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The pandoc conversion is not perfect. Do handwork in order to: - add a title to this chapter; - use the proper warning and note markups; - use kernel-doc to include Kernel header and c files; - remove legacy notes with regards to DocBook; - some other minor adjustments to make it better to read in text mode and in html. Signed-off-by: Mauro Carvalho Chehab <mchehab@s-opensource.com> Acked-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org> Signed-off-by: Jonathan Corbet <corbet@lwn.net>
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========================
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USB Gadget API for Linux
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========================
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:Author: David Brownell
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:Date: 20 August 2004
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Introduction
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============
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This document presents a Linux-USB "Gadget" kernel mode API, for use
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within peripherals and other USB devices that embed Linux. It provides
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an overview of the API structure, and shows how that fits into a system
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development project. This is the first such API released on Linux to
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address a number of important problems, including:
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- Supports USB 2.0, for high speed devices which can stream data at
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several dozen megabytes per second.
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- Handles devices with dozens of endpoints just as well as ones with
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just two fixed-function ones. Gadget drivers can be written so
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they're easy to port to new hardware.
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- Flexible enough to expose more complex USB device capabilities such
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as multiple configurations, multiple interfaces, composite devices,
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and alternate interface settings.
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- USB "On-The-Go" (OTG) support, in conjunction with updates to the
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Linux-USB host side.
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- Sharing data structures and API models with the Linux-USB host side
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API. This helps the OTG support, and looks forward to more-symmetric
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frameworks (where the same I/O model is used by both host and device
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side drivers).
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- Minimalist, so it's easier to support new device controller hardware.
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I/O processing doesn't imply large demands for memory or CPU
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resources.
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Most Linux developers will not be able to use this API, since they have
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USB ``host`` hardware in a PC, workstation, or server. Linux users with
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embedded systems are more likely to have USB peripheral hardware. To
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distinguish drivers running inside such hardware from the more familiar
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Linux "USB device drivers", which are host side proxies for the real USB
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devices, a different term is used: the drivers inside the peripherals
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are "USB gadget drivers". In USB protocol interactions, the device
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driver is the master (or "client driver") and the gadget driver is the
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slave (or "function driver").
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The gadget API resembles the host side Linux-USB API in that both use
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queues of request objects to package I/O buffers, and those requests may
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be submitted or canceled. They share common definitions for the standard
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USB *Chapter 9* messages, structures, and constants. Also, both APIs
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bind and unbind drivers to devices. The APIs differ in detail, since the
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host side's current URB framework exposes a number of implementation
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details and assumptions that are inappropriate for a gadget API. While
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the model for control transfers and configuration management is
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necessarily different (one side is a hardware-neutral master, the other
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is a hardware-aware slave), the endpoint I/0 API used here should also
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be usable for an overhead-reduced host side API.
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Structure of Gadget Drivers
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===========================
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A system running inside a USB peripheral normally has at least three
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layers inside the kernel to handle USB protocol processing, and may have
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additional layers in user space code. The ``gadget`` API is used by the
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middle layer to interact with the lowest level (which directly handles
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hardware).
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In Linux, from the bottom up, these layers are:
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*USB Controller Driver*
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This is the lowest software level. It is the only layer that talks
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to hardware, through registers, fifos, dma, irqs, and the like. The
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``<linux/usb/gadget.h>`` API abstracts the peripheral controller
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endpoint hardware. That hardware is exposed through endpoint
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objects, which accept streams of IN/OUT buffers, and through
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callbacks that interact with gadget drivers. Since normal USB
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devices only have one upstream port, they only have one of these
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drivers. The controller driver can support any number of different
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gadget drivers, but only one of them can be used at a time.
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Examples of such controller hardware include the PCI-based NetChip
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2280 USB 2.0 high speed controller, the SA-11x0 or PXA-25x UDC
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(found within many PDAs), and a variety of other products.
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*Gadget Driver*
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The lower boundary of this driver implements hardware-neutral USB
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functions, using calls to the controller driver. Because such
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hardware varies widely in capabilities and restrictions, and is used
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in embedded environments where space is at a premium, the gadget
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driver is often configured at compile time to work with endpoints
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supported by one particular controller. Gadget drivers may be
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portable to several different controllers, using conditional
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compilation. (Recent kernels substantially simplify the work
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involved in supporting new hardware, by *autoconfiguring* endpoints
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automatically for many bulk-oriented drivers.) Gadget driver
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responsibilities include:
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- handling setup requests (ep0 protocol responses) possibly
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including class-specific functionality
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- returning configuration and string descriptors
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- (re)setting configurations and interface altsettings, including
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enabling and configuring endpoints
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- handling life cycle events, such as managing bindings to
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hardware, USB suspend/resume, remote wakeup, and disconnection
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from the USB host.
