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https://github.com/AsahiLinux/u-boot
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e0f2f15534
Remove the verified boot limitation that only allows a single RSA public exponent of 65537 (F4). This change allows use with existing PKI infrastructure and has been tested with HSM-based PKI. Change the configuration OF tree format to store the RSA public exponent as a 64 bit integer and implement backward compatibility for verified boot configuration trees without this extra field. Parameterise vboot_test.sh to test different public exponents. Mathematics and other hard work by Andrew Bott. Tested with the following public exponents: 3, 5, 17, 257, 39981, 50457, 65537 and 4294967297. Signed-off-by: Andrew Bott <Andrew.Bott@ipaccess.com> Signed-off-by: Andrew Wishart <Andrew.Wishart@ipaccess.com> Signed-off-by: Neil Piercy <Neil.Piercy@ipaccess.com> Signed-off-by: Michael van der Westhuizen <michael@smart-africa.com> Cc: Simon Glass <sjg@chromium.org>
408 lines
12 KiB
Text
408 lines
12 KiB
Text
U-Boot FIT Signature Verification
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=================================
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Introduction
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------------
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FIT supports hashing of images so that these hashes can be checked on
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loading. This protects against corruption of the image. However it does not
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prevent the substitution of one image for another.
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The signature feature allows the hash to be signed with a private key such
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that it can be verified using a public key later. Provided that the private
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key is kept secret and the public key is stored in a non-volatile place,
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any image can be verified in this way.
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See verified-boot.txt for more general information on verified boot.
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Concepts
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--------
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Some familiarity with public key cryptography is assumed in this section.
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The procedure for signing is as follows:
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- hash an image in the FIT
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- sign the hash with a private key to produce a signature
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- store the resulting signature in the FIT
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The procedure for verification is:
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- read the FIT
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- obtain the public key
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- extract the signature from the FIT
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- hash the image from the FIT
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- verify (with the public key) that the extracted signature matches the
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hash
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The signing is generally performed by mkimage, as part of making a firmware
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image for the device. The verification is normally done in U-Boot on the
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device.
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Algorithms
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----------
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In principle any suitable algorithm can be used to sign and verify a hash.
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At present only one class of algorithms is supported: SHA1 hashing with RSA.
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This works by hashing the image to produce a 20-byte hash.
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While it is acceptable to bring in large cryptographic libraries such as
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openssl on the host side (e.g. mkimage), it is not desirable for U-Boot.
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For the run-time verification side, it is important to keep code and data
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size as small as possible.
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For this reason the RSA image verification uses pre-processed public keys
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which can be used with a very small amount of code - just some extraction
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of data from the FDT and exponentiation mod n. Code size impact is a little
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under 5KB on Tegra Seaboard, for example.
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It is relatively straightforward to add new algorithms if required. If
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another RSA variant is needed, then it can be added to the table in
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image-sig.c. If another algorithm is needed (such as DSA) then it can be
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placed alongside rsa.c, and its functions added to the table in image-sig.c
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also.
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Creating an RSA key and certificate
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-----------------------------------
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To create a new public key, size 2048 bits:
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$ openssl genpkey -algorithm RSA -out keys/dev.key \
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-pkeyopt rsa_keygen_bits:2048 -pkeyopt rsa_keygen_pubexp:65537
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To create a certificate for this:
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$ openssl req -batch -new -x509 -key keys/dev.key -out keys/dev.crt
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If you like you can look at the public key also:
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$ openssl rsa -in keys/dev.key -pubout
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Device Tree Bindings
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--------------------
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The following properties are required in the FIT's signature node(s) to
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allow thes signer to operate. These should be added to the .its file.
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Signature nodes sit at the same level as hash nodes and are called
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signature@1, signature@2, etc.
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- algo: Algorithm name (e.g. "sha1,rs2048")
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- key-name-hint: Name of key to use for signing. The keys will normally be in
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a single directory (parameter -k to mkimage). For a given key <name>, its
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private key is stored in <name>.key and the certificate is stored in
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<name>.crt.
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When the image is signed, the following properties are added (mandatory):
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- value: The signature data (e.g. 256 bytes for 2048-bit RSA)
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When the image is signed, the following properties are optional:
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- timestamp: Time when image was signed (standard Unix time_t format)
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- signer-name: Name of the signer (e.g. "mkimage")
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- signer-version: Version string of the signer (e.g. "2013.01")
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- comment: Additional information about the signer or image
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For config bindings (see Signed Configurations below), the following
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additional properties are optional:
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- sign-images: A list of images to sign, each being a property of the conf
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node that contains then. The default is "kernel,fdt" which means that these
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two images will be looked up in the config and signed if present.
