dd0b38d8ee
This is a conversion of the USB documentation to the Sphinx format. No content was altered or reformatted. Signed-off-by: Oliver <oneukum@suse.com> Signed-off-by: Jonathan Corbet <corbet@lwn.net>
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===========================
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The Linux-USB Host Side API
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===========================
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Introduction to USB on Linux
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============================
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A Universal Serial Bus (USB) is used to connect a host, such as a PC or
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workstation, to a number of peripheral devices. USB uses a tree
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structure, with the host as the root (the system's master), hubs as
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interior nodes, and peripherals as leaves (and slaves). Modern PCs
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support several such trees of USB devices, usually
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a few USB 3.0 (5 GBit/s) or USB 3.1 (10 GBit/s) and some legacy
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USB 2.0 (480 MBit/s) busses just in case.
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That master/slave asymmetry was designed-in for a number of reasons, one
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being ease of use. It is not physically possible to mistake upstream and
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downstream or it does not matter with a type C plug (or they are built into the
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peripheral). Also, the host software doesn't need to deal with
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distributed auto-configuration since the pre-designated master node
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manages all that.
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Kernel developers added USB support to Linux early in the 2.2 kernel
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series and have been developing it further since then. Besides support
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for each new generation of USB, various host controllers gained support,
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new drivers for peripherals have been added and advanced features for latency
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measurement and improved power management introduced.
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Linux can run inside USB devices as well as on the hosts that control
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the devices. But USB device drivers running inside those peripherals
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don't do the same things as the ones running inside hosts, so they've
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been given a different name: *gadget drivers*. This document does not
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cover gadget drivers.
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USB Host-Side API Model
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=======================
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Host-side drivers for USB devices talk to the "usbcore" APIs. There are
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two. One is intended for *general-purpose* drivers (exposed through
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driver frameworks), and the other is for drivers that are *part of the
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core*. Such core drivers include the *hub* driver (which manages trees
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of USB devices) and several different kinds of *host controller
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drivers*, which control individual busses.
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The device model seen by USB drivers is relatively complex.
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- USB supports four kinds of data transfers (control, bulk, interrupt,
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and isochronous). Two of them (control and bulk) use bandwidth as
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it's available, while the other two (interrupt and isochronous) are
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scheduled to provide guaranteed bandwidth.
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- The device description model includes one or more "configurations"
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per device, only one of which is active at a time. Devices are supposed
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to be capable of operating at lower than their top
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speeds and may provide a BOS descriptor showing the lowest speed they
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remain fully operational at.
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- From USB 3.0 on configurations have one or more "functions", which
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provide a common functionality and are grouped together for purposes
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of power management.
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- Configurations or functions have one or more "interfaces", each of which may have
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"alternate settings". Interfaces may be standardized by USB "Class"
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specifications, or may be specific to a vendor or device.
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USB device drivers actually bind to interfaces, not devices. Think of
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them as "interface drivers", though you may not see many devices
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where the distinction is important. *Most USB devices are simple,
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with only one function, one configuration, one interface, and one alternate
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setting.*
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- Interfaces have one or more "endpoints", each of which supports one
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type and direction of data transfer such as "bulk out" or "interrupt
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in". The entire configuration may have up to sixteen endpoints in
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each direction, allocated as needed among all the interfaces.
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- Data transfer on USB is packetized; each endpoint has a maximum
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packet size. Drivers must often be aware of conventions such as
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flagging the end of bulk transfers using "short" (including zero
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length) packets.
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- The Linux USB API supports synchronous calls for control and bulk
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messages. It also supports asynchronous calls for all kinds of data
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transfer, using request structures called "URBs" (USB Request
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Blocks).
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Accordingly, the USB Core API exposed to device drivers covers quite a
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lot of territory. You'll probably need to consult the USB 3.0
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specification, available online from www.usb.org at no cost, as well as
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class or device specifications.
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The only host-side drivers that actually touch hardware (reading/writing
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registers, handling IRQs, and so on) are the HCDs. In theory, all HCDs
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provide the same functionality through the same API. In practice, that's
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becoming more true, but there are still differences
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that crop up especially with fault handling on the less common controllers.
