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      1 /*
      2  * Core functions for libusb
      3  * Copyright (C) 2007-2008 Daniel Drake <dsd (at) gentoo.org>
      4  * Copyright (c) 2001 Johannes Erdfelt <johannes (at) erdfelt.com>
      5  *
      6  * This library is free software; you can redistribute it and/or
      7  * modify it under the terms of the GNU Lesser General Public
      8  * License as published by the Free Software Foundation; either
      9  * version 2.1 of the License, or (at your option) any later version.
     10  *
     11  * This library is distributed in the hope that it will be useful,
     12  * but WITHOUT ANY WARRANTY; without even the implied warranty of
     13  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
     14  * Lesser General Public License for more details.
     15  *
     16  * You should have received a copy of the GNU Lesser General Public
     17  * License along with this library; if not, write to the Free Software
     18  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
     19  */
     20 
     21 #include <config.h>
     22 
     23 #include <errno.h>
     24 #include <poll.h>
     25 #include <stdarg.h>
     26 #include <stdio.h>
     27 #include <stdlib.h>
     28 #include <string.h>
     29 #include <sys/types.h>
     30 #include <unistd.h>
     31 
     32 #include "libusb.h"
     33 #include "libusbi.h"
     34 
     35 #if defined(OS_LINUX)
     36 const struct usbi_os_backend * const usbi_backend = &linux_usbfs_backend;
     37 #elif defined(OS_DARWIN)
     38 const struct usbi_os_backend * const usbi_backend = &darwin_backend;
     39 #else
     40 #error "Unsupported OS"
     41 #endif
     42 
     43 struct libusb_context *usbi_default_context = NULL;
     44 static pthread_mutex_t default_context_lock = PTHREAD_MUTEX_INITIALIZER;
     45 
     46 /**
     47  * \mainpage libusb-1.0 API Reference
     48  *
     49  * \section intro Introduction
     50  *
     51  * libusb is an open source library that allows you to communicate with USB
     52  * devices from userspace. For more info, see the
     53  * <a href="http://libusb.sourceforge.net">libusb homepage</a>.
     54  *
     55  * This documentation is aimed at application developers wishing to
     56  * communicate with USB peripherals from their own software. After reviewing
     57  * this documentation, feedback and questions can be sent to the
     58  * <a href="http://sourceforge.net/mail/?group_id=1674">libusb-devel mailing
     59  * list</a>.
     60  *
     61  * This documentation assumes knowledge of how to operate USB devices from
     62  * a software standpoint (descriptors, configurations, interfaces, endpoints,
     63  * control/bulk/interrupt/isochronous transfers, etc). Full information
     64  * can be found in the <a href="http://www.usb.org/developers/docs/">USB 2.0
     65  * Specification</a> which is available for free download. You can probably
     66  * find less verbose introductions by searching the web.
     67  *
     68  * \section features Library features
     69  *
     70  * - All transfer types supported (control/bulk/interrupt/isochronous)
     71  * - 2 transfer interfaces:
     72  *    -# Synchronous (simple)
     73  *    -# Asynchronous (more complicated, but more powerful)
     74  * - Thread safe (although the asynchronous interface means that you
     75  *   usually won't need to thread)
     76  * - Lightweight with lean API
     77  * - Compatible with libusb-0.1 through the libusb-compat-0.1 translation layer
     78  *
     79  * \section gettingstarted Getting Started
     80  *
     81  * To begin reading the API documentation, start with the Modules page which
     82  * links to the different categories of libusb's functionality.
     83  *
     84  * One decision you will have to make is whether to use the synchronous
     85  * or the asynchronous data transfer interface. The \ref io documentation
     86  * provides some insight into this topic.
     87  *
     88  * Some example programs can be found in the libusb source distribution under
     89  * the "examples" subdirectory. The libusb homepage includes a list of
     90  * real-life project examples which use libusb.
     91  *
     92  * \section errorhandling Error handling
     93  *
     94  * libusb functions typically return 0 on success or a negative error code
     95  * on failure. These negative error codes relate to LIBUSB_ERROR constants
     96  * which are listed on the \ref misc "miscellaneous" documentation page.
     97  *
     98  * \section msglog Debug message logging
     99  *
    100  * libusb does not log any messages by default. Your application is therefore
    101  * free to close stdout/stderr and those descriptors may be reused without
    102  * worry.
    103  *
    104  * The libusb_set_debug() function can be used to enable stdout/stderr logging
    105  * of certain messages. Under standard configuration, libusb doesn't really
    106  * log much at all, so you are advised to use this function to enable all
    107  * error/warning/informational messages. It will help you debug problems with
    108  * your software.
    109  *
    110  * The logged messages are unstructured. There is no one-to-one correspondence
    111  * between messages being logged and success or failure return codes from
    112  * libusb functions. There is no format to the messages, so you should not
    113  * try to capture or parse them. They are not and will not be localized.
    114  * These messages are not suitable for being passed to your application user;
    115  * instead, you should interpret the error codes returned from libusb functions
    116  * and provide appropriate notification to the user. The messages are simply
    117  * there to aid you as a programmer, and if you're confused because you're
    118  * getting a strange error code from a libusb function, enabling message
    119  * logging may give you a suitable explanation.
    120  *
    121  * The LIBUSB_DEBUG environment variable can be used to enable message logging
    122  * at run-time. This environment variable should be set to a number, which is
    123  * interpreted the same as the libusb_set_debug() parameter. When this
    124  * environment variable is set, the message logging verbosity level is fixed
    125  * and libusb_set_debug() effectively does nothing.
    126  *
    127  * libusb can be compiled without any logging functions, useful for embedded
    128  * systems. In this case, libusb_set_debug() and the LIBUSB_DEBUG environment
    129  * variable have no effects.
    130  *
    131  * libusb can also be compiled with verbose debugging messages. When the
    132  * library is compiled in this way, all messages of all verbosities are always
    133  * logged.  libusb_set_debug() and the LIBUSB_DEBUG environment variable have
    134  * no effects.
    135  *
    136  * \section remarks Other remarks
    137  *
    138  * libusb does have imperfections. The \ref caveats "caveats" page attempts
    139  * to document these.
    140  */
    141 
    142 /**
    143  * \page caveats Caveats
    144  *
    145  * \section devresets Device resets
    146  *
    147  * The libusb_reset_device() function allows you to reset a device. If your
    148  * program has to call such a function, it should obviously be aware that
    149  * the reset will cause device state to change (e.g. register values may be
    150  * reset).
    151  *
    152  * The problem is that any other program could reset the device your program
    153  * is working with, at any time. libusb does not offer a mechanism to inform
    154  * you when this has happened, so if someone else resets your device it will
    155  * not be clear to your own program why the device state has changed.
    156  *
    157  * Ultimately, this is a limitation of writing drivers in userspace.
    158  * Separation from the USB stack in the underlying kernel makes it difficult
    159  * for the operating system to deliver such notifications to your program.
    160  * The Linux kernel USB stack allows such reset notifications to be delivered
    161  * to in-kernel USB drivers, but it is not clear how such notifications could
    162  * be delivered to second-class drivers that live in userspace.
