| Trusted Firmware-A reset design |
| =============================== |
| |
| |
| |
| |
| .. contents:: |
| |
| This document describes the high-level design of the framework to handle CPU |
| resets in Trusted Firmware-A (TF-A). It also describes how the platform |
| integrator can tailor this code to the system configuration to some extent, |
| resulting in a simplified and more optimised boot flow. |
| |
| This document should be used in conjunction with the `Firmware Design`_, which |
| provides greater implementation details around the reset code, specifically |
| for the cold boot path. |
| |
| General reset code flow |
| ----------------------- |
| |
| The TF-A reset code is implemented in BL1 by default. The following high-level |
| diagram illustrates this: |
| |
| |Default reset code flow| |
| |
| This diagram shows the default, unoptimised reset flow. Depending on the system |
| configuration, some of these steps might be unnecessary. The following sections |
| guide the platform integrator by indicating which build options exclude which |
| steps, depending on the capability of the platform. |
| |
| Note: If BL31 is used as the TF-A entry point instead of BL1, the diagram |
| above is still relevant, as all these operations will occur in BL31 in |
| this case. Please refer to section 6 "Using BL31 entrypoint as the reset |
| address" for more information. |
| |
| Programmable CPU reset address |
| ------------------------------ |
| |
| By default, TF-A assumes that the CPU reset address is not programmable. |
| Therefore, all CPUs start at the same address (typically address 0) whenever |
| they reset. Further logic is then required to identify whether it is a cold or |
| warm boot to direct CPUs to the right execution path. |
| |
| If the reset vector address (reflected in the reset vector base address register |
| ``RVBAR_EL3``) is programmable then it is possible to make each CPU start directly |
| at the right address, both on a cold and warm reset. Therefore, the boot type |
| detection can be skipped, resulting in the following boot flow: |
| |
| |Reset code flow with programmable reset address| |
| |
| To enable this boot flow, compile TF-A with ``PROGRAMMABLE_RESET_ADDRESS=1``. |
| This option only affects the TF-A reset image, which is BL1 by default or BL31 if |
| ``RESET_TO_BL31=1``. |
| |
| On both the FVP and Juno platforms, the reset vector address is not programmable |
| so both ports use ``PROGRAMMABLE_RESET_ADDRESS=0``. |
| |
| Cold boot on a single CPU |
| ------------------------- |
| |
| By default, TF-A assumes that several CPUs may be released out of reset. |
| Therefore, the cold boot code has to arbitrate access to hardware resources |
| shared amongst CPUs. This is done by nominating one of the CPUs as the primary, |
| which is responsible for initialising shared hardware and coordinating the boot |
| flow with the other CPUs. |
| |
| If the platform guarantees that only a single CPU will ever be brought up then |
| no arbitration is required. The notion of primary/secondary CPU itself no longer |
| applies. This results in the following boot flow: |
| |
| |Reset code flow with single CPU released out of reset| |
| |
| To enable this boot flow, compile TF-A with ``COLD_BOOT_SINGLE_CPU=1``. This |
| option only affects the TF-A reset image, which is BL1 by default or BL31 if |
| ``RESET_TO_BL31=1``. |
| |
| On both the FVP and Juno platforms, although only one core is powered up by |
| default, there are platform-specific ways to release any number of cores out of |
| reset. Therefore, both platform ports use ``COLD_BOOT_SINGLE_CPU=0``. |
| |
| Programmable CPU reset address, Cold boot on a single CPU |
| --------------------------------------------------------- |
| |
| It is obviously possible to combine both optimisations on platforms that have |
| a programmable CPU reset address and which release a single CPU out of reset. |
| This results in the following boot flow: |
| |
| |
| |Reset code flow with programmable reset address and single CPU released out of reset| |
| |
| To enable this boot flow, compile TF-A with both ``COLD_BOOT_SINGLE_CPU=1`` |
| and ``PROGRAMMABLE_RESET_ADDRESS=1``. These options only affect the TF-A reset |
