..
# Copyright (c) 2022-2024, Arm Limited.
#
# SPDX-License-Identifier: MIT
#####################################
User Guide: Build & run the software
#####################################
Notice
------
The Corstone-1000 software stack uses the `Yocto Project `__ to build
a tiny Linux distribution suitable for the Corstone-1000 platform (kernel and initramfs filesystem less than 5 MB on the flash).
The Yocto Project relies on the `Bitbake `__
tool as its build tool. Please see `Yocto Project documentation `__
for more information.
Prerequisites
-------------
This guide assumes that your host machine is running Ubuntu 20.04 LTS, with at least
32GB of free disk space and 16GB of RAM as minimum requirement.
The following prerequisites must be available on the host system:
- Git 1.8.3.1 or greater
- tar 1.28 or greater
- Python 3.8.0 or greater.
- gcc 8.0 or greater.
- GNU make 4.0 or greater
Please follow the steps described in the Yocto mega manual:
- `Compatible Linux Distribution `__
- `Build Host Packages `__
Targets
-------
- `Arm Corstone-1000 Ecosystem FVP (Fixed Virtual Platform) `__
- `Arm Corstone-1000 for MPS3 `__
Yocto stable branch
-------------------
Corstone-1000 software stack is built on top of Yocto scarthgap.
Provided components
-------------------
Within the Yocto Project, each component included in the Corstone-1000 software stack is specified as
a `bitbake recipe `__.
The recipes specific to the Corstone-1000 BSP are located at:
``<_workspace>/meta-arm/meta-arm-bsp/``.
The Yocto machine config files for the Corstone-1000 FVP and FPGA targets are:
- ``<_workspace>/meta-arm/meta-arm-bsp/conf/machine/include/corstone1000.inc``
- ``<_workspace>/meta-arm/meta-arm-bsp/conf/machine/corstone1000-fvp.conf``
- ``<_workspace>/meta-arm/meta-arm-bsp/conf/machine/corstone1000-mps3.conf``
**NOTE:** All the paths stated in this document are absolute paths.
*****************
Software for Host
*****************
Trusted Firmware-A
==================
Based on `Trusted Firmware-A `__
+----------+-------------------------------------------------------------------------------------------------+
| bbappend | <_workspace>/meta-arm/meta-arm-bsp/recipes-bsp/trusted-firmware-a/trusted-firmware-a_%.bbappend |
+----------+-------------------------------------------------------------------------------------------------+
| Recipe | <_workspace>/meta-arm/meta-arm/recipes-bsp/trusted-firmware-a/trusted-firmware-a_2.10.4.bb |
+----------+-------------------------------------------------------------------------------------------------+
OP-TEE
======
Based on `OP-TEE `__
+----------+----------------------------------------------------------------------------------------+
| bbappend | <_workspace>/meta-arm/meta-arm-bsp/recipes-security/optee/optee-os_4.%.bbappend |
+----------+----------------------------------------------------------------------------------------+
| Recipe |<_workspace>/meta-arm/meta-arm/recipes-security/optee/optee-os_4.1.0.bb |
+----------+----------------------------------------------------------------------------------------+
U-Boot
======
Based on `U-Boot repo`_
+----------+----------------------------------------------------------------------------+
| bbappend | <_workspace>/meta-arm/meta-arm/recipes-bsp/u-boot/u-boot_%.bbappend |
+----------+----------------------------------------------------------------------------+
| bbappend | <_workspace>/meta-arm/meta-arm-bsp/recipes-bsp/u-boot/u-boot_%.bbappend |
+----------+----------------------------------------------------------------------------+
| Recipe | <_workspace>/meta-arm/meta-arm-bsp/recipes-bsp/u-boot/u-boot_2023.07.02.bb |
+----------+----------------------------------------------------------------------------+
Linux
=====
The distro is based on the `poky-tiny `__
distribution which is a Linux distribution stripped down to a minimal configuration.
The provided distribution is based on busybox and built using musl libc. The
recipe responsible for building a tiny version of Linux is listed below.
+-----------+----------------------------------------------------------------------------------------------+
| bbappend | <_workspace>/meta-arm/meta-arm-bsp/recipes-kernel/linux/linux-yocto_%.bbappend |
+-----------+----------------------------------------------------------------------------------------------+
| Recipe | <_workspace>/poky/meta/recipes-kernel/linux/linux-yocto_6.6.bb |
+-----------+----------------------------------------------------------------------------------------------+
| defconfig | <_workspace>/meta-arm/meta-arm-bsp/recipes-kernel/linux/files/corstone1000/defconfig |
+-----------+----------------------------------------------------------------------------------------------+
**************************************************
Software for Boot Processor (a.k.a Secure Enclave)
**************************************************
Based on `Trusted Firmware-M `__
+----------+-----------------------------------------------------------------------------------------------------+
| bbappend | <_workspace>/meta-arm/meta-arm-bsp/recipes-bsp/trusted-firmware-m/trusted-firmware-m_%.bbappend |
+----------+-----------------------------------------------------------------------------------------------------+
| Recipe | <_workspace>/meta-arm/meta-arm/recipes-bsp/trusted-firmware-m/trusted-firmware-m_2.0.0.bb |
+----------+-----------------------------------------------------------------------------------------------------+
********************************
Software for the External System
********************************
RTX
====
Based on `RTX RTOS `__
+----------+-------------------------------------------------------------------------------------------------------------------------------------------------------+
| Recipe | <_workspace>/meta-arm/meta-arm-bsp/recipes-bsp/external-system/external-system_0.1.0.bb |
+----------+-------------------------------------------------------------------------------------------------------------------------------------------------------+
Building the software stack
---------------------------
Create a new folder that will be your workspace and will henceforth be referred
to as ``<_workspace>`` in these instructions. To create the folder, run:
::
mkdir <_workspace>
cd <_workspace>
Corstone-1000 software is based on the Yocto Project which uses kas and bitbake
commands to build the stack. kas version 4 is required. To install kas, run:
::
pip3 install kas
If 'kas' command is not found in command-line, please make sure the user installation directories are visible on $PATH. If you have sudo rights, try 'sudo pip3 install kas'.
In the top directory of the workspace ``<_workspace>``, run:
::
git clone https://git.yoctoproject.org/git/meta-arm -b CORSTONE1000-2024.06
To build a Corstone-1000 image for MPS3 FPGA, run:
::
kas build meta-arm/kas/corstone1000-mps3.yml:meta-arm/ci/debug.yml
Alternatively, to build a Corstone-1000 image for FVP, you need to accept
the EULA at https://developer.arm.com/downloads/-/arm-ecosystem-fvps/eula
by setting the ARM_FVP_EULA_ACCEPT environment variable as follows:
::
export ARM_FVP_EULA_ACCEPT="True"
then run:
::
kas build meta-arm/kas/corstone1000-fvp.yml:meta-arm/ci/debug.yml
The initial clean build will be lengthy, given that all host utilities are to
be built as well as the target images. This includes host executables (python,
cmake, etc.) and the required toolchain(s).
