blob: a38dee3d815b973e6bafe87fe861d465b383a858 [file] [log] [blame]
.. SPDX-License-Identifier: GPL-2.0
==========================================
Dynamic Thermal Power Management framework
==========================================
On the embedded world, the complexity of the SoC leads to an
increasing number of hotspots which need to be monitored and mitigated
as a whole in order to prevent the temperature to go above the
normative and legally stated 'skin temperature'.
Another aspect is to sustain the performance for a given power budget,
for example virtual reality where the user can feel dizziness if the
performance is capped while a big CPU is processing something else. Or
reduce the battery charging because the dissipated power is too high
compared with the power consumed by other devices.
The user space is the most adequate place to dynamically act on the
different devices by limiting their power given an application
profile: it has the knowledge of the platform.
The Dynamic Thermal Power Management (DTPM) is a technique acting on
the device power by limiting and/or balancing a power budget among
different devices.
The DTPM framework provides an unified interface to act on the
device power.
Overview
========
The DTPM framework relies on the powercap framework to create the
powercap entries in the sysfs directory and implement the backend
driver to do the connection with the power manageable device.
The DTPM is a tree representation describing the power constraints
shared between devices, not their physical positions.
The nodes of the tree are a virtual description aggregating the power
characteristics of the children nodes and their power limitations.
The leaves of the tree are the real power manageable devices.
For instance::
SoC
|
`-- pkg
|
|-- pd0 (cpu0-3)
|
`-- pd1 (cpu4-5)
The pkg power will be the sum of pd0 and pd1 power numbers::
SoC (400mW - 3100mW)
|
`-- pkg (400mW - 3100mW)
|
|-- pd0 (100mW - 700mW)
|
`-- pd1 (300mW - 2400mW)
When the nodes are inserted in the tree, their power characteristics are propagated to the parents::
SoC (600mW - 5900mW)
|
|-- pkg (400mW - 3100mW)
| |
| |-- pd0 (100mW - 700mW)
| |
| `-- pd1 (300mW - 2400mW)
|
`-- pd2 (200mW - 2800mW)
Each node have a weight on a 2^10 basis reflecting the percentage of power consumption along the siblings::
SoC (w=1024)
|
|-- pkg (w=538)
| |
| |-- pd0 (w=231)
| |
| `-- pd1 (w=794)
|
`-- pd2 (w=486)
Note the sum of weights at the same level are equal to 1024.
When a power limitation is applied to a node, then it is distributed along the children given their weights. For example, if we set a power limitation of 3200mW at the 'SoC' root node, the resulting tree will be::
SoC (w=1024) <--- power_limit = 3200mW
|
|-- pkg (w=538) --> power_limit = 1681mW
| |
| |-- pd0 (w=231) --> power_limit = 378mW
| |
| `-- pd1 (w=794) --> power_limit = 1303mW
|
`-- pd2 (w=486) --> power_limit = 1519mW
Flat description
----------------
A root node is created and it is the parent of all the nodes. This
description is the simplest one and it is supposed to give to user
space a flat representation of all the devices supporting the power
limitation without any power limitation distribution.
Hierarchical description
------------------------
The different devices supporting the power limitation are represented
hierarchically. There is one root node, all intermediate nodes are
grouping the child nodes which can be intermediate nodes also or real
devices.
The intermediate nodes aggregate the power information and allows to
set the power limit given the weight of the nodes.
User space API
==============
As stated in the overview, the DTPM framework is built on top of the
powercap framework. Thus the sysfs interface is the same, please refer
to the powercap documentation for further details.
* power_uw: Instantaneous power consumption. If the node is an
intermediate node, then the power consumption will be the sum of all
children power consumption.
* max_power_range_uw: The power range resulting of the maximum power
minus the minimum power.
* name: The name of the node. This is implementation dependent. Even
if it is not recommended for the user space, several nodes can have
the same name.
* constraint_X_name: The name of the constraint.
* constraint_X_max_power_uw: The maximum power limit to be applicable
to the node.
* constraint_X_power_limit_uw: The power limit to be applied to the
node. If the value contained in constraint_X_max_power_uw is set,
the constraint will be removed.
* constraint_X_time_window_us: The meaning of this file will depend
on the constraint number.
Constraints
-----------
* Constraint 0: The power limitation is immediately applied, without
limitation in time.
Kernel API
==========
Overview
--------
The DTPM framework has no power limiting backend support. It is
generic and provides a set of API to let the different drivers to
implement the backend part for the power limitation and create the
power constraints tree.
It is up to the platform to provide the initialization function to
allocate and link the different nodes of the tree.
A special macro has the role of declaring a node and the corresponding
initialization function via a description structure. This one contains
an optional parent field allowing to hook different devices to an
already existing tree at boot time.
For instance::
struct dtpm_descr my_descr = {
.name = "my_name",
.init = my_init_func,
};
DTPM_DECLARE(my_descr);
The nodes of the DTPM tree are described with dtpm structure. The
steps to add a new power limitable device is done in three steps:
* Allocate the dtpm node
* Set the power number of the dtpm node
* Register the dtpm node
The registration of the dtpm node is done with the powercap
ops. Basically, it must implements the callbacks to get and set the
power and the limit.
Alternatively, if the node to be inserted is an intermediate one, then
a simple function to insert it as a future parent is available.
If a device has its power characteristics changing, then the tree must
be updated with the new power numbers and weights.
Nomenclature
------------
* dtpm_alloc() : Allocate and initialize a dtpm structure
* dtpm_register() : Add the dtpm node to the tree
* dtpm_unregister() : Remove the dtpm node from the tree
* dtpm_update_power() : Update the power characteristics of the dtpm node