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|
/* $Id: dvmmbr.cpp $ */
/** @file
* IPRT Disk Volume Management API (DVM) - MBR format backend.
*/
/*
* Copyright (C) 2011-2019 Oracle Corporation
*
* This file is part of VirtualBox Open Source Edition (OSE), as
* available from http://www.virtualbox.org. This file is free software;
* you can redistribute it and/or modify it under the terms of the GNU
* General Public License (GPL) as published by the Free Software
* Foundation, in version 2 as it comes in the "COPYING" file of the
* VirtualBox OSE distribution. VirtualBox OSE is distributed in the
* hope that it will be useful, but WITHOUT ANY WARRANTY of any kind.
*
* The contents of this file may alternatively be used under the terms
* of the Common Development and Distribution License Version 1.0
* (CDDL) only, as it comes in the "COPYING.CDDL" file of the
* VirtualBox OSE distribution, in which case the provisions of the
* CDDL are applicable instead of those of the GPL.
*
* You may elect to license modified versions of this file under the
* terms and conditions of either the GPL or the CDDL or both.
*/
/*********************************************************************************************************************************
* Header Files *
*********************************************************************************************************************************/
#define LOG_GROUP RTLOGGROUP_FS
#include <iprt/types.h>
#include <iprt/assert.h>
#include <iprt/mem.h>
#include <iprt/dvm.h>
#include <iprt/list.h>
#include <iprt/log.h>
#include <iprt/string.h>
#include "internal/dvm.h"
/*********************************************************************************************************************************
* Defined Constants And Macros *
*********************************************************************************************************************************/
/** Checks if the partition type is an extended partition container. */
#define RTDVMMBR_IS_EXTENDED(a_bType) ((a_bType) == 0x05 || (a_bType) == 0x0f)
/*********************************************************************************************************************************
* Structures and Typedefs *
*********************************************************************************************************************************/
/** Pointer to a MBR sector. */
typedef struct RTDVMMBRSECTOR *PRTDVMMBRSECTOR;
/**
* MBR entry.
*/
typedef struct RTDVMMBRENTRY
{
/** Our entry in the in-use partition entry list (RTDVMMBRENTRY). */
RTLISTNODE ListEntry;
/** Pointer to the MBR sector containing this entry. */
PRTDVMMBRSECTOR pSector;
/** Pointer to the next sector in the extended partition table chain. */
PRTDVMMBRSECTOR pChain;
/** The byte offset of the start of the partition (relative to disk). */
uint64_t offPart;
/** Number of bytes for this partition. */
uint64_t cbPart;
/** The partition/filesystem type. */
uint8_t bType;
/** The partition flags. */
uint8_t fFlags;
/** Bad entry. */
bool fBad;
} RTDVMMBRENTRY;
/** Pointer to an MBR entry. */
typedef RTDVMMBRENTRY *PRTDVMMBRENTRY;
/**
* A MBR sector.
*/
typedef struct RTDVMMBRSECTOR
{
/** Internal representation of the entries. */
RTDVMMBRENTRY aEntries[4];
/** The byte offset of this MBR sector (relative to disk).
* We keep this for detecting cycles now, but it will be needed if we start
* updating the partition table at some point. */
uint64_t offOnDisk;
/** Pointer to the previous sector if this isn't a primary one. */
PRTDVMMBRENTRY pPrevSector;
/** Set if this is the primary MBR, cleared if an extended. */
bool fIsPrimary;
/** Number of used entries. */
uint8_t cUsed;
/** Number of extended entries. */
uint8_t cExtended;
/** The extended entry we're following (we only follow one, except when
* fIsPrimary is @c true). UINT8_MAX if none. */
uint8_t idxExtended;
/** The raw data. */
uint8_t abData[512];
} RTDVMMBRSECTOR;
/**
* MBR volume manager data.
*/
typedef struct RTDVMFMTINTERNAL
{
/** Pointer to the underlying disk. */
PCRTDVMDISK pDisk;
/** Head of the list of in-use RTDVMMBRENTRY structures. This excludes
* extended partition table entries. */
RTLISTANCHOR PartitionHead;
/** The total number of partitions, not counting extended ones. */
uint32_t cPartitions;
/** The actual primary MBR sector. */
RTDVMMBRSECTOR Primary;
} RTDVMFMTINTERNAL;
/** Pointer to the MBR volume manager. */
typedef RTDVMFMTINTERNAL *PRTDVMFMTINTERNAL;
/**
* MBR volume data.
