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.. SPDX-License-Identifier: GPL-2.0+
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How USB works with driver model
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===============================
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Introduction
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------------
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Driver model USB support makes use of existing features but changes how
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drivers are found. This document provides some information intended to help
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understand how things work with USB in U-Boot when driver model is enabled.
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Enabling driver model for USB
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-----------------------------
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A new CONFIG_DM_USB option is provided to enable driver model for USB. This
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causes the USB uclass to be included, and drops the equivalent code in
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usb.c. In particular the usb_init() function is then implemented by the
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uclass.
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Support for EHCI and XHCI
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-------------------------
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So far OHCI is not supported. Both EHCI and XHCI drivers should be declared
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as drivers in the USB uclass. For example:
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.. code-block:: c
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static const struct udevice_id ehci_usb_ids[] = {
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{ .compatible = "nvidia,tegra20-ehci", .data = USB_CTLR_T20 },
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{ .compatible = "nvidia,tegra30-ehci", .data = USB_CTLR_T30 },
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{ .compatible = "nvidia,tegra114-ehci", .data = USB_CTLR_T114 },
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{ }
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};
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U_BOOT_DRIVER(usb_ehci) = {
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.name = "ehci_tegra",
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.id = UCLASS_USB,
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.of_match = ehci_usb_ids,
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.ofdata_to_platdata = ehci_usb_ofdata_to_platdata,
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.probe = tegra_ehci_usb_probe,
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.remove = tegra_ehci_usb_remove,
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.ops = &ehci_usb_ops,
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.platdata_auto_alloc_size = sizeof(struct usb_platdata),
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.priv_auto_alloc_size = sizeof(struct fdt_usb),
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.flags = DM_FLAG_ALLOC_PRIV_DMA,
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};
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Here ehci_usb_ids is used to list the controllers that the driver supports.
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Each has its own data value. Controllers must be in the UCLASS_USB uclass.
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The ofdata_to_platdata() method allows the controller driver to grab any
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necessary settings from the device tree.
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The ops here are ehci_usb_ops. All EHCI drivers will use these same ops in
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most cases, since they are all EHCI-compatible. For EHCI there are also some
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special operations that can be overridden when calling ehci_register().
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The driver can use priv_auto_alloc_size to set the size of its private data.
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This can hold run-time information needed by the driver for operation. It
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exists when the device is probed (not when it is bound) and is removed when
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the driver is removed.
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Note that usb_platdata is currently only used to deal with setting up a bus
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in USB device mode (OTG operation). It can be omitted if that is not
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supported.
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The driver's probe() method should do the basic controller init and then
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call ehci_register() to register itself as an EHCI device. It should call
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ehci_deregister() in the remove() method. Registering a new EHCI device
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does not by itself cause the bus to be scanned.
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The old ehci_hcd_init() function is no-longer used. Nor is it necessary to
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set up the USB controllers from board init code. When 'usb start' is used,
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each controller will be probed and its bus scanned.
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XHCI works in a similar way.
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Data structures
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---------------
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The following primary data structures are in use:
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- struct usb_device:
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This holds information about a device on the bus. All devices have
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this structure, even the root hub. The controller itself does not
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have this structure. You can access it for a device 'dev' with
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dev_get_parent_priv(dev). It matches the old structure except that the
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parent and child information is not present (since driver model
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handles that). Once the device is set up, you can find the device
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descriptor and current configuration descriptor in this structure.
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- struct usb_platdata:
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This holds platform data for a controller. So far this is only used
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as a work-around for controllers which can act as USB devices in OTG
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mode, since the gadget framework does not use driver model.
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- struct usb_dev_platdata:
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This holds platform data for a device. You can access it for a
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device 'dev' with dev_get_parent_platdata(dev). It holds the device
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address and speed - anything that can be determined before the device
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driver is actually set up. When probing the bus this structure is
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used to provide essential information to the device driver.
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- struct usb_bus_priv:
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This is private information for each controller, maintained by the
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controller uclass. It is mostly used to keep track of the next
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device address to use.
