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man pages section 7: Device and Network Interfaces     Oracle Solaris 11.1 Information Library
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Document Information

Preface

Introduction

Device and Network Interfaces

1394(7D)

aac(7D)

adpu320(7D)

afe(7D)

agpgart_io(7I)

AH(7P)

ahci(7D)

allkmem(7D)

amd8111s(7D)

arcmsr(7D)

arn(7D)

ARP(7P)

arp(7P)

ast(7D)

asy(7D)

ata(7D)

atge(7D)

ath(7D)

atu(7D)

audio1575(7D)

audio(7D)

audio(7I)

audio810(7D)

audiocmi(7D)

audiocs(7D)

audioemu10k(7D)

audioens(7D)

audiohd(7D)

audioixp(7D)

audiols(7D)

audiop16x(7D)

audiopci(7D)

audiosolo(7D)

audiots(7D)

audiovia823x(7D)

av1394(7D)

balloon(7D)

bbc_beep(7D)

bcm_sata(7D)

bfe(7D)

bge(7D)

blkdev(7D)

bmc(7D)

bnx(7D)

bnxe(7D)

bpf(7D)

bscbus(7D)

bscv(7D)

bufmod(7M)

cdio(7I)

chxge(7D)

cmdk(7D)

connld(7M)

console(7D)

cpqary3(7D)

cpr(7)

cpuid(7D)

ctfs(7FS)

cxge(7D)

dad(7D)

daplt(7D)

dca(7D)

dcam1394(7D)

dcfs(7FS)

dev(7FS)

devchassis(7FS)

devfs(7FS)

devinfo(7D)

dkio(7I)

dlcosmk(7ipp)

dlpi(7P)

dm2s(7D)

dmfe(7D)

dnet(7D)

dr(7d)

drmach(7d)

dscpmk(7ipp)

dsp(7I)

dtrace(7D)

e1000(7D)

e1000g(7D)

ecpp(7D)

efb(7D)

ehci(7D)

eibnx(7D)

elxl(7D)

emlxs(7D)

eoib(7D)

eri(7D)

ESP(7P)

evb(7P)

fas(7D)

fasttrap(7D)

fbio(7I)

fbt(7D)

fcip(7D)

fcoe(7D)

fcoei(7D)

fcoet(7D)

fcp(7D)

fctl(7D)

fipe(7D)

firewire(7D)

flowacct(7ipp)

fp(7d)

FSS(7)

gld(7D)

glm(7D)

hci1394(7D)

hdio(7I)

heci(7D)

hermon(7D)

hid(7D)

hme(7D)

hsfs(7FS)

hubd(7D)

hwa1480_fw(7D)

hwahc(7D)

hwarc(7D)

hxge(7D)

i2bsc(7D)

i915(7d)

ib(7D)

ibcm(7D)

ibdm(7D)

ibdma(7D)

ibmf(7)

ibp(7D)

ibtl(7D)

icmp6(7P)

ICMP(7P)

icmp(7P)

iec61883(7I)

ieee1394(7D)

if(7P)

ifp(7D)

if_tcp(7P)

igb(7D)

igbvf(7D)

ii(7D)

imraid_sas(7D)

inet6(7P)

inet(7P)

ip6(7P)

IP(7P)

ip(7P)

ipgpc(7ipp)

ipmi(7D)

ipnat(7I)

ipnet(7D)

ipqos(7ipp)

iprb(7D)

ipsec(7P)

ipsecah(7P)

ipsecesp(7P)

ipw(7D)

iscsi(7D)

isdnio(7I)

iser(7D)

isp(7D)

iwh(7D)

iwi(7D)

iwk(7D)

iwp(7D)

ixgb(7d)

ixgbe(7D)

ixgbevf(7D)

kb(7M)

kdmouse(7D)

kmdb(7d)

kmem(7D)

kstat(7D)

ksyms(7D)

ldterm(7M)

llc1(7D)

llc2(7D)

lo0(7D)

lockstat(7D)

lofi(7D)

lofs(7FS)

log(7D)

lsc(7D)

marvell88sx(7D)

mc-opl(7D)

mcxe(7D)

md(7D)

mediator(7D)

mega_sas(7D)

mem(7D)

mga(7D)

mhd(7i)

mixer(7I)

mpt(7D)

mpt_sas(7D)

mr_sas(7D)

msglog(7D)

mt(7D)

mtio(7I)

mwl(7D)

mxfe(7D)

myri10ge(7D)

n2cp(7d)

n2rng(7d)

nca(7d)

ncp(7D)

ngdr(7d)

ngdrmach(7d)

nge(7D)

npe(7D)

ntwdt(7D)

ntxn(7D)

null(7D)

nulldriver(7D)

nv_sata(7D)

nxge(7D)

objfs(7FS)

oce(7D)

ohci(7D)

openprom(7D)

oplkmdrv(7D)

oplmsu(7D)

oplpanel(7D)

packet(7P)

pcan(7D)

pcata(7D)

pcfs(7FS)

pcic(7D)

pcicmu(7D)

pcie_pci(7D)

pckt(7M)

pcmcia(7D)

pcn(7D)

pcser(7D)

pcwl(7D)

pf_key(7P)

pfmod(7M)

PF_PACKET(7P)

physmem(7D)

pipemod(7M)

pm(7D)

poll(7d)

prnio(7I)

profile(7D)

ptem(7M)

ptm(7D)

pts(7D)

pty(7D)

qfe(7d)

qlc(7D)

qlcnic(7D)

qlge(7D)

quotactl(7I)

radeon(7d)

ral(7D)

ramdisk(7D)

random(7D)

RARP(7P)

rarp(7P)

rge(7D)

route(7P)

routing(7P)

rtls(7D)

rtw(7D)

rum(7D)

rwd(7D)

rwn(7D)

sad(7D)

sata(7D)

scfd(7D)

scsa1394(7D)

scsa2usb(7D)

scsi_vhci(7D)

SCTP(7P)

sctp(7P)

scu(7D)

sd(7D)

sda(7D)

