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Systemd/src/shared/dissect-image.h

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license: LGPL-2.1+ -> LGPL-2.1-or-later
2020-11-09 05:23:58 +01:00
/* SPDX-License-Identifier: LGPL-2.1-or-later */
util-lib: split out image dissecting code and loopback code from nspawn This adds two new APIs to systemd: - loop-util.h is a simple internal API for allocating, setting up and releasing loopback block devices. - dissect-image.h is an internal API for taking apart disk images and figuring out what the purpose of each partition is. Both APIs are basically refactored versions of similar code in nspawn. This rework should permit us to reuse this in other places than just nspawn in the future. Specifically: to implement RootImage= in the service image, similar to RootDirectory=, but operating on a disk image; to unify the gpt-auto-discovery generator code with the discovery logic in nspawn; to add new API to machined for determining the OS version of a disk image (i.e. not just running containers). This PR does not make any such changes however, it just provides the new reworked API. The reworked code is also slightly more powerful than the nspawn original one. When pointing it to an image or block device with a naked file system (i.e. no partition table) it will simply make it the root device.
2016-12-01 20:25:26 +01:00
#pragma once
#include <stdbool.h>
log: minimize includes in log.h log.h really should only include the bare minimum of other headers, as it is really pulled into pretty much everything else and already in itself one of the most basic pieces of code we have. Let's hence drop inclusion of: 1. sd-id128.h because it's entirely unneeded in current log.h 2. errno.h, dito. 3. sys/signalfd.h which we can replace by a simple struct forward declaration 4. process-util.h which was needed for getpid_cached() which we now hide in a funciton log_emergency_level() instead, which nicely abstracts the details away. 5. sys/socket.h which was needed for struct iovec, but a simple struct forward declaration suffices for that too. Ultimately this actually makes our source tree larger (since users of the functionality above must now include it themselves, log.h won't do that for them), but I think it helps to untangle our web of includes a tiny bit. (Background: I'd like to isolate the generic bits of src/basic/ enough so that we can do a git submodule import into casync for it)
2018-01-11 00:39:12 +01:00
#include "sd-id128.h"
service: add new RootImageOptions feature Allows to specify mount options for RootImage. In case of multi-partition images, the partition number can be prefixed followed by colon. Eg: RootImageOptions=1:ro,dev 2:nosuid nodev In absence of a partition number, 0 is assumed.
2020-06-29 14:19:31 +02:00
#include "list.h"
firstboot: move --image= logic into common code That way we can reuse it in tmpfiles/sysusers/journalctl and so on.
2020-07-28 18:16:19 +02:00
#include "loop-util.h"
util-lib: split out image dissecting code and loopback code from nspawn This adds two new APIs to systemd: - loop-util.h is a simple internal API for allocating, setting up and releasing loopback block devices. - dissect-image.h is an internal API for taking apart disk images and figuring out what the purpose of each partition is. Both APIs are basically refactored versions of similar code in nspawn. This rework should permit us to reuse this in other places than just nspawn in the future. Specifically: to implement RootImage= in the service image, similar to RootDirectory=, but operating on a disk image; to unify the gpt-auto-discovery generator code with the discovery logic in nspawn; to add new API to machined for determining the OS version of a disk image (i.e. not just running containers). This PR does not make any such changes however, it just provides the new reworked API. The reworked code is also slightly more powerful than the nspawn original one. When pointing it to an image or block device with a naked file system (i.e. no partition table) it will simply make it the root device.
2016-12-01 20:25:26 +01:00
#include "macro.h"
typedef struct DissectedImage DissectedImage;
typedef struct DissectedPartition DissectedPartition;
dissect: add support for encrypted images This adds support to the image dissector to deal with encrypted images (only LUKS). Given that we now have a neatly isolated image dissector codebase, let's add a new feature to it: support for automatically dealing with encrypted images. This is then exposed in systemd-dissect and nspawn. It's pretty basic: only support for passphrase-based encryption. In order to ensure that "systemd-dissect --mount" results in mount points whose backing LUKS DM devices are cleaned up automatically we use the DM_DEV_REMOVE ioctl() directly on the device (in DM_DEFERRED_REMOVE mode). libgcryptsetup at the moment doesn't provide a proper API for this. Thankfully, the ioctl() API is pretty easy to use.
2016-12-05 16:26:48 +01:00
typedef struct DecryptedImage DecryptedImage;
service: add new RootImageOptions feature Allows to specify mount options for RootImage. In case of multi-partition images, the partition number can be prefixed followed by colon. Eg: RootImageOptions=1:ro,dev 2:nosuid nodev In absence of a partition number, 0 is assumed.
2020-06-29 14:19:31 +02:00
typedef struct MountOptions MountOptions;
dissect: wrap verity settings in new VeritySettings structure Just some refactoring: let's place the various verity related parameters in a common structure, and pass that around instead of the individual parameters. Also, let's load the PKCS#7 signature data when finding metadata right-away, instead of delaying this until we need it. In all cases we call this there's not much time difference between the metdata finding and the loading, hence this simplifies things and makes sure root hash data and its signature is now always acquired together.
2020-09-15 22:09:08 +02:00
typedef struct VeritySettings VeritySettings;
util-lib: split out image dissecting code and loopback code from nspawn This adds two new APIs to systemd: - loop-util.h is a simple internal API for allocating, setting up and releasing loopback block devices. - dissect-image.h is an internal API for taking apart disk images and figuring out what the purpose of each partition is. Both APIs are basically refactored versions of similar code in nspawn. This rework should permit us to reuse this in other places than just nspawn in the future. Specifically: to implement RootImage= in the service image, similar to RootDirectory=, but operating on a disk image; to unify the gpt-auto-discovery generator code with the discovery logic in nspawn; to add new API to machined for determining the OS version of a disk image (i.e. not just running containers). This PR does not make any such changes however, it just provides the new reworked API. The reworked code is also slightly more powerful than the nspawn original one. When pointing it to an image or block device with a naked file system (i.e. no partition table) it will simply make it the root device.
