| ==================================== |
| System Suspend and Device Interrupts |
| ==================================== |
| |
| Copyright (C) 2014 Intel Corp. |
| Author: Rafael J. Wysocki <rafael.j.wysocki@intel.com> |
| |
| |
| Suspending and Resuming Device IRQs |
| ----------------------------------- |
| |
| Device interrupt request lines (IRQs) are generally disabled during system |
| suspend after the "late" phase of suspending devices (that is, after all of the |
| ->prepare, ->suspend and ->suspend_late callbacks have been executed for all |
| devices). That is done by suspend_device_irqs(). |
| |
| The rationale for doing so is that after the "late" phase of device suspend |
| there is no legitimate reason why any interrupts from suspended devices should |
| trigger and if any devices have not been suspended properly yet, it is better to |
| block interrupts from them anyway. Also, in the past we had problems with |
| interrupt handlers for shared IRQs that device drivers implementing them were |
| not prepared for interrupts triggering after their devices had been suspended. |
| In some cases they would attempt to access, for example, memory address spaces |
| of suspended devices and cause unpredictable behavior to ensue as a result. |
| Unfortunately, such problems are very difficult to debug and the introduction |
| of suspend_device_irqs(), along with the "noirq" phase of device suspend and |
| resume, was the only practical way to mitigate them. |
| |
| Device IRQs are re-enabled during system resume, right before the "early" phase |
| of resuming devices (that is, before starting to execute ->resume_early |
| callbacks for devices). The function doing that is resume_device_irqs(). |
| |
| |
| The IRQF_NO_SUSPEND Flag |
| ------------------------ |
| |
| There are interrupts that can legitimately trigger during the entire system |
| suspend-resume cycle, including the "noirq" phases of suspending and resuming |
| devices as well as during the time when nonboot CPUs are taken offline and |
| brought back online. That applies to timer interrupts in the first place, |
| but also to IPIs and to some other special-purpose interrupts. |
| |
| The IRQF_NO_SUSPEND flag is used to indicate that to the IRQ subsystem when |
| requesting a special-purpose interrupt. It causes suspend_device_irqs() to |
| leave the corresponding IRQ enabled so as to allow the interrupt to work as |
| expected during the suspend-resume cycle, but does not guarantee that the |
| interrupt will wake the system from a suspended state -- for such cases it is |
| necessary to use enable_irq_wake(). |
| |
| Note that the IRQF_NO_SUSPEND flag affects the entire IRQ and not just one |
| user of it. Thus, if the IRQ is shared, all of the interrupt handlers installed |
| for it will be executed as usual after suspend_device_irqs(), even if the |
| IRQF_NO_SUSPEND flag was not passed to request_irq() (or equivalent) by some of |
| the IRQ's users. For this reason, using IRQF_NO_SUSPEND and IRQF_SHARED at the |
| same time should be avoided. |
| |
| |
| System Wakeup Interrupts, enable_irq_wake() and disable_irq_wake() |
| ------------------------------------------------------------------ |
| |
| System wakeup interrupts generally need to be configured to wake up the system |
| from sleep states, especially if they are used for different purposes (e.g. as |
| I/O interrupts) in the working state. |
| |
| That may involve turning on a special signal handling logic within the platform |
| (such as an SoC) so that signals from a given line are routed in a different way |
| during system sleep so as to trigger a system wakeup when needed. For example, |
| the platform may include a dedicated interrupt controller used specifically for |
| handling system wakeup events. Then, if a given interrupt line is supposed to |
| wake up the system from sleep states, the corresponding input of that interrupt |
| controller needs to be enabled to receive signals from the line in question. |
| After wakeup, it generally is better to disable that input to prevent the |
| dedicated controller from triggering interrupts unnecessarily. |
| |
| The IRQ subsystem provides two helper functions to be used by device drivers for |
| those purposes. Namely, enable_irq_wake() turns on the platform's logic for |
| handling the given IRQ as a system wakeup interrupt line and disable_irq_wake() |
| turns that logic off. |
| |
| Calling enable_irq_wake() causes suspend_device_irqs() to treat the given IRQ |
| in a special way. Namely, the IRQ remains enabled, but on the first interrupt |
| it will be disabled, marked as pending and "suspended" so that it will be |
| re-enabled by resume_device_irqs() during the subsequent system resume. Also |
| the PM core is notified about the event which causes the system suspend in |
| progress to be aborted (that doesn't have to happen immediately, but at one |
| of the points where the suspend thread looks for pending wakeup events). |
| |
| This way every interrupt from a wakeup interrupt source will either cause the |
| system suspend currently in progress to be aborted or wake up the system if |
| already suspended. However, after suspend_device_irqs() interrupt handlers are |
| not executed for system wakeup IRQs. They are only executed for IRQF_NO_SUSPEND |
| IRQs at that time, but those IRQs should not be configured for system wakeup |
| using enable_irq_wake(). |
| |
| |
| Interrupts and Suspend-to-Idle |
| ------------------------------ |
| |
| Suspend-to-idle (also known as the "freeze" sleep state) is a relatively new |
| system sleep state that works by idling all of the processors and waiting for |
| interrupts right after the "noirq" phase of suspending devices. |
| |
| Of course, this means that all of the interrupts with the IRQF_NO_SUSPEND flag |
| set will bring CPUs out of idle while in that state, but they will not cause the |
| IRQ subsystem to trigger a system wakeup. |
| |
| System wakeup interrupts, in turn, will trigger wakeup from suspend-to-idle in |
| analogy with what they do in the full system suspend case. The only difference |
| is that the wakeup from suspend-to-idle is signaled using the usual working |
| state interrupt delivery mechanisms and doesn't require the platform to use |
| any special interrupt handling logic for it to work. |
| |
| |
| IRQF_NO_SUSPEND and enable_irq_wake() |
| ------------------------------------- |
| |
| There are very few valid reasons to use both enable_irq_wake() and the |
| IRQF_NO_SUSPEND flag on the same IRQ, and it is never valid to use both for the |
| same device. |
| |
| First of all, if the IRQ is not shared, the rules for handling IRQF_NO_SUSPEND |
| interrupts (interrupt handlers are invoked after suspend_device_irqs()) are |
| directly at odds with the rules for handling system wakeup interrupts (interrupt |
| handlers are not invoked after suspend_device_irqs()). |
| |
| Second, both enable_irq_wake() and IRQF_NO_SUSPEND apply to entire IRQs and not |
| to individual interrupt handlers, so sharing an IRQ between a system wakeup |
| interrupt source and an IRQF_NO_SUSPEND interrupt source does not generally |
| make sense. |
| |
| In rare cases an IRQ can be shared between a wakeup device driver and an |
| IRQF_NO_SUSPEND user. In order for this to be safe, the wakeup device driver |
| must be able to discern spurious IRQs from genuine wakeup events (signalling |
| the latter to the core with pm_system_wakeup()), must use enable_irq_wake() to |
| ensure that the IRQ will function as a wakeup source, and must request the IRQ |
| with IRQF_COND_SUSPEND to tell the core that it meets these requirements. If |
| these requirements are not met, it is not valid to use IRQF_COND_SUSPEND. |