package/simpleramfs/mounts-root - buildroot - Git at Google

 #!/bin/sh
 #
 # You can run this script in case you boot with rdinit=/bin/sh and want to
 # quickly mount the basic kernel filesystems.  It mounts them, but doesn't
 # switch_root.
 #

 . /helpers.sh

 find_sata_blkdev()
 {
   local dev_node result=

   for dev_node in /dev/sd?; do
     [ -b "$dev_node" ] || continue

     local blkdev=${dev_node#/dev/}
     local dev_path=$(realpath "/sys/block/$blkdev/device")
     if [ "${dev_path#*usb}" = "$dev_path" ]; then
       result="$dev_node"
       break
     fi
   done

   [ -n "$result" ] && echo "$result"
 }

 # Finds the *last* /dev/mtd* device with the given realname
 find_mtd()
 {
   local result=
   while IFS=" :" read dev size erasesize name; do
     name=${name#\"}
     name=${name%\"}
     if [ "$name" = "$1" ]; then
       result=${dev#mtd}
       # fall through in case there's a subsequent device with same name
     fi
   done </proc/mtd
   [ -n "$result" ] && echo "$result"
 }

 find_gpt()
 {
   local result=
   sgdisk -p "$1" >/tmp/gptpart 2>/dev/null
   while read number start end size unit code name; do
     if [ "$name" = "$2" ]; then
       result=$number
     fi
   done </tmp/gptpart
   rm -f /tmp/gptpart
   [ -n "$result" ] && echo "$result"
 }

 find_mmc()
 {
   find_gpt /dev/mmcblk0 "$1"
 }

 find_hdd()
 {
   find_gpt "$1" "$2"
 }

 read_cmdline

 # NOTE on ubi.mtd= vs. root=
 #
 # Previously, we relied on the installer+bootloader to set ubi.mtd=xxx, and
 # then root=mtdblock:rootfs.  The problem with that is it depends on the
 # installer/bootloader understanding about UBI devices, which means the
 # installer for a *previous* version needs to understand the format of kernel
 # parameters for the *next* (newly-installed) version.  That can make future
 # upgrades more complicated.
 #
 # So what we do now is provide root=xxx, where xxx is the name of the mtd
 # partition where the rootfs is installed (either rootfs0 or rootfs1).  It's
 # the responsibility of the installed image, ie. this script, to know whether
 # the stuff in rootfs0/rootfs1 is UBI or not.
 #
 # However, for backward compatibility, we still need to support kernel options
 # of the form
 #    ubi.mtd=rootfs0 root=mtdblock:rootfs
 # which we treat as the new-style
 #    root=rootfs0

 # ubi.mtd= only overrides root= if root= is old-style.
 if [ -n "$UBI_MTD" ]; then
   if [ -z "$ROOTDEV" -o "${ROOTDEV%%:*}" = "mtdblock" ]; then
     ROOTDEV=$UBI_MTD
   fi
 fi


 replacefirst() {
   local left right
   # same as sed -e 's/$2/$3/' $1
   right=${1#*$2}
   left=${1%%$2*}
   echo "$left$3$right"
 }


 # Returns true if the string $1 starts with the string $2.
 startswith() {
   [ "${1#"$2"}" != "$1" ]
 }

 oldargstonewargs() {
   local root_dev=$(replacefirst "$4" "payload=" "")
   local hash_dev=$(replacefirst "$5" "hashtree=" "")
   local hashstart=$(replacefirst "$6" "hashstart=" "")
   local alg=$(replacefirst "$7" "alg=" "")
   local root_digest=$(replacefirst "$8" "root_hexdigest=" "")
   local salt=$(replacefirst "$9" "salt=" "")

   local data_blockcount=$(($2 / 8))
   local hash_blockstart=$(($hashstart / 8))

   echo "$1 $2 $3 0 $root_dev $hash_dev 4096 4096 $data_blockcount $hash_blockstart $alg $root_digest $salt"
 }

 # From the verity command line, gets the hash start in Bytes!
 get_hashstart() {
   local hashstart=${6#hashstart=}
   hashstart=$((hashstart * 512))
   echo "$hashstart"
 }

