| Exception Handling Framework |
| ============================ |
| |
| This document describes various aspects of handling exceptions by Runtime |
| Firmware (BL31) that are targeted at EL3, other than SMCs. The |EHF| takes care |
| of the following exceptions when targeted at EL3: |
| |
| - Interrupts |
| - Synchronous External Aborts |
| - Asynchronous External Aborts |
| |
| |TF-A|'s handling of synchronous ``SMC`` exceptions raised from lower ELs is |
| described in the `Firmware Design document`__. However, the |EHF| changes the |
| semantics of `interrupt handling`__ and `synchronous exceptions`__ other than |
| SMCs. |
| |
| .. __: firmware-design.rst#handling-an-smc |
| .. __: `Interrupt handling`_ |
| .. __: `Effect on SMC calls`_ |
| |
| The |EHF| is selected by setting the build option ``EL3_EXCEPTION_HANDLING`` to |
| ``1``, and is only available for AArch64 systems. |
| |
| Introduction |
| ------------ |
| |
| Through various control bits in the ``SCR_EL3`` register, the Arm architecture |
| allows for asynchronous exceptions to be routed to EL3. As described in the |
| `Interrupt Framework Design`_ document, depending on the chosen interrupt |
| routing model, TF-A appropriately sets the ``FIQ`` and ``IRQ`` bits of |
| ``SCR_EL3`` register to effect this routing. For most use cases, other than for |
| the purpose of facilitating context switch between Normal and Secure worlds, |
| FIQs and IRQs routed to EL3 are not required to be handled in EL3. |
| |
| However, the evolving system and standards landscape demands that various |
| exceptions are targeted at and handled in EL3. For instance: |
| |
| - Starting with ARMv8.2 architecture extension, many RAS features have been |
| introduced to the Arm architecture. With RAS features implemented, various |
| components of the system may use one of the asynchronous exceptions to signal |
| error conditions to PEs. These error conditions are of critical nature, and |
| it's imperative that corrective or remedial actions are taken at the earliest |
| opportunity. Therefore, a *Firmware-first Handling* approach is generally |
| followed in response to RAS events in the system. |
| |
| - The Arm `SDEI specification`_ defines interfaces through which Normal world |
| interacts with the Runtime Firmware in order to request notification of |
| system events. The |SDEI| specification requires that these events are |
| notified even when the Normal world executes with the exceptions masked. This |
| too implies that firmware-first handling is required, where the events are |
| first received by the EL3 firmware, and then dispatched to Normal world |
| through purely software mechanism. |
| |
| For |TF-A|, firmware-first handling means that asynchronous exceptions are |
| suitably routed to EL3, and the Runtime Firmware (BL31) is extended to include |
| software components that are capable of handling those exceptions that target |
| EL3. These components—referred to as *dispatchers* [#spd]_ in general—may |
| choose to: |
| |
| .. _delegation-use-cases: |
| |
| - Receive and handle exceptions entirely in EL3, meaning the exceptions |
| handling terminates in EL3. |
| |
| - Receive exceptions, but handle part of the exception in EL3, and delegate the |
| rest of the handling to a dedicated software stack running at lower Secure |
| ELs. In this scheme, the handling spans various secure ELs. |
| |
| - Receive exceptions, but handle part of the exception in EL3, and delegate |
| processing of the error to dedicated software stack running at lower secure |
| ELs (as above); additionally, the Normal world may also be required to |
| participate in the handling, or be notified of such events (for example, as |
| an |SDEI| event). In this scheme, exception handling potentially and |
| maximally spans all ELs in both Secure and Normal worlds. |
| |
| On any given system, all of the above handling models may be employed |
| independently depending on platform choice and the nature of the exception |
| received. |
| |
| .. [#spd] Not to be confused with `Secure Payload Dispatcher`__, which is an |