2016-12-01 20:25:26 +01:00
struct DissectedPartition {
bool found:1;
bool rw:1;
int partno; /* -1 if there was no partition and the images contains a file system directly */
int architecture; /* Intended architecture: either native, secondary or unset (-1). */
dissect: return the GPT partition UUID, too This is useful as we can match up the EFI UUID with the one the firmware supposedly used.
2016-12-15 17:17:43 +01:00
sd_id128_t uuid; /* Partition entry UUID as reported by the GPT */
util-lib: split out image dissecting code and loopback code from nspawn This adds two new APIs to systemd: - loop-util.h is a simple internal API for allocating, setting up and releasing loopback block devices. - dissect-image.h is an internal API for taking apart disk images and figuring out what the purpose of each partition is. Both APIs are basically refactored versions of similar code in nspawn. This rework should permit us to reuse this in other places than just nspawn in the future. Specifically: to implement RootImage= in the service image, similar to RootDirectory=, but operating on a disk image; to unify the gpt-auto-discovery generator code with the discovery logic in nspawn; to add new API to machined for determining the OS version of a disk image (i.e. not just running containers). This PR does not make any such changes however, it just provides the new reworked API. The reworked code is also slightly more powerful than the nspawn original one. When pointing it to an image or block device with a naked file system (i.e. no partition table) it will simply make it the root device.
2016-12-01 20:25:26 +01:00
char *fstype;
char *node;
dissect: add support for encrypted images This adds support to the image dissector to deal with encrypted images (only LUKS). Given that we now have a neatly isolated image dissector codebase, let's add a new feature to it: support for automatically dealing with encrypted images. This is then exposed in systemd-dissect and nspawn. It's pretty basic: only support for passphrase-based encryption. In order to ensure that "systemd-dissect --mount" results in mount points whose backing LUKS DM devices are cleaned up automatically we use the DM_DEV_REMOVE ioctl() directly on the device (in DM_DEFERRED_REMOVE mode). libgcryptsetup at the moment doesn't provide a proper API for this. Thankfully, the ioctl() API is pretty easy to use.
2016-12-05 16:26:48 +01:00
char *decrypted_node;
char *decrypted_fstype;
service: add new RootImageOptions feature Allows to specify mount options for RootImage. In case of multi-partition images, the partition number can be prefixed followed by colon. Eg: RootImageOptions=1:ro,dev 2:nosuid nodev In absence of a partition number, 0 is assumed.
2020-06-29 14:19:31 +02:00
char *mount_options;
util-lib: split out image dissecting code and loopback code from nspawn This adds two new APIs to systemd: - loop-util.h is a simple internal API for allocating, setting up and releasing loopback block devices. - dissect-image.h is an internal API for taking apart disk images and figuring out what the purpose of each partition is. Both APIs are basically refactored versions of similar code in nspawn. This rework should permit us to reuse this in other places than just nspawn in the future. Specifically: to implement RootImage= in the service image, similar to RootDirectory=, but operating on a disk image; to unify the gpt-auto-discovery generator code with the discovery logic in nspawn; to add new API to machined for determining the OS version of a disk image (i.e. not just running containers). This PR does not make any such changes however, it just provides the new reworked API. The reworked code is also slightly more powerful than the nspawn original one. When pointing it to an image or block device with a naked file system (i.e. no partition table) it will simply make it the root device.
2016-12-01 20:25:26 +01:00
};
dissect: introduce PartitionDesignator as real type
2020-09-15 18:02:28 +02:00
typedef enum PartitionDesignator {
util-lib: split out image dissecting code and loopback code from nspawn This adds two new APIs to systemd: - loop-util.h is a simple internal API for allocating, setting up and releasing loopback block devices. - dissect-image.h is an internal API for taking apart disk images and figuring out what the purpose of each partition is. Both APIs are basically refactored versions of similar code in nspawn. This rework should permit us to reuse this in other places than just nspawn in the future. Specifically: to implement RootImage= in the service image, similar to RootDirectory=, but operating on a disk image; to unify the gpt-auto-discovery generator code with the discovery logic in nspawn; to add new API to machined for determining the OS version of a disk image (i.e. not just running containers). This PR does not make any such changes however, it just provides the new reworked API. The reworked code is also slightly more powerful than the nspawn original one. When pointing it to an image or block device with a naked file system (i.e. no partition table) it will simply make it the root device.
2016-12-01 20:25:26 +01:00
PARTITION_ROOT,
PARTITION_ROOT_SECONDARY, /* Secondary architecture */
dissect-image: process /usr/ GPT partition type
2020-08-22 12:21:51 +02:00
PARTITION_USR,
PARTITION_USR_SECONDARY,
util-lib: split out image dissecting code and loopback code from nspawn This adds two new APIs to systemd: - loop-util.h is a simple internal API for allocating, setting up and releasing loopback block devices. - dissect-image.h is an internal API for taking apart disk images and figuring out what the purpose of each partition is. Both APIs are basically refactored versions of similar code in nspawn. This rework should permit us to reuse this in other places than just nspawn in the future. Specifically: to implement RootImage= in the service image, similar to RootDirectory=, but operating on a disk image; to unify the gpt-auto-discovery generator code with the discovery logic in nspawn; to add new API to machined for determining the OS version of a disk image (i.e. not just running containers). This PR does not make any such changes however, it just provides the new reworked API. The reworked code is also slightly more powerful than the nspawn original one. When pointing it to an image or block device with a naked file system (i.e. no partition table) it will simply make it the root device.
2016-12-01 20:25:26 +01:00
PARTITION_HOME,
PARTITION_SRV,
PARTITION_ESP,
dissect: automatically detect boot loader spec $BOOT partition The boot loader spec supports two places to store boot loader configuration: the ESP and a generic replacement for it in case the ESP is not available or not suitable. Let's look for both.
