Device Power Management Data Types

struct dev_pm_ops

device PM callbacks.

Definition

struct dev_pm_ops {
  int (* prepare) (struct device *dev);
  void (* complete) (struct device *dev);
  int (* suspend) (struct device *dev);
  int (* resume) (struct device *dev);
  int (* freeze) (struct device *dev);
  int (* thaw) (struct device *dev);
  int (* poweroff) (struct device *dev);
  int (* restore) (struct device *dev);
  int (* suspend_late) (struct device *dev);
  int (* resume_early) (struct device *dev);
  int (* freeze_late) (struct device *dev);
  int (* thaw_early) (struct device *dev);
  int (* poweroff_late) (struct device *dev);
  int (* restore_early) (struct device *dev);
  int (* suspend_noirq) (struct device *dev);
  int (* resume_noirq) (struct device *dev);
  int (* freeze_noirq) (struct device *dev);
  int (* thaw_noirq) (struct device *dev);
  int (* poweroff_noirq) (struct device *dev);
  int (* restore_noirq) (struct device *dev);
  int (* runtime_suspend) (struct device *dev);
  int (* runtime_resume) (struct device *dev);
  int (* runtime_idle) (struct device *dev);
};

Members

prepare
The principal role of this callback is to prevent new children of the device from being registered after it has returned (the driver’s subsystem and generally the rest of the kernel is supposed to prevent new calls to the probe method from being made too once prepare() has succeeded). If prepare() detects a situation it cannot handle (e.g. registration of a child already in progress), it may return -EAGAIN, so that the PM core can execute it once again (e.g. after a new child has been registered) to recover from the race condition. This method is executed for all kinds of suspend transitions and is followed by one of the suspend callbacks: suspend(), freeze(), or poweroff(). If the transition is a suspend to memory or standby (that is, not related to hibernation), the return value of prepare() may be used to indicate to the PM core to leave the device in runtime suspend if applicable. Namely, if prepare() returns a positive number, the PM core will understand that as a declaration that the device appears to be runtime-suspended and it may be left in that state during the entire transition and during the subsequent resume if all of its descendants are left in runtime suspend too. If that happens, complete() will be executed directly after prepare() and it must ensure the proper functioning of the device after the system resume. The PM core executes subsystem-level prepare() for all devices before starting to invoke suspend callbacks for any of them, so generally devices may be assumed to be functional or to respond to runtime resume requests while prepare() is being executed. However, device drivers may NOT assume anything about the availability of user space at that time and it is NOT valid to request firmware from within prepare() (it’s too late to do that). It also is NOT valid to allocate substantial amounts of memory from prepare() in the GFP_KERNEL mode. [To work around these limitations, drivers may register suspend and hibernation notifiers to be executed before the freezing of tasks.]
complete
Undo the changes made by prepare(). This method is executed for all kinds of resume transitions, following one of the resume callbacks: resume(), thaw(), restore(). Also called if the state transition fails before the driver’s suspend callback: suspend(), freeze() or poweroff(), can be executed (e.g. if the suspend callback fails for one of the other devices that the PM core has unsuccessfully attempted to suspend earlier). The PM core executes subsystem-level complete() after it has executed the appropriate resume callbacks for all devices. If the corresponding prepare() at the beginning of the suspend transition returned a positive number and the device was left in runtime suspend (without executing any suspend and resume callbacks for it), complete() will be the only callback executed for the device during resume. In that case, complete() must be prepared to do whatever is necessary to ensure the proper functioning of the device after the system resume. To this end, complete() can check the power.direct_complete flag of the device to learn whether (unset) or not (set) the previous suspend and resume callbacks have been executed for it.
suspend
Executed before putting the system into a sleep state in which the contents of main memory are preserved. The exact action to perform depends on the device’s subsystem (PM domain, device type, class or bus type), but generally the device must be quiescent after subsystem-level suspend() has returned, so that it doesn’t do any I/O or DMA. Subsystem-level suspend() is executed for all devices after invoking subsystem-level prepare() for all of them.
resume
Executed after waking the system up from a sleep state in which the contents of main memory were preserved. The exact action to perform depends on the device’s subsystem, but generally the driver is expected to start working again, responding to hardware events and software requests (the device itself may be left in a low-power state, waiting for a runtime resume to occur). The state of the device at the time its driver’s resume() callback is run depends on the platform and subsystem the device belongs to. On most platforms, there are no restrictions on availability of resources like clocks during resume(). Subsystem-level resume() is executed for all devices after invoking subsystem-level resume_noirq() for all of them.
freeze
Hibernation-specific, executed before creating a hibernation image. Analogous to suspend(), but it should not enable the device to signal wakeup events or change its power state. The majority of subsystems (with the notable exception of the PCI bus type) expect the driver-level freeze() to save the device settings in memory to be used by restore() during the subsequent resume from hibernation. Subsystem-level freeze() is executed for all devices after invoking subsystem-level prepare() for all of them.
thaw
Hibernation-specific, executed after creating a hibernation image OR if the creation of an image has failed. Also executed after a failing attempt to restore the contents of main memory from such an image. Undo the changes made by the preceding freeze(), so the device can be operated in the same way as immediately before the call to freeze(). Subsystem-level thaw() is executed for all devices after invoking subsystem-level thaw_noirq() for all of them. It also may be executed directly after freeze() in case of a transition error.
poweroff
Hibernation-specific, executed after saving a hibernation image. Analogous to suspend(), but it need not save the device’s settings in memory. Subsystem-level poweroff() is executed for all devices after invoking subsystem-level prepare() for all of them.
restore
Hibernation-specific, executed after restoring the contents of main memory from a hibernation image, analogous to resume().
suspend_late
Continue operations started by suspend(). For a number of devices suspend_late() may point to the same callback routine as the runtime suspend callback.
resume_early
Prepare to execute resume(). For a number of devices resume_early() may point to the same callback routine as the runtime resume callback.
freeze_late
Continue operations started by freeze(). Analogous to suspend_late(), but it should not enable the device to signal wakeup events or change its power state.
thaw_early
Prepare to execute thaw(). Undo the changes made by the preceding freeze_late().
poweroff_late
Continue operations started by poweroff(). Analogous to suspend_late(), but it need not save the device’s settings in memory.
restore_early
Prepare to execute restore(), analogous to resume_early().
suspend_noirq
Complete the actions started by suspend(). Carry out any additional operations required for suspending the device that might be racing with its driver’s interrupt handler, which is guaranteed not to run while suspend_noirq() is being executed. It generally is expected that the device will be in a low-power state (appropriate for the target system sleep state) after subsystem-level suspend_noirq() has returned successfully. If the device can generate system wakeup signals and is enabled to wake up the system, it should be configured to do so at that time. However, depending on the platform and device’s subsystem, suspend() or suspend_late() may be allowed to put the device into the low-power state and configure it to generate wakeup signals, in which case it generally is not necessary to define suspend_noirq().
resume_noirq
Prepare for the execution of resume() by carrying out any operations required for resuming the device that might be racing with its driver’s interrupt handler, which is guaranteed not to run while resume_noirq() is being executed.
freeze_noirq
Complete the actions started by freeze(). Carry out any additional operations required for freezing the device that might be racing with its driver’s interrupt handler, which is guaranteed not to run while freeze_noirq() is being executed. The power state of the device should not be changed by either freeze(), or freeze_late(), or freeze_noirq() and it should not be configured to signal system wakeup by any of these callbacks.
thaw_noirq
Prepare for the execution of thaw() by carrying out any operations required for thawing the device that might be racing with its driver’s interrupt handler, which is guaranteed not to run while thaw_noirq() is being executed.
poweroff_noirq
Complete the actions started by poweroff(). Analogous to suspend_noirq(), but it need not save the device’s settings in memory.
restore_noirq
Prepare for the execution of restore() by carrying out any operations required for thawing the device that might be racing with its driver’s interrupt handler, which is guaranteed not to run while restore_noirq() is being executed. Analogous to resume_noirq().
runtime_suspend
Prepare the device for a condition in which it won’t be able to communicate with the CPU(s) and RAM due to power management. This need not mean that the device should be put into a low-power state. For example, if the device is behind a link which is about to be turned off, the device may remain at full power. If the device does go to low power and is capable of generating runtime wakeup events, remote wakeup (i.e., a hardware mechanism allowing the device to request a change of its power state via an interrupt) should be enabled for it.
runtime_resume
Put the device into the fully active state in response to a wakeup event generated by hardware or at the request of software. If necessary, put the device into the full-power state and restore its registers, so that it is fully operational.
runtime_idle
Device appears to be inactive and it might be put into a low-power state if all of the necessary conditions are satisfied. Check these conditions, and return 0 if it’s appropriate to let the PM core queue a suspend request for the device.

