ugen(4) - NetBSD Manual Pages

Command: Section: Arch: Collection:  
UGEN(4)                 NetBSD Kernel Interfaces Manual                UGEN(4)

ugen -- USB generic device support
ugen* at uhub? flags N ugen* at uhub? vendor V product P flags 1 ugenif* at uhub? vendor V product P configuration C interface I ugenif* at uhub? vendor V product P configuration C interface I flags 1
The ugen driver provides support for all USB devices that do not have a special driver. It supports access to all parts of the device, but not in a way that is as convenient as a special purpose driver. Normally the ugen driver is used when no other driver attaches to a device. If ``flags 1'' is specified, the ugen will instead attach with a very high priority and always be used. Together with the vendor and product locators this can be used to force the ugen driver to be used for a certain device. The `ugenif' form of attachment can be used to ``steal'' only one inter- face from some device for use by the ugen driver. Most likely you want to explicitly specify at least vendor, product and interface with this form, as otherwise the ugen driver would capture all of your usb devices. If ``flags 1'' is specified, the `ugenif' form will match at the lowest priority, thus allowing it to match only otherwise unclaimed interfaces. NOTE: You have to be extremely careful, when using this form, as the attached ugen driver has access to all of the device and can easily interfere with the driver(s) used for the other interface(s). As an example of this second form of attachment there are various debug- ging boards available based on some FTDI chip, where one interface is used for JTAG debugging and the other is used as a serial interface. In this case you want to attach the ugen driver to interface 0 of this par- ticular board identified by vendor and product while letting uftdi(4) together with ucom(4) to attach at interface 1. There can be up to 127 USB devices connected to a USB bus. Each USB device can have up to 16 endpoints. Each of these endpoints will commu- nicate in one of four different modes: control, isochronous, bulk, or interrupt. Each of the endpoints will have a different device node. The four least significant bits in the minor device number determines which endpoint the device accesses and the rest of the bits determines which USB device. If an endpoint address is used both for input and output the device can be opened for both read or write. To find out what endpoints exist there are a series of ioctl(2) opera- tions on the control endpoint that return the USB descriptors of the device, configurations, interfaces, and endpoints. The control transfer mode can only happen on the control endpoint which is always endpoint 0. The control endpoint accepts requests and may respond with an answer to such requests. Control requests are issued by ioctl(2) calls. The bulk transfer mode can be in or out depending on the endpoint. To perform IO on a bulk endpoint read(2) and write(2) should be used. All IO operations on a bulk endpoint are normally unbuffered. The USB_SET_BULK_RA and USB_SET_BULK_WB ioctl(2) calls enable read-ahead and write-behind buffering, respectively. This buffering supports fixed- sized USB transfers and is intended for devices with regular and continu- ing data transfers. When read-ahead or write-behind are enabled, the file descriptor may be set to use non-blocking IO. When in a read-ahead/writeback mode, select(2) for read and write oper- ates normally, returning true if there is data in the read buffer and space in the write buffer, respectively. When not, select(2) always returns true, because there is no way to predict how the device will respond to a read or write request. The interrupt transfer mode can be in or out depending on the endpoint. To perform IO on an interrupt endpoint read(2) and write(2) should be used. A moderate amount of buffering is done by the driver. All endpoints handle the following ioctl(2) calls: USB_SET_SHORT_XFER (int) Allow short read transfer. Normally a transfer from the device which is shorter than the request specified is reported as an error. USB_SET_TIMEOUT (int) Set the timeout on the device operations, the time is specified in milliseconds. The value 0 is used to indicate that there is no timeout. The control endpoint (endpoint 0) handles the following ioctl(2) calls: USB_GET_CONFIG (int) Get the device configuration number. USB_SET_CONFIG (int) Set the device into the given configuration number. This operation can only be performed when the control endpoint is the sole open endpoint. USB_GET_ALTINTERFACE (struct usb_alt_interface) Get the alternative setting number for the interface with the given index. The config_index is ignored in this call. struct usb_alt_interface { int uai_config_index; int uai_interface_index; int uai_alt_no; }; USB_SET_ALTINTERFACE (struct usb_alt_interface) Set the alternative setting to the given number in the interface with the given index. The uai_config_index is ignored in this call. This operation can only be performed when no endpoints for the interface are open. USB_GET_NO_ALT (struct usb_alt_interface) Return the number of different alternate settings in the uai_alt_no field. USB_GET_DEVICE_DESC (usb_device_descriptor_t) Return the device