VirtualBox

source: vbox/trunk/src/VBox/Runtime/common/dvm/dvmgpt.cpp@ 96563

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1/* $Id: dvmgpt.cpp 96407 2022-08-22 17:43:14Z vboxsync $ */
2/** @file
3 * IPRT Disk Volume Management API (DVM) - GPT format backend.
4 */
5
6/*
7 * Copyright (C) 2011-2022 Oracle and/or its affiliates.
8 *
9 * This file is part of VirtualBox base platform packages, as
10 * available from https://www.virtualbox.org.
11 *
12 * This program is free software; you can redistribute it and/or
13 * modify it under the terms of the GNU General Public License
14 * as published by the Free Software Foundation, in version 3 of the
15 * License.
16 *
17 * This program is distributed in the hope that it will be useful, but
18 * WITHOUT ANY WARRANTY; without even the implied warranty of
19 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
20 * General Public License for more details.
21 *
22 * You should have received a copy of the GNU General Public License
23 * along with this program; if not, see <https://www.gnu.org/licenses>.
24 *
25 * The contents of this file may alternatively be used under the terms
26 * of the Common Development and Distribution License Version 1.0
27 * (CDDL), a copy of it is provided in the "COPYING.CDDL" file included
28 * in the VirtualBox distribution, in which case the provisions of the
29 * CDDL are applicable instead of those of the GPL.
30 *
31 * You may elect to license modified versions of this file under the
32 * terms and conditions of either the GPL or the CDDL or both.
33 *
34 * SPDX-License-Identifier: GPL-3.0-only OR CDDL-1.0
35 */
36
37
38/*********************************************************************************************************************************
39* Header Files *
40*********************************************************************************************************************************/
41#include <iprt/dvm.h>
42
43#include <iprt/assert.h>
44#include <iprt/asm.h>
45#include <iprt/mem.h>
46#include <iprt/string.h>
47#include <iprt/utf16.h>
48#include <iprt/uuid.h>
49#include "internal/dvm.h"
50
51
52/*********************************************************************************************************************************
53* Structures and Typedefs *
54*********************************************************************************************************************************/
55/** The GPT signature. */
56#define RTDVM_GPT_SIGNATURE "EFI PART"
57
58/**
59 * GPT on disk header.
60 */
61typedef struct GPTHDR
62{
63 /** 0x00: Signature ("EFI PART"). */
64 char abSignature[8];
65 /** 0x08: Revision. */
66 uint32_t u32Revision;
67 /** 0x0c: Header size. */
68 uint32_t cbHeader;
69 /** 0x10: CRC of header. */
70 uint32_t u32Crc;
71} GPTHDR;
72/** Pointer to a GPT header. */
73typedef struct GPTHDR *PGPTHDR;
74AssertCompileSize(GPTHDR, 20);
75
76/**
77 * Complete GPT table header for revision 1.0.
78 */
79#pragma pack(1)
80typedef struct GPTHDRREV1
81{
82 /** 0x00: Header. */
83 GPTHDR Hdr;
84 /** 0x14: Reserved. */
85 uint32_t u32Reserved;
86 /** 0x18: Current LBA. */
87 uint64_t u64LbaCurrent;
88 /** 0x20: Backup LBA. */
89 uint64_t u64LbaBackup;
90 /** 0x28:First usable LBA for partitions. */
91 uint64_t u64LbaFirstPartition;
92 /** 0x30: Last usable LBA for partitions. */
93 uint64_t u64LbaLastPartition;
94 /** 0x38: Disk UUID. */
95 RTUUID DiskUuid;
96 /** 0x48: LBA of first partition entry. */
97 uint64_t u64LbaPartitionEntries;
98 /** 0x50: Number of partition entries. */
99 uint32_t cPartitionEntries;
100 /** 0x54: Partition entry size. */
101 uint32_t cbPartitionEntry;
102 /** 0x58: CRC of partition entries. */
103 uint32_t u32CrcPartitionEntries;
104} GPTHDRREV1;
105/** Pointer to a revision 1.0 GPT header. */
106typedef GPTHDRREV1 *PGPTHDRREV1;
107#pragma pack()
108AssertCompileSize(GPTHDRREV1, 92);
109
110/**
111 * GPT partition table entry.
