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reactos/drivers/storage/ide/atapi/atapi.c

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/*
* PROJECT: ReactOS Storage Stack
* LICENSE: DDK - see license.txt in the root dir
* FILE: drivers/storage/atapi/atapi.c
* PURPOSE: ATAPI IDE miniport driver
* PROGRAMMERS: Based on a source code sample from Microsoft NT4 DDK
*/
#include <ntddk.h>
#include "atapi.h" // includes scsi.h
#include <ntddscsi.h>
#include <ntdddisk.h>
#include <ntddstor.h>
//#define NDEBUG
#include <debug.h>
//
// Device extension
//
typedef struct _HW_DEVICE_EXTENSION {
//
// Current request on controller.
//
PSCSI_REQUEST_BLOCK CurrentSrb;
//
// Base register locations
//
PIDE_REGISTERS_1 BaseIoAddress1[2];
PIDE_REGISTERS_2 BaseIoAddress2[2];
//
// Interrupt level
//
ULONG InterruptLevel;
//
// Interrupt Mode (Level or Edge)
//
ULONG InterruptMode;
//
// Data buffer pointer.
//
PUSHORT DataBuffer;
//
// Data words left.
//
ULONG WordsLeft;
//
// Number of channels being supported by one instantiation
// of the device extension. Normally (and correctly) one, but
// with so many broken PCI IDE controllers being sold, we have
// to support them.
//
ULONG NumberChannels;
//
// Count of errors. Used to turn off features.
//
ULONG ErrorCount;
//
// Indicates number of platters on changer-ish devices.
//
ULONG DiscsPresent[4];
//
// Flags word for each possible device.
//
USHORT DeviceFlags[4];
//
// Indicates the number of blocks transferred per int. according to the
// identify data.
//
UCHAR MaximumBlockXfer[4];
//
// Indicates expecting an interrupt
//
BOOLEAN ExpectingInterrupt;
//
// Indicate last tape command was DSC Restrictive.
//
BOOLEAN RDP;
//
// Driver is being used by the crash dump utility or ntldr.
//
BOOLEAN DriverMustPoll;
//
// Indicates use of 32-bit PIO
//
BOOLEAN DWordIO;
//
// Indicates whether '0x1f0' is the base address. Used
// in SMART Ioctl calls.
//
BOOLEAN PrimaryAddress;
//
// Placeholder for the sub-command value of the last
// SMART command.
//
UCHAR SmartCommand;
//
// Placeholder for status register after a GET_MEDIA_STATUS command
//
UCHAR ReturningMediaStatus;
UCHAR Reserved[1];
//
// Identify data for device
//
IDENTIFY_DATA FullIdentifyData;
IDENTIFY_DATA2 IdentifyData[4];
//
// Mechanism Status Srb Data
//
PSCSI_REQUEST_BLOCK OriginalSrb;
SCSI_REQUEST_BLOCK InternalSrb;
MECHANICAL_STATUS_INFORMATION_HEADER MechStatusData;
SENSE_DATA MechStatusSense;
ULONG MechStatusRetryCount;
} HW_DEVICE_EXTENSION, *PHW_DEVICE_EXTENSION;
//
// Logical unit extension
//
typedef struct _HW_LU_EXTENSION {
ULONG Reserved;
} HW_LU_EXTENSION, *PHW_LU_EXTENSION;
PSCSI_REQUEST_BLOCK
NTAPI
BuildMechanismStatusSrb (
IN PVOID HwDeviceExtension,
IN ULONG PathId,
IN ULONG TargetId
);
PSCSI_REQUEST_BLOCK
NTAPI
BuildRequestSenseSrb (
IN PVOID HwDeviceExtension,
IN ULONG PathId,
IN ULONG TargetId
);
VOID
NTAPI
AtapiHwInitializeChanger (
IN PVOID HwDeviceExtension,
IN ULONG TargetId,
IN PMECHANICAL_STATUS_INFORMATION_HEADER MechanismStatus
);
ULONG
NTAPI
AtapiSendCommand(
IN PVOID HwDeviceExtension,
IN PSCSI_REQUEST_BLOCK Srb
);
VOID
NTAPI
AtapiZeroMemory(
IN PUCHAR Buffer,
IN ULONG Count
);
VOID
NTAPI
AtapiHexToString (
ULONG Value,
PCHAR *Buffer
);
LONG
NTAPI
AtapiStringCmp (
PCHAR FirstStr,
PCHAR SecondStr,
ULONG Count
);
BOOLEAN
NTAPI
AtapiInterrupt(
IN PVOID HwDeviceExtension
);
BOOLEAN
NTAPI
AtapiHwInitialize(
IN PVOID HwDeviceExtension
);
ULONG
NTAPI
IdeBuildSenseBuffer(
IN PVOID HwDeviceExtension,
IN PSCSI_REQUEST_BLOCK Srb
);
VOID
NTAPI
IdeMediaStatus(
IN BOOLEAN EnableMSN,
IN PVOID HwDeviceExtension,
IN ULONG Channel
);
BOOLEAN
NTAPI
IssueIdentify(
IN PVOID HwDeviceExtension,
IN ULONG DeviceNumber,
IN ULONG Channel,
IN UCHAR Command
)
/*++
Routine Description:
Issue IDENTIFY command to a device.
Arguments:
HwDeviceExtension - HBA miniport driver's adapter data storage
DeviceNumber - Indicates which device.
Command - Either the standard (EC) or the ATAPI packet (A1) IDENTIFY.
Return Value:
TRUE if all goes well.
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PIDE_REGISTERS_1 baseIoAddress1 = deviceExtension->BaseIoAddress1[Channel] ;
PIDE_REGISTERS_2 baseIoAddress2 = deviceExtension->BaseIoAddress2[Channel];
ULONG waitCount = 20000;
ULONG i,j;
UCHAR statusByte;
UCHAR signatureLow,
signatureHigh;
//
// Select device 0 or 1.
//
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,
(UCHAR)((DeviceNumber << 4) | 0xA0));
//
// Check that the status register makes sense.
//
GetBaseStatus(baseIoAddress1, statusByte);
if (Command == IDE_COMMAND_IDENTIFY) {
//
// Mask status byte ERROR bits.
//
statusByte &= ~(IDE_STATUS_ERROR | IDE_STATUS_INDEX);
DebugPrint((1,
"IssueIdentify: Checking for IDE. Status (%x)\n",
statusByte));
//
// Check if register value is reasonable.
//
if (statusByte != IDE_STATUS_IDLE) {
//
// Reset the controller.
//
AtapiSoftReset(baseIoAddress1,DeviceNumber);
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,
(UCHAR)((DeviceNumber << 4) | 0xA0));
WaitOnBusy(baseIoAddress2,statusByte);
signatureLow = ScsiPortReadPortUchar(&baseIoAddress1->CylinderLow);
signatureHigh = ScsiPortReadPortUchar(&baseIoAddress1->CylinderHigh);
if (signatureLow == 0x14 && signatureHigh == 0xEB) {
//
// Device is Atapi.
//
return FALSE;
}
DebugPrint((1,
"IssueIdentify: Resetting controller.\n"));
ScsiPortWritePortUchar(&baseIoAddress2->AlternateStatus,IDE_DC_RESET_CONTROLLER );
ScsiPortStallExecution(500 * 1000);
ScsiPortWritePortUchar(&baseIoAddress2->AlternateStatus,IDE_DC_REENABLE_CONTROLLER);
// We really should wait up to 31 seconds
// The ATA spec. allows device 0 to come back from BUSY in 31 seconds!
// (30 seconds for device 1)
do {
//
// Wait for Busy to drop.
//
ScsiPortStallExecution(100);
GetStatus(baseIoAddress2, statusByte);
} while ((statusByte & IDE_STATUS_BUSY) && waitCount--);
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,
(UCHAR)((DeviceNumber << 4) | 0xA0));
//
// Another check for signature, to deal with one model Atapi that doesn't assert signature after
// a soft reset.
//
signatureLow = ScsiPortReadPortUchar(&baseIoAddress1->CylinderLow);
signatureHigh = ScsiPortReadPortUchar(&baseIoAddress1->CylinderHigh);
if (signatureLow == 0x14 && signatureHigh == 0xEB) {
//
// Device is Atapi.
//
return FALSE;
}
statusByte &= ~IDE_STATUS_INDEX;
if (statusByte != IDE_STATUS_IDLE) {
//
// Give up on this.
//
return FALSE;
}
}
} else {
DebugPrint((1,
"IssueIdentify: Checking for ATAPI. Status (%x)\n",
statusByte));
}
//
// Load CylinderHigh and CylinderLow with number bytes to transfer.
//
ScsiPortWritePortUchar(&baseIoAddress1->CylinderHigh, (0x200 >> 8));
ScsiPortWritePortUchar(&baseIoAddress1->CylinderLow, (0x200 & 0xFF));
for (j = 0; j < 2; j++) {
//
// Send IDENTIFY command.
//
WaitOnBusy(baseIoAddress2,statusByte);
ScsiPortWritePortUchar(&baseIoAddress1->Command, Command);
//
// Wait for DRQ.
//
for (i = 0; i < 4; i++) {
WaitForDrq(baseIoAddress2, statusByte);
if (statusByte & IDE_STATUS_DRQ) {
//
// Read status to acknowledge any interrupts generated.
//
GetBaseStatus(baseIoAddress1, statusByte);
//
// One last check for Atapi.
//
signatureLow = ScsiPortReadPortUchar(&baseIoAddress1->CylinderLow);
signatureHigh = ScsiPortReadPortUchar(&baseIoAddress1->CylinderHigh);
if (signatureLow == 0x14 && signatureHigh == 0xEB) {
//
// Device is Atapi.
//
return FALSE;
}
break;
}
if (Command == IDE_COMMAND_IDENTIFY) {
//
// Check the signature. If DRQ didn't come up it's likely Atapi.
//
signatureLow = ScsiPortReadPortUchar(&baseIoAddress1->CylinderLow);
signatureHigh = ScsiPortReadPortUchar(&baseIoAddress1->CylinderHigh);
if (signatureLow == 0x14 && signatureHigh == 0xEB) {
//
// Device is Atapi.
//
return FALSE;
}
}
WaitOnBusy(baseIoAddress2,statusByte);
}
if (i == 4 && j == 0) {
//
// Device didn't respond correctly. It will be given one more chances.
//
DebugPrint((1,
"IssueIdentify: DRQ never asserted (%x). Error reg (%x)\n",
statusByte,
ScsiPortReadPortUchar((PUCHAR)baseIoAddress1 + 1)));
AtapiSoftReset(baseIoAddress1,DeviceNumber);
GetStatus(baseIoAddress2,statusByte);
DebugPrint((1,
"IssueIdentify: Status after soft reset (%x)\n",
statusByte));
} else {
break;
}
}
//
// Check for error on really stupid master devices that assert random
// patterns of bits in the status register at the slave address.
//
if ((Command == IDE_COMMAND_IDENTIFY) && (statusByte & IDE_STATUS_ERROR)) {
return FALSE;
}
DebugPrint((1,
"IssueIdentify: Status before read words %x\n",
statusByte));
//
// Suck out 256 words. After waiting for one model that asserts busy
// after receiving the Packet Identify command.
//
WaitOnBusy(baseIoAddress2,statusByte);
if (!(statusByte & IDE_STATUS_DRQ)) {
return FALSE;
}
ReadBuffer(baseIoAddress1,
(PUSHORT)&deviceExtension->FullIdentifyData,
256);
//
// Check out a few capabilities / limitations of the device.
//
if (deviceExtension->FullIdentifyData.SpecialFunctionsEnabled & 1) {
//
// Determine if this drive supports the MSN functions.
//
DebugPrint((2,"IssueIdentify: Marking drive %d as removable. SFE = %d\n",
Channel * 2 + DeviceNumber,
deviceExtension->FullIdentifyData.SpecialFunctionsEnabled));
deviceExtension->DeviceFlags[(Channel * 2) + DeviceNumber] |= DFLAGS_REMOVABLE_DRIVE;
}
if (deviceExtension->FullIdentifyData.MaximumBlockTransfer) {
//
// Determine max. block transfer for this device.
//
deviceExtension->MaximumBlockXfer[(Channel * 2) + DeviceNumber] =
(UCHAR)(deviceExtension->FullIdentifyData.MaximumBlockTransfer & 0xFF);
}
ScsiPortMoveMemory(&deviceExtension->IdentifyData[(Channel * 2) + DeviceNumber],&deviceExtension->FullIdentifyData,sizeof(IDENTIFY_DATA2));
if (deviceExtension->IdentifyData[(Channel * 2) + DeviceNumber].GeneralConfiguration & 0x20 &&
Command != IDE_COMMAND_IDENTIFY) {
//
// This device interrupts with the assertion of DRQ after receiving
// Atapi Packet Command
//
deviceExtension->DeviceFlags[(Channel * 2) + DeviceNumber] |= DFLAGS_INT_DRQ;
DebugPrint((2,
"IssueIdentify: Device interrupts on assertion of DRQ.\n"));
} else {
DebugPrint((2,
"IssueIdentify: Device does not interrupt on assertion of DRQ.\n"));
}
if (((deviceExtension->IdentifyData[(Channel * 2) + DeviceNumber].GeneralConfiguration & 0xF00) == 0x100) &&
Command != IDE_COMMAND_IDENTIFY) {
//
// This is a tape.
//
deviceExtension->DeviceFlags[(Channel * 2) + DeviceNumber] |= DFLAGS_TAPE_DEVICE;
DebugPrint((2,
"IssueIdentify: Device is a tape drive.\n"));
} else {
DebugPrint((2,
"IssueIdentify: Device is not a tape drive.\n"));
}
//
// Work around for some IDE and one model Atapi that will present more than
// 256 bytes for the Identify data.
//
WaitOnBusy(baseIoAddress2,statusByte);
for (i = 0; i < 0x10000; i++) {
GetStatus(baseIoAddress2,statusByte);
if (statusByte & IDE_STATUS_DRQ) {
//
// Suck out any remaining bytes and throw away.
//
ScsiPortReadPortUshort(&baseIoAddress1->Data);
} else {
break;
}
}
DebugPrint((3,
"IssueIdentify: Status after read words (%x)\n",
statusByte));
return TRUE;
} // end IssueIdentify()
BOOLEAN
NTAPI
SetDriveParameters(
IN PVOID HwDeviceExtension,
IN ULONG DeviceNumber,
IN ULONG Channel
)
/*++
Routine Description:
Set drive parameters using the IDENTIFY data.
Arguments:
HwDeviceExtension - HBA miniport driver's adapter data storage
DeviceNumber - Indicates which device.
Return Value:
TRUE if all goes well.
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PIDE_REGISTERS_1 baseIoAddress1 = deviceExtension->BaseIoAddress1[Channel];
PIDE_REGISTERS_2 baseIoAddress2 = deviceExtension->BaseIoAddress2[Channel];
PIDENTIFY_DATA2 identifyData = &deviceExtension->IdentifyData[(Channel * 2) + DeviceNumber];
ULONG i;
UCHAR statusByte;
DebugPrint((1,
"SetDriveParameters: Number of heads %x\n",
identifyData->NumberOfHeads));
DebugPrint((1,
"SetDriveParameters: Sectors per track %x\n",
identifyData->SectorsPerTrack));
//
// Set up registers for SET PARAMETER command.
//
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,
(UCHAR)(((DeviceNumber << 4) | 0xA0) | (identifyData->NumberOfHeads - 1)));
ScsiPortWritePortUchar(&baseIoAddress1->BlockCount,
(UCHAR)identifyData->SectorsPerTrack);
//
// Send SET PARAMETER command.
//
ScsiPortWritePortUchar(&baseIoAddress1->Command,
IDE_COMMAND_SET_DRIVE_PARAMETERS);
//
// Wait for up to 30 milliseconds for ERROR or command complete.
//
for (i=0; i<30 * 1000; i++) {
UCHAR errorByte;
GetStatus(baseIoAddress2, statusByte);
if (statusByte & IDE_STATUS_ERROR) {
errorByte = ScsiPortReadPortUchar((PUCHAR)baseIoAddress1 + 1);
DebugPrint((1,
"SetDriveParameters: Error bit set. Status %x, error %x\n",
errorByte,
statusByte));
return FALSE;
} else if ((statusByte & ~IDE_STATUS_INDEX ) == IDE_STATUS_IDLE) {
break;
} else {
ScsiPortStallExecution(100);
}
}
//
// Check for timeout.
//
if (i == 30 * 1000) {
return FALSE;
} else {
return TRUE;
}
} // end SetDriveParameters()
BOOLEAN
NTAPI
AtapiResetController(
IN PVOID HwDeviceExtension,
IN ULONG PathId
)
/*++
Routine Description:
Reset IDE controller and/or Atapi device.
Arguments:
HwDeviceExtension - HBA miniport driver's adapter data storage
Return Value:
Nothing.
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
ULONG numberChannels = deviceExtension->NumberChannels;
PIDE_REGISTERS_1 baseIoAddress1;
PIDE_REGISTERS_2 baseIoAddress2;
BOOLEAN result = FALSE;
ULONG i,j;
UCHAR statusByte;
DebugPrint((2,"AtapiResetController: Reset IDE\n"));
//
// Check and see if we are processing an internal srb
//
if (deviceExtension->OriginalSrb) {
deviceExtension->CurrentSrb = deviceExtension->OriginalSrb;
deviceExtension->OriginalSrb = NULL;
}
//
// Check if request is in progress.
//
if (deviceExtension->CurrentSrb) {
//
// Complete outstanding request with SRB_STATUS_BUS_RESET.
//
ScsiPortCompleteRequest(deviceExtension,
deviceExtension->CurrentSrb->PathId,
deviceExtension->CurrentSrb->TargetId,
deviceExtension->CurrentSrb->Lun,
(ULONG)SRB_STATUS_BUS_RESET);
//
// Clear request tracking fields.
//
deviceExtension->CurrentSrb = NULL;
deviceExtension->WordsLeft = 0;
deviceExtension->DataBuffer = NULL;
//
// Indicate ready for next request.
//
ScsiPortNotification(NextRequest,
deviceExtension,
NULL);
}
//
// Clear expecting interrupt flag.
//
deviceExtension->ExpectingInterrupt = FALSE;
deviceExtension->RDP = FALSE;
for (j = 0; j < numberChannels; j++) {
baseIoAddress1 = deviceExtension->BaseIoAddress1[j];
baseIoAddress2 = deviceExtension->BaseIoAddress2[j];
//
// Do special processing for ATAPI and IDE disk devices.
//
for (i = 0; i < 2; i++) {
//
// Check if device present.
//
if (deviceExtension->DeviceFlags[i + (j * 2)] & DFLAGS_DEVICE_PRESENT) {
//
// Check for ATAPI disk.
//
if (deviceExtension->DeviceFlags[i + (j * 2)] & DFLAGS_ATAPI_DEVICE) {
//
// Issue soft reset and issue identify.
//
GetStatus(baseIoAddress2,statusByte);
DebugPrint((1,
"AtapiResetController: Status before Atapi reset (%x).\n",
statusByte));
AtapiSoftReset(baseIoAddress1,i);
GetStatus(baseIoAddress2,statusByte);
if (statusByte == 0x0) {
IssueIdentify(HwDeviceExtension,
i,
j,
IDE_COMMAND_ATAPI_IDENTIFY);
} else {
DebugPrint((1,
"AtapiResetController: Status after soft reset %x\n",
statusByte));
}
} else {
//
// Write IDE reset controller bits.
//
IdeHardReset(baseIoAddress2,result);
if (!result) {
return FALSE;
}
//
// Set disk geometry parameters.
//
if (!SetDriveParameters(HwDeviceExtension,
i,
j)) {
DebugPrint((1,
"AtapiResetController: SetDriveParameters failed\n"));
}
}
}
}
}
//
// Call the HwInitialize routine to setup multi-block.
//
AtapiHwInitialize(HwDeviceExtension);
return TRUE;
} // end AtapiResetController()
ULONG
NTAPI
MapError(
IN PVOID HwDeviceExtension,
IN PSCSI_REQUEST_BLOCK Srb
)
/*++
Routine Description:
This routine maps ATAPI and IDE errors to specific SRB statuses.
