Merge branch 'master' into sh/hw-breakpoints

This commit is contained in:
Paul Mundt 2010-01-06 15:49:08 +09:00
Родитель 6fbfe8d7cd 56d45b62ce
Коммит fa94ddea2b
644 изменённых файлов: 16192 добавлений и 10854 удалений

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@ -21,25 +21,27 @@ Contact: Alan Stern <stern@rowland.harvard.edu>
Description:
Each USB device directory will contain a file named
power/level. This file holds a power-level setting for
the device, one of "on", "auto", or "suspend".
the device, either "on" or "auto".
"on" means that the device is not allowed to autosuspend,
although normal suspends for system sleep will still
be honored. "auto" means the device will autosuspend
and autoresume in the usual manner, according to the
capabilities of its driver. "suspend" means the device
is forced into a suspended state and it will not autoresume
in response to I/O requests. However remote-wakeup requests
from the device may still be enabled (the remote-wakeup
setting is controlled separately by the power/wakeup
attribute).
capabilities of its driver.
During normal use, devices should be left in the "auto"
level. The other levels are meant for administrative uses.
level. The "on" level is meant for administrative uses.
If you want to suspend a device immediately but leave it
free to wake up in response to I/O requests, you should
write "0" to power/autosuspend.
Device not capable of proper suspend and resume should be
left in the "on" level. Although the USB spec requires
devices to support suspend/resume, many of them do not.
In fact so many don't that by default, the USB core
initializes all non-hub devices in the "on" level. Some
drivers may change this setting when they are bound.
What: /sys/bus/usb/devices/.../power/persist
Date: May 2007
KernelVersion: 2.6.23

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@ -226,5 +226,5 @@ struct driver_attribute driver_attr_debug;
This can then be used to add and remove the attribute from the
driver's directory using:
int driver_create_file(struct device_driver *, struct driver_attribute *);
void driver_remove_file(struct device_driver *, struct driver_attribute *);
int driver_create_file(struct device_driver *, const struct driver_attribute *);
void driver_remove_file(struct device_driver *, const struct driver_attribute *);

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@ -91,8 +91,8 @@ struct device_attribute {
const char *buf, size_t count);
};
int device_create_file(struct device *, struct device_attribute *);
void device_remove_file(struct device *, struct device_attribute *);
int device_create_file(struct device *, const struct device_attribute *);
void device_remove_file(struct device *, const struct device_attribute *);
It also defines this helper for defining device attributes:
@ -316,8 +316,8 @@ DEVICE_ATTR(_name, _mode, _show, _store);
Creation/Removal:
int device_create_file(struct device *device, struct device_attribute * attr);
void device_remove_file(struct device * dev, struct device_attribute * attr);
int device_create_file(struct device *dev, const struct device_attribute * attr);
void device_remove_file(struct device *dev, const struct device_attribute * attr);
- bus drivers (include/linux/device.h)
@ -358,7 +358,7 @@ DRIVER_ATTR(_name, _mode, _show, _store)
Creation/Removal:
int driver_create_file(struct device_driver *, struct driver_attribute *);
void driver_remove_file(struct device_driver *, struct driver_attribute *);
int driver_create_file(struct device_driver *, const struct driver_attribute *);
void driver_remove_file(struct device_driver *, const struct driver_attribute *);

