mirror of
https://github.com/AsahiLinux/u-boot
synced 2024-12-20 18:23:08 +00:00
e33a5c6be5
We currently have an if_type (interface type) and a uclass id. These are closely related and we don't need to have both. Drop the if_type values and use the uclass ones instead. Maintain the existing, subtle, one-way conversion between UCLASS_USB and UCLASS_MASS_STORAGE for now, and add a comment. Signed-off-by: Simon Glass <sjg@chromium.org>
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27 KiB
ReStructuredText
795 lines
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ReStructuredText
.. SPDX-License-Identifier: GPL-2.0+
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.. Copyright (c) 2018 Heinrich Schuchardt
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UEFI on U-Boot
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==============
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The Unified Extensible Firmware Interface Specification (UEFI) [1] has become
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the default for booting on AArch64 and x86 systems. It provides a stable API for
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the interaction of drivers and applications with the firmware. The API comprises
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access to block storage, network, and console to name a few. The Linux kernel
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and boot loaders like GRUB or the FreeBSD loader can be executed.
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Development target
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------------------
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The implementation of UEFI in U-Boot strives to reach the requirements described
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in the "Embedded Base Boot Requirements (EBBR) Specification - Release v1.0"
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[2]. The "Server Base Boot Requirements System Software on ARM Platforms" [3]
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describes a superset of the EBBR specification and may be used as further
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reference.
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A full blown UEFI implementation would contradict the U-Boot design principle
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"keep it small".
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Building U-Boot for UEFI
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------------------------
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The UEFI standard supports only little-endian systems. The UEFI support can be
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activated for ARM and x86 by specifying::
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CONFIG_CMD_BOOTEFI=y
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CONFIG_EFI_LOADER=y
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in the .config file.
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Support for attaching virtual block devices, e.g. iSCSI drives connected by the
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loaded UEFI application [4], requires::
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CONFIG_BLK=y
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CONFIG_PARTITIONS=y
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Executing a UEFI binary
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~~~~~~~~~~~~~~~~~~~~~~~
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The bootefi command is used to start UEFI applications or to install UEFI
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drivers. It takes two parameters::
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bootefi <image address> [fdt address]
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* image address - the memory address of the UEFI binary
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* fdt address - the memory address of the flattened device tree
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Below you find the output of an example session starting GRUB::
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=> load mmc 0:2 ${fdt_addr_r} boot/dtb
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29830 bytes read in 14 ms (2 MiB/s)
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=> load mmc 0:1 ${kernel_addr_r} efi/debian/grubaa64.efi
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reading efi/debian/grubaa64.efi
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120832 bytes read in 7 ms (16.5 MiB/s)
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=> bootefi ${kernel_addr_r} ${fdt_addr_r}
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When booting from a memory location it is unknown from which file it was loaded.
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Therefore the bootefi command uses the device path of the block device partition
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or the network adapter and the file name of the most recently loaded PE-COFF
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file when setting up the loaded image protocol.
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Launching a UEFI binary from a FIT image
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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A signed FIT image can be used to securely boot a UEFI image via the
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bootm command. This feature is available if U-Boot is configured with::
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CONFIG_BOOTM_EFI=y
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A sample configuration is provided as file doc/uImage.FIT/uefi.its.
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Below you find the output of an example session starting GRUB::
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=> load mmc 0:1 ${kernel_addr_r} image.fit
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4620426 bytes read in 83 ms (53.1 MiB/s)
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=> bootm ${kernel_addr_r}#config-grub-nofdt
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## Loading kernel from FIT Image at 40400000 ...
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Using 'config-grub-nofdt' configuration
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Verifying Hash Integrity ... sha256,rsa2048:dev+ OK
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Trying 'efi-grub' kernel subimage
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Description: GRUB EFI Firmware
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Created: 2019-11-20 8:18:16 UTC
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Type: Kernel Image (no loading done)
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Compression: uncompressed
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Data Start: 0x404000d0
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Data Size: 450560 Bytes = 440 KiB
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Hash algo: sha256
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Hash value: 4dbee00021112df618f58b3f7cf5e1595533d543094064b9ce991e8b054a9eec
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Verifying Hash Integrity ... sha256+ OK
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XIP Kernel Image (no loading done)
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## Transferring control to EFI (at address 404000d0) ...