2019-01-23 11:34:31 +01:00
PARTITION_XBOOTLDR,
util-lib: split out image dissecting code and loopback code from nspawn This adds two new APIs to systemd: - loop-util.h is a simple internal API for allocating, setting up and releasing loopback block devices. - dissect-image.h is an internal API for taking apart disk images and figuring out what the purpose of each partition is. Both APIs are basically refactored versions of similar code in nspawn. This rework should permit us to reuse this in other places than just nspawn in the future. Specifically: to implement RootImage= in the service image, similar to RootDirectory=, but operating on a disk image; to unify the gpt-auto-discovery generator code with the discovery logic in nspawn; to add new API to machined for determining the OS version of a disk image (i.e. not just running containers). This PR does not make any such changes however, it just provides the new reworked API. The reworked code is also slightly more powerful than the nspawn original one. When pointing it to an image or block device with a naked file system (i.e. no partition table) it will simply make it the root device.
2016-12-01 20:25:26 +01:00
PARTITION_SWAP,
nspawn/dissect: automatically discover dm-verity verity partitions This adds support for discovering and making use of properly tagged dm-verity data integrity partitions. This extends both systemd-nspawn and systemd-dissect with a new --root-hash= switch that takes the root hash to use for the root partition, and is otherwise fully automatic. Verity partitions are discovered automatically by GPT table type UUIDs, as listed in https://www.freedesktop.org/wiki/Specifications/DiscoverablePartitionsSpec/ (which I updated prior to this change, to include new UUIDs for this purpose. mkosi with https://github.com/systemd/mkosi/pull/39 applied may generate images that carry the necessary integrity data. With that PR and this commit, the following simply lines suffice to boot up an integrity-protected container image: ``` # mkdir test # cd test # mkosi --verity # systemd-nspawn -i ./image.raw -bn ``` Note that mkosi writes the image file to "image.raw" next to a a file "image.roothash" that contains the root hash. systemd-nspawn will look for that file and use it if it exists, in case --root-hash= is not specified explicitly.
2016-12-07 18:28:13 +01:00
PARTITION_ROOT_VERITY, /* verity data for the PARTITION_ROOT partition */
PARTITION_ROOT_SECONDARY_VERITY, /* verity data for the PARTITION_ROOT_SECONDARY partition */
dissect-image: process /usr/ GPT partition type
2020-08-22 12:21:51 +02:00
PARTITION_USR_VERITY,
PARTITION_USR_SECONDARY_VERITY,
dissect: introduce new recognizable partition types for /var and /var/tmp This has been requested many times before. Let's add it finally. GPT auto-discovery for /var is a bit more complex than for other partition types: the other partitions can to some degree be shared between multiple OS installations on the same disk (think: swap, /home, /srv). However, /var is inherently something bound to an installation, i.e. specific to its identity, or actually *is* its identity, and hence something that cannot be shared. To deal with this this new code is particularly careful when it comes to /var: it will not mount things blindly, but insist that the UUID of the partition matches a hashed version of the machine-id of the installation, so that each installation has a very specific /var associated with it, and would never use any other. (We actually use HMAC-SHA256 on the GPT partition type for /var, keyed by the machine-id, since machine-id is something we want to keep somewhat private). Setting the right UUID for installations takes extra care. To make things a bit simpler to set up, we avoid this safety check for nspawn and RootImage= in unit files, under the assumption that such container and service images unlikely will have multiple installations on them. The check is hence only required when booting full machines, i.e. in in systemd-gpt-auto-generator. To help with putting together images for full machines, PR #14368 introduces a repartition tool that can automatically fill in correctly calculated UUIDs on first boot if images have the var partition UUID initialized to all zeroes. With that in place systems can be put together in a way that on first boot the machine ID is determined and the partition table automatically adjusted to have the /var partition with the right UUID.
2019-12-18 12:22:40 +01:00
PARTITION_TMP,
PARTITION_VAR,
util-lib: split out image dissecting code and loopback code from nspawn This adds two new APIs to systemd: - loop-util.h is a simple internal API for allocating, setting up and releasing loopback block devices. - dissect-image.h is an internal API for taking apart disk images and figuring out what the purpose of each partition is. Both APIs are basically refactored versions of similar code in nspawn. This rework should permit us to reuse this in other places than just nspawn in the future. Specifically: to implement RootImage= in the service image, similar to RootDirectory=, but operating on a disk image; to unify the gpt-auto-discovery generator code with the discovery logic in nspawn; to add new API to machined for determining the OS version of a disk image (i.e. not just running containers). This PR does not make any such changes however, it just provides the new reworked API. The reworked code is also slightly more powerful than the nspawn original one. When pointing it to an image or block device with a naked file system (i.e. no partition table) it will simply make it the root device.
2016-12-01 20:25:26 +01:00
_PARTITION_DESIGNATOR_MAX,
_PARTITION_DESIGNATOR_INVALID = -1
dissect: introduce PartitionDesignator as real type
2020-09-15 18:02:28 +02:00
} PartitionDesignator;
util-lib: split out image dissecting code and loopback code from nspawn This adds two new APIs to systemd: - loop-util.h is a simple internal API for allocating, setting up and releasing loopback block devices. - dissect-image.h is an internal API for taking apart disk images and figuring out what the purpose of each partition is. Both APIs are basically refactored versions of similar code in nspawn. This rework should permit us to reuse this in other places than just nspawn in the future. Specifically: to implement RootImage= in the service image, similar to RootDirectory=, but operating on a disk image; to unify the gpt-auto-discovery generator code with the discovery logic in nspawn; to add new API to machined for determining the OS version of a disk image (i.e. not just running containers). This PR does not make any such changes however, it just provides the new reworked API. The reworked code is also slightly more powerful than the nspawn original one. When pointing it to an image or block device with a naked file system (i.e. no partition table) it will simply make it the root device.
