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layerscape: add multiple-configuration generator for FIT images

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This is required for the Traverse LS1043 family, we generate a FIT image
that works on all boards across the family. This is done by creating
multiple configurations that select the right DTB for the board.

The bootloader on these boards is configured to boot like this:
bootm $kernel_load#ls1043s
bootm $kernel_load#ls1043v

This is based on earlier work by Jason Wu for Zynq:
https://lists.openwrt.org/pipermail/openwrt-devel/2016-March/040460.html

Modified to add FDT load addresses and multiple configurations with DTB.

Signed-off-by: Mathew McBride <matt@traverse.com.au>
v19.07.3_mercusys_ac12_duma
Mathew McBride 6 years ago committed by John Crispin
parent 2203815f05
commit 481f870a02
1 changed files with 596 additions and 0 deletions
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target/linux/layerscape/image/mkits-multiple-config.sh
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#!/usr/bin/env bash
#
# Licensed under the terms of the GNU GPL License version 2 or later.
#
# Author: Jason Wu <jason.hy.wu@gmail.com>
# with modifications for multi-DTB-same-image by:
# Mathew McBride <matt@traverse.com.au>
#
# U-Boot firmware supports the booting of images in the Flattened Image
# Tree (FIT) format. The FIT format uses a device tree structure to
# describe a kernel image, device tree blob, ramdisk, etc. This script
# creates an Image Tree Source (.its file) which can be passed to the
# 'mkimage' utility to generate an Image Tree Blob (.itb file). The .itb
# file can then be booted by U-Boot (or other bootloaders which support
# FIT images). See doc/uImage.FIT/howto.txt in U-Boot source code for
# additional information on FIT images.
#
# This tools supports:
# - multi-configuration
# - multi-image support - multiple kernel/fdt/ramdsik
# - per image configuration:
# - hash algorithm and generated required subnodes
# - compression
# - signature and generated required subnodes
#
set -e
# image config limit
MAX_IMG=50
# conf config limit
MAX_CONF=10
# declare main data array
declare -a img_array
declare -a conf_array
# initialize array with empty values
for (( index=1; index<=$MAX_IMG; index++ )); do
declare -a img$index
for i in {0..13}; do
eval img${index}[$i]=""
done
done
for (( index=1; index<=$MAX_CONF; index++ )); do
declare -a conf$index
for i in {0..9}; do
eval conf${index}[$i]=""
done
done
# imgX array index information
# 0: type of image - kernel, fdt, ramdsik
# 1: image location
# 2: image index
# 3: loadaddr of image
# 4: entrypoint of image
# 5: compression
# 6: hash algorithm
# 7: part of the configuration
# 8: Human friend name for the image
# 9: key file name
# 10: signature
# 11: conf friendly name
# confX array index information
# 0: conf number
# 1: kernel conf
# 2: fdt conf
# 3: rootfs conf
# 4: kernel key file
# 5: fdt key file
# 6: rootfs key file
# 7: kernel sign_algorithm
# 8: fdt sign_algorithm
# 9: rootfs sign_algorithm
# 10: conf friendly name
usage() {
echo "Usage: `basename $0` -A arch -v version -o its_file" \
"-k kernel -a addr -e entry [-C none] [-h sha1] [-c conf]"
echo -e "Example1:\n\tkernel image ker_img1 with no compression +"
echo -e "\tsha1 hash + fdt dtb1 with sha1 and crc32 hash for conf 1"
echo -e "\t $ `basename $0` -A arm -v 4.4 \ "
echo -e "\t -k ker_img1 -C none -h sha1 -e 0x8000 -a 0x8000 -c 1 \ "
echo -e "\t -d dtb1 -h sha1 -h crc32 -c 1\n"
echo "General settings:"
echo -e "\t-A ==> set architecture to 'arch'"
echo -e "\t-v ==> set kernel version to 'version'"
echo -e "\t-o ==> create output file 'its_file' [optional]"
echo "Input image type:"
echo -e "\t-k ==> kernel image 'kernel'"
echo -e "\t-d ==> Device Tree Blob 'dtb'"
echo -e "\t-r ==> ramdisk image 'ramdisk"
echo "Per image configurations:"
echo -e "\t-C ==> set compression type 'comp'"
echo -e "\t-c ==> set image config (multiple -c allowed)"
echo -e "\t-a ==> set load address to 'addr' (hex)"
echo -e "\t-e ==> set entry point to 'entry' (hex)"
echo -e "\t-D ==> human friendly 'name' (one word only)"
echo -e "\t-h ==> set hash algorithm (multiple -h allowed)"
echo -e "\t-s ==> set signature for given config image"
echo -e "\t-K ==> set key file for given config image"
exit 1
}
array_check()
{
local a=999
local max_a=0
local max_i=0
if echo $1 | grep -q img; then
max_a=$MAX_IMG
max_i=13
let a=$(echo $1 | awk -F "img" '{print $2}')
elif echo $1 | grep -q conf; then
max_a=$MAX_CONF
max_i=10
let a=$(echo $1 | awk -F "conf" '{print $2}')
fi
if [ ${a} -lt 0 -o ${a} -gt ${max_a} -o \
${2} -lt 0 -o ${2} -gt ${max_i} ]; then
echo "WARNING: Invalid array name, skipping!!!"