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@ -42,80 +42,81 @@ struct dev_pm_ops {
...
};
The ->runtime_suspend() callback is executed by the PM core for the bus type of
the device being suspended. The bus type's callback is then _entirely_
_responsible_ for handling the device as appropriate, which may, but need not
include executing the device driver's own ->runtime_suspend() callback (from the
PM core's point of view it is not necessary to implement a ->runtime_suspend()
callback in a device driver as long as the bus type's ->runtime_suspend() knows
what to do to handle the device).
The ->runtime_suspend(), ->runtime_resume() and ->runtime_idle() callbacks are
executed by the PM core for either the bus type, or device type (if the bus
type's callback is not defined), or device class (if the bus type's and device
type's callbacks are not defined) of given device. The bus type, device type
and device class callbacks are referred to as subsystem-level callbacks in what
follows.
* Once the bus type's ->runtime_suspend() callback has completed successfully
The subsystem-level suspend callback is _entirely_ _responsible_ for handling
the suspend of the device as appropriate, which may, but need not include
executing the device driver's own ->runtime_suspend() callback (from the
PM core's point of view it is not necessary to implement a ->runtime_suspend()
callback in a device driver as long as the subsystem-level suspend callback
knows what to do to handle the device).
* Once the subsystem-level suspend callback has completed successfully
for given device, the PM core regards the device as suspended, which need
not mean that the device has been put into a low power state. It is
supposed to mean, however, that the device will not process data and will
not communicate with the CPU(s) and RAM until its bus type's
->runtime_resume() callback is executed for it. The run-time PM status of
a device after successful execution of its bus type's ->runtime_suspend()
callback is 'suspended'.
not communicate with the CPU(s) and RAM until the subsystem-level resume
callback is executed for it. The run-time PM status of a device after
successful execution of the subsystem-level suspend callback is 'suspended'.
* If the bus type's ->runtime_suspend() callback returns -EBUSY or -EAGAIN,
the device's run-time PM status is supposed to be 'active', which means that
the device _must_ be fully operational afterwards.
* If the subsystem-level suspend callback returns -EBUSY or -EAGAIN,
the device's run-time PM status is 'active', which means that the device
_must_ be fully operational afterwards.
* If the bus type's ->runtime_suspend() callback returns an error code
different from -EBUSY or -EAGAIN, the PM core regards this as a fatal
error and will refuse to run the helper functions described in Section 4
for the device, until the status of it is directly set either to 'active'
or to 'suspended' (the PM core provides special helper functions for this
purpose).
* If the subsystem-level suspend callback returns an error code different
from -EBUSY or -EAGAIN, the PM core regards this as a fatal error and will
refuse to run the helper functions described in Section 4 for the device,
until the status of it is directly set either to 'active', or to 'suspended'
(the PM core provides special helper functions for this purpose).
In particular, if the driver requires remote wakeup capability for proper
functioning and device_run_wake() returns 'false' for the device, then
->runtime_suspend() should return -EBUSY. On the other hand, if
device_run_wake() returns 'true' for the device and the device is put
into a low power state during the execution of its bus type's
->runtime_suspend(), it is expected that remote wake-up (i.e. hardware mechanism
allowing the device to request a change of its power state, such as PCI PME)
will be enabled for the device. Generally, remote wake-up should be enabled
for all input devices put into a low power state at run time.
In particular, if the driver requires remote wake-up capability (i.e. hardware
mechanism allowing the device to request a change of its power state, such as
PCI PME) for proper functioning and device_run_wake() returns 'false' for the
device, then ->runtime_suspend() should return -EBUSY. On the other hand, if
device_run_wake() returns 'true' for the device and the device is put into a low
power state during the execution of the subsystem-level suspend callback, it is
expected that remote wake-up will be enabled for the device. Generally, remote
wake-up should be enabled for all input devices put into a low power state at
run time.
The ->runtime_resume() callback is executed by the PM core for the bus type of
the device being woken up. The bus type's callback is then _entirely_
_responsible_ for handling the device as appropriate, which may, but need not
include executing the device driver's own ->runtime_resume() callback (from the
PM core's point of view it is not necessary to implement a ->runtime_resume()
callback in a device driver as long as the bus type's ->runtime_resume() knows
what to do to handle the device).
The subsystem-level resume callback is _entirely_ _responsible_ for handling the
resume of the device as appropriate, which may, but need not include executing
the device driver's own ->runtime_resume() callback (from the PM core's point of
view it is not necessary to implement a ->runtime_resume() callback in a device
driver as long as the subsystem-level resume callback knows what to do to handle
the device).
* Once the bus type's ->runtime_resume() callback has completed successfully,
the PM core regards the device as fully operational, which means that the
device _must_ be able to complete I/O operations as needed. The run-time
PM status of the device is then 'active'.
* Once the subsystem-level resume callback has completed successfully, the PM
core regards the device as fully operational, which means that the device
_must_ be able to complete I/O operations as needed. The run-time PM status
of the device is then 'active'.
* If the bus type's ->runtime_resume() callback returns an error code, the PM
core regards this as a fatal error and will refuse to run the helper
functions described in Section 4 for the device, until its status is
directly set either to 'active' or to 'suspended' (the PM core provides
special helper functions for this purpose).
* If the subsystem-level resume callback returns an error code, the PM core
regards this as a fatal error and will refuse to run the helper functions
described in Section 4 for the device, until its status is directly set
either to 'active' or to 'suspended' (the PM core provides special helper
functions for this purpose).
The ->runtime_idle() callback is executed by the PM core for the bus type of
given device whenever the device appears to be idle, which is indicated to the
PM core by two counters, the device's usage counter and the counter of 'active'
children of the device.
The subsystem-level idle callback is executed by the PM core whenever the device
appears to be idle, which is indicated to the PM core by two counters, the
device's usage counter and the counter of 'active' children of the device.
* If any of these counters is decreased using a helper function provided by
the PM core and it turns out to be equal to zero, the other counter is
checked. If that counter also is equal to zero, the PM core executes the
device bus type's ->runtime_idle() callback (with the device as an
argument).
subsystem-level idle callback with the device as an argument.
The action performed by a bus type's ->runtime_idle() callback is totally
dependent on the bus type in question, but the expected and recommended action
is to check if the device can be suspended (i.e. if all of the conditions
necessary for suspending the device are satisfied) and to queue up a suspend
request for the device in that case. The value returned by this callback is
ignored by the PM core.
The action performed by a subsystem-level idle callback is totally dependent on
the subsystem in question, but the expected and recommended action is to check
if the device can be suspended (i.e. if all of the conditions necessary for
suspending the device are satisfied) and to queue up a suspend request for the
device in that case. The value returned by this callback is ignored by the PM
core.
The helper functions provided by the PM core, described in Section 4, guarantee
that the following constraints are met with respect to the bus type's run-time
@ -238,41 +239,41 @@ drivers/base/power/runtime.c and include/linux/pm_runtime.h:
removing the device from device hierarchy
int pm_runtime_idle(struct device *dev);
- execute ->runtime_idle() for the device's bus type; returns 0 on success
or error code on failure, where -EINPROGRESS means that ->runtime_idle()
is already being executed
- execute the subsystem-level idle callback for the device; returns 0 on
success or error code on failure, where -EINPROGRESS means that
->runtime_idle() is already being executed
int pm_runtime_suspend(struct device *dev);
- execute ->runtime_suspend() for the device's bus type; returns 0 on
- execute the subsystem-level suspend callback for the device; returns 0 on
success, 1 if the device's run-time PM status was already 'suspended', or
error code on failure, where -EAGAIN or -EBUSY means it is safe to attempt
to suspend the device again in future
int pm_runtime_resume(struct device *dev);
- execute ->runtime_resume() for the device's bus type; returns 0 on
- execute the subsystem-leve resume callback for the device; returns 0 on
success, 1 if the device's run-time PM status was already 'active' or
error code on failure, where -EAGAIN means it may be safe to attempt to
resume the device again in future, but 'power.runtime_error' should be
checked additionally
int pm_request_idle(struct device *dev);
- submit a request to execute ->runtime_idle() for the device's bus type
(the request is represented by a work item in pm_wq); returns 0 on success
or error code if the request has not been queued up
- submit a request to execute the subsystem-level idle callback for the
device (the request is represented by a work item in pm_wq); returns 0 on
success or error code if the request has not been queued up
int pm_schedule_suspend(struct device *dev, unsigned int delay);
- schedule the execution of ->runtime_suspend() for the device's bus type
in future, where 'delay' is the time to wait before queuing up a suspend
work item in pm_wq, in milliseconds (if 'delay' is zero, the work item is
queued up immediately); returns 0 on success, 1 if the device's PM
- schedule the execution of the subsystem-level suspend callback for the
device in future, where 'delay' is the time to wait before queuing up a
suspend work item in pm_wq, in milliseconds (if 'delay' is zero, the work
item is queued up immediately); returns 0 on success, 1 if the device's PM
run-time status was already 'suspended', or error code if the request
hasn't been scheduled (or queued up if 'delay' is 0); if the execution of
->runtime_suspend() is already scheduled and not yet expired, the new
value of 'delay' will be used as the time to wait
int pm_request_resume(struct device *dev);
- submit a request to execute ->runtime_resume() for the device's bus type
(the request is represented by a work item in pm_wq); returns 0 on
- submit a request to execute the subsystem-level resume callback for the
device (the request is represented by a work item in pm_wq); returns 0 on
success, 1 if the device's run-time PM status was already 'active', or
error code if the request hasn't been queued up
@ -303,12 +304,12 @@ drivers/base/power/runtime.c and include/linux/pm_runtime.h:
run-time PM callbacks described in Section 2
int pm_runtime_disable(struct device *dev);
- prevent the run-time PM helper functions from running the device bus
type's run-time PM callbacks, make sure that all of the pending run-time
PM operations on the device are either completed or canceled; returns
1 if there was a resume request pending and it was necessary to execute
->runtime_resume() for the device's bus type to satisfy that request,
otherwise 0 is returned
- prevent the run-time PM helper functions from running subsystem-level
run-time PM callbacks for the device, make sure that all of the pending
run-time PM operations on the device are either completed or canceled;
returns 1 if there was a resume request pending and it was necessary to
execute the subsystem-level resume callback for the device to satisfy that
request, otherwise 0 is returned
void pm_suspend_ignore_children(struct device *dev, bool enable);
- set/unset the power.ignore_children flag of the device
@ -378,5 +379,55 @@ pm_runtime_suspend() or pm_runtime_idle() or their asynchronous counterparts,
they will fail returning -EAGAIN, because the device's usage counter is
incremented by the core before executing ->probe() and ->remove(). Still, it
may be desirable to suspend the device as soon as ->probe() or ->remove() has
finished, so the PM core uses pm_runtime_idle_sync() to invoke the device bus
type's ->runtime_idle() callback at that time.
finished, so the PM core uses pm_runtime_idle_sync() to invoke the
subsystem-level idle callback for the device at that time.
6. Run-time PM and System Sleep
Run-time PM and system sleep (i.e., system suspend and hibernation, also known
as suspend-to-RAM and suspend-to-disk) interact with each other in a couple of
ways. If a device is active when a system sleep starts, everything is
straightforward. But what should happen if the device is already suspended?
The device may have different wake-up settings for run-time PM and system sleep.
For example, remote wake-up may be enabled for run-time suspend but disallowed
for system sleep (device_may_wakeup(dev) returns 'false'). When this happens,
the subsystem-level system suspend callback is responsible for changing the
device's wake-up setting (it may leave that to the device driver's system
suspend routine). It may be necessary to resume the device and suspend it again
in order to do so. The same is true if the driver uses different power levels
or other settings for run-time suspend and system sleep.
During system resume, devices generally should be brought back to full power,
even if they were suspended before the system sleep began. There are several
reasons for this, including:
* The device might need to switch power levels, wake-up settings, etc.
* Remote wake-up events might have been lost by the firmware.
* The device's children may need the device to be at full power in order
to resume themselves.
* The driver's idea of the device state may not agree with the device's
physical state. This can happen during resume from hibernation.
* The device might need to be reset.
* Even though the device was suspended, if its usage counter was > 0 then most
likely it would need a run-time resume in the near future anyway.
* Always going back to full power is simplest.
If the device was suspended before the sleep began, then its run-time PM status
will have to be updated to reflect the actual post-system sleep status. The way
to do this is:
pm_runtime_disable(dev);
pm_runtime_set_active(dev);
pm_runtime_enable(dev);
The PM core always increments the run-time usage counter before calling the
->prepare() callback and decrements it after calling the ->complete() callback.
Hence disabling run-time PM temporarily like this will not cause any run-time
suspend callbacks to be lost.

