| PSCI Library Integration guide for Armv8-A AArch32 systems |
| ========================================================== |
| |
| |
| .. section-numbering:: |
| :suffix: . |
| |
| .. contents:: |
| |
| This document describes the PSCI library interface with a focus on how to |
| integrate with a suitable Trusted OS for an Armv8-A AArch32 system. The PSCI |
| Library implements the PSCI Standard as described in `PSCI spec`_ and is meant |
| to be integrated with EL3 Runtime Software which invokes the PSCI Library |
| interface appropriately. **EL3 Runtime Software** refers to software executing |
| at the highest secure privileged mode, which is EL3 in AArch64 or Secure SVC/ |
| Monitor mode in AArch32, and provides runtime services to the non-secure world. |
| The runtime service request is made via SMC (Secure Monitor Call) and the call |
| must adhere to `SMCCC`_. In AArch32, EL3 Runtime Software may additionally |
| include Trusted OS functionality. A minimal AArch32 Secure Payload, SP-MIN, is |
| provided in Trusted Firmware-A (TF-A) to illustrate the usage and integration |
| of the PSCI library. The description of PSCI library interface and its |
| integration with EL3 Runtime Software in this document is targeted towards |
| AArch32 systems. |
| |
| Generic call sequence for PSCI Library interface (AArch32) |
| ---------------------------------------------------------- |
| |
| The generic call sequence of PSCI Library interfaces (see |
| `PSCI Library Interface`_) during cold boot in AArch32 |
| system is described below: |
| |
| #. After cold reset, the EL3 Runtime Software performs its cold boot |
| initialization including the PSCI library pre-requisites mentioned in |
| `PSCI Library Interface`_, and also the necessary platform |
| setup. |
| |
| #. Call ``psci_setup()`` in Monitor mode. |
| |
| #. Optionally call ``psci_register_spd_pm_hook()`` to register callbacks to |
| do bookkeeping for the EL3 Runtime Software during power management. |
| |
| #. Call ``psci_prepare_next_non_secure_ctx()`` to initialize the non-secure CPU |
| context. |
| |
| #. Get the non-secure ``cpu_context_t`` for the current CPU by calling |
| ``cm_get_context()`` , then programming the registers in the non-secure |
| context and exiting to non-secure world. If the EL3 Runtime Software needs |
| additional configuration to be set for non-secure context, like routing |
| FIQs to the secure world, the values of the registers can be modified prior |
| to programming. See `PSCI CPU context management`_ for more |
| details on CPU context management. |
| |
| The generic call sequence of PSCI library interfaces during warm boot in |
| AArch32 systems is described below: |
| |
| #. After warm reset, the EL3 Runtime Software performs the necessary warm |
| boot initialization including the PSCI library pre-requisites mentioned in |
| `PSCI Library Interface`_ (Note that the Data cache |
| **must not** be enabled). |
| |
| #. Call ``psci_warmboot_entrypoint()`` in Monitor mode. This interface |
| initializes/restores the non-secure CPU context as well. |
| |
| #. Do step 5 of the cold boot call sequence described above. |
| |
| The generic call sequence of PSCI library interfaces on receipt of a PSCI SMC |
| on an AArch32 system is described below: |
| |
| #. On receipt of an SMC, save the register context as per `SMCCC`_. |
| |
| #. If the SMC function identifier corresponds to a SMC32 PSCI API, construct |
| the appropriate arguments and call the ``psci_smc_handler()`` interface. |
| The invocation may or may not return back to the caller depending on |
| whether the PSCI API resulted in power down of the CPU. |
| |
| #. If ``psci_smc_handler()`` returns, populate the return value in R0 (AArch32)/ |
| X0 (AArch64) and restore other registers as per `SMCCC`_. |
| |
| PSCI CPU context management |
| --------------------------- |
| |
| PSCI library is in charge of initializing/restoring the non-secure CPU system |
| registers according to `PSCI specification`_ during cold/warm boot. |
| This is referred to as ``PSCI CPU Context Management``. Registers that need to |
| be preserved across CPU power down/power up cycles are maintained in |
| ``cpu_context_t`` data structure. The initialization of other non-secure CPU |
| system registers which do not require coordination with the EL3 Runtime |
| Software is done directly by the PSCI library (see ``cm_prepare_el3_exit()``). |
