mirror of https://gitee.com/openkylin/linux.git
449 lines
18 KiB
Plaintext
449 lines
18 KiB
Plaintext
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Linux UWB + Wireless USB + WiNET
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(C) 2005-2006 Intel Corporation
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Inaky Perez-Gonzalez <inaky.perez-gonzalez@intel.com>
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This program is free software; you can redistribute it and/or
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modify it under the terms of the GNU General Public License version
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2 as published by the Free Software Foundation.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program; if not, write to the Free Software
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Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
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02110-1301, USA.
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Please visit http://bughost.org/thewiki/Design-overview.txt-1.8 for
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updated content.
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* Design-overview.txt-1.8
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This code implements a Ultra Wide Band stack for Linux, as well as
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drivers for the USB based UWB radio controllers defined in the
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Wireless USB 1.0 specification (including Wireless USB host controller
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and an Intel WiNET controller).
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1. Introduction
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1. HWA: Host Wire adapters, your Wireless USB dongle
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2. DWA: Device Wired Adaptor, a Wireless USB hub for wired
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devices
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3. WHCI: Wireless Host Controller Interface, the PCI WUSB host
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adapter
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2. The UWB stack
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1. Devices and hosts: the basic structure
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2. Host Controller life cycle
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3. On the air: beacons and enumerating the radio neighborhood
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4. Device lists
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5. Bandwidth allocation
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3. Wireless USB Host Controller drivers
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4. Glossary
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Introduction
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UWB is a wide-band communication protocol that is to serve also as the
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low-level protocol for others (much like TCP sits on IP). Currently
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these others are Wireless USB and TCP/IP, but seems Bluetooth and
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Firewire/1394 are coming along.
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UWB uses a band from roughly 3 to 10 GHz, transmitting at a max of
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~-41dB (or 0.074 uW/MHz--geography specific data is still being
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negotiated w/ regulators, so watch for changes). That band is divided in
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a bunch of ~1.5 GHz wide channels (or band groups) composed of three
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subbands/subchannels (528 MHz each). Each channel is independent of each
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other, so you could consider them different "busses". Initially this
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driver considers them all a single one.
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Radio time is divided in 65536 us long /superframes/, each one divided
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in 256 256us long /MASs/ (Media Allocation Slots), which are the basic
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time/media allocation units for transferring data. At the beginning of
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each superframe there is a Beacon Period (BP), where every device
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transmit its beacon on a single MAS. The length of the BP depends on how
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many devices are present and the length of their beacons.
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Devices have a MAC (fixed, 48 bit address) and a device (changeable, 16
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bit address) and send periodic beacons to advertise themselves and pass
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info on what they are and do. They advertise their capabilities and a
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bunch of other stuff.
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The different logical parts of this driver are:
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*
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*UWB*: the Ultra-Wide-Band stack -- manages the radio and
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associated spectrum to allow for devices sharing it. Allows to
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control bandwidth assignment, beaconing, scanning, etc
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*
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*WUSB*: the layer that sits on top of UWB to provide Wireless USB.
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The Wireless USB spec defines means to control a UWB radio and to
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do the actual WUSB.
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HWA: Host Wire adapters, your Wireless USB dongle
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WUSB also defines a device called a Host Wire Adaptor (HWA), which in
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mere terms is a USB dongle that enables your PC to have UWB and Wireless
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USB. The Wireless USB Host Controller in a HWA looks to the host like a
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[Wireless] USB controller connected via USB (!)
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The HWA itself is broken in two or three main interfaces:
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*
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*RC*: Radio control -- this implements an interface to the
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Ultra-Wide-Band radio controller. The driver for this implements a
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USB-based UWB Radio Controller to the UWB stack.
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*
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*HC*: the wireless USB host controller. It looks like a USB host
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whose root port is the radio and the WUSB devices connect to it.
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To the system it looks like a separate USB host. The driver (will)
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implement a USB host controller (similar to UHCI, OHCI or EHCI)
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for which the root hub is the radio...To reiterate: it is a USB
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controller that is connected via USB instead of PCI.
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*
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*WINET*: some HW provide a WiNET interface (IP over UWB). This
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package provides a driver for it (it looks like a network
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interface, winetX). The driver detects when there is a link up for
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their type and kick into gear.
