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Explain block maps by going through two common use-cases. Signed-off-by: Tobias Waldekranz <tobias@waldekranz.com> Reviewed-by: Simon Glass <sjg@chromium.org>
111 lines
3.2 KiB
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111 lines
3.2 KiB
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.. SPDX-License-Identifier: GPL-2.0+
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..
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.. Copyright (c) 2023 Addiva Elektronik
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.. Author: Tobias Waldekranz <tobias@waldekranz.com>
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Block Maps (blkmap)
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===================
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Block maps are a way of looking at various sources of data through the
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lens of a regular block device. It lets you treat devices that are not
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block devices, like RAM, as if they were. It also lets you export a
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slice of an existing block device, which does not have to correspond
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to a partition boundary, as a new block device.
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This is primarily useful because U-Boot's filesystem drivers only
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operate on block devices, so a block map lets you access filesystems
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wherever they might be located.
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The implementation is loosely modeled on Linux's "Device Mapper"
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subsystem, see `kernel documentation`_ for more information.
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.. _kernel documentation: https://docs.kernel.org/admin-guide/device-mapper/index.html
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Example: Netbooting an Ext4 Image
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---------------------------------
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Say that our system is using an Ext4 filesystem as its rootfs, where
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the kernel is stored in ``/boot``. This image is then typically stored
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in an eMMC partition. In this configuration, we can use something like
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``load mmc 0 ${kernel_addr_r} /boot/Image`` to load the kernel image
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into the expected location, and then boot the system. No problems.
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Now imagine that during development, or as a recovery mechanism, we
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want to boot the same type of image by downloading it over the
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network. Getting the image to the target is easy enough:
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::
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dhcp ${ramdisk_addr_r} rootfs.ext4
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But now we are faced with a predicament: how to we extract the kernel
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image? Block maps to the rescue!
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We start by creating a new device:
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::
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blkmap create netboot
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Before setting up the mapping, we figure out the size of the
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downloaded file, in blocks:
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::
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setexpr fileblks ${filesize} + 0x1ff
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setexpr fileblks ${filesize} / 0x200
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Then we can add a mapping to the start of our device, backed by the
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memory at `${loadaddr}`:
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::
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blkmap map netboot 0 ${fileblks} mem ${fileaddr}
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Now we can access the filesystem via the virtual device:
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::
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blkmap get netboot dev devnum
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load blkmap ${devnum} ${kernel_addr_r} /boot/Image
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Example: Accessing a filesystem inside an FIT image
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---------------------------------------------------
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In this example, an FIT image is stored in an eMMC partition. We would
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like to read the file ``/etc/version``, stored inside a Squashfs image
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in the FIT. Since the Squashfs image is not stored on a partition
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boundary, there is no way of accessing it via ``load mmc ...``.
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What we can to instead is to first figure out the offset and size of
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the filesystem:
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::
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mmc dev 0
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mmc read ${loadaddr} 0 0x100
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fdt addr ${loadaddr}
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fdt get value squashaddr /images/ramdisk data-position
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fdt get value squashsize /images/ramdisk data-size
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setexpr squashblk ${squashaddr} / 0x200
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setexpr squashsize ${squashsize} + 0x1ff
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setexpr squashsize ${squashsize} / 0x200
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Then we can create a block map that maps to that slice of the full
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partition:
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::
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blkmap create sq
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blkmap map sq 0 ${squashsize} linear mmc 0 ${squashblk}
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Now we can access the filesystem:
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::
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blkmap get sq dev devnum
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load blkmap ${devnum} ${loadaddr} /etc/version
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