    163  *
    164  * \section blockonly Blocking-only functionality
    165  *
    166  * The functionality listed below is only available through synchronous,
    167  * blocking functions. There are no asynchronous/non-blocking alternatives,
    168  * and no clear ways of implementing these.
    169  *
    170  * - Configuration activation (libusb_set_configuration())
    171  * - Interface/alternate setting activation (libusb_set_interface_alt_setting())
    172  * - Releasing of interfaces (libusb_release_interface())
    173  * - Clearing of halt/stall condition (libusb_clear_halt())
    174  * - Device resets (libusb_reset_device())
    175  *
    176  * \section nohotplug No hotplugging
    177  *
    178  * libusb-1.0 lacks functionality for providing notifications of when devices
    179  * are added or removed. This functionality is planned to be implemented
    180  * for libusb-1.1.
    181  *
    182  * That said, there is basic disconnection handling for open device handles:
    183  *  - If there are ongoing transfers, libusb's handle_events loop will detect
    184  *    disconnections and complete ongoing transfers with the
    185  *    LIBUSB_TRANSFER_NO_DEVICE status code.
    186  *  - Many functions such as libusb_set_configuration() return the special
    187  *    LIBUSB_ERROR_NO_DEVICE error code when the device has been disconnected.
    188  *
    189  * \section configsel Configuration selection and handling
    190  *
    191  * When libusb presents a device handle to an application, there is a chance
    192  * that the corresponding device may be in unconfigured state. For devices
    193  * with multiple configurations, there is also a chance that the configuration
    194  * currently selected is not the one that the application wants to use.
    195  *
    196  * The obvious solution is to add a call to libusb_set_configuration() early
    197  * on during your device initialization routines, but there are caveats to
    198  * be aware of:
    199  * -# If the device is already in the desired configuration, calling
    200  *    libusb_set_configuration() using the same configuration value will cause
    201  *    a lightweight device reset. This may not be desirable behaviour.
    202  * -# libusb will be unable to change configuration if the device is in
    203  *    another configuration and other programs or drivers have claimed
    204  *    interfaces under that configuration.
    205  * -# In the case where the desired configuration is already active, libusb
    206  *    may not even be able to perform a lightweight device reset. For example,
    207  *    take my USB keyboard with fingerprint reader: I'm interested in driving
    208  *    the fingerprint reader interface through libusb, but the kernel's
    209  *    USB-HID driver will almost always have claimed the keyboard interface.
    210  *    Because the kernel has claimed an interface, it is not even possible to
    211  *    perform the lightweight device reset, so libusb_set_configuration() will
    212  *    fail. (Luckily the device in question only has a single configuration.)
    213  *
    214  * One solution to some of the above problems is to consider the currently
    215  * active configuration. If the configuration we want is already active, then
    216  * we don't have to select any configuration:
    217 \code
    218 cfg = libusb_get_configuration(dev);
    219 if (cfg != desired)
    220 	libusb_set_configuration(dev, desired);
    221 \endcode
    222  *
    223  * This is probably suitable for most scenarios, but is inherently racy:
    224  * another application or driver may change the selected configuration
    225  * <em>after</em> the libusb_get_configuration() call.
    226  *
    227  * Even in cases where libusb_set_configuration() succeeds, consider that other
    228  * applications or drivers may change configuration after your application
    229  * calls libusb_set_configuration().
    230  *
    231  * One possible way to lock your device into a specific configuration is as
    232  * follows:
    233  * -# Set the desired configuration (or use the logic above to realise that
    234  *    it is already in the desired configuration)
    235  * -# Claim the interface that you wish to use
    236  * -# Check that the currently active configuration is the one that you want
    237  *    to use.
    238  *
    239  * The above method works because once an interface is claimed, no application
    240  * or driver is able to select another configuration.
    241  *
    242  * \section earlycomp Early transfer completion
    243  *
    244  * NOTE: This section is currently Linux-centric. I am not sure if any of these
    245  * considerations apply to Darwin or other platforms.
    246  *
    247  * When a transfer completes early (i.e. when less data is received/sent in
    248  * any one packet than the transfer buffer allows for) then libusb is designed
    249  * to terminate the transfer immediately, not transferring or receiving any
    250  * more data unless other transfers have been queued by the user.
    251  *
    252  * On legacy platforms, libusb is unable to do this in all situations. After
    253  * the incomplete packet occurs, "surplus" data may be transferred. Prior to
    254  * libusb v1.0.2, this information was lost (and for device-to-host transfers,
    255  * the corresponding data was discarded). As of libusb v1.0.3, this information
    256  * is kept (the data length of the transfer is updated) and, for device-to-host
    257  * transfesr, any surplus data was added to the buffer. Still, this is not
    258  * a nice solution because it loses the information about the end of the short
    259  * packet, and the user probably wanted that surplus data to arrive in the next
    260  * logical transfer.
    261  *
    262  * A previous workaround was to only ever submit transfers of size 16kb or
    263  * less.
    264  *
    265  * As of libusb v1.0.4 and Linux v2.6.32, this is fixed. A technical
    266  * explanation of this issue follows.
    267  *
    268  * When you ask libusb to submit a bulk transfer larger than 16kb in size,
    269  * libusb breaks it up into a number of smaller subtransfers. This is because
    270  * the usbfs kernel interface only accepts transfers of up to 16kb in size.
    271  * The subtransfers are submitted all at once so that the kernel can queue
    272  * them at the hardware level, therefore maximizing bus throughput.
    273  *
    274  * On legacy platforms, this caused problems when transfers completed early
    275  * Upon this event, the kernel would terminate all further packets in that
    276  * subtransfer (but not any following ones). libusb would note this event and
    277  * immediately cancel any following subtransfers that had been queued,
    278  * but often libusb was not fast enough, and the following subtransfers had
    279  * started before libusb got around to cancelling them.
    280  *
    281  * Thanks to an API extension to usbfs, this is fixed with recent kernel and
    282  * libusb releases. The solution was to allow libusb to communicate to the
    283  * kernel where boundaries occur between logical libusb-level transfers. When
    284  * a short transfer (or other error) occurs, the kernel will cancel all the
    285  * subtransfers until the boundary without allowing those transfers to start.
    286  */
    287 
    288 /**
    289  * \page contexts Contexts
    290  *
    291  * It is possible that libusb may be used simultaneously from two independent
    292  * libraries linked into the same executable. For example, if your application
    293  * has a plugin-like system which allows the user to dynamically load a range
    294  * of modules into your program, it is feasible that two independently
    295  * developed modules may both use libusb.
    296  *
    297  * libusb is written to allow for these multiple user scenarios. The two
    298  * "instances" of libusb will not interfere: libusb_set_debug() calls
    299  * from one user will not affect the same settings for other users, other
    300  * users can continue using libusb after one of them calls libusb_exit(), etc.
    301  *
    302  * This is made possible through libusb's <em>context</em> concept. When you
    303  * call libusb_init(), you are (optionally) given a context. You can then pass
    304  * this context pointer back into future libusb functions.
