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reactos/base/setup/lib/utils/partlist.c

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/*
* PROJECT: ReactOS Setup Library
* LICENSE: GPL-2.0+ (https://spdx.org/licenses/GPL-2.0+)
* PURPOSE: Partition list functions
* COPYRIGHT: Copyright 2003-2019 Casper S. Hornstrup (chorns@users.sourceforge.net)
* Copyright 2018-2019 Hermes Belusca-Maito
*/
#include "precomp.h"
#include <ntddscsi.h>
#include "partlist.h"
#include "fsrec.h"
#include "registry.h"
#define NDEBUG
#include <debug.h>
//#define DUMP_PARTITION_TABLE
#include <pshpack1.h>
typedef struct _REG_DISK_MOUNT_INFO
{
ULONG Signature;
LARGE_INTEGER StartingOffset;
} REG_DISK_MOUNT_INFO, *PREG_DISK_MOUNT_INFO;
#include <poppack.h>
/* FUNCTIONS ****************************************************************/
#ifdef DUMP_PARTITION_TABLE
static
VOID
DumpPartitionTable(
PDISKENTRY DiskEntry)
{
PPARTITION_INFORMATION PartitionInfo;
ULONG i;
DbgPrint("\n");
DbgPrint("Index Start Length Hidden Nr Type Boot RW\n");
DbgPrint("----- ------------ ------------ ---------- -- ---- ---- --\n");
for (i = 0; i < DiskEntry->LayoutBuffer->PartitionCount; i++)
{
PartitionInfo = &DiskEntry->LayoutBuffer->PartitionEntry[i];
DbgPrint(" %3lu %12I64u %12I64u %10lu %2lu %2x %c %c\n",
i,
PartitionInfo->StartingOffset.QuadPart / DiskEntry->BytesPerSector,
PartitionInfo->PartitionLength.QuadPart / DiskEntry->BytesPerSector,
PartitionInfo->HiddenSectors,
PartitionInfo->PartitionNumber,
PartitionInfo->PartitionType,
PartitionInfo->BootIndicator ? '*': ' ',
PartitionInfo->RewritePartition ? 'Y': 'N');
}
DbgPrint("\n");
}
#endif
ULONGLONG
AlignDown(
IN ULONGLONG Value,
IN ULONG Alignment)
{
ULONGLONG Temp;
Temp = Value / Alignment;
return Temp * Alignment;
}
ULONGLONG
AlignUp(
IN ULONGLONG Value,
IN ULONG Alignment)
{
ULONGLONG Temp, Result;
Temp = Value / Alignment;
Result = Temp * Alignment;
if (Value % Alignment)
Result += Alignment;
return Result;
}
ULONGLONG
RoundingDivide(
IN ULONGLONG Dividend,
IN ULONGLONG Divisor)
{
return (Dividend + Divisor / 2) / Divisor;
}
static
VOID
GetDriverName(
IN PDISKENTRY DiskEntry)
{
RTL_QUERY_REGISTRY_TABLE QueryTable[2];
WCHAR KeyName[32];
NTSTATUS Status;
RtlInitUnicodeString(&DiskEntry->DriverName, NULL);
RtlStringCchPrintfW(KeyName, ARRAYSIZE(KeyName),
L"\\Scsi\\Scsi Port %hu",
DiskEntry->Port);
RtlZeroMemory(&QueryTable, sizeof(QueryTable));
QueryTable[0].Name = L"Driver";
QueryTable[0].Flags = RTL_QUERY_REGISTRY_DIRECT;
QueryTable[0].EntryContext = &DiskEntry->DriverName;
/* This will allocate DiskEntry->DriverName if needed */
Status = RtlQueryRegistryValues(RTL_REGISTRY_DEVICEMAP,
KeyName,
QueryTable,
NULL,
NULL);
if (!NT_SUCCESS(Status))
{
DPRINT1("RtlQueryRegistryValues() failed (Status %lx)\n", Status);
}
}
static
VOID
AssignDriveLetters(
IN PPARTLIST List)
{
PDISKENTRY DiskEntry;
PPARTENTRY PartEntry;
PLIST_ENTRY Entry1;
PLIST_ENTRY Entry2;
WCHAR Letter;
Letter = L'C';
/* Assign drive letters to primary partitions */
for (Entry1 = List->DiskListHead.Flink;
Entry1 != &List->DiskListHead;
Entry1 = Entry1->Flink)
{
DiskEntry = CONTAINING_RECORD(Entry1, DISKENTRY, ListEntry);
for (Entry2 = DiskEntry->PrimaryPartListHead.Flink;
Entry2 != &DiskEntry->PrimaryPartListHead;
Entry2 = Entry2->Flink)
{
PartEntry = CONTAINING_RECORD(Entry2, PARTENTRY, ListEntry);
PartEntry->DriveLetter = 0;
if (PartEntry->IsPartitioned &&
!IsContainerPartition(PartEntry->PartitionType))
{
ASSERT(PartEntry->PartitionType != PARTITION_ENTRY_UNUSED);
if (IsRecognizedPartition(PartEntry->PartitionType) ||
PartEntry->SectorCount.QuadPart != 0LL)
{
if (Letter <= L'Z')
{
PartEntry->DriveLetter = Letter;
Letter++;
}
}
}
}
}
/* Assign drive letters to logical drives */
for (Entry1 = List->DiskListHead.Flink;
Entry1 != &List->DiskListHead;
Entry1 = Entry1->Flink)
{
DiskEntry = CONTAINING_RECORD(Entry1, DISKENTRY, ListEntry);
for (Entry2 = DiskEntry->LogicalPartListHead.Flink;
Entry2 != &DiskEntry->LogicalPartListHead;
Entry2 = Entry2->Flink)
{
PartEntry = CONTAINING_RECORD(Entry2, PARTENTRY, ListEntry);
PartEntry->DriveLetter = 0;
if (PartEntry->IsPartitioned)
{
ASSERT(PartEntry->PartitionType != PARTITION_ENTRY_UNUSED);
if (IsRecognizedPartition(PartEntry->PartitionType) ||
PartEntry->SectorCount.QuadPart != 0LL)
{
if (Letter <= L'Z')
{
PartEntry->DriveLetter = Letter;
Letter++;
}
}
}
}
}
}
static NTSTATUS
NTAPI
DiskIdentifierQueryRoutine(
PWSTR ValueName,
ULONG ValueType,
PVOID ValueData,
ULONG ValueLength,
PVOID Context,
PVOID EntryContext)
{
PBIOSDISKENTRY BiosDiskEntry = (PBIOSDISKENTRY)Context;
UNICODE_STRING NameU;
if (ValueType == REG_SZ &&
ValueLength == 20 * sizeof(WCHAR) &&
((PWCHAR)ValueData)[8] == L'-')
{
NameU.Buffer = (PWCHAR)ValueData;
NameU.Length = NameU.MaximumLength = 8 * sizeof(WCHAR);
RtlUnicodeStringToInteger(&NameU, 16, &BiosDiskEntry->Checksum);
NameU.Buffer = (PWCHAR)ValueData + 9;
RtlUnicodeStringToInteger(&NameU, 16, &BiosDiskEntry->Signature);
return STATUS_SUCCESS;
}
return STATUS_UNSUCCESSFUL;
}
static NTSTATUS
NTAPI
DiskConfigurationDataQueryRoutine(
PWSTR ValueName,
ULONG ValueType,
PVOID ValueData,
ULONG ValueLength,
PVOID Context,
PVOID EntryContext)
{
PBIOSDISKENTRY BiosDiskEntry = (PBIOSDISKENTRY)Context;
PCM_FULL_RESOURCE_DESCRIPTOR FullResourceDescriptor;
PCM_DISK_GEOMETRY_DEVICE_DATA DiskGeometry;
ULONG i;
if (ValueType != REG_FULL_RESOURCE_DESCRIPTOR ||
ValueLength < sizeof(CM_FULL_RESOURCE_DESCRIPTOR))
return STATUS_UNSUCCESSFUL;
FullResourceDescriptor = (PCM_FULL_RESOURCE_DESCRIPTOR)ValueData;
/* Hm. Version and Revision are not set on Microsoft Windows XP... */
#if 0
if (FullResourceDescriptor->PartialResourceList.Version != 1 ||
FullResourceDescriptor->PartialResourceList.Revision != 1)
return STATUS_UNSUCCESSFUL;
#endif
for (i = 0; i < FullResourceDescriptor->PartialResourceList.Count; i++)
{
if (FullResourceDescriptor->PartialResourceList.PartialDescriptors[i].Type != CmResourceTypeDeviceSpecific ||
FullResourceDescriptor->PartialResourceList.PartialDescriptors[i].u.DeviceSpecificData.DataSize != sizeof(CM_DISK_GEOMETRY_DEVICE_DATA))
continue;
DiskGeometry = (PCM_DISK_GEOMETRY_DEVICE_DATA)&FullResourceDescriptor->PartialResourceList.PartialDescriptors[i + 1];
BiosDiskEntry->DiskGeometry = *DiskGeometry;
return STATUS_SUCCESS;
}
return STATUS_UNSUCCESSFUL;
}
static NTSTATUS
NTAPI
SystemConfigurationDataQueryRoutine(
PWSTR ValueName,
ULONG ValueType,
PVOID ValueData,
ULONG ValueLength,
PVOID Context,
PVOID EntryContext)
{
PCM_FULL_RESOURCE_DESCRIPTOR FullResourceDescriptor;
PCM_INT13_DRIVE_PARAMETER* Int13Drives = (PCM_INT13_DRIVE_PARAMETER*)Context;
ULONG i;
if (ValueType != REG_FULL_RESOURCE_DESCRIPTOR ||
ValueLength < sizeof(CM_FULL_RESOURCE_DESCRIPTOR))
return STATUS_UNSUCCESSFUL;
FullResourceDescriptor = (PCM_FULL_RESOURCE_DESCRIPTOR)ValueData;
/* Hm. Version and Revision are not set on Microsoft Windows XP... */
#if 0
if (FullResourceDescriptor->PartialResourceList.Version != 1 ||
FullResourceDescriptor->PartialResourceList.Revision != 1)
return STATUS_UNSUCCESSFUL;
#endif
for (i = 0; i < FullResourceDescriptor->PartialResourceList.Count; i++)
{
if (FullResourceDescriptor->PartialResourceList.PartialDescriptors[i].Type != CmResourceTypeDeviceSpecific ||
FullResourceDescriptor->PartialResourceList.PartialDescriptors[i].u.DeviceSpecificData.DataSize % sizeof(CM_INT13_DRIVE_PARAMETER) != 0)
continue;
*Int13Drives = (CM_INT13_DRIVE_PARAMETER*)RtlAllocateHeap(ProcessHeap, 0,
FullResourceDescriptor->PartialResourceList.PartialDescriptors[i].u.DeviceSpecificData.DataSize);
if (*Int13Drives == NULL)
return STATUS_NO_MEMORY;
memcpy(*Int13Drives,
&FullResourceDescriptor->PartialResourceList.PartialDescriptors[i + 1],
FullResourceDescriptor->PartialResourceList.PartialDescriptors[i].u.DeviceSpecificData.DataSize);
return STATUS_SUCCESS;
}
return STATUS_UNSUCCESSFUL;
}
static VOID
EnumerateBiosDiskEntries(
IN PPARTLIST PartList)
{
RTL_QUERY_REGISTRY_TABLE QueryTable[3];
WCHAR Name[120];
ULONG AdapterCount;
ULONG ControllerCount;
ULONG DiskCount;
NTSTATUS Status;
PCM_INT13_DRIVE_PARAMETER Int13Drives;
PBIOSDISKENTRY BiosDiskEntry;
#define ROOT_NAME L"\\Registry\\Machine\\HARDWARE\\DESCRIPTION\\System\\MultifunctionAdapter"
memset(QueryTable, 0, sizeof(QueryTable));
QueryTable[1].Name = L"Configuration Data";
QueryTable[1].QueryRoutine = SystemConfigurationDataQueryRoutine;
Int13Drives = NULL;
Status = RtlQueryRegistryValues(RTL_REGISTRY_ABSOLUTE,
L"\\Registry\\Machine\\HARDWARE\\DESCRIPTION\\System",
&QueryTable[1],
(PVOID)&Int13Drives,
NULL);
if (!NT_SUCCESS(Status))
{
DPRINT1("Unable to query the 'Configuration Data' key in '\\Registry\\Machine\\HARDWARE\\DESCRIPTION\\System', status=%lx\n", Status);
return;
}
for (AdapterCount = 0; ; ++AdapterCount)
{
RtlStringCchPrintfW(Name, ARRAYSIZE(Name),
L"%s\\%lu",
ROOT_NAME, AdapterCount);
Status = RtlQueryRegistryValues(RTL_REGISTRY_ABSOLUTE,
Name,
&QueryTable[2],
NULL,
NULL);
if (!NT_SUCCESS(Status))
{
break;
}
RtlStringCchPrintfW(Name, ARRAYSIZE(Name),
L"%s\\%lu\\DiskController",
ROOT_NAME, AdapterCount);
Status = RtlQueryRegistryValues(RTL_REGISTRY_ABSOLUTE,
Name,
&QueryTable[2],
NULL,
NULL);
if (NT_SUCCESS(Status))
{
for (ControllerCount = 0; ; ++ControllerCount)
{
RtlStringCchPrintfW(Name, ARRAYSIZE(Name),
L"%s\\%lu\\DiskController\\%lu",
ROOT_NAME, AdapterCount, ControllerCount);
Status = RtlQueryRegistryValues(RTL_REGISTRY_ABSOLUTE,
Name,
&QueryTable[2],
NULL,
NULL);
if (!NT_SUCCESS(Status))
{
RtlFreeHeap(ProcessHeap, 0, Int13Drives);
return;
}
RtlStringCchPrintfW(Name, ARRAYSIZE(Name),
L"%s\\%lu\\DiskController\\%lu\\DiskPeripheral",
ROOT_NAME, AdapterCount, ControllerCount);
Status = RtlQueryRegistryValues(RTL_REGISTRY_ABSOLUTE,
Name,
&QueryTable[2],
NULL,
NULL);
if (NT_SUCCESS(Status))
{
QueryTable[0].Name = L"Identifier";
QueryTable[0].QueryRoutine = DiskIdentifierQueryRoutine;
QueryTable[1].Name = L"Configuration Data";
QueryTable[1].QueryRoutine = DiskConfigurationDataQueryRoutine;
for (DiskCount = 0; ; ++DiskCount)
{
BiosDiskEntry = (BIOSDISKENTRY*)RtlAllocateHeap(ProcessHeap, HEAP_ZERO_MEMORY, sizeof(BIOSDISKENTRY));
if (BiosDiskEntry == NULL)
{
RtlFreeHeap(ProcessHeap, 0, Int13Drives);
return;
}
RtlStringCchPrintfW(Name, ARRAYSIZE(Name),
L"%s\\%lu\\DiskController\\%lu\\DiskPeripheral\\%lu",
ROOT_NAME, AdapterCount, ControllerCount, DiskCount);
Status = RtlQueryRegistryValues(RTL_REGISTRY_ABSOLUTE,
Name,
QueryTable,
(PVOID)BiosDiskEntry,
NULL);
if (!NT_SUCCESS(Status))
{
RtlFreeHeap(ProcessHeap, 0, BiosDiskEntry);
RtlFreeHeap(ProcessHeap, 0, Int13Drives);
return;
}
BiosDiskEntry->AdapterNumber = 0; // And NOT "AdapterCount" as it needs to be hardcoded for BIOS!
BiosDiskEntry->ControllerNumber = ControllerCount;
BiosDiskEntry->DiskNumber = DiskCount;
BiosDiskEntry->DiskEntry = NULL;
if (DiskCount < Int13Drives[0].NumberDrives)
{
BiosDiskEntry->Int13DiskData = Int13Drives[DiskCount];
}
else
{
DPRINT1("Didn't find Int13 drive data for disk %u\n", DiskCount);
}
InsertTailList(&PartList->BiosDiskListHead, &BiosDiskEntry->ListEntry);
DPRINT("--->\n");
DPRINT("AdapterNumber: %lu\n", BiosDiskEntry->AdapterNumber);
DPRINT("ControllerNumber: %lu\n", BiosDiskEntry->ControllerNumber);
DPRINT("DiskNumber: %lu\n", BiosDiskEntry->DiskNumber);
DPRINT("Signature: %08lx\n", BiosDiskEntry->Signature);
DPRINT("Checksum: %08lx\n", BiosDiskEntry->Checksum);
DPRINT("BytesPerSector: %lu\n", BiosDiskEntry->DiskGeometry.BytesPerSector);
DPRINT("NumberOfCylinders: %lu\n", BiosDiskEntry->DiskGeometry.NumberOfCylinders);
DPRINT("NumberOfHeads: %lu\n", BiosDiskEntry->DiskGeometry.NumberOfHeads);
DPRINT("DriveSelect: %02x\n", BiosDiskEntry->Int13DiskData.DriveSelect);
DPRINT("MaxCylinders: %lu\n", BiosDiskEntry->Int13DiskData.MaxCylinders);
DPRINT("SectorsPerTrack: %d\n", BiosDiskEntry->Int13DiskData.SectorsPerTrack);
DPRINT("MaxHeads: %d\n", BiosDiskEntry->Int13DiskData.MaxHeads);
DPRINT("NumberDrives: %d\n", BiosDiskEntry->Int13DiskData.NumberDrives);
DPRINT("<---\n");
}
}
}
}
}
RtlFreeHeap(ProcessHeap, 0, Int13Drives);
#undef ROOT_NAME
}
/*
* Detects whether a disk reports as a "super-floppy", i.e. an unpartitioned
* disk with a valid VBR, following the criteria used by IoReadPartitionTable()
* and IoWritePartitionTable():
* only one single partition starting at the beginning of the disk; the reported
* defaults are: partition number being zero and its type being FAT16 non-bootable.
