The trusted boot framework on Marvell Armada 38x ================================================ Contents: 1. Overview of the trusted boot 2. Terminology 3. Boot image layout 4. The secured header 5. The secured boot flow 6. Usage example 7. Work to be done 8. Bibliography 1. Overview of the trusted boot ------------------------------- The Armada's trusted boot framework enables the SoC to cryptographically verify a specially prepared boot image. This can be used to establish a chain of trust from the boot firmware all the way to the OS. To achieve this, the Armada SoC requires a specially prepared boot image, which contains the relevant cryptographic data, as well as other information pertaining to the boot process. Furthermore, a eFuse structure (a one-time-writeable memory) need to be configured in the correct way. Roughly, the secure boot process works as follows: * Load the header block of the boot image, extract a special "root" public RSA key from it, and verify its SHA-256 hash against a SHA-256 stored in a eFuse field. * Load an array of code signing public RSA keys from the header block, and verify its RSA signature (contained in the header block as well) using the "root" RSA key. * Choose a code signing key, and use it to verify the header block (excluding the key array). * Verify the binary image's signature (contained in the header block) using the code signing key. * If all checks pass successfully, boot the image. The chain of trust is thus as follows: * The SHA-256 value in the eFuse field verifies the "root" public key. * The "root" public key verifies the code signing key array. * The selected code signing key verifies the header block and the binary image. In the special case of building a boot image containing U-Boot as the binary image, which employs this trusted boot framework, the following tasks need to be addressed: 1. Creation of the needed cryptographic key material. 2. Creation of a conforming boot image containing the U-Boot image as binary image. 3. Burning the necessary eFuse values. (1) will be addressed later, (2) will be taken care of by U-Boot's build system (some user configuration is required, though), and for (3) the necessary data (essentially a series of U-Boot commands to be entered at the U-Boot command prompt) will be created by the build system as well. The documentation of the trusted boot mode is contained in part 1, chapter 7.2.5 in the functional specification [1], and in application note [2]. 2. Terminology -------------- CSK - Code Signing Key(s): An array of RSA key pairs, which are used to sign and verify the secured header and the boot loader image. KAK - Key Authentication Key: A RSA key pair, which is used to sign and verify the array of CSKs. Header block - The first part of the boot image, which contains the image's headers (also known as "headers block", "boot header", and "image header") eFuse - A one-time-writeable memory. BootROM - The Armada's built-in boot firmware, which is responsible for verifying and starting secure images. Boot image - The complete image the SoC's boot firmware loads (contains the header block and the binary image) Main header - The header in the header block containing information and data pertaining to the boot process (used for both the regular and secured boot processes) Binary image - The binary code payload of the boot image; in this case the U-Boot's code (also known as "source image", or just "image") Secured header - The specialized header in the header block that contains information and data pertaining to the trusted boot (also known as "security header") Secured boot mode - A special boot mode of the Armada SoC in which secured images are verified (non-secure images won't boot); the mode is activated by setting a eFuse field. Trusted debug mode - A special mode for the trusted boot that allows debugging of devices employing the trusted boot framework in a secure manner (untested in the current implementation). Trusted boot framework - The ARMADA SoC's implementation of a secure verified boot process. 3. Boot image layout -------------------- +-- Boot image --------------------------------------------+ | | | +-- Header block --------------------------------------+ | | | Main header | | | +------------------------------------------------------+ | | | Secured header | | | +------------------------------------------------------+ | | | BIN header(s) | | | +------------------------------------------------------+ | | | REG header(s) | | | +------------------------------------------------------+ | | | Padding | | | +------------------------------------------------------+ | | | | +------------------------------------------------------+ | | | Binary image + checksum | | | +------------------------------------------------------+ | +----------------------------------------------------------+ 4. The secured header --------------------- For the trusted boot framework, a additional header is added to the boot image. The following data are relevant for the secure boot: KAK: The KAK is contained in the secured header in the form of a RSA-2048 public key in DER format with a length of 524 bytes. Header block signature: The RSA signature of the header block (excluding the CSK array), created using the selected CSK. Binary image signature: The RSA signature of the binary image, created using the selected CSK. CSK array: The array of the 16 CSKs as RSA-2048 public keys in DER format with a length of 8384 = 16 * 524 bytes. CSK block signature: The RSA signature of the CSK array, created using the KAK. NOTE: The JTAG delay, Box ID, and Flash ID header fields do play a role in the trusted boot process to enable and configure secure debugging, but they were not tested in the current implementation of the trusted boot in U-Boot. 5. The secured boot flow ------------------------ The steps in the boot flow that are relevant for the trusted boot framework proceed as follows: 1) Check if trusted boot is enabled, and perform regular boot if it is not. 2) Load the secured header, and verify its checksum. 