Arguments:
HwDeviceExtension - HBA miniport driver's adapter data storage
Srb - IO request packet
Return Value:
SRB status
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PIDE_REGISTERS_1 baseIoAddress1 = deviceExtension->BaseIoAddress1[Srb->TargetId >> 1];
//PIDE_REGISTERS_2 baseIoAddress2 = deviceExtension->BaseIoAddress2[Srb->TargetId >> 1];
ULONG i;
UCHAR errorByte;
UCHAR srbStatus = SRB_STATUS_ERROR;
UCHAR scsiStatus;
//
// Read the error register.
//
errorByte = ScsiPortReadPortUchar((PUCHAR)baseIoAddress1 + 1);
DebugPrint((1,
"MapError: Error register is %x\n",
errorByte));
if (deviceExtension->DeviceFlags[Srb->TargetId] & DFLAGS_ATAPI_DEVICE) {
switch (errorByte >> 4) {
case SCSI_SENSE_NO_SENSE:
DebugPrint((1,
"ATAPI: No sense information\n"));
scsiStatus = SCSISTAT_CHECK_CONDITION;
srbStatus = SRB_STATUS_ERROR;
break;
case SCSI_SENSE_RECOVERED_ERROR:
DebugPrint((1,
"ATAPI: Recovered error\n"));
scsiStatus = 0;
srbStatus = SRB_STATUS_SUCCESS;
break;
case SCSI_SENSE_NOT_READY:
DebugPrint((1,
"ATAPI: Device not ready\n"));
scsiStatus = SCSISTAT_CHECK_CONDITION;
srbStatus = SRB_STATUS_ERROR;
break;
case SCSI_SENSE_MEDIUM_ERROR:
DebugPrint((1,
"ATAPI: Media error\n"));
scsiStatus = SCSISTAT_CHECK_CONDITION;
srbStatus = SRB_STATUS_ERROR;
break;
case SCSI_SENSE_HARDWARE_ERROR:
DebugPrint((1,
"ATAPI: Hardware error\n"));
scsiStatus = SCSISTAT_CHECK_CONDITION;
srbStatus = SRB_STATUS_ERROR;
break;
case SCSI_SENSE_ILLEGAL_REQUEST:
DebugPrint((1,
"ATAPI: Illegal request\n"));
scsiStatus = SCSISTAT_CHECK_CONDITION;
srbStatus = SRB_STATUS_ERROR;
break;
case SCSI_SENSE_UNIT_ATTENTION:
DebugPrint((1,
"ATAPI: Unit attention\n"));
scsiStatus = SCSISTAT_CHECK_CONDITION;
srbStatus = SRB_STATUS_ERROR;
break;
case SCSI_SENSE_DATA_PROTECT:
DebugPrint((1,
"ATAPI: Data protect\n"));
scsiStatus = SCSISTAT_CHECK_CONDITION;
srbStatus = SRB_STATUS_ERROR;
break;
case SCSI_SENSE_BLANK_CHECK:
DebugPrint((1,
"ATAPI: Blank check\n"));
scsiStatus = SCSISTAT_CHECK_CONDITION;
srbStatus = SRB_STATUS_ERROR;
break;
case SCSI_SENSE_ABORTED_COMMAND:
DebugPrint((1,
"Atapi: Command Aborted\n"));
scsiStatus = SCSISTAT_CHECK_CONDITION;
srbStatus = SRB_STATUS_ERROR;
break;
default:
DebugPrint((1,
"ATAPI: Invalid sense information\n"));
scsiStatus = 0;
srbStatus = SRB_STATUS_ERROR;
break;
}
} else {
scsiStatus = 0;
//
// Save errorByte,to be used by SCSIOP_REQUEST_SENSE.
//
deviceExtension->ReturningMediaStatus = errorByte;
if (errorByte & IDE_ERROR_MEDIA_CHANGE_REQ) {
DebugPrint((1,
"IDE: Media change\n"));
scsiStatus = SCSISTAT_CHECK_CONDITION;
srbStatus = SRB_STATUS_ERROR;
} else if (errorByte & IDE_ERROR_COMMAND_ABORTED) {
DebugPrint((1,
"IDE: Command abort\n"));
srbStatus = SRB_STATUS_ABORTED;
scsiStatus = SCSISTAT_CHECK_CONDITION;
if (Srb->SenseInfoBuffer) {
PSENSE_DATA senseBuffer = (PSENSE_DATA)Srb->SenseInfoBuffer;
senseBuffer->ErrorCode = 0x70;
senseBuffer->Valid = 1;
senseBuffer->AdditionalSenseLength = 0xb;
senseBuffer->SenseKey = SCSI_SENSE_ABORTED_COMMAND;
senseBuffer->AdditionalSenseCode = 0;
senseBuffer->AdditionalSenseCodeQualifier = 0;
srbStatus |= SRB_STATUS_AUTOSENSE_VALID;
}
deviceExtension->ErrorCount++;
} else if (errorByte & IDE_ERROR_END_OF_MEDIA) {
DebugPrint((1,
"IDE: End of media\n"));
scsiStatus = SCSISTAT_CHECK_CONDITION;
srbStatus = SRB_STATUS_ERROR;
if (!(deviceExtension->DeviceFlags[Srb->TargetId] & DFLAGS_MEDIA_STATUS_ENABLED)){
deviceExtension->ErrorCount++;
}
} else if (errorByte & IDE_ERROR_ILLEGAL_LENGTH) {
DebugPrint((1,
"IDE: Illegal length\n"));
srbStatus = SRB_STATUS_INVALID_REQUEST;
} else if (errorByte & IDE_ERROR_BAD_BLOCK) {
DebugPrint((1,
"IDE: Bad block\n"));
srbStatus = SRB_STATUS_ERROR;
scsiStatus = SCSISTAT_CHECK_CONDITION;
if (Srb->SenseInfoBuffer) {
PSENSE_DATA senseBuffer = (PSENSE_DATA)Srb->SenseInfoBuffer;
senseBuffer->ErrorCode = 0x70;
senseBuffer->Valid = 1;
senseBuffer->AdditionalSenseLength = 0xb;
senseBuffer->SenseKey = SCSI_SENSE_MEDIUM_ERROR;
senseBuffer->AdditionalSenseCode = 0;
senseBuffer->AdditionalSenseCodeQualifier = 0;
srbStatus |= SRB_STATUS_AUTOSENSE_VALID;
}
} else if (errorByte & IDE_ERROR_ID_NOT_FOUND) {
DebugPrint((1,
"IDE: Id not found\n"));
srbStatus = SRB_STATUS_ERROR;
scsiStatus = SCSISTAT_CHECK_CONDITION;
if (Srb->SenseInfoBuffer) {
PSENSE_DATA senseBuffer = (PSENSE_DATA)Srb->SenseInfoBuffer;
senseBuffer->ErrorCode = 0x70;
senseBuffer->Valid = 1;
senseBuffer->AdditionalSenseLength = 0xb;
senseBuffer->SenseKey = SCSI_SENSE_MEDIUM_ERROR;
senseBuffer->AdditionalSenseCode = 0;
senseBuffer->AdditionalSenseCodeQualifier = 0;
srbStatus |= SRB_STATUS_AUTOSENSE_VALID;
}
deviceExtension->ErrorCount++;
} else if (errorByte & IDE_ERROR_MEDIA_CHANGE) {
DebugPrint((1,
"IDE: Media change\n"));
scsiStatus = SCSISTAT_CHECK_CONDITION;
srbStatus = SRB_STATUS_ERROR;
if (Srb->SenseInfoBuffer) {
PSENSE_DATA senseBuffer = (PSENSE_DATA)Srb->SenseInfoBuffer;
senseBuffer->ErrorCode = 0x70;
senseBuffer->Valid = 1;
senseBuffer->AdditionalSenseLength = 0xb;
senseBuffer->SenseKey = SCSI_SENSE_UNIT_ATTENTION;
senseBuffer->AdditionalSenseCode = SCSI_ADSENSE_MEDIUM_CHANGED;
senseBuffer->AdditionalSenseCodeQualifier = 0;
srbStatus |= SRB_STATUS_AUTOSENSE_VALID;
}
} else if (errorByte & IDE_ERROR_DATA_ERROR) {
DebugPrint((1,
"IDE: Data error\n"));
scsiStatus = SCSISTAT_CHECK_CONDITION;
srbStatus = SRB_STATUS_ERROR;
if (!(deviceExtension->DeviceFlags[Srb->TargetId] & DFLAGS_MEDIA_STATUS_ENABLED)){
deviceExtension->ErrorCount++;
}
//
// Build sense buffer
//
if (Srb->SenseInfoBuffer) {
PSENSE_DATA senseBuffer = (PSENSE_DATA)Srb->SenseInfoBuffer;
senseBuffer->ErrorCode = 0x70;
senseBuffer->Valid = 1;
senseBuffer->AdditionalSenseLength = 0xb;
senseBuffer->SenseKey = SCSI_SENSE_MEDIUM_ERROR;
senseBuffer->AdditionalSenseCode = 0;
senseBuffer->AdditionalSenseCodeQualifier = 0;
srbStatus |= SRB_STATUS_AUTOSENSE_VALID;
}
}
if (deviceExtension->ErrorCount >= MAX_ERRORS) {
deviceExtension->DWordIO = FALSE;
deviceExtension->MaximumBlockXfer[Srb->TargetId] = 0;
DebugPrint((1,
"MapError: Disabling 32-bit PIO and Multi-sector IOs\n"));
//
// Log the error.
//
ScsiPortLogError( HwDeviceExtension,
Srb,
Srb->PathId,
Srb->TargetId,
Srb->Lun,
SP_BAD_FW_WARNING,
4);
//
// Reprogram to not use Multi-sector.
//
for (i = 0; i < 4; i++) {
UCHAR statusByte;
if (deviceExtension->DeviceFlags[i] & DFLAGS_DEVICE_PRESENT &&
!(deviceExtension->DeviceFlags[i] & DFLAGS_ATAPI_DEVICE)) {
//
// Select the device.
//
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,
(UCHAR)(((i & 0x1) << 4) | 0xA0));
//
// Setup sector count to reflect the # of blocks.
//
ScsiPortWritePortUchar(&baseIoAddress1->BlockCount,
0);
//
// Issue the command.
//
ScsiPortWritePortUchar(&baseIoAddress1->Command,
IDE_COMMAND_SET_MULTIPLE);
//
// Wait for busy to drop.
//
WaitOnBaseBusy(baseIoAddress1,statusByte);
//
// Check for errors. Reset the value to 0 (disable MultiBlock) if the
// command was aborted.
//
if (statusByte & IDE_STATUS_ERROR) {
//
// Read the error register.
//
errorByte = ScsiPortReadPortUchar((PUCHAR)baseIoAddress1 + 1);
DebugPrint((1,
"AtapiHwInitialize: Error setting multiple mode. Status %x, error byte %x\n",
statusByte,
errorByte));
//
// Adjust the devExt. value, if necessary.
//
deviceExtension->MaximumBlockXfer[i] = 0;
}
}
}
}
}
//
// Set SCSI status to indicate a check condition.
//
Srb->ScsiStatus = scsiStatus;
return srbStatus;
} // end MapError()
BOOLEAN
NTAPI
AtapiHwInitialize(
IN PVOID HwDeviceExtension
)
/*++
Routine Description:
Arguments:
HwDeviceExtension - HBA miniport driver's adapter data storage
Return Value:
TRUE - if initialization successful.
FALSE - if initialization unsuccessful.
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PIDE_REGISTERS_1 baseIoAddress;
ULONG i;
UCHAR statusByte, errorByte;
for (i = 0; i < 4; i++) {
if (deviceExtension->DeviceFlags[i] & DFLAGS_DEVICE_PRESENT) {
if (!(deviceExtension->DeviceFlags[i] & DFLAGS_ATAPI_DEVICE)) {
//
// Enable media status notification
//
baseIoAddress = deviceExtension->BaseIoAddress1[i >> 1];
IdeMediaStatus(TRUE,HwDeviceExtension,i);
//
// If supported, setup Multi-block transfers.
//
if (deviceExtension->MaximumBlockXfer[i]) {
//
// Select the device.
//
ScsiPortWritePortUchar(&baseIoAddress->DriveSelect,
(UCHAR)(((i & 0x1) << 4) | 0xA0));
//
// Setup sector count to reflect the # of blocks.
//
ScsiPortWritePortUchar(&baseIoAddress->BlockCount,
deviceExtension->MaximumBlockXfer[i]);
//
// Issue the command.
//
ScsiPortWritePortUchar(&baseIoAddress->Command,
IDE_COMMAND_SET_MULTIPLE);
//
// Wait for busy to drop.
//
WaitOnBaseBusy(baseIoAddress,statusByte);
//
// Check for errors. Reset the value to 0 (disable MultiBlock) if the
// command was aborted.
//
if (statusByte & IDE_STATUS_ERROR) {
//
// Read the error register.
//
errorByte = ScsiPortReadPortUchar((PUCHAR)baseIoAddress + 1);
DebugPrint((1,
"AtapiHwInitialize: Error setting multiple mode. Status %x, error byte %x\n",
statusByte,
errorByte));
//
// Adjust the devExt. value, if necessary.
//
deviceExtension->MaximumBlockXfer[i] = 0;
} else {
DebugPrint((2,
"AtapiHwInitialize: Using Multiblock on Device %d. Blocks / int - %d\n",
i,
deviceExtension->MaximumBlockXfer[i]));
}
}
} else if (!(deviceExtension->DeviceFlags[i] & DFLAGS_CHANGER_INITED)){
ULONG j;
UCHAR vendorId[26];
//
// Attempt to identify any special-case devices - psuedo-atapi changers, atapi changers, etc.
//
for (j = 0; j < 13; j += 2) {
//
// Build a buffer based on the identify data.
//
vendorId[j] = ((PUCHAR)deviceExtension->IdentifyData[i].ModelNumber)[j + 1];
vendorId[j+1] = ((PUCHAR)deviceExtension->IdentifyData[i].ModelNumber)[j];
}
if (!AtapiStringCmp ((PCHAR)vendorId, "CD-ROM CDR", 11)) {
//
// Inquiry string for older model had a '-', newer is '_'
//
if (vendorId[12] == 'C') {
//
// Torisan changer. Set the bit. This will be used in several places
// acting like 1) a multi-lun device and 2) building the 'special' TUR's.
//
deviceExtension->DeviceFlags[i] |= (DFLAGS_CHANGER_INITED | DFLAGS_SANYO_ATAPI_CHANGER);
deviceExtension->DiscsPresent[i] = 3;
}
}
}
//
// We need to get our device ready for action before
// returning from this function
//
// According to the atapi spec 2.5 or 2.6, an atapi device
// clears its status BSY bit when it is ready for atapi commands.
// However, some devices (Panasonic SQ-TC500N) are still
// not ready even when the status BSY is clear. They don't react
// to atapi commands.
//
// Since there is really no other indication that tells us
// the drive is really ready for action. We are going to check BSY
// is clear and then just wait for an arbitrary amount of time!
//
if (deviceExtension->DeviceFlags[i] & DFLAGS_ATAPI_DEVICE) {
//PIDE_REGISTERS_1 baseIoAddress1 = deviceExtension->BaseIoAddress1[i >> 1];
PIDE_REGISTERS_2 baseIoAddress2 = deviceExtension->BaseIoAddress2[i >> 1];
ULONG waitCount;
// have to get out of the loop sometime!
// 10000 * 100us = 1000,000us = 1000ms = 1s
waitCount = 10000;
GetStatus(baseIoAddress2, statusByte);
while ((statusByte & IDE_STATUS_BUSY) && waitCount) {
//
// Wait for Busy to drop.
//
ScsiPortStallExecution(100);
GetStatus(baseIoAddress2, statusByte);
waitCount--;
}
// 5000 * 100us = 500,000us = 500ms = 0.5s
waitCount = 5000;
do {
ScsiPortStallExecution(100);
} while (waitCount--);
}
}
}
return TRUE;
} // end AtapiHwInitialize()
VOID
NTAPI
AtapiHwInitializeChanger (
IN PVOID HwDeviceExtension,
IN ULONG TargetId,
IN PMECHANICAL_STATUS_INFORMATION_HEADER MechanismStatus)
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
if (MechanismStatus) {
deviceExtension->DiscsPresent[TargetId] = MechanismStatus->NumberAvailableSlots;
if (deviceExtension->DiscsPresent[TargetId] > 1) {
deviceExtension->DeviceFlags[TargetId] |= DFLAGS_ATAPI_CHANGER;
}
}
return;
}
BOOLEAN
NTAPI
FindDevices(
IN PVOID HwDeviceExtension,
IN BOOLEAN AtapiOnly,
IN ULONG Channel
)
/*++
Routine Description:
This routine is called from AtapiFindController to identify
devices attached to an IDE controller.
Arguments:
HwDeviceExtension - HBA miniport driver's adapter data storage
AtapiOnly - Indicates that routine should return TRUE only if
an ATAPI device is attached to the controller.
Return Value:
TRUE - True if devices found.
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PIDE_REGISTERS_1 baseIoAddress1 = deviceExtension->BaseIoAddress1[Channel];
PIDE_REGISTERS_2 baseIoAddress2 = deviceExtension->BaseIoAddress2[Channel];
BOOLEAN deviceResponded = FALSE,
skipSetParameters = FALSE;
ULONG waitCount = 10000;
ULONG deviceNumber;
ULONG i;
UCHAR signatureLow,
signatureHigh;
UCHAR statusByte;
//
// Clear expecting interrupt flag and current SRB field.
//
deviceExtension->ExpectingInterrupt = FALSE;
deviceExtension->CurrentSrb = NULL;
//
// Search for devices.
//
for (deviceNumber = 0; deviceNumber < 2; deviceNumber++) {
//
// Select the device.
//
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,
(UCHAR)((deviceNumber << 4) | 0xA0));
//
// Check here for some SCSI adapters that incorporate IDE emulation.
//
GetStatus(baseIoAddress2, statusByte);
if (statusByte == 0xFF) {
continue;
}
AtapiSoftReset(baseIoAddress1,deviceNumber);
WaitOnBusy(baseIoAddress2,statusByte);
signatureLow = ScsiPortReadPortUchar(&baseIoAddress1->CylinderLow);
signatureHigh = ScsiPortReadPortUchar(&baseIoAddress1->CylinderHigh);
if (signatureLow == 0x14 && signatureHigh == 0xEB) {
//
// ATAPI signature found.
// Issue the ATAPI identify command if this
// is not for the crash dump utility.
//
atapiIssueId:
if (!deviceExtension->DriverMustPoll) {
//
// Issue ATAPI packet identify command.
//
if (IssueIdentify(HwDeviceExtension,
deviceNumber,
Channel,
IDE_COMMAND_ATAPI_IDENTIFY)) {
//
// Indicate ATAPI device.
//
DebugPrint((1,
"FindDevices: Device %x is ATAPI\n",
deviceNumber));
deviceExtension->DeviceFlags[deviceNumber + (Channel * 2)] |= DFLAGS_ATAPI_DEVICE;
deviceExtension->DeviceFlags[deviceNumber + (Channel * 2)] |= DFLAGS_DEVICE_PRESENT;
deviceResponded = TRUE;
GetStatus(baseIoAddress2, statusByte);
if (statusByte & IDE_STATUS_ERROR) {
AtapiSoftReset(baseIoAddress1, deviceNumber);
}
} else {
//
// Indicate no working device.
//
DebugPrint((1,
"FindDevices: Device %x not responding\n",
deviceNumber));
deviceExtension->DeviceFlags[deviceNumber + (Channel * 2)] &= ~DFLAGS_DEVICE_PRESENT;
}
}
} else {
//
// Issue IDE Identify. If an Atapi device is actually present, the signature
// will be asserted, and the drive will be recognized as such.
//
if (IssueIdentify(HwDeviceExtension,
deviceNumber,
Channel,
IDE_COMMAND_IDENTIFY)) {
//
// IDE drive found.
//
DebugPrint((1,
"FindDevices: Device %x is IDE\n",
deviceNumber));
deviceExtension->DeviceFlags[deviceNumber + (Channel * 2)] |= DFLAGS_DEVICE_PRESENT;
if (!AtapiOnly) {
deviceResponded = TRUE;
}
//
// Indicate IDE - not ATAPI device.
//
deviceExtension->DeviceFlags[deviceNumber + (Channel * 2)] &= ~DFLAGS_ATAPI_DEVICE;
} else {
//
// Look to see if an Atapi device is present.