    305  *
    306  * In order to keep things simple for more simplistic applications, it is
    307  * legal to pass NULL to all functions requiring a context pointer (as long as
    308  * you're sure no other code will attempt to use libusb from the same process).
    309  * When you pass NULL, the default context will be used. The default context
    310  * is created the first time a process calls libusb_init() when no other
    311  * context is alive. Contexts are destroyed during libusb_exit().
    312  *
    313  * You may be wondering why only a subset of libusb functions require a
    314  * context pointer in their function definition. Internally, libusb stores
    315  * context pointers in other objects (e.g. libusb_device instances) and hence
    316  * can infer the context from those objects.
    317  */
    318 
    319 /**
    320  * @defgroup lib Library initialization/deinitialization
    321  * This page details how to initialize and deinitialize libusb. Initialization
    322  * must be performed before using any libusb functionality, and similarly you
    323  * must not call any libusb functions after deinitialization.
    324  */
    325 
    326 /**
    327  * @defgroup dev Device handling and enumeration
    328  * The functionality documented below is designed to help with the following
    329  * operations:
    330  * - Enumerating the USB devices currently attached to the system
    331  * - Choosing a device to operate from your software
    332  * - Opening and closing the chosen device
    333  *
    334  * \section nutshell In a nutshell...
    335  *
    336  * The description below really makes things sound more complicated than they
    337  * actually are. The following sequence of function calls will be suitable
    338  * for almost all scenarios and does not require you to have such a deep
    339  * understanding of the resource management issues:
    340  * \code
    341 // discover devices
    342 libusb_device **list;
    343 libusb_device *found = NULL;
    344 ssize_t cnt = libusb_get_device_list(NULL, &list);
    345 ssize_t i = 0;
    346 int err = 0;
    347 if (cnt < 0)
    348 	error();
    349 
    350 for (i = 0; i < cnt; i++) {
    351 	libusb_device *device = list[i];
    352 	if (is_interesting(device)) {
    353 		found = device;
    354 		break;
    355 	}
    356 }
    357 
    358 if (found) {
    359 	libusb_device_handle *handle;
    360 
    361 	err = libusb_open(found, &handle);
    362 	if (err)
    363 		error();
    364 	// etc
    365 }
    366 
    367 libusb_free_device_list(list, 1);
    368 \endcode
    369  *
    370  * The two important points:
    371  * - You asked libusb_free_device_list() to unreference the devices (2nd
    372  *   parameter)
    373  * - You opened the device before freeing the list and unreferencing the
    374  *   devices
    375  *
    376  * If you ended up with a handle, you can now proceed to perform I/O on the
    377  * device.
    378  *
    379  * \section devshandles Devices and device handles
    380  * libusb has a concept of a USB device, represented by the
    381  * \ref libusb_device opaque type. A device represents a USB device that
    382  * is currently or was previously connected to the system. Using a reference
    383  * to a device, you can determine certain information about the device (e.g.
    384  * you can read the descriptor data).
    385  *
    386  * The libusb_get_device_list() function can be used to obtain a list of
    387  * devices currently connected to the system. This is known as device
    388  * discovery.
    389  *
    390  * Just because you have a reference to a device does not mean it is
    391  * necessarily usable. The device may have been unplugged, you may not have
    392  * permission to operate such device, or another program or driver may be
    393  * using the device.
    394  *
    395  * When you've found a device that you'd like to operate, you must ask
    396  * libusb to open the device using the libusb_open() function. Assuming
    397  * success, libusb then returns you a <em>device handle</em>
    398  * (a \ref libusb_device_handle pointer). All "real" I/O operations then
    399  * operate on the handle rather than the original device pointer.
    400  *
    401  * \section devref Device discovery and reference counting
    402  *
    403  * Device discovery (i.e. calling libusb_get_device_list()) returns a
    404  * freshly-allocated list of devices. The list itself must be freed when
    405  * you are done with it. libusb also needs to know when it is OK to free
    406  * the contents of the list - the devices themselves.
    407  *
    408  * To handle these issues, libusb provides you with two separate items:
    409  * - A function to free the list itself
    410  * - A reference counting system for the devices inside
    411  *
    412  * New devices presented by the libusb_get_device_list() function all have a
    413  * reference count of 1. You can increase and decrease reference count using
    414  * libusb_ref_device() and libusb_unref_device(). A device is destroyed when
    415  * its reference count reaches 0.
    416  *
    417  * With the above information in mind, the process of opening a device can
    418  * be viewed as follows:
    419  * -# Discover devices using libusb_get_device_list().
    420  * -# Choose the device that you want to operate, and call libusb_open().
    421  * -# Unref all devices in the discovered device list.
    422  * -# Free the discovered device list.
    423  *
    424  * The order is important - you must not unreference the device before
    425  * attempting to open it, because unreferencing it may destroy the device.
    426  *
    427  * For convenience, the libusb_free_device_list() function includes a
    428  * parameter to optionally unreference all the devices in the list before
    429  * freeing the list itself. This combines steps 3 and 4 above.
    430  *
    431  * As an implementation detail, libusb_open() actually adds a reference to
    432  * the device in question. This is because the device remains available
    433  * through the handle via libusb_get_device(). The reference is deleted during
    434  * libusb_close().
    435  */
    436 
    437 /** @defgroup misc Miscellaneous */
    438 
    439 /* we traverse usbfs without knowing how many devices we are going to find.
