OBJECT DeviceObject,PFORMAT_PARAMETERS Format)2682 FlopticalFormatMedia(
2683 PDEVICE_OBJECT DeviceObject,
2684 PFORMAT_PARAMETERS Format
2685 )
2686 /*++
2687
2688 Routine Description:
2689
2690 This routine is used to do perform a format tracks for the 20.8 MB
2691 floppy. Because the device does not support format tracks and the full
2692 format takes a long time a write of zeros is done instead.
2693
2694 Arguments:
2695
2696 DeviceObject - Supplies the device object to be tested.
2697
2698 Format - Supplies the format parameters.
2699
2700 Return Value:
2701
2702 Returns a status for the operation.
2703
2704 --*/
2705 {
2706 IO_STATUS_BLOCK ioStatus;
2707 PIRP irp;
2708 KEVENT event;
2709 LARGE_INTEGER offset;
2710 ULONG length;
2711 PVOID buffer;
2712 PDRIVE_MEDIA_CONSTANTS driveMediaConstants;
2713 NTSTATUS status;
2714
2715 PAGED_CODE();
2716
2717 driveMediaConstants = &DriveMediaConstants[Drive2080Media2080];
2718
2719 //
2720 // Calculate the length of the buffer.
2721 //
2722
2723 length = ((Format->EndCylinderNumber - Format->StartCylinderNumber) *
2724 driveMediaConstants->NumberOfHeads +
2725 Format->EndHeadNumber - Format->StartHeadNumber + 1) *
2726 driveMediaConstants->SectorsPerTrack *
2727 driveMediaConstants->BytesPerSector;
2728
2729 buffer = ExAllocatePool(NonPagedPoolNxCacheAligned, length);
2730
2731 if (buffer == NULL) {
2732 return(STATUS_INSUFFICIENT_RESOURCES);
2733 }
2734
2735 RtlZeroMemory(buffer, length);
2736
2737 offset.QuadPart =
2738 (Format->StartCylinderNumber * driveMediaConstants->NumberOfHeads +
2739 Format->StartHeadNumber) * driveMediaConstants->SectorsPerTrack *
2740 driveMediaConstants->BytesPerSector;
2741
2742 //
2743 // Set the event object to the unsignaled state.
2744 // It will be used to signal request completion.
2745 //
2746
2747 KeInitializeEvent(&event, NotificationEvent, FALSE);
2748
2749 //
2750 // Build the synchronous request with data transfer.
2751 //
2752
2753 irp = IoBuildSynchronousFsdRequest(
2754 IRP_MJ_WRITE,
2755 DeviceObject,
2756 buffer,
2757 length,
2758 &offset,
2759 &event,
2760 &ioStatus);
2761
2762 if (irp != NULL) {
2763 status = IoCallDriver(DeviceObject, irp);
2764
2765 if (status == STATUS_PENDING) {
2766
2767 //
2768 // Wait for the request to complete if necessary.
2769 //
2770
2771 KeWaitForSingleObject(&event, Executive, KernelMode, FALSE, NULL);
2772 }
2773
2774 //
2775 // If the call driver suceeded then set the status to the status block.
2776 //
2777
2778 if (NT_SUCCESS(status)) {
2779 status = ioStatus.Status;
2780 }
2781 } else {
2782 status = STATUS_INSUFFICIENT_RESOURCES;
2783 }
2784
2785 ExFreePool(buffer);
2786
2787 return(status);
2788
2789 }
2790
2791
2792 NTSTATUS
2793 #ifdef __REACTOS__
2794 NTAPI
2795 #endif
ScsiFlopRemoveDevice(IN PDEVICE_OBJECT DeviceObject,IN UCHAR Type)2796 ScsiFlopRemoveDevice(
2797 IN PDEVICE_OBJECT DeviceObject,
2798 IN UCHAR Type
2799 )
2800 /*++
2801
2802 Routine Description:
2803
2804 This routine is responsible for releasing any resources in use by the
2805 sfloppy driver. This routine is called
2806 when all outstanding requests have been completed and the driver has
2807 disappeared - no requests may be issued to the lower drivers.