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Welcome to GRUB!
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See doc/uImage.FIT/howto.txt for an introduction to FIT images.
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Configuring UEFI secure boot
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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The UEFI specification[1] defines a secure way of executing UEFI images
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by verifying a signature (or message digest) of image with certificates.
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This feature on U-Boot is enabled with::
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CONFIG_EFI_SECURE_BOOT=y
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To make the boot sequence safe, you need to establish a chain of trust;
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In UEFI secure boot the chain trust is defined by the following UEFI variables
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* PK - Platform Key
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* KEK - Key Exchange Keys
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* db - white list database
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* dbx - black list database
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An in depth description of UEFI secure boot is beyond the scope of this
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document. Please, refer to the UEFI specification and available online
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documentation. Here is a simple example that you can follow for your initial
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attempt (Please note that the actual steps will depend on your system and
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environment.):
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Install the required tools on your host
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* openssl
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* efitools
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* sbsigntool
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Create signing keys and the key database on your host:
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The platform key
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.. code-block:: bash
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openssl req -x509 -sha256 -newkey rsa:2048 -subj /CN=TEST_PK/ \
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-keyout PK.key -out PK.crt -nodes -days 365
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cert-to-efi-sig-list -g 11111111-2222-3333-4444-123456789abc \
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PK.crt PK.esl;
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sign-efi-sig-list -c PK.crt -k PK.key PK PK.esl PK.auth
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The key exchange keys
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.. code-block:: bash
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openssl req -x509 -sha256 -newkey rsa:2048 -subj /CN=TEST_KEK/ \
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-keyout KEK.key -out KEK.crt -nodes -days 365
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cert-to-efi-sig-list -g 11111111-2222-3333-4444-123456789abc \
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KEK.crt KEK.esl
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sign-efi-sig-list -c PK.crt -k PK.key KEK KEK.esl KEK.auth
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The whitelist database
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.. code-block:: bash
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openssl req -x509 -sha256 -newkey rsa:2048 -subj /CN=TEST_db/ \
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-keyout db.key -out db.crt -nodes -days 365
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cert-to-efi-sig-list -g 11111111-2222-3333-4444-123456789abc \
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db.crt db.esl
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sign-efi-sig-list -c KEK.crt -k KEK.key db db.esl db.auth
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Copy the \*.auth files to media, say mmc, that is accessible from U-Boot.
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Sign an image with one of the keys in "db" on your host
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.. code-block:: bash
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sbsign --key db.key --cert db.crt helloworld.efi
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Now in U-Boot install the keys on your board::
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fatload mmc 0:1 <tmpaddr> PK.auth
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setenv -e -nv -bs -rt -at -i <tmpaddr>:$filesize PK
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fatload mmc 0:1 <tmpaddr> KEK.auth
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setenv -e -nv -bs -rt -at -i <tmpaddr>:$filesize KEK
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fatload mmc 0:1 <tmpaddr> db.auth
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setenv -e -nv -bs -rt -at -i <tmpaddr>:$filesize db
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Set up boot parameters on your board::
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efidebug boot add -b 1 HELLO mmc 0:1 /helloworld.efi.signed ""
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Since kernel 5.7 there's an alternative way of loading an initrd using
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LoadFile2 protocol if CONFIG_EFI_LOAD_FILE2_INITRD is enabled.
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The initrd path can be specified with::
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efidebug boot add -b ABE0 'kernel' mmc 0:1 Image -i mmc 0:1 initrd
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Now your board can run the signed image via the boot manager (see below).
