1 /* SPDX-License-Identifier: LGPL-2.1-or-later */
3 #if HAVE_VALGRIND_MEMCHECK_H
4 #include <valgrind/memcheck.h>
10 #include <linux/loop.h>
12 #include <sys/ioctl.h>
15 #include "sd-device.h"
18 #include "alloc-util.h"
19 #include "blkid-util.h"
20 #include "blockdev-util.h"
21 #include "btrfs-util.h"
24 #include "conf-files.h"
25 #include "conf-parser.h"
26 #include "constants.h"
27 #include "cryptsetup-util.h"
28 #include "device-util.h"
29 #include "devnum-util.h"
30 #include "dirent-util.h"
32 #include "errno-util.h"
34 #include "fdisk-util.h"
36 #include "format-table.h"
37 #include "format-util.h"
39 #include "glyph-util.h"
41 #include "hexdecoct.h"
43 #include "id128-util.h"
44 #include "initrd-util.h"
48 #include "loop-util.h"
49 #include "main-func.h"
51 #include "mkfs-util.h"
52 #include "mount-util.h"
53 #include "mountpoint-util.h"
54 #include "nulstr-util.h"
55 #include "openssl-util.h"
56 #include "parse-argument.h"
57 #include "parse-helpers.h"
58 #include "pretty-print.h"
59 #include "proc-cmdline.h"
60 #include "process-util.h"
61 #include "random-util.h"
62 #include "resize-fs.h"
64 #include "sort-util.h"
65 #include "specifier.h"
66 #include "stdio-util.h"
67 #include "string-table.h"
68 #include "string-util.h"
70 #include "sync-util.h"
71 #include "terminal-util.h"
72 #include "tmpfile-util.h"
74 #include "tpm2-util.h"
75 #include "user-util.h"
78 /* If not configured otherwise use a minimal partition size of 10M */
79 #define DEFAULT_MIN_SIZE (10ULL*1024ULL*1024ULL)
81 /* Hard lower limit for new partition sizes */
82 #define HARD_MIN_SIZE 4096ULL
84 /* We know up front we're never going to put more than this in a verity sig partition. */
85 #define VERITY_SIG_SIZE (HARD_MIN_SIZE*4ULL)
87 /* libfdisk takes off slightly more than 1M of the disk size when creating a GPT disk label */
88 #define GPT_METADATA_SIZE (1044ULL*1024ULL)
90 /* LUKS2 takes off 16M of the partition size with its metadata by default */
91 #define LUKS2_METADATA_SIZE (16ULL*1024ULL*1024ULL)
93 /* To do LUKS2 offline encryption, we need to keep some extra free space at the end of the partition. */
94 #define LUKS2_METADATA_KEEP_FREE (LUKS2_METADATA_SIZE*2ULL)
96 /* LUKS2 volume key size. */
97 #define VOLUME_KEY_SIZE (512ULL/8ULL)
99 /* Use 4K as the default filesystem sector size because as long as the partitions are aligned to 4K, the
100 * filesystems will then also be compatible with sector sizes 512, 1024 and 2048. */
101 #define DEFAULT_FILESYSTEM_SECTOR_SIZE 4096ULL
103 #define APIVFS_TMP_DIRS_NULSTR "proc\0sys\0dev\0tmp\0run\0var/tmp\0"
105 /* Note: When growing and placing new partitions we always align to 4K sector size. It's how newer hard disks
106 * are designed, and if everything is aligned to that performance is best. And for older hard disks with 512B
107 * sector size devices were generally assumed to have an even number of sectors, hence at the worst we'll
108 * waste 3K per partition, which is probably fine. */
110 typedef enum EmptyMode
{
111 EMPTY_UNSET
, /* no choice has been made yet */
112 EMPTY_REFUSE
, /* refuse empty disks, never create a partition table */
113 EMPTY_ALLOW
, /* allow empty disks, create partition table if necessary */
114 EMPTY_REQUIRE
, /* require an empty disk, create a partition table */
115 EMPTY_FORCE
, /* make disk empty, erase everything, create a partition table always */
116 EMPTY_CREATE
, /* create disk as loopback file, create a partition table always */
118 _EMPTY_MODE_INVALID
= -EINVAL
,
121 typedef enum FilterPartitionType
{
122 FILTER_PARTITIONS_NONE
,
123 FILTER_PARTITIONS_EXCLUDE
,
124 FILTER_PARTITIONS_INCLUDE
,
125 _FILTER_PARTITIONS_MAX
,
126 _FILTER_PARTITIONS_INVALID
= -EINVAL
,
127 } FilterPartitionsType
;
129 static EmptyMode arg_empty
= EMPTY_UNSET
;
130 static bool arg_dry_run
= true;
131 static char *arg_node
= NULL
;
132 static char *arg_root
= NULL
;
133 static char *arg_image
= NULL
;
134 static char **arg_definitions
= NULL
;
135 static bool arg_discard
= true;
136 static bool arg_can_factory_reset
= false;
137 static int arg_factory_reset
= -1;
138 static sd_id128_t arg_seed
= SD_ID128_NULL
;
139 static bool arg_randomize
= false;
140 static int arg_pretty
= -1;
141 static uint64_t arg_size
= UINT64_MAX
;
142 static bool arg_size_auto
= false;
143 static JsonFormatFlags arg_json_format_flags
= JSON_FORMAT_OFF
;
144 static PagerFlags arg_pager_flags
= 0;
145 static bool arg_legend
= true;
146 static void *arg_key
= NULL
;
147 static size_t arg_key_size
= 0;
148 static EVP_PKEY
*arg_private_key
= NULL
;
149 static X509
*arg_certificate
= NULL
;
150 static char *arg_tpm2_device
= NULL
;
151 static uint32_t arg_tpm2_seal_key_handle
= 0;
152 static char *arg_tpm2_device_key
= NULL
;
153 static Tpm2PCRValue
*arg_tpm2_hash_pcr_values
= NULL
;
154 static size_t arg_tpm2_n_hash_pcr_values
= 0;
155 static char *arg_tpm2_public_key
= NULL
;
156 static uint32_t arg_tpm2_public_key_pcr_mask
= 0;
157 static char *arg_tpm2_pcrlock
= NULL
;
158 static bool arg_split
= false;
159 static GptPartitionType
*arg_filter_partitions
= NULL
;
160 static size_t arg_n_filter_partitions
= 0;
161 static FilterPartitionsType arg_filter_partitions_type
= FILTER_PARTITIONS_NONE
;
162 static GptPartitionType
*arg_defer_partitions
= NULL
;
163 static size_t arg_n_defer_partitions
= 0;
164 static uint64_t arg_sector_size
= 0;
165 static ImagePolicy
*arg_image_policy
= NULL
;
166 static Architecture arg_architecture
= _ARCHITECTURE_INVALID
;
167 static int arg_offline
= -1;
168 static char **arg_copy_from
= NULL
;
169 static char *arg_copy_source
= NULL
;
170 static char *arg_make_ddi
= NULL
;
172 STATIC_DESTRUCTOR_REGISTER(arg_node
, freep
);
173 STATIC_DESTRUCTOR_REGISTER(arg_root
, freep
);
174 STATIC_DESTRUCTOR_REGISTER(arg_image
, freep
);
175 STATIC_DESTRUCTOR_REGISTER(arg_definitions
, strv_freep
);
176 STATIC_DESTRUCTOR_REGISTER(arg_key
, erase_and_freep
);
177 STATIC_DESTRUCTOR_REGISTER(arg_private_key
, EVP_PKEY_freep
);
178 STATIC_DESTRUCTOR_REGISTER(arg_certificate
, X509_freep
);
179 STATIC_DESTRUCTOR_REGISTER(arg_tpm2_device
, freep
);
180 STATIC_DESTRUCTOR_REGISTER(arg_tpm2_device_key
, freep
);
181 STATIC_DESTRUCTOR_REGISTER(arg_tpm2_hash_pcr_values
, freep
);
182 STATIC_DESTRUCTOR_REGISTER(arg_tpm2_public_key
, freep
);
183 STATIC_DESTRUCTOR_REGISTER(arg_tpm2_pcrlock
, freep
);
184 STATIC_DESTRUCTOR_REGISTER(arg_filter_partitions
, freep
);
185 STATIC_DESTRUCTOR_REGISTER(arg_image_policy
, image_policy_freep
);
186 STATIC_DESTRUCTOR_REGISTER(arg_copy_from
, strv_freep
);
187 STATIC_DESTRUCTOR_REGISTER(arg_copy_source
, freep
);
188 STATIC_DESTRUCTOR_REGISTER(arg_make_ddi
, freep
);
190 typedef struct FreeArea FreeArea
;
192 typedef enum EncryptMode
{
196 ENCRYPT_KEY_FILE_TPM2
,
198 _ENCRYPT_MODE_INVALID
= -EINVAL
,
201 typedef enum VerityMode
{
207 _VERITY_MODE_INVALID
= -EINVAL
,
210 typedef enum MinimizeMode
{
215 _MINIMIZE_MODE_INVALID
= -EINVAL
,
218 typedef struct Partition
{
219 char *definition_path
;
220 char **drop_in_files
;
222 GptPartitionType type
;
223 sd_id128_t current_uuid
, new_uuid
;
224 bool new_uuid_is_set
;
225 char *current_label
, *new_label
;
226 sd_id128_t fs_uuid
, luks_uuid
, verity_uuid
;
227 uint8_t verity_salt
[SHA256_DIGEST_SIZE
];
233 uint32_t weight
, padding_weight
;
235 uint64_t current_size
, new_size
;
236 uint64_t size_min
, size_max
;
238 uint64_t current_padding
, new_padding
;
239 uint64_t padding_min
, padding_max
;
244 struct fdisk_partition
*current_partition
;
245 struct fdisk_partition
*new_partition
;
246 FreeArea
*padding_area
;
247 FreeArea
*allocated_to_area
;
249 char *copy_blocks_path
;
250 bool copy_blocks_path_is_our_file
;
251 bool copy_blocks_auto
;
252 const char *copy_blocks_root
;
254 uint64_t copy_blocks_offset
;
255 uint64_t copy_blocks_size
;
259 char **exclude_files_source
;
260 char **exclude_files_target
;
261 char **make_directories
;
265 char *verity_match_key
;
266 MinimizeMode minimize
;
267 uint64_t verity_data_block_size
;
268 uint64_t verity_hash_block_size
;
275 struct iovec roothash
;
277 char *split_name_format
;
280 struct Partition
*siblings
[_VERITY_MODE_MAX
];
282 LIST_FIELDS(struct Partition
, partitions
);
285 #define PARTITION_IS_FOREIGN(p) (!(p)->definition_path)
286 #define PARTITION_EXISTS(p) (!!(p)->current_partition)
294 typedef struct Context
{
295 LIST_HEAD(Partition
, partitions
);
298 FreeArea
**free_areas
;
301 uint64_t start
, end
, total
;
303 struct fdisk_context
*fdisk_context
;
304 uint64_t sector_size
, grain_size
, fs_sector_size
;
309 bool node_is_our_file
;
315 static const char *empty_mode_table
[_EMPTY_MODE_MAX
] = {
316 [EMPTY_UNSET
] = "unset",
317 [EMPTY_REFUSE
] = "refuse",
318 [EMPTY_ALLOW
] = "allow",
319 [EMPTY_REQUIRE
] = "require",
320 [EMPTY_FORCE
] = "force",
321 [EMPTY_CREATE
] = "create",
324 static const char *encrypt_mode_table
[_ENCRYPT_MODE_MAX
] = {
325 [ENCRYPT_OFF
] = "off",
326 [ENCRYPT_KEY_FILE
] = "key-file",
327 [ENCRYPT_TPM2
] = "tpm2",
328 [ENCRYPT_KEY_FILE_TPM2
] = "key-file+tpm2",
331 static const char *verity_mode_table
[_VERITY_MODE_MAX
] = {
332 [VERITY_OFF
] = "off",
333 [VERITY_DATA
] = "data",
334 [VERITY_HASH
] = "hash",
335 [VERITY_SIG
] = "signature",
338 static const char *minimize_mode_table
[_MINIMIZE_MODE_MAX
] = {
339 [MINIMIZE_OFF
] = "off",
340 [MINIMIZE_BEST
] = "best",
341 [MINIMIZE_GUESS
] = "guess",
344 DEFINE_PRIVATE_STRING_TABLE_LOOKUP(empty_mode
, EmptyMode
);
345 DEFINE_PRIVATE_STRING_TABLE_LOOKUP_FROM_STRING_WITH_BOOLEAN(encrypt_mode
, EncryptMode
, ENCRYPT_KEY_FILE
);
346 DEFINE_PRIVATE_STRING_TABLE_LOOKUP(verity_mode
, VerityMode
);
347 DEFINE_PRIVATE_STRING_TABLE_LOOKUP_FROM_STRING_WITH_BOOLEAN(minimize_mode
, MinimizeMode
, MINIMIZE_BEST
);
349 static uint64_t round_down_size(uint64_t v
, uint64_t p
) {
353 static uint64_t round_up_size(uint64_t v
, uint64_t p
) {
355 v
= DIV_ROUND_UP(v
, p
);
357 if (v
> UINT64_MAX
/ p
)
358 return UINT64_MAX
; /* overflow */
363 static Partition
*partition_new(void) {
366 p
= new(Partition
, 1);
373 .current_size
= UINT64_MAX
,
374 .new_size
= UINT64_MAX
,
375 .size_min
= UINT64_MAX
,
376 .size_max
= UINT64_MAX
,
377 .current_padding
= UINT64_MAX
,
378 .new_padding
= UINT64_MAX
,
379 .padding_min
= UINT64_MAX
,
380 .padding_max
= UINT64_MAX
,
381 .partno
= UINT64_MAX
,
382 .offset
= UINT64_MAX
,
383 .copy_blocks_fd
= -EBADF
,
384 .copy_blocks_offset
= UINT64_MAX
,
385 .copy_blocks_size
= UINT64_MAX
,
389 .verity_data_block_size
= UINT64_MAX
,
390 .verity_hash_block_size
= UINT64_MAX
,
396 static Partition
* partition_free(Partition
*p
) {
400 free(p
->current_label
);
402 free(p
->definition_path
);
403 strv_free(p
->drop_in_files
);
405 if (p
->current_partition
)
406 fdisk_unref_partition(p
->current_partition
);
407 if (p
->new_partition
)
408 fdisk_unref_partition(p
->new_partition
);
410 if (p
->copy_blocks_path_is_our_file
)
411 unlink_and_free(p
->copy_blocks_path
);
413 free(p
->copy_blocks_path
);
414 safe_close(p
->copy_blocks_fd
);
417 strv_free(p
->copy_files
);
418 strv_free(p
->exclude_files_source
);
419 strv_free(p
->exclude_files_target
);
420 strv_free(p
->make_directories
);
421 strv_free(p
->subvolumes
);
422 free(p
->verity_match_key
);
424 iovec_done(&p
->roothash
);
426 free(p
->split_name_format
);
427 unlink_and_free(p
->split_path
);
432 static void partition_foreignize(Partition
*p
) {
434 assert(PARTITION_EXISTS(p
));
436 /* Reset several parameters set through definition file to make the partition foreign. */
438 p
->definition_path
= mfree(p
->definition_path
);
439 p
->drop_in_files
= strv_free(p
->drop_in_files
);
441 p
->copy_blocks_path
= mfree(p
->copy_blocks_path
);
442 p
->copy_blocks_fd
= safe_close(p
->copy_blocks_fd
);
443 p
->copy_blocks_root
= NULL
;
445 p
->format
= mfree(p
->format
);
446 p
->copy_files
= strv_free(p
->copy_files
);
447 p
->exclude_files_source
= strv_free(p
->exclude_files_source
);
448 p
->exclude_files_target
= strv_free(p
->exclude_files_target
);
449 p
->make_directories
= strv_free(p
->make_directories
);
450 p
->subvolumes
= strv_free(p
->subvolumes
);
451 p
->verity_match_key
= mfree(p
->verity_match_key
);
455 p
->padding_weight
= 0;
456 p
->size_min
= UINT64_MAX
;
457 p
->size_max
= UINT64_MAX
;
458 p
->padding_min
= UINT64_MAX
;
459 p
->padding_max
= UINT64_MAX
;
463 p
->verity
= VERITY_OFF
;
466 static bool partition_type_exclude(const GptPartitionType
*type
) {
467 if (arg_filter_partitions_type
== FILTER_PARTITIONS_NONE
)
470 for (size_t i
= 0; i
< arg_n_filter_partitions
; i
++)
471 if (sd_id128_equal(type
->uuid
, arg_filter_partitions
[i
].uuid
))
472 return arg_filter_partitions_type
== FILTER_PARTITIONS_EXCLUDE
;
474 return arg_filter_partitions_type
== FILTER_PARTITIONS_INCLUDE
;
477 static bool partition_type_defer(const GptPartitionType
*type
) {
478 for (size_t i
= 0; i
< arg_n_defer_partitions
; i
++)
479 if (sd_id128_equal(type
->uuid
, arg_defer_partitions
[i
].uuid
))
485 static Partition
* partition_unlink_and_free(Context
*context
, Partition
*p
) {
489 LIST_REMOVE(partitions
, context
->partitions
, p
);
491 assert(context
->n_partitions
> 0);
492 context
->n_partitions
--;
494 return partition_free(p
);
497 DEFINE_TRIVIAL_CLEANUP_FUNC(Partition
*, partition_free
);
499 static Context
*context_new(sd_id128_t seed
) {
502 context
= new(Context
, 1);
506 *context
= (Context
) {
516 static void context_free_free_areas(Context
*context
) {
519 for (size_t i
= 0; i
< context
->n_free_areas
; i
++)
520 free(context
->free_areas
[i
]);
522 context
->free_areas
= mfree(context
->free_areas
);
523 context
->n_free_areas
= 0;
526 static Context
*context_free(Context
*context
) {
530 while (context
->partitions
)
531 partition_unlink_and_free(context
, context
->partitions
);
532 assert(context
->n_partitions
== 0);
534 context_free_free_areas(context
);
536 if (context
->fdisk_context
)
537 fdisk_unref_context(context
->fdisk_context
);
539 safe_close(context
->backing_fd
);
540 if (context
->node_is_our_file
)
541 unlink_and_free(context
->node
);
545 return mfree(context
);
548 DEFINE_TRIVIAL_CLEANUP_FUNC(Context
*, context_free
);
550 static int context_add_free_area(
558 assert(!after
|| !after
->padding_area
);
560 if (!GREEDY_REALLOC(context
->free_areas
, context
->n_free_areas
+ 1))
563 a
= new(FreeArea
, 1);
572 context
->free_areas
[context
->n_free_areas
++] = a
;
575 after
->padding_area
= a
;
580 static void partition_drop_or_foreignize(Partition
*p
) {
581 if (!p
|| p
->dropped
|| PARTITION_IS_FOREIGN(p
))
584 if (PARTITION_EXISTS(p
)) {
585 log_info("Can't grow existing partition %s of priority %" PRIi32
", ignoring.",
586 strna(p
->current_label
?: p
->new_label
), p
->priority
);
588 /* Handle the partition as foreign. Do not set dropped flag. */
589 partition_foreignize(p
);
591 log_info("Can't fit partition %s of priority %" PRIi32
", dropping.",
592 p
->definition_path
, p
->priority
);
595 p
->allocated_to_area
= NULL
;
599 static bool context_drop_or_foreignize_one_priority(Context
*context
) {
600 int32_t priority
= 0;
602 LIST_FOREACH(partitions
, p
, context
->partitions
) {
606 priority
= MAX(priority
, p
->priority
);
609 /* Refuse to drop partitions with 0 or negative priorities or partitions of priorities that have at
610 * least one existing priority */
614 LIST_FOREACH(partitions
, p
, context
->partitions
) {
615 if (p
->priority
< priority
)
618 partition_drop_or_foreignize(p
);
620 /* We ensure that all verity sibling partitions have the same priority, so it's safe
621 * to drop all siblings here as well. */
623 for (VerityMode mode
= VERITY_OFF
+ 1; mode
< _VERITY_MODE_MAX
; mode
++)
624 partition_drop_or_foreignize(p
->siblings
[mode
]);
630 static uint64_t partition_min_size(const Context
*context
, const Partition
*p
) {
636 /* Calculate the disk space we really need at minimum for this partition. If the partition already
637 * exists the current size is what we really need. If it doesn't exist yet refuse to allocate less
640 * DEFAULT_MIN_SIZE is the default SizeMin= we configure if nothing else is specified. */
642 if (PARTITION_IS_FOREIGN(p
)) {
643 /* Don't allow changing size of partitions not managed by us */
644 assert(p
->current_size
!= UINT64_MAX
);
645 return p
->current_size
;
648 if (p
->verity
== VERITY_SIG
)
649 return VERITY_SIG_SIZE
;
651 sz
= p
->current_size
!= UINT64_MAX
? p
->current_size
: HARD_MIN_SIZE
;
653 if (!PARTITION_EXISTS(p
)) {
656 if (p
->encrypt
!= ENCRYPT_OFF
)
657 d
+= round_up_size(LUKS2_METADATA_KEEP_FREE
, context
->grain_size
);
659 if (p
->copy_blocks_size
!= UINT64_MAX
)
660 d
+= round_up_size(p
->copy_blocks_size
, context
->grain_size
);
661 else if (p
->format
|| p
->encrypt
!= ENCRYPT_OFF
) {
664 /* If we shall synthesize a file system, take minimal fs size into account (assumed to be 4K if not known) */
665 f
= p
->format
? round_up_size(minimal_size_by_fs_name(p
->format
), context
->grain_size
) : UINT64_MAX
;
666 d
+= f
== UINT64_MAX
? context
->grain_size
: f
;
673 return MAX(round_up_size(p
->size_min
!= UINT64_MAX
? p
->size_min
: DEFAULT_MIN_SIZE
, context
->grain_size
), sz
);
676 static uint64_t partition_max_size(const Context
*context
, const Partition
*p
) {
679 /* Calculate how large the partition may become at max. This is generally the configured maximum
680 * size, except when it already exists and is larger than that. In that case it's the existing size,
681 * since we never want to shrink partitions. */
686 if (PARTITION_IS_FOREIGN(p
)) {
687 /* Don't allow changing size of partitions not managed by us */
688 assert(p
->current_size
!= UINT64_MAX
);
689 return p
->current_size
;
692 if (p
->verity
== VERITY_SIG
)
693 return VERITY_SIG_SIZE
;
695 if (p
->size_max
== UINT64_MAX
)
698 sm
= round_down_size(p
->size_max
, context
->grain_size
);
700 if (p
->current_size
!= UINT64_MAX
)
701 sm
= MAX(p
->current_size
, sm
);
703 return MAX(partition_min_size(context
, p
), sm
);
706 static uint64_t partition_min_padding(const Partition
*p
) {
708 return p
->padding_min
!= UINT64_MAX
? p
->padding_min
: 0;
711 static uint64_t partition_max_padding(const Partition
*p
) {
713 return p
->padding_max
;
716 static uint64_t partition_min_size_with_padding(Context
*context
, const Partition
*p
) {
719 /* Calculate the disk space we need for this partition plus any free space coming after it. This
720 * takes user configured padding into account as well as any additional whitespace needed to align
721 * the next partition to 4K again. */
726 sz
= partition_min_size(context
, p
) + partition_min_padding(p
);
728 if (PARTITION_EXISTS(p
)) {
729 /* If the partition wasn't aligned, add extra space so that any we might add will be aligned */
730 assert(p
->offset
!= UINT64_MAX
);
731 return round_up_size(p
->offset
+ sz
, context
->grain_size
) - p
->offset
;
734 /* If this is a new partition we'll place it aligned, hence we just need to round up the required size here */
735 return round_up_size(sz
, context
->grain_size
);
738 static uint64_t free_area_available(const FreeArea
*a
) {
741 /* Determines how much of this free area is not allocated yet */
743 assert(a
->size
>= a
->allocated
);
744 return a
->size
- a
->allocated
;
747 static uint64_t free_area_current_end(Context
*context
, const FreeArea
*a
) {
752 return free_area_available(a
);
754 assert(a
->after
->offset
!= UINT64_MAX
);
755 assert(a
->after
->current_size
!= UINT64_MAX
);
757 /* Calculate where the free area ends, based on the offset of the partition preceding it. */
758 return round_up_size(a
->after
->offset
+ a
->after
->current_size
, context
->grain_size
) + free_area_available(a
);
761 static uint64_t free_area_min_end(Context
*context
, const FreeArea
*a
) {
768 assert(a
->after
->offset
!= UINT64_MAX
);
769 assert(a
->after
->current_size
!= UINT64_MAX
);
771 /* Calculate where the partition would end when we give it as much as it needs. */
772 return round_up_size(a
->after
->offset
+ partition_min_size_with_padding(context
, a
->after
), context
->grain_size
);
775 static uint64_t free_area_available_for_new_partitions(Context
*context
, const FreeArea
*a
) {
779 /* Similar to free_area_available(), but takes into account that the required size and padding of the
780 * preceding partition is honoured. */
782 return LESS_BY(free_area_current_end(context
, a
), free_area_min_end(context
, a
));
785 static int free_area_compare(FreeArea
*const *a
, FreeArea
*const*b
, Context
*context
) {
788 return CMP(free_area_available_for_new_partitions(context
, *a
),
789 free_area_available_for_new_partitions(context
, *b
));
792 static uint64_t charge_size(Context
*context
, uint64_t total
, uint64_t amount
) {
794 /* Subtract the specified amount from total, rounding up to multiple of 4K if there's room */
795 assert(amount
<= total
);
796 return LESS_BY(total
, round_up_size(amount
, context
->grain_size
));
799 static uint64_t charge_weight(uint64_t total
, uint64_t amount
) {
800 assert(amount
<= total
);
801 return total
- amount
;
804 static bool context_allocate_partitions(Context
*context
, uint64_t *ret_largest_free_area
) {
807 /* This may be called multiple times. Reset previous assignments. */
808 for (size_t i
= 0; i
< context
->n_free_areas
; i
++)
809 context
->free_areas
[i
]->allocated
= 0;
811 /* Sort free areas by size, putting smallest first */
812 typesafe_qsort_r(context
->free_areas
, context
->n_free_areas
, free_area_compare
, context
);
814 /* In any case return size of the largest free area (i.e. not the size of all free areas
816 if (ret_largest_free_area
)
817 *ret_largest_free_area
=
818 context
->n_free_areas
== 0 ? 0 :
819 free_area_available_for_new_partitions(context
, context
->free_areas
[context
->n_free_areas
-1]);
821 /* Check that each existing partition can fit its area. */
822 for (size_t i
= 0; i
< context
->n_free_areas
; i
++)
823 if (free_area_current_end(context
, context
->free_areas
[i
]) <
824 free_area_min_end(context
, context
->free_areas
[i
]))
827 /* A simple first-fit algorithm. We return true if we can fit the partitions in, otherwise false. */
828 LIST_FOREACH(partitions
, p
, context
->partitions
) {
833 /* Skip partitions we already dropped or that already exist */
834 if (p
->dropped
|| PARTITION_EXISTS(p
))
837 /* How much do we need to fit? */
838 required
= partition_min_size_with_padding(context
, p
);
839 assert(required
% context
->grain_size
== 0);
841 for (size_t i
= 0; i
< context
->n_free_areas
; i
++) {
842 a
= context
->free_areas
[i
];
844 if (free_area_available_for_new_partitions(context
, a
) >= required
) {
851 return false; /* 😢 Oh no! We can't fit this partition into any free area! */
853 /* Assign the partition to this free area */
854 p
->allocated_to_area
= a
;
856 /* Budget the minimal partition size */
857 a
->allocated
+= required
;
863 static int context_sum_weights(Context
*context
, FreeArea
*a
, uint64_t *ret
) {
864 uint64_t weight_sum
= 0;
870 /* Determine the sum of the weights of all partitions placed in or before the specified free area */
872 LIST_FOREACH(partitions
, p
, context
->partitions
) {
873 if (p
->padding_area
!= a
&& p
->allocated_to_area
!= a
)
876 if (p
->weight
> UINT64_MAX
- weight_sum
)
878 weight_sum
+= p
->weight
;
880 if (p
->padding_weight
> UINT64_MAX
- weight_sum
)
882 weight_sum
+= p
->padding_weight
;
889 return log_error_errno(SYNTHETIC_ERRNO(EOVERFLOW
), "Combined weight of partition exceeds unsigned 64-bit range, refusing.");
892 static uint64_t scale_by_weight(uint64_t value
, uint64_t weight
, uint64_t weight_sum
) {
893 assert(weight_sum
>= weight
);
898 if (weight
== weight_sum
)
900 if (value
<= UINT64_MAX
/ weight
)
901 return value
* weight
/ weight_sum
;
903 /* Rescale weight and weight_sum to make not the calculation overflow. To satisfy the
904 * following conditions, 'weight_sum' is rounded up but 'weight' is rounded down:
905 * - the sum of scale_by_weight() for all weights must not be larger than the input value,
906 * - scale_by_weight() must not be larger than the ideal value (i.e. calculated with uint128_t). */
907 weight_sum
= DIV_ROUND_UP(weight_sum
, 2);
912 typedef enum GrowPartitionPhase
{
913 /* The zeroth phase: do not touch foreign partitions (i.e. those we don't manage). */
916 /* The first phase: we charge partitions which need more (according to constraints) than their weight-based share. */
919 /* The second phase: we charge partitions which need less (according to constraints) than their weight-based share. */
922 /* The third phase: we distribute what remains among the remaining partitions, according to the weights */
925 _GROW_PARTITION_PHASE_MAX
,
926 } GrowPartitionPhase
;
928 static bool context_grow_partitions_phase(
931 GrowPartitionPhase phase
,
933 uint64_t *weight_sum
) {
935 bool try_again
= false;
942 /* Now let's look at the intended weights and adjust them taking the minimum space assignments into
943 * account. i.e. if a partition has a small weight but a high minimum space value set it should not
944 * get any additional room from the left-overs. Similar, if two partitions have the same weight they
945 * should get the same space if possible, even if one has a smaller minimum size than the other. */