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@ -0,0 +1,42 @@
* OpenPIC and its interrupt numbers on Freescale's e500/e600 cores
The OpenPIC specification does not specify which interrupt source has to
become which interrupt number. This is up to the software implementation
of the interrupt controller. The only requirement is that every
interrupt source has to have an unique interrupt number / vector number.
To accomplish this the current implementation assigns the number zero to
the first source, the number one to the second source and so on until
all interrupt sources have their unique number.
Usually the assigned vector number equals the interrupt number mentioned
in the documentation for a given core / CPU. This is however not true
for the e500 cores (MPC85XX CPUs) where the documentation distinguishes
between internal and external interrupt sources and starts counting at
zero for both of them.
So what to write for external interrupt source X or internal interrupt
source Y into the device tree? Here is an example:
The memory map for the interrupt controller in the MPC8544[0] shows,
that the first interrupt source starts at 0x5_0000 (PIC Register Address
Map-Interrupt Source Configuration Registers). This source becomes the
number zero therefore:
External interrupt 0 = interrupt number 0
External interrupt 1 = interrupt number 1
External interrupt 2 = interrupt number 2
...
Every interrupt number allocates 0x20 bytes register space. So to get
its number it is sufficient to shift the lower 16bits to right by five.
So for the external interrupt 10 we have:
0x0140 >> 5 = 10
After the external sources, the internal sources follow. The in core I2C
controller on the MPC8544 for instance has the internal source number
27. Oo obtain its interrupt number we take the lower 16bits of its memory
address (0x5_0560) and shift it right:
0x0560 >> 5 = 43
Therefore the I2C device node for the MPC8544 CPU has to have the
interrupt number 43 specified in the device tree.
[0] MPC8544E PowerQUICCTM III, Integrated Host Processor Family Reference Manual
MPC8544ERM Rev. 1 10/2007

