remarkable-linux/security/keys/Kconfig

#
# Key management configuration
#

config KEYS
	bool "Enable access key retention support"
	select ASSOCIATIVE_ARRAY
	help
	  This option provides support for retaining authentication tokens and
	  access keys in the kernel.

	  It also includes provision of methods by which such keys might be
	  associated with a process so that network filesystems, encryption
	  support and the like can find them.

	  Furthermore, a special type of key is available that acts as keyring:
	  a searchable sequence of keys. Each process is equipped with access
	  to five standard keyrings: UID-specific, GID-specific, session,
	  process and thread.

	  If you are unsure as to whether this is required, answer N.

config KEYS_COMPAT
	def_bool y
	depends on COMPAT && KEYS

config PERSISTENT_KEYRINGS
	bool "Enable register of persistent per-UID keyrings"
	depends on KEYS
	help
	  This option provides a register of persistent per-UID keyrings,
	  primarily aimed at Kerberos key storage.  The keyrings are persistent
	  in the sense that they stay around after all processes of that UID
	  have exited, not that they survive the machine being rebooted.

	  A particular keyring may be accessed by either the user whose keyring
	  it is or by a process with administrative privileges.  The active
	  LSMs gets to rule on which admin-level processes get to access the
	  cache.

	  Keyrings are created and added into the register upon demand and get
	  removed if they expire (a default timeout is set upon creation).

config BIG_KEYS
	bool "Large payload keys"
	depends on KEYS
	depends on TMPFS
	select CRYPTO
	select CRYPTO_AES
	select CRYPTO_GCM
	help
	  This option provides support for holding large keys within the kernel
	  (for example Kerberos ticket caches).  The data may be stored out to
	  swapspace by tmpfs.

	  If you are unsure as to whether this is required, answer N.

config TRUSTED_KEYS
	tristate "TRUSTED KEYS"
	depends on KEYS && TCG_TPM
	select CRYPTO
	select CRYPTO_HMAC
	select CRYPTO_SHA1
	select CRYPTO_HASH_INFO
	help
	  This option provides support for creating, sealing, and unsealing
	  keys in the kernel. Trusted keys are random number symmetric keys,
	  generated and RSA-sealed by the TPM. The TPM only unseals the keys,
	  if the boot PCRs and other criteria match.  Userspace will only ever
	  see encrypted blobs.

	  If you are unsure as to whether this is required, answer N.

config ENCRYPTED_KEYS
	tristate "ENCRYPTED KEYS"
	depends on KEYS
	select CRYPTO
	select CRYPTO_HMAC
	select CRYPTO_AES
	select CRYPTO_CBC
	select CRYPTO_SHA256
	select CRYPTO_RNG
	help
	  This option provides support for create/encrypting/decrypting keys
	  in the kernel.  Encrypted keys are kernel generated random numbers,
	  which are encrypted/decrypted with a 'master' symmetric key. The
	  'master' key can be either a trusted-key or user-key type.
	  Userspace only ever sees/stores encrypted blobs.

	  If you are unsure as to whether this is required, answer N.

config KEY_DH_OPERATIONS
       bool "Diffie-Hellman operations on retained keys"
       depends on KEYS
       select CRYPTO
       select CRYPTO_HASH
       select CRYPTO_DH
       help
	 This option provides support for calculating Diffie-Hellman
	 public keys and shared secrets using values stored as keys
	 in the kernel.

	 If you are unsure as to whether this is required, answer N.
KEYS: Move the key config into security/keys/Kconfig Move the key config into security/keys/Kconfig as there are going to be a lot of key-related options. Signed-off-by: David Howells <dhowells@redhat.com> Acked-by: Mimi Zohar <zohar@us.ibm.com> 2012-05-11 03:56:56 -06:00			`#`
			`# Key management configuration`
			`#`

			`config KEYS`
			`bool "Enable access key retention support"`
KEYS: Expand the capacity of a keyring Expand the capacity of a keyring to be able to hold a lot more keys by using the previously added associative array implementation. Currently the maximum capacity is: (PAGE_SIZE - sizeof(header)) / sizeof(struct key *) which, on a 64-bit system, is a little more 500. However, since this is being used for the NFS uid mapper, we need more than that. The new implementation gives us effectively unlimited capacity. With some alterations, the keyutils testsuite runs successfully to completion after this patch is applied. The alterations are because (a) keyrings that are simply added to no longer appear ordered and (b) some of the errors have changed a bit. Signed-off-by: David Howells <dhowells@redhat.com> 2013-09-24 03:35:18 -06:00			`select ASSOCIATIVE_ARRAY`
KEYS: Move the key config into security/keys/Kconfig Move the key config into security/keys/Kconfig as there are going to be a lot of key-related options. Signed-off-by: David Howells <dhowells@redhat.com> Acked-by: Mimi Zohar <zohar@us.ibm.com> 2012-05-11 03:56:56 -06:00			`help`
			`This option provides support for retaining authentication tokens and`
			`access keys in the kernel.`