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Different controllers don't
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necessarily report the same aspects of failures, and recovery from
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faults (including software-induced ones like unlinking an URB) isn't yet
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fully consistent. Device driver authors should make a point of doing
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disconnect testing (while the device is active) with each different host
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controller driver, to make sure drivers don't have bugs of their own as
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well as to make sure they aren't relying on some HCD-specific behavior.
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USB-Standard Types
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==================
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In ``<linux/usb/ch9.h>`` you will find the USB data types defined in
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chapter 9 of the USB specification. These data types are used throughout
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USB, and in APIs including this host side API, gadget APIs, and usbfs.
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.. kernel-doc:: include/linux/usb/ch9.h
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:internal:
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Host-Side Data Types and Macros
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===============================
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The host side API exposes several layers to drivers, some of which are
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more necessary than others. These support lifecycle models for host side
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drivers and devices, and support passing buffers through usbcore to some
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HCD that performs the I/O for the device driver.
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.. kernel-doc:: include/linux/usb.h
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:internal:
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USB Core APIs
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=============
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There are two basic I/O models in the USB API. The most elemental one is
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asynchronous: drivers submit requests in the form of an URB, and the
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URB's completion callback handles the next step. All USB transfer types
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support that model, although there are special cases for control URBs
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(which always have setup and status stages, but may not have a data
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stage) and isochronous URBs (which allow large packets and include
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per-packet fault reports). Built on top of that is synchronous API
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support, where a driver calls a routine that allocates one or more URBs,
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submits them, and waits until they complete. There are synchronous
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wrappers for single-buffer control and bulk transfers (which are awkward
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to use in some driver disconnect scenarios), and for scatterlist based
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streaming i/o (bulk or interrupt).
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USB drivers need to provide buffers that can be used for DMA, although
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they don't necessarily need to provide the DMA mapping themselves. There
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are APIs to use used when allocating DMA buffers, which can prevent use
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of bounce buffers on some systems. In some cases, drivers may be able to
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rely on 64bit DMA to eliminate another kind of bounce buffer.
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.. kernel-doc:: drivers/usb/core/urb.c
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:export:
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.. kernel-doc:: drivers/usb/core/message.c
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:export:
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.. kernel-doc:: drivers/usb/core/file.c
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:export:
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.. kernel-doc:: drivers/usb/core/driver.c
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:export:
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.. kernel-doc:: drivers/usb/core/usb.c
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:export:
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.. kernel-doc:: drivers/usb/core/hub.c
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:export:
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Host Controller APIs
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====================
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These APIs are only for use by host controller drivers, most of which
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implement standard register interfaces such as XHCI, EHCI, OHCI, or UHCI. UHCI
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was one of the first interfaces, designed by Intel and also used by VIA;
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it doesn't do much in hardware. OHCI was designed later, to have the
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hardware do more work (bigger transfers, tracking protocol state, and so
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on). EHCI was designed with USB 2.0; its design has features that
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resemble OHCI (hardware does much more work) as well as UHCI (some parts
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of ISO support, TD list processing). XHCI was designed with USB 3.0. It
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continues to shift support for functionality into hardware.
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There are host controllers other than the "big three", although most PCI
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based controllers (and a few non-PCI based ones) use one of those
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interfaces. Not all host controllers use DMA; some use PIO, and there is
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also a simulator and a virtual host controller to pipe USB over the network.
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The same basic APIs are available to drivers for all those controllers.
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For historical reasons they are in two layers: :c:type:`struct
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usb_bus <usb_bus>` is a rather thin layer that became available
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in the 2.2 kernels, while :c:type:`struct usb_hcd <usb_hcd>`
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is a more featureful layer
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that lets HCDs share common code, to shrink driver size and
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significantly reduce hcd-specific behaviors.
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.. kernel-doc:: drivers/usb/core/hcd.c
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:export:
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.. kernel-doc:: drivers/usb/core/hcd-pci.c
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:export:
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.. kernel-doc:: drivers/usb/core/buffer.c
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:internal:
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The USB Filesystem (usbfs)
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==========================
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This chapter presents the Linux *usbfs*. You may prefer to avoid writing
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new kernel code for your USB driver; that's the problem that usbfs set
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out to solve. User mode device drivers are usually packaged as
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applications or libraries, and may use usbfs through some programming
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library that wraps it. Such libraries include
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`libusb <http://libusb.sourceforge.net>`__ for C/C++, and
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`jUSB <http://jUSB.sourceforge.net>`__ for Java.