2016-12-01 20:25:26 +01:00
dissect: introduce PartitionDesignator as real type
2020-09-15 18:02:28 +02:00
static inline PartitionDesignator PARTITION_VERITY_OF(PartitionDesignator p) {
dissect-image: process /usr/ GPT partition type
2020-08-22 12:21:51 +02:00
switch (p) {
case PARTITION_ROOT:
nspawn/dissect: automatically discover dm-verity verity partitions This adds support for discovering and making use of properly tagged dm-verity data integrity partitions. This extends both systemd-nspawn and systemd-dissect with a new --root-hash= switch that takes the root hash to use for the root partition, and is otherwise fully automatic. Verity partitions are discovered automatically by GPT table type UUIDs, as listed in https://www.freedesktop.org/wiki/Specifications/DiscoverablePartitionsSpec/ (which I updated prior to this change, to include new UUIDs for this purpose. mkosi with https://github.com/systemd/mkosi/pull/39 applied may generate images that carry the necessary integrity data. With that PR and this commit, the following simply lines suffice to boot up an integrity-protected container image: ``` # mkdir test # cd test # mkosi --verity # systemd-nspawn -i ./image.raw -bn ``` Note that mkosi writes the image file to "image.raw" next to a a file "image.roothash" that contains the root hash. systemd-nspawn will look for that file and use it if it exists, in case --root-hash= is not specified explicitly.
2016-12-07 18:28:13 +01:00
return PARTITION_ROOT_VERITY;
dissect-image: process /usr/ GPT partition type
2020-08-22 12:21:51 +02:00
case PARTITION_ROOT_SECONDARY:
nspawn/dissect: automatically discover dm-verity verity partitions This adds support for discovering and making use of properly tagged dm-verity data integrity partitions. This extends both systemd-nspawn and systemd-dissect with a new --root-hash= switch that takes the root hash to use for the root partition, and is otherwise fully automatic. Verity partitions are discovered automatically by GPT table type UUIDs, as listed in https://www.freedesktop.org/wiki/Specifications/DiscoverablePartitionsSpec/ (which I updated prior to this change, to include new UUIDs for this purpose. mkosi with https://github.com/systemd/mkosi/pull/39 applied may generate images that carry the necessary integrity data. With that PR and this commit, the following simply lines suffice to boot up an integrity-protected container image: ``` # mkdir test # cd test # mkosi --verity # systemd-nspawn -i ./image.raw -bn ``` Note that mkosi writes the image file to "image.raw" next to a a file "image.roothash" that contains the root hash. systemd-nspawn will look for that file and use it if it exists, in case --root-hash= is not specified explicitly.
2016-12-07 18:28:13 +01:00
return PARTITION_ROOT_SECONDARY_VERITY;
dissect-image: process /usr/ GPT partition type
2020-08-22 12:21:51 +02:00
case PARTITION_USR:
return PARTITION_USR_VERITY;
case PARTITION_USR_SECONDARY:
return PARTITION_USR_SECONDARY_VERITY;
default:
return _PARTITION_DESIGNATOR_INVALID;
}
nspawn/dissect: automatically discover dm-verity verity partitions This adds support for discovering and making use of properly tagged dm-verity data integrity partitions. This extends both systemd-nspawn and systemd-dissect with a new --root-hash= switch that takes the root hash to use for the root partition, and is otherwise fully automatic. Verity partitions are discovered automatically by GPT table type UUIDs, as listed in https://www.freedesktop.org/wiki/Specifications/DiscoverablePartitionsSpec/ (which I updated prior to this change, to include new UUIDs for this purpose. mkosi with https://github.com/systemd/mkosi/pull/39 applied may generate images that carry the necessary integrity data. With that PR and this commit, the following simply lines suffice to boot up an integrity-protected container image: ``` # mkdir test # cd test # mkosi --verity # systemd-nspawn -i ./image.raw -bn ``` Note that mkosi writes the image file to "image.raw" next to a a file "image.roothash" that contains the root hash. systemd-nspawn will look for that file and use it if it exists, in case --root-hash= is not specified explicitly.
2016-12-07 18:28:13 +01:00
}
dissect: add support for encrypted images This adds support to the image dissector to deal with encrypted images (only LUKS). Given that we now have a neatly isolated image dissector codebase, let's add a new feature to it: support for automatically dealing with encrypted images. This is then exposed in systemd-dissect and nspawn. It's pretty basic: only support for passphrase-based encryption. In order to ensure that "systemd-dissect --mount" results in mount points whose backing LUKS DM devices are cleaned up automatically we use the DM_DEV_REMOVE ioctl() directly on the device (in DM_DEFERRED_REMOVE mode). libgcryptsetup at the moment doesn't provide a proper API for this. Thankfully, the ioctl() API is pretty easy to use.
2016-12-05 16:26:48 +01:00
typedef enum DissectImageFlags {
nspawn: make sure images containing an ESP are compatible with userns -U mode In -U mode we might need to re-chown() all files and directories to match the UID shift we want for the image. That's problematic on fat partitions, such as the ESP (and which is generated by mkosi's --bootable switch), because fat of course knows no UID/GID file ownership natively. With this change we take benefit of the uid= and gid= mount options FAT knows: instead of chown()ing all files and directories we can just specify the right UID/GID to use at mount time. This beefs up the image dissection logic in two ways: 1. First of all support for mounting relevant file systems with uid=/gid= is added: when a UID is specified during mount it is used for all applicable file systems. 2. Secondly, two new mount flags are added: DISSECT_IMAGE_MOUNT_ROOT_ONLY and DISSECT_IMAGE_MOUNT_NON_ROOT_ONLY. If one is specified the mount routine will either only mount the root partition of an image, or all partitions except the root partition. This is used by nspawn: first the root partition is mounted, so that we can determine the UID shift in use so far, based on ownership of the image's root directory. Then, we mount the remaining partitions in a second go, this time with the right UID/GID information.
2017-11-28 16:46:26 +01:00
DISSECT_IMAGE_READ_ONLY = 1 << 0,
DISSECT_IMAGE_DISCARD_ON_LOOP = 1 << 1, /* Turn on "discard" if on a loop device and file system supports it */
DISSECT_IMAGE_DISCARD = 1 << 2, /* Turn on "discard" if file system supports it, on all block devices */
DISSECT_IMAGE_DISCARD_ON_CRYPTO = 1 << 3, /* Turn on "discard" also on crypto devices */
dissect: add DISSECT_IMAGE_DISCARD_ANY mask This makes the code to set arg_flags much more readable.
