/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License (the "License").
* You may not use this file except in compliance with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or http://www.opensolaris.org/os/licensing.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*/
/*
* Copyright (c) 2004, 2011, Oracle and/or its affiliates. All rights reserved.
*/
/*
* This library can either be used stand-alone or as plugin
* to the libusb wrapper library.
* The libusb API 0.1.0.10 has been implemented using all original code
* which was not derived from opensource.
*
* XXX issues:
* - timeout thru signal
* - usb_interrupt/bulk_write/read should have common code
*/
#include <stdlib.h>
#include <stdio.h>
#include <errno.h>
#include <unistd.h>
#include <string.h>
#include <fcntl.h>
#include <sys/time.h>
#include <dirent.h>
#include <stdarg.h>
#include <strings.h>
#include <sys/stat.h>
#include <regex.h>
#include <sys/usb/clients/ugen/usb_ugen.h>
#include "usb.h"
#include "libusbugen_impl.h"
/* global variables */
usb_bus_t *usb_busses = NULL;
const char *libusb_version = "1.1";
/* error handling */
static char usb_error_string[1024];
static int usb_error_errno;
static usb_error_type_t usb_error_type = USB_ERROR_TYPE_NONE;
/* debugging */
static int libusb_debug = DEBUG_NONE;
/* api binding */
static int libusb_api = API_RELAXED;
/* internal function prototypes */
static void usb_error_str(int x, char *format, ...);
static int usb_error(int x);
static void usb_dprintf(int level, char *format, ...);
static void usb_dump_data(char *data, int size);
static int usb_open_ep0(usb_dev_handle_impl_t *hdl);
static void usb_close_ep0(usb_dev_handle_impl_t *hdl);
static int usb_check_access(usb_dev_handle *dev);
static int usb_search_dev_usb(usb_device_t **new_devices);
static int usb_do_io(int fd, int stat_fd, char *data, size_t size, int flag);
static int usb_send_msg(int fd, int stat_fd, int requesttype, int request,
int value, int index, char *data, int size);
static int usb_check_device_and_status_open(usb_dev_handle *dev,
int ep, int ep_type, int mode);
static int usb_get_status(int fd);
static void usb_set_ep_iface_alts(usb_dev_handle_impl_t *hdl,
usb_dev_handle_info_t *info, int index, int interface, int alternate);
static int usb_setup_all_configs(usb_dev_handle_impl_t *hdl);
static void usb_free_all_configs(usb_device_t *device);
static int usb_parse_config(usb_dev_handle_impl_t *hdl, uint_t index);
static void usb_free_config(usb_device_t *device, uint_t index);
static int usb_parse_interface(usb_dev_handle_impl_t *hdl, uint_t index,
uint_t iface, char *cloud);
static void usb_free_interface(usb_device_t *device, uint_t index,
uint_t iface);
static int usb_parse_alternate(usb_dev_handle_impl_t *hdl, uint_t index,
uint_t iface, uint_t alt, char *cloud);
static void usb_free_alternate(usb_device_t *device, uint_t index,
uint_t iface, uint_t alt);
static int usb_parse_endpoint(usb_dev_handle_impl_t *hdl, int index,
int iface, int alt, int ep, char *cloud);
static void usb_find_extra(uchar_t *buf, size_t buflen,
unsigned char **extra, int *extralen);
static void usb_close_all_eps(usb_dev_handle_impl_t *hdl);
static void usb_add_device(usb_device_t **list, usb_device_t *dev);
static void usb_remove_device(usb_device_t **list, usb_device_t *dev);
static int usb_check_device_in_list(usb_device_t *list, usb_device_t *dev);
static void usb_free_dev(usb_device_t *dev);
static void usb_free_bus(usb_bus_t *bus);
static size_t usb_parse_dev_descr(uchar_t *buf, size_t buflen,
struct usb_device_descriptor *ret_descr, size_t ret_buf_len);
static size_t usb_parse_cfg_descr(uchar_t *buf, size_t buflen,
usb_cfg_descr_t *ret_descr, size_t ret_buf_len,
unsigned char **extra, int *extralen);
static size_t usb_parse_if_descr(uchar_t *buf, size_t buflen,
uint_t if_number, uint_t alt_if_setting,
usb_if_descr_t *ret_descr, size_t ret_buf_len,
unsigned char **extra, int *extralen);
static size_t usb_parse_ep_descr(uchar_t *buf, size_t buflen,
uint_t if_number, uint_t alt_if_setting, uint_t ep_index,
usb_ep_descr_t *ret_descr, size_t ret_buf_len,
unsigned char **extra, int *extralen);
static uchar_t usb_ep_index(uint8_t ep_addr);
/*
* libusb_init:
*
* Returns: 0 or ENOSUP if we cannot support any bus
*/
int
libusb_init(void)
{
return (0);
}
/*
* libusb_fini:
*
* Returns: always returns 0
*/
int
libusb_fini(void)
{
return (0);
}
/*
* Entry points:
*
* usb_set_debug:
* sets debug level for tracing
*/
void
usb_set_debug(int level)
{
if (getenv("SUN_LIBUSBUGEN_DEBUG")) {
level = atoi(getenv("SUN_LIBUSBUGEN_DEBUG"));
} else if (getenv("SUN_LIBUSB_DEBUG")) {
level = atoi(getenv("SUN_LIBUSB_DEBUG"));
}
if (level < 0)
return;
libusb_debug = level;
usb_dprintf(DEBUG_FUNCTIONS, "usb_set_debug(): "
"Setting debugging level to %d (%s)\n",
level, level ? "on" : "off");
}
/*
* usb_init:
* not much to initialize. just set debug level
*/
void
usb_init(void)
{
if (getenv("LIBUSB_API_STRICT")) {
libusb_api = API_STRICT;
}
usb_set_debug(libusb_debug);
usb_dprintf(DEBUG_FUNCTIONS, "usb_init(): "
"libusb version=%s\n", libusb_version);
}
/*
* usb_get_busses:
* Returns: usb_busses pointer
*/
usb_bus_t *
usb_get_busses(void)
{
return (usb_busses);
}
/*
* usb_find_busses:
* finds all busses in the system. On solaris we have
* only one flat name space, /dev/usb
*
* Returns: change in number of busses or negative errno
*/
int
usb_find_busses(void)
{
usb_bus_t *bus;
/* we only have one name space for all USB busses */
if (usb_busses == NULL) {
/* never freed */
if ((bus = calloc(sizeof (*bus), 1)) == NULL) {
return (usb_error(ENOMEM));
}
(void) strncpy(bus->dirname, "/dev/usb",
sizeof (bus->dirname));
usb_dprintf(DEBUG_FUNCTIONS, "usb_find_busses(): "
"found %s\n", bus->dirname);
usb_busses = bus;
return (1);
}
return (0);
}
/*
* usb_find_devices:
* finds all devices that have appeared and removes devices
* from the list that are no longer there
*
* Returns: change in number of devices or a negative errno
*/
int
usb_find_devices(void)
{
int i, rval, found;
int changes = 0;
usb_device_t *new_devices;
usb_device_t *dev, *next_dev, *new, *next_new;
new_devices = NULL;
rval = usb_search_dev_usb(&new_devices);
if (rval != 0) {
return (usb_error(rval));
}
/* is any of devices on the new list also on the old list? */
for (dev = usb_busses->devices; dev != NULL; dev = next_dev) {
next_dev = dev->next;
found = 0;
for (new = new_devices; new != NULL; new = next_new) {
next_new = new->next;
if (strncmp(dev->filename, new->filename,
sizeof (dev->filename)) == 0) {
usb_remove_device(&new_devices, new);
usb_free_dev(new);
found++;
break;
}
}
/* the device must have been hot removed */
if (!found) {
usb_remove_device(&usb_busses->devices, dev);
usb_free_dev(dev);
}
}
/* add all new_devices to the old_devices list */
usb_dprintf(DEBUG_DETAILED, "moving new to old\n");
for (new = new_devices; new != NULL; new = next_new) {
next_new = new->next;
usb_remove_device(&new_devices, new);
usb_add_device(&usb_busses->devices, new);
(void) usb_close(usb_open(new));
changes++;
}
usb_dprintf(DEBUG_DETAILED, "usb_devices list:\n");
for (i = 0, dev = usb_busses->devices; dev != NULL;
i++, dev = next_dev) {
next_dev = dev->next;
usb_dprintf(DEBUG_DETAILED, "%d: %s\n", i, dev->filename);
}
return (changes);
}
/*
* usb_device:
* included because sane uses this
* Returns: usb_device structure associated with handle
*/
struct usb_device *
usb_device(usb_dev_handle *dev)
{
usb_dev_handle_impl_t *hdl = (usb_dev_handle_impl_t *)dev;
return ((hdl != NULL) ? hdl->device : NULL);
}
/*
* usb_open:
* opens the device for access
*
* Returns: a usb device handle or NULL
*/
usb_dev_handle *
usb_open(usb_device_t *dev)
{
usb_dev_handle_impl_t *hdl;
usb_dev_handle_info_t *info;
int i, rval;
usb_dprintf(DEBUG_FUNCTIONS, "usb_open():\n");
if (usb_check_device_in_list(usb_busses->devices,
dev) == 0) {
usb_dprintf(DEBUG_ERRORS, "usb_open(): "
"illegal usb_device pointer\n");
return (NULL);
}
/* create a handle and info structure */
if ((hdl = calloc(sizeof (*hdl), 1)) == NULL) {
return (NULL);
}
hdl->device = dev;
if ((info = calloc(sizeof (*info), 1)) == NULL) {
free(hdl);
return (NULL);
}
hdl->info = info;
/* set all file descriptors to "closed" */
for (i = 0; i < USB_MAXENDPOINTS; i++) {
hdl->info->ep_fd[i] = -1;
hdl->info->ep_status_fd[i] = -1;
if (i > 0) {
hdl->info->ep_interface[i] = -1;
}
}
/* open default control ep and keep it open */
if ((rval = usb_open_ep0(hdl)) != 0) {
usb_dprintf(DEBUG_ERRORS, "usb_open_ep0 failed: %d\n", rval);
free(info);
free(hdl);
return (NULL);
}
/*
* setup config info: trees of configs, interfaces, alternates
* and endpoints structures
*/
if (usb_setup_all_configs(hdl) != 0) {
usb_free_all_configs(hdl->device);
usb_close_ep0(hdl);
free(info);
free(hdl);
return (NULL);
}
/* set when the app claims an interface */
info->configuration_value =
info->claimed_interface = info->alternate = -1;
usb_dprintf(DEBUG_FUNCTIONS, "usb_open(): hdl=0x%x\n", (int)hdl);
return ((usb_dev_handle *)hdl);
}
/*
* usb_close:
* closes the device and free resources
*
* Returns: 0
*/
int
usb_close(usb_dev_handle *dev)
{
usb_dev_handle_impl_t *hdl = (usb_dev_handle_impl_t *)dev;
usb_dev_handle_info_t *info;
usb_dprintf(DEBUG_FUNCTIONS, "usb_close(): hdl=0x%x\n", hdl);
if (hdl) {
info = hdl->info;
usb_dprintf(DEBUG_DETAILED,
"usb_close(): claimed %d\n",
info->claimed_interface);
if (info->claimed_interface != -1) {
(void) usb_release_interface(dev,
info->claimed_interface);
}
usb_close_all_eps(hdl);
usb_close_ep0(hdl);
free(info);
free(hdl);
return (0);
}
return (usb_error(EINVAL));
}
/*
* usb_control_msg:
* sends a control message
*
* Returns: actual number of data bytes transferred or
* a negative errno
*/
/*ARGSUSED*/
int
usb_control_msg(usb_dev_handle *dev, int requesttype, int request,
int value, int index, char *data, int size, int timeout)
{
usb_dev_handle_impl_t *hdl = (usb_dev_handle_impl_t *)dev;
usb_dev_handle_info_t *info;
int additional;
int rval;
usb_dprintf(DEBUG_FUNCTIONS, "usb_control_msg():\n");
if ((hdl == NULL) || (size < 0)) {
return (usb_error(EINVAL));
}
info = hdl->info;
/*
* no need to do validation since ep0 is always open and
* we do not need to claim an interface first
*
* usb_send_msg returns #bytes xferred or negative errno
*/
rval = usb_send_msg(info->ep_fd[0], info->ep_status_fd[0],
requesttype, request, value, index, data, size);
/* less than setup bytes transferred? */
if (rval < 8) {
usb_error_str(errno,
"error sending control message: %d", rval);
return ((rval >= 0) ?
