docs/plat/qemu.rst - filogic/atf - Gitiles

 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
	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