SDC(7)

sdcard(7D)

sdhost(7D)

sdp(7D)

sdt(7D)

se(7D)

se_hdlc(7D)

ses(7D)

sesio(7I)

sf(7D)

sfe(7D)

sgen(7D)

sharefs(7FS)

si3124(7D)

sip(7P)

slp(7P)

smbfs(7FS)

smbios(7D)

smbus(7D)

smp(7D)

snca(7d)

socal(7D)

sockio(7I)

sol_ofs(7D)

sol_ucma(7D)

sol_umad(7D)

sol_uverbs(7D)

sppptun(7M)

srpt(7D)

ssd(7D)

st(7D)

streamio(7I)

su(7D)

sv(7D)

sxge(7D)

sysmsg(7D)

systrace(7D)

TCP(7P)

tcp(7P)

termio(7I)

termiox(7I)

ticlts(7D)

ticots(7D)

ticotsord(7D)

timod(7M)

tirdwr(7M)

tmpfs(7FS)

todopl(7D)

tokenmt(7ipp)

tsalarm(7D)

tswtclmt(7ipp)

ttcompat(7M)

tty(7D)

ttymux(7D)

tzmon(7d)

uata(7D)

uath(7D)

udfs(7FS)

UDP(7P)

udp(7P)

ufs(7FS)

ugen(7D)

uhci(7D)

ural(7D)

urandom(7D)

urtw(7D)

usb(7D)

usba(7D)

usb_ac(7D)

usb_ah(7M)

usb_as(7D)

usbecm(7D)

usbftdi(7D)

usb_ia(7D)

usbkbm(7M)

usb_mid(7D)

usbms(7M)

usbprn(7D)

usbsacm(7D)

usbser_edge(7D)

usbsksp(7D)

usbsprl(7D)

usbvc(7D)

usbwcm(7M)

uscsi(7I)

usmp(7I)

uvfs(7FS)

uwb(7D)

uwba(7D)

virtualkm(7D)

visual_io(7I)

vni(7d)

vr(7D)

vt(7I)

vuid2ps2(7M)

vuid3ps2(7M)

vuidm3p(7M)

vuidm4p(7M)

vuidm5p(7M)

vuidmice(7M)

vxge(7D)

wpi(7D)

wscons(7D)

wusb_ca(7D)

wusb_df(7D)

xge(7D)

xhci(7D)

yge(7D)

zcons(7D)

zero(7D)

zfs(7FS)

zs(7D)

zsh(7D)

zyd(7D)

ugen

- USB generic driver

Synopsis

Node Name@unit-address
#include <sys/usb/clients/ugen/usb_ugen.h>

Description

ugen is a generic USBA (Solaris USB Architecture) compliant client character driver that presents USB devices to applications through a standard open(2), close(2), read(2), write(2), aioread(3C), aiowrite(3C) Unix interface. Uninterpreted raw data are transferred to and from the device via file descriptors created for each USB endpoint. Status is obtained by reading file descriptors created for endpoint and full device status.

ugen supports control, bulk, isochronous and interrupt (in and out) transfers. libusb(3LIB) uses ugen to access devices that do not contain drivers (such as digital cameras and PDAs). Refer to /usr/sfw/share/doc/libusb/libusb.txt for details.

BINDING

In general, no explicit binding of the ugen driver is necessary because usb_mid(7D) is the default driver for devices without a class or vendor unique driver. usb_mid(7D) creates the same logical device names as ugen, but only if no child interfaces are explicitly bound to ugen. If it is necessary to bind ugen explicitly to a device or interface, the following section explains the necessary steps.

ugen can bind to a device with one or more interfaces in its entirety, or to a single interface of that device. The binding type depends on information that is passed to add_drv(1M) or update_drv(1M).

An add_drv(1M) command binds ugen to a list of device types it is to control. update_drv(1M) adds an additional device type to the list of device types being managed by the driver.

Names used to bind drivers can be found in /var/adm/messages. When a device is on-lined after hot insertion, and no driver is found, there is an entry containing:

USB 2.0 device (usb<vid>,<pid>)...

where vid is the USB vendor identifier in hex and pid is the product identifier in hex supplied by the device descriptor usb_dev_descr(9S).

When using ugen for the first time, you must add the driver utilizing add_drv(1M), using a command of the following form:

Assuming that the vid is 472 and pid is b0b0:

add_drv -n -m '* <device perms> <owner> <group>' 
   -i '"usb472,b0b0"' ugen

If the command fails with:

(ugen) already in use as a driver or alias.

...add the device using update_drv(1M):

update_drv -a -m '* <device perms> <owner> <group>'
   -i '"usb472,b0b0"' ugen 

This binds ugen to the entire device.

If ugen only binds to one interface of the device, use the following driver_alias instead of usb<vid>,<pid>:

       usbif<vid>,<pid>.config<cfg value>.<interface number>

where cfg value is the value of bConfigurationValue in the configuration descriptor (usb_cfg_descr(9S)), for example usbif1234,4567.config1.0.

You can use update_drv to also remove bindings. Please see update_drv(1M) for more information.

After a successful add_drv or update_drv, remove the device and reinsert. Check with the prtconf(1M) -D option to determine if ugen is successfully bound to the device and the nodes created in /dev/usb/<vid>.<pid> (see below).

An example showing how to bind a child device representing interface 0 of configuration 1 of a composite device follows:

update_drv -a -m '* 0666 root sys'
    -i '"usbif472,b0b0.config1.0"' ugen

Note that you can completely uninstall the ugen driver and delete it from the system by doing:

pkgrm SUNWugen

Any pkgadd of SUNWugen after the pkgrm reactivates any pre-existing ugen driver device-bindings.

Any pre-existing ugen driver device-bindings are preserved across operating system upgrades.

LOGICAL DEVICE NAME FORMAT

For each device or child device it manages, ugen creates one logical device name for device-wide status and one logical device name for endpoint 0. ugen also creates logical device names for all other endpoints within the device node's binding scope (interface or device), plus logical device names for their status.