* Note also that accessing \Device\HarddiskN\Partition0 or Partition1 returns
* the same data.
*/
// static
BOOLEAN
IsSuperFloppy(
IN PDISKENTRY DiskEntry)
{
PPARTITION_INFORMATION PartitionInfo;
ULONGLONG PartitionLengthEstimate;
/* No layout buffer: we cannot say anything yet */
if (DiskEntry->LayoutBuffer == NULL)
return FALSE;
/* We must have only one partition */
if (DiskEntry->LayoutBuffer->PartitionCount != 1)
return FALSE;
/* Get the single partition entry */
PartitionInfo = DiskEntry->LayoutBuffer->PartitionEntry;
/* The single partition must start at the beginning of the disk */
if (!(PartitionInfo->StartingOffset.QuadPart == 0 &&
PartitionInfo->HiddenSectors == 0))
{
return FALSE;
}
/* The disk signature is usually set to one; warn in case it's not */
if (DiskEntry->LayoutBuffer->Signature != 1)
{
DPRINT1("Super-Floppy disk %lu signature %08x != 1!\n",
DiskEntry->DiskNumber, DiskEntry->LayoutBuffer->Signature);
}
/*
* The partition number must be zero or one, be recognized,
* have FAT16 type and report as non-bootable.
*/
if ((PartitionInfo->PartitionNumber != 0 &&
PartitionInfo->PartitionNumber != 1) ||
PartitionInfo->RecognizedPartition != TRUE ||
PartitionInfo->PartitionType != PARTITION_FAT_16 ||
PartitionInfo->BootIndicator != FALSE)
{
DPRINT1("Super-Floppy disk %lu does not return default settings!\n"
" PartitionNumber = %lu, expected 0\n"
" RecognizedPartition = %s, expected TRUE\n"
" PartitionType = 0x%02x, expected 0x04 (PARTITION_FAT_16)\n"
" BootIndicator = %s, expected FALSE\n",
DiskEntry->DiskNumber,
PartitionInfo->PartitionNumber,
PartitionInfo->RecognizedPartition ? "TRUE" : "FALSE",
PartitionInfo->PartitionType,
PartitionInfo->BootIndicator ? "TRUE" : "FALSE");
}
/* The partition lengths should agree */
PartitionLengthEstimate = DiskEntry->SectorCount.QuadPart * DiskEntry->BytesPerSector;
if (PartitionInfo->PartitionLength.QuadPart != PartitionLengthEstimate)
{
DPRINT1("PartitionLength = %I64u is different from PartitionLengthEstimate = %I64u\n",
PartitionInfo->PartitionLength.QuadPart, PartitionLengthEstimate);
}
return TRUE;
}
/*
* Inserts the disk region represented by PartEntry into either the primary
* or the logical partition list of the given disk.
* The lists are kept sorted by increasing order of start sectors.
* Of course no disk region should overlap at all with one another.
*/
static
BOOLEAN
InsertDiskRegion(
IN PDISKENTRY DiskEntry,
IN PPARTENTRY PartEntry,
IN BOOLEAN LogicalPartition)
{
PLIST_ENTRY List;
PLIST_ENTRY Entry;
PPARTENTRY PartEntry2;
/* Use the correct partition list */
if (LogicalPartition)
List = &DiskEntry->LogicalPartListHead;
else
List = &DiskEntry->PrimaryPartListHead;
/* Find the first disk region before which we need to insert the new one */
for (Entry = List->Flink; Entry != List; Entry = Entry->Flink)
{
PartEntry2 = CONTAINING_RECORD(Entry, PARTENTRY, ListEntry);
/* Ignore any unused empty region */
if ((PartEntry2->PartitionType == PARTITION_ENTRY_UNUSED &&
PartEntry2->StartSector.QuadPart == 0) || PartEntry2->SectorCount.QuadPart == 0)
{
continue;
}
/* If the current region ends before the one to be inserted, try again */
if (PartEntry2->StartSector.QuadPart + PartEntry2->SectorCount.QuadPart - 1 < PartEntry->StartSector.QuadPart)
continue;
/*
* One of the disk region boundaries crosses the desired region
* (it starts after the desired region, or ends before the end
* of the desired region): this is an impossible situation because
* disk regions (partitions) cannot overlap!
* Throw an error and bail out.
*/
if (max(PartEntry->StartSector.QuadPart, PartEntry2->StartSector.QuadPart)
<=
min( PartEntry->StartSector.QuadPart + PartEntry->SectorCount.QuadPart - 1,
PartEntry2->StartSector.QuadPart + PartEntry2->SectorCount.QuadPart - 1))
{
DPRINT1("Disk region overlap problem, stopping there!\n"
"Partition to be inserted:\n"
" StartSector = %I64u ; EndSector = %I64u\n"
"Existing disk region:\n"
" StartSector = %I64u ; EndSector = %I64u\n",
PartEntry->StartSector.QuadPart,
PartEntry->StartSector.QuadPart + PartEntry->SectorCount.QuadPart - 1,
PartEntry2->StartSector.QuadPart,
PartEntry2->StartSector.QuadPart + PartEntry2->SectorCount.QuadPart - 1);
return FALSE;
}
/* We have found the first region before which the new one has to be inserted */
break;
}
/* Insert the disk region */
InsertTailList(Entry, &PartEntry->ListEntry);
return TRUE;
}
static
PPARTENTRY
CreateInsertBlankRegion(
IN PDISKENTRY DiskEntry,
IN OUT PLIST_ENTRY ListHead,
IN ULONGLONG StartSector,
IN ULONGLONG SectorCount,
IN BOOLEAN LogicalSpace)
{
PPARTENTRY NewPartEntry;
NewPartEntry = RtlAllocateHeap(ProcessHeap,
HEAP_ZERO_MEMORY,
sizeof(PARTENTRY));
if (NewPartEntry == NULL)
return NULL;
NewPartEntry->DiskEntry = DiskEntry;
NewPartEntry->StartSector.QuadPart = StartSector;
NewPartEntry->SectorCount.QuadPart = SectorCount;
NewPartEntry->LogicalPartition = LogicalSpace;
NewPartEntry->IsPartitioned = FALSE;
NewPartEntry->PartitionType = PARTITION_ENTRY_UNUSED;
NewPartEntry->FormatState = Unformatted;
NewPartEntry->FileSystem[0] = L'\0';
DPRINT1("First Sector : %I64u\n", NewPartEntry->StartSector.QuadPart);
DPRINT1("Last Sector : %I64u\n", NewPartEntry->StartSector.QuadPart + NewPartEntry->SectorCount.QuadPart - 1);
DPRINT1("Total Sectors: %I64u\n", NewPartEntry->SectorCount.QuadPart);
/* Insert the new entry into the list */
InsertTailList(ListHead, &NewPartEntry->ListEntry);
return NewPartEntry;
}
static
BOOLEAN
InitializePartitionEntry(
IN OUT PPARTENTRY PartEntry,
IN ULONGLONG SectorCount,
IN BOOLEAN AutoCreate)
{
PDISKENTRY DiskEntry = PartEntry->DiskEntry;
DPRINT1("Current partition sector count: %I64u\n", PartEntry->SectorCount.QuadPart);
/* Fail if we try to initialize this partition entry with more sectors than what it actually contains */
if (SectorCount > PartEntry->SectorCount.QuadPart)
return FALSE;
/* Fail if the partition is already in use */
ASSERT(!PartEntry->IsPartitioned);
if ((AutoCreate != FALSE) ||
(AlignDown(PartEntry->StartSector.QuadPart + SectorCount, DiskEntry->SectorAlignment) -
PartEntry->StartSector.QuadPart == PartEntry->SectorCount.QuadPart))
{
PartEntry->AutoCreate = AutoCreate;
}
else
{
ULONGLONG StartSector;
ULONGLONG SectorCount2;
PPARTENTRY NewPartEntry;
/* Create a partition entry that represents the remaining space after the partition to be initialized */
StartSector = AlignDown(PartEntry->StartSector.QuadPart + SectorCount, DiskEntry->SectorAlignment);
SectorCount2 = PartEntry->StartSector.QuadPart + PartEntry->SectorCount.QuadPart - StartSector;
NewPartEntry = CreateInsertBlankRegion(DiskEntry,
PartEntry->ListEntry.Flink,
StartSector,
SectorCount2,
PartEntry->LogicalPartition);
if (NewPartEntry == NULL)
{
DPRINT1("Failed to create a new empty region for disk space!\n");
return FALSE;
}
/* Resize down the partition entry; its StartSector remains the same */
PartEntry->SectorCount.QuadPart = StartSector - PartEntry->StartSector.QuadPart;
}
/* Convert the partition entry to 'New (Unformatted)' */
PartEntry->New = TRUE;
PartEntry->IsPartitioned = TRUE;
// FIXME: Use FileSystemToMBRPartitionType() only for MBR, otherwise use PARTITION_BASIC_DATA_GUID.
PartEntry->PartitionType = FileSystemToMBRPartitionType(L"RAW",
PartEntry->StartSector.QuadPart,
PartEntry->SectorCount.QuadPart);
ASSERT(PartEntry->PartitionType != PARTITION_ENTRY_UNUSED);
PartEntry->FormatState = Unformatted;
PartEntry->FileSystem[0] = L'\0';
// PartEntry->AutoCreate = AutoCreate;
PartEntry->BootIndicator = FALSE;
DPRINT1("First Sector : %I64u\n", PartEntry->StartSector.QuadPart);
DPRINT1("Last Sector : %I64u\n", PartEntry->StartSector.QuadPart + PartEntry->SectorCount.QuadPart - 1);
DPRINT1("Total Sectors: %I64u\n", PartEntry->SectorCount.QuadPart);
return TRUE;
}
static
VOID
AddPartitionToDisk(
IN ULONG DiskNumber,
IN PDISKENTRY DiskEntry,
IN ULONG PartitionIndex,
IN BOOLEAN LogicalPartition)
{
NTSTATUS Status;
PPARTITION_INFORMATION PartitionInfo;
PPARTENTRY PartEntry;
HANDLE PartitionHandle;
OBJECT_ATTRIBUTES ObjectAttributes;
IO_STATUS_BLOCK IoStatusBlock;
WCHAR PathBuffer[MAX_PATH];
UNICODE_STRING Name;
UCHAR LabelBuffer[sizeof(FILE_FS_VOLUME_INFORMATION) + 256 * sizeof(WCHAR)];
PFILE_FS_VOLUME_INFORMATION LabelInfo = (PFILE_FS_VOLUME_INFORMATION)LabelBuffer;
PartitionInfo = &DiskEntry->LayoutBuffer->PartitionEntry[PartitionIndex];
if (PartitionInfo->PartitionType == PARTITION_ENTRY_UNUSED ||
((LogicalPartition != FALSE) && IsContainerPartition(PartitionInfo->PartitionType)))
{
return;
}
PartEntry = RtlAllocateHeap(ProcessHeap,
HEAP_ZERO_MEMORY,
sizeof(PARTENTRY));
if (PartEntry == NULL)
return;
PartEntry->DiskEntry = DiskEntry;
PartEntry->StartSector.QuadPart = (ULONGLONG)PartitionInfo->StartingOffset.QuadPart / DiskEntry->BytesPerSector;
PartEntry->SectorCount.QuadPart = (ULONGLONG)PartitionInfo->PartitionLength.QuadPart / DiskEntry->BytesPerSector;
PartEntry->BootIndicator = PartitionInfo->BootIndicator;
PartEntry->PartitionType = PartitionInfo->PartitionType;
PartEntry->LogicalPartition = LogicalPartition;
PartEntry->IsPartitioned = TRUE;
PartEntry->OnDiskPartitionNumber = PartitionInfo->PartitionNumber;
PartEntry->PartitionNumber = PartitionInfo->PartitionNumber;
PartEntry->PartitionIndex = PartitionIndex;
/* Specify the partition as initially unformatted */
PartEntry->FormatState = Unformatted;
PartEntry->FileSystem[0] = L'\0';
/* Initialize the partition volume label */
RtlZeroMemory(PartEntry->VolumeLabel, sizeof(PartEntry->VolumeLabel));
if (IsContainerPartition(PartEntry->PartitionType))
{
PartEntry->FormatState = Unformatted;
if (LogicalPartition == FALSE && DiskEntry->ExtendedPartition == NULL)
DiskEntry->ExtendedPartition = PartEntry;
}
else if (IsRecognizedPartition(PartEntry->PartitionType))
{
ASSERT(PartitionInfo->RecognizedPartition);
ASSERT(PartEntry->IsPartitioned && PartEntry->PartitionNumber != 0);
/* Try to open the volume so as to mount it */
RtlStringCchPrintfW(PathBuffer, ARRAYSIZE(PathBuffer),
L"\\Device\\Harddisk%lu\\Partition%lu",
DiskEntry->DiskNumber,
PartEntry->PartitionNumber);
RtlInitUnicodeString(&Name, PathBuffer);
InitializeObjectAttributes(&ObjectAttributes,
&Name,
OBJ_CASE_INSENSITIVE,
NULL,
NULL);
PartitionHandle = NULL;
Status = NtOpenFile(&PartitionHandle,
FILE_READ_DATA | SYNCHRONIZE,
&ObjectAttributes,
&IoStatusBlock,
FILE_SHARE_READ | FILE_SHARE_WRITE,
FILE_SYNCHRONOUS_IO_NONALERT);
if (!NT_SUCCESS(Status))
{
DPRINT1("NtOpenFile() failed, Status 0x%08lx\n", Status);
}
if (PartitionHandle)
{
ASSERT(NT_SUCCESS(Status));
/* We don't have a FS, try to guess one */
Status = InferFileSystem(NULL, PartitionHandle,
PartEntry->FileSystem,
sizeof(PartEntry->FileSystem));
if (!NT_SUCCESS(Status))
DPRINT1("InferFileSystem() failed, Status 0x%08lx\n", Status);
}
if (*PartEntry->FileSystem)
{
ASSERT(PartitionHandle);
/*
* Handle partition mounted with RawFS: it is
* either unformatted or has an unknown format.
*/
if (wcsicmp(PartEntry->FileSystem, L"RAW") == 0)
{
/*
* True unformatted partitions on NT are created with their
* partition type set to either one of the following values,
* and are mounted with RawFS. This is done this way since we
* are assured to have FAT support, which is the only FS that
* uses these partition types. Therefore, having a partition
* mounted with RawFS and with these partition types means that
* the FAT FS was unable to mount it beforehand and thus the
* partition is unformatted.
* However, any partition mounted by RawFS that does NOT have
* any of these partition types must be considered as having
* an unknown format.
*/
if (PartEntry->PartitionType == PARTITION_FAT_12 ||
PartEntry->PartitionType == PARTITION_FAT_16 ||
PartEntry->PartitionType == PARTITION_HUGE ||
PartEntry->PartitionType == PARTITION_XINT13 ||
PartEntry->PartitionType == PARTITION_FAT32 ||
PartEntry->PartitionType == PARTITION_FAT32_XINT13)
{
PartEntry->FormatState = Unformatted;
}
else
{
/* Close the partition before dismounting */
NtClose(PartitionHandle);
PartitionHandle = NULL;
/*
* Dismount the partition since RawFS owns it, and set its
* format to unknown (may or may not be actually formatted).