usb_error(EIO) : usb_error(-rval));
}
rval -= 8; /* substract setup length */
/* for IN requests, now transfer the remaining bytes */
if ((size) && (requesttype & USB_DEV_REQ_DEV_TO_HOST)) {
additional = usb_do_io(info->ep_fd[0],
info->ep_status_fd[0], data, size, READ);
} else {
additional = rval;
}
usb_dprintf(DEBUG_FUNCTIONS,
"usb_control_msg(): additional 0x%x bytes\n", additional);
return (additional);
}
/*
* usb_bulk_write:
* writes to a bulk endpoint
*
* Returns: actual number of data bytes transferred or negative errno
*/
/* ARGSUSED */
int
usb_bulk_write(usb_dev_handle *dev, int ep, char *data, int size,
int timeout)
{
usb_dev_handle_impl_t *hdl = (usb_dev_handle_impl_t *)dev;
usb_dev_handle_info_t *info;
int sent, rval;
int ep_index = usb_ep_index(ep);
usb_dprintf(DEBUG_FUNCTIONS, "usb_bulk_write(): ep=0x%x\n", ep);
if ((hdl == NULL) || (data == NULL) || (size <= 0)) {
usb_dprintf(DEBUG_ERRORS,
"usb_bulk_write(): NULL handle or data\n");
return (usb_error(EINVAL));
}
info = hdl->info;
/* do some validation first */
if ((rval = usb_check_device_and_status_open(dev, ep,
USB_ENDPOINT_TYPE_BULK, O_WRONLY)) != 0) {
usb_dprintf(DEBUG_ERRORS,
"usb_check_device_and_status_open() failed\n");
return (usb_error(rval));
}
/* now write out the bytes */
sent = usb_do_io(info->ep_fd[ep_index], info->ep_status_fd[ep_index],
data, size, WRITE);
return (sent);
}
/*
* usb_bulk_read:
* reads from a bulk endpoint
*
* Returns: actual number of data bytes transferred or negative errno
*/
/* ARGSUSED */
int
usb_bulk_read(usb_dev_handle *dev, int ep, char *data, int size,
int timeout)
{
usb_dev_handle_impl_t *hdl = (usb_dev_handle_impl_t *)dev;
usb_dev_handle_info_t *info;
int ep_index, received, rval;
ep |= USB_ENDPOINT_IN;
ep_index = usb_ep_index(ep);
usb_dprintf(DEBUG_FUNCTIONS, "usb_bulk_read(): ep=0x%x\n", ep);
if ((hdl == NULL) || (data == NULL) || (size <= 0)) {
usb_dprintf(DEBUG_ERRORS,
"usb_bulk_read(): NULL handle or data\n");
return (usb_error(EINVAL));
}
info = hdl->info;
/* do some validation first */
if ((rval = usb_check_device_and_status_open(dev, ep,
USB_ENDPOINT_TYPE_BULK, O_RDONLY)) != 0) {
usb_dprintf(DEBUG_ERRORS,
"usb_check_device_and_status_open() failed\n");
return (usb_error(rval));
}
/* now read in the bytes */
received = usb_do_io(info->ep_fd[ep_index],
info->ep_status_fd[ep_index],
data, size, READ);
return (received);
}
/*
* usb_interrupt_write:
* writes data to an interrupt endpoint
*
* Returns: actual number of data bytes transferred or negative errno
*/
/* ARGSUSED */
int
usb_interrupt_write(usb_dev_handle *dev, int ep, char *data, int size,
int timeout)
{
usb_dev_handle_impl_t *hdl = (usb_dev_handle_impl_t *)dev;
usb_dev_handle_info_t *info;
int sent, rval;
int ep_index = usb_ep_index(ep);
usb_dprintf(DEBUG_FUNCTIONS, "usb_interrupt_write(): ep=0x%x\n", ep);
if ((hdl == NULL) || (data == NULL) || (size <= 0)) {
usb_dprintf(DEBUG_ERRORS,
"usb_interrupt_write(): NULL handle or data\n");
return (usb_error(EINVAL));
}
info = hdl->info;
/* do some validation first */
if ((rval = usb_check_device_and_status_open(dev, ep,
USB_ENDPOINT_TYPE_INTERRUPT, O_WRONLY)) != 0) {
usb_dprintf(DEBUG_ERRORS,
"usb_check_device_and_status_open() failed\n");
return (usb_error(rval));
}
/* now transfer the bytes */
sent = usb_do_io(info->ep_fd[ep_index],
info->ep_status_fd[ep_index],
data, size, WRITE);
return (sent);
}
/*
* usb_interrupt_read:
* reads data from an interrupt endpoint
*
* Returns: actual number of data bytes transferred or negative errno
*/
/* ARGSUSED */
int
usb_interrupt_read(usb_dev_handle *dev, int ep, char *data, int size,
int timeout)
{
usb_dev_handle_impl_t *hdl = (usb_dev_handle_impl_t *)dev;
usb_dev_handle_info_t *info;
int ep_index, received, rval;
ep |= USB_ENDPOINT_IN;
ep_index = usb_ep_index(ep);
usb_dprintf(DEBUG_FUNCTIONS, "usb_interrrupt_read(): ep=0x%x\n", ep);
if ((hdl == NULL) || (data == NULL) || (size <= 0)) {
usb_dprintf(DEBUG_ERRORS,
"usb_interrupt_read(): NULL handle or data\n");
return (usb_error(EINVAL));
}
info = hdl->info;
/* do some validation first */
if ((rval = usb_check_device_and_status_open(dev, ep,
USB_ENDPOINT_TYPE_INTERRUPT, O_RDONLY)) != 0) {
usb_dprintf(DEBUG_ERRORS,
"usb_check_device_and_status_open() failed\n");
return (usb_error(rval));
}
/* now transfer the bytes */
received = usb_do_io(info->ep_fd[ep_index],
info->ep_status_fd[ep_index],
data, size, READ);
/* close the endpoint so we stop polling the endpoint now */
(void) close(info->ep_fd[ep_index]);
(void) close(info->ep_status_fd[ep_index]);
info->ep_fd[ep_index] = -1;
info->ep_status_fd[ep_index] = -1;
return (received);
}
/*
* usb_get_string:
* gets a raw unicode string
*
* Returns: number of bytes transferred or negative errno
*/
int
usb_get_string(usb_dev_handle *dev, int index, int langid, char *buf,
size_t buflen)
{
/*
* We can't use usb_get_descriptor() because it's lacking the index
* parameter. This will be fixed in libusb 1.0
*/
usb_dprintf(DEBUG_FUNCTIONS,
"usb_get_string(): index=%d langid=0x%x len=%d\n",
index, langid, buflen);
if ((dev == NULL) || (buf == NULL) || (buflen == 0)) {
usb_dprintf(DEBUG_ERRORS,
"usb_get_string(): NULL handle or data\n");
return (usb_error(EINVAL));
}
return (usb_control_msg(dev, USB_DEV_REQ_DEV_TO_HOST,
USB_REQ_GET_DESCRIPTOR, (USB_DT_STRING << 8) + index,
langid, buf, (int)buflen, 1000));
}
/*
* usb_get_string_simple:
* gets a cooked ascii string
*
* Returns: number of bytes transferred or negative errno
*/
int
usb_get_string_simple(usb_dev_handle *dev, int index, char *buf,
size_t buflen)
{
char tbuf[256];
int ret, langid, si, di;
usb_dprintf(DEBUG_FUNCTIONS, "usb_get_string_simple(): index=%d\n",
index);
if ((dev == NULL) || (buf == NULL) || (buflen == 0)) {
usb_dprintf(DEBUG_ERRORS,
"usb_get_string_simple(): NULL handle or data\n");
return (usb_error(EINVAL));
}
(void) memset(buf, 0, buflen);
/*
* Asking for the zero'th index is special - it returns a string
* descriptor that contains all the language IDs supported by the
* device. Typically there aren't many - often only one. The
* language IDs are 16 bit numbers, and they start at the third byte
* in the descriptor. See USB 2.0 specification, section 9.6.7, for
* more information on this.
