/* Copyright (c) 2012 The Chromium OS Authors. All rights reserved. * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #ifndef VBOOT_REFERENCE_CGPT_H_ #define VBOOT_REFERENCE_CGPT_H_ #include #ifndef HAVE_MACOS #include #endif #include #include #include #include "cgpt_endian.h" #include "cgptlib.h" #include "gpt.h" struct legacy_partition { uint8_t status; uint8_t f_head; uint8_t f_sect; uint8_t f_cyl; uint8_t type; uint8_t l_head; uint8_t l_sect; uint8_t l_cyl; uint32_t f_lba; uint32_t num_sect; } __attribute__((packed)); // syslinux uses this format: struct pmbr { uint8_t bootcode[424]; Guid boot_guid; uint32_t disk_id; uint8_t magic[2]; // 0x1d, 0x9a struct legacy_partition part[4]; uint8_t sig[2]; // 0x55, 0xaa } __attribute__((packed)); void PMBRToStr(struct pmbr *pmbr, char *str, unsigned int buflen); // Handle to the drive storing the GPT. struct drive { uint64_t size; /* total size (in bytes) */ GptData gpt; struct pmbr pmbr; int fd; /* file descriptor */ }; // Opens a block device or file, loads raw GPT data from it. // 'mode' should be O_RDONLY or O_RDWR. // If 'drive_size' is 0, both the partitions and GPT structs reside on the same // 'drive_path'. // Otherwise, 'drive_size' is taken as the size of the device that all // partitions will reside on, and 'drive_path' is where we store GPT structs. // // Returns CGPT_FAILED if any error happens. // Returns CGPT_OK if success and information are stored in 'drive'. */ int DriveOpen(const char *drive_path, struct drive *drive, int mode, uint64_t drive_size); int DriveClose(struct drive *drive, int update_as_needed); int CheckValid(const struct drive *drive); /* Loads sectors from 'drive'. * *buf is pointed to an allocated memory when returned, and should be * freed. * * drive -- open drive. * buf -- pointer to buffer pointer * sector -- offset of starting sector (in sectors) * sector_bytes -- bytes per sector * sector_count -- number of sectors to load * * Returns CGPT_OK for successful. Aborts if any error occurs. */ int Load(struct drive *drive, uint8_t **buf, const uint64_t sector, const uint64_t sector_bytes, const uint64_t sector_count); /* Saves sectors to 'drive'. * * drive -- open drive * buf -- pointer to buffer * sector -- starting sector offset * sector_bytes -- bytes per sector * sector_count -- number of sector to save * * Returns CGPT_OK for successful, CGPT_FAILED for failed. */ int Save(struct drive *drive, const uint8_t *buf, const uint64_t sector, const uint64_t sector_bytes, const uint64_t sector_count); /* Constant global type values to compare against */ extern const Guid guid_chromeos_firmware; extern const Guid guid_chromeos_kernel; extern const Guid guid_chromeos_rootfs; extern const Guid guid_linux_data; extern const Guid guid_chromeos_reserved; extern const Guid guid_efi; extern const Guid guid_unused; int ReadPMBR(struct drive *drive); int WritePMBR(struct drive *drive); /* Convert possibly unterminated UTF16 string to UTF8. * Caller must prepare enough space for UTF8, which could be up to * twice the byte length of UTF16 string plus the terminating '\0'. * * Return: CGPT_OK --- all character are converted successfully. * CGPT_FAILED --- convert error, i.e. output buffer is too short. */ int UTF16ToUTF8(const uint16_t *utf16, unsigned int maxinput, uint8_t *utf8, unsigned int maxoutput); /* Convert null-terminated UTF8 string to UTF16. * Caller must prepare enough space for UTF16, which is the byte length of UTF8 * plus the terminating 0x0000. * * Return: CGPT_OK --- all character are converted successfully. * CGPT_FAILED --- convert error, i.e. output buffer is too short. */ int UTF8ToUTF16(const uint8_t *utf8, uint16_t *utf16, unsigned int maxoutput); /* Helper functions for supported GPT types. */ int ResolveType(const Guid *type, char *buf); int SupportedType(const char *name, Guid *type); void PrintTypes(void); void EntryDetails(GptEntry *entry, uint32_t index, int raw); uint32_t GetNumberOfEntries(const struct drive *drive); GptEntry *GetEntry(GptData *gpt, int secondary, uint32_t entry_index); void SetRequired(struct drive *drive, int secondary, uint32_t entry_index, int required); int GetRequired(struct drive *drive, int secondary, uint32_t entry_index); void SetLegacyBoot(struct drive *drive, int secondary, uint32_t entry_index, int legacy_boot); int GetLegacyBoot(struct drive *drive, int secondary, uint32_t entry_index); void SetPriority(struct drive *drive, int secondary, uint32_t entry_index, int priority); int GetPriority(struct drive *drive, int secondary, uint32_t entry_index); void SetTries(struct drive *drive, int secondary, uint32_t entry_index, int tries); int GetTries(struct drive *drive, int secondary, uint32_t entry_index); void SetSuccessful(struct drive *drive, int secondary, uint32_t entry_index, int success); int GetSuccessful(struct drive *drive, int secondary, uint32_t entry_index); void SetRaw(struct drive *drive, int secondary, uint32_t entry_index, uint32_t raw); void UpdateAllEntries(struct drive *drive); uint8_t RepairHeader(GptData *gpt, const uint32_t valid_headers); uint8_t RepairEntries(GptData *gpt, const uint32_t valid_entries); void UpdateCrc(GptData *gpt); int IsSynonymous(const GptHeader* a, const GptHeader* b); int IsUnused(struct drive *drive, int secondary, uint32_t index); int IsKernel(struct drive *drive, int secondary, uint32_t index); // Optional. Applications that need this must provide an implementation. // // Explanation: // Some external utilities need to manipulate the GPT, but don't create new // partitions from scratch. The cgpt executable uses libuuid to provide this // functionality, but we don't want to have to build or install a separate // instance of that library just for the 32-bit static post-install tool, // which doesn't need this function. int GenerateGuid(Guid *newguid); // For usage and error messages. void Error(const char *format, ...); void Warning(const char *format, ...); // Command functions. int check_int_parse(char option, const char *buf); int check_int_limit(char option, int val, int low, int high); int cmd_show(int argc, char *argv[]); int cmd_repair(int argc, char *argv[]); int cmd_create(int argc, char *argv[]); int cmd_add(int argc, char *argv[]); int cmd_boot(int argc, char *argv[]); int cmd_find(int argc, char *argv[]); int cmd_edit(int argc, char *argv[]); int cmd_prioritize(int argc, char *argv[]); int cmd_legacy(int argc, char *argv[]); #define ARRAY_COUNT(array) (sizeof(array)/sizeof((array)[0])) const char *GptError(int errnum); // Size in chars of the GPT Entry's PartitionName field #define GPT_PARTNAME_LEN 72 /* The standard "assert" macro goes away when NDEBUG is defined. This doesn't. */ #define require(A) do { \ if (!(A)) { \ fprintf(stderr, "condition (%s) failed at %s:%d\n", \ #A, __FILE__, __LINE__); \ exit(1); } \ } while (0) #endif /* VBOOT_REFERENCE_CGPT_H_ */