| |
| The EL3 Runtime Software is responsible for managing register context |
| during switch between Normal and Secure worlds. The register context to be |
| saved and restored depends on the mechanism used to trigger the world switch. |
| For example, if the world switch was triggered by an SMC call, then the |
| registers need to be saved and restored according to `SMCCC`_. In AArch64, |
| due to the tight integration with BL31, both BL31 and PSCI library |
| use the same ``cpu_context_t`` data structure for PSCI CPU context management |
| and register context management during world switch. This cannot be assumed |
| for AArch32 EL3 Runtime Software since most AArch32 Trusted OSes already implement |
| a mechanism for register context management during world switch. Hence, when |
| the PSCI library is integrated with a AArch32 EL3 Runtime Software, the |
| ``cpu_context_t`` is stripped down for just PSCI CPU context management. |
| |
| During cold/warm boot, after invoking appropriate PSCI library interfaces, it |
| is expected that the EL3 Runtime Software will query the ``cpu_context_t`` and |
| write appropriate values to the corresponding system registers. This mechanism |
| resolves 2 additional problems for AArch32 EL3 Runtime Software: |
| |
| #. Values for certain system registers like SCR and SCTLR cannot be |
| unilaterally determined by PSCI library and need inputs from the EL3 |
| Runtime Software. Using ``cpu_context_t`` as an intermediary data store |
| allows EL3 Runtime Software to modify the register values appropriately |
| before programming them. |
| |
| #. The PSCI library provides appropriate LR and SPSR values (entrypoint |
| information) for exit into non-secure world. Using ``cpu_context_t`` as an |
| intermediary data store allows the EL3 Runtime Software to store these |
| values safely until it is ready for exit to non-secure world. |
| |
| Currently the ``cpu_context_t`` data structure for AArch32 stores the following |
| registers: R0 - R3, LR (R14), SCR, SPSR, SCTLR. |
| |
| The EL3 Runtime Software must implement accessors to get/set pointers |
| to CPU context ``cpu_context_t`` data and these are described in |
| `CPU Context management API`_. |
| |
| PSCI Library Interface |
| ---------------------- |
| |
| The PSCI library implements the `PSCI Specification`_. The interfaces |
| to this library are declared in ``psci.h`` and are as listed below: |
| |
| .. code:: c |
| |
| u_register_t psci_smc_handler(uint32_t smc_fid, u_register_t x1, |
| u_register_t x2, u_register_t x3, |
| u_register_t x4, void *cookie, |
| void *handle, u_register_t flags); |
| int psci_setup(const psci_lib_args_t *lib_args); |
| void psci_warmboot_entrypoint(void); |
| void psci_register_spd_pm_hook(const spd_pm_ops_t *pm); |
| void psci_prepare_next_non_secure_ctx(entry_point_info_t *next_image_info); |
| |
| The CPU context data 'cpu\_context\_t' is programmed to the registers differently |
| when PSCI is integrated with an AArch32 EL3 Runtime Software compared to |
| when the PSCI is integrated with an AArch64 EL3 Runtime Software (BL31). For |
| example, in the case of AArch64, there is no need to retrieve ``cpu_context_t`` |
| data and program the registers as it will done implicitly as part of |
| ``el3_exit``. The description below of the PSCI interfaces is targeted at |
| integration with an AArch32 EL3 Runtime Software. |
| |
| The PSCI library is responsible for initializing/restoring the non-secure world |
| to an appropriate state after boot and may choose to directly program the |
| non-secure system registers. The PSCI generic code takes care not to directly |
| modify any of the system registers affecting the secure world and instead |
| returns the values to be programmed to these registers via ``cpu_context_t``. |
| The EL3 Runtime Software is responsible for programming those registers and |
| can use the proposed values provided in the ``cpu_context_t``, modifying the |
| values if required. |
| |
| PSCI library needs the flexibility to access both secure and non-secure |
| copies of banked registers. Hence it needs to be invoked in Monitor mode |
| for AArch32 and in EL3 for AArch64. The NS bit in SCR (in AArch32) or SCR\_EL3 |
| (in AArch64) must be set to 0. Additional requirements for the PSCI library |
| interfaces are: |
| |
| - Instruction cache must be enabled |
| - Both IRQ and FIQ must be masked for the current CPU |