*/
ret = usb_get_string(dev, index, 0, tbuf, sizeof (tbuf));
usb_dprintf(DEBUG_DETAILED, "usb_get_string() returned %d\n", ret);
if (ret < 4) {
langid = 0x409;
} else {
langid = tbuf[2] | (tbuf[3] << 8);
}
usb_dprintf(DEBUG_DETAILED, "using langid=0x%x\n", langid);
ret = usb_get_string(dev, index, langid, tbuf, sizeof (tbuf));
if (ret < 0) {
return (ret);
}
if (tbuf[1] != USB_DT_STRING) {
return (-EIO);
}
if (tbuf[0] > ret) {
return (-EFBIG);
}
for (di = 0, si = 2; si < tbuf[0]; si += 2) {
if (di >= ((int)buflen - 1)) {
break;
}
if (tbuf[si + 1]) { /* high byte */
buf[di++] = '?';
} else {
buf[di++] = tbuf[si];
}
}
buf[di] = 0;
return (di);
}
/*
* usb_get_descriptor_by_endpoint:
* usb_get_descriptor:
* get a descriptor. by_endpoint does not appear to make
* much sense.
*
* Returns: number of bytes transferred or negative errno
*/
int
usb_get_descriptor_by_endpoint(usb_dev_handle *udev, int ep,
uchar_t type, uchar_t index, void *buf, int size)
{
if ((udev == NULL) || (buf == NULL) || (size <= 0)) {
usb_dprintf(DEBUG_ERRORS,
"usb_get_descriptor_by_endpoint(): "
"NULL handle or data\n");
return (usb_error(EINVAL));
}
(void) memset(buf, 0, size);
return (usb_control_msg(udev,
ep | USB_ENDPOINT_IN, USB_REQ_GET_DESCRIPTOR,
(type << 8) + index, 0, buf, size, 1000));
}
int
usb_get_descriptor(usb_dev_handle *udev, uchar_t type,
uchar_t index, void *buf, int size)
{
if ((udev == NULL) || (buf == NULL) || (size <= 0)) {
usb_dprintf(DEBUG_ERRORS,
"usb_get_string_simple(): NULL handle or data\n");
return (usb_error(EINVAL));
}
(void) memset(buf, 0, size);
return (usb_control_msg(udev,
USB_ENDPOINT_IN, USB_REQ_GET_DESCRIPTOR,
(type << 8) + index, 0, buf, size, 1000));
}
/*
* usb_set_altinterface:
* switches to the alternate interface for the device
* Note that ugen does not really need this. It does implicit
* cfg and alt switches when the endpoint is opened.
*
* Returns: 0 or negative errno
*/
/* ARGSUSED */
int
usb_set_altinterface(usb_dev_handle *dev, int alt)
{
usb_dev_handle_impl_t *hdl = (usb_dev_handle_impl_t *)dev;
usb_dev_handle_info_t *info;
usb_device_specific_t *dev_specific;
int index, iface, err;
usb_dprintf(DEBUG_FUNCTIONS, "usb_set_altinterface(): "
"hdl=0x%x alt=%d\n", hdl, alt);
if (hdl == NULL) {
usb_dprintf(DEBUG_ERRORS,
"usb_set_altinterface(): NULL handle\n");
return (usb_error(EINVAL));
}
info = hdl->info;
if (libusb_api == API_RELAXED) {
if (info->claimed_interface == -1) {
/*
* usb_claim_interface() should always be called
* prior usb_set_altinterface(), but some apps
* do not do this, hence we call it here assuming
* the default interface.
*/
if ((err = usb_claim_interface(dev, 0))) {
return (err);
}
}
}
iface = info->claimed_interface;
dev_specific = (usb_device_specific_t *)(hdl->device->dev);
usb_dprintf(DEBUG_DETAILED, "claimed=%d, cfgvalue=%d, hdl=0x%x\n",
info->claimed_interface, info->configuration_value,
dev_specific->claimed_interfaces[iface], hdl);
if ((info->claimed_interface == -1) ||
(info->configuration_value == -1) ||
(hdl != dev_specific->claimed_interfaces[iface])) {
return (usb_error(EACCES));
}
usb_close_all_eps(hdl);
/* find the conf index */
for (index = 0; index < hdl->device->descriptor.bNumConfigurations;
index++) {
if (info->configuration_value ==
hdl->device->config[index].bConfigurationValue) {
break;
}
}
usb_dprintf(DEBUG_DETAILED,
"cfg value=%d index=%d, iface=%d, alt=%d #alts=%d\n",
info->configuration_value, index, iface, alt,
hdl->device->config[index].interface[iface].num_altsetting);
if ((alt < 0) || (alt >= hdl->device->
config[index].interface[iface].num_altsetting)) {
return (usb_error(EINVAL));
}
info->alternate = alt;
usb_set_ep_iface_alts(hdl, info, index, iface, alt);
return (0);
}
/*
* usb_set_configuration:
* sets the configuration for the device.
* ugen implicitly switches configuration and rejects
* set configuration requests
*
* Returns: 0
*/
/* ARGSUSED */
int
usb_set_configuration(usb_dev_handle *dev, int configuration)
{
usb_dev_handle_impl_t *hdl = (usb_dev_handle_impl_t *)dev;
usb_dev_handle_info_t *info;
int index, i;
usb_dprintf(DEBUG_FUNCTIONS,
"usb_set_configuration(): config = %d\n", configuration);
if (hdl == NULL) {
usb_dprintf(DEBUG_ERRORS,
"usb_set_configuration(): NULL handle\n");
return (usb_error(EINVAL));
}
info = hdl->info;
/* find the conf index */
for (index = 0; index < hdl->device->descriptor.bNumConfigurations;
index++) {
if (configuration ==
hdl->device->config[index].bConfigurationValue) {
break;
}
}
if (index >= hdl->device->descriptor.bNumConfigurations) {
usb_dprintf(DEBUG_ERRORS,
"usb_set_configuration(): invalid\n");
return (usb_error(EINVAL));
}
usb_close_all_eps(hdl);
info->configuration_value = configuration;
info->configuration_index = index;
/* reset ep arrays */
for (i = 0; i < USB_MAXENDPOINTS; i++) {
info->ep_interface[i] = -1;
}
if (info->claimed_interface != -1) {
(void) usb_release_interface(dev, info->claimed_interface);
}
return (0);
}
/*
* usb_clear_halt:
* clears a halted endpoint
* ugen has auto clearing but we send the request anyways
*
* Returns: 0 or negative errno
*/
/* ARGSUSED */
int
usb_clear_halt(usb_dev_handle *dev, unsigned int ep)
{
int rval;
int index = usb_ep_index(ep);
usb_dev_handle_impl_t *hdl = (usb_dev_handle_impl_t *)dev;
usb_dev_handle_info_t *info;
usb_dprintf(DEBUG_FUNCTIONS, "usb_clear_halt(): ep=0x%x\n", ep);
if (dev == NULL) {
usb_dprintf(DEBUG_ERRORS,
"usb_clear_halt(): NULL handle\n");
return (usb_error(EINVAL));
}
info = hdl->info;
usb_dprintf(DEBUG_DETAILED, "index=0x%x, ep_intf=%d\n",
index, info->ep_interface[index]);
if (info->ep_interface[index] == -1) {
return (usb_error(EINVAL));
}
/* only check for ep > 0 */
if (ep && ((rval = usb_check_access(dev) != 0))) {
return (usb_error(rval));
}
rval = usb_control_msg(dev,
USB_DEV_REQ_HOST_TO_DEV | USB_RECIP_ENDPOINT,
USB_REQ_CLEAR_FEATURE, 0, ep, NULL, 0, 0);
if (rval < 0) {
usb_error_str(errno, "could not clear feature on ep=0x%x", ep);
}
return (rval);
}
/*
* usb_claim_interface:
* ugen does not have a claim interface concept but all endpoints
* are opened exclusively. This provides some exclusion. However,
* the interrupt IN endpoint is closed after the read
*
* Returns: 0 or negative errno
*/
int
usb_claim_interface(usb_dev_handle *dev, int interface)
{
usb_dev_handle_impl_t *hdl = (usb_dev_handle_impl_t *)dev;
usb_dev_handle_info_t *info;
usb_device_specific_t *dev_specific;
int index;
if (hdl == NULL) {
usb_dprintf(DEBUG_ERRORS,
"usb_claim_interface(): NULL handle\n");
return (usb_error(EINVAL));
}
info = hdl->info;
dev_specific = (usb_device_specific_t *)(hdl->device->dev);
usb_dprintf(DEBUG_FUNCTIONS, "usb_claim_interface(): hdl=0x%x: "
"interface = %d\n", hdl, interface);
if (info->configuration_value == -1) {
index = 0;
} else {
/* find the conf index */
for (index = 0;
index < hdl->device->descriptor.bNumConfigurations;
index++) {
if (info->configuration_value ==
hdl->device->config[index].bConfigurationValue) {
break;
}
}
}
info->configuration_value =
hdl->device->config[index].bConfigurationValue;
info->configuration_index = index;
usb_dprintf(DEBUG_DETAILED, "configuration_value=%d, index=%d\n",
info->configuration_value, index);
/* is this a valid interface? */
if ((interface < 0) || (interface > 255) ||
(interface >= hdl->device->config[index].bNumInterfaces)) {
return (usb_error(EINVAL));
}
/* already claimed? */
if (dev_specific->claimed_interfaces[interface] == hdl) {
return (0);
}
if (info->claimed_interface != -1) {
return (usb_error(EBUSY));
}
if (dev_specific->claimed_interfaces[interface] != 0) {
return (usb_error(EBUSY));
}
usb_dprintf(DEBUG_DETAILED, "usb_claim_interface(): hdl=0x%x: "
"interface = %d, claimed by this udev=%d, by hdl=0x%x\n",
hdl, interface, info->claimed_interface,
dev_specific->claimed_interfaces[interface]);
info->claimed_interface = interface;
info->alternate = 0;
dev_specific->claimed_interfaces[interface] = hdl;
usb_set_ep_iface_alts(hdl, info, index, interface, 0);
return (0);
}
/*
* usb_release_interface:
* releases the acquired interface
*
* Returns: 0 or negative errno
*/
/* ARGSUSED */
int
usb_release_interface(usb_dev_handle *dev, int interface)
{
usb_dev_handle_impl_t *hdl = (usb_dev_handle_impl_t *)dev;
usb_dev_handle_info_t *info;
usb_device_specific_t *dev_specific;
if (hdl == NULL) {
usb_dprintf(DEBUG_ERRORS,
"usb_release_interface(): NULL handle\n");
return (usb_error(EINVAL));
}
info = hdl->info;
dev_specific = (usb_device_specific_t *)(hdl->device->dev);
usb_dprintf(DEBUG_FUNCTIONS, "usb_release_interface(): hdl=0x%x: "
"interface = %d\n", hdl, interface);
if ((info->claimed_interface == -1) ||
(info->claimed_interface != interface)) {
return (usb_error(EINVAL));
}
usb_dprintf(DEBUG_DETAILED, "usb_release_interface(): hdl=0x%x: "