3) Select the lowest valid CSK from CSK0 to CSK15. 4) Verify the SHA-256 hash of the KAK embedded in the secured header. 5) Verify the RSA signature of the CSK block from the secured header with the KAK. 6) Verify the header block signature (which excludes the CSK block) from the secured header with the selected CSK. 7) Load the binary image to the main memory and verify its checksum. 8) Verify the binary image's RSA signature from the secured header with the selected CSK. 9) Continue the boot process as in the case of the regular boot. NOTE: All RSA signatures are verified according to the PKCS #1 v2.1 standard described in [3]. NOTE: The Box ID and Flash ID are checked after step 6, and the trusted debug mode may be entered there, but since this mode is untested in the current implementation, it is not described further. 6. Usage example ---------------- ### Create key material To employ the trusted boot framework, cryptographic key material needs to be created. In the current implementation, two keys are needed to build a valid secured boot image: The KAK private key and a CSK private key (both have to be 2048 bit RSA keys in PEM format). Note that the usage of more than one CSK is currently not supported. NOTE: Since the public key can be generated from the private key, it is sufficient to store the private key for each key pair. OpenSSL can be used to generate the needed files kwb_kak.key and kwb_csk.key (the names of these files have to be configured, see the next section on kwbimage.cfg settings): openssl genrsa -out kwb_kak.key 2048 openssl genrsa -out kwb_csk.key 2048 The generated files have to be placed in the U-Boot root directory. Alternatively, instead of copying the files, symlinks to the private keys can be placed in the U-Boot root directory. WARNING: Knowledge of the KAK or CSK private key would enable an attacker to generate secured boot images containing arbitrary code. Hence, the private keys should be carefully guarded. ### Create/Modifiy kwbimage.cfg The Kirkwook architecture in U-Boot employs a special board-specific configuration file (kwbimage.cfg), which controls various boot image settings that are interpreted by the BootROM, such as the boot medium. The support the trusted boot framework, several new options were added to faciliate configuration of the secured boot. The configuration file's layout has been retained, only the following new options were added: KAK - The name of the KAK RSA private key file in the U-Boot root directory, without the trailing extension of ".key". CSK - The name of the (active) CSK RSA private key file in the U-Boot root directory, without the trailing extension of ".key". BOX_ID - The BoxID to be used for trusted debugging (a integer value). FLASH_ID - The FlashID to be used for trusted debugging (a integer value). JTAG_DELAY - The JTAG delay to be used for trusted debugging (a integer value). CSK_INDEX - The index of the active CSK (a integer value). SEC_SPECIALIZED_IMG - Flag to indicate whether to include the BoxID and FlashID in the image (that is, whether to use the trusted debug mode or not); no parameters. SEC_BOOT_DEV - The boot device from which the trusted boot is allowed to proceed, identified via a numeric ID. The tested values are 0x34 = NOR flash, 0x31 = SDIO/MMC card; for additional ID values, consult the documentation in [1]. SEC_FUSE_DUMP - Dump the "fuse prog" commands necessary for writing the correct eFuse values to a text file in the U-Boot root directory. The parameter is the architecture for which to dump the commands (currently only "a38x" is supported). The parameter values may be hardcoded into the file, but it is also possible to employ a dynamic approach of creating a Autoconf-like kwbimage.cfg.in, then reading configuration values from Kconfig options or from the board config file, and generating the actual kwbimage.cfg from this template using Makefile mechanisms (see board/gdsys/a38x/Makefile as an example for this approach). ### Set config options To enable the generation of trusted boot images, the corresponding support needs to be activated, and a index for the active CSK needs to be selected as well. Furthermore, eFuse writing support has to be activated in order to burn the eFuse structure's values (this option is just needed for programming the eFuse structure; production boot images may disable it). ARM architecture -> [*] Build image for trusted boot (0) Index of active CSK -> [*] Enable eFuse support [ ] Fake eFuse access (dry run) ### Build and test boot image The creation of the boot image is done via the usual invocation of make (with a suitably set