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PSCI: Add documentation and fix plat_is_my_cpu_primary() 

This patch adds the necessary documentation updates to porting_guide.md
for the changes in the platform interface mandated as a result of the new
PSCI Topology and power state management frameworks. It also adds a
new document `platform-migration-guide.md` to aid the migration of existing
platform ports to the new API.

The patch fixes the implementation and callers of
plat_is_my_cpu_primary() to use w0 as the return parameter as implied by
the function signature rather than x0 which was used previously.

Change-Id: Ic11e73019188c8ba2bd64c47e1729ff5acdcdd5b
This commit is contained in:
Soby Mathew 2015-06-08 12:32:50 +01:00 committed by Achin Gupta
parent f9e858b1f7
commit 58523c076a
7 changed files with 842 additions and 197 deletions
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Guide to migrate to new Platform porting interface
==================================================
Contents
--------
1. [Introduction](#1--introduction)
2. [Platform API modification due to PSCI framework changes](#2--platform-api-modification-due-to-psci-framework-changes)
* [Power domain topology framework platform API modifications](#21-power-domain-topology-framework-platform-api-modifications)
* [Composite power state framework platform API modifications](#22-composite-power-state-framework-platform-api-modifications)
* [Miscellaneous modifications](#23-miscellaneous-modifications)
3. [Compatibility layer](#3--compatibility-layer)
4. [Deprecated Platform API](#4--deprecated-platform-api)
- - - - - - - - - - - - - - - - - -
1. Introduction
----------------
The PSCI implementation in Trusted Firmware has undergone a redesign because of
three requirements that the PSCI 1.0 specification introduced :
* Removing the framework assumption about the structure of the MPIDR, and
its relation to the power topology enables support for deeper and more
complex hierarchies.
* Reworking the power state coordination implementation in the framework
to support the more detailed PSCI 1.0 requirements and reduce platform
port complexity
* Enable the use of the extended power_state parameter and the larger StateID
field
The PSCI 1.0 implementation introduces new frameworks to fulfill the above
requirements. These framework changes mean that the platform porting API must
also be modified. This document is a guide to assist migration of the existing
platform ports to the new platform API.
This document describes the new platform API and compares it with the
deprecated API. It also describes the compatibility layer that enables the
existing platform ports to work with the PSCI 1.0 implementation. The
deprecated platform API is documented for reference.
2. Platform API modification due to PSCI framework changes
-----------------------------------------------------------
This section describes changes to the platform APIs.
2.1 Power domain topology framework platform API modifications
--------------------------------------------------------------
This removes the assumption in the PSCI implementation that MPIDR
based affinity instances map directly to power domains. A power domain, as
described in section 4.2 of [PSCI], could contain a core or a logical group
of cores (a cluster) which share some state on which power management
operations can be performed. The existing affinity instance based APIs
`plat_get_aff_count()` and `plat_get_aff_count()` are deprecated. The new
platform interfaces that are introduced for this framework are:
* `plat_core_pos_by_mpidr()`
* `plat_my_core_pos()`
* `plat_get_power_domain_tree_desc()`
`plat_my_core_pos()` and `plat_core_pos_by_mpidr()` are mandatory
and are meant to replace the existing `platform_get_core_pos()` API.
The description of these APIs can be found in the [Porting Guide][my_core_pos].
These are used by the power domain topology framework such that:
1. The generic PSCI code does not generate MPIDRs or use them to query the
platform about the number of power domains at a particular power level. The
`plat_get_power_domain_tree_desc()` provides a description of the power
domain tree on the SoC through a pointer to the byte array containing the
power domain topology tree description data structure.
2. The linear indices returned by `plat_core_pos_by_mpidr()` and
`plat_my_core_pos()` are used to retrieve core power domain nodes from
the power domain tree. These core indices are unique for a core and it is a
number between `0` and `PLATFORM_CORE_COUNT - 1`. The platform can choose
to implement a static mapping between `MPIDR` and core index or implement
a dynamic mapping, choosing to skip the unavailable/unused cores to compact
the core indices.
In addition, the platforms must define the macros `PLAT_NUM_PWR_DOMAINS` and
`PLAT_MAX_PWR_LVL` which replace the macros `PLAT_NUM_AFFS` and
`PLATFORM_MAX_AFFLVL` respectively. On platforms where the affinity instances
correspond to power domains, the values of new macros remain the same as the
old ones.
More details on the power domain topology description and its platform
interface can be found in [psci pd tree].
2.2 Composite power state framework platform API modifications
--------------------------------------------------------------
The state-ID field in the power-state parameter of a CPU_SUSPEND call can be
used to describe the composite power states specific to a platform. The existing
PSCI state coordination had the limitation that it operates on a run/off
granularity of power states and it did not interpret the state-ID field. This
was acceptable as the specification requirement in PSCI 0.2. The framework's
approach to coordination only requires maintaining a reference
count of the number of cores that have requested the cluster to remain powered.
In the PSCI 1.0 specification, this approach is non optimal. If composite
power states are used, the PSCI implementation cannot make global
decisions about state coordination required because it does not understand the
platform specific states.
The PSCI 1.0 implementation now defines a generic representation of the
power-state parameter :
typedef struct psci_power_state {
plat_local_state_t pwr_domain_state[PLAT_MAX_PWR_LVL + 1];
} psci_power_state_t;
`pwr_domain_state` is an array where each index corresponds to a power level.
Each entry in the array contains the local power state the power domain at
that power level could enter. The meaning of the local power state value is
platform defined, and can vary between levels in a single platform. The PSCI
implementation constraints the values only so that it can classify the state
as RUN, RETENTION or OFF as required by the specification:
1. Zero means RUN
2. All OFF state values at all levels must be higher than all
RETENTION state values at all levels
The platform is required to define the macros `PLAT_MAX_RET_STATE` and
`PLAT_MAX_OFF_STATE` to the framework. The requirement for these macros can
be found in the [Porting Guide].
The PSCI 1.0 implementation adds support to involve the platform in state
coordination. This enables the platform to decide the final target state.
During a request to place a power domain in a low power state, the platform
is passed an array of requested `plat_local_state_t` for that power domain by
each core within it through the `plat_get_target_pwr_state()` API. This API
coordinates amongst these requested states to determine a target
`plat_local_state_t` for that power domain. A default weak implementation of
this API is provided in the platform layer which returns the minimum of the
requested local states back to the PSCI state coordination. More details
of `plat_get_target_pwr_state()` API can be found in the
[Porting Guide][get_target_pwr_state].