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@ -403,4 +403,5 @@ STAC9872
Cirrus Logic CS4206/4207
========================
mbp55 MacBook Pro 5,5
imac27 IMac 27 Inch
auto BIOS setup (default)

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@ -26,13 +26,33 @@ Procedure for submitting patches to the -stable tree:
- Send the patch, after verifying that it follows the above rules, to
stable@kernel.org.
- To have the patch automatically included in the stable tree, add the
the tag
Cc: stable@kernel.org
in the sign-off area. Once the patch is merged it will be applied to
the stable tree without anything else needing to be done by the author
or subsystem maintainer.
- If the patch requires other patches as prerequisites which can be
cherry-picked than this can be specified in the following format in
the sign-off area:
Cc: <stable@kernel.org> # .32.x: a1f84a3: sched: Check for idle
Cc: <stable@kernel.org> # .32.x: 1b9508f: sched: Rate-limit newidle
Cc: <stable@kernel.org> # .32.x: fd21073: sched: Fix affinity logic
Cc: <stable@kernel.org> # .32.x
Signed-off-by: Ingo Molnar <mingo@elte.hu>
The tag sequence has the meaning of:
git cherry-pick a1f84a3
git cherry-pick 1b9508f
git cherry-pick fd21073
git cherry-pick <this commit>
- The sender will receive an ACK when the patch has been accepted into the
queue, or a NAK if the patch is rejected. This response might take a few
days, according to the developer's schedules.
- If accepted, the patch will be added to the -stable queue, for review by
other developers and by the relevant subsystem maintainer.
- If the stable@kernel.org address is added to a patch, when it goes into
Linus's tree it will automatically be emailed to the stable team.
- Security patches should not be sent to this alias, but instead to the
documented security@kernel.org address.