Once the build is successful, all output binaries will be placed in the following folders:
- ``<_workspace>/build/tmp/deploy/images/corstone1000-fvp/`` folder for FVP build;
- ``<_workspace>/build/tmp/deploy/images/corstone1000-mps3/`` folder for FPGA build.
Everything apart from the Secure Enclave ROM firmware and External System firmware, is bundled into a single binary, the
``corstone1000-flash-firmware-image-corstone1000-{mps3,fvp}.wic`` file.
The output binaries run in the Corstone-1000 platform are the following:
- The Secure Enclave ROM firmware: ``<_workspace>/build/tmp/deploy/images/corstone1000-{mps3,fvp}/bl1.bin``
- The External System firmware: ``<_workspace>/build/tmp/deploy/images/corstone1000-{mps3,fvp}/es_flashfw.bin``
- The flash image: ``<_workspace>/build/tmp/deploy/images/corstone1000-{mps3,fvp}/corstone1000-flash-firmware-image-corstone1000-{mps3,fvp}.wic``
Flash the firmware image on FPGA
--------------------------------
The user should download the FPGA bit file image ``AN550: Arm® Corstone™-1000 for MPS3 Version 2.0``
from `this link `__
and under the section ``Arm® Corstone™-1000 for MPS3``. The download is available after logging in.
The directory structure of the FPGA bundle is shown below.
::
Boardfiles
├── config.txt
├── MB
│ ├── BRD_LOG.TXT
│ ├── HBI0309B
│ │ ├── AN550
│ │ │ ├── AN550_v2.bit
│ │ │ ├── an550_v2.txt
│ │ │ └── images.txt
│ │ ├── board.txt
│ │ └── mbb_v210.ebf
│ └── HBI0309C
│ ├── AN550
│ │ ├── AN550_v2.bit
│ │ ├── an550_v2.txt
│ │ └── images.txt
│ ├── board.txt
│ └── mbb_v210.ebf
└── SOFTWARE
├── an550_st.axf
├── bl1.bin
├── cs1000.bin
└── ES0.bin
Depending upon the MPS3 board version (printed on the MPS3 board) you should update the images.txt file
(in corresponding HBI0309x folder. Boardfiles/MB/HBI0309/AN550/images.txt) so that the file points to the images under SOFTWARE directory.
The images.txt file that is compatible with the latest version of the software
stack can be seen below;
::
;************************************************
; Preload port mapping *
;************************************************
; PORT 0 & ADDRESS: 0x00_0000_0000 QSPI Flash (XNVM) (32MB)
; PORT 0 & ADDRESS: 0x00_8000_0000 OCVM (DDR4 2GB)
; PORT 1 Secure Enclave (M0+) ROM (64KB)
; PORT 2 External System 0 (M3) Code RAM (256KB)
; PORT 3 Secure Enclave OTP memory (8KB)
; PORT 4 CVM (4MB)
;************************************************
[IMAGES]
TOTALIMAGES: 3 ;Number of Images (Max: 32)
IMAGE0PORT: 1
IMAGE0ADDRESS: 0x00_0000_0000
IMAGE0UPDATE: RAM
IMAGE0FILE: \SOFTWARE\bl1.bin
IMAGE1PORT: 0
IMAGE1ADDRESS: 0x00_0000_0000
IMAGE1UPDATE: AUTOQSPI
IMAGE1FILE: \SOFTWARE\cs1000.bin
IMAGE2PORT: 2
IMAGE2ADDRESS: 0x00_0000_0000
IMAGE2UPDATE: RAM
IMAGE2FILE: \SOFTWARE\es0.bin
OUTPUT_DIR = ``<_workspace>/build/tmp/deploy/images/corstone1000-mps3``
1. Copy ``bl1.bin`` from OUTPUT_DIR directory to SOFTWARE directory of the FPGA bundle.
2. Copy ``es_flashfw.bin`` from OUTPUT_DIR directory to SOFTWARE directory of the FPGA bundle
and rename the binary to ``es0.bin``.
3. Copy ``corstone1000-flash-firmware-image-corstone1000-mps3.wic`` from OUTPUT_DIR directory to SOFTWARE
directory of the FPGA bundle and rename the wic image to ``cs1000.bin``.
**NOTE:** Renaming of the images are required because MCC firmware has
limitation of 8 characters before .(dot) and 3 characters after .(dot).
Now, copy the entire folder to board's SDCard and reboot the board.
Running the software on FPGA
----------------------------
On the host machine, open 4 serial port terminals. In case of Linux machine it will
be ttyUSB0, ttyUSB1, ttyUSB2, ttyUSB3 and it might be different on Windows machines.
- ttyUSB0 for MCC, OP-TEE and Secure Partition
- ttyUSB1 for Boot Processor (Cortex-M0+)
- ttyUSB2 for Host Processor (Cortex-A35)
- ttyUSB3 for External System Processor (Cortex-M3)
Run following commands to open serial port terminals on Linux:
::
sudo picocom -b 115200 /dev/ttyUSB0 # in one terminal
sudo picocom -b 115200 /dev/ttyUSB1 # in another terminal
sudo picocom -b 115200 /dev/ttyUSB2 # in another terminal.
sudo picocom -b 115200 /dev/ttyUSB3 # in another terminal.
**NOTE:** The MPS3 expects an ethernet cable to be plugged in, otherwise it will
wait for the network for a considerable amount of time, printing the following
logs:
::
Generic PHY 40100000.ethernet-ffffffff:01: attached PHY driver (mii_bus:phy_addr=40100000.ethernet-ffffffff:01, irq=POLL)
smsc911x 40100000.ethernet eth0: SMSC911x/921x identified at 0xffffffc008e50000, IRQ: 17
Waiting up to 100 more seconds for network.
Once the system boot is completed, you should see console
logs on the serial port terminals. Once the HOST(Cortex-A35) is
booted completely, user can login to the shell using
**"root"** login.
If system does not boot and only the ttyUSB1 logs are visible, please follow the
steps in `Clean Secure Flash Before Testing (applicable to FPGA only)`_ under
`SystemReady-IR tests`_ section. The previous image used in FPGA (MPS3) might
have filled the Secure Flash completely. The best practice is to clean the
secure flash in this case.
Running the software on FVP
---------------------------
An FVP (Fixed Virtual Platform) model of the Corstone-1000 platform must be available to run the
Corstone-1000 FVP software image.
A Yocto recipe is provided and allows to download the latest supported FVP version.