| EL3 component that operates in EL3 on behalf of Secure OS. |
| |
| .. __: firmware-design.rst#secure-el1-payloads-and-dispatchers |
| |
| The role of Exception Handling Framework |
| ---------------------------------------- |
| |
| Corollary to the use cases cited above, the primary role of the |EHF| is to |
| facilitate firmware-first handling of exceptions on Arm systems. The |EHF| thus |
| enables multiple exception dispatchers in runtime firmware to co-exist, register |
| for, and handle exceptions targeted at EL3. This section outlines the basics, |
| and the rest of this document expands the various aspects of the |EHF|. |
| |
| In order to arbitrate exception handling among dispatchers, the |EHF| operation |
| is based on a priority scheme. This priority scheme is closely tied to how the |
| Arm GIC architecture defines it, although it's applied to non-interrupt |
| exceptions too (SErrors, for example). |
| |
| The platform is required to `partition`__ the Secure priority space into |
| priority levels as applicable for the Secure software stack. It then assigns the |
| dispatchers to one or more priority levels. The dispatchers then register |
| handlers for the priority levels at runtime. A dispatcher can register handlers |
| for more than one priority level. |
| |
| .. __: `Partitioning priority levels`_ |
| |
| |
| .. _ehf-figure: |
| |
| .. image:: ../resources/diagrams/draw.io/ehf.svg |
| |
| A priority level is *active* when a handler at that priority level is currently |
| executing in EL3, or has delegated the execution to a lower EL. For interrupts, |
| this is implicit when an interrupt is targeted and acknowledged at EL3, and the |
| priority of the acknowledged interrupt is used to match its registered handler. |
| The priority level is likewise implicitly deactivated when the interrupt |
| handling concludes by EOIing the interrupt. |
| |
| Non-interrupt exceptions (SErrors, for example) don't have a notion of priority. |
| In order for the priority arbitration to work, the |EHF| provides APIs in order |
| for these non-interrupt exceptions to assume a priority, and to interwork with |
| interrupts. Dispatchers handling such exceptions must therefore explicitly |
| activate and deactivate the respective priority level as and when they're |
| handled or delegated. |
| |
| Because priority activation and deactivation for interrupt handling is implicit |
| and involves GIC priority masking, it's impossible for a lower priority |
| interrupt to preempt a higher priority one. By extension, this means that a |
| lower priority dispatcher cannot preempt a higher-priority one. Priority |
| activation and deactivation for non-interrupt exceptions, however, has to be |
| explicit. The |EHF| therefore disallows for lower priority level to be activated |
| whilst a higher priority level is active, and would result in a panic. |
| Likewise, a panic would result if it's attempted to deactivate a lower priority |
| level when a higher priority level is active. |
| |
| In essence, priority level activation and deactivation conceptually works like a |
| stack—priority levels stack up in strictly increasing fashion, and need to be |
| unstacked in strictly the reverse order. For interrupts, the GIC ensures this is |
| the case; for non-interrupts, the |EHF| monitors and asserts this. See |
| `Transition of priority levels`_. |
| |
| Interrupt handling |
| ------------------ |
| |
| The |EHF| is a client of *Interrupt Management Framework*, and registers the |
| top-level handler for interrupts that target EL3, as described in the `Interrupt |
| Framework Design`_ document. This has the following implications. |
| |
| - On GICv3 systems, when executing in S-EL1, pending Non-secure interrupts of |
| sufficient priority are signalled as FIQs, and therefore will be routed to |
| EL3. As a result, S-EL1 software cannot expect to handle Non-secure |
| interrupts at S-EL1. Essentially, this deprecates the routing mode described |
| as `CSS=0, TEL3=0`__. |
| |