*/
typedef struct RTDVMVOLUMEFMTINTERNAL
{
/** Pointer to the volume manager. */
PRTDVMFMTINTERNAL pVolMgr;
/** The MBR entry. */
PRTDVMMBRENTRY pEntry;
} RTDVMVOLUMEFMTINTERNAL;
/** Pointer to an MBR volume. */
typedef RTDVMVOLUMEFMTINTERNAL *PRTDVMVOLUMEFMTINTERNAL;
/*********************************************************************************************************************************
* Global Variables *
*********************************************************************************************************************************/
/**
* Mapping of FS types to DVM volume types.
*
* @see https://en.wikipedia.org/wiki/Partition_type
* @see http://www.win.tue.nl/~aeb/partitions/partition_types-1.html
*/
static const struct RTDVMMBRFS2VOLTYPE
{
/** MBR FS Id. */
uint8_t bFsId;
/** DVM volume type. */
RTDVMVOLTYPE enmVolType;
} g_aFs2DvmVolTypes[] =
{
{ 0x01, RTDVMVOLTYPE_FAT12 },
{ 0x04, RTDVMVOLTYPE_FAT16 },
{ 0x06, RTDVMVOLTYPE_FAT16 }, /* big FAT16 */
{ 0x07, RTDVMVOLTYPE_NTFS }, /* Simplification: Used for HPFS, exFAT, ++, too but NTFS is the more common one. */
{ 0x0b, RTDVMVOLTYPE_FAT32 },
{ 0x0c, RTDVMVOLTYPE_FAT32 },
{ 0x0e, RTDVMVOLTYPE_FAT16 },
/* Hidden variants of the above: */
{ 0x11, RTDVMVOLTYPE_FAT12 },
{ 0x14, RTDVMVOLTYPE_FAT16 },
{ 0x16, RTDVMVOLTYPE_FAT16 },
{ 0x17, RTDVMVOLTYPE_NTFS },
{ 0x1b, RTDVMVOLTYPE_FAT32 },
{ 0x1c, RTDVMVOLTYPE_FAT32 },
{ 0x1e, RTDVMVOLTYPE_FAT16 },
{ 0x82, RTDVMVOLTYPE_LINUX_SWAP },
{ 0x83, RTDVMVOLTYPE_LINUX_NATIVE },
{ 0x8e, RTDVMVOLTYPE_LINUX_LVM },
{ 0xa5, RTDVMVOLTYPE_FREEBSD },
{ 0xa9, RTDVMVOLTYPE_NETBSD },
{ 0xa6, RTDVMVOLTYPE_OPENBSD },
{ 0xaf, RTDVMVOLTYPE_DARWIN_HFS },
{ 0xbf, RTDVMVOLTYPE_SOLARIS },
{ 0xfd, RTDVMVOLTYPE_LINUX_SOFTRAID }
};
static DECLCALLBACK(int) rtDvmFmtMbrProbe(PCRTDVMDISK pDisk, uint32_t *puScore)
{
int rc = VINF_SUCCESS;
*puScore = RTDVM_MATCH_SCORE_UNSUPPORTED;
if (pDisk->cbDisk >= 512)
{
/* Read from the disk and check for the 0x55aa signature at the end. */
uint8_t abMbr[512];
rc = rtDvmDiskRead(pDisk, 0, &abMbr[0], sizeof(abMbr));
if ( RT_SUCCESS(rc)
&& abMbr[510] == 0x55
&& abMbr[511] == 0xaa)
*puScore = RTDVM_MATCH_SCORE_SUPPORTED; /* Not perfect because GPTs have a protective MBR. */
}
return rc;
}
static void rtDvmFmtMbrDestroy(PRTDVMFMTINTERNAL pThis)
{
/*
* Delete chains of extended partitions.
*/
for (unsigned i = 0; i < 4; i++)
{
PRTDVMMBRSECTOR pCur = pThis->Primary.aEntries[i].pChain;
while (pCur)
{
PRTDVMMBRSECTOR pNext = pCur->idxExtended != UINT8_MAX ? pCur->aEntries[pCur->idxExtended].pChain : NULL;
RT_ZERO(pCur->aEntries);
pCur->pPrevSector = NULL;
RTMemFree(pCur);
pCur = pNext;
}
}
/*
* Now kill this.
