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nexedi
linux
Commits
9a1f05f0
Commit
9a1f05f0
authored
Apr 01, 2003
by
Rusty Russell
Committed by
Linus Torvalds
Apr 01, 2003
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[PATCH] fix linewrap in Documentation/power/pci.txt
From: ookhoi@humilis.net
parent
8f1b2d39
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Documentation/power/pci.txt
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Documentation/power/pci.txt
View file @
9a1f05f0
...
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@@ -50,33 +50,35 @@ The possible state transitions that a device can undergo are:
| D1, D2, D3 | D0 |
+---------------------------+
Note that when the system is entering a global suspend state, all devices will
be
placed into D3 and when resuming, all devices will be placed into D0. However,
when the system is running, other state transitions are possible.
Note that when the system is entering a global suspend state, all devices will
be placed into D3 and when resuming, all devices will be placed into D0.
However,
when the system is running, other state transitions are possible.
2. How The PCI Subsystem Handles Power Management
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The PCI suspend/resume functionality is accessed indirectly via the Power Management
subsystem. At boot, the PCI driver registers a power management callback with that layer.
Upon entering a suspend state, the PM layer iterates through all of its registered
callbacks. This currently takes place only during APM state transitions.
The PCI suspend/resume functionality is accessed indirectly via the Power
Management subsystem. At boot, the PCI driver registers a power management
callback with that layer. Upon entering a suspend state, the PM layer iterates
through all of its registered callbacks. This currently takes place only during
APM state transitions.
Upon going to sleep, the PCI subsystem walks its device tree twice. Both times, it does
a depth first walk of the device tree. The first walk saves each of the device's state
and checks for devices that will prevent the system from entering a global power state.
The next walk then places the devices in a low power state.
Upon going to sleep, the PCI subsystem walks its device tree twice. Both times,
it does a depth first walk of the device tree. The first walk saves each of the
device's state and checks for devices that will prevent the system from entering
a global power state. The next walk then places the devices in a low power
state.
The first walk allows a graceful recovery in the event of a failure, since none
of the
devices have actually been powered down.
The first walk allows a graceful recovery in the event of a failure, since none
of the
devices have actually been powered down.
In both walks, in particular the second, all children of a bridge are touched
before the
actual bridge itself. This allows the bridge to retain power while its children are being
accessed.
In both walks, in particular the second, all children of a bridge are touched
before the actual bridge itself. This allows the bridge to retain power while
its children are being
accessed.
Upon resuming from sleep, just the opposite must be true: all bridges must be
powered on
and restored before their children are powered on. This is easily accomplished with a
breadth-first walk of the PCI device tree.
Upon resuming from sleep, just the opposite must be true: all bridges must be
powered on and restored before their children are powered on. This is easily
accomplished with a
breadth-first walk of the PCI device tree.
3. PCI Utility Functions
...
...
@@ -86,8 +88,8 @@ These are helper functions designed to be called by individual device drivers.
Assuming that a device behaves as advertised, these should be applicable in most
cases. However, results may vary.
Note that these functions are never implicitly called for the driver. The driver
is always
responsible for deciding when and if to call these.
Note that these functions are never implicitly called for the driver. The driver
is always
responsible for deciding when and if to call these.
pci_save_state
...
...
@@ -97,7 +99,8 @@ Usage:
pci_save_state(dev, buffer);
Description:
Save first 64 bytes of PCI config space. Buffer must be allocated by caller.
Save first 64 bytes of PCI config space. Buffer must be allocated by
caller.
pci_restore_state
...
...
@@ -109,8 +112,8 @@ Usage:
Description:
Restore previously saved config space. (First 64 bytes only);
If buffer is NULL, then restore what information we know about the
device
from bootup: BARs and interrupt line.
If buffer is NULL, then restore what information we know about the
device
from bootup: BARs and interrupt line.
pci_set_power_state
...
...
@@ -120,7 +123,8 @@ Usage:
pci_set_power_state(dev, state);
Description:
Transition device to low power state using PCI PM Capabilities registers.
Transition device to low power state using PCI PM Capabilities
registers.
Will fail under one of the following conditions:
- If state is less than current state, but not D0 (illegal transition)
...
...
@@ -138,14 +142,15 @@ Description:
Enable device to generate PME# during low power state using PCI PM
Capabilities.
Checks whether if device supports generating PME# from requested state and fail
if it does not, unless enable == 0 (request is to disable wake events, which
is implicit if it doesn't even support it in the first place).
Checks whether if device supports generating PME# from requested state
and fail if it does not, unless enable == 0 (request is to disable wake
events, which is implicit if it doesn't even support it in the first
place).
Note that the PMC Register in the device's PM Capabilties has a bitmask
of
the states it supports generating PME# from. D3hot is bit 3 and D3cold is bit
4. So, while a value of 4 as the state may not seem semantically correct, it
is.
