| .. _pm-system: |
| |
| System Power Management |
| ####################### |
| |
| Introduction |
| ************ |
| |
| The kernel enters the idle state when it has nothing to schedule. |
| Enabling :kconfig:option:`CONFIG_PM` allows the kernel to call upon the |
| power management subsystem to put an idle system into one of the supported power states. |
| The kernel requests an amount of time it would like to suspend, then the PM subsystem decides |
| the appropriate power state to transition to based on the configured power management policy. |
| |
| It is the application's responsibility to set up a wake-up event. |
| A wake-up event will typically be an interrupt triggered by an SoC peripheral module. |
| Examples include a SysTick, RTC, counter, or GPIO. |
| Keep in mind that depending on the SoC and the power mode in question, |
| not all peripherals may be active, and therefore |
| some wake-up sources may not be usable in all power modes. |
| |
| The following diagram describes system power management: |
| |
| .. graphviz:: |
| :caption: System power management |
| |
| digraph G { |
| compound=true |
| node [height=1.2 style=rounded] |
| |
| lock [label="Lock interruptions"] |
| config_pm [label="CONFIG_PM" shape=diamond style="rounded,dashed"] |
| forced_state [label="state forced ?", shape=diamond style="rounded,dashed"] |
| config_system_managed_device_pm [label="CONFIG_PM_DEVICE" shape=diamond style="rounded,dashed"] |
| config_system_managed_device_pm2 [label="CONFIG_PM_DEVICE" shape=diamond style="rounded,dashed"] |
| pm_policy [label="Check policy manager\nfor a power state "] |
| pm_suspend_devices [label="Suspend\ndevices"] |
| pm_resume_devices [label="Resume\ndevices"] |
| pm_state_set [label="Change power state\n(SoC API)" style="rounded,bold"] |
| pm_system_resume [label="Finish wake-up\n(SoC API)\n(restore interruptions)" style="rounded,bold"] |
| k_cpu_idle [label="k_cpu_idle()"] |
| |
| subgraph cluster_0 { |
| style=invisible; |
| lock -> config_pm |
| } |
| |
| subgraph cluster_1 { |
| style=dashed |
| label = "pm_system_suspend()" |
| |
| forced_state -> config_system_managed_device_pm [label="yes"] |
| forced_state -> pm_policy [label="no"] |
| pm_policy -> config_system_managed_device_pm |
| config_system_managed_device_pm -> pm_state_set:e [label="no"] |
| config_system_managed_device_pm -> pm_suspend_devices [label="yes"] |
| pm_suspend_devices -> pm_state_set |
| pm_state_set -> config_system_managed_device_pm2 |
| config_system_managed_device_pm2 -> pm_resume_devices [label="yes"] |
| config_system_managed_device_pm2 -> pm_system_resume [label="no"] |
| pm_resume_devices -> pm_system_resume |
| } |
| |
| {rankdir=LR k_cpu_idle; forced_state} |
| pm_policy -> k_cpu_idle [label="PM_STATE_ACTIVE\n(no power state meet requirements)"] |
| config_pm -> k_cpu_idle [label="no"] |
| config_pm -> forced_state [label="yes" lhead="cluster_1"] |
| pm_system_resume:e -> lock:e [constraint=false lhed="cluster_0"] |
| } |
| |
| |
| Power States |
| ============ |
| |
| The power management subsystem defines a set of states described by the |
| power consumption and context retention associated with each of them. |
| |
| The set of power states is defined by :c:enum:`pm_state`. In general, lower power states |
| (higher index in the enum) will offer greater power savings and have higher wake latencies. |
| |
| Power Management Policies |
| ========================= |
| |
| The power management subsystem supports the following power management policies: |
| |
| * Residency based |
| * Application defined |
| |
| The policy manager is the component of the power management subsystem responsible |
| for deciding which power state the system should transition to. |
| The policy manager can only choose between states that have been defined for the platform. |
| Other constraints placed upon the decision may include locks disallowing certain power states, |
| or various kinds of minimum and maximum latency values, depending on the policy. |
| |
| More details on the states definition can be found in the |
| :dtcompatible:`zephyr,power-state` binding documentation. |
| |
| Residency |
| --------- |
| |
| Under the residency policy, the system will enter the power state which offers the highest |
| power savings, with the constraint that the sum of the minimum residency value (see |
| :dtcompatible:`zephyr,power-state`) and the latency to exit the mode must be |
| less than or equal to the system idle time duration scheduled by the kernel. |
| |
| Thus the core logic can be summarized with the following expression: |
| |
| .. code-block:: c |
| |
| if (time_to_next_scheduled_event >= (state.min_residency_us + state.exit_latency)) { |
| return state |
| } |
| |
| Application |
| ----------- |
| |
| The application defines the power management policy by implementing the |
| :c:func:`pm_policy_next_state` function. In this policy, the application is free |
| to decide which power state the system should transition to based on the |
| remaining time until the next scheduled timeout. |
| |
| An example of an application that defines its own policy can be found in |
| :zephyr_file:`tests/subsys/pm/power_mgmt/`. |
| |
| .. _pm-policy-power-states: |
| |
| Policy and Power States |
| ------------------------ |
| |
| The power management subsystem allows different Zephyr components and |
| applications to configure the policy manager to block the system from transitioning |
| into certain power states. This can be used by devices when executing tasks in |
| background to prevent the system from going to a specific state where it would |
| lose context. See :c:func:`pm_policy_state_lock_get`. |
| |
| Examples |
| ======== |
| |
| Some helpful examples showing different power management features: |
| |
| * :zephyr_file:`samples/boards/st/power_mgmt/blinky/` |
| * :zephyr_file:`samples/boards/espressif/deep_sleep/` |
| * :zephyr_file:`samples/subsys/pm/device_pm/` |
| * :zephyr_file:`tests/subsys/pm/power_mgmt/` |
| * :zephyr_file:`tests/subsys/pm/power_mgmt_soc/` |
| * :zephyr_file:`tests/subsys/pm/power_states_api/` |