*/
pThis->pDisk = NULL;
RT_ZERO(pThis->Primary.aEntries);
RTMemFree(pThis);
}
static int rtDvmFmtMbrReadExtended(PRTDVMFMTINTERNAL pThis, PRTDVMMBRENTRY pPrimaryEntry)
{
uint64_t const cbExt = pPrimaryEntry->cbPart;
uint64_t const offExtBegin = pPrimaryEntry->offPart;
uint64_t offCurBegin = offExtBegin;
PRTDVMMBRENTRY pCurEntry = pPrimaryEntry;
for (unsigned cTables = 1; ; cTables++)
{
/*
* Do some sanity checking.
*/
/* Check the address of the partition table. */
if (offCurBegin - offExtBegin >= cbExt)
{
LogRel(("rtDvmFmtMbrReadExtended: offCurBegin=%#RX64 is outside the extended partition: %#RX64..%#RX64 (LB %#RX64)\n",
offCurBegin, offExtBegin, offExtBegin + cbExt - 1, cbExt));
pCurEntry->fBad = true;
return -VERR_OUT_OF_RANGE;
}
/* Limit the chain length. */
if (cTables > 64)
{
LogRel(("rtDvmFmtMbrReadExtended: offCurBegin=%#RX64 is the %uth table, we stop here.\n", offCurBegin, cTables));
pCurEntry->fBad = true;
return -VERR_TOO_MANY_SYMLINKS;
}
/* Check for obvious cycles. */
for (PRTDVMMBRENTRY pPrev = pCurEntry->pSector->pPrevSector; pPrev != NULL; pPrev = pPrev->pSector->pPrevSector)
if (pPrev->offPart == offCurBegin)
{
LogRel(("rtDvmFmtMbrReadExtended: Cycle! We've seen offCurBegin=%#RX64 before\n", offCurBegin));
pCurEntry->fBad = true;
return -VERR_TOO_MANY_SYMLINKS;
}
/*
* Allocate a new sector entry and read the sector with the table.
*/
PRTDVMMBRSECTOR pNext = (PRTDVMMBRSECTOR)RTMemAllocZ(sizeof(*pNext));
if (!pNext)
return VERR_NO_MEMORY;
pNext->offOnDisk = offCurBegin;
pNext->pPrevSector = pCurEntry;
//pNext->fIsPrimary = false;
//pNext->cUsed = 0;
//pNext->cExtended = 0;
pNext->idxExtended = UINT8_MAX;
int rc = rtDvmDiskRead(pThis->pDisk, pNext->offOnDisk, &pNext->abData[0], sizeof(pNext->abData));
if ( RT_FAILURE(rc)
|| pNext->abData[510] != 0x55
|| pNext->abData[511] != 0xaa)
{
if (RT_FAILURE(rc))
LogRel(("rtDvmFmtMbrReadExtended: Error reading extended partition table at sector %#RX64: %Rrc\n", offCurBegin, rc));
else
LogRel(("rtDvmFmtMbrReadExtended: Extended partition table at sector %#RX64 does not have a valid DOS signature: %#x %#x\n",
offCurBegin, pNext->abData[510], pNext->abData[511]));
RTMemFree(pNext);
pCurEntry->fBad = true;
return rc;
}
pCurEntry->pChain = pNext;
/*
* Process the table, taking down the first forward entry.
*
* As noted in the caller of this function, we only deal with one extended
* partition entry at this level since noone really ever put more than one
* here anyway.
