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346 lines
14 KiB
346 lines
14 KiB
Reliability, Availability, and Serviceability (RAS) Extensions
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**************************************************************
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This document describes |TF-A| support for Arm Reliability, Availability, and
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Serviceability (RAS) extensions. RAS is a mandatory extension for Armv8.2 and
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later CPUs, and also an optional extension to the base Armv8.0 architecture.
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For the description of Arm RAS extensions, Standard Error Records, and the
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precise definition of RAS terminology, please refer to the Arm Architecture
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Reference Manual and `RAS Supplement`_. The rest of this document assumes
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familiarity with architecture and terminology.
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**IMPORTANT NOTE**: TF-A implementation assumes that if RAS extension is present
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then FEAT_IESB is also implmented.
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There are two philosophies for handling RAS errors from Non-secure world point
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of view.
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- :ref:`Firmware First Handling (FFH)`
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- :ref:`Kernel First Handling (KFH)`
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.. _Firmware First Handling (FFH):
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Firmware First Handling (FFH)
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=============================
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Introduction
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------------
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EA’s and Error interrupts corresponding to NS nodes are handled first in firmware
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- Errors signaled back to NS world via suitable mechanism
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- Kernel is prohibited from accessing the RAS error records directly
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- Firmware creates CPER records for kernel to navigate and process
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- Firmware signals error back to Kernel via SDEI
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Overview
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--------
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FFH works in conjunction with `Exception Handling Framework`. Exceptions resulting from
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errors in Non-secure world are routed to and handled in EL3. Said errors are Synchronous
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External Abort (SEA), Asynchronous External Abort (signalled as SErrors), Fault Handling
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and Error Recovery interrupts.
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RAS Framework in TF-A allows the platform to define an external abort handler and to
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register RAS nodes and interrupts. It also provides `helpers`__ for accessing Standard
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Error Records as introduced by the RAS extensions
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.. __: `Standard Error Record helpers`_
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.. _Kernel First Handling (KFH):
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Kernel First Handling (KFH)
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===========================
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Introduction
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------------
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EA's originating/attributed to NS world are handled first in NS and Kernel navigates
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the std error records directly.
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- KFH is the default handling mode if platform does not explicitly enable FFH mode.
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- KFH mode does not need any EL3 involvement except for the reflection of errors back
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to lower EL. This happens when there is an error (EA) in the system which is not yet
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signaled to PE while executing at lower EL. During entry into EL3 the errors (EA) are
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synchronized causing async EA to pend at EL3.
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Error Syncronization at EL3 entry
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=================================
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During entry to EL3 from lower EL, if there is any pending async EAs they are either
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reflected back to lower EL (KFH) or handled in EL3 itself (FFH).
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|Image 1|
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TF-A build options
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==================
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- **ENABLE_FEAT_RAS**: Enable RAS extension feature at EL3.
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- **HANDLE_EA_EL3_FIRST_NS**: Required for FFH
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- **RAS_TRAP_NS_ERR_REC_ACCESS**: Trap Non-secure access of RAS error record registers.
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- **RAS_EXTENSION**: Deprecated macro, equivalent to ENABLE_FEAT_RAS and
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HANDLE_EA_EL3_FIRST_NS put together.
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RAS internal macros
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- **FFH_SUPPORT**: Gets enabled if **HANDLE_EA_EL3_FIRST_NS** is enabled.
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RAS feature has dependency on some other TF-A build flags
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- **EL3_EXCEPTION_HANDLING**: Required for FFH
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- **FAULT_INJECTION_SUPPORT**: Required for testing RAS feature on fvp platform
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TF-A Tests
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==========
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RAS functionality is regularly tested in TF-A CI using `RAS test group`_ which has multiple
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configurations for testing lower EL External aborts.
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All the tests are written in TF-A tests which runs as NS-EL2 payload.
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- **FFH without RAS extension**
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*fvp-ea-ffh,fvp-ea-ffh:fvp-tftf-fip.tftf-aemv8a-debug*
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Couple of tests, one each for sync EA and async EA from lower EL which gets handled in El3.
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Inject External aborts(sync/async) which traps in EL3, FVP has a handler which gracefully
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handles these errors and returns back to TF-A Tests
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Build Configs : **HANDLE_EA_EL3_FIRST_NS** , **PLATFORM_TEST_EA_FFH**
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- **FFH with RAS extension**
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Three Tests :
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- *fvp-ras-ffh,fvp-single-fault:fvp-tftf-fip.tftf-aemv8a.fi-debug*
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Inject an unrecoverable RAS error, which gets handled in EL3.