*/
DismountVolume(PartEntry);
PartEntry->FormatState = UnknownFormat;
PartEntry->FileSystem[0] = L'\0';
}
}
else
{
PartEntry->FormatState = Preformatted;
}
}
else
{
PartEntry->FormatState = UnknownFormat;
}
/* Retrieve the partition volume label */
if (PartitionHandle)
{
Status = NtQueryVolumeInformationFile(PartitionHandle,
&IoStatusBlock,
&LabelBuffer,
sizeof(LabelBuffer),
FileFsVolumeInformation);
if (NT_SUCCESS(Status))
{
/* Copy the (possibly truncated) volume label and NULL-terminate it */
RtlStringCbCopyNW(PartEntry->VolumeLabel, sizeof(PartEntry->VolumeLabel),
LabelInfo->VolumeLabel, LabelInfo->VolumeLabelLength);
}
else
{
DPRINT1("NtQueryVolumeInformationFile() failed, Status 0x%08lx\n", Status);
}
}
/* Close the partition */
if (PartitionHandle)
NtClose(PartitionHandle);
}
else
{
/* Unknown partition, hence unknown format (may or may not be actually formatted) */
PartEntry->FormatState = UnknownFormat;
}
InsertDiskRegion(DiskEntry, PartEntry, LogicalPartition);
}
static
VOID
ScanForUnpartitionedDiskSpace(
IN PDISKENTRY DiskEntry)
{
ULONGLONG StartSector;
ULONGLONG SectorCount;
ULONGLONG LastStartSector;
ULONGLONG LastSectorCount;
ULONGLONG LastUnusedSectorCount;
PPARTENTRY PartEntry;
PPARTENTRY NewPartEntry;
PLIST_ENTRY Entry;
DPRINT("ScanForUnpartitionedDiskSpace()\n");
if (IsListEmpty(&DiskEntry->PrimaryPartListHead))
{
DPRINT1("No primary partition!\n");
/* Create a partition entry that represents the empty disk */
if (DiskEntry->SectorAlignment < 2048)
StartSector = 2048ULL;
else
StartSector = (ULONGLONG)DiskEntry->SectorAlignment;
SectorCount = AlignDown(DiskEntry->SectorCount.QuadPart, DiskEntry->SectorAlignment) - StartSector;
NewPartEntry = CreateInsertBlankRegion(DiskEntry,
&DiskEntry->PrimaryPartListHead,
StartSector,
SectorCount,
FALSE);
if (NewPartEntry == NULL)
DPRINT1("Failed to create a new empty region for full disk space!\n");
return;
}
/* Start partition at head 1, cylinder 0 */
if (DiskEntry->SectorAlignment < 2048)
LastStartSector = 2048ULL;
else
LastStartSector = (ULONGLONG)DiskEntry->SectorAlignment;
LastSectorCount = 0ULL;
LastUnusedSectorCount = 0ULL;
for (Entry = DiskEntry->PrimaryPartListHead.Flink;
Entry != &DiskEntry->PrimaryPartListHead;
Entry = Entry->Flink)
{
PartEntry = CONTAINING_RECORD(Entry, PARTENTRY, ListEntry);
if (PartEntry->PartitionType != PARTITION_ENTRY_UNUSED ||
PartEntry->SectorCount.QuadPart != 0ULL)
{
LastUnusedSectorCount =
PartEntry->StartSector.QuadPart - (LastStartSector + LastSectorCount);
if (PartEntry->StartSector.QuadPart > (LastStartSector + LastSectorCount) &&
LastUnusedSectorCount >= (ULONGLONG)DiskEntry->SectorAlignment)
{
DPRINT("Unpartitioned disk space %I64u sectors\n", LastUnusedSectorCount);
StartSector = LastStartSector + LastSectorCount;
SectorCount = AlignDown(StartSector + LastUnusedSectorCount, DiskEntry->SectorAlignment) - StartSector;
/* Insert the table into the list */
NewPartEntry = CreateInsertBlankRegion(DiskEntry,
&PartEntry->ListEntry,
StartSector,
SectorCount,
FALSE);
if (NewPartEntry == NULL)
{
DPRINT1("Failed to create a new empty region for disk space!\n");
return;
}
}
LastStartSector = PartEntry->StartSector.QuadPart;
LastSectorCount = PartEntry->SectorCount.QuadPart;
}
}
/* Check for trailing unpartitioned disk space */
if ((LastStartSector + LastSectorCount) < DiskEntry->SectorCount.QuadPart)
{
LastUnusedSectorCount = AlignDown(DiskEntry->SectorCount.QuadPart - (LastStartSector + LastSectorCount), DiskEntry->SectorAlignment);
if (LastUnusedSectorCount >= (ULONGLONG)DiskEntry->SectorAlignment)
{
DPRINT("Unpartitioned disk space: %I64u sectors\n", LastUnusedSectorCount);
StartSector = LastStartSector + LastSectorCount;
SectorCount = AlignDown(StartSector + LastUnusedSectorCount, DiskEntry->SectorAlignment) - StartSector;
/* Append the table to the list */
NewPartEntry = CreateInsertBlankRegion(DiskEntry,
&DiskEntry->PrimaryPartListHead,
StartSector,
SectorCount,
FALSE);
if (NewPartEntry == NULL)
{
DPRINT1("Failed to create a new empty region for trailing disk space!\n");
return;
}
}
}
if (DiskEntry->ExtendedPartition != NULL)
{
if (IsListEmpty(&DiskEntry->LogicalPartListHead))
{
DPRINT1("No logical partition!\n");
/* Create a partition entry that represents the empty extended partition */
StartSector = DiskEntry->ExtendedPartition->StartSector.QuadPart + (ULONGLONG)DiskEntry->SectorAlignment;
SectorCount = DiskEntry->ExtendedPartition->SectorCount.QuadPart - (ULONGLONG)DiskEntry->SectorAlignment;
NewPartEntry = CreateInsertBlankRegion(DiskEntry,
&DiskEntry->LogicalPartListHead,
StartSector,
SectorCount,
TRUE);
if (NewPartEntry == NULL)
{
DPRINT1("Failed to create a new empty region for full extended partition space!\n");
return;
}
return;
}
/* Start partition at head 1, cylinder 0 */
LastStartSector = DiskEntry->ExtendedPartition->StartSector.QuadPart + (ULONGLONG)DiskEntry->SectorAlignment;
LastSectorCount = 0ULL;
LastUnusedSectorCount = 0ULL;
for (Entry = DiskEntry->LogicalPartListHead.Flink;
Entry != &DiskEntry->LogicalPartListHead;
Entry = Entry->Flink)
{
PartEntry = CONTAINING_RECORD(Entry, PARTENTRY, ListEntry);
if (PartEntry->PartitionType != PARTITION_ENTRY_UNUSED ||
PartEntry->SectorCount.QuadPart != 0ULL)
{
LastUnusedSectorCount =
PartEntry->StartSector.QuadPart - (ULONGLONG)DiskEntry->SectorAlignment - (LastStartSector + LastSectorCount);
if ((PartEntry->StartSector.QuadPart - (ULONGLONG)DiskEntry->SectorAlignment) > (LastStartSector + LastSectorCount) &&
LastUnusedSectorCount >= (ULONGLONG)DiskEntry->SectorAlignment)
{
DPRINT("Unpartitioned disk space %I64u sectors\n", LastUnusedSectorCount);
StartSector = LastStartSector + LastSectorCount;
SectorCount = AlignDown(StartSector + LastUnusedSectorCount, DiskEntry->SectorAlignment) - StartSector;
/* Insert the table into the list */
NewPartEntry = CreateInsertBlankRegion(DiskEntry,
&PartEntry->ListEntry,
StartSector,
SectorCount,
TRUE);
if (NewPartEntry == NULL)
{
DPRINT1("Failed to create a new empty region for extended partition space!\n");
return;
}
}
LastStartSector = PartEntry->StartSector.QuadPart;
LastSectorCount = PartEntry->SectorCount.QuadPart;
}
}
/* Check for trailing unpartitioned disk space */
if ((LastStartSector + LastSectorCount) < DiskEntry->ExtendedPartition->StartSector.QuadPart + DiskEntry->ExtendedPartition->SectorCount.QuadPart)
{
LastUnusedSectorCount = AlignDown(DiskEntry->ExtendedPartition->StartSector.QuadPart +
DiskEntry->ExtendedPartition->SectorCount.QuadPart - (LastStartSector + LastSectorCount),
DiskEntry->SectorAlignment);
if (LastUnusedSectorCount >= (ULONGLONG)DiskEntry->SectorAlignment)
{
DPRINT("Unpartitioned disk space: %I64u sectors\n", LastUnusedSectorCount);
StartSector = LastStartSector + LastSectorCount;
SectorCount = AlignDown(StartSector + LastUnusedSectorCount, DiskEntry->SectorAlignment) - StartSector;
/* Append the table to the list */
NewPartEntry = CreateInsertBlankRegion(DiskEntry,
&DiskEntry->LogicalPartListHead,
StartSector,
SectorCount,
TRUE);
if (NewPartEntry == NULL)
{
DPRINT1("Failed to create a new empty region for extended partition space!\n");
return;
}
}
}
}
DPRINT("ScanForUnpartitionedDiskSpace() done\n");
}
static
VOID
SetDiskSignature(
IN PPARTLIST List,
IN PDISKENTRY DiskEntry)
{
LARGE_INTEGER SystemTime;
TIME_FIELDS TimeFields;
PLIST_ENTRY Entry2;
PDISKENTRY DiskEntry2;
PUCHAR Buffer;
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT("GPT-partitioned disk detected, not currently supported by SETUP!\n");
return;
}
Buffer = (PUCHAR)&DiskEntry->LayoutBuffer->Signature;
while (TRUE)
{
NtQuerySystemTime(&SystemTime);
RtlTimeToTimeFields(&SystemTime, &TimeFields);
Buffer[0] = (UCHAR)(TimeFields.Year & 0xFF) + (UCHAR)(TimeFields.Hour & 0xFF);
Buffer[1] = (UCHAR)(TimeFields.Year >> 8) + (UCHAR)(TimeFields.Minute & 0xFF);
Buffer[2] = (UCHAR)(TimeFields.Month & 0xFF) + (UCHAR)(TimeFields.Second & 0xFF);
Buffer[3] = (UCHAR)(TimeFields.Day & 0xFF) + (UCHAR)(TimeFields.Milliseconds & 0xFF);
if (DiskEntry->LayoutBuffer->Signature == 0)
{
continue;
}
/* Check if the signature already exist */
/* FIXME:
* Check also signatures from disks, which are
* not visible (bootable) by the bios.
*/
for (Entry2 = List->DiskListHead.Flink;
Entry2 != &List->DiskListHead;
Entry2 = Entry2->Flink)
{
DiskEntry2 = CONTAINING_RECORD(Entry2, DISKENTRY, ListEntry);
if (DiskEntry2->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT("GPT-partitioned disk detected, not currently supported by SETUP!\n");
continue;
}
if (DiskEntry != DiskEntry2 &&
DiskEntry->LayoutBuffer->Signature == DiskEntry2->LayoutBuffer->Signature)
break;
}
if (Entry2 == &List->DiskListHead)
break;
}
}
static
VOID
UpdateDiskSignatures(
IN PPARTLIST List)
{
PLIST_ENTRY Entry;
PDISKENTRY DiskEntry;
/* Update each disk */
for (Entry = List->DiskListHead.Flink;
Entry != &List->DiskListHead;
Entry = Entry->Flink)
{
DiskEntry = CONTAINING_RECORD(Entry, DISKENTRY, ListEntry);
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT("GPT-partitioned disk detected, not currently supported by SETUP!\n");
continue;
}
if (DiskEntry->LayoutBuffer &&
DiskEntry->LayoutBuffer->Signature == 0)
{
SetDiskSignature(List, DiskEntry);
DiskEntry->LayoutBuffer->PartitionEntry[0].RewritePartition = TRUE;
}
}
}
static
VOID
UpdateHwDiskNumbers(
IN PPARTLIST List)
{
PLIST_ENTRY ListEntry;
PBIOSDISKENTRY BiosDiskEntry;
PDISKENTRY DiskEntry;
ULONG HwAdapterNumber = 0;
ULONG HwControllerNumber = 0;
ULONG RemovableDiskCount = 0;
/*
* Enumerate the disks recognized by the BIOS and recompute the disk
* numbers on the system when *ALL* removable disks are not connected.
* The entries are inserted in increasing order of AdapterNumber,
* ControllerNumber and DiskNumber.
*/
for (ListEntry = List->BiosDiskListHead.Flink;
ListEntry != &List->BiosDiskListHead;
ListEntry = ListEntry->Flink)
{
BiosDiskEntry = CONTAINING_RECORD(ListEntry, BIOSDISKENTRY, ListEntry);
DiskEntry = BiosDiskEntry->DiskEntry;
/*
* If the adapter or controller numbers change, update them and reset
* the number of removable disks on this adapter/controller.
*/
if (HwAdapterNumber != BiosDiskEntry->AdapterNumber ||
HwControllerNumber != BiosDiskEntry->ControllerNumber)
{
HwAdapterNumber = BiosDiskEntry->AdapterNumber;
HwControllerNumber = BiosDiskEntry->ControllerNumber;
RemovableDiskCount = 0;
}
/* Adjust the actual hardware disk number */
if (DiskEntry)
{
ASSERT(DiskEntry->HwDiskNumber == BiosDiskEntry->DiskNumber);
if (DiskEntry->MediaType == RemovableMedia)
{
/* Increase the number of removable disks and set the disk number to zero */
++RemovableDiskCount;
DiskEntry->HwFixedDiskNumber = 0;
}
else // if (DiskEntry->MediaType == FixedMedia)
{
/* Adjust the fixed disk number, offset by the number of removable disks found before this one */
DiskEntry->HwFixedDiskNumber = BiosDiskEntry->DiskNumber - RemovableDiskCount;
}
}
else
{
DPRINT1("BIOS disk %lu is not recognized by NTOS!\n", BiosDiskEntry->DiskNumber);
}
}
}
static
VOID
AddDiskToList(
IN HANDLE FileHandle,
IN ULONG DiskNumber,
IN PPARTLIST List)
{
DISK_GEOMETRY DiskGeometry;
SCSI_ADDRESS ScsiAddress;
PDISKENTRY DiskEntry;
IO_STATUS_BLOCK Iosb;
NTSTATUS Status;
PPARTITION_SECTOR Mbr;
PULONG Buffer;
LARGE_INTEGER FileOffset;
WCHAR Identifier[20];
ULONG Checksum;
ULONG Signature;
ULONG i;
PLIST_ENTRY ListEntry;
PBIOSDISKENTRY BiosDiskEntry;
ULONG LayoutBufferSize;
PDRIVE_LAYOUT_INFORMATION NewLayoutBuffer;
/* Retrieve the drive geometry */
Status = NtDeviceIoControlFile(FileHandle,
NULL,
NULL,
NULL,
&Iosb,
IOCTL_DISK_GET_DRIVE_GEOMETRY,
NULL,
0,
&DiskGeometry,
sizeof(DiskGeometry));
if (!NT_SUCCESS(Status))
return;
if (DiskGeometry.MediaType != FixedMedia &&
DiskGeometry.MediaType != RemovableMedia)
{
return;
}
/*
* FIXME: Here we suppose the disk is always SCSI. What if it is
* of another type? To check this we need to retrieve the name of
* the driver the disk device belongs to.
*/
Status = NtDeviceIoControlFile(FileHandle,
NULL,
NULL,
NULL,
&Iosb,
IOCTL_SCSI_GET_ADDRESS,
NULL,
0,
&ScsiAddress,
sizeof(ScsiAddress));
if (!NT_SUCCESS(Status))
return;
/*
* Check whether the disk is initialized, by looking at its MBR.
* NOTE that this must be generalized to GPT disks as well!
*/
Mbr = (PARTITION_SECTOR*)RtlAllocateHeap(ProcessHeap,
0,
DiskGeometry.BytesPerSector);
if (Mbr == NULL)
return;
FileOffset.QuadPart = 0;
Status = NtReadFile(FileHandle,
NULL,
NULL,
NULL,
&Iosb,
(PVOID)Mbr,
DiskGeometry.BytesPerSector,
&FileOffset,
NULL);
if (!NT_SUCCESS(Status))
{
RtlFreeHeap(ProcessHeap, 0, Mbr);
DPRINT1("NtReadFile failed, status=%x\n", Status);
return;
}
Signature = Mbr->Signature;
/* Calculate the MBR checksum */
Checksum = 0;
Buffer = (PULONG)Mbr;
for (i = 0; i < 128; i++)
{
Checksum += Buffer[i];
}
Checksum = ~Checksum + 1;
RtlStringCchPrintfW(Identifier, ARRAYSIZE(Identifier),
L"%08x-%08x-%c",
Checksum, Signature,
(Mbr->Magic == PARTITION_MAGIC) ? L'A' : L'X');
DPRINT("Identifier: %S\n", Identifier);
DiskEntry = RtlAllocateHeap(ProcessHeap,
HEAP_ZERO_MEMORY,
sizeof(DISKENTRY));
if (DiskEntry == NULL)
{
RtlFreeHeap(ProcessHeap, 0, Mbr);
DPRINT1("Failed to allocate a new disk entry.\n");
return;
}
DiskEntry->PartList = List;
#if 0
{
FILE_FS_DEVICE_INFORMATION FileFsDevice;
/* Query the device for its type */
Status = NtQueryVolumeInformationFile(FileHandle,
&Iosb,
&FileFsDevice,
sizeof(FileFsDevice),
FileFsDeviceInformation);
if (!NT_SUCCESS(Status))
{
DPRINT1("Couldn't detect device type for disk %lu of identifier '%S'...\n", DiskNumber, Identifier);
}
else
{
DPRINT1("Disk %lu : DeviceType: 0x%08x ; Characteristics: 0x%08x\n", DiskNumber, FileFsDevice.DeviceType, FileFsDevice.Characteristics);
}
}
// NOTE: We may also use NtQueryVolumeInformationFile(FileFsDeviceInformation).
#endif
DiskEntry->MediaType = DiskGeometry.MediaType;
if (DiskEntry->MediaType == RemovableMedia)
{
DPRINT1("Disk %lu of identifier '%S' is removable\n", DiskNumber, Identifier);
}
else // if (DiskEntry->MediaType == FixedMedia)
{
DPRINT1("Disk %lu of identifier '%S' is fixed\n", DiskNumber, Identifier);
}
// DiskEntry->Checksum = Checksum;
// DiskEntry->Signature = Signature;
DiskEntry->BiosFound = FALSE;
/*
* Check if this disk has a valid MBR: verify its signature,
* and whether its two first bytes are a valid instruction
* (related to this, see IsThereAValidBootSector() in partlist.c).
*
* See also ntoskrnl/fstub/fstubex.c!FstubDetectPartitionStyle().