*/
PRTDVMMBRENTRY pEntry = &pNext->aEntries[0];
uint8_t *pbMbrEntry = &pNext->abData[446];
for (unsigned i = 0; i < 4; i++, pEntry++, pbMbrEntry += 16)
{
uint8_t const bType = pbMbrEntry[4];
pEntry->pSector = pNext;
RTListInit(&pEntry->ListEntry);
if (bType != 0)
{
pEntry->bType = bType;
pEntry->fFlags = pbMbrEntry[0];
pEntry->offPart = RT_MAKE_U32_FROM_U8(pbMbrEntry[0x08],
pbMbrEntry[0x08 + 1],
pbMbrEntry[0x08 + 2],
pbMbrEntry[0x08 + 3]);
pEntry->offPart *= 512;
pEntry->cbPart = RT_MAKE_U32_FROM_U8(pbMbrEntry[0x0c],
pbMbrEntry[0x0c + 1],
pbMbrEntry[0x0c + 2],
pbMbrEntry[0x0c + 3]);
pEntry->cbPart *= 512;
if (!RTDVMMBR_IS_EXTENDED(bType))
{
pEntry->offPart += offCurBegin;
pThis->cPartitions++;
RTListAppend(&pThis->PartitionHead, &pEntry->ListEntry);
Log2(("rtDvmFmtMbrReadExtended: %#012RX64::%u: vol%u bType=%#04x fFlags=%#04x offPart=%#012RX64 cbPart=%#012RX64\n",
offCurBegin, i, pThis->cPartitions - 1, pEntry->bType, pEntry->fFlags, pEntry->offPart, pEntry->cbPart));
}
else
{
pEntry->offPart += offExtBegin;
pNext->cExtended++;
if (pNext->idxExtended == UINT8_MAX)
pNext->idxExtended = (uint8_t)i;
else
{
pEntry->fBad = true;
LogRel(("rtDvmFmtMbrReadExtended: Warning! Both #%u and #%u are extended partition table entries! Only following the former\n",
i, pNext->idxExtended));
}
Log2(("rtDvmFmtMbrReadExtended: %#012RX64::%u: ext%u bType=%#04x fFlags=%#04x offPart=%#012RX64 cbPart=%#012RX64\n",
offCurBegin, i, pNext->cExtended - 1, pEntry->bType, pEntry->fFlags, pEntry->offPart, pEntry->cbPart));
}
pNext->cUsed++;
}
/* else: unused */
}
/*
* We're done if we didn't find any extended partition table entry.
* Otherwise, advance to the next one.
*/
if (!pNext->cExtended)
return VINF_SUCCESS;
pCurEntry = &pNext->aEntries[pNext->idxExtended];
offCurBegin = pCurEntry->offPart;
}
}
static DECLCALLBACK(int) rtDvmFmtMbrOpen(PCRTDVMDISK pDisk, PRTDVMFMT phVolMgrFmt)
{
int rc;
PRTDVMFMTINTERNAL pThis = (PRTDVMFMTINTERNAL)RTMemAllocZ(sizeof(RTDVMFMTINTERNAL));
if (pThis)
{
pThis->pDisk = pDisk;
//pThis->cPartitions = 0;
RTListInit(&pThis->PartitionHead);
//pThis->Primary.offOnDisk = 0;
//pThis->Primary.pPrevSector = NULL;
pThis->Primary.fIsPrimary = true;
//pThis->Primary.cUsed = 0;
//pThis->Primary.cExtended = 0;
pThis->Primary.idxExtended = UINT8_MAX;
/*
* Read the primary MBR.
*/
rc = rtDvmDiskRead(pDisk, 0, &pThis->Primary.abData[0], sizeof(pThis->Primary.abData));
if (RT_SUCCESS(rc))
{
Assert(pThis->Primary.abData[510] == 0x55 && pThis->Primary.abData[511] == 0xaa);
/*
* Setup basic data for the 4 entries.
