.. _power_management_api:

Power Management
################

Zephyr RTOS power management subsystem provides several means for a system
integrator to implement power management support that can take full
advantage of the power saving features of SOCs.


Terminology
***********

:dfn:`SOC interface`
   This is a general term for the components that have knowledge of the
   SOC and provide interfaces to the hardware features. It will abstract
   the SOC specific implementations to the applications and the OS.

:dfn:`Idle Thread`
   A system thread that runs when there are no other threads ready to run.

:dfn:`Power gating`
   Power gating reduces power consumption by shutting off current to blocks of
   the integrated circuit that are not in use.

:dfn:`Power State`
   SOC Power State describes processor and device power states implemented at
   the SOC level. Power states are represented by :c:enum:`pm_state` and each
   one has a different meaning.

Overview
********

The interfaces and APIs provided by the power management subsystem
are designed to be architecture and SOC independent. This enables power
management implementations to be easily adapted to different SOCs and
architectures.

The architecture and SOC independence is achieved by separating the core
infrastructure and the SOC specific implementations. The SOC specific
implementations are abstracted to the application and the OS using hardware
abstraction layers.

The power management features are classified into the following categories.

* Tickless Idle
* System Power Management
* Device Power Management

Tickless Idle
*************

This is the name used to identify the event-based idling mechanism of the
Zephyr RTOS kernel scheduler. The kernel scheduler can run in two modes. During
normal operation, when at least one thread is active, it sets up the system
timer in periodic mode and runs in an interval-based scheduling mode. The
interval-based mode allows it to time slice between threads. Many times, the
threads would be waiting on semaphores, timeouts or for events. When there
are no threads running, it is inefficient for the kernel scheduler to run
in interval-based mode. This is because, in this mode the timer would trigger
an interrupt at fixed intervals causing the scheduler to be invoked at each
interval. The scheduler checks if any thread is ready to run. If no thread
is ready to run then it is a waste of power because of the unnecessary CPU
processing. This is avoided by the kernel switching to event-based idling
mode whenever there is no thread ready to run.

The kernel holds an ordered list of thread timeouts in the system. These are
the amount of time each thread has requested to wait. When the last active
thread goes to wait, the idle thread is scheduled. The idle thread programs
the timer to one-shot mode and programs the count to the earliest timeout
from the ordered thread timeout list. When the timer expires, a timer event
is generated. The ISR of this event will invoke the scheduler, which would
schedule the thread associated with the timeout. Before scheduling the
thread, the scheduler would switch the timer again to periodic mode. This
method saves power because the CPU is removed from the wait only when there
is a thread ready to run or if an external event occurred.

System Power Management
***********************

The kernel enters the idle state when it has nothing to schedule. If enabled via
the :option:`CONFIG_PM` Kconfig option, the Power Management
Subsystem can put an idle system in one of the supported power states, based
on the selected power management policy and the duration of the idle time
allotted by the kernel.

It is an application responsibility to set up a wake up event. A wake up event
will typically be an interrupt triggered by one of the SoC peripheral modules
such as a SysTick, RTC, counter, or GPIO. Depending on the power mode entered,
only some SoC peripheral modules may be active and can be used as a wake up
source.

Enabling system power management compels the Zephyr kernel scheduler to work in
tickless idle mode (see :option:`CONFIG_TICKLESS_IDLE`).

Power States
============

The power management subsystem contains a set of states based on
power consumption and context retention.

The list of available power states is defined by :c:enum:`pm_state`. In
general power states with higher indexes will offer greater power savings and
have higher wake latencies. Following is a thorough list of available states:

.. doxygenenumvalue:: PM_STATE_ACTIVE
   :project: Zephyr

.. doxygenenumvalue:: PM_STATE_RUNTIME_IDLE
   :project: Zephyr

.. doxygenenumvalue:: PM_STATE_SUSPEND_TO_IDLE
   :project: Zephyr

.. doxygenenumvalue:: PM_STATE_STANDBY
   :project: Zephyr

.. doxygenenumvalue:: PM_STATE_SUSPEND_TO_RAM
   :project: Zephyr

.. doxygenenumvalue:: PM_STATE_SUSPEND_TO_DISK
   :project: Zephyr

.. doxygenenumvalue:: PM_STATE_SOFT_OFF
   :project: Zephyr

Power Management Policies
=========================

The power management subsystem supports the following power management policies:

* Residency
* Application
* Dummy

Residency
---------

The power management system enters the power state which offers the highest
power savings, and with a minimum residency value (defined by the respective
Kconfig option) less than or equal to the scheduled system idle time duration.

Application
-----------

The power management policy is defined by the application which has to implement
the following function.

.. code-block:: c

   struct pm_state_info pm_policy_next_state(int32_t ticks);

Dummy
-----

This policy returns the next supported power state in a loop. It is used mainly
for testing purposes.