*/
// DiskEntry->NoMbr = (Mbr->Magic != PARTITION_MAGIC || (*(PUSHORT)Mbr->BootCode) == 0x0000);
/* If we have not the 0xAA55 then it's raw partition */
if (Mbr->Magic != PARTITION_MAGIC)
{
DiskEntry->DiskStyle = PARTITION_STYLE_RAW;
}
/* Check partitions types: if first is 0xEE and all the others 0, we have GPT */
else if (Mbr->Partition[0].PartitionType == EFI_PMBR_OSTYPE_EFI &&
Mbr->Partition[1].PartitionType == 0 &&
Mbr->Partition[2].PartitionType == 0 &&
Mbr->Partition[3].PartitionType == 0)
{
DiskEntry->DiskStyle = PARTITION_STYLE_GPT;
}
/* Otherwise, partition table is in MBR */
else
{
DiskEntry->DiskStyle = PARTITION_STYLE_MBR;
}
/* Free the MBR sector buffer */
RtlFreeHeap(ProcessHeap, 0, Mbr);
for (ListEntry = List->BiosDiskListHead.Flink;
ListEntry != &List->BiosDiskListHead;
ListEntry = ListEntry->Flink)
{
BiosDiskEntry = CONTAINING_RECORD(ListEntry, BIOSDISKENTRY, ListEntry);
/* FIXME:
* Compare the size from bios and the reported size from driver.
* If we have more than one disk with a zero or with the same signature
* we must create new signatures and reboot. After the reboot,
* it is possible to identify the disks.
*/
if (BiosDiskEntry->Signature == Signature &&
BiosDiskEntry->Checksum == Checksum &&
BiosDiskEntry->DiskEntry == NULL)
{
if (!DiskEntry->BiosFound)
{
DiskEntry->HwAdapterNumber = BiosDiskEntry->AdapterNumber;
DiskEntry->HwControllerNumber = BiosDiskEntry->ControllerNumber;
DiskEntry->HwDiskNumber = BiosDiskEntry->DiskNumber;
if (DiskEntry->MediaType == RemovableMedia)
{
/* Set the removable disk number to zero */
DiskEntry->HwFixedDiskNumber = 0;
}
else // if (DiskEntry->MediaType == FixedMedia)
{
/* The fixed disk number will later be adjusted using the number of removable disks */
DiskEntry->HwFixedDiskNumber = BiosDiskEntry->DiskNumber;
}
DiskEntry->BiosFound = TRUE;
BiosDiskEntry->DiskEntry = DiskEntry;
break;
}
else
{
// FIXME: What to do?
DPRINT1("Disk %lu of identifier '%S' has already been found?!\n", DiskNumber, Identifier);
}
}
}
if (!DiskEntry->BiosFound)
{
DPRINT1("WARNING: Setup could not find a matching BIOS disk entry. Disk %lu may not be bootable by the BIOS!\n", DiskNumber);
}
DiskEntry->Cylinders = DiskGeometry.Cylinders.QuadPart;
DiskEntry->TracksPerCylinder = DiskGeometry.TracksPerCylinder;
DiskEntry->SectorsPerTrack = DiskGeometry.SectorsPerTrack;
DiskEntry->BytesPerSector = DiskGeometry.BytesPerSector;
DPRINT("Cylinders %I64u\n", DiskEntry->Cylinders);
DPRINT("TracksPerCylinder %lu\n", DiskEntry->TracksPerCylinder);
DPRINT("SectorsPerTrack %lu\n", DiskEntry->SectorsPerTrack);
DPRINT("BytesPerSector %lu\n", DiskEntry->BytesPerSector);
DiskEntry->SectorCount.QuadPart = DiskGeometry.Cylinders.QuadPart *
(ULONGLONG)DiskGeometry.TracksPerCylinder *
(ULONGLONG)DiskGeometry.SectorsPerTrack;
DiskEntry->SectorAlignment = DiskGeometry.SectorsPerTrack;
DiskEntry->CylinderAlignment = DiskGeometry.TracksPerCylinder *
DiskGeometry.SectorsPerTrack;
DPRINT("SectorCount %I64u\n", DiskEntry->SectorCount.QuadPart);
DPRINT("SectorAlignment %lu\n", DiskEntry->SectorAlignment);
DiskEntry->DiskNumber = DiskNumber;
DiskEntry->Port = ScsiAddress.PortNumber;
DiskEntry->Bus = ScsiAddress.PathId;
DiskEntry->Id = ScsiAddress.TargetId;
GetDriverName(DiskEntry);
/*
* Actually it would be more correct somehow to use:
*
* OBJECT_NAME_INFORMATION NameInfo; // ObjectNameInfo;
* ULONG ReturnedLength;
*
* Status = NtQueryObject(SomeHandleToTheDisk,
* ObjectNameInformation,
* &NameInfo,
* sizeof(NameInfo),
* &ReturnedLength);
* etc...
*
* See examples in https://git.reactos.org/?p=reactos.git;a=blob;f=reactos/ntoskrnl/io/iomgr/error.c;hb=2f3a93ee9cec8322a86bf74b356f1ad83fc912dc#l267
*/
InitializeListHead(&DiskEntry->PrimaryPartListHead);
InitializeListHead(&DiskEntry->LogicalPartListHead);
InsertAscendingList(&List->DiskListHead, DiskEntry, DISKENTRY, ListEntry, DiskNumber);
/*
* We now retrieve the disk partition layout
*/
/*
* Stop there now if the disk is GPT-partitioned,
* since we currently do not support such disks.
*/
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT1("GPT-partitioned disk detected, not currently supported by SETUP!\n");
return;
}
/* Allocate a layout buffer with 4 partition entries first */
LayoutBufferSize = sizeof(DRIVE_LAYOUT_INFORMATION) +
((4 - ANYSIZE_ARRAY) * sizeof(PARTITION_INFORMATION));
DiskEntry->LayoutBuffer = RtlAllocateHeap(ProcessHeap,
HEAP_ZERO_MEMORY,
LayoutBufferSize);
if (DiskEntry->LayoutBuffer == NULL)
{
DPRINT1("Failed to allocate the disk layout buffer!\n");
return;
}
/* Keep looping while the drive layout buffer is too small */
for (;;)
{
DPRINT1("Buffer size: %lu\n", LayoutBufferSize);
Status = NtDeviceIoControlFile(FileHandle,
NULL,
NULL,
NULL,
&Iosb,
IOCTL_DISK_GET_DRIVE_LAYOUT,
NULL,
0,
DiskEntry->LayoutBuffer,
LayoutBufferSize);
if (NT_SUCCESS(Status))
break;
if (Status != STATUS_BUFFER_TOO_SMALL)
{
DPRINT1("NtDeviceIoControlFile() failed (Status: 0x%08lx)\n", Status);
return;
}
LayoutBufferSize += 4 * sizeof(PARTITION_INFORMATION);
NewLayoutBuffer = RtlReAllocateHeap(ProcessHeap,
HEAP_ZERO_MEMORY,
DiskEntry->LayoutBuffer,
LayoutBufferSize);
if (NewLayoutBuffer == NULL)
{
DPRINT1("Failed to reallocate the disk layout buffer!\n");
return;
}
DiskEntry->LayoutBuffer = NewLayoutBuffer;
}
DPRINT1("PartitionCount: %lu\n", DiskEntry->LayoutBuffer->PartitionCount);
#ifdef DUMP_PARTITION_TABLE
DumpPartitionTable(DiskEntry);
#endif
if (IsSuperFloppy(DiskEntry))
DPRINT1("Disk %lu is a super-floppy\n", DiskNumber);
if (DiskEntry->LayoutBuffer->PartitionEntry[0].StartingOffset.QuadPart != 0 &&
DiskEntry->LayoutBuffer->PartitionEntry[0].PartitionLength.QuadPart != 0 &&
DiskEntry->LayoutBuffer->PartitionEntry[0].PartitionType != PARTITION_ENTRY_UNUSED)
{
if ((DiskEntry->LayoutBuffer->PartitionEntry[0].StartingOffset.QuadPart / DiskEntry->BytesPerSector) % DiskEntry->SectorsPerTrack == 0)
{
DPRINT("Use %lu Sector alignment!\n", DiskEntry->SectorsPerTrack);
}
else if (DiskEntry->LayoutBuffer->PartitionEntry[0].StartingOffset.QuadPart % (1024 * 1024) == 0)
{
DPRINT1("Use megabyte (%lu Sectors) alignment!\n", (1024 * 1024) / DiskEntry->BytesPerSector);
}
else
{
DPRINT1("No matching alignment found! Partition 1 starts at %I64u\n", DiskEntry->LayoutBuffer->PartitionEntry[0].StartingOffset.QuadPart);
}
}
else
{
DPRINT1("No valid partition table found! Use megabyte (%lu Sectors) alignment!\n", (1024 * 1024) / DiskEntry->BytesPerSector);
}
if (DiskEntry->LayoutBuffer->PartitionCount == 0)
{
DiskEntry->NewDisk = TRUE;
DiskEntry->LayoutBuffer->PartitionCount = 4;
for (i = 0; i < 4; i++)
{
DiskEntry->LayoutBuffer->PartitionEntry[i].RewritePartition = TRUE;
}
}
else
{
/* Enumerate and add the first four primary partitions */
for (i = 0; i < 4; i++)
{
AddPartitionToDisk(DiskNumber, DiskEntry, i, FALSE);
}
/* Enumerate and add the remaining partitions as logical ones */
for (i = 4; i < DiskEntry->LayoutBuffer->PartitionCount; i += 4)
{
AddPartitionToDisk(DiskNumber, DiskEntry, i, TRUE);
}
}
ScanForUnpartitionedDiskSpace(DiskEntry);
}
/*
* Retrieve the system disk, i.e. the fixed disk that is accessible by the
* firmware during boot time and where the system partition resides.
* If no system partition has been determined, we retrieve the first disk
* that verifies the mentioned criteria above.
*/
static
PDISKENTRY
GetSystemDisk(
IN PPARTLIST List)
{
PLIST_ENTRY Entry;
PDISKENTRY DiskEntry;
/* Check for empty disk list */
if (IsListEmpty(&List->DiskListHead))
return NULL;
/*
* If we already have a system partition, the system disk
* is the one on which the system partition resides.
*/
if (List->SystemPartition)
return List->SystemPartition->DiskEntry;
/* Loop over the disks and find the correct one */
for (Entry = List->DiskListHead.Flink;
Entry != &List->DiskListHead;
Entry = Entry->Flink)
{
DiskEntry = CONTAINING_RECORD(Entry, DISKENTRY, ListEntry);
/* The disk must be a fixed disk and be found by the firmware */
if (DiskEntry->MediaType == FixedMedia && DiskEntry->BiosFound)
{
break;
}
}
if (Entry == &List->DiskListHead)
{
/* We haven't encountered any suitable disk */
return NULL;
}
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT1("System disk -- GPT-partitioned disk detected, not currently supported by SETUP!\n");
}
return DiskEntry;
}
/*
* Retrieve the actual "active" partition of the given disk.
* On MBR disks, partition with the Active/Boot flag set;
* on GPT disks, partition with the correct GUID.
*/
BOOLEAN
IsPartitionActive(
IN PPARTENTRY PartEntry)
{
// TODO: Support for GPT disks!
if (IsContainerPartition(PartEntry->PartitionType))
return FALSE;
/* Check if the partition is partitioned, used and active */
if (PartEntry->IsPartitioned &&
// !IsContainerPartition(PartEntry->PartitionType) &&
PartEntry->BootIndicator)
{
/* Yes it is */
ASSERT(PartEntry->PartitionType != PARTITION_ENTRY_UNUSED);
return TRUE;
}
return FALSE;
}
static
PPARTENTRY
GetActiveDiskPartition(
IN PDISKENTRY DiskEntry)
{
PLIST_ENTRY ListEntry;
PPARTENTRY PartEntry;
PPARTENTRY ActivePartition = NULL;
/* Check for empty disk list */
// ASSERT(DiskEntry);
if (!DiskEntry)
return NULL;
/* Check for empty partition list */
if (IsListEmpty(&DiskEntry->PrimaryPartListHead))
return NULL;
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT1("GPT-partitioned disk detected, not currently supported by SETUP!\n");
return NULL;
}
/* Scan all (primary) partitions to find the active disk partition */
for (ListEntry = DiskEntry->PrimaryPartListHead.Flink;
ListEntry != &DiskEntry->PrimaryPartListHead;
ListEntry = ListEntry->Flink)
{
/* Retrieve the partition */
PartEntry = CONTAINING_RECORD(ListEntry, PARTENTRY, ListEntry);
if (IsPartitionActive(PartEntry))
{
/* Yes, we've found it */
ASSERT(DiskEntry == PartEntry->DiskEntry);
ASSERT(PartEntry->IsPartitioned);
ActivePartition = PartEntry;
DPRINT1("Found active system partition %lu in disk %lu, drive letter %C\n",
PartEntry->PartitionNumber, DiskEntry->DiskNumber,
(PartEntry->DriveLetter == 0) ? L'-' : PartEntry->DriveLetter);
break;
}
}
/* Check if the disk is new and if so, use its first partition as the active system partition */
if (DiskEntry->NewDisk && ActivePartition != NULL)
{
// FIXME: What to do??
DPRINT1("NewDisk TRUE but already existing active partition?\n");
}
/* Return the active partition found (or none) */
return ActivePartition;
}
PPARTLIST
CreatePartitionList(VOID)
{
PPARTLIST List;
PDISKENTRY SystemDisk;
OBJECT_ATTRIBUTES ObjectAttributes;
SYSTEM_DEVICE_INFORMATION Sdi;
IO_STATUS_BLOCK Iosb;
ULONG ReturnSize;
NTSTATUS Status;
ULONG DiskNumber;
HANDLE FileHandle;
UNICODE_STRING Name;
WCHAR Buffer[MAX_PATH];
List = (PPARTLIST)RtlAllocateHeap(ProcessHeap,
0,
sizeof(PARTLIST));
if (List == NULL)
return NULL;
List->SystemPartition = NULL;
InitializeListHead(&List->DiskListHead);
InitializeListHead(&List->BiosDiskListHead);
/*
* Enumerate the disks seen by the BIOS; this will be used later
* to map drives seen by NTOS with their corresponding BIOS names.
*/
EnumerateBiosDiskEntries(List);
/* Enumerate disks seen by NTOS */
Status = NtQuerySystemInformation(SystemDeviceInformation,
&Sdi,
sizeof(Sdi),
&ReturnSize);
if (!NT_SUCCESS(Status))
{
DPRINT1("NtQuerySystemInformation() failed, Status 0x%08lx", Status);
RtlFreeHeap(ProcessHeap, 0, List);
return NULL;
}
for (DiskNumber = 0; DiskNumber < Sdi.NumberOfDisks; DiskNumber++)
{
RtlStringCchPrintfW(Buffer, ARRAYSIZE(Buffer),
L"\\Device\\Harddisk%lu\\Partition0",
DiskNumber);
RtlInitUnicodeString(&Name, Buffer);
InitializeObjectAttributes(&ObjectAttributes,
&Name,
OBJ_CASE_INSENSITIVE,
NULL,
NULL);
Status = NtOpenFile(&FileHandle,
FILE_READ_DATA | FILE_READ_ATTRIBUTES | SYNCHRONIZE,
&ObjectAttributes,
&Iosb,
FILE_SHARE_READ | FILE_SHARE_WRITE,
FILE_SYNCHRONOUS_IO_NONALERT);
if (NT_SUCCESS(Status))
{
AddDiskToList(FileHandle, DiskNumber, List);
NtClose(FileHandle);
}
}
UpdateDiskSignatures(List);
UpdateHwDiskNumbers(List);
AssignDriveLetters(List);
/*
* Retrieve the system partition: the active partition on the system
* disk (the one that will be booted by default by the hardware).