 # Echo back the verity args, but with hashstart=0 for the loopback device.
 clear_hashstart() {
   echo "$1 $2 $3 $4 $5 hashstart=0 $7 $8 $9"
 }

 # host:path format in root= means we should do an NFS root
 if [ "${ROOTDEV#*:/}" != "$ROOTDEV" ]; then
   NFSROOT=$ROOTDEV
 fi

 if [ -n "$NFSROOT" ]; then
   log "Mounting nfs: '$NFSROOT'"
   wait  # wait for any pending insmods launched by /init
   NFSADDR=${NFSROOT%:*}
   NFSOPTS="nolock,proto=tcp,mountproto=tcp,vers=3,mountvers=3,addr=$NFSADDR"
   if [ -n "$IP" ]; then
     # Can't necessarily count on the kernel to do this, in case our
     # ethernet driver is a kernel module instead of built-in.
     log "  IP initialization: '$IP'"
     echo "$IP" | {
       IFS=: read client_ip server_ip gw_ip netmask hostname device \
               autoconf dns0_ip dns1_ip junk
       [ -z "$device" ] && device=eth0
       if [ "$ip" != "auto" ]; then
         ifconfig "$device" "$client_ip" netmask 255.255.255.255
       fi
       if [ -n "$gw_ip" ]; then
         route add -net "$gw_ip" netmask 255.255.255.255 dev "$device"
       fi
       if [ "$NFSADDR" != "$gw_ip" ]; then
         if [ -n "$gw_ip" ]; then
           route add -net "$NFSADDR" netmask 255.255.255.255 gw "$gw_ip" \
               dev "$device"
         else
           route add -net "$NFSADDR" netmask 255.255.255.255 dev "$device"
         fi
       fi
     }
     log "  IP initialized."
   fi
   # Some PHYs take >1 second to get a link.  Poll the connection with nc
   # (with a nice short timeout so we cause transmit retries) until it's open,
   # then move on to the real NFS mount.
   for s in $(seq 10); do
     nc -w1 "$NFSADDR" 2049 </dev/null && break
   done &&
   mount -o $NFSOPTS -t nfs "$NFSROOT" /rootfs ||
       die "NFS mount failed"
   log "Mounted nfsroot='$NFSROOT'"
 elif [ -e /rootfs.img ]; then
   cat /rootfs.img >/dev/ram0
   mount -t squashfs -o ro /dev/ram0 /rootfs ||
     die "root='/dev/ram0' mount failed"
   log "Mounted root='/dev/ram0'"
 elif [ -n "$ROOTDEV" ]; then
   if startswith "$ROOTDEV" /dev; then
     mount -o ro -t squashfs "$ROOTDEV" /rootfs ||
         die "root='$ROOTDEV' mount failed"
     log "Mounted root='$ROOTDEV'"
   elif startswith "$ROOTDEV" 9p:; then
     fsdev="${ROOTDEV#9p:}"
     mount -t 9p -o trans=virtio,version=9p2000.L "$fsdev" /rootfs ||
         die "root='$fsdev' (9p) mount failed"
     log "Mounted root='$fsdev' (9p)"
   else
     for s in 1 1 0; do
       KERNELNAME=$(replacefirst $ROOTDEV rootfs kernel)
       mtd=/dev/mtd$(find_mtd "$ROOTDEV")
       mmcraw=/dev/mmcblk0p$(find_mmc "$ROOTDEV")
       sata_blkdev=$(find_sata_blkdev)
       hdd=${sata_blkdev}$(find_hdd "$sata_blkdev" "$ROOTDEV")
       IMAGENAME=$(replacefirst $ROOTDEV rootfs image)
       mmcvfat=/dev/mmcblk0p$(find_mmc "$IMAGENAME")
       [ -e "$mtd" -o -e "$mmcraw" -o -e "$hdd" -o -e "$mmcvfat" \
