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Modify the documentation to match the actual parameter as implemented in kernel/module.c:273. Signed-off-by: James Johnston <johnstonj.public@codenest.com> Reviewed-by: David Howells <dhowells@redhat.com> Signed-off-by: Jonathan Corbet <corbet@lwn.net>
274 lines
10 KiB
Plaintext
274 lines
10 KiB
Plaintext
==============================
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KERNEL MODULE SIGNING FACILITY
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==============================
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CONTENTS
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- Overview.
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- Configuring module signing.
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- Generating signing keys.
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- Public keys in the kernel.
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- Manually signing modules.
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- Signed modules and stripping.
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- Loading signed modules.
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- Non-valid signatures and unsigned modules.
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- Administering/protecting the private key.
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========
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OVERVIEW
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========
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The kernel module signing facility cryptographically signs modules during
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installation and then checks the signature upon loading the module. This
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allows increased kernel security by disallowing the loading of unsigned modules
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or modules signed with an invalid key. Module signing increases security by
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making it harder to load a malicious module into the kernel. The module
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signature checking is done by the kernel so that it is not necessary to have
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trusted userspace bits.
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This facility uses X.509 ITU-T standard certificates to encode the public keys
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involved. The signatures are not themselves encoded in any industrial standard
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type. The facility currently only supports the RSA public key encryption
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standard (though it is pluggable and permits others to be used). The possible
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hash algorithms that can be used are SHA-1, SHA-224, SHA-256, SHA-384, and
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SHA-512 (the algorithm is selected by data in the signature).
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==========================
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CONFIGURING MODULE SIGNING
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==========================
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The module signing facility is enabled by going to the "Enable Loadable Module
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Support" section of the kernel configuration and turning on
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CONFIG_MODULE_SIG "Module signature verification"
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This has a number of options available:
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(1) "Require modules to be validly signed" (CONFIG_MODULE_SIG_FORCE)
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This specifies how the kernel should deal with a module that has a
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signature for which the key is not known or a module that is unsigned.
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If this is off (ie. "permissive"), then modules for which the key is not
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available and modules that are unsigned are permitted, but the kernel will
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be marked as being tainted, and the concerned modules will be marked as
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tainted, shown with the character 'E'.
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If this is on (ie. "restrictive"), only modules that have a valid
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signature that can be verified by a public key in the kernel's possession
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will be loaded. All other modules will generate an error.
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Irrespective of the setting here, if the module has a signature block that
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cannot be parsed, it will be rejected out of hand.
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(2) "Automatically sign all modules" (CONFIG_MODULE_SIG_ALL)
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If this is on then modules will be automatically signed during the
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modules_install phase of a build. If this is off, then the modules must
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be signed manually using:
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scripts/sign-file
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(3) "Which hash algorithm should modules be signed with?"
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This presents a choice of which hash algorithm the installation phase will
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sign the modules with:
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CONFIG_MODULE_SIG_SHA1 "Sign modules with SHA-1"
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CONFIG_MODULE_SIG_SHA224 "Sign modules with SHA-224"
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CONFIG_MODULE_SIG_SHA256 "Sign modules with SHA-256"
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CONFIG_MODULE_SIG_SHA384 "Sign modules with SHA-384"
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CONFIG_MODULE_SIG_SHA512 "Sign modules with SHA-512"
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The algorithm selected here will also be built into the kernel (rather
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than being a module) so that modules signed with that algorithm can have
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their signatures checked without causing a dependency loop.
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(4) "File name or PKCS#11 URI of module signing key" (CONFIG_MODULE_SIG_KEY)
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Setting this option to something other than its default of
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"certs/signing_key.pem" will disable the autogeneration of signing keys
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and allow the kernel modules to be signed with a key of your choosing.
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The string provided should identify a file containing both a private key
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and its corresponding X.509 certificate in PEM form, or — on systems where
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the OpenSSL ENGINE_pkcs11 is functional — a PKCS#11 URI as defined by
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RFC7512. In the latter case, the PKCS#11 URI should reference both a
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certificate and a private key.
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If the PEM file containing the private key is encrypted, or if the
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PKCS#11 token requries a PIN, this can be provided at build time by
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means of the KBUILD_SIGN_PIN variable.
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(5) "Additional X.509 keys for default system keyring" (CONFIG_SYSTEM_TRUSTED_KEYS)
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This option can be set to the filename of a PEM-encoded file containing
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additional certificates which will be included in the system keyring by
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default.
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Note that enabling module signing adds a dependency on the OpenSSL devel
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packages to the kernel build processes for the tool that does the signing.
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=======================
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GENERATING SIGNING KEYS
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=======================
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Cryptographic keypairs are required to generate and check signatures. A
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private key is used to generate a signature and the corresponding public key is
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used to check it. The private key is only needed during the build, after which
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it can be deleted or stored securely. The public key gets built into the
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kernel so that it can be used to check the signatures as the modules are
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loaded.
