It's going to be very hard to give advice on this one without knowing more about what your kernel is configured with.
Since it appears you are booting the system from NAND, i'll assume your kernel is built with mtd support - although it's entirely possible that the system boots the u-boot from NAND, and then the kernel and root filing system from somewhere else.
My experience is with an OMAP2 board with Micron NAND flash, but the general steps should be the same. There seems to be no particularly nice source of documentation other than just trying it.
1: With any luck, your NAND is partitioned and the mtd subsystem compiled into your kernel subsystem, and it found the partitions on the NAND (the sizes are specified either on the kernel boot-line or maybe programmatically in your board-file).
On the console at boot you might see something like this: [caveat: some of this logging might be disabled]
[ 1.670471] Creating 5 MTD partitions on "omap2-nand.0":
[ 1.676086] 0x000000000000-0x000000020000 : "xload"
[ 1.684814] 0x000000020000-0x0000000a0000 : "barebox"
[ 1.692626] 0x0000000a0000-0x0000000c0000 : "bareboxenv"
[ 1.700622] 0x0000000c0000-0x0000004c0000 : "kernel"
[ 1.709899] 0x0000004c0000-0x000040000000 : "root"
Note that I'm using an OMAP2 system here, with Barebox instead of u-boot, but the same applies. Here we have the primary loader partition
xload, the main bootloader
barebox, non volatile storage for barebox (
bareboxenv), the kernel and root filing system.
2: If so, you'll find that there each of these partitions has a dev file in
root@fk-00A0DE4648fe:~# ls /dev/
block mtd4 tty11 tty49
bus mtd4ro tty12 tty52
char mtdblock0 tty13 tty50
console mtdblock1 tty14 tty51
core mtdblock2 tty15 tty520
cpu_dma_latency mtdblock3 tty16 tty53trl
disk mtdblock4 tty17 tty54om
mtdblock files are raw block devices correspond to partitions in step 1
3: You can use
mtdinfo -a for more info:
Eraseblock size: 131072 bytes, 128.0 KiB
Amount of eraseblocks: 4 (524288 bytes, 512.0 KiB)
Minimum input/output unit size: 2048 bytes
Sub-page size: 2048 bytes
OOB size: 64 bytes
Character device major/minor: 90:2
Bad blocks are allowed: true
Device is writable: true
4: You can erase a partition (e.g. block1):
mtd_debug erase /dev/mtdblock1 0x0 0x8000
The two addresses are the offset from the start of the block and the length to erase
5: Copy your image to the newly erased flash
cp <uboot_image> /dev/mtdblock1
This seems to work for me which is perhaps surprising although most NAND flashes have very specific programming sizes - although these are probably multiples of a block.
mtd_debug also provides
write verbs - which do precisely what you'd imagine. I had less success with these than with
It obviously goes without saying that you want an alternative boot arrangement (presumably MMC Card) handy and verified to work before trying this, as your system may well be unbootable afterwards if flash programming didn't work.
Things that have gone wrong for me and proved a pain have been different ECC algorithms used for the partitions. The first couple of erase units of the flash are usually guaranteed to be more robust, and will use whatever ECC the minimal initial loader in mask PROM in your SoC supports. This may well not be what you use on the rest of the device - certainly isn't with the Micron parts I'm using.
This will mean that the bootloader and kernel might not be able to read and write each others' partitions without some modification.