112 */
113typedef struct GPTENTRY
114{
115 /** 0x00: Partition type UUID. */
116 RTUUID UuidType;
117 /** 0x10: Partition UUID. */
118 RTUUID UuidPartition;
119 /** 0x20: First LBA. */
120 uint64_t u64LbaFirst;
121 /** 0x28: Last LBA. */
122 uint64_t u64LbaLast;
123 /** 0x30: Attribute flags. */
124 uint64_t u64Flags;
125 /** 0x38: Partition name (UTF-16LE code units). */
126 RTUTF16 aPartitionName[36];
127} GPTENTRY;
128/** Pointer to a GPT entry. */
129typedef struct GPTENTRY *PGPTENTRY;
130AssertCompileSize(GPTENTRY, 128);
131
132/** Partition flags - System partition. */
133#define RTDVM_GPT_ENTRY_SYSTEM RT_BIT_64(0)
134/** Partition flags - Partition is readonly. */
135#define RTDVM_GPT_ENTRY_READONLY RT_BIT_64(60)
136/** Partition flags - Partition is hidden. */
137#define RTDVM_GPT_ENTRY_HIDDEN RT_BIT_64(62)
138/** Partition flags - Don't automount this partition. */
139#define RTDVM_GPT_ENTRY_NO_AUTOMOUNT RT_BIT_64(63)
140
141/**
142 * GPT volume manager data.
143 */
144typedef struct RTDVMFMTINTERNAL
145{
146 /** Pointer to the underlying disk. */
147 PCRTDVMDISK pDisk;
148 /** GPT header. */
149 GPTHDRREV1 HdrRev1;
150 /** GPT array. */
151 PGPTENTRY paGptEntries;
152 /** Number of occupied partition entries. */
153 uint32_t cPartitions;
154} RTDVMFMTINTERNAL;
155/** Pointer to the MBR volume manager. */
156typedef RTDVMFMTINTERNAL *PRTDVMFMTINTERNAL;
157
158/**
159 * GPT volume data.
160 */
161typedef struct RTDVMVOLUMEFMTINTERNAL
162{
163 /** Pointer to the volume manager. */
164 PRTDVMFMTINTERNAL pVolMgr;
165 /** Partition table entry index. */
166 uint32_t idxEntry;
167 /** Start offset of the volume. */
168 uint64_t offStart;
169 /** Size of the volume. */
170 uint64_t cbVolume;
171 /** Pointer to the GPT entry in the array. */
172 PGPTENTRY pGptEntry;
173} RTDVMVOLUMEFMTINTERNAL;
174/** Pointer to an MBR volume. */
175typedef RTDVMVOLUMEFMTINTERNAL *PRTDVMVOLUMEFMTINTERNAL;
176
177/**
178 * GPT partition type to DVM volume type mapping entry.
179 */
180
181typedef struct RTDVMGPTPARTTYPE2VOLTYPE
182{
183 /** Type UUID. */
184 const char *pcszUuid;
185 /** DVM volume type. */
186 RTDVMVOLTYPE enmVolType;
187} RTDVMGPTPARTTYPE2VOLTYPE;
188/** Pointer to a MBR FS Type to volume type mapping entry. */
189typedef RTDVMGPTPARTTYPE2VOLTYPE *PRTDVMGPTPARTTYPE2VOLTYPE;
190
191/** Converts a LBA number to the byte offset. */
192#define RTDVM_GPT_LBA2BYTE(lba, disk) ((lba) * (disk)->cbSector)
193/** Converts a Byte offset to the LBA number. */
194#define RTDVM_GPT_BYTE2LBA(lba, disk) ((lba) / (disk)->cbSector)
195
196
197/*********************************************************************************************************************************
198* Global Variables *
199*********************************************************************************************************************************/
200/**
201 * Mapping of partition types to DVM volume types.
202 *
203 * From http://en.wikipedia.org/wiki/GUID_Partition_Table
204 */