| - The page tables must be setup and the MMU enabled |
| - The C runtime environment must be setup and stack initialized |
| - The Data cache must be enabled prior to invoking any of the PSCI library |
| interfaces except for ``psci_warmboot_entrypoint()``. For |
| ``psci_warmboot_entrypoint()``, if the build option ``HW_ASSISTED_COHERENCY`` |
| is enabled however, data caches are expected to be enabled. |
| |
| Further requirements for each interface can be found in the interface |
| description. |
| |
| Interface : psci\_setup() |
| ~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| :: |
| |
| Argument : const psci_lib_args_t *lib_args |
| Return : void |
| |
| This function is to be called by the primary CPU during cold boot before |
| any other interface to the PSCI library. It takes ``lib_args``, a const pointer |
| to ``psci_lib_args_t``, as the argument. The ``psci_lib_args_t`` is a versioned |
| structure and is declared in ``psci.h`` header as follows: |
| |
| .. code:: c |
| |
| typedef struct psci_lib_args { |
| /* The version information of PSCI Library Interface */ |
| param_header_t h; |
| /* The warm boot entrypoint function */ |
| mailbox_entrypoint_t mailbox_ep; |
| } psci_lib_args_t; |
| |
| The first field ``h``, of ``param_header_t`` type, provides the version |
| information. The second field ``mailbox_ep`` is the warm boot entrypoint address |
| and is used to configure the platform mailbox. Helper macros are provided in |
| psci.h to construct the ``lib_args`` argument statically or during runtime. Prior |
| to calling the ``psci_setup()`` interface, the platform setup for cold boot |
| must have completed. Major actions performed by this interface are: |
| |
| - Initializes architecture. |
| - Initializes PSCI power domain and state coordination data structures. |
| - Calls ``plat_setup_psci_ops()`` with warm boot entrypoint ``mailbox_ep`` as |
| argument. |
| - Calls ``cm_set_context_by_index()`` (see |
| `CPU Context management API`_) for all the CPUs in the |
| platform |
| |
| Interface : psci\_prepare\_next\_non\_secure\_ctx() |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| :: |
| |
| Argument : entry_point_info_t *next_image_info |
| Return : void |
| |
| After ``psci_setup()`` and prior to exit to the non-secure world, this function |
| must be called by the EL3 Runtime Software to initialize the non-secure world |
| context. The non-secure world entrypoint information ``next_image_info`` (first |
| argument) will be used to determine the non-secure context. After this function |
| returns, the EL3 Runtime Software must retrieve the ``cpu_context_t`` (using |
| cm\_get\_context()) for the current CPU and program the registers prior to exit |
| to the non-secure world. |
| |
| Interface : psci\_register\_spd\_pm\_hook() |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| :: |
| |
| Argument : const spd_pm_ops_t * |
| Return : void |
| |
| As explained in `Secure payload power management callback`_, |
| the EL3 Runtime Software may want to perform some bookkeeping during power |
| management operations. This function is used to register the ``spd_pm_ops_t`` |
| (first argument) callbacks with the PSCI library which will be called |
| ppropriately during power management. Calling this function is optional and |
| need to be called by the primary CPU during the cold boot sequence after |
| ``psci_setup()`` has completed. |
| |
| Interface : psci\_smc\_handler() |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| :: |
| |
| Argument : uint32_t smc_fid, u_register_t x1, |
| u_register_t x2, u_register_t x3, |
| u_register_t x4, void *cookie, |
| void *handle, u_register_t flags |
| Return : u_register_t |
| |
| This function is the top level handler for SMCs which fall within the |
| PSCI service range specified in `SMCCC`_. The function ID ``smc_fid`` (first |
| argument) determines the PSCI API to be called. The ``x1`` to ``x4`` (2nd to 5th |
| arguments), are the values of the registers r1 - r4 (in AArch32) or x1 - x4 |
| (in AArch64) when the SMC is received. These are the arguments to PSCI API as |
| described in `PSCI spec`_. The 'flags' (8th argument) is a bit field parameter |
| and is detailed in 'smcc.h' header. It includes whether the call is from the |
| secure or non-secure world. The ``cookie`` (6th argument) and the ``handle`` |
| (7th argument) are not used and are reserved for future use. |