    440  * so we create this discovered_devs model which is similar to a linked-list
    441  * which grows when required. it can be freed once discovery has completed,
    442  * eliminating the need for a list node in the libusb_device structure
    443  * itself. */
    444 #define DISCOVERED_DEVICES_SIZE_STEP 8
    445 
    446 static struct discovered_devs *discovered_devs_alloc(void)
    447 {
    448 	struct discovered_devs *ret =
    449 		malloc(sizeof(*ret) + (sizeof(void *) * DISCOVERED_DEVICES_SIZE_STEP));
    450 
    451 	if (ret) {
    452 		ret->len = 0;
    453 		ret->capacity = DISCOVERED_DEVICES_SIZE_STEP;
    454 	}
    455 	return ret;
    456 }
    457 
    458 /* append a device to the discovered devices collection. may realloc itself,
    459  * returning new discdevs. returns NULL on realloc failure. */
    460 struct discovered_devs *discovered_devs_append(
    461 	struct discovered_devs *discdevs, struct libusb_device *dev)
    462 {
    463 	size_t len = discdevs->len;
    464 	size_t capacity;
    465 
    466 	/* if there is space, just append the device */
    467 	if (len < discdevs->capacity) {
    468 		discdevs->devices[len] = libusb_ref_device(dev);
    469 		discdevs->len++;
    470 		return discdevs;
    471 	}
    472 
    473 	/* exceeded capacity, need to grow */
    474 	usbi_dbg("need to increase capacity");
    475 	capacity = discdevs->capacity + DISCOVERED_DEVICES_SIZE_STEP;
    476 	discdevs = realloc(discdevs,
    477 		sizeof(*discdevs) + (sizeof(void *) * capacity));
    478 	if (discdevs) {
    479 		discdevs->capacity = capacity;
    480 		discdevs->devices[len] = libusb_ref_device(dev);
    481 		discdevs->len++;
    482 	}
    483 
    484 	return discdevs;
    485 }
    486 
    487 static void discovered_devs_free(struct discovered_devs *discdevs)
    488 {
    489 	size_t i;
    490 
    491 	for (i = 0; i < discdevs->len; i++)
    492 		libusb_unref_device(discdevs->devices[i]);
    493 
    494 	free(discdevs);
    495 }
    496 
    497 /* Allocate a new device with a specific session ID. The returned device has
    498  * a reference count of 1. */
    499 struct libusb_device *usbi_alloc_device(struct libusb_context *ctx,
    500 	unsigned long session_id)
    501 {
    502 	size_t priv_size = usbi_backend->device_priv_size;
    503 	struct libusb_device *dev = malloc(sizeof(*dev) + priv_size);
    504 	int r;
    505 
    506 	if (!dev)
    507 		return NULL;
    508 
    509 	r = pthread_mutex_init(&dev->lock, NULL);
    510 	if (r)
    511 		return NULL;
    512 
    513 	dev->ctx = ctx;
    514 	dev->refcnt = 1;
    515 	dev->session_data = session_id;
    516 	memset(&dev->os_priv, 0, priv_size);
    517 
    518 	pthread_mutex_lock(&ctx->usb_devs_lock);
    519 	list_add(&dev->list, &ctx->usb_devs);
    520 	pthread_mutex_unlock(&ctx->usb_devs_lock);
    521 	return dev;
    522 }
    523 
    524 /* Perform some final sanity checks on a newly discovered device. If this
    525  * function fails (negative return code), the device should not be added
    526  * to the discovered device list. */
    527 int usbi_sanitize_device(struct libusb_device *dev)
    528 {
    529 	int r;
    530 	unsigned char raw_desc[DEVICE_DESC_LENGTH];
    531 	uint8_t num_configurations;
    532 	int host_endian;
    533 
    534 	r = usbi_backend->get_device_descriptor(dev, raw_desc, &host_endian);
    535 	if (r < 0)
    536 		return r;
    537 
    538 	num_configurations = raw_desc[DEVICE_DESC_LENGTH - 1];
    539 	if (num_configurations > USB_MAXCONFIG) {
    540 		usbi_err(DEVICE_CTX(dev), "too many configurations");
    541 		return LIBUSB_ERROR_IO;
    542 	} else if (num_configurations < 1) {
    543 		usbi_dbg("no configurations?");
    544 		return LIBUSB_ERROR_IO;
    545 	}
    546 
    547 	dev->num_configurations = num_configurations;
    548 	return 0;
    549 }
    550 
    551 /* Examine libusb's internal list of known devices, looking for one with
    552  * a specific session ID. Returns the matching device if it was found, and
    553  * NULL otherwise. */
    554 struct libusb_device *usbi_get_device_by_session_id(struct libusb_context *ctx,
    555 	unsigned long session_id)
    556 {
    557 	struct libusb_device *dev;
    558 	struct libusb_device *ret = NULL;
    559 
    560 	pthread_mutex_lock(&ctx->usb_devs_lock);
    561 	list_for_each_entry(dev, &ctx->usb_devs, list)
    562 		if (dev->session_data == session_id) {
    563 			ret = dev;
    564 			break;
    565 		}
    566 	pthread_mutex_unlock(&ctx->usb_devs_lock);
    567 
    568 	return ret;
    569 }
    570 
    571 /** @ingroup dev
    572  * Returns a list of USB devices currently attached to the system. This is
    573  * your entry point into finding a USB device to operate.
    574  *
    575  * You are expected to unreference all the devices when you are done with
    576  * them, and then free the list with libusb_free_device_list(). Note that
    577  * libusb_free_device_list() can unref all the devices for you. Be careful
    578  * not to unreference a device you are about to open until after you have
    579  * opened it.
    580  *
    581  * This return value of this function indicates the number of devices in
    582  * the resultant list. The list is actually one element larger, as it is
    583  * NULL-terminated.
    584  *
    585  * \param ctx the context to operate on, or NULL for the default context
    586  * \param list output location for a list of devices. Must be later freed with
    587  * libusb_free_device_list().
    588  * \returns the number of devices in the outputted list, or LIBUSB_ERROR_NO_MEM
    589  * on memory allocation failure.
    590  */
    591 API_EXPORTED ssize_t libusb_get_device_list(libusb_context *ctx,
    592 	libusb_device ***list)
    593 {
    594 	struct discovered_devs *discdevs = discovered_devs_alloc();
    595 	struct libusb_device **ret;
    596 	int r = 0;
    597 	size_t i;
    598 	ssize_t len;
    599 	USBI_GET_CONTEXT(ctx);
    600 	usbi_dbg("");
    601 
    602 	if (!discdevs)
    603 		return LIBUSB_ERROR_NO_MEM;
    604 
    605 	r = usbi_backend->get_device_list(ctx, &discdevs);
    606 	if (r < 0) {
    607 		len = r;
    608 		goto out;
    609 	}
    610 
    611 	/* convert discovered_devs into a list */
    612 	len = discdevs->len;
    613 	ret = malloc(sizeof(void *) * (len + 1));
    614 	if (!ret) {
    615 		len = LIBUSB_ERROR_NO_MEM;
    616 		goto out;
    617 	}
    618 
    619 	ret[len] = NULL;
    620 	for (i = 0; i < len; i++) {
    621 		struct libusb_device *dev = discdevs->devices[i];
    622 		ret[i] = libusb_ref_device(dev);
    623 	}
    624 	*list = ret;
    625 
    626 out:
    627 	discovered_devs_free(discdevs);
    628 	return len;
    629 }
    630 
    631 /** \ingroup dev
    632  * Frees a list of devices previously discovered using
    633  * libusb_get_device_list(). If the unref_devices parameter is set, the
    634  * reference count of each device in the list is decremented by 1.
    635  * \param list the list to free
    636  * \param unref_devices whether to unref the devices in the list
    637  */
    638 API_EXPORTED void libusb_free_device_list(libusb_device **list,
    639 	int unref_devices)
    640 {
    641 	if (!list)
    642 		return;
    643 
    644 	if (unref_devices) {
    645 		int i = 0;
    646 		struct libusb_device *dev;
    647 
    648 		while ((dev = list[i++]) != NULL)
    649 			libusb_unref_device(dev);
    650 	}
    651 	free(list);
    652 }
    653 
    654 /** \ingroup dev
    655  * Get the number of the bus that a device is connected to.
    656  * \param dev a device
    657  * \returns the bus number
    658  */
    659 API_EXPORTED uint8_t libusb_get_bus_number(libusb_device *dev)
    660 {
    661 	return dev->bus_number;
    662 }
    663 
    664 /** \ingroup dev
    665  * Get the address of the device on the bus it is connected to.