return 255
fi
}
#
# $1: array name
# $2: index
# $3: value
# $4: append operation
#
array_put()
{
# check if array is declared
array_check $1 $2 || return 0
if [ -z "$4" ]; then
eval $1[$2]=$3
else
eval $1[$2]=\"\${$1[$2]} $3\"
fi
}
#
# $1: array name
# $2: index
#
array_get()
{
local val
eval val=\${$1[$2]}
echo $val
}
parse_args() {
local i=-1 k=-1 d=-1 r=-1
while getopts ":A:a:C:c:D:d:e:h:k:K:o:v:r:s:n:" OPTION; do
case $OPTION in
A ) ARCH=$OPTARG;;
a ) array_put img$i 3 $OPTARG;;
C ) value_sanity_chk compression $OPTARG;
array_put img$i 5 $OPTARG;;
c ) array_put img$i 7 $OPTARG append;;
D ) array_put img$i 8 $OPTARG;;
d ) i=$(($i + 1));
d=$(($d + 1));
img_array[$i]=img$i;
array_put img$i 0 fdt;
array_put img$i 1 $OPTARG;
array_put img$i 2 $d;
;;
e ) array_put img$i 4 $OPTARG;;
h ) value_sanity_chk hash $OPTARG;
array_put img$i 6 $OPTARG append;;
k ) i=$(($i + 1));
k=$(($k + 1));
img_array[$i]=img$i;
array_put img$i 0 "kernel";
array_put img$i 1 $OPTARG;
array_put img$i 2 $k;
;;
K ) array_put img$i 9 $OPTARG;;
n ) array_put img$i 11 $OPTARG;;
o ) OUTPUT=$OPTARG;;
v ) VERSION=$OPTARG;;
r ) i=$(($i + 1));
r=$(($r + 1));
img_array[$i]=img$i;
array_put img$i 0 "ramdisk";
array_put img$i 1 $OPTARG;
array_put img$i 2 $r;
;;
s ) value_sanity_chk signature $OPTARG;
array_put img$i 10 $OPTARG;
;;
* ) echo "Invalid option passed to '$0' (options:$@)"
usage;;
esac
done
[ -n "${OUTPUT}" ] || OUTPUT=fitimage.its
[ -n "${VERSION}" ] || VERSION="Unknown"
[ -n "${ARCH}" ] || ARCH=arm
}
#
# sanity check for signature, compression and hash
#
value_sanity_chk()
{
local valid=""
case $1 in
signature) valid="sha-1,rsa-2048 sha-256,rsa-2048 sha-256,rsa-4096";;
compression) valid="gzip bzip2 none";;
hash) valid="sha1 md5 crc32";;
esac
if ! echo $valid | grep -q "$2"; then
echo "Error: Invalid $1 provided '$2'"
echo "Valid options are: $valid"
exit 255
fi
}
#
# Emit the fitImage section bits
#
# $1: Section bit type: fitstart - its header
# imagestart - image section start
# confstart - configuration section start
# sectend - section end
# fitend - fitimage end
# $2: optional variable for confstart section
#
emit_its() {
case $1 in
fitstart)
cat << EOF > ${OUTPUT}
/dts-v1/;
/ {
description = "U-Boot fitImage for ${VERSION} kernel";
#address-cells = <1>;
EOF
;;
imagestart)
echo -e "\n\timages {" >> ${OUTPUT};;
confstart)
# echo -e "\tconfigurations {\n\t\tdefault = \"conf@${2:-0}\";" \
echo -e "\tconfigurations {\n" \
>> ${OUTPUT};;
sectend)
echo -e "\t};" >> ${OUTPUT};;
fitend)
echo -e "};" >> ${OUTPUT};;
esac
}
#
# Emit kernel image node
#
emit_kernel() {
local image=${1}
local count=${2:-${MAX_IMG}}
local loaddaddr=${3:-0x8000}
local entrypoint=${4:-0x8000}
local compresson=${5:-none}
local checksum=${6:-sha1}
local name=${7}
[ -z "${name}" ] || name=" ${name}"
cat << EOF >> ${OUTPUT}
kernel@${count} {