The recipe is located at <_workspace>/meta-arm/meta-arm/recipes-devtools/fvp/fvp-corstone1000.bb
The latest supported Fixed Virtual Platform (FVP) version is 11_23.25 and is automatically downloaded and installed when using the runfvp command as detailed below. The FVP version can be checked by running the following command:
::
kas shell meta-arm/kas/corstone1000-fvp.yml:meta-arm/ci/debug.yml -c "../meta-arm/scripts/runfvp -- --version"
The FVP can also be manually downloaded from the `Arm Ecosystem FVPs`_ page. On this page, navigate
to "Corstone IoT FVPs" section to download the Corstone-1000 platform FVP installer. Follow the
instructions of the installer and setup the FVP.
To run the FVP using the runfvp command, please run the following command:
::
kas shell meta-arm/kas/corstone1000-fvp.yml:meta-arm/ci/debug.yml -c "../meta-arm/scripts/runfvp --terminals=xterm"
When the script is executed, three terminal instances will be launched, one for the boot processor
(aka Secure Enclave) processing element and two for the Host processing element. Once the FVP is
executing, the Boot Processor will start to boot, wherein the relevant memory contents of the .wic
file are copied to their respective memory locations within the model, enforce firewall policies
on memories and peripherals and then, bring the host out of reset.
The host will boot trusted-firmware-a, OP-TEE, U-Boot and then Linux, and present a login prompt
(FVP host_terminal_0):
::
corstone1000-fvp login:
Login using the username root.
Using FVP on Windows or AArch64 Linux
-------------------------------------
The user should follow the build instructions in this document to build on a Linux host machine.
Then, copy the output binaries to the Windows or Aarch64 Linux machine where the FVP is located.
Then, launch the FVP binary.
Security Issue Reporting
------------------------
To report any security issues identified with Corstone-1000, please send an email to psirt@arm.com.
###########################
User Guide: Provided tests
###########################
SystemReady-IR tests
--------------------
*************
Testing steps
*************
**NOTE**: Running the SystemReady-IR tests described below requires the user to
work with USB sticks. In our testing, not all USB stick models work well with
MPS3 FPGA. Here are the USB sticks models that are stable in our test
environment.
- HP V165W 8 GB USB Flash Drive
- SanDisk Ultra 32GB Dual USB Flash Drive USB M3.0
- SanDisk Ultra 16GB Dual USB Flash Drive USB M3.0
**NOTE**:
Before running each of the tests in this chapter, the user should follow the
steps described in following section "Clean Secure Flash Before Testing" to
erase the SecureEnclave flash cleanly and prepare a clean board environment for
the testing.
Prepare EFI System Partition
===========================================================
Corstone-1000 FVP and FPGA do not have enough on-chip nonvolatile memory to host
an EFI System Partition (ESP). Thus, Corstone-1000 uses mass storage device for
ESP. The instructions below should be followed for both FVP and FPGA before
running the ACS tests.
**Common to FVP and FPGA:**
::
kas build meta-arm/kas/corstone1000-{mps3,fvp}.yml:meta-arm/ci/debug.yml --target corstone1000-esp-image
Once the build is successful ``corstone1000-esp-image-corstone1000-{mps3,fvp}.wic`` will be available in either:
- ``<_workspace>/build/tmp/deploy/images/corstone1000-fvp/`` folder for FVP build;
- ``<_workspace>/build/tmp/deploy/images/corstone1000-mps3/`` folder for FPGA build.
**Using ESP in FPGA:**
Once the ESP is created, it needs to be flashed to a second USB drive different than ACS image.
This can be done with the development machine. In the given example here
we assume the USB device is ``/dev/sdb`` (the user should use ``lsblk`` command to
confirm). Be cautious here and don't confuse your host machine own hard drive with the
USB drive. Run the following commands to prepare the ACS image in USB stick:
::
sudo dd if=corstone1000-esp-image-corstone1000-mps3.wic of=/dev/sdb iflag=direct oflag=direct status=progress bs=512; sync;
Now you can plug this USB stick to the board together with ACS test USB stick.
**Using ESP in FVP:**
The ESP disk image once created will be used automatically in the Corstone-1000 FVP as the 2nd MMC card image. It will be used when the SystemReady-IR tests will be performed on the FVP in the later section.
Clean Secure Flash Before Testing (applicable to FPGA only)
===========================================================
To prepare a clean board environment with clean secure flash for the testing,
the user should prepare an image that erases the secure flash cleanly during
boot. Run following commands to build such image.
::
cd <_workspace>
git clone https://git.yoctoproject.org/git/meta-arm -b CORSTONE1000-2024.06
git clone https://git.gitlab.arm.com/arm-reference-solutions/systemready-patch.git -b CORSTONE1000-2024.06
cp -f systemready-patch/embedded-a/corstone1000/erase_flash/0001-embedded-a-corstone1000-clean-secure-flash.patch meta-arm
cd meta-arm
git apply 0001-embedded-a-corstone1000-clean-secure-flash.patch
cd ..
kas build meta-arm/kas/corstone1000-mps3.yml:meta-arm/ci/debug.yml
Replace the bl1.bin and cs1000.bin files on the SD card with following files:
- The ROM firmware: <_workspace>/build/tmp/deploy/images/corstone1000-mps3/bl1.bin
- The flash image: <_workspace>/build/tmp/deploy/images/corstone1000-mps3/corstone1000-flash-firmware-image-corstone1000-mps3.wic
Now reboot the board. This step erases the Corstone-1000 SecureEnclave flash
completely, the user should expect following message from TF-M log (can be seen
in ttyUSB1):
::
!!!SECURE FLASH HAS BEEN CLEANED!!!
NOW YOU CAN FLASH THE ACTUAL CORSTONE1000 IMAGE
PLEASE REMOVE THE LATEST ERASE SECURE FLASH PATCH AND BUILD THE IMAGE AGAIN
Then the user should follow "Building the software stack" to build a clean
software stack and flash the FPGA as normal. And continue the testing.
Run SystemReady-IR ACS tests
============================
Architecture Compliance Suite (ACS) is used to ensure architectural compliance
across different implementations of the architecture. Arm Enterprise ACS
includes a set of examples of the invariant behaviors that are provided by a
set of specifications for enterprise systems (For example: SBSA, SBBR, etc.),
so that implementers can verify if these behaviours have been interpreted correctly.
The ACS image contains a BOOT partition.
Following test suites and bootable applications are under BOOT partition:
* SCT
* FWTS
* BSA uefi
* BSA linux
* grub
* uefi manual capsule application
BOOT partition contains the following:
::
├── EFI
│ └── BOOT
│ ├── app
│ ├── bbr
│ ├── bootaa64.efi
│ ├── bsa
│ ├── debug
│ ├── Shell.efi
│ └── startup.nsh
├── grub
├── grub.cfg
├── Image
├── ramdisk-busybox.img
└── acs_results
The BOOT partition is also used to store the test results. The
results are stored in the `acs_results` folder.