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You can also try this sequence by running Pytest, test_efi_secboot,
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on the sandbox
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.. code-block:: bash
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cd <U-Boot source directory>
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pytest.py test/py/tests/test_efi_secboot/test_signed.py --bd sandbox
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UEFI binaries may be signed by Microsoft using the following certificates:
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* KEK: Microsoft Corporation KEK CA 2011
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http://go.microsoft.com/fwlink/?LinkId=321185.
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* db: Microsoft Windows Production PCA 2011
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http://go.microsoft.com/fwlink/p/?linkid=321192.
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* db: Microsoft Corporation UEFI CA 2011
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http://go.microsoft.com/fwlink/p/?linkid=321194.
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Using OP-TEE for EFI variables
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Instead of implementing UEFI variable services inside U-Boot they can
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also be provided in the secure world by a module for OP-TEE[1]. The
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interface between U-Boot and OP-TEE for variable services is enabled by
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CONFIG_EFI_MM_COMM_TEE=y.
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Tianocore EDK II's standalone management mode driver for variables can
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be linked to OP-TEE for this purpose. This module uses the Replay
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Protected Memory Block (RPMB) of an eMMC device for persisting
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non-volatile variables. When calling the variable services via the
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OP-TEE API U-Boot's OP-TEE supplicant relays calls to the RPMB driver
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which has to be enabled via CONFIG_SUPPORT_EMMC_RPMB=y.
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EDK2 Build instructions
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***********************
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.. code-block:: bash
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$ git clone https://github.com/tianocore/edk2.git
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$ git clone https://github.com/tianocore/edk2-platforms.git
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$ cd edk2
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$ git submodule init && git submodule update --init --recursive
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$ cd ..
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$ export WORKSPACE=$(pwd)
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$ export PACKAGES_PATH=$WORKSPACE/edk2:$WORKSPACE/edk2-platforms
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$ export ACTIVE_PLATFORM="Platform/StandaloneMm/PlatformStandaloneMmPkg/PlatformStandaloneMmRpmb.dsc"
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$ export GCC5_AARCH64_PREFIX=aarch64-linux-gnu-
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$ source edk2/edksetup.sh
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$ make -C edk2/BaseTools
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$ build -p $ACTIVE_PLATFORM -b RELEASE -a AARCH64 -t GCC5 -n `nproc`
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OP-TEE Build instructions
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*************************
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.. code-block:: bash
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$ git clone https://github.com/OP-TEE/optee_os.git
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$ cd optee_os
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$ ln -s ../Build/MmStandaloneRpmb/RELEASE_GCC5/FV/BL32_AP_MM.fd
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$ export ARCH=arm
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$ CROSS_COMPILE32=arm-linux-gnueabihf- make -j32 CFG_ARM64_core=y \
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PLATFORM=<myboard> CFG_STMM_PATH=BL32_AP_MM.fd CFG_RPMB_FS=y \
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CFG_RPMB_FS_DEV_ID=0 CFG_CORE_HEAP_SIZE=524288 CFG_RPMB_WRITE_KEY=y \
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CFG_CORE_DYN_SHM=y CFG_RPMB_TESTKEY=y CFG_REE_FS=n \
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CFG_CORE_ARM64_PA_BITS=48 CFG_TEE_CORE_LOG_LEVEL=1 \
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CFG_TEE_TA_LOG_LEVEL=1 CFG_SCTLR_ALIGNMENT_CHECK=n
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U-Boot Build instructions
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*************************
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Although the StandAloneMM binary comes from EDK2, using and storing the
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variables is currently available in U-Boot only.
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.. code-block:: bash
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$ git clone https://github.com/u-boot/u-boot.git
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$ cd u-boot
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$ export CROSS_COMPILE=aarch64-linux-gnu-
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$ export ARCH=<arch>
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$ make <myboard>_defconfig
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$ make menuconfig
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Enable ``CONFIG_OPTEE``, ``CONFIG_CMD_OPTEE_RPMB`` and ``CONFIG_EFI_MM_COMM_TEE``
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.. warning::
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- Your OP-TEE platform port must support Dynamic shared memory, since that's
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the only kind of memory U-Boot supports for now.