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**Note**
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This particular documentation is incomplete, especially with respect
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to the asynchronous mode. As of kernel 2.5.66 the code and this
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(new) documentation need to be cross-reviewed.
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Configure usbfs into Linux kernels by enabling the *USB filesystem*
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option (CONFIG_USB_DEVICEFS), and you get basic support for user mode
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USB device drivers. Until relatively recently it was often (confusingly)
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called *usbdevfs* although it wasn't solving what *devfs* was. Every USB
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device will appear in usbfs, regardless of whether or not it has a
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kernel driver.
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What files are in "usbfs"?
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--------------------------
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Conventionally mounted at ``/proc/bus/usb``, usbfs features include:
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- ``/proc/bus/usb/devices`` ... a text file showing each of the USB
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devices on known to the kernel, and their configuration descriptors.
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You can also poll() this to learn about new devices.
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- ``/proc/bus/usb/BBB/DDD`` ... magic files exposing the each device's
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configuration descriptors, and supporting a series of ioctls for
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making device requests, including I/O to devices. (Purely for access
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by programs.)
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Each bus is given a number (BBB) based on when it was enumerated; within
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each bus, each device is given a similar number (DDD). Those BBB/DDD
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paths are not "stable" identifiers; expect them to change even if you
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always leave the devices plugged in to the same hub port. *Don't even
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think of saving these in application configuration files.* Stable
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identifiers are available, for user mode applications that want to use
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them. HID and networking devices expose these stable IDs, so that for
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example you can be sure that you told the right UPS to power down its
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second server. "usbfs" doesn't (yet) expose those IDs.
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Mounting and Access Control
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---------------------------
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There are a number of mount options for usbfs, which will be of most
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interest to you if you need to override the default access control
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policy. That policy is that only root may read or write device files
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(``/proc/bus/BBB/DDD``) although anyone may read the ``devices`` or
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``drivers`` files. I/O requests to the device also need the
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CAP_SYS_RAWIO capability,
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The significance of that is that by default, all user mode device
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drivers need super-user privileges. You can change modes or ownership in
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a driver setup when the device hotplugs, or maye just start the driver
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right then, as a privileged server (or some activity within one). That's
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the most secure approach for multi-user systems, but for single user
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systems ("trusted" by that user) it's more convenient just to grant
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everyone all access (using the *devmode=0666* option) so the driver can
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start whenever it's needed.
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The mount options for usbfs, usable in /etc/fstab or in command line
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invocations of *mount*, are:
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*busgid*\ =NNNNN
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Controls the GID used for the /proc/bus/usb/BBB directories.
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(Default: 0)
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*busmode*\ =MMM
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Controls the file mode used for the /proc/bus/usb/BBB directories.
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(Default: 0555)
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*busuid*\ =NNNNN
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Controls the UID used for the /proc/bus/usb/BBB directories.
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(Default: 0)
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*devgid*\ =NNNNN
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Controls the GID used for the /proc/bus/usb/BBB/DDD files. (Default:
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0)
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*devmode*\ =MMM
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Controls the file mode used for the /proc/bus/usb/BBB/DDD files.
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(Default: 0644)
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*devuid*\ =NNNNN
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Controls the UID used for the /proc/bus/usb/BBB/DDD files. (Default:
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0)
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*listgid*\ =NNNNN
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Controls the GID used for the /proc/bus/usb/devices and drivers
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files. (Default: 0)
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*listmode*\ =MMM
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Controls the file mode used for the /proc/bus/usb/devices and
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drivers files. (Default: 0444)
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*listuid*\ =NNNNN
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Controls the UID used for the /proc/bus/usb/devices and drivers
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files. (Default: 0)
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Note that many Linux distributions hard-wire the mount options for usbfs
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in their init scripts, such as ``/etc/rc.d/rc.sysinit``, rather than
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making it easy to set this per-system policy in ``/etc/fstab``.
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/proc/bus/usb/devices
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---------------------
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This file is handy for status viewing tools in user mode, which can scan
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the text format and ignore most of it. More detailed device status
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(including class and vendor status) is available from device-specific
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files. For information about the current format of this file, see the
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``Documentation/usb/proc_usb_info.txt`` file in your Linux kernel
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sources.