    666  * \param dev a device
    667  * \returns the device address
    668  */
    669 API_EXPORTED uint8_t libusb_get_device_address(libusb_device *dev)
    670 {
    671 	return dev->device_address;
    672 }
    673 
    674 static const struct libusb_endpoint_descriptor *find_endpoint(
    675 	struct libusb_config_descriptor *config, unsigned char endpoint)
    676 {
    677 	int iface_idx;
    678 	for (iface_idx = 0; iface_idx < config->bNumInterfaces; iface_idx++) {
    679 		const struct libusb_interface *iface = &config->interface[iface_idx];
    680 		int altsetting_idx;
    681 
    682 		for (altsetting_idx = 0; altsetting_idx < iface->num_altsetting;
    683 				altsetting_idx++) {
    684 			const struct libusb_interface_descriptor *altsetting
    685 				= &iface->altsetting[altsetting_idx];
    686 			int ep_idx;
    687 
    688 			for (ep_idx = 0; ep_idx < altsetting->bNumEndpoints; ep_idx++) {
    689 				const struct libusb_endpoint_descriptor *ep =
    690 					&altsetting->endpoint[ep_idx];
    691 				if (ep->bEndpointAddress == endpoint)
    692 					return ep;
    693 			}
    694 		}
    695 	}
    696 	return NULL;
    697 }
    698 
    699 /** \ingroup dev
    700  * Convenience function to retrieve the wMaxPacketSize value for a particular
    701  * endpoint in the active device configuration.
    702  *
    703  * This function was originally intended to be of assistance when setting up
    704  * isochronous transfers, but a design mistake resulted in this function
    705  * instead. It simply returns the wMaxPacketSize value without considering
    706  * its contents. If you're dealing with isochronous transfers, you probably
    707  * want libusb_get_max_iso_packet_size() instead.
    708  *
    709  * \param dev a device
    710  * \param endpoint address of the endpoint in question
    711  * \returns the wMaxPacketSize value
    712  * \returns LIBUSB_ERROR_NOT_FOUND if the endpoint does not exist
    713  * \returns LIBUSB_ERROR_OTHER on other failure
    714  */
    715 API_EXPORTED int libusb_get_max_packet_size(libusb_device *dev,
    716 	unsigned char endpoint)
    717 {
    718 	struct libusb_config_descriptor *config;
    719 	const struct libusb_endpoint_descriptor *ep;
    720 	int r;
    721 
    722 	r = libusb_get_active_config_descriptor(dev, &config);
    723 	if (r < 0) {
    724 		usbi_err(DEVICE_CTX(dev),
    725 			"could not retrieve active config descriptor");
    726 		return LIBUSB_ERROR_OTHER;
    727 	}
    728 
    729 	ep = find_endpoint(config, endpoint);
    730 	if (!ep)
    731 		return LIBUSB_ERROR_NOT_FOUND;
    732 
    733 	r = ep->wMaxPacketSize;
    734 	libusb_free_config_descriptor(config);
    735 	return r;
    736 }
    737 
    738 /** \ingroup dev
    739  * Calculate the maximum packet size which a specific endpoint is capable is
    740  * sending or receiving in the duration of 1 microframe
    741  *
    742  * Only the active configution is examined. The calculation is based on the
    743  * wMaxPacketSize field in the endpoint descriptor as described in section
    744  * 9.6.6 in the USB 2.0 specifications.
    745  *
    746  * If acting on an isochronous or interrupt endpoint, this function will
    747  * multiply the value found in bits 0:10 by the number of transactions per
    748  * microframe (determined by bits 11:12). Otherwise, this function just
    749  * returns the numeric value found in bits 0:10.
    750  *
    751  * This function is useful for setting up isochronous transfers, for example
    752  * you might pass the return value from this function to
    753  * libusb_set_iso_packet_lengths() in order to set the length field of every
    754  * isochronous packet in a transfer.
    755  *
    756  * Since v1.0.3.
    757  *
    758  * \param dev a device
    759  * \param endpoint address of the endpoint in question
    760  * \returns the maximum packet size which can be sent/received on this endpoint
    761  * \returns LIBUSB_ERROR_NOT_FOUND if the endpoint does not exist
    762  * \returns LIBUSB_ERROR_OTHER on other failure
    763  */
    764 API_EXPORTED int libusb_get_max_iso_packet_size(libusb_device *dev,
    765 	unsigned char endpoint)
    766 {
    767 	struct libusb_config_descriptor *config;
    768 	const struct libusb_endpoint_descriptor *ep;
    769 	enum libusb_transfer_type ep_type;
    770 	uint16_t val;
    771 	int r;
    772 
    773 	r = libusb_get_active_config_descriptor(dev, &config);
    774 	if (r < 0) {
    775 		usbi_err(DEVICE_CTX(dev),
    776 			"could not retrieve active config descriptor");
    777 		return LIBUSB_ERROR_OTHER;
    778 	}
    779 
    780 	ep = find_endpoint(config, endpoint);
    781 	if (!ep)
    782 		return LIBUSB_ERROR_NOT_FOUND;
    783 
    784 	val = ep->wMaxPacketSize;
    785 	ep_type = ep->bmAttributes & 0x3;
    786 	libusb_free_config_descriptor(config);
    787 
    788 	r = val & 0x07ff;
    789 	if (ep_type == LIBUSB_TRANSFER_TYPE_ISOCHRONOUS
    790 			|| ep_type == LIBUSB_TRANSFER_TYPE_INTERRUPT)
    791 		r *= (1 + ((val >> 11) & 3));
    792 	return r;
    793 }
    794 
    795 /** \ingroup dev
    796  * Increment the reference count of a device.
    797  * \param dev the device to reference
    798  * \returns the same device
    799  */
    800 API_EXPORTED libusb_device *libusb_ref_device(libusb_device *dev)
    801 {
    802 	pthread_mutex_lock(&dev->lock);
    803 	dev->refcnt++;
    804 	pthread_mutex_unlock(&dev->lock);
    805 	return dev;
    806 }
    807 
    808 /** \ingroup dev
    809  * Decrement the reference count of a device. If the decrement operation
    810  * causes the reference count to reach zero, the device shall be destroyed.
    811  * \param dev the device to unreference
    812  */
    813 API_EXPORTED void libusb_unref_device(libusb_device *dev)
    814 {
    815 	int refcnt;
    816 
    817 	if (!dev)
    818 		return;
    819 
    820 	pthread_mutex_lock(&dev->lock);
    821 	refcnt = --dev->refcnt;
    822 	pthread_mutex_unlock(&dev->lock);
    823 
    824 	if (refcnt == 0) {
    825 		usbi_dbg("destroy device %d.%d", dev->bus_number, dev->device_address);
    826 
    827 		if (usbi_backend->destroy_device)
    828 			usbi_backend->destroy_device(dev);
    829 
    830 		pthread_mutex_lock(&dev->ctx->usb_devs_lock);
    831 		list_del(&dev->list);
    832 		pthread_mutex_unlock(&dev->ctx->usb_devs_lock);
    833 
    834 		free(dev);
    835 	}
    836 }
    837 
    838 /** \ingroup dev
    839  * Open a device and obtain a device handle. A handle allows you to perform
    840  * I/O on the device in question.
    841  *
    842  * Internally, this function adds a reference to the device and makes it
    843  * available to you through libusb_get_device(). This reference is removed
    844  * during libusb_close().