The PSCI Generic implementation expects platform ports to populate the handlers
for the `plat_psci_ops` structure which is declared as :
typedef struct plat_psci_ops {
void (*cpu_standby)(plat_local_state_t cpu_state);
int (*pwr_domain_on)(u_register_t mpidr);
void (*pwr_domain_off)(const psci_power_state_t *target_state);
void (*pwr_domain_suspend)(const psci_power_state_t *target_state);
void (*pwr_domain_on_finish)(const psci_power_state_t *target_state);
void (*pwr_domain_suspend_finish)(
const psci_power_state_t *target_state);
void (*system_off)(void) __dead2;
void (*system_reset)(void) __dead2;
int (*validate_power_state)(unsigned int power_state,
psci_power_state_t *req_state);
int (*validate_ns_entrypoint)(unsigned long ns_entrypoint);
void (*get_sys_suspend_power_state)(
psci_power_state_t *req_state);
} plat_psci_ops_t;
The description of these handlers can be found in the [Porting Guide][psci_ops].
The previous `plat_pm_ops` structure is deprecated. Compared with the previous
handlers, the major differences are:
* Difference in parameters
The PSCI 1.0 implementation depends on the `validate_power_state` handler to
convert the power-state parameter (possibly encoding a composite power state)
passed in a PSCI `CPU_SUSPEND` to the `psci_power_state` format.
The `plat_psci_ops` handlers, `pwr_domain_off` and `pwr_domain_suspend`, are
passed the target local state for each affected power domain. The platform
must execute operations specific to these target states. Similarly,
`pwr_domain_on_finish` and `pwr_domain_suspend_finish` are passed the local
states of the affected power domains before wakeup. The platform
must execute actions to restore these power domains from these specific
local states.
* Difference in invocation
Whereas the power management handlers in `plat_pm_ops` used to be invoked
for each affinity level till the target affinity level, the new handlers
are only invoked once. The `target_state` encodes the target low power
state or the low power state woken up from for each affected power domain.
* Difference in semantics
Although the previous `suspend` handlers could be used for power down as well
as retention at different affinity levels, the new handlers make this support
explicit. The `pwr_domain_suspend` can be used to specify powerdown and
retention at various power domain levels subject to the conditions mentioned
in section 4.2.1 of [PSCI]
Unlike the previous `standby` handler, the `cpu_standby()` handler is only used
as a fast path for placing a core power domain into a standby or retention
state.
The below diagram shows the sequence of a PSCI SUSPEND call and the interaction
with the platform layer depicting the exchange of data between PSCI Generic
layer and the platform layer.
![Image 1](diagrams/psci-suspend-sequence.png?raw=true)
Refer [plat/arm/board/fvp/fvp_pm.c] for the implementation details of
these handlers for the FVP. The commit b6df6ccbc88cc14592f5e603ef580d3cbf4733c3
demonstrates the migration of ARM reference platforms to the new platform API.
2.3 Miscellaneous modifications
-------------------------------
In addition to the framework changes, unification of warm reset entry points on
wakeup from low power modes has led to a change in the platform API. In the
earlier implementation, the warm reset entry used to be programmed into the
mailboxes by the 'ON' and 'SUSPEND' power management hooks. In the PSCI 1.0
implementation, this information is not required, because it can figure that
out by querying affinity info state whether to execute the 'suspend_finisher`
or 'on_finisher'.
As a result, the warm reset entry point must be programmed only once. The
`plat_setup_psci_ops()` API takes the secure entry point as an
additional parameter to enable the platforms to configure their mailbox. The
plat_psci_ops handlers `pwr_domain_on` and `pwr_domain_suspend` no longer take
the warm reset entry point as a parameter.
Also, some platform APIs which took `MPIDR` as an argument were only ever
invoked to perform actions specific to the caller core which makes the argument
redundant. Therefore the platform APIs `plat_get_my_entrypoint()`,
`plat_is_my_cpu_primary()`, `plat_set_my_stack()` and
`plat_get_my_stack()` are defined which are meant to be invoked only for
operations on the current caller core instead of `platform_get_entrypoint()`,
`platform_is_primary_cpu()`, `platform_set_stack()` and `platform_get_stack()`.
3. Compatibility layer
----------------------
To ease the migration of the platform ports to the new porting interface,
a compatibility layer is introduced that essentially implements a glue layer
between the old platform API and the new API. The build flag
`ENABLE_PLAT_COMPAT` (enabled by default), specifies whether to enable this
layer or not. A platform port which has migrated to the new API can disable
this flag within the platform specific makefile.
The compatibility layer works on the assumption that the onus of
state coordination, in case multiple low power states are supported,
is with the platform. The generic PSCI implementation only takes into
account whether the suspend request is power down or not. This corresponds
with the behavior of the PSCI implementation before the introduction of
new frameworks. Also, it assumes that the affinity levels of the platform
correspond directly to the power domain levels.
The compatibility layer dynamically constructs the new topology
description array by querying the platform using `plat_get_aff_count()`
and `plat_get_aff_count()` APIs. The linear index returned by
`platform_get_core_pos()` is used as the core index for the cores. The
higher level (non-core) power domain nodes must know the cores contained
within its domain. It does so by storing the core index of first core
within it and number of core indexes following it. This means that core
indices returned by `platform_get_core_pos()` for cores within a particular
power domain must be consecutive. We expect that this is the case for most
platform ports including ARM reference platforms.
The old PSCI helpers like `psci_get_suspend_powerstate()`,
`psci_get_suspend_stateid()`, `psci_get_suspend_stateid_by_mpidr()`,
`psci_get_max_phys_off_afflvl()` and `psci_get_suspend_afflvl()` are also
implemented for the compatibility layer. This allows the existing
platform ports to work with the new PSCI frameworks without significant
rework.
4. Deprecated Platform API
---------------------------
This section documents the deprecated platform porting API.
## Common mandatory modifications
The mandatory macros to be defined by the platform port in `platform_def.h`
* **#define : PLATFORM_NUM_AFFS**
Defines the total number of nodes in the affinity hierarchy at all affinity
levels used by the platform.
* **#define : PLATFORM_MAX_AFFLVL**
Defines the maximum affinity level that the power management operations
should apply to. ARMv8-A has support for four affinity levels. It is likely
that hardware will implement fewer affinity levels. This macro allows the
PSCI implementation to consider only those affinity levels in the system
that the platform implements. For example, the Base AEM FVP implements two
clusters with a configurable number of cores. It reports the maximum
affinity level as 1, resulting in PSCI power control up to the cluster
level.
The following functions must be implemented by the platform port to enable
the reset vector code to perform the required tasks.
### Function : platform_get_entrypoint() [mandatory]
Argument : unsigned long
Return : unsigned long
This function is called with the `SCTLR.M` and `SCTLR.C` bits disabled. The core
is identified by its `MPIDR`, which is passed as the argument. The function is
responsible for distinguishing between a warm and cold reset using platform-
specific means. If it is a warm reset, it returns the entrypoint into the
BL3-1 image that the core must jump to. If it is a cold reset, this function
must return zero.