**NOTE**: PLEASE ENSURE THAT the `acs_results` FOLDER UNDER THE BOOT PARTITION IS
EMPTY BEFORE YOU START TESTING. OTHERWISE THE TEST RESULTS WILL NOT BE CONSISTENT.
FPGA instructions for ACS image
===============================
This section describes how the user can build and run Architecture Compliance
Suite (ACS) tests on Corstone-1000.
First, the user should download the `Arm SystemReady ACS repository `__.
This repository contains the infrastructure to build the Architecture
Compliance Suite (ACS) and the bootable prebuilt images to be used for the
certifications of SystemReady-IR. To download the repository, run command:
::
cd <_workspace>
git clone https://github.com/ARM-software/arm-systemready.git
Once the repository is successfully downloaded, the prebuilt ACS live image can be found in:
- ``<_workspace>/arm-systemready/IR/prebuilt_images/v23.09_2.1.0/ir-acs-live-image-generic-arm64.wic.xz``
**NOTE**: This prebuilt ACS image includes v5.13 kernel, which doesn't provide
USB driver support for Corstone-1000. The ACS image with newer kernel version
and with full USB support for Corstone-1000 will be available in the next
SystemReady release in this repository.
Then, the user should prepare a USB stick with ACS image. In the given example here,
we assume the USB device is ``/dev/sdb`` (the user should use ``lsblk`` command to
confirm). Be cautious here and don't confuse your host machine own hard drive with the
USB drive. Run the following commands to prepare the ACS image in USB stick:
::
cd <_workspace>/arm-systemready/IR/prebuilt_images/v23.09_2.1.0
unxz ir-acs-live-image-generic-arm64.wic.xz
sudo dd if=ir-acs-live-image-generic-arm64.wic of=/dev/sdb iflag=direct oflag=direct bs=1M status=progress; sync
Once the USB stick with ACS image is prepared, the user should make sure that
ensure that both USB sticks (ESP and ACS image) are connected to the board,
and then boot the board.
The FPGA will reset multiple times during the test, and it might take approx. 24-36 hours to finish the test.
**NOTE**: The USB stick which contains the ESP partition might cause grub to
unable to find the bootable partition (only in the FPGA). If that's the case, please
remove the USB stick and run the ACS tests. ESP partition can be mounted after
the platform is booted to linux at the end of the ACS tests.
FVP instructions for ACS image and run
======================================
The FVP has been integrated in the meta-arm-systemready layer so the running of the ACS tests can be handled automatically as follows
::
kas build meta-arm/ci/corstone1000-fvp.yml:meta-arm/ci/debug.yml:kas/arm-systemready-ir-acs.yml
The details of how this layer works can be found in : ``<_workspace>/meta-arm-systemready/README.md``
**NOTE:** You can't use the standard meta-arm/kas/corstone1000-fvp.yml kas file as it sets the build up for only building firmware
**NOTE:** These test might take up to 1 day to finish
Common to FVP and FPGA
======================
U-Boot should be able to boot the grub bootloader from
the 1st partition and if grub is not interrupted, tests are executed
automatically in the following sequence:
- SCT
- UEFI BSA
- FWTS
The results can be fetched from the `acs_results` folder in the BOOT partition of the USB stick (FPGA) / SD Card (FVP).
**NOTE:** The FVP uses the ``<_workspace>/build/tmp-glibc/work/corstone1000_fvp-oe-linux/arm-systemready-ir-acs/2.0.0/deploy-arm-systemready-ir-acs/arm-systemready-ir-acs-corstone1000-fvp.wic`` image if the meta-arm-systemready layer is used.
The result can be checked in this image.
#####################################################
Manual capsule update and ESRT checks
-------------------------------------
The following section describes running manual capsule updates by going through
a negative and positive test. Two capsules are needed to perform the positive
and negative updates. The steps also show how to use the EFI System Resource Table
(ESRT) to retrieve the installed capsule details.
In the positive test, a valid capsule is used and the platform boots correctly
until the Linux prompt after the update. In the negative test, an outdated
capsule is used that has a smaller version number. This capsule gets rejected
because of being outdated and the previous firmware will be used instead.
*******************
Generating Capsules
*******************
A no-partition image is needed for the capsule generation. This image is
created automatically during a clean Yocto build and it can be found in
``build/tmp/deploy/images/corstone1000-/corstone1000-_image.nopt``.
A capsule is also automatically generated with U-Boot's ``mkeficapsule`` tool
during the Yocto build that uses this ``corstone1000-_image.nopt``. The
capsule's default metadata, that is passed to the ``mkeficapsule`` tool,
can be found in the ``meta-arm/meta-arm-bsp/recipes-bsp/images/corstone1000-flash-firmware-image.bb``
and ``meta-arm/kas/corstone1000-image-configuration.yml`` files. These
data can be modified before the Yocto build if it is needed. It is
assumed that the default values are used in the following steps.
The automatically generated capsule can be found in
``build/tmp/deploy/images/corstone1000-/corstone1000--v6.uefi.capsule``.
This capsule will be used as the positive capsule during the test in the following
steps.
Generating Capsules Manually
============================
If a new capsule has to be generated with different metadata after the build
process, then it can be done manually by using the ``u-boot-tools``'s
``mkeficapsule`` and the previously created ``.nopt`` image. The
``mkeficapsule`` tool is built automatically for the host machine
during the Yocto build.
The negative capsule needs a lower ``fw-version`` than the positive
capsule. For example if the host's architecture is x86_64, this can
be generated by using the following command:
::
cd <_workspace>
./build/tmp/sysroots-components/x86_64/u-boot-tools-native/usr/bin/mkeficapsule --monotonic-count 1 \
--private-key build/tmp/deploy/images/corstone1000-/corstone1000_capsule_key.key \
--certificate build/tmp/deploy/images/corstone1000-/corstone1000_capsule_cert.crt --index 1 --guid df1865d1-90fb-4d59-9c38-c9f2c1bba8cc \
--fw-version 5 build/tmp/deploy/images/corstone1000-/corstone1000-_image.nopt corstone1000--v5.uefi.capsule
This command will put the negative capsule to the ``<_workspace>`` directory.
****************
Copying Capsules
****************
Copying the FPGA capsules
=========================
The user should prepare a USB stick as explained in ACS image section `FPGA instructions for ACS image`_.
Place the generated ``corstone1000-mps3-v<5/6>.uefi.capsule`` files in the root directory of the boot partition
in the USB stick. Note: As we are running the direct method, the ``corstone1000-mps3-v<5/6>.uefi.capsule`` files
should not be under the EFI/UpdateCapsule directory as this may or may not trigger
the on disk method.
