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NXP S32G274A
============
S32G2 is an NXP vehicle network processor combining ASIL D safety, hardware
security, high-performance real-time and application processing and network
acceleration. S32G2 supports the needs of new vehicle architectures:
service-oriented gateways, domain controllers, zonal processors, safety
processors and more. It is equipped with 4 Cortex-A53 cores operating at
1.0GHz.
The TF-A includes support for one single S32G2-based board called S32G274ARDB2.
The S32G-VNP-RDB2 is a compact, highly optimized and integrated board
engineering for vehicle service-oriented gateway (SoG), domain control
applications, high-performance processing, safety and security applications.
More details about this board can be found at `s32g274ardb2`_.
Boot Flow
---------
::
BootROM -> BL2 (SRAM) -> BL31 (SRAM) -> BL33 (DDR - TODO)
.. warning::
This boot flow is a preliminary version that will serve as a foundation for
upcoming S32G2 contributions. The execution will hang after the BL31 stage
due to U-Boot being deployed in SRAM instead of DDR. This issue will be
resolved with the addition of the DDR driver.
Code Locations
--------------
- Downstream TF-A:
`link: <https://github.com/nxp-auto-linux/arm-trusted-firmware>`__
- Downstream U-Boot:
`link <https://github.com/nxp-auto-linux/u-boot>`__
- Downstream Linux:
`link <https://github.com/nxp-auto-linux/linux>`__
How to build
------------
The port currently available on the S32G274ARDB2 platform is in its initial
stage. This means that important drivers like DDR and storage are not yet
available. Consequently, the boot process depends on BootROM to load all TF-A
stages in SRAM. To create a bootable image, the script below should be used.
This script makes use of the ``mkimage`` tool, which is part of the U-Boot drop
for S32G274A SoCs.
.. code:: bash
#!/bin/bash -xe
TF_A="${TF_A:-`pwd`}"
UBOOT="${UBOOT:-${TF_A}/../u-boot}"
DEBUG="${DEBUG:-1}"
FIP_BASE="0x34100000"
if [ "${DEBUG}" -eq "1" ]; then
BUILD="debug"
else
BUILD="release"
fi
BOOT_IMAGE="build/s32g274ardb2/${BUILD}/BOOT_IMAGE.bin"
BL2_BIN="build/s32g274ardb2/${BUILD}/bl2.bin"
FIP_BIN="build/s32g274ardb2/${BUILD}/fip.bin"
# Generate bl2, bl31 and fip image
make -C "${TF_A}" -j9 'PLAT=s32g274ardb2' \
BL33="${UBOOT}/u-boot-nodtb.bin" DEBUG="${DEBUG}" clean
make -C "${TF_A}" -j9 'PLAT=s32g274ardb2' \
BL33="${UBOOT}/u-boot-nodtb.bin" DEBUG="${DEBUG}" bl2
make -C "${TF_A}" -j9 'PLAT=s32g274ardb2' \
BL33="${UBOOT}/u-boot-nodtb.bin" DEBUG="${DEBUG}" fip
# Extract BL2 entry
BL2_START="0x$(poetry run memory -p s32g274ardb2 -b debug -f | \
grep BL2 | awk -F'|' '{print $3}' | xargs)"
# BL2 bin file size in bytes
BL2_SIZE="$(stat -c "%s" "${BL2_BIN}")"
# Pack bl2.bin and fip.bin by ensuring that the FIP image will start at FIP_BASE
cp -vf "${BL2_BIN}" "${BOOT_IMAGE}"
dd if="${FIP_BIN}" of="${BOOT_IMAGE}" seek="$((FIP_BASE - BL2_START))" bs=1
# Build a bootable image by appending the IVT
"${UBOOT}/tools/mkimage" \
-a "${BL2_START}" \
-e "${BL2_START}" \
-T s32ccimage \
-n "${UBOOT}/u-boot-s32.cfgout" \
-d "${BOOT_IMAGE}" \
fip.s32
SoC Errata Workarounds
----------------------
The S32G274A port of the TF-A includes compilation flags that can be used to
control the workaround for the SoC. These flags are used similarly to how the
:ref:`arm_cpu_macros_errata_workarounds` are used. The list of workarounds
includes the following switches:
- ``ERRATA_S32_051700``: This applies erratum ERR051700 workaround to
SoCs part of the S32 Common Chassis family, and therefore it needs to
be enabled for the S32G and S32R devices.
.. _s32g2: https://www.nxp.com/products/processors-and-microcontrollers/s32-automotive-platform/s32g-vehicle-network-processors/s32g2-processors-for-vehicle-networking:S32G2
.. _s32g274ardb2: https://www.nxp.com/design/design-center/designs/s32g2-vehicle-networking-reference-design:S32G-VNP-RDB2