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[1] https://optee.readthedocs.io/en/latest/building/efi_vars/stmm.html
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Enabling UEFI Capsule Update feature
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Support has been added for the UEFI capsule update feature which
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enables updating the U-Boot image using the UEFI firmware management
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protocol (FMP). The capsules are not passed to the firmware through
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the UpdateCapsule runtime service. Instead, capsule-on-disk
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functionality is used for fetching capsules from the EFI System
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Partition (ESP) by placing capsule files under the directory::
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\EFI\UpdateCapsule
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The directory is checked for capsules only within the
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EFI system partition on the device specified in the active boot option,
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which is determined by BootXXXX variable in BootNext, or if not, the highest
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priority one within BootOrder. Any BootXXXX variables referring to devices
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not present are ignored when determining the active boot option.
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Please note that capsules will be applied in the alphabetic order of
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capsule file names.
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Creating a capsule file
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***********************
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A capsule file can be created by using tools/mkeficapsule.
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To build this tool, enable::
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CONFIG_TOOLS_MKEFICAPSULE=y
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CONFIG_TOOLS_LIBCRYPTO=y
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Run the following command
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.. code-block:: console
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$ mkeficapsule \
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--index <index> --instance 0 \
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--guid <image GUID> \
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<capsule_file_name>
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Performing the update
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*********************
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Put capsule files under the directory mentioned above.
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Then, following the UEFI specification, you'll need to set
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the EFI_OS_INDICATIONS_FILE_CAPSULE_DELIVERY_SUPPORTED
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bit in OsIndications variable with
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.. code-block:: console
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=> setenv -e -nv -bs -rt -v OsIndications =0x0000000000000004
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Since U-boot doesn't currently support SetVariable at runtime, its value
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won't be taken over across the reboot. If this is the case, you can skip
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this feature check with the Kconfig option (CONFIG_EFI_IGNORE_OSINDICATIONS)
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set.
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A few values need to be defined in the board file for performing the
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capsule update. These values are defined in the board file by
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initialisation of a structure which provides information needed for
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capsule updates. The following structures have been defined for
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containing the image related information
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.. code-block:: c
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struct efi_fw_image {
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efi_guid_t image_type_id;
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u16 *fw_name;
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u8 image_index;
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};
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struct efi_capsule_update_info {
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const char *dfu_string;
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struct efi_fw_image *images;
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};
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A string is defined which is to be used for populating the
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dfu_alt_info variable. This string is used by the function
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set_dfu_alt_info. Instead of taking the variable from the environment,
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the capsule update feature requires that the variable be set through
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the function, since that is more robust. Allowing the user to change
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the location of the firmware updates is not a very secure
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practice. Getting this information from the firmware itself is more
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secure, assuming the firmware has been verified by a previous stage
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boot loader.
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The firmware images structure defines the GUID values, image index
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values and the name of the images that are to be updated through
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the capsule update feature. These values are to be defined as part of
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an array. These GUID values would be used by the Firmware Management
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Protocol(FMP) to populate the image descriptor array and also
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displayed as part of the ESRT table. The image index values defined in
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the array should be one greater than the dfu alt number that
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corresponds to the firmware image. So, if the dfu alt number for an
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image is 2, the value of image index in the fw_images array for that
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image should be 3. The dfu alt number can be obtained by running the
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following command::
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dfu list
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When using the FMP for FIT images, the image index value needs to be
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set to 1.
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Finally, the capsule update can be initiated by rebooting the board.