         -o -e $ROOTDEV ] && break
       log "No rootfs found, sleeping"
       # eMMC is sometimes slow to appear; try again.
       sleep $s
       false
     done
     if [ -e "$mtd" ]; then
       log "Found root='$ROOTDEV': $mtd"
       # In this build, the rootdev mtd is always an UBI device.
       ubidetach -p "$mtd"  # Just in case kernel automounted it somewhere
       ubiattach -p "${mtd}ro"
       # In this build, the newly-found mtd is always named 'rootfs'
       ubi_mtd=$(find_mtd "rootfs")
       [ -n "$ubi_mtd" ] || (cat /proc/mtd; die "no mtd named 'rootfs'")
       ROOTDEV=/dev/mtdblock$ubi_mtd
       VERITY_CHAR_DEV=/dev/mtd$(find_mtd "$KERNELNAME")
     elif [ -e "$mmcraw" ]; then
       log "Found root='$ROOTDEV': $mmcraw"
       ROOTDEV=$mmcraw
       VERITYDEV=/dev/mmcblk0p$(find_mmc "$KERNELNAME")
     elif [ -e "$hdd" ]; then
       log "Found root='$ROOTDEV': $hdd"
       ROOTDEV=$hdd
       # On SpaceCast the kernel still lives in the NOR flash
       VERITY_CHAR_DEV=/dev/mtd$(find_mtd "$KERNELNAME")
     elif [ -e "$mmcvfat" ]; then
       # TODO(jnewlin): Remove this after verifying vfat is not used.
       log "Found root='$ROOTDEV': $mmcvfat"
       mount -t vfat -o ro,nodev,noexec,nosuid "$mmcvfat" /vfat
       VERITYDEV=/dev/loop0
       ROOTDEV=/dev/loop1
       losetup $VERITYDEV /vfat/vmlinuz.img
       losetup $ROOTDEV /vfat/rootfs.img
     else
       cat /proc/mtd
       log "root='$ROOTDEV' is not an mtd device."
     fi
     if [ -n "$VERITY_CHAR_DEV" ]; then
       # dump the verity header, and read the verity settings, they are stored
       # in the first 4096 bytes of the image.
       mount -t tmpfs none /veritytmp
       nanddump -x -f /veritytmp/verity.args -l 4096 -s 0 "$VERITY_CHAR_DEV"
       args=$(readverity /veritytmp/verity.args)
       hash_size=$(readverity -s /veritytmp/verity.args)
       rm /veritytmp/verity.args
       hash_offset=$(get_hashstart $args)
       args=$(clear_hashstart $args)
       nanddump -x -f /veritytmp/hash.dat -l "$hash_size" -s "$hash_offset" "$VERITY_CHAR_DEV"
       VERITYDEV=/dev/loop3
       losetup $VERITYDEV /veritytmp/hash.dat
     else
       args=$(readverity $VERITYDEV)
     fi
     args=$(replacefirst "$args" ROOT_DEV "$ROOTDEV")
     args=$(replacefirst "$args" HASH_DEV "$VERITYDEV")
     altargs=$(oldargstonewargs $args)
     echo "dmsetup: $args"
     echo "dmsetup: $altargs"
     if ! dmsetup create vroot -r --table "$args" && ! dmsetup create vroot -r --table "$altargs"; then
       veritynote=
       read x y armplatform platform junk </proc/cpuinfo
       if [ "$platform" = "BCM7425B0" ]; then
         log 'dmsetup failed: platform is unsigned device, continuing anyway.'
         SQUASHFS=$ROOTDEV
       else
         die "dmsetup failed"
       fi
     else
       SQUASHFS="/dev/mapper/vroot"
       veritynote="(verity)"
     fi