Device Power Management Infrastructure
**************************************

The device power management infrastructure consists of interfaces to the
Zephyr RTOS device model. These APIs send control commands to the device driver
to update its power state or to get its current power state.

Zephyr RTOS supports two methods of doing device power management.

* Distributed method
* Central method

Distributed method
==================

In this method, the application or any component that deals with devices directly
and has the best knowledge of their use does the device power management. This
saves power if some devices that are not in use can be turned off or put
in power saving mode. This method allows saving power even when the CPU is
active. The components that use the devices need to be power aware and should
be able to make decisions related to managing device power. In this method, the
SOC interface can enter CPU or SOC power states quickly when
:code:`sys_suspend()` gets called. This is because it does not need to
spend time doing device power management if the devices are already put in
the appropriate power state by the application or component managing the
devices.

Central method
==============

In this method device power management is mostly done inside
:code:`sys_suspend()` along with entering a CPU or SOC power state.

If a decision to enter deep sleep is made, the implementation would enter it
only after checking if the devices are not in the middle of a hardware
transaction that cannot be interrupted. This method can be used in
implementations where the applications and components using devices are not
expected to be power aware and do not implement device power management.

.. image:: central_method.svg
   :align: center

This method can also be used to emulate a hardware feature supported by some
SOCs which cause automatic entry to deep sleep when all devices are idle.
Refer to `Busy Status Indication`_ to see how to indicate whether a device is busy
or idle.

Device Power Management States
==============================
The Zephyr RTOS power management subsystem defines four device states.
These states are classified based on the degree of device context that gets lost
in those states, kind of operations done to save power, and the impact on the
device behavior due to the state transition. Device context includes device
registers, clocks, memory etc.

The four device power states:

:code:`DEVICE_PM_ACTIVE_STATE`

   Normal operation of the device. All device context is retained.

:code:`DEVICE_PM_LOW_POWER_STATE`

   Device context is preserved by the HW and need not be restored by the driver.

:code:`DEVICE_PM_SUSPEND_STATE`

   Most device context is lost by the hardware. Device drivers must save and
   restore or reinitialize any context lost by the hardware.

:code:`DEVICE_PM_OFF_STATE`

   Power has been fully removed from the device. The device context is lost
   when this state is entered. Need to reinitialize the device when powering
   it back on.

Device Power Management Operations
==================================

Zephyr RTOS power management subsystem provides a control function interface
to device drivers to indicate power management operations to perform.
The supported PM control commands are:

* DEVICE_PM_SET_POWER_STATE
* DEVICE_PM_GET_POWER_STATE

Each device driver defines:

* The device's supported power states.
* The device's supported transitions between power states.
* The device's necessary operations to handle the transition between power states.

The following are some examples of operations that the device driver may perform
in transition between power states:

* Save/Restore device states.
* Gate/Un-gate clocks.
* Gate/Un-gate power.
* Mask/Un-mask interrupts.

Device Model with Power Management Support
==========================================

Drivers initialize the devices using macros. See :ref:`device_model_api` for
details on how these macros are used. Use the DEVICE_DEFINE macro to initialize
drivers providing power management support via the PM control function.
One of the macro parameters is the pointer to the device_pm_control handler function.

Default Initializer Function
----------------------------

.. code-block:: c

   int device_pm_control_nop(const struct device *unused_device, uint32_t unused_ctrl_command, void *unused_context);


If the driver doesn't implement any power control operations, the driver can
initialize the corresponding pointer with this default nop function. This
default nop function does nothing and should be used instead of
implementing a dummy function to avoid wasting code memory in the driver.


Device Power Management API
===========================

The SOC interface and application use these APIs to perform power management
operations on the devices.

Get Device List
---------------

.. code-block:: c

   size_t z_device_get_all_static(struct device const **device_list);

The Zephyr RTOS kernel internally maintains a list of all devices in the system.
The SOC interface uses this API to get the device list. The SOC interface can use the list to
identify the devices on which to execute power management operations.

.. note::

   Ensure that the SOC interface does not alter the original list. Since the kernel
   uses the original list, it must remain unchanged.

Device Set Power State
----------------------

.. code-block:: c

   int device_set_power_state(const struct device *device, uint32_t device_power_state, device_pm_cb cb, void *arg);

Calls the :c:func:`device_pm_control()` handler function implemented by the
device driver with DEVICE_PM_SET_POWER_STATE command.

Device Get Power State
----------------------

.. code-block:: c

   int device_get_power_state(const struct device *device, uint32_t * device_power_state);

Calls the :c:func:`device_pm_control()` handler function implemented by the
device driver with DEVICE_PM_GET_POWER_STATE command.