2808
2809 Arguments:
2810
2811 DeviceObject - the device object being removed
2812
2813 Type - the type of remove operation (QUERY, REMOVE or CANCEL)
2814
2815 Return Value:
2816
2817 for a query - success if the device can be removed or a failure code
2818 indiciating why not.
2819
2820 for a remove or cancel - STATUS_SUCCESS
2821
2822 --*/
2823
2824 {
2825 PFUNCTIONAL_DEVICE_EXTENSION deviceExtension =
2826 DeviceObject->DeviceExtension;
2827 PDISK_DATA diskData = deviceExtension->CommonExtension.DriverData;
2828 NTSTATUS status;
2829
2830 PAGED_CODE();
2831
2832 if((Type == IRP_MN_QUERY_REMOVE_DEVICE) ||
2833 (Type == IRP_MN_CANCEL_REMOVE_DEVICE)) {
2834 return STATUS_SUCCESS;
2835 }
2836
2837 if (Type == IRP_MN_REMOVE_DEVICE){
2838 if(deviceExtension->DeviceDescriptor) {
2839 ExFreePool(deviceExtension->DeviceDescriptor);
2840 deviceExtension->DeviceDescriptor = NULL;
2841 }
2842
2843 if(deviceExtension->AdapterDescriptor) {
2844 ExFreePool(deviceExtension->AdapterDescriptor);
2845 deviceExtension->AdapterDescriptor = NULL;
2846 }
2847
2848 if(deviceExtension->SenseData) {
2849 ExFreePool(deviceExtension->SenseData);
2850 deviceExtension->SenseData = NULL;
2851 }
2852
2853 ClassDeleteSrbLookasideList(&deviceExtension->CommonExtension);
2854 }
2855
2856 if(diskData->FloppyInterfaceString.Buffer != NULL) {
2857
2858 status = IoSetDeviceInterfaceState(
2859 &(diskData->FloppyInterfaceString),
2860 FALSE);
2861
2862 if (!NT_SUCCESS(status)) {
2863 // Failed to disable device interface during removal. Not a fatal error.
2864 DebugPrint((1, "ScsiFlopRemoveDevice: Unable to set device "
2865 "interface state to FALSE for fdo %p "
2866 "[%08lx]\n",
2867 DeviceObject, status));
2868 }
2869
2870 RtlFreeUnicodeString(&(diskData->FloppyInterfaceString));
2871 RtlInitUnicodeString(&(diskData->FloppyInterfaceString), NULL);
2872 }
2873
2874 if(Type == IRP_MN_REMOVE_DEVICE) {
2875 IoGetConfigurationInformation()->FloppyCount--;
2876 }
2877
2878 return STATUS_SUCCESS;
2879 }
2880
2881
2882 NTSTATUS
2883 #ifdef __REACTOS__
2884 NTAPI
2885 #endif
ScsiFlopStopDevice(IN PDEVICE_OBJECT DeviceObject,IN UCHAR Type)2886 ScsiFlopStopDevice(
2887 IN PDEVICE_OBJECT DeviceObject,
2888 IN UCHAR Type
2889 )
2890 {
2891 UNREFERENCED_PARAMETER(DeviceObject);
2892 UNREFERENCED_PARAMETER(Type);
2893
2894 return STATUS_SUCCESS;
2895 }
2896
2897
2898 NTSTATUS
USBFlopGetMediaTypes(IN PDEVICE_OBJECT DeviceObject,IN PIRP Irp)2899 USBFlopGetMediaTypes(
2900 IN PDEVICE_OBJECT DeviceObject,
2901 IN PIRP Irp
2902 )
2903 {
2904 /*++
2905
2906 Routine Description:
2907
2908 This routines determines the current or default geometry of the drive
2909 for IOCTL_DISK_GET_DRIVE_GEOMETRY, or all currently supported geometries
2910 of the drive (which is determined by its currently inserted media) for
2911 IOCTL_DISK_GET_MEDIA_TYPES.
2912
2913 The returned geometries are determined by issuing a Read Format Capacities
2914 request and then matching the returned {Number of Blocks, Block Length}
2915 pairs in a table of known floppy geometries.
