I'd like to request for review and advice for the central regulatory
domain agent (CRDA) we have been working towards in the Linux 802.11
subsystem. I'm including linux-kernel in hopes of a wider review.
Particularly I'd like advice on the best path we can take for the
userspace agent which *could* eventually be required upon userspace,
meaning *most* distributions will package it if they want decent
regulatory 802.11 support. But first let me begin with a brief
overview of the concept of a CRDA, the case for it, and patches
submitted and reviewed so far.
* Central regulatory domain agents - a case for it
Contrary to all other drivers in the different subsystems in the
kernel, 802.11 drivers have local regulatory laws to take into
consideration for operation. To this day, due mainly to certification
requirements, vendors have taken it upon themselves to make their
hardware adhere to all regulatory regions their devices will be sold
in. These requirements are now implemented in software on the host
driver or firmware of the device. The reason for this is to enable the
design of one 802.11 chipset with capabilities to operate in different
geographical regions to reduce the cost of manufacturing, bring down
the price of the products sold, and allow users to make use of their
802.11 devices in different countries they may go to. Another shift in
market trends we are seeing is that of vendors moving away from a
FullMAC [1] design model to a SoftMAC [2] design model for most their
802.11 chipsets; development-wise this means the drivers receive raw
802.11 frames instead of Ethernet frames and hence the need for
mac80211, which provides a driver API to such type of devices and
implements a basic STA MLME [3] in-kernel. Some SoftMAC devices also
require complete regulatory control within the host driver. Some of
these drivers end up implementing their own regulatory domain control
and data structures. Except for the vendor-specific components of the
code, usually frequency, power values and sometimes regulatory domain
values, all of this code can instead be centralized as part of he
802.11 subsystem and shared amongst all the 802.11 drivers. This code
sharing would provide a centralized regulatory domain control for
devices which require regulatory domain control on the host, and
additionally provide *enhanced effort* on our part in the operating
system for compliance to local regulatory laws for devices which may
have *out-of-date rules* or *buggy* regulatory domain control code.
The above just addresses the present. What lies ahead for wireless
seems to be making wireless devices smarter, more interoperable, but
always compliant to local regulatory laws. Software Defined Radios
(SDRs) [4] are a breed of wireless devices which are under the horizon
and depending on the definition of an SDR used, can be considered to
already be used and sold in the 802.11 market. Regulatory laws on SDR
are relatively new and are still under review and vary depending upon
geographical region. For example, the "The Software Freedom Law Center
(SFLC) has examined the Federal Communication Commission's (FCC)
rules", which when into into effect on July 6, 2007, "governing
Software Defined Radio (SDR) devices and concluded that the rules do
not restrict the activities of independent developers and distributors
of Free and Open Source Software (FOSS) designed for use with SDR
devices." [5] It also found that the "FCC's SDR rules create an
opportunity for wireless hardware manufacturers, the FOSS community,
and the FCC to communicate openly and productively about the ability
of public disclosure and open standards to strengthen the security and
robustness of wireless devices." With this in mind I think it is
important to try to help the vendors achieve compliance with local
regulatory laws and still remain compliant by supporting FOSS. Its
arguable if this is possible or not, but let us please not get into
this now; what I believe is more important is that we pave the way for
the best technology possible for regulatory rules for 802.11 and also
SDRs. A strong CRDA goes hand-in-hand with advancing SDRs as the
attributes can be expanded as the technology does -- more modulations
supported, different bands added, and so forth. Additionally a
Frequency Broker [6] (note: this link is old and needs some updating
but has the general idea) can later be added to register frequencies,
power level, modulations which each wireless device present on a host
is using to help with interoperability.
A CRDA together with a Frequency Broker can therefore eliminate
redundant regulatory domain code on host drivers, provide a convenient
mechanism to update regulatory rules, and enhance interoperability
between different type of wireless devices.