205static const RTDVMGPTPARTTYPE2VOLTYPE g_aPartType2DvmVolTypes[] =
206{
207 { "C12A7328-F81F-11D2-BA4B-00A0C93EC93B", RTDVMVOLTYPE_EFI_SYSTEM },
208
209 { "EBD0A0A2-B9E5-4433-87C0-68B6B72699C7", RTDVMVOLTYPE_WIN_BASIC },
210 { "E3C9E316-0B5C-4DB8-817D-F92DF00215AE", RTDVMVOLTYPE_WIN_MSR },
211 { "5808C8AA-7E8F-42E0-85D2-E1E90434CFB3", RTDVMVOLTYPE_WIN_LDM_META },
212 { "AF9B60A0-1431-4F62-BC68-3311714A69AD", RTDVMVOLTYPE_WIN_LDM_DATA },
213 { "DE94BBA4-06D1-4D40-A16A-BFD50179D6AC", RTDVMVOLTYPE_WIN_RECOVERY },
214 { "E75CAF8F-F680-4CEE-AFA3-B001E56EFC2D", RTDVMVOLTYPE_WIN_STORAGE_SPACES },
215
216 { "0657FD6D-A4AB-43C4-84E5-0933C84B4F4F", RTDVMVOLTYPE_LINUX_SWAP },
217 { "0FC63DAF-8483-4772-8E79-3D69D8477DE4", RTDVMVOLTYPE_LINUX_NATIVE },
218 { "44479540-F297-41B2-9AF7-D131D5F0458A", RTDVMVOLTYPE_LINUX_NATIVE }, /* x86 root */
219 { "4F68BCE3-E8CD-4DB1-96E7-FBCAF984B709", RTDVMVOLTYPE_LINUX_NATIVE }, /* AMD64 root */
220 { "69DAD710-2CE4-4E3C-B16C-21A1D49ABED3", RTDVMVOLTYPE_LINUX_NATIVE }, /* ARM32 root */
221 { "B921B045-1DF0-41C3-AF44-4C6F280D3FAE", RTDVMVOLTYPE_LINUX_NATIVE }, /* ARM64 root */
222 { "E6D6D379-F507-44C2-A23C-238F2A3DF928", RTDVMVOLTYPE_LINUX_LVM },
223 { "A19D880F-05FC-4D3B-A006-743F0F84911E", RTDVMVOLTYPE_LINUX_SOFTRAID },
224
225 { "83BD6B9D-7F41-11DC-BE0B-001560B84F0F", RTDVMVOLTYPE_FREEBSD }, /* Boot */
226 { "516E7CB4-6ECF-11D6-8FF8-00022D09712B", RTDVMVOLTYPE_FREEBSD }, /* Data */
227 { "516E7CB5-6ECF-11D6-8FF8-00022D09712B", RTDVMVOLTYPE_FREEBSD }, /* Swap */
228 { "516E7CB6-6ECF-11D6-8FF8-00022D09712B", RTDVMVOLTYPE_FREEBSD }, /* UFS */
229 { "516E7CB8-6ECF-11D6-8FF8-00022D09712B", RTDVMVOLTYPE_FREEBSD }, /* Vinum */
230 { "516E7CBA-6ECF-11D6-8FF8-00022D09712B", RTDVMVOLTYPE_FREEBSD }, /* ZFS */
231
232 { "49F48D32-B10E-11DC-B99B-0019D1879648", RTDVMVOLTYPE_NETBSD }, /* Swap */
233 { "49F48D5A-B10E-11DC-B99B-0019D1879648", RTDVMVOLTYPE_NETBSD }, /* FFS */
234 { "49F48D82-B10E-11DC-B99B-0019D1879648", RTDVMVOLTYPE_NETBSD }, /* LFS */
235 { "49F48DAA-B10E-11DC-B99B-0019D1879648", RTDVMVOLTYPE_NETBSD }, /* Raid */
236 { "2DB519C4-B10F-11DC-B99B-0019D1879648", RTDVMVOLTYPE_NETBSD }, /* Concatenated */
237 { "2DB519EC-B10F-11DC-B99B-0019D1879648", RTDVMVOLTYPE_NETBSD }, /* Encrypted */
238
239 { "48465300-0000-11AA-AA11-00306543ECAC", RTDVMVOLTYPE_DARWIN_HFS },
240 { "7C3457EF-0000-11AA-AA11-00306543ECAC", RTDVMVOLTYPE_DARWIN_APFS },
241
242 { "6A82CB45-1DD2-11B2-99A6-080020736631", RTDVMVOLTYPE_SOLARIS }, /* Boot */
243 { "6A85CF4D-1DD2-11B2-99A6-080020736631", RTDVMVOLTYPE_SOLARIS }, /* Root */
244 { "6A87C46F-1DD2-11B2-99A6-080020736631", RTDVMVOLTYPE_SOLARIS }, /* Swap */
245 { "6A8B642B-1DD2-11B2-99A6-080020736631", RTDVMVOLTYPE_SOLARIS }, /* Backup */
246 { "6A898CC3-1DD2-11B2-99A6-080020736631", RTDVMVOLTYPE_SOLARIS }, /* /usr */
247 { "6A8EF2E9-1DD2-11B2-99A6-080020736631", RTDVMVOLTYPE_SOLARIS }, /* /var */
248 { "6A90BA39-1DD2-11B2-99A6-080020736631", RTDVMVOLTYPE_SOLARIS }, /* /home */
249 { "6A9283A5-1DD2-11B2-99A6-080020736631", RTDVMVOLTYPE_SOLARIS }, /* Alternate sector */
