openwrt/target/linux/ipq40xx/base-files/lib/upgrade/dualboot_datachk.sh
Marek Lindner ea5bb6bbfe ipq40xx: add support for Plasma Cloud PA1200
Device specifications:

* QCA IPQ4018
* 256 MB of RAM
* 32 MB of SPI NOR flash (w25q256)
  - 2x 15 MB available; but one of the 15 MB regions is the recovery image
* 2T2R 2.4 GHz
  - QCA4019 hw1.0 (SoC)
  - requires special BDF in QCA4019/hw1.0/board-2.bin with
    bus=ahb,bmi-chip-id=0,bmi-board-id=16,variant=PlasmaCloud-PA1200
* 2T2R 5 GHz
  - QCA4019 hw1.0 (SoC)
  - requires special BDF in QCA4019/hw1.0/board-2.bin with
    bus=ahb,bmi-chip-id=0,bmi-board-id=17,variant=PlasmaCloud-PA1200
* 3x GPIO-LEDs for status (cyan, purple, yellow)
* 1x GPIO-button (reset)
* 1x USB (xHCI)
* TTL pins are on board (arrow points to VCC, then follows: GND, TX, RX)
* 2x gigabit ethernet
  - phy@mdio4:
    + Label: Ethernet 1
    + gmac0 (ethaddr) in original firmware
    + used as LAN interface
  - phy@mdio3:
    + Label: Ethernet 2
    + gmac1 (eth1addr) in original firmware
    + 802.3af/at POE(+)
    + used as WAN interface
* 12V/24V 1A DC

Flashing instructions:

The tool ap51-flash (https://github.com/ap51-flash/ap51-flash) should be
used to transfer the factory image to the u-boot when the device boots up.

Signed-off-by: Marek Lindner <marek.lindner@kaiwoo.ai>
[sven@narfation.org: prepare commit message, rebase, use all LEDs, switch
to dualboot_datachk upgrade script, use eth1 as designated WAN interface]
Signed-off-by: Sven Eckelmann <sven@narfation.org>
2020-12-22 19:11:50 +01:00

108 lines
4.1 KiB
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# The U-Boot loader with the datachk patchset for dualbooting requires image
# sizes and checksums to be provided in the U-Boot environment.
# The devices come with 2 main partitions - while one is active
# sysupgrade will flash the other. The boot order is changed to boot the
# newly flashed partition. If the new partition can't be booted due to
# upgrade failures the previously used partition is loaded.
platform_do_upgrade_dualboot_datachk() {
local tar_file="$1"
local restore_backup
local primary_kernel_mtd
local setenv_script="/tmp/fw_env_upgrade"
local kernel_mtd="$(find_mtd_index $PART_NAME)"
local kernel_offset="$(cat /sys/class/mtd/mtd${kernel_mtd}/offset)"
local total_size="$(cat /sys/class/mtd/mtd${kernel_mtd}/size)"
# detect to which flash region the new image is written to.
#
# 1. check what is the mtd index for the first flash region on this
# device
# 2. check if the target partition ("inactive") has the mtd index of
# the first flash region
#
# - when it is: the new bootseq will be 1,2 and the first region is
# modified
# - when it isnt: bootseq will be 2,1 and the second region is
# modified
#
# The detection has to be done via the hardcoded mtd partition because
# the current boot might be done with the fallback region. Let us
# assume that the current bootseq is 1,2. The bootloader detected that
# the image in flash region 1 is corrupt and thus switches to flash
# region 2. The bootseq in the u-boot-env is now still the same and
# the sysupgrade code can now only rely on the actual mtd indexes and
# not the bootseq variable to detect the currently booted flash
# region/image.
#
# In the above example, an implementation which uses bootseq ("1,2") to
# detect the currently booted image would assume that region 1 is booted
# and then overwrite the variables for the wrong flash region (aka the
# one which isn't modified). This could result in a device which doesn't
# boot anymore to Linux until it was reflashed with ap51-flash.
local next_boot_part="1"
case "$(board_name)" in
plasmacloud,pa1200|\
openmesh,a42)
primary_kernel_mtd=8
;;
openmesh,a62)
primary_kernel_mtd=10
;;
*)
echo "failed to detect primary kernel mtd partition for board"
return 1
;;
esac
[ "$kernel_mtd" = "$primary_kernel_mtd" ] || next_boot_part="2"
local board_dir=$(tar tf $tar_file | grep -m 1 '^sysupgrade-.*/$')
board_dir=${board_dir%/}
local kernel_length=$(tar xf $tar_file ${board_dir}/kernel -O | wc -c)
local rootfs_length=$(tar xf $tar_file ${board_dir}/root -O | wc -c)
# rootfs without EOF marker
rootfs_length=$((rootfs_length-4))
local kernel_md5=$(tar xf $tar_file ${board_dir}/kernel -O | md5sum); kernel_md5="${kernel_md5%% *}"
# md5 checksum of rootfs with EOF marker
local rootfs_md5=$(tar xf $tar_file ${board_dir}/root -O | dd bs=1 count=$rootfs_length | md5sum); rootfs_md5="${rootfs_md5%% *}"
#
# add tar support to get_image() to use default_do_upgrade() instead?
#
# take care of restoring a saved config
[ -n "$UPGRADE_BACKUP" ] && restore_backup="${MTD_CONFIG_ARGS} -j ${UPGRADE_BACKUP}"
mtd -q erase inactive
tar xf $tar_file ${board_dir}/root -O | mtd -n -p $kernel_length $restore_backup write - $PART_NAME
tar xf $tar_file ${board_dir}/kernel -O | mtd -n write - $PART_NAME
# prepare new u-boot env
if [ "$next_boot_part" = "1" ]; then
echo "bootseq 1,2" > $setenv_script
else
echo "bootseq 2,1" > $setenv_script
fi
printf "kernel_size_%i 0x%08x\n" $next_boot_part $kernel_length >> $setenv_script
printf "vmlinux_start_addr 0x%08x\n" ${kernel_offset} >> $setenv_script
printf "vmlinux_size 0x%08x\n" ${kernel_length} >> $setenv_script
printf "vmlinux_checksum %s\n" ${kernel_md5} >> $setenv_script
printf "rootfs_size_%i 0x%08x\n" $next_boot_part $((total_size-kernel_length)) >> $setenv_script
printf "rootfs_start_addr 0x%08x\n" $((kernel_offset+kernel_length)) >> $setenv_script
printf "rootfs_size 0x%08x\n" ${rootfs_length} >> $setenv_script
printf "rootfs_checksum %s\n" ${rootfs_md5} >> $setenv_script
# store u-boot env changes
mkdir -p /var/lock
fw_setenv -s $setenv_script || {
echo "failed to update U-Boot environment"
return 1
}
}