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67969516b0
replace info logs with debug logs Signed-off-by: Abdellatif El Khlifi <abdellatif.elkhlifi@arm.com> Cc: Tom Rini <trini@konsulko.com> Cc: Simon Glass <sjg@chromium.org> Reviewed-by: Simon Glass <sjg@chromium.org>
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9.3 KiB
ReStructuredText
261 lines
9.3 KiB
ReStructuredText
.. SPDX-License-Identifier: GPL-2.0+
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Arm FF-A Support
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================
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Summary
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-------
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FF-A stands for Firmware Framework for Arm A-profile processors.
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FF-A specifies interfaces that enable a pair of software execution environments aka partitions to
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communicate with each other. A partition could be a VM in the Normal or Secure world, an
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application in S-EL0, or a Trusted OS in S-EL1.
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The U-Boot FF-A support (the bus) implements the interfaces to communicate
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with partitions in the Secure world aka Secure partitions (SPs).
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The FF-A support specifically focuses on communicating with SPs that
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isolate portions of EFI runtime services that must run in a protected
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environment which is inaccessible by the Host OS or Hypervisor.
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Examples of such services are set/get variables.
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The FF-A support uses the SMC ABIs defined by the FF-A specification to:
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- Discover the presence of SPs of interest
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- Access an SP's service through communication protocols
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e.g. EFI MM communication protocol
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At this stage of development only EFI boot-time services are supported.
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Runtime support will be added in future developments.
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The U-Boot FF-A support provides the following parts:
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- A Uclass driver providing generic FF-A methods.
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- An Arm FF-A device driver providing Arm-specific methods and reusing the Uclass methods.
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- A sandbox emulator for Arm FF-A, emulates the FF-A side of the Secure World and provides
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FF-A ABIs inspection methods.
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- An FF-A sandbox device driver for FF-A communication with the emulated Secure World.
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The driver leverages the FF-A Uclass to establish FF-A communication.
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- Sandbox FF-A test cases.
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FF-A and SMC specifications
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-------------------------------------------
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The current implementation of the U-Boot FF-A support relies on
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`FF-A v1.0 specification`_ and uses SMC32 calling convention which
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means using the first 32-bit data of the Xn registers.
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At this stage we only need the FF-A v1.0 features.
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The FF-A support has been tested with OP-TEE which supports SMC32 calling
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convention.
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Hypervisors are supported if they are configured to trap SMC calls.
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The FF-A support uses 64-bit registers as per `SMC Calling Convention v1.2 specification`_.
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Supported hardware
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--------------------------------
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Aarch64 plaforms
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Configuration
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----------------------
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CONFIG_ARM_FFA_TRANSPORT
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Enables the FF-A support. Turn this on if you want to use FF-A
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communication.
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When using an Arm 64-bit platform, the Arm FF-A driver will be used.
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When using sandbox, the sandbox FF-A emulator and FF-A sandbox driver will be used.
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FF-A ABIs under the hood
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---------------------------------------
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Invoking an FF-A ABI involves providing to the secure world/hypervisor the
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expected arguments from the ABI.
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On an Arm 64-bit platform, the ABI arguments are stored in x0 to x7 registers.
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Then, an SMC instruction is executed.
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At the secure side level or hypervisor the ABI is handled at a higher exception
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level and the arguments are read and processed.
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The response is put back through x0 to x7 registers and control is given back
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to the U-Boot Arm FF-A driver (non-secure world).
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The driver reads the response and processes it accordingly.
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This methodology applies to all the FF-A ABIs.
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FF-A bus discovery on Arm 64-bit platforms
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---------------------------------------------
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When CONFIG_ARM_FFA_TRANSPORT is enabled, the FF-A bus is considered as
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an architecture feature and discovered using ARM_SMCCC_FEATURES mechanism.
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This discovery mechanism is performed by the PSCI driver.
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The PSCI driver comes with a PSCI device tree node which is the root node for all
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architecture features including FF-A bus.
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::
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=> dm tree
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Class Index Probed Driver Name
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-----------------------------------------------------------
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firmware 0 [ + ] psci |-- psci
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ffa 0 [ ] arm_ffa | `-- arm_ffa
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The PSCI driver is bound to the PSCI device and when probed it tries to discover
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the architecture features by calling a callback the features drivers provide.
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In case of FF-A, the callback is arm_ffa_is_supported() which tries to discover the
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FF-A framework by querying the FF-A framework version from secure world using
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FFA_VERSION ABI. When discovery is successful, the ARM_SMCCC_FEATURES
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mechanism creates a U-Boot device for the FF-A bus and binds the Arm FF-A driver
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with the device using device_bind_driver().
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At this stage the FF-A bus is registered with the DM and can be interacted with using
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the DM APIs.
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Clients are able to probe then use the FF-A bus by calling uclass_first_device().
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Please refer to the armffa command implementation as an example of how to probe
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and interact with the FF-A bus.