"interface = %d, claimed by this udev=%d, by hdl=0x%x\n",
hdl, interface, info->claimed_interface,
dev_specific->claimed_interfaces[interface]);
dev_specific->claimed_interfaces[interface] = 0;
info->claimed_interface = -1;
return (0);
}
/*
* usb_resetep
* resets the endpoint
*
* Returns: 0 or negative errno
*/
int
usb_resetep(usb_dev_handle *dev, unsigned int ep)
{
usb_dprintf(DEBUG_FUNCTIONS, "usb_resetep(): ep=0x%x\n", ep);
return (usb_clear_halt(dev, ep));
}
/*
* usb_reset:
* resets the device
* Returns: -ENOTSUP
*/
/* ARGSUSED */
int
usb_reset(usb_dev_handle * dev)
{
int rval;
usb_dprintf(DEBUG_FUNCTIONS, "usb_reset():\n");
if (dev == NULL) {
usb_dprintf(DEBUG_ERRORS,
"usb_reset(): NULL handle\n");
return (usb_error(EINVAL));
}
if ((rval = usb_check_access(dev)) != 0) {
return (usb_error(rval));
}
return (usb_error(ENOTSUP));
}
/*
* Helper functions
*
* usb_send_msg:
* creates setup data and send it
*
* Returns: number of bytes transferred or negative errno
*/
static int
usb_send_msg(int fd, int stat_fd, int requesttype, int request, int value,
int index, char *data, int size)
{
uint8_t req[8];
int rval;
usb_dprintf(DEBUG_DETAILED, "usb_send_msg():\n"
"\trequesttype 0x%x\n"
"\trequest 0x%x\n"
"\tvalue 0x%x\n"
"\tindex 0x%x\n"
"\tsize 0x%x\n",
requesttype, request, value, index, size);
req[0] = (uint8_t)requesttype;
req[1] = (uint8_t)request;
req[2] = (uint8_t)value;
req[3] = (uint8_t)(value >> 8);
req[4] = (uint8_t)index;
req[5] = (uint8_t)(index >> 8);
req[6] = (uint8_t)size;
req[7] = (uint8_t)(size >> 8);
if (requesttype & USB_DEV_REQ_DEV_TO_HOST) {
rval = usb_do_io(fd, stat_fd, (char *)&req,
sizeof (req), WRITE);
} else {
/* append the write data */
char *buffer;
if ((buffer = malloc(size + 8)) == NULL) {
return (usb_error(ENOMEM));
}
(void) memcpy(buffer, &req, 8);
(void) memcpy(&buffer[8], data, size);
rval = usb_do_io(fd, stat_fd, buffer,
(uint_t)sizeof (req) + size, WRITE);
free(buffer);
}
usb_dprintf(DEBUG_FUNCTIONS, "usb_send_msg(): rval=%d\n", rval);
return (rval);
}
/*
* usb_do_io:
* performs i/o to/from an endpoint and check the
* status of the device if error or short xfer.
*
* Returns: bytes transferred or negative errno
*/
static int
usb_do_io(int fd, int stat_fd, char *data, size_t size, int flag)
{
int error;
ssize_t ret;
usb_dprintf(DEBUG_FUNCTIONS, "usb_do_io(): size=0x%x flag=%d\n",
size, flag);
if (size == 0) {
return (0);
}
switch (flag) {
case READ:
ret = read(fd, data, size);
usb_dump_data(data, (int)size);
break;
case WRITE:
usb_dump_data(data, (int)size);
ret = write(fd, data, size);
break;
}
if (ret < 0) {
int save_errno = errno;
/* usb_get_status will do a read and overwrite errno */
error = usb_get_status(stat_fd);
usb_error_str(save_errno, "error %d doing io: errno=%d",
error, save_errno);
return (-save_errno);
}
usb_dprintf(DEBUG_FUNCTIONS, "usb_do_io(): amount=%d\n", ret);
return ((int)ret);
}
/*
* usb_check_access:
* basically checks if the interface has been claimed
*
* Returns: 0 or EACCES/EINVAL
*/
static int
usb_check_access(usb_dev_handle *dev)
{
usb_dev_handle_impl_t *hdl = (usb_dev_handle_impl_t *)dev;
usb_dev_handle_info_t *info = hdl->info;
if (hdl == NULL) {
return (EINVAL);
}
info = hdl->info;
usb_dprintf(DEBUG_FUNCTIONS, "usb_check_access(): "
"hdl=0x%x conf=%d claimed=%d alternate=%d\n",
(int)hdl, info->configuration_value,
info->claimed_interface, info->alternate);
if ((info->configuration_value == -1) ||
(info->claimed_interface == -1) ||
(info->alternate == -1)) {
return (EACCES);
}
return (0);
}
/*
* usb_set_ep_iface_alts:
* initialize ep_interface arrays
*/
static void
usb_set_ep_iface_alts(usb_dev_handle_impl_t *hdl, usb_dev_handle_info_t *info,
int index, int interface, int alternate)
{
struct usb_interface_descriptor *if_descr;
struct usb_endpoint_descriptor *ep_descr;
int i;
/* reinitialize endpoint arrays */
for (i = 0; i < USB_MAXENDPOINTS; i++) {
info->ep_interface[i] = -1;
}
/*
* for the current config, this interface and alt,
* which endpoints are available
*/
if_descr = &hdl->device->config[index].interface[interface].
altsetting[alternate];
usb_dprintf(DEBUG_DETAILED, "cfg%d.%d.%d has %d endpoints\n",
info->configuration_value, interface, alternate,
if_descr->bNumEndpoints);
for (i = 0; i < if_descr->bNumEndpoints; i++) {
ep_descr = &hdl->device->config[index].interface[interface].
altsetting[alternate].endpoint[i];
info->ep_interface[usb_ep_index(
ep_descr->bEndpointAddress)] = interface;
}
usb_dprintf(DEBUG_DETAILED, "ep_interface:\n");
for (i = 0; i < USB_MAXENDPOINTS; i++) {
usb_dprintf(DEBUG_DETAILED, "%d ",
info->ep_interface[i]);
}
usb_dprintf(DEBUG_DETAILED, "\n");
}
/*
* usb_check_device_and_status_open:
* Make sure that the endpoint and status device for the endpoint
* can be opened, or have already been opened.
*
* Returns: errno
*/
static int
usb_check_device_and_status_open(usb_dev_handle *dev, int ep, int ep_type,
int mode)
{
usb_dev_handle_impl_t *hdl = (usb_dev_handle_impl_t *)dev;
usb_dev_handle_info_t *info = hdl->info;
char *filename, *statfilename, cfg_num[16], alt_num[16];
int fd, fdstat, index, rval;
index = usb_ep_index(ep);
usb_dprintf(DEBUG_FUNCTIONS,
"usb_check_device_and_status_open(): "
"ep=0x%x mode=%d index=%d\n", ep, mode, index);
if ((rval = usb_check_access(dev)) != 0) {
return (rval);
}
if ((index < 0) || (index > 31)) {
return (EINVAL);
}
usb_dprintf(DEBUG_DETAILED, "claimed=%d ep_interface=%d\n",
info->claimed_interface, info->ep_interface[index]);
if (info->claimed_interface != info->ep_interface[index]) {
return (EINVAL);
}
if ((info->ep_fd[index] > 0) && (info->ep_status_fd[index] > 0)) {
return (0);
}
if (ep == 0) {
/* should already be open */
return (0);
}
if ((filename = malloc(PATH_MAX+1)) == NULL) {
return (ENOMEM);
}
if ((statfilename = malloc(PATH_MAX+1)) == NULL) {
free(filename);
return (ENOMEM);
}
usb_dprintf(DEBUG_DETAILED, "cfgvalue=%d\n",
info->configuration_value);
/* create filename */
if (info->configuration_index > 0) {
(void) snprintf(cfg_num, sizeof (cfg_num), "cfg%d",
info->configuration_value);
} else {
(void) memset(cfg_num, 0, sizeof (cfg_num));
}
if (info->alternate > 0) {
(void) snprintf(alt_num, sizeof (alt_num), ".%d",
info->alternate);
} else {
(void) memset(alt_num, 0, sizeof (alt_num));
}
(void) snprintf(filename, PATH_MAX, "%s/%s/%sif%d%s%s%d",
hdl->device->bus->dirname, hdl->device->filename,
cfg_num, info->ep_interface[index],
alt_num, (ep & USB_EP_DIR_MASK) ? "in" :
"out", (ep & USB_EP_NUM_MASK));
usb_dprintf(DEBUG_DETAILED,
"usb_check_device_and_status_open: %s\n", filename);
/*
* for interrupt IN endpoints, we need to enable one xfer
* mode before opening the endpoint
*/
(void) snprintf(statfilename, PATH_MAX, "%sstat", filename);
if ((ep_type == USB_ENDPOINT_TYPE_INTERRUPT) &&
(ep & USB_ENDPOINT_IN)) {
char control = USB_EP_INTR_ONE_XFER;
ssize_t count;
/* open the status device node for the ep first RDWR */
if ((fdstat = open(statfilename, O_RDWR)) == -1) {
usb_error_str(errno, "can't open %s RDWR: %d",
statfilename, errno);
/* might be an older ugen version, try RDONLY */
if ((fdstat = open(statfilename,
O_RDONLY)) == -1) {
usb_error_str(errno,
"can't open %s RDONLY: %d",
filename, errno);
free(filename);
free(statfilename);
return (errno);
}
} else {
count = write(fdstat, &control, sizeof (control));
if (count != 1) {
/* this should have worked */
usb_error_str(errno, "can't write to %s: %d",
filename, errno);
free(filename);
free(statfilename);
(void) close(fdstat);
return (errno);
}
}
} else {
if ((fdstat = open(statfilename, O_RDONLY)) == -1) {
usb_error_str(errno, "can't open %s: %d",
statfilename, errno);
free(filename);
free(statfilename);
return (errno);
}
}
/* open the ep */
if ((fd = open(filename, mode)) == -1) {
usb_error_str(errno, "can't open %s: %d",
filename, errno);
(void) close(fdstat);
free(filename);
free(statfilename);
return (errno);
}
free(filename);
free(statfilename);
info->ep_fd[index] = fd;
info->ep_status_fd[index] = fdstat;
return (0);
}
/*
* usb_ep_index:
* creates an index from endpoint address that can
* be used to index into endpoint lists
*
* Returns: ep index (a number between 0 and 31)
*/
static uchar_t
usb_ep_index(uint8_t ep_addr)
{
return ((ep_addr & USB_EP_NUM_MASK) +
((ep_addr & USB_EP_DIR_MASK) ? 16 : 0));
}
/*
* usb_open_ep0:
* opens default pipe
*
* Returns: errno
*/
static int
usb_open_ep0(usb_dev_handle_impl_t *hdl)
{
char *filename;
usb_device_specific_t *dev_specific =
(usb_device_specific_t *)(hdl->device->dev);
usb_dprintf(DEBUG_FUNCTIONS, "usb_open_ep0():\n");
if (dev_specific->ep0_fd) {
dev_specific->ref_count++;
hdl->info->ep_fd[0] = dev_specific->ep0_fd;
hdl->info->ep_status_fd[0] = dev_specific->ep0_fd_stat;
usb_dprintf(DEBUG_DETAILED,
"usb_open_ep0(): already open, ref=%d\n",
dev_specific->ref_count);
return (0);
}
