Runtime Security Subsystem (RSS)
Introduction
Runtime Security Subsystem (RSS) is an Arm subsystem that provides a reference implementation of the HES Host in the Arm Confidential Compute Architecture (CCA). It is designed to be integrated into A-profile compute subsystems that implement Arm CCA, where it serves as the Root of Trust.
RSS initially boots from immutable code (BL1_1) in its internal ROM, before jumping to BL1_2, which is provisioned and hash-locked in RSS OTP. The updatable MCUBoot BL2 boot stage is loaded from host system flash into RSS SRAM, where it is authenticated. BL2 loads and authenticates the TF-M runtime into RSS SRAM from host flash. BL2 is also responsible for loading initial boot code into other subsystems within the host.
The RSS platform port supports the TF-M Crypto, TF-M Initial Attestation, Measured Boot and TF-M Platform services along with the corresponding regression tests. It supports the IPC model in multi-core topology with Isolation Level 1 and 2.
Building TF-M
Follow the instructions in Build instructions. Build TF-M with platform name: arm/rss/<rss platform name>
For example for building RSS for Total Compute platforms:
-DTFM_PLATFORM=arm/rss/tc
Signing host images
RSS BL2 can load boot images into other subsystems within the host system. It expects images to be signed, with the signatures attached to the images in the MCUBoot metadata format.
The imgtool Python package can be used to sign images in the required format. To sign a host image using the development key distributed with TF-M, use the following command:
imgtool sign \
-k <TF-M base directory>/bl2/ext/mcuboot/root-RSA-3072.pem \
--public-key-format full \
--max-align 8 \
--align 1 \
-v "0.0.1" \
-s 1 \
-H 0x2000 \
--pad-header \
-S 0x80000 \
--pad \
-L <load address> \
<binary infile> \
<signed binary outfile>
The load address
is the logical address in the RSS memory map to which BL2
will load the image. RSS FW expects the first host image to be loaded to address
0x70000000
(the beginning of the RSS ATU host access region), and each
subsequent host image to be loaded at an offset of 0x1000000
from the
previous image. The RSS ATU should be configured to map these logical addresses
to the physical addresses in the host system that the images need to be loaded
to.
For more information on the imgtool
parameters, see the MCUBoot
imgtool documentation.
Warning
The TF-M development key must never be used in production. To generate a production key, follow the imgtool documentation.
Running the code
To run the built images, first the ROM image must be created from the bl1_1 binary and the ROM DMA Initial Command Sequence (ICS).:
srec_cat \
bl1_1.bin -Binary -offset 0x0 \
rom_dma_ics.bin -Binary -offset 0x1F000 \
-o rom.bin -Binary
Then, the flash image must be created by concatenating the images that are
output from the build. To create the flash image, the following fiptool
command should be run. fiptool
documentation can be found here.
Note that an up-to-date fiptool that supports the RSS UUIDs must be used.:
fiptool create \
--align 8192 --rss-bl2 bl2_signed.bin \
--align 8192 --rss-ns tfm_ns_signed.bin \
--align 8192 --rss-s tfm_s_signed.bin \
--align 8192 --rss-scp-bl1 <signed Host SCP BL1 image> \
--align 8192 --rss-ap-bl1 <signed Host AP BL1 image> \
fip.bin
If you already have a fip.bin
containing host firmware images, RSS FIP
images can be patched in:
fiptool update --align 8192 --rss-bl2 bl2_signed.bin fip.bin
fiptool update --align 8192 --rss-ns tfm_ns.bin fip.bin
fiptool update --align 8192 --rss-s tfm_s.bin fip.bin
If XIP mode is enabled, the following fiptool
command should be run to
create the flash image:
fiptool create \
--align 8192 --rss-bl2 bl2_signed.bin \
--align 8192 --rss-ns tfm_ns_encrypted.bin \
--align 8192 --rss-s tfm_s_encrypted.bin \
--align 8192 --rss-sic-tables-ns tfm_ns_sic_tables_signed.bin \
--align 8192 --rss-sic-tables-s tfm_s_sic_tables_signed.bin \
--align 8192 --rss-scp-bl1 <signed Host SCP BL1 image> \
--align 8192 --rss-ap-bl1 <signed Host AP BL1 image> \
fip.bin
Once the FIP is prepared, a host flash image can be created using srec_cat
:
srec_cat \
fip.bin -Binary -offset 0x0 \
-o host_flash.bin -Binary
If GPT support is enabled, and a host fip.bin
and fip_gpt.bin
has been
obtained, RSS images can be inserted by first patching the host FIP and then
inserting that patched FIP into the GPT image:
sector_size=$(gdisk -l fip_gpt.bin | grep -i "sector size (logical):" | \
sed 's/.*logical): \([0-9]*\) bytes/\1/')
fip_label=" FIP_A$"
fip_start_sector=$(gdisk -l fip_gpt.bin | grep "$fip_label" | awk '{print $2}')
fip_sector_am=$(gdisk -l fip_gpt.bin | grep "$fip_label" | awk '{print $3 - $2}')
dd if=fip.bin of=fip_gpt.bin bs=$sector_size seek=$fip_start_sector \
count=$fip_sector_am conv=notrunc
fip_label = " FIP_B$"
fip_start_sector = $(gdisk -l fip_gpt.bin | grep "$fip_label" | awk '{print $2}')
fip_sector_am = $(gdisk -l fip_gpt.bin | grep "$fip_label" | awk '{print $3 - $2}')
dd if=fip.bin of=fip_gpt.bin bs=$sector_size seek=$fip_start_sector \
count=$fip_sector_am conv=notrunc
To patch a fip_gpt.bin
without having an initial fip.bin
, the FIP can be
extracted from the GPT image using the following commands (and can then be
patched and reinserted using the above commands):
sector_size=$(gdisk -l fip_gpt.bin | grep -i "sector size (logical):" | \
sed 's/.*logical): \([0-9]*\) bytes/\1/')
fip_label=" FIP_A$"
fip_start_sector=$(gdisk -l fip_gpt.bin | grep "$fip_label" | awk '{print $2}')
fip_sector_am=$(gdisk -l fip_gpt.bin | grep "$fip_label" | awk '{print $3 - $2}')
dd if=fip_gpt.bin of=fip.bin bs=$sector_size skip=$fip_start_sector \
count=$fip_sector_am conv=notrunc
Once the fip_gpt.bin
is prepared, it is placed at the base of the host flash
image:
srec_cat \
fip_gpt.bin -Binary -offset 0x0 \
-o host_flash.bin -Binary
The RSS ROM binary should be placed in RSS ROM at 0x11000000
and the host
flash binary should be placed at the base of the host flash. For the TC
platform, this is at 0x80000000
.
The RSS OTP must be provisioned. On a development platform with
TFM_DUMMY_PROVISIONING
enabled, BL1_1 expects provisioning bundles to be
preloaded into SRAM. Preload encrypted_cm_provisioning_bundle_0.bin
to the
base of VM0, and encrypted_dm_provisioning_bundle.bin
to the base of VM1.
If TFM_DUMMY_PROVISIONING
is disabled and provisioning is required, then
BL1_1 will first wait for the TP mode to be set by a debugger (setting the
tp_mode
variable in the current stack frame is easiest). BL1_1 will then
wait for provisioning bundles to be loaded to VM0 and VM1 in the same way as
when TFM_DUMMY_PROVISIONING
is enabled, except that it will not
automatically perform the reset once each provisioning state is complete. For
more details about provisioning flows, see
RSS provisioning.
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