::
sudo cp /corstone1000-mps3-v6.uefi.capsule /BOOT/
sudo cp /corstone1000-mps3-v5.uefi.capsule /BOOT/
sync
Copying the FVP capsules
========================
The ACS image should be used for the FVP as well. Downloaded and extract the
image the same way as for the FPGA `FPGA instructions for ACS image`_.
Creating an USB stick with the image is not needed for the FVP.
After getting the ACS image, find the 1st partition's offset of the
``ir-acs-live-image-generic-arm64.wic`` image. The partition table can be
listed using the ``fdisk`` tool.
::
fdisk -lu /ir-acs-live-image-generic-arm64.wic
Device Start End Sectors Size Type
/ir-acs-live-image-generic-arm64.wic1 2048 309247 307200 150M Microsoft basic data
/ir-acs-live-image-generic-arm64.wic2 309248 1343339 1034092 505M Linux filesystem
The first partition starts at the 2048th sector. This has to be multiplied
by the sector size which is 512 so the offset is 2048 * 512 = 1048576.
Next, mount the IR image using the previously calculated offset:
::
sudo mkdir /mnt/test
sudo mount -o rw,offset= /ir-acs-live-image-generic-arm64.wic /mnt/test
Then, copy the capsules:
::
sudo cp /corstone1000-fvp-v6.uefi.capsule /mnt/test/
sudo cp /corstone1000-fvp-v5.uefi.capsule /mnt/test/
sync
Then, unmount the IR image:
::
sudo umount /mnt/test
******************************
Performing the capsule update
******************************
During this section we will be using the capsule with the higher version
(``corstone1000--v6.uefi.capsule``) for the positive scenario
and then the capsule with the lower version (``corstone1000--v5.uefi.capsule``)
for the negative scenario. The two tests have to be done after each other
in the correct order to make sure that the negative capsule will get rejected.
Running the FPGA with the IR prebuilt image
===========================================
Insert the prepared USB stick which has the IR prebuilt image and two capsules,
then Power cycle the MPS3 board.
Running the FVP with the IR prebuilt image
==========================================
Run the FVP with the IR prebuilt image:
::
kas shell meta-arm/kas/corstone1000-fvp.yml:meta-arm/ci/debug.yml -c "../meta-arm/scripts/runfvp --terminals=xterm -- -C board.msd_mmc.p_mmc_file=/ir-acs-live-image-generic-arm64.wic"
**NOTE:** must start from the root directory. make sure there are no spaces before or after of "=". board.msd_mmc.p_mmc_file=/ir-acs-live-image-generic-arm64.wic.
**NOTE:** Do not restart the FVP between the positive and negative test because it will start from a clean state.
Executing capsule update for FVP and FPGA
=========================================
Wait until U-boot loads EFI from the ACS image stick and interrupt the EFI
shell by pressing ESC when the following prompt is displayed in the Host
terminal (ttyUSB2).
::
Press ESC in 4 seconds to skip startup.nsh or any other key to continue.
Then, type FS0: as shown below:
::
FS0:
Then start the CapsuleApp application. Use the positive capsule
(corstone1000--v6.uefi.capsule) first.
::
EFI/BOOT/app/CapsuleApp.efi corstone1000--v6.uefi.capsule
The capsule update will be started.
**NOTE:** On the FVP it takes around 15-30 minutes, on the FPGA it takes less time.
After successfully updating the capsule the system will reset. Make sure the
Corstone-1000's Poky Distro is booted after the reset so the ESRT can be checked.
It is described in the `Select Corstone-1000 Linux kernel boot`_ section how to
boot the Poky distro after the capsule update.
The `Positive scenario`_ sections describes how the result should be inspected.
After the result is checked, the system can be rebooted with the ``reboot`` command in the Host
terminal (ttyUSB2).
Interrupt the EFI shell again and now start the capsule update with the negative capsule:
::
EFI/BOOT/app/CapsuleApp.efi corstone1000--v5.uefi.capsule
The command above should fail and in the TF-M logs the following message should appear:
::
ERROR: flash_full_capsule: version error
Then, reboot manually:
::
Shell> reset
Make sure the Corstone-1000's Poky Distro is booted again
(`Select Corstone-1000 Linux kernel boot`_) in order to check the results
`Negative scenario`_.
Select Corstone-1000 Linux kernel boot
======================================
Interrupt the U-Boot shell.
::
Hit any key to stop autoboot:
Run the following commands in order to run the Corstone-1000 Linux kernel and being able to check the ESRT table.
**NOTE:** Otherwise, the execution ends up in the ACS live image.
::
$ unzip $kernel_addr 0x90000000
$ loadm 0x90000000 $kernel_addr_r $filesize
$ bootefi $kernel_addr_r $fdtcontroladdr
*********************
Capsule update status
*********************
Positive scenario
=================
In the positive case scenario, the software stack copies the capsule to the
External Flash, which is shared between the Secure Enclave and Host,
then a reboot is triggered. The TF-M accepts the capsule.
The user should see following TF-M log in the Secure Enclave terminal (ttyUSB1)
before the system reboots automatically, indicating the new capsule
image is successfully applied, and the board boots correctly.
::
...
SysTick_Handler: counted = 10, expiring on = 360
SysTick_Handler: counted = 20, expiring on = 360
SysTick_Handler: counted = 30, expiring on = 360
...
metadata_write: success: active = 1, previous = 0
flash_full_capsule: exit
corstone1000_fwu_flash_image: exit: ret = 0
...
And after the reboot:
::
...
fmp_set_image_info:133 Enter
FMP image update: image id = 0
FMP image update: status = 0version=6 last_attempt_version=6.
fmp_set_image_info:157 Exit.
corstone1000_fwu_host_ack: exit: ret = 0
...
It's possible to check the content of the ESRT table after the system fully boots.
In the Linux command-line run the following:
::
# cd /sys/firmware/efi/esrt/entries/entry0
# cat *
0x0
989f3a4e-46e0-4cd0-9877-a25c70c01329
0
6
0
6
0
.. line-block::
capsule_flags: 0x0
fw_class: 989f3a4e-46e0-4cd0-9877-a25c70c01329
fw_type: 0
fw_version: 6
last_attempt_status: 0
last_attempt_version: 6
lowest_supported_fw_ver: 0
Negative scenario
=================
In the negative case scenario (rollback the capsule version),
the TF-M detects that the new capsule's version number is
smaller then the current version. The capsule is rejected because
of this.
The user should see appropriate logs in the Secure Enclave terminal (ttyUSB1) before the system reboots itself.
