/* SPDX-License-Identifier: LGPL-2.1-or-later */ #include "gpt.h" #include "string-table.h" #include "string-util.h" #include "utf8.h" /* Gently push people towards defining GPT type UUIDs for all architectures we know */ #if !defined(SD_GPT_ROOT_NATIVE) || \ !defined(SD_GPT_ROOT_NATIVE_VERITY) || \ !defined(SD_GPT_ROOT_NATIVE_VERITY_SIG) || \ !defined(SD_GPT_USR_NATIVE) || \ !defined(SD_GPT_USR_NATIVE_VERITY) || \ !defined(SD_GPT_USR_NATIVE_VERITY_SIG) #pragma message "Please define GPT partition types for your architecture." #endif bool partition_designator_is_versioned(PartitionDesignator d) { /* Returns true for all designators where we want to support a concept of "versioning", i.e. which * likely contain software binaries (or hashes thereof) that make sense to be versioned as a * whole. We use this check to automatically pick the newest version of these partitions, by version * comparing the partition labels. */ return IN_SET(d, PARTITION_ROOT, PARTITION_USR, PARTITION_ROOT_VERITY, PARTITION_USR_VERITY, PARTITION_ROOT_VERITY_SIG, PARTITION_USR_VERITY_SIG); } PartitionDesignator partition_verity_of(PartitionDesignator p) { switch (p) { case PARTITION_ROOT: return PARTITION_ROOT_VERITY; case PARTITION_USR: return PARTITION_USR_VERITY; default: return _PARTITION_DESIGNATOR_INVALID; } } PartitionDesignator partition_verity_sig_of(PartitionDesignator p) { switch (p) { case PARTITION_ROOT: return PARTITION_ROOT_VERITY_SIG; case PARTITION_USR: return PARTITION_USR_VERITY_SIG; default: return _PARTITION_DESIGNATOR_INVALID; } } PartitionDesignator partition_verity_to_data(PartitionDesignator d) { switch (d) { case PARTITION_ROOT_VERITY: return PARTITION_ROOT; case PARTITION_USR_VERITY: return PARTITION_USR; default: return _PARTITION_DESIGNATOR_INVALID; } } PartitionDesignator partition_verity_sig_to_data(PartitionDesignator d) { switch (d) { case PARTITION_ROOT_VERITY_SIG: return PARTITION_ROOT; case PARTITION_USR_VERITY_SIG: return PARTITION_USR; default: return _PARTITION_DESIGNATOR_INVALID; } } static const char *const partition_designator_table[_PARTITION_DESIGNATOR_MAX] = { [PARTITION_ROOT] = "root", [PARTITION_USR] = "usr", [PARTITION_HOME] = "home", [PARTITION_SRV] = "srv", [PARTITION_ESP] = "esp", [PARTITION_XBOOTLDR] = "xbootldr", [PARTITION_SWAP] = "swap", [PARTITION_ROOT_VERITY] = "root-verity", [PARTITION_USR_VERITY] = "usr-verity", [PARTITION_ROOT_VERITY_SIG] = "root-verity-sig", [PARTITION_USR_VERITY_SIG] = "usr-verity-sig", [PARTITION_TMP] = "tmp", [PARTITION_VAR] = "var", }; DEFINE_STRING_TABLE_LOOKUP(partition_designator, PartitionDesignator); static const char *const partition_mountpoint_table[_PARTITION_DESIGNATOR_MAX] = { [PARTITION_ROOT] = "/\0", [PARTITION_USR] = "/usr\0", [PARTITION_HOME] = "/home\0", [PARTITION_SRV] = "/srv\0", [PARTITION_ESP] = "/efi\0/boot\0", [PARTITION_XBOOTLDR] = "/boot\0", [PARTITION_TMP] = "/var/tmp\0", [PARTITION_VAR] = "/var\0", }; DEFINE_PRIVATE_STRING_TABLE_LOOKUP_TO_STRING(partition_mountpoint, PartitionDesignator); #define _GPT_ARCH_SEXTET(arch, name) \ { SD_GPT_ROOT_##arch, "root-" name, ARCHITECTURE_##arch, .designator = PARTITION_ROOT }, \ { SD_GPT_ROOT_##arch##_VERITY, "root-" name "-verity", ARCHITECTURE_##arch, .designator = PARTITION_ROOT_VERITY }, \ { SD_GPT_ROOT_##arch##_VERITY_SIG, "root-" name "-verity-sig", ARCHITECTURE_##arch, .designator = PARTITION_ROOT_VERITY_SIG }, \ { SD_GPT_USR_##arch, "usr-" name, ARCHITECTURE_##arch, .designator = PARTITION_USR }, \ { SD_GPT_USR_##arch##_VERITY, "usr-" name "-verity", ARCHITECTURE_##arch, .designator = PARTITION_USR_VERITY }, \ { SD_GPT_USR_##arch##_VERITY_SIG, "usr-" name "-verity-sig", ARCHITECTURE_##arch, .designator = PARTITION_USR_VERITY_SIG } /* Two special cases: alias aarch64 to arm64, and amd64 to x86-64. The DSP mixes debianisms and CPUisms: for * x86, it uses x86 and x86_64, but for aarch64 it uses arm64. This is confusing, and leads to issues for * callers that have to know which -ism to use for which architecture. But we also don't really want to * change the spec and add new partition labels, so add a user-friendly aliasing here, so that both are * accepted but the end result on disk (ie: the partition label). * So always list the canonical name FIRST, and then any aliases later, so that we can match on aliases, * but always return the canonical name. And never return directly a match on the name, always re-resolve * by UUID so that the canonical entry is always found. */ const GptPartitionType gpt_partition_type_table[] = { _GPT_ARCH_SEXTET(ALPHA, "alpha"), _GPT_ARCH_SEXTET(ARC, "arc"), _GPT_ARCH_SEXTET(ARM, "arm"), _GPT_ARCH_SEXTET(ARM, "armv7l"), /* Alias: must be listed after arm */ _GPT_ARCH_SEXTET(ARM64, "arm64"), _GPT_ARCH_SEXTET(ARM64, "aarch64"), /* Alias: must be listed after arm64 */ _GPT_ARCH_SEXTET(IA64, "ia64"), _GPT_ARCH_SEXTET(LOONGARCH64, "loongarch64"), _GPT_ARCH_SEXTET(MIPS, "mips"), _GPT_ARCH_SEXTET(MIPS64, "mips64"), _GPT_ARCH_SEXTET(MIPS_LE, "mips-le"), _GPT_ARCH_SEXTET(MIPS64_LE, "mips64-le"), _GPT_ARCH_SEXTET(PARISC, "parisc"), _GPT_ARCH_SEXTET(PPC, "ppc"), _GPT_ARCH_SEXTET(PPC64, "ppc64"), _GPT_ARCH_SEXTET(PPC64_LE, "ppc64-le"), _GPT_ARCH_SEXTET(PPC64_LE, "ppc64le"), /* Alias: must be listed after ppc64-le */ _GPT_ARCH_SEXTET(RISCV32, "riscv32"), _GPT_ARCH_SEXTET(RISCV64, "riscv64"), _GPT_ARCH_SEXTET(S390, "s390"), _GPT_ARCH_SEXTET(S390X, "s390x"), _GPT_ARCH_SEXTET(TILEGX, "tilegx"), _GPT_ARCH_SEXTET(X86, "x86"), _GPT_ARCH_SEXTET(X86_64, "x86-64"), _GPT_ARCH_SEXTET(X86_64, "x86_64"), /* Alias: must be listed after x86-64 */ _GPT_ARCH_SEXTET(X86_64, "amd64"), /* Alias: must be listed after x86-64 */ #ifdef SD_GPT_ROOT_NATIVE { SD_GPT_ROOT_NATIVE, "root", native_architecture(), .designator = PARTITION_ROOT }, { SD_GPT_ROOT_NATIVE_VERITY, "root-verity", native_architecture(), .designator = PARTITION_ROOT_VERITY }, { SD_GPT_ROOT_NATIVE_VERITY_SIG, "root-verity-sig", native_architecture(), .designator = PARTITION_ROOT_VERITY_SIG }, { SD_GPT_USR_NATIVE, "usr", native_architecture(), .designator = PARTITION_USR }, { SD_GPT_USR_NATIVE_VERITY, "usr-verity", native_architecture(), .designator = PARTITION_USR_VERITY }, { SD_GPT_USR_NATIVE_VERITY_SIG, "usr-verity-sig", native_architecture(), .designator = PARTITION_USR_VERITY_SIG }, #endif #ifdef SD_GPT_ROOT_SECONDARY { SD_GPT_ROOT_SECONDARY, "root-secondary", ARCHITECTURE_SECONDARY, .designator = PARTITION_ROOT }, { SD_GPT_ROOT_SECONDARY_VERITY, "root-secondary-verity", ARCHITECTURE_SECONDARY, .designator = PARTITION_ROOT_VERITY }, { SD_GPT_ROOT_SECONDARY_VERITY_SIG, "root-secondary-verity-sig", ARCHITECTURE_SECONDARY, .designator = PARTITION_ROOT_VERITY_SIG }, { SD_GPT_USR_SECONDARY, "usr-secondary", ARCHITECTURE_SECONDARY, .designator = PARTITION_USR }, { SD_GPT_USR_SECONDARY_VERITY, "usr-secondary-verity", ARCHITECTURE_SECONDARY, .designator = PARTITION_USR_VERITY }, { SD_GPT_USR_SECONDARY_VERITY_SIG, "usr-secondary-verity-sig", ARCHITECTURE_SECONDARY, .designator = PARTITION_USR_VERITY_SIG }, #endif { SD_GPT_ESP, "esp", _ARCHITECTURE_INVALID, .designator = PARTITION_ESP }, { SD_GPT_XBOOTLDR, "xbootldr", _ARCHITECTURE_INVALID, .designator = PARTITION_XBOOTLDR }, { SD_GPT_SWAP, "swap", _ARCHITECTURE_INVALID, .designator = PARTITION_SWAP }, { SD_GPT_HOME, "home", _ARCHITECTURE_INVALID, .designator = PARTITION_HOME }, { SD_GPT_SRV, "srv", _ARCHITECTURE_INVALID, .designator = PARTITION_SRV }, { SD_GPT_VAR, "var", _ARCHITECTURE_INVALID, .designator = PARTITION_VAR }, { SD_GPT_TMP, "tmp", _ARCHITECTURE_INVALID, .designator = PARTITION_TMP }, { SD_GPT_USER_HOME, "user-home", _ARCHITECTURE_INVALID, .designator = _PARTITION_DESIGNATOR_INVALID }, { SD_GPT_LINUX_GENERIC, "linux-generic", _ARCHITECTURE_INVALID, .designator = _PARTITION_DESIGNATOR_INVALID }, {} }; static const GptPartitionType *gpt_partition_type_find_by_uuid(sd_id128_t id) { FOREACH_ARRAY(t, gpt_partition_type_table, ELEMENTSOF(gpt_partition_type_table) - 1) if (sd_id128_equal(id, t->uuid)) return t; return NULL; } const char *gpt_partition_type_uuid_to_string(sd_id128_t id) { const GptPartitionType *pt; pt = gpt_partition_type_find_by_uuid(id); if (!pt) return NULL; return pt->name; } const char *gpt_partition_type_uuid_to_string_harder( sd_id128_t id, char buffer[static SD_ID128_UUID_STRING_MAX]) { const char *s; assert(buffer); s = gpt_partition_type_uuid_to_string(id); if (s) return s; return sd_id128_to_uuid_string(id, buffer); } int gpt_partition_type_from_string(const char *s, GptPartitionType *ret) { sd_id128_t id = SD_ID128_NULL; int r; assert(s); FOREACH_ARRAY(t, gpt_partition_type_table, ELEMENTSOF(gpt_partition_type_table) - 1) if (streq(s, t->name)) { /* Don't