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An example of setting the values in the struct efi_fw_image and
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struct efi_capsule_update_info is shown below
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.. code-block:: c
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struct efi_fw_image fw_images[] = {
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{
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.image_type_id = DEVELOPERBOX_UBOOT_IMAGE_GUID,
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.fw_name = u"DEVELOPERBOX-UBOOT",
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.image_index = 1,
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},
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{
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.image_type_id = DEVELOPERBOX_FIP_IMAGE_GUID,
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.fw_name = u"DEVELOPERBOX-FIP",
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.image_index = 2,
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},
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{
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.image_type_id = DEVELOPERBOX_OPTEE_IMAGE_GUID,
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.fw_name = u"DEVELOPERBOX-OPTEE",
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.image_index = 3,
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},
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};
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struct efi_capsule_update_info update_info = {
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.dfu_string = "mtd nor1=u-boot.bin raw 200000 100000;"
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"fip.bin raw 180000 78000;"
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"optee.bin raw 500000 100000",
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.images = fw_images,
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};
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Platforms must declare a variable update_info of type struct
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efi_capsule_update_info as shown in the example above. The platform
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will also define a fw_images array which contains information of all
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the firmware images that are to be updated through capsule update
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mechanism. The dfu_string is the string that is to be set as
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dfu_alt_info. In the example above, the image index to be set for
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u-boot.bin binary is 0x1, for fip.bin is 0x2 and for optee.bin is 0x3.
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As an example, for generating the capsule for the optee.bin image, the
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following command can be issued
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.. code-block:: bash
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$ ./tools/mkeficapsule \
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--index 0x3 --instance 0 \
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--guid c1b629f1-ce0e-4894-82bf-f0a38387e630 \
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optee.bin optee.capsule
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Enabling Capsule Authentication
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*******************************
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The UEFI specification defines a way of authenticating the capsule to
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be updated by verifying the capsule signature. The capsule signature
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is computed and prepended to the capsule payload at the time of
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capsule generation. This signature is then verified by using the
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public key stored as part of the X509 certificate. This certificate is
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in the form of an efi signature list (esl) file, which is embedded in
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a device tree.
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The capsule authentication feature can be enabled through the
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following config, in addition to the configs listed above for capsule
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update::
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CONFIG_EFI_CAPSULE_AUTHENTICATE=y
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The public and private keys used for the signing process are generated
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and used by the steps highlighted below.
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1. Install utility commands on your host
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* openssl
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* efitools
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2. Create signing keys and certificate files on your host
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.. code-block:: console
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$ openssl req -x509 -sha256 -newkey rsa:2048 -subj /CN=CRT/ \
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-keyout CRT.key -out CRT.crt -nodes -days 365
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$ cert-to-efi-sig-list CRT.crt CRT.esl
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3. Run the following command to create and sign the capsule file
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.. code-block:: console
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$ mkeficapsule --monotonic-count 1 \
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--private-key CRT.key \
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--certificate CRT.crt \
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--index 1 --instance 0 \
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[--fit | --raw | --guid <guid-string] \
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|
<image_blob> <capsule_file_name>
|
|
|
|
4. Insert the signature list into a device tree in the following format::
|
|
|
|
{
|
|
signature {
|
|
capsule-key = [ <binary of signature list> ];
|
|
}
|
|
...
|
|
}
|
|
|
|
You can do step-4 manually with
|
|
|
|
.. code-block:: console
|
|
|
|
$ dtc -@ -I dts -O dtb -o signature.dtbo signature.dts
|
|
$ fdtoverlay -i orig.dtb -o new.dtb -v signature.dtbo
|
|
|
|
where signature.dts looks like::
|
|
|
|
&{/} {
|
|
signature {
|
|
capsule-key = /incbin/("CRT.esl");
|
|
};
|
|
};
|
|
|
|
Executing the boot manager
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
The UEFI specification foresees to define boot entries and boot sequence via
|
|
UEFI variables. Booting according to these variables is possible via::
|
|
|
|
bootefi bootmgr [fdt address]
|
|
|
|
As of U-Boot v2020.10 UEFI variables cannot be set at runtime. The U-Boot
|
|
command 'efidebug' can be used to set the variables.
|
|
|
|
Executing the built in hello world application
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
A hello world UEFI application can be built with::
|
|
|
|
CONFIG_CMD_BOOTEFI_HELLO_COMPILE=y
|
|
|
|
It can be embedded into the U-Boot binary with::
|
|
|
|
CONFIG_CMD_BOOTEFI_HELLO=y
|
|
|
|
The bootefi command is used to start the embedded hello world application::
|
|
|
|
bootefi hello [fdt address]
|
|
|
|
Below you find the output of an example session::
|
|
|
|
=> bootefi hello ${fdtcontroladdr}
|
|
## Starting EFI application at 01000000 ...
|
|
WARNING: using memory device/image path, this may confuse some payloads!