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Of these, only struct usb_device was used prior to driver model.
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USB buses
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---------
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Given a controller, you know the bus - it is the one attached to the
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controller. Each controller handles exactly one bus. Every controller has a
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root hub attached to it. This hub, which is itself a USB device, can provide
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one or more 'ports' to which additional devices can be attached. It is
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possible to power up a hub and find out which of its ports have devices
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attached.
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Devices are given addresses starting at 1. The root hub is always address 1,
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and from there the devices are numbered in sequence. The USB uclass takes
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care of this numbering automatically during enumeration.
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USB devices are enumerated by finding a device on a particular hub, and
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setting its address to the next available address. The USB bus stretches out
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in a tree structure, potentially with multiple hubs each with several ports
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and perhaps other hubs. Some hubs will have their own power since otherwise
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the 5V 500mA power supplied by the controller will not be sufficient to run
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very many devices.
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Enumeration in U-Boot takes a long time since devices are probed one at a
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time, and each is given sufficient time to wake up and announce itself. The
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timeouts are set for the slowest device.
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Up to 127 devices can be on each bus. USB has four bus speeds: low
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(1.5Mbps), full (12Mbps), high (480Mbps) which is only available with USB2
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and newer (EHCI), and super (5Gbps) which is only available with USB3 and
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newer (XHCI). If you connect a super-speed device to a high-speed hub, you
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will only get high-speed.
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USB operations
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--------------
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As before driver model, messages can be sent using submit_bulk_msg() and the
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like. These are now implemented by the USB uclass and route through the
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controller drivers. Note that messages are not sent to the driver of the
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device itself - i.e. they don't pass down the stack to the controller.
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U-Boot simply finds the controller to which the device is attached, and sends
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the message there with an appropriate 'pipe' value so it can be addressed
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properly. Having said that, the USB device which should receive the message
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is passed in to the driver methods, for use by sandbox. This design decision
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is open for review and the code impact of changing it is small since the
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methods are typically implemented by the EHCI and XHCI stacks.
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Controller drivers (in UCLASS_USB) themselves provide methods for sending
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each message type. For XHCI an additional alloc_device() method is provided
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since XHCI needs to allocate a device context before it can even read the
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device's descriptor.
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These methods use a 'pipe' which is a collection of bit fields used to
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describe the type of message, direction of transfer and the intended
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recipient (device number).
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USB Devices
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-----------
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USB devices are found using a simple algorithm which works through the
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available hubs in a depth-first search. Devices can be in any uclass, but
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are attached to a parent hub (or controller in the case of the root hub) and
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so have parent data attached to them (this is struct usb_device).
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By the time the device's probe() method is called, it is enumerated and is
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ready to talk to the host.
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The enumeration process needs to work out which driver to attach to each USB
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device. It does this by examining the device class, interface class, vendor
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ID, product ID, etc. See struct usb_driver_entry for how drivers are matched
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with USB devices - you can use the USB_DEVICE() macro to declare a USB
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driver. For example, usb_storage.c defines a USB_DEVICE() to handle storage
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devices, and it will be used for all USB devices which match.
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Technical details on enumeration flow
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-------------------------------------
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It is useful to understand precisely how a USB bus is enumerating to avoid
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confusion when dealing with USB devices.
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Device initialisation happens roughly like this:
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- At some point the 'usb start' command is run
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- This calls usb_init() which works through each controller in turn
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- The controller is probed(). This does no enumeration.
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- Then usb_scan_bus() is called. This calls usb_scan_device() to scan the
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(only) device that is attached to the controller - a root hub
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- usb_scan_device() sets up a fake struct usb_device and calls
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usb_setup_device(), passing the port number to be scanned, in this case
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port 0
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- usb_setup_device() first calls usb_prepare_device() to set the device
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address, then usb_select_config() to select the first configuration
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- at this point the device is enumerated but we do not have a real struct
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udevice for it. But we do have the descriptor in struct usb_device so we can
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use this to figure out what driver to use
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- back in usb_scan_device(), we call usb_find_child() to try to find an
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existing device which matches the one we just found on the bus. This can
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happen if the device is mentioned in the device tree, or if we previously
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scanned the bus and so the device was created before
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- if usb_find_child() does not find an existing device, we call
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usb_find_and_bind_driver() which tries to bind one
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- usb_find_and_bind_driver() searches all available USB drivers (declared
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with USB_DEVICE()). If it finds a match it binds that driver to create a
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new device.
