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515c535762
The prev_state member of struct dev_pm_info (defined in include/linux/pm.h) is only used during a resume to check if the device's state before the suspend was 'off', in which case the device is not resumed. However, in such cases the decision whether or not to resume the device should be made on the driver level and the resume callbacks from the device's bus and class should be executed anyway (the may be needed for some things other than just powering on the device). Signed-off-by: Rafael J. Wysocki <rjw@sisk.pl> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
352 lines
12 KiB
C
352 lines
12 KiB
C
/*
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* pm.h - Power management interface
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*
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* Copyright (C) 2000 Andrew Henroid
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
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*/
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#ifndef _LINUX_PM_H
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#define _LINUX_PM_H
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#ifdef __KERNEL__
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#include <linux/list.h>
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#include <asm/atomic.h>
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/*
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* Power management requests... these are passed to pm_send_all() and friends.
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*
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* these functions are old and deprecated, see below.
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*/
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typedef int __bitwise pm_request_t;
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#define PM_SUSPEND ((__force pm_request_t) 1) /* enter D1-D3 */
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#define PM_RESUME ((__force pm_request_t) 2) /* enter D0 */
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/*
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* Device types... these are passed to pm_register
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*/
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typedef int __bitwise pm_dev_t;
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#define PM_UNKNOWN_DEV ((__force pm_dev_t) 0) /* generic */
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#define PM_SYS_DEV ((__force pm_dev_t) 1) /* system device (fan, KB controller, ...) */
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#define PM_PCI_DEV ((__force pm_dev_t) 2) /* PCI device */
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#define PM_USB_DEV ((__force pm_dev_t) 3) /* USB device */
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#define PM_SCSI_DEV ((__force pm_dev_t) 4) /* SCSI device */
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#define PM_ISA_DEV ((__force pm_dev_t) 5) /* ISA device */
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#define PM_MTD_DEV ((__force pm_dev_t) 6) /* Memory Technology Device */
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/*
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* System device hardware ID (PnP) values
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*/
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enum
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{
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PM_SYS_UNKNOWN = 0x00000000, /* generic */
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PM_SYS_KBC = 0x41d00303, /* keyboard controller */
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PM_SYS_COM = 0x41d00500, /* serial port */
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PM_SYS_IRDA = 0x41d00510, /* IRDA controller */
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PM_SYS_FDC = 0x41d00700, /* floppy controller */
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PM_SYS_VGA = 0x41d00900, /* VGA controller */
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PM_SYS_PCMCIA = 0x41d00e00, /* PCMCIA controller */
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};
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/*
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* Device identifier
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*/
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#define PM_PCI_ID(dev) ((dev)->bus->number << 16 | (dev)->devfn)
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/*
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* Request handler callback
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*/
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struct pm_dev;
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typedef int (*pm_callback)(struct pm_dev *dev, pm_request_t rqst, void *data);
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/*
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* Dynamic device information
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*/
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struct pm_dev
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{
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pm_dev_t type;
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unsigned long id;
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pm_callback callback;
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void *data;
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unsigned long flags;
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unsigned long state;
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unsigned long prev_state;
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struct list_head entry;
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};
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/* Functions above this comment are list-based old-style power
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* managment. Please avoid using them. */
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/*
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* Callbacks for platform drivers to implement.
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*/
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extern void (*pm_idle)(void);
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extern void (*pm_power_off)(void);
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typedef int __bitwise suspend_state_t;
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#define PM_SUSPEND_ON ((__force suspend_state_t) 0)
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#define PM_SUSPEND_STANDBY ((__force suspend_state_t) 1)
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#define PM_SUSPEND_MEM ((__force suspend_state_t) 3)
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#define PM_SUSPEND_MAX ((__force suspend_state_t) 4)
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/**
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* struct pm_ops - Callbacks for managing platform dependent system sleep
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* states.
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*
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* @valid: Callback to determine if given system sleep state is supported by
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* the platform.
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* Valid (ie. supported) states are advertised in /sys/power/state. Note
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* that it still may be impossible to enter given system sleep state if the
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* conditions aren't right.
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* There is the %pm_valid_only_mem function available that can be assigned
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* to this if the platform only supports mem sleep.