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- *fvp-ras-ffh,fvp-uncontainable:fvp-tftf.fault-fip.tftf-aemv8a.fi-debug*
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Inject uncontainable RAS errors which causes platform to panic.
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- *fvp-ras-ffh,fvp-ras-ffh-nested:fvp-tftf-fip.tftf-ras_ffh_nested-aemv8a.fi-debug*
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Test nested exception handling at El3 for synchronized async EAs. Inject an SError in lower EL
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which remain pending until we enter EL3 through SMC call. At EL3 entry on encountering a pending
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async EA it will handle the async EA first (nested exception) before handling the original SMC call.
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- **KFH with RAS extension**
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Couple of tests in the group :
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- *fvp-ras-kfh,fvp-ras-kfh:fvp-tftf-fip.tftf-aemv8a.fi-debug*
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Inject and handle RAS errors in TF-A tests (no El3 involvement)
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- *fvp-ras-kfh,fvp-ras-kfh-reflect:fvp-tftf-fip.tftf-ras_kfh_reflection-aemv8a.fi-debug*
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Reflection of synchronized errors from EL3 to TF-A tests, two tests one each for reflecting
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in IRQ and SMC path.
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RAS Framework
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=============
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.. _ras-figure:
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.. image:: ../resources/diagrams/draw.io/ras.svg
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Platform APIs
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-------------
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The RAS framework allows the platform to define handlers for External Abort,
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Uncontainable Errors, Double Fault, and errors rising from EL3 execution. Please
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refer to :ref:`RAS Porting Guide <External Abort handling and RAS Support>`.
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Registering RAS error records
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-----------------------------
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RAS nodes are components in the system capable of signalling errors to PEs
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through one one of the notification mechanisms—SEAs, SErrors, or interrupts. RAS
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nodes contain one or more error records, which are registers through which the
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nodes advertise various properties of the signalled error. Arm recommends that
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error records are implemented in the Standard Error Record format. The RAS
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architecture allows for error records to be accessible via system or
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memory-mapped registers.
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The platform should enumerate the error records providing for each of them:
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- A handler to probe error records for errors;
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- When the probing identifies an error, a handler to handle it;
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- For memory-mapped error record, its base address and size in KB; for a system
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register-accessed record, the start index of the record and number of
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continuous records from that index;
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- Any node-specific auxiliary data.
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With this information supplied, when the run time firmware receives one of the
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notification mechanisms, the RAS framework can iterate through and probe error
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records for error, and invoke the appropriate handler to handle it.
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The RAS framework provides the macros to populate error record information. The
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macros are versioned, and the latest version as of this writing is 1. These
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macros create a structure of type ``struct err_record_info`` from its arguments,
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which are later passed to probe and error handlers.
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For memory-mapped error records:
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.. code:: c
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ERR_RECORD_MEMMAP_V1(base_addr, size_num_k, probe, handler, aux)
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And, for system register ones:
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.. code:: c
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ERR_RECORD_SYSREG_V1(idx_start, num_idx, probe, handler, aux)
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The probe handler must have the following prototype:
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.. code:: c
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typedef int (*err_record_probe_t)(const struct err_record_info *info,
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int *probe_data);
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The probe handler must return a non-zero value if an error was detected, or 0
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otherwise. The ``probe_data`` output parameter can be used to pass any useful
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information resulting from probe to the error handler (see `below`__). For
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example, it could return the index of the record.
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.. __: `Standard Error Record helpers`_
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The error handler must have the following prototype:
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.. code:: c
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typedef int (*err_record_handler_t)(const struct err_record_info *info,
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int probe_data, const struct err_handler_data *const data);
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The ``data`` constant parameter describes the various properties of the error,
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including the reason for the error, exception syndrome, and also ``flags``,
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``cookie``, and ``handle`` parameters from the :ref:`top-level exception handler
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<EL3 interrupts>`.
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The platform is expected populate an array using the macros above, and register
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the it with the RAS framework using the macro ``REGISTER_ERR_RECORD_INFO()``,
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passing it the name of the array describing the records. Note that the macro
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must be used in the same file where the array is defined.
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Standard Error Record helpers
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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The |TF-A| RAS framework provides probe handlers for Standard Error Records, for
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both memory-mapped and System Register accesses:
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.. code:: c
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int ras_err_ser_probe_memmap(const struct err_record_info *info,
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int *probe_data);
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int ras_err_ser_probe_sysreg(const struct err_record_info *info,
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int *probe_data);
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When the platform enumerates error records, for those records in the Standard
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Error Record format, these helpers maybe used instead of rolling out their own.