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DWA: Device Wired Adaptor, a Wireless USB hub for wired devices
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These are the complement to HWAs. They are a USB host for connecting
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wired devices, but it is connected to your PC connected via Wireless
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USB. To the system it looks like yet another USB host. To the untrained
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eye, it looks like a hub that connects upstream wirelessly.
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We still offer no support for this; however, it should share a lot of
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code with the HWA-RC driver; there is a bunch of factorization work that
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has been done to support that in upcoming releases.
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WHCI: Wireless Host Controller Interface, the PCI WUSB host adapter
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This is your usual PCI device that implements WHCI. Similar in concept
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to EHCI, it allows your wireless USB devices (including DWAs) to connect
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to your host via a PCI interface. As in the case of the HWA, it has a
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Radio Control interface and the WUSB Host Controller interface per se.
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There is still no driver support for this, but will be in upcoming
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releases.
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The UWB stack
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The main mission of the UWB stack is to keep a tally of which devices
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are in radio proximity to allow drivers to connect to them. As well, it
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provides an API for controlling the local radio controllers (RCs from
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now on), such as to start/stop beaconing, scan, allocate bandwidth, etc.
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Devices and hosts: the basic structure
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The main building block here is the UWB device (struct uwb_dev). For
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each device that pops up in radio presence (ie: the UWB host receives a
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beacon from it) you get a struct uwb_dev that will show up in
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/sys/class/uwb and in /sys/bus/uwb/devices.
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For each RC that is detected, a new struct uwb_rc is created. In turn, a
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RC is also a device, so they also show in /sys/class/uwb and
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/sys/bus/uwb/devices, but at the same time, only radio controllers show
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up in /sys/class/uwb_rc.
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*
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[*] The reason for RCs being also devices is that not only we can
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see them while enumerating the system device tree, but also on the
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radio (their beacons and stuff), so the handling has to be
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likewise to that of a device.
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Each RC driver is implemented by a separate driver that plugs into the
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interface that the UWB stack provides through a struct uwb_rc_ops. The
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spec creators have been nice enough to make the message format the same
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for HWA and WHCI RCs, so the driver is really a very thin transport that
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moves the requests from the UWB API to the device [/uwb_rc_ops->cmd()/]
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and sends the replies and notifications back to the API
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[/uwb_rc_neh_grok()/]. Notifications are handled to the UWB daemon, that
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is chartered, among other things, to keep the tab of how the UWB radio
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neighborhood looks, creating and destroying devices as they show up or
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disappear.
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Command execution is very simple: a command block is sent and a event
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block or reply is expected back. For sending/receiving command/events, a
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handle called /neh/ (Notification/Event Handle) is opened with
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/uwb_rc_neh_open()/.
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The HWA-RC (USB dongle) driver (drivers/uwb/hwa-rc.c) does this job for
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the USB connected HWA. Eventually, drivers/whci-rc.c will do the same
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for the PCI connected WHCI controller.
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Host Controller life cycle
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So let's say we connect a dongle to the system: it is detected and
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firmware uploaded if needed [for Intel's i1480
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/drivers/uwb/ptc/usb.c:ptc_usb_probe()/] and then it is reenumerated.
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Now we have a real HWA device connected and
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/drivers/uwb/hwa-rc.c:hwarc_probe()/ picks it up, that will set up the
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Wire-Adaptor environment and then suck it into the UWB stack's vision of
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the world [/drivers/uwb/lc-rc.c:uwb_rc_add()/].
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*
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[*] The stack should put a new RC to scan for devices
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[/uwb_rc_scan()/] so it finds what's available around and tries to
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connect to them, but this is policy stuff and should be driven
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from user space. As of now, the operator is expected to do it
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manually; see the release notes for documentation on the procedure.
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When a dongle is disconnected, /drivers/uwb/hwa-rc.c:hwarc_disconnect()/
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takes time of tearing everything down safely (or not...).
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On the air: beacons and enumerating the radio neighborhood
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So assuming we have devices and we have agreed for a channel to connect
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on (let's say 9), we put the new RC to beacon:
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*
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$ echo 9 0 > /sys/class/uwb_rc/uwb0/beacon
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Now it is visible. If there were other devices in the same radio channel
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and beacon group (that's what the zero is for), the dongle's radio
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control interface will send beacon notifications on its
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notification/event endpoint (NEEP). The beacon notifications are part of
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the event stream that is funneled into the API with
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/drivers/uwb/neh.c:uwb_rc_neh_grok()/ and delivered to the UWBD, the UWB
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daemon through a notification list.