*/
PRTDVMMBRENTRY pEntry = &pThis->Primary.aEntries[0];
uint8_t *pbMbrEntry = &pThis->Primary.abData[446];
for (unsigned i = 0; i < 4; i++, pEntry++, pbMbrEntry += 16)
{
pEntry->pSector = &pThis->Primary;
RTListInit(&pEntry->ListEntry);
uint8_t const bType = pbMbrEntry[4];
if (bType != 0)
{
pEntry->offPart = RT_MAKE_U32_FROM_U8(pbMbrEntry[0x08 + 0],
pbMbrEntry[0x08 + 1],
pbMbrEntry[0x08 + 2],
pbMbrEntry[0x08 + 3]);
pEntry->offPart *= 512;
pEntry->cbPart = RT_MAKE_U32_FROM_U8(pbMbrEntry[0x0c + 0],
pbMbrEntry[0x0c + 1],
pbMbrEntry[0x0c + 2],
pbMbrEntry[0x0c + 3]);
pEntry->cbPart *= 512;
pEntry->bType = bType;
pEntry->fFlags = pbMbrEntry[0];
if (!RTDVMMBR_IS_EXTENDED(bType))
{
pThis->cPartitions++;
RTListAppend(&pThis->PartitionHead, &pEntry->ListEntry);
Log2(("rtDvmFmtMbrOpen: %u: vol%u bType=%#04x fFlags=%#04x offPart=%#012RX64 cbPart=%#012RX64\n",
i, pThis->cPartitions - 1, pEntry->bType, pEntry->fFlags, pEntry->offPart, pEntry->cbPart));
}
else
{
pThis->Primary.cExtended++;
Log2(("rtDvmFmtMbrOpen: %u: ext%u bType=%#04x fFlags=%#04x offPart=%#012RX64 cbPart=%#012RX64\n",
i, pThis->Primary.cExtended - 1, pEntry->bType, pEntry->fFlags, pEntry->offPart, pEntry->cbPart));
}
pThis->Primary.cUsed++;
}
/* else: unused */
}
/*
* Now read any extended partitions. Since it's no big deal for us, we allow
* the primary partition table to have more than one extended partition. However
* in the extended tables we only allow a single forward link to avoid having to
* deal with recursion.
*/
if (pThis->Primary.cExtended > 0)
for (unsigned i = 0; i < 4; i++)
if (RTDVMMBR_IS_EXTENDED(pThis->Primary.aEntries[i].bType))
{
if (pThis->Primary.idxExtended == UINT8_MAX)
pThis->Primary.idxExtended = (uint8_t)i;
rc = rtDvmFmtMbrReadExtended(pThis, &pThis->Primary.aEntries[i]);
if (RT_FAILURE(rc))
break;
}
if (RT_SUCCESS(rc))
{
*phVolMgrFmt = pThis;
return rc;
}
}
}
else
rc = VERR_NO_MEMORY;
return rc;
}
static DECLCALLBACK(int) rtDvmFmtMbrInitialize(PCRTDVMDISK pDisk, PRTDVMFMT phVolMgrFmt)
{
int rc;
PRTDVMFMTINTERNAL pThis = (PRTDVMFMTINTERNAL)RTMemAllocZ(sizeof(RTDVMFMTINTERNAL));
if (pThis)
{
pThis->pDisk = pDisk;
//pThis->cPartitions = 0;
RTListInit(&pThis->PartitionHead);
//pThis->Primary.offOnDisk = 0
//pThis->Primary.pPrevSector = NULL;
pThis->Primary.fIsPrimary = true;
//pThis->Primary.cUsed = 0;
//pThis->Primary.cExtended = 0;
pThis->Primary.idxExtended = UINT8_MAX;
/* Setup a new MBR and write it to the disk. */
pThis->Primary.abData[510] = 0x55;
pThis->Primary.abData[511] = 0xaa;
rc = rtDvmDiskWrite(pDisk, 0, &pThis->Primary.abData[0], sizeof(pThis->Primary.abData));
if (RT_SUCCESS(rc))
{
pThis->pDisk = pDisk;
*phVolMgrFmt = pThis;
}
else
RTMemFree(pThis);
}
else
rc = VERR_NO_MEMORY;
return rc;
}
static DECLCALLBACK(void) rtDvmFmtMbrClose(RTDVMFMT hVolMgrFmt)
{
rtDvmFmtMbrDestroy(hVolMgrFmt);
}
static DECLCALLBACK(int) rtDvmFmtMbrQueryRangeUse(RTDVMFMT hVolMgrFmt, uint64_t off, uint64_t cbRange, bool *pfUsed)
{
PRTDVMFMTINTERNAL pThis = hVolMgrFmt;
/*
* The MBR definitely uses the first 512 bytes, but we consider anything up
* to 1MB of alignment padding / cylinder gap to be considered in use too.
*
* The cylinder gap has been used by several boot managers and boot loaders
* to store code and data.
