| .. SPDX-License-Identifier: GPL-2.0+: |
| |
| U-Boot Standard Boot |
| ==================== |
| |
| Introduction |
| ------------ |
| |
| Standard boot provides a built-in way for U-Boot to automatically boot |
| an Operating System without custom scripting and other customisation. It |
| introduces the following concepts: |
| |
| - bootdev - a device which can hold or access a distro (e.g. MMC, Ethernet) |
| - bootmeth - a method to scan a bootdev to find bootflows (e.g. distro boot) |
| - bootflow - a description of how to boot (provided by the distro) |
| |
| For Linux, the distro (Linux distribution, e.g. Debian, Fedora) is responsible |
| for creating a bootflow for each kernel combination that it wants to offer. |
| These bootflows are stored on media so they can be discovered by U-Boot. This |
| feature is typically called `distro boot` (see :doc:`distro`) because it is |
| a way for distributions to boot on any hardware. |
| |
| Traditionally U-Boot has relied on scripts to implement this feature. See |
| distro_bootcmd_ for details. This is done because U-Boot has no native support |
| for scanning devices. While the scripts work remarkably well, they can be hard |
| to understand and extend, and the feature does not include tests. They are also |
| making it difficult to move away from ad-hoc CONFIGs, since they are implemented |
| using the environment and a lot of #defines. |
| |
| Standard boot is a generalisation of distro boot. It provides a more built-in |
| way to boot with U-Boot. The feature is extensible to different Operating |
| Systems (such as Chromium OS) and devices (beyond just block and network |
| devices). It supports EFI boot and EFI bootmgr too. |
| |
| Finally, standard boot supports the operation of :doc:`vbe`. |
| |
| Bootflow |
| -------- |
| |
| A bootflow is a file that describes how to boot a distro. Conceptually there can |
| be different formats for that file but at present U-Boot only supports the |
| BootLoaderSpec_ format. which looks something like this:: |
| |
| menu autoboot Welcome to Fedora-Workstation-armhfp-31-1.9. Automatic boot in # second{,s}. Press a key for options. |
| menu title Fedora-Workstation-armhfp-31-1.9 Boot Options. |
| menu hidden |
| |
| label Fedora-Workstation-armhfp-31-1.9 (5.3.7-301.fc31.armv7hl) |
| kernel /vmlinuz-5.3.7-301.fc31.armv7hl |
| append ro root=UUID=9732b35b-4cd5-458b-9b91-80f7047e0b8a rhgb quiet LANG=en_US.UTF-8 cma=192MB cma=256MB |
| fdtdir /dtb-5.3.7-301.fc31.armv7hl/ |
| initrd /initramfs-5.3.7-301.fc31.armv7hl.img |
| |
| As you can see it specifies a kernel, a ramdisk (initrd) and a directory from |
| which to load devicetree files. The details are described in distro_bootcmd_. |
| |
| The bootflow is provided by the distro. It is not part of U-Boot. U-Boot's job |
| is simply to interpret the file and carry out the instructions. This allows |
| distros to boot on essentially any device supported by U-Boot. |
| |
| Typically the first available bootflow is selected and booted. If that fails, |
| then the next one is tried. |
| |
| |
| Bootdev |
| ------- |
| |
| Where does U-Boot find the media that holds the operating systems? That is the |
| job of bootdev. A bootdev is simply a layer on top of a media device (such as |
| MMC, NVMe). The bootdev accesses the device, including partitions and |
| filesystems that might contain things related to an operating system. |
| |
| For example, an MMC bootdev provides access to the individual partitions on the |
| MMC device. It scans through these to find filesystems with the boot flag set, |
| then provides a list of these for consideration. |
| |
| Some bootdevs are not visible until a bus is enumerated, e.g. flash sticks |
| attached via USB. To deal with this, each bootdev has an associated 'hunter' |
| which can hunt for bootdevs of a particular uclass type. For example, the SCSI |
| bootdev scans the SCSI bus looking for devices, creating a bootdev for each |
| Logical Unit Number (LUN) that it finds. |
| |
| |
| Bootmeth |
| -------- |
| |
| Once the list of filesystems is provided, how does U-Boot find the bootflow |
| files in these filesystems. That is the job of bootmeth. Each boot method has |