2916
2917 Arguments:
2918
2919 DeviceObject - Supplies the device object.
2920
2921 Irp - A IOCTL_DISK_GET_DRIVE_GEOMETRY or a IOCTL_DISK_GET_MEDIA_TYPES Irp.
2922 If NULL, the device geometry is updated with the current device
2923 geometry.
2924
2925 Return Value:
2926
2927 Status is returned.
2928
2929 --*/
2930 PFUNCTIONAL_DEVICE_EXTENSION fdoExtension;
2931 PIO_STACK_LOCATION irpStack;
2932 ULONG ioControlCode;
2933 PDISK_GEOMETRY outputBuffer;
2934 PDISK_GEOMETRY outputBufferEnd;
2935 ULONG outputBufferLength;
2936 PSCSI_REQUEST_BLOCK srb;
2937 PVOID dataBuffer;
2938 ULONG dataTransferLength;
2939 struct _READ_FORMATTED_CAPACITIES *cdb;
2940 PFORMATTED_CAPACITY_LIST capList;
2941 NTSTATUS status;
2942
2943 PAGED_CODE();
2944
2945 fdoExtension = DeviceObject->DeviceExtension;
2946
2947 if (Irp != NULL) {
2948
2949 // Get the Irp parameters
2950 //
2951 irpStack = IoGetCurrentIrpStackLocation(Irp);
2952
2953 ioControlCode = irpStack->Parameters.DeviceIoControl.IoControlCode;
2954
2955 Irp->IoStatus.Information = 0;
2956
2957 outputBuffer = (PDISK_GEOMETRY) Irp->AssociatedIrp.SystemBuffer;
2958
2959 outputBufferLength = irpStack->Parameters.DeviceIoControl.OutputBufferLength;
2960
2961 if (outputBufferLength < sizeof(DISK_GEOMETRY))
2962 {
2963 return STATUS_BUFFER_TOO_SMALL;
2964 }
2965
2966 // Pointer arithmetic to allow multiple DISK_GEOMETRY's to be returned.
2967 // Rounds BufferEnd down to integral multiple of DISK_GEOMETRY structs.
2968 //
2969 outputBufferEnd = outputBuffer +
2970 outputBufferLength / sizeof(DISK_GEOMETRY);
2971
2972 } else {
2973
2974 // No Irp to return the result in, just update the current geometry
2975 // in the device extension.
2976 //
2977 ioControlCode = IOCTL_DISK_GET_DRIVE_GEOMETRY;
2978
2979 outputBuffer = NULL;
2980
2981 outputBufferEnd = NULL;
2982
2983 outputBufferLength = 0;
2984 }
2985
2986 if (ioControlCode == IOCTL_DISK_GET_DRIVE_GEOMETRY) {
2987
2988 fdoExtension->DiskGeometry.MediaType = Unknown;
2989
2990 status = ClassReadDriveCapacity(DeviceObject);
2991
2992 if (!NT_SUCCESS(status))
2993 {
2994 // If the media is not recongized, we want to return the default
2995 // geometry so that the media can be formatted. Unrecognized media
2996 // causes SCSI_SENSE_MEDIUM_ERROR, which gets reported as
2997 // STATUS_DEVICE_DATA_ERROR. Ignore these errors, but return other
2998 // errors, such as STATUS_NO_MEDIA_IN_DEVICE.
2999 //
3000 if (status != STATUS_UNRECOGNIZED_MEDIA)
3001 {
3002 DebugPrint((2,"IOCTL_DISK_GET_DRIVE_GEOMETRY returns %08X\n", status));
3003
3004 return status;
3005 }
3006 }
3007 }
3008
3009 // Allocate an SRB for the SCSIOP_READ_FORMATTED_CAPACITY request
3010 //
3011 srb = ExAllocatePool(NonPagedPoolNx, SCSI_REQUEST_BLOCK_SIZE);
3012
3013 if (srb == NULL)
3014 {
3015 return STATUS_INSUFFICIENT_RESOURCES;
3016 }
3017
3018 // Allocate a transfer buffer for the SCSIOP_READ_FORMATTED_CAPACITY request
3019 // The length of the returned descriptor array is limited to a byte field
3020 // in the capacity list header.