| |
| The return value from this interface is the return value from the underlying |
| PSCI API corresponding to ``smc_fid``. This function may not return back to the |
| caller if PSCI API causes power down of the CPU. In this case, when the CPU |
| wakes up, it will start execution from the warm reset address. |
| |
| Interface : psci\_warmboot\_entrypoint() |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| :: |
| |
| Argument : void |
| Return : void |
| |
| This function performs the warm boot initialization/restoration as mandated by |
| `PSCI spec`_. For AArch32, on wakeup from power down the CPU resets to secure SVC |
| mode and the EL3 Runtime Software must perform the prerequisite initializations |
| mentioned at top of this section. This function must be called with Data cache |
| disabled (unless build option ``HW_ASSISTED_COHERENCY`` is enabled) but with MMU |
| initialized and enabled. The major actions performed by this function are: |
| |
| - Invalidates the stack and enables the data cache. |
| - Initializes architecture and PSCI state coordination. |
| - Restores/Initializes the peripheral drivers to the required state via |
| appropriate ``plat_psci_ops_t`` hooks |
| - Restores the EL3 Runtime Software context via appropriate ``spd_pm_ops_t`` |
| callbacks. |
| - Restores/Initializes the non-secure context and populates the |
| ``cpu_context_t`` for the current CPU. |
| |
| Upon the return of this function, the EL3 Runtime Software must retrieve the |
| non-secure ``cpu_context_t`` using ``cm_get_context()`` and program the registers |
| prior to exit to the non-secure world. |
| |
| EL3 Runtime Software dependencies |
| --------------------------------- |
| |
| The PSCI Library includes supporting frameworks like context management, |
| cpu operations (cpu\_ops) and per-cpu data framework. Other helper library |
| functions like bakery locks and spin locks are also included in the library. |
| The dependencies which must be fulfilled by the EL3 Runtime Software |
| for integration with PSCI library are described below. |
| |
| General dependencies |
| ~~~~~~~~~~~~~~~~~~~~ |
| |
| The PSCI library being a Multiprocessor (MP) implementation, EL3 Runtime |
| Software must provide an SMC handling framework capable of MP adhering to |
| `SMCCC`_ specification. |
| |
| The EL3 Runtime Software must also export cache maintenance primitives |
| and some helper utilities for assert, print and memory operations as listed |
| below. The TF-A source tree provides implementations for all |
| these functions but the EL3 Runtime Software may use its own implementation. |
| |
| **Functions : assert(), memcpy(), memset** |
| |
| These must be implemented as described in ISO C Standard. |
| |
| **Function : flush\_dcache\_range()** |
| |
| :: |
| |
| Argument : uintptr_t addr, size_t size |
| Return : void |
| |
| This function cleans and invalidates (flushes) the data cache for memory |
| at address ``addr`` (first argument) address and of size ``size`` (second argument). |
| |
| **Function : inv\_dcache\_range()** |
| |
| :: |
| |
| Argument : uintptr_t addr, size_t size |
| Return : void |
| |
| This function invalidates (flushes) the data cache for memory at address |
| ``addr`` (first argument) address and of size ``size`` (second argument). |
| |
| **Function : do\_panic()** |
| |
| :: |
| |
| Argument : void |
| Return : void |
| |
| This function will be called by the PSCI library on encountering a critical |
| failure that cannot be recovered from. This function **must not** return. |
| |
| **Function : tf\_printf()** |
| |
| This is printf-compatible function, but unlike printf, it does not return any |
| value. The TF-A source tree provides an implementation which |
| is optimized for stack usage and supports only a subset of format specifiers. |
| The details of the format specifiers supported can be found in the |
| ``tf_printf.c`` file in the TF-A source tree. |
| |
| CPU Context management API |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| The CPU context management data memory is statically allocated by PSCI library |
| in BSS section. The PSCI library requires the EL3 Runtime Software to implement |
| APIs to store and retrieve pointers to this CPU context data. SP-MIN |
| demonstrates how these APIs can be implemented but the EL3 Runtime Software can |