| its own way of doing this. |
| |
| For example, the distro bootmeth simply looks through the provided filesystem |
| for a file called `extlinux/extlinux.conf`. This files constitutes a bootflow. |
| If the distro bootmeth is used on multiple partitions it may produce multiple |
| bootflows. |
| |
| Note: it is possible to have a bootmeth that uses a partition or a whole device |
| directly, but it is more common to use a filesystem. |
| |
| Note that some bootmeths are 'global', meaning that they select the bootdev |
| themselves. Examples include VBE and EFI boot manager. In this case, they |
| provide a `read_bootflow()` method which checks whatever bootdevs it likes, then |
| returns the bootflow, if found. Some of these bootmeths may be very slow, if |
| they scan a lot of devices. |
| |
| |
| Boot process |
| ------------ |
| |
| U-Boot tries to use the 'lazy init' approach whereever possible and distro boot |
| is no exception. The algorithm is:: |
| |
| while (get next bootdev) |
| while (get next bootmeth) |
| while (get next bootflow) |
| try to boot it |
| |
| So U-Boot works its way through the bootdevs, trying each bootmeth in turn to |
| obtain bootflows, until it either boots or exhausts the available options. |
| |
| Instead of 500 lines of #defines and a 4KB boot script, all that is needed is |
| the following command:: |
| |
| bootflow scan -lb |
| |
| which scans for available bootflows, optionally listing each find it finds (-l) |
| and trying to boot it (-b). |
| |
| When global bootmeths are available, these are typically checked before the |
| above bootdev scanning. |
| |
| |
| Controlling ordering |
| -------------------- |
| |
| Several options are available to control the ordering of boot scanning: |
| |
| |
| boot_targets |
| ~~~~~~~~~~~~ |
| |
| This environment variable can be used to control the list of bootdevs searched |
| and their ordering, for example:: |
| |
| setenv boot_targets "mmc0 mmc1 usb pxe" |
| |
| Entries may be removed or re-ordered in this list to affect the boot order. If |
| the variable is empty, the default ordering is used, based on the priority of |
| bootdevs and their sequence numbers. |
| |
| |
| bootmeths |
| ~~~~~~~~~ |
| |
| This environment variable can be used to control the list of bootmeths used and |
| their ordering for example:: |
| |
| setenv bootmeths "extlinux efi" |
| |
| Entries may be removed or re-ordered in this list to affect the order the |
| bootmeths are tried on each bootdev. If the variable is empty, the default |
| ordering is used, based on the bootmeth sequence numbers, which can be |
| controlled by aliases. |
| |
| The :ref:`usage/cmd/bootmeth:bootmeth command` (`bootmeth order`) operates in |
| the same way as setting this variable. |
| |
| |
| Bootdev uclass |
| -------------- |
| |
| The bootdev uclass provides an simple API call to obtain a bootflows from a |
| device:: |
| |
| int bootdev_get_bootflow(struct udevice *dev, struct bootflow_iter *iter, |
| struct bootflow *bflow); |
| |
| This takes a iterator which indicates the bootdev, partition and bootmeth to |
| use. It returns a bootflow. This is the core of the bootdev implementation. The |
| bootdev drivers that implement this differ depending on the media they are |
| reading from, but each is responsible for returning a valid bootflow if |
| available. |
| |
| A helper called `bootdev_find_in_blk()` makes it fairly easy to implement this |
| function for each media device uclass, in a few lines of code. For many types |
| ot bootdevs, the `get_bootflow` member can be NULL, indicating that the default |
| handler is used. This is called `default_get_bootflow()` and it only works with |
| block devices. |
| |
| |
| Bootdev drivers |
| --------------- |
| |
| A bootdev driver is typically fairly simple. Here is one for mmc:: |
| |
| static int mmc_bootdev_bind(struct udevice *dev) |
| { |
| struct bootdev_uc_plat *ucp = dev_get_uclass_plat(dev); |
| |
| ucp->prio = BOOTDEVP_2_INTERNAL_FAST; |
| |
| return 0; |
| } |
| |
| struct bootdev_ops mmc_bootdev_ops = { |
| }; |
| |
| static const struct udevice_id mmc_bootdev_ids[] = { |
