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 firmwares
 ---------------------------------

 Boot firmwares are loaded via secure FLASH0 device so ``bl1.bin`` and
 ``fip.bin`` should be concatenated to create a ``flash.bin`` that is flashed
 onto secure FLASH0.

 -  ``bl32.bin`` -> BL32 (``tee-header_v2.bin``)
 -  ``bl32_extra1.bin`` -> BL32 Extra1 (``tee-pager_v2.bin``)
 -  ``bl32_extra2.bin`` -> BL32 Extra2 (``tee-pageable_v2.bin``)
 -  ``bl33.bin`` -> BL33 (``QEMU_EFI.fd``)
 -  ``Image`` -> linux/arch/arm64/boot/Image

 To build:

 .. 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

 To build with TBBR enabled, 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

 To build flash.bin:

 .. 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

 To start (QEMU v5.0.0):

 .. code:: shell

     qemu-system-aarch64 -nographic -machine virt,secure=on -cpu cortex-a57  \
         -kernel Image -no-acpi                     \
         -append 'console=ttyAMA0,38400 keep_bootcon'  \
         -initrd rootfs.cpio.gz -smp 2 -m 1024 -bios flash.bin   \
         -d unimp

 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 firmwares
	---------------------------------

	Boot firmwares are loaded via secure FLASH0 device so ``bl1.bin`` and
	``fip.bin`` should be concatenated to create a ``flash.bin`` that is flashed
	onto secure FLASH0.

	- ``bl32.bin`` -> BL32 (``tee-header_v2.bin``)
	- ``bl32_extra1.bin`` -> BL32 Extra1 (``tee-pager_v2.bin``)
	- ``bl32_extra2.bin`` -> BL32 Extra2 (``tee-pageable_v2.bin``)
	- ``bl33.bin`` -> BL33 (``QEMU_EFI.fd``)
	- ``Image`` -> linux/arch/arm64/boot/Image

	To build:

	.. 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

	To build with TBBR enabled, 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

	To build flash.bin:

	.. 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

	To start (QEMU v5.0.0):

	.. code:: shell

	qemu-system-aarch64 -nographic -machine virt,secure=on -cpu cortex-a57 \
	-kernel Image -no-acpi \
	-append 'console=ttyAMA0,38400 keep_bootcon' \
	-initrd rootfs.cpio.gz -smp 2 -m 1024 -bios flash.bin \
	-d unimp

	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