|
|
Hello, world!
|
|
Running on UEFI 2.7
|
|
Have SMBIOS table
|
|
Have device tree
|
|
Load options: root=/dev/sdb3 init=/sbin/init rootwait ro
|
|
## Application terminated, r = 0
|
|
|
|
The environment variable fdtcontroladdr points to U-Boot's internal device tree
|
|
(if available).
|
|
|
|
Executing the built-in self-test
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
An UEFI self-test suite can be embedded in U-Boot by building with::
|
|
|
|
CONFIG_CMD_BOOTEFI_SELFTEST=y
|
|
|
|
For testing the UEFI implementation the bootefi command can be used to start the
|
|
self-test::
|
|
|
|
bootefi selftest [fdt address]
|
|
|
|
The environment variable 'efi_selftest' can be used to select a single test. If
|
|
it is not provided all tests are executed except those marked as 'on request'.
|
|
If the environment variable is set to 'list' a list of all tests is shown.
|
|
|
|
Below you can find the output of an example session::
|
|
|
|
=> setenv efi_selftest simple network protocol
|
|
=> bootefi selftest
|
|
Testing EFI API implementation
|
|
Selected test: 'simple network protocol'
|
|
Setting up 'simple network protocol'
|
|
Setting up 'simple network protocol' succeeded
|
|
Executing 'simple network protocol'
|
|
DHCP Discover
|
|
DHCP reply received from 192.168.76.2 (52:55:c0:a8:4c:02)
|
|
as broadcast message.
|
|
Executing 'simple network protocol' succeeded
|
|
Tearing down 'simple network protocol'
|
|
Tearing down 'simple network protocol' succeeded
|
|
Boot services terminated
|
|
Summary: 0 failures
|
|
Preparing for reset. Press any key.
|
|
|
|
The UEFI life cycle
|
|
-------------------
|
|
|
|
After the U-Boot platform has been initialized the UEFI API provides two kinds
|
|
of services:
|
|
|
|
* boot services
|
|
* runtime services
|
|
|
|
The API can be extended by loading UEFI drivers which come in two variants:
|
|
|
|
* boot drivers
|
|
* runtime drivers
|
|
|
|
UEFI drivers are installed with U-Boot's bootefi command. With the same command
|
|
UEFI applications can be executed.
|
|
|
|
Loaded images of UEFI drivers stay in memory after returning to U-Boot while
|
|
loaded images of applications are removed from memory.
|
|
|
|
An UEFI application (e.g. an operating system) that wants to take full control
|
|
of the system calls ExitBootServices. After a UEFI application calls
|
|
ExitBootServices
|
|
|
|
* boot services are not available anymore
|
|
* timer events are stopped
|
|
* the memory used by U-Boot except for runtime services is released
|
|
* the memory used by boot time drivers is released
|
|
|
|
So this is a point of no return. Afterwards the UEFI application can only return
|
|
to U-Boot by rebooting.
|
|
|
|
The UEFI object model
|
|
---------------------
|
|
|
|
UEFI offers a flexible and expandable object model. The objects in the UEFI API
|
|
are devices, drivers, and loaded images. These objects are referenced by
|
|
handles.
|
|
|
|
The interfaces implemented by the objects are referred to as protocols. These
|
|
are identified by GUIDs. They can be installed and uninstalled by calling the
|
|
appropriate boot services.
|
|
|
|
Handles are created by the InstallProtocolInterface or the
|
|
InstallMultipleProtocolinterfaces service if NULL is passed as handle.
|
|
|
|
Handles are deleted when the last protocol has been removed with the
|
|
UninstallProtocolInterface or the UninstallMultipleProtocolInterfaces service.
