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><H1

><A

NAME="POWER-INTRO">Introduction</H1

><DIV

CLASS="REFNAMEDIV"

><A

NAME="AEN15587"

></A

><H2

>Name</H2

>Introduction&nbsp;--&nbsp;eCos support for Power Management</DIV

><DIV

CLASS="REFSECT1"

><A

NAME="POWER-INTRO-INTRO"

></A

><H2

>Introduction</H2

><P

>The eCos Power Management package provides a framework for

incorporating power management facilities in an embedded application.

However its functionality is deliberately limited.</P

><P

></P

><OL

TYPE="1"

><LI

><P

>The package does not contain any support for controlling the current

power mode of any given processor, device or board. Instead it is the

responsibility of the appropriate HAL or device driver package to

implement such support, by implementing <I

CLASS="FIRSTTERM"

>power

controllers</I

>. The power management package groups these

power controllers together and provides an interface for manipulating

them.</P

></LI

><LI

><P

>The package does not contain any power management policy support.

Specifically, including this package in an application does not by

itself ever cause the system to go into low-power mode. Instead it is

the responsibility of a separate policy module, provided by

higher-level application code or by some other package, to decide when

it would be appropriate to switch from one power mode to another. The

power management package then provides the mechanisms for making it

happen.</P

></LI

></OL

></DIV

><DIV

CLASS="REFSECT1"

><A

NAME="POWER-INTRO-INCLUDE"

></A

><H2

>Including Power Management</H2

><P

>The power management package is never included automatically in an

eCos configuration: it is not part of any target specification or of

any template. Instead it must be added explicitly to a configuration

if the intended application requires power management functionality.

When using the command-line <B

CLASS="COMMAND"

>ecosconfig</B

> tool this

can be achieved using a command such as:</P

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="SCREEN"

>$ ecosconfig add power</PRE

></TD

></TR

></TABLE

><P

>The generic eCos user documentation should be consulted for more

information on how to use the various tools. The functionality

provided by the power management package is defined in the header file

<TT

CLASS="FILENAME"

>cyg/power/power.h</TT

>. This header

file can be used by both C and C++ code.</P

></DIV

><DIV

CLASS="REFSECT1"

><A

NAME="POWER-INTRO-MODES"

></A

><H2

>Power Modes</H2

><P

>There are four defined modes of operation:</P

><P

></P

><DIV

CLASS="VARIABLELIST"

><DL

><DT

>active</DT

><DD

><P

>The system is fully operational, and power consumption is expected to

be high.</P

></DD

><DT

>idle</DT

><DD

><P

>There has been little or no activity for a short period of time. It is

up to the policy module to determine what constitutes a short period

of time, but typically it will be some tenths of a second or some

small number of seconds. A possible action when entering idle mode is

to reduce the system's clock speed, thus reducing the power drawn by

the cpu.</P

><P

>Note that typically this power mode is not entered automatically

whenever the idle thread starts running. Instead it is entered when

the policy module discovers that for a certain period of time the

system has been spending most of its time in the idle thread.

Theoretically it is possible to implement a policy module that would

cause a switch to idle mode as soon as the idle thread starts running,

but that could result in a great many power mode changes for no

immediate benefit.</P

></DD

><DT

>sleep</DT

><DD

><P

>The system has been idle for a significant period of time, perhaps

some tens of seconds. It is desirable to shut down any hardware that

is drawing a significant amount of power, for example a screen

backlight.</P

></DD

><DT

>off</DT

><DD

><P

>The system is powered down. Power consumption should be minimized.

Some special action may be needed before the system comes back up, for

example the user may need to press a specific button.</P

></DD

></DL

></DIV

><P

>The exact transitions that will happen are decided by the policy

module. One policy module might include transitions from active to

idle, from idle to sleep, from sleep to off, and from any of idle,

sleep or off directly back to active. Another policy module might

only use the active and off states, bypassing the intermediate ones.</P

></DIV

><DIV

CLASS="REFSECT1"

><A

NAME="POWER-INTRO-CONTROLLERS"

></A

><H2

>Power Controllers</H2

><P

>The power management package operates primarily on power controllers.

