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See also Generic Secure Boot Wiki Page for information on securing the rest of your firmware.
i.MX8M High Assurance Boot (HAB)
The i.MX family of processors provides a High Assurance Boot (HAB) feature in the on-chip BOOT ROM responsible for loading the initial program image from the boot media. HAB enables the BOOT ROM to authenticate and/or decrypt the program image by using crypto operations.
The HABv4 secure boot feature uses digital signatures to prevent unauthorized code execution during the device boot sequence. This authentication is based on public key cryptography using RSA where the firmware image data is signed offline using a private key and the resulting signed image data is verified on the processor using the corresponding public key hash value programmed into the SoC fuses for establishing the root of trust.
See also:
- https://elixir.bootlin.com/u-boot/latest/source/doc/imx/habv4/guides/mx6_mx7_spl_secure_boot.txt
- https://elixir.bootlin.com/u-boot/latest/source/doc/imx/habv4/introduction_habv4.txt
- NXP AN4581 - i.MX Secure Boot on HABv4 Supported Devices
Terminology:
- CSF: Command Sequence File (generated off-line using the HAB CST)
- CST: Code-Signing Tool
- DCD: Device Configuration Data
- DEK: Data Encryption Key
- HAB: High Assurance Boot
- IVT: Image Vector Table
- SRK: Super Root Key
In order to use High Assurance Boot (HAB) features you must have the NXP Code Signing Tool (CST): https://www.nxp.com/webapp/Download?colCode=IMX_CST_TOOL_NEW
i.MX secure boot SPL
Boards using U-Boot SPL and U-Boot propper for boot firmware support using HABv4 authentication for both images.
The HAB library is a sub-component of the boot ROM on i.MX processors. It is responsible for verifying the digital signatures included as part of the product software and ensures that, when the processor is configured as a secure device, no unauthenticated code is allowed to run.
On an 'open' device you can see HAB events which will tell you if the image would pass the authentication process. This is useful to test before you 'close' the device.
In General you must:
- Build boot firmware that contains HABv4 support
- Create a PKI tree and SRK table via the NXP Code Signing Tool
- Construct boot firmware with a proper Command Sequence File (CSF) (CSF blobs are created with the NXP Code Signing Tool)
- Blow One Time Programmable (OTP) fuses on the target board with public keys
- Flash signed firmware
- Boot and verify no HAB events via 'hab_status' U-Boot command
- Close the device to force trusted boot
Detailed Procedure (for Venice):
- Creation of Code Signing Key:
- Retrieve the NXP Code Signing Tool (CST): https://www.nxp.com/webapp/Download?colCode=IMX_CST_TOOL_NEW (Account required on NXP site)
- Unpack the CST :
tar xvf cst-3.3.1.tgz cd cst-3.3.1/keys
- Create a text file named "serial", which contains 8 digits. OpenSSL uses the contents of this file for the 'certificate serial numbers'.
echo "12345678" > serial
- Create a text file named "key_pass.txt which contains your pass phrase that will protect the HAB code signing private keys. The format is the first pass phrase repeated on the first and second lines:
PASS=mypassphrase printf "$PASS\n$PASS" > key_pass.txt
- Create the signature keys (PKI tree) with hab4_pki_tree.sh (Must do this in the keys dir as the script hard-codes a relative path to certs)
./hab4_pki_tree.sh ... Do you want to use an existing CA key (y/n)?: n Do you want to use Elliptic Curve Cryptography (y/n)?: n Enter key length in bits for PKI tree: 4096 Enter PKI tree duration (years): 10 How many Super Root Keys should be generated? 4 Do you want the SRK certificates to have the CA flag set? (y/n)?: y ...