3021 //
3022 dataTransferLength = sizeof(FORMATTED_CAPACITY_LIST) +
3023 31 * sizeof(FORMATTED_CAPACITY_DESCRIPTOR);
3024
3025 ASSERT(dataTransferLength < 0x100);
3026
3027 dataBuffer = ExAllocatePool(NonPagedPoolNx, dataTransferLength);
3028
3029 if (dataBuffer == NULL)
3030 {
3031 ExFreePool(srb);
3032 return STATUS_INSUFFICIENT_RESOURCES;
3033 }
3034
3035 // Initialize the SRB and CDB
3036 //
3037 RtlZeroMemory(srb, SCSI_REQUEST_BLOCK_SIZE);
3038
3039 RtlZeroMemory(dataBuffer, dataTransferLength);
3040
3041 srb->CdbLength = sizeof(struct _READ_FORMATTED_CAPACITIES);
3042
3043 srb->TimeOutValue = fdoExtension->TimeOutValue;
3044
3045 cdb = (struct _READ_FORMATTED_CAPACITIES *)srb->Cdb;
3046
3047 cdb->OperationCode = SCSIOP_READ_FORMATTED_CAPACITY;
3048 cdb->AllocationLength[1] = (UCHAR)dataTransferLength;
3049
3050 //
3051 // Send down the SCSIOP_READ_FORMATTED_CAPACITY request
3052 //
3053 status = ClassSendSrbSynchronous(DeviceObject,
3054 srb,
3055 dataBuffer,
3056 dataTransferLength,
3057 FALSE);
3058
3059 capList = (PFORMATTED_CAPACITY_LIST)dataBuffer;
3060
3061 // If we don't get as much data as requested, it is not an error.
3062 //
3063 if (SRB_STATUS(srb->SrbStatus) == SRB_STATUS_DATA_OVERRUN)
3064 {
3065 status = STATUS_SUCCESS;
3066 }
3067
3068 if (NT_SUCCESS(status) &&
3069 srb->DataTransferLength >= sizeof(FORMATTED_CAPACITY_LIST) &&
3070 capList->CapacityListLength &&
3071 capList->CapacityListLength % sizeof(FORMATTED_CAPACITY_DESCRIPTOR) == 0)
3072 {
3073 ULONG NumberOfBlocks;
3074 ULONG BlockLength;
3075 ULONG count;
3076 ULONG i, j;
3077 LONG currentGeometry;
3078 BOOLEAN capacityMatches[FLOPPY_CAPACITIES];
3079
3080 // Subtract the size of the Capacity List Header to get
3081 // just the size of the Capacity List Descriptor array.
3082 //
3083 srb->DataTransferLength -= sizeof(FORMATTED_CAPACITY_LIST);
3084
3085 // Only look at the Capacity List Descriptors that were actually
3086 // returned.
3087 //
3088 if (srb->DataTransferLength < capList->CapacityListLength)
3089 {
3090 count = srb->DataTransferLength /
3091 sizeof(FORMATTED_CAPACITY_DESCRIPTOR);
3092 }
3093 else
3094 {
3095 count = capList->CapacityListLength /
3096 sizeof(FORMATTED_CAPACITY_DESCRIPTOR);
3097 }
3098
3099 // Updated only if a match is found for the first Capacity List
3100 // Descriptor returned by the device.
3101 //
3102 currentGeometry = -1;
3103
3104 // Initialize the array of capacities that hit a match.
3105 //
3106 RtlZeroMemory(capacityMatches, sizeof(capacityMatches));
3107
3108 // Iterate over each Capacity List Descriptor returned from the device
3109 // and record matching capacities in the capacity match array.
