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This file is almost compatible with ReST. Just minor changes were needed: - Adjust document and titles markups; - Adjust numbered list markups; - Add a comments markup for the Contents section; - Add markups for literal blocks. Acked-by: Jarkko Sakkinen <jarkko.sakkinen@linux.intel.com> Signed-off-by: Mauro Carvalho Chehab <mchehab+huawei@kernel.org> Link: https://lore.kernel.org/r/c2275ea94e0507a01b020ab66dfa824d8b1c2545.1592203650.git.mchehab+huawei@kernel.org Signed-off-by: Jonathan Corbet <corbet@lwn.net>
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425 lines
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.. SPDX-License-Identifier: GPL-2.0
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=============================================
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Asymmetric / Public-key Cryptography Key Type
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=============================================
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.. Contents:
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- Overview.
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- Key identification.
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- Accessing asymmetric keys.
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- Signature verification.
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- Asymmetric key subtypes.
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- Instantiation data parsers.
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- Keyring link restrictions.
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Overview
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========
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The "asymmetric" key type is designed to be a container for the keys used in
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public-key cryptography, without imposing any particular restrictions on the
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form or mechanism of the cryptography or form of the key.
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The asymmetric key is given a subtype that defines what sort of data is
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associated with the key and provides operations to describe and destroy it.
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However, no requirement is made that the key data actually be stored in the
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key.
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A completely in-kernel key retention and operation subtype can be defined, but
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it would also be possible to provide access to cryptographic hardware (such as
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a TPM) that might be used to both retain the relevant key and perform
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operations using that key. In such a case, the asymmetric key would then
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merely be an interface to the TPM driver.
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Also provided is the concept of a data parser. Data parsers are responsible
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for extracting information from the blobs of data passed to the instantiation
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function. The first data parser that recognises the blob gets to set the
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subtype of the key and define the operations that can be done on that key.
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A data parser may interpret the data blob as containing the bits representing a
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key, or it may interpret it as a reference to a key held somewhere else in the
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system (for example, a TPM).
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Key Identification
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==================
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If a key is added with an empty name, the instantiation data parsers are given
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the opportunity to pre-parse a key and to determine the description the key
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should be given from the content of the key.
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This can then be used to refer to the key, either by complete match or by
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partial match. The key type may also use other criteria to refer to a key.
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The asymmetric key type's match function can then perform a wider range of
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comparisons than just the straightforward comparison of the description with
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the criterion string:
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1) If the criterion string is of the form "id:<hexdigits>" then the match
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function will examine a key's fingerprint to see if the hex digits given
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after the "id:" match the tail. For instance::
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keyctl search @s asymmetric id:5acc2142
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will match a key with fingerprint::
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1A00 2040 7601 7889 DE11 882C 3823 04AD 5ACC 2142
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2) If the criterion string is of the form "<subtype>:<hexdigits>" then the
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match will match the ID as in (1), but with the added restriction that
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only keys of the specified subtype (e.g. tpm) will be matched. For
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instance::
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keyctl search @s asymmetric tpm:5acc2142
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Looking in /proc/keys, the last 8 hex digits of the key fingerprint are
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displayed, along with the subtype::
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1a39e171 I----- 1 perm 3f010000 0 0 asymmetric modsign.0: DSA 5acc2142 []
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Accessing Asymmetric Keys
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=========================
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For general access to asymmetric keys from within the kernel, the following
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inclusion is required::
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#include <crypto/public_key.h>
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This gives access to functions for dealing with asymmetric / public keys.
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Three enums are defined there for representing public-key cryptography
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algorithms::
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enum pkey_algo
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digest algorithms used by those::
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enum pkey_hash_algo
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and key identifier representations::
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enum pkey_id_type
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Note that the key type representation types are required because key
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identifiers from different standards aren't necessarily compatible. For
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instance, PGP generates key identifiers by hashing the key data plus some
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PGP-specific metadata, whereas X.509 has arbitrary certificate identifiers.
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The operations defined upon a key are:
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1) Signature verification.
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Other operations are possible (such as encryption) with the same key data
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required for verification, but not currently supported, and others
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(eg. decryption and signature generation) require extra key data.
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Signature Verification
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----------------------
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An operation is provided to perform cryptographic signature verification, using
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an asymmetric key to provide or to provide access to the public key::
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int verify_signature(const struct key *key,
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const struct public_key_signature *sig);
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The caller must have already obtained the key from some source and can then use
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it to check the signature. The caller must have parsed the signature and
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transferred the relevant bits to the structure pointed to by sig::
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struct public_key_signature {
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u8 *digest;
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u8 digest_size;
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enum pkey_hash_algo pkey_hash_algo : 8;
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u8 nr_mpi;
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union {
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MPI mpi[2];
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...
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};
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};
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The algorithm used must be noted in sig->pkey_hash_algo, and all the MPIs that
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make up the actual signature must be stored in sig->mpi[] and the count of MPIs
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placed in sig->nr_mpi.
