From: Simon Glass Date: Sat, 30 Jul 2022 21:52:35 +0000 (-0600) Subject: bootstd: Update documentation X-Git-Url: http://git.dujemihanovic.xyz/?a=commitdiff_plain;h=228fe57ad20343dd9ff25ad103b6af3602aea602;p=u-boot.git bootstd: Update documentation Add some documentation updates, particularly about global bootmeths. Signed-off-by: Simon Glass --- diff --git a/doc/develop/bootstd.rst b/doc/develop/bootstd.rst index dadd3473e5..b8773f8339 100644 --- a/doc/develop/bootstd.rst +++ b/doc/develop/bootstd.rst @@ -90,6 +90,12 @@ 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 ------------ @@ -113,6 +119,9 @@ the following command:: 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 -------------------- @@ -270,18 +279,8 @@ 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 or a system bootdev, they -should be children of the bootstd device. See `arch/sandbox/dts/test.dts` for -an example of this. - - -The system bootdev ------------------- - -Some bootmeths don't operate on individual bootdevs, but on the whole system. -For example, the EFI boot manager does its own device scanning and does not -make use of the bootdev devices. Such bootmeths can make use of the system -bootdev, typically considered last, after everything else has been tried. +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`: @@ -292,12 +291,11 @@ 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 as well as a -system bootdev. +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, as well as the system bootdev if needed, since no bootmeth devices -will be created automatically in that case. +want to use, since no bootmeth devices will be created automatically in that +case. Using devicetree @@ -348,6 +346,7 @@ Bootmeth drivers are provided for: - distro boot from a disk (syslinux) - distro boot from a network (PXE) - EFI boot using bootefi + - VBE - EFI boot using boot manager @@ -434,18 +433,23 @@ case, the iterator ends up with a `dev_order` array containing the bootdevs that are going to be used, with `num_devs` set to the number of bootdevs and `cur_dev` starting at 0. -Next, the ordering of bootdevs is determined, by `bootmeth_setup_iter_order()`. +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`. Then `cur_method` is set to 0. +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 bootdev and bootmeth -selected. All 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 +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. @@ -456,6 +460,10 @@ If the `BOOTFLOWF_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, but 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. @@ -474,9 +482,10 @@ the least-sigificant digit on the right, counting like this: 0 0 2 0 1 0 0 1 1 - 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 @@ -488,6 +497,31 @@ 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. + 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 @@ -517,17 +551,19 @@ 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. +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 responds with, `bootflow_check()` either +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 `BOOTFLOWF_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. -Each one can adopt its own approach. +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 diff --git a/doc/usage/cmd/bootmeth.rst b/doc/usage/cmd/bootmeth.rst index 9fc7ebf0ab..29d8215a0c 100644 --- a/doc/usage/cmd/bootmeth.rst +++ b/doc/usage/cmd/bootmeth.rst @@ -31,7 +31,9 @@ scanning bootdevs, each bootmeth is tried in turn to see if it can find a valid bootflow. You can use this command to adjust the order or even to omit some boomeths. -The argument is a quoted list of bootmeths to use, by name. +The argument is a quoted list of bootmeths to use, by name. If global bootmeths +are included, they must be at the end, otherwise the scanning mechanism will not +work correctly. bootmeth list @@ -47,14 +49,15 @@ Order Seq Name Description 1 1 efi EFI boot from an .efi file 2 2 pxe PXE boot from a network device 3 3 sandbox Sandbox boot for testing - 4 4 efi_mgr EFI bootmgr flow + glob 4 efi_mgr EFI bootmgr flow ===== === ================== ================================= The fields are as follows: Order: The order in which these bootmeths are invoked for each bootdev. If this - shows as a hyphen, then the bootmeth is not in the current ordering. + shows as a hyphen, then the bootmeth is not in the current ordering. If it + shows as 'glob', then this is a global bootmeth and should be at the end. Seq: The sequence number of the bootmeth, i.e. the normal ordering if none is set