if ((filename = malloc(PATH_MAX+1)) == NULL) {
return (ENOMEM);
}
(void) snprintf(filename, PATH_MAX, "%s/%s/cntrl0",
hdl->device->bus->dirname, hdl->device->filename);
usb_dprintf(DEBUG_DETAILED, "opening %s\n", filename);
hdl->info->ep_fd[0] = open(filename, O_RDWR);
if (hdl->info->ep_fd[0] < 0) {
usb_dprintf(DEBUG_ERRORS, "opening ep0 failed, %d\n",
hdl->info->ep_fd[0]);
free(filename);
return (errno);
}
(void) snprintf(filename, PATH_MAX, "%s/%s/cntrl0stat",
hdl->device->bus->dirname, hdl->device->filename);
usb_dprintf(DEBUG_DETAILED, "opening %s\n", filename);
hdl->info->ep_status_fd[0] = open(filename, O_RDONLY);
if (hdl->info->ep_status_fd[0] < 0) {
free(filename);
return (errno);
}
/* allow sharing between multiple opens */
dev_specific->ep0_fd = hdl->info->ep_fd[0];
dev_specific->ep0_fd_stat = hdl->info->ep_status_fd[0];
dev_specific->ref_count++;
usb_dprintf(DEBUG_DETAILED, "ep0 opened\n");
free(filename);
return (0);
}
/*
* usb_close_ep0:
* closes default ep0
*/
static void
usb_close_ep0(usb_dev_handle_impl_t *hdl)
{
usb_device_specific_t *dev_specific =
(usb_device_specific_t *)(hdl->device->dev);
usb_dprintf(DEBUG_FUNCTIONS, "usb_close_ep0():\n");
if (dev_specific->ep0_fd) {
if (--(dev_specific->ref_count) > 0) {
usb_dprintf(DEBUG_DETAILED,
"usb_close_ep0(): ref_count=%d\n",
dev_specific->ref_count);
return;
}
}
if (hdl->info->ep_fd[0] != -1) {
(void) close(hdl->info->ep_fd[0]);
hdl->info->ep_fd[0] = -1;
}
if (hdl->info->ep_status_fd[0] != -1) {
(void) close(hdl->info->ep_status_fd[0]);
hdl->info->ep_status_fd[0] = -1;
}
dev_specific->ep0_fd = 0;
dev_specific->ep0_fd_stat = 0;
}
/*
* usb_close_all_eps:
* closes all open endpoints except 0
*/
static void
usb_close_all_eps(usb_dev_handle_impl_t *hdl)
{
int i;
usb_dprintf(DEBUG_FUNCTIONS, "usb_close_all_eps():\n");
for (i = 1; i < USB_MAXENDPOINTS; i++) {
if (hdl->info->ep_fd[i] != -1) {
(void) close(hdl->info->ep_fd[i]);
hdl->info->ep_fd[i] = -1;
}
if (hdl->info->ep_status_fd[i] != -1) {
(void) close(hdl->info->ep_status_fd[i]);
hdl->info->ep_status_fd[i] = -1;
}
}
}
/*
* usb_setup_all_configs:
* parses config cloud for each config
*
* Returns: errno
*/
static int
usb_setup_all_configs(usb_dev_handle_impl_t *hdl)
{
char buffer[USB_DEV_DESCR_SIZE];
int rval, len;
uint_t index;
if (hdl->device->config) {
return (0);
}
usb_dprintf(DEBUG_FUNCTIONS, "usb_setup_all_configs():\n");
/* get device descriptor */
rval = usb_control_msg((usb_dev_handle *)hdl,
USB_DEV_REQ_DEV_TO_HOST | USB_TYPE_STANDARD,
USB_REQ_GET_DESCRIPTOR, USB_DESCR_TYPE_SETUP_DEV,
0, buffer, USB_DEV_DESCR_SIZE, 0);
usb_dprintf(DEBUG_DETAILED, "dev descr rval=%d\n", rval);
if (rval != USB_DEV_DESCR_SIZE) {
return (EIO);
}
/* parse device descriptor */
rval = (int)usb_parse_dev_descr((uchar_t *)buffer, sizeof (buffer),
(struct usb_device_descriptor *)&hdl->device->descriptor,
sizeof (struct usb_device_descriptor));
usb_dprintf(DEBUG_DETAILED, "parse dev descr rval=%d\n", rval);
if (rval != (int)sizeof (struct usb_device_descriptor)) {
return (EIO);
}
/* allocate config array */
len = (int) sizeof (struct usb_config_descriptor) *
hdl->device->descriptor.bNumConfigurations;
if ((hdl->device->config = calloc(len, 1)) == NULL) {
return (ENOMEM);
}
/* parse each config cloud */
for (index = 0; index < hdl->device->descriptor.bNumConfigurations;
index++) {
if ((rval = usb_parse_config(hdl, index)) != 0) {
return (rval);
}
}
return (0);
}
/*
* usb_free_all_configs:
* frees all allocated resources
*/
static void
usb_free_all_configs(usb_device_t *dev)
{
uint_t index;
usb_dprintf(DEBUG_FUNCTIONS, "usb_free_all_configs(): "
"dev=0x%x config=0x%x #conf=%d\n",
dev, dev->config, dev->descriptor.bNumConfigurations);
if (dev->config) {
for (index = 0; index < dev->descriptor.bNumConfigurations;
index++) {
usb_free_config(dev, index);
}
free(dev->config);
dev->config = NULL;
}
}
/*
* usb_parse_config:
* parse config descriptor and get cloud
*
* Returns: errno
*/
static int
usb_parse_config(usb_dev_handle_impl_t *hdl, uint_t index)
{
int rval;
uint_t iface, len;
char buffer[USB_CFG_DESCR_SIZE];
char *cloud;
unsigned char *extra;
int extralen;
usb_dprintf(DEBUG_FUNCTIONS, "usb_parse_config(): index=%d\n",
index);
rval = usb_control_msg((usb_dev_handle *)hdl,
USB_DEV_REQ_DEV_TO_HOST | USB_TYPE_STANDARD,
USB_REQ_GET_DESCRIPTOR, USB_DESCR_TYPE_SETUP_CFG | index,
0, buffer, USB_CFG_DESCR_SIZE, 0);
usb_dprintf(DEBUG_DETAILED, "config descr rval=%d expecting %d\n",
rval, USB_CFG_DESCR_SIZE);
if (rval < USB_CFG_DESCR_SIZE) {
return (EIO);
}
rval = (int)usb_parse_cfg_descr((uchar_t *)buffer, sizeof (buffer),
(usb_cfg_descr_t *)&hdl->device->config[index],
sizeof (usb_cfg_descr_t), &extra, &extralen);
usb_dprintf(DEBUG_DETAILED, "config descr rval=%d expecting %d\n",
rval, sizeof (usb_cfg_descr_t));
if (rval < USB_CFG_DESCR_SIZE) {
return (EIO);
}
usb_dprintf(DEBUG_DETAILED,
"cfg%d: len=%d type=%d total=%d #if=%d cf=%d\n", index,
hdl->device->config[index].bLength,
hdl->device->config[index].bDescriptorType,
hdl->device->config[index].wTotalLength,
hdl->device->config[index].bNumInterfaces,
hdl->device->config[index].bConfigurationValue);
if ((cloud = malloc(hdl->device->config[index].wTotalLength)) ==
NULL) {
return (ENOMEM);
}
/* get complete cloud */
rval = usb_control_msg((usb_dev_handle *)hdl,
USB_DEV_REQ_DEV_TO_HOST | USB_TYPE_STANDARD,
USB_REQ_GET_DESCRIPTOR, USB_DESCR_TYPE_SETUP_CFG | index,
0, (char *)cloud,
hdl->device->config[index].wTotalLength, 0);
if (rval != hdl->device->config[index].wTotalLength) {
free(cloud);
return (EIO);
}
/* parse descriptor again to get extra descriptors */
rval = (int)usb_parse_cfg_descr((uchar_t *)cloud,
hdl->device->config[index].wTotalLength,
(usb_cfg_descr_t *)&hdl->device->config[index],
sizeof (usb_cfg_descr_t), &extra, &extralen);
if (extralen) {
usb_dprintf(DEBUG_DETAILED,
"cfg%d: extra descriptors length=%d:\n",
index, extralen);
usb_dump_data((char *)extra, extralen);
if ((hdl->device->config[index].extra =
calloc(extralen, 1)) == NULL) {
free(cloud);
return (ENOMEM);
}
(void) memcpy(hdl->device->config[index].extra, extra,
extralen);
hdl->device->config[index].extralen = extralen;
}
/* allocate interface array */
len = hdl->device->config[index].bNumInterfaces *
(int)sizeof (struct usb_interface);
if ((hdl->device->config[index].interface = calloc(len, 1)) ==
NULL) {
free(cloud);
return (ENOMEM);
}
for (iface = 0; iface < hdl->device->config[index].bNumInterfaces;
iface++) {
rval = usb_parse_interface(hdl, index, iface, cloud);
if (rval != 0) {
free(cloud);
return (rval);
}
}
free(cloud);
return (0);
}
/*
* usb_free_config:
* frees all allocated config resources
*/
static void
usb_free_config(usb_device_t *device, uint_t index)
{
uint_t iface;
usb_dprintf(DEBUG_FUNCTIONS, "usb_free_config(): index=%d\n",
index);
if (device->config[index].interface) {
for (iface = 0; iface < device->config[index].bNumInterfaces;
iface++) {
usb_free_interface(device, index, iface);
}
if (device->config[index].extralen) {
free(device->config[index].extra);
}
free(device->config[index].interface);
}
}
/*
* usb_parse_interface:
* parse an interface descriptor
*
* Returns: errno
*/
static int
usb_parse_interface(usb_dev_handle_impl_t *hdl, uint_t index, uint_t iface,
char *cloud)
{
usb_if_descr_t if_descr;
int rval;
uint_t alt, max_alt, len;
unsigned char *extra;
int extralen;
usb_dprintf(DEBUG_FUNCTIONS, "usb_parse_interface(): "
"index=%d, iface=%d\n", index, iface);
/* count the number of alternates for this interface */
for (max_alt = alt = 0; alt < USB_MAXALTSETTING; alt++) {
rval = (int)usb_parse_if_descr((uchar_t *)cloud,
hdl->device->config[index].wTotalLength,
iface, alt, &if_descr, sizeof (if_descr),
&extra, &extralen);
usb_dprintf(DEBUG_DETAILED, "usb_parse_interface: "
"alt %d: rval=%d expecting %d\n",
alt, rval, sizeof (if_descr));
if (rval != (int)sizeof (if_descr)) {
break;
}
max_alt = alt;
}
usb_dprintf(DEBUG_DETAILED,
"usb_parse_interface: max_alt=%d\n", max_alt);
/* allocate alt interface setting array */
len = ++max_alt * (int)sizeof (struct usb_interface_descriptor);
if ((hdl->device->config[index].interface[iface].altsetting =
calloc(len, 1)) == NULL) {
return (ENOMEM);
}
hdl->device->config[index].interface[iface].num_altsetting =
max_alt;
for (alt = 0; alt < max_alt; alt++) {
rval = usb_parse_alternate(hdl, index, iface, alt, cloud);
if (rval != 0) {
return (rval);
}
}
return (0);
}
/*
* usb_free_interface:
* frees interface resources
*
* Returns: errno
*/
static void
usb_free_interface(usb_device_t *device, uint_t index, uint_t iface)
{
uint_t alt, max_alt;
usb_dprintf(DEBUG_FUNCTIONS, "usb_free_interface(): "
"index=%d, iface=%d\n", index, iface);
if (device->config[index].interface[iface].altsetting) {
max_alt = device->config[index].interface[iface].