| choose a more optimal implementation (like dedicating the secure TPIDRPRW |
| system register (in AArch32) for storing these pointers). |
| |
| **Function : cm\_set\_context\_by\_index()** |
| |
| :: |
| |
| Argument : unsigned int cpu_idx, void *context, unsigned int security_state |
| Return : void |
| |
| This function is called during cold boot when the ``psci_setup()`` PSCI library |
| interface is called. |
| |
| This function must store the pointer to the CPU context data, ``context`` (2nd |
| argument), for the specified ``security_state`` (3rd argument) and CPU identified |
| by ``cpu_idx`` (first argument). The ``security_state`` will always be non-secure |
| when called by PSCI library and this argument is retained for compatibility |
| with BL31. The ``cpu_idx`` will correspond to the index returned by the |
| ``plat_core_pos_by_mpidr()`` for ``mpidr`` of the CPU. |
| |
| The actual method of storing the ``context`` pointers is implementation specific. |
| For example, SP-MIN stores the pointers in the array ``sp_min_cpu_ctx_ptr`` |
| declared in ``sp_min_main.c``. |
| |
| **Function : cm\_get\_context()** |
| |
| :: |
| |
| Argument : uint32_t security_state |
| Return : void * |
| |
| This function must return the pointer to the ``cpu_context_t`` structure for |
| the specified ``security_state`` (first argument) for the current CPU. The caller |
| must ensure that ``cm_set_context_by_index`` is called first and the appropriate |
| context pointers are stored prior to invoking this API. The ``security_state`` |
| will always be non-secure when called by PSCI library and this argument |
| is retained for compatibility with BL31. |
| |
| **Function : cm\_get\_context\_by\_index()** |
| |
| :: |
| |
| Argument : unsigned int cpu_idx, unsigned int security_state |
| Return : void * |
| |
| This function must return the pointer to the ``cpu_context_t`` structure for |
| the specified ``security_state`` (second argument) for the CPU identified by |
| ``cpu_idx`` (first argument). The caller must ensure that |
| ``cm_set_context_by_index`` is called first and the appropriate context |
| pointers are stored prior to invoking this API. The ``security_state`` will |
| always be non-secure when called by PSCI library and this argument is |
| retained for compatibility with BL31. The ``cpu_idx`` will correspond to the |
| index returned by the ``plat_core_pos_by_mpidr()`` for ``mpidr`` of the CPU. |
| |
| Platform API |
| ~~~~~~~~~~~~ |
| |
| The platform layer abstracts the platform-specific details from the generic |
| PSCI library. The following platform APIs/macros must be defined by the EL3 |
| Runtime Software for integration with the PSCI library. |
| |
| The mandatory platform APIs are: |
| |
| - plat\_my\_core\_pos |
| - plat\_core\_pos\_by\_mpidr |
| - plat\_get\_syscnt\_freq2 |
| - plat\_get\_power\_domain\_tree\_desc |
| - plat\_setup\_psci\_ops |
| - plat\_reset\_handler |
| - plat\_panic\_handler |
| - plat\_get\_my\_stack |
| |
| The mandatory platform macros are: |
| |
| - PLATFORM\_CORE\_COUNT |
| - PLAT\_MAX\_PWR\_LVL |
| - PLAT\_NUM\_PWR\_DOMAINS |
| - CACHE\_WRITEBACK\_GRANULE |
| - PLAT\_MAX\_OFF\_STATE |
| - PLAT\_MAX\_RET\_STATE |
| - PLAT\_MAX\_PWR\_LVL\_STATES (optional) |
| - PLAT\_PCPU\_DATA\_SIZE (optional) |
| |
| The details of these APIs/macros can be found in `Porting Guide`_. |
| |
| All platform specific operations for power management are done via |
| ``plat_psci_ops_t`` callbacks registered by the platform when |
| ``plat_setup_psci_ops()`` API is called. The description of each of |
| the callbacks in ``plat_psci_ops_t`` can be found in PSCI section of the |
| `Porting Guide`_. If any these callbacks are not registered, then the |
| PSCI API associated with that callback will not be supported by PSCI |
| library. |
| |
| Secure payload power management callback |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| During PSCI power management operations, the EL3 Runtime Software may |
| need to perform some bookkeeping, and PSCI library provides |
| ``spd_pm_ops_t`` callbacks for this purpose. These hooks must be |
| populated and registered by using ``psci_register_spd_pm_hook()`` PSCI |
| library interface. |
| |
| Typical bookkeeping during PSCI power management calls include save/restore |
| of the EL3 Runtime Software context. Also if the EL3 Runtime Software makes |
| use of secure interrupts, then these interrupts must also be managed |