*/
SystemDisk = GetSystemDisk(List);
List->SystemPartition = (SystemDisk ? GetActiveDiskPartition(SystemDisk) : NULL);
return List;
}
VOID
DestroyPartitionList(
IN PPARTLIST List)
{
PDISKENTRY DiskEntry;
PBIOSDISKENTRY BiosDiskEntry;
PPARTENTRY PartEntry;
PLIST_ENTRY Entry;
/* Release disk and partition info */
while (!IsListEmpty(&List->DiskListHead))
{
Entry = RemoveHeadList(&List->DiskListHead);
DiskEntry = CONTAINING_RECORD(Entry, DISKENTRY, ListEntry);
/* Release driver name */
RtlFreeUnicodeString(&DiskEntry->DriverName);
/* Release primary partition list */
while (!IsListEmpty(&DiskEntry->PrimaryPartListHead))
{
Entry = RemoveHeadList(&DiskEntry->PrimaryPartListHead);
PartEntry = CONTAINING_RECORD(Entry, PARTENTRY, ListEntry);
RtlFreeHeap(ProcessHeap, 0, PartEntry);
}
/* Release logical partition list */
while (!IsListEmpty(&DiskEntry->LogicalPartListHead))
{
Entry = RemoveHeadList(&DiskEntry->LogicalPartListHead);
PartEntry = CONTAINING_RECORD(Entry, PARTENTRY, ListEntry);
RtlFreeHeap(ProcessHeap, 0, PartEntry);
}
/* Release layout buffer */
if (DiskEntry->LayoutBuffer != NULL)
RtlFreeHeap(ProcessHeap, 0, DiskEntry->LayoutBuffer);
/* Release disk entry */
RtlFreeHeap(ProcessHeap, 0, DiskEntry);
}
/* Release the bios disk info */
while (!IsListEmpty(&List->BiosDiskListHead))
{
Entry = RemoveHeadList(&List->BiosDiskListHead);
BiosDiskEntry = CONTAINING_RECORD(Entry, BIOSDISKENTRY, ListEntry);
RtlFreeHeap(ProcessHeap, 0, BiosDiskEntry);
}
/* Release list head */
RtlFreeHeap(ProcessHeap, 0, List);
}
PDISKENTRY
GetDiskByBiosNumber(
IN PPARTLIST List,
IN ULONG HwDiskNumber)
{
PDISKENTRY DiskEntry;
PLIST_ENTRY Entry;
/* Loop over the disks and find the correct one */
for (Entry = List->DiskListHead.Flink;
Entry != &List->DiskListHead;
Entry = Entry->Flink)
{
DiskEntry = CONTAINING_RECORD(Entry, DISKENTRY, ListEntry);
if (DiskEntry->HwDiskNumber == HwDiskNumber)
{
/* Disk found */
return DiskEntry;
}
}
/* Disk not found, stop there */
return NULL;
}
PDISKENTRY
GetDiskByNumber(
IN PPARTLIST List,
IN ULONG DiskNumber)
{
PDISKENTRY DiskEntry;
PLIST_ENTRY Entry;
/* Loop over the disks and find the correct one */
for (Entry = List->DiskListHead.Flink;
Entry != &List->DiskListHead;
Entry = Entry->Flink)
{
DiskEntry = CONTAINING_RECORD(Entry, DISKENTRY, ListEntry);
if (DiskEntry->DiskNumber == DiskNumber)
{
/* Disk found */
return DiskEntry;
}
}
/* Disk not found, stop there */
return NULL;
}
PDISKENTRY
GetDiskBySCSI(
IN PPARTLIST List,
IN USHORT Port,
IN USHORT Bus,
IN USHORT Id)
{
PDISKENTRY DiskEntry;
PLIST_ENTRY Entry;
/* Loop over the disks and find the correct one */
for (Entry = List->DiskListHead.Flink;
Entry != &List->DiskListHead;
Entry = Entry->Flink)
{
DiskEntry = CONTAINING_RECORD(Entry, DISKENTRY, ListEntry);
if (DiskEntry->Port == Port &&
DiskEntry->Bus == Bus &&
DiskEntry->Id == Id)
{
/* Disk found */
return DiskEntry;
}
}
/* Disk not found, stop there */
return NULL;
}
PDISKENTRY
GetDiskBySignature(
IN PPARTLIST List,
IN ULONG Signature)
{
PDISKENTRY DiskEntry;
PLIST_ENTRY Entry;
/* Loop over the disks and find the correct one */
for (Entry = List->DiskListHead.Flink;
Entry != &List->DiskListHead;
Entry = Entry->Flink)
{
DiskEntry = CONTAINING_RECORD(Entry, DISKENTRY, ListEntry);
if (DiskEntry->LayoutBuffer->Signature == Signature)
{
/* Disk found */
return DiskEntry;
}
}
/* Disk not found, stop there */
return NULL;
}
PPARTENTRY
GetPartition(
// IN PPARTLIST List,
IN PDISKENTRY DiskEntry,
IN ULONG PartitionNumber)
{
PPARTENTRY PartEntry;
PLIST_ENTRY Entry;
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT("GPT-partitioned disk detected, not currently supported by SETUP!\n");
return NULL;
}
/* Disk found, loop over the primary partitions first... */
for (Entry = DiskEntry->PrimaryPartListHead.Flink;
Entry != &DiskEntry->PrimaryPartListHead;
Entry = Entry->Flink)
{
PartEntry = CONTAINING_RECORD(Entry, PARTENTRY, ListEntry);
if (PartEntry->PartitionNumber == PartitionNumber)
{
/* Partition found */
return PartEntry;
}
}
/* ... then over the logical partitions if needed */
for (Entry = DiskEntry->LogicalPartListHead.Flink;
Entry != &DiskEntry->LogicalPartListHead;
Entry = Entry->Flink)
{
PartEntry = CONTAINING_RECORD(Entry, PARTENTRY, ListEntry);
if (PartEntry->PartitionNumber == PartitionNumber)
{
/* Partition found */
return PartEntry;
}
}
/* The partition was not found on the disk, stop there */
return NULL;
}
BOOLEAN
GetDiskOrPartition(
IN PPARTLIST List,
IN ULONG DiskNumber,
IN ULONG PartitionNumber OPTIONAL,
OUT PDISKENTRY* pDiskEntry,
OUT PPARTENTRY* pPartEntry OPTIONAL)
{
PDISKENTRY DiskEntry;
PPARTENTRY PartEntry = NULL;
/* Find the disk */
DiskEntry = GetDiskByNumber(List, DiskNumber);
if (!DiskEntry)
return FALSE;
/* If we have a partition (PartitionNumber != 0), find it */
if (PartitionNumber != 0)
{
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT("GPT-partitioned disk detected, not currently supported by SETUP!\n");
return FALSE;
}
PartEntry = GetPartition(/*List,*/ DiskEntry, PartitionNumber);
if (!PartEntry)
return FALSE;
ASSERT(PartEntry->DiskEntry == DiskEntry);
}
/* Return the disk (and optionally the partition) */
*pDiskEntry = DiskEntry;
if (pPartEntry) *pPartEntry = PartEntry;
return TRUE;
}
//
// NOTE: Was introduced broken in r6258 by Casper
//
PPARTENTRY
SelectPartition(
IN PPARTLIST List,
IN ULONG DiskNumber,
IN ULONG PartitionNumber)
{
PDISKENTRY DiskEntry;
PPARTENTRY PartEntry;
DiskEntry = GetDiskByNumber(List, DiskNumber);
if (!DiskEntry)
return NULL;
PartEntry = GetPartition(/*List,*/ DiskEntry, PartitionNumber);
if (!PartEntry)
return NULL;
ASSERT(PartEntry->DiskEntry == DiskEntry);
ASSERT(DiskEntry->DiskNumber == DiskNumber);
ASSERT(PartEntry->PartitionNumber == PartitionNumber);
return PartEntry;
}
PPARTENTRY
GetNextPartition(
IN PPARTLIST List,
IN PPARTENTRY CurrentPart OPTIONAL)
{
PLIST_ENTRY DiskListEntry;
PLIST_ENTRY PartListEntry;
PDISKENTRY CurrentDisk;
/* Fail if no disks are available */
if (IsListEmpty(&List->DiskListHead))
return NULL;
/* Check for the next usable entry on the current partition's disk */
if (CurrentPart != NULL)
{
CurrentDisk = CurrentPart->DiskEntry;
if (CurrentPart->LogicalPartition)
{
/* Logical partition */
PartListEntry = CurrentPart->ListEntry.Flink;
if (PartListEntry != &CurrentDisk->LogicalPartListHead)
{
/* Next logical partition */
CurrentPart = CONTAINING_RECORD(PartListEntry, PARTENTRY, ListEntry);
return CurrentPart;
}
else
{
PartListEntry = CurrentDisk->ExtendedPartition->ListEntry.Flink;
if (PartListEntry != &CurrentDisk->PrimaryPartListHead)
{
CurrentPart = CONTAINING_RECORD(PartListEntry, PARTENTRY, ListEntry);
return CurrentPart;
}
}
}
else
{
/* Primary or extended partition */
if (CurrentPart->IsPartitioned &&
IsContainerPartition(CurrentPart->PartitionType))
{
/* First logical partition */
PartListEntry = CurrentDisk->LogicalPartListHead.Flink;
if (PartListEntry != &CurrentDisk->LogicalPartListHead)
{
CurrentPart = CONTAINING_RECORD(PartListEntry, PARTENTRY, ListEntry);
return CurrentPart;
}
}
else
{
/* Next primary partition */
PartListEntry = CurrentPart->ListEntry.Flink;
if (PartListEntry != &CurrentDisk->PrimaryPartListHead)
{
CurrentPart = CONTAINING_RECORD(PartListEntry, PARTENTRY, ListEntry);
return CurrentPart;
}
}
}
}
/* Search for the first partition entry on the next disk */
for (DiskListEntry = (CurrentPart ? CurrentDisk->ListEntry.Flink
: List->DiskListHead.Flink);
DiskListEntry != &List->DiskListHead;
DiskListEntry = DiskListEntry->Flink)
{
CurrentDisk = CONTAINING_RECORD(DiskListEntry, DISKENTRY, ListEntry);
if (CurrentDisk->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT("GPT-partitioned disk detected, not currently supported by SETUP!\n");
continue;
}
PartListEntry = CurrentDisk->PrimaryPartListHead.Flink;
if (PartListEntry != &CurrentDisk->PrimaryPartListHead)
{
CurrentPart = CONTAINING_RECORD(PartListEntry, PARTENTRY, ListEntry);
return CurrentPart;
}
}
return NULL;
}
PPARTENTRY
GetPrevPartition(
IN PPARTLIST List,
IN PPARTENTRY CurrentPart OPTIONAL)
{
PLIST_ENTRY DiskListEntry;
PLIST_ENTRY PartListEntry;
PDISKENTRY CurrentDisk;
/* Fail if no disks are available */
if (IsListEmpty(&List->DiskListHead))
return NULL;
/* Check for the previous usable entry on the current partition's disk */
if (CurrentPart != NULL)
{
CurrentDisk = CurrentPart->DiskEntry;
if (CurrentPart->LogicalPartition)
{
/* Logical partition */
PartListEntry = CurrentPart->ListEntry.Blink;
if (PartListEntry != &CurrentDisk->LogicalPartListHead)
{
/* Previous logical partition */
CurrentPart = CONTAINING_RECORD(PartListEntry, PARTENTRY, ListEntry);
}
else
{
/* Extended partition */
CurrentPart = CurrentDisk->ExtendedPartition;
}
return CurrentPart;
}
else
{
/* Primary or extended partition */
PartListEntry = CurrentPart->ListEntry.Blink;
if (PartListEntry != &CurrentDisk->PrimaryPartListHead)
{
CurrentPart = CONTAINING_RECORD(PartListEntry, PARTENTRY, ListEntry);
if (CurrentPart->IsPartitioned &&
IsContainerPartition(CurrentPart->PartitionType))
{
PartListEntry = CurrentDisk->LogicalPartListHead.Blink;
CurrentPart = CONTAINING_RECORD(PartListEntry, PARTENTRY, ListEntry);
}
return CurrentPart;
}
}
}
/* Search for the last partition entry on the previous disk */
for (DiskListEntry = (CurrentPart ? CurrentDisk->ListEntry.Blink
: List->DiskListHead.Blink);
DiskListEntry != &List->DiskListHead;
DiskListEntry = DiskListEntry->Blink)
{
CurrentDisk = CONTAINING_RECORD(DiskListEntry, DISKENTRY, ListEntry);
if (CurrentDisk->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT("GPT-partitioned disk detected, not currently supported by SETUP!\n");
continue;
}
PartListEntry = CurrentDisk->PrimaryPartListHead.Blink;
if (PartListEntry != &CurrentDisk->PrimaryPartListHead)
{
CurrentPart = CONTAINING_RECORD(PartListEntry, PARTENTRY, ListEntry);
if (CurrentPart->IsPartitioned &&
IsContainerPartition(CurrentPart->PartitionType))
{
PartListEntry = CurrentDisk->LogicalPartListHead.Blink;
if (PartListEntry != &CurrentDisk->LogicalPartListHead)
{
CurrentPart = CONTAINING_RECORD(PartListEntry, PARTENTRY, ListEntry);
return CurrentPart;
}
}
else
{
return CurrentPart;
}
}
}
return NULL;
}
// static
FORCEINLINE
BOOLEAN
IsEmptyLayoutEntry(
IN PPARTITION_INFORMATION PartitionInfo)
{
if (PartitionInfo->StartingOffset.QuadPart == 0 &&
PartitionInfo->PartitionLength.QuadPart == 0)
{
return TRUE;
}
return FALSE;
}
// static
FORCEINLINE
BOOLEAN
IsSamePrimaryLayoutEntry(
IN PPARTITION_INFORMATION PartitionInfo,
IN PDISKENTRY DiskEntry,
IN PPARTENTRY PartEntry)
{
if (PartitionInfo->StartingOffset.QuadPart == PartEntry->StartSector.QuadPart * DiskEntry->BytesPerSector &&
PartitionInfo->PartitionLength.QuadPart == PartEntry->SectorCount.QuadPart * DiskEntry->BytesPerSector)
// PartitionInfo->PartitionType == PartEntry->PartitionType
{
return TRUE;
}
return FALSE;
}
static
ULONG
GetPrimaryPartitionCount(
IN PDISKENTRY DiskEntry)
{
PLIST_ENTRY Entry;
PPARTENTRY PartEntry;
ULONG Count = 0;
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT("GPT-partitioned disk detected, not currently supported by SETUP!\n");
return 0;
}
for (Entry = DiskEntry->PrimaryPartListHead.Flink;
Entry != &DiskEntry->PrimaryPartListHead;
Entry = Entry->Flink)
{
PartEntry = CONTAINING_RECORD(Entry, PARTENTRY, ListEntry);
if (PartEntry->IsPartitioned)
Count++;
}
return Count;
}
static
ULONG
GetLogicalPartitionCount(
IN PDISKENTRY DiskEntry)
{
PLIST_ENTRY ListEntry;
PPARTENTRY PartEntry;
ULONG Count = 0;
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT("GPT-partitioned disk detected, not currently supported by SETUP!\n");
return 0;
}
for (ListEntry = DiskEntry->LogicalPartListHead.Flink;
ListEntry != &DiskEntry->LogicalPartListHead;
ListEntry = ListEntry->Flink)
{
PartEntry = CONTAINING_RECORD(ListEntry, PARTENTRY, ListEntry);
if (PartEntry->IsPartitioned)
Count++;
}
return Count;
}
static
BOOLEAN
ReAllocateLayoutBuffer(
IN PDISKENTRY DiskEntry)
{
PDRIVE_LAYOUT_INFORMATION NewLayoutBuffer;
ULONG NewPartitionCount;
ULONG CurrentPartitionCount = 0;
ULONG LayoutBufferSize;
ULONG i;
DPRINT1("ReAllocateLayoutBuffer()\n");
NewPartitionCount = 4 + GetLogicalPartitionCount(DiskEntry) * 4;
if (DiskEntry->LayoutBuffer)
CurrentPartitionCount = DiskEntry->LayoutBuffer->PartitionCount;
DPRINT1("CurrentPartitionCount: %lu ; NewPartitionCount: %lu\n",
CurrentPartitionCount, NewPartitionCount);
if (CurrentPartitionCount == NewPartitionCount)
return TRUE;
LayoutBufferSize = sizeof(DRIVE_LAYOUT_INFORMATION) +
((NewPartitionCount - ANYSIZE_ARRAY) * sizeof(PARTITION_INFORMATION));
NewLayoutBuffer = RtlReAllocateHeap(ProcessHeap,
HEAP_ZERO_MEMORY,
DiskEntry->LayoutBuffer,
LayoutBufferSize);
if (NewLayoutBuffer == NULL)
{
DPRINT1("Failed to allocate the new layout buffer (size: %lu)\n", LayoutBufferSize);
return FALSE;
}
NewLayoutBuffer->PartitionCount = NewPartitionCount;
/* If the layout buffer grows, make sure the new (empty) entries are written to the disk */
if (NewPartitionCount > CurrentPartitionCount)
{
for (i = CurrentPartitionCount; i < NewPartitionCount; i++)
{
NewLayoutBuffer->PartitionEntry[i].RewritePartition = TRUE;
}
}
DiskEntry->LayoutBuffer = NewLayoutBuffer;
return TRUE;
}
static
VOID
UpdateDiskLayout(
IN PDISKENTRY DiskEntry)
{
PPARTITION_INFORMATION PartitionInfo;
PPARTITION_INFORMATION LinkInfo = NULL;
PLIST_ENTRY ListEntry;
PPARTENTRY PartEntry;
LARGE_INTEGER HiddenSectors64;
ULONG Index;
ULONG PartitionNumber = 1;
DPRINT1("UpdateDiskLayout()\n");
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT1("GPT-partitioned disk detected, not currently supported by SETUP!\n");
return;
}
/* Resize the layout buffer if necessary */
if (ReAllocateLayoutBuffer(DiskEntry) == FALSE)
{
DPRINT("ReAllocateLayoutBuffer() failed.\n");
return;
}
/* Update the primary partition table */
Index = 0;
for (ListEntry = DiskEntry->PrimaryPartListHead.Flink;
ListEntry != &DiskEntry->PrimaryPartListHead;
ListEntry = ListEntry->Flink)
{
PartEntry = CONTAINING_RECORD(ListEntry, PARTENTRY, ListEntry);
if (PartEntry->IsPartitioned)
{
ASSERT(PartEntry->PartitionType != PARTITION_ENTRY_UNUSED);
PartitionInfo = &DiskEntry->LayoutBuffer->PartitionEntry[Index];
PartEntry->PartitionIndex = Index;
/* Reset the current partition number only for newly-created (unmounted) partitions */
if (PartEntry->New)
PartEntry->PartitionNumber = 0;
PartEntry->OnDiskPartitionNumber = (!IsContainerPartition(PartEntry->PartitionType) ? PartitionNumber : 0);
if (!IsSamePrimaryLayoutEntry(PartitionInfo, DiskEntry, PartEntry))
{
DPRINT1("Updating primary partition entry %lu\n", Index);
PartitionInfo->StartingOffset.QuadPart = PartEntry->StartSector.QuadPart * DiskEntry->BytesPerSector;
PartitionInfo->PartitionLength.QuadPart = PartEntry->SectorCount.QuadPart * DiskEntry->BytesPerSector;
PartitionInfo->HiddenSectors = PartEntry->StartSector.LowPart;
PartitionInfo->PartitionNumber = PartEntry->PartitionNumber;
PartitionInfo->PartitionType = PartEntry->PartitionType;
PartitionInfo->BootIndicator = PartEntry->BootIndicator;