//
AtapiSoftReset(baseIoAddress1,deviceNumber);
WaitOnBusy(baseIoAddress2,statusByte);
signatureLow = ScsiPortReadPortUchar(&baseIoAddress1->CylinderLow);
signatureHigh = ScsiPortReadPortUchar(&baseIoAddress1->CylinderHigh);
if (signatureLow == 0x14 && signatureHigh == 0xEB) {
goto atapiIssueId;
}
}
}
}
for (i = 0; i < 2; i++) {
if ((deviceExtension->DeviceFlags[i + (Channel * 2)] & DFLAGS_DEVICE_PRESENT) &&
(!(deviceExtension->DeviceFlags[i + (Channel * 2)] & DFLAGS_ATAPI_DEVICE)) && deviceResponded) {
//
// This hideous hack is to deal with ESDI devices that return
// garbage geometry in the IDENTIFY data.
// This is ONLY for the crashdump environment as
// these are ESDI devices.
//
if (deviceExtension->IdentifyData[i].SectorsPerTrack ==
0x35 &&
deviceExtension->IdentifyData[i].NumberOfHeads ==
0x07) {
DebugPrint((1,
"FindDevices: Found nasty Compaq ESDI!\n"));
//
// Change these values to something reasonable.
//
deviceExtension->IdentifyData[i].SectorsPerTrack =
0x34;
deviceExtension->IdentifyData[i].NumberOfHeads =
0x0E;
}
if (deviceExtension->IdentifyData[i].SectorsPerTrack ==
0x35 &&
deviceExtension->IdentifyData[i].NumberOfHeads ==
0x0F) {
DebugPrint((1,
"FindDevices: Found nasty Compaq ESDI!\n"));
//
// Change these values to something reasonable.
//
deviceExtension->IdentifyData[i].SectorsPerTrack =
0x34;
deviceExtension->IdentifyData[i].NumberOfHeads =
0x0F;
}
if (deviceExtension->IdentifyData[i].SectorsPerTrack ==
0x36 &&
deviceExtension->IdentifyData[i].NumberOfHeads ==
0x07) {
DebugPrint((1,
"FindDevices: Found nasty UltraStor ESDI!\n"));
//
// Change these values to something reasonable.
//
deviceExtension->IdentifyData[i].SectorsPerTrack =
0x3F;
deviceExtension->IdentifyData[i].NumberOfHeads =
0x10;
skipSetParameters = TRUE;
}
if (!skipSetParameters) {
WaitOnBusy(baseIoAddress2,statusByte);
//
// Select the device.
//
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,
(UCHAR)((i << 4) | 0xA0));
GetStatus(baseIoAddress2, statusByte);
if (statusByte & IDE_STATUS_ERROR) {
//
// Reset the device.
//
DebugPrint((2,
"FindDevices: Resetting controller before SetDriveParameters.\n"));
ScsiPortWritePortUchar(&baseIoAddress2->AlternateStatus,IDE_DC_RESET_CONTROLLER );
ScsiPortStallExecution(500 * 1000);
ScsiPortWritePortUchar(&baseIoAddress2->AlternateStatus,IDE_DC_REENABLE_CONTROLLER);
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,
(UCHAR)((i << 4) | 0xA0));
do {
//
// Wait for Busy to drop.
//
ScsiPortStallExecution(100);
GetStatus(baseIoAddress2, statusByte);
} while ((statusByte & IDE_STATUS_BUSY) && waitCount--);
}
WaitOnBusy(baseIoAddress2,statusByte);
DebugPrint((2,
"FindDevices: Status before SetDriveParameters: (%x) (%x)\n",
statusByte,
ScsiPortReadPortUchar(&baseIoAddress1->DriveSelect)));
//
// Use the IDENTIFY data to set drive parameters.
//
if (!SetDriveParameters(HwDeviceExtension,i,Channel)) {
DebugPrint((0,
"AtapHwInitialize: Set drive parameters for device %d failed\n",
i));
//
// Don't use this device as writes could cause corruption.
//
deviceExtension->DeviceFlags[i + Channel] = 0;
continue;
}
if (deviceExtension->DeviceFlags[deviceNumber + (Channel * 2)] & DFLAGS_REMOVABLE_DRIVE) {
//
// Pick up ALL IDE removable drives that conform to Yosemite V0.2...
//
AtapiOnly = FALSE;
}
//
// Indicate that a device was found.
//
if (!AtapiOnly) {
deviceResponded = TRUE;
}
}
}
}
//
// Make sure master device is selected on exit.
//
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect, 0xA0);
//
// Reset the controller. This is a feeble attempt to leave the ESDI
// controllers in a state that ATDISK driver will recognize them.
// The problem in ATDISK has to do with timings as it is not reproducible
// in debug. The reset should restore the controller to its poweron state
// and give the system enough time to settle.
//
if (!deviceResponded) {
ScsiPortWritePortUchar(&baseIoAddress2->AlternateStatus,IDE_DC_RESET_CONTROLLER );
ScsiPortStallExecution(50 * 1000);
ScsiPortWritePortUchar(&baseIoAddress2->AlternateStatus,IDE_DC_REENABLE_CONTROLLER);
}
return deviceResponded;
} // end FindDevices()
ULONG
NTAPI
AtapiParseArgumentString(
IN PCHAR String,
IN PCHAR KeyWord
)
/*++
Routine Description:
This routine will parse the string for a match on the keyword, then
calculate the value for the keyword and return it to the caller.
Arguments:
String - The ASCII string to parse.
KeyWord - The keyword for the value desired.
Return Values:
Zero if value not found
Value converted from ASCII to binary.
--*/
{
PCHAR cptr;
PCHAR kptr;
ULONG value;
ULONG stringLength = 0;
ULONG keyWordLength = 0;
ULONG index;
if (!String) {
return 0;
}
if (!KeyWord) {
return 0;
}
//
// Calculate the string length and lower case all characters.
//
cptr = String;
while (*cptr) {
if (*cptr >= 'A' && *cptr <= 'Z') {
*cptr = *cptr + ('a' - 'A');
}
cptr++;
stringLength++;
}
//
// Calculate the keyword length and lower case all characters.
//
cptr = KeyWord;
while (*cptr) {
if (*cptr >= 'A' && *cptr <= 'Z') {
*cptr = *cptr + ('a' - 'A');
}
cptr++;
keyWordLength++;
}
if (keyWordLength > stringLength) {
//
// Can't possibly have a match.
//
return 0;
}
//
// Now setup and start the compare.
//
cptr = String;
ContinueSearch:
//
// The input string may start with white space. Skip it.
//
while (*cptr == ' ' || *cptr == '\t') {
cptr++;
}
if (*cptr == '\0') {
//
// end of string.
//
return 0;
}
kptr = KeyWord;
while (*cptr++ == *kptr++) {
if (*(cptr - 1) == '\0') {
//
// end of string
//
return 0;
}
}
if (*(kptr - 1) == '\0') {
//
// May have a match backup and check for blank or equals.
//
cptr--;
while (*cptr == ' ' || *cptr == '\t') {
cptr++;
}
//
// Found a match. Make sure there is an equals.
//
if (*cptr != '=') {
//
// Not a match so move to the next semicolon.
//
while (*cptr) {
if (*cptr++ == ';') {
goto ContinueSearch;
}
}
return 0;
}
//
// Skip the equals sign.
//
cptr++;
//
// Skip white space.
//
while ((*cptr == ' ') || (*cptr == '\t')) {
cptr++;
}
if (*cptr == '\0') {
//
// Early end of string, return not found
//
return 0;
}
if (*cptr == ';') {
//
// This isn't it either.
//
cptr++;
goto ContinueSearch;
}
value = 0;
if ((*cptr == '0') && (*(cptr + 1) == 'x')) {
//
// Value is in Hex. Skip the "0x"
//
cptr += 2;
for (index = 0; *(cptr + index); index++) {
if (*(cptr + index) == ' ' ||
*(cptr + index) == '\t' ||
*(cptr + index) == ';') {
break;
}
if ((*(cptr + index) >= '0') && (*(cptr + index) <= '9')) {
value = (16 * value) + (*(cptr + index) - '0');
} else {
if ((*(cptr + index) >= 'a') && (*(cptr + index) <= 'f')) {
value = (16 * value) + (*(cptr + index) - 'a' + 10);
} else {
//
// Syntax error, return not found.
//
return 0;
}
}
}
} else {
//
// Value is in Decimal.
//
for (index = 0; *(cptr + index); index++) {
if (*(cptr + index) == ' ' ||
*(cptr + index) == '\t' ||
*(cptr + index) == ';') {
break;
}
if ((*(cptr + index) >= '0') && (*(cptr + index) <= '9')) {
value = (10 * value) + (*(cptr + index) - '0');
} else {
//
// Syntax error return not found.
//
return 0;
}
}
}
return value;
} else {
//
// Not a match check for ';' to continue search.
//
while (*cptr) {
if (*cptr++ == ';') {
goto ContinueSearch;
}
}
return 0;
}
}
ULONG
NTAPI
AtapiFindController(
IN PVOID HwDeviceExtension,
IN PVOID Context,
IN PVOID BusInformation,
IN PCHAR ArgumentString,
IN OUT PPORT_CONFIGURATION_INFORMATION ConfigInfo,
OUT PBOOLEAN Again
)
/*++
Routine Description:
This function is called by the OS-specific port driver after
the necessary storage has been allocated, to gather information
about the adapter's configuration.
Arguments:
HwDeviceExtension - HBA miniport driver's adapter data storage
Context - Address of adapter count
ArgumentString - Used to determine whether driver is client of ntldr or crash dump utility.
ConfigInfo - Configuration information structure describing HBA
Again - Indicates search for adapters to continue
Return Value:
ULONG
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PULONG adapterCount = (PULONG)Context;
PUCHAR ioSpace = NULL;
ULONG i;
ULONG irq;
ULONG portBase;
ULONG retryCount;
PCI_SLOT_NUMBER slotData;
PPCI_COMMON_CONFIG pciData;
ULONG pciBuffer;
BOOLEAN atapiOnly;
UCHAR statusByte;
BOOLEAN preConfig = FALSE;
//
// The following table specifies the ports to be checked when searching for
// an IDE controller. A zero entry terminates the search.
//
CONST ULONG AdapterAddresses[5] = {0x1F0, 0x170, 0x1e8, 0x168, 0};
//
// The following table specifies interrupt levels corresponding to the
// port addresses in the previous table.
//
CONST ULONG InterruptLevels[5] = {14, 15, 11, 10, 0};
if (!deviceExtension) {
return SP_RETURN_ERROR;
}
//
// Check to see if this is a special configuration environment.
//
portBase = irq = 0;
if (ArgumentString) {
irq = AtapiParseArgumentString(ArgumentString, "Interrupt");
if (irq ) {
//
// Both parameters must be present to proceed
//
portBase = AtapiParseArgumentString(ArgumentString, "BaseAddress");
if (!portBase) {
//
// Try a default search for the part.
//
irq = 0;
}
}
}
//
// Scan though the adapter address looking for adapters.
//
if (ScsiPortConvertPhysicalAddressToUlong((*ConfigInfo->AccessRanges)[0].RangeStart) != 0) {
ioSpace = ScsiPortGetDeviceBase(HwDeviceExtension,
ConfigInfo->AdapterInterfaceType,
ConfigInfo->SystemIoBusNumber,
(*ConfigInfo->AccessRanges)[0].RangeStart,
(*ConfigInfo->AccessRanges)[0].RangeLength,
(BOOLEAN) !((*ConfigInfo->AccessRanges)[0].RangeInMemory));
*Again = FALSE;
//
// Since we have pre-configured information we only need to go through this loop once
//
preConfig = TRUE;
portBase = ScsiPortConvertPhysicalAddressToUlong((*ConfigInfo->AccessRanges)[0].RangeStart);
}
while (AdapterAddresses[*adapterCount] != 0) {
retryCount = 4;
for (i = 0; i < 4; i++) {
//
// Zero device fields to ensure that if earlier devices were found,
// but not claimed, the fields are cleared.
//
deviceExtension->DeviceFlags[i] &= ~(DFLAGS_ATAPI_DEVICE | DFLAGS_DEVICE_PRESENT | DFLAGS_TAPE_DEVICE);
}
//
// Get the system physical address for this IO range.
//
//
// Check if configInfo has the default information
// if not, we go and find ourselves
//
if (preConfig == FALSE) {
if (portBase) {
ioSpace = ScsiPortGetDeviceBase(HwDeviceExtension,
ConfigInfo->AdapterInterfaceType,
ConfigInfo->SystemIoBusNumber,
ScsiPortConvertUlongToPhysicalAddress(portBase),
8,
TRUE);
} else {
ioSpace = ScsiPortGetDeviceBase(HwDeviceExtension,
ConfigInfo->AdapterInterfaceType,
ConfigInfo->SystemIoBusNumber,
ScsiPortConvertUlongToPhysicalAddress(AdapterAddresses[*adapterCount]),
8,
TRUE);
}
}// ConfigInfo check
//
// Update the adapter count.
//
(*adapterCount)++;
//
// Check if ioSpace accessible.
//
if (!ioSpace) {
continue;
}
retryIdentifier:
//
// Select master.
//
ScsiPortWritePortUchar(&((PIDE_REGISTERS_1)ioSpace)->DriveSelect, 0xA0);
//
// Check if card at this address.
//
ScsiPortWritePortUchar(&((PIDE_REGISTERS_1)ioSpace)->CylinderLow, 0xAA);
//
// Check if identifier can be read back.
//
if ((statusByte = ScsiPortReadPortUchar(&((PIDE_REGISTERS_1)ioSpace)->CylinderLow)) != 0xAA) {
DebugPrint((2,
"AtapiFindController: Identifier read back from Master (%x)\n",
statusByte));
statusByte = ScsiPortReadPortUchar(&((PATAPI_REGISTERS_2)ioSpace)->AlternateStatus);
if (statusByte & IDE_STATUS_BUSY) {
i = 0;
//
// Could be the TEAC in a thinkpad. Their dos driver puts it in a sleep-mode that
// warm boots don't clear.
//
do {
ScsiPortStallExecution(1000);
statusByte = ScsiPortReadPortUchar(&((PATAPI_REGISTERS_1)ioSpace)->Command);
DebugPrint((3,
"AtapiFindController: First access to status %x\n",
statusByte));
} while ((statusByte & IDE_STATUS_BUSY) && ++i < 10);
if (retryCount-- && (!(statusByte & IDE_STATUS_BUSY))) {
goto retryIdentifier;
}
}
//
// Select slave.
//
ScsiPortWritePortUchar(&((PIDE_REGISTERS_1)ioSpace)->DriveSelect, 0xB0);
//
// See if slave is present.
//
ScsiPortWritePortUchar(&((PIDE_REGISTERS_1)ioSpace)->CylinderLow, 0xAA);
if ((statusByte = ScsiPortReadPortUchar(&((PIDE_REGISTERS_1)ioSpace)->CylinderLow)) != 0xAA) {
DebugPrint((2,
"AtapiFindController: Identifier read back from Slave (%x)\n",
statusByte));
//
//
// No controller at this base address.
//
ScsiPortFreeDeviceBase(HwDeviceExtension,
ioSpace);
continue;
}
}
//
// Record base IO address.
//
deviceExtension->BaseIoAddress1[0] = (PIDE_REGISTERS_1)(ioSpace);
//
// Fill in the access array information only if default params are not in there.
//
if (preConfig == FALSE) {
//
// An adapter has been found request another call, only if we didn't get preconfigured info.
//
*Again = TRUE;
if (portBase) {
(*ConfigInfo->AccessRanges)[0].RangeStart = ScsiPortConvertUlongToPhysicalAddress(portBase);
} else {
(*ConfigInfo->AccessRanges)[0].RangeStart =
ScsiPortConvertUlongToPhysicalAddress(AdapterAddresses[*adapterCount - 1]);
}
(*ConfigInfo->AccessRanges)[0].RangeLength = 8;
(*ConfigInfo->AccessRanges)[0].RangeInMemory = FALSE;
//
// Indicate the interrupt level corresponding to this IO range.
//
if (irq) {
ConfigInfo->BusInterruptLevel = irq;
} else {
ConfigInfo->BusInterruptLevel = InterruptLevels[*adapterCount - 1];
}
if (ConfigInfo->AdapterInterfaceType == MicroChannel) {
ConfigInfo->InterruptMode = LevelSensitive;
} else {
ConfigInfo->InterruptMode = Latched;
}
}
//
// Get the system physical address for the second IO range.
//
if (portBase) {
ioSpace = ScsiPortGetDeviceBase(HwDeviceExtension,
ConfigInfo->AdapterInterfaceType,
ConfigInfo->SystemIoBusNumber,
ScsiPortConvertUlongToPhysicalAddress(portBase + 0x206),
1,
TRUE);
} else {
ioSpace = ScsiPortGetDeviceBase(HwDeviceExtension,
ConfigInfo->AdapterInterfaceType,
ConfigInfo->SystemIoBusNumber,
ScsiPortConvertUlongToPhysicalAddress(AdapterAddresses[*adapterCount - 1] + 0x206),
1,
TRUE);
}
deviceExtension->BaseIoAddress2[0] = (PIDE_REGISTERS_2)(ioSpace);
deviceExtension->NumberChannels = 1;
ConfigInfo->NumberOfBuses = 1;
ConfigInfo->MaximumNumberOfTargets = 2;
//
// Indicate maximum transfer length is 64k.
//
ConfigInfo->MaximumTransferLength = 0x10000;
DebugPrint((1,
"AtapiFindController: Found IDE at %x\n",
deviceExtension->BaseIoAddress1[0]));
//
// For Daytona, the atdisk driver gets the first shot at the
// primary and secondary controllers.
//
if (preConfig == FALSE) {
if (*adapterCount - 1 < 2) {
//
// Determine whether this driver is being initialized by the
// system or as a crash dump driver.
//
if (ArgumentString) {
if (AtapiParseArgumentString(ArgumentString, "dump") == 1) {
DebugPrint((3,
"AtapiFindController: Crash dump\n"));
atapiOnly = FALSE;
deviceExtension->DriverMustPoll = TRUE;
} else {
DebugPrint((3,
"AtapiFindController: Atapi Only\n"));
atapiOnly = TRUE;
deviceExtension->DriverMustPoll = FALSE;
}
} else {
DebugPrint((3,
"AtapiFindController: Atapi Only\n"));
atapiOnly = TRUE;
deviceExtension->DriverMustPoll = FALSE;
}
} else {
atapiOnly = FALSE;
}
//
// If this is a PCI machine, pick up all devices.
//
pciData = (PPCI_COMMON_CONFIG)&pciBuffer;
slotData.u.bits.DeviceNumber = 0;
slotData.u.bits.FunctionNumber = 0;
if (ScsiPortGetBusData(deviceExtension,
PCIConfiguration,
0, // BusNumber
slotData.u.AsULONG,
pciData,
sizeof(ULONG))) {
atapiOnly = FALSE;
//
// Wait on doing this, until a reliable method
// of determining support is found.
//
#if 0
deviceExtension->DWordIO = TRUE;
#endif
} else {
deviceExtension->DWordIO = FALSE;
}
} else {
atapiOnly = FALSE;
deviceExtension->DriverMustPoll = FALSE;
}// preConfig check
//
// Save the Interrupt Mode for later use
//
deviceExtension->InterruptMode = ConfigInfo->InterruptMode;
//
// Search for devices on this controller.
//
if (FindDevices(HwDeviceExtension,
atapiOnly,
0)) {
//
// Claim primary or secondary ATA IO range.
//
if (portBase) {
switch (portBase) {
case 0x170:
ConfigInfo->AtdiskSecondaryClaimed = TRUE;
deviceExtension->PrimaryAddress = FALSE;
break;
case 0x1f0:
ConfigInfo->AtdiskPrimaryClaimed = TRUE;
deviceExtension->PrimaryAddress = TRUE;
break;
default:
break;
}
} else {
if (*adapterCount == 1) {
ConfigInfo->AtdiskPrimaryClaimed = TRUE;
deviceExtension->PrimaryAddress = TRUE;
} else if (*adapterCount == 2) {
ConfigInfo->AtdiskSecondaryClaimed = TRUE;
deviceExtension->PrimaryAddress = FALSE;
}
}
return(SP_RETURN_FOUND);
}
}
//
// The entire table has been searched and no adapters have been found.
// There is no need to call again and the device base can now be freed.
// Clear the adapter count for the next bus.
