[Draft] Running NixOS on Banana Pi R4: Building the boot sequence
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content/posts/nixos-bpi-r4/2024-09-29-uboot-console.md
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content/posts/nixos-bpi-r4/2024-09-29-uboot-console.md
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title = 'Running NixOS on the Banana Pi R4: Building the boot sequence'
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date = 2024-09-29T08:37:23+02:00
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draft = true
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+++
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# Before starting
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- I'm by no mean an expert about U-Boot, neither in ARM CPUs.
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This is just me trying to port NixOS on the Banana Pi R4, and sharing what I learned.
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As such, I may (and certainly will) utter false statements.
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If I'm wrong about something, you can reach me by mail or on fedi and I will gladly correct it !
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- I can't say really that I'm fluent in English. If you see some grammar or spelling mistakes, please reach me too !
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- This post's goal is not to be exhaustive, but I want to emphasize what I think is important or useful to know.
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My goal here is that anyone, even with only basic knowledge about Nix and embedded systems, could use this as material.
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Thanks for your comprehension, and have a great time reading this.
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# How did we get there
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It has been a while since I started waiting for the Banana Pi R4.
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I bought it as soon as a complete bundle with the Wi-Fi 7 module was available.
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I initially planned to run OpenWrt on it, without bothering too much.
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But if my machines (including my ROCKPro64) are all running NixOS with my
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[common flake configuration](https://git.dalaran.fr/dala/nixos-config), there is no reason why my router
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should not.
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This is because I use a [colmena](https://github.com/zhaofengli/colmena)-based deployment system.
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It allows me to build (and cross-compile) all my machines configurations and to deploy them from my PC.
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However, there are two caveats here:
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- The Nix store usually takes some place on storage devices, so the embedded 8 GB eMMC might not be enough.
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But, since the BPI R4 has an integrated slot for a NVMe SSD and I have an empty 500 GB SSD available,
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it is way more than enough.
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- There is currently no support or available image of NixOS for the BPI R4.
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This whole blog post is about me feeling confident enough to create my own NixOS image for the BPI R4.
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For your information, this is what I had before starting this project:
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- Some basic Nix knowledge.
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- I already used U-Boot on some boards with prebuilt Linux images, but never really installed it or tweaked it myself.
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- Some knowledge about basic Linux utilities used for embedded.
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- A USB-Serial cable.
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For a NixOS SD image generation, some people chose to build it with their Nix configuration already
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applied to it, and then just flash this image to their board flash device.
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I will personally just build an image that just serve as an installation media, and then manually do
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all the installation process as I would do on a PC.
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Today's post is the first part about building our boot components and getting access to the U-Boot console.
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Let's get started !
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# The ARMv8 boot sequence
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Before focusing on the Linux kernel or NixOS, we will have to build the boot sequence for the R4.
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This includes ARM TrustedFirmware-A and U-Boot.
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On 64-bits Cortex-A based SoCs, the boot sequence (the succession of programs that will be run to init our board)
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is standardized with the following elements:
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- BL1: this is a software brick that is already present in the board's Boot ROM. It performs basic
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hardware initialization and then pass the control to the next step (BL2).
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- BL2: Another software brick whose goal is to create a secure environment for the software that will be run, and then
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pass the control to the last step.
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- BL3: the final element of the boot sequence. It is basically what the board will finally run.
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In fact, this is a bit more complicated as BL3 itself is subdivided between BL31 (Secure runtime software),
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an optional BL32 and BL33 (Non-trusted Firmware) which is the final software that will be run.
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It seems in reality a bit more complicated than that, dealing with ARM Exception Level, but we will stick
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to this simple representation.
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ARM TrustedFirmware-A provides a standard implementation for BL2, BL31 and BL32. Its documentation is available
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[here](https://trustedfirmware-a.readthedocs.io/en/latest/index.html).
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U-Boot is the bootloader which is the most commonly used on ARM boards, and that will act as BL33.
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It has all the necessary utilities to load and boot the Linux kernel.