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When calling uclass_first_device(), the FF-A driver is probed and ends up calling
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ffa_do_probe() provided by the Uclass which does the following:
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- saving the FF-A framework version in uc_priv
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- querying from secure world the u-boot endpoint ID
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- querying from secure world the supported features of FFA_RXTX_MAP
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- mapping the RX/TX buffers
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- querying from secure world all the partitions information
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When one of the above actions fails, probing fails and the driver stays not active
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and can be probed again if needed.
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Requirements for clients
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-------------------------------------
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When using the FF-A bus with EFI, clients must query the SPs they are looking for
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during EFI boot-time mode using the service UUID.
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The RX/TX buffers are only available at EFI boot-time. Querying partitions is
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done at boot time and data is cached for future use.
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RX/TX buffers should be unmapped before EFI runtime mode starts.
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The driver provides a bus operation for that called ffa_rxtx_unmap().
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The user should call ffa_rxtx_unmap() to unmap the RX/TX buffers when required
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(e.g: at efi_exit_boot_services()).
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The Linux kernel allocates its own RX/TX buffers. To be able to register these kernel buffers
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with secure world, the U-Boot's RX/TX buffers should be unmapped before EFI runtime starts.
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When invoking FF-A direct messaging, clients should specify which ABI protocol
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they want to use (32-bit vs 64-bit). Selecting the protocol means using
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the 32-bit or 64-bit version of FFA_MSG_SEND_DIRECT_{REQ, RESP}.
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The calling convention between U-Boot and the secure world stays the same: SMC32.
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Requirements for user drivers
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-------------------------------------
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Users who want to implement their custom FF-A device driver while reusing the FF-A Uclass can do so
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by implementing their own invoke_ffa_fn() in the user driver.
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The bus driver layer
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------------------------------
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FF-A support comes on top of the SMCCC layer and is implemented by the FF-A Uclass drivers/firmware/arm-ffa/arm-ffa-uclass.c
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The following features are provided:
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- Support for the 32-bit version of the following ABIs:
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- FFA_VERSION
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- FFA_ID_GET
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- FFA_FEATURES
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- FFA_PARTITION_INFO_GET
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- FFA_RXTX_UNMAP
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- FFA_RX_RELEASE
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- FFA_RUN
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- FFA_ERROR
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- FFA_SUCCESS
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- FFA_INTERRUPT
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- FFA_MSG_SEND_DIRECT_REQ
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- FFA_MSG_SEND_DIRECT_RESP
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- Support for the 64-bit version of the following ABIs:
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- FFA_RXTX_MAP
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- FFA_MSG_SEND_DIRECT_REQ
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- FFA_MSG_SEND_DIRECT_RESP
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- Processing the received data from the secure world/hypervisor and caching it
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- Hiding from upper layers the FF-A protocol and registers details. Upper
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layers focus on exchanged data, FF-A support takes care of how to transport
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that to the secure world/hypervisor using FF-A
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- FF-A support provides driver operations to be used by upper layers:
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- ffa_partition_info_get
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- ffa_sync_send_receive
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- ffa_rxtx_unmap
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- FF-A bus discovery makes sure FF-A framework is responsive and compatible
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with the driver
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- FF-A bus can be compiled and used without EFI
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Relationship between the sandbox emulator and the FF-A device
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---------------------------------------------------------------
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::
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=> dm tree
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Class Index Probed Driver Name
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-----------------------------------------------------------
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ffa_emul 0 [ + ] sandbox_ffa_emul `-- arm-ffa-emul
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ffa 0 [ ] sandbox_arm_ffa `-- sandbox-arm-ffa
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The armffa command
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-----------------------------------
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armffa is a command showcasing how to use the FF-A bus and how to invoke the driver operations.
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Please refer the command documentation at :doc:`../usage/cmd/armffa`
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Example of boot logs with FF-A enabled
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--------------------------------------
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For example, when using FF-A with Corstone-1000, debug logs enabled, the output is as follows:
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::
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U-Boot 2023.01 (May 10 2023 - 11:08:07 +0000) corstone1000 aarch64
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DRAM: 2 GiB
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Arm FF-A framework discovery
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FF-A driver 1.0
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FF-A framework 1.0
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FF-A versions are compatible
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...
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FF-A driver 1.0
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FF-A framework 1.0
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FF-A versions are compatible
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EFI: MM partition ID 0x8003
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...
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EFI stub: Booting Linux Kernel...
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...
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Linux version 6.1.9-yocto-standard (oe-user@oe-host) (aarch64-poky-linux-musl-gcc (GCC) 12.2.0, GNU ld (GNU Binutils) 2.40.202301193
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Machine model: ARM Corstone1000 FPGA MPS3 board
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Contributors
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------------
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* Abdellatif El Khlifi <abdellatif.elkhlifi@arm.com>
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.. _`FF-A v1.0 specification`: https://documentation-service.arm.com/static/5fb7e8a6ca04df4095c1d65e
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.. _`SMC Calling Convention v1.2 specification`: https://documentation-service.arm.com/static/5f8edaeff86e16515cdbe4c6
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