The main functionality provided by a power controller is to switch the

power mode for some part of the system, for example the lcd display or

the cpu. A power controller consists primarily of a function which

will be invoked to switch the power mode for the part of the overall

system being controlled, plus some auxiliary data. A typical system

will include a number of different power controllers:</P

><P

></P

><OL

TYPE="1"

><LI

><P

>Usually there will be one power controller

<TT

CLASS="VARNAME"

>power_controller_cpu</TT

> associated with the processor

or with the target platform, and provided by the corresponding HAL

package. It is this controller which is responsible for switching off

the system when entering the <SPAN

CLASS="TYPE"

>off</SPAN

> mode, which makes it

somewhat special: attempting to switch off the cpu before other

devices like the lcd display does not make sense because the cpu would

no longer be executing any instructions for the latter operation.

Therefore this power controller has to be invoked last when switching

to a lower-power mode, and similarly when switching back to a

higher-power mode it will be invoked first.</P

><P

>It should be noted that providing power management support is not a

hard requirement when porting eCos to a new processor or platform, and

many eCos ports predate the availability of power management support.

Therefore for any given platform it is distinctly possible that

<TT

CLASS="VARNAME"

>power_controller_cpu</TT

> is not yet provided, and if

full power management functionality is desired then the appropriate

HAL package would have to be extended first. System developers should

examine the relevant HAL documentation and sources to determine what

is actually available.</P

></LI

><LI

><P

>Some or all of the device drivers will supply their own power

controllers, as part of the device driver package. It is not required

that all device drivers provide power controllers. In some cases,

especially for devices that are integrated with the processor,

<TT

CLASS="VARNAME"

>power_controller_cpu</TT

> will take care of the

integrated devices as a side effect. In other cases the hardware may

not provide any functionality that allows power consumption to be

controlled. For any given device driver it is also possible that no

power controller exists either because it was not required when the

driver was written, or because the driver predates the availability of

power management. Again the relevant documentation and sources should

be consulted for further information.</P

></LI

><LI

><P

>There may be power controllers which are not associated directly with

any specific hardware. For example a TCP/IP stack could provide a

power controller so that it gets informed when the system has been

reactivated: by looking at the system clock it can determine for how

long the system has been switched off; using this information it can

then recover from expired dhcp leases, or even to shut down any stream

connections that may have become invalid (although arguably the stack

should have refused to go to <SPAN

CLASS="TYPE"

>off</SPAN

> mode while there were

open connections).</P

></LI

></OL

></DIV

><DIV

CLASS="REFSECT1"

><A

NAME="POWER-INTRO-OPERATION"

></A

><H2

>Basic Operation</H2

><P

>By default the Power Management package creates a thread during

initialization. It is also possible for the package to be used without

such a thread, for example in configurations which do not include a

full kernel, and this alternative is described below. When a separate

thread is used the stacksize and priority for this thread can be

controlled by configuration options

<TT

CLASS="VARNAME"

>CYGNUM_POWER_THREAD_STACKSIZE</TT

> and

<TT

CLASS="VARNAME"

>CYGNUM_POWER_THREAD_PRIORITY</TT

>. Typically the thread

will just wait on a semaphore internal to the package, and will do

nothing until some other part of the system requests a change to the

power mode.</P

><P

>At some point the policy module will decide that the system should

move into a lower-power mode, for example from active to idle. This is

achieved by calling the function <TT

CLASS="FUNCTION"

>power_set_mode</TT

>,

provided by the power management package and declared in <TT

CLASS="FILENAME"

>cyg/power/power.h</TT

>, with a single

argument, <TT

CLASS="LITERAL"

>PowerMode_Idle</TT

>. This function manipulates

some internal state and posts the semaphore, thus waking up the power

management thread. Note that the function returns before the mode

change has completed, and in fact depending on thread priorities this

return may happen before any power controller has been invoked.</P

><P

>When the power management thread wakes up it examines the internal

state to figure out what it should be doing. In this case it is

supposed to change the global power mode, so it will iterate over all

the power controllers requesting each one to switch to the

<SPAN

CLASS="TYPE"