*/
if (off < (uint64_t)_1M)
{
*pfUsed = true;
return VINF_SUCCESS;
}
/* Ditto for any extended partition tables. */
for (uint32_t iPrimary = 0; iPrimary < 4; iPrimary++)
{
PRTDVMMBRSECTOR pCur = pThis->Primary.aEntries[iPrimary].pChain;
while (pCur)
{
if ( off < pCur->offOnDisk + _1M
&& off + cbRange > pCur->offOnDisk)
{
*pfUsed = true;
return VINF_SUCCESS;
}
if (pCur->idxExtended == UINT8_MAX)
break;
pCur = pCur->aEntries[pCur->idxExtended].pChain;
}
}
/* Not in use. */
*pfUsed = false;
return VINF_SUCCESS;
}
static DECLCALLBACK(uint32_t) rtDvmFmtMbrGetValidVolumes(RTDVMFMT hVolMgrFmt)
{
PRTDVMFMTINTERNAL pThis = hVolMgrFmt;
return pThis->cPartitions;
}
static DECLCALLBACK(uint32_t) rtDvmFmtMbrGetMaxVolumes(RTDVMFMT hVolMgrFmt)
{
NOREF(hVolMgrFmt);
return 4; /** @todo Add support for EBR? */
}
/**
* Creates a new volume.
*
* @returns IPRT status code.
* @param pThis The MBR volume manager data.
* @param pEntry The MBR entry to create a volume handle for.
* @param phVolFmt Where to store the volume data on success.
*/
static int rtDvmFmtMbrVolumeCreate(PRTDVMFMTINTERNAL pThis, PRTDVMMBRENTRY pEntry, PRTDVMVOLUMEFMT phVolFmt)
{
PRTDVMVOLUMEFMTINTERNAL pVol = (PRTDVMVOLUMEFMTINTERNAL)RTMemAllocZ(sizeof(RTDVMVOLUMEFMTINTERNAL));
if (pVol)
{
pVol->pVolMgr = pThis;
pVol->pEntry = pEntry;
*phVolFmt = pVol;
return VINF_SUCCESS;
}
return VERR_NO_MEMORY;
}
static DECLCALLBACK(int) rtDvmFmtMbrQueryFirstVolume(RTDVMFMT hVolMgrFmt, PRTDVMVOLUMEFMT phVolFmt)
{
PRTDVMFMTINTERNAL pThis = hVolMgrFmt;
if (pThis->cPartitions != 0)
return rtDvmFmtMbrVolumeCreate(pThis, RTListGetFirst(&pThis->PartitionHead, RTDVMMBRENTRY, ListEntry), phVolFmt);
return VERR_DVM_MAP_EMPTY;
}
static DECLCALLBACK(int) rtDvmFmtMbrQueryNextVolume(RTDVMFMT hVolMgrFmt, RTDVMVOLUMEFMT hVolFmt, PRTDVMVOLUMEFMT phVolFmtNext)
{
PRTDVMFMTINTERNAL pThis = hVolMgrFmt;
PRTDVMVOLUMEFMTINTERNAL pCurVol = hVolFmt;
if (pCurVol)
{
PRTDVMMBRENTRY pNextEntry = RTListGetNext(&pThis->PartitionHead, pCurVol->pEntry, RTDVMMBRENTRY, ListEntry);
if (pNextEntry)
return rtDvmFmtMbrVolumeCreate(pThis, pNextEntry, phVolFmtNext);
return VERR_DVM_MAP_NO_VOLUME;
}
if (pThis->cPartitions != 0)
return rtDvmFmtMbrVolumeCreate(pThis, RTListGetFirst(&pThis->PartitionHead, RTDVMMBRENTRY, ListEntry), phVolFmtNext);
return VERR_DVM_MAP_EMPTY;
}
static DECLCALLBACK(void) rtDvmFmtMbrVolumeClose(RTDVMVOLUMEFMT hVolFmt)
{
PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
pVol->pVolMgr = NULL;
pVol->pEntry = NULL;
RTMemFree(pVol);
}
static DECLCALLBACK(uint64_t) rtDvmFmtMbrVolumeGetSize(RTDVMVOLUMEFMT hVolFmt)
{
PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
return pVol->pEntry->cbPart;
}
static DECLCALLBACK(int) rtDvmFmtMbrVolumeQueryName(RTDVMVOLUMEFMT hVolFmt, char **ppszVolName)
{
NOREF(hVolFmt); NOREF(ppszVolName);