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- If it does not, it binds a generic driver. A generic driver is good enough
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to allow access to the device (sending it packets, etc.) but all
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functionality will need to be implemented outside the driver model.
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- in any case, when usb_find_child() and/or usb_find_and_bind_driver() are
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done, we have a device with the correct uclass. At this point we want to
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probe the device
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- first we store basic information about the new device (address, port,
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speed) in its parent platform data. We cannot store it its private data
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since that will not exist until the device is probed.
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- then we call device_probe() which probes the device
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- the first probe step is actually the USB controller's (or USB hubs's)
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child_pre_probe() method. This gets called before anything else and is
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intended to set up a child device ready to be used with its parent bus. For
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USB this calls usb_child_pre_probe() which grabs the information that was
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stored in the parent platform data and stores it in the parent private data
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(which is struct usb_device, a real one this time). It then calls
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usb_select_config() again to make sure that everything about the device is
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set up
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- note that we have called usb_select_config() twice. This is inefficient
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but the alternative is to store additional information in the platform data.
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The time taken is minimal and this way is simpler
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- at this point the device is set up and ready for use so far as the USB
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subsystem is concerned
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- the device's probe() method is then called. It can send messages and do
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whatever else it wants to make the device work.
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Note that the first device is always a root hub, and this must be scanned to
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find any devices. The above steps will have created a hub (UCLASS_USB_HUB),
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given it address 1 and set the configuration.
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For hubs, the hub uclass has a post_probe() method. This means that after
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any hub is probed, the uclass gets to do some processing. In this case
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usb_hub_post_probe() is called, and the following steps take place:
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- usb_hub_post_probe() calls usb_hub_scan() to scan the hub, which in turn
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calls usb_hub_configure()
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- hub power is enabled
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- we loop through each port on the hub, performing the same steps for each
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- first, check if there is a device present. This happens in
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usb_hub_port_connect_change(). If so, then usb_scan_device() is called to
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scan the device, passing the appropriate port number.
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- you will recognise usb_scan_device() from the steps above. It sets up the
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device ready for use. If it is a hub, it will scan that hub before it
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continues here (recursively, depth-first)
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- once all hub ports are scanned in this way, the hub is ready for use and
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all of its downstream devices also
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- additional controllers are scanned in the same way
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The above method has some nice properties:
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- the bus enumeration happens by virtue of driver model's natural device flow
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- most logic is in the USB controller and hub uclasses; the actual device
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drivers do not need to know they are on a USB bus, at least so far as
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enumeration goes
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- hub scanning happens automatically after a hub is probed
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Hubs
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----
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USB hubs are scanned as in the section above. While hubs have their own
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uclass, they share some common elements with controllers:
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- they both attach private data to their children (struct usb_device,
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accessible for a child with dev_get_parent_priv(child))
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- they both use usb_child_pre_probe() to set up their children as proper USB
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devices
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Example - Mass Storage
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----------------------
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As an example of a USB device driver, see usb_storage.c. It uses its own
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uclass and declares itself as follows:
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.. code-block:: c
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U_BOOT_DRIVER(usb_mass_storage) = {
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.name = "usb_mass_storage",
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.id = UCLASS_MASS_STORAGE,
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.of_match = usb_mass_storage_ids,
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.probe = usb_mass_storage_probe,
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};
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static const struct usb_device_id mass_storage_id_table[] = {
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{ .match_flags = USB_DEVICE_ID_MATCH_INT_CLASS,
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.bInterfaceClass = USB_CLASS_MASS_STORAGE},
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{ } /* Terminating entry */
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};
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USB_DEVICE(usb_mass_storage, mass_storage_id_table);
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The USB_DEVICE() macro attaches the given table of matching information to
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the given driver. Note that the driver is declared in U_BOOT_DRIVER() as
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'usb_mass_storage' and this must match the first parameter of USB_DEVICE.