    845  *
    846  * This is a non-blocking function; no requests are sent over the bus.
    847  *
    848  * \param dev the device to open
    849  * \param handle output location for the returned device handle pointer. Only
    850  * populated when the return code is 0.
    851  * \returns 0 on success
    852  * \returns LIBUSB_ERROR_NO_MEM on memory allocation failure
    853  * \returns LIBUSB_ERROR_ACCESS if the user has insufficient permissions
    854  * \returns LIBUSB_ERROR_NO_DEVICE if the device has been disconnected
    855  * \returns another LIBUSB_ERROR code on other failure
    856  */
    857 API_EXPORTED int libusb_open(libusb_device *dev, libusb_device_handle **handle)
    858 {
    859 	struct libusb_context *ctx = DEVICE_CTX(dev);
    860 	struct libusb_device_handle *_handle;
    861 	size_t priv_size = usbi_backend->device_handle_priv_size;
    862 	unsigned char dummy = 1;
    863 	int r;
    864 	usbi_dbg("open %d.%d", dev->bus_number, dev->device_address);
    865 
    866 	_handle = malloc(sizeof(*_handle) + priv_size);
    867 	if (!_handle)
    868 		return LIBUSB_ERROR_NO_MEM;
    869 
    870 	r = pthread_mutex_init(&_handle->lock, NULL);
    871 	if (r)
    872 		return LIBUSB_ERROR_OTHER;
    873 
    874 	_handle->dev = libusb_ref_device(dev);
    875 	_handle->claimed_interfaces = 0;
    876 	memset(&_handle->os_priv, 0, priv_size);
    877 
    878 	r = usbi_backend->open(_handle);
    879 	if (r < 0) {
    880 		libusb_unref_device(dev);
    881 		free(_handle);
    882 		return r;
    883 	}
    884 
    885 	pthread_mutex_lock(&ctx->open_devs_lock);
    886 	list_add(&_handle->list, &ctx->open_devs);
    887 	pthread_mutex_unlock(&ctx->open_devs_lock);
    888 	*handle = _handle;
    889 
    890 
    891 	/* At this point, we want to interrupt any existing event handlers so
    892 	 * that they realise the addition of the new device's poll fd. One
    893 	 * example when this is desirable is if the user is running a separate
    894 	 * dedicated libusb events handling thread, which is running with a long
    895 	 * or infinite timeout. We want to interrupt that iteration of the loop,
    896 	 * so that it picks up the new fd, and then continues. */
    897 
    898 	/* record that we are messing with poll fds */
    899 	pthread_mutex_lock(&ctx->pollfd_modify_lock);
    900 	ctx->pollfd_modify++;
    901 	pthread_mutex_unlock(&ctx->pollfd_modify_lock);
    902 
    903 	/* write some data on control pipe to interrupt event handlers */
    904 	r = write(ctx->ctrl_pipe[1], &dummy, sizeof(dummy));
    905 	if (r <= 0) {
    906 		usbi_warn(ctx, "internal signalling write failed");
    907 		pthread_mutex_lock(&ctx->pollfd_modify_lock);
    908 		ctx->pollfd_modify--;
    909 		pthread_mutex_unlock(&ctx->pollfd_modify_lock);
    910 		return 0;
    911 	}
    912 
    913 	/* take event handling lock */
    914 	libusb_lock_events(ctx);
    915 
    916 	/* read the dummy data */
    917 	r = read(ctx->ctrl_pipe[0], &dummy, sizeof(dummy));
    918 	if (r <= 0)
    919 		usbi_warn(ctx, "internal signalling read failed");
    920 
    921 	/* we're done with modifying poll fds */
    922 	pthread_mutex_lock(&ctx->pollfd_modify_lock);
    923 	ctx->pollfd_modify--;
    924 	pthread_mutex_unlock(&ctx->pollfd_modify_lock);
    925 
    926 	/* Release event handling lock and wake up event waiters */
    927 	libusb_unlock_events(ctx);
    928 
    929 	return 0;
    930 }
    931 
    932 /** \ingroup dev
    933  * Convenience function for finding a device with a particular
    934  * <tt>idVendor</tt>/<tt>idProduct</tt> combination. This function is intended
    935  * for those scenarios where you are using libusb to knock up a quick test
    936  * application - it allows you to avoid calling libusb_get_device_list() and
    937  * worrying about traversing/freeing the list.
    938  *
    939  * This function has limitations and is hence not intended for use in real
    940  * applications: if multiple devices have the same IDs it will only
    941  * give you the first one, etc.
    942  *
    943  * \param ctx the context to operate on, or NULL for the default context
    944  * \param vendor_id the idVendor value to search for
    945  * \param product_id the idProduct value to search for
    946  * \returns a handle for the first found device, or NULL on error or if the
    947  * device could not be found. */
    948 API_EXPORTED libusb_device_handle *libusb_open_device_with_vid_pid(
    949 	libusb_context *ctx, uint16_t vendor_id, uint16_t product_id)
    950 {
    951 	struct libusb_device **devs;
    952 	struct libusb_device *found = NULL;
    953 	struct libusb_device *dev;
    954 	struct libusb_device_handle *handle = NULL;
    955 	size_t i = 0;
    956 	int r;
    957 
    958 	if (libusb_get_device_list(ctx, &devs) < 0)
    959 		return NULL;
    960 
    961 	while ((dev = devs[i++]) != NULL) {
    962 		struct libusb_device_descriptor desc;
    963 		r = libusb_get_device_descriptor(dev, &desc);
    964 		if (r < 0)
    965 			goto out;
    966 		if (desc.idVendor == vendor_id && desc.idProduct == product_id) {
    967 			found = dev;
    968 			break;
    969 		}
    970 	}
    971 
    972 	if (found) {
    973 		r = libusb_open(found, &handle);
    974 		if (r < 0)
    975 			handle = NULL;
    976 	}
    977 
    978 out:
    979 	libusb_free_device_list(devs, 1);
    980 	return handle;
    981 }
    982 
    983 static void do_close(struct libusb_context *ctx,
    984 	struct libusb_device_handle *dev_handle)
    985 {
    986 	pthread_mutex_lock(&ctx->open_devs_lock);
    987 	list_del(&dev_handle->list);
    988 	pthread_mutex_unlock(&ctx->open_devs_lock);
    989 
    990 	usbi_backend->close(dev_handle);
    991 	libusb_unref_device(dev_handle->dev);
    992 	free(dev_handle);
    993 }
    994 
    995 /** \ingroup dev
    996  * Close a device handle. Should be called on all open handles before your
    997  * application exits.
    998  *
    999  * Internally, this function destroys the reference that was added by
   1000  * libusb_open() on the given device.
   1001  *
   1002  * This is a non-blocking function; no requests are sent over the bus.