num_altsetting;
for (alt = 0; alt < max_alt; alt++) {
usb_free_alternate(device, index, iface, alt);
}
free(device->config[index].interface[iface].altsetting);
}
}
/*
* usb_parse_alternate:
* parses each alternate descriptor
*
* Returns: errno
*/
static int
usb_parse_alternate(usb_dev_handle_impl_t *hdl, uint_t index, uint_t iface,
uint_t alt, char *cloud)
{
uint_t ep, len;
usb_if_descr_t if_descr;
int rval;
unsigned char *extra;
int extralen;
usb_dprintf(DEBUG_FUNCTIONS, "usb_parse_alternate(): "
"index=%d, iface=%d, alt=%d\n", index, iface, alt);
rval = (int)usb_parse_if_descr((uchar_t *)cloud,
hdl->device->config[index].wTotalLength,
iface, alt, &if_descr, sizeof (if_descr), &extra, &extralen);
if (rval != (int)sizeof (if_descr)) {
usb_dprintf(DEBUG_ERRORS, "usb_parse_alternate: rval=%d\n",
rval);
return (EIO);
}
usb_dprintf(DEBUG_DETAILED,
"cfg%d.if%d.%d: len=%d type=%d num=%d alt=%d #ep=%d c=%d"
" sc=%d p=%d i=%d\n", index, iface, alt,
if_descr.bLength,
if_descr.bDescriptorType,
if_descr.bInterfaceNumber,
if_descr.bAlternateSetting,
if_descr.bNumEndpoints,
if_descr.bInterfaceClass,
if_descr.bInterfaceSubClass,
if_descr.bInterfaceProtocol,
if_descr.iInterface);
(void) memcpy(
&hdl->device->config[index].interface[iface].altsetting[alt],
&if_descr, sizeof (if_descr));
if (extralen) {
usb_dprintf(DEBUG_DETAILED,
"cfg%d.if%d.%d: extralen=%d:\n", index, iface, alt,
extralen);
usb_dump_data((char *)extra, extralen);
if ((hdl->device->config[index].interface[iface].
altsetting[alt].extra = calloc(extralen, 1)) == NULL) {
return (ENOMEM);
}
(void) memcpy(
hdl->device->config[index].interface[iface].
altsetting[alt].extra, extra, extralen);
hdl->device->config[index].interface[iface].
altsetting[alt].extralen = extralen;
}
if (if_descr.bNumEndpoints == 0) {
return (0);
}
/* allocate endpoint array for this alternate */
len = if_descr.bNumEndpoints *
(int)sizeof (struct usb_endpoint_descriptor);
if ((hdl->device->config[index].interface[iface].altsetting[alt].
endpoint = calloc(len, 1)) == NULL) {
return (ENOMEM);
}
for (ep = 0; ep < if_descr.bNumEndpoints; ep++) {
rval = usb_parse_endpoint(hdl, index, iface, alt, ep, cloud);
if (rval != 0) {
return (rval);
}
}
return (0);
}
/*
* usb_free_alternate:
* frees all alternate resources
*/
static void
usb_free_alternate(usb_device_t *device, uint_t index, uint_t iface,
uint_t alt)
{
usb_dprintf(DEBUG_FUNCTIONS, "usb_free_alternate(): "
"index=%d, iface=%d, alt=%d\n", index, iface, alt);
if (device->config[index].interface[iface].altsetting[alt].
endpoint) {
uint_t ep;
struct usb_interface_descriptor *if_descr =
&device->config[index].
interface[iface].altsetting[alt];
for (ep = 0; ep < if_descr->bNumEndpoints; ep++) {
if (if_descr->extralen) {
free(if_descr->extra);
}
}
if (device->config[index].interface[iface].altsetting[alt].
extralen) {
free(device->config[index].interface[iface].
altsetting[alt].extra);
}
free(device->config[index].interface[iface].altsetting[alt].
endpoint);
}
}
/*
* usb_parse_endpoint:
* parses an endpoint descriptor
*
* Returns: errno
*/
static int
usb_parse_endpoint(usb_dev_handle_impl_t *hdl, int index, int iface,
int alt, int ep, char *cloud)
{
usb_ep_descr_t ep_descr;
int rval;
unsigned char *extra;
int extralen;
usb_dprintf(DEBUG_FUNCTIONS, "usb_parse_endpoint(): "
"index=%d, iface=%d, alt=%d, ep=0x%x\n",
index, iface, alt, ep);
rval = (int)usb_parse_ep_descr((uchar_t *)cloud,
hdl->device->config[index].wTotalLength,
iface, alt, ep, &ep_descr, sizeof (ep_descr),
&extra, &extralen);
if (rval < USB_EP_DESCR_SIZE) {
usb_dprintf(DEBUG_ERRORS, "usb_parse_endpoint: rval=%d, "
"expecting %d\n", rval, USB_EP_DESCR_SIZE);
return (rval);
}
usb_dprintf(DEBUG_DETAILED,
"\tl=%d t=%d a=0x%x attr=0x%x max=%d int=%d\n",
ep_descr.bLength, ep_descr.bDescriptorType,
ep_descr.bEndpointAddress, ep_descr.bmAttributes,
ep_descr.wMaxPacketSize, ep_descr.bInterval);
(void) memcpy(&hdl->device->
config[index].interface[iface].altsetting[alt].endpoint[ep],
&ep_descr, sizeof (ep_descr));
if (extralen) {
usb_dprintf(DEBUG_DETAILED,
"cfg%d.if%d.%d.ep%d: extralen=%d:\n",
index, iface, alt, ep, extralen);
usb_dump_data((char *)extra, extralen);
if ((hdl->device->config[index].interface[iface].
altsetting[alt].endpoint[ep].extra =
calloc(extralen, 1)) == NULL) {
return (ENOMEM);
}
(void) memcpy(hdl->device->config[index].interface[iface].
altsetting[alt].endpoint[ep].extra, extra, extralen);
hdl->device->config[index].interface[iface].
