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Device drivers ported from the Linux kernel USB ### Controller configuration ~~~~~~~~~~~~~~~~~~~~~~~~ The driver can be started using different or all USB controller types a platform offers (USB 1.0/2.0/3.0). Note that not all controllers are supported by all platforms. Controllers can be enabled as attribute in the config node of the driver. Supported attributes are: 'uhci', 'ohci', 'ehci', and 'xhci'. Configuration snippet to enable UHCI and EHCI ! <config uhci="yes" ehci="yes"> BIOS Handoff ~~~~~~~~~~~~ Per default the USB driver performs a hand off of the USB controller from the BIOS, since it still may access the controller when booting, for example, from a USB device. The BIOS hand off induces the execution of BIOS/SMM USB driver code and potentially DMA operations. Unfortunately, some ACPI tables report wrong RMRR information, which implicates IOMMU faults on illegal DMA operations and consequently the hand off may fail after noticeably long timeouts. Therefore, the hand off can be disabled in the USB driver configuration like follows. ! <config bios_handoff="no"/> HID ~~~ Supports keyboard and mouse. A run script can be found under 'run/usb_hid.run'. Configuration snippet: !<start name="usb_drv"> ! <resource name="RAM" quantum="3M"/> ! <provides><service name="Input"/></provides> ! <config uhci="yes" ohci="yes" ehci="yes" xhci="yes"> ! <hid/> ! </config> !</start> Note: It has been observed that certain 1.0 versions of Qemu do not generate mouse interrupts. The mouse driver should work correctly on Qemu 1.0.93 and above. HID - Touchscreen support ~~~~~~~~~~~~~~~~~~~~~~~~~ Touchscreen absolute coordinates must be calibrated (e.g. re-calculated) to screen absolute coordinates. The screen resolution is not determined automatically by the USB driver, but can be configured as sub node of the hid xml tag: !... !<hid> ! <touchscreen width="1024" height="768" multitouch="no"/> !<hid/> !... If a touchscreen is multi-touch-capable than the multitouch attribute gears which type of Genode input events are generated. If set to 'no' (default) than absolute events are generated and no multitouch events. If set to 'yes' solely multitouch events are generated. Storage ~~~~~~~ Currently supports one USB storage device. Hot plugging has not been tested. A run script can be found under 'run/usb_storage.run'. Configuration snippet: !<start name="usb_drv"> ! <resource name="RAM" quantum="2M"/> ! <provides> <service name="Block"/> </provides> ! <config><storage /></config> !</start> Network (Nic) ~~~~~~~~~~~~~ Configuration snippet: !<start name="usb_drv"> ! <resource name="RAM" quantum="3M"/> ! <provides> ! <service name="Nic"/> ! <service name="Input"/> ! </provides> ! <config ehci="yes" xhci="yes"> ! <nic mac="2e:60:90:0c:4e:01" /> ! <hid/> ! </config> !</start> Please observe that this setup starts the HID and Nic service at the same time. Also there is the 'mac' attribute where one can specify the hardware address of the network interface. This is necessary in case the EEPROM of the network card cannot be accessed via the host controller making it impossible to retrieve the devices hardware address. If this is the case and no 'mac' attribute is given a fallback address will be assigned to the network device. Note that the fallback address will always be the same. RAW ~~~ Allows raw access to USB devices via the 'Usb' session interface. Configuration snippet: !<start name="usb_drv"> ! <resource name="RAM" quantum="8M"/> ! <provides><service name="Usb"/></provides> ! <config uhci="yes" ohci="yes" ehci="yes" xhci="yes"> ! <raw> ! <report devices="yes"/> ! </raw> ! </config> !</start> The optional 'devices' report lists the connected devices and gets updated when devices are added or removed. Example report: !<devices> ! <device label="usb-1-7" vendor_id="0x1f75" product_id="0x0917" bus="0x0001" dev="0x0007"/> ! <device label="usb-1-6" vendor_id="0x13fe" product_id="0x5200" bus="0x0001" dev="0x0006"/> ! <device label="usb-1-4" vendor_id="0x17ef" product_id="0x4816" bus="0x0001" dev="0x0004"/> ! <device label="usb-1-3" vendor_id="0x0a5c" product_id="0x217f" bus="0x0001" dev="0x0003"/> ! <device label="usb-2-2" vendor_id="0x8087" product_id="0x0020" bus="0x0002" dev="0x0002"/> ! <device label="usb-1-2" vendor_id="0x8087" product_id="0x0020" bus="0x0001" dev="0x0002"/> ! <device label="usb-2-1" vendor_id="0x1d6b" product_id="0x0002" bus="0x0002" dev="0x0001"/> ! <device label="usb-1-1" vendor_id="0x1d6b" product_id="0x0002" bus="0x0001" dev="0x0001"/> !</devices> For every device a unique identifier is generated that is used to access the USB device. Only devices that have a valid policy configured at the USB driver can be accessed by a client. The following configuration allows 'comp1' to access the device 'usb-1-6': !<start name="usb_drv"> ! <resource name="RAM" quantum="8M"/> ! <provides><service name="Usb"/></provides> ! <config uhci="yes" ohci="yes" ehci="yes" xhci="yes"> ! <raw> ! <report devices="yes"/> ! <policy label="comp1 -> usb-1-6" vendor_id="0x13fe" product_id="0x5200" bus="0x0001" dev="0x0006"/> ! </raw> ! </config> !