If separate ugen instances control different interfaces of the same device, the device-wide status and endpoint logical device names created for each instance shares access to the same source or endpoint pipes. For example, a device with two interfaces, each operated by their own ugen instance, shows endpoint0 as if0cntrl0 to the first interface, and shows it as if1cntrl0 to the second interface. Both of these logical device names share endpoint0. Likewise for the same device, ugen makes the device-wide status available as if0devstat to the first interface and as if1devstat to the second interface. if0devstat and if1devstat both return the same data.

Any ugen logical device name can be held open by only one user at a time, regardless of whether the O_EXCL flag passed to open(2). When a single pipe or data source is shared by multiple logical device names, such as if[0,1]cntrl0 or if[0,1]devstat above, more than one logical device name sharing the pipe or data source can be open at a time. However, only one user can access the shared pipe or data source at a time, regardless of the logical device name used for access.

When ugen is bound to an entire device, the following logical device names are created (each on a single line). N represents the instance number of the device type.

Endpoint 0 (default endpoint):

        /dev/usb/<vid>.<pid>/<N>/cntrl0
        /dev/usb/<vid>.<pid>/<N>/cntrl0stat

    For example:

        /dev/usb/472.b0b0/0/cntrl0
        /dev/usb/472.b0b0/0/cntrl0stat

Configuration index 1, Endpoints > 0, alternate 0:

        /dev/usb/<vid>.<pid>/<N>/if<interface#>
                                <in|out|cntrl><endpoint#>
        /dev/usb/<vid>.<pid>/<N>/if<interface#>
                                <in|out|cntrl><endpoint#>stat

    For example:

        /dev/usb/472.b0b0/0/if0in1
        /dev/usb/472.b0b0/0/if0in1stat

Configuration index 1, Endpoints > 0, alternate > 0:

        /dev/usb/<vid>.<pid>/<N>/if<interface#>.
                                <alternate><in|out|cntrl><endpoint#>
        /dev/usb/<vid>.<pid>/<N>/if<interface#>.
                                <alternate<in|out|cntrl><endpoint#>stat

    For example:
 
        /dev/usb/472.b0b0/0/if0.1in3
        /dev/usb/472.b0b0/0/if0.1in3stat

Configuration index> 1, Endpoints > 0, alternate 0:
        /dev/usb/<vid>.<pid>/<N>/cfg<value>if<interface#>
                                <in|out|cntrl><endpoint#>
        /dev/usb/<vid>.<pid>/<N>/cfg<value>if<interface#>
                                <in|out|cntrl><endpoint#>stat

    For example:

       /dev/usb/472.b0b0/0/cfg2if0in1
       /dev/usb/472.b0b0/0/cfg2if0in1stat
    
    Note that the configuration value from the configuration
    descriptor indexed by the configuration index is used in
    the node name and not the configuration index itself.

Configuration index> 1, Endpoints > 0, alternate > 0:
        /dev/usb/<vid>.<pid>/<N>/cfg<value>if<interface#>.
                                <alternate<in|out|cntrl><endpoint#>
        /dev/usb/<vid>.<pid>/<N>/cfg<value>if<interface#>.
                                <alternate<in|out|cntrl><endpoint#>stat

    For example:

        /dev/usb/472.b0b0/0/cfg2if0.1in1
        /dev/usb/472.b0b0/0/cfg2if0.1in1stat

  Device status:

        /dev/usb/<vid>.<pid>/<N>/devstat

    For example:

        /dev/usb/472.b0b0/0/devstat

When ugen is bound to a single device interface, the following logical device nodes are created:

Endpoint 0 (default endpoint):

         /dev/usb/<vid>.<pid>/<N>/if<interface#>cntrl0
         /dev/usb/<vid>.<pid>/<N>/if<interface#>cntrl0stat

    For example:

         /dev/usb/472.b0b0/0/if0cntrl0
         /dev/usb/472.b0b0/0/if0cntrl0stat

Device status:
        /dev/usb/<vid>.<pid>/<N>/if<interface#>devstat

    For example:
        /dev/usb/472.b0b0/0/if0devstat

The format for all other logical device names is identical to the format used when ugen is bound to the entire device.

Opening the endpoint of a different configuration or different alternate interface causes an implicit change of configuration or a switch to an alternate interface. A configuration change is prohibited when any non-zero endpoint device nodes are open. An alternate interface switch is prohibited if any endpoint in the same interface is open.

HOT-PLUGGING

A device can be hot-removed at any time. Following hot-removal, the device status changes to USB_DEV_STAT_DISCONNECTED, the status of open endpoints change to USB_LC_STAT_DISCONNECTED upon their access, and all subsequent transfer requests fail. Endpoints are reactivated by first reinserting the device and then closing and reopening all endpoints that were open when the device was disconnected.

CPR (CHECKPOINT/RESUME)

CPR (Checkpoint/Resume) can be initiated at any time and is treated similarly to a hot-removal. Upon successful suspend and resume, all subsequent transfer requests fail as an indication to the application to re-initialize. Applications should close and reopen all endpoints to reinstate them. All endpoint and device status on Resume (before close and reopen) is USB_LC_STAT_SUSPENDED. A system suspend fails while ugen is performing a transfer.

DEVICE POWER MANAGEMENT

Devices which support remote wakeup can be power managed when they have no open logical device nodes. When an application opens the first logical device node of a device, that application should assume that a re-initialization of device state is required.

DEVICE STATUS MANAGEMENT

Applications can monitor device status changes by reading the device status from the device status logical name. When opened without O_NONBLOCK and O_NDELAY, all reads from that file descriptor (with the exception of the initial read that follows the open) block until a device status change occurs. Calls to read always return immediately if opened with O_NONBLOCK or O_NDELAY. Nonblocking calls to read which have no data to return, return no error and zero bytes read.

Device statuses are:

USB_DEV_STAT_ONLINE

Device is available.