| .. __: interrupt-framework-design.rst#el3-interrupts |
| |
| In order for S-EL1 software to handle Non-secure interrupts while having |
| |EHF| enabled, the dispatcher must adopt a model where Non-secure interrupts |
| are received at EL3, but are then `synchronously`__ handled over to S-EL1. |
| |
| .. __: interrupt-framework-design.rst#secure-payload |
| |
| - On GICv2 systems, it's required that the build option ``GICV2_G0_FOR_EL3`` is |
| set to ``1`` so that *Group 0* interrupts target EL3. |
| |
| - While executing in Secure world, |EHF| sets GIC Priority Mask Register to the |
| lowest Secure priority. This means that no Non-secure interrupts can preempt |
| Secure execution. See `Effect on SMC calls`_ for more details. |
| |
| As mentioned above, with |EHF|, the platform is required to partition *Group 0* |
| interrupts into distinct priority levels. A dispatcher that chooses to receive |
| interrupts can then *own* one or more priority levels, and register interrupt |
| handlers for them. A given priority level can be assigned to only one handler. A |
| dispatcher may register more than one priority level. |
| |
| Dispatchers are assigned interrupt priority levels in two steps: |
| |
| Partitioning priority levels |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Interrupts are associated to dispatchers by way of grouping and assigning |
| interrupts to a priority level. In other words, all interrupts that are to |
| target a particular dispatcher should fall in a particular priority level. For |
| priority assignment: |
| |
| - Of the 8 bits of priority that Arm GIC architecture permits, bit 7 must be 0 |
| (secure space). |
| |
| - Depending on the number of dispatchers to support, the platform must choose |
| to use the top *n* of the 7 remaining bits to identify and assign interrupts |
| to individual dispatchers. Choosing *n* bits supports up to 2\ :sup:`n` |
| distinct dispatchers. For example, by choosing 2 additional bits (i.e., bits |
| 6 and 5), the platform can partition into 4 secure priority ranges: ``0x0``, |
| ``0x20``, ``0x40``, and ``0x60``. See `Interrupt handling example`_. |
| |
| .. note:: |
| |
| The Arm GIC architecture requires that a GIC implementation that supports two |
| security states must implement at least 32 priority levels; i.e., at least 5 |
| upper bits of the 8 bits are writeable. In the scheme described above, when |
| choosing *n* bits for priority range assignment, the platform must ensure |
| that at least ``n+1`` top bits of GIC priority are writeable. |
| |
| The priority thus assigned to an interrupt is also used to determine the |
| priority of delegated execution in lower ELs. Delegated execution in lower EL is |
| associated with a priority level chosen with ``ehf_activate_priority()`` API |
| (described `later`__). The chosen priority level also determines the interrupts |
| masked while executing in a lower EL, therefore controls preemption of delegated |
| execution. |
| |
| .. __: `ehf-apis`_ |
| |
| The platform expresses the chosen priority levels by declaring an array of |
| priority level descriptors. Each entry in the array is of type |
| ``ehf_pri_desc_t``, and declares a priority level, and shall be populated by the |
| ``EHF_PRI_DESC()`` macro. |
| |
| .. warning:: |
| |
| The macro ``EHF_PRI_DESC()`` installs the descriptors in the array at a |
| computed index, and not necessarily where the macro is placed in the array. |
| The size of the array might therefore be larger than what it appears to be. |
| The ``ARRAY_SIZE()`` macro therefore should be used to determine the size of |
| array. |
| |
| Finally, this array of descriptors is exposed to |EHF| via the |
| ``EHF_REGISTER_PRIORITIES()`` macro. |
| |
| Refer to the `Interrupt handling example`_ for usage. See also: `Interrupt |
| Prioritisation Considerations`_. |
| |
| Programming priority |
| ~~~~~~~~~~~~~~~~~~~~ |
| |
| The text in `Partitioning priority levels`_ only describes how the platform |
| expresses the required levels of priority. It however doesn't choose interrupts |
| nor program the required priority in GIC. |