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This file, in combination with the poll() system call, can also be used
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to detect when devices are added or removed:
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::
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int fd;
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struct pollfd pfd;
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fd = open("/proc/bus/usb/devices", O_RDONLY);
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pfd = { fd, POLLIN, 0 };
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for (;;) {
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/* The first time through, this call will return immediately. */
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poll(&pfd, 1, -1);
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/* To see what's changed, compare the file's previous and current
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contents or scan the filesystem. (Scanning is more precise.) */
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}
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Note that this behavior is intended to be used for informational and
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debug purposes. It would be more appropriate to use programs such as
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udev or HAL to initialize a device or start a user-mode helper program,
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for instance.
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/proc/bus/usb/BBB/DDD
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---------------------
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Use these files in one of these basic ways:
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*They can be read,* producing first the device descriptor (18 bytes) and
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then the descriptors for the current configuration. See the USB 2.0 spec
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for details about those binary data formats. You'll need to convert most
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multibyte values from little endian format to your native host byte
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order, although a few of the fields in the device descriptor (both of
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the BCD-encoded fields, and the vendor and product IDs) will be
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byteswapped for you. Note that configuration descriptors include
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descriptors for interfaces, altsettings, endpoints, and maybe additional
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class descriptors.
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*Perform USB operations* using *ioctl()* requests to make endpoint I/O
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requests (synchronously or asynchronously) or manage the device. These
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requests need the CAP_SYS_RAWIO capability, as well as filesystem
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access permissions. Only one ioctl request can be made on one of these
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device files at a time. This means that if you are synchronously reading
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an endpoint from one thread, you won't be able to write to a different
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endpoint from another thread until the read completes. This works for
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*half duplex* protocols, but otherwise you'd use asynchronous i/o
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requests.
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Life Cycle of User Mode Drivers
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-------------------------------
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Such a driver first needs to find a device file for a device it knows
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how to handle. Maybe it was told about it because a ``/sbin/hotplug``
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event handling agent chose that driver to handle the new device. Or
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maybe it's an application that scans all the /proc/bus/usb device files,
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and ignores most devices. In either case, it should :c:func:`read()`
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all the descriptors from the device file, and check them against what it
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knows how to handle. It might just reject everything except a particular
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vendor and product ID, or need a more complex policy.
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Never assume there will only be one such device on the system at a time!
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If your code can't handle more than one device at a time, at least
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detect when there's more than one, and have your users choose which
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device to use.
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Once your user mode driver knows what device to use, it interacts with
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it in either of two styles. The simple style is to make only control
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requests; some devices don't need more complex interactions than those.
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(An example might be software using vendor-specific control requests for
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some initialization or configuration tasks, with a kernel driver for the
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rest.)
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More likely, you need a more complex style driver: one using non-control
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endpoints, reading or writing data and claiming exclusive use of an
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interface. *Bulk* transfers are easiest to use, but only their sibling
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*interrupt* transfers work with low speed devices. Both interrupt and
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*isochronous* transfers offer service guarantees because their bandwidth
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is reserved. Such "periodic" transfers are awkward to use through usbfs,
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unless you're using the asynchronous calls. However, interrupt transfers
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can also be used in a synchronous "one shot" style.
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Your user-mode driver should never need to worry about cleaning up
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request state when the device is disconnected, although it should close
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its open file descriptors as soon as it starts seeing the ENODEV errors.
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The ioctl() Requests
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--------------------
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To use these ioctls, you need to include the following headers in your
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userspace program:
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::
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#include <linux/usb.h>
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#include <linux/usbdevice_fs.h>
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#include <asm/byteorder.h>
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The standard USB device model requests, from "Chapter 9" of the USB 2.0
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specification, are automatically included from the ``<linux/usb/ch9.h>``
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header.
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Unless noted otherwise, the ioctl requests described here will update
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the modification time on the usbfs file to which they are applied
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(unless they fail). A return of zero indicates success; otherwise, a
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standard USB error code is returned. (These are documented in
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``Documentation/usb/error-codes.txt`` in your kernel sources.)
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Each of these files multiplexes access to several I/O streams, one per
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endpoint. Each device has one control endpoint (endpoint zero) which
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supports a limited RPC style RPC access. Devices are configured by
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hub_wq (in the kernel) setting a device-wide *configuration* that
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affects things like power consumption and basic functionality. The
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endpoints are part of USB *interfaces*, which may have *altsettings*
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affecting things like which endpoints are available. Many devices only
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have a single configuration and interface, so drivers for them will
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ignore configurations and altsettings.