2016-12-07 21:26:11 +01:00
DISSECT_IMAGE_DISCARD_ANY = DISSECT_IMAGE_DISCARD_ON_LOOP |
DISSECT_IMAGE_DISCARD |
DISSECT_IMAGE_DISCARD_ON_CRYPTO,
nspawn: make sure images containing an ESP are compatible with userns -U mode In -U mode we might need to re-chown() all files and directories to match the UID shift we want for the image. That's problematic on fat partitions, such as the ESP (and which is generated by mkosi's --bootable switch), because fat of course knows no UID/GID file ownership natively. With this change we take benefit of the uid= and gid= mount options FAT knows: instead of chown()ing all files and directories we can just specify the right UID/GID to use at mount time. This beefs up the image dissection logic in two ways: 1. First of all support for mounting relevant file systems with uid=/gid= is added: when a UID is specified during mount it is used for all applicable file systems. 2. Secondly, two new mount flags are added: DISSECT_IMAGE_MOUNT_ROOT_ONLY and DISSECT_IMAGE_MOUNT_NON_ROOT_ONLY. If one is specified the mount routine will either only mount the root partition of an image, or all partitions except the root partition. This is used by nspawn: first the root partition is mounted, so that we can determine the UID shift in use so far, based on ownership of the image's root directory. Then, we mount the remaining partitions in a second go, this time with the right UID/GID information.
2017-11-28 16:46:26 +01:00
DISSECT_IMAGE_GPT_ONLY = 1 << 4, /* Only recognize images with GPT partition tables */
dissect-image: process /usr/ GPT partition type
2020-08-22 12:21:51 +02:00
DISSECT_IMAGE_REQUIRE_ROOT = 1 << 5, /* Don't accept disks without root partition (and if no partition table or only single generic partition, assume it's root) */
DISSECT_IMAGE_MOUNT_ROOT_ONLY = 1 << 6, /* Mount only the root and /usr partitions */
DISSECT_IMAGE_MOUNT_NON_ROOT_ONLY = 1 << 7, /* Mount only the non-root and non-/usr partitions */
codespell: fix spelling errors
2019-04-27 02:22:40 +02:00
DISSECT_IMAGE_VALIDATE_OS = 1 << 8, /* Refuse mounting images that aren't identifiable as OS images */
gpt-auto-generator: don't wait for udev Generators run in a context where waiting for udev is not an option, simply because it's not running there yet. Hence, let's not wait for it in this case. This is generally OK to do as we are operating on the root disk only here, which should have been probed already by the time we come this far. An alternative fix might be to remove the udev dependency from image dissection again in the long run (and thus replace reliance on /dev/block/x:y somehow with something else). Fixes: #11205
2018-12-19 17:17:35 +01:00
DISSECT_IMAGE_NO_UDEV = 1 << 9, /* Don't wait for udev initializing things */
dissect: introduce new recognizable partition types for /var and /var/tmp This has been requested many times before. Let's add it finally. GPT auto-discovery for /var is a bit more complex than for other partition types: the other partitions can to some degree be shared between multiple OS installations on the same disk (think: swap, /home, /srv). However, /var is inherently something bound to an installation, i.e. specific to its identity, or actually *is* its identity, and hence something that cannot be shared. To deal with this this new code is particularly careful when it comes to /var: it will not mount things blindly, but insist that the UUID of the partition matches a hashed version of the machine-id of the installation, so that each installation has a very specific /var associated with it, and would never use any other. (We actually use HMAC-SHA256 on the GPT partition type for /var, keyed by the machine-id, since machine-id is something we want to keep somewhat private). Setting the right UUID for installations takes extra care. To make things a bit simpler to set up, we avoid this safety check for nspawn and RootImage= in unit files, under the assumption that such container and service images unlikely will have multiple installations on them. The check is hence only required when booting full machines, i.e. in in systemd-gpt-auto-generator. To help with putting together images for full machines, PR #14368 introduces a repartition tool that can automatically fill in correctly calculated UUIDs on first boot if images have the var partition UUID initialized to all zeroes. With that in place systems can be put together in a way that on first boot the machine ID is determined and the partition table automatically adjusted to have the /var partition with the right UUID.
2019-12-18 12:22:40 +01:00
DISSECT_IMAGE_RELAX_VAR_CHECK = 1 << 10, /* Don't insist that the UUID of /var is hashed from /etc/machine-id */
dissect: optionally, run fsck before mounting dissected images Some file systems want us to run fsck before mounting, hence do so, optionally.
2020-01-29 19:13:24 +01:00
DISSECT_IMAGE_FSCK = 1 << 11, /* File system check the partition before mounting (no effect when combined with DISSECT_IMAGE_READ_ONLY) */
dissect: support single-filesystem verity images with external verity hash dm-verity support in dissect-image at the moment is restricted to GPT volumes. If the image a single-filesystem type without a partition table (eg: squashfs) and a roothash/verity file are passed, set the verity flag and mark as read-only.
2020-05-29 18:51:20 +02:00
DISSECT_IMAGE_NO_PARTITION_TABLE = 1 << 12, /* Only recognize single file system images */
verity: re-use already open devices if the hashes match Opening a verity device is an expensive operation. The kernelspace operations are mostly sequential with a global lock held regardless of which device is being opened. In userspace jumps in and out of multiple libraries are required. When signatures are used, there's the additional cryptographic checks. We know when two devices are identical: they have the same root hash. If libcrypsetup returns EEXIST, double check that the hashes are really the same, and that either both or none have a signature, and if everything matches simply remount the already open device. The kernel will do reference counting for us. In order to quickly and reliably discover if a device is already open, change the node naming scheme from '/dev/mapper/major:minor-verity' to '/dev/mapper/$roothash-verity'. Unfortunately libdevmapper is not 100% reliable, so in some case it will say that the device already exists and it is active, but in reality it is not usable. Fallback to an individually-activated unique device name in those cases for robustness.