| |
| The `Firmware Design guide`__ explains methods for configuring secure |
| interrupts. |EHF| requires the platform to enumerate interrupt properties (as |
| opposed to just numbers) of Secure interrupts. The priority of secure interrupts |
| must match that as determined in the `Partitioning priority levels`_ section above. |
| |
| .. __: firmware-design.rst#configuring-secure-interrupts |
| |
| See `Limitations`_, and also refer to `Interrupt handling example`_ for |
| illustration. |
| |
| Registering handler |
| ------------------- |
| |
| Dispatchers register handlers for their priority levels through the following |
| API: |
| |
| .. code:: c |
| |
| int ehf_register_priority_handler(int pri, ehf_handler_t handler) |
| |
| The API takes two arguments: |
| |
| - The priority level for which the handler is being registered; |
| |
| - The handler to be registered. The handler must be aligned to 4 bytes. |
| |
| If a dispatcher owns more than one priority levels, it has to call the API for |
| each of them. |
| |
| The API will succeed, and return ``0``, only if: |
| |
| - There exists a descriptor with the priority level requested. |
| |
| - There are no handlers already registered by a previous call to the API. |
| |
| Otherwise, the API returns ``-1``. |
| |
| The interrupt handler should have the following signature: |
| |
| .. code:: c |
| |
| typedef int (*ehf_handler_t)(uint32_t intr_raw, uint32_t flags, void *handle, |
| void *cookie); |
| |
| The parameters are as obtained from the top-level `EL3 interrupt handler`__. |
| |
| .. __: interrupt-framework-design.rst#el3-runtime-firmware |
| |
| The `SDEI dispatcher`__, for example, expects the platform to allocate two |
| different priority levels—``PLAT_SDEI_CRITICAL_PRI``, and |
| ``PLAT_SDEI_NORMAL_PRI``—and registers the same handler to handle both levels. |
| |
| .. __: sdei.rst |
| |
| Interrupt handling example |
| -------------------------- |
| |
| The following annotated snippet demonstrates how a platform might choose to |
| assign interrupts to fictitious dispatchers: |
| |
| .. code:: c |
| |
| #include <common/interrupt_props.h> |
| #include <drivers/arm/gic_common.h> |
| #include <exception_mgmt.h> |
| |
| ... |
| |
| /* |
| * This platform uses 2 bits for interrupt association. In total, 3 upper |
| * bits are in use. |
| * |
| * 7 6 5 3 0 |
| * .-.-.-.----------. |
| * |0|b|b| ..0.. | |
| * '-'-'-'----------' |
| */ |
| #define PLAT_PRI_BITS 2 |
| |
| /* Priorities for individual dispatchers */ |
| #define DISP0_PRIO 0x00 /* Not used */ |
| #define DISP1_PRIO 0x20 |
| #define DISP2_PRIO 0x40 |
| #define DISP3_PRIO 0x60 |
| |
| /* Install priority level descriptors for each dispatcher */ |
| ehf_pri_desc_t plat_exceptions[] = { |
| EHF_PRI_DESC(PLAT_PRI_BITS, DISP1_PRIO), |
| EHF_PRI_DESC(PLAT_PRI_BITS, DISP2_PRIO), |
| EHF_PRI_DESC(PLAT_PRI_BITS, DISP3_PRIO), |
| }; |
| |
| /* Expose priority descriptors to Exception Handling Framework */ |
| EHF_REGISTER_PRIORITIES(plat_exceptions, ARRAY_SIZE(plat_exceptions), |
| PLAT_PRI_BITS); |
| |
| ... |
| |
| /* List interrupt properties for GIC driver. All interrupts target EL3 */ |
| const interrupt_prop_t plat_interrupts[] = { |
| /* Dispatcher 1 owns interrupts d1_0 and d1_1, so assigns priority DISP1_PRIO */ |
| INTR_PROP_DESC(d1_0, DISP1_PRIO, INTR_TYPE_EL3, GIC_INTR_CFG_LEVEL), |
| INTR_PROP_DESC(d1_1, DISP1_PRIO, INTR_TYPE_EL3, GIC_INTR_CFG_LEVEL), |
| |
| /* Dispatcher 2 owns interrupts d2_0 and d2_1, so assigns priority DISP2_PRIO */ |
| INTR_PROP_DESC(d2_0, DISP2_PRIO, INTR_TYPE_EL3, GIC_INTR_CFG_LEVEL), |
| INTR_PROP_DESC(d2_1, DISP2_PRIO, INTR_TYPE_EL3, GIC_INTR_CFG_LEVEL), |
| |
| /* Dispatcher 3 owns interrupts d3_0 and d3_1, so assigns priority DISP3_PRIO */ |
| INTR_PROP_DESC(d3_0, DISP3_PRIO, INTR_TYPE_EL3, GIC_INTR_CFG_LEVEL), |
| INTR_PROP_DESC(d3_1, DISP3_PRIO, INTR_TYPE_EL3, GIC_INTR_CFG_LEVEL), |
| }; |
| |
| ... |
| |
| /* Dispatcher 1 registers its handler */ |
| ehf_register_priority_handler(DISP1_PRIO, disp1_handler); |
| |
| /* Dispatcher 2 registers its handler */ |