Busy Status Indication
======================

The SOC interface executes some power policies that can turn off power to devices,
causing them to lose their state. If the devices are in the middle of some
hardware transaction, like writing to flash memory when the power is turned
off, then such transactions would be left in an inconsistent state. This
infrastructure guards such transactions by indicating to the SOC interface that
the device is in the middle of a hardware transaction.

When the :code:`sys_suspend()` is called, the SOC interface checks if any device
is busy. The SOC interface can then decide to execute a power management scheme other than deep sleep or
to defer power management operations until the next call of
:code:`sys_suspend()`.

An alternative to using the busy status mechanism is to use the
`distributed method`_ of device power management. In such a method where the
device power management is handled in a distributed manner rather than centrally in
:code:`sys_suspend()`, the decision to enter deep sleep can be made based
on whether all devices are already turned off.

This feature can be also used to emulate a hardware feature found in some SOCs
that causes the system to automatically enter deep sleep when all devices are idle.
In such an usage, the busy status can be set by default and cleared as each
device becomes idle. When :code:`sys_suspend()` is called, deep sleep can
be entered if no device is found to be busy.

Here are the APIs used to set, clear, and check the busy status of devices.

Indicate Busy Status API
------------------------

.. code-block:: c

   void device_busy_set(const struct device *busy_dev);

Sets a bit corresponding to the device, in a data structure maintained by the
kernel, to indicate whether or not it is in the middle of a transaction.

Clear Busy Status API
---------------------

.. code-block:: c

   void device_busy_clear(const struct device *busy_dev);

Clears the bit corresponding to the device in a data structure
maintained by the kernel to indicate that the device is not in the middle of
a transaction.

Check Busy Status of Single Device API
--------------------------------------

.. code-block:: c

   int device_busy_check(const struct device *chk_dev);

Checks whether a device is busy. The API returns 0 if the device
is not busy.

Check Busy Status of All Devices API
------------------------------------

.. code-block:: c

   int device_any_busy_check(void);

Checks if any device is busy. The API returns 0 if no device in the system is busy.

Device Idle Power Management
****************************


The Device Idle Power Management framework is a Active Power
Management mechanism which reduces the overall system Power consumtion
by suspending the devices which are idle or not being used while the
System is active or running.

The framework uses device_set_power_state() API set the
device power state accordingly based on the usage count.

The interfaces and APIs provided by the Device Idle PM are
designed to be generic and architecture independent.

Device Idle Power Management API
================================

The Device Drivers use these APIs to perform device idle power management
operations on the devices.

Enable Device Idle Power Management of a Device API
---------------------------------------------------

.. code-block:: c

   void device_pm_enable(const struct device *dev);

Enbles Idle Power Management of the device.

Disable Device Idle Power Management of a Device API
----------------------------------------------------

.. code-block:: c

   void device_pm_disable(const struct device *dev);

Disables Idle Power Management of the device.

Resume Device asynchronously API
--------------------------------

.. code-block:: c

   int device_pm_get(const struct device *dev);

Marks the device as being used. This API will asynchronously
bring the device to resume state. The API returns 0 on success.

Resume Device synchronously API
-------------------------------

.. code-block:: c

   int device_pm_get_sync(const struct device *dev);

Marks the device as being used. It will bring up or resume
the device if it is in suspended state based on the device
usage count. This call is blocked until the device PM state
is changed to active. The API returns 0 on success.

Suspend Device asynchronously API
---------------------------------

.. code-block:: c

   int device_pm_put(const struct device *dev);

Marks the device as being released. This API asynchronously put
the device to suspend state if not already in suspend state.
The API returns 0 on success.

Suspend Device synchronously API
--------------------------------

.. code-block:: c

   int device_pm_put_sync(const struct device *dev);

Marks the device as being released. It will put the device to
suspended state if is is in active state based on the device
usage count. This call is blocked until the device PM state
is changed to resume. The API returns 0 on success. This
call is blocked until the device is suspended.


Power Management Configuration Flags
************************************

The Power Management features can be individually enabled and disabled using
the following configuration flags.

:option:`CONFIG_PM`

   This flag enables the power management subsystem.

:option:`CONFIG_TICKLESS_IDLE`

   This flag enables the tickless idle power saving feature.

:option:`CONFIG_PM_DEVICE`

   This flag is enabled if the SOC interface and the devices support device power
   management.

:code:`CONFIG_PM_DEVICE_IDLE`

   This flag enables the Device Idle Power Management.

API Reference
*************

Power Management Hook Interface
===============================

.. doxygengroup:: power_management_hook_interface
   :project: Zephyr

System Power Management APIs
============================

.. doxygengroup:: system_power_management_api
   :project: Zephyr

Device Power Management APIs
============================

.. doxygengroup:: device_power_management_api
   :project: Zephyr