			`It also includes provision of methods by which such keys might be`
			`associated with a process so that network filesystems, encryption`
			`support and the like can find them.`

			`Furthermore, a special type of key is available that acts as keyring:`
			`a searchable sequence of keys. Each process is equipped with access`
			`to five standard keyrings: UID-specific, GID-specific, session,`
			`process and thread.`

			`If you are unsure as to whether this is required, answer N.`

security/keys: add CONFIG_KEYS_COMPAT to Kconfig CONFIG_KEYS_COMPAT is defined in arch-specific Kconfigs and is missing for several 64-bit architectures : mips, parisc, tile. At the moment and for those architectures, calling in 32-bit userspace the keyctl syscall would return an ENOSYS error. This patch moves the CONFIG_KEYS_COMPAT option to security/keys/Kconfig, to make sure the compatibility wrapper is registered by default for any 64-bit architecture as long as it is configured with CONFIG_COMPAT. [DH: Modified to remove arm64 compat enablement also as requested by Eric Biggers] Signed-off-by: Bilal Amarni <bilal.amarni@gmail.com> Signed-off-by: David Howells <dhowells@redhat.com> Reviewed-by: Arnd Bergmann <arnd@arndb.de> cc: Eric Biggers <ebiggers3@gmail.com> Signed-off-by: James Morris <james.l.morris@oracle.com> 2017-06-08 07:47:26 -06:00			`config KEYS_COMPAT`
			`def_bool y`
			`depends on COMPAT && KEYS`

KEYS: Add per-user_namespace registers for persistent per-UID kerberos caches Add support for per-user_namespace registers of persistent per-UID kerberos caches held within the kernel. This allows the kerberos cache to be retained beyond the life of all a user's processes so that the user's cron jobs can work. The kerberos cache is envisioned as a keyring/key tree looking something like: struct user_namespace \___ .krb_cache keyring - The register \___ _krb.0 keyring - Root's Kerberos cache \___ _krb.5000 keyring - User 5000's Kerberos cache \___ _krb.5001 keyring - User 5001's Kerberos cache \___ tkt785 big_key - A ccache blob \___ tkt12345 big_key - Another ccache blob Or possibly: struct user_namespace \___ .krb_cache keyring - The register \___ _krb.0 keyring - Root's Kerberos cache \___ _krb.5000 keyring - User 5000's Kerberos cache \___ _krb.5001 keyring - User 5001's Kerberos cache \___ tkt785 keyring - A ccache \___ krbtgt/REDHAT.COM@REDHAT.COM big_key \___ http/REDHAT.COM@REDHAT.COM user \___ afs/REDHAT.COM@REDHAT.COM user \___ nfs/REDHAT.COM@REDHAT.COM user \___ krbtgt/KERNEL.ORG@KERNEL.ORG big_key \___ http/KERNEL.ORG@KERNEL.ORG big_key What goes into a particular Kerberos cache is entirely up to userspace. Kernel support is limited to giving you the Kerberos cache keyring that you want. The user asks for their Kerberos cache by: krb_cache = keyctl_get_krbcache(uid, dest_keyring); The uid is -1 or the user's own UID for the user's own cache or the uid of some other user's cache (requires CAP_SETUID). This permits rpc.gssd or whatever to mess with the cache. The cache returned is a keyring named "_krb.<uid>" that the possessor can read, search, clear, invalidate, unlink from and add links to. Active LSMs get a chance to rule on whether the caller is permitted to make a link. Each uid's cache keyring is created when it first accessed and is given a timeout that is extended each time this function is called so that the keyring goes away after a while. The timeout is configurable by sysctl but defaults to three days. Each user_namespace struct gets a lazily-created keyring that serves as the register. The cache keyrings are added to it. This means that standard key search and garbage collection facilities are available. The user_namespace struct's register goes away when it does and anything left in it is then automatically gc'd. Signed-off-by: David Howells <dhowells@redhat.com> Tested-by: Simo Sorce <simo@redhat.com> cc: Serge E. Hallyn <serge.hallyn@ubuntu.com> cc: Eric W. Biederman <ebiederm@xmission.com> 2013-09-24 03:35:19 -06:00			`config PERSISTENT_KEYRINGS`
			`bool "Enable register of persistent per-UID keyrings"`
			`depends on KEYS`
			`help`
			`This option provides a register of persistent per-UID keyrings,`
			`primarily aimed at Kerberos key storage. The keyrings are persistent`
			`in the sense that they stay around after all processes of that UID`
			`have exited, not that they survive the machine being rebooted.`