| ehf_register_priority_handler(DISP2_PRIO, disp2_handler); |
| |
| /* Dispatcher 3 registers its handler */ |
| ehf_register_priority_handler(DISP3_PRIO, disp3_handler); |
| |
| ... |
| |
| See also the `Build-time flow`_ and the `Run-time flow`_. |
| |
| Activating and Deactivating priorities |
| -------------------------------------- |
| |
| A priority level is said to be *active* when an exception of that priority is |
| being handled: for interrupts, this is implied when the interrupt is |
| acknowledged; for non-interrupt exceptions, such as SErrors or `SDEI explicit |
| dispatches`__, this has to be done via calling ``ehf_activate_priority()``. See |
| `Run-time flow`_. |
| |
| .. __: sdei.rst#explicit-dispatch-of-events |
| |
| Conversely, when the dispatcher has reached a logical resolution for the cause |
| of the exception, the corresponding priority level ought to be deactivated. As |
| above, for interrupts, this is implied when the interrupt is EOId in the GIC; |
| for other exceptions, this has to be done via calling |
| ``ehf_deactivate_priority()``. |
| |
| Thanks to `different provisions`__ for exception delegation, there are |
| potentially more than one work flow for deactivation: |
| |
| .. __: `delegation-use-cases`_ |
| |
| .. _deactivation workflows: |
| |
| - The dispatcher has addressed the cause of the exception, and decided to take |
| no further action. In this case, the dispatcher's handler deactivates the |
| priority level before returning to the |EHF|. Runtime firmware, upon exit |
| through an ``ERET``, resumes execution before the interrupt occurred. |
| |
| - The dispatcher has to delegate the execution to lower ELs, and the cause of |
| the exception can be considered resolved only when the lower EL returns |
| signals complete (via an ``SMC``) at a future point in time. The following |
| sequence ensues: |
| |
| #. The dispatcher calls ``setjmp()`` to setup a jump point, and arranges to |
| enter a lower EL upon the next ``ERET``. |
| |
| #. Through the ensuing ``ERET`` from runtime firmware, execution is delegated |
| to a lower EL. |
| |
| #. The lower EL completes its execution, and signals completion via an |
| ``SMC``. |
| |
| #. The ``SMC`` is handled by the same dispatcher that handled the exception |
| previously. Noticing the conclusion of exception handling, the dispatcher |
| does ``longjmp()`` to resume beyond the previous jump point. |
| |
| As mentioned above, the |EHF| provides the following APIs for activating and |
| deactivating interrupt: |
| |
| .. _ehf-apis: |
| |
| - ``ehf_activate_priority()`` activates the supplied priority level, but only |
| if the current active priority is higher than the given one; otherwise |
| panics. Also, to prevent interruption by physical interrupts of lower |
| priority, the |EHF| programs the *Priority Mask Register* corresponding to |
| the PE to the priority being activated. Dispatchers typically only need to |
| call this when handling exceptions other than interrupts, and it needs to |
| delegate execution to a lower EL at a desired priority level. |
| |
| - ``ehf_deactivate_priority()`` deactivates a given priority, but only if the |
| current active priority is equal to the given one; otherwise panics. |EHF| |
| also restores the *Priority Mask Register* corresponding to the PE to the |
| priority before the call to ``ehf_activate_priority()``. Dispatchers |
| typically only need to call this after handling exceptions other than |
| interrupts. |
| |
| The calling of APIs are subject to allowed `transitions`__. See also the |
| `Run-time flow`_. |
| |
| .. __: `Transition of priority levels`_ |
| |
| Transition of priority levels |
| ----------------------------- |
| |
| The |EHF| APIs ``ehf_activate_priority()`` and ``ehf_deactivate_priority()`` can |
| be called to transition the current priority level on a PE. A given sequence of |
| calls to these APIs are subject to the following conditions: |
| |
| - For activation, the |EHF| only allows for the priority to increase (i.e. |
| numeric value decreases); |