PartitionInfo->RecognizedPartition = IsRecognizedPartition(PartEntry->PartitionType);
PartitionInfo->RewritePartition = TRUE;
}
if (!IsContainerPartition(PartEntry->PartitionType))
PartitionNumber++;
Index++;
}
}
ASSERT(Index <= 4);
/* Update the logical partition table */
Index = 4;
for (ListEntry = DiskEntry->LogicalPartListHead.Flink;
ListEntry != &DiskEntry->LogicalPartListHead;
ListEntry = ListEntry->Flink)
{
PartEntry = CONTAINING_RECORD(ListEntry, PARTENTRY, ListEntry);
if (PartEntry->IsPartitioned)
{
ASSERT(PartEntry->PartitionType != PARTITION_ENTRY_UNUSED);
PartitionInfo = &DiskEntry->LayoutBuffer->PartitionEntry[Index];
PartEntry->PartitionIndex = Index;
/* Reset the current partition number only for newly-created (unmounted) partitions */
if (PartEntry->New)
PartEntry->PartitionNumber = 0;
PartEntry->OnDiskPartitionNumber = PartitionNumber;
DPRINT1("Updating logical partition entry %lu\n", Index);
PartitionInfo->StartingOffset.QuadPart = PartEntry->StartSector.QuadPart * DiskEntry->BytesPerSector;
PartitionInfo->PartitionLength.QuadPart = PartEntry->SectorCount.QuadPart * DiskEntry->BytesPerSector;
PartitionInfo->HiddenSectors = DiskEntry->SectorAlignment;
PartitionInfo->PartitionNumber = PartEntry->PartitionNumber;
PartitionInfo->PartitionType = PartEntry->PartitionType;
PartitionInfo->BootIndicator = FALSE;
PartitionInfo->RecognizedPartition = IsRecognizedPartition(PartEntry->PartitionType);
PartitionInfo->RewritePartition = TRUE;
/* Fill the link entry of the previous partition entry */
if (LinkInfo != NULL)
{
LinkInfo->StartingOffset.QuadPart = (PartEntry->StartSector.QuadPart - DiskEntry->SectorAlignment) * DiskEntry->BytesPerSector;
LinkInfo->PartitionLength.QuadPart = (PartEntry->StartSector.QuadPart + DiskEntry->SectorAlignment) * DiskEntry->BytesPerSector;
HiddenSectors64.QuadPart = PartEntry->StartSector.QuadPart - DiskEntry->SectorAlignment - DiskEntry->ExtendedPartition->StartSector.QuadPart;
LinkInfo->HiddenSectors = HiddenSectors64.LowPart;
LinkInfo->PartitionNumber = 0;
LinkInfo->PartitionType = PARTITION_EXTENDED;
LinkInfo->BootIndicator = FALSE;
LinkInfo->RecognizedPartition = FALSE;
LinkInfo->RewritePartition = TRUE;
}
/* Save a pointer to the link entry of the current partition entry */
LinkInfo = &DiskEntry->LayoutBuffer->PartitionEntry[Index + 1];
PartitionNumber++;
Index += 4;
}
}
/* Wipe unused primary partition entries */
for (Index = GetPrimaryPartitionCount(DiskEntry); Index < 4; Index++)
{
DPRINT1("Primary partition entry %lu\n", Index);
PartitionInfo = &DiskEntry->LayoutBuffer->PartitionEntry[Index];
if (!IsEmptyLayoutEntry(PartitionInfo))
{
DPRINT1("Wiping primary partition entry %lu\n", Index);
PartitionInfo->StartingOffset.QuadPart = 0;
PartitionInfo->PartitionLength.QuadPart = 0;
PartitionInfo->HiddenSectors = 0;
PartitionInfo->PartitionNumber = 0;
PartitionInfo->PartitionType = PARTITION_ENTRY_UNUSED;
PartitionInfo->BootIndicator = FALSE;
PartitionInfo->RecognizedPartition = FALSE;
PartitionInfo->RewritePartition = TRUE;
}
}
/* Wipe unused logical partition entries */
for (Index = 4; Index < DiskEntry->LayoutBuffer->PartitionCount; Index++)
{
if (Index % 4 >= 2)
{
DPRINT1("Logical partition entry %lu\n", Index);
PartitionInfo = &DiskEntry->LayoutBuffer->PartitionEntry[Index];
if (!IsEmptyLayoutEntry(PartitionInfo))
{
DPRINT1("Wiping partition entry %lu\n", Index);
PartitionInfo->StartingOffset.QuadPart = 0;
PartitionInfo->PartitionLength.QuadPart = 0;
PartitionInfo->HiddenSectors = 0;
PartitionInfo->PartitionNumber = 0;
PartitionInfo->PartitionType = PARTITION_ENTRY_UNUSED;
PartitionInfo->BootIndicator = FALSE;
PartitionInfo->RecognizedPartition = FALSE;
PartitionInfo->RewritePartition = TRUE;
}
}
}
// HACK: See the FIXMEs in WritePartitions(): (Re)set the PartitionStyle to MBR.
DiskEntry->DiskStyle = PARTITION_STYLE_MBR;
DiskEntry->Dirty = TRUE;
#ifdef DUMP_PARTITION_TABLE
DumpPartitionTable(DiskEntry);
#endif
}
static
PPARTENTRY
GetPrevUnpartitionedEntry(
IN PPARTENTRY PartEntry)
{
PDISKENTRY DiskEntry = PartEntry->DiskEntry;
PPARTENTRY PrevPartEntry;
PLIST_ENTRY ListHead;
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT("GPT-partitioned disk detected, not currently supported by SETUP!\n");
return NULL;
}
if (PartEntry->LogicalPartition)
ListHead = &DiskEntry->LogicalPartListHead;
else
ListHead = &DiskEntry->PrimaryPartListHead;
if (PartEntry->ListEntry.Blink != ListHead)
{
PrevPartEntry = CONTAINING_RECORD(PartEntry->ListEntry.Blink,
PARTENTRY,
ListEntry);
if (!PrevPartEntry->IsPartitioned)
{
ASSERT(PrevPartEntry->PartitionType == PARTITION_ENTRY_UNUSED);
return PrevPartEntry;
}
}
return NULL;
}
static
PPARTENTRY
GetNextUnpartitionedEntry(
IN PPARTENTRY PartEntry)
{
PDISKENTRY DiskEntry = PartEntry->DiskEntry;
PPARTENTRY NextPartEntry;
PLIST_ENTRY ListHead;
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT("GPT-partitioned disk detected, not currently supported by SETUP!\n");
return NULL;
}
if (PartEntry->LogicalPartition)
ListHead = &DiskEntry->LogicalPartListHead;
else
ListHead = &DiskEntry->PrimaryPartListHead;
if (PartEntry->ListEntry.Flink != ListHead)
{
NextPartEntry = CONTAINING_RECORD(PartEntry->ListEntry.Flink,
PARTENTRY,
ListEntry);
if (!NextPartEntry->IsPartitioned)
{
ASSERT(NextPartEntry->PartitionType == PARTITION_ENTRY_UNUSED);
return NextPartEntry;
}
}
return NULL;
}
BOOLEAN
CreatePrimaryPartition(
IN PPARTLIST List,
IN OUT PPARTENTRY PartEntry,
IN ULONGLONG SectorCount,
IN BOOLEAN AutoCreate)
{
ERROR_NUMBER Error;
DPRINT1("CreatePrimaryPartition(%I64u)\n", SectorCount);
if (List == NULL || PartEntry == NULL ||
PartEntry->DiskEntry == NULL || PartEntry->IsPartitioned)
{
return FALSE;
}
Error = PrimaryPartitionCreationChecks(PartEntry);
if (Error != NOT_AN_ERROR)
{
DPRINT1("PrimaryPartitionCreationChecks() failed with error %lu\n", Error);
return FALSE;
}
/* Initialize the partition entry, inserting a new blank region if needed */
if (!InitializePartitionEntry(PartEntry, SectorCount, AutoCreate))
return FALSE;
ASSERT(PartEntry->LogicalPartition == FALSE);
UpdateDiskLayout(PartEntry->DiskEntry);
AssignDriveLetters(List);
return TRUE;
}
static
VOID
AddLogicalDiskSpace(
IN PDISKENTRY DiskEntry)
{
ULONGLONG StartSector;
ULONGLONG SectorCount;
PPARTENTRY NewPartEntry;
DPRINT1("AddLogicalDiskSpace()\n");
/* Create a partition entry that represents the empty space in the container partition */
StartSector = DiskEntry->ExtendedPartition->StartSector.QuadPart + (ULONGLONG)DiskEntry->SectorAlignment;
SectorCount = DiskEntry->ExtendedPartition->SectorCount.QuadPart - (ULONGLONG)DiskEntry->SectorAlignment;
NewPartEntry = CreateInsertBlankRegion(DiskEntry,
&DiskEntry->LogicalPartListHead,
StartSector,
SectorCount,
TRUE);
if (NewPartEntry == NULL)
{
DPRINT1("Failed to create a new empty region for extended partition space!\n");
return;
}
}
BOOLEAN
CreateExtendedPartition(
IN PPARTLIST List,
IN OUT PPARTENTRY PartEntry,
IN ULONGLONG SectorCount)
{
ERROR_NUMBER Error;
DPRINT1("CreateExtendedPartition(%I64u)\n", SectorCount);
if (List == NULL || PartEntry == NULL ||
PartEntry->DiskEntry == NULL || PartEntry->IsPartitioned)
{
return FALSE;
}
Error = ExtendedPartitionCreationChecks(PartEntry);
if (Error != NOT_AN_ERROR)
{
DPRINT1("ExtendedPartitionCreationChecks() failed with error %lu\n", Error);
return FALSE;
}
/* Initialize the partition entry, inserting a new blank region if needed */
if (!InitializePartitionEntry(PartEntry, SectorCount, FALSE))
return FALSE;
ASSERT(PartEntry->LogicalPartition == FALSE);
if (PartEntry->StartSector.QuadPart < 1450560)
{
/* Partition starts below the 8.4GB boundary ==> CHS partition */
PartEntry->PartitionType = PARTITION_EXTENDED;
}
else
{
/* Partition starts above the 8.4GB boundary ==> LBA partition */
PartEntry->PartitionType = PARTITION_XINT13_EXTENDED;
}
// FIXME? Possibly to make GetNextUnformattedPartition work (i.e. skip the extended partition container)
PartEntry->New = FALSE;
PartEntry->FormatState = Formatted;
PartEntry->DiskEntry->ExtendedPartition = PartEntry;
AddLogicalDiskSpace(PartEntry->DiskEntry);
UpdateDiskLayout(PartEntry->DiskEntry);
AssignDriveLetters(List);
return TRUE;
}
BOOLEAN
CreateLogicalPartition(
IN PPARTLIST List,
IN OUT PPARTENTRY PartEntry,
IN ULONGLONG SectorCount,
IN BOOLEAN AutoCreate)
{
ERROR_NUMBER Error;
DPRINT1("CreateLogicalPartition(%I64u)\n", SectorCount);
if (List == NULL || PartEntry == NULL ||
PartEntry->DiskEntry == NULL || PartEntry->IsPartitioned)
{
return FALSE;
}
Error = LogicalPartitionCreationChecks(PartEntry);
if (Error != NOT_AN_ERROR)
{
DPRINT1("LogicalPartitionCreationChecks() failed with error %lu\n", Error);
return FALSE;
}
/* Initialize the partition entry, inserting a new blank region if needed */
if (!InitializePartitionEntry(PartEntry, SectorCount, AutoCreate))
return FALSE;
ASSERT(PartEntry->LogicalPartition == TRUE);
UpdateDiskLayout(PartEntry->DiskEntry);
AssignDriveLetters(List);
return TRUE;
}
NTSTATUS
DismountVolume(
IN PPARTENTRY PartEntry)
{
NTSTATUS Status;
NTSTATUS LockStatus;
UNICODE_STRING Name;
OBJECT_ATTRIBUTES ObjectAttributes;
IO_STATUS_BLOCK IoStatusBlock;
HANDLE PartitionHandle;
WCHAR Buffer[MAX_PATH];
/* Check whether the partition is valid and was mounted by the system */
if (!PartEntry->IsPartitioned ||
IsContainerPartition(PartEntry->PartitionType) ||
!IsRecognizedPartition(PartEntry->PartitionType) ||
PartEntry->FormatState == UnknownFormat ||
// NOTE: If FormatState == Unformatted but *FileSystem != 0 this means
// it has been usually mounted with RawFS and thus needs to be dismounted.
!*PartEntry->FileSystem ||
PartEntry->PartitionNumber == 0)
{
/* The partition is not mounted, so just return success */
return STATUS_SUCCESS;
}
ASSERT(PartEntry->PartitionType != PARTITION_ENTRY_UNUSED);
/* Open the volume */
RtlStringCchPrintfW(Buffer, ARRAYSIZE(Buffer),
L"\\Device\\Harddisk%lu\\Partition%lu",
PartEntry->DiskEntry->DiskNumber,
PartEntry->PartitionNumber);
RtlInitUnicodeString(&Name, Buffer);
InitializeObjectAttributes(&ObjectAttributes,
&Name,
OBJ_CASE_INSENSITIVE,
NULL,
NULL);
Status = NtOpenFile(&PartitionHandle,
GENERIC_READ | GENERIC_WRITE | SYNCHRONIZE,
&ObjectAttributes,
&IoStatusBlock,
FILE_SHARE_READ | FILE_SHARE_WRITE,
FILE_SYNCHRONOUS_IO_NONALERT);
if (!NT_SUCCESS(Status))
{
DPRINT1("ERROR: Cannot open volume %wZ for dismounting! (Status 0x%lx)\n", &Name, Status);
return Status;
}
/* Lock the volume */
LockStatus = NtFsControlFile(PartitionHandle,
NULL,
NULL,
NULL,
&IoStatusBlock,
FSCTL_LOCK_VOLUME,
NULL,
0,
NULL,
0);
if (!NT_SUCCESS(LockStatus))
{
DPRINT1("WARNING: Failed to lock volume! Operations may fail! (Status 0x%lx)\n", LockStatus);
}
/* Dismount the volume */
Status = NtFsControlFile(PartitionHandle,
NULL,
NULL,
NULL,
&IoStatusBlock,
FSCTL_DISMOUNT_VOLUME,
NULL,
0,
NULL,
0);
if (!NT_SUCCESS(Status))
{
DPRINT1("Failed to unmount volume (Status 0x%lx)\n", Status);
}
/* Unlock the volume */
LockStatus = NtFsControlFile(PartitionHandle,
NULL,
NULL,
NULL,
&IoStatusBlock,
FSCTL_UNLOCK_VOLUME,
NULL,
0,
NULL,
0);
if (!NT_SUCCESS(LockStatus))
{
DPRINT1("Failed to unlock volume (Status 0x%lx)\n", LockStatus);
}
/* Close the volume */
NtClose(PartitionHandle);
return Status;
}
BOOLEAN
DeletePartition(
IN PPARTLIST List,
IN PPARTENTRY PartEntry,
OUT PPARTENTRY* FreeRegion OPTIONAL)
{
PDISKENTRY DiskEntry;
PPARTENTRY PrevPartEntry;
PPARTENTRY NextPartEntry;
PPARTENTRY LogicalPartEntry;
PLIST_ENTRY Entry;
if (List == NULL || PartEntry == NULL ||
PartEntry->DiskEntry == NULL || PartEntry->IsPartitioned == FALSE)
{
return FALSE;
}
ASSERT(PartEntry->PartitionType != PARTITION_ENTRY_UNUSED);
/* Clear the system partition if it is being deleted */
if (List->SystemPartition == PartEntry)
{
ASSERT(List->SystemPartition);
List->SystemPartition = NULL;
}
DiskEntry = PartEntry->DiskEntry;
/* Check which type of partition (primary/logical or extended) is being deleted */
if (DiskEntry->ExtendedPartition == PartEntry)
{
/* An extended partition is being deleted: delete all logical partition entries */
while (!IsListEmpty(&DiskEntry->LogicalPartListHead))
{
Entry = RemoveHeadList(&DiskEntry->LogicalPartListHead);
LogicalPartEntry = CONTAINING_RECORD(Entry, PARTENTRY, ListEntry);
/* Dismount the logical partition */
DismountVolume(LogicalPartEntry);
/* Delete it */
RtlFreeHeap(ProcessHeap, 0, LogicalPartEntry);
}
DiskEntry->ExtendedPartition = NULL;
}
else
{
/* A primary partition is being deleted: dismount it */
DismountVolume(PartEntry);
}
/* Adjust the unpartitioned disk space entries */
/* Get pointer to previous and next unpartitioned entries */
PrevPartEntry = GetPrevUnpartitionedEntry(PartEntry);
NextPartEntry = GetNextUnpartitionedEntry(PartEntry);
if (PrevPartEntry != NULL && NextPartEntry != NULL)
{
/* Merge the previous, current and next unpartitioned entries */
/* Adjust the previous entry length */
PrevPartEntry->SectorCount.QuadPart += (PartEntry->SectorCount.QuadPart + NextPartEntry->SectorCount.QuadPart);
/* Remove the current and next entries */
RemoveEntryList(&PartEntry->ListEntry);
RtlFreeHeap(ProcessHeap, 0, PartEntry);
RemoveEntryList(&NextPartEntry->ListEntry);
RtlFreeHeap(ProcessHeap, 0, NextPartEntry);
/* Optionally return the freed region */
if (FreeRegion)
*FreeRegion = PrevPartEntry;
}
else if (PrevPartEntry != NULL && NextPartEntry == NULL)
{
/* Merge the current and the previous unpartitioned entries */
/* Adjust the previous entry length */
PrevPartEntry->SectorCount.QuadPart += PartEntry->SectorCount.QuadPart;
/* Remove the current entry */
RemoveEntryList(&PartEntry->ListEntry);
RtlFreeHeap(ProcessHeap, 0, PartEntry);
/* Optionally return the freed region */
if (FreeRegion)
*FreeRegion = PrevPartEntry;
}
else if (PrevPartEntry == NULL && NextPartEntry != NULL)
{
/* Merge the current and the next unpartitioned entries */
/* Adjust the next entry offset and length */
NextPartEntry->StartSector.QuadPart = PartEntry->StartSector.QuadPart;
NextPartEntry->SectorCount.QuadPart += PartEntry->SectorCount.QuadPart;
/* Remove the current entry */
RemoveEntryList(&PartEntry->ListEntry);
RtlFreeHeap(ProcessHeap, 0, PartEntry);
/* Optionally return the freed region */
if (FreeRegion)
*FreeRegion = NextPartEntry;
}
else
{
/* Nothing to merge but change the current entry */
PartEntry->IsPartitioned = FALSE;
PartEntry->OnDiskPartitionNumber = 0;
PartEntry->PartitionNumber = 0;
// PartEntry->PartitionIndex = 0;
PartEntry->BootIndicator = FALSE;
PartEntry->PartitionType = PARTITION_ENTRY_UNUSED;
PartEntry->FormatState = Unformatted;
PartEntry->FileSystem[0] = L'\0';
PartEntry->DriveLetter = 0;
RtlZeroMemory(PartEntry->VolumeLabel, sizeof(PartEntry->VolumeLabel));
/* Optionally return the freed region */
if (FreeRegion)
*FreeRegion = PartEntry;
}
UpdateDiskLayout(DiskEntry);
AssignDriveLetters(List);
return TRUE;
}
static
BOOLEAN
IsSupportedActivePartition(
IN PPARTENTRY PartEntry)
{
/* Check the type and the file system of this partition */
/*
* We do not support extended partition containers (on MBR disks) marked
* as active, and containing code inside their extended boot records.