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Both helpers above:
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- Return non-zero value when an error is detected in a Standard Error Record;
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- Set ``probe_data`` to the index of the error record upon detecting an error.
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Registering RAS interrupts
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--------------------------
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RAS nodes can signal errors to the PE by raising Fault Handling and/or Error
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Recovery interrupts. For the firmware-first handling paradigm for interrupts to
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work, the platform must setup and register with |EHF|. See `Interaction with
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Exception Handling Framework`_.
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For each RAS interrupt, the platform has to provide structure of type ``struct
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ras_interrupt``:
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- Interrupt number;
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- The associated error record information (pointer to the corresponding
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``struct err_record_info``);
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- Optionally, a cookie.
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The platform is expected to define an array of ``struct ras_interrupt``, and
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register it with the RAS framework using the macro
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``REGISTER_RAS_INTERRUPTS()``, passing it the name of the array. Note that the
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macro must be used in the same file where the array is defined.
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The array of ``struct ras_interrupt`` must be sorted in the increasing order of
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interrupt number. This allows for fast look of handlers in order to service RAS
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interrupts.
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Double-fault handling
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---------------------
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A Double Fault condition arises when an error is signalled to the PE while
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handling of a previously signalled error is still underway. When a Double Fault
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condition arises, the Arm RAS extensions only require for handler to perform
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orderly shutdown of the system, as recovery may be impossible.
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The RAS extensions part of Armv8.4 introduced new architectural features to deal
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with Double Fault conditions, specifically, the introduction of ``NMEA`` and
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``EASE`` bits to ``SCR_EL3`` register. These were introduced to assist EL3
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software which runs part of its entry/exit routines with exceptions momentarily
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masked—meaning, in such systems, External Aborts/SErrors are not immediately
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handled when they occur, but only after the exceptions are unmasked again.
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|TF-A|, for legacy reasons, executes entire EL3 with all exceptions unmasked.
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This means that all exceptions routed to EL3 are handled immediately. |TF-A|
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thus is able to detect a Double Fault conditions in software, without needing
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the intended advantages of Armv8.4 Double Fault architecture extensions.
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Double faults are fatal, and terminate at the platform double fault handler, and
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doesn't return.
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Engaging the RAS framework
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--------------------------
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Enabling RAS support is a platform choice
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The RAS support in |TF-A| introduces a default implementation of
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``plat_ea_handler``, the External Abort handler in EL3. When ``ENABLE_FEAT_RAS``
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is set to ``1``, it'll first call ``ras_ea_handler()`` function, which is the
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top-level RAS exception handler. ``ras_ea_handler`` is responsible for iterating
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to through platform-supplied error records, probe them, and when an error is
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identified, look up and invoke the corresponding error handler.
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Note that, if the platform chooses to override the ``plat_ea_handler`` function
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and intend to use the RAS framework, it must explicitly call
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``ras_ea_handler()`` from within.
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Similarly, for RAS interrupts, the framework defines
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``ras_interrupt_handler()``. The RAS framework arranges for it to be invoked
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when a RAS interrupt taken at EL3. The function bisects the platform-supplied
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sorted array of interrupts to look up the error record information associated
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with the interrupt number. That error handler for that record is then invoked to
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handle the error.
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Interaction with Exception Handling Framework
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---------------------------------------------
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As mentioned in earlier sections, RAS framework interacts with the |EHF| to
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arbitrate handling of RAS exceptions with others that are routed to EL3. This
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means that the platform must partition a :ref:`priority level <Partitioning
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priority levels>` for handling RAS exceptions. The platform must then define
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the macro ``PLAT_RAS_PRI`` to the priority level used for RAS exceptions.
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Platforms would typically want to allocate the highest secure priority for
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RAS handling.
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Handling of both :ref:`interrupt <interrupt-flow>` and :ref:`non-interrupt
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<non-interrupt-flow>` exceptions follow the sequences outlined in the |EHF|
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documentation. I.e., for interrupts, the priority management is implicit; but
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for non-interrupt exceptions, they're explicit using :ref:`EHF APIs
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<Activating and Deactivating priorities>`.
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--------------
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*Copyright (c) 2018-2023, Arm Limited and Contributors. All rights reserved.*
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.. _RAS Supplement: https://developer.arm.com/documentation/ddi0587/latest
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.. _RAS Test group: https://git.trustedfirmware.org/ci/tf-a-ci-scripts.git/tree/group/tf-l3-boot-tests-ras?h=refs/heads/master
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.. |Image 1| image:: ../resources/diagrams/bl31-exception-entry-error-synchronization.png
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