2020-07-08 20:57:31 +02:00
DISSECT_IMAGE_VERITY_SHARE = 1 << 13, /* When activating a verity device, reuse existing one if already open */
dissect: optionally mkdir directory to overmount
2020-07-28 18:50:17 +02:00
DISSECT_IMAGE_MKDIR = 1 << 14, /* Make directory to mount right before mounting, if missing */
dissect: add support for encrypted images This adds support to the image dissector to deal with encrypted images (only LUKS). Given that we now have a neatly isolated image dissector codebase, let's add a new feature to it: support for automatically dealing with encrypted images. This is then exposed in systemd-dissect and nspawn. It's pretty basic: only support for passphrase-based encryption. In order to ensure that "systemd-dissect --mount" results in mount points whose backing LUKS DM devices are cleaned up automatically we use the DM_DEV_REMOVE ioctl() directly on the device (in DM_DEFERRED_REMOVE mode). libgcryptsetup at the moment doesn't provide a proper API for this. Thankfully, the ioctl() API is pretty easy to use.
2016-12-05 16:26:48 +01:00
} DissectImageFlags;
util-lib: split out image dissecting code and loopback code from nspawn This adds two new APIs to systemd: - loop-util.h is a simple internal API for allocating, setting up and releasing loopback block devices. - dissect-image.h is an internal API for taking apart disk images and figuring out what the purpose of each partition is. Both APIs are basically refactored versions of similar code in nspawn. This rework should permit us to reuse this in other places than just nspawn in the future. Specifically: to implement RootImage= in the service image, similar to RootDirectory=, but operating on a disk image; to unify the gpt-auto-discovery generator code with the discovery logic in nspawn; to add new API to machined for determining the OS version of a disk image (i.e. not just running containers). This PR does not make any such changes however, it just provides the new reworked API. The reworked code is also slightly more powerful than the nspawn original one. When pointing it to an image or block device with a naked file system (i.e. no partition table) it will simply make it the root device.
2016-12-01 20:25:26 +01:00
struct DissectedImage {
nspawn/dissect: automatically discover dm-verity verity partitions This adds support for discovering and making use of properly tagged dm-verity data integrity partitions. This extends both systemd-nspawn and systemd-dissect with a new --root-hash= switch that takes the root hash to use for the root partition, and is otherwise fully automatic. Verity partitions are discovered automatically by GPT table type UUIDs, as listed in https://www.freedesktop.org/wiki/Specifications/DiscoverablePartitionsSpec/ (which I updated prior to this change, to include new UUIDs for this purpose. mkosi with https://github.com/systemd/mkosi/pull/39 applied may generate images that carry the necessary integrity data. With that PR and this commit, the following simply lines suffice to boot up an integrity-protected container image: ``` # mkdir test # cd test # mkosi --verity # systemd-nspawn -i ./image.raw -bn ``` Note that mkosi writes the image file to "image.raw" next to a a file "image.roothash" that contains the root hash. systemd-nspawn will look for that file and use it if it exists, in case --root-hash= is not specified explicitly.
2016-12-07 18:28:13 +01:00
bool encrypted:1;
bool verity:1; /* verity available and usable */
bool can_verity:1; /* verity available, but not necessarily used */
dissect: support single-filesystem verity images with external verity hash dm-verity support in dissect-image at the moment is restricted to GPT volumes. If the image a single-filesystem type without a partition table (eg: squashfs) and a roothash/verity file are passed, set the verity flag and mark as read-only.
2020-05-29 18:51:20 +02:00
bool single_file_system:1; /* MBR/GPT or single file system */
dissect: add an API that can read various metadata bits out of a dissected image We focus on four kinds of metadata: 1. /etc/hostname 2. /etc/machine-id 3. /etc/machine-info 4. /etc/os-release or /usr/lib/os-release This makes dissected images nicely self-contained as we can figure out what they are just by dissecting them.
2017-11-14 23:22:46 +01:00
util-lib: split out image dissecting code and loopback code from nspawn This adds two new APIs to systemd: - loop-util.h is a simple internal API for allocating, setting up and releasing loopback block devices. - dissect-image.h is an internal API for taking apart disk images and figuring out what the purpose of each partition is. Both APIs are basically refactored versions of similar code in nspawn. This rework should permit us to reuse this in other places than just nspawn in the future. Specifically: to implement RootImage= in the service image, similar to RootDirectory=, but operating on a disk image; to unify the gpt-auto-discovery generator code with the discovery logic in nspawn; to add new API to machined for determining the OS version of a disk image (i.e. not just running containers). This PR does not make any such changes however, it just provides the new reworked API. The reworked code is also slightly more powerful than the nspawn original one. When pointing it to an image or block device with a naked file system (i.e. no partition table) it will simply make it the root device.
2016-12-01 20:25:26 +01:00
DissectedPartition partitions[_PARTITION_DESIGNATOR_MAX];
dissect: add an API that can read various metadata bits out of a dissected image We focus on four kinds of metadata: 1. /etc/hostname 2. /etc/machine-id 3. /etc/machine-info 4. /etc/os-release or /usr/lib/os-release This makes dissected images nicely self-contained as we can figure out what they are just by dissecting them.
2017-11-14 23:22:46 +01:00
char *hostname;
sd_id128_t machine_id;
char **machine_info;
char **os_release;
util-lib: split out image dissecting code and loopback code from nspawn This adds two new APIs to systemd: - loop-util.h is a simple internal API for allocating, setting up and releasing loopback block devices. - dissect-image.h is an internal API for taking apart disk images and figuring out what the purpose of each partition is. Both APIs are basically refactored versions of similar code in nspawn. This rework should permit us to reuse this in other places than just nspawn in the future. Specifically: to implement RootImage= in the service image, similar to RootDirectory=, but operating on a disk image; to unify the gpt-auto-discovery generator code with the discovery logic in nspawn; to add new API to machined for determining the OS version of a disk image (i.e. not just running containers). This PR does not make any such changes however, it just provides the new reworked API. The reworked code is also slightly more powerful than the nspawn original one. When pointing it to an image or block device with a naked file system (i.e. no partition table) it will simply make it the root device.