//
*Again = FALSE;
*(adapterCount) = 0;
return(SP_RETURN_NOT_FOUND);
} // end AtapiFindController()
BOOLEAN
NTAPI
FindBrokenController(
IN PVOID DeviceExtension,
IN PUCHAR VendorID,
IN ULONG VendorIDLength,
IN PUCHAR DeviceID,
IN ULONG DeviceIDLength,
IN OUT PULONG FunctionNumber,
IN OUT PULONG SlotNumber,
IN ULONG BusNumber,
OUT PBOOLEAN LastSlot
)
/*++
Routine Description:
Walk PCI slot information looking for Vendor and Product ID matches.
Arguments:
Return Value:
TRUE if card found.
--*/
{
ULONG pciBuffer;
ULONG slotNumber;
ULONG functionNumber;
PCI_SLOT_NUMBER slotData;
PPCI_COMMON_CONFIG pciData;
UCHAR vendorString[5];
UCHAR deviceString[5];
PUCHAR vendorStrPtr;
PUCHAR deviceStrPtr;
pciData = (PPCI_COMMON_CONFIG)&pciBuffer;
slotData.u.AsULONG = 0;
//
// Look at each device.
//
for (slotNumber = *SlotNumber;
slotNumber < 32;
slotNumber++) {
slotData.u.bits.DeviceNumber = slotNumber;
//
// Look at each function.
//
for (functionNumber= *FunctionNumber;
functionNumber < 8;
functionNumber++) {
slotData.u.bits.FunctionNumber = functionNumber;
if (!ScsiPortGetBusData(DeviceExtension,
PCIConfiguration,
BusNumber,
slotData.u.AsULONG,
pciData,
sizeof(ULONG))) {
//
// Out of PCI data.
//
*LastSlot = TRUE;
return FALSE;
}
if (pciData->VendorID == PCI_INVALID_VENDORID) {
//
// No PCI device, or no more functions on device
// move to next PCI device.
//
break;
}
//
// Translate hex ids to strings.
//
vendorStrPtr = vendorString;
deviceStrPtr = deviceString;
AtapiHexToString(pciData->VendorID, (PCHAR*)&vendorStrPtr);
AtapiHexToString(pciData->DeviceID, (PCHAR*)&deviceStrPtr);
DebugPrint((2,
"FindBrokenController: Bus %x Slot %x Function %x Vendor %s Product %s\n",
BusNumber,
slotNumber,
functionNumber,
vendorString,
deviceString));
//
// Compare strings.
//
if (AtapiStringCmp((PCHAR)vendorString,
(PCHAR)VendorID,
VendorIDLength) ||
AtapiStringCmp((PCHAR)deviceString,
(PCHAR)DeviceID,
DeviceIDLength)) {
//
// Not our PCI device. Try next device/function
//
continue;
}
*FunctionNumber = functionNumber;
*SlotNumber = slotNumber;
return TRUE;
} // next PCI function
*FunctionNumber = 0;
} // next PCI slot
*LastSlot = TRUE;
return FALSE;
} // end FindBrokenController
ULONG
NTAPI
AtapiFindNativeModeController(
IN PVOID HwDeviceExtension,
IN PVOID Context,
IN PVOID BusInformation,
IN PCHAR ArgumentString,
IN OUT PPORT_CONFIGURATION_INFORMATION ConfigInfo,
OUT PBOOLEAN Again
)
/*++
Routine Description:
This function is called by the OS-specific port driver after
the necessary storage has been allocated, to gather information
about the adapter's configuration.
Arguments:
HwDeviceExtension - HBA miniport driver's adapter data storage
Context - Address of adapter count
BusInformation -
ArgumentString - Used to determine whether driver is client of ntldr or crash dump utility.
ConfigInfo - Configuration information structure describing HBA
Again - Indicates search for adapters to continue
Return Value:
ULONG
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
ULONG nativeModeAdapterTableIndex = (ULONG_PTR)Context;
ULONG channel;
PUCHAR ioSpace;
BOOLEAN atapiOnly,
deviceFound = FALSE;
UCHAR statusByte;
PCI_SLOT_NUMBER slotData;
PCI_COMMON_CONFIG pciData;
ULONG funcNumber;
ULONG busDataRead;
UCHAR vendorString[5];
UCHAR deviceString[5];
PUCHAR vendorStrPtr;
PUCHAR deviceStrPtr;
SCSI_PHYSICAL_ADDRESS IoBasePort1;
SCSI_PHYSICAL_ADDRESS IoBasePort2;
//
// The following table specifies the ports to be checked when searching for
// an IDE controller. A zero entry terminates the search.
//
CONST ULONG AdapterAddresses[3] = {0x1F0, 0x170, 0};
if (!deviceExtension) {
return SP_RETURN_ERROR;
}
*Again = FALSE;
slotData.u.AsULONG = 0;
slotData.u.bits.DeviceNumber = ConfigInfo->SlotNumber;
for (funcNumber= 0; funcNumber < 8; funcNumber++) {
slotData.u.bits.FunctionNumber = funcNumber;
busDataRead = ScsiPortGetBusData(HwDeviceExtension,
PCIConfiguration,
ConfigInfo->SystemIoBusNumber,
slotData.u.AsULONG,
&pciData,
sizeof (pciData));
if (busDataRead != sizeof (pciData)) {
return SP_RETURN_ERROR;
}
if (pciData.VendorID == PCI_INVALID_VENDORID) {
return SP_RETURN_ERROR;
}
//
// Translate hex ids to strings.
//
vendorStrPtr = vendorString;
deviceStrPtr = deviceString;
AtapiHexToString(pciData.VendorID, (PCHAR*)&vendorStrPtr);
AtapiHexToString(pciData.DeviceID, (PCHAR*)&deviceStrPtr);
//
// Compare strings.
//
if (AtapiStringCmp((PCHAR)vendorString,
NativeModeAdapters[nativeModeAdapterTableIndex].VendorId,
NativeModeAdapters[nativeModeAdapterTableIndex].VendorIdLength) ||
AtapiStringCmp((PCHAR)deviceString,
NativeModeAdapters[nativeModeAdapterTableIndex].DeviceId,
NativeModeAdapters[nativeModeAdapterTableIndex].DeviceIdLength)) {
continue;
}
if (pciData.ProgIf & ((1 << 2) | (1 << 0))) {
// both primary and secondary channel are in native mode
// Found our device
*Again = TRUE;
break;
}
}
if (*Again != FALSE) {
for (channel = 0; channel < 2; channel++) {
IoBasePort1 = (*ConfigInfo->AccessRanges)[channel * 2 + 0].RangeStart;
IoBasePort2 = (*ConfigInfo->AccessRanges)[channel * 2 + 1].RangeStart;
IoBasePort2 = ScsiPortConvertUlongToPhysicalAddress(ScsiPortConvertPhysicalAddressToUlong(IoBasePort2) + 2);
//
// Get the system physical address for this IO range.
//
ioSpace = ScsiPortGetDeviceBase(HwDeviceExtension,
ConfigInfo->AdapterInterfaceType,
ConfigInfo->SystemIoBusNumber,
IoBasePort1,
8,
TRUE);
//
// Check if ioSpace accessible.
//
if (!ioSpace) {
continue;
}
//
// Select master.
//
ScsiPortWritePortUchar(&((PIDE_REGISTERS_1)ioSpace)->DriveSelect, 0xA0);
//
// Check if card at this address.
//
ScsiPortWritePortUchar(&((PIDE_REGISTERS_1)ioSpace)->CylinderLow, 0xAA);
//
// Check if identifier can be read back.
//
if ((statusByte = ScsiPortReadPortUchar(&((PIDE_REGISTERS_1)ioSpace)->CylinderLow)) != 0xAA) {
DebugPrint((2,
"AtapiFindPciController: Identifier read back from Master (%x)\n",
statusByte));
//
// Select slave.
//
ScsiPortWritePortUchar(&((PIDE_REGISTERS_1)ioSpace)->DriveSelect, 0xB0);
//
// See if slave is present.
//
ScsiPortWritePortUchar(&((PIDE_REGISTERS_1)ioSpace)->CylinderLow, 0xAA);
if ((statusByte = ScsiPortReadPortUchar(&((PIDE_REGISTERS_1)ioSpace)->CylinderLow)) != 0xAA) {
DebugPrint((2,
"AtapiFindPciController: Identifier read back from Slave (%x)\n",
statusByte));
//
//
// No controller at this base address.
//
ScsiPortFreeDeviceBase(HwDeviceExtension,
ioSpace);
//
// If the chip is there, but we couldn't find the primary channel, try the secondary.
// If we couldn't find a secondary, who cares.
//
if (channel == 1) {
goto setStatusAndExit;
} else {
continue;
}
}
}
//
// Record base IO address.
//
deviceExtension->BaseIoAddress1[channel] = (PIDE_REGISTERS_1)(ioSpace);
//
// Get the system physical address for the second IO range.
//
ioSpace = ScsiPortGetDeviceBase(HwDeviceExtension,
ConfigInfo->AdapterInterfaceType,
ConfigInfo->SystemIoBusNumber,
IoBasePort2,
1,
TRUE);
deviceExtension->BaseIoAddress2[channel] = (PIDE_REGISTERS_2)(ioSpace);
deviceExtension->NumberChannels = 2;
//
// Indicate only one bus.
//
ConfigInfo->NumberOfBuses = 1;
//
// Indicate four devices can be attached to the adapter, since we
// have to serialize access to the two channels.
//
ConfigInfo->MaximumNumberOfTargets = 4;
//
// Indicate maximum transfer length is 64k.
//
ConfigInfo->MaximumTransferLength = 0x10000;
DebugPrint((1,
"AtapiFindPciController: Found native mode IDE at %x\n",
deviceExtension->BaseIoAddress1[channel]));
//
// Since we will always pick up this part, and not atdisk, so indicate.
//
atapiOnly = FALSE;
//
// Save the Interrupt Mode for later use
//
deviceExtension->InterruptMode = ConfigInfo->InterruptMode;
//
// Search for devices on this controller.
//
if (FindDevices(HwDeviceExtension,
atapiOnly,
channel)){
deviceFound = TRUE;
}
//
// Claim primary or secondary ATA IO range.
//
if (ScsiPortConvertPhysicalAddressToUlong(IoBasePort1) == AdapterAddresses[0]) {
ConfigInfo->AtdiskPrimaryClaimed = TRUE;
deviceExtension->PrimaryAddress = TRUE;
} else if (ScsiPortConvertPhysicalAddressToUlong(IoBasePort2) == AdapterAddresses[1]) {
ConfigInfo->AtdiskSecondaryClaimed = TRUE;
deviceExtension->PrimaryAddress = FALSE;
}
}
}
setStatusAndExit:
if (deviceFound) {
*Again = TRUE;
return SP_RETURN_FOUND;
}
*Again = FALSE;
return SP_RETURN_NOT_FOUND;
} // end AtapiFindNativeModeController()
ULONG
NTAPI
AtapiFindPCIController(
IN PVOID HwDeviceExtension,
IN PVOID Context,
IN PVOID BusInformation,
IN PCHAR ArgumentString,
IN OUT PPORT_CONFIGURATION_INFORMATION ConfigInfo,
OUT PBOOLEAN Again
)
/*++
Routine Description:
This function is called by the OS-specific port driver after
the necessary storage has been allocated, to gather information
about the adapter's configuration.
Arguments:
HwDeviceExtension - HBA miniport driver's adapter data storage
Context - Address of adapter count
BusInformation -
ArgumentString - Used to determine whether driver is client of ntldr or crash dump utility.
ConfigInfo - Configuration information structure describing HBA
Again - Indicates search for adapters to continue
Return Value:
ULONG
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PULONG adapterCount = (PULONG)Context;
ULONG channel = 0;
static ULONG functionNumber,
slotNumber,
controllers;
ULONG i,j;
PUCHAR ioSpace;
BOOLEAN atapiOnly,
lastSlot,
controllerFound = FALSE,
deviceFound = FALSE;
UCHAR statusByte;
//
// The following table specifies the ports to be checked when searching for
// an IDE controller. A zero entry terminates the search.
//
CONST ULONG AdapterAddresses[5] = {0x1F0, 0x170, 0x1e8, 0x168, 0};
//
// The following table specifies interrupt levels corresponding to the
// port addresses in the previous table.
//
CONST ULONG InterruptLevels[5] = {14, 15, 11, 10, 0};
if (!deviceExtension) {
return SP_RETURN_ERROR;
}
//
// Since scsiport will call this function first before it calls AtapiFindController
// we need to bypass it if we have data installed in ConfigInfo, by the pcmcia driver.
// In that case atapifindcontroller should be called first.
// Instead of modifying atapi driverEntry to search of PCIBus first (now its ISA)
// the check is put here.
//
if (ScsiPortConvertPhysicalAddressToUlong((*ConfigInfo->AccessRanges)[0].RangeStart) != 0) {
return AtapiFindController(HwDeviceExtension,
Context,
BusInformation,
ArgumentString,
ConfigInfo,
Again);
}
//
// Gronk PCI config space looking for the broken PCI IDE controllers that have only
// one FIFO for both channels.
// Don't do this. It's incorrect and nasty. It has to be done to work around these
// broken parts, no other reason can justify this.
//
for (i = controllers; i < BROKEN_ADAPTERS; i++) {
//
// Determine if both channels are enabled and have devices.
//
lastSlot = FALSE;
if (FindBrokenController(deviceExtension,
(PUCHAR)BrokenAdapters[i].VendorId,
BrokenAdapters[i].VendorIdLength,
(PUCHAR)BrokenAdapters[i].DeviceId,
BrokenAdapters[i].DeviceIdLength,
&functionNumber,
&slotNumber,
ConfigInfo->SystemIoBusNumber,
&lastSlot)) {
slotNumber++;
functionNumber = 0;
controllerFound = TRUE;
DebugPrint((1,
"Found broken PCI IDE controller: VendorId %s, DeviceId %s\n",
BrokenAdapters[i].VendorId,
BrokenAdapters[i].DeviceId));
if (AdapterAddresses[*adapterCount] != 0) {
for (j = 0; j < 2; j++) {
//
// Get the system physical address for this IO range.
//
ioSpace = ScsiPortGetDeviceBase(HwDeviceExtension,
ConfigInfo->AdapterInterfaceType,
ConfigInfo->SystemIoBusNumber,
ScsiPortConvertUlongToPhysicalAddress(AdapterAddresses[*adapterCount]),
8,
TRUE);
//
// Update the adapter count.
//
(*adapterCount)++;
//
// Check if ioSpace accessible.
//
if (!ioSpace) {
continue;
}
//
// Select master.
//
ScsiPortWritePortUchar(&((PIDE_REGISTERS_1)ioSpace)->DriveSelect, 0xA0);
//
// Check if card at this address.
//
ScsiPortWritePortUchar(&((PIDE_REGISTERS_1)ioSpace)->CylinderLow, 0xAA);
//
// Check if identifier can be read back.
//
if ((statusByte = ScsiPortReadPortUchar(&((PIDE_REGISTERS_1)ioSpace)->CylinderLow)) != 0xAA) {
DebugPrint((2,
"AtapiFindPciController: Identifier read back from Master (%x)\n",
statusByte));
//
// Select slave.
//
ScsiPortWritePortUchar(&((PIDE_REGISTERS_1)ioSpace)->DriveSelect, 0xB0);
//
// See if slave is present.
//
ScsiPortWritePortUchar(&((PIDE_REGISTERS_1)ioSpace)->CylinderLow, 0xAA);
if ((statusByte = ScsiPortReadPortUchar(&((PIDE_REGISTERS_1)ioSpace)->CylinderLow)) != 0xAA) {
DebugPrint((2,
"AtapiFindPciController: Identifier read back from Slave (%x)\n",
statusByte));
//
//
// No controller at this base address.
//
ScsiPortFreeDeviceBase(HwDeviceExtension,
ioSpace);
//
// If the chip is there, but we couldn't find the primary channel, try the secondary.
// If we couldn't find a secondary, who cares.
//
if (j == 1) {
goto setStatusAndExit;
} else {
continue;
}
}
}
if (controllerFound) {
//
// Record base IO address.
//
deviceExtension->BaseIoAddress1[channel] = (PIDE_REGISTERS_1)(ioSpace);
//
// Fill in the access array information.
//
(*ConfigInfo->AccessRanges)[channel].RangeStart =
ScsiPortConvertUlongToPhysicalAddress(AdapterAddresses[*adapterCount - 1]);
(*ConfigInfo->AccessRanges)[channel].RangeLength = 8;
(*ConfigInfo->AccessRanges)[channel].RangeInMemory = FALSE;
//
// Indicate the interrupt level corresponding to this IO range.
//
if (channel == 0) {
ConfigInfo->BusInterruptLevel = InterruptLevels[*adapterCount - 1];
ConfigInfo->InterruptMode = Latched;
} else {
ConfigInfo->BusInterruptLevel2 = InterruptLevels[*adapterCount - 1];
ConfigInfo->InterruptMode2 = Latched;
}
//
// Get the system physical address for the second IO range.
//
ioSpace = ScsiPortGetDeviceBase(HwDeviceExtension,
ConfigInfo->AdapterInterfaceType,
ConfigInfo->SystemIoBusNumber,
ScsiPortConvertUlongToPhysicalAddress(AdapterAddresses[*adapterCount - 1] + 0x206),
1,
TRUE);
deviceExtension->BaseIoAddress2[channel] = (PIDE_REGISTERS_2)(ioSpace);
deviceExtension->NumberChannels = 2;
//
// Indicate only one bus.
//
ConfigInfo->NumberOfBuses = 1;
//
// Indicate four devices can be attached to the adapter, since we
// have to serialize access to the two channels.
//
ConfigInfo->MaximumNumberOfTargets = 4;
//
// Indicate maximum transfer length is 64k.
//
ConfigInfo->MaximumTransferLength = 0x10000;
DebugPrint((1,
"AtapiFindPciController: Found broken IDE at %x\n",
deviceExtension->BaseIoAddress1[channel]));
//
// Since we will always pick up this part, and not atdisk, so indicate.
//
atapiOnly = FALSE;
//
// Save the Interrupt Mode for later use
//
deviceExtension->InterruptMode = ConfigInfo->InterruptMode;
//
// Search for devices on this controller.
//
if (FindDevices(HwDeviceExtension,
atapiOnly,
channel++)){
deviceFound = TRUE;
}
//
// Claim primary or secondary ATA IO range.
//
if (*adapterCount == 1) {
ConfigInfo->AtdiskPrimaryClaimed = TRUE;
deviceExtension->PrimaryAddress = TRUE;
} else if (*adapterCount == 2) {
ConfigInfo->AtdiskSecondaryClaimed = TRUE;
deviceExtension->PrimaryAddress = FALSE;
}
}
}
}
}
setStatusAndExit:
if (lastSlot) {
slotNumber = 0;
functionNumber = 0;
}
controllers = i;
if (controllerFound && deviceFound) {
*Again = TRUE;
return SP_RETURN_FOUND;
}
}
//
// The entire table has been searched and no adapters have been found.
//
*Again = FALSE;
return SP_RETURN_NOT_FOUND;
} // end AtapiFindPCIController()
ULONG
NTAPI
Atapi2Scsi(
IN PSCSI_REQUEST_BLOCK Srb,
IN char *DataBuffer,
IN ULONG ByteCount
)
{
ULONG bytesAdjust = 0;
if (Srb->Cdb[0] == ATAPI_MODE_SENSE) {
PMODE_PARAMETER_HEADER_10 header_10 = (PMODE_PARAMETER_HEADER_10)DataBuffer;
PMODE_PARAMETER_HEADER header = (PMODE_PARAMETER_HEADER)DataBuffer;
header->ModeDataLength = header_10->ModeDataLengthLsb;
header->MediumType = header_10->MediumType;
//
// ATAPI Mode Parameter Header doesn't have these fields.
//
header->DeviceSpecificParameter = header_10->Reserved[0];
header->BlockDescriptorLength = header_10->Reserved[1];
ByteCount -= sizeof(MODE_PARAMETER_HEADER_10);
if (ByteCount > 0)
ScsiPortMoveMemory(DataBuffer+sizeof(MODE_PARAMETER_HEADER),
DataBuffer+sizeof(MODE_PARAMETER_HEADER_10),
ByteCount);
//
// Change ATAPI_MODE_SENSE opcode back to SCSIOP_MODE_SENSE
// so that we don't convert again.