3110 //
3111 for (i = 0; i < count; i++)
3112 {
3113 NumberOfBlocks = (capList->Descriptors[i].NumberOfBlocks[0] << 24) +
3114 (capList->Descriptors[i].NumberOfBlocks[1] << 16) +
3115 (capList->Descriptors[i].NumberOfBlocks[2] << 8) +
3116 (capList->Descriptors[i].NumberOfBlocks[3]);
3117
3118 BlockLength = (capList->Descriptors[i].BlockLength[0] << 16) +
3119 (capList->Descriptors[i].BlockLength[1] << 8) +
3120 (capList->Descriptors[i].BlockLength[2]);
3121
3122 // Given the {NumberOfBlocks, BlockLength} from this Capacity List
3123 // Descriptor, find a matching entry in FloppyCapacities[].
3124 //
3125 for (j = 0; j < FLOPPY_CAPACITIES; j++)
3126 {
3127 if (NumberOfBlocks == FloppyCapacities[j].NumberOfBlocks &&
3128 BlockLength == FloppyCapacities[j].BlockLength)
3129 {
3130 // A matching capacity was found, record it.
3131 //
3132 capacityMatches[j] = TRUE;
3133
3134 // A match was found for the first Capacity List
3135 // Descriptor returned by the device.
3136 //
3137 if (i == 0)
3138 {
3139 currentGeometry = j;
3140 }
3141 } else if ((capList->Descriptors[i].Valid) &&
3142 (BlockLength == FloppyCapacities[j].BlockLength)) {
3143
3144 ULONG inx;
3145 ULONG mediaInx;
3146
3147 //
3148 // Check if this is 32MB media type. 32MB media
3149 // reports variable NumberOfBlocks. So we cannot
3150 // use that to determine the drive type
3151 //
3152 inx = DetermineDriveType(DeviceObject);
3153 if (inx != DRIVE_TYPE_NONE) {
3154 mediaInx = DriveMediaLimits[inx].HighestDriveMediaType;
3155 if ((DriveMediaConstants[mediaInx].MediaType)
3156 == F3_32M_512) {
3157 capacityMatches[j] = TRUE;
3158
3159 if (i == 0) {
3160 currentGeometry = j;
3161 }
3162 }
3163 }
3164 }
3165 }
3166 }
3167
3168 // Default status is STATUS_UNRECOGNIZED_MEDIA, unless we return
3169 // either STATUS_SUCCESS or STATUS_BUFFER_OVERFLOW.
3170 //
3171 status = STATUS_UNRECOGNIZED_MEDIA;
3172
3173 if (ioControlCode == IOCTL_DISK_GET_DRIVE_GEOMETRY) {
3174
3175 if (currentGeometry != -1)
3176 {
3177 // Update the current device geometry
3178 //
3179 fdoExtension->DiskGeometry = FloppyGeometries[currentGeometry];
3180
3181 //
3182 // Calculate sector to byte shift.
3183 //
3184
3185 WHICH_BIT(fdoExtension->DiskGeometry.BytesPerSector,
3186 fdoExtension->SectorShift);
3187
3188 fdoExtension->CommonExtension.PartitionLength.QuadPart =
3189 (LONGLONG)FloppyCapacities[currentGeometry].NumberOfBlocks *
3190 FloppyCapacities[currentGeometry].BlockLength;
3191
3192 DebugPrint((2,"geometry is: %3d %2d %d %2d %4d %2d %08X\n",
3193 fdoExtension->DiskGeometry.Cylinders.LowPart,
3194 fdoExtension->DiskGeometry.MediaType,
3195 fdoExtension->DiskGeometry.TracksPerCylinder,
3196 fdoExtension->DiskGeometry.SectorsPerTrack,
3197 fdoExtension->DiskGeometry.BytesPerSector,
3198 fdoExtension->SectorShift,
3199 fdoExtension->CommonExtension.PartitionLength.LowPart));
3200
3201 // Return the current device geometry
3202 //
3203 if (Irp != NULL)
3204 {
3205 *outputBuffer = FloppyGeometries[currentGeometry];
3206
3207 Irp->IoStatus.Information = sizeof(DISK_GEOMETRY);
3208 }
3209
3210 status = STATUS_SUCCESS;
3211 }
3212
3213 } else {
3214
3215 // Iterate over the capacities and return the geometry
3216 // corresponding to each matching Capacity List Descriptor
3217 // returned from the device.