| image, which is BL1 by default or BL31 if ``RESET_TO_BL31=1``. |
| |
| Using BL31 entrypoint as the reset address |
| ------------------------------------------ |
| |
| On some platforms the runtime firmware (BL3x images) for the application |
| processors are loaded by some firmware running on a secure system processor |
| on the SoC, rather than by BL1 and BL2 running on the primary application |
| processor. For this type of SoC it is desirable for the application processor |
| to always reset to BL31 which eliminates the need for BL1 and BL2. |
| |
| TF-A provides a build-time option ``RESET_TO_BL31`` that includes some additional |
| logic in the BL31 entry point to support this use case. |
| |
| In this configuration, the platform's Trusted Boot Firmware must ensure that |
| BL31 is loaded to its runtime address, which must match the CPU's ``RVBAR_EL3`` |
| reset vector base address, before the application processor is powered on. |
| Additionally, platform software is responsible for loading the other BL3x images |
| required and providing entry point information for them to BL31. Loading these |
| images might be done by the Trusted Boot Firmware or by platform code in BL31. |
| |
| Although the Arm FVP platform does not support programming the reset base |
| address dynamically at run-time, it is possible to set the initial value of the |
| ``RVBAR_EL3`` register at start-up. This feature is provided on the Base FVP only. |
| It allows the Arm FVP port to support the ``RESET_TO_BL31`` configuration, in |
| which case the ``bl31.bin`` image must be loaded to its run address in Trusted |
| SRAM and all CPU reset vectors be changed from the default ``0x0`` to this run |
| address. See the `User Guide`_ for details of running the FVP models in this way. |
| |
| Although technically it would be possible to program the reset base address with |
| the right support in the SCP firmware, this is currently not implemented so the |
| Juno port doesn't support the ``RESET_TO_BL31`` configuration. |
| |
| The ``RESET_TO_BL31`` configuration requires some additions and changes in the |
| BL31 functionality: |
| |
| Determination of boot path |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| In this configuration, BL31 uses the same reset framework and code as the one |
| described for BL1 above. Therefore, it is affected by the |
| ``PROGRAMMABLE_RESET_ADDRESS`` and ``COLD_BOOT_SINGLE_CPU`` build options in the |
| same way. |
| |
| In the default, unoptimised BL31 reset flow, on a warm boot a CPU is directed |
| to the PSCI implementation via a platform defined mechanism. On a cold boot, |
| the platform must place any secondary CPUs into a safe state while the primary |
| CPU executes a modified BL31 initialization, as described below. |
| |
| Platform initialization |
| ~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| In this configuration, when the CPU resets to BL31 there are no parameters that |
| can be passed in registers by previous boot stages. Instead, the platform code |
| in BL31 needs to know, or be able to determine, the location of the BL32 (if |
| required) and BL33 images and provide this information in response to the |
| ``bl31_plat_get_next_image_ep_info()`` function. |
| |
| Additionally, platform software is responsible for carrying out any security |
| initialisation, for example programming a TrustZone address space controller. |
| This might be done by the Trusted Boot Firmware or by platform code in BL31. |
| |
| -------------- |
| |
| *Copyright (c) 2015-2018, Arm Limited and Contributors. All rights reserved.* |
| |
| .. _Firmware Design: firmware-design.rst |
| .. _User Guide: ../getting_started/user-guide.rst |
| |
| .. |Default reset code flow| image:: ../diagrams/default_reset_code.png?raw=true |
| .. |Reset code flow with programmable reset address| image:: ../diagrams/reset_code_no_boot_type_check.png?raw=true |
| .. |Reset code flow with single CPU released out of reset| image:: ../diagrams/reset_code_no_cpu_check.png?raw=true |
| .. |Reset code flow with programmable reset address and single CPU released out of reset| image:: ../diagrams/reset_code_no_checks.png?raw=true |