250
251 { "37AFFC90-EF7D-4E96-91C3-2D7AE055B174", RTDVMVOLTYPE_IBM_GPFS },
252
253 { "90B6FF38-B98F-4358-A21F-48F35B4A8AD3", RTDVMVOLTYPE_ARCA_OS2 }, /* OS/2 type 1 defined by Arca Noae */
254};
255
256static DECLCALLBACK(int) rtDvmFmtGptProbe(PCRTDVMDISK pDisk, uint32_t *puScore)
257{
258 int rc = VINF_SUCCESS;
259 GPTHDR Hdr;
260
261 *puScore = RTDVM_MATCH_SCORE_UNSUPPORTED;
262
263 if (rtDvmDiskGetSectors(pDisk) >= 2)
264 {
265 /* Read from the disk and check for the signature. */
266 rc = rtDvmDiskReadUnaligned(pDisk, RTDVM_GPT_LBA2BYTE(1, pDisk), &Hdr, sizeof(GPTHDR));
267 if ( RT_SUCCESS(rc)
268 && !strncmp(&Hdr.abSignature[0], RTDVM_GPT_SIGNATURE, RT_ELEMENTS(Hdr.abSignature))
269 && RT_LE2H_U32(Hdr.u32Revision) == 0x00010000
270 && RT_LE2H_U32(Hdr.cbHeader) == sizeof(GPTHDRREV1))
271 *puScore = RTDVM_MATCH_SCORE_PERFECT;
272 }
273
274 return rc;
275}
276
277static DECLCALLBACK(int) rtDvmFmtGptOpen(PCRTDVMDISK pDisk, PRTDVMFMT phVolMgrFmt)
278{
279 int rc = VINF_SUCCESS;
280 PRTDVMFMTINTERNAL pThis = NULL;
281
282 pThis = (PRTDVMFMTINTERNAL)RTMemAllocZ(sizeof(RTDVMFMTINTERNAL));
283 if (pThis)
284 {
285 pThis->pDisk = pDisk;
286 pThis->cPartitions = 0;
287
288 /* Read the complete GPT header and convert to host endianess. */
289 rc = rtDvmDiskReadUnaligned(pDisk, RTDVM_GPT_LBA2BYTE(1, pDisk), &pThis->HdrRev1, sizeof(pThis->HdrRev1));
290 if (RT_SUCCESS(rc))
291 {
292 pThis->HdrRev1.Hdr.u32Revision = RT_LE2H_U32(pThis->HdrRev1.Hdr.u32Revision);
293 pThis->HdrRev1.Hdr.cbHeader = RT_LE2H_U32(pThis->HdrRev1.Hdr.cbHeader);
294 pThis->HdrRev1.Hdr.u32Crc = RT_LE2H_U32(pThis->HdrRev1.Hdr.u32Crc);
295 pThis->HdrRev1.u64LbaCurrent = RT_LE2H_U64(pThis->HdrRev1.u64LbaCurrent);
296 pThis->HdrRev1.u64LbaBackup = RT_LE2H_U64(pThis->HdrRev1.u64LbaBackup);
297 pThis->HdrRev1.u64LbaFirstPartition = RT_LE2H_U64(pThis->HdrRev1.u64LbaFirstPartition);
298 pThis->HdrRev1.u64LbaLastPartition = RT_LE2H_U64(pThis->HdrRev1.u64LbaLastPartition);
299 /** @todo Disk UUID */
300 pThis->HdrRev1.u64LbaPartitionEntries = RT_LE2H_U64(pThis->HdrRev1.u64LbaPartitionEntries);
301 pThis->HdrRev1.cPartitionEntries = RT_LE2H_U32(pThis->HdrRev1.cPartitionEntries);
302 pThis->HdrRev1.cbPartitionEntry = RT_LE2H_U32(pThis->HdrRev1.cbPartitionEntry);
303 pThis->HdrRev1.u32CrcPartitionEntries = RT_LE2H_U32(pThis->HdrRev1.u32CrcPartitionEntries);
304
305 if (pThis->HdrRev1.cbPartitionEntry == sizeof(GPTENTRY))
306 {
307 size_t cbAlignedGptEntries = RT_ALIGN_Z(pThis->HdrRev1.cPartitionEntries * pThis->HdrRev1.cbPartitionEntry, pDisk->cbSector);
308 pThis->paGptEntries = (PGPTENTRY)RTMemAllocZ(cbAlignedGptEntries);
309 if (pThis->paGptEntries)
310 {
311 rc = rtDvmDiskRead(pDisk, RTDVM_GPT_LBA2BYTE(pThis->HdrRev1.u64LbaPartitionEntries, pDisk),
312 pThis->paGptEntries, cbAlignedGptEntries);
313 if (RT_SUCCESS(rc))
314 {
315 /* Count the occupied entries. */
316 for (unsigned i = 0; i < pThis->HdrRev1.cPartitionEntries; i++)
317 if (!RTUuidIsNull(&pThis->paGptEntries[i].UuidType))