Description

Several device power state transitions are externally visible, affecting the state of pending I/O queues and (for drivers that touch hardware) interrupts, wakeups, DMA, and other hardware state. There may also be internal transitions to various low-power modes which are transparent to the rest of the driver stack (such as a driver that’s ON gating off clocks which are not in active use).

The externally visible transitions are handled with the help of callbacks included in this structure in such a way that, typically, two levels of callbacks are involved. First, the PM core executes callbacks provided by PM domains, device types, classes and bus types. They are the subsystem-level callbacks expected to execute callbacks provided by device drivers, although they may choose not to do that. If the driver callbacks are executed, they have to collaborate with the subsystem-level callbacks to achieve the goals appropriate for the given system transition, given transition phase and the subsystem the device belongs to.

All of the above callbacks, except for complete(), return error codes. However, the error codes returned by resume(), thaw(), restore(), resume_noirq(), thaw_noirq(), and restore_noirq(), do not cause the PM core to abort the resume transition during which they are returned. The error codes returned in those cases are only printed to the system logs for debugging purposes. Still, it is recommended that drivers only return error codes from their resume methods in case of an unrecoverable failure (i.e. when the device being handled refuses to resume and becomes unusable) to allow the PM core to be modified in the future, so that it can avoid attempting to handle devices that failed to resume and their children.

It is allowed to unregister devices while the above callbacks are being executed. However, a callback routine MUST NOT try to unregister the device it was called for, although it may unregister children of that device (for example, if it detects that a child was unplugged while the system was asleep).

There also are callbacks related to runtime power management of devices. Again, as a rule these callbacks are executed by the PM core for subsystems (PM domains, device types, classes and bus types) and the subsystem-level callbacks are expected to invoke the driver callbacks. Moreover, the exact actions to be performed by a device driver’s callbacks generally depend on the platform and subsystem the device belongs to.

Refer to Documentation/power/runtime_pm.txt for more information about the role of the runtime_suspend(), runtime_resume() and runtime_idle() callbacks in device runtime power management.

struct dev_pm_domain

power management domain representation.

Definition

struct dev_pm_domain {
  struct dev_pm_ops ops;
  void (* detach) (struct device *dev, bool power_off);
  int (* activate) (struct device *dev);
  void (* sync) (struct device *dev);
  void (* dismiss) (struct device *dev);
};

Members

ops
Power management operations associated with this domain.
detach
Called when removing a device from the domain.
activate
Called before executing probe routines for bus types and drivers.
sync
Called after successful driver probe.
dismiss
Called after unsuccessful driver probe and after driver removal.

Description

Power domains provide callbacks that are executed during system suspend, hibernation, system resume and during runtime PM transitions instead of subsystem-level and driver-level callbacks.