USB_DEV_STAT_DISCONNECTED

Device has been disconnected.

USB_DEV_STAT_RESUMED

Device has been resumed, however, endpoints which were open on suspend have not yet been closed and reopened.

USB_DEV_STAT_UNAVAILABLE

Device has been reconnected, however, endpoints which were open on disconnect have not yet been closed and reopened.

The following code reads the device status device logical name:

int fd;
int status;

if ((fd = open("/dev/usb/472.b0b0/0/devstat",
    O_RDONLY)) < 0)     {
        /* handle error */
}

if (read(fd, &status, sizeof(status))  != sizeof(status)) {
        /* handle error */
}

switch (status) {
case USB_DEV_STAT_DISCONNECTED:
        printf ("Terminating as device has been disconnected.\n");
        exit (0);

case USB_DEV_STAT_RESUMED:
case USB_DEV_STAT_UNAVAILABLE:
        /*
         * Close and reopen endpoints to reestablish device access,
         * then reset device.
         */
        break;

case USB_DEV_STAT_ONLINE:
default:
        break;
}

Use poll(2) to block on several logical names simultaneously, including device status logical names. Poll indicates when reading a logical name would return data. See poll(2) for details. Calls to read can be done whether or not they follow calls to poll.

ENDPOINT STATUS MANAGEMENT

Each data endpoint has a corresponding status logical name. Use the status logical name to retrieve the state of the data endpoint, including detail on how its most recent transfer failed. Reads of the status file descriptors always return immediately. See the ERRORS section for more information on endpoint status values. All logical device name files created for returning status must be opened with O_RDONLY.

The following code illustrates reading the status file descriptor of an endpoint which just failed a data transfer in order to get more information on the failure.

int data_xfered, status;
int ep1_data_fd, ep1_stat_fd;
uchar_t request[8];

ep1_data_fd = open ("/dev/usb/472.b0b0/0/if0out1", O_WRONLY);

if (ep1_data_fd < 0) {
        /* Handle open error. */
}

ep1_stat_fd = open ("/dev/usb/472.b0b0/0/if0out1stat",
    O_RDONLY);
if (ep1_stat_fd < 0) {
        /* Handle open error. */
}

data_xfered = write(ep1_data_fd, request, sizeof (request));

/* An error occured during the data transfer. */
if (data_xfered != sizeof (request)) {

        /* Read status file descriptor for details on failure. */
        if (read(ep1_stat_fd, (int *)&status, sizeof (status)) !=
            sizeof (status)) {
                status = USB_LC_STAT_UNSPECIFIED_ERR;
        }

        /* Take appropriate action. */
        switch (status) {
        case USB_LC_STAT_STALL:
                printf ("Endpoint stalled.\n");
                break;
        case ...
                ...
        }

   }

CONTROL TRANSFERS

The control endpoint is typically used to set up the device and to query device status or configuration.

Applications requiring I/O on a control endpoint should open the corresponding logical device name and use regular UNIX I/O system calls. For example: read(2), write(2), aioread(3C) and aiowrite(3C). poll(2) is not supported on control endpoints.

A control endpoint must be opened with O_RDWR since it is bidirectional. It cannot be opened with O_NONBLOCK or O_NDELAY.

For example:

fd = open("/dev/usb/472.b0b0/0/cntrl0", O_RDWR);
        
fdstat = open("/dev/usb/472.b0b0/0/cntrl0stat", O_RDONLY);

Control endpoints can be read and written. A read operation receives data from the device and a write operation sends data to the device.

To perform a control-IN transfer, perform a write(2) of USB setup data (see section 9.3 of the USB 1.1 or 2.0 specifications) followed by a read(2) on the same control endpoint to fetch the desired data. For example:

void init_cntrl_req(
    uchar_t *req, uchar_t bmRequestType, uchar_t bRequest,
    ushort_t wValue, ushort_t wIndex, ushort_t wLength) {
        req[0] = bmRequestType;
        req[1] = bRequest;
        req[2] = 0xFF & wValue;
        req[3] = 0xFF & (wValue >> 8);
        req[4] = 0xFF & wIndex;
        req[5] = 0xFF & (wIndex >> 8);
        req[6] = 0xFF & wLength;
        req[7] = 0xFF & (wLength >> 8);
 }

 ....


        uchar_t dev_descr_req[8];
        usb_dev_descr_t descr;

        init_cntrl_req(dev_descr_req,
            USB_DEV_REQ_DEV_TO_HOST, USB_REQ_GET_DESCR,
            USB_DESCR_TYPE_SETUP_DEV, 0, sizeof (descr));

        count = write(fd, dev_descr_req, sizeof (dev_descr_req));
        if (count != sizeof (dev_descr_req)) {
                /* do some error recovery */
                ...
        }

        count = read(fd, &descr, sizeof (descr));
        if (count != sizeof (descr)) {
                /* do some error recovery */
        }

The application can issue any number of reads to read data received on a control endpoint. ugen successfully completes all reads, returning the number of bytes transferred. Zero is returned when there is no data to transfer.

If the read/write fails and returns –1, you can access the endpoint's status device logical name for precise error information:

        int status;

        count = read(fdstat, &status, sizeof (status));
        if (count == sizeof (status)) {
                switch (status) {
                case USB_LC_STAT_SUSPENDED:
                case USB_LC_STAT_DISCONNECTED:
                        /* close all endpoints */
                        ...
                        break;
                default:
                        ...
                        break;
                }
        }

Refer to the ERRORS section for all possible error values.

To perform a control-OUT transfer, send in a single transfer, the USB setup data followed by any accompanying data bytes.

    /* 1st 8 bytes of wbuf are setup. */
    init_cntrl_req(wbuf, .......);

    /* Data bytes begin at byte 8 of wbuf. */
    bcopy(data, &wuf[8], sizeof (data));

    /* Send it all in a single transfer. */
    count = write(fd, wbuf, sizeof (wbuf));

A write(2) returns the number of bytes (both setup and data) actually transferred, (whether or not the write is completely successful), provided that some data is actually transferred. When no data is transferred, write(2) returns -1. Applications can read the corresponding endpoint status to retrieve detailed error information. Note that it is an error to specify a size different than:

(number of data bytes + number of setup bytes).