318 {
319 /* Convert to host endianess. */
320 /** @todo Uuids */
321 pThis->paGptEntries[i].u64LbaFirst = RT_LE2H_U64(pThis->paGptEntries[i].u64LbaFirst);
322 pThis->paGptEntries[i].u64LbaLast = RT_LE2H_U64(pThis->paGptEntries[i].u64LbaLast);
323 pThis->paGptEntries[i].u64Flags = RT_LE2H_U64(pThis->paGptEntries[i].u64Flags);
324 for (unsigned cwc = 0; cwc < RT_ELEMENTS(pThis->paGptEntries[i].aPartitionName); cwc++)
325 pThis->paGptEntries[i].aPartitionName[cwc] = RT_LE2H_U16(pThis->paGptEntries[i].aPartitionName[cwc]);
326
327 pThis->cPartitions++;
328 }
329
330 if (RT_SUCCESS(rc))
331 {
332 *phVolMgrFmt = pThis;
333 return rc;
334 }
335 }
336 RTMemFree(pThis->paGptEntries);
337 }
338 else
339 rc = VERR_NO_MEMORY;
340 }
341 else
342 rc = VERR_NOT_SUPPORTED;
343 }
344 RTMemFree(pThis);
345 }
346 else
347 rc = VERR_NO_MEMORY;
348
349 return rc;
350}
351
352static DECLCALLBACK(int) rtDvmFmtGptInitialize(PCRTDVMDISK pDisk, PRTDVMFMT phVolMgrFmt)
353{
354 NOREF(pDisk); NOREF(phVolMgrFmt);
355 return VERR_NOT_IMPLEMENTED;
356}
357
358static DECLCALLBACK(void) rtDvmFmtGptClose(RTDVMFMT hVolMgrFmt)
359{
360 PRTDVMFMTINTERNAL pThis = hVolMgrFmt;
361
362 pThis->pDisk = NULL;
363 RT_ZERO(pThis->HdrRev1);
364
365 RTMemFree(pThis->paGptEntries);
366 pThis->paGptEntries = NULL;
367
368 RTMemFree(pThis);
369}
370
371static DECLCALLBACK(int) rtDvmFmtGptQueryRangeUse(RTDVMFMT hVolMgrFmt,
372 uint64_t off, uint64_t cbRange,
373 bool *pfUsed)
374{
375 PRTDVMFMTINTERNAL pThis = hVolMgrFmt;
376
377 NOREF(cbRange);
378
379 if (off < 33*pThis->pDisk->cbSector)
380 *pfUsed = true;
381 else
382 *pfUsed = false;
383
384 return VINF_SUCCESS;
385}
386
387/** @copydoc RTDVMFMTOPS::pfnQueryDiskUuid */
388static DECLCALLBACK(int) rtDvmFmtGptQueryDiskUuid(RTDVMFMT hVolMgrFmt, PRTUUID pUuid)
389{
390 PRTDVMFMTINTERNAL pThis = hVolMgrFmt;
391
392 *pUuid = pThis->HdrRev1.DiskUuid;
393 return VINF_SUCCESS;
394}
395
396static DECLCALLBACK(uint32_t) rtDvmFmtGptGetValidVolumes(RTDVMFMT hVolMgrFmt)
397{
398 PRTDVMFMTINTERNAL pThis = hVolMgrFmt;
399
400 return pThis->cPartitions;
401}
402
403static DECLCALLBACK(uint32_t) rtDvmFmtGptGetMaxVolumes(RTDVMFMT hVolMgrFmt)
404{
405 PRTDVMFMTINTERNAL pThis = hVolMgrFmt;
406
407 return pThis->HdrRev1.cPartitionEntries;
408}
409
410/**
411 * Creates a new volume.
412 *
413 * @returns IPRT status code.
414 * @param pThis The MBR volume manager data.
415 * @param pGptEntry The GPT entry.
416 * @param idx The index in the partition array.
417 * @param phVolFmt Where to store the volume data on success.
418 */
419static int rtDvmFmtMbrVolumeCreate(PRTDVMFMTINTERNAL pThis, PGPTENTRY pGptEntry,
420 uint32_t idx, PRTDVMVOLUMEFMT phVolFmt)
421{
422 int rc = VINF_SUCCESS;
423 PRTDVMVOLUMEFMTINTERNAL pVol = (PRTDVMVOLUMEFMTINTERNAL)RTMemAllocZ(sizeof(RTDVMVOLUMEFMTINTERNAL));
424
425 if (pVol)
426 {
427 pVol->pVolMgr = pThis;
428 pVol->idxEntry = idx;
429 pVol->pGptEntry = pGptEntry;
430 pVol->offStart = RTDVM_GPT_LBA2BYTE(pGptEntry->u64LbaFirst, pThis->pDisk);