::
...
uefi_capsule_retrieve_images: image 0 at 0xa0000070, size=15654928
uefi_capsule_retrieve_images: exit
flash_full_capsule: enter: image = 0x0xa0000070, size = 7764541, version = 5
ERROR: flash_full_capsule: version error
private_metadata_write: enter: boot_index = 1
private_metadata_write: success
fmp_set_image_info:133 Enter
FMP image update: image id = 0
FMP image update: status = 1version=6 last_attempt_version=5.
fmp_set_image_info:157 Exit.
corstone1000_fwu_flash_image: exit: ret = -1
fmp_get_image_info:232 Enter
pack_image_info:207 ImageInfo size = 105, ImageName size = 34, ImageVersionName
size = 36
fmp_get_image_info:236 Exit
...
If capsule pass initial verification, but fails verifications performed during
boot time, Secure Enclave will try new images predetermined number of times
(defined in the code), before reverting back to the previous good bank.
::
...
metadata_write: success: active = 0, previous = 1
fwu_select_previous: in regular state by choosing previous active bank
...
It's possible to check the content of the ESRT table after the system fully boots.
In the Linux command-line run the following:
::
# cd /sys/firmware/efi/esrt/entries/entry0
# cat *
0x0
989f3a4e-46e0-4cd0-9877-a25c70c01329
0
6
1
5
0
.. line-block::
capsule_flags: 0x0
fw_class: 989f3a4e-46e0-4cd0-9877-a25c70c01329
fw_type: 0
fw_version: 6
last_attempt_status: 1
last_attempt_version: 5
lowest_supported_fw_ver: 0
Linux distros tests
-------------------
*************************************************************
Debian install and boot preparation
*************************************************************
There is a known issue in the `Shim 15.7 `__
provided with the Debian installer image (see below). This bug causes a fatal
error when attempting to boot media installer for Debian, and it resets the platform before installation starts.
A patch to be applied to the Corstone-1000 stack (only applicable when
installing Debian) is provided to
`Skip the Shim `__.
This patch makes U-Boot automatically bypass the Shim and run grub and allows
the user to proceed with a normal installation. If at the moment of reading this
document the problem is solved in the Shim, the user is encouraged to try the
corresponding new installer image. Otherwise, please apply the patch as
indicated by the instructions listed below. These instructions assume that the
user has already built the stack by following the build steps of this
documentation.
::
cd <_workspace>
git clone https://git.gitlab.arm.com/arm-reference-solutions/systemready-patch.git -b CORSTONE1000-2024.06
cp -f systemready-patch/embedded-a/corstone1000/shim/0001-arm-bsp-u-boot-corstone1000-Skip-the-shim-by-booting.patch meta-arm
cd meta-arm
git am 0001-arm-bsp-u-boot-corstone1000-Skip-the-shim-by-booting.patch
cd ..
**On FPGA**
::
kas shell meta-arm/kas/corstone1000-mps3.yml:meta-arm/ci/debug.yml -c="bitbake u-boot trusted-firmware-a corstone1000-flash-firmware-image -c cleansstate; bitbake corstone1000-flash-firmware-image"
**On FVP**
::
kas shell meta-arm/kas/corstone1000-fvp.yml:meta-arm/ci/debug.yml -c="bitbake u-boot trusted-firmware-a corstone1000-flash-firmware-image -c cleansstate; bitbake corstone1000-flash-firmware-image"
On FPGA, please update the cs1000.bin on the SD card with the newly generated wic file.
**NOTE:** Skip the shim patch only applies to Debian installation. The user should remove the patch from meta-arm before running the software to boot OpenSUSE or executing any other tests in this user guide. You can make sure of removing the skip the shim patch by executing the steps below.
::
cd <_workspace>/meta-arm
git reset --hard HEAD~1
cd ..
kas shell meta-arm/kas/corstone1000-fvp.yml:meta-arm/ci/debug.yml -c="bitbake u-boot -c cleanall; bitbake trusted-firmware-a -c cleanall; bitbake corstone1000-flash-firmware-image -c cleanall; bitbake corstone1000-flash-firmware-image"
*************************************************
Preparing the Installation Media
*************************************************
Download one of following Linux distro images:
- `Debian installer image `__
- `OpenSUSE Tumbleweed installer image `__ (Tested on: openSUSE-Tumbleweed-DVD-aarch64-Snapshot20240516-Media.iso)
**NOTE:** For OpenSUSE Tumbleweed, the user should look for a DVD Snapshot like
openSUSE-Tumbleweed-DVD-aarch64-Snapshot-Media.iso
FPGA
==================================================
To test Linux distro install and boot on FPGA, the user should prepare two empty USB
sticks (minimum size should be 4GB and formatted with FAT32).
The downloaded iso file needs to be flashed to your USB drive.
This can be done with your development machine.
In the example given below, we assume the USB device is ``/dev/sdb`` (the user
should use the `lsblk` command to confirm).
**NOTE:** Please don't confuse your host machine own hard drive with the USB drive.
Then, copy the contents of the iso file into the first USB stick by running the
following command in the development machine:
::
sudo dd if= of=/dev/sdb iflag=direct oflag=direct status=progress bs=1M; sync;
FVP
==================================================
To test Linux distro install and boot on FVP, the user should prepare an mmc image.
With a minimum size of 8GB formatted with gpt.
::
#Generating os_file
dd if=/dev/zero of=<_workspace>/os_file.img bs=1 count=0 seek=10G; sync;
parted -s os_file.img mklabel gpt
*************************************************
Debian/openSUSE install
*************************************************
FPGA
==================================================
Unplug the first USB stick from the development machine and connect it to the
MSP3 board. At this moment, only the first USB stick should be connected. Open
the following picocom sessions in your development machine:
::
sudo picocom -b 115200 /dev/ttyUSB0 # in one terminal
sudo picocom -b 115200 /dev/ttyUSB2 # in another terminal.
When the installation screen is visible in ttyUSB2, plug in the second USB stick
in the MPS3 and start the distro installation process. If the installer does not
start, please try to reboot the board with both USB sticks connected and repeat
the process.
**NOTE:** Due to the performance limitation of Corstone-1000 MPS3 FPGA, the
distro installation process can take up to 24 hours to complete.
FVP
==================================================
::
kas shell meta-arm/kas/corstone1000-fvp.yml:meta-arm/ci/debug.yml -c "../meta-arm/scripts/runfvp --terminals=xterm -- -C board.msd_mmc.p_mmc_file=<_workspace>/os_file.img -C board.msd_mmc_2.p_mmc_file="
The installer should now start.
The OS will be installed on 'os_file.img'.
*******************************************************
Debian install clarifications
*******************************************************
As the installation process for Debian is different than the one for openSUSE,
Debian may need some extra steps, that are indicated below:
During Debian installation, please answer the following question:
- "Force grub installation to the EFI removable media path?" Yes
- "Update NVRAM variables to automatically boot into Debian?" No
If the grub installation fails, these are the steps to follow on the subsequent
popups:
1. Select "Continue", then "Continue" again on the next popup
2. Scroll down and select "Execute a shell"
3. Select "Continue"
4. Enter the following command:
::
in-target grub-install --no-nvram --force-extra-removable
5. Enter the following command:
::
in-target update-grub
6. Enter the following command:
::
exit
7. Select "Continue without boot loader", then select "Continue" on the next popup
8. At this stage, the installation should proceed as normal.
*****************************************************************
Debian/openSUSE boot after installation
*****************************************************************
FPGA
===============
Once the installation is complete, unplug the first USB stick and reboot the
board.