//
Srb->Cdb[0] = SCSIOP_MODE_SENSE;
bytesAdjust = sizeof(MODE_PARAMETER_HEADER_10) -
sizeof(MODE_PARAMETER_HEADER);
}
//
// Convert to words.
//
return bytesAdjust >> 1;
}
VOID
NTAPI
AtapiCallBack(
IN PVOID HwDeviceExtension
)
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PSCSI_REQUEST_BLOCK srb = deviceExtension->CurrentSrb;
PATAPI_REGISTERS_2 baseIoAddress2;
UCHAR statusByte;
//
// If the last command was DSC restrictive, see if it's set. If so, the device is
// ready for a new request. Otherwise, reset the timer and come back to here later.
//
if (srb && (!(deviceExtension->ExpectingInterrupt))) {
#if DBG
if (!IS_RDP((srb->Cdb[0]))) {
DebugPrint((1,
"AtapiCallBack: Invalid CDB marked as RDP - %x\n",
srb->Cdb[0]));
}
#endif
baseIoAddress2 = (PATAPI_REGISTERS_2)deviceExtension->BaseIoAddress2[srb->TargetId >> 1];
if (deviceExtension->RDP) {
GetStatus(baseIoAddress2, statusByte);
if (statusByte & IDE_STATUS_DSC) {
ScsiPortNotification(RequestComplete,
deviceExtension,
srb);
//
// Clear current SRB.
//
deviceExtension->CurrentSrb = NULL;
deviceExtension->RDP = FALSE;
//
// Ask for next request.
//
ScsiPortNotification(NextRequest,
deviceExtension,
NULL);
return;
} else {
DebugPrint((3,
"AtapiCallBack: Requesting another timer for Op %x\n",
deviceExtension->CurrentSrb->Cdb[0]));
ScsiPortNotification(RequestTimerCall,
HwDeviceExtension,
AtapiCallBack,
1000);
return;
}
}
}
DebugPrint((2,
"AtapiCallBack: Calling ISR directly due to BUSY\n"));
AtapiInterrupt(HwDeviceExtension);
}
BOOLEAN
NTAPI
AtapiInterrupt(
IN PVOID HwDeviceExtension
)
/*++
Routine Description:
This is the interrupt service routine for ATAPI IDE miniport driver.
Arguments:
HwDeviceExtension - HBA miniport driver's adapter data storage
Return Value:
TRUE if expecting an interrupt.
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PSCSI_REQUEST_BLOCK srb = deviceExtension->CurrentSrb;
PATAPI_REGISTERS_1 baseIoAddress1;
PATAPI_REGISTERS_2 baseIoAddress2;
ULONG wordCount = 0, wordsThisInterrupt = 256;
ULONG status;
ULONG i;
UCHAR statusByte,interruptReason;
BOOLEAN atapiDev = FALSE;
if (srb) {
baseIoAddress1 = (PATAPI_REGISTERS_1)deviceExtension->BaseIoAddress1[srb->TargetId >> 1];
baseIoAddress2 = (PATAPI_REGISTERS_2)deviceExtension->BaseIoAddress2[srb->TargetId >> 1];
} else {
DebugPrint((2,
"AtapiInterrupt: CurrentSrb is NULL\n"));
//
// We can only support one ATAPI IDE master on Carolina, so find
// the base address that is non NULL and clear its interrupt before
// returning.
//
#ifdef _PPC_
if ((PATAPI_REGISTERS_1)deviceExtension->BaseIoAddress1[0] != NULL) {
baseIoAddress1 = (PATAPI_REGISTERS_1)deviceExtension->BaseIoAddress1[0];
} else {
baseIoAddress1 = (PATAPI_REGISTERS_1)deviceExtension->BaseIoAddress1[1];
}
GetBaseStatus(baseIoAddress1, statusByte);
#else
if (deviceExtension->InterruptMode == LevelSensitive) {
if (deviceExtension->BaseIoAddress1[0] != NULL) {
baseIoAddress1 = (PATAPI_REGISTERS_1)deviceExtension->BaseIoAddress1[0];
GetBaseStatus(baseIoAddress1, statusByte);
}
if (deviceExtension->BaseIoAddress1[1] != NULL) {
baseIoAddress1 = (PATAPI_REGISTERS_1)deviceExtension->BaseIoAddress1[1];
GetBaseStatus(baseIoAddress1, statusByte);
}
}
#endif
return FALSE;
}
if (!(deviceExtension->ExpectingInterrupt)) {
DebugPrint((3,
"AtapiInterrupt: Unexpected interrupt.\n"));
return FALSE;
}
//
// Clear interrupt by reading status.
//
GetBaseStatus(baseIoAddress1, statusByte);
DebugPrint((3,
"AtapiInterrupt: Entered with status (%x)\n",
statusByte));
if (statusByte & IDE_STATUS_BUSY) {
if (deviceExtension->DriverMustPoll) {
//
// Crashdump is polling and we got caught with busy asserted.
// Just go away, and we will be polled again shortly.
//
DebugPrint((3,
"AtapiInterrupt: Hit BUSY while polling during crashdump.\n"));
return TRUE;
}
//
// Ensure BUSY is non-asserted.
//
for (i = 0; i < 10; i++) {
GetBaseStatus(baseIoAddress1, statusByte);
if (!(statusByte & IDE_STATUS_BUSY)) {
break;
}
ScsiPortStallExecution(5000);
}
if (i == 10) {
DebugPrint((2,
"AtapiInterrupt: BUSY on entry. Status %x, Base IO %x\n",
statusByte,
baseIoAddress1));
ScsiPortNotification(RequestTimerCall,
HwDeviceExtension,
AtapiCallBack,
500);
return TRUE;
}
}
//
// Check for error conditions.
//
if (statusByte & IDE_STATUS_ERROR) {
if (srb->Cdb[0] != SCSIOP_REQUEST_SENSE) {
//
// Fail this request.
//
status = SRB_STATUS_ERROR;
goto CompleteRequest;
}
}
//
// check reason for this interrupt.
//
if (deviceExtension->DeviceFlags[srb->TargetId] & DFLAGS_ATAPI_DEVICE) {
interruptReason = (ScsiPortReadPortUchar(&baseIoAddress1->InterruptReason) & 0x3);
atapiDev = TRUE;
wordsThisInterrupt = 256;
} else {
if (statusByte & IDE_STATUS_DRQ) {
if (deviceExtension->MaximumBlockXfer[srb->TargetId]) {
wordsThisInterrupt = 256 * deviceExtension->MaximumBlockXfer[srb->TargetId];
}
if (srb->SrbFlags & SRB_FLAGS_DATA_IN) {
interruptReason = 0x2;
} else if (srb->SrbFlags & SRB_FLAGS_DATA_OUT) {
interruptReason = 0x0;
} else {
status = SRB_STATUS_ERROR;
goto CompleteRequest;
}
} else if (statusByte & IDE_STATUS_BUSY) {
return FALSE;
} else {
if (deviceExtension->WordsLeft) {
ULONG k;
//
// Funky behaviour seen with PCI IDE (not all, just one).
// The ISR hits with DRQ low, but comes up later.
//
for (k = 0; k < 5000; k++) {
GetStatus(baseIoAddress2,statusByte);
if (!(statusByte & IDE_STATUS_DRQ)) {
ScsiPortStallExecution(100);
} else {
break;
}
}
if (k == 5000) {
//
// reset the controller.
//
DebugPrint((1,
"AtapiInterrupt: Resetting due to DRQ not up. Status %x, Base IO %x\n",
statusByte,
baseIoAddress1));
AtapiResetController(HwDeviceExtension,srb->PathId);
return TRUE;
} else {
interruptReason = (srb->SrbFlags & SRB_FLAGS_DATA_IN) ? 0x2 : 0x0;
}
} else {
//
// Command complete - verify, write, or the SMART enable/disable.
//
// Also get_media_status
interruptReason = 0x3;
}
}
}
if (interruptReason == 0x1 && (statusByte & IDE_STATUS_DRQ)) {
//
// Write the packet.
//
DebugPrint((2,
"AtapiInterrupt: Writing Atapi packet.\n"));
//
// Send CDB to device.
//
WriteBuffer(baseIoAddress1,
(PUSHORT)srb->Cdb,
6);
return TRUE;
} else if (interruptReason == 0x0 && (statusByte & IDE_STATUS_DRQ)) {
//
// Write the data.
//
if (deviceExtension->DeviceFlags[srb->TargetId] & DFLAGS_ATAPI_DEVICE) {
//
// Pick up bytes to transfer and convert to words.
//
wordCount =
ScsiPortReadPortUchar(&baseIoAddress1->ByteCountLow);
wordCount |=
ScsiPortReadPortUchar(&baseIoAddress1->ByteCountHigh) << 8;
//
// Covert bytes to words.
//
wordCount >>= 1;
if (wordCount != deviceExtension->WordsLeft) {
DebugPrint((3,
"AtapiInterrupt: %d words requested; %d words xferred\n",
deviceExtension->WordsLeft,
wordCount));
}
//
// Verify this makes sense.
//
if (wordCount > deviceExtension->WordsLeft) {
wordCount = deviceExtension->WordsLeft;
}
} else {
//
// IDE path. Check if words left is at least 256.
//
if (deviceExtension->WordsLeft < wordsThisInterrupt) {
//
// Transfer only words requested.
//
wordCount = deviceExtension->WordsLeft;
} else {
//
// Transfer next block.
//
wordCount = wordsThisInterrupt;
}
}
//
// Ensure that this is a write command.
//
if (srb->SrbFlags & SRB_FLAGS_DATA_OUT) {
DebugPrint((3,
"AtapiInterrupt: Write interrupt\n"));
WaitOnBusy(baseIoAddress2,statusByte);
if (atapiDev || !deviceExtension->DWordIO) {
WriteBuffer(baseIoAddress1,
deviceExtension->DataBuffer,
wordCount);
} else {
PIDE_REGISTERS_3 address3 = (PIDE_REGISTERS_3)baseIoAddress1;
WriteBuffer2(address3,
(PULONG)(deviceExtension->DataBuffer),
wordCount / 2);
}
} else {
DebugPrint((1,
"AtapiInterrupt: Int reason %x, but srb is for a write %x.\n",
interruptReason,
srb));
//
// Fail this request.
//
status = SRB_STATUS_ERROR;
goto CompleteRequest;
}
//
// Advance data buffer pointer and bytes left.
//
deviceExtension->DataBuffer += wordCount;
deviceExtension->WordsLeft -= wordCount;
return TRUE;
} else if (interruptReason == 0x2 && (statusByte & IDE_STATUS_DRQ)) {
if (deviceExtension->DeviceFlags[srb->TargetId] & DFLAGS_ATAPI_DEVICE) {
//
// Pick up bytes to transfer and convert to words.
//
wordCount =
ScsiPortReadPortUchar(&baseIoAddress1->ByteCountLow);
wordCount |=
ScsiPortReadPortUchar(&baseIoAddress1->ByteCountHigh) << 8;
//
// Covert bytes to words.
//
wordCount >>= 1;
if (wordCount != deviceExtension->WordsLeft) {
DebugPrint((3,
"AtapiInterrupt: %d words requested; %d words xferred\n",
deviceExtension->WordsLeft,
wordCount));
}
//
// Verify this makes sense.
//
if (wordCount > deviceExtension->WordsLeft) {
wordCount = deviceExtension->WordsLeft;
}
} else {
//
// Check if words left is at least 256.
//
if (deviceExtension->WordsLeft < wordsThisInterrupt) {
//
// Transfer only words requested.
//
wordCount = deviceExtension->WordsLeft;
} else {
//
// Transfer next block.
//
wordCount = wordsThisInterrupt;
}
}
//
// Ensure that this is a read command.
//
if (srb->SrbFlags & SRB_FLAGS_DATA_IN) {
DebugPrint((3,
"AtapiInterrupt: Read interrupt\n"));
WaitOnBusy(baseIoAddress2,statusByte);
if (atapiDev || !deviceExtension->DWordIO) {
ReadBuffer(baseIoAddress1,
deviceExtension->DataBuffer,
wordCount);
} else {
PIDE_REGISTERS_3 address3 = (PIDE_REGISTERS_3)baseIoAddress1;
ReadBuffer2(address3,
(PULONG)(deviceExtension->DataBuffer),
wordCount / 2);
}
} else {
DebugPrint((1,
"AtapiInterrupt: Int reason %x, but srb is for a read %x.\n",
interruptReason,
srb));
//
// Fail this request.
//
status = SRB_STATUS_ERROR;
goto CompleteRequest;
}
//
// Translate ATAPI data back to SCSI data if needed
//
if (srb->Cdb[0] == ATAPI_MODE_SENSE &&
deviceExtension->DeviceFlags[srb->TargetId] & DFLAGS_ATAPI_DEVICE) {
//
//convert and adjust the wordCount
//
wordCount -= Atapi2Scsi(srb, (char *)deviceExtension->DataBuffer,
wordCount << 1);
}
//
// Advance data buffer pointer and bytes left.
//
deviceExtension->DataBuffer += wordCount;
deviceExtension->WordsLeft -= wordCount;
//
// Check for read command complete.
//
if (deviceExtension->WordsLeft == 0) {
if (deviceExtension->DeviceFlags[srb->TargetId] & DFLAGS_ATAPI_DEVICE) {
//
// Work around to make many atapi devices return correct sector size
// of 2048. Also certain devices will have sector count == 0x00, check
// for that also.
//
if ((srb->Cdb[0] == 0x25) &&
((deviceExtension->IdentifyData[srb->TargetId].GeneralConfiguration >> 8) & 0x1f) == 0x05) {
deviceExtension->DataBuffer -= wordCount;
if (deviceExtension->DataBuffer[0] == 0x00) {
*((ULONG *) &(deviceExtension->DataBuffer[0])) = 0xFFFFFF7F;
}
*((ULONG *) &(deviceExtension->DataBuffer[2])) = 0x00080000;
deviceExtension->DataBuffer += wordCount;
}
} else {
//
// Completion for IDE drives.
//
if (deviceExtension->WordsLeft) {
status = SRB_STATUS_DATA_OVERRUN;
} else {
status = SRB_STATUS_SUCCESS;
}
goto CompleteRequest;
}
}
return TRUE;
} else if (interruptReason == 0x3 && !(statusByte & IDE_STATUS_DRQ)) {
//
// Command complete.
//
if (deviceExtension->WordsLeft) {
status = SRB_STATUS_DATA_OVERRUN;
} else {
status = SRB_STATUS_SUCCESS;
}
CompleteRequest:
//
// Check and see if we are processing our secret (mechanism status/request sense) srb
//
if (deviceExtension->OriginalSrb) {
ULONG srbStatus;
if (srb->Cdb[0] == SCSIOP_MECHANISM_STATUS) {
if (status == SRB_STATUS_SUCCESS) {
// Bingo!!
AtapiHwInitializeChanger (HwDeviceExtension,
srb->TargetId,
(PMECHANICAL_STATUS_INFORMATION_HEADER) srb->DataBuffer);
// Get ready to issue the original srb
srb = deviceExtension->CurrentSrb = deviceExtension->OriginalSrb;
deviceExtension->OriginalSrb = NULL;
} else {
// failed! Get the sense key and maybe try again
srb = deviceExtension->CurrentSrb = BuildRequestSenseSrb (
HwDeviceExtension,
deviceExtension->OriginalSrb->PathId,
deviceExtension->OriginalSrb->TargetId);
}
srbStatus = AtapiSendCommand(HwDeviceExtension, deviceExtension->CurrentSrb);
if (srbStatus == SRB_STATUS_PENDING) {
return TRUE;
}
} else { // srb->Cdb[0] == SCSIOP_REQUEST_SENSE)
PSENSE_DATA senseData = (PSENSE_DATA) srb->DataBuffer;
if (status == SRB_STATUS_DATA_OVERRUN) {
// Check to see if we at least get minimum number of bytes
if ((srb->DataTransferLength - deviceExtension->WordsLeft) >
(FIELD_OFFSET (SENSE_DATA, AdditionalSenseLength) + sizeof(senseData->AdditionalSenseLength))) {
status = SRB_STATUS_SUCCESS;
}
}
if (status == SRB_STATUS_SUCCESS) {
if ((senseData->SenseKey != SCSI_SENSE_ILLEGAL_REQUEST) &&
deviceExtension->MechStatusRetryCount) {
// The sense key doesn't say the last request is illegal, so try again
deviceExtension->MechStatusRetryCount--;
srb = deviceExtension->CurrentSrb = BuildMechanismStatusSrb (
HwDeviceExtension,
deviceExtension->OriginalSrb->PathId,
deviceExtension->OriginalSrb->TargetId);
} else {
// last request was illegal. No point trying again
AtapiHwInitializeChanger (HwDeviceExtension,
srb->TargetId,
(PMECHANICAL_STATUS_INFORMATION_HEADER) NULL);
// Get ready to issue the original srb
srb = deviceExtension->CurrentSrb = deviceExtension->OriginalSrb;
deviceExtension->OriginalSrb = NULL;
}
srbStatus = AtapiSendCommand(HwDeviceExtension, deviceExtension->CurrentSrb);
if (srbStatus == SRB_STATUS_PENDING) {
return TRUE;
}
}
}
// If we get here, it means AtapiSendCommand() has failed
// Can't recover. Pretend the original srb has failed and complete it.
if (deviceExtension->OriginalSrb) {
AtapiHwInitializeChanger (HwDeviceExtension,
srb->TargetId,
(PMECHANICAL_STATUS_INFORMATION_HEADER) NULL);
srb = deviceExtension->CurrentSrb = deviceExtension->OriginalSrb;
deviceExtension->OriginalSrb = NULL;
}
// fake an error and read no data
status = SRB_STATUS_ERROR;
srb->ScsiStatus = 0;
deviceExtension->DataBuffer = srb->DataBuffer;
deviceExtension->WordsLeft = srb->DataTransferLength;
deviceExtension->RDP = FALSE;
} else if (status == SRB_STATUS_ERROR) {
//
// Map error to specific SRB status and handle request sense.
//
status = MapError(deviceExtension,
srb);
deviceExtension->RDP = FALSE;
} else {
//
// Wait for busy to drop.
//
for (i = 0; i < 30; i++) {
GetStatus(baseIoAddress2,statusByte);
if (!(statusByte & IDE_STATUS_BUSY)) {
break;
}
ScsiPortStallExecution(500);
}
if (i == 30) {
//
// reset the controller.
//
DebugPrint((1,
"AtapiInterrupt: Resetting due to BSY still up - %x. Base Io %x\n",
statusByte,
baseIoAddress1));
AtapiResetController(HwDeviceExtension,srb->PathId);
return TRUE;
}
//
// Check to see if DRQ is still up.
//
if (statusByte & IDE_STATUS_DRQ) {
for (i = 0; i < 500; i++) {
GetStatus(baseIoAddress2,statusByte);
if (!(statusByte & IDE_STATUS_DRQ)) {
break;
}
ScsiPortStallExecution(100);
}
if (i == 500) {
//
// reset the controller.
//
DebugPrint((1,
"AtapiInterrupt: Resetting due to DRQ still up - %x\n",
statusByte));
AtapiResetController(HwDeviceExtension,srb->PathId);
return TRUE;
}
}
}
//
// Clear interrupt expecting flag.
//
deviceExtension->ExpectingInterrupt = FALSE;
//
// Sanity check that there is a current request.
//
if (srb != NULL) {
//
// Set status in SRB.
//
srb->SrbStatus = (UCHAR)status;
//
// Check for underflow.
//
if (deviceExtension->WordsLeft) {
//
// Subtract out residual words and update if filemark hit,
// setmark hit , end of data, end of media...
//
if (!(deviceExtension->DeviceFlags[srb->TargetId] & DFLAGS_TAPE_DEVICE)) {
if (status == SRB_STATUS_DATA_OVERRUN) {
srb->DataTransferLength -= deviceExtension->WordsLeft;
} else {
srb->DataTransferLength = 0;
}
} else {
srb->DataTransferLength -= deviceExtension->WordsLeft;
}
}
if (srb->Function != SRB_FUNCTION_IO_CONTROL) {
//
// Indicate command complete.