| appropriately during CPU power down/power up. Any secure interrupt targeted |
| to the current CPU must be disabled or re-targeted to other running CPU prior |
| to power down of the current CPU. During power up, these interrupt can be |
| enabled/re-targeted back to the current CPU. |
| |
| .. code:: c |
| |
| typedef struct spd_pm_ops { |
| void (*svc_on)(u_register_t target_cpu); |
| int32_t (*svc_off)(u_register_t __unused); |
| void (*svc_suspend)(u_register_t max_off_pwrlvl); |
| void (*svc_on_finish)(u_register_t __unused); |
| void (*svc_suspend_finish)(u_register_t max_off_pwrlvl); |
| int32_t (*svc_migrate)(u_register_t from_cpu, u_register_t to_cpu); |
| int32_t (*svc_migrate_info)(u_register_t *resident_cpu); |
| void (*svc_system_off)(void); |
| void (*svc_system_reset)(void); |
| } spd_pm_ops_t; |
| |
| A brief description of each callback is given below: |
| |
| - svc\_on, svc\_off, svc\_on\_finish |
| |
| The ``svc_on``, ``svc_off`` callbacks are called during PSCI\_CPU\_ON, |
| PSCI\_CPU\_OFF APIs respectively. The ``svc_on_finish`` is called when the |
| target CPU of PSCI\_CPU\_ON API powers up and executes the |
| ``psci_warmboot_entrypoint()`` PSCI library interface. |
| |
| - svc\_suspend, svc\_suspend\_finish |
| |
| The ``svc_suspend`` callback is called during power down bu either |
| PSCI\_SUSPEND or PSCI\_SYSTEM\_SUSPEND APIs. The ``svc_suspend_finish`` is |
| called when the CPU wakes up from suspend and executes the |
| ``psci_warmboot_entrypoint()`` PSCI library interface. The ``max_off_pwrlvl`` |
| (first parameter) denotes the highest power domain level being powered down |
| to or woken up from suspend. |
| |
| - svc\_system\_off, svc\_system\_reset |
| |
| These callbacks are called during PSCI\_SYSTEM\_OFF and PSCI\_SYSTEM\_RESET |
| PSCI APIs respectively. |
| |
| - svc\_migrate\_info |
| |
| This callback is called in response to PSCI\_MIGRATE\_INFO\_TYPE or |
| PSCI\_MIGRATE\_INFO\_UP\_CPU APIs. The return value of this callback must |
| correspond to the return value of PSCI\_MIGRATE\_INFO\_TYPE API as described |
| in `PSCI spec`_. If the secure payload is a Uniprocessor (UP) |
| implementation, then it must update the mpidr of the CPU it is resident in |
| via ``resident_cpu`` (first argument). The updates to ``resident_cpu`` is |
| ignored if the secure payload is a multiprocessor (MP) implementation. |
| |
| - svc\_migrate |
| |
| This callback is only relevant if the secure payload in EL3 Runtime |
| Software is a Uniprocessor (UP) implementation and supports migration from |
| the current CPU ``from_cpu`` (first argument) to another CPU ``to_cpu`` |
| (second argument). This callback is called in response to PSCI\_MIGRATE |
| API. This callback is never called if the secure payload is a |
| Multiprocessor (MP) implementation. |
| |
| CPU operations |
| ~~~~~~~~~~~~~~ |
| |
| The CPU operations (cpu\_ops) framework implement power down sequence specific |
| to the CPU and the details of which can be found in the |
| ``CPU specific operations framework`` section of `Firmware Design`_. The TF-A |
| tree implements the ``cpu_ops`` for various supported CPUs and the EL3 Runtime |
| Software needs to include the required ``cpu_ops`` in its build. The start and |
| end of the ``cpu_ops`` descriptors must be exported by the EL3 Runtime Software |
| via the ``__CPU_OPS_START__`` and ``__CPU_OPS_END__`` linker symbols. |
| |
| The ``cpu_ops`` descriptors also include reset sequences and may include errata |
| workarounds for the CPU. The EL3 Runtime Software can choose to call this |
| during cold/warm reset if it does not implement its own reset sequence/errata |
| workarounds. |
| |
| -------------- |
| |
| *Copyright (c) 2016-2018, Arm Limited and Contributors. All rights reserved.* |
| |
| .. _PSCI spec: http://infocenter.arm.com/help/topic/com.arm.doc.den0022c/DEN0022C_Power_State_Coordination_Interface.pdf |
| .. _SMCCC: https://silver.arm.com/download/ARM_and_AMBA_Architecture/AR570-DA-80002-r0p0-00rel0/ARM_DEN0028A_SMC_Calling_Convention.pdf |
| .. _PSCI specification: http://infocenter.arm.com/help/topic/com.arm.doc.den0022c/DEN0022C_Power_State_Coordination_Interface.pdf |
| .. _PSCI Specification: http://infocenter.arm.com/help/topic/com.arm.doc.den0022c/DEN0022C_Power_State_Coordination_Interface.pdf |
| .. _Porting Guide: porting-guide.rst |
| .. _Firmware Design: ./firmware-design.rst |