return VERR_NOT_SUPPORTED;
}
static DECLCALLBACK(RTDVMVOLTYPE) rtDvmFmtMbrVolumeGetType(RTDVMVOLUMEFMT hVolFmt)
{
PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
uint8_t const bType = pVol->pEntry->bType;
for (unsigned i = 0; i < RT_ELEMENTS(g_aFs2DvmVolTypes); i++)
if (g_aFs2DvmVolTypes[i].bFsId == bType)
return g_aFs2DvmVolTypes[i].enmVolType;
return RTDVMVOLTYPE_UNKNOWN;
}
static DECLCALLBACK(uint64_t) rtDvmFmtMbrVolumeGetFlags(RTDVMVOLUMEFMT hVolFmt)
{
PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
uint64_t fFlags = 0;
if (pVol->pEntry->bType & 0x80)
fFlags |= DVMVOLUME_FLAGS_BOOTABLE | DVMVOLUME_FLAGS_ACTIVE;
return fFlags;
}
static DECLCALLBACK(bool) rtDvmFmtMbrVolumeIsRangeIntersecting(RTDVMVOLUMEFMT hVolFmt, uint64_t offStart, size_t cbRange,
uint64_t *poffVol, uint64_t *pcbIntersect)
{
PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
if (RTDVM_RANGE_IS_INTERSECTING(pVol->pEntry->offPart, pVol->pEntry->cbPart, offStart))
{
*poffVol = offStart - pVol->pEntry->offPart;
*pcbIntersect = RT_MIN(cbRange, pVol->pEntry->offPart + pVol->pEntry->cbPart - offStart);
return true;
}
return false;
}
static DECLCALLBACK(int) rtDvmFmtMbrVolumeRead(RTDVMVOLUMEFMT hVolFmt, uint64_t off, void *pvBuf, size_t cbRead)
{
PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
AssertReturn(off + cbRead <= pVol->pEntry->cbPart, VERR_INVALID_PARAMETER);
return rtDvmDiskRead(pVol->pVolMgr->pDisk, pVol->pEntry->offPart + off, pvBuf, cbRead);
}
static DECLCALLBACK(int) rtDvmFmtMbrVolumeWrite(RTDVMVOLUMEFMT hVolFmt, uint64_t off, const void *pvBuf, size_t cbWrite)
{
PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
AssertReturn(off + cbWrite <= pVol->pEntry->cbPart, VERR_INVALID_PARAMETER);
return rtDvmDiskWrite(pVol->pVolMgr->pDisk, pVol->pEntry->offPart + off, pvBuf, cbWrite);
}
RTDVMFMTOPS g_rtDvmFmtMbr =
{
/* pszFmt */
"MBR",
/* enmFormat */
RTDVMFORMATTYPE_MBR,
/* pfnProbe */
rtDvmFmtMbrProbe,
/* pfnOpen */
rtDvmFmtMbrOpen,
/* pfnInitialize */
rtDvmFmtMbrInitialize,
/* pfnClose */
rtDvmFmtMbrClose,
/* pfnQueryRangeUse */
rtDvmFmtMbrQueryRangeUse,
/* pfnGetValidVolumes */
rtDvmFmtMbrGetValidVolumes,
/* pfnGetMaxVolumes */
rtDvmFmtMbrGetMaxVolumes,
/* pfnQueryFirstVolume */
rtDvmFmtMbrQueryFirstVolume,
/* pfnQueryNextVolume */
rtDvmFmtMbrQueryNextVolume,
/* pfnVolumeClose */
rtDvmFmtMbrVolumeClose,
/* pfnVolumeGetSize */
rtDvmFmtMbrVolumeGetSize,
/* pfnVolumeQueryName */
rtDvmFmtMbrVolumeQueryName,
/* pfnVolumeGetType */
rtDvmFmtMbrVolumeGetType,
/* pfnVolumeGetFlags */
rtDvmFmtMbrVolumeGetFlags,
/* pfnVOlumeIsRangeIntersecting */
rtDvmFmtMbrVolumeIsRangeIntersecting,
/* pfnVolumeRead */
rtDvmFmtMbrVolumeRead,
/* pfnVolumeWrite */
rtDvmFmtMbrVolumeWrite
};
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