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- managing IN and OUT transfers on all currently enabled endpoints
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Such drivers may be modules of proprietary code, although that
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approach is discouraged in the Linux community.
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*Upper Level*
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Most gadget drivers have an upper boundary that connects to some
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Linux driver or framework in Linux. Through that boundary flows the
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data which the gadget driver produces and/or consumes through
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protocol transfers over USB. Examples include:
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- user mode code, using generic (gadgetfs) or application specific
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files in ``/dev``
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- networking subsystem (for network gadgets, like the CDC Ethernet
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Model gadget driver)
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- data capture drivers, perhaps video4Linux or a scanner driver; or
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test and measurement hardware.
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- input subsystem (for HID gadgets)
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- sound subsystem (for audio gadgets)
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- file system (for PTP gadgets)
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- block i/o subsystem (for usb-storage gadgets)
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- ... and more
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*Additional Layers*
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Other layers may exist. These could include kernel layers, such as
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network protocol stacks, as well as user mode applications building
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on standard POSIX system call APIs such as ``open()``, ``close()``,
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``read()`` and ``write()``. On newer systems, POSIX Async I/O calls may
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be an option. Such user mode code will not necessarily be subject to
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the GNU General Public License (GPL).
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OTG-capable systems will also need to include a standard Linux-USB host
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side stack, with ``usbcore``, one or more *Host Controller Drivers*
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(HCDs), *USB Device Drivers* to support the OTG "Targeted Peripheral
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List", and so forth. There will also be an *OTG Controller Driver*,
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which is visible to gadget and device driver developers only indirectly.
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That helps the host and device side USB controllers implement the two
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new OTG protocols (HNP and SRP). Roles switch (host to peripheral, or
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vice versa) using HNP during USB suspend processing, and SRP can be
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viewed as a more battery-friendly kind of device wakeup protocol.
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Over time, reusable utilities are evolving to help make some gadget
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driver tasks simpler. For example, building configuration descriptors
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from vectors of descriptors for the configurations interfaces and
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endpoints is now automated, and many drivers now use autoconfiguration
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to choose hardware endpoints and initialize their descriptors. A
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potential example of particular interest is code implementing standard
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USB-IF protocols for HID, networking, storage, or audio classes. Some
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developers are interested in KDB or KGDB hooks, to let target hardware
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be remotely debugged. Most such USB protocol code doesn't need to be
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hardware-specific, any more than network protocols like X11, HTTP, or
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NFS are. Such gadget-side interface drivers should eventually be
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combined, to implement composite devices.
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Kernel Mode Gadget API
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======================
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Gadget drivers declare themselves through a struct
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:c:type:`usb_gadget_driver`, which is responsible for most parts of enumeration
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for a struct :c:type:`usb_gadget`. The response to a set_configuration usually
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involves enabling one or more of the struct :c:type:`usb_ep` objects exposed by
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the gadget, and submitting one or more struct :c:type:`usb_request` buffers to
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transfer data. Understand those four data types, and their operations,
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and you will understand how this API works.
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.. Note::
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Other than the "Chapter 9" data types, most of the significant data
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types and functions are described here.
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However, some relevant information is likely omitted from what you
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are reading. One example of such information is endpoint
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autoconfiguration. You'll have to read the header file, and use
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example source code (such as that for "Gadget Zero"), to fully
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understand the API.
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The part of the API implementing some basic driver capabilities is
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specific to the version of the Linux kernel that's in use. The 2.6
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and upper kernel versions include a *driver model* framework that has
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no analogue on earlier kernels; so those parts of the gadget API are
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not fully portable. (They are implemented on 2.4 kernels, but in a
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different way.) The driver model state is another part of this API that is
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ignored by the kerneldoc tools.
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The core API does not expose every possible hardware feature, only the
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most widely available ones. There are significant hardware features,
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such as device-to-device DMA (without temporary storage in a memory
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buffer) that would be added using hardware-specific APIs.
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This API allows drivers to use conditional compilation to handle
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endpoint capabilities of different hardware, but doesn't require that.
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Hardware tends to have arbitrary restrictions, relating to transfer
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types, addressing, packet sizes, buffering, and availability. As a rule,
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such differences only matter for "endpoint zero" logic that handles
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device configuration and management. The API supports limited run-time
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detection of capabilities, through naming conventions for endpoints.