| |
| - For deactivation, the |EHF| only allows for the priority to decrease (i.e. |
| numeric value increases). Additionally, the priority being deactivated is |
| required to be the current priority. |
| |
| If these are violated, a panic will result. |
| |
| Effect on SMC calls |
| ------------------- |
| |
| In general, Secure execution is regarded as more important than Non-secure |
| execution. As discussed elsewhere in this document, EL3 execution, and any |
| delegated execution thereafter, has the effect of raising GIC's priority |
| mask—either implicitly by acknowledging Secure interrupts, or when dispatchers |
| call ``ehf_activate_priority()``. As a result, Non-secure interrupts cannot |
| preempt any Secure execution. |
| |
| SMCs from Non-secure world are synchronous exceptions, and are mechanisms for |
| Non-secure world to request Secure services. They're broadly classified as |
| *Fast* or *Yielding* (see `SMCCC`__). |
| |
| .. __: `http://infocenter.arm.com/help/topic/com.arm.doc.den0028a/index.html` |
| |
| - *Fast* SMCs are atomic from the caller's point of view. I.e., they return |
| to the caller only when the Secure world has finished serving the request. |
| Any Non-secure interrupts that become pending meanwhile cannot preempt Secure |
| execution. |
| |
| - *Yielding* SMCs carry the semantics of a preemptible, lower-priority request. |
| A pending Non-secure interrupt can preempt Secure execution handling a |
| Yielding SMC. I.e., the caller might observe a Yielding SMC returning when |
| either: |
| |
| #. Secure world completes the request, and the caller would find ``SMC_OK`` |
| as the return code. |
| |
| #. A Non-secure interrupt preempts Secure execution. Non-secure interrupt is |
| handled, and Non-secure execution resumes after ``SMC`` instruction. |
| |
| The dispatcher handling a Yielding SMC must provide a different return code |
| to the Non-secure caller to distinguish the latter case. This return code, |
| however, is not standardised (unlike ``SMC_UNKNOWN`` or ``SMC_OK``, for |
| example), so will vary across dispatchers that handle the request. |
| |
| For the latter case above, dispatchers before |EHF| expect Non-secure interrupts |
| to be taken to S-EL1 [#irq]_, so would get a chance to populate the designated |
| preempted error code before yielding to Non-secure world. |
| |
| The introduction of |EHF| changes the behaviour as described in `Interrupt |
| handling`_. |
| |
| When |EHF| is enabled, in order to allow Non-secure interrupts to preempt |
| Yielding SMC handling, the dispatcher must call ``ehf_allow_ns_preemption()`` |
| API. The API takes one argument, the error code to be returned to the Non-secure |
| world upon getting preempted. |
| |
| .. [#irq] In case of GICv2, Non-secure interrupts while in S-EL1 were signalled |
| as IRQs, and in case of GICv3, FIQs. |
| |
| Build-time flow |
| --------------- |
| |
| Please refer to the `figure`__ above. |
| |
| .. __: `ehf-figure`_ |
| |
| The build-time flow involves the following steps: |
| |
| #. Platform assigns priorities by installing priority level descriptors for |
| individual dispatchers, as described in `Partitioning priority levels`_. |
| |
| #. Platform provides interrupt properties to GIC driver, as described in |
| `Programming priority`_. |
| |
| #. Dispatcher calling ``ehf_register_priority_handler()`` to register an |
| interrupt handler. |
| |
| Also refer to the `Interrupt handling example`_. |
| |
| Run-time flow |
| ------------- |
| |
| .. _interrupt-flow: |
| |
| The following is an example flow for interrupts: |
| |
| #. The GIC driver, during initialization, iterates through the platform-supplied |
| interrupt properties (see `Programming priority`_), and configures the |
| interrupts. This programs the appropriate priority and group (Group 0) on |
| interrupts belonging to different dispatchers. |
| |
| #. The |EHF|, during its initialisation, registers a top-level interrupt handler |
| with the `Interrupt Management Framework`__ for EL3 interrupts. This also |