| { .compatible = "u-boot,bootdev-mmc" }, |
| { } |
| }; |
| |
| U_BOOT_DRIVER(mmc_bootdev) = { |
| .name = "mmc_bootdev", |
| .id = UCLASS_BOOTDEV, |
| .ops = &mmc_bootdev_ops, |
| .bind = mmc_bootdev_bind, |
| .of_match = mmc_bootdev_ids, |
| }; |
| |
| You may notice that the `get_bootflow` memory is not provided, so is NULL. This |
| means that `default_get_bootflow()` is used. This simply obtains the |
| block device and calls a bootdev helper function to do the rest. The |
| implementation of `bootdev_find_in_blk()` checks the partition table, and |
| attempts to read a file from a filesystem on the partition number given by the |
| `@iter->part` parameter. If there are any bootable partitions in the table, |
| then only bootable partitions are considered. |
| |
| Each bootdev has a priority, which indicates the order in which it is used, |
| if `boot_targets` is not used. Faster bootdevs are used first, since they are |
| more likely to be able to boot the device quickly. |
| |
| |
| Environment Variables |
| --------------------- |
| |
| Various environment variables are used by standard boot. These allow the board |
| to control where things are placed when booting the OS. You should ensure that |
| your boards sets values for these. |
| |
| fdtfile |
| Name of the flattened device tree (FDT) file to load, e.g. |
| "rockchip/rk3399-rockpro64.dtb" |
| |
| fdtaddr_addr_r |
| Address at which to load the FDT, e.g. 0x01f00000 |
| |
| fdtoverlay_addr_r (needed if overlays are used) |
| Address at which to load the overlay for the FDT, e.g. 0x02000000 |
| |
| kernel_addr_r |
| Address at which to load the kernel, e.g. 0x02080000 |
| |
| kernel_comp_addr_r |
| Address to which to decompress the kernel, e.g. 0x08000000 |
| |
| kernel_comp_size |
| Size of available space for decompressed kernel, e.g. 0x2000000 |
| |
| pxefile_addr_r |
| Address at which to load the PXE file, e.g. 0x00600000 |
| |
| ramdisk_addr_r |
| Address at which to load the ramdisk, e.g. 0x06000000 |
| |
| scriptaddr |
| Address at which to load the U-Boot script, e.g. 0x00500000 |
| |
| script_offset_f |
| SPI flash offset from which to load the U-Boot script, e.g. 0xffe000 |
| |
| script_size_f |
| Size of the script to load, e.g. 0x2000 |
| |
| Some variables are set by script bootmeth: |
| |
| devtype |
| Device type being used for boot, e.g. mmc |
| |
| devnum |
| Device number being used for boot, e.g. 1 |
| |
| distro_bootpart |
| Partition being used for boot, e.g. 2 |
| |
| prefix |
| Directory containing the script |
| |
| mmc_bootdev |
| Device number being used for boot (e.g. 1). This is only used by MMC on |
| sunxi boards. |
| |
| |
| Device hierarchy |
| ---------------- |
| |
| A bootdev device is a child of the media device. In this example, you can see |
| that the bootdev is a sibling of the block device and both are children of |
| media device:: |
| |
| mmc 0 [ + ] bcm2835-sdhost | |-- mmc@7e202000 |
| blk 0 [ + ] mmc_blk | | |-- mmc@7e202000.blk |
| bootdev 0 [ ] mmc_bootdev | | `-- mmc@7e202000.bootdev |
| mmc 1 [ + ] sdhci-bcm2835 | |-- sdhci@7e300000 |
| blk 1 [ ] mmc_blk | | |-- sdhci@7e300000.blk |
| bootdev 1 [ ] mmc_bootdev | | `-- sdhci@7e300000.bootdev |
| |
| The bootdev device is typically created automatically in the media uclass' |
| `post_bind()` method by calling `bootdev_setup_for_dev()` or |
| `bootdev_setup_for_sibling_blk()`. The code typically something like this:: |
| |
| /* dev is the Ethernet device */ |
| ret = bootdev_setup_for_dev(dev, "eth_bootdev"); |
| if (ret) |
| return log_msg_ret("bootdev", ret); |
| |
| or:: |
| |
| /* blk is the block device (child of MMC device) |
| ret = bootdev_setup_for_sibling_blk(blk, "mmc_bootdev"); |
| if (ret) |
| return log_msg_ret("bootdev", ret); |
| |
| |
| Here, `eth_bootdev` is the name of the Ethernet bootdev driver and `dev` |
| is the ethernet device. This function is safe to call even if standard boot is |
| not enabled, since it does nothing in that case. It can be added to all uclasses |
| which implement suitable media. |
| |
| |
| The bootstd device |
| ------------------ |
| |
| Standard boot requires a single instance of the bootstd device to make things |