			`A particular keyring may be accessed by either the user whose keyring`
			`it is or by a process with administrative privileges. The active`
			`LSMs gets to rule on which admin-level processes get to access the`
			`cache.`

			`Keyrings are created and added into the register upon demand and get`
			`removed if they expire (a default timeout is set upon creation).`

KEYS: Implement a big key type that can save to tmpfs Implement a big key type that can save its contents to tmpfs and thus swapspace when memory is tight. This is useful for Kerberos ticket caches. Signed-off-by: David Howells <dhowells@redhat.com> Tested-by: Simo Sorce <simo@redhat.com> 2013-09-24 03:35:18 -06:00			`config BIG_KEYS`
KEYS: Make BIG_KEYS boolean Having the big_keys functionality as a module is very marginally useful. The userspace code that would use this functionality will get odd error messages from the keys layer if the module isn't loaded. The code itself is fairly small, so just have this as a boolean option and not a tristate. Signed-off-by: Josh Boyer <jwboyer@fedoraproject.org> Signed-off-by: David Howells <dhowells@redhat.com> 2013-10-30 05:15:23 -06:00			`bool "Large payload keys"`
KEYS: Implement a big key type that can save to tmpfs Implement a big key type that can save its contents to tmpfs and thus swapspace when memory is tight. This is useful for Kerberos ticket caches. Signed-off-by: David Howells <dhowells@redhat.com> Tested-by: Simo Sorce <simo@redhat.com> 2013-09-24 03:35:18 -06:00			`depends on KEYS`
			`depends on TMPFS`
security/keys: BIG_KEY requires CONFIG_CRYPTO The recent rework introduced a possible randconfig build failure when CONFIG_CRYPTO configured to only allow modules: security/keys/big_key.o: In function `big_key_crypt': big_key.c:(.text+0x29f): undefined reference to `crypto_aead_setkey' security/keys/big_key.o: In function `big_key_init': big_key.c:(.init.text+0x1a): undefined reference to `crypto_alloc_aead' big_key.c:(.init.text+0x45): undefined reference to `crypto_aead_setauthsize' big_key.c:(.init.text+0x77): undefined reference to `crypto_destroy_tfm' crypto/gcm.o: In function `gcm_hash_crypt_remain_continue': gcm.c:(.text+0x167): undefined reference to `crypto_ahash_finup' crypto/gcm.o: In function `crypto_gcm_exit_tfm': gcm.c:(.text+0x847): undefined reference to `crypto_destroy_tfm' When we 'select CRYPTO' like the other users, we always get a configuration that builds. Fixes: 428490e38b2e ("security/keys: rewrite all of big_key crypto") Signed-off-by: Arnd Bergmann <arnd@arndb.de> Signed-off-by: David Howells <dhowells@redhat.com> 2017-10-04 04:27:00 -06:00			`select CRYPTO`
Security: Keys: Big keys stored encrypted Solved TODO task: big keys saved to shmem file are now stored encrypted. The encryption key is randomly generated and saved to payload[big_key_data]. Signed-off-by: Kirill Marinushkin <k.marinushkin@gmail.com> Signed-off-by: David Howells <dhowells@redhat.com> 2016-04-12 12:54:58 -06:00			`select CRYPTO_AES`
security/keys: rewrite all of big_key crypto This started out as just replacing the use of crypto/rng with get_random_bytes_wait, so that we wouldn't use bad randomness at boot time. But, upon looking further, it appears that there were even deeper underlying cryptographic problems, and that this seems to have been committed with very little crypto review. So, I rewrote the whole thing, trying to keep to the conventions introduced by the previous author, to fix these cryptographic flaws. It makes no sense to seed crypto/rng at boot time and then keep using it like this, when in fact there's already get_random_bytes_wait, which can ensure there's enough entropy and be a much more standard way of generating keys. Since this sensitive material is being stored untrusted, using ECB and no authentication is simply not okay at all. I find it surprising and a bit horrifying that this code even made it past basic crypto review, which perhaps points to some larger issues. This patch moves from using AES-ECB to using AES-GCM. Since keys are uniquely generated each time, we can set the nonce to zero. There was also a race condition in which the same key would be reused at the same time in different threads. A mutex fixes this issue now. So, to summarize, this commit fixes the following vulnerabilities: * Low entropy key generation, allowing an attacker to potentially guess or predict keys. * Unauthenticated encryption, allowing an attacker to modify the cipher text in particular ways in order to manipulate the plaintext, which is is even more frightening considering the next point. * Use of ECB mode, allowing an attacker to trivially swap blocks or compare identical plaintext blocks. * Key re-use. * Faulty memory zeroing. Signed-off-by: Jason A. Donenfeld <Jason@zx2c4.com> Reviewed-by: Eric Biggers <ebiggers3@gmail.com> Signed-off-by: David Howells <dhowells@redhat.com> Cc: Herbert Xu <herbert@gondor.apana.org.au> Cc: Kirill Marinushkin <k.marinushkin@gmail.com> Cc: security@kernel.org Cc: stable@vger.kernel.org 2017-09-20 08:58:39 -06:00			`select CRYPTO_GCM`
KEYS: Implement a big key type that can save to tmpfs Implement a big key type that can save its contents to tmpfs and thus swapspace when memory is tight. This is useful for Kerberos ticket caches. Signed-off-by: David Howells <dhowells@redhat.com> Tested-by: Simo Sorce <simo@redhat.com> 2013-09-24 03:35:18 -06:00			`help`
			`This option provides support for holding large keys within the kernel`
			`(for example Kerberos ticket caches). The data may be stored out to`
			`swapspace by tmpfs.`