2016-12-01 20:25:26 +01:00
};
service: add new RootImageOptions feature Allows to specify mount options for RootImage. In case of multi-partition images, the partition number can be prefixed followed by colon. Eg: RootImageOptions=1:ro,dev 2:nosuid nodev In absence of a partition number, 0 is assumed.
2020-06-29 14:19:31 +02:00
struct MountOptions {
dissect: introduce PartitionDesignator as real type
2020-09-15 18:02:28 +02:00
PartitionDesignator partition_designator;
service: add new RootImageOptions feature Allows to specify mount options for RootImage. In case of multi-partition images, the partition number can be prefixed followed by colon. Eg: RootImageOptions=1:ro,dev 2:nosuid nodev In absence of a partition number, 0 is assumed.
2020-06-29 14:19:31 +02:00
char *options;
LIST_FIELDS(MountOptions, mount_options);
};
dissect: wrap verity settings in new VeritySettings structure Just some refactoring: let's place the various verity related parameters in a common structure, and pass that around instead of the individual parameters. Also, let's load the PKCS#7 signature data when finding metadata right-away, instead of delaying this until we need it. In all cases we call this there's not much time difference between the metdata finding and the loading, hence this simplifies things and makes sure root hash data and its signature is now always acquired together.
2020-09-15 22:09:08 +02:00
struct VeritySettings {
/* Binary root hash for the Verity Merkle tree */
void *root_hash;
size_t root_hash_size;
/* PKCS#7 signature of the above */
void *root_hash_sig;
size_t root_hash_sig_size;
/* Path to the verity data file, if stored externally */
char *data_path;
dissect-image: process /usr/ GPT partition type
2020-08-22 12:21:51 +02:00
/* PARTITION_ROOT or PARTITION_USR, depending on what these Verity settings are for */
PartitionDesignator designator;
dissect: wrap verity settings in new VeritySettings structure Just some refactoring: let's place the various verity related parameters in a common structure, and pass that around instead of the individual parameters. Also, let's load the PKCS#7 signature data when finding metadata right-away, instead of delaying this until we need it. In all cases we call this there's not much time difference between the metdata finding and the loading, hence this simplifies things and makes sure root hash data and its signature is now always acquired together.
2020-09-15 22:09:08 +02:00
};
dissect-image: process /usr/ GPT partition type
2020-08-22 12:21:51 +02:00
#define VERITY_SETTINGS_DEFAULT { \
.designator = _PARTITION_DESIGNATOR_INVALID \
}
service: add new RootImageOptions feature Allows to specify mount options for RootImage. In case of multi-partition images, the partition number can be prefixed followed by colon. Eg: RootImageOptions=1:ro,dev 2:nosuid nodev In absence of a partition number, 0 is assumed.
2020-06-29 14:19:31 +02:00
MountOptions* mount_options_free_all(MountOptions *options);
DEFINE_TRIVIAL_CLEANUP_FUNC(MountOptions*, mount_options_free_all);
dissect: introduce PartitionDesignator as real type
2020-09-15 18:02:28 +02:00
const char* mount_options_from_designator(const MountOptions *options, PartitionDesignator designator);
service: add new RootImageOptions feature Allows to specify mount options for RootImage. In case of multi-partition images, the partition number can be prefixed followed by colon. Eg: RootImageOptions=1:ro,dev 2:nosuid nodev In absence of a partition number, 0 is assumed.
2020-06-29 14:19:31 +02:00
growfs: add support for resizing encrypted partitions
2017-11-21 18:56:52 +01:00
int probe_filesystem(const char *node, char **ret_fstype);
dissect: wrap verity settings in new VeritySettings structure Just some refactoring: let's place the various verity related parameters in a common structure, and pass that around instead of the individual parameters. Also, let's load the PKCS#7 signature data when finding metadata right-away, instead of delaying this until we need it. In all cases we call this there's not much time difference between the metdata finding and the loading, hence this simplifies things and makes sure root hash data and its signature is now always acquired together.
2020-09-15 22:09:08 +02:00
int dissect_image(int fd, const VeritySettings *verity, const MountOptions *mount_options, DissectImageFlags flags, DissectedImage **ret);
int dissect_image_and_warn(int fd, const char *name, const VeritySettings *verity, const MountOptions *mount_options, DissectImageFlags flags, DissectedImage **ret);
util-lib: split out image dissecting code and loopback code from nspawn This adds two new APIs to systemd: - loop-util.h is a simple internal API for allocating, setting up and releasing loopback block devices. - dissect-image.h is an internal API for taking apart disk images and figuring out what the purpose of each partition is. Both APIs are basically refactored versions of similar code in nspawn. This rework should permit us to reuse this in other places than just nspawn in the future. Specifically: to implement RootImage= in the service image, similar to RootDirectory=, but operating on a disk image; to unify the gpt-auto-discovery generator code with the discovery logic in nspawn; to add new API to machined for determining the OS version of a disk image (i.e. not just running containers). This PR does not make any such changes however, it just provides the new reworked API. The reworked code is also slightly more powerful than the nspawn original one. When pointing it to an image or block device with a naked file system (i.e. no partition table) it will simply make it the root device.
2016-12-01 20:25:26 +01:00
DissectedImage* dissected_image_unref(DissectedImage *m);
DEFINE_TRIVIAL_CLEANUP_FUNC(DissectedImage*, dissected_image_unref);
dissect: wrap verity settings in new VeritySettings structure Just some refactoring: let's place the various verity related parameters in a common structure, and pass that around instead of the individual parameters. Also, let's load the PKCS#7 signature data when finding metadata right-away, instead of delaying this until we need it. In all cases we call this there's not much time difference between the metdata finding and the loading, hence this simplifies things and makes sure root hash data and its signature is now always acquired together.