return immediately, instead re-resolve by UUID so that we can support * aliases like aarch64 -> arm64 transparently. */ id = t->uuid; break; } if (sd_id128_is_null(id)) { r = sd_id128_from_string(s, &id); if (r < 0) return r; } if (ret) *ret = gpt_partition_type_from_uuid(id); return 0; } GptPartitionType gpt_partition_type_override_architecture(GptPartitionType type, Architecture arch) { assert(arch >= 0); FOREACH_ARRAY(t, gpt_partition_type_table, ELEMENTSOF(gpt_partition_type_table) - 1) if (t->designator == type.designator && t->arch == arch) return *t; /* If we can't find an entry with the same designator and the requested architecture, just return the * original partition type. */ return type; } Architecture gpt_partition_type_uuid_to_arch(sd_id128_t id) { const GptPartitionType *pt; pt = gpt_partition_type_find_by_uuid(id); if (!pt) return _ARCHITECTURE_INVALID; return pt->arch; } int gpt_partition_label_valid(const char *s) { _cleanup_free_ char16_t *recoded = NULL; recoded = utf8_to_utf16(s, SIZE_MAX); if (!recoded) return -ENOMEM; return char16_strlen(recoded) <= GPT_LABEL_MAX; } GptPartitionType gpt_partition_type_from_uuid(sd_id128_t id) { const GptPartitionType *pt; pt = gpt_partition_type_find_by_uuid(id); if (pt) return *pt; return (GptPartitionType) { .uuid = id, .arch = _ARCHITECTURE_INVALID, .designator = _PARTITION_DESIGNATOR_INVALID, }; } const char *gpt_partition_type_mountpoint_nulstr(GptPartitionType type) { return partition_mountpoint_to_string(type.designator); } bool gpt_partition_type_knows_read_only(GptPartitionType type) { return IN_SET(type.designator, PARTITION_ROOT, PARTITION_USR, /* pretty much implied, but let's set the bit to make things really clear */ PARTITION_ROOT_VERITY, PARTITION_USR_VERITY, PARTITION_HOME, PARTITION_SRV, PARTITION_VAR, PARTITION_TMP, PARTITION_XBOOTLDR); } bool gpt_partition_type_knows_growfs(GptPartitionType type) { return IN_SET(type.designator, PARTITION_ROOT, PARTITION_USR, PARTITION_HOME, PARTITION_SRV, PARTITION_VAR, PARTITION_TMP, PARTITION_XBOOTLDR); } bool gpt_partition_type_knows_no_auto(GptPartitionType type) { return IN_SET(type.designator, PARTITION_ROOT, PARTITION_ROOT_VERITY, PARTITION_USR, PARTITION_USR_VERITY, PARTITION_HOME, PARTITION_SRV, PARTITION_VAR, PARTITION_TMP, PARTITION_XBOOTLDR, PARTITION_SWAP); } bool gpt_header_has_signature(const GptHeader *p) { assert(p); if (memcmp(p->signature, (const char[8]) { 'E', 'F', 'I', ' ', 'P', 'A', 'R', 'T' }, 8) != 0) return false; if (le32toh(p->revision) != UINT32_C(0x00010000)) /* the only known revision of the spec: 1.0 */ return false; if (le32toh(p->header_size) < sizeof(GptHeader)) return false; if (le32toh(p->header_size) > 4096) /* larger than a sector? something is off… */ return false; if (le64toh(p->my_lba) != 1) /* this sector must claim to be at sector offset 1 */ return false; return true; }