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We hardcode the pinctrl setting for the MMC controllers in boards.c, since we need them also in the SPL, where there is no DT yet. Add the respective setting for the H616 SoC, to enable eMMC on boards with this SoC as well. Also to make diagnosing this problem easier, print a warning if a board tries to setup MMC2 pins without a respective SoC setting being defined. Signed-off-by: Andre Przywara <andre.przywara@arm.com> Reviewed-by: Jagan Teki <jagan at amarulasolutions.com> Reviewed-by: Jernej Skrabec <jernej.skrabec at siol.net> |
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board.c | ||
chip.c | ||
dram_sun4i_auto.c | ||
dram_sun5i_auto.c | ||
dram_timings_sun4i.h | ||
gmac.c | ||
MAINTAINERS | ||
Makefile | ||
README.nand | ||
README.sunxi64 |
Allwinner 64-bit boards README ============================== Newer Allwinner SoCs feature ARMv8 cores (ARM Cortex-A53) with support for both the 64-bit AArch64 mode and the ARMv7 compatible 32-bit AArch32 mode. Examples are the Allwinner A64 (used for instance on the Pine64 board) or the Allwinner H5 SoC (as used on the OrangePi PC 2). These SoCs are wired to start in AArch32 mode on reset and execute 32-bit code from the Boot ROM (BROM). As this has some implications on U-Boot, this file describes how to make full use of the 64-bit capabilities. Quick Start / Overview ====================== - Build the ARM Trusted Firmware binary (see "ARM Trusted Firmware (ATF)" below) $ cd /src/arm-trusted-firmware $ make PLAT=sun50i_a64 DEBUG=1 bl31 - Build the SCP firmware binary (see "SCP firmware (Crust)" below) $ cd /src/crust $ make pine64_plus_defconfig && make -j5 scp - Build U-Boot (see "SPL/U-Boot" below) $ export BL31=/path/to/bl31.bin $ export SCP=/src/crust/build/scp/scp.bin $ make pine64_plus_defconfig && make -j5 - Transfer to an uSD card (see "microSD card" below) $ dd if=u-boot-sunxi-with-spl.bin of=/dev/sdx bs=8k seek=1 - Boot and enjoy! Building the firmware ===================== The Allwinner A64/H5/H6 firmware consists of several parts: U-Boot's SPL, ARM Trusted Firmware (ATF), optional System Control Processor (SCP) firmware (e.g. Crust), and the U-Boot proper. The SPL will load all of the other firmware binaries into RAM, along with the right device tree blob (.dtb), and will pass execution to ATF (in EL3). If SCP firmware was loaded, ATF will power on the SCP and wait for it to boot. ATF will then drop into U-Boot proper (in EL2). As the ATF binary and SCP firmware will become part of the U-Boot image file, you will need to build them first. ARM Trusted Firmware (ATF) ---------------------------- Checkout the latest master branch from the official ATF repository [1] and build it: $ export CROSS_COMPILE=aarch64-linux-gnu- $ make PLAT=sun50i_a64 DEBUG=1 bl31 The resulting binary is build/sun50i_a64/debug/bl31.bin. Either put the location of this file into the BL31 environment variable or copy this to the root of your U-Boot build directory (or create a symbolic link). $ export BL31=/src/arm-trusted-firmware/build/sun50i_a64/debug/bl31.bin (adjust the actual path accordingly) The platform target "sun50i_a64" covers all boards with either an Allwinner A64 or H5 SoC (since they are very similar). For boards with an Allwinner H6 SoC use "sun50i_h6". If you run into size issues with the resulting U-Boot image file, it might help to use a release build, by using "DEBUG=0" when building bl31.bin. As sometimes the ATF build process is a bit picky about the toolchain used, or if you can't be bothered with building ATF, there are known working binaries in the firmware repository[3], purely for convenience reasons. SCP firmware (Crust) ---------------------- SCP firmware is responsible for implementing system suspend/resume, and (on boards without a PMIC) soft poweroff/on. ATF contains fallback code for CPU power control, so SCP firmware is optional if you don't need either of these features. It runs on the AR100, with is an or1k CPU, not ARM, so it needs a different cross toolchain. There is one SCP firmware implementation currently available, Crust: $ git clone https://github.com/crust-firmware/crust $ cd crust $ export CROSS_COMPILE=or1k-linux-musl- $ make pine64_plus_defconfig $ make scp The same configuration generally works on any board with the same SoC (A64, H5, or H6), so if there is no config for your board, use one for a similar board. Like for ATF, U-Boot finds the SCP firmware binary via an environment variable: $ export SCP=/src/crust/build/scp/scp.bin If you do not want to use SCP firmware, you can silence the warning from binman by pointing it to an empty file: $ export SCP=/dev/null SPL/U-Boot ------------ Both U-Boot proper and the SPL are using the 64-bit mode. As the boot ROM enters the SPL still in AArch32 secure SVC mode, there is some shim code to enter AArch64 very early. The rest of the SPL runs in AArch64 EL3. U-Boot proper runs in EL2 and can load any AArch64 code (using the "go" command), EFI applications (with "bootefi") or arm64 Linux kernel images (often named "Image"), using the "booti" command. $ make clean $ export CROSS_COMPILE=aarch64-linux-gnu- $ make pine64_plus_defconfig $ make This will build the SPL in spl/sunxi-spl.bin and a FIT image called u-boot.itb, which contains the rest of the firmware. u-boot-sunxi-with-spl.bin joins those two components in one convenient image file. Boot process ============ The on-die BROM code will try several methods to load and execute the firmware. On a typical board like