| results in setting the routing bits in ``SCR_EL3``. |
| |
| .. __: interrupt-framework-design.rst#el3-runtime-firmware |
| |
| #. When an interrupt belonging to a dispatcher fires, GIC raises an EL3/Group 0 |
| interrupt, and is taken to EL3. |
| |
| #. The top-level EL3 interrupt handler executes. The handler acknowledges the |
| interrupt, reads its *Running Priority*, and from that, determines the |
| dispatcher handler. |
| |
| #. The |EHF| programs the *Priority Mask Register* of the PE to the priority of |
| the interrupt received. |
| |
| #. The |EHF| marks that priority level *active*, and jumps to the dispatcher |
| handler. |
| |
| #. Once the dispatcher handler finishes its job, it has to immediately |
| *deactivate* the priority level before returning to the |EHF|. See |
| `deactivation workflows`_. |
| |
| .. _non-interrupt-flow: |
| |
| The following is an example flow for exceptions that targets EL3 other than |
| interrupt: |
| |
| #. The platform provides handlers for the specific kind of exception. |
| |
| #. The exception arrives, and the corresponding handler is executed. |
| |
| #. The handler calls ``ehf_activate_priority()`` to activate the required |
| priority level. This also has the effect of raising GIC priority mask, thus |
| preventing interrupts of lower priority from preempting the handling. The |
| handler may choose to do the handling entirely in EL3 or delegate to a lower |
| EL. |
| |
| #. Once exception handling concludes, the handler calls |
| ``ehf_deactivate_priority()`` to deactivate the priority level activated |
| earlier. This also has the effect of lowering GIC priority mask to what it |
| was before. |
| |
| Interrupt Prioritisation Considerations |
| --------------------------------------- |
| |
| The GIC priority scheme, by design, prioritises Secure interrupts over Normal |
| world ones. The platform further assigns relative priorities amongst Secure |
| dispatchers through |EHF|. |
| |
| As mentioned in `Partitioning priority levels`_, interrupts targeting distinct |
| dispatchers fall in distinct priority levels. Because they're routed via the |
| GIC, interrupt delivery to the PE is subject to GIC prioritisation rules. In |
| particular, when an interrupt is being handled by the PE (i.e., the interrupt is |
| in *Active* state), only interrupts of higher priority are signalled to the PE, |
| even if interrupts of same or lower priority are pending. This has the side |
| effect of one dispatcher being starved of interrupts by virtue of another |
| dispatcher handling its (higher priority) interrupts. |
| |
| The |EHF| doesn't enforce a particular prioritisation policy, but the platform |
| should carefully consider the assignment of priorities to dispatchers integrated |
| into runtime firmware. The platform should sensibly delineate priority to |
| various dispatchers according to their nature. In particular, dispatchers of |
| critical nature (RAS, for example) should be assigned higher priority than |
| others (|SDEI|, for example); and within |SDEI|, Critical priority |
| |SDEI| should be assigned higher priority than Normal ones. |
| |
| Limitations |
| ----------- |
| |
| The |EHF| has the following limitations: |
| |
| - Although there could be up to 128 Secure dispatchers supported by the GIC |
| priority scheme, the size of descriptor array exposed with |
| ``EHF_REGISTER_PRIORITIES()`` macro is currently limited to 32. This serves most |
| expected use cases. This may be expanded in the future, should use cases |
| demand so. |
| |
| - The platform must ensure that the priority assigned to the dispatcher in the |
| exception descriptor and the programmed priority of interrupts handled by the |
| dispatcher match. The |EHF| cannot verify that this has been followed. |
| |
| ---- |
| |
| *Copyright (c) 2018, Arm Limited and Contributors. All rights reserved.* |
| |
| .. _Interrupt Framework Design: interrupt-framework-design.rst |
| .. _SDEI specification: http://infocenter.arm.com/help/topic/com.arm.doc.den0054a/ARM_DEN0054A_Software_Delegated_Exception_Interface.pdf |