|
|
|
|
Devices offer the EFI_DEVICE_PATH_PROTOCOL. A device path is the concatenation
|
|
of device nodes. By their device paths all devices of a system are arranged in a
|
|
tree.
|
|
|
|
Drivers offer the EFI_DRIVER_BINDING_PROTOCOL. This protocol is used to connect
|
|
a driver to devices (which are referenced as controllers in this context).
|
|
|
|
Loaded images offer the EFI_LOADED_IMAGE_PROTOCOL. This protocol provides meta
|
|
information about the image and a pointer to the unload callback function.
|
|
|
|
The UEFI events
|
|
---------------
|
|
|
|
In the UEFI terminology an event is a data object referencing a notification
|
|
function which is queued for calling when the event is signaled. The following
|
|
types of events exist:
|
|
|
|
* periodic and single shot timer events
|
|
* exit boot services events, triggered by calling the ExitBootServices() service
|
|
* virtual address change events
|
|
* memory map change events
|
|
* read to boot events
|
|
* reset system events
|
|
* system table events
|
|
* events that are only triggered programmatically
|
|
|
|
Events can be created with the CreateEvent service and deleted with CloseEvent
|
|
service.
|
|
|
|
Events can be assigned to an event group. If any of the events in a group is
|
|
signaled, all other events in the group are also set to the signaled state.
|
|
|
|
The UEFI driver model
|
|
---------------------
|
|
|
|
A driver is specific for a single protocol installed on a device. To install a
|
|
driver on a device the ConnectController service is called. In this context
|
|
controller refers to the device for which the driver is installed.
|
|
|
|
The relevant drivers are identified using the EFI_DRIVER_BINDING_PROTOCOL. This
|
|
protocol has has three functions:
|
|
|
|
* supported - determines if the driver is compatible with the device
|
|
* start - installs the driver by opening the relevant protocol with
|
|
attribute EFI_OPEN_PROTOCOL_BY_DRIVER
|
|
* stop - uninstalls the driver
|
|
|
|
The driver may create child controllers (child devices). E.g. a driver for block
|
|
IO devices will create the device handles for the partitions. The child
|
|
controllers will open the supported protocol with the attribute
|
|
EFI_OPEN_PROTOCOL_BY_CHILD_CONTROLLER.
|
|
|
|
A driver can be detached from a device using the DisconnectController service.
|
|
|
|
U-Boot devices mapped as UEFI devices
|
|
-------------------------------------
|
|
|
|
Some of the U-Boot devices are mapped as UEFI devices
|
|
|
|
* block IO devices
|
|
* console
|
|
* graphical output
|
|
* network adapter
|
|
|
|
As of U-Boot 2018.03 the logic for doing this is hard coded.
|
|
|
|
The development target is to integrate the setup of these UEFI devices with the
|
|
U-Boot driver model [5]. So when a U-Boot device is discovered a handle should
|
|
be created and the device path protocol and the relevant IO protocol should be
|
|
installed. The UEFI driver then would be attached by calling ConnectController.
|
|
When a U-Boot device is removed DisconnectController should be called.
|
|
|
|
UEFI devices mapped as U-Boot devices
|
|
-------------------------------------
|
|
|
|
UEFI drivers binaries and applications may create new (virtual) devices, install
|
|
a protocol and call the ConnectController service. Now the matching UEFI driver
|
|
is determined by iterating over the implementations of the
|
|
EFI_DRIVER_BINDING_PROTOCOL.
|
|
|
|
It is the task of the UEFI driver to create a corresponding U-Boot device and to
|
|
proxy calls for this U-Boot device to the controller.
|
|
|
|
In U-Boot 2018.03 this has only been implemented for block IO devices.
|
|
|
|
UEFI uclass
|
|
~~~~~~~~~~~
|
|
|
|
An UEFI uclass driver (lib/efi_driver/efi_uclass.c) has been created that
|
|
takes care of initializing the UEFI drivers and providing the
|
|
EFI_DRIVER_BINDING_PROTOCOL implementation for the UEFI drivers.