the Pine64 this will result in the following boot order: 1) Reading 32KB from sector 16 (@8K) of the microSD card to SRAM A1. If the BROM finds the magic "eGON" header in the first bytes, it will execute that code. If not (no SD card at all or invalid magic), it will: 2) Try to read 32KB from sector 16 (@8K) of memory connected to the MMC2 controller, typically an on-board eMMC chip. If there is no eMMC or it does not contain a valid boot header, it will: 3) Initialize the SPI0 controller and try to access a NOR flash connected to it (using the CS0 pin). If a flash chip is found, the BROM will load the first 32KB (from offset 0) into SRAM A1. Now it checks for the magic eGON header and checksum and will execute the code upon finding it. If not, it will: 4) Initialize the USB OTG controller and will wait for a host to connect to it, speaking the Allwinner proprietary (but deciphered) "FEL" USB protocol. To boot the Pine64 board, you can use U-Boot and any of the described methods. FEL boot (USB OTG) ------------------ FEL is the name of the Allwinner defined USB boot protocol built in the mask ROM of most Allwinner SoCs. It allows to bootstrap a board solely by using the USB-OTG interface and a host port on another computer. As the FEL mode is controlled by the boot ROM, it expects to be running in AArch32. For now the AArch64 SPL cannot properly return into FEL mode, so the feature is disabled in the configuration at the moment. The repository in [3] contains FEL capable SPL binaries, built using an off-tree branch to generate 32-bit ARM code (along with instructions how to re-create them). microSD card ------------ Transfer the SPL and the U-Boot FIT image directly to an uSD card: # dd if=spl/sunxi-spl.bin of=/dev/sdx bs=8k seek=1 # dd if=u-boot.itb of=/dev/sdx bs=8k seek=5 # sync (replace /dev/sdx with you SD card device file name, which could be /dev/mmcblk[x] as well). Alternatively you can use the SPL and the U-Boot FIT image combined into a single file and transfer that instead: # dd if=u-boot-sunxi-with-spl.bin of=/dev/sdx bs=8k seek=1 You can partition the microSD card, but leave the first MB unallocated (most partitioning tools will do this anyway). NOR flash --------- Some boards (like the SoPine, Pinebook or the OrangePi PC2) come with a soldered SPI NOR flash chip. On other boards like the Pine64 such a chip can be connected to the SPI0/CS0 pins on the PI-2 headers. Create the SPL and FIT image like described above for the SD card. Now connect either an "A to A" USB cable to the upper USB port on the Pine64 or get an adaptor and use a regular A-microB cable connected to it. Other boards often have a proper micro-B USB socket connected to the USB OTB port. Remove a microSD card from the slot and power on the board. On your host computer download and build the sunxi-tools package[2], then use "sunxi-fel" to access the board: $ ./sunxi-fel ver -v -p This should give you an output starting with: AWUSBFEX soc=00001689(A64) ... Now use the sunxi-fel tool to write to the NOR flash: $ ./sunxi-fel spiflash-write 0 spl/sunxi-spl.bin $ ./sunxi-fel spiflash-write 32768 u-boot.itb Now boot the board without an SD card inserted and you should see the U-Boot prompt on the serial console. (Legacy) boot0 method --------------------- boot0 is Allwinner's secondary program loader and it can be used as some kind of SPL replacement to get U-Boot up and running from an microSD card. For some time using boot0 was the only option to get the Pine64 booted. With working DRAM init code in U-Boot's SPL this is no longer necessary, but this method is described here for the sake of completeness. Please note that this method works only with the boot0 files shipped with A64 based boards, the H5 uses an incompatible layout which is not supported by this method. The boot0 binary is a 32 KByte blob and contained in the official Pine64 images distributed by Pine64 or Allwinner. It can be easily extracted from a micro SD card or an image file: # dd if=/dev/sd<x> of=boot0.bin bs=8k skip=1 count=4 where /dev/sd<x> is the device name of the uSD card or the name of the image file. Apparently Allwinner allows re-distribution of this proprietary code "as-is". This boot0 blob takes care of DRAM initialisation and loads the remaining firmware parts, then switches the core into AArch64 mode. The original boot0 code looks for U-Boot at a certain place on an uSD card (at 19096 KB), also it expects a header with magic bytes and a checksum. There is a tool called boot0img[3] which takes a boot0.bin image and a compiled U-Boot binary (plus other binaries) and will populate that header accordingly. To make space for the magic header, the pine64_plus_defconfig will make sure there is sufficient space at the beginning of the U-Boot binary. boot0img will also take care of putting the different binaries at the right places on the uSD card and works around unused, but mandatory parts by using trampoline code. See the output of "boot0img -h" for more information. boot0img can also patch boot0 to avoid loading U-Boot from 19MB, instead fetching it from just behind the boot0 binary (-B option). $ ./boot0img -o firmware.img -B boot0.img -u u-boot-dtb.bin -e -s bl31.bin \ -a 0x44008 -d trampoline64:0x44000 Then write this image to a microSD card, replacing /dev/sdx with the right device file (see above): $ dd if=firmware.img of=/dev/sdx bs=8k seek=1 [1] https://github.com/ARM-software/arm-trusted-firmware.git [2] git://github.com/linux-sunxi/sunxi-tools.git [3] https://github.com/apritzel/pine64/