Here is a more extensive example which gets all descriptors of a device configuration. For sake of brevity, uninteresting parts are omitted.

   #include <sys/usb/usba.h>
   #include <sys/usb/clients/ugen/usb_ugen.h>

   uchar_t *config_cloud;
   uchar_t *curr_descr;

   uchar_t *bytes;
  
   int curr_descr_len;
   int curr_descr_type;
   
   usb_cfg_descr_t cfg_descr;
   usb_if_descr_t if_descr;
   usb_ep_descr_t ep_descr;
  
   /* See 9.13 of USB 2.0 spec for ordering. */
   static char *pipetypes[] = {
        "Control", "Isochronous", "Bulk", "Interrupt"
   };
  
   /*
    * Setup to send a request to read just the config descriptor.  The
    * size of the whole cloud, containing all cfg, interface, endpoint,
    * class and vendor-specific descriptors, will be returned as part of
    * the config descriptor.
    */
   init_cntrl_req(&setup_data, USB_DEV_REQ_DEV_TO_HOST, USB_REQ_GET_DESCR,
                   USB_DESCR_TYPE_SETUP_CFG, 0, USB_CFG_DESCR_SIZE);
   
   /*
    * Write setup data. USB device will prepare to return the whole
    * config cloud as a response to this. We will read this separately.
    */
   count = write(ctrl_fd, &setup_data, sizeof (setup_data));
   if (count != sizeof (setup_data)) {
            /* Error recovery. */
   } else {
           count = read(ctrl_fd, &cfg_descr, USB_CFG_DESCR_SIZE);
           if (count != USB_CFG_DESCR_SIZE) {
                    /* Error recovery. */
           }
   }
   
   /* USB data is little endian. */
   bytes = (uchar_t *)(&cfg_descr.wTotalLength);
   totalLength = bytes[0] + (bytes[1] << 8);
   
   /*
    * The size of the whole cloud is in the bLength field.  Set up
    * to read this amount of data, to get the whole cloud.
    */
   config_cloud = malloc(totalLength);
   
   init_cntrl_req(&setup_data, USB_DEV_REQ_DEV_TO_HOST, USB_REQ_GET_DESCR,
                   USB_DESCR_TYPE_SETUP_CFG, 0, totalLength);
   
   count = write(ctrl_fd, &setup_data, sizeof (setup_data));                                                                                                 
   if (count != sizeof (setup_data)) {
           /* Error recovery. */
   } else {
           count = read(ctrl_fd, config_cloud, totalLength);
           if (count != totalLength) {
                   /* Error recovery. */
            }
   }
   
   /* Got the data.  Now loop, dumping out the descriptors found. */
   
   curr_descr = config_cloud;
   offset = 0;
   while (offset < totalLength) {
   
           /* All descr have length and type at offset 0 and 1 */
           curr_descr_len = curr_descr[0];
           curr_descr_type = curr_descr[1];
           
           switch (curr_descr_type) {
           case USB_DESCR_TYPE_CFG:
           
                    /*
                     * Copy data into separate structure, needed for                                                                   
                     * proper alignment of all non char fields.  Note:
                     * non-char fields of all descriptors begin on aligned
                     * boundaries.  The issue is that some structures may
                     * be adjacent to others which have an odd-numbered
                     * byte size, and may thus start on an odd-numbered
                     * boundary.  */
                    bcopy(curr_descr, &cfg_descr, curr_descr_len);    

                    /* Remember to read any words in endian-neutral way. */
                    
                    (void) printf("\nConfig %d found.\n",
                        cfg_descr.bConfigurationValue);
                    break;
                     
            case USB_DESCR_TYPE_IF:
                    bcopy(curr_descr, &if_descr, curr_descr_len);
                    (void) printf("\n\tInterface %d, Alt %d found.\n",
                        if_descr.bInterfaceNumber,
                        if_descr.bAlternateSetting);
                    break;
                  
            case USB_DESCR_TYPE_EP:
                    bcopy(curr_descr, &ep_descr, curr_descr_len);
                    (void) printf("\n\t\tEndpoint %d (%s-%s) found.\n",
                        (ep_descr.bEndpointAddress & USB_EP_NUM_MASK),
                        (pipetypes[
                            ep_descr.bmAttributes & USB_EP_ATTR_MASK]),
                        ((ep_descr.bEndpointAddress &
                        USB_EP_DIR_IN) ? "IN" : "OUT"));
                     break;

             default:
                     (void) printf(
                         "\n\t\t\tOther descriptor found.  Type:%d\n",
                         curr_descr_type);
                     break;
             }
             
             offset += curr_descr_len;
             curr_descr = &config_cloud[offset];
   }

INTERRUPT-IN TRANSFERS

Applications requiring data from an interrupt-IN endpoint should open the corresponding logical device name and use read(2), aioread(3C) and poll(2) system calls.

An interrupt-IN endpoint must be opened with O_RDONLY. It can also be opened using O_NONBLOCK or O_NDELAY if desired.

fd = open("/dev/usb/472.b0b0/0/if0in1", O_RDONLY);
fdstat = open("/dev/usb/472.b0b0/0/if0in1stat", O_RDONLY);
    

ugen starts polling interrupt—IN endpoints immediately upon opening them and stops polling them upon closure. (Polling refers to interrogation of the device by the driver and should not be confused with poll(2), which is an interrogation of the driver by the application.)

A read(2) of an endpoint opened with the O_NONBLOCK or O_NDELAY flags set do not block when there is insufficient data available to satisfy the request. The read simply returns what it can without signifying any error.