3218 //
3219 // The resulting list should be in sorted ascending order,
3220 // assuming that the FloppyGeometries[] array is in sorted
3221 // ascending order.
3222 //
3223 for (i = 0; i < FLOPPY_CAPACITIES; i++)
3224 {
3225 if (capacityMatches[i] && FloppyCapacities[i].CanFormat)
3226 {
3227 if (outputBuffer < outputBufferEnd)
3228 {
3229 *outputBuffer++ = FloppyGeometries[i];
3230
3231 Irp->IoStatus.Information += sizeof(DISK_GEOMETRY);
3232
3233 DebugPrint((2,"geometry : %3d %2d %d %2d %4d\n",
3234 FloppyGeometries[i].Cylinders.LowPart,
3235 FloppyGeometries[i].MediaType,
3236 FloppyGeometries[i].TracksPerCylinder,
3237 FloppyGeometries[i].SectorsPerTrack,
3238 FloppyGeometries[i].BytesPerSector));
3239
3240 status = STATUS_SUCCESS;
3241 }
3242 else
3243 {
3244 // We ran out of output buffer room before we ran out
3245 // geometries to return.
3246 //
3247 status = STATUS_BUFFER_OVERFLOW;
3248 }
3249 }
3250 }
3251 }
3252 }
3253 else if (NT_SUCCESS(status))
3254 {
3255 // The SCSIOP_READ_FORMATTED_CAPACITY request was successful, but
3256 // returned data does not appear valid.
3257 //
3258 status = STATUS_UNSUCCESSFUL;
3259 }
3260
3261 ExFreePool(dataBuffer);
3262 ExFreePool(srb);
3263
3264 return status;
3265 }
3266
3267
3268 NTSTATUS
USBFlopFormatTracks(IN PDEVICE_OBJECT DeviceObject,IN PIRP Irp)3269 USBFlopFormatTracks(
3270 IN PDEVICE_OBJECT DeviceObject,
3271 IN PIRP Irp
3272 )
3273 {
3274 /*++
3275
3276 Routine Description:
3277
3278 This routines formats the specified tracks. If multiple tracks are
3279 specified, each is formatted with a separate Format Unit request.