| work. This includes global information about the state of standard boot. See |
| `struct bootstd_priv` for this structure, accessed with `bootstd_get_priv()`. |
| |
| Within the devicetree, if you add bootmeth devices, they should be children of |
| the bootstd device. See `arch/sandbox/dts/test.dts` for an example of this. |
| |
| |
| .. _`Automatic Devices`: |
| |
| Automatic devices |
| ----------------- |
| |
| It is possible to define all the required devices in the devicetree manually, |
| but it is not necessary. The bootstd uclass includes a `dm_scan_other()` |
| function which creates the bootstd device if not found. If no bootmeth devices |
| are found at all, it creates one for each available bootmeth driver. |
| |
| If your devicetree has any bootmeth device it must have all of them that you |
| want to use, since no bootmeth devices will be created automatically in that |
| case. |
| |
| |
| Using devicetree |
| ---------------- |
| |
| If a bootdev is complicated or needs configuration information, it can be |
| added to the devicetree as a child of the media device. For example, imagine a |
| bootdev which reads a bootflow from SPI flash. The devicetree fragment might |
| look like this:: |
| |
| spi@0 { |
| flash@0 { |
| reg = <0>; |
| compatible = "spansion,m25p16", "jedec,spi-nor"; |
| spi-max-frequency = <40000000>; |
| |
| bootdev { |
| compatible = "u-boot,sf-bootdev"; |
| offset = <0x2000>; |
| size = <0x1000>; |
| }; |
| }; |
| }; |
| |
| The `sf-bootdev` driver can implement a way to read from the SPI flash, using |
| the offset and size provided, and return that bootflow file back to the caller. |
| When distro boot wants to read the kernel it calls distro_getfile() which must |
| provide a way to read from the SPI flash. See `distro_boot()` at distro_boot_ |
| for more details. |
| |
| Of course this is all internal to U-Boot. All the distro sees is another way |
| to boot. |
| |
| |
| Configuration |
| ------------- |
| |
| Standard boot is enabled with `CONFIG_BOOTSTD`. Each bootmeth has its own CONFIG |
| option also. For example, `CONFIG_BOOTMETH_EXTLINUX` enables support for |
| booting from a disk using an `extlinux.conf` file. |
| |
| To enable all feature sof standard boot, use `CONFIG_BOOTSTD_FULL`. This |
| includes the full set of commands, more error messages when things go wrong and |
| bootmeth ordering with the bootmeths environment variable. |
| |
| You should probably also enable `CONFIG_BOOTSTD_DEFAULTS`, which provides |
| several filesystem and network features (if `CONFIG_NET` is enabled) so that |
| a good selection of boot options is available. |
| |
| |
| Available bootmeth drivers |
| -------------------------- |
| |
| Bootmeth drivers are provided for: |
| |
| - extlinux / syslinux boot from a disk |
| - extlinux boot from a network (PXE) |
| - U-Boot scripts from disk, network or SPI flash |
| - EFI boot using bootefi from disk |
| - VBE |
| - EFI boot using boot manager |
| |
| |
| Command interface |
| ----------------- |
| |
| Three commands are available: |
| |
| `bootdev` |
| Allows listing of available bootdevs, selecting a particular one and |
| getting information about it. See :doc:`../usage/cmd/bootdev` |
| |
| `bootflow` |
| Allows scanning one or more bootdevs for bootflows, listing available |
| bootflows, selecting one, obtaining information about it and booting it. |
| See :doc:`../usage/cmd/bootflow` |
| |
| `bootmeth` |
| Allow listing of available bootmethds and setting the order in which they |
| are tried. See :doc:`../usage/cmd/bootmeth` |
| |
| .. _BootflowStates: |
| |
| Bootflow states |
| --------------- |
| |
| Here is a list of states that a bootflow can be in: |
| |
| ======= ======================================================================= |
| State Meaning |
| ======= ======================================================================= |
| base Starting-out state, indicates that no media/partition was found. For an |
| SD card socket it may indicate that the card is not inserted. |
| media Media was found (e.g. SD card is inserted) but no partition information |
| was found. It might lack a partition table or have a read error. |