This function is also responsible for implementing a platform-specific mechanism
to handle the condition where the core has been warm reset but there is no
entrypoint to jump to.
This function does not follow the Procedure Call Standard used by the
Application Binary Interface for the ARM 64-bit architecture. The caller should
not assume that callee saved registers are preserved across a call to this
function.
### Function : platform_is_primary_cpu() [mandatory]
Argument : unsigned long
Return : unsigned int
This function identifies a core by its `MPIDR`, which is passed as the argument,
to determine whether this core is the primary core or a secondary core. A return
value of zero indicates that the core is not the primary core, while a non-zero
return value indicates that the core is the primary core.
## Common optional modifications
### Function : platform_get_core_pos()
Argument : unsigned long
Return : int
A platform may need to convert the `MPIDR` of a core to an absolute number, which
can be used as a core-specific linear index into blocks of memory (for example
while allocating per-core stacks). This routine contains a simple mechanism
to perform this conversion, using the assumption that each cluster contains a
maximum of four cores:
linear index = cpu_id + (cluster_id * 4)
cpu_id = 8-bit value in MPIDR at affinity level 0
cluster_id = 8-bit value in MPIDR at affinity level 1
### Function : platform_set_stack()
Argument : unsigned long
Return : void
This function sets the current stack pointer to the normal memory stack that
has been allocated for the core specified by MPIDR. For BL images that only
require a stack for the primary core the parameter is ignored. The size of
the stack allocated to each core is specified by the platform defined constant
`PLATFORM_STACK_SIZE`.
Common implementations of this function for the UP and MP BL images are
provided in [plat/common/aarch64/platform_up_stack.S] and
[plat/common/aarch64/platform_mp_stack.S]
### Function : platform_get_stack()
Argument : unsigned long
Return : unsigned long
This function returns the base address of the normal memory stack that
has been allocated for the core specificed by MPIDR. For BL images that only
require a stack for the primary core the parameter is ignored. The size of
the stack allocated to each core is specified by the platform defined constant
`PLATFORM_STACK_SIZE`.
Common implementations of this function for the UP and MP BL images are
provided in [plat/common/aarch64/platform_up_stack.S] and
[plat/common/aarch64/platform_mp_stack.S]
## Modifications for Power State Coordination Interface (in BL3-1)
The following functions must be implemented to initialize PSCI functionality in
the ARM Trusted Firmware.
### Function : plat_get_aff_count() [mandatory]
Argument : unsigned int, unsigned long
Return : unsigned int
This function may execute with the MMU and data caches enabled if the platform
port does the necessary initializations in `bl31_plat_arch_setup()`. It is only
called by the primary core.
This function is called by the PSCI initialization code to detect the system
topology. Its purpose is to return the number of affinity instances implemented
at a given `affinity level` (specified by the first argument) and a given
`MPIDR` (specified by the second argument). For example, on a dual-cluster
system where first cluster implements two cores and the second cluster
implements four cores, a call to this function with an `MPIDR` corresponding
to the first cluster (`0x0`) and affinity level 0, would return 2. A call
to this function with an `MPIDR` corresponding to the second cluster (`0x100`)
and affinity level 0, would return 4.
### Function : plat_get_aff_state() [mandatory]
Argument : unsigned int, unsigned long
Return : unsigned int
This function may execute with the MMU and data caches enabled if the platform
port does the necessary initializations in `bl31_plat_arch_setup()`. It is only
called by the primary core.
This function is called by the PSCI initialization code. Its purpose is to
return the state of an affinity instance. The affinity instance is determined by
the affinity ID at a given `affinity level` (specified by the first argument)
and an `MPIDR` (specified by the second argument). The state can be one of
`PSCI_AFF_PRESENT` or `PSCI_AFF_ABSENT`. The latter state is used to cater for
system topologies where certain affinity instances are unimplemented. For
example, consider a platform that implements a single cluster with four cores and
another core implemented directly on the interconnect with the cluster. The
`MPIDR`s of the cluster would range from `0x0-0x3`. The `MPIDR` of the single
core is 0x100 to indicate that it does not belong to cluster 0. Cluster 1
is missing but needs to be accounted for to reach this single core in the
topology tree. Therefore it is marked as `PSCI_AFF_ABSENT`.
### Function : platform_setup_pm() [mandatory]
Argument : const plat_pm_ops **
Return : int
This function may execute with the MMU and data caches enabled if the platform
port does the necessary initializations in `bl31_plat_arch_setup()`. It is only
called by the primary core.
This function is called by PSCI initialization code. Its purpose is to export
handler routines for platform-specific power management actions by populating
the passed pointer with a pointer to the private `plat_pm_ops` structure of
BL3-1.
A description of each member of this structure is given below. A platform port
is expected to implement these handlers if the corresponding PSCI operation
is to be supported and these handlers are expected to succeed if the return
type is `void`.
#### plat_pm_ops.affinst_standby()
Perform the platform-specific setup to enter the standby state indicated by the
passed argument. The generic code expects the handler to succeed.
#### plat_pm_ops.affinst_on()
Perform the platform specific setup to power on an affinity instance, specified
by the `MPIDR` (first argument) and `affinity level` (third argument). The
`state` (fourth argument) contains the current state of that affinity instance
(ON or OFF). This is useful to determine whether any action must be taken. For
example, while powering on a core, the cluster that contains this core might
already be in the ON state. The platform decides what actions must be taken to
transition from the current state to the target state (indicated by the power
management operation). The generic code expects the platform to return
E_SUCCESS on success or E_INTERN_FAIL for any failure.
#### plat_pm_ops.affinst_off()
Perform the platform specific setup to power off an affinity instance of the
calling core. It is called by the PSCI `CPU_OFF` API implementation.
The `affinity level` (first argument) and `state` (second argument) have
a similar meaning as described in the `affinst_on()` operation. They
identify the affinity instance on which the call is made and its
current state. This gives the platform port an indication of the
state transition it must make to perform the requested action. For example, if
the calling core is the last powered on core in the cluster, after powering down
affinity level 0 (the core), the platform port should power down affinity
level 1 (the cluster) as well. The generic code expects the handler to succeed.
#### plat_pm_ops.affinst_suspend()
Perform the platform specific setup to power off an affinity instance of the
calling core. It is called by the PSCI `CPU_SUSPEND` API and `SYSTEM_SUSPEND`
API implementation
The `affinity level` (second argument) and `state` (third argument) have a
similar meaning as described in the `affinst_on()` operation. They are used to
identify the affinity instance on which the call is made and its current state.
This gives the platform port an indication of the state transition it must
make to perform the requested action. For example, if the calling core is the
last powered on core in the cluster, after powering down affinity level 0
(the core), the platform port should power down affinity level 1 (the cluster)
as well.