431 pVol->cbVolume = RTDVM_GPT_LBA2BYTE(pGptEntry->u64LbaLast - pGptEntry->u64LbaFirst + 1, pThis->pDisk);
432
433 *phVolFmt = pVol;
434 }
435 else
436 rc = VERR_NO_MEMORY;
437
438 return rc;
439}
440
441static DECLCALLBACK(int) rtDvmFmtGptQueryFirstVolume(RTDVMFMT hVolMgrFmt, PRTDVMVOLUMEFMT phVolFmt)
442{
443 PRTDVMFMTINTERNAL pThis = hVolMgrFmt;
444
445 if (pThis->cPartitions != 0)
446 {
447 PGPTENTRY pGptEntry = &pThis->paGptEntries[0];
448
449 /* Search for the first non empty entry. */
450 for (unsigned i = 0; i < pThis->HdrRev1.cPartitionEntries; i++)
451 {
452 if (!RTUuidIsNull(&pGptEntry->UuidType))
453 return rtDvmFmtMbrVolumeCreate(pThis, pGptEntry, i, phVolFmt);
454 pGptEntry++;
455 }
456 AssertFailed();
457 }
458 return VERR_DVM_MAP_EMPTY;
459}
460
461static DECLCALLBACK(int) rtDvmFmtGptQueryNextVolume(RTDVMFMT hVolMgrFmt, RTDVMVOLUMEFMT hVolFmt, PRTDVMVOLUMEFMT phVolFmtNext)
462{
463 PRTDVMFMTINTERNAL pThis = hVolMgrFmt;
464 PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
465 PGPTENTRY pGptEntry = pVol->pGptEntry + 1;
466
467 for (unsigned i = pVol->idxEntry + 1; i < pThis->HdrRev1.cPartitionEntries; i++)
468 {
469 if (!RTUuidIsNull(&pGptEntry->UuidType))
470 return rtDvmFmtMbrVolumeCreate(pThis, pGptEntry, i, phVolFmtNext);
471 pGptEntry++;
472 }
473
474 return VERR_DVM_MAP_NO_VOLUME;
475}
476
477/** @copydoc RTDVMFMTOPS::pfnQueryTableLocations */
478static DECLCALLBACK(int) rtDvmFmtGptQueryTableLocations(RTDVMFMT hVolMgrFmt, uint32_t fFlags, PRTDVMTABLELOCATION paLocations,
479 size_t cLocations, size_t *pcActual)
480{
481 PRTDVMFMTINTERNAL pThis = hVolMgrFmt;
482
483 /*
484 * The MBR if requested.
485 */
486 int rc = VINF_SUCCESS;
487 size_t iLoc = 0;
488 if (fFlags & RTDVMMAPQTABLOC_F_INCLUDE_LEGACY)
489 {
490 if (cLocations > 0)
491 {
492 paLocations[iLoc].off = 0;
493 paLocations[iLoc].cb = RTDVM_GPT_LBA2BYTE(1, pThis->pDisk);
494 paLocations[iLoc].cbPadding = 0;
495 }
496 else
497 rc = VERR_BUFFER_OVERFLOW;
498 iLoc++;
499 }
500
501 /*
502 * The GPT.
503 */
504 if (cLocations > iLoc)
505 {
506 uint64_t const offEnd = (pThis->HdrRev1.cPartitionEntries * pThis->HdrRev1.cbPartitionEntry + pThis->pDisk->cbSector - 1)
507 / pThis->pDisk->cbSector
508 * pThis->pDisk->cbSector;
509 paLocations[iLoc].off = RTDVM_GPT_LBA2BYTE(1, pThis->pDisk);
510 paLocations[iLoc].cb = offEnd - paLocations[iLoc].off;
511
512 uint64_t uLbaFirstPart = pThis->pDisk->cbDisk / pThis->pDisk->cbSector;
513 for (unsigned i = 0; i < pThis->HdrRev1.cPartitionEntries; i++)
514 if ( pThis->paGptEntries[i].u64LbaFirst < uLbaFirstPart
515 && !RTUuidIsNull(&pThis->paGptEntries[i].UuidType))
516 uLbaFirstPart = pThis->paGptEntries[i].u64LbaFirst;
517
518 paLocations[iLoc].cbPadding = RTDVM_GPT_LBA2BYTE(uLbaFirstPart, pThis->pDisk);
519 if (paLocations[iLoc].cbPadding > offEnd)
520 paLocations[iLoc].cbPadding -= offEnd;
521 else
522 AssertFailedStmt(paLocations[iLoc].cbPadding = 0);
523 }
524 else
525 rc = VERR_BUFFER_OVERFLOW;
526 iLoc++;
527
528 /*
529 * Return values.