*/
if (IsContainerPartition(PartEntry->PartitionType))
{
DPRINT1("System partition %lu in disk %lu is an extended partition container?!\n",
PartEntry->PartitionNumber, PartEntry->DiskEntry->DiskNumber);
return FALSE;
}
/*
* ADDITIONAL CHECKS / BIG HACK:
*
* Retrieve its file system and check whether we have
* write support for it. If that is the case we are fine
* and we can use it directly. However if we don't have
* write support we will need to change the active system
* partition.
*
* NOTE that this is completely useless on architectures
* where a real system partition is required, as on these
* architectures the partition uses the FAT FS, for which
* we do have write support.
* NOTE also that for those architectures looking for a
* partition boot indicator is insufficient.
*/
if (PartEntry->FormatState == Unformatted)
{
/* If this partition is mounted, it would use RawFS ("RAW") */
return TRUE;
}
else if ((PartEntry->FormatState == Preformatted) ||
(PartEntry->FormatState == Formatted))
{
ASSERT(*PartEntry->FileSystem);
/* NOTE: Please keep in sync with the RegisteredFileSystems list! */
if (wcsicmp(PartEntry->FileSystem, L"FAT") == 0 ||
wcsicmp(PartEntry->FileSystem, L"FAT32") == 0 ||
// wcsicmp(PartEntry->FileSystem, L"NTFS") == 0 ||
wcsicmp(PartEntry->FileSystem, L"BTRFS") == 0)
{
return TRUE;
}
else
{
// WARNING: We cannot write on this FS yet!
DPRINT1("Recognized file system '%S' that doesn't have write support yet!\n",
PartEntry->FileSystem);
return FALSE;
}
}
else // if (PartEntry->FormatState == UnknownFormat)
{
ASSERT(!*PartEntry->FileSystem);
DPRINT1("System partition %lu in disk %lu with no or unknown FS?!\n",
PartEntry->PartitionNumber, PartEntry->DiskEntry->DiskNumber);
return FALSE;
}
// HACK: WARNING: We cannot write on this FS yet!
// See fsutil.c:InferFileSystem()
if (PartEntry->PartitionType == PARTITION_IFS)
{
DPRINT1("Recognized file system '%S' that doesn't have write support yet!\n",
PartEntry->FileSystem);
return FALSE;
}
return TRUE;
}
PPARTENTRY
FindSupportedSystemPartition(
IN PPARTLIST List,
IN BOOLEAN ForceSelect,
IN PDISKENTRY AlternativeDisk OPTIONAL,
IN PPARTENTRY AlternativePart OPTIONAL)
{
PLIST_ENTRY ListEntry;
PDISKENTRY DiskEntry;
PPARTENTRY PartEntry;
PPARTENTRY ActivePartition;
PPARTENTRY CandidatePartition = NULL;
/* Check for empty disk list */
if (IsListEmpty(&List->DiskListHead))
{
/* No system partition! */
ASSERT(List->SystemPartition == NULL);
goto NoSystemPartition;
}
/* Adjust the optional alternative disk if needed */
if (!AlternativeDisk && AlternativePart)
AlternativeDisk = AlternativePart->DiskEntry;
/* Ensure that the alternative partition is on the alternative disk */
if (AlternativePart)
ASSERT(AlternativeDisk && (AlternativePart->DiskEntry == AlternativeDisk));
/* Ensure that the alternative disk is in the list */
if (AlternativeDisk)
ASSERT(AlternativeDisk->PartList == List);
/* Start fresh */
CandidatePartition = NULL;
//
// Step 1 : Check the system disk.
//
/*
* First, check whether the system disk, i.e. the one that will be booted
* by default by the hardware, contains an active partition. If so this
* should be our system partition.
*/
DiskEntry = GetSystemDisk(List);
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT1("System disk -- GPT-partitioned disk detected, not currently supported by SETUP!\n");
goto UseAlternativeDisk;
}
/* If we have a system partition (in the system disk), validate it */
ActivePartition = List->SystemPartition;
if (ActivePartition && IsSupportedActivePartition(ActivePartition))
{
CandidatePartition = ActivePartition;
DPRINT1("Use the current system partition %lu in disk %lu, drive letter %C\n",
CandidatePartition->PartitionNumber,
CandidatePartition->DiskEntry->DiskNumber,
(CandidatePartition->DriveLetter == 0) ? L'-' : CandidatePartition->DriveLetter);
/* Return the candidate system partition */
return CandidatePartition;
}
/* If the system disk is not the optional alternative disk, perform the minimal checks */
if (DiskEntry != AlternativeDisk)
{
/*
* No active partition has been recognized. Enumerate all the (primary)
* partitions in the system disk, excluding the possible current active
* partition, to find a new candidate.
*/
for (ListEntry = DiskEntry->PrimaryPartListHead.Flink;
ListEntry != &DiskEntry->PrimaryPartListHead;
ListEntry = ListEntry->Flink)
{
/* Retrieve the partition */
PartEntry = CONTAINING_RECORD(ListEntry, PARTENTRY, ListEntry);
/* Skip the current active partition */
if (PartEntry == ActivePartition)
continue;
/* Check if the partition is partitioned and used */
if (PartEntry->IsPartitioned &&
!IsContainerPartition(PartEntry->PartitionType))
{
ASSERT(PartEntry->PartitionType != PARTITION_ENTRY_UNUSED);
/* If we get a candidate active partition in the disk, validate it */
if (IsSupportedActivePartition(PartEntry))
{
CandidatePartition = PartEntry;
goto UseAlternativePartition;
}
}
#if 0
/* Check if the partition is partitioned and used */
if (!PartEntry->IsPartitioned)
{
ASSERT(PartEntry->PartitionType == PARTITION_ENTRY_UNUSED);
// TODO: Check for minimal size!!
CandidatePartition = PartEntry;
goto UseAlternativePartition;
}
#endif
}
/*
* Still nothing, look whether there is some free space that we can use
* for the new system partition. We must be sure that the total number
* of partition is less than the maximum allowed, and that the minimal
* size is fine.
*/
//
// TODO: Fix the handling of system partition being created in unpartitioned space!!
// --> When to partition it? etc...
//
if (GetPrimaryPartitionCount(DiskEntry) < 4)
{
for (ListEntry = DiskEntry->PrimaryPartListHead.Flink;
ListEntry != &DiskEntry->PrimaryPartListHead;
ListEntry = ListEntry->Flink)
{
/* Retrieve the partition */
PartEntry = CONTAINING_RECORD(ListEntry, PARTENTRY, ListEntry);
/* Skip the current active partition */
if (PartEntry == ActivePartition)
continue;
/* Check for unpartitioned space */
if (!PartEntry->IsPartitioned)
{
ASSERT(PartEntry->PartitionType == PARTITION_ENTRY_UNUSED);
// TODO: Check for minimal size!!
CandidatePartition = PartEntry;
goto UseAlternativePartition;
}
}
}
}
//
// Step 2 : No active partition found: Check the alternative disk if specified.
//
UseAlternativeDisk:
if (!AlternativeDisk || (!ForceSelect && (DiskEntry != AlternativeDisk)))
goto NoSystemPartition;
if (AlternativeDisk->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT1("Alternative disk -- GPT-partitioned disk detected, not currently supported by SETUP!\n");
goto NoSystemPartition;
}
if (DiskEntry != AlternativeDisk)
{
/* Choose the alternative disk */
DiskEntry = AlternativeDisk;
/* If we get a candidate active partition, validate it */
ActivePartition = GetActiveDiskPartition(DiskEntry);
if (ActivePartition && IsSupportedActivePartition(ActivePartition))
{
CandidatePartition = ActivePartition;
goto UseAlternativePartition;
}
}
/* We now may have an unsupported active partition, or none */
/***
*** TODO: Improve the selection:
*** - If we want a really separate system partition from the partition where
*** we install, do something similar to what's done below in the code.
*** - Otherwise if we allow for the system partition to be also the partition
*** where we install, just directly fall down to using AlternativePart.
***/
/* Retrieve the first partition of the disk */
PartEntry = CONTAINING_RECORD(DiskEntry->PrimaryPartListHead.Flink,
PARTENTRY, ListEntry);
ASSERT(DiskEntry == PartEntry->DiskEntry);
CandidatePartition = PartEntry;
//
// See: https://svn.reactos.org/svn/reactos/trunk/reactos/base/setup/usetup/partlist.c?r1=63355&r2=63354&pathrev=63355#l2318
//
/* Check if the disk is new and if so, use its first partition as the active system partition */
if (DiskEntry->NewDisk)
{
// !IsContainerPartition(PartEntry->PartitionType);
if (!CandidatePartition->IsPartitioned || !CandidatePartition->BootIndicator) /* CandidatePartition != ActivePartition */
{
ASSERT(DiskEntry == CandidatePartition->DiskEntry);
DPRINT1("Use new first active system partition %lu in disk %lu, drive letter %C\n",
CandidatePartition->PartitionNumber,
CandidatePartition->DiskEntry->DiskNumber,
(CandidatePartition->DriveLetter == 0) ? L'-' : CandidatePartition->DriveLetter);
/* Return the candidate system partition */
return CandidatePartition;
}
// FIXME: What to do??
DPRINT1("NewDisk TRUE but first partition is used?\n");
}
/*
* The disk is not new, check if any partition is initialized;
* if not, the first one becomes the system partition.
*/
for (ListEntry = DiskEntry->PrimaryPartListHead.Flink;
ListEntry != &DiskEntry->PrimaryPartListHead;
ListEntry = ListEntry->Flink)
{
/* Retrieve the partition */
PartEntry = CONTAINING_RECORD(ListEntry, PARTENTRY, ListEntry);
/* Check if the partition is partitioned and is used */
// !IsContainerPartition(PartEntry->PartitionType);
if (/* PartEntry->IsPartitioned && */
PartEntry->PartitionType != PARTITION_ENTRY_UNUSED || PartEntry->BootIndicator)
{
break;
}
}
if (ListEntry == &DiskEntry->PrimaryPartListHead)
{
/*
* OK we haven't encountered any used and active partition,
* so use the first one as the system partition.
*/
ASSERT(DiskEntry == CandidatePartition->DiskEntry);
DPRINT1("Use first active system partition %lu in disk %lu, drive letter %C\n",
CandidatePartition->PartitionNumber,
CandidatePartition->DiskEntry->DiskNumber,
(CandidatePartition->DriveLetter == 0) ? L'-' : CandidatePartition->DriveLetter);
/* Return the candidate system partition */
return CandidatePartition;
}
/*
* The disk is not new, we did not find any actual active partition,
* or the one we found was not supported, or any possible other candidate
* is not supported. We then use the alternative partition if specified.
*/
if (AlternativePart)
{
DPRINT1("No valid or supported system partition has been found, use the alternative partition!\n");
CandidatePartition = AlternativePart;
goto UseAlternativePartition;
}
else
{
NoSystemPartition:
DPRINT1("No valid or supported system partition has been found on this system!\n");
return NULL;
}
UseAlternativePartition:
/*
* We are here because we did not find any (active) candidate system
* partition that we know how to support. What we are going to do is
* to change the existing system partition and use the alternative partition
* (e.g. on which we install ReactOS) as the new system partition.
* Then we will need to add in FreeLdr's boot menu an entry for booting
* from the original system partition.
*/
ASSERT(CandidatePartition);
DPRINT1("Use alternative active system partition %lu in disk %lu, drive letter %C\n",
CandidatePartition->PartitionNumber,
CandidatePartition->DiskEntry->DiskNumber,
(CandidatePartition->DriveLetter == 0) ? L'-' : CandidatePartition->DriveLetter);
/* Return the candidate system partition */
return CandidatePartition;
}
BOOLEAN
SetActivePartition(
IN PPARTLIST List,
IN PPARTENTRY PartEntry,
IN PPARTENTRY OldActivePart OPTIONAL)
{
/* Check for empty disk list */
if (IsListEmpty(&List->DiskListHead))
return FALSE;
/* Validate the partition entry */
if (!PartEntry)
return FALSE;
/*
* If the partition entry is already the system partition, or if it is
* the same as the old active partition hint the user provided (and if
* it is already active), just return success.
*/
if ((PartEntry == List->SystemPartition) ||
((PartEntry == OldActivePart) && IsPartitionActive(OldActivePart)))
{
return TRUE;
}
ASSERT(PartEntry->DiskEntry);
/* Ensure that the partition's disk is in the list */
ASSERT(PartEntry->DiskEntry->PartList == List);
/*
* If the user provided an old active partition hint, verify that it is
* indeeed active and belongs to the same disk where the new partition
* belongs. Otherwise determine the current active partition on the disk
* where the new partition belongs.
*/
if (!(OldActivePart && IsPartitionActive(OldActivePart) && (OldActivePart->DiskEntry == PartEntry->DiskEntry)))
{
/* It's not, determine the current active partition for the disk */
OldActivePart = GetActiveDiskPartition(PartEntry->DiskEntry);
}
/* Unset the old active partition if it exists */
if (OldActivePart)
{
OldActivePart->BootIndicator = FALSE;
OldActivePart->DiskEntry->LayoutBuffer->PartitionEntry[OldActivePart->PartitionIndex].BootIndicator = FALSE;
OldActivePart->DiskEntry->LayoutBuffer->PartitionEntry[OldActivePart->PartitionIndex].RewritePartition = TRUE;
OldActivePart->DiskEntry->Dirty = TRUE;
}
/* Modify the system partition if the new partition is on the system disk */
if (PartEntry->DiskEntry == GetSystemDisk(List))
List->SystemPartition = PartEntry;
/* Set the new active partition */
PartEntry->BootIndicator = TRUE;
PartEntry->DiskEntry->LayoutBuffer->PartitionEntry[PartEntry->PartitionIndex].BootIndicator = TRUE;
PartEntry->DiskEntry->LayoutBuffer->PartitionEntry[PartEntry->PartitionIndex].RewritePartition = TRUE;
PartEntry->DiskEntry->Dirty = TRUE;
return TRUE;
}
NTSTATUS
WritePartitions(
IN PDISKENTRY DiskEntry)
{
NTSTATUS Status;
OBJECT_ATTRIBUTES ObjectAttributes;
UNICODE_STRING Name;
HANDLE FileHandle;
IO_STATUS_BLOCK Iosb;
ULONG BufferSize;
PPARTITION_INFORMATION PartitionInfo;
ULONG PartitionCount;
PLIST_ENTRY ListEntry;
PPARTENTRY PartEntry;
WCHAR DstPath[MAX_PATH];
DPRINT("WritePartitions() Disk: %lu\n", DiskEntry->DiskNumber);
/* If the disk is not dirty, there is nothing to do */
if (!DiskEntry->Dirty)
return STATUS_SUCCESS;
RtlStringCchPrintfW(DstPath, ARRAYSIZE(DstPath),
L"\\Device\\Harddisk%lu\\Partition0",
DiskEntry->DiskNumber);
RtlInitUnicodeString(&Name, DstPath);
InitializeObjectAttributes(&ObjectAttributes,
&Name,
OBJ_CASE_INSENSITIVE,
NULL,
NULL);
Status = NtOpenFile(&FileHandle,
GENERIC_READ | GENERIC_WRITE | SYNCHRONIZE,
&ObjectAttributes,
&Iosb,
0,
FILE_SYNCHRONOUS_IO_NONALERT);
if (!NT_SUCCESS(Status))
{
DPRINT1("NtOpenFile() failed (Status %lx)\n", Status);
return Status;
}
#ifdef DUMP_PARTITION_TABLE
DumpPartitionTable(DiskEntry);
#endif
//
// FIXME: We first *MUST* use IOCTL_DISK_CREATE_DISK to initialize
// the disk in MBR or GPT format in case the disk was not initialized!!