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When usb_find_and_bind_driver() is called on a USB device with the
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bInterfaceClass value of USB_CLASS_MASS_STORAGE, it will automatically find
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this driver and use it.
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Counter-example: USB Ethernet
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-----------------------------
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As an example of the old way of doing things, see usb_ether.c. When the bus
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is scanned, all Ethernet devices will be created as generic USB devices (in
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uclass UCLASS_USB_DEV_GENERIC). Then, when the scan is completed,
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usb_host_eth_scan() will be called. This looks through all the devices on
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each bus and manually figures out which are Ethernet devices in the ways of
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yore.
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In fact, usb_ether should be moved to driver model. Each USB Ethernet driver
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(e.g drivers/usb/eth/asix.c) should include a USB_DEVICE() declaration, so
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that it will be found as part of normal USB enumeration. Then, instead of a
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generic USB driver, a real (driver-model-aware) driver will be used. Since
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Ethernet now supports driver model, this should be fairly easy to achieve,
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and then usb_ether.c and the usb_host_eth_scan() will melt away.
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Sandbox
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-------
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All driver model uclasses must have tests and USB is no exception. To
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achieve this, a sandbox USB controller is provided. This can make use of
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emulation drivers which pretend to be USB devices. Emulations are provided
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for a hub and a flash stick. These are enough to create a pretend USB bus
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(defined by the sandbox device tree sandbox.dts) which can be scanned and
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used.
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Tests in test/dm/usb.c make use of this feature. It allows much of the USB
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stack to be tested without real hardware being needed.
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Here is an example device tree fragment:
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.. code-block:: none
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usb@1 {
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compatible = "sandbox,usb";
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hub {
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compatible = "usb-hub";
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usb,device-class = <USB_CLASS_HUB>;
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hub-emul {
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compatible = "sandbox,usb-hub";
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#address-cells = <1>;
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#size-cells = <0>;
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flash-stick {
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reg = <0>;
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compatible = "sandbox,usb-flash";
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sandbox,filepath = "flash.bin";
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};
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};
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};
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};
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This defines a single controller, containing a root hub (which is required).
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The hub is emulated by a hub emulator, and the emulated hub has a single
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flash stick to emulate on one of its ports.
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When 'usb start' is used, the following 'dm tree' output will be available::
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usb [ + ] `-- usb@1
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usb_hub [ + ] `-- hub
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usb_emul [ + ] |-- hub-emul
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usb_emul [ + ] | `-- flash-stick
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usb_mass_st [ + ] `-- usb_mass_storage
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This may look confusing. Most of it mirrors the device tree, but the
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'usb_mass_storage' device is not in the device tree. This is created by
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usb_find_and_bind_driver() based on the USB_DRIVER in usb_storage.c. While
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'flash-stick' is the emulation device, 'usb_mass_storage' is the real U-Boot
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USB device driver that talks to it.
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Future work
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-----------
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It is pretty uncommon to have a large USB bus with lots of hubs on an
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embedded system. In fact anything other than a root hub is uncommon. Still
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it would be possible to speed up enumeration in two ways:
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- breadth-first search would allow devices to be reset and probed in
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parallel to some extent
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- enumeration could be lazy, in the sense that we could enumerate just the
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root hub at first, then only progress to the next 'level' when a device is
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used that we cannot find. This could be made easier if the devices were
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statically declared in the device tree (which is acceptable for production
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boards where the same, known, things are on each bus).
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But in common cases the current algorithm is sufficient.
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Other things that need doing:
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- Convert usb_ether to use driver model as described above
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- Test that keyboards work (and convert to driver model)
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- Move the USB gadget framework to driver model
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- Implement OHCI in driver model
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- Implement USB PHYs in driver model
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- Work out a clever way to provide lazy init for USB devices
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.. Simon Glass <sjg@chromium.org>
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.. 23-Mar-15
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