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For config bindings, these properties are added by the signer:
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- hashed-nodes: A list of nodes which were hashed by the signer. Each is
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a string - the full path to node. A typical value might be:
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hashed-nodes = "/", "/configurations/conf@1", "/images/kernel@1",
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"/images/kernel@1/hash@1", "/images/fdt@1",
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"/images/fdt@1/hash@1";
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- hashed-strings: The start and size of the string region of the FIT that
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was hashed
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Example: See sign-images.its for an example image tree source file and
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sign-configs.its for config signing.
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Public Key Storage
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------------------
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In order to verify an image that has been signed with a public key we need to
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have a trusted public key. This cannot be stored in the signed image, since
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it would be easy to alter. For this implementation we choose to store the
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public key in U-Boot's control FDT (using CONFIG_OF_CONTROL).
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Public keys should be stored as sub-nodes in a /signature node. Required
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properties are:
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- algo: Algorithm name (e.g. "sha1,rs2048")
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Optional properties are:
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- key-name-hint: Name of key used for signing. This is only a hint since it
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is possible for the name to be changed. Verification can proceed by checking
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all available signing keys until one matches.
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- required: If present this indicates that the key must be verified for the
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image / configuration to be considered valid. Only required keys are
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normally verified by the FIT image booting algorithm. Valid values are
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"image" to force verification of all images, and "conf" to force verfication
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of the selected configuration (which then relies on hashes in the images to
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verify those).
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Each signing algorithm has its own additional properties.
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For RSA the following are mandatory:
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- rsa,num-bits: Number of key bits (e.g. 2048)
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- rsa,modulus: Modulus (N) as a big-endian multi-word integer
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- rsa,exponent: Public exponent (E) as a 64 bit unsigned integer
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- rsa,r-squared: (2^num-bits)^2 as a big-endian multi-word integer
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- rsa,n0-inverse: -1 / modulus[0] mod 2^32
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Signed Configurations
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---------------------
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While signing images is useful, it does not provide complete protection
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against several types of attack. For example, it it possible to create a
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FIT with the same signed images, but with the configuration changed such
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that a different one is selected (mix and match attack). It is also possible
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to substitute a signed image from an older FIT version into a newer FIT
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(roll-back attack).
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As an example, consider this FIT:
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/ {
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images {
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kernel@1 {
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data = <data for kernel1>
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signature@1 {
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algo = "sha1,rsa2048";
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value = <...kernel signature 1...>
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};
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};
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kernel@2 {
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data = <data for kernel2>
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signature@1 {
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algo = "sha1,rsa2048";
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value = <...kernel signature 2...>
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};
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};
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fdt@1 {
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data = <data for fdt1>;
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signature@1 {
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algo = "sha1,rsa2048";
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vaue = <...fdt signature 1...>
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};
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};
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fdt@2 {
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data = <data for fdt2>;
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signature@1 {
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algo = "sha1,rsa2048";
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vaue = <...fdt signature 2...>
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};
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};
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};
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configurations {
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default = "conf@1";
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conf@1 {
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kernel = "kernel@1";
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fdt = "fdt@1";
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};
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conf@1 {
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kernel = "kernel@2";
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fdt = "fdt@2";
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};
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};
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};
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Since both kernels are signed it is easy for an attacker to add a new
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configuration 3 with kernel 1 and fdt 2:
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configurations {
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default = "conf@1";
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conf@1 {
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kernel = "kernel@1";
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fdt = "fdt@1";
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};
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conf@1 {
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kernel = "kernel@2";
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fdt = "fdt@2";
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};
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conf@3 {
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kernel = "kernel@1";
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fdt = "fdt@2";
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};
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};
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With signed images, nothing protects against this. Whether it gains an
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advantage for the attacker is debatable, but it is not secure.
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To solved this problem, we support signed configurations. In this case it
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is the configurations that are signed, not the image. Each image has its
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own hash, and we include the hash in the configuration signature.