The difference between turning an affinity instance off and suspending it
is that in the former case, the affinity instance is expected to re-initialize
its state when it is next powered on (see `affinst_on_finish()`). In the latter
case, the affinity instance is expected to save enough state so that it can
resume execution by restoring this state when it is powered on (see
`affinst_suspend_finish()`).The generic code expects the handler to succeed.
#### plat_pm_ops.affinst_on_finish()
This function is called by the PSCI implementation after the calling core is
powered on and released from reset in response to an earlier PSCI `CPU_ON` call.
It performs the platform-specific setup required to initialize enough state for
this core to enter the Normal world and also provide secure runtime firmware
services.
The `affinity level` (first argument) and `state` (second argument) have a
similar meaning as described in the previous operations. The generic code
expects the handler to succeed.
#### plat_pm_ops.affinst_suspend_finish()
This function is called by the PSCI implementation after the calling core is
powered on and released from reset in response to an asynchronous wakeup
event, for example a timer interrupt that was programmed by the core during the
`CPU_SUSPEND` call or `SYSTEM_SUSPEND` call. It performs the platform-specific
setup required to restore the saved state for this core to resume execution
in the Normal world and also provide secure runtime firmware services.
The `affinity level` (first argument) and `state` (second argument) have a
similar meaning as described in the previous operations. The generic code
expects the platform to succeed.
#### plat_pm_ops.validate_power_state()
This function is called by the PSCI implementation during the `CPU_SUSPEND`
call to validate the `power_state` parameter of the PSCI API. If the
`power_state` is known to be invalid, the platform must return
PSCI_E_INVALID_PARAMS as an error, which is propagated back to the Normal
world PSCI client.
#### plat_pm_ops.validate_ns_entrypoint()
This function is called by the PSCI implementation during the `CPU_SUSPEND`,
`SYSTEM_SUSPEND` and `CPU_ON` calls to validate the Non-secure `entry_point`
parameter passed by the Normal world. If the `entry_point` is known to be
invalid, the platform must return PSCI_E_INVALID_PARAMS as an error, which is
propagated back to the Normal world PSCI client.
#### plat_pm_ops.get_sys_suspend_power_state()
This function is called by the PSCI implementation during the `SYSTEM_SUSPEND`
call to return the `power_state` parameter. This allows the platform to encode
the appropriate State-ID field within the `power_state` parameter which can be
utilized in `affinst_suspend()` to suspend to system affinity level. The
`power_state` parameter should be in the same format as specified by the
PSCI specification for the CPU_SUSPEND API.
- - - - - - - - - - - - - - - - - - - - - - - - - -
_Copyright (c) 2015, ARM Limited and Contributors. All rights reserved._
[Porting Guide]: porting-guide.md
[Power Domain Topology Design]: psci-pd-tree.md
[PSCI]: http://infocenter.arm.com/help/topic/com.arm.doc.den0022c/DEN0022C_Power_State_Coordination_Interface.pdf
[psci pd tree]: psci-pd-tree.md
[my_core_pos]: porting-guide.md#function--plat_my_core_pos
[get_target_pwr_state]: porting-guide.md#function--plat_get_target_pwr_state-optional
[psci_ops]: porting-guide.md#function--plat_setup_psci_ops-mandatory
[plat/arm/board/fvp/fvp_pm.c]: ../plat/arm/board/fvp/fvp_pm.c
[plat/common/aarch64/platform_mp_stack.S]: ../plat/common/aarch64/platform_mp_stack.S
[plat/common/aarch64/platform_up_stack.S]: ../plat/common/aarch64/platform_up_stack.S

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docs/porting-guide.md
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@ -8,7 +8,8 @@ Contents
2. [Common Modifications](#2--common-modifications)
* [Common mandatory modifications](#21-common-mandatory-modifications)
* [Handling reset](#22-handling-reset)
* [Common optional modifications](#23-common-optional-modifications)
* [Common mandatory modifications](#23-common-mandatory-modifications)
* [Common optional modifications](#24-common-optional-modifications)
3. [Boot Loader stage specific modifications](#3--modifications-specific-to-a-boot-loader-stage)
* [Boot Loader stage 1 (BL1)](#31-boot-loader-stage-1-bl1)
* [Boot Loader stage 2 (BL2)](#32-boot-loader-stage-2-bl2)
@ -25,6 +26,10 @@ Contents
1. Introduction
----------------
Please note that this document has been updated for the new platform API
as required by the PSCI v1.0 implementation. Please refer to the
[Migration Guide] for the previous platform API.
Porting the ARM Trusted Firmware to a new platform involves making some
mandatory and optional modifications for both the cold and warm boot paths.
Modifications consist of:
@ -139,21 +144,39 @@ platform port to define additional platform porting constants in
Defines the total number of CPUs implemented by the platform across all
clusters in the system.
* **#define : PLATFORM_NUM_AFFS**
* **#define : PLAT_NUM_PWR_DOMAINS**
Defines the total number of nodes in the affinity heirarchy at all affinity
levels used by the platform.
Defines the total number of nodes in the power domain topology
tree at all the power domain levels used by the platform.
This macro is used by the PSCI implementation to allocate
data structures to represent power domain topology.
* **#define : PLATFORM_MAX_AFFLVL**
* **#define : PLAT_MAX_PWR_LVL**
Defines the maximum affinity level that the power management operations
should apply to. ARMv8-A has support for 4 affinity levels. It is likely
that hardware will implement fewer affinity levels. This macro allows the
PSCI implementation to consider only those affinity levels in the system
that the platform implements. For example, the Base AEM FVP implements two
clusters with a configurable number of CPUs. It reports the maximum
affinity level as 1, resulting in PSCI power control up to the cluster
level.
Defines the maximum power domain level that the power management operations
should apply to. More often, but not always, the power domain level
corresponds to affinity level. This macro allows the PSCI implementation
to know the highest power domain level that it should consider for power
management operations in the system that the platform implements. For
example, the Base AEM FVP implements two clusters with a configurable
number of CPUs and it reports the maximum power domain level as 1.
* **#define : PLAT_MAX_OFF_STATE**
Defines the local power state corresponding to the deepest power down
possible at every power domain level in the platform. The local power
states for each level may be sparsely allocated between 0 and this value
with 0 being reserved for the RUN state. The PSCI implementation uses this
value to initialize the local power states of the power domain nodes and
to specify the requested power state for a PSCI_CPU_OFF call.
* **#define : PLAT_MAX_RET_STATE**
Defines the local power state corresponding to the deepest retention state
possible at every power domain level in the platform. This macro should be
a value less than PLAT_MAX_OFF_STATE and greater than 0. It is used by the
PSCI implementation to distuiguish between retention and power down local
power states within PSCI_CPU_SUSPEND call.