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Management/Status Requests
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~~~~~~~~~~~~~~~~~~~~~~~~~~
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A number of usbfs requests don't deal very directly with device I/O.
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They mostly relate to device management and status. These are all
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synchronous requests.
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USBDEVFS_CLAIMINTERFACE
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This is used to force usbfs to claim a specific interface, which has
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not previously been claimed by usbfs or any other kernel driver. The
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ioctl parameter is an integer holding the number of the interface
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(bInterfaceNumber from descriptor).
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Note that if your driver doesn't claim an interface before trying to
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use one of its endpoints, and no other driver has bound to it, then
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the interface is automatically claimed by usbfs.
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This claim will be released by a RELEASEINTERFACE ioctl, or by
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closing the file descriptor. File modification time is not updated
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by this request.
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USBDEVFS_CONNECTINFO
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Says whether the device is lowspeed. The ioctl parameter points to a
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structure like this:
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::
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struct usbdevfs_connectinfo {
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unsigned int devnum;
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unsigned char slow;
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};
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File modification time is not updated by this request.
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*You can't tell whether a "not slow" device is connected at high
|
|
speed (480 MBit/sec) or just full speed (12 MBit/sec).* You should
|
|
know the devnum value already, it's the DDD value of the device file
|
|
name.
|
|
|
|
USBDEVFS_GETDRIVER
|
|
Returns the name of the kernel driver bound to a given interface (a
|
|
string). Parameter is a pointer to this structure, which is
|
|
modified:
|
|
|
|
::
|
|
|
|
struct usbdevfs_getdriver {
|
|
unsigned int interface;
|
|
char driver[USBDEVFS_MAXDRIVERNAME + 1];
|
|
};
|
|
|
|
File modification time is not updated by this request.
|
|
|
|
USBDEVFS_IOCTL
|
|
Passes a request from userspace through to a kernel driver that has
|
|
an ioctl entry in the *struct usb_driver* it registered.
|
|
|
|
::
|
|
|
|
struct usbdevfs_ioctl {
|
|
int ifno;
|
|
int ioctl_code;
|
|
void *data;
|
|
};
|
|
|
|
/* user mode call looks like this.
|
|
* 'request' becomes the driver->ioctl() 'code' parameter.
|
|
* the size of 'param' is encoded in 'request', and that data
|
|
* is copied to or from the driver->ioctl() 'buf' parameter.
|
|
*/
|
|
static int
|
|
usbdev_ioctl (int fd, int ifno, unsigned request, void *param)
|
|
{
|
|
struct usbdevfs_ioctl wrapper;
|
|
|
|
wrapper.ifno = ifno;
|
|
wrapper.ioctl_code = request;
|
|
wrapper.data = param;
|
|
|
|
return ioctl (fd, USBDEVFS_IOCTL, &wrapper);
|
|
}
|
|
|
|
File modification time is not updated by this request.
|
|
|
|
This request lets kernel drivers talk to user mode code through
|
|
filesystem operations even when they don't create a character or
|
|
block special device. It's also been used to do things like ask
|
|
devices what device special file should be used. Two pre-defined
|
|
ioctls are used to disconnect and reconnect kernel drivers, so that
|
|
user mode code can completely manage binding and configuration of
|
|
devices.
|
|
|
|
USBDEVFS_RELEASEINTERFACE
|
|
This is used to release the claim usbfs made on interface, either
|
|
implicitly or because of a USBDEVFS_CLAIMINTERFACE call, before the
|
|
file descriptor is closed. The ioctl parameter is an integer holding
|
|
the number of the interface (bInterfaceNumber from descriptor); File
|
|
modification time is not updated by this request.
|
|
|
|
**Warning**
|
|
|
|
*No security check is made to ensure that the task which made
|
|
the claim is the one which is releasing it. This means that user
|
|
mode driver may interfere other ones.*
|
|
|
|
USBDEVFS_RESETEP
|
|
Resets the data toggle value for an endpoint (bulk or interrupt) to
|
|
DATA0. The ioctl parameter is an integer endpoint number (1 to 15,
|
|
as identified in the endpoint descriptor), with USB_DIR_IN added
|
|
if the device's endpoint sends data to the host.