- this creates the following files which you can archive away as your 'PKI tree':
../crts/CA1_sha256_4096_65537_v3_ca_crt.der ../crts/CA1_sha256_4096_65537_v3_ca_crt.pem ../crts/CSF1_1_sha256_4096_65537_v3_usr_crt.der ../crts/CSF1_1_sha256_4096_65537_v3_usr_crt.pem ../crts/CSF2_1_sha256_4096_65537_v3_usr_crt.der ../crts/CSF2_1_sha256_4096_65537_v3_usr_crt.pem ../crts/CSF3_1_sha256_4096_65537_v3_usr_crt.der ../crts/CSF3_1_sha256_4096_65537_v3_usr_crt.pem ../crts/CSF4_1_sha256_4096_65537_v3_usr_crt.der ../crts/CSF4_1_sha256_4096_65537_v3_usr_crt.pem ../crts/IMG1_1_sha256_4096_65537_v3_usr_crt.der ../crts/IMG1_1_sha256_4096_65537_v3_usr_crt.pem ../crts/IMG2_1_sha256_4096_65537_v3_usr_crt.der ../crts/IMG2_1_sha256_4096_65537_v3_usr_crt.pem ../crts/IMG3_1_sha256_4096_65537_v3_usr_crt.der ../crts/IMG3_1_sha256_4096_65537_v3_usr_crt.pem ../crts/IMG4_1_sha256_4096_65537_v3_usr_crt.der ../crts/IMG4_1_sha256_4096_65537_v3_usr_crt.pem ../crts/SRK1_sha256_4096_65537_v3_ca_crt.der ../crts/SRK1_sha256_4096_65537_v3_ca_crt.pem ../crts/SRK2_sha256_4096_65537_v3_ca_crt.der ../crts/SRK2_sha256_4096_65537_v3_ca_crt.pem ../crts/SRK3_sha256_4096_65537_v3_ca_crt.der ../crts/SRK3_sha256_4096_65537_v3_ca_crt.pem ../crts/SRK4_sha256_4096_65537_v3_ca_crt.der ../crts/SRK4_sha256_4096_65537_v3_ca_crt.pem ./CA1_sha256_4096_65537_v3_ca_key.der ./CA1_sha256_4096_65537_v3_ca_key.pem ./CSF1_1_sha256_4096_65537_v3_usr_key.der ./CSF1_1_sha256_4096_65537_v3_usr_key.pem ./CSF2_1_sha256_4096_65537_v3_usr_key.der ./CSF2_1_sha256_4096_65537_v3_usr_key.pem ./CSF3_1_sha256_4096_65537_v3_usr_key.der ./CSF3_1_sha256_4096_65537_v3_usr_key.pem ./CSF4_1_sha256_4096_65537_v3_usr_key.der ./CSF4_1_sha256_4096_65537_v3_usr_key.pem ./IMG1_1_sha256_4096_65537_v3_usr_key.der ./IMG1_1_sha256_4096_65537_v3_usr_key.pem ./IMG2_1_sha256_4096_65537_v3_usr_key.der ./IMG2_1_sha256_4096_65537_v3_usr_key.pem ./IMG3_1_sha256_4096_65537_v3_usr_key.der ./IMG3_1_sha256_4096_65537_v3_usr_key.pem ./IMG4_1_sha256_4096_65537_v3_usr_key.der ./IMG4_1_sha256_4096_65537_v3_usr_key.pem ./SRK1_sha256_4096_65537_v3_ca_key.der ./SRK1_sha256_4096_65537_v3_ca_key.pem ./SRK2_sha256_4096_65537_v3_ca_key.der ./SRK2_sha256_4096_65537_v3_ca_key.pem ./SRK3_sha256_4096_65537_v3_ca_key.der ./SRK3_sha256_4096_65537_v3_ca_key.pem ./SRK4_sha256_4096_65537_v3_ca_key.der ./SRK4_sha256_4096_65537_v3_ca_key.pem
- this creates the following files which you can archive away as your 'PKI tree':
- Create the fuse table and binary (to be programmed to IMX OPT fuse blocks) using the SRK*_ca_crt.pem files created in the crts dir with srktool:
../linux64/bin/srktool -h 4 -t SRK_1_2_3_4_table.bin -e SRK_1_2_3_4_fuse.bin -d sha256 -c ./SRK1_sha256_4096_65537_v3_ca_crt.pem,./SRK2_sha256_4096_65537_v3_ca_crt.pem,./SRK3_sha256_4096_65537_v3_ca_crt.pem,./SRK4_sha256_4096_65537_v3_ca_crt.pem -f 1
- creates SRK_1_2_3_4_table.bin SRK_1_2_3_4_fuse.bin and
- Use hexdump to obtain the fuse table (8x 32bit fuse values) in the correct endianness for programming with u-boot 'fuse prog':
$ hexdump -e '/4 "0x"' -e '/4 "%X""\n"' < SRK_1_2_3_4_fuse.bin 0xDCE644DB 0x3900ABA 0x1D00ECF6 0xC4EE5E23 0x5BCA8A8 0x75B0AB86 0xF88753CC 0xDB9B5895
- Note the above fuse values will differ per your serial/passphrase
- Build U-boot with HABv4 enabled and a single DTB:
# checkout u-boot git clone https://github.com/Gateworks/uboot-venice.git -b v2021.07-venice cd u-boot # setup cross toolchain environment (ie source setup-environment in Venice BSP dir) export PATH=$VENICE_BSP/buildroot/output/host/bin:$PATH export CROSS_COMPILE="aarch64-linux-" export ARCH=arm64 export ATF_LOAD_ADDR=0x920000 # IMX8MM # configure for venice board make imx8mm_venice_defconfig make menuconfig # select CONFIG_IMX_HAB=y 'Support i.MX HAB features' and CONFIG_OF_LIST to specify a single board dtb make flash.bin
- Use the v2021.07-venice U-Boot branch as this has support for IMX8M HAB