//
if (!(deviceExtension->RDP)) {
ScsiPortNotification(RequestComplete,
deviceExtension,
srb);
}
} else {
PSENDCMDOUTPARAMS cmdOutParameters = (PSENDCMDOUTPARAMS)(((PUCHAR)srb->DataBuffer) + sizeof(SRB_IO_CONTROL));
UCHAR error = 0;
if (status != SRB_STATUS_SUCCESS) {
error = ScsiPortReadPortUchar((PUCHAR)baseIoAddress1 + 1);
}
//
// Build the SMART status block depending upon the completion status.
//
cmdOutParameters->cBufferSize = wordCount;
cmdOutParameters->DriverStatus.bDriverError = (error) ? SMART_IDE_ERROR : 0;
cmdOutParameters->DriverStatus.bIDEError = error;
//
// If the sub-command is return smart status, jam the value from cylinder low and high, into the
// data buffer.
//
if (deviceExtension->SmartCommand == RETURN_SMART_STATUS) {
cmdOutParameters->bBuffer[0] = RETURN_SMART_STATUS;
cmdOutParameters->bBuffer[1] = ScsiPortReadPortUchar(&baseIoAddress1->InterruptReason);
cmdOutParameters->bBuffer[2] = ScsiPortReadPortUchar(&baseIoAddress1->Unused1);
cmdOutParameters->bBuffer[3] = ScsiPortReadPortUchar(&baseIoAddress1->ByteCountLow);
cmdOutParameters->bBuffer[4] = ScsiPortReadPortUchar(&baseIoAddress1->ByteCountHigh);
cmdOutParameters->bBuffer[5] = ScsiPortReadPortUchar(&baseIoAddress1->DriveSelect);
cmdOutParameters->bBuffer[6] = SMART_CMD;
cmdOutParameters->cBufferSize = 8;
}
//
// Indicate command complete.
//
ScsiPortNotification(RequestComplete,
deviceExtension,
srb);
}
} else {
DebugPrint((1,
"AtapiInterrupt: No SRB!\n"));
}
//
// Indicate ready for next request.
//
if (!(deviceExtension->RDP)) {
//
// Clear current SRB.
//
deviceExtension->CurrentSrb = NULL;
ScsiPortNotification(NextRequest,
deviceExtension,
NULL);
} else {
ScsiPortNotification(RequestTimerCall,
HwDeviceExtension,
AtapiCallBack,
2000);
}
return TRUE;
} else {
//
// Unexpected int.
//
DebugPrint((3,
"AtapiInterrupt: Unexpected interrupt. InterruptReason %x. Status %x.\n",
interruptReason,
statusByte));
return FALSE;
}
return TRUE;
} // end AtapiInterrupt()
ULONG
NTAPI
IdeSendSmartCommand(
IN PVOID HwDeviceExtension,
IN PSCSI_REQUEST_BLOCK Srb
)
/*++
Routine Description:
This routine handles SMART enable, disable, read attributes and threshold commands.
Arguments:
HwDeviceExtension - HBA miniport driver's adapter data storage
Srb - IO request packet
Return Value:
SRB status
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PIDE_REGISTERS_1 baseIoAddress1 = deviceExtension->BaseIoAddress1[Srb->TargetId >> 1];
PIDE_REGISTERS_2 baseIoAddress2 = deviceExtension->BaseIoAddress2[Srb->TargetId >> 1];
PSENDCMDOUTPARAMS cmdOutParameters = (PSENDCMDOUTPARAMS)(((PUCHAR)Srb->DataBuffer) + sizeof(SRB_IO_CONTROL));
SENDCMDINPARAMS cmdInParameters = *(PSENDCMDINPARAMS)(((PUCHAR)Srb->DataBuffer) + sizeof(SRB_IO_CONTROL));
PIDEREGS regs = &cmdInParameters.irDriveRegs;
ULONG i;
UCHAR statusByte,targetId;
if (cmdInParameters.irDriveRegs.bCommandReg == SMART_CMD) {
targetId = cmdInParameters.bDriveNumber;
//TODO optimize this check
if ((!(deviceExtension->DeviceFlags[targetId] & DFLAGS_DEVICE_PRESENT)) ||
(deviceExtension->DeviceFlags[targetId] & DFLAGS_ATAPI_DEVICE)) {
return SRB_STATUS_SELECTION_TIMEOUT;
}
deviceExtension->SmartCommand = cmdInParameters.irDriveRegs.bFeaturesReg;
//
// Determine which of the commands to carry out.
//
if ((cmdInParameters.irDriveRegs.bFeaturesReg == READ_ATTRIBUTES) ||
(cmdInParameters.irDriveRegs.bFeaturesReg == READ_THRESHOLDS)) {
WaitOnBusy(baseIoAddress2,statusByte);
if (statusByte & IDE_STATUS_BUSY) {
DebugPrint((1,
"IdeSendSmartCommand: Returning BUSY status\n"));
return SRB_STATUS_BUSY;
}
//
// Zero the output buffer as the input buffer info. has been saved off locally (the buffers are the same).
//
for (i = 0; i < (sizeof(SENDCMDOUTPARAMS) + READ_ATTRIBUTE_BUFFER_SIZE - 1); i++) {
((PUCHAR)cmdOutParameters)[i] = 0;
}
//
// Set data buffer pointer and words left.
//
deviceExtension->DataBuffer = (PUSHORT)cmdOutParameters->bBuffer;
deviceExtension->WordsLeft = READ_ATTRIBUTE_BUFFER_SIZE / 2;
//
// Indicate expecting an interrupt.
//
deviceExtension->ExpectingInterrupt = TRUE;
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,(UCHAR)(((targetId & 0x1) << 4) | 0xA0));
ScsiPortWritePortUchar((PUCHAR)baseIoAddress1 + 1,regs->bFeaturesReg);
ScsiPortWritePortUchar(&baseIoAddress1->BlockCount,regs->bSectorCountReg);
ScsiPortWritePortUchar(&baseIoAddress1->BlockNumber,regs->bSectorNumberReg);
ScsiPortWritePortUchar(&baseIoAddress1->CylinderLow,regs->bCylLowReg);
ScsiPortWritePortUchar(&baseIoAddress1->CylinderHigh,regs->bCylHighReg);
ScsiPortWritePortUchar(&baseIoAddress1->Command,regs->bCommandReg);
//
// Wait for interrupt.
//
return SRB_STATUS_PENDING;
} else if ((cmdInParameters.irDriveRegs.bFeaturesReg == ENABLE_SMART) ||
(cmdInParameters.irDriveRegs.bFeaturesReg == DISABLE_SMART) ||
(cmdInParameters.irDriveRegs.bFeaturesReg == RETURN_SMART_STATUS) ||
(cmdInParameters.irDriveRegs.bFeaturesReg == ENABLE_DISABLE_AUTOSAVE) ||
(cmdInParameters.irDriveRegs.bFeaturesReg == EXECUTE_OFFLINE_DIAGS) ||
(cmdInParameters.irDriveRegs.bFeaturesReg == SAVE_ATTRIBUTE_VALUES)) {
WaitOnBusy(baseIoAddress2,statusByte);
if (statusByte & IDE_STATUS_BUSY) {
DebugPrint((1,
"IdeSendSmartCommand: Returning BUSY status\n"));
return SRB_STATUS_BUSY;
}
//
// Zero the output buffer as the input buffer info. has been saved off locally (the buffers are the same).
//
for (i = 0; i < (sizeof(SENDCMDOUTPARAMS) - 1); i++) {
((PUCHAR)cmdOutParameters)[i] = 0;
}
//
// Set data buffer pointer and indicate no data transfer.
//
deviceExtension->DataBuffer = (PUSHORT)cmdOutParameters->bBuffer;
deviceExtension->WordsLeft = 0;
//
// Indicate expecting an interrupt.
//
deviceExtension->ExpectingInterrupt = TRUE;
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,(UCHAR)(((targetId & 0x1) << 4) | 0xA0));
ScsiPortWritePortUchar((PUCHAR)baseIoAddress1 + 1,regs->bFeaturesReg);
ScsiPortWritePortUchar(&baseIoAddress1->BlockCount,regs->bSectorCountReg);
ScsiPortWritePortUchar(&baseIoAddress1->BlockNumber,regs->bSectorNumberReg);
ScsiPortWritePortUchar(&baseIoAddress1->CylinderLow,regs->bCylLowReg);
ScsiPortWritePortUchar(&baseIoAddress1->CylinderHigh,regs->bCylHighReg);
ScsiPortWritePortUchar(&baseIoAddress1->Command,regs->bCommandReg);
//
// Wait for interrupt.
//
return SRB_STATUS_PENDING;
}
}
return SRB_STATUS_INVALID_REQUEST;
} // end IdeSendSmartCommand()
ULONG
NTAPI
IdeReadWrite(
IN PVOID HwDeviceExtension,
IN PSCSI_REQUEST_BLOCK Srb
)
/*++
Routine Description:
This routine handles IDE read and writes.
Arguments:
HwDeviceExtension - HBA miniport driver's adapter data storage
Srb - IO request packet
Return Value:
SRB status
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PIDE_REGISTERS_1 baseIoAddress1 = deviceExtension->BaseIoAddress1[Srb->TargetId >> 1];
PIDE_REGISTERS_2 baseIoAddress2 = deviceExtension->BaseIoAddress2[Srb->TargetId >> 1];
ULONG startingSector,i;
ULONG wordCount;
UCHAR statusByte,statusByte2;
UCHAR cylinderHigh,cylinderLow,drvSelect,sectorNumber;
//
// Select device 0 or 1.
//
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,
(UCHAR)(((Srb->TargetId & 0x1) << 4) | 0xA0));
WaitOnBusy(baseIoAddress2,statusByte2);
if (statusByte2 & IDE_STATUS_BUSY) {
DebugPrint((1,
"IdeReadWrite: Returning BUSY status\n"));
return SRB_STATUS_BUSY;
}
//
// Set data buffer pointer and words left.
//
deviceExtension->DataBuffer = (PUSHORT)Srb->DataBuffer;
deviceExtension->WordsLeft = Srb->DataTransferLength / 2;
//
// Indicate expecting an interrupt.
//
deviceExtension->ExpectingInterrupt = TRUE;
//
// Set up sector count register. Round up to next block.
//
ScsiPortWritePortUchar(&baseIoAddress1->BlockCount,
(UCHAR)((Srb->DataTransferLength + 0x1FF) / 0x200));
//
// Get starting sector number from CDB.
//
startingSector = ((PCDB)Srb->Cdb)->CDB10.LogicalBlockByte3 |
((PCDB)Srb->Cdb)->CDB10.LogicalBlockByte2 << 8 |
((PCDB)Srb->Cdb)->CDB10.LogicalBlockByte1 << 16 |
((PCDB)Srb->Cdb)->CDB10.LogicalBlockByte0 << 24;
DebugPrint((2,
"IdeReadWrite: Starting sector is %x, Number of bytes %x\n",
startingSector,
Srb->DataTransferLength));
//
// Set up sector number register.
//
sectorNumber = (UCHAR)((startingSector % deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack) + 1);
ScsiPortWritePortUchar(&baseIoAddress1->BlockNumber,sectorNumber);
//
// Set up cylinder low register.
//
cylinderLow = (UCHAR)(startingSector / (deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack *
deviceExtension->IdentifyData[Srb->TargetId].NumberOfHeads));
ScsiPortWritePortUchar(&baseIoAddress1->CylinderLow,cylinderLow);
//
// Set up cylinder high register.
//
cylinderHigh = (UCHAR)((startingSector / (deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack *
deviceExtension->IdentifyData[Srb->TargetId].NumberOfHeads)) >> 8);
ScsiPortWritePortUchar(&baseIoAddress1->CylinderHigh,cylinderHigh);
//
// Set up head and drive select register.
//
drvSelect = (UCHAR)(((startingSector / deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack) %
deviceExtension->IdentifyData[Srb->TargetId].NumberOfHeads) |((Srb->TargetId & 0x1) << 4) | 0xA0);
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,drvSelect);
DebugPrint((2,
"IdeReadWrite: Cylinder %x Head %x Sector %x\n",
startingSector /
(deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack *
deviceExtension->IdentifyData[Srb->TargetId].NumberOfHeads),
(startingSector /
deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack) %
deviceExtension->IdentifyData[Srb->TargetId].NumberOfHeads,
startingSector %
deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack + 1));
//
// Check if write request.
//
if (Srb->SrbFlags & SRB_FLAGS_DATA_IN) {
//
// Send read command.
//
if (deviceExtension->MaximumBlockXfer[Srb->TargetId]) {
ScsiPortWritePortUchar(&baseIoAddress1->Command,
IDE_COMMAND_READ_MULTIPLE);
} else {
ScsiPortWritePortUchar(&baseIoAddress1->Command,
IDE_COMMAND_READ);
}
} else {
//
// Send write command.
//
if (deviceExtension->MaximumBlockXfer[Srb->TargetId]) {
wordCount = 256 * deviceExtension->MaximumBlockXfer[Srb->TargetId];
if (deviceExtension->WordsLeft < wordCount) {
//
// Transfer only words requested.
//
wordCount = deviceExtension->WordsLeft;
}
ScsiPortWritePortUchar(&baseIoAddress1->Command,
IDE_COMMAND_WRITE_MULTIPLE);
} else {
wordCount = 256;
ScsiPortWritePortUchar(&baseIoAddress1->Command,
IDE_COMMAND_WRITE);
}
//
// Wait for BSY and DRQ.
//
WaitOnBaseBusy(baseIoAddress1,statusByte);
if (statusByte & IDE_STATUS_BUSY) {
DebugPrint((1,
"IdeReadWrite 2: Returning BUSY status %x\n",
statusByte));
return SRB_STATUS_BUSY;
}
for (i = 0; i < 1000; i++) {
GetBaseStatus(baseIoAddress1, statusByte);
if (statusByte & IDE_STATUS_DRQ) {
break;
}
ScsiPortStallExecution(200);
}
if (!(statusByte & IDE_STATUS_DRQ)) {
DebugPrint((1,
"IdeReadWrite: DRQ never asserted (%x) original status (%x)\n",
statusByte,
statusByte2));
deviceExtension->WordsLeft = 0;
//
// Clear interrupt expecting flag.
//
deviceExtension->ExpectingInterrupt = FALSE;
//
// Clear current SRB.
//
deviceExtension->CurrentSrb = NULL;
return SRB_STATUS_TIMEOUT;
}
//
// Write next 256 words.
//
WriteBuffer(baseIoAddress1,
deviceExtension->DataBuffer,
wordCount);
//
// Adjust buffer address and words left count.
//
deviceExtension->WordsLeft -= wordCount;
deviceExtension->DataBuffer += wordCount;
}
//
// Wait for interrupt.
//
return SRB_STATUS_PENDING;
} // end IdeReadWrite()
ULONG
NTAPI
IdeVerify(
IN PVOID HwDeviceExtension,
IN PSCSI_REQUEST_BLOCK Srb
)
/*++
Routine Description:
This routine handles IDE Verify.
Arguments:
HwDeviceExtension - HBA miniport driver's adapter data storage
Srb - IO request packet
Return Value:
SRB status
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PIDE_REGISTERS_1 baseIoAddress1 = deviceExtension->BaseIoAddress1[Srb->TargetId >> 1];
//PIDE_REGISTERS_2 baseIoAddress2 = deviceExtension->BaseIoAddress2[Srb->TargetId >> 1];
ULONG startingSector;
ULONG sectors;
ULONG endSector;
USHORT sectorCount;
//
// Drive has these number sectors.
//
sectors = deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack *
deviceExtension->IdentifyData[Srb->TargetId].NumberOfHeads *
deviceExtension->IdentifyData[Srb->TargetId].NumberOfCylinders;
DebugPrint((3,
"IdeVerify: Total sectors %x\n",
sectors));
//
// Get starting sector number from CDB.
//
startingSector = ((PCDB)Srb->Cdb)->CDB10.LogicalBlockByte3 |
((PCDB)Srb->Cdb)->CDB10.LogicalBlockByte2 << 8 |
((PCDB)Srb->Cdb)->CDB10.LogicalBlockByte1 << 16 |
((PCDB)Srb->Cdb)->CDB10.LogicalBlockByte0 << 24;
DebugPrint((3,
"IdeVerify: Starting sector %x. Number of blocks %x\n",
startingSector,
((PCDB)Srb->Cdb)->CDB10.TransferBlocksLsb));
sectorCount = (USHORT)(((PCDB)Srb->Cdb)->CDB10.TransferBlocksMsb << 8 |
((PCDB)Srb->Cdb)->CDB10.TransferBlocksLsb );
endSector = startingSector + sectorCount;
DebugPrint((3,
"IdeVerify: Ending sector %x\n",
endSector));
if (endSector > sectors) {
//
// Too big, round down.
//
DebugPrint((1,
"IdeVerify: Truncating request to %x blocks\n",
sectors - startingSector - 1));
ScsiPortWritePortUchar(&baseIoAddress1->BlockCount,
(UCHAR)(sectors - startingSector - 1));
} else {
//
// Set up sector count register. Round up to next block.
//
if (sectorCount > 0xFF) {
sectorCount = (USHORT)0xFF;
}
ScsiPortWritePortUchar(&baseIoAddress1->BlockCount,(UCHAR)sectorCount);
}
//
// Set data buffer pointer and words left.
//
deviceExtension->DataBuffer = (PUSHORT)Srb->DataBuffer;
deviceExtension->WordsLeft = Srb->DataTransferLength / 2;
//
// Indicate expecting an interrupt.
//
deviceExtension->ExpectingInterrupt = TRUE;
//
// Set up sector number register.
//
ScsiPortWritePortUchar(&baseIoAddress1->BlockNumber,
(UCHAR)((startingSector %
deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack) + 1));
//
// Set up cylinder low register.
//
ScsiPortWritePortUchar(&baseIoAddress1->CylinderLow,
(UCHAR)(startingSector /
(deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack *
deviceExtension->IdentifyData[Srb->TargetId].NumberOfHeads)));
//
// Set up cylinder high register.
//
ScsiPortWritePortUchar(&baseIoAddress1->CylinderHigh,
(UCHAR)((startingSector /
(deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack *
deviceExtension->IdentifyData[Srb->TargetId].NumberOfHeads)) >> 8));
//
// Set up head and drive select register.
//
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,
(UCHAR)(((startingSector /
deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack) %
deviceExtension->IdentifyData[Srb->TargetId].NumberOfHeads) |
((Srb->TargetId & 0x1) << 4) | 0xA0));
DebugPrint((2,
"IdeVerify: Cylinder %x Head %x Sector %x\n",
startingSector /
(deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack *
deviceExtension->IdentifyData[Srb->TargetId].NumberOfHeads),
(startingSector /
deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack) %
deviceExtension->IdentifyData[Srb->TargetId].NumberOfHeads,
startingSector %
deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack + 1));
//
// Send verify command.
//
ScsiPortWritePortUchar(&baseIoAddress1->Command,
IDE_COMMAND_VERIFY);
//
// Wait for interrupt.
//
return SRB_STATUS_PENDING;
} // end IdeVerify()
VOID
NTAPI
Scsi2Atapi(
IN PSCSI_REQUEST_BLOCK Srb
)
/*++
Routine Description:
Convert SCSI packet command to Atapi packet command.
Arguments:
Srb - IO request packet
Return Value:
None
--*/
{
//
// Change the cdb length
//
Srb->CdbLength = 12;
switch (Srb->Cdb[0]) {
case SCSIOP_MODE_SENSE: {
PMODE_SENSE_10 modeSense10 = (PMODE_SENSE_10)Srb->Cdb;
UCHAR PageCode = ((PCDB)Srb->Cdb)->MODE_SENSE.PageCode;
UCHAR Length = ((PCDB)Srb->Cdb)->MODE_SENSE.AllocationLength;
AtapiZeroMemory(Srb->Cdb,MAXIMUM_CDB_SIZE);
modeSense10->OperationCode = ATAPI_MODE_SENSE;
modeSense10->PageCode = PageCode;
modeSense10->ParameterListLengthMsb = 0;
modeSense10->ParameterListLengthLsb = Length;
break;
}
case SCSIOP_MODE_SELECT: {
PMODE_SELECT_10 modeSelect10 = (PMODE_SELECT_10)Srb->Cdb;
UCHAR Length = ((PCDB)Srb->Cdb)->MODE_SELECT.ParameterListLength;
//
// Zero the original cdb
//
AtapiZeroMemory(Srb->Cdb,MAXIMUM_CDB_SIZE);
modeSelect10->OperationCode = ATAPI_MODE_SELECT;
modeSelect10->PFBit = 1;
modeSelect10->ParameterListLengthMsb = 0;
modeSelect10->ParameterListLengthLsb = Length;
break;
}
case SCSIOP_FORMAT_UNIT:
Srb->Cdb[0] = ATAPI_FORMAT_UNIT;
break;
}
}
ULONG
NTAPI
AtapiSendCommand(
IN PVOID HwDeviceExtension,
IN PSCSI_REQUEST_BLOCK Srb
)
/*++
Routine Description:
Send ATAPI packet command to device.