946 LIST_FOREACH(partitions
, p
, context
->partitions
) {
948 /* Look only at partitions associated with this free area, i.e. immediately
949 * preceding it, or allocated into it */
950 if (p
->allocated_to_area
!= a
&& p
->padding_area
!= a
)
953 if (p
->new_size
== UINT64_MAX
) {
954 uint64_t share
, rsz
, xsz
;
957 /* Calculate how much this space this partition needs if everyone would get
958 * the weight based share */
959 share
= scale_by_weight(*span
, p
->weight
, *weight_sum
);
961 rsz
= partition_min_size(context
, p
);
962 xsz
= partition_max_size(context
, p
);
964 if (phase
== PHASE_FOREIGN
&& PARTITION_IS_FOREIGN(p
)) {
965 /* Never change of foreign partitions (i.e. those we don't manage) */
967 p
->new_size
= p
->current_size
;
970 } else if (phase
== PHASE_OVERCHARGE
&& rsz
> share
) {
971 /* This partition needs more than its calculated share. Let's assign
972 * it that, and take this partition out of all calculations and start
976 charge
= try_again
= true;
978 } else if (phase
== PHASE_UNDERCHARGE
&& xsz
< share
) {
979 /* This partition accepts less than its calculated
980 * share. Let's assign it that, and take this partition out
981 * of all calculations and start again. */
984 charge
= try_again
= true;
986 } else if (phase
== PHASE_DISTRIBUTE
) {
987 /* This partition can accept its calculated share. Let's
988 * assign it. There's no need to restart things here since
989 * assigning this shouldn't impact the shares of the other
992 assert(share
>= rsz
);
993 p
->new_size
= CLAMP(round_down_size(share
, context
->grain_size
), rsz
, xsz
);
998 *span
= charge_size(context
, *span
, p
->new_size
);
999 *weight_sum
= charge_weight(*weight_sum
, p
->weight
);
1003 if (p
->new_padding
== UINT64_MAX
) {
1004 uint64_t share
, rsz
, xsz
;
1005 bool charge
= false;
1007 share
= scale_by_weight(*span
, p
->padding_weight
, *weight_sum
);
1009 rsz
= partition_min_padding(p
);
1010 xsz
= partition_max_padding(p
);
1012 if (phase
== PHASE_OVERCHARGE
&& rsz
> share
) {
1013 p
->new_padding
= rsz
;
1014 charge
= try_again
= true;
1015 } else if (phase
== PHASE_UNDERCHARGE
&& xsz
< share
) {
1016 p
->new_padding
= xsz
;
1017 charge
= try_again
= true;
1018 } else if (phase
== PHASE_DISTRIBUTE
) {
1019 assert(share
>= rsz
);
1020 p
->new_padding
= CLAMP(round_down_size(share
, context
->grain_size
), rsz
, xsz
);
1025 *span
= charge_size(context
, *span
, p
->new_padding
);
1026 *weight_sum
= charge_weight(*weight_sum
, p
->padding_weight
);
1034 static void context_grow_partition_one(Context
*context
, FreeArea
*a
, Partition
*p
, uint64_t *span
) {
1045 if (p
->allocated_to_area
!= a
)
1048 if (PARTITION_IS_FOREIGN(p
))
1051 assert(p
->new_size
!= UINT64_MAX
);
1053 /* Calculate new size and align. */
1054 m
= round_down_size(p
->new_size
+ *span
, context
->grain_size
);
1055 /* But ensure this doesn't shrink the size. */
1056 m
= MAX(m
, p
->new_size
);
1057 /* And ensure this doesn't exceed the maximum size. */
1058 m
= MIN(m
, partition_max_size(context
, p
));
1060 assert(m
>= p
->new_size
);
1062 *span
= charge_size(context
, *span
, m
- p
->new_size
);
1066 static int context_grow_partitions_on_free_area(Context
*context
, FreeArea
*a
) {
1067 uint64_t weight_sum
= 0, span
;
1073 r
= context_sum_weights(context
, a
, &weight_sum
);
1077 /* Let's calculate the total area covered by this free area and the partition before it */
1080 assert(a
->after
->offset
!= UINT64_MAX
);
1081 assert(a
->after
->current_size
!= UINT64_MAX
);
1083 span
+= round_up_size(a
->after
->offset
+ a
->after
->current_size
, context
->grain_size
) - a
->after
->offset
;
1086 for (GrowPartitionPhase phase
= 0; phase
< _GROW_PARTITION_PHASE_MAX
;)
1087 if (context_grow_partitions_phase(context
, a
, phase
, &span
, &weight_sum
))
1088 phase
++; /* go to the next phase */
1090 /* We still have space left over? Donate to preceding partition if we have one */
1091 if (span
> 0 && a
->after
)
1092 context_grow_partition_one(context
, a
, a
->after
, &span
);
1094 /* What? Even still some space left (maybe because there was no preceding partition, or it had a
1095 * size limit), then let's donate it to whoever wants it. */
1097 LIST_FOREACH(partitions
, p
, context
->partitions
) {
1098 context_grow_partition_one(context
, a
, p
, &span
);
1103 /* Yuck, still no one? Then make it padding */
1104 if (span
> 0 && a
->after
) {
1105 assert(a
->after
->new_padding
!= UINT64_MAX
);
1106 a
->after
->new_padding
+= span
;
1112 static int context_grow_partitions(Context
*context
) {
1117 for (size_t i
= 0; i
< context
->n_free_areas
; i
++) {
1118 r
= context_grow_partitions_on_free_area(context
, context
->free_areas
[i
]);
1123 /* All existing partitions that have no free space after them can't change size */
1124 LIST_FOREACH(partitions
, p
, context
->partitions
) {
1128 if (!PARTITION_EXISTS(p
) || p
->padding_area
) {
1129 /* The algorithm above must have initialized this already */
1130 assert(p
->new_size
!= UINT64_MAX
);
1134 assert(p
->new_size
== UINT64_MAX
);
1135 p
->new_size
= p
->current_size
;
1137 assert(p
->new_padding
== UINT64_MAX
);
1138 p
->new_padding
= p
->current_padding
;
1144 static uint64_t find_first_unused_partno(Context
*context
) {
1145 uint64_t partno
= 0;
1149 for (partno
= 0;; partno
++) {
1151 LIST_FOREACH(partitions
, p
, context
->partitions
)
1152 if (p
->partno
!= UINT64_MAX
&& p
->partno
== partno
)
1161 static void context_place_partitions(Context
*context
) {
1165 for (size_t i
= 0; i
< context
->n_free_areas
; i
++) {
1166 FreeArea
*a
= context
->free_areas
[i
];
1167 _unused_
uint64_t left
;
1171 assert(a
->after
->offset
!= UINT64_MAX
);
1172 assert(a
->after
->new_size
!= UINT64_MAX
);
1173 assert(a
->after
->new_padding
!= UINT64_MAX
);
1175 start
= a
->after
->offset
+ a
->after
->new_size
+ a
->after
->new_padding
;
1177 start
= context
->start
;
1179 start
= round_up_size(start
, context
->grain_size
);
1182 LIST_FOREACH(partitions
, p
, context
->partitions
) {
1183 if (p
->allocated_to_area
!= a
)
1187 p
->partno
= find_first_unused_partno(context
);
1189 assert(left
>= p
->new_size
);
1190 start
+= p
->new_size
;
1191 left
-= p
->new_size
;
1193 assert(left
>= p
->new_padding
);
1194 start
+= p
->new_padding
;
1195 left
-= p
->new_padding
;
1200 static int config_parse_type(
1202 const char *filename
,
1204 const char *section
,
1205 unsigned section_line
,
1212 GptPartitionType
*type
= ASSERT_PTR(data
);
1217 r
= gpt_partition_type_from_string(rvalue
, type
);
1219 return log_syntax(unit
, LOG_ERR
, filename
, line
, r
, "Failed to parse partition type: %s", rvalue
);
1221 if (arg_architecture
>= 0)
1222 *type
= gpt_partition_type_override_architecture(*type
, arg_architecture
);
1227 static int config_parse_label(
1229 const char *filename
,
1231 const char *section
,
1232 unsigned section_line
,
1239 _cleanup_free_
char *resolved
= NULL
;
1240 char **label
= ASSERT_PTR(data
);
1245 /* Nota bene: the empty label is a totally valid one. Let's hence not follow our usual rule of
1246 * assigning the empty string to reset to default here, but really accept it as label to set. */
1248 r
= specifier_printf(rvalue
, GPT_LABEL_MAX
, system_and_tmp_specifier_table
, arg_root
, NULL
, &resolved
);
1250 log_syntax(unit
, LOG_WARNING
, filename
, line
, r
,
1251 "Failed to expand specifiers in Label=, ignoring: %s", rvalue
);
1255 if (!utf8_is_valid(resolved
)) {
1256 log_syntax(unit
, LOG_WARNING
, filename
, line
, 0,
1257 "Partition label not valid UTF-8, ignoring: %s", rvalue
);
1261 r
= gpt_partition_label_valid(resolved
);
1263 log_syntax(unit
, LOG_WARNING
, filename
, line
, r
,
1264 "Failed to check if string is valid as GPT partition label, ignoring: \"%s\" (from \"%s\")",
1269 log_syntax(unit
, LOG_WARNING
, filename
, line
, 0,
1270 "Partition label too long for GPT table, ignoring: \"%s\" (from \"%s\")",
1275 free_and_replace(*label
, resolved
);
1279 static int config_parse_weight(
1281 const char *filename
,
1283 const char *section
,
1284 unsigned section_line
,
1291 uint32_t *w
= ASSERT_PTR(data
), v
;
1296 r
= safe_atou32(rvalue
, &v
);
1298 log_syntax(unit
, LOG_WARNING
, filename
, line
, r
,
1299 "Failed to parse weight value, ignoring: %s", rvalue
);
1303 if (v
> 1000U*1000U) {
1304 log_syntax(unit
, LOG_WARNING
, filename
, line
, 0,
1305 "Weight needs to be in range 0…10000000, ignoring: %" PRIu32
, v
);
1313 static int config_parse_size4096(
1315 const char *filename
,
1317 const char *section
,
1318 unsigned section_line
,
1325 uint64_t *sz
= data
, parsed
;
1331 r
= parse_size(rvalue
, 1024, &parsed
);
1333 return log_syntax(unit
, LOG_ERR
, filename
, line
, r
,
1334 "Failed to parse size value: %s", rvalue
);
1337 *sz
= round_up_size(parsed
, 4096);
1339 *sz
= round_down_size(parsed
, 4096);
1344 log_syntax(unit
, LOG_NOTICE
, filename
, line
, r
, "Rounded %s= size %" PRIu64
" %s %" PRIu64
", a multiple of 4096.",
1345 lvalue
, parsed
, special_glyph(SPECIAL_GLYPH_ARROW_RIGHT
), *sz
);
1350 static int config_parse_block_size(
1352 const char *filename
,
1354 const char *section
,
1355 unsigned section_line
,
1362 uint64_t *blksz
= ASSERT_PTR(data
), parsed
;
1367 r
= parse_size(rvalue
, 1024, &parsed
);
1369 return log_syntax(unit
, LOG_ERR
, filename
, line
, r
,
1370 "Failed to parse size value: %s", rvalue
);
1372 if (parsed
< 512 || parsed
> 4096)
1373 return log_syntax(unit
, LOG_ERR
, filename
, line
, SYNTHETIC_ERRNO(EINVAL
),
1374 "Value not between 512 and 4096: %s", rvalue
);
1376 if (!ISPOWEROF2(parsed
))
1377 return log_syntax(unit
, LOG_ERR
, filename
, line
, SYNTHETIC_ERRNO(EINVAL
),
1378 "Value not a power of 2: %s", rvalue
);
1384 static int config_parse_fstype(
1386 const char *filename
,
1388 const char *section
,
1389 unsigned section_line
,
1396 char **fstype
= ASSERT_PTR(data
);
1401 /* Let's provide an easy way to override the chosen fstype for file system partitions */
1402 e
= secure_getenv("SYSTEMD_REPART_OVERRIDE_FSTYPE");
1403 if (e
&& !streq(rvalue
, e
)) {
1404 log_syntax(unit
, LOG_NOTICE
, filename
, line
, 0,
1405 "Overriding defined file system type '%s' with '%s'.", rvalue
, e
);
1409 if (!filename_is_valid(rvalue
))
1410 return log_syntax(unit
, LOG_ERR
, filename
, line
, 0,
1411 "File system type is not valid, refusing: %s", rvalue
);
1413 return free_and_strdup_warn(fstype
, rvalue
);
1416 static int config_parse_copy_files(
1418 const char *filename
,
1420 const char *section
,
1421 unsigned section_line
,
1428 _cleanup_free_
char *source
= NULL
, *buffer
= NULL
, *resolved_source
= NULL
, *resolved_target
= NULL
;
1429 const char *p
= rvalue
, *target
;
1430 char ***copy_files
= ASSERT_PTR(data
);
1435 r
= extract_first_word(&p
, &source
, ":", EXTRACT_CUNESCAPE
|EXTRACT_DONT_COALESCE_SEPARATORS
);
1437 return log_syntax(unit
, LOG_ERR
, filename
, line
, r
, "Failed to extract source path: %s", rvalue
);
1439 log_syntax(unit
, LOG_WARNING
, filename
, line
, 0, "No argument specified: %s", rvalue
);
1443 r
= extract_first_word(&p
, &buffer
, ":", EXTRACT_CUNESCAPE
|EXTRACT_DONT_COALESCE_SEPARATORS
);
1445 return log_syntax(unit
, LOG_ERR
, filename
, line
, r
, "Failed to extract target path: %s", rvalue
);
1447 target
= source
; /* No target, then it's the same as the source */
1452 return log_syntax(unit
, LOG_ERR
, filename
, line
, SYNTHETIC_ERRNO(EINVAL
), "Too many arguments: %s", rvalue
);
1454 r
= specifier_printf(source
, PATH_MAX
-1, system_and_tmp_specifier_table
, arg_root
, NULL
, &resolved_source
);
1456 log_syntax(unit
, LOG_WARNING
, filename
, line
, r
,
1457 "Failed to expand specifiers in CopyFiles= source, ignoring: %s", rvalue
);
1461 r
= path_simplify_and_warn(resolved_source
, PATH_CHECK_ABSOLUTE
, unit
, filename
, line
, lvalue
);
1465 r
= specifier_printf(target
, PATH_MAX
-1, system_and_tmp_specifier_table
, arg_root
, NULL
, &resolved_target
);
1467 log_syntax(unit
, LOG_WARNING
, filename
, line
, r
,
1468 "Failed to expand specifiers in CopyFiles= target, ignoring: %s", resolved_target
);
1472 r
= path_simplify_and_warn(resolved_target
, PATH_CHECK_ABSOLUTE
, unit
, filename
, line
, lvalue
);
1476 r
= strv_consume_pair(copy_files
, TAKE_PTR(resolved_source
), TAKE_PTR(resolved_target
));
1483 static int config_parse_exclude_files(
1485 const char *filename
,
1487 const char *section
,
1488 unsigned section_line
,
1494 _cleanup_free_
char *resolved
= NULL
;
1495 char ***exclude_files
= ASSERT_PTR(data
);
1498 if (isempty(rvalue
)) {
1499 *exclude_files
= strv_free(*exclude_files
);
1503 r
= specifier_printf(rvalue
, PATH_MAX
-1, system_and_tmp_specifier_table
, arg_root
, NULL
, &resolved
);
1505 log_syntax(unit
, LOG_WARNING
, filename
, line
, r
,
1506 "Failed to expand specifiers in ExcludeFiles= path, ignoring: %s", rvalue
);
1510 r
= path_simplify_and_warn(resolved
, PATH_CHECK_ABSOLUTE
|PATH_KEEP_TRAILING_SLASH
, unit
, filename
, line
, lvalue
);
1514 if (strv_consume(exclude_files
, TAKE_PTR(resolved
)) < 0)
1520 static int config_parse_copy_blocks(
1522 const char *filename
,
1524 const char *section
,
1525 unsigned section_line
,
1532 _cleanup_free_
char *d
= NULL
;
1533 Partition
*partition
= ASSERT_PTR(data
);
1538 if (isempty(rvalue
)) {
1539 partition
->copy_blocks_path
= mfree(partition
->copy_blocks_path
);
1540 partition
->copy_blocks_auto
= false;
1544 if (streq(rvalue
, "auto")) {
1545 partition
->copy_blocks_path
= mfree(partition
->copy_blocks_path
);
1546 partition
->copy_blocks_auto
= true;
1547 partition
->copy_blocks_root
= arg_root
;
1551 r
= specifier_printf(rvalue
, PATH_MAX
-1, system_and_tmp_specifier_table
, arg_root
, NULL
, &d
);
1553 log_syntax(unit
, LOG_WARNING
, filename
, line
, r
,
1554 "Failed to expand specifiers in CopyBlocks= source path, ignoring: %s", rvalue
);
1558 r
= path_simplify_and_warn(d
, PATH_CHECK_ABSOLUTE
, unit
, filename
, line
, lvalue
);
1562 free_and_replace(partition
->copy_blocks_path
, d
);
1563 partition
->copy_blocks_auto
= false;
1564 partition
->copy_blocks_root
= arg_root
;
1568 static int config_parse_make_dirs(
1570 const char *filename
,
1572 const char *section
,
1573 unsigned section_line
,
1580 char ***sv
= ASSERT_PTR(data
);
1581 const char *p
= ASSERT_PTR(rvalue
);
1585 _cleanup_free_
char *word
= NULL
, *d
= NULL
;
1587 r
= extract_first_word(&p
, &word
, NULL
, EXTRACT_UNQUOTE
);
1591 log_syntax(unit
, LOG_WARNING
, filename
, line
, r
, "Invalid syntax, ignoring: %s", rvalue
);
1597 r
= specifier_printf(word
, PATH_MAX
-1, system_and_tmp_specifier_table
, arg_root
, NULL
, &d
);
1599 log_syntax(unit
, LOG_WARNING
, filename
, line
, r
,
1600 "Failed to expand specifiers in MakeDirectories= parameter, ignoring: %s", word
);
1604 r
= path_simplify_and_warn(d
, PATH_CHECK_ABSOLUTE
, unit
, filename
, line
, lvalue
);
1608 r
= strv_consume(sv
, TAKE_PTR(d
));
1614 static DEFINE_CONFIG_PARSE_ENUM_WITH_DEFAULT(config_parse_encrypt
, encrypt_mode
, EncryptMode
, ENCRYPT_OFF
, "Invalid encryption mode");
1616 static int config_parse_gpt_flags(
1618 const char *filename
,
1620 const char *section
,
1621 unsigned section_line
,
1628 uint64_t *gpt_flags
= ASSERT_PTR(data
);
1633 r
= safe_atou64(rvalue
, gpt_flags
);
1635 log_syntax(unit
, LOG_WARNING
, filename
, line
, r
,
1636 "Failed to parse Flags= value, ignoring: %s", rvalue
);
1643 static int config_parse_uuid(
1645 const char *filename
,
1647 const char *section
,
1648 unsigned section_line
,
1655 Partition
*partition
= ASSERT_PTR(data
);
1658 if (isempty(rvalue
)) {
1659 partition
->new_uuid
= SD_ID128_NULL
;
1660 partition
->new_uuid_is_set
= false;
1664 if (streq(rvalue
, "null")) {
1665 partition
->new_uuid
= SD_ID128_NULL
;
1666 partition
->new_uuid_is_set
= true;
1670 r
= sd_id128_from_string(rvalue
, &partition
->new_uuid
);
1672 log_syntax(unit
, LOG_WARNING
, filename
, line
, r
, "Failed to parse 128-bit ID/UUID, ignoring: %s", rvalue
);
1676 partition
->new_uuid_is_set
= true;
1681 static DEFINE_CONFIG_PARSE_ENUM_WITH_DEFAULT(config_parse_verity
, verity_mode
, VerityMode
, VERITY_OFF
, "Invalid verity mode");
1682 static DEFINE_CONFIG_PARSE_ENUM_WITH_DEFAULT(config_parse_minimize
, minimize_mode
, MinimizeMode
, MINIMIZE_OFF
, "Invalid minimize mode");
1684 static int partition_read_definition(Partition
*p
, const char *path
, const char *const *conf_file_dirs
) {
1686 ConfigTableItem table
[] = {
1687 { "Partition", "Type", config_parse_type
, 0, &p
->type
},
1688 { "Partition", "Label", config_parse_label
, 0, &p
->new_label
},
1689 { "Partition", "UUID", config_parse_uuid
, 0, p
},
1690 { "Partition", "Priority", config_parse_int32
, 0, &p
->priority
},
1691 { "Partition", "Weight", config_parse_weight
, 0, &p
->weight
},
1692 { "Partition", "PaddingWeight", config_parse_weight
, 0, &p
->padding_weight
},
1693 { "Partition", "SizeMinBytes", config_parse_size4096
, -1, &p
->size_min
},
1694 { "Partition", "SizeMaxBytes", config_parse_size4096
, 1, &p
->size_max
},
1695 { "Partition", "PaddingMinBytes", config_parse_size4096
, -1, &p
->padding_min
},
1696 { "Partition", "PaddingMaxBytes", config_parse_size4096
, 1, &p
->padding_max
},
1697 { "Partition", "FactoryReset", config_parse_bool
, 0, &p
->factory_reset
},
1698 { "Partition", "CopyBlocks", config_parse_copy_blocks
, 0, p
},
1699 { "Partition", "Format", config_parse_fstype
, 0, &p
->format
},
1700 { "Partition", "CopyFiles", config_parse_copy_files
, 0, &p
->copy_files
},
1701 { "Partition", "ExcludeFiles", config_parse_exclude_files
, 0, &p
->exclude_files_source
},
1702 { "Partition", "ExcludeFilesTarget", config_parse_exclude_files
, 0, &p
->exclude_files_target
},
1703 { "Partition", "MakeDirectories", config_parse_make_dirs
, 0, &p
->make_directories
},
1704 { "Partition", "Encrypt", config_parse_encrypt
, 0, &p
->encrypt
},
1705 { "Partition", "Verity", config_parse_verity
, 0, &p
->verity
},
1706 { "Partition", "VerityMatchKey", config_parse_string
, 0, &p
->verity_match_key
},
1707 { "Partition", "Flags", config_parse_gpt_flags
, 0, &p
->gpt_flags
},
1708 { "Partition", "ReadOnly", config_parse_tristate
, 0, &p
->read_only
},
1709 { "Partition", "NoAuto", config_parse_tristate
, 0, &p
->no_auto
},
1710 { "Partition", "GrowFileSystem", config_parse_tristate
, 0, &p
->growfs
},
1711 { "Partition", "SplitName", config_parse_string
, 0, &p
->split_name_format
},
1712 { "Partition", "Minimize", config_parse_minimize
, 0, &p
->minimize
},
1713 { "Partition", "Subvolumes", config_parse_make_dirs
, 0, &p
->subvolumes
},
1714 { "Partition", "VerityDataBlockSizeBytes", config_parse_block_size
, 0, &p
->verity_data_block_size
},
1715 { "Partition", "VerityHashBlockSizeBytes", config_parse_block_size
, 0, &p
->verity_hash_block_size
},
1719 _cleanup_free_
char *filename
= NULL
;
1720 const char* dropin_dirname
;
1722 r
= path_extract_filename(path
, &filename
);
1724 return log_error_errno(r
, "Failed to extract filename from path '%s': %m", path
);
1726 dropin_dirname
= strjoina(filename
, ".d");
1728 r
= config_parse_many(
1729 STRV_MAKE_CONST(path
),
1732 arg_definitions
? NULL
: arg_root
,
1734 config_item_table_lookup
, table
,
1742 if (partition_type_exclude(&p
->type
))
1745 if (p
->size_min
!= UINT64_MAX
&& p
->size_max
!= UINT64_MAX
&& p
->size_min
> p
->size_max
)
1746 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EINVAL
),
1747 "SizeMinBytes= larger than SizeMaxBytes=, refusing.");
1749 if (p
->padding_min
!= UINT64_MAX
&& p
->padding_max
!= UINT64_MAX
&& p
->padding_min
> p
->padding_max
)
1750 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EINVAL
),
1751 "PaddingMinBytes= larger than PaddingMaxBytes=, refusing.");
1753 if (sd_id128_is_null(p
->type
.uuid
))
1754 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EINVAL
),
1755 "Type= not defined, refusing.");
1757 if ((p
->copy_blocks_path
|| p
->copy_blocks_auto
) &&
1758 (p
->format
|| !strv_isempty(p
->copy_files
) || !strv_isempty(p
->make_directories
)))
1759 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EINVAL
),
1760 "Format=/CopyFiles=/MakeDirectories= and CopyBlocks= cannot be combined, refusing.");
1762 if ((!strv_isempty(p
->copy_files
) || !strv_isempty(p
->make_directories
)) && streq_ptr(p
->format
, "swap"))
1763 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EINVAL
),
1764 "Format=swap and CopyFiles= cannot be combined, refusing.");
1767 const char *format
= NULL
;
1769 if (!strv_isempty(p
->copy_files
) || !strv_isempty(p
->make_directories
) || (p
->encrypt
!= ENCRYPT_OFF
&& !(p
->copy_blocks_path
|| p
->copy_blocks_auto
)))
1770 /* Pick "vfat" as file system for esp and xbootldr partitions, otherwise default to "ext4". */
1771 format
= IN_SET(p
->type
.designator
, PARTITION_ESP
, PARTITION_XBOOTLDR
) ? "vfat" : "ext4";
1772 else if (p
->type
.designator
== PARTITION_SWAP
)
1776 p
->format
= strdup(format
);
1782 if (p
->minimize
!= MINIMIZE_OFF
&& !p
->format
&& p
->verity
!= VERITY_HASH
)
1783 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EINVAL
),
1784 "Minimize= can only be enabled if Format= or Verity=hash are set");
1786 if (p
->minimize
== MINIMIZE_BEST
&& (p
->format
&& !fstype_is_ro(p
->format
)) && p
->verity
!= VERITY_HASH
)
1787 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EINVAL
),
1788 "Minimize=best can only be used with read-only filesystems or Verity=hash");
1790 if ((!strv_isempty(p
->copy_files
) || !strv_isempty(p
->make_directories
)) && !mkfs_supports_root_option(p
->format
) && geteuid() != 0)
1791 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EPERM
),
1792 "Need to be root to populate %s filesystems with CopyFiles=/MakeDirectories=",
1795 if (p
->format
&& fstype_is_ro(p
->format
) && strv_isempty(p
->copy_files
) && strv_isempty(p
->make_directories
))
1796 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EINVAL
),
1797 "Cannot format %s filesystem without source files, refusing", p
->format
);
1799 if (p
->verity
!= VERITY_OFF
|| p
->encrypt
!= ENCRYPT_OFF
) {
1800 r
= dlopen_cryptsetup();
1802 return log_syntax(NULL
, LOG_ERR
, path
, 1, r
,
1803 "libcryptsetup not found, Verity=/Encrypt= are not supported: %m");
1806 if (p
->verity
!= VERITY_OFF
&& !p
->verity_match_key
)
1807 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EINVAL
),
1808 "VerityMatchKey= must be set if Verity=%s", verity_mode_to_string(p
->verity
));
1810 if (p
->verity
== VERITY_OFF
&& p
->verity_match_key
)
1811 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EINVAL
),
1812 "VerityMatchKey= can only be set if Verity= is not \"%s\"",
1813 verity_mode_to_string(p
->verity
));
1815 if (IN_SET(p
->verity
, VERITY_HASH
, VERITY_SIG
) &&
1816 (p
->copy_files
|| p
->copy_blocks_path
|| p
->copy_blocks_auto
|| p
->format
|| p
->make_directories
))
1817 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EINVAL
),
1818 "CopyBlocks=/CopyFiles=/Format=/MakeDirectories= cannot be used with Verity=%s",
1819 verity_mode_to_string(p
->verity
));
1821 if (p
->verity
!= VERITY_OFF
&& p
->encrypt
!= ENCRYPT_OFF
)
1822 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EINVAL
),
1823 "Encrypting verity hash/data partitions is not supported");
1825 if (p
->verity
== VERITY_SIG
&& !arg_private_key
)
1826 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EINVAL
),
1827 "Verity signature partition requested but no private key provided (--private-key=)");
1829 if (p
->verity
== VERITY_SIG
&& !arg_certificate
)
1830 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EINVAL
),
1831 "Verity signature partition requested but no PEM certificate provided (--certificate=)");
1833 if (p
->verity
== VERITY_SIG
&& (p
->size_min
!= UINT64_MAX
|| p
->size_max
!= UINT64_MAX
))
1834 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EINVAL
),
1835 "SizeMinBytes=/SizeMaxBytes= cannot be used with Verity=%s",
1836 verity_mode_to_string(p
->verity
));
1838 if (!strv_isempty(p
->subvolumes
) && arg_offline
> 0)
1839 return log_syntax(NULL
, LOG_ERR
, path
, 1, SYNTHETIC_ERRNO(EOPNOTSUPP
),
1840 "Subvolumes= cannot be used with --offline=yes");
1842 /* Verity partitions are read only, let's imply the RO flag hence, unless explicitly configured otherwise. */
1843 if ((IN_SET(p
->type
.designator
,
1844 PARTITION_ROOT_VERITY
,
1845 PARTITION_USR_VERITY
) || p
->verity
== VERITY_DATA
) && p
->read_only
< 0)
1846 p
->read_only
= true;
1848 /* Default to "growfs" on, unless read-only */
1849 if (gpt_partition_type_knows_growfs(p
->type
) &&
1853 if (!p
->split_name_format
) {
1854 char *s
= strdup("%t");
1858 p
->split_name_format
= s
;
1859 } else if (streq(p
->split_name_format
, "-"))
1860 p
->split_name_format
= mfree(p
->split_name_format
);
1865 static int find_verity_sibling(Context
*context
, Partition
*p
, VerityMode mode
, Partition
**ret
) {
1866 Partition
*s
= NULL
;
1869 assert(p
->verity
!= VERITY_OFF
);
1870 assert(p
->verity_match_key
);
1871 assert(mode
!= VERITY_OFF
);
1872 assert(p
->verity
!= mode
);
1875 /* Try to find the matching sibling partition of the given type for a verity partition. For a data
1876 * partition, this is the corresponding hash partition with the same verity name (and vice versa for
1877 * the hash partition). */
