kumquat-buildroot/board/chromebook/snow/mksd.sh
Alex Suykov 330ac8e6d2 board: add support for Chromebook Snow
Chromebook Snow (Samsung XE303C12) is an Exynos 5 board with
a keyboard, an 11 inch screen and a battery attached.
It is relatively developer-friendly and can run mainline Linux
kernels with little to no effort.

There is barely anything special about this target as far as toolchain
is concerned, but its bootloader only accepts signed kernel images
in a Chromium OS specific format, and is not controllable otherwise.

This config provides a script for building the proper kernel blobs,
and a short manual for booting Buildroot images on this device.

In-tree exynos_defconfig is used for the kernel, with a fragment
to change mwifiex into a module. When built statically, mwifiex
attempts to load its firmware before rootfs is mounted and fails.

[Peter: use BR2_KERNEL_HEADERS_AS_KERNEL=y, lock kernel version,
	enable fit support in u-boot mkimage]
Signed-off-by: Alex Suykov <alex.suykov@gmail.com>
Signed-off-by: Peter Korsgaard <peter@korsgaard.com>
2016-07-03 22:24:57 +02:00

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#!/bin/sh
# This scripts makes a minimal bootable SD card image for the Chromebook.
# The resulting file is called bootsd.img. It should be written directly
# to the card:
#
# SD=/dev/mmcblk1 # check your device name!
# dd if=output/images/bootsd.img of=$SD
#
# The partitions are created just large enough to hold the kernel and
# the rootfs image. Most of the card will be empty, and the secondary
# GPT will not be in its proper location.
# cgpt does not create protective MBR, and the kernel refuses to read
# GPT unless there's some kind of MBR in sector 0. So we need parted
# to write that single sector before doing anything with the GPT.
cgpt=$HOST_DIR/usr/bin/cgpt
parted=$HOST_DIR/usr/sbin/parted
kernel=$BINARIES_DIR/uImage.kpart
rootfs=$BINARIES_DIR/rootfs.ext2
run() { echo "$@"; "$@"; }
die() { echo "$@" >&2; exit 1; }
test -f $kernel || die "No kernel image found"
test -f $rootfs || die "No rootfs image found"
test -x $cgpt || die "cgpt not found (host-vboot-utils have not been built?)"
# True file sizes in bytes
kernelsize=`stat -t $kernel | cut -d\ -f2`
rootfssize=`stat -t $rootfs | cut -d\ -f2`
# The card is partitioned in sectors of 8KB.
# 4 sectors are reserved for MBR+GPT. Their actual size turns out
# to be 33 512-blocks which is just over 2 sectors, but we align
# it to a nice round number.
sec=8192
kernelsec=$(((kernelsize+8191)>>13))
rootfssec=$(((rootfssize+8191)>>13))
headersec=4
# There is also a copy of MBR+GPT at the end of the image.
# It's going to be useless but both tools assume it's there.
imagesec=$((2*headersec+kernelsec+rootfssec))
bootsd="$BINARIES_DIR/bootsd.img"
run dd bs=$sec count=$imagesec if=/dev/zero of=$bootsd
# cgpt needs offsets and sizes in 512-blocks.
block=512
kernelstart=$((headersec<<4))
kernelblocks=$((kernelsec<<4))
rootfsblocks=$((rootfssec<<4))
rootfsstart=$((kernelstart+kernelblocks))
# This command initializes both GPT and MBR
run $parted -s $bootsd mklabel gpt
# The kernel partition must be marked as bootable, that's why -S -T -P
run $cgpt add -i 1 -b $kernelstart -s $kernelblocks \
-t kernel -l kernel \
-S 1 -T 1 -P 10 $bootsd
# It does not really matter where the rootfs partition is located as long
# as the kernel can find it.
# However, if anything is changed here, kernel.args must be updated as well.
run $cgpt add -i 2 -b $rootfsstart -s $rootfsblocks \
-t data -l rootfs $bootsd
run dd bs=$block if=$kernel of=$bootsd seek=$kernelstart
run dd bs=$block if=$rootfs of=$bootsd seek=$rootfsstart