530 */
531 if (pcActual)
532 *pcActual = iLoc;
533 else if (cLocations != iLoc && RT_SUCCESS(rc))
534 {
535 RT_BZERO(&paLocations[iLoc], (cLocations - iLoc) * sizeof(paLocations[0]));
536 rc = VERR_BUFFER_UNDERFLOW;
537 }
538 return rc;
539}
540
541static DECLCALLBACK(void) rtDvmFmtGptVolumeClose(RTDVMVOLUMEFMT hVolFmt)
542{
543 PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
544
545 pVol->pVolMgr = NULL;
546 pVol->offStart = 0;
547 pVol->cbVolume = 0;
548 pVol->pGptEntry = NULL;
549
550 RTMemFree(pVol);
551}
552
553static DECLCALLBACK(uint64_t) rtDvmFmtGptVolumeGetSize(RTDVMVOLUMEFMT hVolFmt)
554{
555 PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
556
557 return pVol->cbVolume;
558}
559
560static DECLCALLBACK(int) rtDvmFmtGptVolumeQueryName(RTDVMVOLUMEFMT hVolFmt, char **ppszVolName)
561{
562 PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
563
564 *ppszVolName = NULL;
565 return RTUtf16ToUtf8Ex(&pVol->pGptEntry->aPartitionName[0], RT_ELEMENTS(pVol->pGptEntry->aPartitionName),
566 ppszVolName, 0, NULL);
567}
568
569static DECLCALLBACK(RTDVMVOLTYPE) rtDvmFmtGptVolumeGetType(RTDVMVOLUMEFMT hVolFmt)
570{
571 PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
572
573 for (unsigned i = 0; i < RT_ELEMENTS(g_aPartType2DvmVolTypes); i++)
574 if (!RTUuidCompareStr(&pVol->pGptEntry->UuidType, g_aPartType2DvmVolTypes[i].pcszUuid))
575 return g_aPartType2DvmVolTypes[i].enmVolType;
576
577 return RTDVMVOLTYPE_UNKNOWN;
578}
579
580static DECLCALLBACK(uint64_t) rtDvmFmtGptVolumeGetFlags(RTDVMVOLUMEFMT hVolFmt)
581{
582 NOREF(hVolFmt);
583 return DVMVOLUME_F_CONTIGUOUS;
584}
585
586static DECLCALLBACK(int) rtDvmFmtGptVolumeQueryRange(RTDVMVOLUMEFMT hVolFmt, uint64_t *poffStart, uint64_t *poffLast)
587{
588 PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
589 *poffStart = pVol->offStart;
590 *poffLast = pVol->offStart + pVol->cbVolume - 1;
591 return VINF_SUCCESS;
592}
593
594static DECLCALLBACK(bool) rtDvmFmtGptVolumeIsRangeIntersecting(RTDVMVOLUMEFMT hVolFmt,
595 uint64_t offStart, size_t cbRange,
596 uint64_t *poffVol,
597 uint64_t *pcbIntersect)
598{
599 PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
600
601 if (RTDVM_RANGE_IS_INTERSECTING(pVol->offStart, pVol->cbVolume, offStart))
602 {
603 *poffVol = offStart - pVol->offStart;
604 *pcbIntersect = RT_MIN(cbRange, pVol->offStart + pVol->cbVolume - offStart);
605 return true;
606 }
607 return false;
608}
609
610/** @copydoc RTDVMFMTOPS::pfnVolumeQueryTableLocation */
611static DECLCALLBACK(int) rtDvmFmtGptVolumeQueryTableLocation(RTDVMVOLUMEFMT hVolFmt, uint64_t *poffTable, uint64_t *pcbTable)
612{
613 PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
614 PRTDVMFMTINTERNAL pVolMgr = pVol->pVolMgr;
615 *poffTable = RTDVM_GPT_LBA2BYTE(1, pVolMgr->pDisk);
616 *pcbTable = RTDVM_GPT_LBA2BYTE(pVolMgr->HdrRev1.u64LbaPartitionEntries, pVolMgr->pDisk)
617 + RT_ALIGN_Z(pVolMgr->HdrRev1.cPartitionEntries * pVolMgr->HdrRev1.cbPartitionEntry, pVolMgr->pDisk->cbSector)
618 - *poffTable;
619 return VINF_SUCCESS;
620}
621
622/** @copydoc RTDVMFMTOPS::pfnVolumeGetIndex */
623static DECLCALLBACK(uint32_t) rtDvmFmtGptVolumeGetIndex(RTDVMVOLUMEFMT hVolFmt, RTDVMVOLIDX enmIndex)
624{
625 PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
626 switch (enmIndex)
627 {
628 case RTDVMVOLIDX_USER_VISIBLE:
629 case RTDVMVOLIDX_ALL:
630 case RTDVMVOLIDX_LINUX:
631 return pVol->idxEntry + 1;
632
633 case RTDVMVOLIDX_IN_TABLE:
634 return pVol->idxEntry;
635
636 case RTDVMVOLIDX_INVALID:
637 case RTDVMVOLIDX_HOST:
638 case RTDVMVOLIDX_END:
639 case RTDVMVOLIDX_32BIT_HACK:
640 break;
641 /* no default! */
642 }
643 AssertFailed();
644 return UINT32_MAX;
645}
646
647/** @copydoc RTDVMFMTOPS::pfnVolumeQueryProp */
648static DECLCALLBACK(int) rtDvmFmtGptVolumeQueryProp(RTDVMVOLUMEFMT hVolFmt, RTDVMVOLPROP enmProperty,
649 void *pvBuf, size_t cbBuf, size_t *pcbBuf)
650{
651 PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
652 switch (enmProperty)
653 {
654 case RTDVMVOLPROP_MBR_FIRST_CYLINDER:
655 case RTDVMVOLPROP_MBR_FIRST_HEAD:
656 case RTDVMVOLPROP_MBR_FIRST_SECTOR:
657 case RTDVMVOLPROP_MBR_LAST_CYLINDER:
658 case RTDVMVOLPROP_MBR_LAST_HEAD:
659 case RTDVMVOLPROP_MBR_LAST_SECTOR:
660 case RTDVMVOLPROP_MBR_TYPE:
661 return VERR_NOT_SUPPORTED;
662
663 case RTDVMVOLPROP_GPT_TYPE:
664 *pcbBuf = sizeof(RTUUID);
665 Assert(cbBuf >= *pcbBuf);
666 *(PRTUUID)pvBuf = pVol->pGptEntry->UuidType;
667 return VINF_SUCCESS;
668
669 case RTDVMVOLPROP_GPT_UUID:
670 *pcbBuf = sizeof(RTUUID);
671 Assert(cbBuf >= *pcbBuf);
672 *(PRTUUID)pvBuf = pVol->pGptEntry->UuidPartition;
673 return VINF_SUCCESS;
674
675 case RTDVMVOLPROP_INVALID:
676 case RTDVMVOLPROP_END:
677 case RTDVMVOLPROP_32BIT_HACK:
678 break;
679 /* not default! */
680 }
681 AssertFailed();
682 RT_NOREF(cbBuf);
683 return VERR_NOT_SUPPORTED;
684}
685
686static DECLCALLBACK(int) rtDvmFmtGptVolumeRead(RTDVMVOLUMEFMT hVolFmt, uint64_t off, void *pvBuf, size_t cbRead)
687{
688 PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
689 AssertReturn(off + cbRead <= pVol->cbVolume, VERR_INVALID_PARAMETER);
690
691 return rtDvmDiskRead(pVol->pVolMgr->pDisk, pVol->offStart + off, pvBuf, cbRead);
692}
693
694static DECLCALLBACK(int) rtDvmFmtGptVolumeWrite(RTDVMVOLUMEFMT hVolFmt, uint64_t off, const void *pvBuf, size_t cbWrite)
695{
696 PRTDVMVOLUMEFMTINTERNAL pVol = hVolFmt;
697 AssertReturn(off + cbWrite <= pVol->cbVolume, VERR_INVALID_PARAMETER);
698
699 return rtDvmDiskWrite(pVol->pVolMgr->pDisk, pVol->offStart + off, pvBuf, cbWrite);
700}
701
702DECL_HIDDEN_CONST(const RTDVMFMTOPS) g_rtDvmFmtGpt =
703{
704 /* pszFmt */
705 "GPT",
706 /* enmFormat, */
707 RTDVMFORMATTYPE_GPT,
708 /* pfnProbe */
709 rtDvmFmtGptProbe,
710 /* pfnOpen */
711 rtDvmFmtGptOpen,
712 /* pfnInitialize */
713 rtDvmFmtGptInitialize,
714 /* pfnClose */
715 rtDvmFmtGptClose,
716 /* pfnQueryRangeUse */
717 rtDvmFmtGptQueryRangeUse,
718 /* pfnQueryDiskUuid */
719 rtDvmFmtGptQueryDiskUuid,
720 /* pfnGetValidVolumes */
721 rtDvmFmtGptGetValidVolumes,
722 /* pfnGetMaxVolumes */
723 rtDvmFmtGptGetMaxVolumes,
724 /* pfnQueryFirstVolume */
725 rtDvmFmtGptQueryFirstVolume,
726 /* pfnQueryNextVolume */
727 rtDvmFmtGptQueryNextVolume,
728 /* pfnQueryTableLocations */
729 rtDvmFmtGptQueryTableLocations,
730 /* pfnVolumeClose */
731 rtDvmFmtGptVolumeClose,
732 /* pfnVolumeGetSize */
733 rtDvmFmtGptVolumeGetSize,
734 /* pfnVolumeQueryName */
735 rtDvmFmtGptVolumeQueryName,
736 /* pfnVolumeGetType */
737 rtDvmFmtGptVolumeGetType,
738 /* pfnVolumeGetFlags */
739 rtDvmFmtGptVolumeGetFlags,
740 /* pfnVolumeQueryRange */
741 rtDvmFmtGptVolumeQueryRange,
742 /* pfnVolumeIsRangeIntersecting */
743 rtDvmFmtGptVolumeIsRangeIntersecting,
744 /* pfnVolumeQueryTableLocation */
745 rtDvmFmtGptVolumeQueryTableLocation,
746 /* pfnVolumeGetIndex */
747 rtDvmFmtGptVolumeGetIndex,
748 /* pfnVolumeQueryProp */
749 rtDvmFmtGptVolumeQueryProp,
750 /* pfnVolumeRead */
751 rtDvmFmtGptVolumeRead,
752 /* pfnVolumeWrite */
753 rtDvmFmtGptVolumeWrite
754};
755
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