Note that the PMC Register in the device's PM Capabilties has a bitmask
of the states it supports generating PME# from. D3hot is bit 3 and
D3cold is bit 4. So, while a value of 4 as the state may not seem
semantically correct, it
is.
4. PCI Device Drivers
...
...
@@ -169,24 +174,25 @@ if (dev->driver && dev->driver->save_state)
dev->driver->save_state(dev,state);
The driver should use this callback to save device state. It should take into
account the current state of the device and the requested state in order to
avoid
any unnecessary operations.
account the current state of the device and the requested state in order to
a
void a
ny unnecessary operations.
For example, a video card that supports all 4 states (D0-D3), all controller
context
is preserved when entering D1, but the screen is placed into a low power state
(blanked).
For example, a video card that supports all 4 states (D0-D3), all controller
context is preserved when entering D1, but the screen is placed into a low power
state
(blanked).
The driver can also interpret this function as a notification that it may be
entering
a sleep state in the near future. If it knows that the device cannot enter the
requested state, either because of lack of support for it, or because the device is
middle of some critical operation, then it should fail.
The driver can also interpret this function as a notification that it may be
entering a sleep state in the near future. If it knows that the device cannot
enter the requested state, either because of lack of support for it, or because
the device is
middle of some critical operation, then it should fail.
This function should not be used to set any state in the device or the driver
because
the device may not actually enter the sleep state (e.g. another driver later causes
causes a global state transition to fail).
This function should not be used to set any state in the device or the driver
because the device may not actually enter the sleep state (e.g. another driver
later causes
causes a global state transition to fail).
Note that in intermediate low power states, a device's I/O and memory spaces may be
disabled and may not be available in subsequent transitions to lower power states.
Note that in intermediate low power states, a device's I/O and memory spaces may
be disabled and may not be available in subsequent transitions to lower power
states.
suspend
...
...
@@ -198,26 +204,26 @@ if (dev->driver && dev->driver->suspend)
dev->driver->suspend(dev,state);
A driver uses this function to actually transition the device into a low power
state. This may include disabling I/O, memory and bus-mastering, as well as
physically
transitioning the device to a lower power state.
state. This may include disabling I/O, memory and bus-mastering, as well as
physically
transitioning the device to a lower power state.
Bus mastering may be disabled by doing:
pci_disable_device(dev);
For devices that support the PCI PM Spec, this may be used to set the device's
power
state:
For devices that support the PCI PM Spec, this may be used to set the device's
power
state:
pci_set_power_state(dev,state);
The driver is also responsible for disabling any other device-specific features
(e.g blanking screen, turning off on-card memory, etc).
The driver should be sure to track the current state of the device, as it may
obviate
the need for some operations.
The driver should be sure to track the current state of the device, as it may
obviate
the need for some operations.
The driver should update the current_state field in its pci_dev structure in
this
function.
The driver should update the current_state field in its pci_dev structure in
this
function.
resume
------
...
...
@@ -231,32 +237,33 @@ The resume callback may be called from any power state, and is always meant to
transition the device to the D0 state.
The driver is responsible for reenabling any features of the device that had
been disabled during previous suspend calls and restoring all state that was
saved
in previous save_state calls.
been disabled during previous suspend calls and restoring all state that was
saved
in previous save_state calls.
If the device is currently in D3, it must be completely reinitialized, as it must be
assumed that the device has lost all of its context (even that of its PCI config
space). For almost all current drivers, this means that the initialization code that
the driver does at boot must be separated out and called again from the resume
callback. Note that some values for the device may not have to be probed for this
time around if they are saved before entering the low power state.
If the device is currently in D3, it must be completely reinitialized, as it
must be assumed that the device has lost all of its context (even that of its
PCI config space). For almost all current drivers, this means that the
initialization code that the driver does at boot must be separated out and
called again from the resume callback. Note that some values for the device may
not have to be probed for this time around if they are saved before entering the
low power state.
If the device supports the PCI PM Spec, it can use this to physically transition
the
device to D0:
If the device supports the PCI PM Spec, it can use this to physically transition
the
device to D0:
pci_set_power_state(dev,0);
Note that if the entire system is transitioning out of a global sleep state, all
devices will be placed in the D0 state, so this is not necessary. However, in
the
event that the device is placed in the D3 state during normal operation, this call
is necessary. It is impossible to determine which of the two events is taking place
in the driver, so it is always a good idea to make that call.
devices will be placed in the D0 state, so this is not necessary. However, in
the event that the device is placed in the D3 state during normal operation,
this call is necessary. It is impossible to determine which of the two events is
taking place
in the driver, so it is always a good idea to make that call.
The driver should take note of the state that it is resuming from in order to
ensure
correct (and speedy) operation.
The driver should take note of the state that it is resuming from in order to
ensure
correct (and speedy) operation.
The driver should update the current_state field in its pci_dev structure in
this
function.
The driver should update the current_state field in its pci_dev structure in
this
function.
enable_wake
...
...
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