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*
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* @set_target: Tell the platform which system sleep state is going to be
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* entered.
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* @set_target() is executed right prior to suspending devices. The
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* information conveyed to the platform code by @set_target() should be
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* disregarded by the platform as soon as @finish() is executed and if
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* @prepare() fails. If @set_target() fails (ie. returns nonzero),
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* @prepare(), @enter() and @finish() will not be called by the PM core.
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* This callback is optional. However, if it is implemented, the argument
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* passed to @prepare(), @enter() and @finish() is meaningless and should
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* be ignored.
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*
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* @prepare: Prepare the platform for entering the system sleep state indicated
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* by @set_target() or represented by the argument if @set_target() is not
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* implemented.
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* @prepare() is called right after devices have been suspended (ie. the
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* appropriate .suspend() method has been executed for each device) and
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* before the nonboot CPUs are disabled (it is executed with IRQs enabled).
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* This callback is optional. It returns 0 on success or a negative
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* error code otherwise, in which case the system cannot enter the desired
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* sleep state (@enter() and @finish() will not be called in that case).
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*
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* @enter: Enter the system sleep state indicated by @set_target() or
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* represented by the argument if @set_target() is not implemented.
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* This callback is mandatory. It returns 0 on success or a negative
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* error code otherwise, in which case the system cannot enter the desired
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* sleep state.
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*
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* @finish: Called when the system has just left a sleep state, right after
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* the nonboot CPUs have been enabled and before devices are resumed (it is
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* executed with IRQs enabled). If @set_target() is not implemented, the
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* argument represents the sleep state being left.
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* This callback is optional, but should be implemented by the platforms
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* that implement @prepare(). If implemented, it is always called after
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* @enter() (even if @enter() fails).
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*/
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struct pm_ops {
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int (*valid)(suspend_state_t state);
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int (*set_target)(suspend_state_t state);
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int (*prepare)(suspend_state_t state);
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int (*enter)(suspend_state_t state);
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int (*finish)(suspend_state_t state);
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};
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extern struct pm_ops *pm_ops;
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/**
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* pm_set_ops - set platform dependent power management ops
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* @pm_ops: The new power management operations to set.
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*/
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extern void pm_set_ops(struct pm_ops *pm_ops);
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extern int pm_valid_only_mem(suspend_state_t state);
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/**
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* arch_suspend_disable_irqs - disable IRQs for suspend
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*
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* Disables IRQs (in the default case). This is a weak symbol in the common
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* code and thus allows architectures to override it if more needs to be
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* done. Not called for suspend to disk.
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*/
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extern void arch_suspend_disable_irqs(void);
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/**
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* arch_suspend_enable_irqs - enable IRQs after suspend
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*
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* Enables IRQs (in the default case). This is a weak symbol in the common
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* code and thus allows architectures to override it if more needs to be
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* done. Not called for suspend to disk.
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*/
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extern void arch_suspend_enable_irqs(void);
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extern int pm_suspend(suspend_state_t state);
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/*
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* Device power management
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*/
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struct device;
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typedef struct pm_message {
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int event;
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} pm_message_t;
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/*
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* Several driver power state transitions are externally visible, affecting
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* the state of pending I/O queues and (for drivers that touch hardware)
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* interrupts, wakeups, DMA, and other hardware state. There may also be
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* internal transitions to various low power modes, which are transparent
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* to the rest of the driver stack (such as a driver that's ON gating off
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* clocks which are not in active use).
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*
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* One transition is triggered by resume(), after a suspend() call; the
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* message is implicit:
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*
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* ON Driver starts working again, responding to hardware events
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* and software requests. The hardware may have gone through
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* a power-off reset, or it may have maintained state from the
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* previous suspend() which the driver will rely on while
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* resuming. On most platforms, there are no restrictions on
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* availability of resources like clocks during resume().
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*
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* Other transitions are triggered by messages sent using suspend(). All
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* these transitions quiesce the driver, so that I/O queues are inactive.
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* That commonly entails turning off IRQs and DMA; there may be rules
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* about how to quiesce that are specific to the bus or the device's type.
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* (For example, network drivers mark the link state.) Other details may
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* differ according to the message:
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*
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* SUSPEND Quiesce, enter a low power device state appropriate for
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* the upcoming system state (such as PCI_D3hot), and enable
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* wakeup events as appropriate.