* **#define : BL1_RO_BASE**
@ -408,21 +431,17 @@ The following functions need to be implemented by the platform port to enable
reset vector code to perform the above tasks.
### Function : platform_get_entrypoint() [mandatory]
### Function : plat_get_my_entrypoint() [mandatory when PROGRAMMABLE_RESET_ADDRESS == 0]
Argument : unsigned long
Return : unsigned int
Argument : void
Return : unsigned long
This function is called with the `SCTLR.M` and `SCTLR.C` bits disabled. The CPU
is identified by its `MPIDR`, which is passed as the argument. The function is
responsible for distinguishing between a warm and cold reset using platform-
specific means. If it's a warm reset then it returns the entrypoint into the
BL3-1 image that the CPU must jump to. If it's a cold reset then this function
must return zero.
This function is also responsible for implementing a platform-specific mechanism
to handle the condition where the CPU has been warm reset but there is no
entrypoint to jump to.
This function is called with the called with the MMU and caches disabled
(`SCTLR_EL3.M` = 0 and `SCTLR_EL3.C` = 0). The function is responsible for
distinguishing between a warm and cold reset for the current CPU using
platform-specific means. If it's a warm reset, then it returns the warm
reset entrypoint point provided to `plat_setup_psci_ops()` during
BL3-1 initialization. If it's a cold reset then this function must return zero.
This function does not follow the Procedure Call Standard used by the
Application Binary Interface for the ARM 64-bit architecture. The caller should
@ -431,11 +450,16 @@ function.
This function fulfills requirement 1 and 3 listed above.
Note that for platforms that support programming the reset address, it is
expected that a CPU will start executing code directly at the right address,
both on a cold and warm reset. In this case, there is no need to identify the
type of reset nor to query the warm reset entrypoint. Therefore, implementing
this function is not required on such platforms.
### Function : plat_secondary_cold_boot_setup() [mandatory]
Argument : void
Return : void
This function is called with the MMU and data caches disabled. It is responsible
for placing the executing secondary CPU in a platform-specific state until the
@ -449,15 +473,15 @@ requires them.
This function fulfills requirement 2 above.
### Function : platform_is_primary_cpu() [mandatory]
### Function : plat_is_my_cpu_primary() [mandatory]
Argument : unsigned long
Argument : void
Return : unsigned int
This function identifies a CPU by its `MPIDR`, which is passed as the argument,
to determine whether this CPU is the primary CPU or a secondary CPU. A return
value of zero indicates that the CPU is not the primary CPU, while a non-zero
return value indicates that the CPU is the primary CPU.
This function identifies whether the current CPU is the primary CPU or a
secondary CPU. A return value of zero indicates that the CPU is not the
primary CPU, while a non-zero return value indicates that the CPU is the
primary CPU.
### Function : platform_mem_init() [mandatory]
@ -501,58 +525,75 @@ retrieved from the platform. The function also reports extra information related
to the ROTPK in the flags parameter.
2.3 Common mandatory modifications
---------------------------------
2.3 Common optional modifications
The following functions are mandatory functions which need to be implemented
by the platform port.
### Function : plat_my_core_pos()
Argument : void
Return : unsigned int
This funtion returns the index of the calling CPU which is used as a
CPU-specific linear index into blocks of memory (for example while allocating
per-CPU stacks). This function will be invoked very early in the
initialization sequence which mandates that this function should be
implemented in assembly and should not rely on the avalability of a C
runtime environment.
This function plays a crucial role in the power domain topology framework in
PSCI and details of this can be found in [Power Domain Topology Design].
### Function : plat_core_pos_by_mpidr()
Argument : u_register_t
Return : int
This function validates the `MPIDR` of a CPU and converts it to an index,
which can be used as a CPU-specific linear index into blocks of memory. In
case the `MPIDR` is invalid, this function returns -1. This function will only
be invoked by BL3-1 after the power domain topology is initialized and can
utilize the C runtime environment. For further details about how ARM Trusted
Firmware represents the power domain topology and how this relates to the
linear CPU index, please refer [Power Domain Topology Design].
2.4 Common optional modifications
---------------------------------
The following are helper functions implemented by the firmware that perform
common platform-specific tasks. A platform may choose to override these
definitions.
### Function : plat_set_my_stack()
### Function : platform_get_core_pos()
Argument : unsigned long
Return : int
A platform may need to convert the `MPIDR` of a CPU to an absolute number, which
can be used as a CPU-specific linear index into blocks of memory (for example
while allocating per-CPU stacks). This routine contains a simple mechanism
to perform this conversion, using the assumption that each cluster contains a
maximum of 4 CPUs:
linear index = cpu_id + (cluster_id * 4)
cpu_id = 8-bit value in MPIDR at affinity level 0
cluster_id = 8-bit value in MPIDR at affinity level 1
### Function : platform_set_stack()
Argument : unsigned long
Argument : void
Return : void
This function sets the current stack pointer to the normal memory stack that
has been allocated for the CPU specificed by MPIDR. For BL images that only
require a stack for the primary CPU the parameter is ignored. The size of
the stack allocated to each CPU is specified by the platform defined constant
`PLATFORM_STACK_SIZE`.
has been allocated for the current CPU. For BL images that only require a
stack for the primary CPU, the UP version of the function is used. The size
of the stack allocated to each CPU is specified by the platform defined
constant `PLATFORM_STACK_SIZE`.
Common implementations of this function for the UP and MP BL images are
provided in [plat/common/aarch64/platform_up_stack.S] and
[plat/common/aarch64/platform_mp_stack.S]
### Function : platform_get_stack()
### Function : plat_get_my_stack()
Argument : unsigned long
Argument : void
Return : unsigned long
This function returns the base address of the normal memory stack that
has been allocated for the CPU specificed by MPIDR. For BL images that only
require a stack for the primary CPU the parameter is ignored. The size of
the stack allocated to each CPU is specified by the platform defined constant
`PLATFORM_STACK_SIZE`.
has been allocated for the current CPU. For BL images that only require a
stack for the primary CPU, the UP version of the function is used. The size
of the stack allocated to each CPU is specified by the platform defined
constant `PLATFORM_STACK_SIZE`.
Common implementations of this function for the UP and MP BL images are
provided in [plat/common/aarch64/platform_up_stack.S] and
@ -1113,147 +1154,159 @@ modes table.