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@ -1,7 +1,7 @@
Subsystem Trace Points: kmem
The tracing system kmem captures events related to object and page allocation
within the kernel. Broadly speaking there are four major subheadings.
The kmem tracing system captures events related to object and page allocation
within the kernel. Broadly speaking there are five major subheadings.
o Slab allocation of small objects of unknown type (kmalloc)
o Slab allocation of small objects of known type
@ -9,7 +9,7 @@ within the kernel. Broadly speaking there are four major subheadings.
o Per-CPU Allocator Activity
o External Fragmentation
This document will describe what each of the tracepoints are and why they
This document describes what each of the tracepoints is and why they
might be useful.
1. Slab allocation of small objects of unknown type
@ -34,7 +34,7 @@ kmem_cache_free call_site=%lx ptr=%p
These events are similar in usage to the kmalloc-related events except that
it is likely easier to pin the event down to a specific cache. At the time
of writing, no information is available on what slab is being allocated from,
but the call_site can usually be used to extrapolate that information
but the call_site can usually be used to extrapolate that information.
3. Page allocation
==================
@ -80,9 +80,9 @@ event indicating whether it is for a percpu_refill or not.
When the per-CPU list is too full, a number of pages are freed, each one
which triggers a mm_page_pcpu_drain event.
The individual nature of the events are so that pages can be tracked
The individual nature of the events is so that pages can be tracked
between allocation and freeing. A number of drain or refill pages that occur
consecutively imply the zone->lock being taken once. Large amounts of PCP
consecutively imply the zone->lock being taken once. Large amounts of per-CPU
refills and drains could imply an imbalance between CPUs where too much work
is being concentrated in one place. It could also indicate that the per-CPU
lists should be a larger size. Finally, large amounts of refills on one CPU
@ -102,6 +102,6 @@ is important.
Large numbers of this event implies that memory is fragmenting and
high-order allocations will start failing at some time in the future. One
means of reducing the occurange of this event is to increase the size of
means of reducing the occurrence of this event is to increase the size of
min_free_kbytes in increments of 3*pageblock_size*nr_online_nodes where
pageblock_size is usually the size of the default hugepage size.

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@ -71,12 +71,10 @@ being accessed through sysfs, then it definitely is idle.
Forms of dynamic PM
-------------------
Dynamic suspends can occur in two ways: manual and automatic.
"Manual" means that the user has told the kernel to suspend a device,
whereas "automatic" means that the kernel has decided all by itself to
suspend a device. Automatic suspend is called "autosuspend" for
short. In general, a device won't be autosuspended unless it has been
idle for some minimum period of time, the so-called idle-delay time.
Dynamic suspends occur when the kernel decides to suspend an idle
device. This is called "autosuspend" for short. In general, a device
won't be autosuspended unless it has been idle for some minimum period
of time, the so-called idle-delay time.
Of course, nothing the kernel does on its own initiative should
prevent the computer or its devices from working properly. If a
@ -96,10 +94,11 @@ idle.
We can categorize power management events in two broad classes:
external and internal. External events are those triggered by some
agent outside the USB stack: system suspend/resume (triggered by
userspace), manual dynamic suspend/resume (also triggered by
userspace), and remote wakeup (triggered by the device). Internal
events are those triggered within the USB stack: autosuspend and
autoresume.
userspace), manual dynamic resume (also triggered by userspace), and
remote wakeup (triggered by the device). Internal events are those
triggered within the USB stack: autosuspend and autoresume. Note that
all dynamic suspend events are internal; external agents are not
allowed to issue dynamic suspends.
The user interface for dynamic PM
@ -145,9 +144,9 @@ relevant attribute files are: wakeup, level, and autosuspend.
number of seconds the device should remain idle before
the kernel will autosuspend it (the idle-delay time).
The default is 2. 0 means to autosuspend as soon as
the device becomes idle, and -1 means never to
autosuspend. You can write a number to the file to
change the autosuspend idle-delay time.
the device becomes idle, and negative values mean
never to autosuspend. You can write a number to the
file to change the autosuspend idle-delay time.
Writing "-1" to power/autosuspend and writing "on" to power/level do
essentially the same thing -- they both prevent the device from being
@ -377,9 +376,9 @@ the device hasn't been idle for long enough, a delayed workqueue
routine is automatically set up to carry out the operation when the
autosuspend idle-delay has expired.
Autoresume attempts also can fail. This will happen if power/level is
set to "suspend" or if the device doesn't manage to resume properly.
Unlike autosuspend, there's no delay for an autoresume.
Autoresume attempts also can fail, although failure would mean that
the device is no longer present or operating properly. Unlike
autosuspend, there's no delay for an autoresume.
Other parts of the driver interface
@ -527,13 +526,3 @@ succeed, it may still remain active and thus cause the system to
resume as soon as the system suspend is complete. Or the remote
wakeup may fail and get lost. Which outcome occurs depends on timing
and on the hardware and firmware design.
More interestingly, a device might undergo a manual resume or
autoresume during system suspend. With current kernels this shouldn't
happen, because manual resumes must be initiated by userspace and
autoresumes happen in response to I/O requests, but all user processes
and I/O should be quiescent during a system suspend -- thanks to the
freezer. However there are plans to do away with the freezer, which
would mean these things would become possible. If and when this comes
about, the USB core will carefully arrange matters so that either type
of resume will block until the entire system has resumed.