1879 LIST_FOREACH(partitions
, q
, context
->partitions
) {
1883 if (q
->verity
!= mode
)
1886 assert(q
->verity_match_key
);
1888 if (!streq(p
->verity_match_key
, q
->verity_match_key
))
1905 static int context_open_and_lock_backing_fd(const char *node
, int operation
, int *backing_fd
) {
1906 _cleanup_close_
int fd
= -EBADF
;
1911 if (*backing_fd
>= 0)
1914 fd
= open(node
, O_RDONLY
|O_CLOEXEC
);
1916 return log_error_errno(errno
, "Failed to open device '%s': %m", node
);
1918 /* Tell udev not to interfere while we are processing the device */
1919 if (flock(fd
, operation
) < 0)
1920 return log_error_errno(errno
, "Failed to lock device '%s': %m", node
);
1922 log_debug("Device %s opened and locked.", node
);
1923 *backing_fd
= TAKE_FD(fd
);
1927 static int determine_current_padding(
1928 struct fdisk_context
*c
,
1929 struct fdisk_table
*t
,
1930 struct fdisk_partition
*p
,
1935 size_t n_partitions
;
1936 uint64_t offset
, next
= UINT64_MAX
;
1943 if (!fdisk_partition_has_end(p
))
1944 return log_error_errno(SYNTHETIC_ERRNO(EIO
), "Partition has no end!");
1946 offset
= fdisk_partition_get_end(p
);
1947 assert(offset
< UINT64_MAX
);
1948 offset
++; /* The end is one sector before the next partition or padding. */
1949 assert(offset
< UINT64_MAX
/ secsz
);
1952 n_partitions
= fdisk_table_get_nents(t
);
1953 for (size_t i
= 0; i
< n_partitions
; i
++) {
1954 struct fdisk_partition
*q
;
1957 q
= fdisk_table_get_partition(t
, i
);
1959 return log_error_errno(SYNTHETIC_ERRNO(EIO
), "Failed to read partition metadata: %m");
1961 if (fdisk_partition_is_used(q
) <= 0)
1964 if (!fdisk_partition_has_start(q
))
1967 start
= fdisk_partition_get_start(q
);
1968 assert(start
< UINT64_MAX
/ secsz
);
1971 if (start
>= offset
&& (next
== UINT64_MAX
|| next
> start
))
1975 if (next
== UINT64_MAX
) {
1976 /* No later partition? In that case check the end of the usable area */
1977 next
= fdisk_get_last_lba(c
);
1978 assert(next
< UINT64_MAX
);
1979 next
++; /* The last LBA is one sector before the end */
1981 assert(next
< UINT64_MAX
/ secsz
);
1985 return log_error_errno(SYNTHETIC_ERRNO(EIO
), "Partition end beyond disk end.");
1988 assert(next
>= offset
);
1989 offset
= round_up_size(offset
, grainsz
);
1990 next
= round_down_size(next
, grainsz
);
1992 *ret
= LESS_BY(next
, offset
); /* Saturated subtraction, rounding might have fucked things up */
1996 static int context_copy_from_one(Context
*context
, const char *src
) {
1997 _cleanup_close_
int fd
= -EBADF
;
1998 _cleanup_(fdisk_unref_contextp
) struct fdisk_context
*c
= NULL
;
1999 _cleanup_(fdisk_unref_tablep
) struct fdisk_table
*t
= NULL
;
2000 Partition
*last
= NULL
;
2001 unsigned long secsz
, grainsz
;
2002 size_t n_partitions
;
2007 r
= context_open_and_lock_backing_fd(src
, LOCK_SH
, &fd
);
2011 r
= fd_verify_regular(fd
);
2013 return log_error_errno(r
, "%s is not a file: %m", src
);
2015 r
= fdisk_new_context_at(fd
, /* path = */ NULL
, /* read_only = */ true, /* sector_size = */ UINT32_MAX
, &c
);
2017 return log_error_errno(r
, "Failed to create fdisk context: %m");
2019 secsz
= fdisk_get_sector_size(c
);
2020 grainsz
= fdisk_get_grain_size(c
);
2022 /* Insist on a power of two, and that it's a multiple of 512, i.e. the traditional sector size. */
2023 if (secsz
< 512 || !ISPOWEROF2(secsz
))
2024 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
), "Sector size %lu is not a power of two larger than 512? Refusing.", secsz
);
2026 if (!fdisk_is_labeltype(c
, FDISK_DISKLABEL_GPT
))
2027 return log_error_errno(SYNTHETIC_ERRNO(EHWPOISON
), "Cannot copy from disk %s with no GPT disk label.", src
);
2029 r
= fdisk_get_partitions(c
, &t
);
2031 return log_error_errno(r
, "Failed to acquire partition table: %m");
2033 n_partitions
= fdisk_table_get_nents(t
);
2034 for (size_t i
= 0; i
< n_partitions
; i
++) {
2035 _cleanup_(partition_freep
) Partition
*np
= NULL
;
2036 _cleanup_free_
char *label_copy
= NULL
;
2037 struct fdisk_partition
*p
;
2039 uint64_t sz
, start
, padding
;
2040 sd_id128_t ptid
, id
;
2041 GptPartitionType type
;
2043 p
= fdisk_table_get_partition(t
, i
);
2045 return log_error_errno(SYNTHETIC_ERRNO(EIO
), "Failed to read partition metadata: %m");
2047 if (fdisk_partition_is_used(p
) <= 0)
2050 if (fdisk_partition_has_start(p
) <= 0 ||
2051 fdisk_partition_has_size(p
) <= 0 ||
2052 fdisk_partition_has_partno(p
) <= 0)
2053 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
), "Found a partition without a position, size or number.");
2055 r
= fdisk_partition_get_type_as_id128(p
, &ptid
);
2057 return log_error_errno(r
, "Failed to query partition type UUID: %m");
2059 type
= gpt_partition_type_from_uuid(ptid
);
2061 r
= fdisk_partition_get_uuid_as_id128(p
, &id
);
2063 return log_error_errno(r
, "Failed to query partition UUID: %m");
2065 label
= fdisk_partition_get_name(p
);
2066 if (!isempty(label
)) {
2067 label_copy
= strdup(label
);
2072 sz
= fdisk_partition_get_size(p
);
2073 assert(sz
<= UINT64_MAX
/secsz
);
2076 start
= fdisk_partition_get_start(p
);
2077 assert(start
<= UINT64_MAX
/secsz
);
2080 if (partition_type_exclude(&type
))
2083 np
= partition_new();
2089 np
->new_uuid_is_set
= true;
2090 np
->size_min
= np
->size_max
= sz
;
2091 np
->new_label
= TAKE_PTR(label_copy
);
2093 np
->definition_path
= strdup(src
);
2094 if (!np
->definition_path
)
2097 r
= determine_current_padding(c
, t
, p
, secsz
, grainsz
, &padding
);
2101 np
->padding_min
= np
->padding_max
= padding
;
2103 np
->copy_blocks_path
= strdup(src
);
2104 if (!np
->copy_blocks_path
)
2107 np
->copy_blocks_fd
= fcntl(fd
, F_DUPFD_CLOEXEC
, 3);
2108 if (np
->copy_blocks_fd
< 0)
2109 return log_error_errno(r
, "Failed to duplicate file descriptor of %s: %m", src
);
2111 np
->copy_blocks_offset
= start
;
2112 np
->copy_blocks_size
= sz
;
2114 r
= fdisk_partition_get_attrs_as_uint64(p
, &np
->gpt_flags
);
2116 return log_error_errno(r
, "Failed to get partition flags: %m");
2118 LIST_INSERT_AFTER(partitions
, context
->partitions
, last
, np
);
2119 last
= TAKE_PTR(np
);
2120 context
->n_partitions
++;
2126 static int context_copy_from(Context
*context
) {
2131 STRV_FOREACH(src
, arg_copy_from
) {
2132 r
= context_copy_from_one(context
, *src
);
2140 static int context_read_definitions(Context
*context
) {
2141 _cleanup_strv_free_
char **files
= NULL
;
2142 Partition
*last
= LIST_FIND_TAIL(partitions
, context
->partitions
);
2143 const char *const *dirs
;
2148 dirs
= (const char* const*) (arg_definitions
?: CONF_PATHS_STRV("repart.d"));
2150 r
= conf_files_list_strv(&files
, ".conf", arg_definitions
? NULL
: arg_root
, CONF_FILES_REGULAR
|CONF_FILES_FILTER_MASKED
, dirs
);
2152 return log_error_errno(r
, "Failed to enumerate *.conf files: %m");
2154 STRV_FOREACH(f
, files
) {
2155 _cleanup_(partition_freep
) Partition
*p
= NULL
;
2157 p
= partition_new();
2161 p
->definition_path
= strdup(*f
);
2162 if (!p
->definition_path
)
2165 r
= partition_read_definition(p
, *f
, dirs
);
2171 LIST_INSERT_AFTER(partitions
, context
->partitions
, last
, p
);
2173 context
->n_partitions
++;
2176 /* Check that each configured verity hash/data partition has a matching verity data/hash partition. */
2178 LIST_FOREACH(partitions
, p
, context
->partitions
) {
2179 if (p
->verity
== VERITY_OFF
)
2182 for (VerityMode mode
= VERITY_OFF
+ 1; mode
< _VERITY_MODE_MAX
; mode
++) {
2183 Partition
*q
= NULL
;
2185 if (p
->verity
== mode
)
2188 if (p
->siblings
[mode
])
2191 r
= find_verity_sibling(context
, p
, mode
, &q
);
2193 if (mode
!= VERITY_SIG
)
2194 return log_syntax(NULL
, LOG_ERR
, p
->definition_path
, 1, SYNTHETIC_ERRNO(EINVAL
),
2195 "Missing verity %s partition for verity %s partition with VerityMatchKey=%s",
2196 verity_mode_to_string(mode
), verity_mode_to_string(p
->verity
), p
->verity_match_key
);
2197 } else if (r
== -ENOTUNIQ
)
2198 return log_syntax(NULL
, LOG_ERR
, p
->definition_path
, 1, SYNTHETIC_ERRNO(EINVAL
),
2199 "Multiple verity %s partitions found for verity %s partition with VerityMatchKey=%s",
2200 verity_mode_to_string(mode
), verity_mode_to_string(p
->verity
), p
->verity_match_key
);
2202 return log_syntax(NULL
, LOG_ERR
, p
->definition_path
, 1, r
,
2203 "Failed to find verity %s partition for verity %s partition with VerityMatchKey=%s",
2204 verity_mode_to_string(mode
), verity_mode_to_string(p
->verity
), p
->verity_match_key
);
2207 if (q
->priority
!= p
->priority
)
2208 return log_syntax(NULL
, LOG_ERR
, p
->definition_path
, 1, SYNTHETIC_ERRNO(EINVAL
),
2209 "Priority mismatch (%i != %i) for verity sibling partitions with VerityMatchKey=%s",
2210 p
->priority
, q
->priority
, p
->verity_match_key
);
2212 p
->siblings
[mode
] = q
;
2217 LIST_FOREACH(partitions
, p
, context
->partitions
) {
2220 if (p
->verity
!= VERITY_HASH
)
2223 if (p
->minimize
== MINIMIZE_OFF
)
2226 assert_se(dp
= p
->siblings
[VERITY_DATA
]);
2228 if (dp
->minimize
== MINIMIZE_OFF
&& !(dp
->copy_blocks_path
|| dp
->copy_blocks_auto
))
2229 return log_syntax(NULL
, LOG_ERR
, p
->definition_path
, 1, SYNTHETIC_ERRNO(EINVAL
),
2230 "Minimize= set for verity hash partition but data partition does "
2231 "not set CopyBlocks= or Minimize=");
2238 static int fdisk_ask_cb(struct fdisk_context
*c
, struct fdisk_ask
*ask
, void *data
) {
2239 _cleanup_free_
char *ids
= NULL
;
2242 if (fdisk_ask_get_type(ask
) != FDISK_ASKTYPE_STRING
)
2245 ids
= new(char, SD_ID128_UUID_STRING_MAX
);
2249 r
= fdisk_ask_string_set_result(ask
, sd_id128_to_uuid_string(*(sd_id128_t
*) data
, ids
));
2257 static int fdisk_set_disklabel_id_by_uuid(struct fdisk_context
*c
, sd_id128_t id
) {
2260 r
= fdisk_set_ask(c
, fdisk_ask_cb
, &id
);
2264 r
= fdisk_set_disklabel_id(c
);
2268 return fdisk_set_ask(c
, NULL
, NULL
);
2271 static int derive_uuid(sd_id128_t base
, const char *token
, sd_id128_t
*ret
) {
2273 uint8_t md
[SHA256_DIGEST_SIZE
];
2280 /* Derive a new UUID from the specified UUID in a stable and reasonably safe way. Specifically, we
2281 * calculate the HMAC-SHA256 of the specified token string, keyed by the supplied base (typically the
2282 * machine ID). We use the machine ID as key (and not as cleartext!) of the HMAC operation since it's
2283 * the machine ID we don't want to leak. */
2285 hmac_sha256(base
.bytes
, sizeof(base
.bytes
), token
, strlen(token
), result
.md
);
2287 /* Take the first half, mark it as v4 UUID */
2288 assert_cc(sizeof(result
.md
) == sizeof(result
.id
) * 2);
2289 *ret
= id128_make_v4_uuid(result
.id
);
2293 static void derive_salt(sd_id128_t base
, const char *token
, uint8_t ret
[static SHA256_DIGEST_SIZE
]) {
2296 hmac_sha256(base
.bytes
, sizeof(base
.bytes
), token
, strlen(token
), ret
);
2299 static int context_load_partition_table(Context
*context
) {
2300 _cleanup_(fdisk_unref_contextp
) struct fdisk_context
*c
= NULL
;
2301 _cleanup_(fdisk_unref_tablep
) struct fdisk_table
*t
= NULL
;
2302 uint64_t left_boundary
= UINT64_MAX
, first_lba
, last_lba
, nsectors
;
2303 _cleanup_free_
char *disk_uuid_string
= NULL
;
2304 bool from_scratch
= false;
2305 sd_id128_t disk_uuid
;
2306 size_t n_partitions
;
2307 unsigned long secsz
;
2308 uint64_t grainsz
, fs_secsz
= DEFAULT_FILESYSTEM_SECTOR_SIZE
;
2312 assert(!context
->fdisk_context
);
2313 assert(!context
->free_areas
);
2314 assert(context
->start
== UINT64_MAX
);
2315 assert(context
->end
== UINT64_MAX
);
2316 assert(context
->total
== UINT64_MAX
);
2318 c
= fdisk_new_context();
2322 if (arg_sector_size
> 0) {
2323 fs_secsz
= arg_sector_size
;
2324 r
= fdisk_save_user_sector_size(c
, /* phy= */ 0, arg_sector_size
);
2329 r
= context_open_and_lock_backing_fd(context
->node
, arg_dry_run
? LOCK_SH
: LOCK_EX
,
2330 &context
->backing_fd
);
2334 if (fstat(context
->backing_fd
, &st
) < 0)
2335 return log_error_errno(errno
, "Failed to stat %s: %m", context
->node
);
2337 /* Auto-detect sector size if not specified. */
2338 r
= probe_sector_size_prefer_ioctl(context
->backing_fd
, &ssz
);
2340 return log_error_errno(r
, "Failed to probe sector size of '%s': %m", context
->node
);
2342 /* If we found the sector size and we're operating on a block device, use it as the file
2343 * system sector size as well, as we know its the sector size of the actual block device and
2344 * not just the offset at which we found the GPT header. */
2345 if (r
> 0 && S_ISBLK(st
.st_mode
))
2348 r
= fdisk_save_user_sector_size(c
, /* phy= */ 0, ssz
);
2351 return log_error_errno(r
, "Failed to set sector size: %m");
2353 /* libfdisk doesn't have an API to operate on arbitrary fds, hence reopen the fd going via the
2354 * /proc/self/fd/ magic path if we have an existing fd. Open the original file otherwise. */
2355 r
= fdisk_assign_device(
2357 context
->backing_fd
>= 0 ? FORMAT_PROC_FD_PATH(context
->backing_fd
) : context
->node
,
2359 if (r
== -EINVAL
&& arg_size_auto
) {
2362 /* libfdisk returns EINVAL if opening a file of size zero. Let's check for that, and accept
2363 * it if automatic sizing is requested. */
2365 if (context
->backing_fd
< 0)
2366 r
= stat(context
->node
, &st
);
2368 r
= fstat(context
->backing_fd
, &st
);
2370 return log_error_errno(errno
, "Failed to stat block device '%s': %m", context
->node
);
2372 if (S_ISREG(st
.st_mode
) && st
.st_size
== 0) {
2373 /* Use the fallback values if we have no better idea */
2374 context
->sector_size
= fdisk_get_sector_size(c
);
2375 context
->fs_sector_size
= fs_secsz
;
2376 context
->grain_size
= 4096;
2377 return /* from_scratch = */ true;
2383 return log_error_errno(r
, "Failed to open device '%s': %m", context
->node
);
2385 if (context
->backing_fd
< 0) {
2386 /* If we have no fd referencing the device yet, make a copy of the fd now, so that we have one */
2387 r
= context_open_and_lock_backing_fd(FORMAT_PROC_FD_PATH(fdisk_get_devfd(c
)),
2388 arg_dry_run
? LOCK_SH
: LOCK_EX
,
2389 &context
->backing_fd
);
2394 /* The offsets/sizes libfdisk returns to us will be in multiple of the sector size of the
2395 * device. This is typically 512, and sometimes 4096. Let's query libfdisk once for it, and then use
2396 * it for all our needs. Note that the values we use ourselves always are in bytes though, thus mean
2397 * the same thing universally. Also note that regardless what kind of sector size is in use we'll
2398 * place partitions at multiples of 4K. */
2399 secsz
= fdisk_get_sector_size(c
);
2401 /* Insist on a power of two, and that it's a multiple of 512, i.e. the traditional sector size. */
2402 if (secsz
< 512 || !ISPOWEROF2(secsz
))
2403 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
), "Sector size %lu is not a power of two larger than 512? Refusing.", secsz
);
2405 /* Use at least 4K, and ensure it's a multiple of the sector size, regardless if that is smaller or
2407 grainsz
= secsz
< 4096 ? 4096 : secsz
;
2409 log_debug("Sector size of device is %lu bytes. Using grain size of %" PRIu64
".", secsz
, grainsz
);
2411 switch (arg_empty
) {
2414 /* Refuse empty disks, insist on an existing GPT partition table */
2415 if (!fdisk_is_labeltype(c
, FDISK_DISKLABEL_GPT
))
2416 return log_notice_errno(SYNTHETIC_ERRNO(EHWPOISON
), "Disk %s has no GPT disk label, not repartitioning.", context
->node
);
2421 /* Require an empty disk, refuse any existing partition table */
2422 r
= fdisk_has_label(c
);
2424 return log_error_errno(r
, "Failed to determine whether disk %s has a disk label: %m", context
->node
);
2426 return log_notice_errno(SYNTHETIC_ERRNO(EHWPOISON
), "Disk %s already has a disk label, refusing.", context
->node
);
2428 from_scratch
= true;
2432 /* Allow both an empty disk and an existing partition table, but only GPT */
2433 r
= fdisk_has_label(c
);
2435 return log_error_errno(r
, "Failed to determine whether disk %s has a disk label: %m", context
->node
);
2437 if (!fdisk_is_labeltype(c
, FDISK_DISKLABEL_GPT
))
2438 return log_notice_errno(SYNTHETIC_ERRNO(EHWPOISON
), "Disk %s has non-GPT disk label, not repartitioning.", context
->node
);
2440 from_scratch
= true;
2446 /* Always reinitiaize the disk, don't consider what there was on the disk before */
2447 from_scratch
= true;
2451 assert_not_reached();
2455 r
= fdisk_create_disklabel(c
, "gpt");
2457 return log_error_errno(r
, "Failed to create GPT disk label: %m");
2459 r
= derive_uuid(context
->seed
, "disk-uuid", &disk_uuid
);
2461 return log_error_errno(r
, "Failed to acquire disk GPT uuid: %m");
2463 r
= fdisk_set_disklabel_id_by_uuid(c
, disk_uuid
);
2465 return log_error_errno(r
, "Failed to set GPT disk label: %m");
2467 goto add_initial_free_area
;
2470 r
= fdisk_get_disklabel_id(c
, &disk_uuid_string
);
2472 return log_error_errno(r
, "Failed to get current GPT disk label UUID: %m");
2474 r
= id128_from_string_nonzero(disk_uuid_string
, &disk_uuid
);
2476 r
= derive_uuid(context
->seed
, "disk-uuid", &disk_uuid
);
2478 return log_error_errno(r
, "Failed to acquire disk GPT uuid: %m");
2480 r
= fdisk_set_disklabel_id(c
);
2482 return log_error_errno(r
, "Failed to set GPT disk label: %m");
2484 return log_error_errno(r
, "Failed to parse current GPT disk label UUID: %m");
2486 r
= fdisk_get_partitions(c
, &t
);
2488 return log_error_errno(r
, "Failed to acquire partition table: %m");
2490 n_partitions
= fdisk_table_get_nents(t
);
2491 for (size_t i
= 0; i
< n_partitions
; i
++) {
2492 _cleanup_free_
char *label_copy
= NULL
;
2493 Partition
*last
= NULL
;
2494 struct fdisk_partition
*p
;
2498 sd_id128_t ptid
, id
;
2501 p
= fdisk_table_get_partition(t
, i
);
2503 return log_error_errno(SYNTHETIC_ERRNO(EIO
), "Failed to read partition metadata: %m");
2505 if (fdisk_partition_is_used(p
) <= 0)
2508 if (fdisk_partition_has_start(p
) <= 0 ||
2509 fdisk_partition_has_size(p
) <= 0 ||
2510 fdisk_partition_has_partno(p
) <= 0)
2511 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
), "Found a partition without a position, size or number.");
2513 r
= fdisk_partition_get_type_as_id128(p
, &ptid
);
2515 return log_error_errno(r
, "Failed to query partition type UUID: %m");
2517 r
= fdisk_partition_get_uuid_as_id128(p
, &id
);
2519 return log_error_errno(r
, "Failed to query partition UUID: %m");
2521 label
= fdisk_partition_get_name(p
);
2522 if (!isempty(label
)) {
2523 label_copy
= strdup(label
);
2528 sz
= fdisk_partition_get_size(p
);
2529 assert(sz
<= UINT64_MAX
/secsz
);
2532 start
= fdisk_partition_get_start(p
);
2533 assert(start
<= UINT64_MAX
/secsz
);
2536 partno
= fdisk_partition_get_partno(p
);
2538 if (left_boundary
== UINT64_MAX
|| left_boundary
> start
)
2539 left_boundary
= start
;
2541 /* Assign this existing partition to the first partition of the right type that doesn't have
2542 * an existing one assigned yet. */
2543 LIST_FOREACH(partitions
, pp
, context
->partitions
) {
2546 if (!sd_id128_equal(pp
->type
.uuid
, ptid
))
2549 if (!pp
->current_partition
) {
2550 pp
->current_uuid
= id
;
2551 pp
->current_size
= sz
;
2553 pp
->partno
= partno
;
2554 pp
->current_label
= TAKE_PTR(label_copy
);
2556 pp
->current_partition
= p
;
2557 fdisk_ref_partition(p
);
2559 r
= determine_current_padding(c
, t
, p
, secsz
, grainsz
, &pp
->current_padding
);
2563 if (pp
->current_padding
> 0) {
2564 r
= context_add_free_area(context
, pp
->current_padding
, pp
);
2574 /* If we have no matching definition, create a new one. */
2576 _cleanup_(partition_freep
) Partition
*np
= NULL
;
2578 np
= partition_new();
2582 np
->current_uuid
= id
;
2583 np
->type
= gpt_partition_type_from_uuid(ptid
);
2584 np
->current_size
= sz
;
2586 np
->partno
= partno
;
2587 np
->current_label
= TAKE_PTR(label_copy
);
2589 np
->current_partition
= p
;
2590 fdisk_ref_partition(p
);
2592 r
= determine_current_padding(c
, t
, p
, secsz
, grainsz
, &np
->current_padding
);
2596 if (np
->current_padding
> 0) {
2597 r
= context_add_free_area(context
, np
->current_padding
, np
);
2602 LIST_INSERT_AFTER(partitions
, context
->partitions
, last
, TAKE_PTR(np
));
2603 context
->n_partitions
++;
2607 add_initial_free_area
:
2608 nsectors
= fdisk_get_nsectors(c
);
2609 assert(nsectors
<= UINT64_MAX
/secsz
);
2612 first_lba
= fdisk_get_first_lba(c
);
2613 assert(first_lba
<= UINT64_MAX
/secsz
);
2616 last_lba
= fdisk_get_last_lba(c
);
2617 assert(last_lba
< UINT64_MAX
);
2619 assert(last_lba
<= UINT64_MAX
/secsz
);
2622 assert(last_lba
>= first_lba
);
2624 if (left_boundary
== UINT64_MAX
) {
2625 /* No partitions at all? Then the whole disk is up for grabs. */
2627 first_lba
= round_up_size(first_lba
, grainsz
);
2628 last_lba
= round_down_size(last_lba
, grainsz
);
2630 if (last_lba
> first_lba
) {
2631 r
= context_add_free_area(context
, last_lba
- first_lba
, NULL
);
2636 /* Add space left of first partition */
2637 assert(left_boundary
>= first_lba
);
2639 first_lba
= round_up_size(first_lba
, grainsz
);
2640 left_boundary
= round_down_size(left_boundary
, grainsz
);
2641 last_lba
= round_down_size(last_lba
, grainsz
);
2643 if (left_boundary
> first_lba
) {
2644 r
= context_add_free_area(context
, left_boundary
- first_lba
, NULL
);
2650 context
->start
= first_lba
;
2651 context
->end
= last_lba
;
2652 context
->total
= nsectors
;
2653 context
->sector_size
= secsz
;
2654 context
->fs_sector_size
= fs_secsz
;
2655 context
->grain_size
= grainsz
;
2656 context
->fdisk_context
= TAKE_PTR(c
);
2658 return from_scratch
;
2661 static void context_unload_partition_table(Context
*context
) {
2664 LIST_FOREACH(partitions
, p
, context
->partitions
) {
2666 /* Entirely remove partitions that have no configuration */
2667 if (PARTITION_IS_FOREIGN(p
)) {
2668 partition_unlink_and_free(context
, p
);
2672 /* Otherwise drop all data we read off the block device and everything we might have
2673 * calculated based on it */
2676 p
->current_size
= UINT64_MAX
;
2677 p
->new_size
= UINT64_MAX
;
2678 p
->current_padding
= UINT64_MAX
;
2679 p
->new_padding
= UINT64_MAX
;
2680 p
->partno
= UINT64_MAX
;
2681 p
->offset
= UINT64_MAX
;
2683 if (p
->current_partition
) {
2684 fdisk_unref_partition(p
->current_partition
);
2685 p
->current_partition
= NULL
;
2688 if (p
->new_partition
) {
2689 fdisk_unref_partition(p
->new_partition
);
2690 p
->new_partition
= NULL
;
2693 p
->padding_area
= NULL
;
2694 p
->allocated_to_area
= NULL
;
2696 p
->current_uuid
= SD_ID128_NULL
;
2697 p
->current_label
= mfree(p
->current_label
);
2700 context
->start
= UINT64_MAX
;
2701 context
->end
= UINT64_MAX
;
2702 context
->total
= UINT64_MAX
;
2704 if (context
->fdisk_context
) {
2705 fdisk_unref_context(context
->fdisk_context
);
2706 context
->fdisk_context
= NULL
;
2709 context_free_free_areas(context
);
2712 static int format_size_change(uint64_t from
, uint64_t to
, char **ret
) {
2715 if (from
!= UINT64_MAX
) {
2716 if (from
== to
|| to
== UINT64_MAX
)
2717 t
= strdup(FORMAT_BYTES(from
));
2719 t
= strjoin(FORMAT_BYTES(from
), " ", special_glyph(SPECIAL_GLYPH_ARROW_RIGHT
), " ", FORMAT_BYTES(to
));
2720 } else if (to
!= UINT64_MAX
)
2721 t
= strjoin(special_glyph(SPECIAL_GLYPH_ARROW_RIGHT
), " ", FORMAT_BYTES(to
));
2734 static const char *partition_label(const Partition
*p
) {
2738 return p
->new_label
;
2740 if (p
->current_label
)
2741 return p
->current_label
;
2743 return gpt_partition_type_uuid_to_string(p
->type
.uuid
);
2746 static int context_dump_partitions(Context
*context
) {
2747 _cleanup_(table_unrefp
) Table
*t
= NULL
;
2748 uint64_t sum_padding
= 0, sum_size
= 0;
2750 const size_t roothash_col
= 14, dropin_files_col
= 15, split_path_col
= 16;
2751 bool has_roothash
= false, has_dropin_files
= false, has_split_path
= false;
2753 if ((arg_json_format_flags
& JSON_FORMAT_OFF
) && context
->n_partitions
== 0) {
2754 log_info("Empty partition table.");
2758 t
= table_new("type",
2778 if (!DEBUG_LOGGING
) {
2779 if (arg_json_format_flags
& JSON_FORMAT_OFF
)
2780 (void) table_set_display(t
, (size_t) 0, (size_t) 1, (size_t) 2, (size_t) 3, (size_t) 4,
2781 (size_t) 8, (size_t) 9, (size_t) 12, roothash_col
, dropin_files_col
,
2784 (void) table_set_display(t
, (size_t) 0, (size_t) 1, (size_t) 2, (size_t) 3, (size_t) 4,
2785 (size_t) 5, (size_t) 6, (size_t) 7, (size_t) 8, (size_t) 10,
2786 (size_t) 11, (size_t) 13, roothash_col
, dropin_files_col
,
2790 (void) table_set_align_percent(t
, table_get_cell(t
, 0, 5), 100);
2791 (void) table_set_align_percent(t
, table_get_cell(t
, 0, 6), 100);
2792 (void) table_set_align_percent(t
, table_get_cell(t
, 0, 7), 100);
2793 (void) table_set_align_percent(t
, table_get_cell(t
, 0, 8), 100);
2794 (void) table_set_align_percent(t
, table_get_cell(t
, 0, 9), 100);
2795 (void) table_set_align_percent(t
, table_get_cell(t
, 0, 10), 100);
2796 (void) table_set_align_percent(t
, table_get_cell(t
, 0, 11), 100);
2798 LIST_FOREACH(partitions
, p
, context
->partitions
) {
2799 _cleanup_free_
char *size_change
= NULL
, *padding_change
= NULL
, *partname
= NULL
, *rh
= NULL
;
2800 char uuid_buffer
[SD_ID128_UUID_STRING_MAX
];
2801 const char *label
, *activity
= NULL
;
2806 if (p
->current_size
== UINT64_MAX
)
2807 activity
= "create";
2808 else if (p
->current_size
!= p
->new_size
)
2809 activity
= "resize";
2811 label
= partition_label(p
);
2812 partname
= p
->partno
!= UINT64_MAX
? fdisk_partname(context
->node
, p
->partno
+1) : NULL
;
2814 r
= format_size_change(p
->current_size
, p
->new_size