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In addition, the data must have been digested by the caller and the resulting
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hash must be pointed to by sig->digest and the size of the hash be placed in
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sig->digest_size.
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The function will return 0 upon success or -EKEYREJECTED if the signature
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doesn't match.
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The function may also return -ENOTSUPP if an unsupported public-key algorithm
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or public-key/hash algorithm combination is specified or the key doesn't
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support the operation; -EBADMSG or -ERANGE if some of the parameters have weird
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data; or -ENOMEM if an allocation can't be performed. -EINVAL can be returned
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if the key argument is the wrong type or is incompletely set up.
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Asymmetric Key Subtypes
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=======================
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Asymmetric keys have a subtype that defines the set of operations that can be
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performed on that key and that determines what data is attached as the key
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payload. The payload format is entirely at the whim of the subtype.
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The subtype is selected by the key data parser and the parser must initialise
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the data required for it. The asymmetric key retains a reference on the
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subtype module.
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The subtype definition structure can be found in::
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#include <keys/asymmetric-subtype.h>
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and looks like the following::
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struct asymmetric_key_subtype {
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struct module *owner;
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const char *name;
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void (*describe)(const struct key *key, struct seq_file *m);
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void (*destroy)(void *payload);
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int (*query)(const struct kernel_pkey_params *params,
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struct kernel_pkey_query *info);
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int (*eds_op)(struct kernel_pkey_params *params,
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const void *in, void *out);
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int (*verify_signature)(const struct key *key,
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const struct public_key_signature *sig);
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};
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Asymmetric keys point to this with their payload[asym_subtype] member.
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The owner and name fields should be set to the owning module and the name of
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the subtype. Currently, the name is only used for print statements.
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There are a number of operations defined by the subtype:
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1) describe().
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Mandatory. This allows the subtype to display something in /proc/keys
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against the key. For instance the name of the public key algorithm type
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could be displayed. The key type will display the tail of the key
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identity string after this.
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2) destroy().
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Mandatory. This should free the memory associated with the key. The
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asymmetric key will look after freeing the fingerprint and releasing the
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reference on the subtype module.
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3) query().
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Mandatory. This is a function for querying the capabilities of a key.
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4) eds_op().
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Optional. This is the entry point for the encryption, decryption and
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signature creation operations (which are distinguished by the operation ID
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in the parameter struct). The subtype may do anything it likes to
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implement an operation, including offloading to hardware.
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5) verify_signature().
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Optional. This is the entry point for signature verification. The
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subtype may do anything it likes to implement an operation, including
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offloading to hardware.
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Instantiation Data Parsers
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==========================
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The asymmetric key type doesn't generally want to store or to deal with a raw
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blob of data that holds the key data. It would have to parse it and error
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check it each time it wanted to use it. Further, the contents of the blob may
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have various checks that can be performed on it (eg. self-signatures, validity
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dates) and may contain useful data about the key (identifiers, capabilities).
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Also, the blob may represent a pointer to some hardware containing the key
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rather than the key itself.
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Examples of blob formats for which parsers could be implemented include:
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- OpenPGP packet stream [RFC 4880].
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- X.509 ASN.1 stream.
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- Pointer to TPM key.
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- Pointer to UEFI key.
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- PKCS#8 private key [RFC 5208].
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- PKCS#5 encrypted private key [RFC 2898].
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During key instantiation each parser in the list is tried until one doesn't
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return -EBADMSG.
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The parser definition structure can be found in::
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#include <keys/asymmetric-parser.h>
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and looks like the following::
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struct asymmetric_key_parser {
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struct module *owner;
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const char *name;
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int (*parse)(struct key_preparsed_payload *prep);
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};
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The owner and name fields should be set to the owning module and the name of
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the parser.
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There is currently only a single operation defined by the parser, and it is
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mandatory:
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1) parse().
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This is called to preparse the key from the key creation and update paths.
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In particular, it is called during the key creation _before_ a key is
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allocated, and as such, is permitted to provide the key's description in
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the case that the caller declines to do so.
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The caller passes a pointer to the following struct with all of the fields
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cleared, except for data, datalen and quotalen [see
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Documentation/security/keys/core.rst]::
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struct key_preparsed_payload {
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char *description;
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void *payload[4];
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const void *data;
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size_t datalen;
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size_t quotalen;
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};
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The instantiation data is in a blob pointed to by data and is datalen in
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size. The parse() function is not permitted to change these two values at
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all, and shouldn't change any of the other values _unless_ they are
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recognise the blob format and will not return -EBADMSG to indicate it is
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not theirs.
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If the parser is happy with the blob, it should propose a description for
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the key and attach it to ->description, ->payload[asym_subtype] should be
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set to point to the subtype to be used, ->payload[asym_crypto] should be
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set to point to the initialised data for that subtype,
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->payload[asym_key_ids] should point to one or more hex fingerprints and
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quotalen should be updated to indicate how much quota this key should
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account for.