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Under normal conditions, when CONFIG_MODULE_SIG_KEY is unchanged from its
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default, the kernel build will automatically generate a new keypair using
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openssl if one does not exist in the file:
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certs/signing_key.pem
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during the building of vmlinux (the public part of the key needs to be built
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into vmlinux) using parameters in the:
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certs/x509.genkey
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file (which is also generated if it does not already exist).
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It is strongly recommended that you provide your own x509.genkey file.
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Most notably, in the x509.genkey file, the req_distinguished_name section
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should be altered from the default:
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[ req_distinguished_name ]
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#O = Unspecified company
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CN = Build time autogenerated kernel key
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#emailAddress = unspecified.user@unspecified.company
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The generated RSA key size can also be set with:
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[ req ]
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default_bits = 4096
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It is also possible to manually generate the key private/public files using the
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x509.genkey key generation configuration file in the root node of the Linux
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kernel sources tree and the openssl command. The following is an example to
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generate the public/private key files:
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openssl req -new -nodes -utf8 -sha256 -days 36500 -batch -x509 \
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-config x509.genkey -outform PEM -out kernel_key.pem \
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-keyout kernel_key.pem
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The full pathname for the resulting kernel_key.pem file can then be specified
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in the CONFIG_MODULE_SIG_KEY option, and the certificate and key therein will
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be used instead of an autogenerated keypair.
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=========================
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PUBLIC KEYS IN THE KERNEL
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=========================
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The kernel contains a ring of public keys that can be viewed by root. They're
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in a keyring called ".system_keyring" that can be seen by:
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[root@deneb ~]# cat /proc/keys
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...
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223c7853 I------ 1 perm 1f030000 0 0 keyring .system_keyring: 1
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302d2d52 I------ 1 perm 1f010000 0 0 asymmetri Fedora kernel signing key: d69a84e6bce3d216b979e9505b3e3ef9a7118079: X509.RSA a7118079 []
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...
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Beyond the public key generated specifically for module signing, additional
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trusted certificates can be provided in a PEM-encoded file referenced by the
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CONFIG_SYSTEM_TRUSTED_KEYS configuration option.
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Further, the architecture code may take public keys from a hardware store and
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add those in also (e.g. from the UEFI key database).
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Finally, it is possible to add additional public keys by doing:
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keyctl padd asymmetric "" [.system_keyring-ID] <[key-file]
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e.g.:
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keyctl padd asymmetric "" 0x223c7853 <my_public_key.x509
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Note, however, that the kernel will only permit keys to be added to
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.system_keyring _if_ the new key's X.509 wrapper is validly signed by a key
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that is already resident in the .system_keyring at the time the key was added.
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=========================
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MANUALLY SIGNING MODULES
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=========================
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To manually sign a module, use the scripts/sign-file tool available in
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the Linux kernel source tree. The script requires 4 arguments:
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1. The hash algorithm (e.g., sha256)
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2. The private key filename or PKCS#11 URI
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3. The public key filename
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4. The kernel module to be signed
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The following is an example to sign a kernel module:
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scripts/sign-file sha512 kernel-signkey.priv \
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kernel-signkey.x509 module.ko
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The hash algorithm used does not have to match the one configured, but if it
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doesn't, you should make sure that hash algorithm is either built into the
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kernel or can be loaded without requiring itself.
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If the private key requires a passphrase or PIN, it can be provided in the
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$KBUILD_SIGN_PIN environment variable.
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============================
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SIGNED MODULES AND STRIPPING
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============================
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A signed module has a digital signature simply appended at the end. The string
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"~Module signature appended~." at the end of the module's file confirms that a
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signature is present but it does not confirm that the signature is valid!
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Signed modules are BRITTLE as the signature is outside of the defined ELF
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container. Thus they MAY NOT be stripped once the signature is computed and
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attached. Note the entire module is the signed payload, including any and all
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debug information present at the time of signing.
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======================
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LOADING SIGNED MODULES
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======================
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Modules are loaded with insmod, modprobe, init_module() or finit_module(),
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exactly as for unsigned modules as no processing is done in userspace. The
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signature checking is all done within the kernel.
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=========================================
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NON-VALID SIGNATURES AND UNSIGNED MODULES
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=========================================
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If CONFIG_MODULE_SIG_FORCE is enabled or module.sig_enforce=1 is supplied on
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the kernel command line, the kernel will only load validly signed modules
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for which it has a public key. Otherwise, it will also load modules that are
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unsigned. Any module for which the kernel has a key, but which proves to have
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a signature mismatch will not be permitted to load.
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Any module that has an unparseable signature will be rejected.
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=========================================
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ADMINISTERING/PROTECTING THE PRIVATE KEY
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=========================================
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Since the private key is used to sign modules, viruses and malware could use
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the private key to sign modules and compromise the operating system. The
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private key must be either destroyed or moved to a secure location and not kept
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in the root node of the kernel source tree.
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