| QEMU virt Armv8-A |
| ================= |
| |
| Trusted Firmware-A (TF-A) implements the EL3 firmware layer for QEMU virt |
| Armv8-A. BL1 is used as the BootROM, supplied with the -bios argument. |
| When QEMU starts all CPUs are released simultaneously, BL1 selects a |
| primary CPU to handle the boot and the secondaries are placed in a polling |
| loop to be released by normal world via PSCI. |
| |
| BL2 edits the Flattened Device Tree, FDT, generated by QEMU at run-time to |
| add a node describing PSCI and also enable methods for the CPUs. |
| |
| If ``ARM_LINUX_KERNEL_AS_BL33`` is set to 1 then this FDT will be passed to BL33 |
| via register x0, as expected by a Linux kernel. This allows a Linux kernel image |
| to be booted directly as BL33 rather than using a bootloader. |
| |
| An ARM64 defconfig v5.5 Linux kernel is known to boot, FDT doesn't need to be |
| provided as it's generated by QEMU. |
| |
| Current limitations: |
| |
| - Only cold boot is supported |
| |
| Getting non-TF images |
| --------------------- |
| |
| ``QEMU_EFI.fd`` can be downloaded from |
| http://snapshots.linaro.org/components/kernel/leg-virt-tianocore-edk2-upstream/latest/QEMU-KERNEL-AARCH64/RELEASE_GCC5/QEMU_EFI.fd |
| |
| or, can be built as follows: |
| |
| .. code:: shell |
| |
| git clone https://github.com/tianocore/edk2.git |
| cd edk2 |
| git submodule update --init |
| make -C BaseTools |
| source edksetup.sh |
| export GCC5_AARCH64_PREFIX=aarch64-linux-gnu- |
| build -a AARCH64 -t GCC5 -p ArmVirtPkg/ArmVirtQemuKernel.dsc |
| |
| ```` |
| |
| Then, you will get ``Build/ArmVirtQemuKernel-AARCH64/DEBUG_GCC5/FV/QEMU_EFI.fd`` |
| |
| Please note you do not need to use GCC 5 in spite of the environment variable |
| ``GCC5_AARCH64_PREFIX``. |
| |
| The rootfs can be built by using Buildroot as follows: |
| |
| .. code:: shell |
| |
| git clone git://git.buildroot.net/buildroot.git |
| cd buildroot |
| make qemu_aarch64_virt_defconfig |
| utils/config -e BR2_TARGET_ROOTFS_CPIO |
| utils/config -e BR2_TARGET_ROOTFS_CPIO_GZIP |
| make olddefconfig |
| make |
| |
| Then, you will get ``output/images/rootfs.cpio.gz``. |
| |
| Booting via semi-hosting option |
| ------------------------------- |
| |
| Boot binaries, except BL1, are primarily loaded via semi-hosting so all |
| binaries has to reside in the same directory as QEMU is started from. This |
| is conveniently achieved with symlinks the local names as: |
| |
| - ``bl2.bin`` -> BL2 |
| - ``bl31.bin`` -> BL31 |
| - ``bl33.bin`` -> BL33 (``QEMU_EFI.fd``) |
| - ``Image`` -> linux/arch/arm64/boot/Image |
| |
| To build: |
| |
| .. code:: shell |
| |
| make CROSS_COMPILE=aarch64-none-elf- PLAT=qemu |
| |
| To start (QEMU v5.0.0): |
| |
| .. code:: shell |
| |
| qemu-system-aarch64 -nographic -machine virt,secure=on -cpu cortex-a57 \ |
| -kernel Image \ |
| -append "console=ttyAMA0,38400 keep_bootcon" \ |
| -initrd rootfs.cpio.gz -smp 2 -m 1024 -bios bl1.bin \ |
| -d unimp -semihosting-config enable,target=native |
| |
| Booting via flash based firmware |
| -------------------------------- |
| |
| An alternate approach to deploy a full system stack on QEMU is to load the |
| firmware via a secure flash device. This involves concatenating ``bl1.bin`` and |
| ``fip.bin`` to create a boot ROM that is flashed onto secure FLASH0 with the |
| ``-bios`` option. |
| |
| For example, to test the following firmware stack: |
| |
| |
| - BL32 - ``bl32.bin`` -> ``tee-header_v2.bin`` |
| - BL32 Extra1 - ``bl32_extra1.bin`` -> ``tee-pager_v2.bin`` |
| - BL32 Extra2 - ``bl32_extra2.bin`` -> ``tee-pageable_v2.bin`` |
| - BL33 - ``bl33.bin`` -> ``QEMU_EFI.fd`` (EDK II) |