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So the above example is adjusted to look like this:
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/ {
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images {
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kernel@1 {
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data = <data for kernel1>
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hash@1 {
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algo = "sha1";
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value = <...kernel hash 1...>
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};
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};
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kernel@2 {
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data = <data for kernel2>
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hash@1 {
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algo = "sha1";
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value = <...kernel hash 2...>
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};
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};
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fdt@1 {
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data = <data for fdt1>;
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hash@1 {
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algo = "sha1";
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value = <...fdt hash 1...>
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};
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};
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fdt@2 {
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data = <data for fdt2>;
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hash@1 {
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algo = "sha1";
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value = <...fdt hash 2...>
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};
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};
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};
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configurations {
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default = "conf@1";
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conf@1 {
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kernel = "kernel@1";
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fdt = "fdt@1";
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signature@1 {
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algo = "sha1,rsa2048";
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value = <...conf 1 signature...>;
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};
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};
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conf@2 {
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kernel = "kernel@2";
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fdt = "fdt@2";
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signature@1 {
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algo = "sha1,rsa2048";
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value = <...conf 1 signature...>;
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};
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};
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};
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};
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You can see that we have added hashes for all images (since they are no
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longer signed), and a signature to each configuration. In the above example,
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mkimage will sign configurations/conf@1, the kernel and fdt that are
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pointed to by the configuration (/images/kernel@1, /images/kernel@1/hash@1,
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/images/fdt@1, /images/fdt@1/hash@1) and the root structure of the image
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(so that it isn't possible to add or remove root nodes). The signature is
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written into /configurations/conf@1/signature@1/value. It can easily be
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verified later even if the FIT has been signed with other keys in the
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meantime.
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Verification
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------------
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FITs are verified when loaded. After the configuration is selected a list
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of required images is produced. If there are 'required' public keys, then
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each image must be verified against those keys. This means that every image
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that might be used by the target needs to be signed with 'required' keys.
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This happens automatically as part of a bootm command when FITs are used.
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Enabling FIT Verification
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-------------------------
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In addition to the options to enable FIT itself, the following CONFIGs must
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be enabled:
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CONFIG_FIT_SIGNATURE - enable signing and verfication in FITs
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CONFIG_RSA - enable RSA algorithm for signing
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WARNING: When relying on signed FIT images with required signature check
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the legacy image format is default disabled by not defining
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CONFIG_IMAGE_FORMAT_LEGACY
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Testing
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-------
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An easy way to test signing and verfication is to use the test script
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provided in test/vboot/vboot_test.sh. This uses sandbox (a special version
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of U-Boot which runs under Linux) to show the operation of a 'bootm'
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command loading and verifying images.
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A sample run is show below:
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$ make O=sandbox sandbox_config
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$ make O=sandbox
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$ O=sandbox ./test/vboot/vboot_test.sh
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Simple Verified Boot Test
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=========================
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Please see doc/uImage.FIT/verified-boot.txt for more information
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/home/hs/ids/u-boot/sandbox/tools/mkimage -D -I dts -O dtb -p 2000
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Build keys
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do sha1 test
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Build FIT with signed images
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Test Verified Boot Run: unsigned signatures:: OK
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Sign images
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Test Verified Boot Run: signed images: OK
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Build FIT with signed configuration
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Test Verified Boot Run: unsigned config: OK
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Sign images
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Test Verified Boot Run: signed config: OK
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check signed config on the host
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Signature check OK
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OK
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Test Verified Boot Run: signed config: OK
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Test Verified Boot Run: signed config with bad hash: OK
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do sha256 test
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Build FIT with signed images
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Test Verified Boot Run: unsigned signatures:: OK
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Sign images
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Test Verified Boot Run: signed images: OK
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Build FIT with signed configuration
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Test Verified Boot Run: unsigned config: OK
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Sign images
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Test Verified Boot Run: signed config: OK
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check signed config on the host
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Signature check OK
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OK
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Test Verified Boot Run: signed config: OK
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Test Verified Boot Run: signed config with bad hash: OK
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Test passed
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Future Work
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-----------
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- Roll-back protection using a TPM is done using the tpm command. This can
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be scripted, but we might consider a default way of doing this, built into
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bootm.
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Possible Future Work
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--------------------
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- Add support for other RSA/SHA variants, such as rsa4096,sha512.
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- Other algorithms besides RSA
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- More sandbox tests for failure modes
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- Passwords for keys/certificates
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- Perhaps implement OAEP
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- Enhance bootm to permit scripted signature verification (so that a script
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can verify an image but not actually boot it)
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Simon Glass
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sjg@chromium.org
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1-1-13
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