The board will then enter recovery mode, from which the user can access a shell
after entering the password for the root user.
FVP
==============
The platform should automatically boot into the installed OS image.
To cold boot:
::
kas shell meta-arm/kas/corstone1000-fvp.yml:meta-arm/ci/debug.yml -c "../meta-arm/scripts/runfvp --terminals=xterm -- -C board.msd_mmc.p_mmc_file=<_workspace>/os_file.img"
The board will then enter recovery mode, from which the user can access a shell
after entering the password for the root user.
**NOTE:** To manually enter recovery mode, once the FVP begins booting, you can quickly
change the boot option in grub, to boot into recovery mode. This option will disappear
quickly, so it's best to preempt it.
Select 'Advanced Options for '' and then ' (recovery mode)'.
Common
==============
Proceed to edit the following files accordingly:
::
#Only applicable to Debian
vi /etc/systemd/system.conf
DefaultDeviceTimeoutSec=infinity
::
#Only applicable to openSUSE
vi /usr/lib/systemd/system.conf
DefaultDeviceTimeoutSec=infinity
The system.conf has been moved from /etc/systemd/ to /usr/lib/systemd/ and directly modifying
the /usr/lib/systemd/system.conf is not working and it is getting overridden. We have to create
drop ins system configurations in /etc/systemd/system.conf.d/ directory. So, copy the
/usr/lib/systemd/system.conf to /etc/systemd/system.conf.d/ directory after the mentioned modifications.
The file to be edited next is different depending on the installed distro:
::
vi /etc/login.defs # Only applicable to Debian
vi /usr/etc/login.defs # Only applicable to openSUSE
LOGIN_TIMEOUT 180
To make sure the changes are applied, please run:
::
systemctl daemon-reload
After applying the previous commands, please reboot the board or restart the runfvp command.
The user should see a login prompt after booting, for example, for debian:
::
debian login:
Login with the username root and its corresponding password (already set at
installation time).
**NOTE:** Debian/OpenSUSE Timeouts are not applicable for all systems. Some systems are faster than the others (especially when running the FVP) and works well with default timeouts. If the system boots to Debian or OpenSUSE unmodified, the user can skip this section.
PSA API tests
-------------
***********************************************************
Run PSA API test commands (applicable to both FPGA and FVP)
***********************************************************
When running PSA API test commands (aka PSA Arch Tests) on MPS3 FPGA, the user should make sure there is no
USB stick connected to the board. Power on the board and boot the board to
Linux. Then, the user should follow the steps below to run the tests.
When running the tests on the Corstone-1000 FVP, the user should follow the
instructions in `Running the software on FVP`_ section to boot Linux in FVP
host_terminal_0, and login using the username ``root``.
First, load FF-A TEE kernel module:
::
insmod /lib/modules/*-yocto-standard/updates/arm-tstee.ko
Then, check whether the FF-A TEE driver is loaded correctly by using the following command:
::
cat /proc/modules | grep arm_tstee
The output should be similar to:
::
arm_tstee 16384 - - Live 0xffffffc000510000 (O)
Now, run the PSA API tests in the following order:
::
psa-iat-api-test
psa-crypto-api-test
psa-its-api-test
psa-ps-api-test
UEFI Secureboot (SB) test
-------------------------
Before running the SB test, the user should make sure that the `FVP and FPGA software has been compiled and the ESP image for both the FVP and FPGA has been created` as mentioned in the previous sections and user should use the same workspace directory under which sources have been compiled.
The SB test is applicable on both the FVP and the FPGA and this involves testing both the signed and unsigned kernel images. Successful test results in executing the signed image correctly and not allowing the unsigned image to run at all.
***********************************************************
Below steps are applicable to FVP as well as FPGA
***********************************************************
Firstly, the flash firmware image has to be built for both the FVP and FPGA as follows:
For FVP,
::
kas shell meta-arm/kas/corstone1000-fvp.yml:meta-arm/ci/debug.yml -c bitbake -c build corstone1000-flash-firmware-image"
For FPGA,
::
kas shell meta-arm/kas/corstone1000-mps3.yml:meta-arm/ci/debug.yml -c bitbake -c build corstone1000-flash-firmware-image"
In order to test SB for FVP and FPGA, a bash script is available in the systemready-patch repo which is responsible in creating the relevant keys, sign the respective kernel images, and copy the same in their corresponding ESP images.
Clone the systemready-patch repo under <_workspace. Then, change directory to where the script `create_keys_and_sign.sh` is and execute the script as follows:
::
git clone https://git.gitlab.arm.com/arm-reference-solutions/systemready-patch.git -b CORSTONE1000-2024.06
cd systemready-patch/embedded-a/corstone1000/secureboot/
**NOTE:** The efitools package is required to execute the script. Install the efitools package on your system, if it doesn't exist.
The script is responsible to create the required UEFI secureboot keys, sign the kernel images and copy the public keys and the kernel images (both signed and unsigned) to the ESP image for both the FVP and FPGA.
::
./create_keys_and_sign.sh -w directory under which sources have been compiled> -v
For ex: ./create_keys_and_sign.sh -w "/home/xyz/workspace/meta-arm" -v 365
For help: ./create_keys_and_sign.sh -h
**NOTE:** The above script is interactive and contains some commands that would require sudo password/permissions.
After executing the above script, the relevant keys and the signed/unsigned kernel images will be copied to the ESP images for both the FVP and FGPA. The modified ESP images can be found at the same location i.e.