   1003  *
   1004  * \param dev_handle the handle to close
   1005  */
   1006 API_EXPORTED void libusb_close(libusb_device_handle *dev_handle)
   1007 {
   1008 	struct libusb_context *ctx;
   1009 	unsigned char dummy = 1;
   1010 	ssize_t r;
   1011 
   1012 	if (!dev_handle)
   1013 		return;
   1014 	usbi_dbg("");
   1015 
   1016 	ctx = HANDLE_CTX(dev_handle);
   1017 
   1018 	/* Similarly to libusb_open(), we want to interrupt all event handlers
   1019 	 * at this point. More importantly, we want to perform the actual close of
   1020 	 * the device while holding the event handling lock (preventing any other
   1021 	 * thread from doing event handling) because we will be removing a file
   1022 	 * descriptor from the polling loop. */
   1023 
   1024 	/* record that we are messing with poll fds */
   1025 	pthread_mutex_lock(&ctx->pollfd_modify_lock);
   1026 	ctx->pollfd_modify++;
   1027 	pthread_mutex_unlock(&ctx->pollfd_modify_lock);
   1028 
   1029 	/* write some data on control pipe to interrupt event handlers */
   1030 	r = write(ctx->ctrl_pipe[1], &dummy, sizeof(dummy));
   1031 	if (r <= 0) {
   1032 		usbi_warn(ctx, "internal signalling write failed, closing anyway");
   1033 		do_close(ctx, dev_handle);
   1034 		pthread_mutex_lock(&ctx->pollfd_modify_lock);
   1035 		ctx->pollfd_modify--;
   1036 		pthread_mutex_unlock(&ctx->pollfd_modify_lock);
   1037 		return;
   1038 	}
   1039 
   1040 	/* take event handling lock */
   1041 	libusb_lock_events(ctx);
   1042 
   1043 	/* read the dummy data */
   1044 	r = read(ctx->ctrl_pipe[0], &dummy, sizeof(dummy));
   1045 	if (r <= 0)
   1046 		usbi_warn(ctx, "internal signalling read failed, closing anyway");
   1047 
   1048 	/* Close the device */
   1049 	do_close(ctx, dev_handle);
   1050 
   1051 	/* we're done with modifying poll fds */
   1052 	pthread_mutex_lock(&ctx->pollfd_modify_lock);
   1053 	ctx->pollfd_modify--;
   1054 	pthread_mutex_unlock(&ctx->pollfd_modify_lock);
   1055 
   1056 	/* Release event handling lock and wake up event waiters */
   1057 	libusb_unlock_events(ctx);
   1058 }
   1059 
   1060 /** \ingroup dev
   1061  * Get the underlying device for a handle. This function does not modify
   1062  * the reference count of the returned device, so do not feel compelled to
   1063  * unreference it when you are done.
   1064  * \param dev_handle a device handle
   1065  * \returns the underlying device
   1066  */
   1067 API_EXPORTED libusb_device *libusb_get_device(libusb_device_handle *dev_handle)
   1068 {
   1069 	return dev_handle->dev;
   1070 }
   1071 
   1072 /** \ingroup dev
   1073  * Determine the bConfigurationValue of the currently active configuration.
   1074  *
   1075  * You could formulate your own control request to obtain this information,
   1076  * but this function has the advantage that it may be able to retrieve the
   1077  * information from operating system caches (no I/O involved).
   1078  *
   1079  * If the OS does not cache this information, then this function will block
   1080  * while a control transfer is submitted to retrieve the information.
   1081  *
   1082  * This function will return a value of 0 in the <tt>config</tt> output
   1083  * parameter if the device is in unconfigured state.
   1084  *
   1085  * \param dev a device handle
   1086  * \param config output location for the bConfigurationValue of the active
   1087  * configuration (only valid for return code 0)
   1088  * \returns 0 on success
   1089  * \returns LIBUSB_ERROR_NO_DEVICE if the device has been disconnected
   1090  * \returns another LIBUSB_ERROR code on other failure
   1091  */
   1092 API_EXPORTED int libusb_get_configuration(libusb_device_handle *dev,
   1093 	int *config)
   1094 {
   1095 	int r = LIBUSB_ERROR_NOT_SUPPORTED;
   1096 
   1097 	usbi_dbg("");
   1098 	if (usbi_backend->get_configuration)
   1099 		r = usbi_backend->get_configuration(dev, config);
   1100 
   1101 	if (r == LIBUSB_ERROR_NOT_SUPPORTED) {
   1102 		uint8_t tmp = 0;
   1103 		usbi_dbg("falling back to control message");
   1104 		r = libusb_control_transfer(dev, LIBUSB_ENDPOINT_IN,
   1105 			LIBUSB_REQUEST_GET_CONFIGURATION, 0, 0, &tmp, 1, 1000);
   1106 		if (r == 0) {
   1107 			usbi_err(HANDLE_CTX(dev), "zero bytes returned in ctrl transfer?");
   1108 			r = LIBUSB_ERROR_IO;
   1109 		} else if (r == 1) {
   1110 			r = 0;
   1111 			*config = tmp;
   1112 		} else {
   1113 			usbi_dbg("control failed, error %d", r);
   1114 		}
   1115 	}
   1116 
   1117 	if (r == 0)
   1118 		usbi_dbg("active config %d", *config);
   1119 
   1120 	return r;
   1121 }
   1122 
   1123 /** \ingroup dev
   1124  * Set the active configuration for a device.
   1125  *
   1126  * The operating system may or may not have already set an active
   1127  * configuration on the device. It is up to your application to ensure the
   1128  * correct configuration is selected before you attempt to claim interfaces
   1129  * and perform other operations.
   1130  *
   1131  * If you call this function on a device already configured with the selected
   1132  * configuration, then this function will act as a lightweight device reset:
   1133  * it will issue a SET_CONFIGURATION request using the current configuration,
   1134  * causing most USB-related device state to be reset (altsetting reset to zero,
   1135  * endpoint halts cleared, toggles reset).
   1136  *
   1137  * You cannot change/reset configuration if your application has claimed
   1138  * interfaces - you should free them with libusb_release_interface() first.
   1139  * You cannot change/reset configuration if other applications or drivers have
   1140  * claimed interfaces.
   1141  *
   1142  * A configuration value of -1 will put the device in unconfigured state.
   1143  * The USB specifications state that a configuration value of 0 does this,
   1144  * however buggy devices exist which actually have a configuration 0.
   1145  *
   1146  * You should always use this function rather than formulating your own
   1147  * SET_CONFIGURATION control request. This is because the underlying operating
   1148  * system needs to know when such changes happen.
   1149  *
   1150  * This is a blocking function.
   1151  *
   1152  * \param dev a device handle
   1153  * \param configuration the bConfigurationValue of the configuration you
   1154  * wish to activate, or -1 if you wish to put the device in unconfigured state
   1155  * \returns 0 on success
   1156  * \returns LIBUSB_ERROR_NOT_FOUND if the requested configuration does not exist
   1157  * \returns LIBUSB_ERROR_BUSY if interfaces are currently claimed
   1158  * \returns LIBUSB_ERROR_NO_DEVICE if the device has been disconnected
   1159  * \returns another LIBUSB_ERROR code on other failure
   1160  */
   1161 API_EXPORTED int libusb_set_configuration(libusb_device_handle *dev,
   1162 	int configuration)
   1163 {
   1164 	usbi_dbg("configuration %d", configuration);
   1165 	return usbi_backend->set_configuration(dev, configuration);
   1166 }
   1167 
   1168 /** \ingroup dev
   1169  * Claim an interface on a given device handle. You must claim the interface
   1170  * you wish to use before you can perform I/O on any of its endpoints.