3280
3281 Arguments:
3282
3283 DeviceObject - Supplies the device object.
3284
3285 Irp - A IOCTL_DISK_FORMAT_TRACKS Irp.
3286
3287 Return Value:
3288
3289 Status is returned.
3290
3291 --*/
3292 PFUNCTIONAL_DEVICE_EXTENSION fdoExtension;
3293 PIO_STACK_LOCATION irpStack;
3294 PFORMAT_PARAMETERS formatParameters;
3295 PDISK_GEOMETRY geometry;
3296 PFORMATTED_CAPACITY capacity;
3297 PSCSI_REQUEST_BLOCK srb;
3298 PFORMAT_UNIT_PARAMETER_LIST parameterList;
3299 PCDB12FORMAT cdb;
3300 ULONG i;
3301 ULONG cylinder, head;
3302 NTSTATUS status = STATUS_SUCCESS;
3303
3304 PAGED_CODE();
3305
3306 fdoExtension = DeviceObject->DeviceExtension;
3307
3308 // Get the Irp parameters
3309 //
3310 irpStack = IoGetCurrentIrpStackLocation(Irp);
3311
3312 if (irpStack->Parameters.DeviceIoControl.InputBufferLength <
3313 sizeof(FORMAT_PARAMETERS))
3314 {
3315 return STATUS_INVALID_PARAMETER;
3316 }
3317
3318 formatParameters = (PFORMAT_PARAMETERS)Irp->AssociatedIrp.SystemBuffer;
3319
3320 // Find the geometry / capacity entries corresponding to the format
3321 // parameters MediaType
3322 //
3323 geometry = NULL;
3324 capacity = NULL;
3325
3326 for (i=0; i<FLOPPY_CAPACITIES; i++)
3327 {
3328 if (FloppyGeometries[i].MediaType == formatParameters->MediaType)
3329 {
3330 geometry = &FloppyGeometries[i];
3331 capacity = &FloppyCapacities[i];
3332
3333 break;
3334 }
3335 }
3336
3337 if (geometry == NULL)
3338 {
3339 return STATUS_INVALID_PARAMETER;
3340 }
3341
3342 // Check if the format parameters are valid
3343 //
3344 if ((formatParameters->StartCylinderNumber >
3345 geometry->Cylinders.LowPart - 1) ||
3346
3347 (formatParameters->EndCylinderNumber >
3348 geometry->Cylinders.LowPart - 1) ||
3349
3350 (formatParameters->StartHeadNumber >
3351 geometry->TracksPerCylinder - 1) ||
3352
3353 (formatParameters->EndHeadNumber >
3354 geometry->TracksPerCylinder - 1) ||
3355
3356 (formatParameters->StartCylinderNumber >
3357 formatParameters->EndCylinderNumber) ||
3358
3359 (formatParameters->StartHeadNumber >
3360 formatParameters->EndHeadNumber))
3361 {
3362 return STATUS_INVALID_PARAMETER;
3363 }
3364
3365 // Don't low level format LS-120 media, Imation says it's best to not
3366 // do this.
3367 //
3368 if ((formatParameters->MediaType == F3_120M_512) ||
3369 (formatParameters->MediaType == F3_240M_512) ||
3370 (formatParameters->MediaType == F3_32M_512))
3371 {
3372 return STATUS_SUCCESS;
3373 }
3374
3375 // Allocate an SRB for the SCSIOP_FORMAT_UNIT request
3376 //
3377 srb = ExAllocatePool(NonPagedPoolNx, SCSI_REQUEST_BLOCK_SIZE);
3378
3379 if (srb == NULL)
3380 {
3381 return STATUS_INSUFFICIENT_RESOURCES;
3382 }
3383
3384 // Allocate a transfer buffer for the SCSIOP_FORMAT_UNIT parameter list
3385 //
3386 parameterList = ExAllocatePool(NonPagedPoolNx,
3387 sizeof(FORMAT_UNIT_PARAMETER_LIST));
3388
3389 if (parameterList == NULL)
3390 {
3391 ExFreePool(srb);
3392 return STATUS_INSUFFICIENT_RESOURCES;
3393 }
3394
3395 // Initialize the parameter list
3396 //
3397 RtlZeroMemory(parameterList, sizeof(FORMAT_UNIT_PARAMETER_LIST));
3398
3399 parameterList->DefectListHeader.SingleTrack = 1;
3400 parameterList->DefectListHeader.DisableCert = 1; // TEAC requires this set
3401 parameterList->DefectListHeader.FormatOptionsValid = 1;
3402 parameterList->DefectListHeader.DefectListLengthLsb = 8;
3403