* Implementation of the CRDA
I posted my first series on October of 2006 [7] however the first
series stuffed everything into the kernel, the data structures were
overly complex, and no solid integration with mac80211 (d80211 then)
was provided [8]. The second series, posted on September of 2007 [9],
still left everything in the kernel, was more simplified and had
integration with mac80211 and cfg80211, additionally zd1211rw was
ported to the new framework and tested. After some discussion one the
lists and IRC it was determined we should just move the database of
regulatory domains into userspace and have just one regulatory domain
defined in kernel space at a time. Userspace can then pass to kernel
space a regulatory domain via the new nl80211. 802.11 devices can then
register with cfg80211 its hardware capabilities and only allowed
"channels" will be enabled, all others will be disabled. We can keep
two standard regulatory domains in kernel space, however: a world
regulatory domain which is a common denominator of all regulatory law
-- its basically FCC with relaxed power requirements and no 5 GHz
communication -- and a debug regulatory domain which enables
everything.
The regulatory domain used on the 802.11 subsystem will reflect the
user's latest selected preference if one is set (this will override
all settings), an 802.11 card's EEPROM reading, or country defined by
an 802.11d country information element broadcast by a local access
point (depending upon configuration and preferences).
* Request for advice:
cfg80211 can take the "installed" regulatory domain and only enable
power settings / frequency settings dependent upon current defined
regulatory rules. But in order to install a regulatory domain into the
kernel we need userspace to upload it via nl80211. This is easily
accomplished once userspace has one defined via structures defined in
nl80211 for a regulatory domain. Regulatory domain rules vary,
however, and I expect users to contribute on expanding the rules to be
as accurate as possible. As such it *is* expected that as time goes by
userspace will have rules updated, attributes added (will go
hand-in-hand with nl80211 updates), or completely new regulatory
domains defined. We therefore need a way to keep a database of
regulatory domains, and a way to parse this database to finally hand
to the kernel the desired regulatory domain.
My initial take on this was to use a berkely db or sqlite db for the
database and keep this local on hosts, however this would enforce
certain package requirements upon most installations and do not think
that's the best approach. Another approach is to keep the real
database only on some development machines and let people send updates
to it as well as view the database online. An output of the database
can then be dumped as a flat file to a host in some format. The
regulatory daemon would then parse this flat file and upon changes to
the file update its local database of regulatory domains. I'd like
feedback on suggestions for the file format used which would keep
distributions requirements at a minimal. If there is some extremely
light weight and acceptable database and database API most of us
wouldn't mind seeing on most installs please name them too (although I
don't think this is really a good idea).
My preference is to keep the real database on a development box which
has some web interface which people can use to view. Ideally users can
then send updates to the database to provide updates to rules. The
database can then be dumped and an application used to generate some
flat file. Distributions can then pick this flat file up and propagate
it to users. A user's host would have the CRDA userspace daemon
running, and once a new file is downloaded the regulatory daemon is
informed about it. The reg daemon would then parse the flat file and
update its internal database and new regulatory rules would become
available to the kernel. What I am not sure on is the best format to
use for the flat file.
Thanks in advance,
Luis
[1] http://linuxwireless.org/en/developers/Documentation/Glossary#FullMAC
[2] http://linuxwireless.org/en/developers/Documentation/Glossary#SoftMAC
[3] http://linuxwireless.org/en/developers/Documentation/Glossary#MLME
[4] http://en.wikipedia.org/wiki/Software_radio
[5] http://www.softwarefreedom.org/resources/2007/fcc-sdr-whitepaper.html
[6] http://linuxwireless.org/en/developers/FrequencyBroker
[7] http://lwn.net/Articles/205988/
[8] http://lwn.net/Articles/206014/
[9] http://www.kernel.org/pub/linux/kernel/people/mcgrof/v2-regdomain-patches/
On Wednesday 27 February 2008 08:55:50 Luis R. Rodriguez wrote:
> I'd like to request for review and advice for the central regulatory
> domain agent (CRDA) we have been working towards in the Linux 802.11
> subsystem. I'm including linux-kernel in hopes of a wider review.
> Particularly I'd like advice on the best path we can take for the
> userspace agent which *could* eventually be required upon userspace,
> meaning *most* distributions will package it if they want decent
> regulatory 802.11 support. But first let me begin with a brief
> overview of the concept of a CRDA, the case for it, and patches
> submitted and reviewed so far.