|
|
|
|
**Warning**
|
|
|
|
*Avoid using this request. It should probably be removed.* Using
|
|
it typically means the device and driver will lose toggle
|
|
synchronization. If you really lost synchronization, you likely
|
|
need to completely handshake with the device, using a request
|
|
like CLEAR_HALT or SET_INTERFACE.
|
|
|
|
USBDEVFS_DROP_PRIVILEGES
|
|
This is used to relinquish the ability to do certain operations
|
|
which are considered to be privileged on a usbfs file descriptor.
|
|
This includes claiming arbitrary interfaces, resetting a device on
|
|
which there are currently claimed interfaces from other users, and
|
|
issuing USBDEVFS_IOCTL calls. The ioctl parameter is a 32 bit mask
|
|
of interfaces the user is allowed to claim on this file descriptor.
|
|
You may issue this ioctl more than one time to narrow said mask.
|
|
|
|
Synchronous I/O Support
|
|
~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
Synchronous requests involve the kernel blocking until the user mode
|
|
request completes, either by finishing successfully or by reporting an
|
|
error. In most cases this is the simplest way to use usbfs, although as
|
|
noted above it does prevent performing I/O to more than one endpoint at
|
|
a time.
|
|
|
|
USBDEVFS_BULK
|
|
Issues a bulk read or write request to the device. The ioctl
|
|
parameter is a pointer to this structure:
|
|
|
|
::
|
|
|
|
struct usbdevfs_bulktransfer {
|
|
unsigned int ep;
|
|
unsigned int len;
|
|
unsigned int timeout; /* in milliseconds */
|
|
void *data;
|
|
};
|
|
|
|
The "ep" value identifies a bulk endpoint number (1 to 15, as
|
|
identified in an endpoint descriptor), masked with USB_DIR_IN when
|
|
referring to an endpoint which sends data to the host from the
|
|
device. The length of the data buffer is identified by "len"; Recent
|
|
kernels support requests up to about 128KBytes. *FIXME say how read
|
|
length is returned, and how short reads are handled.*.
|
|
|
|
USBDEVFS_CLEAR_HALT
|
|
Clears endpoint halt (stall) and resets the endpoint toggle. This is
|
|
only meaningful for bulk or interrupt endpoints. The ioctl parameter
|
|
is an integer endpoint number (1 to 15, as identified in an endpoint
|
|
descriptor), masked with USB_DIR_IN when referring to an endpoint
|
|
which sends data to the host from the device.
|
|
|
|
Use this on bulk or interrupt endpoints which have stalled,
|
|
returning *-EPIPE* status to a data transfer request. Do not issue
|
|
the control request directly, since that could invalidate the host's
|
|
record of the data toggle.
|
|
|
|
USBDEVFS_CONTROL
|
|
Issues a control request to the device. The ioctl parameter points
|
|
to a structure like this:
|
|
|
|
::
|
|
|
|
struct usbdevfs_ctrltransfer {
|
|
__u8 bRequestType;
|
|
__u8 bRequest;
|
|
__u16 wValue;
|
|
__u16 wIndex;
|
|
__u16 wLength;
|
|
__u32 timeout; /* in milliseconds */
|
|
void *data;
|
|
};
|
|
|
|
The first eight bytes of this structure are the contents of the
|
|
SETUP packet to be sent to the device; see the USB 2.0 specification
|
|
for details. The bRequestType value is composed by combining a
|
|
USB_TYPE_\* value, a USB_DIR_\* value, and a USB_RECIP_\*
|
|
value (from *<linux/usb.h>*). If wLength is nonzero, it describes
|
|
the length of the data buffer, which is either written to the device
|
|
(USB_DIR_OUT) or read from the device (USB_DIR_IN).
|
|
|
|
At this writing, you can't transfer more than 4 KBytes of data to or
|
|
from a device; usbfs has a limit, and some host controller drivers
|
|
have a limit. (That's not usually a problem.) *Also* there's no way
|
|
to say it's not OK to get a short read back from the device.
|
|
|
|
USBDEVFS_RESET
|
|
Does a USB level device reset. The ioctl parameter is ignored. After
|
|
the reset, this rebinds all device interfaces. File modification
|
|
time is not updated by this request.