| - ``Image`` -> linux/arch/arm64/boot/Image |
| |
| |
| 1. Compile TF-A |
| |
| .. code:: shell |
| |
| make CROSS_COMPILE=aarch64-linux-gnu- PLAT=qemu BL32=bl32.bin \ |
| BL32_EXTRA1=bl32_extra1.bin BL32_EXTRA2=bl32_extra2.bin \ |
| BL33=bl33.bin BL32_RAM_LOCATION=tdram SPD=opteed all fip |
| |
| Or, alternatively, to build with TBBR enabled, as well as, BL31 and BL32 encrypted with |
| test key: |
| |
| .. code:: shell |
| |
| make CROSS_COMPILE=aarch64-linux-gnu- PLAT=qemu BL32=bl32.bin \ |
| BL32_EXTRA1=bl32_extra1.bin BL32_EXTRA2=bl32_extra2.bin \ |
| BL33=bl33.bin BL32_RAM_LOCATION=tdram SPD=opteed all fip \ |
| MBEDTLS_DIR=<path-to-mbedtls-repo> TRUSTED_BOARD_BOOT=1 \ |
| GENERATE_COT=1 DECRYPTION_SUPPORT=aes_gcm FW_ENC_STATUS=0 \ |
| ENCRYPT_BL31=1 ENCRYPT_BL32=1 |
| |
| 2. Concatenate ``bl1.bin`` and ``fip.bin`` to create the boot ROM |
| |
| .. code:: shell |
| |
| dd if=build/qemu/release/bl1.bin of=flash.bin bs=4096 conv=notrunc |
| dd if=build/qemu/release/fip.bin of=flash.bin seek=64 bs=4096 conv=notrunc |
| |
| 3. Launch QEMU |
| |
| .. code:: shell |
| |
| qemu-system-aarch64 -nographic -machine virt,secure=on |
| -cpu cortex-a57 -kernel Image \ |
| -append 'console=ttyAMA0,38400 keep_bootcon' \ |
| -initrd rootfs.cpio.gz -smp 2 -m 1024 -bios flash.bin \ |
| -d unimp |
| |
| The ``-bios`` option abstracts the loading of raw bare metal binaries into flash |
| or ROM memory. QEMU loads the binary into the region corresponding to |
| the hardware's entrypoint, from which the binary is executed upon a platform |
| "reset". In addition to this, it places the information about the kernel |
| provided with option ``-kernel``, and the RamDisk provided with ``-initrd``, |
| into the firmware configuration ``fw_cfg``. In this setup, EDK II is responsible |
| for extracting and launching these from ``fw_cfg``. |
| |
| .. note:: |
| QEMU may be launched with or without ACPI (``-acpi``/``-no-acpi``). In |
| either case, ensure that the kernel build options are aligned with the |
| parameters passed to QEMU. |
| |
| Running QEMU in OpenCI |
| ----------------------- |
| |
| Linaro's continuous integration platform OpenCI supports running emulated tests |
| on QEMU. The tests are kicked off on Jenkins and deployed through the Linaro |
| Automation and Validation Architecture `LAVA`_. |
| |
| There are a set of Linux boot tests provided in OpenCI. They rely on prebuilt |
| `binaries`_ for UEFI, the kernel, root file system, as well as, any other TF-A |
| dependencies, and are run as part of the OpenCI TF-A `daily job`_. To run them |
| manually, a `builder`_ job may be triggered with the test configuration |
| ``qemu-boot-tests``. |
| |
| |
| You may see the following warning repeated several times in the boot logs: |
| |
| .. code:: shell |
| |
| pflash_write: Write to buffer emulation is flawed |
| |
| Please ignore this as it is an unresolved `issue in QEMU`_, it is an internal |
| QEMU warning that logs flawed use of "write to buffer". |
| |
| .. note:: |
| For more information on how to trigger jobs in OpenCI, please refer to |
| Linaro's CI documentation, which explains how to trigger a `manual job`_. |
| |
| .. _binaries: https://downloads.trustedfirmware.org/tf-a/linux_boot/ |
| .. _daily job: https://ci.trustedfirmware.org/view/TF-A/job/tf-a-main/ |
| .. _builder: https://ci.trustedfirmware.org/view/TF-A/job/tf-a-builder/ |
| .. _LAVA: https://tf.validation.linaro.org/ |
| .. _manual job: https://tf-ci-users-guide.readthedocs.io/en/latest/#manual-job-trigger |
| .. _issue in QEMU: https://git.qemu.org/?p=qemu.git;a=blob;f=hw/block/pflash_cfi01.c;h=0cbc2fb4cbf62c9a033b8dd89012374ff74ed610;hb=refs/heads/master#l500 |