</start> In addition to the mandatory 'label' attribute the policy node also contains optional attribute tuples of which at least one has to be present. The 'vendor_id' and 'product_id' tuple selects a device regardless of its location on the USB bus and is mostly used in static configurations. The 'bus' and 'dev' tuple selects a specific device via its bus locations and device address. It is mostly used in dynamic configurations because the device address is not fixed and may change every time the same device is plugged in. The configuration of the USB driver can be changed at runtime to satisfy dynamic configurations or rather policies when using the 'Usb' session interface. LXIP #### LXIP is a port of the Linux TCP/IP stack to Genode. It is build as a shared library named 'lxip.lib.so'. The IP stack can be interfaced using Genode's version of 'libc' by linking your application to 'lxip_libc' plugin in your 'target.mk' file. WIFI #### The wifi_drv component is a port of the Linux mac802.11 stack, including the iwlwifi driver as well as libnl and wpa_supplicant, to Genode. Configuration snippet: !<start name="wifi_drv"> ! <resource name="RAM" quantum="32M"/> ! <provides><service name="Nic"/></provides> ! <config> ! <libc stdout="/dev/log" stderr="/dev/log" rtc="/dev/rtc"> ! <vfs> ! <dir name="dev"> <log/> <rtc/> ! <jitterentropy name="random"/> ! <jitterentropy name="urandom"/> ! </dir> ! <dir name="config"> <ram/> </dir> ! </vfs> ! </libc> ! </config> ! <route> ! <service name="Rtc"> <any-child /> </service> ! <any-service> <parent/> <any-child /> </any-service> ! </route> !</start Per default, the driver scans for available networks only when not connected. This can be changed with the 'connected_scan_interval' config attribute, which specifies the interval for connected scans in seconds, e.g. !<config connected_scan_interval="30">...</config> Also, the driver can be switched to verbose logging with !<config verbose="yes">...</config> The wifi_drv creates two distinct reports to communicate its state and information about the wireless infrastructure to other components. The first one is a list of all available accesspoints. The following examplary report shows its structure: !<wlan_accesspoints> ! <accesspoint ssid="skynet" bssid="00:01:02:03:04:05" quality="40"/> ! <accesspoint ssid="foobar" bssid="01:02:03:04:05:06" quality="70" protection="WPA-PSK"/> ! <accesspoint ssid="foobar" bssid="01:02:03:04:05:07" quality="10" protection="WPA-PSK"/> !</wlan_accesspoints> Each accesspoint node has attributes that contain the SSID and the BSSID of the accesspoint as well as the link quality (signal strength). These attributes are mandatory. If the network is protected, the node will also have an attribute describing the type of protection in addition. The second report provides information about the state of the connection to the currently connected accesspoint: !<wlan_state> ! <accesspoint ssid="foobar" bssid="01:02:03:04:05:06" quality="70" protection="WPA-PSK" state="connected"/> !</wlan_state> Valid state values are 'connected', 'disconnected', 'connecting' and 'disconnecting'. In return, the wifi_drv get its configuration via a ROM module. This ROM module contains the configuration for the selected accesspoint. To connect to an open accesspoint a configuration like the following is used: !<selected_accesspoint ssid="foobar"/> If the network is protected by, e.g., WPA/WPA2, the protection type as well as the the pre-shared key have to be specified: !<selected_accesspoint ssid="securefoobar" protection="WPA-PSK" psk="foobar123!"/> If a network consists of several different access points and a particular one should be used it can be selected by specifing its BSSID in a 'bssid' attribute. Of all attributes only the 'ssid' attribute is mandatory, all others are optional and should only be used when needed. To disconnect from an accesspoint, a empty configuration is sent: !<selected_accesspoint/> By subscribing to both reports and providing the required ROM module, a component can control the wireless driver. An example therefore is the Qt based component in 'src/app/qt_wifi_connect'. Currently only WPA/WPA2 protection using a pre-shared key is supported. On certain cards, e.g. Intel Wireless 6200 ABG, it may be necessary to disable the 11n mode. This can be achieved by setting the 'use_11n' attribute in the config node to 'no'. lx_kit ###### The modular lx_kit seperates the required back end functionality of the Linux emulation environment from the front end. Thereby each driver can reuse specific parts or supply more suitable implementations by itself. It is used to reduce the amount of redundant code in each driver. The lx_kit is split into several layers whose structure is as follows: The first layer in _repos/dde_linux/src/include/lx_emul_ contains those header files that provide the structural definitions and function declarations of the Linux API, e.g. _errno.h_ provides all error code values. The second layer in _repos/dde_linux/src/include/lx_emul/impl_ contains the implementation of selected functions, e.g. _slab.h_ provides the implementation of 'kmalloc()'. The lx_kit back end API is the third layer and provides the _Lx::Malloc_ interface (_repos/dde_linux/src/include/lx_kit/malloc.h_) which is used to implement 'kmalloc()'. There are several generic implementations of the lx_kit interfaces that can be used by a driver. A driver typically includes a 'lx_emul/impl/xyz.h' header once directly in its lx_emul compilation unit. The lx_kit interface files are only included in those compilation units that use or implement the interface. If a driver wants to use a generic implementation it must add the source file to its source file list. The generic implementations are located in _repos/dde_linux/src/lx_kit/_. The modular lx_kit still depends on the private _lx_emul.h_ header file that is tailored to each driver. Since the lx_kit already contains much of the declarations and definitions that were originally placed in these private header files, those files can now ommit a large amount of code.