2020-09-15 22:09:08 +02:00
int dissected_image_decrypt(DissectedImage *m, const char *passphrase, const VeritySettings *verity, DissectImageFlags flags, DecryptedImage **ret);
int dissected_image_decrypt_interactively(DissectedImage *m, const char *passphrase, const VeritySettings *verity, DissectImageFlags flags, DecryptedImage **ret);
nspawn: make sure images containing an ESP are compatible with userns -U mode In -U mode we might need to re-chown() all files and directories to match the UID shift we want for the image. That's problematic on fat partitions, such as the ESP (and which is generated by mkosi's --bootable switch), because fat of course knows no UID/GID file ownership natively. With this change we take benefit of the uid= and gid= mount options FAT knows: instead of chown()ing all files and directories we can just specify the right UID/GID to use at mount time. This beefs up the image dissection logic in two ways: 1. First of all support for mounting relevant file systems with uid=/gid= is added: when a UID is specified during mount it is used for all applicable file systems. 2. Secondly, two new mount flags are added: DISSECT_IMAGE_MOUNT_ROOT_ONLY and DISSECT_IMAGE_MOUNT_NON_ROOT_ONLY. If one is specified the mount routine will either only mount the root partition of an image, or all partitions except the root partition. This is used by nspawn: first the root partition is mounted, so that we can determine the UID shift in use so far, based on ownership of the image's root directory. Then, we mount the remaining partitions in a second go, this time with the right UID/GID information.
2017-11-28 16:46:26 +01:00
int dissected_image_mount(DissectedImage *m, const char *dest, uid_t uid_shift, DissectImageFlags flags);
dissect: introduce new helper dissected_image_mount_and_warn() and use it everywhere
2020-08-11 15:56:12 +02:00
int dissected_image_mount_and_warn(DissectedImage *m, const char *where, uid_t uid_shift, DissectImageFlags flags);
dissect: add support for encrypted images This adds support to the image dissector to deal with encrypted images (only LUKS). Given that we now have a neatly isolated image dissector codebase, let's add a new feature to it: support for automatically dealing with encrypted images. This is then exposed in systemd-dissect and nspawn. It's pretty basic: only support for passphrase-based encryption. In order to ensure that "systemd-dissect --mount" results in mount points whose backing LUKS DM devices are cleaned up automatically we use the DM_DEV_REMOVE ioctl() directly on the device (in DM_DEFERRED_REMOVE mode). libgcryptsetup at the moment doesn't provide a proper API for this. Thankfully, the ioctl() API is pretty easy to use.
2016-12-05 16:26:48 +01:00
dissect: add an API that can read various metadata bits out of a dissected image We focus on four kinds of metadata: 1. /etc/hostname 2. /etc/machine-id 3. /etc/machine-info 4. /etc/os-release or /usr/lib/os-release This makes dissected images nicely self-contained as we can figure out what they are just by dissecting them.
2017-11-14 23:22:46 +01:00
int dissected_image_acquire_metadata(DissectedImage *m);
dissect: add support for encrypted images This adds support to the image dissector to deal with encrypted images (only LUKS). Given that we now have a neatly isolated image dissector codebase, let's add a new feature to it: support for automatically dealing with encrypted images. This is then exposed in systemd-dissect and nspawn. It's pretty basic: only support for passphrase-based encryption. In order to ensure that "systemd-dissect --mount" results in mount points whose backing LUKS DM devices are cleaned up automatically we use the DM_DEV_REMOVE ioctl() directly on the device (in DM_DEFERRED_REMOVE mode). libgcryptsetup at the moment doesn't provide a proper API for this. Thankfully, the ioctl() API is pretty easy to use.
2016-12-05 16:26:48 +01:00
DecryptedImage* decrypted_image_unref(DecryptedImage *p);
DEFINE_TRIVIAL_CLEANUP_FUNC(DecryptedImage*, decrypted_image_unref);
int decrypted_image_relinquish(DecryptedImage *d);
util-lib: split out image dissecting code and loopback code from nspawn This adds two new APIs to systemd: - loop-util.h is a simple internal API for allocating, setting up and releasing loopback block devices. - dissect-image.h is an internal API for taking apart disk images and figuring out what the purpose of each partition is. Both APIs are basically refactored versions of similar code in nspawn. This rework should permit us to reuse this in other places than just nspawn in the future. Specifically: to implement RootImage= in the service image, similar to RootDirectory=, but operating on a disk image; to unify the gpt-auto-discovery generator code with the discovery logic in nspawn; to add new API to machined for determining the OS version of a disk image (i.e. not just running containers). This PR does not make any such changes however, it just provides the new reworked API. The reworked code is also slightly more powerful than the nspawn original one. When pointing it to an image or block device with a naked file system (i.e. no partition table) it will simply make it the root device.
2016-12-01 20:25:26 +01:00
dissect: introduce PartitionDesignator as real type
2020-09-15 18:02:28 +02:00
const char* partition_designator_to_string(PartitionDesignator d) _const_;
PartitionDesignator partition_designator_from_string(const char *name) _pure_;
core,nspawn,dissect: make nspawn's .roothash file search reusable This makes nspawn's logic of automatically discovering the root hash of an image file generic, and then reuses it in systemd-dissect and in PID1's RootImage= logic, so that verity is automatically set up whenever we can.
2016-12-23 17:10:42 +01:00
dissect: wrap verity settings in new VeritySettings structure Just some refactoring: let's place the various verity related parameters in a common structure, and pass that around instead of the individual parameters. Also, let's load the PKCS#7 signature data when finding metadata right-away, instead of delaying this until we need it. In all cases we call this there's not much time difference between the metdata finding and the loading, hence this simplifies things and makes sure root hash data and its signature is now always acquired together.
2020-09-15 22:09:08 +02:00
int verity_settings_load(VeritySettings *verity, const char *image, const char *root_hash_path, const char *root_hash_sig_path);
void verity_settings_done(VeritySettings *verity);
dissect: introduce PartitionDesignator as real type
2020-09-15 18:02:28 +02:00
bool dissected_image_can_do_verity(const DissectedImage *image, PartitionDesignator d);
bool dissected_image_has_verity(const DissectedImage *image, PartitionDesignator d);
firstboot: move --image= logic into common code That way we can reuse it in tmpfiles/sysusers/journalctl and so on.
2020-07-28 18:16:19 +02:00
int mount_image_privately_interactively(const char *path, DissectImageFlags flags, char **ret_directory, LoopDevice **ret_loop_device, DecryptedImage **ret_decrypted_image);