inherit sdcard_image-rpi IMAGE_CMD_rpi-sdimg () { # Get rootfs size if echo "${SDIMG_ROOTFS_TYPE}" | egrep -q "*\.xz" then ROOTPART_SIZE=`xz -l --robot ${SDIMG_ROOTFS} | grep "^file" | cut -f` else ROOTPART_SIZE=`du -Lb ${SDIMG_ROOTFS} | cut -f1` fi ROOTPART_SIZE=$(expr ${ROOTPART_SIZE} / 1024) # just in case our file system block size is not a multiple of 1KiB if [ $(expr ${ROOTPART_SIZE} % 1024) != 0 ]; then ROOTPART_SIZE=$(expr ${ROOTPART_SIZE} + 1) fi # Align partitions BOOT_SPACE_ALIGNED=$(expr ${BOOT_SPACE} + ${IMAGE_ROOTFS_ALIGNMENT} - 1) BOOT_SPACE_ALIGNED=$(expr ${BOOT_SPACE_ALIGNED} - ${BOOT_SPACE_ALIGNED} % ${IMAGE_ROOTFS_ALIGNMENT}) SDIMG_SIZE=$(expr ${IMAGE_ROOTFS_ALIGNMENT} + ${BOOT_SPACE_ALIGNED} + $ROOTPART_SIZE) echo "Creating filesystem with Boot partition ${BOOT_SPACE_ALIGNED} KiB and RootFS $ROOTPART_SIZE KiB" # Check if we are building with device tree support DTS="${@get_dts(d, None)}" # Initialize sdcard image file dd if=/dev/zero of=${SDIMG} bs=1024 count=0 seek=${SDIMG_SIZE} # Create partition table parted -s ${SDIMG} mklabel msdos # Create boot partition and mark it as bootable parted -s ${SDIMG} unit KiB mkpart primary fat32 ${IMAGE_ROOTFS_ALIGNMENT} $(expr ${BOOT_SPACE_ALIGNED} \+ ${IMAGE_ROOTFS_ALIGNMENT}) parted -s ${SDIMG} set 1 boot on # Create rootfs partition to the end of disk parted -s ${SDIMG} -- unit KiB mkpart primary ext2 $(expr ${BOOT_SPACE_ALIGNED} \+ ${IMAGE_ROOTFS_ALIGNMENT}) -1s parted ${SDIMG} print # Create a vfat image with boot files BOOT_BLOCKS=$(LC_ALL=C parted -s ${SDIMG} unit b print | awk '/ 1 / { print substr($4, 1, length($4 -1)) / 512 /2 }') rm -f ${WORKDIR}/boot.img mkfs.vfat -n "${BOOTDD_VOLUME_ID}" -S 512 -C ${WORKDIR}/boot.img $BOOT_BLOCKS mcopy -i ${WORKDIR}/boot.img -s ${DEPLOY_DIR_IMAGE}/bcm2835-bootfiles/* ::/ case "${KERNEL_IMAGETYPE}" in "uImage") mcopy -i ${WORKDIR}/boot.img -s ${DEPLOY_DIR_IMAGE}/u-boot.img ::${SDIMG_KERNELIMAGE} mcopy -i ${WORKDIR}/boot.img -s ${DEPLOY_DIR_IMAGE}/${KERNEL_IMAGETYPE}${KERNEL_INITRAMFS}-${MACHINE}.bin ::uImage ;; *) if test -n "${DTS}"; then # Device Tree Overlays are assumed to be suffixed by '-overlay.dtb' string and will be put in a dedicated folder DT_OVERLAYS="${@split_overlays(d, 0)}" DT_ROOT="${@split_overlays(d, 1)}" # Copy board device trees to root folder for DTB in ${DT_ROOT}; do DTB_BASE_NAME=`basename ${DTB} .dtb` mcopy -i ${WORKDIR}/boot.img -s ${DEPLOY_DIR_IMAGE}/${KERNEL_IMAGETYPE}-${DTB_BASE_NAME}.dtb ::${DTB_BASE_NAME}.dtb done # Copy device tree overlays to dedicated folder mmd -i ${WORKDIR}/boot.img overlays for DTB in ${DT_OVERLAYS}; do DTB_EXT=${DTB##*.} DTB_BASE_NAME=`basename ${DTB} ."${DTB_EXT}"` mcopy -i ${WORKDIR}/boot.img -s ${DEPLOY_DIR_IMAGE}/${KERNEL_IMAGETYPE}-${DTB_BASE_NAME}.${DTB_EXT} ::overlays/${DTB_BASE_NAME}.${DTB_EXT} done fi mcopy -i ${WORKDIR}/boot.img -s ${DEPLOY_DIR_IMAGE}/${KERNEL_IMAGETYPE}${KERNEL_INITRAMFS}-${MACHINE}.bin ::${SDIMG_KERNELIMAGE} ;; esac if [ -n ${FATPAYLOAD} ] ; then echo "Copying payload into VFAT" for entry in ${FATPAYLOAD} ; do # add the || true to stop aborting on vfat issues like not supporting .~lock files mcopy -i ${WORKDIR}/boot.img -s -v ${IMAGE_ROOTFS}$entry :: || true done fi # Add stamp file echo "${IMAGE_NAME}-${IMAGEDATESTAMP}" > ${WORKDIR}/image-version-info mcopy -i ${WORKDIR}/boot.img -v ${WORKDIR}//image-version-info :: # Burn Partitions dd if=${WORKDIR}/boot.img of=${SDIMG} conv=notrunc seek=1 bs=$(expr ${IMAGE_ROOTFS_ALIGNMENT} \* 1024) && sync && sync # If SDIMG_ROOTFS_TYPE is a .xz file use xzcat if echo "${SDIMG_ROOTFS_TYPE}" | egrep -q "*\.xz" then xzcat ${SDIMG_ROOTFS} | dd of=${SDIMG} conv=notrunc seek=1 bs=$(expr 1024 \* ${BOOT_SPACE_ALIGNED} + ${IMAGE_ROOTFS_ALIGNMENT} \* 1024) && sync && sync else dd if=${SDIMG_ROOTFS} of=${SDIMG} conv=notrunc seek=1 bs=$(expr 1024 \* ${BOOT_SPACE_ALIGNED} + ${IMAGE_ROOTFS_ALIGNMENT} \* 1024) && sync && sync fi # Optionally apply compression case "${SDIMG_COMPRESSION}" in "gzip") gzip -k9 "${SDIMG}" ;; "bzip2") bzip2 -k9 "${SDIMG}" ;; "xz") xz -k "${SDIMG}" ;; esac }