------------------------------------------------
The ARM Trusted Firmware's implementation of the PSCI API is based around the
concept of an _affinity instance_. Each _affinity instance_ can be uniquely
identified in a system by a CPU ID (the processor `MPIDR` is used in the PSCI
interface) and an _affinity level_. A processing element (for example, a
CPU) is at level 0. If the CPUs in the system are described in a tree where the
node above a CPU is a logical grouping of CPUs that share some state, then
affinity level 1 is that group of CPUs (for example, a cluster), and affinity
level 2 is a group of clusters (for example, the system). The implementation
assumes that the affinity level 1 ID can be computed from the affinity level 0
ID (for example, a unique cluster ID can be computed from the CPU ID). The
current implementation computes this on the basis of the recommended use of
`MPIDR` affinity fields in the ARM Architecture Reference Manual.
concept of a _power domain_. A _power domain_ is a CPU or a logical group of
CPUs which share some state on which power management operations can be
performed as specified by [PSCI]. Each CPU in the system is assigned a cpu
index which is a unique number between `0` and `PLATFORM_CORE_COUNT - 1`.
The _power domains_ are arranged in a hierarchial tree structure and
each _power domain_ can be identified in a system by the cpu index of any CPU
that is part of that domain and a _power domain level_. A processing element
(for example, a CPU) is at level 0. If the _power domain_ node above a CPU is
a logical grouping of CPUs that share some state, then level 1 is that group
of CPUs (for example, a cluster), and level 2 is a group of clusters
(for example, the system). More details on the power domain topology and its
organization can be found in [Power Domain Topology Design].
BL3-1's platform initialization code exports a pointer to the platform-specific
power management operations required for the PSCI implementation to function
correctly. This information is populated in the `plat_pm_ops` structure. The
PSCI implementation calls members of the `plat_pm_ops` structure for performing
power management operations for each affinity instance. For example, the target
CPU is specified by its `MPIDR` in a PSCI `CPU_ON` call. The `affinst_on()`
handler (if present) is called for each affinity instance as the PSCI
implementation powers up each affinity level implemented in the `MPIDR` (for
example, CPU, cluster and system).
correctly. This information is populated in the `plat_psci_ops` structure. The
PSCI implementation calls members of the `plat_psci_ops` structure for performing
power management operations on the power domains. For example, the target
CPU is specified by its `MPIDR` in a PSCI `CPU_ON` call. The `pwr_domain_on()`
handler (if present) is called for the CPU power domain.
The `power-state` parameter of a PSCI `CPU_SUSPEND` call can be used to
describe composite power states specific to a platform. The PSCI implementation
defines a generic representation of the power-state parameter viz which is an
array of local power states where each index corresponds to a power domain
level. Each entry contains the local power state the power domain at that power
level could enter. It depends on the `validate_power_state()` handler to
convert the power-state parameter (possibly encoding a composite power state)
passed in a PSCI `CPU_SUSPEND` call to this representation.
The following functions must be implemented to initialize PSCI functionality in
the ARM Trusted Firmware.
### Function : plat_get_aff_count() [mandatory]
### Function : plat_get_target_pwr_state() [optional]
Argument : unsigned int, unsigned long
Return : unsigned int
Argument : unsigned int, const plat_local_state_t *, unsigned int
Return : plat_local_state_t
This function may execute with the MMU and data caches enabled if the platform
port does the necessary initializations in `bl31_plat_arch_setup()`. It is only
called by the primary CPU.
The PSCI generic code uses this function to let the platform participate in
state coordination during a power management operation. The function is passed
a pointer to an array of platform specific local power state `states` (second
argument) which contains the requested power state for each CPU at a particular
power domain level `lvl` (first argument) within the power domain. The function
is expected to traverse this array of upto `ncpus` (third argument) and return
a coordinated target power state by the comparing all the requested power
states. The target power state should not be deeper than any of the requested
power states.
This function is called by the PSCI initialization code to detect the system
topology. Its purpose is to return the number of affinity instances implemented
at a given `affinity level` (specified by the first argument) and a given
`MPIDR` (specified by the second argument). For example, on a dual-cluster
system where first cluster implements 2 CPUs and the second cluster implements 4
CPUs, a call to this function with an `MPIDR` corresponding to the first cluster
(`0x0`) and affinity level 0, would return 2. A call to this function with an
`MPIDR` corresponding to the second cluster (`0x100`) and affinity level 0,
would return 4.
A weak definition of this API is provided by default wherein it assumes
that the platform assigns a local state value in order of increasing depth
of the power state i.e. for two power states X & Y, if X < Y
then X represents a shallower power state than Y. As a result, the
coordinated target local power state for a power domain will be the minimum
of the requested local power state values.
### Function : plat_get_aff_state() [mandatory]
### Function : plat_get_power_domain_tree_desc() [mandatory]
Argument : unsigned int, unsigned long
Return : unsigned int
Argument : void
Return : const unsigned char *
This function may execute with the MMU and data caches enabled if the platform
port does the necessary initializations in `bl31_plat_arch_setup()`. It is only
called by the primary CPU.
This function is called by the PSCI initialization code. Its purpose is to
return the state of an affinity instance. The affinity instance is determined by
the affinity ID at a given `affinity level` (specified by the first argument)
and an `MPIDR` (specified by the second argument). The state can be one of
`PSCI_AFF_PRESENT` or `PSCI_AFF_ABSENT`. The latter state is used to cater for
system topologies where certain affinity instances are unimplemented. For
example, consider a platform that implements a single cluster with 4 CPUs and
another CPU implemented directly on the interconnect with the cluster. The
`MPIDR`s of the cluster would range from `0x0-0x3`. The `MPIDR` of the single
CPU would be 0x100 to indicate that it does not belong to cluster 0. Cluster 1
is missing but needs to be accounted for to reach this single CPU in the
topology tree. Hence it is marked as `PSCI_AFF_ABSENT`.
This function returns a pointer to the byte array containing the power domain
topology tree description. The format and method to construct this array are
described in [Power Domain Topology Design]. The BL3-1 PSCI initilization code
requires this array to be described by the platform, either statically or
dynamically, to initialize the power domain topology tree. In case the array
is populated dynamically, then plat_core_pos_by_mpidr() and
plat_my_core_pos() should also be implemented suitably so that the topology
tree description matches the CPU indices returned by these APIs. These APIs
together form the platform interface for the PSCI topology framework.
### Function : platform_setup_pm() [mandatory]
## Function : plat_setup_psci_ops() [mandatory]
Argument : const plat_pm_ops **
Argument : uintptr_t, const plat_psci_ops **
Return : int
This function may execute with the MMU and data caches enabled if the platform
port does the necessary initializations in `bl31_plat_arch_setup()`. It is only
called by the primary CPU.
This function is called by PSCI initialization code. Its purpose is to export
handler routines for platform-specific power management actions by populating
the passed pointer with a pointer to BL3-1's private `plat_pm_ops` structure.
This function is called by PSCI initialization code. Its purpose is to let
the platform layer know about the warm boot entrypoint through the
`sec_entrypoint` (first argument) and to export handler routines for
platform-specific psci power management actions by populating the passed
pointer with a pointer to BL3-1's private `plat_psci_ops` structure.