>
> * Central regulatory domain agents - a case for it
>
> Contrary to all other drivers in the different subsystems in the
> kernel, 802.11 drivers have local regulatory laws to take into
> consideration for operation. To this day, due mainly to certification
> requirements, vendors have taken it upon themselves to make their
> hardware adhere to all regulatory regions their devices will be sold
> in. These requirements are now implemented in software on the host
> driver or firmware of the device. The reason for this is to enable the
> design of one 802.11 chipset with capabilities to operate in different
> geographical regions to reduce the cost of manufacturing, bring down
> the price of the products sold, and allow users to make use of their
> 802.11 devices in different countries they may go to. Another shift in
> market trends we are seeing is that of vendors moving away from a
> FullMAC [1] design model to a SoftMAC [2] design model for most their
> 802.11 chipsets; development-wise this means the drivers receive raw
> 802.11 frames instead of Ethernet frames and hence the need for
> mac80211, which provides a driver API to such type of devices and
> implements a basic STA MLME [3] in-kernel. Some SoftMAC devices also
> require complete regulatory control within the host driver. Some of
> these drivers end up implementing their own regulatory domain control
> and data structures. Except for the vendor-specific components of the
> code, usually frequency, power values and sometimes regulatory domain
> values, all of this code can instead be centralized as part of he
> 802.11 subsystem and shared amongst all the 802.11 drivers. This code
> sharing would provide a centralized regulatory domain control for
> devices which require regulatory domain control on the host, and
> additionally provide *enhanced effort* on our part in the operating
> system for compliance to local regulatory laws for devices which may
> have *out-of-date rules* or *buggy* regulatory domain control code.
>
> The above just addresses the present. What lies ahead for wireless
> seems to be making wireless devices smarter, more interoperable, but
> always compliant to local regulatory laws. Software Defined Radios
> (SDRs) [4] are a breed of wireless devices which are under the horizon
> and depending on the definition of an SDR used, can be considered to
> already be used and sold in the 802.11 market. Regulatory laws on SDR
> are relatively new and are still under review and vary depending upon
> geographical region. For example, the "The Software Freedom Law Center
> (SFLC) has examined the Federal Communication Commission's (FCC)
> rules", which when into into effect on July 6, 2007, "governing
> Software Defined Radio (SDR) devices and concluded that the rules do
> not restrict the activities of independent developers and distributors
> of Free and Open Source Software (FOSS) designed for use with SDR
> devices." [5] It also found that the "FCC's SDR rules create an
> opportunity for wireless hardware manufacturers, the FOSS community,
> and the FCC to communicate openly and productively about the ability
> of public disclosure and open standards to strengthen the security and
> robustness of wireless devices." With this in mind I think it is
> important to try to help the vendors achieve compliance with local
> regulatory laws and still remain compliant by supporting FOSS. Its
> arguable if this is possible or not, but let us please not get into
> this now; what I believe is more important is that we pave the way for
> the best technology possible for regulatory rules for 802.11 and also
> SDRs. A strong CRDA goes hand-in-hand with advancing SDRs as the
> attributes can be expanded as the technology does -- more modulations
> supported, different bands added, and so forth. Additionally a
> Frequency Broker [6] (note: this link is old and needs some updating
> but has the general idea) can later be added to register frequencies,
> power level, modulations which each wireless device present on a host
> is using to help with interoperability.
>
> A CRDA together with a Frequency Broker can therefore eliminate
> redundant regulatory domain code on host drivers, provide a convenient
> mechanism to update regulatory rules, and enhance interoperability
> between different type of wireless devices.
>
> * Implementation of the CRDA
>
> I posted my first series on October of 2006 [7] however the first
> series stuffed everything into the kernel, the data structures were
> overly complex, and no solid integration with mac80211 (d80211 then)
> was provided [8]. The second series, posted on September of 2007 [9],
> still left everything in the kernel, was more simplified and had
> integration with mac80211 and cfg80211, additionally zd1211rw was
> ported to the new framework and tested. After some discussion one the
> lists and IRC it was determined we should just move the database of
> regulatory domains into userspace and have just one regulatory domain
> defined in kernel space at a time. Userspace can then pass to kernel
> space a regulatory domain via the new nl80211. 802.11 devices can then
> register with cfg80211 its hardware capabilities and only allowed
> "channels" will be enabled, all others will be disabled. We can keep
> two standard regulatory domains in kernel space, however: a world
> regulatory domain which is a common denominator of all regulatory law
> -- its basically FCC with relaxed power requirements and no 5 GHz
> communication -- and a debug regulatory domain which enables
> everything.