::
For MPS3 FPGA : _workspace/meta-arm/build/tmp/deploy/images/corstone1000-mps3/corstone1000-esp-image-corstone1000-mps3.wic
For FVP : _workspace/meta-arm/build/tmp/deploy/images/corstone1000-fvp/corstone1000-esp-image-corstone1000-fvp.wic
Now, it is time to test the SB for the Corstone-1000
***********************************************************
Steps to test SB on FVP
***********************************************************
Now, as mentioned in the previous section **Prepare EFI System Partition**, the ESP image will be used automatically in the Corstone-1000 FVP as the 2nd MMC card image. Change directory to your workspace and run the FVP as follows:
::
kas shell meta-arm/kas/corstone1000-fvp.yml:meta-arm/ci/debug.yml -c "../meta-arm/scripts/runfvp --terminals=xterm"
When the script is executed, three terminal instances will be launched, one for the boot processor (aka Secure Enclave) processing element and two for the Host processing element. On the host side, stop the execution at the U-Boot prompt which looks like `corstone1000#`. There is a timeout of 3 seconds to stop the execution at the U-Boot prompt. At the U-Boot prompt, run the following commands:
Set the current mmc device
::
corstone1000# mmc dev 1
Enroll the four UEFI Secureboot authenticated variables
::
corstone1000# load mmc 1:1 ${loadaddr} corstone1000_secureboot_keys/PK.auth && setenv -e -nv -bs -rt -at -i ${loadaddr}:$filesize PK
corstone1000# load mmc 1:1 ${loadaddr} corstone1000_secureboot_keys/KEK.auth && setenv -e -nv -bs -rt -at -i ${loadaddr}:$filesize KEK
corstone1000# load mmc 1:1 ${loadaddr} corstone1000_secureboot_keys/db.auth && setenv -e -nv -bs -rt -at -i ${loadaddr}:$filesize db
corstone1000# load mmc 1:1 ${loadaddr} corstone1000_secureboot_keys/dbx.auth && setenv -e -nv -bs -rt -at -i ${loadaddr}:$filesize dbx
Now, load the unsigned FVP kernel image and execute it. This unsigned kernel image should not boot and result as follows
::
corstone1000# load mmc 1:1 ${loadaddr} corstone1000_secureboot_fvp_images/Image_fvp
corstone1000# loadm $loadaddr $kernel_addr_r $filesize
corstone1000# bootefi $kernel_addr_r $fdtcontroladdr
Booting /MemoryMapped(0x0,0x88200000,0x236aa00)
Image not authenticated
Loading image failed
The next step is to verify the signed linux kernel image. Load the signed kernel image and execute it as follows:
::
corstone1000# load mmc 1:1 ${loadaddr} corstone1000_secureboot_fvp_images/Image_fvp.signed
corstone1000# loadm $loadaddr $kernel_addr_r $filesize
corstone1000# bootefi $kernel_addr_r $fdtcontroladdr
The above set of commands should result in booting of signed linux kernel image successfully.
***********************************************************
Steps to test SB on MPS3 FPGA
***********************************************************
Now, as mentioned in the previous section **Prepare EFI System Partition**, the ESP image for MPS3 FPGA needs to be copied to the USB drive.
Follow the steps mentioned in the same section for MPS3 FPGA to prepare the USB drive with the ESP image. The modified ESP image corresponds to MPS3 FPGA can be found at the location as mentioned before i.e. `_workspace/meta-arm/build/tmp/deploy/images/corstone1000-mps3/corstone1000-esp-image-corstone1000-mps3.wic`.
Insert this USB drive to the MPS3 FPGA and boot, and stop the execution at the U-Boot prompt similar to the FVP. At the U-Boot prompt, run the following commands:
Reset the USB
::
corstone1000# usb reset
resetting USB...
Bus usb@40200000: isp1763 bus width: 16, oc: not available
USB ISP 1763 HW rev. 32 started
scanning bus usb@40200000 for devices... port 1 high speed
3 USB Device(s) found
scanning usb for storage devices... 1 Storage Device(s) found
**NOTE:** Sometimes, the usb reset doesn't recognize the USB device. It is recomended to rerun the usb reset command.
Set the current USB device
::
corstone1000# usb dev 0
Enroll the four UEFI Secureboot authenticated variables
::
corstone1000# load usb 0 $loadaddr corstone1000_secureboot_keys/PK.auth && setenv -e -nv -bs -rt -at -i $loadaddr:$filesize PK
corstone1000# load usb 0 $loadaddr corstone1000_secureboot_keys/KEK.auth && setenv -e -nv -bs -rt -at -i $loadaddr:$filesize KEK
corstone1000# load usb 0 $loadaddr corstone1000_secureboot_keys/db.auth && setenv -e -nv -bs -rt -at -i $loadaddr:$filesize db
corstone1000# load usb 0 $loadaddr corstone1000_secureboot_keys/dbx.auth && setenv -e -nv -bs -rt -at -i $loadaddr:$filesize dbx
Now, load the unsigned MPS3 FPGA linux kernel image and execute it. This unsigned kernel image should not boot and result as follows
::
corstone1000# load usb 0 $loadaddr corstone1000_secureboot_mps3_images/Image_mps3
corstone1000# loadm $loadaddr $kernel_addr_r $filesize
corstone1000# bootefi $kernel_addr_r $fdtcontroladdr
Booting /MemoryMapped(0x0,0x88200000,0x236aa00)
Image not authenticated
Loading image failed
The next step is to verify the signed linux kernel image. Load the signed kernel image and execute it as follows:
::
corstone1000# load usb 0 $loadaddr corstone1000_secureboot_mps3_images/Image_mps3.signed
corstone1000# loadm $loadaddr $kernel_addr_r $filesize
corstone1000# bootefi $kernel_addr_r $fdtcontroladdr
The above set of commands should result in booting of signed linux kernel image successfully.
***********************************************************
Steps to disable Secureboot on both FVP and MPS3 FPGA
***********************************************************
Now, after testing the SB, UEFI authenticated variables get stored in the secure flash. When you try to reboot, the U-Boot will automatically read the UEFI authenticated variables and authenticates the images before executing them. In normal booting scenario, the linux kernel images will not be signed and hence this will not allow the system to boot, as image authentication will fail. We need to delete the Platform Key (one of the UEFI authenticated variable for SB) in order to disable the SB. At the U-Boot prompt, run the following commands.
On the FVP
::
corstone1000# mmc dev 1
corstone1000# load mmc 1:1 $loadaddr corstone1000_secureboot_keys/PK_delete.auth && setenv -e -nv -bs -rt -at -i $loadaddr:$filesize PK
corstone1000# boot
On the MPS3 FPGA
::
corstone1000# usb reset
corstone1000# usb dev 0
corstone1000# load usb 0 $loadaddr corstone1000_secureboot_keys/PK_delete.auth && setenv -e -nv -bs -rt -at -i $loadaddr:$filesize PK
corstone1000# boot
The above commands will delete the Platform key (PK) and allow the normal system boot flow without SB.
Testing the External System
---------------------------
During Linux boot the remoteproc subsystem automatically starts
the external system.
The external system can be switched on/off on demand with the following commands:
::
echo stop > /sys/class/remoteproc/remoteproc0/state
::
echo start > /sys/class/remoteproc/remoteproc0/state
Tests results
-------------
As a reference for the end user, reports for various tests for `Corstone-1000 software (CORSTONE1000-2024.06) `__
can be found `here `__.
--------------
*Copyright (c) 2022-2024, Arm Limited. All rights reserved.*
.. _Arm Ecosystem FVPs: https://developer.arm.com/tools-and-software/open-source-software/arm-platforms-software/arm-ecosystem-fvps
.. _U-Boot repo: https://github.com/u-boot/u-boot.git