descriptor. USB_GET_CONFIG_DESC (struct usb_config_desc) Return the descriptor for the configuration with the given index. For convenience the current configuration can be specified by USB_CURRENT_CONFIG_INDEX. struct usb_config_desc { int ucd_config_index; usb_config_descriptor_t ucd_desc; }; USB_GET_INTERFACE_DESC (struct usb_interface_desc) Return the interface descriptor for an interface specified by its configuration index, interface index, and alternative index. For convenience the current alternative can be specified by USB_CURRENT_ALT_INDEX. struct usb_interface_desc { int uid_config_index; int uid_interface_index; int uid_alt_index; usb_interface_descriptor_t uid_desc; }; USB_GET_ENDPOINT_DESC (struct usb_endpoint_desc) Return the endpoint descriptor for the endpoint specified by its configuration index, interface index, alternative index, and end- point index. struct usb_endpoint_desc { int ued_config_index; int ued_interface_index; int ued_alt_index; int ued_endpoint_index; usb_endpoint_descriptor_t ued_desc; }; USB_GET_FULL_DESC (struct usb_full_desc) Return all the descriptors for the given configuration. struct usb_full_desc { int ufd_config_index; u_int ufd_size; u_char *ufd_data; }; The ufd_data field should point to a memory area of the size given in the ufd_size field. The proper size can be determined by first issuing a USB_GET_CONFIG_DESC and inspecting the wTotalLength field. USB_GET_STRING_DESC (struct usb_string_desc) Get a string descriptor for the given language id and string index. struct usb_string_desc { int usd_string_index; int usd_language_id; usb_string_descriptor_t usd_desc; }; USB_DO_REQUEST Send a USB request to the device on the control endpoint. Any data sent to/from the device is located at data. The size of the transferred data is determined from the request. The ucr_addr field is ignored in this call. The ucr_flags field can be used to flag that the request is allowed to be shorter than the requested size, and the ucr_actlen field will contain the actual size on completion. struct usb_ctl_request { int ucr_addr; usb_device_request_t ucr_request; void *ucr_data; int ucr_flags; #define USBD_SHORT_XFER_OK 0x04 /* allow short reads */ int ucr_actlen; /* actual length transferred */ }; This is a dangerous operation in that it can perform arbitrary operations on the device. Some of the most dangerous (e.g., changing the device address) are not allowed. USB_GET_DEVICEINFO (struct usb_device_info) Get an information summary for the device. This call will not issue any USB transactions. Bulk endpoints handle the following ioctl(2) calls: USB_SET_BULK_RA (int) Enable or disable bulk read-ahead. When enabled, the driver will begin to read data from the device into a buffer, and will per- form reads from the device whenever there is room in the buffer. The read(2) call will read data from this buffer, blocking if necessary until there is enough data to read the length of data requested. The buffer size and the read request length can be set by the USB_SET_BULK_RA_OPT ioctl(2) call. USB_SET_BULK_WB (int) Enable or disable bulk write-behind. When enabled, the driver will buffer data from the write(2) call before writing it to the device, enabling the write(2) call to return immediately. write(2) will block if there is not enough room in the buffer for all the data. The buffer size and the write request length can be set by the USB_SET_BULK_WB_OPT ioctl(2) call. USB_SET_BULK_RA_OPT (struct usb_bulk_ra_wb_opt) Set the size of the buffer and the length of the read requests used by the driver when bulk read-ahead is enabled. The changes do not take effect until the next time bulk read-ahead is enabled. Read requests are made for the length specified, and the host controller driver (i.e., ehci(4), ohci(4), and uhci(4)) will perform as many bus transfers as required. If transfers from the device should be smaller than the maximum length, ra_wb_request_size must be set to the required length. struct usb_bulk_ra_wb_opt { u_int ra_wb_buffer_size; u_int ra_wb_request_size; }; USB_SET_BULK_WB_OPT (struct usb_bulk_ra_wb_opt) Set the size of the buffer and the length of the write requests used by the driver when bulk write-behind is enabled. The changes do not take effect until the next time bulk write-behind is enabled. Note that there are two different ways of addressing configurations, interfaces, alternatives, and endpoints: by index or by number. The index is the ordinal number (starting from 0) of the descriptor as pre- sented by the device. The number is the respective number of the entity as found in its descriptor. Enumeration of descriptors use the index, getting and setting typically uses numbers. Example: All endpoints (except the control endpoint) for the current con- figuration can be found by iterating the interface_index from 0 to config_desc->bNumInterface-1 and for each of these iterating the endpoint_index from 0 to interface_desc->bNumEndpoints. The config_index should set to USB_CURRENT_CONFIG_INDEX and alt_index should be set to USB_CURRENT_ALT_INDEX.
/dev/ugenN.EE Endpoint EE of device N.
The ugen driver appeared in NetBSD 1.4. NetBSD 10.99 March 25, 2024 NetBSD 10.99
Powered by man-cgi (2024-03-20). Maintained for NetBSD by Kimmo Suominen. Based on man-cgi by Panagiotis Christias.