>idle</SPAN

> mode. It is up to each power controller to handle

this request appropriately. Optionally the thread will invoke a

callback function after processing each power controller, so that

higher-level code such as the policy module can more easily keep

track of the actual state of each controller. Once the thread has

iterated through all the power controllers it will again wait on the

internal semaphore for the next request to arrive.</P

><DIV

CLASS="NOTE"

><BLOCKQUOTE

CLASS="NOTE"

><P

><B

>Note: </B

>At present the power management thread always runs at a single

priority, which defaults to a low priority. A possible future

enhancement would be to support two separate priorities. When

switching to a lower-powered mode the thread would run at a low

priority as before, thus allowing other threads to run and get a

chance to cancel this mode change. When switching to a higher-powered

mode the thread would run at a high priority. This could be especially

important when moving out of the <SPAN

CLASS="TYPE"

>off</SPAN

> state: for example

it would ensure that all device drivers get a chance to wake up before

ordinary application threads get to run again and possibly attempt I/O

operations.</P

></BLOCKQUOTE

></DIV

><P

>Although usually calls to <TT

CLASS="FUNCTION"

>power_set_mode</TT

> will

come from just one place in the policy module, this is not a hard

requirement. It is possible for multiple threads to call this

function, with no need for any synchronization. If the power

management thread is in the middle of performing a mode change and a

new request comes in, the thread will detect this, abort the current

operation, and start iterating through the power controllers again

with the new mode. This check happens between every power controller

invocation. Usefully this makes it possible for power controllers

themselves to manipulate power modes: a power controller is invoked to

change mode; for some reason it determines that the new mode is

inappropriate; it calls <TT

CLASS="FUNCTION"

>power_set_mode</TT

> to move

the system back to another mode; when the power controller returns

this event will be detected; the power management thread will abort

the current mode change, and start the new one.</P

><P

>In addition to changing the power mode for the system as a whole,

individual controllers can be manipulated using the function

<TT

CLASS="FUNCTION"

>power_set_controller_mode</TT

>. For example, while the

system as a whole might be in <SPAN

CLASS="TYPE"

>active</SPAN

> mode certain devices

might be kept in <SPAN

CLASS="TYPE"

>sleep</SPAN

> mode until they are explicitly

activated. It is possible to mix concurrent calls to

<TT

CLASS="FUNCTION"

>power_set_mode</TT

> and

<TT

CLASS="FUNCTION"

>power_set_controller_mode</TT

>, and when a power

controller is invoked it may use

<TT

CLASS="FUNCTION"

>power_set_controller_mode</TT

> to request further

changes to its own or to another controller's mode as required.</P

><P

>There are some scenarios where the power management package should not

use its own thread. One scenario is if the configuration is

specifically for a single-threaded application such as RedBoot.

Another scenario is if the policy module already involves a separate

thread: it may make more sense if the various power management

operations are synchronous with respect to the calling thread. The use

of a separate thread inside the power management package is controlled

by the configuration option <TT

CLASS="VARNAME"

>CYGPKG_POWER_THREAD</TT

>,

which is active only if the kernel package is present and enabled by

default.</P

><P

>If no separate power management thread is used then obviously the

implementations of <TT

CLASS="FUNCTION"

>power_set_mode</TT

> and

<TT

CLASS="FUNCTION"

>power_set_controller_mode</TT

> will be somewhat

different: instead of waking up a separate thread to do the work,

these functions will now manipulate the power controllers directly. If

the system does still involve multiple threads then only one thread

may call <TT

CLASS="FUNCTION"

>power_set_mode</TT

> or

<TT

CLASS="FUNCTION"

>power_set_controller_mode</TT

> at a time: the power

management package will not provide any synchronization, that must

happen at a higher level. However when a power controller is invoked

it can still call these functions as required.</P

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