| part Partition was found but a filesystem could not be read. This could be |
| because the partition does not hold a filesystem or the filesystem is |
| very corrupted. |
| fs Filesystem was found but the file could not be read. It could be |
| missing or in the wrong subdirectory. |
| file File was found and its size detected, but it could not be read. This |
| could indicate filesystem corruption. |
| ready File was loaded and is ready for use. In this state the bootflow is |
| ready to be booted. |
| ======= ======================================================================= |
| |
| |
| Theory of operation |
| ------------------- |
| |
| This describes how standard boot progresses through to booting an operating |
| system. |
| |
| To start. all the necessary devices must be bound, including bootstd, which |
| provides the top-level `struct bootstd_priv` containing optional configuration |
| information. The bootstd device is also holds the various lists used while |
| scanning. This step is normally handled automatically by driver model, as |
| described in `Automatic Devices`_. |
| |
| Bootdevs are also required, to provide access to the media to use. These are not |
| useful by themselves: bootmeths are needed to provide the means of scanning |
| those bootdevs. So, all up, we need a single bootstd device, one or more bootdev |
| devices and one or more bootmeth devices. |
| |
| Once these are ready, typically a `bootflow scan` command is issued. This kicks |
| of the iteration process, which involves hunting for bootdevs and looking |
| through the bootdevs and their partitions one by one to find bootflows. |
| |
| Iteration is kicked off using `bootflow_scan_first()`. |
| |
| The iterator is set up with `bootflow_iter_init()`. This simply creates an |
| empty one with the given flags. Flags are used to control whether each |
| iteration is displayed, whether to return iterations even if they did not result |
| in a valid bootflow, whether to iterate through just a single bootdev, etc. |
| |
| Then the iterator is set up to according to the parameters given: |
| |
| - When `dev` is provided, then a single bootdev is scanned. In this case, |
| `BOOTFLOWIF_SKIP_GLOBAL` and `BOOTFLOWIF_SINGLE_DEV` are set. No hunters are |
| used in this case |
| |
| - Otherwise, when `label` is provided, then a single label or named bootdev is |
| scanned. In this case `BOOTFLOWIF_SKIP_GLOBAL` is set and there are three |
| options (with an effect on the `iter_incr()` function described later): |
| |
| - If `label` indicates a numeric bootdev number (e.g. "2") then |
| `BOOTFLOW_METHF_SINGLE_DEV` is set. In this case, moving to the next bootdev |
| simple stops, since there is only one. No hunters are used. |
| - If `label` indicates a particular media device (e.g. "mmc1") then |
| `BOOTFLOWIF_SINGLE_MEDIA` is set. In this case, moving to the next bootdev |
| processes just the children of the media device. Hunters are used, in this |
| example just the "mmc" hunter. |
| - If `label` indicates a media uclass (e.g. "mmc") then |
| `BOOTFLOWIF_SINGLE_UCLASS` is set. In this case, all bootdevs in that uclass |
| are used. Hunters are used, in this example just the "mmc" hunter |
| |
| - Otherwise, none of the above flags is set and iteration is set up to work |
| through `boot_targets` environment variable (or `bootdev-order` device tree |
| property) in order, running the relevant hunter first. In this case |
| `cur_label` is used to indicate the label being processed. If there is no list |
| of labels, then all bootdevs are processed in order of priority, running the |
| hunters as it goes. |
| |
| With the above it is therefore possible to iterate in a variety of ways. |
| |
| No attempt is made to determine the ordering of bootdevs, since this cannot be |
| known in advance if we are using the hunters. Any hunter might discover a new |
| bootdev and disturb the original ordering. |
| |
| Next, the ordering of bootmeths is determined, by `bootmeth_setup_iter_order()`. |
| By default the ordering is again by sequence number, i.e. the `/aliases` node, |
| or failing that the order in the devicetree. But the `bootmeth order` command |