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@ -1402,6 +1402,8 @@ L: linux-usb@vger.kernel.org
S: Supported
F: Documentation/usb/WUSB-Design-overview.txt
F: Documentation/usb/wusb-cbaf
F: drivers/usb/host/hwa-hc.c
F: drivers/usb/host/whci/
F: drivers/usb/wusbcore/
F: include/linux/usb/wusb*
@ -1470,6 +1472,12 @@ L: linux-scsi@vger.kernel.org
S: Supported
F: drivers/scsi/fnic/
CMPC ACPI DRIVER
M: Thadeu Lima de Souza Cascardo <cascardo@holoscopio.com>
M: Daniel Oliveira Nascimento <don@syst.com.br>
S: Supported
F: drivers/platform/x86/classmate-laptop.c
CODA FILE SYSTEM
M: Jan Harkes <jaharkes@cs.cmu.edu>
M: coda@cs.cmu.edu
@ -3644,6 +3652,11 @@ W: http://0pointer.de/lennart/tchibo.html
S: Maintained
F: drivers/platform/x86/msi-laptop.c
MSI WMI SUPPORT
M: Anisse Astier <anisse@astier.eu>
S: Supported
F: drivers/platform/x86/msi-wmi.c
MULTIFUNCTION DEVICES (MFD)
M: Samuel Ortiz <sameo@linux.intel.com>
T: git git://git.kernel.org/pub/scm/linux/kernel/git/sameo/mfd-2.6.git
@ -3677,7 +3690,7 @@ F: include/linux/isicom.h
MUSB MULTIPOINT HIGH SPEED DUAL-ROLE CONTROLLER
M: Felipe Balbi <felipe.balbi@nokia.com>
L: linux-usb@vger.kernel.org
T: git git://gitorious.org/musb/mainline.git
T: git git://gitorious.org/usb/usb.git
S: Maintained
F: drivers/usb/musb/
@ -5430,7 +5443,10 @@ ULTRA-WIDEBAND (UWB) SUBSYSTEM:
M: David Vrabel <david.vrabel@csr.com>
L: linux-usb@vger.kernel.org
S: Supported
F: drivers/uwb/*
F: drivers/uwb/
X: drivers/uwb/wlp/
X: drivers/uwb/i1480/i1480u-wlp/
X: drivers/uwb/i1480/i1480-wlp.h
F: include/linux/uwb.h
F: include/linux/uwb/
@ -5943,9 +5959,12 @@ W: http://linuxwimax.org
WIMEDIA LLC PROTOCOL (WLP) SUBSYSTEM
M: David Vrabel <david.vrabel@csr.com>
L: netdev@vger.kernel.org
S: Maintained
F: include/linux/wlp.h
F: drivers/uwb/wlp/
F: drivers/uwb/i1480/i1480u-wlp/
F: drivers/uwb/i1480/i1480-wlp.h
WISTRON LAPTOP BUTTON DRIVER
M: Miloslav Trmac <mitr@volny.cz>

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@ -1,7 +1,7 @@
VERSION = 2
PATCHLEVEL = 6
SUBLEVEL = 33
EXTRAVERSION = -rc1
EXTRAVERSION = -rc2
NAME = Man-Eating Seals of Antiquity
# *DOCUMENTATION*

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@ -312,7 +312,7 @@ static inline void unmap_single(struct device *dev, dma_addr_t dma_addr,
* we need to ensure that the data will be coherent
* with user mappings.
*/
__cpuc_flush_kernel_dcache_area(ptr, size);
__cpuc_flush_dcache_area(ptr, size);
}
free_safe_buffer(dev->archdata.dmabounce, buf);
}

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@ -187,7 +187,6 @@ CONFIG_MACH_ACS5K=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM922T=y
CONFIG_CPU_32v4T=y
CONFIG_CPU_ABRT_EV4T=y

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@ -186,7 +186,6 @@ CONFIG_MACH_ACS5K=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM922T=y
CONFIG_CPU_32v4T=y
CONFIG_CPU_ABRT_EV4T=y

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@ -227,7 +227,6 @@ CONFIG_AT91_EARLY_DBGU=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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@ -189,7 +189,6 @@ CONFIG_PXA25x=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSCALE=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -233,7 +233,6 @@ CONFIG_MACH_OMAP3517EVM=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_32v6K=y
CONFIG_CPU_V7=y
CONFIG_CPU_32v7=y

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@ -210,7 +210,6 @@ CONFIG_OMAP_ARM_150MHZ=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM925T=y
CONFIG_CPU_32v4T=y
CONFIG_CPU_ABRT_EV4T=y

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@ -101,7 +101,6 @@ CONFIG_SA1100_ASSABET=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_SA1100=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4=y

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@ -181,7 +181,6 @@ CONFIG_AT91_TIMER_HZ=100
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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@ -130,7 +130,6 @@ CONFIG_AT91_PROGRAMMABLE_CLOCKS=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM920T=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4T=y

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@ -129,7 +129,6 @@ CONFIG_AT91_PROGRAMMABLE_CLOCKS=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM920T=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4T=y

