126 строки
6.1 KiB
Plaintext
126 строки
6.1 KiB
Plaintext
System Power Management Sleep States
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(C) 2014 Intel Corp., Rafael J. Wysocki <rafael.j.wysocki@intel.com>
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The kernel supports up to four system sleep states generically, although three
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of them depend on the platform support code to implement the low-level details
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for each state.
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The states are represented by strings that can be read or written to the
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/sys/power/state file. Those strings may be "mem", "standby", "freeze" and
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"disk", where the last three always represent Power-On Suspend (if supported),
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Suspend-To-Idle and hibernation (Suspend-To-Disk), respectively.
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The meaning of the "mem" string is controlled by the /sys/power/mem_sleep file.
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It contains strings representing the available modes of system suspend that may
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be triggered by writing "mem" to /sys/power/state. These modes are "s2idle"
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(Suspend-To-Idle), "shallow" (Power-On Suspend) and "deep" (Suspend-To-RAM).
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The "s2idle" mode is always available, while the other ones are only available
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if supported by the platform (if not supported, the strings representing them
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are not present in /sys/power/mem_sleep). The string representing the suspend
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mode to be used subsequently is enclosed in square brackets. Writing one of
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the other strings present in /sys/power/mem_sleep to it causes the suspend mode
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to be used subsequently to change to the one represented by that string.
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Consequently, there are two ways to cause the system to go into the
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Suspend-To-Idle sleep state. The first one is to write "freeze" directly to
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/sys/power/state. The second one is to write "s2idle" to /sys/power/mem_sleep
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and then to wrtie "mem" to /sys/power/state. Similarly, there are two ways
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to cause the system to go into the Power-On Suspend sleep state (the strings to
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write to the control files in that case are "standby" or "shallow" and "mem",
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respectively) if that state is supported by the platform. In turn, there is
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only one way to cause the system to go into the Suspend-To-RAM state (write
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"deep" into /sys/power/mem_sleep and "mem" into /sys/power/state).
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The default suspend mode (ie. the one to be used without writing anything into
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/sys/power/mem_sleep) is either "deep" (if Suspend-To-RAM is supported) or
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"s2idle", but it can be overridden by the value of the "mem_sleep_default"
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parameter in the kernel command line.
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The properties of all of the sleep states are described below.
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State: Suspend-To-Idle
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ACPI state: S0
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Label: "s2idle" ("freeze")
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This state is a generic, pure software, light-weight, system sleep state.
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It allows more energy to be saved relative to runtime idle by freezing user
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space and putting all I/O devices into low-power states (possibly
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lower-power than available at run time), such that the processors can
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spend more time in their idle states.
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This state can be used for platforms without Power-On Suspend/Suspend-to-RAM
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support, or it can be used in addition to Suspend-to-RAM to provide reduced
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resume latency. It is always supported.
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State: Standby / Power-On Suspend
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ACPI State: S1
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Label: "shallow" ("standby")
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This state, if supported, offers moderate, though real, power savings, while
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providing a relatively low-latency transition back to a working system. No
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operating state is lost (the CPU retains power), so the system easily starts up
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again where it left off.
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In addition to freezing user space and putting all I/O devices into low-power
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states, which is done for Suspend-To-Idle too, nonboot CPUs are taken offline
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and all low-level system functions are suspended during transitions into this
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state. For this reason, it should allow more energy to be saved relative to
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Suspend-To-Idle, but the resume latency will generally be greater than for that
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state.
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State: Suspend-to-RAM
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ACPI State: S3
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Label: "deep"
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This state, if supported, offers significant power savings as everything in the
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system is put into a low-power state, except for memory, which should be placed
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into the self-refresh mode to retain its contents. All of the steps carried out
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when entering Power-On Suspend are also carried out during transitions to STR.
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Additional operations may take place depending on the platform capabilities. In
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particular, on ACPI systems the kernel passes control to the BIOS (platform
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firmware) as the last step during STR transitions and that usually results in
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powering down some more low-level components that aren't directly controlled by
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the kernel.
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System and device state is saved and kept in memory. All devices are suspended
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and put into low-power states. In many cases, all peripheral buses lose power
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when entering STR, so devices must be able to handle the transition back to the
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"on" state.
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For at least ACPI, STR requires some minimal boot-strapping code to resume the
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system from it. This may be the case on other platforms too.
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State: Suspend-to-disk
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ACPI State: S4
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Label: "disk"
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This state offers the greatest power savings, and can be used even in
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the absence of low-level platform support for power management. This
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state operates similarly to Suspend-to-RAM, but includes a final step
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of writing memory contents to disk. On resume, this is read and memory
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is restored to its pre-suspend state.
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STD can be handled by the firmware or the kernel. If it is handled by
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the firmware, it usually requires a dedicated partition that must be
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setup via another operating system for it to use. Despite the
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inconvenience, this method requires minimal work by the kernel, since
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the firmware will also handle restoring memory contents on resume.
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For suspend-to-disk, a mechanism called 'swsusp' (Swap Suspend) is used
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to write memory contents to free swap space. swsusp has some restrictive
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requirements, but should work in most cases. Some, albeit outdated,
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documentation can be found in Documentation/power/swsusp.txt.
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Alternatively, userspace can do most of the actual suspend to disk work,
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see userland-swsusp.txt.
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Once memory state is written to disk, the system may either enter a
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low-power state (like ACPI S4), or it may simply power down. Powering
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down offers greater savings, and allows this mechanism to work on any
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system. However, entering a real low-power state allows the user to
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trigger wake up events (e.g. pressing a key or opening a laptop lid).
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