Arguments:
HwDeviceExtension - HBA miniport driver's adapter data storage
Srb - IO request packet
Return Value:
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PATAPI_REGISTERS_1 baseIoAddress1 = (PATAPI_REGISTERS_1)deviceExtension->BaseIoAddress1[Srb->TargetId >> 1];
PATAPI_REGISTERS_2 baseIoAddress2 = (PATAPI_REGISTERS_2)deviceExtension->BaseIoAddress2[Srb->TargetId >> 1];
ULONG i;
ULONG flags;
UCHAR statusByte,byteCountLow,byteCountHigh;
//
// We need to know how many platters our atapi cd-rom device might have.
// Before anyone tries to send a srb to our target for the first time,
// we must "secretly" send down a separate mechanism status srb in order to
// initialize our device extension changer data. That's how we know how
// many platters our target has.
//
if (!(deviceExtension->DeviceFlags[Srb->TargetId] & DFLAGS_CHANGER_INITED) &&
!deviceExtension->OriginalSrb) {
ULONG srbStatus;
//
// Set this flag now. If the device hangs on the mech. status
// command, we will not have the change to set it.
//
deviceExtension->DeviceFlags[Srb->TargetId] |= DFLAGS_CHANGER_INITED;
deviceExtension->MechStatusRetryCount = 3;
deviceExtension->CurrentSrb = BuildMechanismStatusSrb (
HwDeviceExtension,
Srb->PathId,
Srb->TargetId);
deviceExtension->OriginalSrb = Srb;
srbStatus = AtapiSendCommand(HwDeviceExtension, deviceExtension->CurrentSrb);
if (srbStatus == SRB_STATUS_PENDING) {
return srbStatus;
} else {
deviceExtension->CurrentSrb = deviceExtension->OriginalSrb;
deviceExtension->OriginalSrb = NULL;
AtapiHwInitializeChanger (HwDeviceExtension,
Srb->TargetId,
(PMECHANICAL_STATUS_INFORMATION_HEADER) NULL);
// fall out
}
}
DebugPrint((2,
"AtapiSendCommand: Command %x to TargetId %d lun %d\n",
Srb->Cdb[0],
Srb->TargetId,
Srb->Lun));
//
// Make sure command is to ATAPI device.
//
flags = deviceExtension->DeviceFlags[Srb->TargetId];
if (flags & (DFLAGS_SANYO_ATAPI_CHANGER | DFLAGS_ATAPI_CHANGER)) {
if ((Srb->Lun) > (deviceExtension->DiscsPresent[Srb->TargetId] - 1)) {
//
// Indicate no device found at this address.
//
return SRB_STATUS_SELECTION_TIMEOUT;
}
} else if (Srb->Lun > 0) {
return SRB_STATUS_SELECTION_TIMEOUT;
}
if (!(flags & DFLAGS_ATAPI_DEVICE)) {
return SRB_STATUS_SELECTION_TIMEOUT;
}
//
// Select device 0 or 1.
//
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,
(UCHAR)(((Srb->TargetId & 0x1) << 4) | 0xA0));
//
// Verify that controller is ready for next command.
//
GetStatus(baseIoAddress2,statusByte);
DebugPrint((2,
"AtapiSendCommand: Entered with status %x\n",
statusByte));
if (statusByte & IDE_STATUS_BUSY) {
DebugPrint((1,
"AtapiSendCommand: Device busy (%x)\n",
statusByte));
return SRB_STATUS_BUSY;
}
if (statusByte & IDE_STATUS_ERROR) {
if (Srb->Cdb[0] != SCSIOP_REQUEST_SENSE) {
DebugPrint((1,
"AtapiSendCommand: Error on entry: (%x)\n",
statusByte));
//
// Read the error reg. to clear it and fail this request.
//
return MapError(deviceExtension,
Srb);
}
}
//
// If a tape drive has doesn't have DSC set and the last command is restrictive, don't send
// the next command. See discussion of Restrictive Delayed Process commands in QIC-157.
//
if ((!(statusByte & IDE_STATUS_DSC)) &&
(flags & DFLAGS_TAPE_DEVICE) && deviceExtension->RDP) {
ScsiPortStallExecution(1000);
DebugPrint((2,"AtapiSendCommand: DSC not set. %x\n",statusByte));
return SRB_STATUS_BUSY;
}
if (IS_RDP(Srb->Cdb[0])) {
deviceExtension->RDP = TRUE;
DebugPrint((3,
"AtapiSendCommand: %x mapped as DSC restrictive\n",
Srb->Cdb[0]));
} else {
deviceExtension->RDP = FALSE;
}
if (statusByte & IDE_STATUS_DRQ) {
DebugPrint((1,
"AtapiSendCommand: Entered with status (%x). Attempting to recover.\n",
statusByte));
//
// Try to drain the data that one preliminary device thinks that it has
// to transfer. Hopefully this random assertion of DRQ will not be present
// in production devices.
//
for (i = 0; i < 0x10000; i++) {
GetStatus(baseIoAddress2, statusByte);
if (statusByte & IDE_STATUS_DRQ) {
ScsiPortReadPortUshort(&baseIoAddress1->Data);
} else {
break;
}
}
if (i == 0x10000) {
DebugPrint((1,
"AtapiSendCommand: DRQ still asserted.Status (%x)\n",
statusByte));
AtapiSoftReset(baseIoAddress1,Srb->TargetId);
DebugPrint((1,
"AtapiSendCommand: Issued soft reset to Atapi device. \n"));
//
// Re-initialize Atapi device.
//
IssueIdentify(HwDeviceExtension,
(Srb->TargetId & 0x1),
(Srb->TargetId >> 1),
IDE_COMMAND_ATAPI_IDENTIFY);
//
// Inform the port driver that the bus has been reset.
//
ScsiPortNotification(ResetDetected, HwDeviceExtension, 0);
//
// Clean up device extension fields that AtapiStartIo won't.
//
deviceExtension->ExpectingInterrupt = FALSE;
deviceExtension->RDP = FALSE;
return SRB_STATUS_BUS_RESET;
}
}
if (flags & (DFLAGS_SANYO_ATAPI_CHANGER | DFLAGS_ATAPI_CHANGER)) {
//
// As the cdrom driver sets the LUN field in the cdb, it must be removed.
//
Srb->Cdb[1] &= ~0xE0;
if ((Srb->Cdb[0] == SCSIOP_TEST_UNIT_READY) && (flags & DFLAGS_SANYO_ATAPI_CHANGER)) {
//
// Torisan changer. TUR's are overloaded to be platter switches.
//
Srb->Cdb[7] = Srb->Lun;
}
}
//
// Convert SCSI to ATAPI commands if needed
//
switch (Srb->Cdb[0]) {
case SCSIOP_MODE_SENSE:
case SCSIOP_MODE_SELECT:
case SCSIOP_FORMAT_UNIT:
if (!(flags & DFLAGS_TAPE_DEVICE)) {
Scsi2Atapi(Srb);
}
break;
}
//
// Set data buffer pointer and words left.
//
deviceExtension->DataBuffer = (PUSHORT)Srb->DataBuffer;
deviceExtension->WordsLeft = Srb->DataTransferLength / 2;
WaitOnBusy(baseIoAddress2,statusByte);
//
// Write transfer byte count to registers.
//
byteCountLow = (UCHAR)(Srb->DataTransferLength & 0xFF);
byteCountHigh = (UCHAR)(Srb->DataTransferLength >> 8);
if (Srb->DataTransferLength >= 0x10000) {
byteCountLow = byteCountHigh = 0xFF;
}
ScsiPortWritePortUchar(&baseIoAddress1->ByteCountLow,byteCountLow);
ScsiPortWritePortUchar(&baseIoAddress1->ByteCountHigh, byteCountHigh);
ScsiPortWritePortUchar((PUCHAR)baseIoAddress1 + 1,0);
if (flags & DFLAGS_INT_DRQ) {
//
// This device interrupts when ready to receive the packet.
//
// Write ATAPI packet command.
//
ScsiPortWritePortUchar(&baseIoAddress1->Command,
IDE_COMMAND_ATAPI_PACKET);
DebugPrint((3,
"AtapiSendCommand: Wait for int. to send packet. Status (%x)\n",
statusByte));
deviceExtension->ExpectingInterrupt = TRUE;
return SRB_STATUS_PENDING;
} else {
//
// Write ATAPI packet command.
//
ScsiPortWritePortUchar(&baseIoAddress1->Command,
IDE_COMMAND_ATAPI_PACKET);
//
// Wait for DRQ.
//
WaitOnBusy(baseIoAddress2, statusByte);
WaitForDrq(baseIoAddress2, statusByte);
if (!(statusByte & IDE_STATUS_DRQ)) {
DebugPrint((1,
"AtapiSendCommand: DRQ never asserted (%x)\n",
statusByte));
return SRB_STATUS_ERROR;
}
}
//
// Need to read status register.
//
GetBaseStatus(baseIoAddress1, statusByte);
//
// Send CDB to device.
//
WaitOnBusy(baseIoAddress2,statusByte);
WriteBuffer(baseIoAddress1,
(PUSHORT)Srb->Cdb,
6);
//
// Indicate expecting an interrupt and wait for it.
//
deviceExtension->ExpectingInterrupt = TRUE;
return SRB_STATUS_PENDING;
} // end AtapiSendCommand()
ULONG
NTAPI
IdeSendCommand(
IN PVOID HwDeviceExtension,
IN PSCSI_REQUEST_BLOCK Srb
)
/*++
Routine Description:
Program ATA registers for IDE disk transfer.
Arguments:
HwDeviceExtension - ATAPI driver storage.
Srb - System request block.
Return Value:
SRB status (pending if all goes well).
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PIDE_REGISTERS_1 baseIoAddress1 = deviceExtension->BaseIoAddress1[Srb->TargetId >> 1];
PIDE_REGISTERS_2 baseIoAddress2 = deviceExtension->BaseIoAddress2[Srb->TargetId >> 1];
PCDB cdb;
UCHAR statusByte,errorByte;
ULONG status;
ULONG i;
PMODE_PARAMETER_HEADER modeData;
DebugPrint((2,
"IdeSendCommand: Command %x to device %d\n",
Srb->Cdb[0],
Srb->TargetId));
switch (Srb->Cdb[0]) {
case SCSIOP_INQUIRY:
//
// Filter out all TIDs but 0 and 1 since this is an IDE interface
// which support up to two devices.
//
if ((Srb->Lun != 0) ||
(!(deviceExtension->DeviceFlags[Srb->TargetId] & DFLAGS_DEVICE_PRESENT))) {
//
// Indicate no device found at this address.
//
status = SRB_STATUS_SELECTION_TIMEOUT;
break;
} else {
PINQUIRYDATA inquiryData = Srb->DataBuffer;
PIDENTIFY_DATA2 identifyData = &deviceExtension->IdentifyData[Srb->TargetId];
//
// Zero INQUIRY data structure.
//
for (i = 0; i < Srb->DataTransferLength; i++) {
((PUCHAR)Srb->DataBuffer)[i] = 0;
}
//
// Standard IDE interface only supports disks.
//
inquiryData->DeviceType = DIRECT_ACCESS_DEVICE;
//
// Set the removable bit, if applicable.
//
if (deviceExtension->DeviceFlags[Srb->TargetId] & DFLAGS_REMOVABLE_DRIVE) {
inquiryData->RemovableMedia = 1;
}
//
// Fill in vendor identification fields.
//
for (i = 0; i < 8; i += 2) {
inquiryData->VendorId[i] =
((PUCHAR)identifyData->ModelNumber)[i + 1];
inquiryData->VendorId[i+1] =
((PUCHAR)identifyData->ModelNumber)[i];
}
for (i = 0; i < 12; i += 2) {
inquiryData->ProductId[i] =
((PUCHAR)identifyData->ModelNumber)[i + 8 + 1];
inquiryData->ProductId[i+1] =
((PUCHAR)identifyData->ModelNumber)[i + 8];
}
//
// Initialize unused portion of product id.
//
for (i = 0; i < 4; i++) {
inquiryData->ProductId[12+i] = ' ';
}
//
// Move firmware revision from IDENTIFY data to
// product revision in INQUIRY data.
//
for (i = 0; i < 4; i += 2) {
inquiryData->ProductRevisionLevel[i] =
((PUCHAR)identifyData->FirmwareRevision)[i+1];
inquiryData->ProductRevisionLevel[i+1] =
((PUCHAR)identifyData->FirmwareRevision)[i];
}
status = SRB_STATUS_SUCCESS;
}
break;
case SCSIOP_MODE_SENSE:
//
// This is used to determine of the media is write-protected.
// Since IDE does not support mode sense then we will modify just the portion we need
// so the higher level driver can determine if media is protected.
//
if (deviceExtension->DeviceFlags[Srb->TargetId] & DFLAGS_MEDIA_STATUS_ENABLED) {
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,
(UCHAR)(((Srb->TargetId & 0x1) << 4) | 0xA0));
ScsiPortWritePortUchar(&baseIoAddress1->Command,IDE_COMMAND_GET_MEDIA_STATUS);
WaitOnBusy(baseIoAddress2,statusByte);
if (!(statusByte & IDE_STATUS_ERROR)){
//
// no error occured return success, media is not protected
//
deviceExtension->ExpectingInterrupt = FALSE;
} else {
//
// error occured, handle it locally, clear interrupt
//
errorByte = ScsiPortReadPortUchar((PUCHAR)baseIoAddress1 + 1);
GetBaseStatus(baseIoAddress1, statusByte);
deviceExtension->ExpectingInterrupt = FALSE;
if (errorByte & IDE_ERROR_DATA_ERROR) {
//
//media is write-protected, set bit in mode sense buffer
//
modeData = (PMODE_PARAMETER_HEADER)Srb->DataBuffer;
Srb->DataTransferLength = sizeof(MODE_PARAMETER_HEADER);
modeData->DeviceSpecificParameter |= MODE_DSP_WRITE_PROTECT;
}
}
status = SRB_STATUS_SUCCESS;
} else {
status = SRB_STATUS_INVALID_REQUEST;
}
break;
case SCSIOP_TEST_UNIT_READY:
if (deviceExtension->DeviceFlags[Srb->TargetId] & DFLAGS_MEDIA_STATUS_ENABLED) {
//
// Select device 0 or 1.
//
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,
(UCHAR)(((Srb->TargetId & 0x1) << 4) | 0xA0));
ScsiPortWritePortUchar(&baseIoAddress1->Command,IDE_COMMAND_GET_MEDIA_STATUS);
//
// Wait for busy. If media has not changed, return success
//
WaitOnBusy(baseIoAddress2,statusByte);
if (!(statusByte & IDE_STATUS_ERROR)){
deviceExtension->ExpectingInterrupt = FALSE;
status = SRB_STATUS_SUCCESS;
} else {
errorByte = ScsiPortReadPortUchar((PUCHAR)baseIoAddress1 + 1);
if (errorByte == IDE_ERROR_DATA_ERROR){
//
// Special case: If current media is write-protected,
// the 0xDA command will always fail since the write-protect bit
// is sticky,so we can ignore this error
//
GetBaseStatus(baseIoAddress1, statusByte);
deviceExtension->ExpectingInterrupt = FALSE;
status = SRB_STATUS_SUCCESS;
} else {
//
// Request sense buffer to be build
//
deviceExtension->ExpectingInterrupt = TRUE;
status = SRB_STATUS_PENDING;
}
}
} else {
status = SRB_STATUS_SUCCESS;
}
break;
case SCSIOP_READ_CAPACITY:
//
// Claim 512 byte blocks (big-endian).
//
((PREAD_CAPACITY_DATA)Srb->DataBuffer)->BytesPerBlock = 0x20000;
//
// Calculate last sector.
//
i = (deviceExtension->IdentifyData[Srb->TargetId].NumberOfHeads *
deviceExtension->IdentifyData[Srb->TargetId].NumberOfCylinders *
deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack) - 1;
((PREAD_CAPACITY_DATA)Srb->DataBuffer)->LogicalBlockAddress =
(((PUCHAR)&i)[0] << 24) | (((PUCHAR)&i)[1] << 16) |
(((PUCHAR)&i)[2] << 8) | ((PUCHAR)&i)[3];
DebugPrint((1,
"IDE disk %x - #sectors %x, #heads %x, #cylinders %x\n",
Srb->TargetId,
deviceExtension->IdentifyData[Srb->TargetId].SectorsPerTrack,
deviceExtension->IdentifyData[Srb->TargetId].NumberOfHeads,
deviceExtension->IdentifyData[Srb->TargetId].NumberOfCylinders));
status = SRB_STATUS_SUCCESS;
break;
case SCSIOP_VERIFY:
status = IdeVerify(HwDeviceExtension,Srb);
break;
case SCSIOP_READ:
case SCSIOP_WRITE:
status = IdeReadWrite(HwDeviceExtension,
Srb);
break;
case SCSIOP_START_STOP_UNIT:
//
//Determine what type of operation we should perform
//
cdb = (PCDB)Srb->Cdb;
if (cdb->START_STOP.LoadEject == 1){
//
// Eject media,
// first select device 0 or 1.
//
ScsiPortWritePortUchar(&baseIoAddress1->DriveSelect,
(UCHAR)(((Srb->TargetId & 0x1) << 4) | 0xA0));
ScsiPortWritePortUchar(&baseIoAddress1->Command,IDE_COMMAND_MEDIA_EJECT);
}
status = SRB_STATUS_SUCCESS;
break;
case SCSIOP_REQUEST_SENSE:
// this function makes sense buffers to report the results
// of the original GET_MEDIA_STATUS command
if (deviceExtension->DeviceFlags[Srb->TargetId] & DFLAGS_MEDIA_STATUS_ENABLED) {
status = IdeBuildSenseBuffer(HwDeviceExtension,Srb);
break;
}
default:
DebugPrint((1,
"IdeSendCommand: Unsupported command %x\n",
Srb->Cdb[0]));
status = SRB_STATUS_INVALID_REQUEST;
} // end switch
return status;
} // end IdeSendCommand()
VOID
NTAPI
IdeMediaStatus(
BOOLEAN EnableMSN,
IN PVOID HwDeviceExtension,
ULONG Channel
)
/*++
Routine Description:
Enables disables media status notification
Arguments:
HwDeviceExtension - ATAPI driver storage.
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PIDE_REGISTERS_1 baseIoAddress = deviceExtension->BaseIoAddress1[Channel >> 1];
UCHAR statusByte,errorByte;
if (EnableMSN != FALSE){
//
// If supported enable Media Status Notification support
//
if ((deviceExtension->DeviceFlags[Channel] & DFLAGS_REMOVABLE_DRIVE)) {
//
// enable
//
ScsiPortWritePortUchar((PUCHAR)baseIoAddress + 1,(UCHAR) (0x95));
ScsiPortWritePortUchar(&baseIoAddress->Command,
IDE_COMMAND_ENABLE_MEDIA_STATUS);
WaitOnBaseBusy(baseIoAddress,statusByte);
if (statusByte & IDE_STATUS_ERROR) {
//
// Read the error register.
//
errorByte = ScsiPortReadPortUchar((PUCHAR)baseIoAddress + 1);
DebugPrint((1,
"IdeMediaStatus: Error enabling media status. Status %x, error byte %x\n",
statusByte,
errorByte));
} else {
deviceExtension->DeviceFlags[Channel] |= DFLAGS_MEDIA_STATUS_ENABLED;
DebugPrint((1,"IdeMediaStatus: Media Status Notification Supported\n"));
deviceExtension->ReturningMediaStatus = 0;
}
}
} else { // end if EnableMSN != FALSE
//
// disable if previously enabled
//
if ((deviceExtension->DeviceFlags[Channel] & DFLAGS_MEDIA_STATUS_ENABLED)) {
ScsiPortWritePortUchar((PUCHAR)baseIoAddress + 1,(UCHAR) (0x31));
ScsiPortWritePortUchar(&baseIoAddress->Command,
IDE_COMMAND_ENABLE_MEDIA_STATUS);
WaitOnBaseBusy(baseIoAddress,statusByte);
deviceExtension->DeviceFlags[Channel] &= ~DFLAGS_MEDIA_STATUS_ENABLED;
}
}
}
ULONG
NTAPI
IdeBuildSenseBuffer(
IN PVOID HwDeviceExtension,
IN PSCSI_REQUEST_BLOCK Srb
)
/*++
Routine Description:
Builts an artificial sense buffer to report the results of a GET_MEDIA_STATUS
command. This function is invoked to satisfy the SCSIOP_REQUEST_SENSE.