Applications should continuously check for and consume interrupt data. ugen enables buffering of up to one second of incoming data. In case of buffer overflow, ugen stops polling the interrupt-IN endpoint until the application consumes all the data. In this case, a read(2) of an empty buffer returns -1, sets the endpoint status to USB_LC_STAT_INTR_BUF_FULL (to indicate that the buffer had been full and polling had been stopped) and causes ugen to start polling the endpoint again. To retrieve the status, the application can open and read the corresponding endpoint's status device logical name.

for (;;) {
        count = read(fd, buf, sizeof(buf));
        if (count == -1) {
                int cnt, status;

                cnt = read(fdstat, &status, sizeof (status));
                if (cnt == -1) {
                         /* more error recovery here */
                } else {
                        switch (status) {
                        case USB_LC_STAT_INTR_BUF_FULL:
                               ...
                               break;
                        default:
                               ...
                               break;
                        }
                }
           }
           /* process the data */
           ....
        }

ugen never drop data. However, the device can drop data if the application cannot read it at the rate that it is produced.

Applications requiring unbuffered data from an interrupt-IN endpoint should open the associated status endpoint with O_RDWR before opening the associated interrupt-IN endpoint and write a control byte with USB_EP_INTR_ONE_XFER set. All other bits are reserved and should be 0.

One transfer mode persists until disabled explicitly after the associated interrupt-IN endpoint has been closed by writing a control byte with USB_EP_INTR_ONE_XFER cleared.

One transfer mode is implicitly disabled when the status/control endpoint is closed.

Attempts to change the one transfer mode while the endpoint is open results in EINVAL.

An application can open multiple interrupt-IN endpoints and can call poll(2) to monitor the availability of new data. (Note: poll works with interrupt-IN data endpoints, not their status endpoints.)

        struct pollfd pfd[2];

        bzero(pfd, sizeof (pfd));
        pfd[0].fd = fd1;    /* fd1 is one interrupt-IN endpoint. */
        pfd[0].events = POLLIN;
        pfd[1].fd = fd2;    /* fd2 is another interrupt-IN endpoint. */
        pfd[1].events = POLLIN;

        for (;;) {
                poll(pfd, 2, -1);

                if (pfd[0].revents & POLLIN) {
                        count = read(fd1, buf, sizeof (buf));
                        ....
                } 
                if (pfd[1].revents & POLLIN) {
                        count = read(fd2, buf, sizeof (buf));
                        ....
                } 
        }

You can monitor the device status endpoint via poll(2) concurrently with the multiple interrupt-IN endpoints. Simply add another pollfd element to the pfd array in the previous code example, and initialize the new element's fd field with the file descriptor of the device status endpoint (opened without O_NONBLOCK or O_NDELAY). Set the new element's event field to POLLIN like the other elements. Note that only interrupt–IN endpoints and the device status endpoint can be monitored using poll(2).

INTERRUPT-OUT TRANSFERS

Applications requiring output on an interrupt-OUT endpoint can open the corresponding logical device name and perform regular UNIX I/O system calls such as write(2) and aiowrite(3C).

An interrupt-OUT endpoint must be opened with O_WRONLY.

fd = open("/dev/usb/472.b0b0/0/if0out3", O_WRONLY);

fdstat = open("/dev/usb/472.b0b0/0/if0out3stat", O_RDONLY);

Data can be written to an interrupt-OUT endpoint as follows:

      count = write(fd, buf, sizeof (buf)):
      if (count == -1) {
             /* error recovery */
      }

BULK TRANSFERS

Applications requiring I/O on a bulk endpoint can open the corresponding logical device name and perform regular UNIX I/O system calls. For example: read(2), write(2), aioread(3C) and aiowrite(3C). poll(2) is not supported on bulk endpoints.

A bulk endpoint must be opened with O_RDONLY or O_WRONLY and cannot be opened with O_NONBLOCK or O_NDELAY:

fd = open("/dev/usb/472.b0b0/0/if0in2", O_RDONLY);
fdstat = open("/dev/usb/472.b0b0/0/if0in2stat", O_RDONLY);

Data can be read from a bulk-IN endpoint as follows:

        count = read(fd, buf, sizeof (buf)):
        if (count == -1) {
                /* error recovery */
        }

 Data can be written to a bulk-OUT endpoint as follows:

        count = write(fd, buf, sizeof (buf)):
        if (count == -1) {
                /* error recovery */
        }

ISOCHRONOUS TRANSFERS

Applications requiring I/O on an isochronous endpoint can open the corresponding logical device name and perform regular UNIX I/O system calls such as read(2), write(2), poll(2), aioread(3C) and aiowrite(3C). An isochronous endpoint must be opened with O_RDWR.

fd = open("/dev/usb/472.b0b0/0/if0.3in2", O_RDWR);

fdstat = open("/dev/usb/472.b0b0/0/if0.3in2stat", O_RDONLY);

Applications can use the status logical name to retrieve the state of the isochronous data endpoint, including details on why the most recent transfer failed.

Applications have the flexibility to specify the number of isochronous packets and the size of individual packets they want to transfer. Applications should use the following data structures to exchange isochronous packet information with the ugen driver:

typedef struct ugen_isoc_pkt_descr {
        /*
        * Set by the application, for all isochro.
        * requests, to the num. of bytes to xfer
        * in a packet.
        */
           ushort_t        dsc_isoc_pkt_len;
 
        /*         
        * Set by ugen to actual num. of bytes sent/received
        * in a packet.
            */
       ushort_t        dsc_isoc_pkt_actual_len;
 
        /*
        * Per pkt. status set by ugen driver both for the
        * isochronous IN and OUT requests. Application can
        * use USB_LC_STAT_* to parse the status.
        */
      int     dsc_isoc_pkt_status;
 } ugen_isoc_pkt_descr_t; 
      
 typedef struct ugen_isoc_req_head {
   /* pkt count of the isoc request */
    int req_isoc_pkts_count;
 
  /* pkt descriptors */
  ugen_isoc_pkt_descr_t req_isoc_pkt_descrs[1]; 
 } ugen_isoc_req_head_t;

req_isoc_pkts_count is limited by the capability of the USB host controller driver. The current upper bound for the uhci and ohci drivers is 512. The upper bound for the ehci driver is 1024.