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UWBD wakes up and scans the event list; finds a beacon and adds it to
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the BEACON CACHE (/uwb_beca/). If he receives a number of beacons from
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the same device, he considers it to be 'onair' and creates a new device
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[/drivers/uwb/lc-dev.c:uwbd_dev_onair()/]. Similarly, when no beacons
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are received in some time, the device is considered gone and wiped out
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[uwbd calls periodically /uwb/beacon.c:uwb_beca_purge()/ that will purge
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the beacon cache of dead devices].
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Device lists
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All UWB devices are kept in the list of the struct bus_type uwb_bus.
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Bandwidth allocation
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The UWB stack maintains a local copy of DRP availability through
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processing of incoming *DRP Availability Change* notifications. This
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local copy is currently used to present the current bandwidth
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availability to the user through the sysfs file
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/sys/class/uwb_rc/uwbx/bw_avail. In the future the bandwidth
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availability information will be used by the bandwidth reservation
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routines.
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The bandwidth reservation routines are in progress and are thus not
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present in the current release. When completed they will enable a user
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to initiate DRP reservation requests through interaction with sysfs. DRP
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reservation requests from remote UWB devices will also be handled. The
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bandwidth management done by the UWB stack will include callbacks to the
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higher layers will enable the higher layers to use the reservations upon
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completion. [Note: The bandwidth reservation work is in progress and
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subject to change.]
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Wireless USB Host Controller drivers
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*WARNING* This section needs a lot of work!
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As explained above, there are three different types of HCs in the WUSB
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world: HWA-HC, DWA-HC and WHCI-HC.
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HWA-HC and DWA-HC share that they are Wire-Adapters (USB or WUSB
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connected controllers), and their transfer management system is almost
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identical. So is their notification delivery system.
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HWA-HC and WHCI-HC share that they are both WUSB host controllers, so
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they have to deal with WUSB device life cycle and maintenance, wireless
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root-hub
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HWA exposes a Host Controller interface (HWA-HC 0xe0/02/02). This has
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three endpoints (Notifications, Data Transfer In and Data Transfer
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Out--known as NEP, DTI and DTO in the code).
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We reserve UWB bandwidth for our Wireless USB Cluster, create a Cluster
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ID and tell the HC to use all that. Then we start it. This means the HC
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starts sending MMCs.
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*
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The MMCs are blocks of data defined somewhere in the WUSB1.0 spec
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that define a stream in the UWB channel time allocated for sending
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WUSB IEs (host to device commands/notifications) and Device
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Notifications (device initiated to host). Each host defines a
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unique Wireless USB cluster through MMCs. Devices can connect to a
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single cluster at the time. The IEs are Information Elements, and
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among them are the bandwidth allocations that tell each device
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when can they transmit or receive.
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Now it all depends on external stimuli.
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*New device connection*
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A new device pops up, it scans the radio looking for MMCs that give out
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the existence of Wireless USB channels. Once one (or more) are found,
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selects which one to connect to. Sends a /DN_Connect/ (device
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notification connect) during the DNTS (Device Notification Time
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Slot--announced in the MMCs
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HC picks the /DN_Connect/ out (nep module sends to notif.c for delivery
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into /devconnect/). This process starts the authentication process for
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the device. First we allocate a /fake port/ and assign an
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unauthenticated address (128 to 255--what we really do is
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0x80 | fake_port_idx). We fiddle with the fake port status and /khubd/
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sees a new connection, so he moves on to enable the fake port with a reset.
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So now we are in the reset path -- we know we have a non-yet enumerated
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device with an unauthorized address; we ask user space to authenticate
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(FIXME: not yet done, similar to bluetooth pairing), then we do the key
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exchange (FIXME: not yet done) and issue a /set address 0/ to bring the
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device to the default state. Device is authenticated.
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From here, the USB stack takes control through the usb_hcd ops. khubd
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has seen the port status changes, as we have been toggling them. It will
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start enumerating and doing transfers through usb_hcd->urb_enqueue() to
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read descriptors and move our data.