description = "Linux Kernel${name}";
data = /incbin/("${image}");
type = "kernel";
arch = "${ARCH}";
os = "linux";
compression = "${compresson}";
load = <${loaddaddr}>;
entry = <${entrypoint}>;
EOF
emit_cksum ${checksum}
if [ -z "$SIGN_IN_CONF" ] ; then
emit_signature "$9" "" "" "$8" "" ""
fi
echo " };" >> ${OUTPUT}
}
#
# Emit fdt node
#
emit_fdt() {
local image=${1}
local count=${2:-${MAX_IMG}}
local compresson=${3:-none}
local checksum=${4:-sha1}
local name=${5}
local loadaddr=${6}
[ -z "${name}" ] || name=" ${name}"
cat << EOF >> ${OUTPUT}
fdt@${count} {
description = "Flattened Device Tree blob${name}";
data = /incbin/("${image}");
type = "flat_dt";
arch = "${ARCH}";
load = <${loadaddr}>;
compression = "none";
EOF
emit_cksum ${checksum}
if [ -z "$SIGN_IN_CONF" ] ; then
emit_signature "" "$7" "" "" "$6" ""
fi
echo " };" >> ${OUTPUT}
}
#
# Emit ramdisk node
#
emit_ramdisk() {
local image=${1}
local count=${2:-${MAX_IMG}}
local compresson=${3:-none}
local checksum=${4:-sha1}
local name=${5}
[ -z "${name}" ] || name=" ${name}"
cat << EOF >> ${OUTPUT}
ramdisk@${count} {
description = "ramdisk${name}";
data = /incbin/("${image}");
type = "ramdisk";
arch = "${ARCH}";
os = "linux";
compression = "${compresson}";
EOF
emit_cksum ${checksum}
if [ -z "$SIGN_IN_CONF" ] ; then
emit_signature "" "" "$7" "" "" "$6"
fi
echo " };" >> ${OUTPUT}
}
#
# Emit check sum sub node
#
emit_cksum() {
csum_list=$@
count=1
for csum in ${csum_list}; do
cat << EOF >> ${OUTPUT}
hash@${count} {
algo = "${csum}";
};
EOF
count=`expr ${count} + 1`
done
}
#
# Emit signature sub node
#
emit_signature() {
local kernel=$1
local fdt=$2
local rootfs=$3
local kernel_key=$4
local fdt_key=$5
local rootfs_key=$6
local imgs=""
local count=0
local chk_list="" algo="" algos="" i=""
for i in kernel fdt rootfs; do
eval algo=\$$i
eval key=\$${i}_key
[ -n "$algo" ] || continue
if ! echo "$algos" | grep -q $algo; then
if [ -z "$algos" ]; then
algos=$algo
else
algos="${algos} $algo"
fi
fi
if ! echo "$keys" | grep -q $key; then
if [ -z "$keys" ]; then
keys=$key
else
keys="${keys} $key"
fi
fi
done
for algo in $algos; do
for key in $keys; do
img=""
for i in kernel fdt rootfs; do
eval tmp_algo=\$$i
eval tmp_key=\$${i}_key
[ "$tmp_algo" == "$algo" ] || continue
[ "$tmp_key" == "$key" ] || continue
if [ -z "$img" ]; then
img=$i
else
img=${img},$i
fi
done
[ -n "$img" ] || continue
cat << EOF >> ${OUTPUT}
signature@${count} {
algo = "${algo}";
key-name-hint = "${key}";
EOF
if [ -n "$SIGN_IN_CONF" ] ; then
echo " sign-images = \"$img\";" >> ${OUTPUT}
fi
echo " };" >> ${OUTPUT}
count=`expr ${count} + 1`
done
done
}
#
# Emit config sub nodes
#
emit_config() {
local conf_csum="sha1"
config_name="conf@${1}"
if [ ! -z "${11}" ]; then
config_name="${11}"
fi
if [ -z "${2}" ]; then
echo "Error: config has no kernel img, skipping conf node!"