// For this we must ask the user which format to use.
//
/* Save the original partition count to be restored later (see comment below) */
PartitionCount = DiskEntry->LayoutBuffer->PartitionCount;
/* Set the new disk layout and retrieve its updated version with possibly modified partition numbers */
BufferSize = sizeof(DRIVE_LAYOUT_INFORMATION) +
((PartitionCount - 1) * sizeof(PARTITION_INFORMATION));
Status = NtDeviceIoControlFile(FileHandle,
NULL,
NULL,
NULL,
&Iosb,
IOCTL_DISK_SET_DRIVE_LAYOUT,
DiskEntry->LayoutBuffer,
BufferSize,
DiskEntry->LayoutBuffer,
BufferSize);
NtClose(FileHandle);
/*
* IOCTL_DISK_SET_DRIVE_LAYOUT calls IoWritePartitionTable(), which converts
* DiskEntry->LayoutBuffer->PartitionCount into a partition *table* count,
* where such a table is expected to enumerate up to 4 partitions:
* partition *table* count == ROUND_UP(PartitionCount, 4) / 4 .
* Due to this we need to restore the original PartitionCount number.
*/
DiskEntry->LayoutBuffer->PartitionCount = PartitionCount;
/* Check whether the IOCTL_DISK_SET_DRIVE_LAYOUT call succeeded */
if (!NT_SUCCESS(Status))
{
DPRINT1("IOCTL_DISK_SET_DRIVE_LAYOUT failed (Status 0x%08lx)\n", Status);
return Status;
}
#ifdef DUMP_PARTITION_TABLE
DumpPartitionTable(DiskEntry);
#endif
/* Update the partition numbers */
/* Update the primary partition table */
for (ListEntry = DiskEntry->PrimaryPartListHead.Flink;
ListEntry != &DiskEntry->PrimaryPartListHead;
ListEntry = ListEntry->Flink)
{
PartEntry = CONTAINING_RECORD(ListEntry, PARTENTRY, ListEntry);
if (PartEntry->IsPartitioned)
{
ASSERT(PartEntry->PartitionType != PARTITION_ENTRY_UNUSED);
PartitionInfo = &DiskEntry->LayoutBuffer->PartitionEntry[PartEntry->PartitionIndex];
PartEntry->PartitionNumber = PartitionInfo->PartitionNumber;
}
}
/* Update the logical partition table */
for (ListEntry = DiskEntry->LogicalPartListHead.Flink;
ListEntry != &DiskEntry->LogicalPartListHead;
ListEntry = ListEntry->Flink)
{
PartEntry = CONTAINING_RECORD(ListEntry, PARTENTRY, ListEntry);
if (PartEntry->IsPartitioned)
{
ASSERT(PartEntry->PartitionType != PARTITION_ENTRY_UNUSED);
PartitionInfo = &DiskEntry->LayoutBuffer->PartitionEntry[PartEntry->PartitionIndex];
PartEntry->PartitionNumber = PartitionInfo->PartitionNumber;
}
}
//
// NOTE: Originally (see r40437), we used to install here also a new MBR
// for this disk (by calling InstallMbrBootCodeToDisk), only if:
// DiskEntry->NewDisk == TRUE and DiskEntry->HwDiskNumber == 0.
// Then after that, both DiskEntry->NewDisk and DiskEntry->NoMbr were set
// to FALSE. In the other place (in usetup.c) where InstallMbrBootCodeToDisk
// was called too, the installation test was modified by checking whether
// DiskEntry->NoMbr was TRUE (instead of NewDisk).
//
// HACK: Parts of FIXMEs described above: (Re)set the PartitionStyle to MBR.
DiskEntry->DiskStyle = PARTITION_STYLE_MBR;
/* The layout has been successfully updated, the disk is not dirty anymore */
DiskEntry->Dirty = FALSE;
return Status;
}
BOOLEAN
WritePartitionsToDisk(
IN PPARTLIST List)
{
NTSTATUS Status;
PLIST_ENTRY Entry;
PDISKENTRY DiskEntry;
if (List == NULL)
return TRUE;
for (Entry = List->DiskListHead.Flink;
Entry != &List->DiskListHead;
Entry = Entry->Flink)
{
DiskEntry = CONTAINING_RECORD(Entry, DISKENTRY, ListEntry);
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT("GPT-partitioned disk detected, not currently supported by SETUP!\n");
continue;
}
if (DiskEntry->Dirty != FALSE)
{
Status = WritePartitions(DiskEntry);
if (!NT_SUCCESS(Status))
{
DPRINT1("WritePartitionsToDisk() failed to update disk %lu, Status 0x%08lx\n",
DiskEntry->DiskNumber, Status);
}
}
}
return TRUE;
}
BOOLEAN
SetMountedDeviceValue(
IN WCHAR Letter,
IN ULONG Signature,
IN LARGE_INTEGER StartingOffset)
{
NTSTATUS Status;
OBJECT_ATTRIBUTES ObjectAttributes;
UNICODE_STRING KeyName = RTL_CONSTANT_STRING(L"SYSTEM\\MountedDevices");
UNICODE_STRING ValueName;
WCHAR ValueNameBuffer[16];
HANDLE KeyHandle;
REG_DISK_MOUNT_INFO MountInfo;
RtlStringCchPrintfW(ValueNameBuffer, ARRAYSIZE(ValueNameBuffer),
L"\\DosDevices\\%c:", Letter);
RtlInitUnicodeString(&ValueName, ValueNameBuffer);
InitializeObjectAttributes(&ObjectAttributes,
&KeyName,
OBJ_CASE_INSENSITIVE,
GetRootKeyByPredefKey(HKEY_LOCAL_MACHINE, NULL),
NULL);
Status = NtOpenKey(&KeyHandle,
KEY_ALL_ACCESS,
&ObjectAttributes);
if (!NT_SUCCESS(Status))
{
Status = NtCreateKey(&KeyHandle,
KEY_ALL_ACCESS,
&ObjectAttributes,
0,
NULL,
REG_OPTION_NON_VOLATILE,
NULL);
}
if (!NT_SUCCESS(Status))
{
DPRINT1("NtCreateKey() failed (Status %lx)\n", Status);
return FALSE;
}
MountInfo.Signature = Signature;
MountInfo.StartingOffset = StartingOffset;
Status = NtSetValueKey(KeyHandle,
&ValueName,
0,
REG_BINARY,
(PVOID)&MountInfo,
sizeof(MountInfo));
NtClose(KeyHandle);
if (!NT_SUCCESS(Status))
{
DPRINT1("NtSetValueKey() failed (Status %lx)\n", Status);
return FALSE;
}
return TRUE;
}
BOOLEAN
SetMountedDeviceValues(
IN PPARTLIST List)
{
PLIST_ENTRY Entry1, Entry2;
PDISKENTRY DiskEntry;
PPARTENTRY PartEntry;
LARGE_INTEGER StartingOffset;
if (List == NULL)
return FALSE;
for (Entry1 = List->DiskListHead.Flink;
Entry1 != &List->DiskListHead;
Entry1 = Entry1->Flink)
{
DiskEntry = CONTAINING_RECORD(Entry1,
DISKENTRY,
ListEntry);
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT("GPT-partitioned disk detected, not currently supported by SETUP!\n");
continue;
}
for (Entry2 = DiskEntry->PrimaryPartListHead.Flink;
Entry2 != &DiskEntry->PrimaryPartListHead;
Entry2 = Entry2->Flink)
{
PartEntry = CONTAINING_RECORD(Entry2, PARTENTRY, ListEntry);
if (PartEntry->IsPartitioned) // && !IsContainerPartition(PartEntry->PartitionType)
{
ASSERT(PartEntry->PartitionType != PARTITION_ENTRY_UNUSED);
/* Assign a "\DosDevices\#:" mount point to this partition */
if (PartEntry->DriveLetter)
{
StartingOffset.QuadPart = PartEntry->StartSector.QuadPart * DiskEntry->BytesPerSector;
if (!SetMountedDeviceValue(PartEntry->DriveLetter,
DiskEntry->LayoutBuffer->Signature,
StartingOffset))
{
return FALSE;
}
}
}
}
for (Entry2 = DiskEntry->LogicalPartListHead.Flink;
Entry2 != &DiskEntry->LogicalPartListHead;
Entry2 = Entry2->Flink)
{
PartEntry = CONTAINING_RECORD(Entry2, PARTENTRY, ListEntry);
if (PartEntry->IsPartitioned) // && !IsContainerPartition(PartEntry->PartitionType)
{
ASSERT(PartEntry->PartitionType != PARTITION_ENTRY_UNUSED);
/* Assign a "\DosDevices\#:" mount point to this partition */
if (PartEntry->DriveLetter)
{
StartingOffset.QuadPart = PartEntry->StartSector.QuadPart * DiskEntry->BytesPerSector;
if (!SetMountedDeviceValue(PartEntry->DriveLetter,
DiskEntry->LayoutBuffer->Signature,
StartingOffset))
{
return FALSE;
}
}
}
}
}
return TRUE;
}
VOID
SetMBRPartitionType(
IN PPARTENTRY PartEntry,
IN UCHAR PartitionType)
{
PDISKENTRY DiskEntry = PartEntry->DiskEntry;
ASSERT(DiskEntry->DiskStyle == PARTITION_STYLE_MBR);
PartEntry->PartitionType = PartitionType;
DiskEntry->Dirty = TRUE;
DiskEntry->LayoutBuffer->PartitionEntry[PartEntry->PartitionIndex].PartitionType = PartitionType;
DiskEntry->LayoutBuffer->PartitionEntry[PartEntry->PartitionIndex].RecognizedPartition = IsRecognizedPartition(PartitionType);
DiskEntry->LayoutBuffer->PartitionEntry[PartEntry->PartitionIndex].RewritePartition = TRUE;
}
ERROR_NUMBER
PrimaryPartitionCreationChecks(
IN PPARTENTRY PartEntry)
{
PDISKENTRY DiskEntry = PartEntry->DiskEntry;
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT1("GPT-partitioned disk detected, not currently supported by SETUP!\n");
return ERROR_WARN_PARTITION;
}
/* Fail if the partition is already in use */
if (PartEntry->IsPartitioned)
return ERROR_NEW_PARTITION;
/* Only one primary partition is allowed on super-floppy */
if (IsSuperFloppy(DiskEntry))
return ERROR_PARTITION_TABLE_FULL;
/* Fail if there are already 4 primary partitions in the list */
if (GetPrimaryPartitionCount(DiskEntry) >= 4)
return ERROR_PARTITION_TABLE_FULL;
return ERROR_SUCCESS;
}
ERROR_NUMBER
ExtendedPartitionCreationChecks(
IN PPARTENTRY PartEntry)
{
PDISKENTRY DiskEntry = PartEntry->DiskEntry;
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT1("GPT-partitioned disk detected, not currently supported by SETUP!\n");
return ERROR_WARN_PARTITION;
}
/* Fail if the partition is already in use */
if (PartEntry->IsPartitioned)
return ERROR_NEW_PARTITION;
/* Only one primary partition is allowed on super-floppy */
if (IsSuperFloppy(DiskEntry))
return ERROR_PARTITION_TABLE_FULL;
/* Fail if there are already 4 primary partitions in the list */
if (GetPrimaryPartitionCount(DiskEntry) >= 4)
return ERROR_PARTITION_TABLE_FULL;
/* Fail if there is another extended partition in the list */
if (DiskEntry->ExtendedPartition != NULL)
return ERROR_ONLY_ONE_EXTENDED;
return ERROR_SUCCESS;
}
ERROR_NUMBER
LogicalPartitionCreationChecks(
IN PPARTENTRY PartEntry)
{
PDISKENTRY DiskEntry = PartEntry->DiskEntry;
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT1("GPT-partitioned disk detected, not currently supported by SETUP!\n");
return ERROR_WARN_PARTITION;
}
/* Fail if the partition is already in use */
if (PartEntry->IsPartitioned)
return ERROR_NEW_PARTITION;
/* Only one primary partition is allowed on super-floppy */
if (IsSuperFloppy(DiskEntry))
return ERROR_PARTITION_TABLE_FULL;
return ERROR_SUCCESS;
}
BOOLEAN
GetNextUnformattedPartition(
IN PPARTLIST List,
OUT PDISKENTRY *pDiskEntry OPTIONAL,
OUT PPARTENTRY *pPartEntry)
{
PLIST_ENTRY Entry1, Entry2;
PDISKENTRY DiskEntry;
PPARTENTRY PartEntry;
for (Entry1 = List->DiskListHead.Flink;
Entry1 != &List->DiskListHead;
Entry1 = Entry1->Flink)
{
DiskEntry = CONTAINING_RECORD(Entry1,
DISKENTRY,
ListEntry);
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT("GPT-partitioned disk detected, not currently supported by SETUP!\n");
continue;
}
for (Entry2 = DiskEntry->PrimaryPartListHead.Flink;
Entry2 != &DiskEntry->PrimaryPartListHead;
Entry2 = Entry2->Flink)
{
PartEntry = CONTAINING_RECORD(Entry2, PARTENTRY, ListEntry);
if (PartEntry->IsPartitioned && PartEntry->New)
{
ASSERT(DiskEntry == PartEntry->DiskEntry);
if (pDiskEntry) *pDiskEntry = DiskEntry;
*pPartEntry = PartEntry;
return TRUE;
}
}
for (Entry2 = DiskEntry->LogicalPartListHead.Flink;
Entry2 != &DiskEntry->LogicalPartListHead;
Entry2 = Entry2->Flink)
{
PartEntry = CONTAINING_RECORD(Entry2, PARTENTRY, ListEntry);
if (PartEntry->IsPartitioned && PartEntry->New)
{
ASSERT(DiskEntry == PartEntry->DiskEntry);
if (pDiskEntry) *pDiskEntry = DiskEntry;
*pPartEntry = PartEntry;
return TRUE;
}
}
}
if (pDiskEntry) *pDiskEntry = NULL;
*pPartEntry = NULL;
return FALSE;
}
BOOLEAN
GetNextUncheckedPartition(
IN PPARTLIST List,
OUT PDISKENTRY *pDiskEntry OPTIONAL,
OUT PPARTENTRY *pPartEntry)
{
PLIST_ENTRY Entry1, Entry2;
PDISKENTRY DiskEntry;
PPARTENTRY PartEntry;
for (Entry1 = List->DiskListHead.Flink;
Entry1 != &List->DiskListHead;
Entry1 = Entry1->Flink)
{
DiskEntry = CONTAINING_RECORD(Entry1,
DISKENTRY,
ListEntry);
if (DiskEntry->DiskStyle == PARTITION_STYLE_GPT)
{
DPRINT("GPT-partitioned disk detected, not currently supported by SETUP!\n");
continue;
}
for (Entry2 = DiskEntry->PrimaryPartListHead.Flink;
Entry2 != &DiskEntry->PrimaryPartListHead;
Entry2 = Entry2->Flink)
{
PartEntry = CONTAINING_RECORD(Entry2, PARTENTRY, ListEntry);
if (PartEntry->IsPartitioned && PartEntry->NeedsCheck)
{
ASSERT(DiskEntry == PartEntry->DiskEntry);
if (pDiskEntry) *pDiskEntry = DiskEntry;
*pPartEntry = PartEntry;
return TRUE;
}
}
for (Entry2 = DiskEntry->LogicalPartListHead.Flink;
Entry2 != &DiskEntry->LogicalPartListHead;
Entry2 = Entry2->Flink)
{
PartEntry = CONTAINING_RECORD(Entry2, PARTENTRY, ListEntry);
if (PartEntry->IsPartitioned && PartEntry->NeedsCheck)
{
ASSERT(DiskEntry == PartEntry->DiskEntry);
if (pDiskEntry) *pDiskEntry = DiskEntry;
*pPartEntry = PartEntry;
return TRUE;
}
}
}
if (pDiskEntry) *pDiskEntry = NULL;
*pPartEntry = NULL;
return FALSE;
}
/* EOF */
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