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Once the board reach U-Boot, it will be able to boot NixOS.
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Nixpkgs provide two functions to build these two elements as Nix derivations: `buildUBoot` and `buildArmTrustedFirmware`.
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These two functions make the creation of such derivations fairly easy.
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# Cross compilation on NixOS (for Nix-beginners)
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If you're not on an aarch64 machine (or did not enable native build through QEMU on your configuration),
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you won't be able to build the following derivations.
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To do so, we have to set up cross-compilation.
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Everybody knows nixpkgs as a collection of Nix derivations that contains some utility functions like `mkDerivation` too.
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It also provides a cross-compilation system that allows to cross compile each derivation for a compatible architecture !
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For example, if we want to build any aarch64 package from any architecture (like `hello`), we can just run:
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```bash
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nix-build '<nixpkgs>' --arg crossSystem '(import <nixpkgs/lib>).systems.examples.aarch64-multiplatform' -A hello
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```
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This will cross-compile `hello` for aarch64 in the Nix store.
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It is possible, because as any package in nixpkgs, `hello` is declared through a Nix recipe (a callPackage derivation) that
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is called by the `callPackage` function of nixpkgs.
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This function setup a bunch of things and among them cross-compilation.
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It does so by looking at the `crossSystem` parameter provided to nixpkgs.
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It will then cross-compile every dependency of the derivation before finally building our package.
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To cross-compile every program we need, we just have to create the following `default.nix` file:
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```nix
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{
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pkgs ? import <nixpkgs> {
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crossSystem = (import <nixpkgs/lib>).systems.examples.aarch64-multiplatform;
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},
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}:
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{
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myProgram = pkgs.callPackage ./myProgram { };
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}
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```
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Here, we just need to have a `myProgram` directory with a `default.nix` file containing a callPackage derivation
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for our program, and then call `nix-build -A myProgram`.
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# Building U-Boot
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Most of current Linux images for the BPI R4 uses [frank-w's U-Boot fork](https://github.com/frank-w/u-boot).
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This is because, for now, mainline U-Boot does not support the router.
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His modifications to bring support for our device are just few commits that I'll export as patch, and apply
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them on top of mainline U-Boot.
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Let's create the following `default.nix` file:
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```nix
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{
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pkgs ? import <nixpkgs> {
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crossSystem = (import <nixpkgs/lib>).systems.examples.aarch64-multiplatform;
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},
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}:
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{
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ubootBpiR4 = pkgs.callPackage ./u-boot { };
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}
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```
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In a `u-boot` directory, we will create a `default.nix` file and a `patches` directory that will contain
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all the patches that I took from frank-w's U-Boot.
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Within the `u-boot/default.nix` file, we will just have to write the following callPackage derivation:
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```nix
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{ buildUBoot, ... }:
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buildUBoot {
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defconfig = "mt7988a_bpir4_sd_defconfig";
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extraMeta.platforms = [ "aarch64-linux" ];
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extraPatches = [
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./patches/0001-pci-mediatek-add-PCIe-controller-support-for-Filogic.patch
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./patches/0002-Fix-PCIE-on-BPIR4.patch
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./patches/0003-arm-dts-enable-pcie-in-sd-dts-too.patch
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./patches/0004-dts-r4-disable-pcie2-in-emmc-dts.patch
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./patches/0005-defconfig-uEnv-add-defconfigs-and-environment-files.patch
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./patches/0006-defconfig-r4-update-with-pcie-options.patch
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./patches/0007-defconfig-r4-add-pstore.patch
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./patches/0008-defconfig-r4-update-emmc-defconfig.patch
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./patches/0009-defconfig-r4-fix-duplicates-in-emmc-defconfig.patch
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./patches/0010-arm64-dts-move-pcie-phy-to-dedicated-xsphy-no-driver.patch
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./patches/0011-pci-mediatek-print-controller-address-for-card-detec.patch
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];
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extraConfig = ''
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CONFIG_FIT=n
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CONFIG_USE_DEFAULT_ENV_FILE=n
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'';
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filesToInstall = [ "u-boot.bin" ];
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}
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```
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As I said previously, nixpkgs provides a `buildUBoot` function, to which we have just to pass some arguments.