			`If you are unsure as to whether this is required, answer N.`

KEYS: Move the key config into security/keys/Kconfig Move the key config into security/keys/Kconfig as there are going to be a lot of key-related options. Signed-off-by: David Howells <dhowells@redhat.com> Acked-by: Mimi Zohar <zohar@us.ibm.com> 2012-05-11 03:56:56 -06:00			`config TRUSTED_KEYS`
			`tristate "TRUSTED KEYS"`
			`depends on KEYS && TCG_TPM`
			`select CRYPTO`
			`select CRYPTO_HMAC`
			`select CRYPTO_SHA1`
keys, trusted: select hash algorithm for TPM2 chips Added 'hash=' option for selecting the hash algorithm for add_key() syscall and documentation for it. Added entry for sm3-256 to the following tables in order to support TPM_ALG_SM3_256: * hash_algo_name * hash_digest_size Includes support for the following hash algorithms: * sha1 * sha256 * sha384 * sha512 * sm3-256 Signed-off-by: Jarkko Sakkinen <jarkko.sakkinen@linux.intel.com> Tested-by: Colin Ian King <colin.king@canonical.com> Reviewed-by: James Morris <james.l.morris@oracle.com> Reviewed-by: Mimi Zohar <zohar@linux.vnet.ibm.com> Acked-by: Peter Huewe <peterhuewe@gmx.de> 2015-11-05 12:43:06 -07:00			`select CRYPTO_HASH_INFO`
KEYS: Move the key config into security/keys/Kconfig Move the key config into security/keys/Kconfig as there are going to be a lot of key-related options. Signed-off-by: David Howells <dhowells@redhat.com> Acked-by: Mimi Zohar <zohar@us.ibm.com> 2012-05-11 03:56:56 -06:00			`help`
			`This option provides support for creating, sealing, and unsealing`
			`keys in the kernel. Trusted keys are random number symmetric keys,`
			`generated and RSA-sealed by the TPM. The TPM only unseals the keys,`
			`if the boot PCRs and other criteria match. Userspace will only ever`
			`see encrypted blobs.`

			`If you are unsure as to whether this is required, answer N.`

			`config ENCRYPTED_KEYS`
			`tristate "ENCRYPTED KEYS"`
			`depends on KEYS`
			`select CRYPTO`
			`select CRYPTO_HMAC`
			`select CRYPTO_AES`
			`select CRYPTO_CBC`
			`select CRYPTO_SHA256`
			`select CRYPTO_RNG`
			`help`
			`This option provides support for create/encrypting/decrypting keys`
			`in the kernel. Encrypted keys are kernel generated random numbers,`
			`which are encrypted/decrypted with a 'master' symmetric key. The`
			`'master' key can be either a trusted-key or user-key type.`
			`Userspace only ever sees/stores encrypted blobs.`