>
> The regulatory domain used on the 802.11 subsystem will reflect the
> user's latest selected preference if one is set (this will override
> all settings), an 802.11 card's EEPROM reading, or country defined by
> an 802.11d country information element broadcast by a local access
> point (depending upon configuration and preferences).
>
> * Request for advice:
>
> cfg80211 can take the "installed" regulatory domain and only enable
> power settings / frequency settings dependent upon current defined
> regulatory rules. But in order to install a regulatory domain into the
> kernel we need userspace to upload it via nl80211. This is easily
> accomplished once userspace has one defined via structures defined in
> nl80211 for a regulatory domain. Regulatory domain rules vary,
> however, and I expect users to contribute on expanding the rules to be
> as accurate as possible. As such it *is* expected that as time goes by
> userspace will have rules updated, attributes added (will go
> hand-in-hand with nl80211 updates), or completely new regulatory
> domains defined. We therefore need a way to keep a database of
> regulatory domains, and a way to parse this database to finally hand
> to the kernel the desired regulatory domain.
>
> My initial take on this was to use a berkely db or sqlite db for the
> database and keep this local on hosts, however this would enforce
> certain package requirements upon most installations and do not think
> that's the best approach. Another approach is to keep the real
> database only on some development machines and let people send updates
> to it as well as view the database online. An output of the database
> can then be dumped as a flat file to a host in some format. The
> regulatory daemon would then parse this flat file and upon changes to
> the file update its local database of regulatory domains. I'd like
> feedback on suggestions for the file format used which would keep
> distributions requirements at a minimal. If there is some extremely
> light weight and acceptable database and database API most of us
> wouldn't mind seeing on most installs please name them too (although I
> don't think this is really a good idea).
>
> My preference is to keep the real database on a development box which
> has some web interface which people can use to view. Ideally users can
> then send updates to the database to provide updates to rules. The
> database can then be dumped and an application used to generate some
> flat file. Distributions can then pick this flat file up and propagate
> it to users. A user's host would have the CRDA userspace daemon
> running, and once a new file is downloaded the regulatory daemon is
> informed about it. The reg daemon would then parse the flat file and
> update its internal database and new regulatory rules would become
> available to the kernel. What I am not sure on is the best format to
> use for the flat file.
if at all, i'd suggest a simple binary format for that file. it's not that we
would have to do a lot of searching thru it, so i think something
database-like is not necessary. also it has to be included in embedded
systems so it should be quite small. a text-based approach would make it too
easy for users to change and override regulatory settings. i know the basic
idea is to put the liability to the user, but at the same time i think we
should not make it too easy to alter the regulatory rules.
actually i think the best way to keep and update the regulatory table is as
part of a source tree! instead of building a huge new infrastructure - a
server with a db which users can upload regulatory changes to, a review
process for these changes, a file export for downloading the latest db, a
file format for keeping the db on the host and then parsing them into the
application - why not just maintain the regulatory rules as part of the
source tree and use the processes (version management, peer review) we
already have in place there?
well, which source tree? i don't really know. iw maybe? or would'nt it make
sense to make a library which can be used by iw, wpa_supplicant, hostapd and
other applications alike to access the wireless settings, including
regulatory domains?
bruno
On Tue, Mar 4, 2008 at 9:32 PM, bruno randolf <[email protected]> wrote:
> > My preference is to keep the real database on a development box which
> > has some web interface which people can use to view. Ideally users can
> > then send updates to the database to provide updates to rules. The
> > database can then be dumped and an application used to generate some
> > flat file. Distributions can then pick this flat file up and propagate
> > it to users. A user's host would have the CRDA userspace daemon
> > running, and once a new file is downloaded the regulatory daemon is
> > informed about it. The reg daemon would then parse the flat file and
> > update its internal database and new regulatory rules would become
> > available to the kernel. What I am not sure on is the best format to
> > use for the flat file.
>
> if at all, i'd suggest a simple binary format for that file. it's not that we
> would have to do a lot of searching thru it, so i think something
> database-like is not necessary. also it has to be included in embedded
> systems so it should be quite small. a text-based approach would make it too
> easy for users to change and override regulatory settings. i know the basic
> idea is to put the liability to the user, but at the same time i think we
> should not make it too easy to alter the regulatory rules.