For an isochronous-IN endpoint, applications must first use the ugen_isoc_req_head_t structure followed by ugen_isoc_pkt_descr_t to write packet request information to the ugen node. The ugen driver then checks the validity of the request. If it is valid, the driver immediately begins isochronous polling on the IN endpoint and applications can proceed with read(2) of the data on the isochronous-IN endpoint. Upon successful return of read(2), isochronous packet descriptors (whose dsc_isoc_pkt_actual_len and dsc_isoc_pkt_status fields were filled by the driver) are returned, followed by the request's device payload data.

Applications should continuously check for and consume isochronous data. The ugen driver enables buffering of up to eight seconds of incoming data for full-speed isochronous endpoint, one second of data for high-speed isochronous endpoints who request one transaction per microframe and 1/3 of a second of incoming data for high-speed high-bandwidth isochronous endpoints who request three transactions per microframe. In case of buffer overflow, ugen discards the oldest data.

The isochronous-IN polling can only be stopped by a close(2) associated file descriptor. If applications want to change packet information, they must first close(2) the endpoint to stop the isochronous-IN polling, then open(2) the endpoint and write(2) new packets request.

The following example shows how to read an isochronous-IN endpoint:

        #include  <sys/usb/clients/ugen/usb_ugen.h>

        char *buf, *p;
        ushort_t  pktlen;
        int pktcnt, i;
        int len;
        ugen_isoc_req_head_t *req;
        ugen_isoc_pkt_descr_t *pktdesc;
        char rdbuf[5000];
 
        pktcnt = 4; /* 4 packets in this request */
     
        len = sizeof(int) +
            sizeof(ugen_isoc_pkt_descr_t) * pktcount;
  
        buf = malloc(len);
        if (!buf) {
            /* Error recovery. */
         }
 
        req = (ugen_isoc_req_head_t *)buf;
        req->req_isoc_pkts_count = pktcnt;
 
        pktdesc = (ugen_isoc_pkt_descr_t *)
            (req->req_isoc_pkt_descrs);
 
     for (i = 0; i < pktcnt; i++) {
                /*
                * pktlen should not exceed xfer
                * capability of an endpoint
                */
                pktdesc[i].dsc_isoc_pkt_len = pktlen; 
 
                 pktdesc[i].dsc_isoc_pkt_actual_len = 0;
                pktdesc[i].dsc_isoc_pkt_status = 0;
         }
 
            /*
            * write request info to driver and len must
            * be exactly the sum of
            * sizeof(int) + sizeof(ugen_isoc_pkt_descr_t) * pktcnt.
            * Otherwise, an error is returned.
            */
            if (write(fd, buf, len) < 0) {
                /* Error recovery. */
         } 
 
            /*
            * Read length should be sum of all pkt descriptors
            * length + payload data length of all pkts
            * (sizeof(ugen_isoc_pkt_descr_t) + pktlen) * pktcnt
            */
            if (read(fd, rdbuf, (sizeof(ugen_isoc_pkt_descr_t) +
             pktlen) * pktcnt) < 0) {
                /* Error recovery. */
         }
 
            pktdesc = (ugen_isoc_pkt_descr_t *) rdbuf;
 
            /* points to payload beginning */
            p = rdbuf + pktcnt * sizeof(ugen_isoc_pkt_descr_t);
 
            for (i = 0; i < pktcnt; i++) {
                printf("packet %d len = %d,"
                    " actual_len = %d, status = 0x%x\n",
                    i, pktdesc->dsc_isoc_pkt_len,
                    pktdesc->dsc_isoc_pkt_actual_len,
                    pktdesc->dsc_isoc_pkt_status);
 
                /* Processing data */
 
                /*
                * next packet data payload, do NOT use
                * dsc_isoc_pkt_actual_len
                */
                p += pktdesc->dsc_isoc_pkt_len; 
 
                pktdesc++;
 }

For an isochronous-OUT endpoint, applications use the same packet descriptor and request structures to write request information to the ugen node. Following the packet request head information is the packet payload data. Upon successful return of write(2), applications can read(2) the same ugen file immediately to retrieve the individual packet transfer status of the last request. If the application isn't concerned about the status, it can omit it.

In the following example, an application transfers data on an isochronous-OUT endpoint:

        #include <sys/usb/clients/ugen/usb_ugen.h>
        char *buf, *p;
        ushort_t i, pktlen;
        int len, pktcnt;
        ugen_isoc_req_head_t *req;
        ugen_isoc_pkt_descr_t *pktdesc;
        char rdbuf[4096];
 
        pktcnt = 4;
 
        /*
        * set packet length to a proper value, don't
        * exceed endpoint's capability
        */
        pktlen = 1024; 
 
        len = sizeof(int) +
            sizeof(ugen_isoc_pkt_descr_t) * pktcount;
         
        len += pktlen * pktcnt;
 
        buf = malloc(len);
        if (!buf) {
            /* Error recovery. */
         }
     
        req = (ugen_isoc_req_head_t *)buf;
        req->req_isoc_pkts_count = pktcnt;
 
        pktdesc =
            (ugen_isoc_pkt_descr_t *)(req->req_isoc_pkt_descrs);
 
        for (i = 0; i < pktcnt; i++) {
            pktdesc[i].dsc_isoc_pkt_len = pktlen;
            pktdesc[i].dsc_isoc_pkt_actual_len = 0;
            pktdesc[i].dsc_isoc_pkt_status = 0;
         }
     
        /* moving to beginning of payload data */
        p = buf + sizeof(int) + sizeof(*pktdesc) * pktcnt;
        for (i = 0; i < pktcnt; i++) {
 
            /* fill in the data buffer */
 
            p += pktlen;
     }
 
        /*
        * write packet request information and data to ugen driver
        *
        * len should be the exact value of sizeof(int) +
        *    sizeof(ugen_isoc_pkt_descr_t) * pktcnt + payload length
        */
        if (write(fd, buf, len) < 0) {
            /* Error recovery. */
         } 
 
        /* read packet status */
        if (read(fd, rdbuf, sizeof(*pktdesc) * pktcnt) < 0) {
 
            /* Error recovery. */
 
        } else {
 
            /* Parse every packet's transfer status */
 
          }

Errors

The following statuses are returned by endpoint status device logical names:

USB_LC_STAT_NOERROR

No error.