CROSS_COMPILE environment variable, of course). The resulting boot image u-boot-spl.kwb can then be tested, if so desired. The hdrparser from [5] can be used for this purpose. To build the tool, invoke make in the 'tools/marvell/doimage_mv' directory of [5], which builds a stand-alone hdrparser executable. A test can be conducted by calling hdrparser with the produced boot image and the following (mandatory) parameters: ./hdrparser -k 0 -t u-boot-spl.kwb Here we assume that the CSK index is 0 and the boot image file resides in the same directory (adapt accordingly if needed). The tool should report that all checksums are valid ("GOOD"), that all signature verifications succeed ("PASSED"), and, finally, that the overall test was successful ("T E S T S U C C E E D E D" in the last line of output). ### Burn eFuse structure +----------------------------------------------------------+ | WARNING: Burning the eFuse structure is a irreversible | | operation! Should wrong or corrupted values be used, the | | board won't boot anymore, and recovery is likely | | impossible! | +----------------------------------------------------------+ After the build process has finished, and the SEC_FUSE_DUMP option was set in the kwbimage.cfg was set, a text file kwb_fuses_a38x.txt should be present in the U-Boot top-level directory. It contains all the necessary commands to set the eFuse structure to the values needed for the used KAK digest, as well as the CSK index, Flash ID and Box ID that were selected in kwbimage.cfg. Sequentially executing the commands in this file at the U-Boot command prompt will write these values to the eFuse structure. If the SEC_FUSE_DUMP option was not set, the commands needed to burn the fuses have to be crafted by hand. The needed fuse lines can be looked up in [1]; a rough overview of the process is: * Burn the KAK public key hash. The hash itself can be found in the file pub_kak_hash.txt in the U-Boot top-level directory; be careful to account for the endianness! * Burn the CSK selection, BoxID, and FlashID * Enable trusted boot by burning the corresponding fuse (WARNING: this must be the last fuse line written!) * Lock the unused fuse lines The command to employ is the "fuse prog" command previously enabled by setting the corresponding configuration option. For the trusted boot, the fuse prog command has a special syntax, since the ARMADA SoC demands that whole fuse lines (64 bit values) have to be written as a whole. The fuse prog command itself allows lists of 32 bit words to be written at a time, but this is translated to a series of single 32 bit write operations to the fuse line, where the individual 32 bit words are identified by a "word" counter that is increased for each write. To work around this restriction, we interpret each line to have three "words" (0-2): The first and second words are the values to be written to the fuse line, and the third is a lock flag, which is supposed to lock the fuse line when set to 1. Writes to the first and second words are memoized between function calls, and the fuse line is only really written and locked (on writing the third word) if both words were previously set, so that "incomplete" writes are prevented. An exception to this is a single write to the third word (index 2) without previously writing neither the first nor the second word, which locks the fuse line without setting any value; this is needed to lock the unused fuse lines. As an example, to write the value 0011223344556677 to fuse line 10, we would use the following command: fuse prog -y 10 0 00112233 44556677 1 Here 10 is the fuse line number, 0 is the index of the first word to be written, 00112233 and 44556677 are the values to be written to the fuse line (first and second word) and the trailing 1 is the value for the third word responsible for locking the line. A "lock-only" command would look like this: fuse prog -y 11 2 1 Here 11 is the fuse number, 2 is the index of the first word to be written (notice that we only write to word 2 here; the third word for fuse line locking), and the 1 is the value for the word we are writing to. WARNING: According to application note [4], the VHV pin of the SoC must be connected to a 1.8V source during eFuse programming, but *must* be disconnected for normal operation. The AN [4] describes a software-controlled circuit (based on a N-channel or P-channel FET and a free GPIO pin of the SoC) to achieve this, but a jumper-based circuit should suffice as well. Regardless of the chosen circuit, the issue needs to be addressed accordingly! 7. Work to be done ------------------ * Add the ability to populate more than one CSK * Test secure debug * Test on Armada XP 8. Bibliography --------------- [1] ARMADA(R) 38x Family High-Performance Single/Dual CPU System on Chip Functional Specification; MV-S109094-00, Rev. C; August 2, 2015, Preliminary [2] AN-383: ARMADA(R) 38x Families Secure Boot Mode Support; MV-S302501-00 Rev. A; March 11, 2015, Preliminary [3] Public-Key Cryptography Standards (PKCS) #1: RSA Cryptography Specifications Version 2.1; February 2003; https://www.ietf.org/rfc/rfc3447.txt [4] AN-389: ARMADA(R) VHV Power; MV-S302545-00 Rev. B; January 28, 2016, Released [5] Marvell Armada 38x U-Boot support; November 25, 2015; https://github.com/MarvellEmbeddedProcessors/u-boot-marvell 2017-01-05, Mario Six