Arguments:
HwDeviceExtension - ATAPI driver storage.
Srb - System request block.
Return Value:
SRB status (ALWAYS SUCCESS).
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PSENSE_DATA senseBuffer = (PSENSE_DATA)Srb->DataBuffer;
if (senseBuffer){
if(deviceExtension->ReturningMediaStatus & IDE_ERROR_MEDIA_CHANGE) {
senseBuffer->ErrorCode = 0x70;
senseBuffer->Valid = 1;
senseBuffer->AdditionalSenseLength = 0xb;
senseBuffer->SenseKey = SCSI_SENSE_UNIT_ATTENTION;
senseBuffer->AdditionalSenseCode = SCSI_ADSENSE_MEDIUM_CHANGED;
senseBuffer->AdditionalSenseCodeQualifier = 0;
} else if(deviceExtension->ReturningMediaStatus & IDE_ERROR_MEDIA_CHANGE_REQ) {
senseBuffer->ErrorCode = 0x70;
senseBuffer->Valid = 1;
senseBuffer->AdditionalSenseLength = 0xb;
senseBuffer->SenseKey = SCSI_SENSE_UNIT_ATTENTION;
senseBuffer->AdditionalSenseCode = SCSI_ADSENSE_MEDIUM_CHANGED;
senseBuffer->AdditionalSenseCodeQualifier = 0;
} else if(deviceExtension->ReturningMediaStatus & IDE_ERROR_END_OF_MEDIA) {
senseBuffer->ErrorCode = 0x70;
senseBuffer->Valid = 1;
senseBuffer->AdditionalSenseLength = 0xb;
senseBuffer->SenseKey = SCSI_SENSE_NOT_READY;
senseBuffer->AdditionalSenseCode = SCSI_ADSENSE_NO_MEDIA_IN_DEVICE;
senseBuffer->AdditionalSenseCodeQualifier = 0;
} else if(deviceExtension->ReturningMediaStatus & IDE_ERROR_DATA_ERROR) {
senseBuffer->ErrorCode = 0x70;
senseBuffer->Valid = 1;
senseBuffer->AdditionalSenseLength = 0xb;
senseBuffer->SenseKey = SCSI_SENSE_DATA_PROTECT;
senseBuffer->AdditionalSenseCode = 0;
senseBuffer->AdditionalSenseCodeQualifier = 0;
}
return SRB_STATUS_SUCCESS;
}
return SRB_STATUS_ERROR;
}// End of IdeBuildSenseBuffer
BOOLEAN
NTAPI
AtapiStartIo(
IN PVOID HwDeviceExtension,
IN PSCSI_REQUEST_BLOCK Srb
)
/*++
Routine Description:
This routine is called from the SCSI port driver synchronized
with the kernel to start an IO request.
Arguments:
HwDeviceExtension - HBA miniport driver's adapter data storage
Srb - IO request packet
Return Value:
TRUE
--*/
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
ULONG status;
//
// Determine which function.
//
switch (Srb->Function) {
case SRB_FUNCTION_EXECUTE_SCSI:
//
// Sanity check. Only one request can be outstanding on a
// controller.
//
if (deviceExtension->CurrentSrb) {
DebugPrint((1,
"AtapiStartIo: Already have a request!\n"));
Srb->SrbStatus = SRB_STATUS_BUSY;
ScsiPortNotification(RequestComplete,
deviceExtension,
Srb);
return FALSE;
}
//
// Indicate that a request is active on the controller.
//
deviceExtension->CurrentSrb = Srb;
//
// Send command to device.
//
if (deviceExtension->DeviceFlags[Srb->TargetId] & DFLAGS_ATAPI_DEVICE) {
status = AtapiSendCommand(HwDeviceExtension,
Srb);
} else if (deviceExtension->DeviceFlags[Srb->TargetId] & DFLAGS_DEVICE_PRESENT) {
status = IdeSendCommand(HwDeviceExtension,
Srb);
} else {
status = SRB_STATUS_SELECTION_TIMEOUT;
}
break;
case SRB_FUNCTION_ABORT_COMMAND:
//
// Verify that SRB to abort is still outstanding.
//
if (!deviceExtension->CurrentSrb) {
DebugPrint((1, "AtapiStartIo: SRB to abort already completed\n"));
//
// Complete abort SRB.
//
status = SRB_STATUS_ABORT_FAILED;
break;
}
//
// Abort function indicates that a request timed out.
// Call reset routine. Card will only be reset if
// status indicates something is wrong.
// Fall through to reset code.
//
case SRB_FUNCTION_RESET_BUS:
//
// Reset Atapi and SCSI bus.
//
DebugPrint((1, "AtapiStartIo: Reset bus request received\n"));
if (!AtapiResetController(deviceExtension,
Srb->PathId)) {
DebugPrint((1,"AtapiStartIo: Reset bus failed\n"));
//
// Log reset failure.
//
ScsiPortLogError(
HwDeviceExtension,
NULL,
0,
0,
0,
SP_INTERNAL_ADAPTER_ERROR,
5 << 8
);
status = SRB_STATUS_ERROR;
} else {
status = SRB_STATUS_SUCCESS;
}
break;
case SRB_FUNCTION_IO_CONTROL:
if (deviceExtension->CurrentSrb) {
DebugPrint((1,
"AtapiStartIo: Already have a request!\n"));
Srb->SrbStatus = SRB_STATUS_BUSY;
ScsiPortNotification(RequestComplete,
deviceExtension,
Srb);
return FALSE;
}
//
// Indicate that a request is active on the controller.
//
deviceExtension->CurrentSrb = Srb;
if (AtapiStringCmp( (PCHAR)((PSRB_IO_CONTROL)(Srb->DataBuffer))->Signature,"SCSIDISK",strlen("SCSIDISK"))) {
DebugPrint((1,
"AtapiStartIo: IoControl signature incorrect. Send %s, expected %s\n",
((PSRB_IO_CONTROL)(Srb->DataBuffer))->Signature,
"SCSIDISK"));
status = SRB_STATUS_INVALID_REQUEST;
break;
}
switch (((PSRB_IO_CONTROL)(Srb->DataBuffer))->ControlCode) {
case IOCTL_SCSI_MINIPORT_SMART_VERSION: {
PGETVERSIONINPARAMS versionParameters = (PGETVERSIONINPARAMS)(((PUCHAR)Srb->DataBuffer) + sizeof(SRB_IO_CONTROL));
UCHAR deviceNumber;
//
// Version and revision per SMART 1.03
//
versionParameters->bVersion = 1;
versionParameters->bRevision = 1;
versionParameters->bReserved = 0;
//
// Indicate that support for IDE IDENTIFY, ATAPI IDENTIFY and SMART commands.
//
versionParameters->fCapabilities = (CAP_ATA_ID_CMD | CAP_ATAPI_ID_CMD | CAP_SMART_CMD);
//
// This is done because of how the IOCTL_SCSI_MINIPORT
// determines 'targetid's'. Disk.sys places the real target id value
// in the DeviceMap field. Once we do some parameter checking, the value passed
// back to the application will be determined.
//
deviceNumber = versionParameters->bIDEDeviceMap;
if (!(deviceExtension->DeviceFlags[Srb->TargetId] & DFLAGS_DEVICE_PRESENT) ||
(deviceExtension->DeviceFlags[Srb->TargetId] & DFLAGS_ATAPI_DEVICE)) {
status = SRB_STATUS_SELECTION_TIMEOUT;
break;
}
//
// NOTE: This will only set the bit
// corresponding to this drive's target id.
// The bit mask is as follows:
//
// Sec Pri
// S M S M
// 3 2 1 0
//
if (deviceExtension->NumberChannels == 1) {
if (deviceExtension->PrimaryAddress) {
deviceNumber = 1 << Srb->TargetId;
} else {
deviceNumber = 4 << Srb->TargetId;
}
} else {
deviceNumber = 1 << Srb->TargetId;
}
versionParameters->bIDEDeviceMap = deviceNumber;
status = SRB_STATUS_SUCCESS;
break;
}
case IOCTL_SCSI_MINIPORT_IDENTIFY: {
PSENDCMDOUTPARAMS cmdOutParameters = (PSENDCMDOUTPARAMS)(((PUCHAR)Srb->DataBuffer) + sizeof(SRB_IO_CONTROL));
SENDCMDINPARAMS cmdInParameters = *(PSENDCMDINPARAMS)(((PUCHAR)Srb->DataBuffer) + sizeof(SRB_IO_CONTROL));
ULONG i;
UCHAR targetId;
if (cmdInParameters.irDriveRegs.bCommandReg == ID_CMD) {
//
// Extract the target.
//
targetId = cmdInParameters.bDriveNumber;
if (!(deviceExtension->DeviceFlags[Srb->TargetId] & DFLAGS_DEVICE_PRESENT) ||
(deviceExtension->DeviceFlags[Srb->TargetId] & DFLAGS_ATAPI_DEVICE)) {
status = SRB_STATUS_SELECTION_TIMEOUT;
break;
}
//
// Zero the output buffer
//
for (i = 0; i < (sizeof(SENDCMDOUTPARAMS) + IDENTIFY_BUFFER_SIZE - 1); i++) {
((PUCHAR)cmdOutParameters)[i] = 0;
}
//
// Build status block.
//
cmdOutParameters->cBufferSize = IDENTIFY_BUFFER_SIZE;
cmdOutParameters->DriverStatus.bDriverError = 0;
cmdOutParameters->DriverStatus.bIDEError = 0;
//
// Extract the identify data from the device extension.
//
ScsiPortMoveMemory (cmdOutParameters->bBuffer, &deviceExtension->IdentifyData[targetId], IDENTIFY_DATA_SIZE);
status = SRB_STATUS_SUCCESS;
} else {
status = SRB_STATUS_INVALID_REQUEST;
}
break;
}
case IOCTL_SCSI_MINIPORT_READ_SMART_ATTRIBS:
case IOCTL_SCSI_MINIPORT_READ_SMART_THRESHOLDS:
case IOCTL_SCSI_MINIPORT_ENABLE_SMART:
case IOCTL_SCSI_MINIPORT_DISABLE_SMART:
case IOCTL_SCSI_MINIPORT_RETURN_STATUS:
case IOCTL_SCSI_MINIPORT_ENABLE_DISABLE_AUTOSAVE:
case IOCTL_SCSI_MINIPORT_SAVE_ATTRIBUTE_VALUES:
case IOCTL_SCSI_MINIPORT_EXECUTE_OFFLINE_DIAGS:
status = IdeSendSmartCommand(HwDeviceExtension,Srb);
break;
default :
status = SRB_STATUS_INVALID_REQUEST;
break;
}
break;
default:
//
// Indicate unsupported command.
//
status = SRB_STATUS_INVALID_REQUEST;
break;
} // end switch
//
// Check if command complete.
//
if (status != SRB_STATUS_PENDING) {
DebugPrint((2,
"AtapiStartIo: Srb %x complete with status %x\n",
Srb,
status));
//
// Clear current SRB.
//
deviceExtension->CurrentSrb = NULL;
//
// Set status in SRB.
//
Srb->SrbStatus = (UCHAR)status;
//
// Indicate command complete.
//
ScsiPortNotification(RequestComplete,
deviceExtension,
Srb);
//
// Indicate ready for next request.
//
ScsiPortNotification(NextRequest,
deviceExtension,
NULL);
}
return TRUE;
} // end AtapiStartIo()
ULONG
NTAPI
DriverEntry(
IN PVOID DriverObject,
IN PVOID Argument2
)
/*++
Routine Description:
Installable driver initialization entry point for system.
Arguments:
Driver Object
Return Value:
Status from ScsiPortInitialize()
--*/
{
HW_INITIALIZATION_DATA hwInitializationData;
ULONG adapterCount;
ULONG i;
ULONG statusToReturn, newStatus;
DebugPrint((1,"\n\nATAPI IDE MiniPort Driver\n"));
statusToReturn = 0xffffffff;
//
// Zero out structure.
//
AtapiZeroMemory(((PUCHAR)&hwInitializationData), sizeof(HW_INITIALIZATION_DATA));
//
// Set size of hwInitializationData.
//
hwInitializationData.HwInitializationDataSize =
sizeof(HW_INITIALIZATION_DATA);
//
// Set entry points.
//
hwInitializationData.HwInitialize = AtapiHwInitialize;
hwInitializationData.HwResetBus = AtapiResetController;
hwInitializationData.HwStartIo = AtapiStartIo;
hwInitializationData.HwInterrupt = AtapiInterrupt;
//
// Specify size of extensions.
//
hwInitializationData.DeviceExtensionSize = sizeof(HW_DEVICE_EXTENSION);
hwInitializationData.SpecificLuExtensionSize = sizeof(HW_LU_EXTENSION);
//
// Indicate PIO device.
//
hwInitializationData.MapBuffers = TRUE;
//
// Native Mode Devices
//
for (i=0; i <NUM_NATIVE_MODE_ADAPTERS; i++) {
hwInitializationData.HwFindAdapter = AtapiFindNativeModeController;
hwInitializationData.NumberOfAccessRanges = 4;
hwInitializationData.AdapterInterfaceType = PCIBus;
hwInitializationData.VendorId = NativeModeAdapters[i].VendorId;
hwInitializationData.VendorIdLength = (USHORT) NativeModeAdapters[i].VendorIdLength;
hwInitializationData.DeviceId = NativeModeAdapters[i].DeviceId;
hwInitializationData.DeviceIdLength = (USHORT) NativeModeAdapters[i].DeviceIdLength;
newStatus = ScsiPortInitialize(DriverObject,
Argument2,
&hwInitializationData,
(PVOID)(ULONG_PTR)i);
if (newStatus < statusToReturn)
statusToReturn = newStatus;
}
hwInitializationData.VendorId = 0;
hwInitializationData.VendorIdLength = 0;
hwInitializationData.DeviceId = 0;
hwInitializationData.DeviceIdLength = 0;
//
// The adapter count is used by the find adapter routine to track how
// which adapter addresses have been tested.
//
adapterCount = 0;
hwInitializationData.HwFindAdapter = AtapiFindPCIController;
hwInitializationData.NumberOfAccessRanges = 4;
hwInitializationData.AdapterInterfaceType = Isa;
newStatus = ScsiPortInitialize(DriverObject,
Argument2,
&hwInitializationData,
&adapterCount);
if (newStatus < statusToReturn)
statusToReturn = newStatus;
//
// Indicate 2 access ranges and reset FindAdapter.
//
hwInitializationData.NumberOfAccessRanges = 2;
hwInitializationData.HwFindAdapter = AtapiFindController;
//
// Indicate ISA bustype.
//
hwInitializationData.AdapterInterfaceType = Isa;
//
// Call initialization for ISA bustype.
//
newStatus = ScsiPortInitialize(DriverObject,
Argument2,
&hwInitializationData,
&adapterCount);
if (newStatus < statusToReturn)
statusToReturn = newStatus;
//
// Set up for MCA
//
hwInitializationData.AdapterInterfaceType = MicroChannel;
adapterCount = 0;
newStatus = ScsiPortInitialize(DriverObject,
Argument2,
&hwInitializationData,
&adapterCount);
if (newStatus < statusToReturn)
statusToReturn = newStatus;
return statusToReturn;
} // end DriverEntry()
LONG
NTAPI
AtapiStringCmp (
PCHAR FirstStr,
PCHAR SecondStr,
ULONG Count
)
{
UCHAR first ,last;
if (Count) {
do {
//
// Get next char.
//
first = *FirstStr++;
last = *SecondStr++;
if (first != last) {
//
// If no match, try lower-casing.
//
if (first>='A' && first<='Z') {
first = first - 'A' + 'a';
}
if (last>='A' && last<='Z') {
last = last - 'A' + 'a';
}
if (first != last) {
//
// No match
//
return first - last;
}
}
}while (--Count && first);
}
return 0;
}
VOID
NTAPI
AtapiZeroMemory(
IN PUCHAR Buffer,
IN ULONG Count
)
{
ULONG i;
for (i = 0; i < Count; i++) {
Buffer[i] = 0;
}
}
VOID
NTAPI
AtapiHexToString (
IN ULONG Value,
IN OUT PCHAR *Buffer
)
{
PCHAR string;
PCHAR firstdig;
CHAR temp;
ULONG i;
USHORT digval;
string = *Buffer;
firstdig = string;
for (i = 0; i < 4; i++) {
digval = (USHORT)(Value % 16);
Value /= 16;
//
// convert to ascii and store. Note this will create
// the buffer with the digits reversed.
//
if (digval > 9) {
*string++ = (char) (digval - 10 + 'a');
} else {
*string++ = (char) (digval + '0');
}
}
//
// Reverse the digits.
//
*string-- = '\0';
do {
temp = *string;
*string = *firstdig;
*firstdig = temp;
--string;
++firstdig;
} while (firstdig < string);
}
PSCSI_REQUEST_BLOCK
NTAPI
BuildMechanismStatusSrb (
IN PVOID HwDeviceExtension,
IN ULONG PathId,
IN ULONG TargetId
)
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PSCSI_REQUEST_BLOCK srb;
PCDB cdb;
srb = &deviceExtension->InternalSrb;
AtapiZeroMemory((PUCHAR) srb, sizeof(SCSI_REQUEST_BLOCK));
srb->PathId = (UCHAR) PathId;
srb->TargetId = (UCHAR) TargetId;
srb->Function = SRB_FUNCTION_EXECUTE_SCSI;
srb->Length = sizeof(SCSI_REQUEST_BLOCK);
//
// Set flags to disable synchronous negotiation.
//
srb->SrbFlags = SRB_FLAGS_DATA_IN | SRB_FLAGS_DISABLE_SYNCH_TRANSFER;
//
// Set timeout to 2 seconds.
//
srb->TimeOutValue = 4;
srb->CdbLength = 6;
srb->DataBuffer = &deviceExtension->MechStatusData;
srb->DataTransferLength = sizeof(MECHANICAL_STATUS_INFORMATION_HEADER);
//
// Set CDB operation code.
//
cdb = (PCDB)srb->Cdb;
cdb->MECH_STATUS.OperationCode = SCSIOP_MECHANISM_STATUS;
cdb->MECH_STATUS.AllocationLength[1] = sizeof(MECHANICAL_STATUS_INFORMATION_HEADER);
return srb;
}
PSCSI_REQUEST_BLOCK
NTAPI
BuildRequestSenseSrb (
IN PVOID HwDeviceExtension,
IN ULONG PathId,
IN ULONG TargetId
)
{
PHW_DEVICE_EXTENSION deviceExtension = HwDeviceExtension;
PSCSI_REQUEST_BLOCK srb;
PCDB cdb;
srb = &deviceExtension->InternalSrb;
AtapiZeroMemory((PUCHAR) srb, sizeof(SCSI_REQUEST_BLOCK));
srb->PathId = (UCHAR) PathId;
srb->TargetId = (UCHAR) TargetId;
srb->Function = SRB_FUNCTION_EXECUTE_SCSI;
srb->Length = sizeof(SCSI_REQUEST_BLOCK);
//
// Set flags to disable synchronous negotiation.
//
srb->SrbFlags = SRB_FLAGS_DATA_IN | SRB_FLAGS_DISABLE_SYNCH_TRANSFER;
//
// Set timeout to 2 seconds.
//
srb->TimeOutValue = 4;
srb->CdbLength = 6;
srb->DataBuffer = &deviceExtension->MechStatusSense;
srb->DataTransferLength = sizeof(SENSE_DATA);
//
// Set CDB operation code.
//
cdb = (PCDB)srb->Cdb;
cdb->CDB6INQUIRY.OperationCode = SCSIOP_REQUEST_SENSE;
cdb->CDB6INQUIRY.AllocationLength = sizeof(SENSE_DATA);
return srb;
}
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