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Many drivers will be able to at least partially autoconfigure
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themselves. In particular, driver init sections will often have endpoint
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autoconfiguration logic that scans the hardware's list of endpoints to
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find ones matching the driver requirements (relying on those
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conventions), to eliminate some of the most common reasons for
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conditional compilation.
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Like the Linux-USB host side API, this API exposes the "chunky" nature
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of USB messages: I/O requests are in terms of one or more "packets", and
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packet boundaries are visible to drivers. Compared to RS-232 serial
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protocols, USB resembles synchronous protocols like HDLC (N bytes per
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frame, multipoint addressing, host as the primary station and devices as
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secondary stations) more than asynchronous ones (tty style: 8 data bits
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per frame, no parity, one stop bit). So for example the controller
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drivers won't buffer two single byte writes into a single two-byte USB
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IN packet, although gadget drivers may do so when they implement
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protocols where packet boundaries (and "short packets") are not
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significant.
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Driver Life Cycle
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-----------------
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Gadget drivers make endpoint I/O requests to hardware without needing to
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know many details of the hardware, but driver setup/configuration code
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needs to handle some differences. Use the API like this:
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1. Register a driver for the particular device side usb controller
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hardware, such as the net2280 on PCI (USB 2.0), sa11x0 or pxa25x as
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found in Linux PDAs, and so on. At this point the device is logically
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in the USB ch9 initial state (``attached``), drawing no power and not
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usable (since it does not yet support enumeration). Any host should
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not see the device, since it's not activated the data line pullup
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used by the host to detect a device, even if VBUS power is available.
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2. Register a gadget driver that implements some higher level device
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function. That will then bind() to a :c:type:`usb_gadget`, which activates
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the data line pullup sometime after detecting VBUS.
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3. The hardware driver can now start enumerating. The steps it handles
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are to accept USB ``power`` and ``set_address`` requests. Other steps are
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handled by the gadget driver. If the gadget driver module is unloaded
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before the host starts to enumerate, steps before step 7 are skipped.
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4. The gadget driver's ``setup()`` call returns usb descriptors, based both
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on what the bus interface hardware provides and on the functionality
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being implemented. That can involve alternate settings or
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configurations, unless the hardware prevents such operation. For OTG
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devices, each configuration descriptor includes an OTG descriptor.
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5. The gadget driver handles the last step of enumeration, when the USB
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host issues a ``set_configuration`` call. It enables all endpoints used
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in that configuration, with all interfaces in their default settings.
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That involves using a list of the hardware's endpoints, enabling each
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endpoint according to its descriptor. It may also involve using
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``usb_gadget_vbus_draw`` to let more power be drawn from VBUS, as
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allowed by that configuration. For OTG devices, setting a
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configuration may also involve reporting HNP capabilities through a
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user interface.
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6. Do real work and perform data transfers, possibly involving changes
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to interface settings or switching to new configurations, until the
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device is disconnect()ed from the host. Queue any number of transfer
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requests to each endpoint. It may be suspended and resumed several
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times before being disconnected. On disconnect, the drivers go back
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to step 3 (above).
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7. When the gadget driver module is being unloaded, the driver unbind()
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callback is issued. That lets the controller driver be unloaded.
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Drivers will normally be arranged so that just loading the gadget driver
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module (or statically linking it into a Linux kernel) allows the
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peripheral device to be enumerated, but some drivers will defer
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enumeration until some higher level component (like a user mode daemon)
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enables it. Note that at this lowest level there are no policies about
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how ep0 configuration logic is implemented, except that it should obey
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USB specifications. Such issues are in the domain of gadget drivers,
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including knowing about implementation constraints imposed by some USB
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controllers or understanding that composite devices might happen to be
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built by integrating reusable components.
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Note that the lifecycle above can be slightly different for OTG devices.
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Other than providing an additional OTG descriptor in each configuration,
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only the HNP-related differences are particularly visible to driver
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code. They involve reporting requirements during the ``SET_CONFIGURATION``
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request, and the option to invoke HNP during some suspend callbacks.
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Also, SRP changes the semantics of ``usb_gadget_wakeup`` slightly.
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USB 2.0 Chapter 9 Types and Constants
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-------------------------------------
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Gadget drivers rely on common USB structures and constants defined in
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the :ref:`linux/usb/ch9.h <usb_chapter9>` header file, which is standard in
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Linux 2.6+ kernels. These are the same types and constants used by host side
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drivers (and usbcore).