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Here, frank-w's U-Boot patches define a new defconfig called `mt7988a_bpi_r4_sd_defconfig` for the R4.
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This config enables the generation of a Flattened Image Tree.
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As far as I understand, this is a blob containing all the necessary boot configurations and files that U-Boot needs to launch our kernel.
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In my case, at least for the beginning, I chose to stick with the plain-old U-Boot builds (without using FIT) to learn to do it myself instead of using
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any special packaging format.
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In the end, the `filesToInstall` arguments just specifies which final build products we want to keep in the derivation output.
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For now, we will only keep the u-boot binary and see if we actually need anything else later.
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That's it for U-Boot ! We can try to build it with `nix-build -A ubootBpiR4` and see the `u-boot.bin` file
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appear in the Nix store, and in the `result` folder !
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# ARM TrustedFirmware-A
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As with U-Boot, the mainline version of TrustedFirmware does not support the BPI-R4.
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For now, distributions are using [this fork](https://github.com/mtk-openwrt/arm-trusted-firmware).
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I don't really know for sure who is behind this account, but there is a bit too much commits for me
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to export them as patch to apply on top of mainline.
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Once again, we will use the nixpkgs's `buildArmTrustedFirmware` function.
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Before that, and as we can see on the [frank-w's U-Boot build scripts](https://github.com/frank-w/u-boot/blob/mtk-atf/build.sh#L40),
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we will need to pass to U-Boot binary. It should be included within the final `fip.bin` file.
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---
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To be honest there, I don't really know if TrustedFirmware is mandatory to run U-boot
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on our SoC, or if U-Boot by itself could have handled everything.
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But for now, I decided to proceed like the OpenWrt and Debian images.
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I will surely dig in the TrustedFirmware and ARM documentations later.
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I'll eventually to a follow-up post later if I achieve to figure out how everything is working.
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---
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So, let's create our callPackage derivation in `trusted-firmware/default.nix`:
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```nix
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{
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buildArmTrustedFirmware,
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fetchFromGitHub,
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dtc,
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ubootBpiR4,
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ubootTools,
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openssl,
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...
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}:
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(buildArmTrustedFirmware rec {
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platform = "mt7988";
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extraMeta.platforms = [ "aarch64-linux" ];
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extraMakeFlags = [
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"USE_MKIMAGE=1"
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"BOOT_DEVICE=sdmmc"
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"DRAM_USE_COMB=1"
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"BL33=${ubootBpiR4}/u-boot.bin"
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"all"
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"fip"
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];
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filesToInstall = [
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"build/${platform}/release/bl2.img"
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"build/${platform}/release/fip.bin"
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];
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}).overrideAttrs (old: {
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src = fetchFromGitHub {
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owner = "mtk-openwrt";
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repo = "arm-trusted-firmware";
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rev = "bacca82a8cac369470df052a9d801a0ceb9b74ca";
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hash = "sha256-n5D3styntdoKpVH+vpAfDkCciRJjCZf9ivrI9eEdyqw=";
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};
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version = "2.10.0-mtk";
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nativeBuildInputs = old.nativeBuildInputs ++ [ dtc ubootTools openssl ];
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}
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```
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This is very similar what we have done with U-Boot, we select our platform, then pass the necessary flags for compilation,
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and then grab the two output files that we need.
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However, in our situation, there are some extra steps.
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Both `buildUBoot` and `buildArmTrustedFirmware` assumes that you're building the mainline U-Boot and TF-A.
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It was the case with our U-Boot build to which we just add some extra patches.
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However, with TF-A, we will here use the mtk-openwrt's fork.
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So we need to override the derivation produced by `buildArmTrustedFirmware` to pass our own sources and needed dependencies thanks
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to the `overrideAttrs` function.