     mount -o ro -t squashfs "$SQUASHFS" /rootfs ||
         die "root='$ROOTDEV' mount failed $veritynote"
     log "Mounted root='$ROOTDEV' $veritynote"
   fi
 else
   die "No root= or nfsroot= provided."
 fi

 mount -t tmpfs none /rootfs/tmp

 #TODO(apenwarr): network setup code depends on this file, but it shouldn't.
 # It should just always refuse to touch the network if the network was already
 # set up.
 [ -n "$NFSROOT" ] && echo NFS >/rootfs/tmp/NFS

 true
	#!/bin/sh
	#
	# You can run this script in case you boot with rdinit=/bin/sh and want to
	# quickly mount the basic kernel filesystems. It mounts them, but doesn't
	# switch_root.
	#

	. /helpers.sh

	find_sata_blkdev()
	{
	local dev_node result=

	for dev_node in /dev/sd?; do
	[ -b "$dev_node" ] \|\| continue

	local blkdev=${dev_node#/dev/}
	local dev_path=$(realpath "/sys/block/$blkdev/device")
	if [ "${dev_path#*usb}" = "$dev_path" ]; then
	result="$dev_node"
	break
	fi
	done

	[ -n "$result" ] && echo "$result"
	}

	# Finds the last /dev/mtd* device with the given realname
	find_mtd()
	{
	local result=
	while IFS=" :" read dev size erasesize name; do
	name=${name#\"}
	name=${name%\"}
	if [ "$name" = "$1" ]; then
	result=${dev#mtd}
	# fall through in case there's a subsequent device with same name
	fi
	done </proc/mtd
	[ -n "$result" ] && echo "$result"
	}

	find_gpt()
	{
	local result=
	sgdisk -p "$1" >/tmp/gptpart 2>/dev/null
	while read number start end size unit code name; do
	if [ "$name" = "$2" ]; then
	result=$number
	fi
	done </tmp/gptpart
	rm -f /tmp/gptpart
	[ -n "$result" ] && echo "$result"
	}

	find_mmc()
	{
	find_gpt /dev/mmcblk0 "$1"
	}

	find_hdd()
	{
	find_gpt "$1" "$2"
	}

	read_cmdline

	# NOTE on ubi.mtd= vs. root=
	#
	# Previously, we relied on the installer+bootloader to set ubi.mtd=xxx, and
	# then root=mtdblock:rootfs. The problem with that is it depends on the
	# installer/bootloader understanding about UBI devices, which means the
	# installer for a previous version needs to understand the format of kernel
	# parameters for the next (newly-installed) version. That can make future
	# upgrades more complicated.
	#
	# So what we do now is provide root=xxx, where xxx is the name of the mtd
	# partition where the rootfs is installed (either rootfs0 or rootfs1). It's
	# the responsibility of the installed image, ie. this script, to know whether
	# the stuff in rootfs0/rootfs1 is UBI or not.
	#
	# However, for backward compatibility, we still need to support kernel options
	# of the form
	# ubi.mtd=rootfs0 root=mtdblock:rootfs
	# which we treat as the new-style
	# root=rootfs0

	# ubi.mtd= only overrides root= if root= is old-style.
	if [ -n "$UBI_MTD" ]; then
	if [ -z "$ROOTDEV" -o "${ROOTDEV%%:*}" = "mtdblock" ]; then
	ROOTDEV=$UBI_MTD
	fi
	fi


	replacefirst() {
	local left right
	# same as sed -e 's/$2/$3/' $1
	right=${1#*$2}
	left=${1%%$2*}
	echo "$left$3$right"
	}


	# Returns true if the string $1 starts with the string $2.
	startswith() {
	[ "${1#"$2"}" != "$1" ]
	}

	oldargstonewargs() {
	local root_dev=$(replacefirst "$4" "payload=" "")
	local hash_dev=$(replacefirst "$5" "hashtree=" "")
	local hashstart=$(replacefirst "$6" "hashstart=" "")
	local alg=$(replacefirst "$7" "alg=" "")
	local root_digest=$(replacefirst "$8" "root_hexdigest=" "")
	local salt=$(replacefirst "$9" "salt=" "")

	local data_blockcount=$(($2 / 8))
	local hash_blockstart=$(($hashstart / 8))

	echo "$1 $2 $3 0 $root_dev $hash_dev 4096 4096 $data_blockcount $hash_blockstart $alg $root_digest $salt"
	}

	# From the verity command line, gets the hash start in Bytes!
	get_hashstart() {
	local hashstart=${6#hashstart=}
	hashstart=$((hashstart * 512))
	echo "$hashstart"
	}