, &size_change
);
2818 r
= format_size_change(p
->current_padding
, p
->new_padding
, &padding_change
);
2822 if (p
->new_size
!= UINT64_MAX
)
2823 sum_size
+= p
->new_size
;
2824 if (p
->new_padding
!= UINT64_MAX
)
2825 sum_padding
+= p
->new_padding
;
2827 if (p
->verity
!= VERITY_OFF
) {
2828 Partition
*hp
= p
->verity
== VERITY_HASH
? p
: p
->siblings
[VERITY_HASH
];
2830 rh
= iovec_is_set(&hp
->roothash
) ? hexmem(hp
->roothash
.iov_base
, hp
->roothash
.iov_len
) : strdup("TBD");
2837 TABLE_STRING
, gpt_partition_type_uuid_to_string_harder(p
->type
.uuid
, uuid_buffer
),
2838 TABLE_STRING
, empty_to_null(label
) ?: "-", TABLE_SET_COLOR
, empty_to_null(label
) ? NULL
: ansi_grey(),
2839 TABLE_UUID
, p
->new_uuid_is_set
? p
->new_uuid
: p
->current_uuid
,
2840 TABLE_UINT64
, p
->partno
,
2841 TABLE_PATH_BASENAME
, p
->definition_path
, TABLE_SET_COLOR
, p
->definition_path
? NULL
: ansi_grey(),
2842 TABLE_STRING
, partname
?: "-", TABLE_SET_COLOR
, partname
? NULL
: ansi_highlight(),
2843 TABLE_UINT64
, p
->offset
,
2844 TABLE_UINT64
, p
->current_size
== UINT64_MAX
? 0 : p
->current_size
,
2845 TABLE_UINT64
, p
->new_size
,
2846 TABLE_STRING
, size_change
, TABLE_SET_COLOR
, !p
->partitions_next
&& sum_size
> 0 ? ansi_underline() : NULL
,
2847 TABLE_UINT64
, p
->current_padding
== UINT64_MAX
? 0 : p
->current_padding
,
2848 TABLE_UINT64
, p
->new_padding
,
2849 TABLE_STRING
, padding_change
, TABLE_SET_COLOR
, !p
->partitions_next
&& sum_padding
> 0 ? ansi_underline() : NULL
,
2850 TABLE_STRING
, activity
?: "unchanged",
2852 TABLE_STRV
, p
->drop_in_files
,
2853 TABLE_STRING
, empty_to_null(p
->split_path
) ?: "-");
2855 return table_log_add_error(r
);
2857 has_roothash
= has_roothash
|| !isempty(rh
);
2858 has_dropin_files
= has_dropin_files
|| !strv_isempty(p
->drop_in_files
);
2859 has_split_path
= has_split_path
|| !isempty(p
->split_path
);
2862 if ((arg_json_format_flags
& JSON_FORMAT_OFF
) && (sum_padding
> 0 || sum_size
> 0)) {
2865 a
= strjoina(special_glyph(SPECIAL_GLYPH_SIGMA
), " = ", FORMAT_BYTES(sum_size
));
2866 b
= strjoina(special_glyph(SPECIAL_GLYPH_SIGMA
), " = ", FORMAT_BYTES(sum_padding
));
2888 return table_log_add_error(r
);
2891 if (!has_roothash
) {
2892 r
= table_hide_column_from_display(t
, roothash_col
);
2894 return log_error_errno(r
, "Failed to set columns to display: %m");
2897 if (!has_dropin_files
) {
2898 r
= table_hide_column_from_display(t
, dropin_files_col
);
2900 return log_error_errno(r
, "Failed to set columns to display: %m");
2903 if (!has_split_path
) {
2904 r
= table_hide_column_from_display(t
, split_path_col
);
2906 return log_error_errno(r
, "Failed to set columns to display: %m");
2909 return table_print_with_pager(t
, arg_json_format_flags
, arg_pager_flags
, arg_legend
);
2912 static int context_bar_char_process_partition(
2917 size_t **start_array
,
2918 size_t *n_start_array
) {
2920 uint64_t from
, to
, total
;
2927 assert(start_array
);
2928 assert(n_start_array
);
2933 assert(p
->offset
!= UINT64_MAX
);
2934 assert(p
->new_size
!= UINT64_MAX
);
2937 to
= from
+ p
->new_size
;
2939 assert(context
->total
> 0);
2940 total
= context
->total
;
2942 assert(from
<= total
);
2943 x
= from
* n
/ total
;
2945 assert(to
<= total
);
2951 for (size_t i
= x
; i
< y
; i
++)
2954 if (!GREEDY_REALLOC_APPEND(*start_array
, *n_start_array
, &x
, 1))
2960 static int partition_hint(const Partition
*p
, const char *node
, char **ret
) {
2961 _cleanup_free_
char *buf
= NULL
;
2965 /* Tries really hard to find a suitable description for this partition */
2967 if (p
->definition_path
)
2968 return path_extract_filename(p
->definition_path
, ret
);
2970 label
= partition_label(p
);
2971 if (!isempty(label
)) {
2972 buf
= strdup(label
);
2976 if (p
->partno
!= UINT64_MAX
) {
2977 buf
= fdisk_partname(node
, p
->partno
+1);
2981 if (p
->new_uuid_is_set
)
2983 else if (!sd_id128_is_null(p
->current_uuid
))
2984 id
= p
->current_uuid
;
2988 buf
= strdup(SD_ID128_TO_UUID_STRING(id
));
2994 *ret
= TAKE_PTR(buf
);
2998 static int context_dump_partition_bar(Context
*context
) {
2999 _cleanup_free_ Partition
**bar
= NULL
;
3000 _cleanup_free_
size_t *start_array
= NULL
;
3001 size_t n_start_array
= 0;
3002 Partition
*last
= NULL
;
3007 assert_se((c
= columns()) >= 2);
3008 c
-= 2; /* We do not use the leftmost and rightmost character cell */
3010 bar
= new0(Partition
*, c
);
3014 LIST_FOREACH(partitions
, p
, context
->partitions
) {
3015 r
= context_bar_char_process_partition(context
, bar
, c
, p
, &start_array
, &n_start_array
);
3022 for (size_t i
= 0; i
< c
; i
++) {
3027 fputs(z
? ansi_green() : ansi_yellow(), stdout
);
3028 fputs(special_glyph(SPECIAL_GLYPH_DARK_SHADE
), stdout
);
3030 fputs(ansi_normal(), stdout
);
3031 fputs(special_glyph(SPECIAL_GLYPH_LIGHT_SHADE
), stdout
);
3037 fputs(ansi_normal(), stdout
);
3040 for (size_t i
= 0; i
< n_start_array
; i
++) {
3041 _cleanup_free_
char **line
= NULL
;
3043 line
= new0(char*, c
);
3048 LIST_FOREACH(partitions
, p
, context
->partitions
) {
3049 _cleanup_free_
char *d
= NULL
;
3056 if (i
< n_start_array
- j
) {
3058 if (line
[start_array
[j
-1]]) {
3061 /* Upgrade final corner to the right with a branch to the right */
3062 e
= startswith(line
[start_array
[j
-1]], special_glyph(SPECIAL_GLYPH_TREE_RIGHT
));
3064 d
= strjoin(special_glyph(SPECIAL_GLYPH_TREE_BRANCH
), e
);
3071 d
= strdup(special_glyph(SPECIAL_GLYPH_TREE_VERTICAL
));
3076 } else if (i
== n_start_array
- j
) {
3077 _cleanup_free_
char *hint
= NULL
;
3079 (void) partition_hint(p
, context
->node
, &hint
);
3081 if (streq_ptr(line
[start_array
[j
-1]], special_glyph(SPECIAL_GLYPH_TREE_VERTICAL
)))
3082 d
= strjoin(special_glyph(SPECIAL_GLYPH_TREE_BRANCH
), " ", strna(hint
));
3084 d
= strjoin(special_glyph(SPECIAL_GLYPH_TREE_RIGHT
), " ", strna(hint
));
3091 free_and_replace(line
[start_array
[j
-1]], d
);
3099 fputs(line
[j
], stdout
);
3100 j
+= utf8_console_width(line
[j
]);
3109 for (j
= 0; j
< c
; j
++)
3116 static bool context_has_roothash(Context
*context
) {
3117 LIST_FOREACH(partitions
, p
, context
->partitions
)
3118 if (iovec_is_set(&p
->roothash
))
3124 static int context_dump(Context
*context
, bool late
) {
3129 if (arg_pretty
== 0 && FLAGS_SET(arg_json_format_flags
, JSON_FORMAT_OFF
))
3132 /* If we're outputting JSON, only dump after doing all operations so we can include the roothashes
3134 if (!late
&& !FLAGS_SET(arg_json_format_flags
, JSON_FORMAT_OFF
))
3137 /* If we're not outputting JSON, only dump again after doing all operations if there are any
3138 * roothashes that we need to communicate to the user. */
3139 if (late
&& FLAGS_SET(arg_json_format_flags
, JSON_FORMAT_OFF
) && !context_has_roothash(context
))
3142 r
= context_dump_partitions(context
);
3146 /* Make sure we only write the partition bar once, even if we're writing the partition table twice to
3147 * communicate roothashes. */
3148 if (FLAGS_SET(arg_json_format_flags
, JSON_FORMAT_OFF
) && !late
) {
3151 r
= context_dump_partition_bar(context
);
3164 static bool context_changed(const Context
*context
) {
3167 LIST_FOREACH(partitions
, p
, context
->partitions
) {
3171 if (p
->allocated_to_area
)
3174 if (p
->new_size
!= p
->current_size
)
3181 static int context_wipe_range(Context
*context
, uint64_t offset
, uint64_t size
) {
3182 _cleanup_(blkid_free_probep
) blkid_probe probe
= NULL
;
3186 assert(offset
!= UINT64_MAX
);
3187 assert(size
!= UINT64_MAX
);
3189 probe
= blkid_new_probe();
3194 r
= blkid_probe_set_device(probe
, fdisk_get_devfd(context
->fdisk_context
), offset
, size
);
3196 return log_error_errno(errno
?: SYNTHETIC_ERRNO(EIO
), "Failed to allocate device probe for wiping.");
3199 if (blkid_probe_enable_superblocks(probe
, true) < 0 ||
3200 blkid_probe_set_superblocks_flags(probe
, BLKID_SUBLKS_MAGIC
|BLKID_SUBLKS_BADCSUM
) < 0 ||
3201 blkid_probe_enable_partitions(probe
, true) < 0 ||
3202 blkid_probe_set_partitions_flags(probe
, BLKID_PARTS_MAGIC
) < 0)
3203 return log_error_errno(errno
?: SYNTHETIC_ERRNO(EIO
), "Failed to enable superblock and partition probing.");
3207 r
= blkid_do_probe(probe
);
3209 return log_error_errno(errno_or_else(EIO
), "Failed to probe for file systems.");
3214 if (blkid_do_wipe(probe
, false) < 0)
3215 return log_error_errno(errno_or_else(EIO
), "Failed to wipe file system signature.");
3221 static int context_wipe_partition(Context
*context
, Partition
*p
) {
3226 assert(!PARTITION_EXISTS(p
)); /* Safety check: never wipe existing partitions */
3228 assert(p
->offset
!= UINT64_MAX
);
3229 assert(p
->new_size
!= UINT64_MAX
);
3231 r
= context_wipe_range(context
, p
->offset
, p
->new_size
);
3235 log_info("Successfully wiped file system signatures from future partition %" PRIu64
".", p
->partno
);
3239 static int context_discard_range(
3248 assert(offset
!= UINT64_MAX
);
3249 assert(size
!= UINT64_MAX
);
3254 assert_se((fd
= fdisk_get_devfd(context
->fdisk_context
)) >= 0);
3256 if (fstat(fd
, &st
) < 0)
3259 if (S_ISREG(st
.st_mode
)) {
3260 if (fallocate(fd
, FALLOC_FL_PUNCH_HOLE
|FALLOC_FL_KEEP_SIZE
, offset
, size
) < 0) {
3261 if (ERRNO_IS_NOT_SUPPORTED(errno
))
3270 if (S_ISBLK(st
.st_mode
)) {
3271 uint64_t range
[2], end
;
3273 range
[0] = round_up_size(offset
, context
->sector_size
);
3275 if (offset
> UINT64_MAX
- size
)
3278 end
= offset
+ size
;
3279 if (end
<= range
[0])
3282 range
[1] = round_down_size(end
- range
[0], context
->sector_size
);
3286 if (ioctl(fd
, BLKDISCARD
, range
) < 0) {
3287 if (ERRNO_IS_NOT_SUPPORTED(errno
))
3299 static int context_discard_partition(Context
*context
, Partition
*p
) {
3305 assert(p
->offset
!= UINT64_MAX
);
3306 assert(p
->new_size
!= UINT64_MAX
);
3307 assert(!PARTITION_EXISTS(p
)); /* Safety check: never discard existing partitions */
3312 r
= context_discard_range(context
, p
->offset
, p
->new_size
);
3313 if (r
== -EOPNOTSUPP
) {
3314 log_info("Storage does not support discard, not discarding data in future partition %" PRIu64
".", p
->partno
);
3318 /* Let's handle this gracefully: https://bugzilla.kernel.org/show_bug.cgi?id=211167 */
3319 log_info("Block device is busy, not discarding partition %" PRIu64
" because it probably is mounted.", p
->partno
);
3323 log_info("Partition %" PRIu64
" too short for discard, skipping.", p
->partno
);
3327 return log_error_errno(r
, "Failed to discard data for future partition %" PRIu64
".", p
->partno
);
3329 log_info("Successfully discarded data from future partition %" PRIu64
".", p
->partno
);
3333 static int context_discard_gap_after(Context
*context
, Partition
*p
) {
3334 uint64_t gap
, next
= UINT64_MAX
;
3338 assert(!p
|| (p
->offset
!= UINT64_MAX
&& p
->new_size
!= UINT64_MAX
));
3344 gap
= p
->offset
+ p
->new_size
;
3346 /* The context start gets rounded up to grain_size, however
3347 * existing partitions may be before that so ensure the gap
3348 * starts at the first actually usable lba
3350 gap
= fdisk_get_first_lba(context
->fdisk_context
) * context
->sector_size
;
3352 LIST_FOREACH(partitions
, q
, context
->partitions
) {
3356 assert(q
->offset
!= UINT64_MAX
);
3357 assert(q
->new_size
!= UINT64_MAX
);
3359 if (q
->offset
< gap
)
3362 if (next
== UINT64_MAX
|| q
->offset
< next
)
3366 if (next
== UINT64_MAX
) {
3367 next
= (fdisk_get_last_lba(context
->fdisk_context
) + 1) * context
->sector_size
;
3369 return log_error_errno(SYNTHETIC_ERRNO(EIO
), "Partition end beyond disk end.");
3372 assert(next
>= gap
);
3373 r
= context_discard_range(context
, gap
, next
- gap
);
3374 if (r
== -EOPNOTSUPP
) {
3376 log_info("Storage does not support discard, not discarding gap after partition %" PRIu64
".", p
->partno
);
3378 log_info("Storage does not support discard, not discarding gap at beginning of disk.");
3381 if (r
== 0) /* Too short */
3385 return log_error_errno(r
, "Failed to discard gap after partition %" PRIu64
".", p
->partno
);
3387 return log_error_errno(r
, "Failed to discard gap at beginning of disk.");
3391 log_info("Successfully discarded gap after partition %" PRIu64
".", p
->partno
);
3393 log_info("Successfully discarded gap at beginning of disk.");
3398 static int context_wipe_and_discard(Context
*context
) {
3403 if (arg_empty
== EMPTY_CREATE
) /* If we just created the image, no need to wipe */
3406 /* Wipe and discard the contents of all partitions we are about to create. We skip the discarding if
3407 * we were supposed to start from scratch anyway, as in that case we just discard the whole block
3408 * device in one go early on. */
3410 LIST_FOREACH(partitions
, p
, context
->partitions
) {
3412 if (!p
->allocated_to_area
)
3415 if (partition_type_defer(&p
->type
))
3418 r
= context_wipe_partition(context
, p
);
3422 if (!context
->from_scratch
) {
3423 r
= context_discard_partition(context
, p
);
3427 r
= context_discard_gap_after(context
, p
);
3433 if (!context
->from_scratch
) {
3434 r
= context_discard_gap_after(context
, NULL
);
3442 typedef struct DecryptedPartitionTarget
{
3446 struct crypt_device
*device
;
3447 } DecryptedPartitionTarget
;
3449 static DecryptedPartitionTarget
* decrypted_partition_target_free(DecryptedPartitionTarget
*t
) {
3450 #if HAVE_LIBCRYPTSETUP
3458 /* udev or so might access out block device in the background while we are done. Let's hence
3459 * force detach the volume. We sync'ed before, hence this should be safe. */
3460 r
= sym_crypt_deactivate_by_name(t
->device
, t
->dm_name
, CRYPT_DEACTIVATE_FORCE
);
3462 log_warning_errno(r
, "Failed to deactivate LUKS device, ignoring: %m");
3464 sym_crypt_free(t
->device
);
3477 DecryptedPartitionTarget
*decrypted
;
3480 static int partition_target_fd(PartitionTarget
*t
) {
3482 assert(t
->loop
|| t
->fd
>= 0 || t
->whole_fd
>= 0);
3485 return t
->decrypted
->fd
;
3496 static const char* partition_target_path(PartitionTarget
*t
) {
3498 assert(t
->loop
|| t
->path
);
3501 return t
->decrypted
->volume
;
3504 return t
->loop
->node
;
3509 static PartitionTarget
*partition_target_free(PartitionTarget
*t
) {
3513 decrypted_partition_target_free(t
->decrypted
);
3514 loop_device_unref(t
->loop
);
3516 unlink_and_free(t
->path
);
3521 DEFINE_TRIVIAL_CLEANUP_FUNC(PartitionTarget
*, partition_target_free
);
3523 static int prepare_temporary_file(PartitionTarget
*t
, uint64_t size
) {
3524 _cleanup_(unlink_and_freep
) char *temp
= NULL
;
3525 _cleanup_close_
int fd
= -EBADF
;
3531 r
= var_tmp_dir(&vt
);
3533 return log_error_errno(r
, "Could not determine temporary directory: %m");
3535 temp
= path_join(vt
, "repart-XXXXXX");
3539 fd
= mkostemp_safe(temp
);
3541 return log_error_errno(fd
, "Failed to create temporary file: %m");
3543 if (ftruncate(fd
, size
) < 0)
3544 return log_error_errno(errno
, "Failed to truncate temporary file to %s: %m",
3545 FORMAT_BYTES(size
));
3547 t
->fd
= TAKE_FD(fd
);
3548 t
->path
= TAKE_PTR(temp
);
3553 static int partition_target_prepare(
3558 PartitionTarget
**ret
) {
3560 _cleanup_(partition_target_freep
) PartitionTarget
*t
= NULL
;
3561 _cleanup_(loop_device_unrefp
) LoopDevice
*d
= NULL
;
3568 assert_se((whole_fd
= fdisk_get_devfd(context
->fdisk_context
)) >= 0);
3570 t
= new(PartitionTarget
, 1);
3573 *t
= (PartitionTarget
) {
3579 if (lseek(whole_fd
, p
->offset
, SEEK_SET
) < 0)
3580 return log_error_errno(errno
, "Failed to seek to partition offset: %m");
3582 t
->whole_fd
= whole_fd
;
3587 /* Loopback block devices are not only useful to turn regular files into block devices, but
3588 * also to cut out sections of block devices into new block devices. */
3590 if (arg_offline
<= 0) {
3591 r
= loop_device_make(whole_fd
, O_RDWR
, p
->offset
, size
, context
->sector_size
, 0, LOCK_EX
, &d
);
3592 if (r
< 0 && (arg_offline
== 0 || (r
!= -ENOENT
&& !ERRNO_IS_PRIVILEGE(r
)) || !strv_isempty(p
->subvolumes
)))
3593 return log_error_errno(r
, "Failed to make loopback device of future partition %" PRIu64
": %m", p
->partno
);
3595 t
->loop
= TAKE_PTR(d
);
3600 log_debug_errno(r
, "No access to loop devices, falling back to a regular file");
3603 /* If we can't allocate a loop device, let's write to a regular file that we copy into the final
3604 * image so we can run in containers and without needing root privileges. On filesystems with
3605 * reflinking support, we can take advantage of this and just reflink the result into the image.
3608 r
= prepare_temporary_file(t
, size
);
3617 static int partition_target_grow(PartitionTarget
*t
, uint64_t size
) {
3621 assert(!t
->decrypted
);
3624 r
= loop_device_refresh_size(t
->loop
, UINT64_MAX
, size
);
3626 return log_error_errno(r
, "Failed to refresh loopback device size: %m");
3627 } else if (t
->fd
>= 0) {
3628 if (ftruncate(t
->fd
, size
) < 0)
3629 return log_error_errno(errno
, "Failed to grow '%s' to %s by truncation: %m",
3630 t
->path
, FORMAT_BYTES(size
));
3636 static int partition_target_sync(Context
*context
, Partition
*p
, PartitionTarget
*t
) {
3643 assert_se((whole_fd
= fdisk_get_devfd(context
->fdisk_context
)) >= 0);
3645 if (t
->decrypted
&& fsync(t
->decrypted
->fd
) < 0)
3646 return log_error_errno(errno
, "Failed to sync changes to '%s': %m", t
->decrypted
->volume
);
3649 r
= loop_device_sync(t
->loop
);
3651 return log_error_errno(r
, "Failed to sync loopback device: %m");
3652 } else if (t
->fd
>= 0) {
3655 if (lseek(whole_fd
, p
->offset
, SEEK_SET
) < 0)
3656 return log_error_errno(errno
, "Failed to seek to partition offset: %m");
3658 if (lseek(t
->fd
, 0, SEEK_SET
) < 0)
3659 return log_error_errno(errno
, "Failed to seek to start of temporary file: %m");
3661 if (fstat(t
->fd
, &st
) < 0)
3662 return log_error_errno(errno
, "Failed to stat temporary file: %m");
3664 if (st
.st_size
> (off_t
) p
->new_size
)
3665 return log_error_errno(SYNTHETIC_ERRNO(ENOSPC
),
3666 "Partition %" PRIu64
"'s contents (%s) don't fit in the partition (%s)",
3667 p
->partno
, FORMAT_BYTES(st
.st_size
), FORMAT_BYTES(p
->new_size
));
3669 r
= copy_bytes(t
->fd
, whole_fd
, UINT64_MAX
, COPY_REFLINK
|COPY_HOLES
|COPY_FSYNC
);
3671 return log_error_errno(r
, "Failed to copy bytes to partition: %m");
3673 if (fsync(t
->whole_fd
) < 0)
3674 return log_error_errno(errno
, "Failed to sync changes: %m");
3680 static int partition_encrypt(Context
*context
, Partition
*p
, PartitionTarget
*target
, bool offline
) {
3681 #if HAVE_LIBCRYPTSETUP && HAVE_CRYPT_SET_DATA_OFFSET && HAVE_CRYPT_REENCRYPT_INIT_BY_PASSPHRASE && HAVE_CRYPT_REENCRYPT
3682 const char *node
= partition_target_path(target
);
3683 struct crypt_params_luks2 luks_params
= {
3684 .label
= strempty(ASSERT_PTR(p
)->new_label
),
3685 .sector_size
= ASSERT_PTR(context
)->fs_sector_size
,
3686 .data_device
= offline
? node
: NULL
,
3688 struct crypt_params_reencrypt reencrypt_params
= {
3689 .mode
= CRYPT_REENCRYPT_ENCRYPT
,
3690 .direction
= CRYPT_REENCRYPT_BACKWARD
,
3691 .resilience
= "datashift",
3692 .data_shift
= LUKS2_METADATA_SIZE
/ 512,
3693 .luks2
= &luks_params
,
3694 .flags
= CRYPT_REENCRYPT_INITIALIZE_ONLY
|CRYPT_REENCRYPT_MOVE_FIRST_SEGMENT
,
3696 _cleanup_(sym_crypt_freep
) struct crypt_device
*cd
= NULL
;
3697 _cleanup_(erase_and_freep
) char *base64_encoded
= NULL
;
3698 _cleanup_fclose_
FILE *h
= NULL
;
3699 _cleanup_free_
char *hp
= NULL
, *vol
= NULL
, *dm_name
= NULL
;
3700 const char *passphrase
= NULL
;
3701 size_t passphrase_size
= 0;
3707 assert(p
->encrypt
!= ENCRYPT_OFF
);
3709 r
= dlopen_cryptsetup();
3711 return log_error_errno(r
, "libcryptsetup not found, cannot encrypt: %m");
3713 log_info("Encrypting future partition %" PRIu64
"...", p
->partno
);
3716 r
= var_tmp_dir(&vt
);
3718 return log_error_errno(r
, "Failed to determine temporary files directory: %m");
3720 r
= fopen_temporary_child(vt
, &h
, &hp
);
3722 return log_error_errno(r
, "Failed to create temporary LUKS header file: %m");
3724 /* Weird cryptsetup requirement which requires the header file to be the size of at least one
3726 if (ftruncate(fileno(h
), luks_params
.sector_size
) < 0)
3727 return log_error_errno(errno
, "Failed to grow temporary LUKS header file: %m");
3729 if (asprintf(&dm_name
, "luks-repart-%08" PRIx64
, random_u64()) < 0)
3732 vol
= path_join("/dev/mapper/", dm_name
);
3737 r
= sym_crypt_init(&cd
, offline
? hp
: node
);
3739 return log_error_errno(r
, "Failed to allocate libcryptsetup context for %s: %m", hp
);
3741 cryptsetup_enable_logging(cd
);
3744 /* Disable kernel keyring usage by libcryptsetup as a workaround for
3745 * https://gitlab.com/cryptsetup/cryptsetup/-/merge_requests/273. This makes sure that we can
3746 * do offline encryption even when repart is running in a container. */
3747 r
= sym_crypt_volume_key_keyring(cd
, false);
3749 return log_error_errno(r
, "Failed to disable kernel keyring: %m");
3751 r
= sym_crypt_metadata_locking(cd
, false);
3753 return log_error_errno(r
, "Failed to disable metadata locking: %m");
3755 r
= sym_crypt_set_data_offset(cd
, LUKS2_METADATA_SIZE
/ 512);
3757 return log_error_errno(r
, "Failed to set data offset: %m");
3760 r
= sym_crypt_format(
3765 SD_ID128_TO_UUID_STRING(p
->luks_uuid
),
3770 return log_error_errno(r
, "Failed to LUKS2 format future partition: %m");
3772 if (IN_SET(p
->encrypt
, ENCRYPT_KEY_FILE
, ENCRYPT_KEY_FILE_TPM2
)) {
3773 r
= sym_crypt_keyslot_add_by_volume_key(
3781 return log_error_errno(r
, "Failed to add LUKS2 key: %m");
3783 passphrase
= strempty(arg_key
);
3784 passphrase_size
= arg_key_size
;
3787 if (IN_SET(p
->encrypt
, ENCRYPT_TPM2
, ENCRYPT_KEY_FILE_TPM2
)) {
3789 _cleanup_(iovec_done
) struct iovec pubkey
= {}, blob
= {}, srk
= {};
3790 _cleanup_(iovec_done_erase
) struct iovec secret
= {};
3791 _cleanup_(json_variant_unrefp
) JsonVariant
*v
= NULL
;
3792 ssize_t base64_encoded_size
;
3794 TPM2Flags flags
= 0;
3796 if (arg_tpm2_public_key_pcr_mask
!= 0) {
3797 r
= tpm2_load_pcr_public_key(arg_tpm2_public_key
, &pubkey
.iov_base
, &pubkey
.iov_len
);
3799 if (arg_tpm2_public_key
|| r
!= -ENOENT
)
3800 return log_error_errno(r
, "Failed to read TPM PCR public key: %m");
3802 log_debug_errno(r
, "Failed to read TPM2 PCR public key, proceeding without: %m");
3803 arg_tpm2_public_key_pcr_mask
= 0;
3807 TPM2B_PUBLIC
public;
3808 if (iovec_is_set(&pubkey
)) {
3809 r
= tpm2_tpm2b_public_from_pem(pubkey
.iov_base
, pubkey
.iov_len
, &public);
3811 return log_error_errno(r
, "Could not convert public key to TPM2B_PUBLIC: %m");
3814 _cleanup_(tpm2_pcrlock_policy_done
) Tpm2PCRLockPolicy pcrlock_policy
= {};
3815 if (arg_tpm2_pcrlock
) {
3816 r
= tpm2_pcrlock_policy_load(arg_tpm2_pcrlock
, &pcrlock_policy
);
3820 flags
|= TPM2_FLAGS_USE_PCRLOCK
;
3823 _cleanup_(tpm2_context_unrefp
) Tpm2Context
*tpm2_context
= NULL
;
3824 TPM2B_PUBLIC device_key_public
= {};
3825 if (arg_tpm2_device_key
) {
3826 r
= tpm2_load_public_key_file(arg_tpm2_device_key
, &device_key_public
);
3830 if (!tpm2_pcr_values_has_all_values(arg_tpm2_hash_pcr_values
, arg_tpm2_n_hash_pcr_values
))
3831 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
),
3832 "Must provide all PCR values when using TPM2 device key.");
3834 r
= tpm2_context_new(arg_tpm2_device
, &tpm2_context
);
3836 return log_error_errno(r
, "Failed to create TPM2 context: %m");
3838 if (!tpm2_pcr_values_has_all_values(arg_tpm2_hash_pcr_values
, arg_tpm2_n_hash_pcr_values
)) {
3839 r
= tpm2_pcr_read_missing_values(tpm2_context
, arg_tpm2_hash_pcr_values
, arg_tpm2_n_hash_pcr_values
);
3841 return log_error_errno(r
, "Could not read pcr values: %m");
3845 uint16_t hash_pcr_bank
= 0;
3846 uint32_t hash_pcr_mask
= 0;
3847 if (arg_tpm2_n_hash_pcr_values
> 0) {
3849 r
= tpm2_pcr_values_hash_count(arg_tpm2_hash_pcr_values
, arg_tpm2_n_hash_pcr_values
, &hash_count
);
3851 return log_error_errno(r
, "Could not get hash count: %m");
3854 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
), "Multiple PCR banks selected.");
3856 hash_pcr_bank
= arg_tpm2_hash_pcr_values
[0].hash
;
3857 r
= tpm2_pcr_values_to_mask(arg_tpm2_hash_pcr_values
, arg_tpm2_n_hash_pcr_values
, hash_pcr_bank
, &hash_pcr_mask
);
3859 return log_error_errno(r
, "Could not get hash mask: %m");
3862 TPM2B_DIGEST policy
= TPM2B_DIGEST_MAKE(NULL
, TPM2_SHA256_DIGEST_SIZE
);
3863 r
= tpm2_calculate_sealing_policy(
3864 arg_tpm2_hash_pcr_values
,
3865 arg_tpm2_n_hash_pcr_values
,
3866 iovec_is_set(&pubkey
) ? &public : NULL
,
3867 /* use_pin= */ false,
3868 arg_tpm2_pcrlock
? &pcrlock_policy
: NULL
,
3871 return log_error_errno(r
, "Could not calculate sealing policy digest: %m");
3873 if (arg_tpm2_device_key
)
3874 r
= tpm2_calculate_seal(
3875 arg_tpm2_seal_key_handle
,
3877 /* attributes= */ NULL
,
3885 r
= tpm2_seal(tpm2_context
,
3886 arg_tpm2_seal_key_handle
,
3891 /* ret_primary_alg= */ NULL
,
3894 return log_error_errno(r
, "Failed to seal to TPM2: %m");
3896 base64_encoded_size
= base64mem(secret
.iov_base
, secret
.iov_len
, &base64_encoded
);
3897 if (base64_encoded_size
< 0)
3898 return log_error_errno(base64_encoded_size
, "Failed to base64 encode secret key: %m");
3900 r
= cryptsetup_set_minimal_pbkdf(cd
);
3902 return log_error_errno(r
, "Failed to set minimal PBKDF: %m");
3904 keyslot
= sym_crypt_keyslot_add_by_volume_key(
3907 /* volume_key= */ NULL
,
3908 /* volume_key_size= */ VOLUME_KEY_SIZE
,
3910 base64_encoded_size
);
3912 return log_error_errno(keyslot