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As we can see, this callPackage derivation needs to access our previous `ubootBpiR4` derivation.
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All the other derivations arguments are provided by nixpkgs itself through the `callPackage` function.
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However, `ubootBpiR4` is itself not present within nixpkgs, we have to manually pass it.
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There are two methods to do so, the first one is to use a nixpkgs overlay.
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The other one is to pass it manually as a `callPackage` argument.
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That's what we'll do here.
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This makes our `default.nix` file looks like that:
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```nix
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{
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pkgs ? import <nixpkgs> {
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crossSystem = (import <nixpkgs/lib>).systems.examples.aarch64-multiplatform;
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},
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}:
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rec {
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ubootBpiR4 = pkgs.callPackage ./u-boot { };
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armTrustedFirmwareBpiR4 = pkgs.callPackage ./trusted-firmware { inherit ubootBpiR4; };
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}
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```
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Now, we can run `nix-build -A armTrustedFirmwareBpiR4` to build everything we need.
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# Side note on the U-Boot and TF-A combination
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If you check how to build the full boot sequence binaries for various board, you will maybe feel like me
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that it seems to be highly dependent on the SoC manufacturer.
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In our case, we build U-Boot first and then pass it to TF-A as BL33.
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For some Allwinner SoCs, TF-A is built first and then passed to U-boot as BL31.
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For Rockchip based boards there is this whole `idbloader.img` due to Rockchip's miniloader.
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At this point, I don't really know if there is a "standard way" to build to whole boot sequence for each SoC.
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I don't even know what causes these differences in the build process between manufacturers.
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I guess it's related to the manufacturer implementation, or maybe things that could be done both in U-Boot and in TF-A
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and then depends on where the manufacturer implemented them ?
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# Create our boot image
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The final step is just to create an empty image and flash what we have built so far at the matching address ranges.
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This will be done with a simple bash script derivation in the `image/default.nix` file.
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```nix
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{
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runCommand,
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armTrustedFirmwareBpiR4,
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gptfdisk,
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...
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}:
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runCommand "bpi-r4-image" {
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nativeBuildInputs = [
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gptfdisk
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];
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} ''
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IMAGE=$out/nixos-r4-image.img
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mkdir $out
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dd if=/dev/zero of=$IMAGE bs=1M count=4000
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sgdisk -o $IMAGE
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sgdisk -a 1 -n 1:34:8191 -A 1:set:2 -t 1:8300 -c 1:"bl2" $IMAGE
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sgdisk -a 1 -n 2:8192:9215 -A 2:set:63 -t 2:8300 -c 2:"u-boot-env" $IMAGE
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sgdisk -a 1 -n 3:9216:13311 -A 3:set:63 -t 3:8300 -c 3:"factory" $IMAGE
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sgdisk -a 1 -n 4:13312:17407 -A 4:set:63 -t 4:8300 -c 4:"fip" $IMAGE
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dd if=${armTrustedFirmwareBpiR4}/bl2.img of=$IMAGE seek=34 conv=notrunc,fsync
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dd if=${armTrustedFirmwareBpiR4}/fip.bin of=$IMAGE seek=13312 conv=notrunc,fsync
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''
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```
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The nixpkgs `runCommand` function creates a derivation that runs a bash script.
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This bash script is running into the nixpkgs standard environment, but we can override this environment with the set passed
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as the second argument.
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In this case, we add the `gptfdisk` package as a dependency to use `sgdisk` within our bash script.
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The third argument is the script in itself.
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We then create the derivation output directory, and generate a zero-filled 4 GB image with `dd`.
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Then, we generate our partition table with `sgdisk` with the following partition map:
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```
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Block size of 512 bytes
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Blocks 34 to 8191: BL2
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Blocks 8192 to 9215: Space for U-Boot environment variables
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Blocks 9216 to 13311: Factory
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Blocks 13312 to 17407: FIP
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```
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Finally, we flash our TF-A build outputs into the matching partitions with `dd`.