	# Echo back the verity args, but with hashstart=0 for the loopback device.
	clear_hashstart() {
	echo "$1 $2 $3 $4 $5 hashstart=0 $7 $8 $9"
	}

	# host:path format in root= means we should do an NFS root
	if [ "${ROOTDEV#*:/}" != "$ROOTDEV" ]; then
	NFSROOT=$ROOTDEV
	fi

	if [ -n "$NFSROOT" ]; then
	log "Mounting nfs: '$NFSROOT'"
	wait # wait for any pending insmods launched by /init
	NFSADDR=${NFSROOT%:*}
	NFSOPTS="nolock,proto=tcp,mountproto=tcp,vers=3,mountvers=3,addr=$NFSADDR"
	if [ -n "$IP" ]; then
	# Can't necessarily count on the kernel to do this, in case our
	# ethernet driver is a kernel module instead of built-in.
	log " IP initialization: '$IP'"
	echo "$IP" \| {
	IFS=: read client_ip server_ip gw_ip netmask hostname device \
	autoconf dns0_ip dns1_ip junk
	[ -z "$device" ] && device=eth0
	if [ "$ip" != "auto" ]; then
	ifconfig "$device" "$client_ip" netmask 255.255.255.255
	fi
	if [ -n "$gw_ip" ]; then
	route add -net "$gw_ip" netmask 255.255.255.255 dev "$device"
	fi
	if [ "$NFSADDR" != "$gw_ip" ]; then
	if [ -n "$gw_ip" ]; then
	route add -net "$NFSADDR" netmask 255.255.255.255 gw "$gw_ip" \
	dev "$device"
	else
	route add -net "$NFSADDR" netmask 255.255.255.255 dev "$device"
	fi
	fi
	}
	log " IP initialized."
	fi
	# Some PHYs take >1 second to get a link. Poll the connection with nc
	# (with a nice short timeout so we cause transmit retries) until it's open,
	# then move on to the real NFS mount.
	for s in $(seq 10); do
	nc -w1 "$NFSADDR" 2049 </dev/null && break
	done &&
	mount -o $NFSOPTS -t nfs "$NFSROOT" /rootfs \|\|
	die "NFS mount failed"
	log "Mounted nfsroot='$NFSROOT'"
	elif [ -e /rootfs.img ]; then
	cat /rootfs.img >/dev/ram0
	mount -t squashfs -o ro /dev/ram0 /rootfs \|\|
	die "root='/dev/ram0' mount failed"
	log "Mounted root='/dev/ram0'"
	elif [ -n "$ROOTDEV" ]; then
	if startswith "$ROOTDEV" /dev; then
	mount -o ro -t squashfs "$ROOTDEV" /rootfs \|\|
	die "root='$ROOTDEV' mount failed"
	log "Mounted root='$ROOTDEV'"
	elif startswith "$ROOTDEV" 9p:; then
	fsdev="${ROOTDEV#9p:}"
	mount -t 9p -o trans=virtio,version=9p2000.L "$fsdev" /rootfs \|\|
	die "root='$fsdev' (9p) mount failed"
	log "Mounted root='$fsdev' (9p)"
	else
	for s in 1 1 0; do
	KERNELNAME=$(replacefirst $ROOTDEV rootfs kernel)
	mtd=/dev/mtd$(find_mtd "$ROOTDEV")
	mmcraw=/dev/mmcblk0p$(find_mmc "$ROOTDEV")
	sata_blkdev=$(find_sata_blkdev)
	hdd=${sata_blkdev}$(find_hdd "$sata_blkdev" "$ROOTDEV")
	IMAGENAME=$(replacefirst $ROOTDEV rootfs image)
	mmcvfat=/dev/mmcblk0p$(find_mmc "$IMAGENAME")
	[ -e "$mtd" -o -e "$mmcraw" -o -e "$hdd" -o -e "$mmcvfat" \
	-o -e $ROOTDEV ] && break
	log "No rootfs found, sleeping"
	# eMMC is sometimes slow to appear; try again.
	sleep $s
	false
	done
	if [ -e "$mtd" ]; then
	log "Found root='$ROOTDEV': $mtd"