altsetting[alt].endpoint[ep].extralen = extralen;
}
return (0);
}
/*
* usb_add_device:
* adds dev to the beginning of the list
*/
static void
usb_add_device(usb_device_t **list, usb_device_t *dev)
{
if (*list) {
dev->next = *list;
dev->next->prev = dev;
} else {
dev->next = NULL;
}
dev->prev = NULL;
*list = dev;
}
/*
* usb_remove_device:
* removes dev from a list
*/
static void
usb_remove_device(usb_device_t **list, usb_device_t *dev)
{
if (dev->prev) {
dev->prev->next = dev->next;
} else {
*list = dev->next;
}
if (dev->next) {
dev->next->prev = dev->prev;
}
dev->prev = dev->next = NULL;
}
/*
* usb_check_device_in_list:
* checks if dev is in list
*
* Returns: 1 (yes), 0 (no)
*/
static int
usb_check_device_in_list(usb_device_t *list, usb_device_t *dev)
{
usb_device_t *d = list;
while (d != NULL) {
if (d == dev) {
return (1);
}
d = d->next;
}
return (0);
}
/*
* usb_free_bus:
* frees the entire bus structure, not used, just for
* completeness
*/
static void
usb_free_bus(usb_bus_t *bus)
{
free(bus);
}
/*
* usb_free_dev:
* frees all configs and then the device structure itself
*/
static void
usb_free_dev(usb_device_t *dev)
{
usb_dprintf(DEBUG_FUNCTIONS, "usb_free_dev(): 0x%x\n", (int)dev);
usb_free_all_configs(dev);
free(dev->dev);
free(dev);
}
/*
* usb_get_device_status:
* gets status of device
*
* Returns: ugen dev status values
*/
static int
usb_get_device_status(int fd)
{
int status, error;
usb_dprintf(DEBUG_FUNCTIONS, "usb_get_device_status():\n");
error = (int)read(fd, &status, (size_t)sizeof (status));
if (error != (int)sizeof (status)) {
usb_error_str(errno, "Could not read device status: %d",
error);
return (USB_DEV_STAT_UNAVAILABLE);
} else {
switch (status) {
case USB_DEV_STAT_ONLINE:
usb_dprintf(DEBUG_DETAILED, "Device is available\n");
break;
case USB_DEV_STAT_DISCONNECTED:
usb_dprintf(DEBUG_DETAILED, "Device has been "
"disconnected\n");
break;
case USB_DEV_STAT_RESUMED:
usb_dprintf(DEBUG_DETAILED,
"Device has been resumed\n");
break;
case USB_DEV_STAT_UNAVAILABLE:
usb_dprintf(DEBUG_DETAILED,
"Device is powered down\n");
break;
default:
usb_dprintf(DEBUG_DETAILED,
"Device status=%d\n", status);
}
}
return (status);
}
/*
* usb_search_dev_usb:
* finds all names of devices in the /usb/dev tree
* this will be the VID/PID and instance no
*
* Returns: errno
*/
static int
usb_search_dev_usb(usb_device_t **new_devices)
{
DIR *dir, *subdir;
struct dirent *dir_entry, *subdir_entry;
char *device, *filename;
usb_bus_t *bus = usb_busses;
struct stat statbuf;
regex_t regex;
usb_dprintf(DEBUG_FUNCTIONS, "usb_search_dev_usb():\n");
if ((device = malloc(PATH_MAX+1)) == NULL) {
return (ENOMEM);
}
if ((filename = malloc(PATH_MAX+1)) == NULL) {
free(device);
return (ENOMEM);
}
if (!(dir = opendir(bus->dirname))) {
free(device);
free(filename);
usb_error_str(errno,
"couldn't opendir %s: %d", bus->dirname, errno);
return (errno);
}
/* make sure we only open ugen directories */
if ((regcomp(®ex, "/dev/usb/[0-9a-f]+[.][0-9a-f]+",
REG_EXTENDED) != 0)) {
return (EINVAL);
}
/* search for devices */
while ((dir_entry = readdir(dir)) != NULL) {
usb_dprintf(DEBUG_FUNCTIONS, "usb_search_dev_usb(): dir=%s\n",
dir_entry->d_name);
if (dir_entry->d_name[0] == '.') {
continue;
}
(void) snprintf(device, PATH_MAX, "%s/%s", bus->dirname,
dir_entry->d_name);
/*
* make sure we don't accidentily open /dev/usb/hid* nodes
* which will get them unlinked from the virtual console
*/
if (lstat(device, &statbuf) == -1) {
continue;
}
if (!S_ISDIR(statbuf.st_mode)) {
continue;
}
if (regexec(®ex, device, 0, NULL, 0) != 0) {
continue;
}
usb_dprintf(DEBUG_FUNCTIONS, "checking %s\n", device);
/* need to search instances */
if (!(subdir = opendir(device))) {
continue;
}
while ((subdir_entry = readdir(subdir)) != NULL) {
usb_device_t *dev;
usb_device_specific_t *dev_specific;
int fd;
if (subdir_entry->d_name[0] == '.') {
continue;
}
if ((dev = calloc(sizeof (*dev), 1)) == NULL) {
free(device);
free(filename);
regfree(®ex);
(void) closedir(subdir);
(void) closedir(dir);
return (ENOMEM);
}
if ((dev_specific = calloc(sizeof (*dev_specific),
1)) == NULL) {
free(device);
free(filename);
free(dev);
regfree(®ex);
(void) closedir(subdir);
(void) closedir(dir);
return (ENOMEM);
}
dev->dev = (void *)dev_specific;
dev->bus = bus;
(void) snprintf(dev->filename, PATH_MAX, "%s/%s",
dir_entry->d_name, subdir_entry->d_name);
/* See if the device is online */
(void) snprintf(filename, PATH_MAX, "%s/%s/devstat",
bus->dirname, dev->filename);
usb_dprintf(DEBUG_DETAILED, "filename %s\n", filename);
usb_dprintf(DEBUG_DETAILED, "dev filename %s\n",
dev->filename);
if ((fd = open(filename, O_RDONLY|O_EXCL)) < 0) {
usb_dprintf(DEBUG_ERRORS,
"usb_search_dev_usb: Couldn't open %s\n",
filename);
free(dev_specific);
free(dev);
continue;
}
if (usb_get_device_status(fd) != USB_DEV_STAT_ONLINE) {
(void) close(fd);
usb_error_str(EIO, "Device %s is not online",
dev->filename);
free(dev_specific);
free(dev);
continue;
}
(void) close(fd);
usb_add_device(new_devices, dev);
}
(void) closedir(subdir);
}
regfree(®ex);
free(filename);
free(device);
(void) closedir(dir);
return (0);
}
/*
* usb_get_status:
* gets status of endpoint
*
* Returns: ugen's last cmd status
*/
static int
usb_get_status(int fd)
{
int status, error;
usb_dprintf(DEBUG_FUNCTIONS, "usb_get_status(): fd=%d\n", fd);
error = (int)read(fd, &status, sizeof (status));
if (error == (int)sizeof (status)) {
switch (status) {
case USB_LC_STAT_NOERROR:
usb_dprintf(DEBUG_DETAILED, "No Error\n");
break;
case USB_LC_STAT_CRC:
usb_dprintf(DEBUG_ERRORS, "CRC Timeout Detected\n");
break;
case USB_LC_STAT_BITSTUFFING:
usb_dprintf(DEBUG_ERRORS, "Bit Stuffing Violation\n");
break;
case USB_LC_STAT_DATA_TOGGLE_MM:
usb_dprintf(DEBUG_ERRORS, "Data Toggle Mismatch\n");
break;
case USB_LC_STAT_STALL:
usb_dprintf(DEBUG_ERRORS, "End Point Stalled\n");
break;
case USB_LC_STAT_DEV_NOT_RESP:
usb_dprintf(DEBUG_ERRORS, "Device is Not Responding\n");
break;
case USB_LC_STAT_PID_CHECKFAILURE:
usb_dprintf(DEBUG_ERRORS, "PID Check Failure\n");
break;
case USB_LC_STAT_UNEXP_PID:
usb_dprintf(DEBUG_ERRORS, "Unexpected PID\n");
break;
case USB_LC_STAT_DATA_OVERRUN:
usb_dprintf(DEBUG_ERRORS, "Data Exceeded Size\n");
break;
case USB_LC_STAT_DATA_UNDERRUN:
usb_dprintf(DEBUG_ERRORS, "Less data received\n");
break;
case USB_LC_STAT_BUFFER_OVERRUN:
usb_dprintf(DEBUG_ERRORS, "Buffer Size Exceeded\n");
break;
case USB_LC_STAT_BUFFER_UNDERRUN:
usb_dprintf(DEBUG_ERRORS, "Buffer Underrun\n");
break;
case USB_LC_STAT_TIMEOUT:
usb_dprintf(DEBUG_ERRORS, "Command Timed Out\n");
break;
case USB_LC_STAT_NOT_ACCESSED:
usb_dprintf(DEBUG_ERRORS, "Not Accessed by h/w\n");
break;
case USB_LC_STAT_UNSPECIFIED_ERR:
usb_dprintf(DEBUG_ERRORS, "Unspecified Error\n");
break;
case USB_LC_STAT_NO_BANDWIDTH:
usb_dprintf(DEBUG_ERRORS, "No Bandwidth\n");
break;
case USB_LC_STAT_HW_ERR:
usb_dprintf(DEBUG_ERRORS,
"Host Controller h/w Error\n");
break;
case USB_LC_STAT_SUSPENDED:
usb_dprintf(DEBUG_ERRORS, "Device was Suspended\n");
break;
case USB_LC_STAT_DISCONNECTED:
usb_dprintf(DEBUG_ERRORS, "Device was Disconnected\n");
break;
case USB_LC_STAT_INTR_BUF_FULL:
usb_dprintf(DEBUG_ERRORS,
"Interrupt buffer was full\n");
break;
case USB_LC_STAT_INVALID_REQ:
usb_dprintf(DEBUG_ERRORS, "Request was Invalid\n");
break;
case USB_LC_STAT_INTERRUPTED:
usb_dprintf(DEBUG_ERRORS, "Request was Interrupted\n");
break;
case USB_LC_STAT_NO_RESOURCES:
usb_dprintf(DEBUG_ERRORS, "No resources available for "
"request\n");
break;
case USB_LC_STAT_INTR_POLLING_FAILED:
usb_dprintf(DEBUG_ERRORS, "Failed to Restart Poll");
break;
default:
usb_dprintf(DEBUG_ERRORS, "Error Not Determined %d\n",
status);
break;
}
}
return (status);
}
/*
* Descriptor parsing functions, taken from USBA code
*
* usb_parse_data:
* take a raw buffer and pads it according to format
*
* Returns: USB_PARSE_ERROR or length parsed
*/
static size_t
usb_parse_data(char *format, uchar_t *data, size_t datalen,
void *structure, size_t structlen)
{
int fmt;
size_t counter = 1;
int multiplier = 0;
uchar_t *dataend = data + datalen;
char *structstart = (char *)structure;
void *structend = (void *)((intptr_t)structstart + structlen);
if ((format == NULL) || (data == NULL) || (structure == NULL)) {
return (USB_PARSE_ERROR);
}
while ((fmt = *format) != '\0') {
/*
* Could some one pass a "format" that is greater than
* the structlen? Conversely, one could pass a ret_buf_len
* that is less than the "format" length.
* If so, we need to protect against writing over memory.
