Typical USB 2.0 Sequence
The steps below are a typical sequence of events that occurs during enumeration of a USB 2.0 device under Windows. Device firmware shouldn’t assume that enumeration requests and events will occur in a particular order. To function successfully, a device must detect and respond to any control request or other bus event at any time.
1. The system has a new device. A user attaches a device to a USB port, or the system powers up with a device attached. The port may be on the root hub at the host or on a hub that connects downstream from the host. The hub provides power to the port, and the device is in the Powered state. The device can draw up to 100 mA from the bus.
2. The hub detects the device. The hub monitors the voltages on the signal lines (D+ and D-) at each of its ports. The hub has a pull-down resistor of 14.25k–24.8kW on each line. A device has a pull-up resistor of 900–1575W on D+ for a full-speed device or D- for a low-speed device. High-speed-capable devices attach at full speed. On attaching to a port, the device’s pull-up brings its line high, enabling the hub to detect that a device is attached. On detecting a device, the hub continues to provide power but doesn’t yet transmit USB traffic to the device. Chapter 15 has more on how hubs detect devices.
3. The host learns of the new device. Each hub uses its interrupt endpoint to report events at the hub. The report indicates only whether the hub or a port (and if so, which port) has experienced an event. On learning of an event, the host sends the hub a Get Port Status request to find out more. Get Port Status and the other hub-class requests described are standard requests that all hubs support. The information returned tells the host when a device is newly attached.
4. The hub detects whether a device is low or full speed. Just before resetting the device, the hub determines whether the device is low or full speed by examining the voltages on the two signal lines. The hub detects the device’s speed by determining which line has a higher voltage when idle. The hub sends the information to the host in response to the next Get Port Status request. A USB 1.x hub may instead detect the device’s speed just after a bus reset. USB 2.0 requires speed detection before the reset so the hub knows whether to check for a high-speed-capable device during reset as described below.
5. The hub resets the device. When a host learns of a new device, the host sends the hub a Set Port Feature request that asks the hub to reset the port. The hub places the device’s USB data lines in the Reset condition for at least 10 ms. Reset is a special condition where both D+ and D- are logic low. (Normally, the lines have opposite logic states.) The hub sends the reset only to the new device. Other hubs and devices on the bus don’t see the reset.
6. The host learns if a full-speed device supports high speed. Detecting whether a device supports high speed uses two special signal states. In the Chirp J state, only the D+ line is driven and in the Chirp K state, only the D- line is driven.
During the reset, a device that supports high speed sends a Chirp K. A high-speed-capable hub detects the Chirp K and responds with a series of alternating Chirp K and Chirp J. On detecting the pattern KJKJKJ, the device removes its full-speed pull-up and performs all further communications at high speed. If the hub doesn’t respond to the device’s Chirp K, the device knows it must continue to communicate at full speed. All high-speed devices must be capable of responding to control requests at full speed.
7. The hub establishes a signal path between the device and the bus. The host verifies that the device has exited the reset state by sending a Get Port Status request. A bit in the returned data indicates whether the device is still in the reset state. If necessary, the host repeats the request until the device has exited the reset state.
When the hub removes the reset, the device is in the Default state. The device’s USB registers are in their reset states, and the device is ready to respond to control transfers at endpoint zero. The device communicates with the host using the default address of 00h.
8. The host sends a Get Descriptor request to learn the maximum packet size of the default pipe. The host sends the request to device address 00h, endpoint zero. Because the host enumerates only one device at a time, only one device will respond to communications addressed to device address 00h even if several devices attach at once.
The eighth byte of the device descriptor contains the maximum packet size supported by endpoint zero. A Windows host requests 64 bytes but after receiving just one packet (whether or not it has 64 bytes), the host begins the Status stage of the transfer. On completing the Status stage, Windows requests the hub to reset the device as in step 5 above. The USB 2.0 specification doesn’t require a reset here. The reset is a precaution that ensures that the device will be in a known state when the reset ends.
9. The host assigns an address. When the reset is complete, the host controller assigns a unique address to the device by sending a Set Address request. The device completes the Status stage of the request using the default address and then implements the new address. The device is now in the Address state. All communications from this point on use the new address. The address is valid until the device is detached, a hub resets the port, or the system reboots. On the next enumeration, the host may assign a different address to the device.
10. The host learns about the device’s abilities. The host sends a Get Descriptor request to the new address to read the device descriptor. This time the host retrieves the entire descriptor. The descriptor contains the maximum packet size for endpoint zero, the number of configurations the device supports, and other basic information about the device.
The host continues to learn about the device by requesting the one or more configuration descriptors specified in the device descriptor. A request for a configuration descriptor is actually a request for the configuration descriptor followed by all of its subordinate descriptors up to the number of bytes requested. A Windows host begins by requesting just the configuration descriptor’s nine bytes. Included in these bytes is the total length of the configuration descriptor and its subordinate descriptors.
Windows then requests the configuration descriptor again, this time requesting the number of bytes in the retrieved total length. The device responds by sending the configuration descriptor followed by all of the configuration’s subordinate descriptors, including interface descriptor(s), with each interface descriptor followed by any endpoint descriptors for the interface. Some configurations also have class- or vendor-specific descriptors. This chapter has more on what the descriptors contain.
11. The host assigns and loads a device driver (except for composite devices). After learning about a device from its descriptors, the host looks for the best match in a driver to manage communications with the device. Windows hosts use INF files to identify the best match. The INF file may be a system file for a USB class or a vendor-provided file that contains the device’s Vendor ID and Product ID. Chapter 9 has more about selecting a driver.
For devices that have been enumerated previously, Windows may use stored information instead of searching the INF files. After the operating system assigns and loads the driver, the driver may request the device to resend descriptors or send other class-specific descriptors.
An exception to this sequence is composite devices, which can have different drivers assigned to multiple interfaces in a configuration. The host can assign these drivers only after enabling the interfaces, so the host must first configure the device as described below.
12. The host’s device driver selects a configuration. After learning about a device from the descriptors, the device driver requests a configuration by sending a Set Configuration request with the desired configuration number. Many devices support only one configuration. If a device supports multiple configurations, the driver can decide which configuration to request based on information the driver has about how the device will be used, or the driver can ask the user what to do or just select the first configuration. (Many drivers only select the first configuration.) On receiving the request, the device implements the requested configuration. The device is now in the Configured state and the device’s interface(s) are enabled.
For composite devices, the host can now assign drivers. As with other devices, the host uses the information retrieved from the device to find a driver for each active interface in the configuration. The device is then ready for use.
Hubs are also USB devices, and the host enumerates a newly attached hub in the same way as other devices. If the hub has devices attached, the host enumerates these after the hub informs the host of their presence.
Attached state. If the hub isn’t providing power to a device’s VBUS line, the device is in the Attached state. The absence of power may occur if the hub has detected an over-current condition or if the host requests the hub to remove power from the port. With no power on VBUS, the host and device can’t communicate, so from their perspective, the situation is the same as when the device isn’t attached.
Suspend State. A device enters the Suspend state after detecting no bus activity, including SOF markers, for at least 3 ms. In the Suspend state, the device should limit its use of bus power. Both configured and unconfigured devices must support this state. Chapter 16 has more about the Suspend state.