			`If you are unsure as to whether this is required, answer N.`
KEYS: Add KEYCTL_DH_COMPUTE command This adds userspace access to Diffie-Hellman computations through a new keyctl() syscall command to calculate shared secrets or public keys using input parameters stored in the keyring. Input key ids are provided in a struct due to the current 5-arg limit for the keyctl syscall. Only user keys are supported in order to avoid exposing the content of logon or encrypted keys. The output is written to the provided buffer, based on the assumption that the values are only needed in userspace. Future support for other types of key derivation would involve a new command, like KEYCTL_ECDH_COMPUTE. Once Diffie-Hellman support is included in the crypto API, this code can be converted to use the crypto API to take advantage of possible hardware acceleration and reduce redundant code. Signed-off-by: Mat Martineau <mathew.j.martineau@linux.intel.com> Signed-off-by: David Howells <dhowells@redhat.com> 2016-04-12 12:54:58 -06:00
			`config KEY_DH_OPERATIONS`
			`bool "Diffie-Hellman operations on retained keys"`
			`depends on KEYS`
keys: select CONFIG_CRYPTO when selecting DH / KDF Select CONFIG_CRYPTO in addition to CONFIG_HASH to ensure that also CONFIG_HASH2 is selected. Both are needed for the shash cipher support required for the KDF operation. Signed-off-by: Stephan Mueller <smueller@chronox.de> Signed-off-by: David Howells <dhowells@redhat.com> 2017-04-11 05:07:07 -06:00			`select CRYPTO`
KEYS: add SP800-56A KDF support for DH SP800-56A defines the use of DH with key derivation function based on a counter. The input to the KDF is defined as (DH shared secret \|\| other information). The value for the "other information" is to be provided by the caller. The KDF is implemented using the hash support from the kernel crypto API. The implementation uses the symmetric hash support as the input to the hash operation is usually very small. The caller is allowed to specify the hash name that he wants to use to derive the key material allowing the use of all supported hashes provided with the kernel crypto API. As the KDF implements the proper truncation of the DH shared secret to the requested size, this patch fills the caller buffer up to its size. The patch is tested with a new test added to the keyutils user space code which uses a CAVS test vector testing the compliance with SP800-56A. Signed-off-by: Stephan Mueller <smueller@chronox.de> Signed-off-by: David Howells <dhowells@redhat.com> 2016-08-19 12:39:09 -06:00			`select CRYPTO_HASH`
KEYS: Convert KEYCTL_DH_COMPUTE to use the crypto KPP API The initial Diffie-Hellman computation made direct use of the MPI library because the crypto module did not support DH at the time. Now that KPP is implemented, KEYCTL_DH_COMPUTE should use it to get rid of duplicate code and leverage possible hardware acceleration. This fixes an issue whereby the input to the KDF computation would include additional uninitialized memory when the result of the Diffie-Hellman computation was shorter than the input prime number. Signed-off-by: Mat Martineau <mathew.j.martineau@linux.intel.com> Signed-off-by: David Howells <dhowells@redhat.com> Signed-off-by: James Morris <james.l.morris@oracle.com> 2017-06-08 07:50:11 -06:00			`select CRYPTO_DH`
KEYS: Add KEYCTL_DH_COMPUTE command This adds userspace access to Diffie-Hellman computations through a new keyctl() syscall command to calculate shared secrets or public keys using input parameters stored in the keyring. Input key ids are provided in a struct due to the current 5-arg limit for the keyctl syscall. Only user keys are supported in order to avoid exposing the content of logon or encrypted keys. The output is written to the provided buffer, based on the assumption that the values are only needed in userspace. Future support for other types of key derivation would involve a new command, like KEYCTL_ECDH_COMPUTE. Once Diffie-Hellman support is included in the crypto API, this code can be converted to use the crypto API to take advantage of possible hardware acceleration and reduce redundant code. Signed-off-by: Mat Martineau <mathew.j.martineau@linux.intel.com> Signed-off-by: David Howells <dhowells@redhat.com> 2016-04-12 12:54:58 -06:00			`help`
			`This option provides support for calculating Diffie-Hellman`
			`public keys and shared secrets using values stored as keys`
			`in the kernel.`

			`If you are unsure as to whether this is required, answer N.`