USB_LC_STAT_CRC

CRC error detected.

USB_LC_STAT_BITSTUFFING

Bit stuffing error.

USB_LC_STAT_DATA_TOGGLE_MM

Data toggle did not match.

USB_LC_STAT_STALL

Endpoint returned stall.

USB_LC_STAT_DEV_NOT_RESP

Device not responding.

USB_LC_STAT_UNEXP_PID

Unexpected Packet Identifier (PID).

USB_LC_STAT_PID_CHECKFAILURE

Check bits on PID failed.

USB_LC_STAT_DATA_OVERRUN

Data overrun.

USB_LC_STAT_DATA_UNDERRUN

Data underrun.

USB_LC_STAT_BUFFER_OVERRUN

Buffer overrun.

USB_LC_STAT_BUFFER_UNDERRUN

Buffer underrun.

USB_LC_STAT_TIMEOUT

Command timed out.

USB_LC_STAT_NOT_ACCESSED

Not accessed by the hardware.

USB_LC_STAT_UNSPECIFIED_ERR

Unspecified USBA or HCD error.

USB_LC_STAT_NO_BANDWIDTH

No bandwidth available.

USB_LC_STAT_HW_ERR

Host Controller h/w error.

USB_LC_STAT_SUSPENDED

Device was suspended.

USB_LC_STAT_DISCONNECTED

Device was disconnected.

USB_LC_STAT_INTR_BUF_FULL

Polling was stopped as the interrupt-IN data buffer was full. Buffer is now empty and polling has been resumed.

USB_LC_STAT_INTERRUPTED

Request was interrupted.

USB_LC_STAT_NO_RESOURCES

No resources available for request.

USB_LC_STAT_INTR_POLLING_FAILED

Failed to restart polling.

USB_LC_STAT_ISOC_POLLING_FAILED

Failed to start isochronous polling.

USB_LC_STAT_ISOC_UNINITIALIZED

Isochronous packet information not initialized.

USB_LC_STAT_ISOC_PKT_ERROR

All packets in this isochronous request have errors. The polling on this isochronous-IN endpoint is suspended and can be resumed on next read(2).

The following system call errno values are returned:

EINVAL

An attempt was made to enable or disable one transfer mode while the associated endpoint was open.

EBUSY

The endpoint has been opened and another open is attempted.

EACCES

An endpoint open was attempted with incorrect flags.

ENOTSUP

Operation not supported.

ENXIO

Device associated with the file descriptor does not exist.

ENODEV

Device has been hot-removed or a suspend/resume happened before this command.

EIO

An I/O error occurred. Send a read on the endpoint status minor node to get the exact error information.

EINTR

Interrupted system call.

ENOMEM

No memory for the allocation of internal structures.

Files

        /kernel/drv/ugen   32 bit ELF kernel module (x86 platform only)
        /kernel/drv/sparcv9/ugen   64 bit ELF kernel module

        /dev/usb/<vid>.<pid>/<N>/cntrl0
        /dev/usb/<vid>.<pid>/<N>/cntrl0stat

        /dev/usb/<vid>.<pid>/<N>/if<interface#>
                                <in|out|cntrl><endpoint#>
        /dev/usb/<vid>.<pid>/<N>/if<interface#>
                                <in|out|cntrl><endpoint#>stat

        /dev/usb/<vid>.<pid>/<N>/if<interface#>.
                                <alternate><in|out|cntrl<endpoint#>
        /dev/usb/<vid>.<pid>/<N>/if<interface#>.
                                <alternate><in|out|cntrl><endpoint#>stat

        /dev/usb/<vid>.<pid>/<N>/cfg<value>if<interface#>
                                <in|out|cntrl><endpoint#>
        /dev/usb/<vid>.<pid>/<N>/cfg<value>if<interface#>
                                <in|out|cntrl<endpoint#stat>

        /dev/usb/<vid>.<pid>/<N>/cfg<value>if<interface#>.
                                <alternate><in|out|cntrl><endpoint#>
        /dev/usb/<vid>.<pid>/<N>/cfg<value>if<interface#>.
                                <alternate><in|out|cntrl><endpoint#>stat


        /dev/usb/<vid>.<pid>/<N>/devstat

        /dev/usb/<vid>.<pid>/<N>/if<interface#>cntrl0
        /dev/usb/<vid>.<pid>/<N>/if<interface#>cntrl0stat

where N is an integer representing the instance number of this type of device. (All logical device names for a single device share the same N.)

Attributes

See attributes(5) for descriptions of the following attributes:

ATTRIBUTE TYPE
ATTRIBUTE VALUE
Architecture
PCI-based SPARC
Availability
system/io/usb

See Also

libusb(3LIB), close(2), poll(2), read(2), write(2), aioread(3C), aiowrite(3C), usba(7D), usb_dev_descr(9S).

Diagnostics

In addition to being logged, the following messages can appear on the system console. All messages are formatted in the following manner:

Warning: <device path> (ugen<instance num>): Error Message...
Too many minor nodes.

Device has too many minor nodes. Not all are available.

Instance number too high (<number>).

Too many devices are using this driver.

Cannot access <device>. Please reconnect.

This device has been disconnected because a device other than the original one has been inserted. The driver informs you of this fact by displaying the name of the original device.

Device is not identical to the previous one on this port. Please disconnect and reconnect.

Same condition as described above; however in this case, the driver is unable to identify the original device with a name string.

Notes

ugen returns -1 for all commands and sets errno to ENODEV when device has been hot-removed or resumed from a suspend. The application must close and reopen all open minor nodes to reinstate successful communication.