, "Failed to add new TPM2 key: %m");
3914 r
= tpm2_make_luks2_json(
3919 arg_tpm2_public_key_pcr_mask
,
3920 /* primary_alg= */ 0,
3922 &IOVEC_MAKE(policy
.buffer
, policy
.size
),
3923 /* salt= */ NULL
, /* no salt because tpm2_seal has no pin */
3928 return log_error_errno(r
, "Failed to prepare TPM2 JSON token object: %m");
3930 r
= cryptsetup_add_token_json(cd
, v
);
3932 return log_error_errno(r
, "Failed to add TPM2 JSON token to LUKS2 header: %m");
3934 passphrase
= base64_encoded
;
3935 passphrase_size
= strlen(base64_encoded
);
3937 return log_error_errno(SYNTHETIC_ERRNO(EOPNOTSUPP
),
3938 "Support for TPM2 enrollment not enabled.");
3943 r
= sym_crypt_reencrypt_init_by_passphrase(
3950 sym_crypt_get_cipher(cd
),
3951 sym_crypt_get_cipher_mode(cd
),
3954 return log_error_errno(r
, "Failed to prepare for reencryption: %m");
3956 /* crypt_reencrypt_init_by_passphrase() doesn't actually put the LUKS header at the front, we
3957 * have to do that ourselves. */
3962 r
= sym_crypt_init(&cd
, node
);
3964 return log_error_errno(r
, "Failed to allocate libcryptsetup context for %s: %m", node
);
3966 r
= sym_crypt_header_restore(cd
, CRYPT_LUKS2
, hp
);
3968 return log_error_errno(r
, "Failed to place new LUKS header at head of %s: %m", node
);
3970 reencrypt_params
.flags
&= ~CRYPT_REENCRYPT_INITIALIZE_ONLY
;
3972 r
= sym_crypt_reencrypt_init_by_passphrase(
3983 return log_error_errno(r
, "Failed to load reencryption context: %m");
3985 r
= sym_crypt_reencrypt(cd
, NULL
);
3987 return log_error_errno(r
, "Failed to encrypt %s: %m", node
);
3989 _cleanup_free_ DecryptedPartitionTarget
*t
= NULL
;
3990 _cleanup_close_
int dev_fd
= -1;
3992 r
= sym_crypt_activate_by_volume_key(
3997 arg_discard
? CRYPT_ACTIVATE_ALLOW_DISCARDS
: 0);
3999 return log_error_errno(r
, "Failed to activate LUKS superblock: %m");
4001 dev_fd
= open(vol
, O_RDWR
|O_CLOEXEC
|O_NOCTTY
);
4003 return log_error_errno(errno
, "Failed to open LUKS volume '%s': %m", vol
);
4005 if (flock(dev_fd
, LOCK_EX
) < 0)
4006 return log_error_errno(errno
, "Failed to lock '%s': %m", vol
);
4008 t
= new(DecryptedPartitionTarget
, 1);
4012 *t
= (DecryptedPartitionTarget
) {
4013 .fd
= TAKE_FD(dev_fd
),
4014 .dm_name
= TAKE_PTR(dm_name
),
4015 .volume
= TAKE_PTR(vol
),
4016 .device
= TAKE_PTR(cd
),
4019 target
->decrypted
= TAKE_PTR(t
);
4022 log_info("Successfully encrypted future partition %" PRIu64
".", p
->partno
);
4026 return log_error_errno(SYNTHETIC_ERRNO(EOPNOTSUPP
),
4027 "libcryptsetup is not supported or is missing required symbols, cannot encrypt: %m");
4031 static int partition_format_verity_hash(
4035 const char *data_node
) {
4037 #if HAVE_LIBCRYPTSETUP
4039 _cleanup_(partition_target_freep
) PartitionTarget
*t
= NULL
;
4040 _cleanup_(sym_crypt_freep
) struct crypt_device
*cd
= NULL
;
4041 _cleanup_free_
char *hint
= NULL
;
4046 assert(p
->verity
== VERITY_HASH
);
4052 if (PARTITION_EXISTS(p
)) /* Never format existing partitions */
4055 /* Minimized partitions will use the copy blocks logic so let's make sure to skip those here. */
4056 if (p
->copy_blocks_fd
>= 0)
4059 assert_se(dp
= p
->siblings
[VERITY_DATA
]);
4060 assert(!dp
->dropped
);
4062 (void) partition_hint(p
, node
, &hint
);
4064 r
= dlopen_cryptsetup();
4066 return log_error_errno(r
, "libcryptsetup not found, cannot setup verity: %m");
4069 r
= partition_target_prepare(context
, p
, p
->new_size
, /*need_path=*/ true, &t
);
4073 node
= partition_target_path(t
);
4076 if (p
->verity_data_block_size
== UINT64_MAX
)
4077 p
->verity_data_block_size
= context
->fs_sector_size
;
4078 if (p
->verity_hash_block_size
== UINT64_MAX
)
4079 p
->verity_hash_block_size
= context
->fs_sector_size
;
4081 r
= sym_crypt_init(&cd
, node
);
4083 return log_error_errno(r
, "Failed to allocate libcryptsetup context for %s: %m", node
);
4085 cryptsetup_enable_logging(cd
);
4087 r
= sym_crypt_format(
4088 cd
, CRYPT_VERITY
, NULL
, NULL
, SD_ID128_TO_UUID_STRING(p
->verity_uuid
), NULL
, 0,
4089 &(struct crypt_params_verity
){
4090 .data_device
= data_node
,
4091 .flags
= CRYPT_VERITY_CREATE_HASH
,
4092 .hash_name
= "sha256",
4094 .data_block_size
= p
->verity_data_block_size
,
4095 .hash_block_size
= p
->verity_hash_block_size
,
4096 .salt_size
= sizeof(p
->verity_salt
),
4097 .salt
= (const char*)p
->verity_salt
,
4100 /* libcryptsetup reports non-descriptive EIO errors for every I/O failure. Luckily, it
4101 * doesn't clobber errno so let's check for ENOSPC so we can report a better error if the
4102 * partition is too small. */
4103 if (r
== -EIO
&& errno
== ENOSPC
)
4104 return log_error_errno(errno
,
4105 "Verity hash data does not fit in partition %s with size %s",
4106 strna(hint
), FORMAT_BYTES(p
->new_size
));
4108 return log_error_errno(r
, "Failed to setup verity hash data of partition %s: %m", strna(hint
));
4112 r
= partition_target_sync(context
, p
, t
);
4117 r
= sym_crypt_get_volume_key_size(cd
);
4119 return log_error_errno(r
, "Failed to determine verity root hash size of partition %s: %m", strna(hint
));
4121 _cleanup_(iovec_done
) struct iovec rh
= {
4122 .iov_base
= malloc(r
),
4128 r
= sym_crypt_volume_key_get(cd
, CRYPT_ANY_SLOT
, (char *) rh
.iov_base
, &rh
.iov_len
, NULL
, 0);
4130 return log_error_errno(r
, "Failed to get verity root hash of partition %s: %m", strna(hint
));
4132 assert(rh
.iov_len
>= sizeof(sd_id128_t
) * 2);
4134 if (!dp
->new_uuid_is_set
) {
4135 memcpy_safe(dp
->new_uuid
.bytes
, rh
.iov_base
, sizeof(sd_id128_t
));
4136 dp
->new_uuid_is_set
= true;
4139 if (!p
->new_uuid_is_set
) {
4140 memcpy_safe(p
->new_uuid
.bytes
, (uint8_t*) rh
.iov_base
+ (rh
.iov_len
- sizeof(sd_id128_t
)), sizeof(sd_id128_t
));
4141 p
->new_uuid_is_set
= true;
4144 p
->roothash
= TAKE_STRUCT(rh
);
4148 return log_error_errno(SYNTHETIC_ERRNO(EOPNOTSUPP
), "libcryptsetup is not supported, cannot setup verity hashes: %m");
4152 static int sign_verity_roothash(
4153 const struct iovec
*roothash
,
4154 struct iovec
*ret_signature
) {
4157 _cleanup_(BIO_freep
) BIO
*rb
= NULL
;
4158 _cleanup_(PKCS7_freep
) PKCS7
*p7
= NULL
;
4159 _cleanup_free_
char *hex
= NULL
;
4160 _cleanup_free_
uint8_t *sig
= NULL
;
4164 assert(iovec_is_set(roothash
));
4165 assert(ret_signature
);
4167 hex
= hexmem(roothash
->iov_base
, roothash
->iov_len
);
4171 rb
= BIO_new_mem_buf(hex
, -1);
4175 p7
= PKCS7_sign(arg_certificate
, arg_private_key
, NULL
, rb
, PKCS7_DETACHED
|PKCS7_NOATTR
|PKCS7_BINARY
);
4177 return log_error_errno(SYNTHETIC_ERRNO(EIO
), "Failed to calculate PKCS7 signature: %s",
4178 ERR_error_string(ERR_get_error(), NULL
));
4180 sigsz
= i2d_PKCS7(p7
, &sig
);
4182 return log_error_errno(SYNTHETIC_ERRNO(EIO
), "Failed to convert PKCS7 signature to DER: %s",
4183 ERR_error_string(ERR_get_error(), NULL
));
4185 *ret_signature
= IOVEC_MAKE(TAKE_PTR(sig
), sigsz
);
4189 return log_error_errno(SYNTHETIC_ERRNO(EOPNOTSUPP
), "OpenSSL is not supported, cannot setup verity signature: %m");
4193 static int partition_format_verity_sig(Context
*context
, Partition
*p
) {
4194 _cleanup_(json_variant_unrefp
) JsonVariant
*v
= NULL
;
4195 _cleanup_(iovec_done
) struct iovec sig
= {};
4196 _cleanup_free_
char *text
= NULL
, *hint
= NULL
;
4198 uint8_t fp
[X509_FINGERPRINT_SIZE
];
4201 assert(p
->verity
== VERITY_SIG
);
4206 if (PARTITION_EXISTS(p
))
4209 (void) partition_hint(p
, context
->node
, &hint
);
4211 assert_se(hp
= p
->siblings
[VERITY_HASH
]);
4212 assert(!hp
->dropped
);
4214 assert(arg_certificate
);
4216 assert_se((whole_fd
= fdisk_get_devfd(context
->fdisk_context
)) >= 0);
4218 r
= sign_verity_roothash(&hp
->roothash
, &sig
);
4222 r
= x509_fingerprint(arg_certificate
, fp
);
4224 return log_error_errno(r
, "Unable to calculate X509 certificate fingerprint: %m");
4228 JSON_BUILD_PAIR("rootHash", JSON_BUILD_HEX(hp
->roothash
.iov_base
, hp
->roothash
.iov_len
)),
4230 "certificateFingerprint",
4231 JSON_BUILD_HEX(fp
, sizeof(fp
))
4233 JSON_BUILD_PAIR("signature", JSON_BUILD_IOVEC_BASE64(&sig
))
4237 return log_error_errno(r
, "Failed to build verity signature JSON object: %m");
4239 r
= json_variant_format(v
, 0, &text
);
4241 return log_error_errno(r
, "Failed to format verity signature JSON object: %m");
4243 if (strlen(text
)+1 > p
->new_size
)
4244 return log_error_errno(SYNTHETIC_ERRNO(E2BIG
), "Verity signature too long for partition: %m");
4246 r
= strgrowpad0(&text
, p
->new_size
);
4248 return log_error_errno(r
, "Failed to pad string to %s", FORMAT_BYTES(p
->new_size
));
4250 if (lseek(whole_fd
, p
->offset
, SEEK_SET
) < 0)
4251 return log_error_errno(errno
, "Failed to seek to partition %s offset: %m", strna(hint
));
4253 r
= loop_write(whole_fd
, text
, p
->new_size
);
4255 return log_error_errno(r
, "Failed to write verity signature to partition %s: %m", strna(hint
));
4257 if (fsync(whole_fd
) < 0)
4258 return log_error_errno(errno
, "Failed to synchronize partition %s: %m", strna(hint
));
4263 static int context_copy_blocks(Context
*context
) {
4268 /* Copy in file systems on the block level */
4270 LIST_FOREACH(partitions
, p
, context
->partitions
) {
4271 _cleanup_(partition_target_freep
) PartitionTarget
*t
= NULL
;
4273 if (p
->copy_blocks_fd
< 0)
4279 if (PARTITION_EXISTS(p
)) /* Never copy over existing partitions */
4282 if (partition_type_defer(&p
->type
))
4285 assert(p
->new_size
!= UINT64_MAX
);
4286 assert(p
->copy_blocks_size
!= UINT64_MAX
);
4287 assert(p
->new_size
>= p
->copy_blocks_size
+ (p
->encrypt
!= ENCRYPT_OFF
? LUKS2_METADATA_KEEP_FREE
: 0));
4289 usec_t start_timestamp
= now(CLOCK_MONOTONIC
);
4291 r
= partition_target_prepare(context
, p
, p
->new_size
,
4292 /*need_path=*/ p
->encrypt
!= ENCRYPT_OFF
|| p
->siblings
[VERITY_HASH
],
4297 if (p
->encrypt
!= ENCRYPT_OFF
&& t
->loop
) {
4298 r
= partition_encrypt(context
, p
, t
, /* offline = */ false);
4303 if (p
->copy_blocks_offset
== UINT64_MAX
)
4304 log_info("Copying in '%s' (%s) on block level into future partition %" PRIu64
".",
4305 p
->copy_blocks_path
, FORMAT_BYTES(p
->copy_blocks_size
), p
->partno
);
4307 log_info("Copying in '%s' @ %" PRIu64
" (%s) on block level into future partition %" PRIu64
".",
4308 p
->copy_blocks_path
, p
->copy_blocks_offset
, FORMAT_BYTES(p
->copy_blocks_size
), p
->partno
);
4310 if (lseek(p
->copy_blocks_fd
, p
->copy_blocks_offset
, SEEK_SET
) < 0)
4311 return log_error_errno(errno
, "Failed to seek to copy blocks offset in %s: %m", p
->copy_blocks_path
);
4314 r
= copy_bytes(p
->copy_blocks_fd
, partition_target_fd(t
), p
->copy_blocks_size
, COPY_REFLINK
);
4316 return log_error_errno(r
, "Failed to copy in data from '%s': %m", p
->copy_blocks_path
);
4318 log_info("Copying in of '%s' on block level completed.", p
->copy_blocks_path
);
4320 if (p
->encrypt
!= ENCRYPT_OFF
&& !t
->loop
) {
4321 r
= partition_encrypt(context
, p
, t
, /* offline = */ true);
4326 r
= partition_target_sync(context
, p
, t
);
4330 usec_t time_spent
= usec_sub_unsigned(now(CLOCK_MONOTONIC
), start_timestamp
);
4331 if (time_spent
> 250 * USEC_PER_MSEC
) /* Show throughput, but not if we spent too little time on it, since it's just noise then */
4332 log_info("Block level copying and synchronization of partition %" PRIu64
" complete in %s (%s/s).",
4333 p
->partno
, FORMAT_TIMESPAN(time_spent
, 0), FORMAT_BYTES((uint64_t) ((double) p
->copy_blocks_size
/ time_spent
* USEC_PER_SEC
)));
4335 log_info("Block level copying and synchronization of partition %" PRIu64
" complete in %s.",
4336 p
->partno
, FORMAT_TIMESPAN(time_spent
, 0));
4338 if (p
->siblings
[VERITY_HASH
] && !partition_type_defer(&p
->siblings
[VERITY_HASH
]->type
)) {
4339 r
= partition_format_verity_hash(context
, p
->siblings
[VERITY_HASH
],
4340 /* node = */ NULL
, partition_target_path(t
));
4345 if (p
->siblings
[VERITY_SIG
] && !partition_type_defer(&p
->siblings
[VERITY_SIG
]->type
)) {
4346 r
= partition_format_verity_sig(context
, p
->siblings
[VERITY_SIG
]);
4355 static int add_exclude_path(const char *path
, Hashmap
**denylist
, DenyType type
) {
4356 _cleanup_free_
struct stat
*st
= NULL
;
4362 st
= new(struct stat
, 1);
4366 r
= chase_and_stat(path
, arg_copy_source
, CHASE_PREFIX_ROOT
, NULL
, st
);
4370 return log_error_errno(r
, "Failed to stat source file '%s/%s': %m", strempty(arg_copy_source
), path
);
4372 r
= hashmap_ensure_put(denylist
, &inode_hash_ops
, st
, INT_TO_PTR(type
));
4383 static int make_copy_files_denylist(
4390 _cleanup_hashmap_free_ Hashmap
*denylist
= NULL
;
4399 /* Always exclude the top level APIVFS and temporary directories since the contents of these
4400 * directories are almost certainly not intended to end up in an image. */
4402 NULSTR_FOREACH(s
, APIVFS_TMP_DIRS_NULSTR
) {
4403 r
= add_exclude_path(s
, &denylist
, DENY_CONTENTS
);
4408 /* Add the user configured excludes. */
4410 STRV_FOREACH(e
, p
->exclude_files_source
) {
4411 r
= add_exclude_path(*e
, &denylist
, endswith(*e
, "/") ? DENY_CONTENTS
: DENY_INODE
);
4416 STRV_FOREACH(e
, p
->exclude_files_target
) {
4417 _cleanup_free_
char *path
= NULL
;
4419 const char *s
= path_startswith(*e
, target
);
4423 path
= path_join(source
, s
);
4427 r
= add_exclude_path(path
, &denylist
, endswith(*e
, "/") ? DENY_CONTENTS
: DENY_INODE
);
4432 /* If we're populating a root partition, we don't want any files to end up under the APIVFS mount
4433 * points. While we already exclude <source>/proc, users could still do something such as
4434 * "CopyFiles=/abc:/". Now, if /abc has a proc subdirectory with files in it, those will end up in
4435 * the top level proc directory in the root partition, which we want to avoid. To deal with these
4436 * cases, whenever we're populating a root partition and the target of CopyFiles= is the root
4437 * directory of the root partition, we exclude all directories under the source that are named after
4438 * APIVFS directories or named after mount points of other partitions that are also going to be part
4441 if (p
->type
.designator
== PARTITION_ROOT
&& empty_or_root(target
)) {
4442 LIST_FOREACH(partitions
, q
, context
->partitions
) {
4443 if (q
->type
.designator
== PARTITION_ROOT
)
4446 const char *sources
= gpt_partition_type_mountpoint_nulstr(q
->type
);
4450 NULSTR_FOREACH(s
, sources
) {
4451 _cleanup_free_
char *path
= NULL
;
4453 /* Exclude only the children of partition mount points so that the nested
4454 * partition mount point itself still ends up in the upper partition. */
4456 path
= path_join(source
, s
);
4460 r
= add_exclude_path(path
, &denylist
, DENY_CONTENTS
);
4466 NULSTR_FOREACH(s
, APIVFS_TMP_DIRS_NULSTR
) {
4467 _cleanup_free_
char *path
= NULL
;
4469 path
= path_join(source
, s
);
4473 r
= add_exclude_path(path
, &denylist
, DENY_CONTENTS
);
4479 *ret
= TAKE_PTR(denylist
);
4483 static int add_subvolume_path(const char *path
, Set
**subvolumes
) {
4484 _cleanup_free_
struct stat
*st
= NULL
;
4490 st
= new(struct stat
, 1);
4494 r
= chase_and_stat(path
, arg_copy_source
, CHASE_PREFIX_ROOT
, NULL
, st
);
4498 return log_error_errno(r
, "Failed to stat source file '%s/%s': %m", strempty(arg_copy_source
), path
);
4500 r
= set_ensure_consume(subvolumes
, &inode_hash_ops
, TAKE_PTR(st
));
4507 static int make_subvolumes_set(
4513 _cleanup_set_free_ Set
*subvolumes
= NULL
;
4521 STRV_FOREACH(subvolume
, p
->subvolumes
) {
4522 _cleanup_free_
char *path
= NULL
;
4524 const char *s
= path_startswith(*subvolume
, target
);
4528 path
= path_join(source
, s
);
4532 r
= add_subvolume_path(path
, &subvolumes
);
4537 *ret
= TAKE_PTR(subvolumes
);
4541 static int do_copy_files(Context
*context
, Partition
*p
, const char *root
) {
4547 /* copy_tree_at() automatically copies the permissions of source directories to target directories if
4548 * it created them. However, the root directory is created by us, so we have to manually take care
4549 * that it is initialized. We use the first source directory targeting "/" as the metadata source for
4550 * the root directory. */
4551 STRV_FOREACH_PAIR(source
, target
, p
->copy_files
) {
4552 _cleanup_close_
int rfd
= -EBADF
, sfd
= -EBADF
;
4554 if (!path_equal(*target
, "/"))
4557 rfd
= open(root
, O_DIRECTORY
|O_CLOEXEC
|O_NOFOLLOW
);
4561 sfd
= chase_and_open(*source
, arg_copy_source
, CHASE_PREFIX_ROOT
, O_PATH
|O_DIRECTORY
|O_CLOEXEC
|O_NOCTTY
, NULL
);
4563 return log_error_errno(sfd
, "Failed to open source file '%s%s': %m", strempty(arg_copy_source
), *source
);
4565 (void) copy_xattr(sfd
, NULL
, rfd
, NULL
, COPY_ALL_XATTRS
);
4566 (void) copy_access(sfd
, rfd
);
4567 (void) copy_times(sfd
, rfd
, 0);
4572 STRV_FOREACH_PAIR(source
, target
, p
->copy_files
) {
4573 _cleanup_hashmap_free_ Hashmap
*denylist
= NULL
;
4574 _cleanup_set_free_ Set
*subvolumes_by_source_inode
= NULL
;
4575 _cleanup_close_
int sfd
= -EBADF
, pfd
= -EBADF
, tfd
= -EBADF
;
4577 r
= make_copy_files_denylist(context
, p
, *source
, *target
, &denylist
);
4581 r
= make_subvolumes_set(context
, p
, *source
, *target
, &subvolumes_by_source_inode
);
4585 sfd
= chase_and_open(*source
, arg_copy_source
, CHASE_PREFIX_ROOT
, O_CLOEXEC
|O_NOCTTY
, NULL
);
4586 if (sfd
== -ENOENT
) {
4587 log_notice_errno(sfd
, "Failed to open source file '%s%s', skipping: %m", strempty(arg_copy_source
), *source
);
4591 return log_error_errno(sfd
, "Failed to open source file '%s%s': %m", strempty(arg_copy_source
), *source
);
4593 r
= fd_verify_regular(sfd
);
4596 return log_error_errno(r
, "Failed to check type of source file '%s': %m", *source
);
4598 /* We are looking at a directory */
4599 tfd
= chase_and_open(*target
, root
, CHASE_PREFIX_ROOT
, O_RDONLY
|O_DIRECTORY
|O_CLOEXEC
, NULL
);
4601 _cleanup_free_
char *dn
= NULL
, *fn
= NULL
;
4604 return log_error_errno(tfd
, "Failed to open target directory '%s': %m", *target
);
4606 r
= path_extract_filename(*target
, &fn
);
4608 return log_error_errno(r
, "Failed to extract filename from '%s': %m", *target
);
4610 r
= path_extract_directory(*target
, &dn
);
4612 return log_error_errno(r
, "Failed to extract directory from '%s': %m", *target
);
4614 r
= mkdir_p_root(root
, dn
, UID_INVALID
, GID_INVALID
, 0755, p
->subvolumes
);
4616 return log_error_errno(r
, "Failed to create parent directory '%s': %m", dn
);
4618 pfd
= chase_and_open(dn
, root
, CHASE_PREFIX_ROOT
, O_RDONLY
|O_DIRECTORY
|O_CLOEXEC
, NULL
);
4620 return log_error_errno(pfd
, "Failed to open parent directory of target: %m");
4625 UID_INVALID
, GID_INVALID
,
4626 COPY_REFLINK
|COPY_HOLES
|COPY_MERGE
|COPY_REPLACE
|COPY_SIGINT
|COPY_HARDLINKS
|COPY_ALL_XATTRS
|COPY_GRACEFUL_WARN
|COPY_TRUNCATE
,
4627 denylist
, subvolumes_by_source_inode
);
4632 UID_INVALID
, GID_INVALID
,
4633 COPY_REFLINK
|COPY_HOLES
|COPY_MERGE
|COPY_REPLACE
|COPY_SIGINT
|COPY_HARDLINKS
|COPY_ALL_XATTRS
|COPY_GRACEFUL_WARN
|COPY_TRUNCATE
,
4634 denylist
, subvolumes_by_source_inode
);
4636 return log_error_errno(r
, "Failed to copy '%s%s' to '%s%s': %m",
4637 strempty(arg_copy_source
), *source
, strempty(root
), *target
);
4639 _cleanup_free_
char *dn
= NULL
, *fn
= NULL
;
4641 /* We are looking at a regular file */
4643 r
= path_extract_filename(*target
, &fn
);
4644 if (r
== -EADDRNOTAVAIL
|| r
== O_DIRECTORY
)
4645 return log_error_errno(SYNTHETIC_ERRNO(EISDIR
),
4646 "Target path '%s' refers to a directory, but source path '%s' refers to regular file, can't copy.", *target
, *source
);
4648 return log_error_errno(r
, "Failed to extract filename from '%s': %m", *target
);
4650 r
= path_extract_directory(*target
, &dn
);
4652 return log_error_errno(r
, "Failed to extract directory from '%s': %m", *target
);
4654 r
= mkdir_p_root(root
, dn
, UID_INVALID
, GID_INVALID
, 0755, p
->subvolumes
);
4656 return log_error_errno(r
, "Failed to create parent directory: %m");
4658 pfd
= chase_and_open(dn
, root
, CHASE_PREFIX_ROOT
, O_RDONLY
|O_DIRECTORY
|O_CLOEXEC
, NULL
);
4660 return log_error_errno(pfd
, "Failed to open parent directory of target: %m");
4662 tfd
= openat(pfd
, fn
, O_CREAT
|O_EXCL
|O_WRONLY
|O_CLOEXEC
, 0700);
4664 return log_error_errno(errno
, "Failed to create target file '%s': %m", *target
);
4666 r
= copy_bytes(sfd
, tfd
, UINT64_MAX
, COPY_REFLINK
|COPY_HOLES
|COPY_SIGINT
|COPY_TRUNCATE
);
4668 return log_error_errno(r
, "Failed to copy '%s' to '%s%s': %m", *source
, strempty(arg_copy_source
), *target
);
4670 (void) copy_xattr(sfd
, NULL
, tfd
, NULL
, COPY_ALL_XATTRS
);
4671 (void) copy_access(sfd
, tfd
);
4672 (void) copy_times(sfd
, tfd
, 0);
4679 static int do_make_directories(Partition
*p
, const char *root
) {
4685 STRV_FOREACH(d
, p
->make_directories
) {
4686 r
= mkdir_p_root(root
, *d
, UID_INVALID
, GID_INVALID
, 0755, p
->subvolumes
);
4688 return log_error_errno(r
, "Failed to create directory '%s' in file system: %m", *d
);
4694 static bool partition_needs_populate(Partition
*p
) {
4696 return !strv_isempty(p
->copy_files
) || !strv_isempty(p
->make_directories
);
4699 static int partition_populate_directory(Context
*context
, Partition
*p
, char **ret
) {
4700 _cleanup_(rm_rf_physical_and_freep
) char *root
= NULL
;
4706 log_info("Populating %s filesystem.", p
->format
);
4708 r
= var_tmp_dir(&vt
);
4710 return log_error_errno(r
, "Could not determine temporary directory: %m");
4712 r
= tempfn_random_child(vt
, "repart", &root
);
4714 return log_error_errno(r
, "Failed to generate temporary directory: %m");
4716 r
= mkdir(root
, 0755);
4718 return log_error_errno(errno
, "Failed to create temporary directory: %m");
4720 r
= do_copy_files(context
, p
, root
);
4724 r
= do_make_directories(p
, root
);
4728 log_info("Successfully populated %s filesystem.", p
->format
);
4730 *ret
= TAKE_PTR(root
);
4734 static int partition_populate_filesystem(Context
*context
, Partition
*p
, const char *node
) {
4740 log_info("Populating %s filesystem.", p
->format
);
4742 /* We copy in a child process, since we have to mount the fs for that, and we don't want that fs to
4743 * appear in the host namespace. Hence we fork a child that has its own file system namespace and
4744 * detached mount propagation. */
4746 r
= safe_fork("(sd-copy)", FORK_DEATHSIG_SIGTERM
|FORK_LOG
|FORK_WAIT
|FORK_NEW_MOUNTNS
|FORK_MOUNTNS_SLAVE
, NULL
);
4750 static const char fs
[] = "/run/systemd/mount-root";
4751 /* This is a child process with its own mount namespace and propagation to host turned off */
4753 r
= mkdir_p(fs
, 0700);
4755 log_error_errno(r
, "Failed to create mount point: %m");
4756 _exit(EXIT_FAILURE
);
4759 if (mount_nofollow_verbose(LOG_ERR
, node
, fs
, p
->format
, MS_NOATIME
|MS_NODEV
|MS_NOEXEC
|MS_NOSUID
, NULL
) < 0)
4760 _exit(EXIT_FAILURE
);
4762 if (do_copy_files(context
, p
, fs
) < 0)
4763 _exit(EXIT_FAILURE
);
4765 if (do_make_directories(p
, fs
) < 0)
4766 _exit(EXIT_FAILURE
);
4768 r
= syncfs_path(AT_FDCWD
, fs
);
4770 log_error_errno(r
, "Failed to synchronize written files: %m");
4771 _exit(EXIT_FAILURE
);
4774 _exit(EXIT_SUCCESS
);
4777 log_info("Successfully populated %s filesystem.", p
->format
);
4781 static int context_mkfs(Context
*context
) {
4786 /* Make a file system */
4788 LIST_FOREACH(partitions
, p
, context
->partitions
) {
4789 _cleanup_(rm_rf_physical_and_freep
) char *root
= NULL
;
4790 _cleanup_(partition_target_freep
) PartitionTarget
*t
= NULL
;
4791 _cleanup_strv_free_
char **extra_mkfs_options
= NULL
;
4796 if (PARTITION_EXISTS(p
)) /* Never format existing partitions */
4802 /* Minimized partitions will use the copy blocks logic so let's make sure to skip those here. */
4803 if (p
->copy_blocks_fd
>= 0)
4806 if (partition_type_defer(&p
->type
))
4809 assert(p
->offset
!= UINT64_MAX
);
4810 assert(p
->new_size
!= UINT64_MAX
);
4811 assert(p
->new_size
>= (p
->encrypt
!= ENCRYPT_OFF
? LUKS2_METADATA_KEEP_FREE
: 0));
4813 /* If we're doing encryption, we make sure we keep free space at the end which is required
4814 * for cryptsetup's offline encryption. */
4815 r
= partition_target_prepare(context
, p
,
4816 p
->new_size
- (p
->encrypt
!= ENCRYPT_OFF
? LUKS2_METADATA_KEEP_FREE
: 0),
4817 /*need_path=*/ true,
4822 if (p
->encrypt
!= ENCRYPT_OFF
&& t
->loop
) {
4823 r
= partition_target_grow(t
, p
->new_size
);
4827 r
= partition_encrypt(context
, p
, t
, /* offline = */ false);
4829 return log_error_errno(r
, "Failed to encrypt device: %m");
4832 log_info("Formatting future partition %" PRIu64
".", p
->partno
);
4834 /* If we're not writing to a loop device or if we're populating a read-only filesystem, we
4835 * have to populate using the filesystem's mkfs's --root (or equivalent) option. To do that,
4836 * we need to set up the final directory tree beforehand. */
4838 if (partition_needs_populate(p
) && (!t
->loop
|| fstype_is_ro(p
->format
))) {
4839 if (!mkfs_supports_root_option(p
->format
))
4840 return log_error_errno(SYNTHETIC_ERRNO(ENODEV
),
4841 "Loop device access is required to populate %s filesystems.",
4844 r
= partition_populate_directory(context
, p
, &root
);
4849 r
= mkfs_options_from_env("REPART", p
->format
, &extra_mkfs_options
);
4851 return log_error_errno(r
,
4852 "Failed to determine mkfs command line options for '%s': %m",
4855 r
= make_filesystem(partition_target_path(t
), p
->format
, strempty(p
->new_label
), root
,
4856 p
->fs_uuid
, arg_discard
, /* quiet = */ false,
4857 context
->fs_sector_size