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*Device life cycle and keep alives*
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Every time there is a successful transfer to/from a device, we update a
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per-device activity timestamp. If not, every now and then we check and
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if the activity timestamp gets old, we ping the device by sending it a
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Keep Alive IE; it responds with a /DN_Alive/ pong during the DNTS (this
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arrives to us as a notification through
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devconnect.c:wusb_handle_dn_alive(). If a device times out, we
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disconnect it from the system (cleaning up internal information and
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toggling the bits in the fake hub port, which kicks khubd into removing
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the rest of the stuff).
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This is done through devconnect:__wusb_check_devs(), which will scan the
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device list looking for whom needs refreshing.
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If the device wants to disconnect, it will either die (ugly) or send a
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/DN_Disconnect/ that will prompt a disconnection from the system.
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*Sending and receiving data*
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Data is sent and received through /Remote Pipes/ (rpipes). An rpipe is
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/aimed/ at an endpoint in a WUSB device. This is the same for HWAs and
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DWAs.
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Each HC has a number of rpipes and buffers that can be assigned to them;
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when doing a data transfer (xfer), first the rpipe has to be aimed and
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prepared (buffers assigned), then we can start queueing requests for
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data in or out.
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Data buffers have to be segmented out before sending--so we send first a
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header (segment request) and then if there is any data, a data buffer
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immediately after to the DTI interface (yep, even the request). If our
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buffer is bigger than the max segment size, then we just do multiple
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requests.
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[This sucks, because doing USB scatter gatter in Linux is resource
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intensive, if any...not that the current approach is not. It just has to
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be cleaned up a lot :)].
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If reading, we don't send data buffers, just the segment headers saying
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we want to read segments.
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When the xfer is executed, we receive a notification that says data is
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ready in the DTI endpoint (handled through
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xfer.c:wa_handle_notif_xfer()). In there we read from the DTI endpoint a
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descriptor that gives us the status of the transfer, its identification
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(given when we issued it) and the segment number. If it was a data read,
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we issue another URB to read into the destination buffer the chunk of
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data coming out of the remote endpoint. Done, wait for the next guy. The
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callbacks for the URBs issued from here are the ones that will declare
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the xfer complete at some point and call its callback.
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Seems simple, but the implementation is not trivial.
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*
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*WARNING* Old!!
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The main xfer descriptor, wa_xfer (equivalent to a URB) contains an
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array of segments, tallys on segments and buffers and callback
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information. Buried in there is a lot of URBs for executing the segments
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and buffer transfers.
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For OUT xfers, there is an array of segments, one URB for each, another
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one of buffer URB. When submitting, we submit URBs for segment request
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1, buffer 1, segment 2, buffer 2...etc. Then we wait on the DTI for xfer
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result data; when all the segments are complete, we call the callback to
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finalize the transfer.
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For IN xfers, we only issue URBs for the segments we want to read and
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then wait for the xfer result data.
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*URB mapping into xfers*
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This is done by hwahc_op_urb_[en|de]queue(). In enqueue() we aim an
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rpipe to the endpoint where we have to transmit, create a transfer
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context (wa_xfer) and submit it. When the xfer is done, our callback is
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called and we assign the status bits and release the xfer resources.
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In dequeue() we are basically cancelling/aborting the transfer. We issue
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a xfer abort request to the HC, cancel all the URBs we had submitted
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and not yet done and when all that is done, the xfer callback will be
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called--this will call the URB callback.
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Glossary
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*DWA* -- Device Wire Adapter
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USB host, wired for downstream devices, upstream connects wirelessly
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with Wireless USB.
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*EVENT* -- Response to a command on the NEEP
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*HWA* -- Host Wire Adapter / USB dongle for UWB and Wireless USB
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*NEH* -- Notification/Event Handle
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Handle/file descriptor for receiving notifications or events. The WA
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code requires you to get one of this to listen for notifications or
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events on the NEEP.
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*NEEP* -- Notification/Event EndPoint
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Stuff related to the management of the first endpoint of a HWA USB
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dongle that is used to deliver an stream of events and notifications to
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the host.
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*NOTIFICATION* -- Message coming in the NEEP as response to something.
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*RC* -- Radio Control
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Design-overview.txt-1.8 (last edited 2006-11-04 12:22:24 by
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InakyPerezGonzalez)
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