| or `bootmeths` environment variable can be used to set up an ordering. If that |
| has been done, the ordering is in `struct bootstd_priv`, so that ordering is |
| simply copied into the iterator. Either way, the `method_order` array it set up, |
| along with `num_methods`. |
| |
| Note that global bootmeths are always put at the end of the ordering. If any are |
| present, `cur_method` is set to the first one, so that global bootmeths are done |
| first. Once all have been used, these bootmeths are dropped from the iteration. |
| When there are no global bootmeths, `cur_method` is set to 0. |
| |
| At this point the iterator is ready to use, with the first bootmeth selected. |
| Most of the other fields are 0. This means that the current partition |
| is 0, which is taken to mean the whole device, since partition numbers start at |
| 1. It also means that `max_part` is 0, i.e. the maximum partition number we know |
| about is 0, meaning that, as far as we know, there is no partition table on this |
| bootdev. |
| |
| With the iterator ready, `bootflow_scan_first()` checks whether the current |
| settings produce a valid bootflow. This is handled by `bootflow_check()`, which |
| either returns 0 (if it got something) or an error if not (more on that later). |
| If the `BOOTFLOWIF_ALL` iterator flag is set, even errors are returned as |
| incomplete bootflows, but normally an error results in moving onto the next |
| iteration. |
| |
| Note that `bootflow_check()` handles global bootmeths explicitly, by calling |
| `bootmeth_get_bootflow()` on each one. The `doing_global` flag indicates when |
| the iterator is in that state. |
| |
| The `bootflow_scan_next()` function handles moving onto the next iteration and |
| checking it. In fact it sits in a loop doing that repeatedly until it finds |
| something it wants to return. |
| |
| The actual 'moving on' part is implemented in `iter_incr()`. This is a fairly |
| simple function. It increments the first counter. If that hits its maximum, it |
| sets it to zero and increments the second counter. You can think of all the |
| counters together as a number with three digits which increment in order, with |
| the least-sigificant digit on the right, counting like this: |
| |
| ======== ======= ======= |
| bootdev part method |
| ======== ======= ======= |
| 0 0 0 |
| 0 0 1 |
| 0 0 2 |
| 0 1 0 |
| 0 1 1 |
| 0 1 2 |
| 1 0 0 |
| 1 0 1 |
| ... |
| ======== ======= ======= |
| |
| The maximum value for `method` is `num_methods - 1` so when it exceeds that, it |
| goes back to 0 and the next `part` is considered. The maximum value for that is |
| `max_part`, which is initially zero for all bootdevs. If we find a partition |
| table on that bootdev, `max_part` can be updated during the iteration to a |
| higher value - see `bootdev_find_in_blk()` for that, described later. If that |
| exceeds its maximum, then the next bootdev is used. In this way, iter_incr() |
| works its way through all possibilities, moving forward one each time it is |
| called. |
| |
| Note that global bootmeths introduce a subtlety into the above description. |
| When `doing_global` is true, the iteration takes place only among the bootmeths, |
| i.e. the last column above. The global bootmeths are at the end of the list. |
| Assuming that they are entries 3 and 4 in the list, the iteration then looks |
| like this: |
| |
| ======== ======= ======= ======================================= |
| bootdev part method notes |
| ======== ======= ======= ======================================= |
| . . 3 doing_global = true, method_count = 5 |
| . . 4 |
| 0 0 0 doing_global = false, method_count = 3 |
| 0 0 1 |
| 0 0 2 |
| 0 1 0 |
| 0 1 1 |
| 0 1 2 |
| 1 0 0 |
| 1 0 1 |
| ... |
| ======== ======= ======= ======================================= |
| |
| The changeover of the value of `doing_global` from true to false is handled in |
| `iter_incr()` as well. |
| |
| Note that the value in the `bootdev` column above is not actually stored - it is |
| just for illustration. In practice, `iter_incr()` uses the flags to determine |
| whether to move to the next bootdev in the uclass, the next child of the media |