A description of each member of this structure is given below. Please refer to
the ARM FVP specific implementation of these handlers in
[plat/arm/board/fvp/fvp_pm.c] as an example. A platform port is expected to
implement these handlers if the corresponding PSCI operation is to be supported
and these handlers are expected to succeed if the return type is `void`.
[plat/arm/board/fvp/fvp_pm.c] as an example. For each PSCI function that the
platform wants to support, the associated operation or operations in this
structure must be provided and implemented (Refer section 4 of
[Firmware Design] for the PSCI API supported in Trusted Firmware). To disable
a PSCI function in a platform port, the operation should be removed from this
structure instead of providing an empty implementation.
#### plat_pm_ops.affinst_standby()
#### plat_psci_ops.cpu_standby()
Perform the platform-specific setup to enter the standby state indicated by the
passed argument. The generic code expects the handler to succeed.
Perform the platform-specific actions to enter the standby state for a cpu
indicated by the passed argument. This provides a fast path for CPU standby
wherein overheads of PSCI state management and lock acquistion is avoided.
For this handler to be invoked by the PSCI `CPU_SUSPEND` API implementation,
the suspend state type specified in the `power-state` parameter should be
STANDBY and the target power domain level specified should be the CPU. The
handler should put the CPU into a low power retention state (usually by
issuing a wfi instruction) and ensure that it can be woken up from that
state by a normal interrupt. The generic code expects the handler to succeed.
#### plat_pm_ops.affinst_on()
#### plat_psci_ops.pwr_domain_on()
Perform the platform specific setup to power on an affinity instance, specified
by the `MPIDR` (first argument) and `affinity level` (third argument). The
`state` (fourth argument) contains the current state of that affinity instance
(ON or OFF). This is useful to determine whether any action must be taken. For
example, while powering on a CPU, the cluster that contains this CPU might
already be in the ON state. The platform decides what actions must be taken to
transition from the current state to the target state (indicated by the power
management operation). The generic code expects the platform to return
E_SUCCESS on success or E_INTERN_FAIL for any failure.
Perform the platform specific actions to power on a CPU, specified
by the `MPIDR` (first argument). The generic code expects the platform to
return PSCI_E_SUCCESS on success or PSCI_E_INTERN_FAIL for any failure.
#### plat_pm_ops.affinst_off()
#### plat_psci_ops.pwr_domain_off()
Perform the platform specific setup to power off an affinity instance of the
calling CPU. It is called by the PSCI `CPU_OFF` API implementation.
Perform the platform specific actions to prepare to power off the calling CPU
and its higher parent power domain levels as indicated by the `target_state`
(first argument). It is called by the PSCI `CPU_OFF` API implementation.
The `affinity level` (first argument) and `state` (second argument) have
a similar meaning as described in the `affinst_on()` operation. They are
used to identify the affinity instance on which the call is made and its
current state. This gives the platform port an indication of the
state transition it must make to perform the requested action. For example, if
the calling CPU is the last powered on CPU in the cluster, after powering down
affinity level 0 (CPU), the platform port should power down affinity level 1
(the cluster) as well. The generic code expects the handler to succeed.
The `target_state` encodes the platform coordinated target local power states
for the CPU power domain and its parent power domain levels. The handler
needs to perform power management operation corresponding to the local state
at each power level.
#### plat_pm_ops.affinst_suspend()
For this handler, the local power state for the CPU power domain will be a
power down state where as it could be either power down, retention or run state
for the higher power domain levels depending on the result of state
coordination. The generic code expects the handler to succeed.
Perform the platform specific setup to power off an affinity instance of the
calling CPU. It is called by the PSCI `CPU_SUSPEND` API and `SYSTEM_SUSPEND`
API implementation
#### plat_psci_ops.pwr_domain_suspend()
The `affinity level` (second argument) and `state` (third argument) have a
similar meaning as described in the `affinst_on()` operation. They are used to
identify the affinity instance on which the call is made and its current state.
This gives the platform port an indication of the state transition it must
make to perform the requested action. For example, if the calling CPU is the
last powered on CPU in the cluster, after powering down affinity level 0 (CPU),
the platform port should power down affinity level 1 (the cluster) as well.
Perform the platform specific actions to prepare to suspend the calling
CPU and its higher parent power domain levels as indicated by the
`target_state` (first argument). It is called by the PSCI `CPU_SUSPEND`
API implementation.
The difference between turning an affinity instance off versus suspending it
is that in the former case, the affinity instance is expected to re-initialize
its state when its next powered on (see `affinst_on_finish()`). In the latter
case, the affinity instance is expected to save enough state so that it can
The `target_state` has a similar meaning as described in
the `pwr_domain_off()` operation. It encodes the platform coordinated
target local power states for the CPU power domain and its parent
power domain levels. The handler needs to perform power management operation
corresponding to the local state at each power level. The generic code
expects the handler to succeed.
The difference between turning a power domain off versus suspending it
is that in the former case, the power domain is expected to re-initialize
its state when it is next powered on (see `pwr_domain_on_finish()`). In the
latter case, the power domain is expected to save enough state so that it can
resume execution by restoring this state when its powered on (see
`affinst_suspend_finish()`).The generic code expects the handler to succeed.
`pwr_domain_suspend_finish()`).
#### plat_pm_ops.affinst_on_finish()
#### plat_psci_ops.pwr_domain_on_finish()
This function is called by the PSCI implementation after the calling CPU is
powered on and released from reset in response to an earlier PSCI `CPU_ON` call.
@ -1261,11 +1314,12 @@ It performs the platform-specific setup required to initialize enough state for
this CPU to enter the normal world and also provide secure runtime firmware
services.
The `affinity level` (first argument) and `state` (second argument) have a
similar meaning as described in the previous operations. The generic code
expects the handler to succeed.
The `target_state` (first argument) is the prior state of the power domains
immediately before the CPU was turned on. It indicates which power domains
above the CPU might require initialization due to having previously been in
low power states. The generic code expects the handler to succeed.
#### plat_pm_ops.affinst_suspend_finish()
#### plat_psci_ops.pwr_domain_suspend_finish()
This function is called by the PSCI implementation after the calling CPU is
powered on and released from reset in response to an asynchronous wakeup
@ -1274,40 +1328,36 @@ event, for example a timer interrupt that was programmed by the CPU during the
setup required to restore the saved state for this CPU to resume execution
in the normal world and also provide secure runtime firmware services.
The `affinity level` (first argument) and `state` (second argument) have a
similar meaning as described in the previous operations. The generic code
expects the platform to succeed.
The `target_state` (first argument) has a similar meaning as described in
the `pwr_domain_on_finish()` operation. The generic code expects the platform
to succeed.