3404 parameterList->FormatDescriptor.NumberOfBlocks[0] =
3405 (UCHAR)((capacity->NumberOfBlocks >> 24) & 0xFF);
3406
3407 parameterList->FormatDescriptor.NumberOfBlocks[1] =
3408 (UCHAR)((capacity->NumberOfBlocks >> 16) & 0xFF);
3409
3410 parameterList->FormatDescriptor.NumberOfBlocks[2] =
3411 (UCHAR)((capacity->NumberOfBlocks >> 8) & 0xFF);
3412
3413 parameterList->FormatDescriptor.NumberOfBlocks[3] =
3414 (UCHAR)(capacity->NumberOfBlocks & 0xFF);
3415
3416 parameterList->FormatDescriptor.BlockLength[0] =
3417 (UCHAR)((capacity->BlockLength >> 16) & 0xFF);
3418
3419 parameterList->FormatDescriptor.BlockLength[1] =
3420 (UCHAR)((capacity->BlockLength >> 8) & 0xFF);
3421
3422 parameterList->FormatDescriptor.BlockLength[2] =
3423 (UCHAR)(capacity->BlockLength & 0xFF);
3424
3425
3426 for (cylinder = formatParameters->StartCylinderNumber;
3427 cylinder <= formatParameters->EndCylinderNumber;
3428 cylinder++)
3429 {
3430 for (head = formatParameters->StartHeadNumber;
3431 head <= formatParameters->EndHeadNumber;
3432 head++)
3433 {
3434 // Initialize the SRB and CDB
3435 //
3436 RtlZeroMemory(srb, SCSI_REQUEST_BLOCK_SIZE);
3437
3438 srb->CdbLength = sizeof(CDB12FORMAT);
3439
3440 srb->TimeOutValue = fdoExtension->TimeOutValue;
3441
3442 cdb = (PCDB12FORMAT)srb->Cdb;
3443
3444 cdb->OperationCode = SCSIOP_FORMAT_UNIT;
3445 cdb->DefectListFormat = 7;
3446 cdb->FmtData = 1;
3447 cdb->TrackNumber = (UCHAR)cylinder;
3448 cdb->ParameterListLengthLsb = sizeof(FORMAT_UNIT_PARAMETER_LIST);
3449
3450 parameterList->DefectListHeader.Side = (UCHAR)head;
3451
3452 //
3453 // Send down the SCSIOP_FORMAT_UNIT request
3454 //
3455 status = ClassSendSrbSynchronous(DeviceObject,
3456 srb,
3457 parameterList,
3458 sizeof(FORMAT_UNIT_PARAMETER_LIST),
3459 TRUE);
3460
3461 if (!NT_SUCCESS(status))
3462 {
3463 break;
3464 }
3465 }
3466 if (!NT_SUCCESS(status))
3467 {
3468 break;
3469 }
3470 }
3471
3472 if (NT_SUCCESS(status) && formatParameters->StartCylinderNumber == 0)
3473 {
3474 // Update the device geometry
3475 //
3476
3477 DebugPrint((2,"geometry was: %3d %2d %d %2d %4d %2d %08X\n",
3478 fdoExtension->DiskGeometry.Cylinders.LowPart,
3479 fdoExtension->DiskGeometry.MediaType,
3480 fdoExtension->DiskGeometry.TracksPerCylinder,
3481 fdoExtension->DiskGeometry.SectorsPerTrack,
3482 fdoExtension->DiskGeometry.BytesPerSector,
3483 fdoExtension->SectorShift,
3484 fdoExtension->CommonExtension.PartitionLength.LowPart));
3485
3486 fdoExtension->DiskGeometry = *geometry;
3487
3488 //
3489 // Calculate sector to byte shift.
3490 //
3491
3492 WHICH_BIT(fdoExtension->DiskGeometry.BytesPerSector,
3493 fdoExtension->SectorShift);
3494
3495 fdoExtension->CommonExtension.PartitionLength.QuadPart =
3496 (LONGLONG)capacity->NumberOfBlocks *
3497 capacity->BlockLength;
3498
3499 DebugPrint((2,"geometry is: %3d %2d %d %2d %4d %2d %08X\n",
3500 fdoExtension->DiskGeometry.Cylinders.LowPart,
3501 fdoExtension->DiskGeometry.MediaType,
3502 fdoExtension->DiskGeometry.TracksPerCylinder,
3503 fdoExtension->DiskGeometry.SectorsPerTrack,
3504 fdoExtension->DiskGeometry.BytesPerSector,
3505 fdoExtension->SectorShift,
3506 fdoExtension->CommonExtension.PartitionLength.LowPart));
3507 }
3508
3509 // Free everything we allocated
3510 //
3511 ExFreePool(parameterList);
3512 ExFreePool(srb);
3513
3514 return status;
3515 }
3516