| Raspberry Pi 4 |
| ============== |
| |
| The `Raspberry Pi 4`_ is an inexpensive single-board computer that contains four |
| Arm Cortex-A72 cores. Also in contrast to previous Raspberry Pi versions this |
| model has a GICv2 interrupt controller. |
| |
| This port is a minimal port to support loading non-secure EL2 payloads such |
| as a 64-bit Linux kernel. Other payloads such as U-Boot or EDK-II should work |
| as well, but have not been tested at this point. |
| |
| **IMPORTANT NOTE**: This port isn't secure. All of the memory used is DRAM, |
| which is available from both the Non-secure and Secure worlds. The SoC does |
| not seem to feature a secure memory controller of any kind, so portions of |
| DRAM can't be protected properly from the Non-secure world. |
| |
| Build Instructions |
| ------------------ |
| |
| There are no real configuration options at this point, so there is only |
| one universal binary (bl31.bin), which can be built with: |
| |
| .. code:: shell |
| |
| CROSS_COMPILE=aarch64-none-elf- make PLAT=rpi4 DEBUG=1 |
| |
| Copy the generated build/rpi4/debug/bl31.bin to the SD card, either |
| renaming it to ``armstub8.bin`` or adding an entry starting with ``armstub=``, |
| then followed by the respective file name to ``config.txt``. |
| You should have AArch64 code in the file loaded as the "kernel", as BL31 |
| will drop into AArch64/EL2 to the respective load address. |
| arm64 Linux kernels are known to work this way. |
| |
| Other options that should be set in ``config.txt`` to properly boot 64-bit |
| kernels are: |
| |
| :: |
| |
| enable_uart=1 |
| arm_64bit=1 |
| enable_gic=1 |
| |
| The BL31 code will patch the provided device tree blob in memory to advertise |
| PSCI support, also will add a reserved-memory node to the DT to tell the |
| non-secure payload to not touch the resident TF-A code. |
| |
| If you connect a serial cable between the Mini UART and your computer, and |
| connect to it (for example, with ``screen /dev/ttyUSB0 115200``) you should |
| see some text from BL31, followed by the output of the EL2 payload. |
| The command line provided is read from the ``cmdline.txt`` file on the SD card. |
| |
| TF-A port design |
| ---------------- |
| |
| In contrast to the existing Raspberry Pi 3 port this one here is a BL31-only |
| port, also it deviates quite a lot from the RPi3 port in many other ways. |
| There is not so much difference between the two models, so eventually those |
| two could be (more) unified in the future. |
| |
| As with the previous models, the GPU and its firmware are the first entity to |
| run after the SoC gets its power. The on-chip Boot ROM loads the next stage |
| (bootcode.bin) from flash (EEPROM), which is again GPU code. |
| This part knows how to access the MMC controller and how to parse a FAT |
| filesystem, so it will load further compononents and configuration files |
| from the first FAT partition on the SD card. |
| |
| To accommodate this existing way of configuring and setting up the board, |
| we use as much of this workflow as possible. |
| If bootcode.bin finds a file called ``armstub8.bin`` on the SD card or it gets |
| pointed to such code by finding a ``armstub=`` key in ``config.txt``, it will |
| load this file to the beginning of DRAM (address 0) and execute it in |
| AArch64 EL3. |
| But before doing that, it will also load a "kernel" and the device tree into |
| memory. The load addresses have a default, but can also be changed by |
| setting them in ``config.txt``. If the GPU firmware finds a magic value in the |
| armstub image file, it will put those two load addresses in memory locations |
| near the beginning of memory, where TF-A code picks them up. |
| |
| To keep things simple, we will just use the kernel load address as the BL33 |
| entry point, also put the DTB address in the x0 register, as requested by |
| the arm64 Linux kernel boot protocol. This does not necessarily mean that |
| the EL2 payload needs to be a Linux kernel, a bootloader or any other kernel |
| would work as well, as long as it can cope with having the DT address in |
| register x0. If the payload has other means of finding the device tree, it |
| could ignore this address as well. |