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@ -188,7 +188,6 @@ CONFIG_AT91_TIMER_HZ=100
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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@ -181,7 +181,6 @@ CONFIG_AT91_TIMER_HZ=100
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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@ -181,7 +181,6 @@ CONFIG_AT91_TIMER_HZ=100
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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@ -187,7 +187,6 @@ CONFIG_AT91_EARLY_DBGU=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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@ -179,7 +179,6 @@ CONFIG_AT91_TIMER_HZ=100
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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@ -132,7 +132,6 @@ CONFIG_MACH_ATEB9200=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM920T=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4T=y

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@ -103,7 +103,6 @@ CONFIG_SA1100_BADGE4=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_SA1100=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4=y

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@ -181,7 +181,6 @@ CONFIG_BCM_ZRELADDR=0x8000
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_V6=y
CONFIG_CPU_32v6K=y
CONFIG_CPU_32v6=y

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@ -196,7 +196,6 @@ CONFIG_AT91_EARLY_DBGU=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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@ -97,7 +97,6 @@ CONFIG_MACH_CARMEVA=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM920T=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4T=y

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@ -105,7 +105,6 @@ CONFIG_SA1100_CERF_FLASH_16MB=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_SA1100=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4=y

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@ -236,7 +236,6 @@ CONFIG_MACH_CM_T35=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_32v6K=y
CONFIG_CPU_V7=y
CONFIG_CPU_32v7=y

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@ -205,7 +205,6 @@ CONFIG_PXA_SSP=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSCALE=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -247,7 +247,6 @@ CONFIG_PLAT_PXA=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSC3=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -204,7 +204,6 @@ CONFIG_PXA27x=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSCALE=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -212,7 +212,6 @@ CONFIG_PXA3xx=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSC3=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -125,7 +125,6 @@ CONFIG_SA1100_COLLIE=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_SA1100=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4=y

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@ -214,7 +214,6 @@ CONFIG_PXA_HAVE_BOARD_IRQS=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSCALE=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -229,7 +229,6 @@ CONFIG_AT91_EARLY_DBGU=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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@ -219,7 +219,6 @@ CONFIG_AT91_EARLY_DBGU=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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@ -230,7 +230,6 @@ CONFIG_AT91_EARLY_DBGU=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM920T=y
CONFIG_CPU_32v4T=y
CONFIG_CPU_ABRT_EV4T=y

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@ -193,7 +193,6 @@ CONFIG_AT91_TIMER_HZ=128
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM920T=y
CONFIG_CPU_32v4T=y
CONFIG_CPU_ABRT_EV4T=y

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@ -215,7 +215,6 @@ CONFIG_AT91_EARLY_DBGU=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM920T=y
CONFIG_CPU_32v4T=y
CONFIG_CPU_ABRT_EV4T=y

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@ -225,7 +225,6 @@ CONFIG_DAVINCI_RESET_CLOCKS=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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@ -223,7 +223,6 @@ CONFIG_DAVINCI_RESET_CLOCKS=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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@ -186,7 +186,6 @@ CONFIG_PLAT_ORION=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_V6=y
CONFIG_CPU_32v6K=y
CONFIG_CPU_32v6=y

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@ -83,7 +83,6 @@ CONFIG_ARCH_EBSA110=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_SA110=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4=y

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@ -186,7 +186,6 @@ CONFIG_AT91_PROGRAMMABLE_CLOCKS=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM920T=y
CONFIG_CPU_32v4T=y
CONFIG_CPU_ABRT_EV4T=y

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@ -90,7 +90,6 @@ CONFIG_ARCH_EP7211=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM720T=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_LV4T=y

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@ -202,7 +202,6 @@ CONFIG_PXA_SSP=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSCALE=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -198,7 +198,6 @@ CONFIG_EP93XX_EARLY_UART1=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM920T=y
CONFIG_CPU_32v4T=y
CONFIG_CPU_ABRT_EV4T=y

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@ -203,7 +203,6 @@ CONFIG_PXA_HAVE_BOARD_IRQS=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSCALE=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -240,7 +240,6 @@ CONFIG_PLAT_PXA=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSCALE=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -95,7 +95,6 @@ CONFIG_ARCH_EBSA285=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_SA110=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4=y

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@ -88,7 +88,6 @@ CONFIG_ARCH_FORTUNET=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM720T=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_LV4T=y

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@ -205,7 +205,6 @@ CONFIG_SA1100_H3600=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_SA1100=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4=y

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@ -206,7 +206,6 @@ CONFIG_PXA25x=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSCALE=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -87,7 +87,6 @@ CONFIG_CPU_H7201=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM720T=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_LV4T=y

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@ -91,7 +91,6 @@ CONFIG_CPU_H7202=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM720T=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_LV4T=y

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@ -103,7 +103,6 @@ CONFIG_SA1100_HACKKIT=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_SA1100=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4=y

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@ -241,7 +241,6 @@ CONFIG_OMAP_ARM_195MHZ=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM925T=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v4T=y

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@ -238,7 +238,6 @@ CONFIG_MACH_IGEP0020=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_32v6K=y
CONFIG_CPU_V7=y
CONFIG_CPU_32v7=y