	# In this build, the rootdev mtd is always an UBI device.
	ubidetach -p "$mtd" # Just in case kernel automounted it somewhere
	ubiattach -p "${mtd}ro"
	# In this build, the newly-found mtd is always named 'rootfs'
	ubi_mtd=$(find_mtd "rootfs")
	[ -n "$ubi_mtd" ] \|\| (cat /proc/mtd; die "no mtd named 'rootfs'")
	ROOTDEV=/dev/mtdblock$ubi_mtd
	VERITY_CHAR_DEV=/dev/mtd$(find_mtd "$KERNELNAME")
	elif [ -e "$mmcraw" ]; then
	log "Found root='$ROOTDEV': $mmcraw"
	ROOTDEV=$mmcraw
	VERITYDEV=/dev/mmcblk0p$(find_mmc "$KERNELNAME")
	elif [ -e "$hdd" ]; then
	log "Found root='$ROOTDEV': $hdd"
	ROOTDEV=$hdd
	# On SpaceCast the kernel still lives in the NOR flash
	VERITY_CHAR_DEV=/dev/mtd$(find_mtd "$KERNELNAME")
	elif [ -e "$mmcvfat" ]; then
	# TODO(jnewlin): Remove this after verifying vfat is not used.
	log "Found root='$ROOTDEV': $mmcvfat"
	mount -t vfat -o ro,nodev,noexec,nosuid "$mmcvfat" /vfat
	VERITYDEV=/dev/loop0
	ROOTDEV=/dev/loop1
	losetup $VERITYDEV /vfat/vmlinuz.img
	losetup $ROOTDEV /vfat/rootfs.img
	else
	cat /proc/mtd
	log "root='$ROOTDEV' is not an mtd device."
	fi
	if [ -n "$VERITY_CHAR_DEV" ]; then
	# dump the verity header, and read the verity settings, they are stored
	# in the first 4096 bytes of the image.
	mount -t tmpfs none /veritytmp
	nanddump -x -f /veritytmp/verity.args -l 4096 -s 0 "$VERITY_CHAR_DEV"
	args=$(readverity /veritytmp/verity.args)
	hash_size=$(readverity -s /veritytmp/verity.args)
	rm /veritytmp/verity.args
	hash_offset=$(get_hashstart $args)
	args=$(clear_hashstart $args)
	nanddump -x -f /veritytmp/hash.dat -l "$hash_size" -s "$hash_offset" "$VERITY_CHAR_DEV"
	VERITYDEV=/dev/loop3
	losetup $VERITYDEV /veritytmp/hash.dat
	else
	args=$(readverity $VERITYDEV)
	fi
	args=$(replacefirst "$args" ROOT_DEV "$ROOTDEV")
	args=$(replacefirst "$args" HASH_DEV "$VERITYDEV")
	altargs=$(oldargstonewargs $args)
	echo "dmsetup: $args"
	echo "dmsetup: $altargs"
	if ! dmsetup create vroot -r --table "$args" && ! dmsetup create vroot -r --table "$altargs"; then
	veritynote=
	read x y armplatform platform junk </proc/cpuinfo
	if [ "$platform" = "BCM7425B0" ]; then
	log 'dmsetup failed: platform is unsigned device, continuing anyway.'
	SQUASHFS=$ROOTDEV
	else
	die "dmsetup failed"
	fi
	else
	SQUASHFS="/dev/mapper/vroot"
	veritynote="(verity)"
	fi

	mount -o ro -t squashfs "$SQUASHFS" /rootfs \|\|
	die "root='$ROOTDEV' mount failed $veritynote"
	log "Mounted root='$ROOTDEV' $veritynote"
	fi
	else
	die "No root= or nfsroot= provided."
	fi

	mount -t tmpfs none /rootfs/tmp

	#TODO(apenwarr): network setup code depends on this file, but it shouldn't.
	# It should just always refuse to touch the network if the network was already
	# set up.
	[ -n "$NFSROOT" ] && echo NFS >/rootfs/tmp/NFS

	true