| device, the next label, or the next priority level, depending on the flag |
| settings (see `BOOTFLOW_METHF_SINGLE_DEV`, etc. above). |
| |
| There is no expectation that iteration will actually finish. Quite often a |
| valid bootflow is found early on. With `bootflow scan -b`, that causes the |
| bootflow to be immediately booted. Assuming it is successful, the iteration never |
| completes. |
| |
| Also note that the iterator hold the **current** combination being considered. |
| So when `iter_incr()` is called, it increments to the next one and returns it, |
| the new **current** combination. |
| |
| Note also the `err` field in `struct bootflow_iter`. This is normally 0 and has |
| thus has no effect on `iter_inc()`. But if it is non-zero, signalling an error, |
| it indicates to the iterator what it should do when called. It can force moving |
| to the next partition, or bootdev, for example. The special values |
| `BF_NO_MORE_PARTS` and `BF_NO_MORE_DEVICES` handle this. When `iter_incr` sees |
| `BF_NO_MORE_PARTS` it knows that it should immediately move to the next bootdev. |
| When it sees `BF_NO_MORE_DEVICES` it knows that there is nothing more it can do |
| so it should immediately return. The caller of `iter_incr()` is responsible for |
| updating the `err` field, based on the return value it sees. |
| |
| The above describes the iteration process at a high level. It is basically a |
| very simple increment function with a checker called `bootflow_check()` that |
| checks the result of each iteration generated, to determine whether it can |
| produce a bootflow. |
| |
| So what happens inside of `bootflow_check()`? It simply calls the uclass |
| method `bootdev_get_bootflow()` to ask the bootdev to return a bootflow. It |
| passes the iterator to the bootdev method, so that function knows what we are |
| talking about. At first, the bootflow is set up in the state `BOOTFLOWST_BASE`, |
| with just the `method` and `dev` intiialised. But the bootdev may fill in more, |
| e.g. updating the state, depending on what it finds. For global bootmeths the |
| `bootmeth_get_bootflow()` function is called instead of |
| `bootdev_get_bootflow()`. |
| |
| Based on what the bootdev or bootmeth responds with, `bootflow_check()` either |
| returns a valid bootflow, or a partial one with an error. A partial bootflow |
| is one that has some fields set up, but did not reach the `BOOTFLOWST_READY` |
| state. As noted before, if the `BOOTFLOWIF_ALL` iterator flag is set, then all |
| bootflows are returned, even partial ones. This can help with debugging. |
| |
| So at this point you can see that total control over whether a bootflow can |
| be generated from a particular iteration, or not, rests with the bootdev (or |
| global bootmeth). Each one can adopt its own approach. |
| |
| Going down a level, what does the bootdev do in its `get_bootflow()` method? |
| Let us consider the MMC bootdev. In that case the call to |
| `bootdev_get_bootflow()` ends up in `default_get_bootflow()`. It locates the |
| parent device of the bootdev, i.e. the `UCLASS_MMC` device itself, then finds |
| the block device associated with it. It then calls the helper function |
| `bootdev_find_in_blk()` to do all the work. This is common with just about any |
| bootdev that is based on a media device. |
| |
| The `bootdev_find_in_blk()` helper is implemented in the bootdev uclass. It |
| names the bootflow and copies the partition number in from the iterator. Then it |
| calls the bootmeth device to check if it can support this device. This is |
| important since some bootmeths only work with network devices, for example. If |
| that check fails, it stops. |
| |
| Assuming the bootmeth is happy, or at least indicates that it is willing to try |
| (by returning 0 from its `check()` method), the next step is to try the |
| partition. If that works it tries to detect a file system. If that works then it |
| calls the bootmeth device once more, this time to read the bootflow. |
| |
| Note: Normally a filesystem is needed for the bootmeth to be called on block |
| devices, but bootmeths which don't need that can set the BOOTMETHF_ANY_PART |