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We add this callPackage derivation into our `default.nix`:
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```nix
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{
|
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pkgs ? import <nixpkgs> {
|
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crossSystem = (import <nixpkgs/lib>).systems.examples.aarch64-multiplatform;
|
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},
|
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}:
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rec {
|
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ubootBpiR4 = pkgs.callPackage ./u-boot { };
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armTrustedFirmwareBpiR4 = pkgs.callPackage ./trusted-firmware { inherit ubootBpiR4; };
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image = pkgs.callPackage ./image { inherit armTrustedFirmwareBpiR4; };
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}
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```
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And we can build our boot sequence components with `nix-shell -A image` to get our `nixos-r4-image.img`.
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# Flashing and running
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So let's flash the resulting image into an SD card.
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```bash
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dd if=result/nixos-r4-image.img of={Your SD Card} conv=sync status=progress
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```
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After plugging it in the BPI-R4 SD slot and set the boot device jumper to SD boot.
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We get the following logs with `minicom`:
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```
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F0: 102B 0000
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FA: 1042 0000
|
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FA: 1042 0000 [0200]
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F9: 1041 0000
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F3: 1001 0000 [0200]
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F3: 1001 0000
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F6: 380E 5800
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F5: 0000 0000
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V0: 0000 0000 [0001]
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00: 0000 0000
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BP: 0600 0041 [0000]
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||||
G0: 1190 0000
|
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EC: 0000 0000 [3000]
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MK: 0000 0000 [0000]
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T0: 0000 0221 [0101]
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Jump to BL
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NOTICE: BL2: v2.10.0 (release):
|
||||
NOTICE: BL2: Built : 00:00:00, Jan 1 1980
|
||||
NOTICE: WDT: Cold boot
|
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NOTICE: WDT: disabled
|
||||
NOTICE: CPU: MT7988
|
||||
NOTICE: EMI: Using DDR unknown settings
|
||||
NOTICE: EMI: Detected DRAM size: 4096 MB
|
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NOTICE: EMI: complex R/W mem test passed
|
||||
NOTICE: BL2: Booting BL31
|
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NOTICE: BL31: v2.10.0 (release):
|
||||
NOTICE: BL31: Built : 00:00:00, Jan 1 1980
|
||||
|
||||
|
||||
U-Boot 2024.04 (Apr 02 2024 - 10:58:58 +0000)
|
||||
|
||||
CPU: MediaTek MT7988
|
||||
Model: mt7988-rfb
|
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DRAM: 4 GiB
|
||||
Core: 49 devices, 19 uclasses, devicetree: separate
|
||||
MMC: mmc@11230000: 0
|
||||
Loading Environment from nowhere... OK
|
||||
In: serial@11000000
|
||||
Out: serial@11000000
|
||||
Err: serial@11000000
|
||||
Net:
|
||||
Warning: ethernet@15100000 (eth0) using random MAC address - 56:69:11:bc:68:06
|
||||
eth0: ethernet@15100000
|
||||
BPI-R4>
|
||||
```
|
||||
And here we have our initial access to the U-Boot console !
|
||||
|
||||
# Sources
|
||||
|
||||
I successfully got to this point after myself reading some documentation and a bunch of blog posts.
|
||||
Those where the resources I used:
|
||||
- [frank-w's dokuwiki](https://www.fw-web.de/dokuwiki/doku.php?id=en:bpi-r4:start)
|
||||
- [Kasper Kondzielski's blog post about running NixOS on the BPI-R3](https://github.com/ghostbuster91/blogposts/blob/main/router2023/main.md)
|
||||
- [Weijie Gao's post on the Banana Pi Discourse about U-Boot and TF-A on Mediatek SoCs](ihttps://forum.banana-pi.org/t/tutorial-build-customize-and-use-mediatek-open-source-u-boot-and-atf/13785)
|
||||
- [*Understanding ARM Trusted Firmware using QEMU* by Hemanth Nandish](https://lnxblog.github.io/2020/08/20/qemu-arm-tf.html)
|
||||
|
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