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@ -92,7 +92,6 @@ CONFIG_ARCH_INTEGRATOR_AP=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM720T=y
CONFIG_CPU_ARM920T=y
# CONFIG_CPU_ARM922T is not set

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@ -163,7 +163,6 @@ CONFIG_PLAT_IOP=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSC3=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -168,7 +168,6 @@ CONFIG_PLAT_IOP=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSCALE=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -198,7 +198,6 @@ CONFIG_PLAT_IOP=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSCALE=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -151,7 +151,6 @@ CONFIG_ARCH_IXDP2X01=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSCALE=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -145,7 +145,6 @@ CONFIG_MACH_ROADRUNNER=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSC3=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -189,7 +189,6 @@ CONFIG_IXP4XX_NPE=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSCALE=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -202,7 +202,6 @@ CONFIG_SA1100_SSP=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_SA1100=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4=y

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@ -132,7 +132,6 @@ CONFIG_MACH_KAFA=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM920T=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4T=y

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@ -230,7 +230,6 @@ CONFIG_AT91_EARLY_DBGU=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM920T=y
CONFIG_CPU_32v4T=y
CONFIG_CPU_ABRT_EV4T=y

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@ -201,7 +201,6 @@ CONFIG_PLAT_ORION=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_FEROCEON=y
# CONFIG_CPU_FEROCEON_OLD_ID is not set
CONFIG_CPU_32v5=y

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@ -186,7 +186,6 @@ CONFIG_MACH_DSM320=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM922T=y
CONFIG_CPU_32v4T=y
CONFIG_CPU_ABRT_EV4T=y

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@ -99,7 +99,6 @@ CONFIG_SA1100_LART=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_SA1100=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4=y

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@ -174,7 +174,6 @@ CONFIG_PLAT_ORION=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_FEROCEON=y
# CONFIG_CPU_FEROCEON_OLD_ID is not set
CONFIG_CPU_32v5=y

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@ -143,7 +143,6 @@ CONFIG_PXA27x=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSCALE=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -95,7 +95,6 @@ CONFIG_LPD7A40X_CPLD_SSP=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM922T=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4T=y

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@ -117,7 +117,6 @@ CONFIG_ARCH_LH7A404=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM922T=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4T=y

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@ -92,7 +92,6 @@ CONFIG_PXA25x=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSCALE=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -82,7 +82,6 @@ CONFIG_ARCH_L7200=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM720T=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_LV4T=y

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@ -204,7 +204,6 @@ CONFIG_PXA_HAVE_BOARD_IRQS=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSCALE=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -93,7 +93,6 @@ CONFIG_IWMMXT=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_XSCALE=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5T=y

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@ -256,7 +256,6 @@ CONFIG_MACH_MINI2440=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM920T=y
CONFIG_CPU_32v4T=y
CONFIG_CPU_ABRT_EV4T=y

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@ -155,7 +155,6 @@ CONFIG_MSM_SMD=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_V6=y
# CONFIG_CPU_32v6K is not set
CONFIG_CPU_32v6=y

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@ -181,7 +181,6 @@ CONFIG_PLAT_ORION=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_FEROCEON=y
CONFIG_CPU_FEROCEON_OLD_ID=y
CONFIG_CPU_32v5=y

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@ -190,7 +190,6 @@ CONFIG_MXC_IRQ_PRIOR=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM920T=y
CONFIG_CPU_32v4T=y
CONFIG_CPU_ABRT_EV4T=y

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@ -88,7 +88,6 @@ CONFIG_ARCH_MX1ADS=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM920T=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4T=y

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@ -185,7 +185,6 @@ CONFIG_MXC_PWM=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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@ -207,7 +207,6 @@ CONFIG_MXC_PWM=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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@ -173,7 +173,6 @@ CONFIG_MACH_MX31_3DS=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_V6=y
# CONFIG_CPU_32v6K is not set
CONFIG_CPU_32v6=y

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@ -218,7 +218,6 @@ CONFIG_ARCH_MXC_IOMUX_V3=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_V6=y
# CONFIG_CPU_32v6K is not set
CONFIG_CPU_32v6=y

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@ -210,7 +210,6 @@ CONFIG_OMAP_ARM_216MHZ=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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@ -232,7 +232,6 @@ CONFIG_MACH_NOKIA_N8X0=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_V6=y
# CONFIG_CPU_32v6K is not set
CONFIG_CPU_32v6=y

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@ -218,7 +218,6 @@ CONFIG_AT91_EARLY_DBGU=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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@ -103,7 +103,6 @@ CONFIG_ASSABET_NEPONSET=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_SA1100=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4=y

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@ -89,7 +89,6 @@ CONFIG_FOOTBRIDGE_HOST=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_SA110=y
CONFIG_CPU_32v4=y
CONFIG_CPU_ABRT_EV4=y

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@ -122,7 +122,6 @@ CONFIG_MACH_NXEB500HMI=y
#
# Processor Type
#
CONFIG_CPU_32=y
CONFIG_CPU_ARM926T=y
CONFIG_CPU_32v5=y
CONFIG_CPU_ABRT_EV5TJ=y

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