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Core Objects and Methods
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------------------------
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These are declared in ``<linux/usb/gadget.h>``, and are used by gadget
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drivers to interact with USB peripheral controller drivers.
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.. kernel-doc:: include/linux/usb/gadget.h
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:internal:
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Optional Utilities
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------------------
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The core API is sufficient for writing a USB Gadget Driver, but some
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optional utilities are provided to simplify common tasks. These
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utilities include endpoint autoconfiguration.
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.. kernel-doc:: drivers/usb/gadget/usbstring.c
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:export:
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.. kernel-doc:: drivers/usb/gadget/config.c
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:export:
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Composite Device Framework
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--------------------------
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The core API is sufficient for writing drivers for composite USB devices
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(with more than one function in a given configuration), and also
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multi-configuration devices (also more than one function, but not
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necessarily sharing a given configuration). There is however an optional
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framework which makes it easier to reuse and combine functions.
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Devices using this framework provide a struct :c:type:`usb_composite_driver`,
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which in turn provides one or more struct :c:type:`usb_configuration`
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instances. Each such configuration includes at least one struct
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:c:type:`usb_function`, which packages a user visible role such as "network
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link" or "mass storage device". Management functions may also exist,
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such as "Device Firmware Upgrade".
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.. kernel-doc:: include/linux/usb/composite.h
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:internal:
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.. kernel-doc:: drivers/usb/gadget/composite.c
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:export:
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Composite Device Functions
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--------------------------
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At this writing, a few of the current gadget drivers have been converted
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to this framework. Near-term plans include converting all of them,
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except for ``gadgetfs``.
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Peripheral Controller Drivers
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=============================
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The first hardware supporting this API was the NetChip 2280 controller,
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which supports USB 2.0 high speed and is based on PCI. This is the
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``net2280`` driver module. The driver supports Linux kernel versions 2.4
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and 2.6; contact NetChip Technologies for development boards and product
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information.
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Other hardware working in the ``gadget`` framework includes: Intel's PXA
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25x and IXP42x series processors (``pxa2xx_udc``), Toshiba TC86c001
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"Goku-S" (``goku_udc``), Renesas SH7705/7727 (``sh_udc``), MediaQ 11xx
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(``mq11xx_udc``), Hynix HMS30C7202 (``h7202_udc``), National 9303/4
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(``n9604_udc``), Texas Instruments OMAP (``omap_udc``), Sharp LH7A40x
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(``lh7a40x_udc``), and more. Most of those are full speed controllers.
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At this writing, there are people at work on drivers in this framework
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for several other USB device controllers, with plans to make many of
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them be widely available.
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A partial USB simulator, the ``dummy_hcd`` driver, is available. It can
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act like a net2280, a pxa25x, or an sa11x0 in terms of available
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endpoints and device speeds; and it simulates control, bulk, and to some
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extent interrupt transfers. That lets you develop some parts of a gadget
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driver on a normal PC, without any special hardware, and perhaps with
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the assistance of tools such as GDB running with User Mode Linux. At
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least one person has expressed interest in adapting that approach,
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hooking it up to a simulator for a microcontroller. Such simulators can
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help debug subsystems where the runtime hardware is unfriendly to
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software development, or is not yet available.
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Support for other controllers is expected to be developed and
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contributed over time, as this driver framework evolves.
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Gadget Drivers
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==============
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In addition to *Gadget Zero* (used primarily for testing and development
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with drivers for usb controller hardware), other gadget drivers exist.
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There's an ``ethernet`` gadget driver, which implements one of the most
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useful *Communications Device Class* (CDC) models. One of the standards
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for cable modem interoperability even specifies the use of this ethernet
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model as one of two mandatory options. Gadgets using this code look to a
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USB host as if they're an Ethernet adapter. It provides access to a
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network where the gadget's CPU is one host, which could easily be
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bridging, routing, or firewalling access to other networks. Since some
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hardware can't fully implement the CDC Ethernet requirements, this
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driver also implements a "good parts only" subset of CDC Ethernet. (That
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subset doesn't advertise itself as CDC Ethernet, to avoid creating
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problems.)
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Support for Microsoft's ``RNDIS`` protocol has been contributed by
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Pengutronix and Auerswald GmbH. This is like CDC Ethernet, but it runs
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on more slightly USB hardware (but less than the CDC subset). However,
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its main claim to fame is being able to connect directly to recent
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versions of Windows, using drivers that Microsoft bundles and supports,
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making it much simpler to network with Windows.