I second a binary file format but not for security purposes -- instead
I second it to reduce the size and make it easily readable to the
regulatory daemon. Although I acknowledge the importance of obeying
local regulatory laws by no means do I think this should interfere
with us coming up with the best possible solution to the problem. I
also envision that down the road we'd want to make it easy to
automatically change current restrictions not due to regulatory rules
but instead to enhance communication dynamically based on currently
read wireless trends in your local environment. We don't want to lock
users but enable them and assist them in obeying local regulatory
laws. Hardware vendors, on the other hand, are currently legally tied
to strictly obeying local regulatory restrictions or at least their
attorney's interpretation of such laws but that doesn't mean that its
right too or that their attorney's interpretation is right. Security
through obscurity simply does not work for restricting devices and
having laws that stick to this philosophy and supporting it deters
technology and communication in the end instead of enhancing them
which IMHO *is* the purpose of regulatory agencies.
> actually i think the best way to keep and update the regulatory table is as
> part of a source tree! instead of building a huge new infrastructure - a
> server with a db which users can upload regulatory changes to, a review
> process for these changes, a file export for downloading the latest db, a
> file format for keeping the db on the host and then parsing them into the
> application - why not just maintain the regulatory rules as part of the
> source tree and use the processes (version management, peer review) we
> already have in place there?
Well the whole notion of using a db was for the purpose of
presentation and for easy review. I'd like to make it easy for
non-developers to contribute changes to the regulatory db. My v2
patches kept regulatory domains in C files in structs which basically
were tables with some sort of shared key. I have to say that while
trying to update them even I found it difficult and sometimes made
easy mistakes. To easily view regulatory domain restrictions I think
what's easiest is some sort of HTML table online for each regulatory
domain.
For patching purposes I think you're right and that its easiest
through patches as that is what we're used to. But I can also see SQL
statements for modifications working or plain English proposals which
maintainers can then translate to SQL or just alter through a DB admin
interface. I guess either way its easy to make mistakes. One way or
another we do need a way to make the db easily visible and we also
need that binary end file. A db seems nice as you can easily query
data and do whatever you want with it. If we keep it in C files a db
database would need to be drop'd and created each time changes are
made. If you don't use a DB I don't know how you can make the
regulatory db easily visible.
> well, which source tree? i don't really know. iw maybe?
Hm, was actually thinking of splitting up some stuff for licensing
purposes. More on this below.
> or would'nt it make
> sense to make a library which can be used by iw, wpa_supplicant, hostapd and
> other applications alike to access the wireless settings, including
> regulatory domains?
Definitely, although I'd like to separate our own tools and the
central reg daemon/libs to reading/parsing reg domains on a binary
file. This is because I'd like to work together with the BSD family on
a decent reg db. I think we can both benefit by working on this
together, just like with radiotap. Operating System-wise the parsing
of the file can remain the same but what we would differ in is what we
do with the info we parse. For example I expect a regdaemon to sit
there and have at its disposal all available regulatory info. Should
we need to change country/regdomain manually we can use iw. iw will
query the regulatory daemon for its desired regulatory domain, return
it to iw and then iw can use nl80211 to upload it to the kernel.
Another example, should an 802.11d frame arrive and the wireless
subsystem accepts it to change regdomain the kernel can query the
regulatory daemon using nl80211 to get its regulatory domain. I would
want the regulatory daemon licensed under the ISC/BSD and our tools
can simply keep with the GPL tradition.
Luis
Hi all.
> Well the whole notion of using a db was for the purpose of
> presentation and for easy review. I'd like to make it easy for
> non-developers to contribute changes to the regulatory db.
How about keeping the master file in a yet-to-be-defined XML format?
It's not too hard to make the webserver display it (via XSLT, some
server-side script or whatever). Even without the webserver being
available it's possible for a human to make sense of the content of the
master file.
Being a text file it can be managed with virtually any version control
system. It's possible to make sense of and understand all recorded changes
without additional tools.
Users of the file could decide to compile the master file from XML into
whatever format their tools prefer. For Linux it would be some binary
format, for the reasons stated earlier in this thread. Other OS/users
might decide on something else, even on using the master file as is.
The compiler could use a standard XML library, making it easy for
distributors to satisfy the dependencies. If necessary it could fall back
on it's own simple XML parser. Support for various output formats could be
implemented as modules or even as plugins.
Just my 2 cents.
Bye, Mike