return 0
fi
# Test if we have any DTBs at all
if [ -z "${3}" ] ; then
conf_desc="Boot Linux kernel"
fdt_line=""
else
conf_desc="Boot Linux kernel with FDT blob"
fdt_line="
fdt = \"fdt@${3}\";"
fi
# Test if we have any ROOTFS at all
if [ -n "${4}" ] ; then
conf_desc="$conf_desc + ramdisk"
fdt_line="${fdt_line}
ramdisk = \"ramdisk@${4}\";"
fi
kernel_line="kernel = \"kernel@${2}\";"
cat << EOF >> ${OUTPUT}
${config_name} {
description = "${conf_desc}";
${kernel_line}${fdt_line}
hash@1 {
algo = "${conf_csum}";
};
EOF
if [ -n "$SIGN_IN_CONF" ] ; then
emit_signature "$5" "$6" "$7" "$8" "$9" "${10}"
fi
echo " };" >> ${OUTPUT}
}
#
# remove prefix space
#
remove_prefix_space()
{
echo "$@" | sed "s:^ ::g"
}
#
# generate image nodes and its subnodes
#
emit_image_nodes()
{
local t img_c img_i img_index chk
local img_type img_path img_count img_loadadr img_entrypoint \
img_compression img_hash img_conf img_name img_key img_sign \
img_index
emit_its imagestart
for t in "kernel" "fdt" "ramdisk"; do
img_index=0
for a in ${img_array[@]}; do
img_type=$(array_get $a 0)
img_path=$(array_get $a 1)
img_count=$(array_get $a 2)
img_loadadr=$(array_get $a 3)
img_entrypoint=$(array_get $a 4)
img_compression=$(array_get $a 5)
img_hash=$(array_get $a 6)
img_conf=$(array_get $a 7)
img_name=$(array_get $a 8)
img_key=$(array_get $a 9)
img_sign=$(array_get $a 10)
img_cname=$(array_get $a 11)
img_conf=$(remove_prefix_space $img_conf)
img_hash=$(remove_prefix_space $img_hash)
[ "${img_type}" == $t ] || continue
# generate sub nodes
eval chk=\$DEF_$t
[ -n "${chk}" ] || eval DEF_$t=$img_count
case $t in
kernel) emit_kernel "$img_path" "$img_count" \
"$img_loadadr" "$img_entrypoint" \
"$img_compression" "$img_hash" \
"$img_name" "$img_key" "$img_sign";;
fdt) emit_fdt "$img_path" "$img_count" \
"$img_compression" "$img_hash" \
"$img_name" "$img_loadadr" "$img_key" "$img_sign" ;;
ramdisk) emit_ramdisk "$img_path" "$img_count" \
"$img_compression" "$img_hash" \
"$img_name" "$img_key" "$img_sign";;
esac
# set up configuration data
for img_c in $img_conf; do
img_i=""
#set up default configuration if its not set
[ -n "$DEF_CONFIG" ] || DEF_CONFIG=$img_c
[ -z "${img_c}" ] || conf_array[$img_c]=conf$img_c
array_put conf$img_c 0 ${img_c}
case $t in
kernel) img_i=1;;
fdt) img_i=2;;
ramdisk) img_i=3;;
esac
array_put conf$img_c $img_i $img_index
array_put conf$img_c $(($img_i + 3)) ${img_sign}
array_put conf$img_c $(($img_i + 6)) ${img_key}
array_put conf$img_c 10 $img_cname
done
img_index=$((img_index + 1))
done
done
emit_its sectend
}
#
# generate configuration node and its subnodes
#
emit_configuration_nodes ()
{
local count kernel fdt ramdisk ker_file fdt_file rfs_file ker_sign \
fdt_sign rfs_sign
emit_its confstart $DEF_CONFIG
for a in ${conf_array[@]}; do
count=$(array_get $a 0)
kernel=$(array_get $a 1)
fdt=$(array_get $a 2)
ramdisk=$(array_get $a 3)
er_file=$(array_get $a 4)
fdt_file=$(array_get $a 5)
rfs_file=$(array_get $a 6)
ker_sign=$(array_get $a 7)
fdt_sign=$(array_get $a 8)
rfs_sign=$(array_get $a 9)
cname=$(array_get $a 10)
emit_config "$count" "$kernel" "$fdt" "$ramdisk" "$ker_file" \
"$fdt_file" "$rfs_file" "$ker_sign" "$fdt_sign" \
"$rfs_sign" "${cname}"
done
if [ -z "${DEF_CONFIG}" ]; then
emit_config "0" "$DEF_kernel" "$DEF_fdt" "$DEF_ramdisk"
fi
emit_its sectend
}
# Set to none empty to create signature sub node under images node
SIGN_IN_CONF=${SIGN_IN_CONF:-""}
# Set to default config used
DEF_CONFIG=${DEF_CONFIG:-""}
parse_args $@
emit_its fitstart
emit_image_nodes
emit_configuration_nodes
emit_its fitend
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