#### plat_pm_ops.validate_power_state()
#### plat_psci_ops.validate_power_state()
This function is called by the PSCI implementation during the `CPU_SUSPEND`
call to validate the `power_state` parameter of the PSCI API. If the
`power_state` is known to be invalid, the platform must return
PSCI_E_INVALID_PARAMS as error, which is propagated back to the normal
world PSCI client.
call to validate the `power_state` parameter of the PSCI API and if valid,
populate it in `req_state` (second argument) array as power domain level
specific local states. If the `power_state` is invalid, the platform must
return PSCI_E_INVALID_PARAMS as error, which is propagated back to the
normal world PSCI client.
#### plat_pm_ops.validate_ns_entrypoint()
#### plat_psci_ops.validate_ns_entrypoint()
This function is called by the PSCI implementation during the `CPU_SUSPEND`,
`SYSTEM_SUSPEND` and `CPU_ON` calls to validate the non-secure `entry_point`
parameter passed by the normal world. If the `entry_point` is known to be
invalid, the platform must return PSCI_E_INVALID_PARAMS as error, which is
parameter passed by the normal world. If the `entry_point` is invalid,
the platform must return PSCI_E_INVALID_ADDRESS as error, which is
propagated back to the normal world PSCI client.
#### plat_pm_ops.get_sys_suspend_power_state()
#### plat_psci_ops.get_sys_suspend_power_state()
This function is called by the PSCI implementation during the `SYSTEM_SUSPEND`
call to return the `power_state` parameter. This allows the platform to encode
the appropriate State-ID field within the `power_state` parameter which can be
utilized in `affinst_suspend()` to suspend to system affinity level. The
`power_state` parameter should be in the same format as specified by the
PSCI specification for the CPU_SUSPEND API.
call to get the `req_state` parameter from platform which encodes the power
domain level specific local states to suspend to system affinity level. The
`req_state` will be utilized to do the PSCI state coordination and
`pwr_domain_suspend()` will be invoked with the coordinated target state to
enter system suspend.
BL3-1 platform initialization code must also detect the system topology and
the state of each affinity instance in the topology. This information is
critical for the PSCI runtime service to function correctly. More details are
provided in the description of the `plat_get_aff_count()` and
`plat_get_aff_state()` functions above.
3.4 Interrupt Management framework (in BL3-1)
----------------------------------------------
@ -1475,6 +1525,12 @@ register x0.
4. Build flags
---------------
* **ENABLE_PLAT_COMPAT**
All the platforms ports conforming to this API specification should define
the build flag `ENABLE_PLAT_COMPAT` to 0 as the compatibility layer should
be disabled. For more details on compatibility layer, refer
[Migration Guide].
There are some build flags which can be defined by the platform to control
inclusion or exclusion of certain BL stages from the FIP image. These flags
need to be defined in the platform makefile which will get included by the
@ -1589,6 +1645,9 @@ _Copyright (c) 2013-2015, ARM Limited and Contributors. All rights reserved._
[User Guide]: user-guide.md
[FreeBSD]: http://www.freebsd.org
[Firmware Design]: firmware-design.md
[Power Domain Topology Design]: psci-pd-tree.md
[PSCI]: http://infocenter.arm.com/help/topic/com.arm.doc.den0022c/DEN0022C_Power_State_Coordination_Interface.pdf
[Migration Guide]: platform-migration-guide.md
[plat/common/aarch64/platform_mp_stack.S]: ../plat/common/aarch64/platform_mp_stack.S
[plat/common/aarch64/platform_up_stack.S]: ../plat/common/aarch64/platform_up_stack.S

8
docs/user-guide.md
View File

@ -351,7 +351,12 @@ performed.
* `PROGRAMMABLE_RESET_ADDRESS`: This option indicates whether the reset
vector address can be programmed or is fixed on the platform. It can take
either 0 (fixed) or 1 (programmable). Default is 0.
either 0 (fixed) or 1 (programmable). Default is 0. If the platform has a
programmable reset address, it is expected that a CPU will start executing
code directly at the right address, both on a cold and warm reset. In this
case, there is no need to identify the entrypoint on boot and this has
implication for `plat_get_my_entrypoint()` platform porting interface.
(see the [Porting Guide] for details)
* `PSCI_EXTENDED_STATE_ID`: As per PSCI1.0 Specification, there are 2 formats
possible for the PSCI power-state parameter viz original and extended
@ -1092,4 +1097,5 @@ _Copyright (c) 2013-2015, ARM Limited and Contributors. All rights reserved._
[Juno Software Guide]: http://community.arm.com/docs/DOC-8396
[DS-5]: http://www.arm.com/products/tools/software-tools/ds-5/index.php
[mbedTLS Repository]: https://github.com/ARMmbed/mbedtls.git
[Porting Guide]: ./porting-guide.md
[Trusted Board Boot]: trusted-board-boot.md

2
include/common/el3_common_macros.S
View File

@ -181,7 +181,7 @@
* -------------------------------------------------------------
*/
bl plat_is_my_cpu_primary
cbnz x0, do_primary_cold_boot
cbnz w0, do_primary_cold_boot
/* This is a cold boot on a secondary CPU */
bl plat_secondary_cold_boot_setup

10
plat/arm/board/fvp/aarch64/fvp_helpers.S
View File

@ -154,11 +154,17 @@ _panic:
b _panic
endfunc plat_get_my_entrypoint
/* -----------------------------------------------------
* unsigned int plat_is_my_cpu_primary (void);
*
* Find out whether the current cpu is the primary
* cpu.
* -----------------------------------------------------
*/
func plat_is_my_cpu_primary
mrs x0, mpidr_el1
and x0, x0, #(MPIDR_CLUSTER_MASK | MPIDR_CPU_MASK)
cmp x0, #FVP_PRIMARY_CPU
cset x0, eq
cset w0, eq
ret
endfunc plat_is_my_cpu_primary

4
plat/arm/css/common/aarch64/css_helpers.S
View File

@ -77,7 +77,7 @@ endfunc plat_get_my_entrypoint
* Function to calculate the core position by
* swapping the cluster order. This is necessary in order to
* match the format of the boot information passed by the SCP
* and read in platform_is_primary_cpu below.
* and read in plat_is_my_cpu_primary below.
* -----------------------------------------------------------
*/
func plat_arm_calc_core_pos
@ -102,6 +102,6 @@ func plat_is_my_cpu_primary
ldr x1, [x1]
ubfx x1, x1, #PRIMARY_CPU_SHIFT, #PRIMARY_CPU_BIT_WIDTH
cmp x0, x1
cset x0, eq
cset w0, eq
ret x9
endfunc plat_is_my_cpu_primary