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When clearing up, the data attached to ->payload[asym_key_ids] and
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->description will be kfree()'d and the data attached to
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->payload[asm_crypto] will be passed to the subtype's ->destroy() method
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to be disposed of. A module reference for the subtype pointed to by
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->payload[asym_subtype] will be put.
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If the data format is not recognised, -EBADMSG should be returned. If it
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is recognised, but the key cannot for some reason be set up, some other
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negative error code should be returned. On success, 0 should be returned.
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The key's fingerprint string may be partially matched upon. For a
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public-key algorithm such as RSA and DSA this will likely be a printable
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hex version of the key's fingerprint.
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Functions are provided to register and unregister parsers::
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int register_asymmetric_key_parser(struct asymmetric_key_parser *parser);
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void unregister_asymmetric_key_parser(struct asymmetric_key_parser *subtype);
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Parsers may not have the same name. The names are otherwise only used for
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displaying in debugging messages.
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Keyring Link Restrictions
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=========================
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Keyrings created from userspace using add_key can be configured to check the
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signature of the key being linked. Keys without a valid signature are not
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allowed to link.
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Several restriction methods are available:
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1) Restrict using the kernel builtin trusted keyring
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- Option string used with KEYCTL_RESTRICT_KEYRING:
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- "builtin_trusted"
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The kernel builtin trusted keyring will be searched for the signing key.
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If the builtin trusted keyring is not configured, all links will be
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rejected. The ca_keys kernel parameter also affects which keys are used
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for signature verification.
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2) Restrict using the kernel builtin and secondary trusted keyrings
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- Option string used with KEYCTL_RESTRICT_KEYRING:
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- "builtin_and_secondary_trusted"
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The kernel builtin and secondary trusted keyrings will be searched for the
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signing key. If the secondary trusted keyring is not configured, this
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restriction will behave like the "builtin_trusted" option. The ca_keys
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kernel parameter also affects which keys are used for signature
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verification.
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3) Restrict using a separate key or keyring
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- Option string used with KEYCTL_RESTRICT_KEYRING:
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- "key_or_keyring:<key or keyring serial number>[:chain]"
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Whenever a key link is requested, the link will only succeed if the key
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being linked is signed by one of the designated keys. This key may be
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specified directly by providing a serial number for one asymmetric key, or
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a group of keys may be searched for the signing key by providing the
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serial number for a keyring.
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When the "chain" option is provided at the end of the string, the keys
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within the destination keyring will also be searched for signing keys.
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This allows for verification of certificate chains by adding each
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certificate in order (starting closest to the root) to a keyring. For
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instance, one keyring can be populated with links to a set of root
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certificates, with a separate, restricted keyring set up for each
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certificate chain to be validated::
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# Create and populate a keyring for root certificates
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root_id=`keyctl add keyring root-certs "" @s`
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keyctl padd asymmetric "" $root_id < root1.cert
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keyctl padd asymmetric "" $root_id < root2.cert
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# Create and restrict a keyring for the certificate chain
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chain_id=`keyctl add keyring chain "" @s`
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keyctl restrict_keyring $chain_id asymmetric key_or_keyring:$root_id:chain
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# Attempt to add each certificate in the chain, starting with the
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# certificate closest to the root.
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keyctl padd asymmetric "" $chain_id < intermediateA.cert
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keyctl padd asymmetric "" $chain_id < intermediateB.cert
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keyctl padd asymmetric "" $chain_id < end-entity.cert
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If the final end-entity certificate is successfully added to the "chain"
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keyring, we can be certain that it has a valid signing chain going back to
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one of the root certificates.
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A single keyring can be used to verify a chain of signatures by
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restricting the keyring after linking the root certificate::
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# Create a keyring for the certificate chain and add the root
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chain2_id=`keyctl add keyring chain2 "" @s`
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keyctl padd asymmetric "" $chain2_id < root1.cert
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# Restrict the keyring that already has root1.cert linked. The cert
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# will remain linked by the keyring.
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keyctl restrict_keyring $chain2_id asymmetric key_or_keyring:0:chain
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# Attempt to add each certificate in the chain, starting with the
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# certificate closest to the root.
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keyctl padd asymmetric "" $chain2_id < intermediateA.cert
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keyctl padd asymmetric "" $chain2_id < intermediateB.cert
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keyctl padd asymmetric "" $chain2_id < end-entity.cert
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If the final end-entity certificate is successfully added to the "chain2"
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keyring, we can be certain that there is a valid signing chain going back
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to the root certificate that was added before the keyring was restricted.
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In all of these cases, if the signing key is found the signature of the key to
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be linked will be verified using the signing key. The requested key is added
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to the keyring only if the signature is successfully verified. -ENOKEY is
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returned if the parent certificate could not be found, or -EKEYREJECTED is
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returned if the signature check fails or the key is blacklisted. Other errors
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may be returned if the signature check could not be performed.
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