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There is also support for user mode gadget drivers, using ``gadgetfs``.
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This provides a *User Mode API* that presents each endpoint as a single
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file descriptor. I/O is done using normal ``read()`` and ``read()`` calls.
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Familiar tools like GDB and pthreads can be used to develop and debug
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user mode drivers, so that once a robust controller driver is available
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many applications for it won't require new kernel mode software. Linux
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2.6 *Async I/O (AIO)* support is available, so that user mode software
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can stream data with only slightly more overhead than a kernel driver.
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There's a USB Mass Storage class driver, which provides a different
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solution for interoperability with systems such as MS-Windows and MacOS.
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That *Mass Storage* driver uses a file or block device as backing store
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for a drive, like the ``loop`` driver. The USB host uses the BBB, CB, or
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CBI versions of the mass storage class specification, using transparent
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SCSI commands to access the data from the backing store.
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There's a "serial line" driver, useful for TTY style operation over USB.
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The latest version of that driver supports CDC ACM style operation, like
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a USB modem, and so on most hardware it can interoperate easily with
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MS-Windows. One interesting use of that driver is in boot firmware (like
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a BIOS), which can sometimes use that model with very small systems
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without real serial lines.
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Support for other kinds of gadget is expected to be developed and
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contributed over time, as this driver framework evolves.
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USB On-The-GO (OTG)
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===================
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USB OTG support on Linux 2.6 was initially developed by Texas
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Instruments for `OMAP <http://www.omap.com>`__ 16xx and 17xx series
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processors. Other OTG systems should work in similar ways, but the
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hardware level details could be very different.
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Systems need specialized hardware support to implement OTG, notably
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including a special *Mini-AB* jack and associated transceiver to support
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*Dual-Role* operation: they can act either as a host, using the standard
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Linux-USB host side driver stack, or as a peripheral, using this
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``gadget`` framework. To do that, the system software relies on small
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additions to those programming interfaces, and on a new internal
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component (here called an "OTG Controller") affecting which driver stack
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connects to the OTG port. In each role, the system can re-use the
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existing pool of hardware-neutral drivers, layered on top of the
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controller driver interfaces (:c:type:`usb_bus` or :c:type:`usb_gadget`).
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Such drivers need at most minor changes, and most of the calls added to
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support OTG can also benefit non-OTG products.
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- Gadget drivers test the ``is_otg`` flag, and use it to determine
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whether or not to include an OTG descriptor in each of their
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configurations.
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- Gadget drivers may need changes to support the two new OTG protocols,
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exposed in new gadget attributes such as ``b_hnp_enable`` flag. HNP
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support should be reported through a user interface (two LEDs could
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suffice), and is triggered in some cases when the host suspends the
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peripheral. SRP support can be user-initiated just like remote
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wakeup, probably by pressing the same button.
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- On the host side, USB device drivers need to be taught to trigger HNP
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at appropriate moments, using ``usb_suspend_device()``. That also
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conserves battery power, which is useful even for non-OTG
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configurations.
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- Also on the host side, a driver must support the OTG "Targeted
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Peripheral List". That's just a whitelist, used to reject peripherals
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not supported with a given Linux OTG host. *This whitelist is
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product-specific; each product must modify* ``otg_whitelist.h`` *to
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match its interoperability specification.*
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Non-OTG Linux hosts, like PCs and workstations, normally have some
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solution for adding drivers, so that peripherals that aren't
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recognized can eventually be supported. That approach is unreasonable
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for consumer products that may never have their firmware upgraded,
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and where it's usually unrealistic to expect traditional
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PC/workstation/server kinds of support model to work. For example,
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it's often impractical to change device firmware once the product has
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been distributed, so driver bugs can't normally be fixed if they're
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found after shipment.
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Additional changes are needed below those hardware-neutral :c:type:`usb_bus`
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and :c:type:`usb_gadget` driver interfaces; those aren't discussed here in any
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detail. Those affect the hardware-specific code for each USB Host or
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Peripheral controller, and how the HCD initializes (since OTG can be
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active only on a single port). They also involve what may be called an
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*OTG Controller Driver*, managing the OTG transceiver and the OTG state
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machine logic as well as much of the root hub behavior for the OTG port.
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The OTG controller driver needs to activate and deactivate USB
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controllers depending on the relevant device role. Some related changes
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were needed inside usbcore, so that it can identify OTG-capable devices
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and respond appropriately to HNP or SRP protocols.
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