- Select a single board DTB for CONFIG_OF_LIST
- create a signed_flash.bin using the sign_hab_imx8m.sh script
# setup env to point to the CST export CST_DIR=/usr/src/nxp/cst-3.3.1/ export CST_BIN=$CST_DIR/linux64/bin/cst export SIGN_KEY=$CST_DIR/crts/CSF1_1_sha256_4096_65537_v3_usr_crt.pem export IMG_KEY=$CST_DIR/crts/IMG1_1_sha256_4096_65537_v3_usr_crt.pem export SRK_TABLE=$CST_DIR/crts/SRK_1_2_3_4_table.bin # sign it $ ./sign_hab_imx8m.sh Install SRK Install CSFK Authenticate CSF Install key Authenticate data CSF Processed successfully and signed data available in csf_spl.bin Install SRK Install CSFK Authenticate CSF Install key Authenticate data CSF Processed successfully and signed data available in csf_fit.bin 6472+0 records in 6472+0 records out 6472 bytes (6.5 kB, 6.3 KiB) copied, 0.0102526 s, 631 kB/s 6488+0 records in 6488+0 records out 6488 bytes (6.5 kB, 6.3 KiB) copied, 0.0119102 s, 545 kB/s signed_flash.bin is ready! # create a JTAG image if needed mkimage_jtag --emmc -s signed_flash.bin@user:erase_none:66-32640 > signed_u-boot_spl-imx8mm.bin
- the script will create csf_spl.txt and csf_fit.txt which are templates used to create csf_spl.bin and csf_fit.bin which are then copied to the correct offsets in flash.bin to create signed_flash.bin
- Program SRK Hash fuses from Step 1 into IMX OTP (using U-Boot and the keys from fuse bin)
fuse prog -y 6 0 0xDCE644DB fuse prog -y 6 1 0x3900ABA fuse prog -y 6 2 0x1D00ECF6 fuse prog -y 6 3 0xC4EE5E23 fuse prog -y 7 0 0x5BCA8A8 fuse prog -y 7 1 0x75B0AB86 fuse prog -y 7 2 0xF88753CC fuse prog -y 7 3 0xDB9B5895
- Do not use the above fuse values - use values generated above from your serial/passphrase
- OTP fuses can only be programmed once - be careful to use the correct values
- Program signed firmware image:
jtag_usbv4 -p signed_u-boot_spl-imx8mm.bin
- Boot it and verify no HAB events:
u-boot=> hab_status Secure boot disabled HAB Configuration: 0xf0, HAB State: 0x66 No HAB Events Found!
7 Close the device (lock it down!) - this step is irreversible, make sure there are no HAB events from the prior step
u-boot=> fuse prog 1 3 0x2000000
- This sets the SEC_CONFIG[1] fuse on the i.MX8M and once done the processor will not load an image that has not been signed using the correct PKI tree
HABv4 encrypted boot architecture
The IMX HABv4 also provides an extra optional security operation by using cryptography (AES-CCM) to obscure the boot image so it can not be seen or used by unauthorized users.
Encrypted boot adds an extra layer of security to the boot sequence using cryptographic techniques to obscure the bootloader data (which can be extended to the entire firmware image)so that it can not be seen or used by unauthorized users. This mechanism protects and conceals the bootloader code residing in flash.
The Data Encryption Key (DEK) is an AES key used to encrypt the boot image (via the Code Signing Tool) and decrypt the boot image (using the DEK blob appended to the image). The DEK blob is used as a security layer to wrap and store the DEK off-chip which is unique to the chip that generated the blob.
Generation of the DEK blob that gets appended to your image must be done on the IMX via the U-Boot dek_blob command which is enabled with CONFIG_CMD_DEKBLOB=y.
References:
- https://elixir.bootlin.com/u-boot/latest/source/doc/imx/habv4/introduction_habv4.txt
- https://elixir.bootlin.com/u-boot/v2021.07/source/doc/imx/habv4/guides/encrypted_boot.txt
- NXP AN12056 - Encrypted Boot on HABv4 and CAAM Enabled devices