, extra_mkfs_options
);
4861 /* The mkfs binary we invoked might have removed our temporary file when we're not operating
4862 * on a loop device, so let's make sure we open the file again to make sure our file
4863 * descriptor points to any potential new file. */
4865 if (t
->fd
>= 0 && t
->path
&& !t
->loop
) {
4867 t
->fd
= open(t
->path
, O_RDWR
|O_CLOEXEC
);
4869 return log_error_errno(errno
, "Failed to reopen temporary file: %m");
4872 log_info("Successfully formatted future partition %" PRIu64
".", p
->partno
);
4874 /* If we're writing to a loop device, we can now mount the empty filesystem and populate it. */
4875 if (partition_needs_populate(p
) && !root
) {
4878 r
= partition_populate_filesystem(context
, p
, partition_target_path(t
));
4883 if (p
->encrypt
!= ENCRYPT_OFF
&& !t
->loop
) {
4884 r
= partition_target_grow(t
, p
->new_size
);
4888 r
= partition_encrypt(context
, p
, t
, /* offline = */ true);
4890 return log_error_errno(r
, "Failed to encrypt device: %m");
4893 /* Note that we always sync explicitly here, since mkfs.fat doesn't do that on its own, and
4894 * if we don't sync before detaching a block device the in-flight sectors possibly won't hit
4897 r
= partition_target_sync(context
, p
, t
);
4901 if (p
->siblings
[VERITY_HASH
] && !partition_type_defer(&p
->siblings
[VERITY_HASH
]->type
)) {
4902 r
= partition_format_verity_hash(context
, p
->siblings
[VERITY_HASH
],
4903 /* node = */ NULL
, partition_target_path(t
));
4908 if (p
->siblings
[VERITY_SIG
] && !partition_type_defer(&p
->siblings
[VERITY_SIG
]->type
)) {
4909 r
= partition_format_verity_sig(context
, p
->siblings
[VERITY_SIG
]);
4918 static int parse_x509_certificate(const char *certificate
, size_t certificate_size
, X509
**ret
) {
4920 _cleanup_(X509_freep
) X509
*cert
= NULL
;
4921 _cleanup_(BIO_freep
) BIO
*cb
= NULL
;
4923 assert(certificate
);
4924 assert(certificate_size
> 0);
4927 cb
= BIO_new_mem_buf(certificate
, certificate_size
);
4931 cert
= PEM_read_bio_X509(cb
, NULL
, NULL
, NULL
);
4933 return log_error_errno(SYNTHETIC_ERRNO(EBADMSG
), "Failed to parse X.509 certificate: %s",
4934 ERR_error_string(ERR_get_error(), NULL
));
4937 *ret
= TAKE_PTR(cert
);
4941 return log_error_errno(SYNTHETIC_ERRNO(EOPNOTSUPP
), "OpenSSL is not supported, cannot parse X509 certificate.");
4945 static int parse_private_key(const char *key
, size_t key_size
, EVP_PKEY
**ret
) {
4947 _cleanup_(BIO_freep
) BIO
*kb
= NULL
;
4948 _cleanup_(EVP_PKEY_freep
) EVP_PKEY
*pk
= NULL
;
4951 assert(key_size
> 0);
4954 kb
= BIO_new_mem_buf(key
, key_size
);
4958 pk
= PEM_read_bio_PrivateKey(kb
, NULL
, NULL
, NULL
);
4960 return log_error_errno(SYNTHETIC_ERRNO(EIO
), "Failed to parse PEM private key: %s",
4961 ERR_error_string(ERR_get_error(), NULL
));
4964 *ret
= TAKE_PTR(pk
);
4968 return log_error_errno(SYNTHETIC_ERRNO(EOPNOTSUPP
), "OpenSSL is not supported, cannot parse private key.");
4972 static int partition_acquire_uuid(Context
*context
, Partition
*p
, sd_id128_t
*ret
) {
4974 sd_id128_t type_uuid
;
4976 } _packed_ plaintext
= {};
4978 uint8_t md
[SHA256_DIGEST_SIZE
];
4989 /* Calculate a good UUID for the indicated partition. We want a certain degree of reproducibility,
4990 * hence we won't generate the UUIDs randomly. Instead we use a cryptographic hash (precisely:
4991 * HMAC-SHA256) to derive them from a single seed. The seed is generally the machine ID of the
4992 * installation we are processing, but if random behaviour is desired can be random, too. We use the
4993 * seed value as key for the HMAC (since the machine ID is something we generally don't want to leak)
4994 * and the partition type as plaintext. The partition type is suffixed with a counter (only for the
4995 * second and later partition of the same type) if we have more than one partition of the same
4996 * time. Or in other words:
4999 * SEED := /etc/machine-id
5001 * If first partition instance of type TYPE_UUID:
5002 * PARTITION_UUID := HMAC-SHA256(SEED, TYPE_UUID)
5004 * For all later partition instances of type TYPE_UUID with INSTANCE being the LE64 encoded instance number:
5005 * PARTITION_UUID := HMAC-SHA256(SEED, TYPE_UUID || INSTANCE)
5008 LIST_FOREACH(partitions
, q
, context
->partitions
) {
5012 if (!sd_id128_equal(p
->type
.uuid
, q
->type
.uuid
))
5018 plaintext
.type_uuid
= p
->type
.uuid
;
5019 plaintext
.counter
= htole64(k
);
5021 hmac_sha256(context
->seed
.bytes
, sizeof(context
->seed
.bytes
),
5023 k
== 0 ? sizeof(sd_id128_t
) : sizeof(plaintext
),
5026 /* Take the first half, mark it as v4 UUID */
5027 assert_cc(sizeof(result
.md
) == sizeof(result
.id
) * 2);
5028 result
.id
= id128_make_v4_uuid(result
.id
);
5030 /* Ensure this partition UUID is actually unique, and there's no remaining partition from an earlier run? */
5031 LIST_FOREACH(partitions
, q
, context
->partitions
) {
5035 if (sd_id128_in_set(result
.id
, q
->current_uuid
, q
->new_uuid
)) {
5036 log_warning("Partition UUID calculated from seed for partition %" PRIu64
" already used, reverting to randomized UUID.", p
->partno
);
5038 r
= sd_id128_randomize(&result
.id
);
5040 return log_error_errno(r
, "Failed to generate randomized UUID: %m");
5050 static int partition_acquire_label(Context
*context
, Partition
*p
, char **ret
) {
5051 _cleanup_free_
char *label
= NULL
;
5059 prefix
= gpt_partition_type_uuid_to_string(p
->type
.uuid
);
5064 const char *ll
= label
?: prefix
;
5067 LIST_FOREACH(partitions
, q
, context
->partitions
) {
5071 if (streq_ptr(ll
, q
->current_label
) ||
5072 streq_ptr(ll
, q
->new_label
)) {
5081 label
= mfree(label
);
5082 if (asprintf(&label
, "%s-%u", prefix
, ++k
) < 0)
5087 label
= strdup(prefix
);
5092 *ret
= TAKE_PTR(label
);
5096 static int context_acquire_partition_uuids_and_labels(Context
*context
) {
5101 LIST_FOREACH(partitions
, p
, context
->partitions
) {
5104 /* Never touch foreign partitions */
5105 if (PARTITION_IS_FOREIGN(p
)) {
5106 p
->new_uuid
= p
->current_uuid
;
5108 if (p
->current_label
) {
5109 r
= free_and_strdup_warn(&p
->new_label
, strempty(p
->current_label
));
5117 if (!sd_id128_is_null(p
->current_uuid
))
5118 p
->new_uuid
= uuid
= p
->current_uuid
; /* Never change initialized UUIDs */
5119 else if (p
->new_uuid_is_set
)
5122 /* Not explicitly set by user! */
5123 r
= partition_acquire_uuid(context
, p
, &uuid
);
5127 /* The final verity hash/data UUIDs can only be determined after formatting the
5128 * verity hash partition. However, we still want to use the generated partition UUID
5129 * to derive other UUIDs to keep things unique and reproducible, so we always
5130 * generate a UUID if none is set, but we only use it as the actual partition UUID if
5131 * verity is not configured. */
5132 if (!IN_SET(p
->verity
, VERITY_DATA
, VERITY_HASH
)) {
5134 p
->new_uuid_is_set
= true;
5138 /* Calculate the UUID for the file system as HMAC-SHA256 of the string "file-system-uuid",
5139 * keyed off the partition UUID. */
5140 r
= derive_uuid(uuid
, "file-system-uuid", &p
->fs_uuid
);
5144 if (p
->encrypt
!= ENCRYPT_OFF
) {
5145 r
= derive_uuid(uuid
, "luks-uuid", &p
->luks_uuid
);
5150 /* Derive the verity salt and verity superblock UUID from the seed to keep them reproducible */
5151 if (p
->verity
== VERITY_HASH
) {
5152 derive_salt(context
->seed
, "verity-salt", p
->verity_salt
);
5154 r
= derive_uuid(context
->seed
, "verity-uuid", &p
->verity_uuid
);
5156 return log_error_errno(r
, "Failed to acquire verity uuid: %m");
5159 if (!isempty(p
->current_label
)) {
5160 /* never change initialized labels */
5161 r
= free_and_strdup_warn(&p
->new_label
, p
->current_label
);
5164 } else if (!p
->new_label
) {
5165 /* Not explicitly set by user! */
5167 r
= partition_acquire_label(context
, p
, &p
->new_label
);
5176 static int set_gpt_flags(struct fdisk_partition
*q
, uint64_t flags
) {
5177 _cleanup_free_
char *a
= NULL
;
5179 for (unsigned i
= 0; i
< sizeof(flags
) * 8; i
++) {
5180 uint64_t bit
= UINT64_C(1) << i
;
5181 char buf
[DECIMAL_STR_MAX(unsigned)+1];
5183 if (!FLAGS_SET(flags
, bit
))
5186 xsprintf(buf
, "%u", i
);
5187 if (!strextend_with_separator(&a
, ",", buf
))
5191 return fdisk_partition_set_attrs(q
, a
);
5194 static uint64_t partition_merge_flags(Partition
*p
) {
5201 if (p
->no_auto
>= 0) {
5202 if (gpt_partition_type_knows_no_auto(p
->type
))
5203 SET_FLAG(f
, SD_GPT_FLAG_NO_AUTO
, p
->no_auto
);
5205 char buffer
[SD_ID128_UUID_STRING_MAX
];
5206 log_warning("Configured NoAuto=%s for partition type '%s' that doesn't support it, ignoring.",
5208 gpt_partition_type_uuid_to_string_harder(p
->type
.uuid
, buffer
));
5212 if (p
->read_only
>= 0) {
5213 if (gpt_partition_type_knows_read_only(p
->type
))
5214 SET_FLAG(f
, SD_GPT_FLAG_READ_ONLY
, p
->read_only
);
5216 char buffer
[SD_ID128_UUID_STRING_MAX
];
5217 log_warning("Configured ReadOnly=%s for partition type '%s' that doesn't support it, ignoring.",
5218 yes_no(p
->read_only
),
5219 gpt_partition_type_uuid_to_string_harder(p
->type
.uuid
, buffer
));
5223 if (p
->growfs
>= 0) {
5224 if (gpt_partition_type_knows_growfs(p
->type
))
5225 SET_FLAG(f
, SD_GPT_FLAG_GROWFS
, p
->growfs
);
5227 char buffer
[SD_ID128_UUID_STRING_MAX
];
5228 log_warning("Configured GrowFileSystem=%s for partition type '%s' that doesn't support it, ignoring.",
5230 gpt_partition_type_uuid_to_string_harder(p
->type
.uuid
, buffer
));
5237 static int context_mangle_partitions(Context
*context
) {
5242 LIST_FOREACH(partitions
, p
, context
->partitions
) {
5246 if (partition_type_defer(&p
->type
))
5249 assert(p
->new_size
!= UINT64_MAX
);
5250 assert(p
->offset
!= UINT64_MAX
);
5251 assert(p
->partno
!= UINT64_MAX
);
5253 if (PARTITION_EXISTS(p
)) {
5254 bool changed
= false;
5256 assert(p
->current_partition
);
5258 if (p
->new_size
!= p
->current_size
) {
5259 assert(p
->new_size
>= p
->current_size
);
5260 assert(p
->new_size
% context
->sector_size
== 0);
5262 r
= fdisk_partition_size_explicit(p
->current_partition
, true);
5264 return log_error_errno(r
, "Failed to enable explicit sizing: %m");
5266 r
= fdisk_partition_set_size(p
->current_partition
, p
->new_size
/ context
->sector_size
);
5268 return log_error_errno(r
, "Failed to grow partition: %m");
5270 log_info("Growing existing partition %" PRIu64
".", p
->partno
);
5274 if (!sd_id128_equal(p
->new_uuid
, p
->current_uuid
)) {
5275 r
= fdisk_partition_set_uuid(p
->current_partition
, SD_ID128_TO_UUID_STRING(p
->new_uuid
));
5277 return log_error_errno(r
, "Failed to set partition UUID: %m");
5279 log_info("Initializing UUID of existing partition %" PRIu64
".", p
->partno
);
5283 if (!streq_ptr(p
->new_label
, p
->current_label
)) {
5284 r
= fdisk_partition_set_name(p
->current_partition
, strempty(p
->new_label
));
5286 return log_error_errno(r
, "Failed to set partition label: %m");
5288 log_info("Setting partition label of existing partition %" PRIu64
".", p
->partno
);
5293 assert(!PARTITION_IS_FOREIGN(p
)); /* never touch foreign partitions */
5295 r
= fdisk_set_partition(context
->fdisk_context
, p
->partno
, p
->current_partition
);
5297 return log_error_errno(r
, "Failed to update partition: %m");
5300 _cleanup_(fdisk_unref_partitionp
) struct fdisk_partition
*q
= NULL
;
5301 _cleanup_(fdisk_unref_parttypep
) struct fdisk_parttype
*t
= NULL
;
5303 assert(!p
->new_partition
);
5304 assert(p
->offset
% context
->sector_size
== 0);
5305 assert(p
->new_size
% context
->sector_size
== 0);
5306 assert(p
->new_label
);
5308 t
= fdisk_new_parttype();
5312 r
= fdisk_parttype_set_typestr(t
, SD_ID128_TO_UUID_STRING(p
->type
.uuid
));
5314 return log_error_errno(r
, "Failed to initialize partition type: %m");
5316 q
= fdisk_new_partition();
5320 r
= fdisk_partition_set_type(q
, t
);
5322 return log_error_errno(r
, "Failed to set partition type: %m");
5324 r
= fdisk_partition_size_explicit(q
, true);
5326 return log_error_errno(r
, "Failed to enable explicit sizing: %m");
5328 r
= fdisk_partition_set_start(q
, p
->offset
/ context
->sector_size
);
5330 return log_error_errno(r
, "Failed to position partition: %m");
5332 r
= fdisk_partition_set_size(q
, p
->new_size
/ context
->sector_size
);
5334 return log_error_errno(r
, "Failed to grow partition: %m");
5336 r
= fdisk_partition_set_partno(q
, p
->partno
);
5338 return log_error_errno(r
, "Failed to set partition number: %m");
5340 r
= fdisk_partition_set_uuid(q
, SD_ID128_TO_UUID_STRING(p
->new_uuid
));
5342 return log_error_errno(r
, "Failed to set partition UUID: %m");
5344 r
= fdisk_partition_set_name(q
, strempty(p
->new_label
));
5346 return log_error_errno(r
, "Failed to set partition label: %m");
5348 /* Merge the no auto + read only + growfs setting with the literal flags, and set them for the partition */
5349 r
= set_gpt_flags(q
, partition_merge_flags(p
));
5351 return log_error_errno(r
, "Failed to set GPT partition flags: %m");
5353 log_info("Adding new partition %" PRIu64
" to partition table.", p
->partno
);
5355 r
= fdisk_add_partition(context
->fdisk_context
, q
, NULL
);
5357 return log_error_errno(r
, "Failed to add partition: %m");
5359 assert(!p
->new_partition
);
5360 p
->new_partition
= TAKE_PTR(q
);
5367 static int split_name_printf(Partition
*p
, char **ret
) {
5370 const Specifier table
[] = {
5371 { 't', specifier_string
, GPT_PARTITION_TYPE_UUID_TO_STRING_HARDER(p
->type
.uuid
) },
5372 { 'T', specifier_id128
, &p
->type
.uuid
},
5373 { 'U', specifier_id128
, &p
->new_uuid
},
5374 { 'n', specifier_uint64
, &p
->partno
},
5376 COMMON_SYSTEM_SPECIFIERS
,
5380 return specifier_printf(p
->split_name_format
, NAME_MAX
, table
, arg_root
, p
, ret
);
5383 static int split_node(const char *node
, char **ret_base
, char **ret_ext
) {
5384 _cleanup_free_
char *base
= NULL
, *ext
= NULL
;
5392 r
= path_extract_filename(node
, &base
);
5393 if (r
== O_DIRECTORY
|| r
== -EADDRNOTAVAIL
)
5394 return log_error_errno(r
, "Device node %s cannot be a directory", node
);
5396 return log_error_errno(r
, "Failed to extract filename from %s: %m", node
);
5398 e
= endswith(base
, ".raw");
5407 *ret_base
= TAKE_PTR(base
);
5408 *ret_ext
= TAKE_PTR(ext
);
5413 static int split_name_resolve(Context
*context
) {
5414 _cleanup_free_
char *parent
= NULL
, *base
= NULL
, *ext
= NULL
;
5419 r
= path_extract_directory(context
->node
, &parent
);
5420 if (r
< 0 && r
!= -EDESTADDRREQ
)
5421 return log_error_errno(r
, "Failed to extract directory from %s: %m", context
->node
);
5423 r
= split_node(context
->node
, &base
, &ext
);
5427 LIST_FOREACH(partitions
, p
, context
->partitions
) {
5428 _cleanup_free_
char *resolved
= NULL
;
5433 if (!p
->split_name_format
)
5436 r
= split_name_printf(p
, &resolved
);
5438 return log_error_errno(r
, "Failed to resolve specifiers in %s: %m", p
->split_name_format
);
5441 p
->split_path
= strjoin(parent
, "/", base
, ".", resolved
, ext
);
5443 p
->split_path
= strjoin(base
, ".", resolved
, ext
);
5448 LIST_FOREACH(partitions
, p
, context
->partitions
) {
5452 LIST_FOREACH(partitions
, q
, context
->partitions
) {
5459 if (!streq(p
->split_path
, q
->split_path
))
5462 return log_error_errno(SYNTHETIC_ERRNO(ENOTUNIQ
),
5463 "%s and %s have the same resolved split name \"%s\", refusing",
5464 p
->definition_path
, q
->definition_path
, p
->split_path
);
5471 static int context_split(Context
*context
) {
5479 /* We can't do resolution earlier because the partition UUIDs for verity partitions are only filled
5480 * in after they've been generated. */
5482 r
= split_name_resolve(context
);
5486 LIST_FOREACH(partitions
, p
, context
->partitions
) {
5487 _cleanup_close_
int fdt
= -EBADF
;
5495 if (partition_type_defer(&p
->type
))
5498 fdt
= open(p
->split_path
, O_WRONLY
|O_NOCTTY
|O_CLOEXEC
|O_NOFOLLOW
|O_CREAT
|O_EXCL
, 0666);
5500 return log_error_errno(fdt
, "Failed to open split partition file %s: %m", p
->split_path
);
5503 assert_se((fd
= fdisk_get_devfd(context
->fdisk_context
)) >= 0);
5505 if (lseek(fd
, p
->offset
, SEEK_SET
) < 0)
5506 return log_error_errno(errno
, "Failed to seek to partition offset: %m");
5508 r
= copy_bytes(fd
, fdt
, p
->new_size
, COPY_REFLINK
|COPY_HOLES
|COPY_TRUNCATE
);
5510 return log_error_errno(r
, "Failed to copy to split partition %s: %m", p
->split_path
);
5516 static int context_write_partition_table(Context
*context
) {
5517 _cleanup_(fdisk_unref_tablep
) struct fdisk_table
*original_table
= NULL
;
5522 if (!context
->from_scratch
&& !context_changed(context
)) {
5523 log_info("No changes.");
5528 log_notice("Refusing to repartition, please re-run with --dry-run=no.");
5532 log_info("Applying changes to %s.", context
->node
);
5534 if (context
->from_scratch
&& arg_empty
!= EMPTY_CREATE
) {
5535 /* Erase everything if we operate from scratch, except if the image was just created anyway, and thus is definitely empty. */
5536 r
= context_wipe_range(context
, 0, context
->total
);
5540 log_info("Wiped block device.");
5543 r
= context_discard_range(context
, 0, context
->total
);
5544 if (r
== -EOPNOTSUPP
)
5545 log_info("Storage does not support discard, not discarding entire block device data.");
5547 return log_error_errno(r
, "Failed to discard entire block device: %m");
5549 log_info("Discarded entire block device.");
5553 r
= fdisk_get_partitions(context
->fdisk_context
, &original_table
);
5555 return log_error_errno(r
, "Failed to acquire partition table: %m");
5557 /* Wipe fs signatures and discard sectors where the new partitions are going to be placed and in the
5558 * gaps between partitions, just to be sure. */
5559 r
= context_wipe_and_discard(context
);
5563 r
= context_copy_blocks(context
);
5567 r
= context_mkfs(context
);
5571 r
= context_mangle_partitions(context
);
5575 log_info("Writing new partition table.");
5577 r
= fdisk_write_disklabel(context
->fdisk_context
);
5579 return log_error_errno(r
, "Failed to write partition table: %m");
5581 capable
= blockdev_partscan_enabled(fdisk_get_devfd(context
->fdisk_context
));
5582 if (capable
== -ENOTBLK
)
5583 log_debug("Not telling kernel to reread partition table, since we are not operating on a block device.");
5584 else if (capable
< 0)
5585 return log_error_errno(capable
, "Failed to check if block device supports partition scanning: %m");
5586 else if (capable
> 0) {
5587 log_info("Telling kernel to reread partition table.");
5589 if (context
->from_scratch
)
5590 r
= fdisk_reread_partition_table(context
->fdisk_context
);
5592 r
= fdisk_reread_changes(context
->fdisk_context
, original_table
);
5594 return log_error_errno(r
, "Failed to reread partition table: %m");
5596 log_notice("Not telling kernel to reread partition table, because selected image does not support kernel partition block devices.");
5598 log_info("All done.");
5603 static int context_read_seed(Context
*context
, const char *root
) {
5608 if (!sd_id128_is_null(context
->seed
))
5611 if (!arg_randomize
) {
5612 r
= id128_get_machine(root
, &context
->seed
);
5616 if (!ERRNO_IS_MACHINE_ID_UNSET(r
))
5617 return log_error_errno(r
, "Failed to parse machine ID of image: %m");
5619 log_info("No machine ID set, using randomized partition UUIDs.");
5622 r
= sd_id128_randomize(&context
->seed
);
5624 return log_error_errno(r
, "Failed to generate randomized seed: %m");
5629 static int context_factory_reset(Context
*context
) {
5635 if (arg_factory_reset
<= 0)
5638 if (context
->from_scratch
) /* Nothing to reset if we start from scratch */
5642 log_notice("Refusing to factory reset, please re-run with --dry-run=no.");
5646 log_info("Applying factory reset.");
5648 LIST_FOREACH(partitions
, p
, context
->partitions
) {
5650 if (!p
->factory_reset
|| !PARTITION_EXISTS(p
))
5653 assert(p
->partno
!= UINT64_MAX
);
5655 log_info("Removing partition %" PRIu64
" for factory reset.", p
->partno
);
5657 r
= fdisk_delete_partition(context
->fdisk_context
, p
->partno
);
5659 return log_error_errno(r
, "Failed to remove partition %" PRIu64
": %m", p
->partno
);
5665 log_info("Factory reset requested, but no partitions to delete found.");
5669 r
= fdisk_write_disklabel(context
->fdisk_context
);
5671 return log_error_errno(r
, "Failed to write disk label: %m");
5673 log_info("Successfully deleted %zu partitions.", n
);
5677 static int context_can_factory_reset(Context
*context
) {
5680 LIST_FOREACH(partitions
, p
, context
->partitions
)
5681 if (p
->factory_reset
&& PARTITION_EXISTS(p
))
5687 static int resolve_copy_blocks_auto_candidate(
5688 dev_t partition_devno
,
5689 GptPartitionType partition_type
,
5690 dev_t restrict_devno
,
5691 sd_id128_t
*ret_uuid
) {
5693 _cleanup_(blkid_free_probep
) blkid_probe b
= NULL
;
5694 _cleanup_close_
int fd
= -EBADF
;
5695 _cleanup_free_
char *p
= NULL
;
5696 const char *pttype
, *t
;
5697 sd_id128_t pt_parsed
, u
;
5703 /* Checks if the specified partition has the specified GPT type UUID, and is located on the specified
5704 * 'restrict_devno' device. The type check is particularly relevant if we have Verity volume which is
5705 * backed by two separate partitions: the data and the hash partitions, and we need to find the right
5706 * one of the two. */
5708 r
= block_get_whole_disk(partition_devno
, &whole_devno
);
5710 return log_error_errno(
5712 "Unable to determine containing block device of partition %u:%u: %m",
5713 major(partition_devno
), minor(partition_devno
));
5715 if (restrict_devno
!= (dev_t
) -1 &&
5716 restrict_devno
!= whole_devno
)
5717 return log_error_errno(
5718 SYNTHETIC_ERRNO(EPERM
),
5719 "Partition %u:%u is located outside of block device %u:%u, refusing.",
5720 major(partition_devno
), minor(partition_devno
),
5721 major(restrict_devno
), minor(restrict_devno
));
5723 fd
= r
= device_open_from_devnum(S_IFBLK
, whole_devno
, O_RDONLY
|O_CLOEXEC
|O_NONBLOCK
, &p
);
5725 return log_error_errno(r
, "Failed to open block device " DEVNUM_FORMAT_STR
": %m",
5726 DEVNUM_FORMAT_VAL(whole_devno
));
5728 b
= blkid_new_probe();
5733 r
= blkid_probe_set_device(b
, fd
, 0, 0);
5735 return log_error_errno(errno_or_else(ENOMEM
), "Failed to open block device '%s': %m", p
);
5737 (void) blkid_probe_enable_partitions(b
, 1);
5738 (void) blkid_probe_set_partitions_flags(b
, BLKID_PARTS_ENTRY_DETAILS
);
5741 r
= blkid_do_safeprobe(b
);
5742 if (r
== _BLKID_SAFEPROBE_ERROR
)
5743 return log_error_errno(errno_or_else(EIO
), "Unable to probe for partition table of '%s': %m", p
);
5744 if (IN_SET(r
, _BLKID_SAFEPROBE_AMBIGUOUS
, _BLKID_SAFEPROBE_NOT_FOUND
)) {
5745 log_debug("Didn't find partition table on block device '%s'.", p
);
5749 assert(r
== _BLKID_SAFEPROBE_FOUND
);
5751 (void) blkid_probe_lookup_value(b
, "PTTYPE", &pttype
, NULL
);
5752 if (!streq_ptr(pttype
, "gpt")) {
5753 log_debug("Didn't find a GPT partition table on '%s'.", p
);
5758 pl
= blkid_probe_get_partitions(b
);
5760 return log_error_errno(errno_or_else(EIO
), "Unable read partition table of '%s': %m", p
);
5762 pp
= blkid_partlist_devno_to_partition(pl
, partition_devno
);
5764 log_debug("Partition %u:%u has no matching partition table entry on '%s'.",
5765 major(partition_devno
), minor(partition_devno
), p
);
5769 t
= blkid_partition_get_type_string(pp
);
5771 log_debug("Partition %u:%u has no type on '%s'.",
5772 major(partition_devno
), minor(partition_devno
), p
);
5776 r
= sd_id128_from_string(t
, &pt_parsed
);
5778 log_debug_errno(r
, "Failed to parse partition type \"%s\": %m", t
);
5782 if (!sd_id128_equal(pt_parsed
, partition_type
.uuid
)) {
5783 log_debug("Partition %u:%u has non-matching partition type " SD_ID128_FORMAT_STR
" (needed: " SD_ID128_FORMAT_STR
"), ignoring.",
5784 major(partition_devno
), minor(partition_devno
),
5785 SD_ID128_FORMAT_VAL(pt_parsed
), SD_ID128_FORMAT_VAL(partition_type
.uuid
));
5789 r
= blkid_partition_get_uuid_id128(pp
, &u
);
5791 log_debug_errno(r
, "Partition " DEVNUM_FORMAT_STR
" has no UUID.", DEVNUM_FORMAT_VAL(partition_devno
));
5795 log_debug_errno(r
, "Failed to read partition UUID of " DEVNUM_FORMAT_STR
": %m", DEVNUM_FORMAT_VAL(partition_devno
));
5799 log_debug("Automatically found partition " DEVNUM_FORMAT_STR
" of right type " SD_ID128_FORMAT_STR
".",
5800 DEVNUM_FORMAT_VAL(partition_devno
),
5801 SD_ID128_FORMAT_VAL(pt_parsed
));
5809 static int find_backing_devno(
5814 _cleanup_free_
char *resolved
= NULL
;
5819 r
= chase(path
, root
, CHASE_PREFIX_ROOT
, &resolved
, NULL
);
5823 r
= path_is_mount_point(resolved
, NULL
, 0);
5826 if (r
== 0) /* Not a mount point, then it's not a partition of its own, let's not automatically use it. */
5829 r
= get_block_device(resolved
, ret
);
5832 if (r
== 0) /* Not backed by physical file system, we can't use this */
5838 static int resolve_copy_blocks_auto(
5839 GptPartitionType type
,
5841 dev_t restrict_devno
,
5843 sd_id128_t
*ret_uuid
) {
5845 const char *try1
= NULL
, *try2
= NULL
;
5846 char p
[SYS_BLOCK_PATH_MAX("/slaves")];
5847 _cleanup_closedir_
DIR *d
= NULL
;
5848 sd_id128_t found_uuid
= SD_ID128_NULL
;
5849 dev_t devno
, found
= 0;
5852 /* Enforce some security restrictions: CopyBlocks=auto should not be an avenue to get outside of the
5853 * --root=/--image= confinement. Specifically, refuse CopyBlocks= in combination with --root= at all,
5854 * and restrict block device references in the --image= case to loopback block device we set up.