| flag to indicate that they can scan any partition. An example is the ChromiumOS |
| bootmeth which can store a kernel in a raw partition. Note also that sandbox is |
| a special case, since in that case the host filesystem can be accessed even |
| though the block device is NULL. |
| |
| If we take the example of the `bootmeth_extlinux` driver, this call ends up at |
| `extlinux_read_bootflow()`. It has the filesystem ready, so tries various |
| filenames to try to find the `extlinux.conf` file, reading it if possible. If |
| all goes well the bootflow ends up in the `BOOTFLOWST_READY` state. |
| |
| At this point, we fall back from the bootmeth driver, to |
| `bootdev_find_in_blk()`, then back to `default_get_bootflow()`, then to |
| `bootdev_get_bootflow()`, then to `bootflow_check()` and finally to its caller, |
| either `bootflow_scan_first()` or `bootflow_scan_next()`. In either case, |
| the bootflow is returned as the result of this iteration, assuming it made it to |
| the `BOOTFLOWST_READY` state. |
| |
| That is the basic operation of scanning for bootflows. The process of booting a |
| bootflow is handled by the bootmeth driver for that bootflow. In the case of |
| extlinux boot, this parses and processes the `extlinux.conf` file that was read. |
| See `extlinux_boot()` for how that works. The processing may involve reading |
| additional files, which is handled by the `read_file()` method, which is |
| `extlinux_read_file()` in this case. All bootmethds should support reading |
| files, since the bootflow is typically only the basic instructions and does not |
| include the operating system itself, ramdisk, device tree, etc. |
| |
| The vast majority of the bootstd code is concerned with iterating through |
| partitions on bootdevs and using bootmethds to find bootflows. |
| |
| How about bootdevs which are not block devices? They are handled by the same |
| methods as above, but with a different implementation. For example, the bootmeth |
| for PXE boot (over a network) uses `tftp` to read files rather than `fs_read()`. |
| But other than that it is very similar. |
| |
| |
| Tests |
| ----- |
| |
| Tests are located in `test/boot` and cover the core functionality as well as |
| the commands. All tests use sandbox so can be run on a standard Linux computer |
| and in U-Boot's CI. |
| |
| For testing, a DOS-formatted disk image is used with a FAT partition on it and |
| a second unused partition. This is created in `setup_bootflow_image()`, with a |
| canned one from the source tree used if it cannot be created (e.g. in CI). |
| |
| |
| Bootflow internals |
| ------------------ |
| |
| The bootstd device holds a linked list of scanned bootflows as well as the |
| currently selected bootdev and bootflow (for use by commands). This is in |
| `struct bootstd_priv`. |
| |
| Each bootdev device has its own `struct bootdev_uc_plat` which holds a |
| list of scanned bootflows just for that device. |
| |
| The bootflow itself is documented in bootflow_h_. It includes various bits of |
| information about the bootflow and a buffer to hold the file. |
| |
| |
| Future |
| ------ |
| |
| Apart from the to-do items below, different types of bootflow files may be |
| implemented in future, e.g. Chromium OS support which is currently only |
| available as a script in chromebook_coral. |
| |
| |
| To do |
| ----- |
| |
| Some things that need to be done to completely replace the distro-boot scripts: |
| |
| - add bootdev drivers for dhcp, sata, scsi, ide, virtio |
| - PXE boot for EFI |
| - support for loading U-Boot scripts |
| |
| Other ideas: |
| |
| - `bootflow prep` to load everything preparing for boot, so that `bootflow boot` |
| can just do the boot. |
| - automatically load kernel, FDT, etc. to suitable addresses so the board does |
| not need to specify things like `pxefile_addr_r` |
| |
| |
| .. _distro_bootcmd: https://github.com/u-boot/u-boot/blob/master/include/config_distro_bootcmd.h |
| .. _BootLoaderSpec: http://www.freedesktop.org/wiki/Specifications/BootLoaderSpec/ |
| .. _distro_boot: https://github.com/u-boot/u-boot/blob/master/boot/distro.c |
| .. _bootflow_h: https://github.com/u-boot/u-boot/blob/master/include/bootflow.h |