|
|
|
|
A linker created list is used to keep track of the UEFI drivers. To create an
|
|
entry in the list the UEFI driver uses the U_BOOT_DRIVER macro specifying
|
|
UCLASS_EFI_LOADER as the ID of its uclass, e.g::
|
|
|
|
/* Identify as UEFI driver */
|
|
U_BOOT_DRIVER(efi_block) = {
|
|
.name = "EFI block driver",
|
|
.id = UCLASS_EFI_LOADER,
|
|
.ops = &driver_ops,
|
|
};
|
|
|
|
The available operations are defined via the structure struct efi_driver_ops::
|
|
|
|
struct efi_driver_ops {
|
|
const efi_guid_t *protocol;
|
|
const efi_guid_t *child_protocol;
|
|
int (*bind)(efi_handle_t handle, void *interface);
|
|
};
|
|
|
|
When the supported() function of the EFI_DRIVER_BINDING_PROTOCOL is called the
|
|
uclass checks if the protocol GUID matches the protocol GUID of the UEFI driver.
|
|
In the start() function the bind() function of the UEFI driver is called after
|
|
checking the GUID.
|
|
The stop() function of the EFI_DRIVER_BINDING_PROTOCOL disconnects the child
|
|
controllers created by the UEFI driver and the UEFI driver. (In U-Boot v2013.03
|
|
this is not yet completely implemented.)
|
|
|
|
UEFI block IO driver
|
|
~~~~~~~~~~~~~~~~~~~~
|
|
|
|
The UEFI block IO driver supports devices exposing the EFI_BLOCK_IO_PROTOCOL.
|
|
|
|
When connected it creates a new U-Boot block IO device with interface type
|
|
UCLASS_EFI_LOADER, adds child controllers mapping the partitions, and installs
|
|
the EFI_SIMPLE_FILE_SYSTEM_PROTOCOL on these. This can be used together with the
|
|
software iPXE to boot from iSCSI network drives [4].
|
|
|
|
This driver is only available if U-Boot is configured with::
|
|
|
|
CONFIG_BLK=y
|
|
CONFIG_PARTITIONS=y
|
|
|
|
Miscellaneous
|
|
-------------
|
|
|
|
Load file 2 protocol
|
|
~~~~~~~~~~~~~~~~~~~~
|
|
|
|
The load file 2 protocol can be used by the Linux kernel to load the initial
|
|
RAM disk. U-Boot can be configured to provide an implementation with::
|
|
|
|
EFI_LOAD_FILE2_INITRD=y
|
|
|
|
When the option is enabled the user can add the initrd path with the efidebug
|
|
command.
|
|
|
|
Load options Boot#### have a FilePathList[] member. The first element of
|
|
the array (FilePathList[0]) is the EFI binary to execute. When an initrd
|
|
is specified the Device Path for the initrd is denoted by a VenMedia node
|
|
with the EFI_INITRD_MEDIA_GUID. Each entry of the array is terminated by the
|
|
'end of entire device path' subtype (0xff). If a user wants to define multiple
|
|
initrds, those must by separated by the 'end of this instance' identifier of
|
|
the end node (0x01).
|
|
|
|
So our final format of the FilePathList[] is::
|
|
|
|
Loaded image - end node (0xff) - VenMedia - initrd_1 - [end node (0x01) - initrd_n ...] - end node (0xff)
|
|
|
|
Links
|
|
-----
|
|
|
|
* [1] http://uefi.org/specifications - UEFI specifications
|
|
* [2] https://github.com/ARM-software/ebbr/releases/download/v1.0/ebbr-v1.0.pdf -
|
|
Embedded Base Boot Requirements (EBBR) Specification - Release v1.0
|
|
* [3] https://developer.arm.com/docs/den0044/latest/server-base-boot-requirements-system-software-on-arm-platforms-version-11 -
|
|
Server Base Boot Requirements System Software on ARM Platforms - Version 1.1
|
|
* [4] :doc:`iscsi`
|
|
* [5] :doc:`../driver-model/index`
|