5856 * restrict_devno contain the dev_t of the loop back device we operate on in case of --image=, and
5857 * thus declares which device (and its partition subdevices) we shall limit access to. If
5858 * restrict_devno is zero no device probing access shall be allowed at all (used for --root=) and if
5859 * it is (dev_t) -1 then free access shall be allowed (if neither switch is used). */
5861 if (restrict_devno
== 0)
5862 return log_error_errno(SYNTHETIC_ERRNO(EPERM
),
5863 "Automatic discovery of backing block devices not permitted in --root= mode, refusing.");
5865 /* Handles CopyBlocks=auto, and finds the right source partition to copy from. We look for matching
5866 * partitions in the host, using the appropriate directory as key and ensuring that the partition
5869 if (type
.designator
== PARTITION_ROOT
)
5871 else if (type
.designator
== PARTITION_USR
)
5873 else if (type
.designator
== PARTITION_ROOT_VERITY
)
5875 else if (type
.designator
== PARTITION_USR_VERITY
)
5877 else if (type
.designator
== PARTITION_ESP
) {
5880 } else if (type
.designator
== PARTITION_XBOOTLDR
)
5883 return log_error_errno(SYNTHETIC_ERRNO(EOPNOTSUPP
),
5884 "Partition type " SD_ID128_FORMAT_STR
" not supported from automatic source block device discovery.",
5885 SD_ID128_FORMAT_VAL(type
.uuid
));
5887 r
= find_backing_devno(try1
, root
, &devno
);
5888 if (r
== -ENOENT
&& try2
)
5889 r
= find_backing_devno(try2
, root
, &devno
);
5891 return log_error_errno(r
, "Failed to resolve automatic CopyBlocks= path for partition type " SD_ID128_FORMAT_STR
", sorry: %m",
5892 SD_ID128_FORMAT_VAL(type
.uuid
));
5894 xsprintf_sys_block_path(p
, "/slaves", devno
);
5900 _cleanup_free_
char *q
= NULL
, *t
= NULL
;
5905 de
= readdir_no_dot(d
);
5908 return log_error_errno(errno
, "Failed to read directory '%s': %m", p
);
5913 if (!IN_SET(de
->d_type
, DT_LNK
, DT_UNKNOWN
))
5916 q
= path_join(p
, de
->d_name
, "/dev");
5920 r
= read_one_line_file(q
, &t
);
5922 return log_error_errno(r
, "Failed to read %s: %m", q
);
5924 r
= parse_devnum(t
, &sl
);
5926 log_debug_errno(r
, "Failed to parse %s, ignoring: %m", q
);
5929 if (major(sl
) == 0) {
5930 log_debug("Device backing %s is special, ignoring.", q
);
5934 r
= resolve_copy_blocks_auto_candidate(sl
, type
, restrict_devno
, &u
);
5938 /* We found a matching one! */
5940 return log_error_errno(SYNTHETIC_ERRNO(ENOTUNIQ
),
5941 "Multiple matching partitions found, refusing.");
5947 } else if (errno
!= ENOENT
)
5948 return log_error_errno(errno
, "Failed open %s: %m", p
);
5950 r
= resolve_copy_blocks_auto_candidate(devno
, type
, restrict_devno
, &found_uuid
);
5958 return log_error_errno(SYNTHETIC_ERRNO(ENXIO
),
5959 "Unable to automatically discover suitable partition to copy blocks from.");
5965 *ret_uuid
= found_uuid
;
5970 static int context_open_copy_block_paths(
5972 dev_t restrict_devno
) {
5978 LIST_FOREACH(partitions
, p
, context
->partitions
) {
5979 _cleanup_close_
int source_fd
= -EBADF
;
5980 _cleanup_free_
char *opened
= NULL
;
5981 sd_id128_t uuid
= SD_ID128_NULL
;
5985 if (p
->copy_blocks_fd
>= 0)
5988 assert(p
->copy_blocks_size
== UINT64_MAX
);
5990 if (PARTITION_EXISTS(p
)) /* Never copy over partitions that already exist! */
5993 if (p
->copy_blocks_path
) {
5995 source_fd
= chase_and_open(p
->copy_blocks_path
, p
->copy_blocks_root
, CHASE_PREFIX_ROOT
, O_RDONLY
|O_CLOEXEC
|O_NONBLOCK
, &opened
);
5997 return log_error_errno(source_fd
, "Failed to open '%s': %m", p
->copy_blocks_path
);
5999 if (fstat(source_fd
, &st
) < 0)
6000 return log_error_errno(errno
, "Failed to stat block copy file '%s': %m", opened
);
6002 if (!S_ISREG(st
.st_mode
) && restrict_devno
!= (dev_t
) -1)
6003 return log_error_errno(SYNTHETIC_ERRNO(EPERM
),
6004 "Copying from block device node is not permitted in --image=/--root= mode, refusing.");
6006 } else if (p
->copy_blocks_auto
) {
6007 dev_t devno
= 0; /* Fake initialization to appease gcc. */
6009 r
= resolve_copy_blocks_auto(p
->type
, p
->copy_blocks_root
, restrict_devno
, &devno
, &uuid
);
6014 source_fd
= r
= device_open_from_devnum(S_IFBLK
, devno
, O_RDONLY
|O_CLOEXEC
|O_NONBLOCK
, &opened
);
6016 return log_error_errno(r
, "Failed to open automatically determined source block copy device " DEVNUM_FORMAT_STR
": %m",
6017 DEVNUM_FORMAT_VAL(devno
));
6019 if (fstat(source_fd
, &st
) < 0)
6020 return log_error_errno(errno
, "Failed to stat block copy file '%s': %m", opened
);
6024 if (S_ISDIR(st
.st_mode
)) {
6025 _cleanup_free_
char *bdev
= NULL
;
6028 /* If the file is a directory, automatically find the backing block device */
6030 if (major(st
.st_dev
) != 0)
6033 /* Special support for btrfs */
6034 r
= btrfs_get_block_device_fd(source_fd
, &devt
);
6036 return btrfs_log_dev_root(LOG_ERR
, r
, opened
);
6038 return log_error_errno(r
, "Unable to determine backing block device of '%s': %m", opened
);
6041 safe_close(source_fd
);
6043 source_fd
= r
= device_open_from_devnum(S_IFBLK
, devt
, O_RDONLY
|O_CLOEXEC
|O_NONBLOCK
, &bdev
);
6045 return log_error_errno(r
, "Failed to open block device backing '%s': %m", opened
);
6047 if (fstat(source_fd
, &st
) < 0)
6048 return log_error_errno(errno
, "Failed to stat block device '%s': %m", bdev
);
6051 if (S_ISREG(st
.st_mode
))
6053 else if (S_ISBLK(st
.st_mode
)) {
6054 r
= blockdev_get_device_size(source_fd
, &size
);
6056 return log_error_errno(r
, "Failed to determine size of block device to copy from: %m");
6058 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
), "Specified path to copy blocks from '%s' is not a regular file, block device or directory, refusing: %m", opened
);
6061 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
), "File to copy bytes from '%s' has zero size, refusing.", opened
);
6062 if (size
% 512 != 0)
6063 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
), "File to copy bytes from '%s' has size that is not multiple of 512, refusing.", opened
);
6065 p
->copy_blocks_fd
= TAKE_FD(source_fd
);
6066 p
->copy_blocks_size
= size
;
6068 free_and_replace(p
->copy_blocks_path
, opened
);
6070 /* When copying from an existing partition copy that partitions UUID if none is configured explicitly */
6071 if (!p
->new_uuid_is_set
&& !sd_id128_is_null(uuid
)) {
6073 p
->new_uuid_is_set
= true;
6080 static int fd_apparent_size(int fd
, uint64_t *ret
) {
6087 initial
= lseek(fd
, 0, SEEK_CUR
);
6089 return log_error_errno(errno
, "Failed to get file offset: %m");
6091 for (off_t off
= 0;;) {
6094 r
= lseek(fd
, off
, SEEK_DATA
);
6095 if (r
< 0 && errno
== ENXIO
)
6096 /* If errno == ENXIO, that means we've reached the final hole of the file and
6097 * that hole isn't followed by more data. */
6100 return log_error_errno(errno
, "Failed to seek data in file from offset %"PRIi64
": %m", off
);
6102 off
= r
; /* Set the offset to the start of the data segment. */
6104 /* After copying a potential hole, find the end of the data segment by looking for
6105 * the next hole. If we get ENXIO, we're at EOF. */
6106 r
= lseek(fd
, off
, SEEK_HOLE
);
6110 return log_error_errno(errno
, "Failed to seek hole in file from offset %"PRIi64
": %m", off
);
6117 if (lseek(fd
, initial
, SEEK_SET
) < 0)
6118 return log_error_errno(errno
, "Failed to reset file offset: %m");
6125 static int context_minimize(Context
*context
) {
6126 const char *vt
= NULL
;
6131 LIST_FOREACH(partitions
, p
, context
->partitions
) {
6132 _cleanup_(rm_rf_physical_and_freep
) char *root
= NULL
;
6133 _cleanup_(unlink_and_freep
) char *temp
= NULL
;
6134 _cleanup_(loop_device_unrefp
) LoopDevice
*d
= NULL
;
6135 _cleanup_strv_free_
char **extra_mkfs_options
= NULL
;
6136 _cleanup_close_
int fd
= -EBADF
;
6137 _cleanup_free_
char *hint
= NULL
;
6145 if (PARTITION_EXISTS(p
)) /* Never format existing partitions */
6151 if (p
->copy_blocks_fd
>= 0)
6154 if (p
->minimize
== MINIMIZE_OFF
)
6157 if (!partition_needs_populate(p
))
6160 assert(!p
->copy_blocks_path
);
6162 (void) partition_hint(p
, context
->node
, &hint
);
6164 log_info("Pre-populating %s filesystem of partition %s twice to calculate minimal partition size",
6165 p
->format
, strna(hint
));
6168 r
= var_tmp_dir(&vt
);
6170 return log_error_errno(r
, "Could not determine temporary directory: %m");
6173 r
= tempfn_random_child(vt
, "repart", &temp
);
6175 return log_error_errno(r
, "Failed to generate temporary file path: %m");
6177 if (fstype_is_ro(p
->format
))
6178 fs_uuid
= p
->fs_uuid
;
6180 fd
= open(temp
, O_CREAT
|O_EXCL
|O_CLOEXEC
|O_RDWR
|O_NOCTTY
, 0600);
6182 return log_error_errno(errno
, "Failed to open temporary file %s: %m", temp
);
6184 /* This may seem huge but it will be created sparse so it doesn't take up any space
6185 * on disk until written to. */
6186 if (ftruncate(fd
, 1024ULL * 1024ULL * 1024ULL * 1024ULL) < 0)
6187 return log_error_errno(errno
, "Failed to truncate temporary file to %s: %m",
6188 FORMAT_BYTES(1024ULL * 1024ULL * 1024ULL * 1024ULL));
6190 if (arg_offline
<= 0) {
6191 r
= loop_device_make(fd
, O_RDWR
, 0, UINT64_MAX
, context
->sector_size
, 0, LOCK_EX
, &d
);
6192 if (r
< 0 && (arg_offline
== 0 || (r
!= -ENOENT
&& !ERRNO_IS_PRIVILEGE(r
)) || !strv_isempty(p
->subvolumes
)))
6193 return log_error_errno(r
, "Failed to make loopback device of %s: %m", temp
);
6196 /* We're going to populate this filesystem twice so use a random UUID the first time
6197 * to avoid UUID conflicts. */
6198 r
= sd_id128_randomize(&fs_uuid
);
6203 if (!d
|| fstype_is_ro(p
->format
)) {
6204 if (!mkfs_supports_root_option(p
->format
))
6205 return log_error_errno(SYNTHETIC_ERRNO(ENODEV
),
6206 "Loop device access is required to populate %s filesystems",
6209 r
= partition_populate_directory(context
, p
, &root
);
6214 r
= mkfs_options_from_env("REPART", p
->format
, &extra_mkfs_options
);
6216 return log_error_errno(r
,
6217 "Failed to determine mkfs command line options for '%s': %m",
6220 r
= make_filesystem(d
? d
->node
: temp
,
6222 strempty(p
->new_label
),
6225 arg_discard
, /* quiet = */ false,
6226 context
->fs_sector_size
,
6227 extra_mkfs_options
);
6231 /* Read-only filesystems are minimal from the first try because they create and size the
6232 * loopback file for us. */
6233 if (fstype_is_ro(p
->format
)) {
6236 fd
= open(temp
, O_RDONLY
|O_CLOEXEC
|O_NONBLOCK
);
6238 return log_error_errno(errno
, "Failed to open temporary file %s: %m", temp
);
6240 if (fstat(fd
, &st
) < 0)
6241 return log_error_errno(errno
, "Failed to stat temporary file: %m");
6243 log_info("Minimal partition size of %s filesystem of partition %s is %s",
6244 p
->format
, strna(hint
), FORMAT_BYTES(st
.st_size
));
6246 p
->copy_blocks_path
= TAKE_PTR(temp
);
6247 p
->copy_blocks_path_is_our_file
= true;
6248 p
->copy_blocks_fd
= TAKE_FD(fd
);
6249 p
->copy_blocks_size
= st
.st_size
;
6256 r
= partition_populate_filesystem(context
, p
, d
->node
);
6261 /* Other filesystems need to be provided with a pre-sized loopback file and will adapt to
6262 * fully occupy it. Because we gave the filesystem a 1T sparse file, we need to shrink the
6263 * filesystem down to a reasonable size again to fit it in the disk image. While there are
6264 * some filesystems that support shrinking, it doesn't always work properly (e.g. shrinking
6265 * btrfs gives us a 2.0G filesystem regardless of what we put in it). Instead, let's populate
6266 * the filesystem again, but this time, instead of providing the filesystem with a 1T sparse
6267 * loopback file, let's size the loopback file based on the actual data used by the
6268 * filesystem in the sparse file after the first attempt. This should be a good guess of the
6269 * minimal amount of space needed in the filesystem to fit all the required data.
6271 r
= fd_apparent_size(fd
, &fsz
);
6275 /* Massage the size a bit because just going by actual data used in the sparse file isn't
6277 uint64_t heuristic
= streq(p
->format
, "xfs") ? fsz
: fsz
/ 2;
6278 fsz
= round_up_size(fsz
+ heuristic
, context
->grain_size
);
6279 if (minimal_size_by_fs_name(p
->format
) != UINT64_MAX
)
6280 fsz
= MAX(minimal_size_by_fs_name(p
->format
), fsz
);
6282 log_info("Minimal partition size of %s filesystem of partition %s is %s",
6283 p
->format
, strna(hint
), FORMAT_BYTES(fsz
));
6285 d
= loop_device_unref(d
);
6287 /* Erase the previous filesystem first. */
6288 if (ftruncate(fd
, 0) < 0)
6289 return log_error_errno(errno
, "Failed to erase temporary file: %m");
6291 if (ftruncate(fd
, fsz
) < 0)
6292 return log_error_errno(errno
, "Failed to truncate temporary file to %s: %m", FORMAT_BYTES(fsz
));
6294 if (arg_offline
<= 0) {
6295 r
= loop_device_make(fd
, O_RDWR
, 0, UINT64_MAX
, context
->sector_size
, 0, LOCK_EX
, &d
);
6296 if (r
< 0 && (arg_offline
== 0 || (r
!= -ENOENT
&& !ERRNO_IS_PRIVILEGE(r
)) || !strv_isempty(p
->subvolumes
)))
6297 return log_error_errno(r
, "Failed to make loopback device of %s: %m", temp
);
6300 r
= make_filesystem(d
? d
->node
: temp
,
6302 strempty(p
->new_label
),
6306 /* quiet = */ false,
6307 context
->fs_sector_size
,
6308 extra_mkfs_options
);
6315 r
= partition_populate_filesystem(context
, p
, d
->node
);
6320 if (fstat(fd
, &st
) < 0)
6321 return log_error_errno(errno
, "Failed to stat temporary file: %m");
6323 p
->copy_blocks_path
= TAKE_PTR(temp
);
6324 p
->copy_blocks_path_is_our_file
= true;
6325 p
->copy_blocks_fd
= TAKE_FD(fd
);
6326 p
->copy_blocks_size
= st
.st_size
;
6329 /* Now that we've done the data partitions, do the verity hash partitions. We do these in a separate
6330 * step because they might depend on data generated in the previous step. */
6332 LIST_FOREACH(partitions
, p
, context
->partitions
) {
6333 _cleanup_(unlink_and_freep
) char *temp
= NULL
;
6334 _cleanup_free_
char *hint
= NULL
;
6335 _cleanup_close_
int fd
= -EBADF
;
6342 if (PARTITION_EXISTS(p
)) /* Never format existing partitions */
6345 if (p
->minimize
== MINIMIZE_OFF
)
6348 if (p
->verity
!= VERITY_HASH
)
6351 assert_se(dp
= p
->siblings
[VERITY_DATA
]);
6352 assert(!dp
->dropped
);
6353 assert(dp
->copy_blocks_path
);
6355 (void) partition_hint(p
, context
->node
, &hint
);
6357 log_info("Pre-populating verity hash data of partition %s to calculate minimal partition size",
6361 r
= var_tmp_dir(&vt
);
6363 return log_error_errno(r
, "Could not determine temporary directory: %m");
6366 r
= tempfn_random_child(vt
, "repart", &temp
);
6368 return log_error_errno(r
, "Failed to generate temporary file path: %m");
6372 return log_error_errno(r
, "Failed to create temporary file: %m");
6374 r
= partition_format_verity_hash(context
, p
, temp
, dp
->copy_blocks_path
);
6378 fd
= open(temp
, O_RDONLY
|O_CLOEXEC
|O_NONBLOCK
);
6380 return log_error_errno(errno
, "Failed to open temporary file %s: %m", temp
);
6382 if (fstat(fd
, &st
) < 0)
6383 return log_error_errno(errno
, "Failed to stat temporary file: %m");
6385 log_info("Minimal partition size of verity hash partition %s is %s",
6386 strna(hint
), FORMAT_BYTES(st
.st_size
));
6388 p
->copy_blocks_path
= TAKE_PTR(temp
);
6389 p
->copy_blocks_path_is_our_file
= true;
6390 p
->copy_blocks_fd
= TAKE_FD(fd
);
6391 p
->copy_blocks_size
= st
.st_size
;
6397 static int parse_partition_types(const char *p
, GptPartitionType
**partitions
, size_t *n_partitions
) {
6401 assert(n_partitions
);
6404 _cleanup_free_
char *name
= NULL
;
6405 GptPartitionType type
;
6407 r
= extract_first_word(&p
, &name
, ",", EXTRACT_CUNESCAPE
|EXTRACT_DONT_COALESCE_SEPARATORS
);
6411 return log_error_errno(r
, "Failed to extract partition type identifier or GUID: %s", p
);
6413 r
= gpt_partition_type_from_string(name
, &type
);
6415 return log_error_errno(r
, "'%s' is not a valid partition type identifier or GUID", name
);
6417 if (!GREEDY_REALLOC(*partitions
, *n_partitions
+ 1))
6420 (*partitions
)[(*n_partitions
)++] = type
;
6426 static int help(void) {
6427 _cleanup_free_
char *link
= NULL
;
6430 r
= terminal_urlify_man("systemd-repart", "8", &link
);
6434 printf("%s [OPTIONS...] [DEVICE]\n"
6435 "\n%sGrow and add partitions to partition table.%s\n\n"
6436 " -h --help Show this help\n"
6437 " --version Show package version\n"
6438 " --no-pager Do not pipe output into a pager\n"
6439 " --no-legend Do not show the headers and footers\n"
6440 " --dry-run=BOOL Whether to run dry-run operation\n"
6441 " --empty=MODE One of refuse, allow, require, force, create; controls\n"
6442 " how to handle empty disks lacking partition tables\n"
6443 " --discard=BOOL Whether to discard backing blocks for new partitions\n"
6444 " --pretty=BOOL Whether to show pretty summary before doing changes\n"
6445 " --factory-reset=BOOL Whether to remove data partitions before recreating\n"
6447 " --can-factory-reset Test whether factory reset is defined\n"
6448 " --root=PATH Operate relative to root path\n"
6449 " --image=PATH Operate relative to image file\n"
6450 " --image-policy=POLICY\n"
6451 " Specify disk image dissection policy\n"
6452 " --definitions=DIR Find partition definitions in specified directory\n"
6453 " --key-file=PATH Key to use when encrypting partitions\n"
6454 " --private-key=PATH Private key to use when generating verity roothash\n"
6456 " --certificate=PATH PEM certificate to use when generating verity\n"
6457 " roothash signatures\n"
6458 " --tpm2-device=PATH Path to TPM2 device node to use\n"
6459 " --tpm2-device-key=PATH\n"
6460 " Enroll a TPM2 device using its public key\n"
6461 " --tpm2-seal-key-handle=HANDLE\n"
6462 " Specify handle of key to use for sealing\n"
6463 " --tpm2-pcrs=PCR1+PCR2+PCR3+…\n"
6464 " TPM2 PCR indexes to use for TPM2 enrollment\n"
6465 " --tpm2-public-key=PATH\n"
6466 " Enroll signed TPM2 PCR policy against PEM public key\n"
6467 " --tpm2-public-key-pcrs=PCR1+PCR2+PCR3+…\n"
6468 " Enroll signed TPM2 PCR policy for specified TPM2 PCRs\n"
6469 " --tpm2-pcrlock=PATH\n"
6470 " Specify pcrlock policy to lock against\n"
6471 " --seed=UUID 128-bit seed UUID to derive all UUIDs from\n"
6472 " --size=BYTES Grow loopback file to specified size\n"
6473 " --json=pretty|short|off\n"
6474 " Generate JSON output\n"
6475 " --split=BOOL Whether to generate split artifacts\n"
6476 " --include-partitions=PARTITION1,PARTITION2,PARTITION3,…\n"
6477 " Ignore partitions not of the specified types\n"
6478 " --exclude-partitions=PARTITION1,PARTITION2,PARTITION3,…\n"
6479 " Ignore partitions of the specified types\n"
6480 " --defer-partitions=PARTITION1,PARTITION2,PARTITION3,…\n"
6481 " Take partitions of the specified types into account\n"
6482 " but don't populate them yet\n"
6483 " --sector-size=SIZE Set the logical sector size for the image\n"
6484 " --architecture=ARCH Set the generic architecture for the image\n"
6485 " --offline=BOOL Whether to build the image offline\n"
6486 " -s --copy-source=PATH Specify the primary source tree to copy files from\n"
6487 " --copy-from=IMAGE Copy partitions from the given image(s)\n"
6488 " -S --make-ddi=sysext Make a system extension DDI\n"
6489 " -C --make-ddi=confext Make a configuration extension DDI\n"
6490 " -P --make-ddi=portable Make a portable service DDI\n"
6491 "\nSee the %s for details.\n",
6492 program_invocation_short_name
,
6500 static int parse_argv(int argc
, char *argv
[]) {
6503 ARG_VERSION
= 0x100,
6510 ARG_CAN_FACTORY_RESET
,
6523 ARG_TPM2_DEVICE_KEY
,
6524 ARG_TPM2_SEAL_KEY_HANDLE
,
6526 ARG_TPM2_PUBLIC_KEY
,
6527 ARG_TPM2_PUBLIC_KEY_PCRS
,
6530 ARG_INCLUDE_PARTITIONS
,
6531 ARG_EXCLUDE_PARTITIONS
,
6532 ARG_DEFER_PARTITIONS
,
6534 ARG_SKIP_PARTITIONS
,
6541 static const struct option options
[] = {
6542 { "help", no_argument
, NULL
, 'h' },
6543 { "version", no_argument
, NULL
, ARG_VERSION
},
6544 { "no-pager", no_argument
, NULL
, ARG_NO_PAGER
},
6545 { "no-legend", no_argument
, NULL
, ARG_NO_LEGEND
},
6546 { "dry-run", required_argument
, NULL
, ARG_DRY_RUN
},
6547 { "empty", required_argument
, NULL
, ARG_EMPTY
},
6548 { "discard", required_argument
, NULL
, ARG_DISCARD
},
6549 { "factory-reset", required_argument
, NULL
, ARG_FACTORY_RESET
},
6550 { "can-factory-reset", no_argument
, NULL
, ARG_CAN_FACTORY_RESET
},
6551 { "root", required_argument
, NULL
, ARG_ROOT
},
6552 { "image", required_argument
, NULL
, ARG_IMAGE
},
6553 { "image-policy", required_argument
, NULL
, ARG_IMAGE_POLICY
},
6554 { "seed", required_argument
, NULL
, ARG_SEED
},
6555 { "pretty", required_argument
, NULL
, ARG_PRETTY
},
6556 { "definitions", required_argument
, NULL
, ARG_DEFINITIONS
},
6557 { "size", required_argument
, NULL
, ARG_SIZE
},
6558 { "json", required_argument
, NULL
, ARG_JSON
},
6559 { "key-file", required_argument
, NULL
, ARG_KEY_FILE
},
6560 { "private-key", required_argument
, NULL
, ARG_PRIVATE_KEY
},
6561 { "certificate", required_argument
, NULL
, ARG_CERTIFICATE
},
6562 { "tpm2-device", required_argument
, NULL
, ARG_TPM2_DEVICE
},
6563 { "tpm2-device-key", required_argument
, NULL
, ARG_TPM2_DEVICE_KEY
},
6564 { "tpm2-seal-key-handle", required_argument
, NULL
, ARG_TPM2_SEAL_KEY_HANDLE
},
6565 { "tpm2-pcrs", required_argument
, NULL
, ARG_TPM2_PCRS
},
6566 { "tpm2-public-key", required_argument
, NULL
, ARG_TPM2_PUBLIC_KEY
},
6567 { "tpm2-public-key-pcrs", required_argument
, NULL
, ARG_TPM2_PUBLIC_KEY_PCRS
},
6568 { "tpm2-pcrlock", required_argument
, NULL
, ARG_TPM2_PCRLOCK
},
6569 { "split", required_argument
, NULL
, ARG_SPLIT
},
6570 { "include-partitions", required_argument
, NULL
, ARG_INCLUDE_PARTITIONS
},
6571 { "exclude-partitions", required_argument
, NULL
, ARG_EXCLUDE_PARTITIONS
},
6572 { "defer-partitions", required_argument
, NULL
, ARG_DEFER_PARTITIONS
},
6573 { "sector-size", required_argument
, NULL
, ARG_SECTOR_SIZE
},
6574 { "architecture", required_argument
, NULL
, ARG_ARCHITECTURE
},
6575 { "offline", required_argument
, NULL
, ARG_OFFLINE
},
6576 { "copy-from", required_argument
, NULL
, ARG_COPY_FROM
},
6577 { "copy-source", required_argument
, NULL
, 's' },
6578 { "make-ddi", required_argument
, NULL
, ARG_MAKE_DDI
},
6582 bool auto_hash_pcr_values
= true, auto_public_key_pcr_mask
= true, auto_pcrlock
= true;
6588 while ((c
= getopt_long(argc
, argv
, "hs:SCP", options
, NULL
)) >= 0)
6599 arg_pager_flags
|= PAGER_DISABLE
;
6607 r
= parse_boolean_argument("--dry-run=", optarg
, &arg_dry_run
);
6613 if (isempty(optarg
)) {
6614 arg_empty
= EMPTY_UNSET
;
6618 arg_empty
= empty_mode_from_string(optarg
);
6620 return log_error_errno(arg_empty
, "Failed to parse --empty= parameter: %s", optarg
);
6625 r
= parse_boolean_argument("--discard=", optarg
, &arg_discard
);
6630 case ARG_FACTORY_RESET
:
6631 r
= parse_boolean_argument("--factory-reset=", optarg
, NULL
);
6634 arg_factory_reset
= r
;
6637 case ARG_CAN_FACTORY_RESET
:
6638 arg_can_factory_reset
= true;
6642 r
= parse_path_argument(optarg
, /* suppress_root= */ false, &arg_root
);
6648 r
= parse_path_argument(optarg
, /* suppress_root= */ false, &arg_image
);
6653 case ARG_IMAGE_POLICY
:
6654 r
= parse_image_policy_argument(optarg
, &arg_image_policy
);
6660 if (isempty(optarg
)) {
6661 arg_seed
= SD_ID128_NULL
;
6662 arg_randomize
= false;
6663 } else if (streq(optarg
, "random"))
6664 arg_randomize
= true;
6666 r
= sd_id128_from_string(optarg
, &arg_seed
);
6668 return log_error_errno(r
, "Failed to parse seed: %s", optarg
);
6670 arg_randomize
= false;
6676 r
= parse_boolean_argument("--pretty=", optarg
, NULL
);
6682 case ARG_DEFINITIONS
: {
6683 _cleanup_free_
char *path
= NULL
;
6684 r
= parse_path_argument(optarg
, false, &path
);
6687 if (strv_consume(&arg_definitions
, TAKE_PTR(path
)) < 0)
6693 uint64_t parsed
, rounded
;
6695 if (streq(optarg
, "auto")) {
6696 arg_size
= UINT64_MAX
;
6697 arg_size_auto
= true;
6701 r
= parse_size(optarg
, 1024, &parsed
);
6703 return log_error_errno(r
, "Failed to parse --size= parameter: %s", optarg
);
6705 rounded
= round_up_size(parsed
, 4096);
6707 return log_error_errno(SYNTHETIC_ERRNO(ERANGE
), "Specified image size too small, refusing.");
6708 if (rounded
== UINT64_MAX
)
6709 return log_error_errno(SYNTHETIC_ERRNO(ERANGE
), "Specified image size too large, refusing.");
6711 if (rounded
!= parsed
)
6712 log_warning("Specified size is not a multiple of 4096, rounding up automatically. (%" PRIu64
" %s %" PRIu64
")",
6713 parsed
, special_glyph(SPECIAL_GLYPH_ARROW_RIGHT
), rounded
);
6716 arg_size_auto
= false;
6721 r
= parse_json_argument(optarg
, &arg_json_format_flags
);
6727 case ARG_KEY_FILE
: {
6728 _cleanup_(erase_and_freep
) char *k
= NULL
;
6731 r
= read_full_file_full(
6732 AT_FDCWD
, optarg
, UINT64_MAX
, SIZE_MAX
,
6733 READ_FULL_FILE_SECURE
|READ_FULL_FILE_WARN_WORLD_READABLE
|READ_FULL_FILE_CONNECT_SOCKET
,
6737 return log_error_errno(r
, "Failed to read key file '%s': %m", optarg
);
6739 erase_and_free(arg_key
);
6740 arg_key
= TAKE_PTR(k
);
6745 case ARG_PRIVATE_KEY
: {
6746 _cleanup_(erase_and_freep
) char *k
= NULL
;
6749 r
= read_full_file_full(
6750 AT_FDCWD
, optarg
, UINT64_MAX
, SIZE_MAX
,
6751 READ_FULL_FILE_SECURE
|READ_FULL_FILE_WARN_WORLD_READABLE
|READ_FULL_FILE_CONNECT_SOCKET
,
6755 return log_error_errno(r
, "Failed to read key file '%s': %m", optarg
);
6757 EVP_PKEY_free(arg_private_key
);
6758 arg_private_key
= NULL
;
6759 r
= parse_private_key(k
, n
, &arg_private_key
);
6765 case ARG_CERTIFICATE
: {
6766 _cleanup_free_
char *cert
= NULL
;
6769 r
= read_full_file_full(
6770 AT_FDCWD
, optarg
, UINT64_MAX
, SIZE_MAX
,
6771 READ_FULL_FILE_CONNECT_SOCKET
,
6775 return log_error_errno(r
, "Failed to read certificate file '%s': %m", optarg
);
6777 X509_free(arg_certificate
);
6778 arg_certificate
= NULL
;
6779 r
= parse_x509_certificate(cert
, n
, &arg_certificate
);
6785 case ARG_TPM2_DEVICE
: {
6786 _cleanup_free_
char *device