*/
if (counter++ > structlen) {
break;
}
if (fmt == 'c') {
uint8_t *cp = (uint8_t *)structure;
cp = (uint8_t *)(((uintptr_t)cp + _CHAR_ALIGNMENT - 1) &
~(_CHAR_ALIGNMENT - 1));
if (((data + 1) > dataend) ||
((cp + 1) > (uint8_t *)structend))
break;
*cp++ = *data++;
structure = (void *)cp;
if (multiplier) {
multiplier--;
}
if (multiplier == 0) {
format++;
}
} else if (fmt == 's') {
uint16_t *sp = (uint16_t *)structure;
sp = (uint16_t *)
(((uintptr_t)sp + _SHORT_ALIGNMENT - 1) &
~(_SHORT_ALIGNMENT - 1));
if (((data + 2) > dataend) ||
((sp + 1) > (uint16_t *)structend))
break;
*sp++ = (data[1] << 8) + data[0];
data += 2;
structure = (void *)sp;
if (multiplier) {
multiplier--;
}
if (multiplier == 0) {
format++;
}
} else if (fmt == 'l') {
uint32_t *lp = (uint32_t *)structure;
lp = (uint32_t *)
(((uintptr_t)lp + _INT_ALIGNMENT - 1) &
~(_INT_ALIGNMENT - 1));
if (((data + 4) > dataend) ||
((lp + 1) > (uint32_t *)structend))
break;
*lp++ = (((((
(uint32_t)data[3] << 8) | data[2]) << 8) |
data[1]) << 8) | data[0];
data += 4;
structure = (void *)lp;
if (multiplier) {
multiplier--;
}
if (multiplier == 0) {
format++;
}
} else if (fmt == 'L') {
uint64_t *llp = (uint64_t *)structure;
llp = (uint64_t *)
(((uintptr_t)llp + _LONG_LONG_ALIGNMENT - 1) &
~(_LONG_LONG_ALIGNMENT - 1));
if (((data + 8) > dataend) ||
((llp + 1) >= (uint64_t *)structend))
break;
*llp++ = (((((((((((((data[7] << 8) |
data[6]) << 8) | data[5]) << 8) |
data[4]) << 8) | data[3]) << 8) |
data[2]) << 8) | data[1]) << 8) |
data[0];
data += 8;
structure = (void *)llp;
if (multiplier) {
multiplier--;
}
if (multiplier == 0) {
format++;
}
} else if (isdigit(fmt)) {
multiplier = (multiplier * 10) + (fmt - '0');
counter--;
format++;
} else {
multiplier = 0;
break;
}
}
return ((intptr_t)structure - (intptr_t)structstart);
}
/*
* usb_nth_descr:
* finds pointer to n-th descriptor of
* type descr_type, unless the end of the buffer or a descriptor
* of type stop_descr_type1 or stop_descr_type2 is encountered first.
*
* Returns: returns pointer to n-th descriptor
*/
static uchar_t *
usb_nth_descr(uchar_t *buf, size_t buflen, int descr_type, uint_t n,
int stop_descr_type1, int stop_descr_type2)
{
uchar_t *bufstart = buf;
uchar_t *bufend = buf + buflen;
if (buf == NULL) {
return (NULL);
}
while (buf + 2 <= bufend) {
if ((buf != bufstart) && ((buf[1] == stop_descr_type1) ||
(buf[1] == stop_descr_type2))) {
return (NULL);
}
if ((descr_type == USB_DESCR_TYPE_ANY) ||
(buf[1] == descr_type)) {
if (n-- == 0) {
return (buf);
}
}
/*
* Check for a bad buffer.
* If buf[0] is 0, then this will be an infite loop
*/
INCREMENT_BUF(buf);
}
return (NULL);
}
/*
* usb_parse_dev_descr:
* parse device descriptor
*
* Returns: #bytes parsed
*/
static size_t
usb_parse_dev_descr(uchar_t *buf, size_t buflen,
struct usb_device_descriptor *ret_descr, size_t ret_buf_len)
{
if ((buf == NULL) || (ret_descr == NULL) ||
(buflen < 2) || (buf[1] != USB_DESCR_TYPE_DEV)) {
return (USB_PARSE_ERROR);
}
return (usb_parse_data("ccsccccssscccc",
buf, buflen, ret_descr, ret_buf_len));
}
/*
* usb_parse_cfg_descr:
* parse config descriptor
*
* Returns: #bytes parsed
*/
static size_t
usb_parse_cfg_descr(uchar_t *buf, size_t buflen, usb_cfg_descr_t *ret_descr,
size_t ret_buf_len, unsigned char **extra, int *extralen)
{
size_t rval;
if ((buf == NULL) || (ret_descr == NULL) ||
(buflen < 2) || (buf[1] != USB_DESCR_TYPE_CFG)) {
return (USB_PARSE_ERROR);
}
rval = usb_parse_data("ccsccccc",
buf, buflen, ret_descr, ret_buf_len);
usb_find_extra(buf, buflen, extra, extralen);
return (rval);
}
/*
* usb_parse_if_descr:
* parse interface descriptor
*
* Returns: #bytes parsed
*/
static size_t
usb_parse_if_descr(uchar_t *buf, size_t buflen, uint_t if_number,
uint_t alt_if_setting, usb_if_descr_t *ret_descr, size_t ret_buf_len,
unsigned char **extra, int *extralen)
{
uchar_t *bufend = buf + buflen;
size_t rval;
if ((buf == NULL) || (ret_descr == NULL)) {
return (USB_PARSE_ERROR);
}
while (buf + 4 <= bufend) {
if ((buf[1] == USB_DESCR_TYPE_IF) &&
(buf[2] == if_number) &&
(buf[3] == alt_if_setting)) {
rval = usb_parse_data("ccccccccc",
buf, ((uintptr_t)bufend - (uintptr_t)buf),
ret_descr, ret_buf_len);
usb_find_extra(buf,
((uintptr_t)bufend - (uintptr_t)buf),
extra, extralen);
return (rval);
}
/*
* Check for a bad buffer.
* If buf[0] is 0, then this will be an infinite loop
*/
INCREMENT_BUF(buf);
}
return (USB_PARSE_ERROR);
}
/*
* usb_parse_ep_descr:
* parse config descriptor
* the endpoint index is relative to the interface. index 0 is
* the first endpoint
*
* Returns: #bytes parsed
*/
size_t
usb_parse_ep_descr(uchar_t *buf, size_t buflen, uint_t if_number,
uint_t alt_if_setting, uint_t ep_index, usb_ep_descr_t *ret_descr,
size_t ret_buf_len, unsigned char **extra, int *extralen)
{
uchar_t *bufend = buf + buflen;
size_t rval;
if ((buf == NULL) || (ret_descr == NULL)) {
return (USB_PARSE_ERROR);
}
while ((buf + 4) <= bufend) {
if (buf[1] == USB_DESCR_TYPE_IF &&
buf[2] == if_number &&
buf[3] == alt_if_setting) {
if ((buf = usb_nth_descr(buf,
(uintptr_t)bufend - (uintptr_t)buf,
USB_DESCR_TYPE_EP, ep_index,
USB_DESCR_TYPE_IF, -1)) == NULL) {
break;
}
rval = usb_parse_data("ccccsccc", buf,
(uintptr_t)bufend - (uintptr_t)buf,
ret_descr, ret_buf_len);
usb_find_extra(buf, (uintptr_t)bufend - (uintptr_t)buf,
extra, extralen);
return (rval);
}
/*
* Check for a bad buffer.
* If buf[0] is 0, then this will be an infinite loop
*/
INCREMENT_BUF(buf);
}
return (USB_PARSE_ERROR);
}
/*
* extra descriptor handling
*
* usb_find_extra:
* finds any non-standard descriptor after the current
* standard descriptor and puts a pointer in extra argument
* and the length in extralen
*/
static void
usb_find_extra(uchar_t *buf, size_t buflen,
unsigned char **extra, int *extralen)
{
uchar_t *next = buf + buf[0];
*extralen = 0;
*extra = next;
while (((uintptr_t)next - (uintptr_t)buf + 1) < buflen) {
if ((next[1] == USB_DT_CONFIG) ||
(next[1] == USB_DT_INTERFACE) ||
(next[1] == USB_DT_ENDPOINT)) {
*extralen = (int)((uintptr_t)next -
(uintptr_t)buf - buf[0]);
return;
}
next += next[0];
}
}
/*
* error handling
*
* usb_strerror:
* lookup error string
*
* Returns: error string
*/
char *
usb_strerror(void)
{
usb_dprintf(DEBUG_FUNCTIONS, "usb_strerror(): "
"usb_error_type=%d, errno=%d\n", usb_error_type, usb_error_errno);
switch (usb_error_type) {
case USB_ERROR_TYPE_NONE:
return ("No error");
case USB_ERROR_TYPE_STRING:
return (usb_error_string);
case USB_ERROR_TYPE_ERRNO:
if (usb_error_errno > 0) {
return (strerror(usb_error_errno));
}
default:
break;
}
return ("Unknown error");
}
/*
* usb_error:
* stores the error number in the global usb_error_errno
*
* Returns: negative error number
*/
static int
usb_error(int x)
{
usb_dprintf(DEBUG_FUNCTIONS, "usb_error(): error=%d\n", x);
usb_error_type = USB_ERROR_TYPE_ERRNO;
usb_error_errno = x;
return (-x);
}
/*
* usb_error_str:
* creates error string
*/
static void
usb_error_str(int x, char *format, ...)
{
va_list ap;
va_start(ap, format);
usb_error_type = USB_ERROR_TYPE_ERRNO;
usb_error_errno = x;
(void) vsnprintf(usb_error_string, sizeof (usb_error_string),
format, ap);
usb_dprintf(DEBUG_ERRORS, "USB error (%d): %s\n", x, usb_error_string);
va_end(ap);
}
/*
* usb_dprintf:
* prints out tracing messages according to level
*/
static void
usb_dprintf(int level, char *format, ...)
{
va_list ap;
char buf[512];
va_start(ap, format);
(void) vsnprintf(buf, sizeof (buf), format, ap);
if (libusb_debug >= level) {
(void) fprintf(stderr, buf);
}
va_end(ap);
}
/*
* usb_dump_data:
* print data buffer
*/
static void
usb_dump_data(char *data, int size)
{
int i;
if (libusb_debug >= DEBUG_DATA_DUMP) {
(void) fprintf(stderr, "data dump:");
for (i = 0; i < size; i++) {
if (i % 16 == 0) {
(void) fprintf(stderr, "\n%08x ", i);
}
(void) fprintf(stderr, "%02x ", (uchar_t)data[i]);
}
(void) fprintf(stderr, "\n");
}
}