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*
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* FREEZE Quiesce operations so that a consistent image can be saved;
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* but do NOT otherwise enter a low power device state, and do
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* NOT emit system wakeup events.
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*
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* PRETHAW Quiesce as if for FREEZE; additionally, prepare for restoring
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* the system from a snapshot taken after an earlier FREEZE.
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* Some drivers will need to reset their hardware state instead
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* of preserving it, to ensure that it's never mistaken for the
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* state which that earlier snapshot had set up.
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*
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* A minimally power-aware driver treats all messages as SUSPEND, fully
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* reinitializes its device during resume() -- whether or not it was reset
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* during the suspend/resume cycle -- and can't issue wakeup events.
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*
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* More power-aware drivers may also use low power states at runtime as
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* well as during system sleep states like PM_SUSPEND_STANDBY. They may
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* be able to use wakeup events to exit from runtime low-power states,
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* or from system low-power states such as standby or suspend-to-RAM.
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*/
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#define PM_EVENT_ON 0
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#define PM_EVENT_FREEZE 1
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#define PM_EVENT_SUSPEND 2
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#define PM_EVENT_PRETHAW 3
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#define PMSG_FREEZE ((struct pm_message){ .event = PM_EVENT_FREEZE, })
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#define PMSG_PRETHAW ((struct pm_message){ .event = PM_EVENT_PRETHAW, })
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#define PMSG_SUSPEND ((struct pm_message){ .event = PM_EVENT_SUSPEND, })
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#define PMSG_ON ((struct pm_message){ .event = PM_EVENT_ON, })
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struct dev_pm_info {
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pm_message_t power_state;
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unsigned can_wakeup:1;
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#ifdef CONFIG_PM
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unsigned should_wakeup:1;
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struct list_head entry;
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#endif
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};
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extern int device_power_down(pm_message_t state);
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extern void device_power_up(void);
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extern void device_resume(void);
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#ifdef CONFIG_PM
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extern int device_suspend(pm_message_t state);
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extern int device_prepare_suspend(pm_message_t state);
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#define device_set_wakeup_enable(dev,val) \
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((dev)->power.should_wakeup = !!(val))
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#define device_may_wakeup(dev) \
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(device_can_wakeup(dev) && (dev)->power.should_wakeup)
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extern int dpm_runtime_suspend(struct device *, pm_message_t);
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extern void dpm_runtime_resume(struct device *);
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extern void __suspend_report_result(const char *function, void *fn, int ret);
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#define suspend_report_result(fn, ret) \
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do { \
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__suspend_report_result(__FUNCTION__, fn, ret); \
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} while (0)
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/*
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* Platform hook to activate device wakeup capability, if that's not already
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* handled by enable_irq_wake() etc.
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* Returns zero on success, else negative errno
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*/
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extern int (*platform_enable_wakeup)(struct device *dev, int is_on);
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static inline int call_platform_enable_wakeup(struct device *dev, int is_on)
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{
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if (platform_enable_wakeup)
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return (*platform_enable_wakeup)(dev, is_on);
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return 0;
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}
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#else /* !CONFIG_PM */
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static inline int device_suspend(pm_message_t state)
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{
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return 0;
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}
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#define device_set_wakeup_enable(dev,val) do{}while(0)
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#define device_may_wakeup(dev) (0)
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static inline int dpm_runtime_suspend(struct device * dev, pm_message_t state)
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{
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return 0;
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}
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static inline void dpm_runtime_resume(struct device * dev)
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{
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}
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#define suspend_report_result(fn, ret) do { } while (0)
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static inline int call_platform_enable_wakeup(struct device *dev, int is_on)
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{
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return 0;
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}
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#endif
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/* changes to device_may_wakeup take effect on the next pm state change.
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* by default, devices should wakeup if they can.
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*/
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#define device_can_wakeup(dev) \
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((dev)->power.can_wakeup)
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#define device_init_wakeup(dev,val) \
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do { \
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device_can_wakeup(dev) = !!(val); \
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device_set_wakeup_enable(dev,val); \
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} while(0)
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#endif /* __KERNEL__ */
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#endif /* _LINUX_PM_H */
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