|
|
|
|
**Warning**
|
|
|
|
*Avoid using this call* until some usbcore bugs get fixed, since
|
|
it does not fully synchronize device, interface, and driver (not
|
|
just usbfs) state.
|
|
|
|
USBDEVFS_SETINTERFACE
|
|
Sets the alternate setting for an interface. The ioctl parameter is
|
|
a pointer to a structure like this:
|
|
|
|
::
|
|
|
|
struct usbdevfs_setinterface {
|
|
unsigned int interface;
|
|
unsigned int altsetting;
|
|
};
|
|
|
|
File modification time is not updated by this request.
|
|
|
|
Those struct members are from some interface descriptor applying to
|
|
the current configuration. The interface number is the
|
|
bInterfaceNumber value, and the altsetting number is the
|
|
bAlternateSetting value. (This resets each endpoint in the
|
|
interface.)
|
|
|
|
USBDEVFS_SETCONFIGURATION
|
|
Issues the :c:func:`usb_set_configuration()` call for the
|
|
device. The parameter is an integer holding the number of a
|
|
configuration (bConfigurationValue from descriptor). File
|
|
modification time is not updated by this request.
|
|
|
|
**Warning**
|
|
|
|
*Avoid using this call* until some usbcore bugs get fixed, since
|
|
it does not fully synchronize device, interface, and driver (not
|
|
just usbfs) state.
|
|
|
|
Asynchronous I/O Support
|
|
~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
As mentioned above, there are situations where it may be important to
|
|
initiate concurrent operations from user mode code. This is particularly
|
|
important for periodic transfers (interrupt and isochronous), but it can
|
|
be used for other kinds of USB requests too. In such cases, the
|
|
asynchronous requests described here are essential. Rather than
|
|
submitting one request and having the kernel block until it completes,
|
|
the blocking is separate.
|
|
|
|
These requests are packaged into a structure that resembles the URB used
|
|
by kernel device drivers. (No POSIX Async I/O support here, sorry.) It
|
|
identifies the endpoint type (USBDEVFS_URB_TYPE_\*), endpoint
|
|
(number, masked with USB_DIR_IN as appropriate), buffer and length,
|
|
and a user "context" value serving to uniquely identify each request.
|
|
(It's usually a pointer to per-request data.) Flags can modify requests
|
|
(not as many as supported for kernel drivers).
|
|
|
|
Each request can specify a realtime signal number (between SIGRTMIN and
|
|
SIGRTMAX, inclusive) to request a signal be sent when the request
|
|
completes.
|
|
|
|
When usbfs returns these urbs, the status value is updated, and the
|
|
buffer may have been modified. Except for isochronous transfers, the
|
|
actual_length is updated to say how many bytes were transferred; if the
|
|
USBDEVFS_URB_DISABLE_SPD flag is set ("short packets are not OK"), if
|
|
fewer bytes were read than were requested then you get an error report.
|
|
|
|
::
|
|
|
|
struct usbdevfs_iso_packet_desc {
|
|
unsigned int length;
|
|
unsigned int actual_length;
|
|
unsigned int status;
|
|
};
|
|
|
|
struct usbdevfs_urb {
|
|
unsigned char type;
|
|
unsigned char endpoint;
|
|
int status;
|
|
unsigned int flags;
|
|
void *buffer;
|
|
int buffer_length;
|
|
int actual_length;
|
|
int start_frame;
|
|
int number_of_packets;
|
|
int error_count;
|
|
unsigned int signr;
|
|
void *usercontext;
|
|
struct usbdevfs_iso_packet_desc iso_frame_desc[];
|
|
};
|
|
|
|
For these asynchronous requests, the file modification time reflects
|
|
when the request was initiated. This contrasts with their use with the
|
|
synchronous requests, where it reflects when requests complete.
|
|
|
|
USBDEVFS_DISCARDURB
|
|
*TBS* File modification time is not updated by this request.
|
|
|
|
USBDEVFS_DISCSIGNAL
|
|
*TBS* File modification time is not updated by this request.
|
|
|
|
USBDEVFS_REAPURB
|
|
*TBS* File modification time is not updated by this request.
|
|
|
|
USBDEVFS_REAPURBNDELAY
|
|
*TBS* File modification time is not updated by this request.
|
|
|
|
USBDEVFS_SUBMITURB
|
|
*TBS*
|