= NULL
;
6788 if (streq(optarg
, "list"))
6789 return tpm2_list_devices();
6791 if (!streq(optarg
, "auto")) {
6792 device
= strdup(optarg
);
6797 free(arg_tpm2_device
);
6798 arg_tpm2_device
= TAKE_PTR(device
);
6802 case ARG_TPM2_DEVICE_KEY
:
6803 r
= parse_path_argument(optarg
, /* suppress_root= */ false, &arg_tpm2_device_key
);
6809 case ARG_TPM2_SEAL_KEY_HANDLE
:
6810 r
= safe_atou32_full(optarg
, 16, &arg_tpm2_seal_key_handle
);
6812 return log_error_errno(r
, "Could not parse TPM2 seal key handle index '%s': %m", optarg
);
6817 auto_hash_pcr_values
= false;
6818 r
= tpm2_parse_pcr_argument_append(optarg
, &arg_tpm2_hash_pcr_values
, &arg_tpm2_n_hash_pcr_values
);
6824 case ARG_TPM2_PUBLIC_KEY
:
6825 r
= parse_path_argument(optarg
, /* suppress_root= */ false, &arg_tpm2_public_key
);
6831 case ARG_TPM2_PUBLIC_KEY_PCRS
:
6832 auto_public_key_pcr_mask
= false;
6833 r
= tpm2_parse_pcr_argument_to_mask(optarg
, &arg_tpm2_public_key_pcr_mask
);
6839 case ARG_TPM2_PCRLOCK
:
6840 r
= parse_path_argument(optarg
, /* suppress_root= */ false, &arg_tpm2_pcrlock
);
6844 auto_pcrlock
= false;
6848 r
= parse_boolean_argument("--split=", optarg
, NULL
);
6855 case ARG_INCLUDE_PARTITIONS
:
6856 if (arg_filter_partitions_type
== FILTER_PARTITIONS_EXCLUDE
)
6857 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
),
6858 "Combination of --include-partitions= and --exclude-partitions= is invalid.");
6860 r
= parse_partition_types(optarg
, &arg_filter_partitions
, &arg_n_filter_partitions
);
6864 arg_filter_partitions_type
= FILTER_PARTITIONS_INCLUDE
;
6868 case ARG_EXCLUDE_PARTITIONS
:
6869 if (arg_filter_partitions_type
== FILTER_PARTITIONS_INCLUDE
)
6870 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
),
6871 "Combination of --include-partitions= and --exclude-partitions= is invalid.");
6873 r
= parse_partition_types(optarg
, &arg_filter_partitions
, &arg_n_filter_partitions
);
6877 arg_filter_partitions_type
= FILTER_PARTITIONS_EXCLUDE
;
6881 case ARG_DEFER_PARTITIONS
:
6882 r
= parse_partition_types(optarg
, &arg_defer_partitions
, &arg_n_defer_partitions
);
6888 case ARG_SECTOR_SIZE
:
6889 r
= parse_sector_size(optarg
, &arg_sector_size
);
6895 case ARG_ARCHITECTURE
:
6896 r
= architecture_from_string(optarg
);
6898 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
), "Invalid architecture '%s'", optarg
);
6900 arg_architecture
= r
;
6904 if (streq(optarg
, "auto"))
6907 r
= parse_boolean_argument("--offline=", optarg
, NULL
);
6916 case ARG_COPY_FROM
: {
6917 _cleanup_free_
char *p
= NULL
;
6919 r
= parse_path_argument(optarg
, /* suppress_root= */ false, &p
);
6923 if (strv_consume(&arg_copy_from
, TAKE_PTR(p
)) < 0)
6930 r
= parse_path_argument(optarg
, /* suppress_root= */ false, &arg_copy_source
);
6936 if (!filename_is_valid(optarg
))
6937 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
), "Invalid DDI type: %s", optarg
);
6939 r
= free_and_strdup_warn(&arg_make_ddi
, optarg
);
6945 r
= free_and_strdup_warn(&arg_make_ddi
, "sysext");
6951 r
= free_and_strdup_warn(&arg_make_ddi
, "confext");
6957 r
= free_and_strdup_warn(&arg_make_ddi
, "portable");
6966 assert_not_reached();
6969 if (argc
- optind
> 1)
6970 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
),
6971 "Expected at most one argument, the path to the block device or image file.");
6974 if (arg_definitions
)
6975 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
), "Combination of --make-ddi= and --definitions= is not supported.");
6976 if (!IN_SET(arg_empty
, EMPTY_UNSET
, EMPTY_CREATE
))
6977 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
), "Combination of --make-ddi= and --empty=%s is not supported.", empty_mode_to_string(arg_empty
));
6979 /* Imply automatic sizing in DDI mode */
6980 if (arg_size
== UINT64_MAX
)
6981 arg_size_auto
= true;
6983 if (!arg_copy_source
)
6984 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
), "No --copy-source= specified, refusing.");
6986 r
= dir_is_empty(arg_copy_source
, /* ignore_hidden_or_backup= */ false);
6988 return log_error_errno(r
, "Failed to determine if '%s' is empty: %m", arg_copy_source
);
6990 return log_error_errno(SYNTHETIC_ERRNO(ENOENT
), "Source directory '%s' is empty, refusing to create empty image.", arg_copy_source
);
6992 if (sd_id128_is_null(arg_seed
) && !arg_randomize
) {
6993 /* We don't want that /etc/machine-id leaks into any image built this way, hence
6994 * let's randomize the seed if not specified explicitly */
6995 log_notice("No seed value specified, randomizing generated UUIDs, resulting image will not be reproducible.");
6996 arg_randomize
= true;
6999 arg_empty
= EMPTY_CREATE
;
7002 if (arg_empty
== EMPTY_UNSET
) /* default to refuse mode, if not otherwise specified */
7003 arg_empty
= EMPTY_REFUSE
;
7005 if (arg_factory_reset
> 0 && IN_SET(arg_empty
, EMPTY_FORCE
, EMPTY_REQUIRE
, EMPTY_CREATE
))
7006 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
),
7007 "Combination of --factory-reset=yes and --empty=force/--empty=require/--empty=create is invalid.");
7009 if (arg_can_factory_reset
)
7010 arg_dry_run
= true; /* When --can-factory-reset is specified we don't make changes, hence
7011 * non-dry-run mode makes no sense. Thus, imply dry run mode so that we
7012 * open things strictly read-only. */
7013 else if (arg_empty
== EMPTY_CREATE
)
7014 arg_dry_run
= false; /* Imply --dry-run=no if we create the loopback file anew. After all we
7015 * cannot really break anyone's partition tables that way. */
7017 /* Disable pager once we are not just reviewing, but doing things. */
7019 arg_pager_flags
|= PAGER_DISABLE
;
7021 if (arg_empty
== EMPTY_CREATE
&& arg_size
== UINT64_MAX
&& !arg_size_auto
)
7022 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
),
7023 "If --empty=create is specified, --size= must be specified, too.");
7025 if (arg_image
&& arg_root
)
7026 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
), "Please specify either --root= or --image=, the combination of both is not supported.");
7027 else if (!arg_image
&& !arg_root
&& in_initrd()) {
7029 /* By default operate on /sysusr/ or /sysroot/ when invoked in the initrd. We prefer the
7030 * former, if it is mounted, so that we have deterministic behaviour on systems where /usr/
7031 * is vendor-supplied but the root fs formatted on first boot. */
7032 r
= path_is_mount_point("/sysusr/usr", NULL
, 0);
7034 if (r
< 0 && r
!= -ENOENT
)
7035 log_debug_errno(r
, "Unable to determine whether /sysusr/usr is a mount point, assuming it is not: %m");
7037 arg_root
= strdup("/sysroot");
7039 arg_root
= strdup("/sysusr");
7044 if (argc
> optind
) {
7045 arg_node
= strdup(argv
[optind
]);
7050 if (IN_SET(arg_empty
, EMPTY_FORCE
, EMPTY_REQUIRE
, EMPTY_CREATE
) && !arg_node
&& !arg_image
)
7051 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
),
7052 "A path to a device node or image file must be specified when --make-ddi=, --empty=force, --empty=require or --empty=create are used.");
7054 if (arg_split
&& !arg_node
)
7055 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
),
7056 "A path to an image file must be specified when --split is used.");
7059 assert(!arg_tpm2_pcrlock
);
7061 r
= tpm2_pcrlock_search_file(NULL
, NULL
, &arg_tpm2_pcrlock
);
7064 log_warning_errno(r
, "Search for pcrlock.json failed, assuming it does not exist: %m");
7066 log_debug("Automatically using pcrlock policy '%s'.", arg_tpm2_pcrlock
);
7069 if (auto_public_key_pcr_mask
) {
7070 assert(arg_tpm2_public_key_pcr_mask
== 0);
7071 arg_tpm2_public_key_pcr_mask
= INDEX_TO_MASK(uint32_t, TPM2_PCR_KERNEL_BOOT
);
7074 if (auto_hash_pcr_values
&& !arg_tpm2_pcrlock
) { /* Only lock to PCR 7 if no pcr policy is specified. */
7075 assert(arg_tpm2_n_hash_pcr_values
== 0);
7077 if (!GREEDY_REALLOC_APPEND(
7078 arg_tpm2_hash_pcr_values
,
7079 arg_tpm2_n_hash_pcr_values
,
7080 &TPM2_PCR_VALUE_MAKE(TPM2_PCR_INDEX_DEFAULT
, /* hash= */ 0, /* value= */ {}),
7085 if (arg_pretty
< 0 && isatty(STDOUT_FILENO
))
7088 if (arg_architecture
>= 0) {
7089 FOREACH_ARRAY(p
, arg_filter_partitions
, arg_n_filter_partitions
)
7090 *p
= gpt_partition_type_override_architecture(*p
, arg_architecture
);
7092 FOREACH_ARRAY(p
, arg_defer_partitions
, arg_n_defer_partitions
)
7093 *p
= gpt_partition_type_override_architecture(*p
, arg_architecture
);
7099 static int parse_proc_cmdline_factory_reset(void) {
7103 if (arg_factory_reset
>= 0) /* Never override what is specified on the process command line */
7106 if (!in_initrd()) /* Never honour kernel command line factory reset request outside of the initrd */
7109 r
= proc_cmdline_get_bool("systemd.factory_reset", /* flags = */ 0, &b
);
7111 return log_error_errno(r
, "Failed to parse systemd.factory_reset kernel command line argument: %m");
7113 arg_factory_reset
= b
;
7116 log_notice("Honouring factory reset requested via kernel command line.");
7122 static int parse_efi_variable_factory_reset(void) {
7123 _cleanup_free_
char *value
= NULL
;
7126 if (arg_factory_reset
>= 0) /* Never override what is specified on the process command line */
7129 if (!in_initrd()) /* Never honour EFI variable factory reset request outside of the initrd */
7132 r
= efi_get_variable_string(EFI_SYSTEMD_VARIABLE(FactoryReset
), &value
);
7134 if (r
== -ENOENT
|| ERRNO_IS_NOT_SUPPORTED(r
))
7136 return log_error_errno(r
, "Failed to read EFI variable FactoryReset: %m");
7139 r
= parse_boolean(value
);
7141 return log_error_errno(r
, "Failed to parse EFI variable FactoryReset: %m");
7143 arg_factory_reset
= r
;
7145 log_notice("Factory reset requested via EFI variable FactoryReset.");
7150 static int remove_efi_variable_factory_reset(void) {
7153 r
= efi_set_variable(EFI_SYSTEMD_VARIABLE(FactoryReset
), NULL
, 0);
7155 if (r
== -ENOENT
|| ERRNO_IS_NOT_SUPPORTED(r
))
7157 return log_error_errno(r
, "Failed to remove EFI variable FactoryReset: %m");
7160 log_info("Successfully unset EFI variable FactoryReset.");
7164 static int acquire_root_devno(
7171 _cleanup_free_
char *found_path
= NULL
, *node
= NULL
;
7172 dev_t devno
, fd_devno
= MODE_INVALID
;
7173 _cleanup_close_
int fd
= -EBADF
;
7181 fd
= chase_and_open(p
, root
, CHASE_PREFIX_ROOT
, mode
, &found_path
);
7185 if (fstat(fd
, &st
) < 0)
7188 if (S_ISREG(st
.st_mode
)) {
7189 *ret
= TAKE_PTR(found_path
);
7190 *ret_fd
= TAKE_FD(fd
);
7194 if (S_ISBLK(st
.st_mode
)) {
7195 /* Refuse referencing explicit block devices if a root dir is specified, after all we should
7196 * not be able to leave the image the root path constrains us to. */
7200 fd_devno
= devno
= st
.st_rdev
;
7201 } else if (S_ISDIR(st
.st_mode
)) {
7204 if (major(devno
) == 0) {
7205 r
= btrfs_get_block_device_fd(fd
, &devno
);
7206 if (r
== -ENOTTY
) /* not btrfs */
7214 /* From dm-crypt to backing partition */
7215 r
= block_get_originating(devno
, &devno
);
7217 log_debug_errno(r
, "Device '%s' has no dm-crypt/dm-verity device, no need to look for underlying block device.", p
);
7219 log_debug_errno(r
, "Failed to find underlying block device for '%s', ignoring: %m", p
);
7221 /* From partition to whole disk containing it */
7222 r
= block_get_whole_disk(devno
, &devno
);
7224 log_debug_errno(r
, "Failed to find whole disk block device for '%s', ignoring: %m", p
);
7226 r
= devname_from_devnum(S_IFBLK
, devno
, &node
);
7228 return log_debug_errno(r
, "Failed to determine canonical path for '%s': %m", p
);
7230 /* Only if we still look at the same block device we can reuse the fd. Otherwise return an
7231 * invalidated fd. */
7232 if (fd_devno
!= MODE_INVALID
&& fd_devno
== devno
) {
7233 /* Tell udev not to interfere while we are processing the device */
7234 if (flock(fd
, arg_dry_run
? LOCK_SH
: LOCK_EX
) < 0)
7235 return log_error_errno(errno
, "Failed to lock device '%s': %m", node
);
7237 *ret_fd
= TAKE_FD(fd
);
7241 *ret
= TAKE_PTR(node
);
7245 static int find_root(Context
*context
) {
7246 _cleanup_free_
char *device
= NULL
;
7252 if (arg_empty
== EMPTY_CREATE
) {
7253 _cleanup_close_
int fd
= -EBADF
;
7254 _cleanup_free_
char *s
= NULL
;
7256 s
= strdup(arg_node
);
7260 fd
= open(arg_node
, O_RDONLY
|O_CREAT
|O_EXCL
|O_CLOEXEC
|O_NOFOLLOW
, 0666);
7262 return log_error_errno(errno
, "Failed to create '%s': %m", arg_node
);
7264 context
->node
= TAKE_PTR(s
);
7265 context
->node_is_our_file
= true;
7266 context
->backing_fd
= TAKE_FD(fd
);
7270 /* Note that we don't specify a root argument here: if the user explicitly configured a node
7271 * we'll take it relative to the host, not the image */
7272 r
= acquire_root_devno(arg_node
, NULL
, O_RDONLY
|O_CLOEXEC
, &context
->node
, &context
->backing_fd
);
7274 return btrfs_log_dev_root(LOG_ERR
, r
, arg_node
);
7276 return log_error_errno(r
, "Failed to open file or determine backing device of %s: %m", arg_node
);
7281 assert(IN_SET(arg_empty
, EMPTY_REFUSE
, EMPTY_ALLOW
));
7283 /* If the root mount has been replaced by some form of volatile file system (overlayfs), the
7284 * original root block device node is symlinked in /run/systemd/volatile-root. Let's read that
7286 r
= readlink_malloc("/run/systemd/volatile-root", &device
);
7287 if (r
== -ENOENT
) { /* volatile-root not found */
7288 /* Let's search for the root device. We look for two cases here: first in /, and then in /usr. The
7289 * latter we check for cases where / is a tmpfs and only /usr is an actual persistent block device
7290 * (think: volatile setups) */
7292 FOREACH_STRING(p
, "/", "/usr") {
7294 r
= acquire_root_devno(p
, arg_root
, O_RDONLY
|O_DIRECTORY
|O_CLOEXEC
, &context
->node
,
7295 &context
->backing_fd
);
7298 return btrfs_log_dev_root(LOG_ERR
, r
, p
);
7300 return log_error_errno(r
, "Failed to determine backing device of %s: %m", p
);
7305 return log_error_errno(r
, "Failed to read symlink /run/systemd/volatile-root: %m");
7307 r
= acquire_root_devno(device
, NULL
, O_RDONLY
|O_CLOEXEC
, &context
->node
, &context
->backing_fd
);
7309 return btrfs_log_dev_root(LOG_ERR
, r
, device
);
7311 return log_error_errno(r
, "Failed to open file or determine backing device of %s: %m", device
);
7316 return log_error_errno(SYNTHETIC_ERRNO(ENODEV
), "Failed to discover root block device.");
7319 static int resize_pt(int fd
, uint64_t sector_size
) {
7320 _cleanup_(fdisk_unref_contextp
) struct fdisk_context
*c
= NULL
;
7323 /* After resizing the backing file we need to resize the partition table itself too, so that it takes
7324 * possession of the enlarged backing file. For this it suffices to open the device with libfdisk and
7325 * immediately write it again, with no changes. */
7327 r
= fdisk_new_context_at(fd
, /* path= */ NULL
, /* read_only= */ false, sector_size
, &c
);
7329 return log_error_errno(r
, "Failed to open device '%s': %m", FORMAT_PROC_FD_PATH(fd
));
7331 r
= fdisk_has_label(c
);
7333 return log_error_errno(r
, "Failed to determine whether disk '%s' has a disk label: %m", FORMAT_PROC_FD_PATH(fd
));
7335 log_debug("Not resizing partition table, as there currently is none.");
7339 r
= fdisk_write_disklabel(c
);
7341 return log_error_errno(r
, "Failed to write resized partition table: %m");
7343 log_info("Resized partition table.");
7347 static int resize_backing_fd(
7348 const char *node
, /* The primary way we access the disk image to operate on */
7349 int *fd
, /* An O_RDONLY fd referring to that inode */
7350 const char *backing_file
, /* If the above refers to a loopback device, the backing regular file for that, which we can grow */
7351 LoopDevice
*loop_device
,
7352 uint64_t sector_size
) {
7354 _cleanup_close_
int writable_fd
= -EBADF
;
7355 uint64_t current_size
;
7362 if (arg_size
== UINT64_MAX
) /* Nothing to do */
7366 /* Open the file if we haven't opened it yet. Note that we open it read-only here, just to
7367 * keep a reference to the file we can pass around. */
7368 *fd
= open(node
, O_RDONLY
|O_CLOEXEC
);
7370 return log_error_errno(errno
, "Failed to open '%s' in order to adjust size: %m", node
);
7373 if (fstat(*fd
, &st
) < 0)
7374 return log_error_errno(errno
, "Failed to stat '%s': %m", node
);
7376 if (S_ISBLK(st
.st_mode
)) {
7378 return log_error_errno(SYNTHETIC_ERRNO(EBADF
), "Cannot resize block device '%s'.", node
);
7380 assert(loop_device
);
7382 r
= blockdev_get_device_size(*fd
, ¤t_size
);
7384 return log_error_errno(r
, "Failed to determine size of block device %s: %m", node
);
7386 r
= stat_verify_regular(&st
);
7388 return log_error_errno(r
, "Specified path '%s' is not a regular file or loopback block device, cannot resize: %m", node
);
7390 assert(!backing_file
);
7391 assert(!loop_device
);
7392 current_size
= st
.st_size
;
7395 if (current_size
>= arg_size
) {
7396 log_info("File '%s' already is of requested size or larger, not growing. (%s >= %s)",
7397 node
, FORMAT_BYTES(current_size
), FORMAT_BYTES(arg_size
));
7401 if (S_ISBLK(st
.st_mode
)) {
7402 assert(backing_file
);
7404 /* This is a loopback device. We can't really grow those directly, but we can grow the
7405 * backing file, hence let's do that. */
7407 writable_fd
= open(backing_file
, O_WRONLY
|O_CLOEXEC
|O_NONBLOCK
);
7408 if (writable_fd
< 0)
7409 return log_error_errno(errno
, "Failed to open backing file '%s': %m", backing_file
);
7411 if (fstat(writable_fd
, &st
) < 0)
7412 return log_error_errno(errno
, "Failed to stat() backing file '%s': %m", backing_file
);
7414 r
= stat_verify_regular(&st
);
7416 return log_error_errno(r
, "Backing file '%s' of block device is not a regular file: %m", backing_file
);
7418 if ((uint64_t) st
.st_size
!= current_size
)
7419 return log_error_errno(SYNTHETIC_ERRNO(EINVAL
),
7420 "Size of backing file '%s' of loopback block device '%s' don't match, refusing.",
7421 node
, backing_file
);
7423 assert(S_ISREG(st
.st_mode
));
7424 assert(!backing_file
);
7426 /* The file descriptor is read-only. In order to grow the file we need to have a writable fd. We
7427 * reopen the file for that temporarily. We keep the writable fd only open for this operation though,
7428 * as fdisk can't accept it anyway. */
7430 writable_fd
= fd_reopen(*fd
, O_WRONLY
|O_CLOEXEC
);
7431 if (writable_fd
< 0)
7432 return log_error_errno(writable_fd
, "Failed to reopen backing file '%s' writable: %m", node
);
7436 if (fallocate(writable_fd
, 0, 0, arg_size
) < 0) {
7437 if (!ERRNO_IS_NOT_SUPPORTED(errno
))
7438 return log_error_errno(errno
, "Failed to grow '%s' from %s to %s by allocation: %m",
7439 node
, FORMAT_BYTES(current_size
), FORMAT_BYTES(arg_size
));
7441 /* Fallback to truncation, if fallocate() is not supported. */
7442 log_debug("Backing file system does not support fallocate(), falling back to ftruncate().");
7444 if (current_size
== 0) /* Likely regular file just created by us */
7445 log_info("Allocated %s for '%s'.", FORMAT_BYTES(arg_size
), node
);
7447 log_info("File '%s' grown from %s to %s by allocation.",
7448 node
, FORMAT_BYTES(current_size
), FORMAT_BYTES(arg_size
));
7454 if (ftruncate(writable_fd
, arg_size
) < 0)
7455 return log_error_errno(errno
, "Failed to grow '%s' from %s to %s by truncation: %m",
7456 node
, FORMAT_BYTES(current_size
), FORMAT_BYTES(arg_size
));
7458 if (current_size
== 0) /* Likely regular file just created by us */
7459 log_info("Sized '%s' to %s.", node
, FORMAT_BYTES(arg_size
));
7461 log_info("File '%s' grown from %s to %s by truncation.",
7462 node
, FORMAT_BYTES(current_size
), FORMAT_BYTES(arg_size
));
7465 r
= resize_pt(writable_fd
, sector_size
);
7470 r
= loop_device_refresh_size(loop_device
, UINT64_MAX
, arg_size
);
7472 return log_error_errno(r
, "Failed to update loop device size: %m");
7478 static int determine_auto_size(Context
*c
) {
7483 sum
= round_up_size(GPT_METADATA_SIZE
, 4096);
7485 LIST_FOREACH(partitions
, p
, c
->partitions
) {
7491 m
= partition_min_size_with_padding(c
, p
);
7492 if (m
> UINT64_MAX
- sum
)
7493 return log_error_errno(SYNTHETIC_ERRNO(EOVERFLOW
), "Image would grow too large, refusing.");
7498 if (c
->total
!= UINT64_MAX
)
7499 /* Image already allocated? Then show its size. */
7500 log_info("Automatically determined minimal disk image size as %s, current image size is %s.",
7501 FORMAT_BYTES(sum
), FORMAT_BYTES(c
->total
));
7503 /* If the image is being created right now, then it has no previous size, suppress any comment about it hence. */
7504 log_info("Automatically determined minimal disk image size as %s.",
7511 static int run(int argc
, char *argv
[]) {
7512 _cleanup_(loop_device_unrefp
) LoopDevice
*loop_device
= NULL
;
7513 _cleanup_(umount_and_freep
) char *mounted_dir
= NULL
;
7514 _cleanup_(context_freep
) Context
* context
= NULL
;
7515 bool node_is_our_loop
= false;
7518 log_show_color(true);
7519 log_parse_environment();
7522 r
= parse_argv(argc
, argv
);
7526 r
= parse_proc_cmdline_factory_reset();
7530 r
= parse_efi_variable_factory_reset();
7534 #if HAVE_LIBCRYPTSETUP
7535 cryptsetup_enable_logging(NULL
);
7541 /* Mount this strictly read-only: we shall modify the partition table, not the file
7543 r
= mount_image_privately_interactively(
7546 DISSECT_IMAGE_MOUNT_READ_ONLY
|
7547 (arg_node
? DISSECT_IMAGE_DEVICE_READ_ONLY
: 0) | /* If a different node to make changes to is specified let's open the device in read-only mode) */
7548 DISSECT_IMAGE_GPT_ONLY
|
7549 DISSECT_IMAGE_RELAX_VAR_CHECK
|
7550 DISSECT_IMAGE_USR_NO_ROOT
|
7551 DISSECT_IMAGE_REQUIRE_ROOT
,
7553 /* ret_dir_fd= */ NULL
,
7558 arg_root
= strdup(mounted_dir
);
7563 arg_node
= strdup(loop_device
->node
);
7567 /* Remember that the device we are about to manipulate is actually the one we
7568 * allocated here, and thus to increase its backing file we know what to do */
7569 node_is_our_loop
= true;
7573 if (!arg_copy_source
&& arg_root
) {
7574 /* If no explicit copy source is specified, then use --root=/--image= */
7575 arg_copy_source
= strdup(arg_root
);
7576 if (!arg_copy_source
)
7580 context
= context_new(arg_seed
);
7584 r
= context_copy_from(context
);
7589 _cleanup_free_
char *d
= NULL
, *dp
= NULL
;
7590 assert(!arg_definitions
);
7592 d
= strjoin(arg_make_ddi
, ".repart.d/");
7596 r
= search_and_access(d
, F_OK
, NULL
, CONF_PATHS_USR_STRV("systemd/repart/definitions"), &dp
);
7598 return log_error_errno(r
, "DDI type '%s' is not defined: %m", arg_make_ddi
);
7600 if (strv_consume(&arg_definitions
, TAKE_PTR(dp
)) < 0)
7603 strv_uniq(arg_definitions
);
7605 r
= context_read_definitions(context
);
7609 r
= find_root(context
);
7611 return 76; /* Special return value which means "Root block device not found, so not doing
7612 * anything". This isn't really an error when called at boot. */
7616 if (arg_size
!= UINT64_MAX
) {
7617 r
= resize_backing_fd(
7619 &context
->backing_fd
,
7620 node_is_our_loop
? arg_image
: NULL
,
7621 node_is_our_loop
? loop_device
: NULL
,
7622 context
->sector_size
);
7627 r
= context_load_partition_table(context
);
7628 if (r
== -EHWPOISON
)
7629 return 77; /* Special return value which means "Not GPT, so not doing anything". This isn't
7630 * really an error when called at boot. */
7633 context
->from_scratch
= r
> 0; /* Starting from scratch */
7635 if (arg_can_factory_reset
) {
7636 r
= context_can_factory_reset(context
);
7640 return EXIT_FAILURE
;
7645 r
= context_factory_reset(context
);
7649 /* We actually did a factory reset! */
7650 r
= remove_efi_variable_factory_reset();
7654 /* Reload the reduced partition table */
7655 context_unload_partition_table(context
);
7656 r
= context_load_partition_table(context
);
7661 r
= context_read_seed(context
, arg_root
);
7665 /* Make sure each partition has a unique UUID and unique label */
7666 r
= context_acquire_partition_uuids_and_labels(context
);
7670 /* Open all files to copy blocks from now, since we want to take their size into consideration */
7671 r
= context_open_copy_block_paths(
7673 loop_device
? loop_device
->devno
: /* if --image= is specified, only allow partitions on the loopback device */
7674 arg_root
&& !arg_image
? 0 : /* if --root= is specified, don't accept any block device */
7675 (dev_t
) -1); /* if neither is specified, make no restrictions */
7679 r
= context_minimize(context
);
7683 if (arg_size_auto
) {
7684 r
= determine_auto_size(context
);
7688 /* Flush out everything again, and let's grow the file first, then start fresh */
7689 context_unload_partition_table(context
);
7691 assert(arg_size
!= UINT64_MAX
);
7692 r
= resize_backing_fd(
7694 &context
->backing_fd
,
7695 node_is_our_loop
? arg_image
: NULL
,
7696 node_is_our_loop
? loop_device
: NULL
,
7697 context
->sector_size
);
7701 r
= context_load_partition_table(context
);
7706 /* First try to fit new partitions in, dropping by priority until it fits */
7708 uint64_t largest_free_area
;
7710 if (context_allocate_partitions(context
, &largest_free_area
))
7711 break; /* Success! */
7713 if (!context_drop_or_foreignize_one_priority(context
)) {
7714 r
= log_error_errno(SYNTHETIC_ERRNO(ENOSPC
),
7715 "Can't fit requested partitions into available free space (%s), refusing.",
7716 FORMAT_BYTES(largest_free_area
));
7717 determine_auto_size(context
);
7722 /* Now assign free space according to the weight logic */
7723 r
= context_grow_partitions(context
);
7727 /* Now calculate where each new partition gets placed */
7728 context_place_partitions(context
);
7730 (void) context_dump(context
, /*late=*/ false);
7732 r
= context_write_partition_table(context
);
7736 r
= context_split(context
);
7740 (void) context_dump(context
, /*late=*/ true);
7742 context
->node
= mfree(context
->node
);
7744 LIST_FOREACH(partitions
, p
, context
->partitions
)
7745 p
->split_path
= mfree(p
->split_path
);
7750 DEFINE_MAIN_FUNCTION_WITH_POSITIVE_FAILURE(run
);