   1171  *
   1172  * It is legal to attempt to claim an already-claimed interface, in which
   1173  * case libusb just returns 0 without doing anything.
   1174  *
   1175  * Claiming of interfaces is a purely logical operation; it does not cause
   1176  * any requests to be sent over the bus. Interface claiming is used to
   1177  * instruct the underlying operating system that your application wishes
   1178  * to take ownership of the interface.
   1179  *
   1180  * This is a non-blocking function.
   1181  *
   1182  * \param dev a device handle
   1183  * \param interface_number the <tt>bInterfaceNumber</tt> of the interface you
   1184  * wish to claim
   1185  * \returns 0 on success
   1186  * \returns LIBUSB_ERROR_NOT_FOUND if the requested interface does not exist
   1187  * \returns LIBUSB_ERROR_BUSY if another program or driver has claimed the
   1188  * interface
   1189  * \returns LIBUSB_ERROR_NO_DEVICE if the device has been disconnected
   1190  * \returns a LIBUSB_ERROR code on other failure
   1191  */
   1192 API_EXPORTED int libusb_claim_interface(libusb_device_handle *dev,
   1193 	int interface_number)
   1194 {
   1195 	int r = 0;
   1196 
   1197 	usbi_dbg("interface %d", interface_number);
   1198 	if (interface_number >= sizeof(dev->claimed_interfaces) * 8)
   1199 		return LIBUSB_ERROR_INVALID_PARAM;
   1200 
   1201 	pthread_mutex_lock(&dev->lock);
   1202 	if (dev->claimed_interfaces & (1 << interface_number))
   1203 		goto out;
   1204 
   1205 	r = usbi_backend->claim_interface(dev, interface_number);
   1206 	if (r == 0)
   1207 		dev->claimed_interfaces |= 1 << interface_number;
   1208 
   1209 out:
   1210 	pthread_mutex_unlock(&dev->lock);
   1211 	return r;
   1212 }
   1213 
   1214 /** \ingroup dev
   1215  * Release an interface previously claimed with libusb_claim_interface(). You
   1216  * should release all claimed interfaces before closing a device handle.
   1217  *
   1218  * This is a blocking function. A SET_INTERFACE control request will be sent
   1219  * to the device, resetting interface state to the first alternate setting.
   1220  *
   1221  * \param dev a device handle
   1222  * \param interface_number the <tt>bInterfaceNumber</tt> of the
   1223  * previously-claimed interface
   1224  * \returns 0 on success
   1225  * \returns LIBUSB_ERROR_NOT_FOUND if the interface was not claimed
   1226  * \returns LIBUSB_ERROR_NO_DEVICE if the device has been disconnected
   1227  * \returns another LIBUSB_ERROR code on other failure
   1228  */
   1229 API_EXPORTED int libusb_release_interface(libusb_device_handle *dev,
   1230 	int interface_number)
   1231 {
   1232 	int r;
   1233 
   1234 	usbi_dbg("interface %d", interface_number);
   1235 	if (interface_number >= sizeof(dev->claimed_interfaces) * 8)
   1236 		return LIBUSB_ERROR_INVALID_PARAM;
   1237 
   1238 	pthread_mutex_lock(&dev->lock);
   1239 	if (!(dev->claimed_interfaces & (1 << interface_number))) {
   1240 		r = LIBUSB_ERROR_NOT_FOUND;
   1241 		goto out;
   1242 	}
   1243 
   1244 	r = usbi_backend->release_interface(dev, interface_number);
   1245 	if (r == 0)
   1246 		dev->claimed_interfaces &= ~(1 << interface_number);
   1247 
   1248 out:
   1249 	pthread_mutex_unlock(&dev->lock);
   1250 	return r;
   1251 }
   1252 
   1253 /** \ingroup dev
   1254  * Activate an alternate setting for an interface. The interface must have
   1255  * been previously claimed with libusb_claim_interface().
   1256  *
   1257  * You should always use this function rather than formulating your own
   1258  * SET_INTERFACE control request. This is because the underlying operating
   1259  * system needs to know when such changes happen.
   1260  *
   1261  * This is a blocking function.
   1262  *
   1263  * \param dev a device handle
   1264  * \param interface_number the <tt>bInterfaceNumber</tt> of the
   1265  * previously-claimed interface
   1266  * \param alternate_setting the <tt>bAlternateSetting</tt> of the alternate
   1267  * setting to activate
   1268  * \returns 0 on success
   1269  * \returns LIBUSB_ERROR_NOT_FOUND if the interface was not claimed, or the
   1270  * requested alternate setting does not exist
   1271  * \returns LIBUSB_ERROR_NO_DEVICE if the device has been disconnected
   1272  * \returns another LIBUSB_ERROR code on other failure
   1273  */
   1274 API_EXPORTED int libusb_set_interface_alt_setting(libusb_device_handle *dev,
   1275 	int interface_number, int alternate_setting)
   1276 {
   1277 	usbi_dbg("interface %d altsetting %d",
   1278 		interface_number, alternate_setting);
   1279 	if (interface_number >= sizeof(dev->claimed_interfaces) * 8)
   1280 		return LIBUSB_ERROR_INVALID_PARAM;
   1281 
   1282 	pthread_mutex_lock(&dev->lock);
   1283 	if (!(dev->claimed_interfaces & (1 << interface_number))) {
   1284 		pthread_mutex_unlock(&dev->lock);
   1285 		return LIBUSB_ERROR_NOT_FOUND;
   1286 	}
   1287 	pthread_mutex_unlock(&dev->lock);
   1288 
   1289 	return usbi_backend->set_interface_altsetting(dev, interface_number,
   1290 		alternate_setting);
   1291 }
   1292 
   1293 /** \ingroup dev
   1294  * Clear the halt/stall condition for an endpoint. Endpoints with halt status
   1295  * are unable to receive or transmit data until the halt condition is stalled.
   1296  *
   1297  * You should cancel all pending transfers before attempting to clear the halt
   1298  * condition.
   1299  *
   1300  * This is a blocking function.
   1301  *
   1302  * \param dev a device handle
   1303  * \param endpoint the endpoint to clear halt status
   1304  * \returns 0 on success
   1305  * \returns LIBUSB_ERROR_NOT_FOUND if the endpoint does not exist
   1306  * \returns LIBUSB_ERROR_NO_DEVICE if the device has been disconnected
   1307  * \returns another LIBUSB_ERROR code on other failure
   1308  */
   1309 API_EXPORTED int libusb_clear_halt(libusb_device_handle *dev,
   1310 	unsigned char endpoint)
   1311 {
   1312 	usbi_dbg("endpoint %x", endpoint);
   1313 	return usbi_backend->clear_halt(dev, endpoint);
   1314 }
   1315 
   1316 /** \ingroup dev
   1317  * Perform a USB port reset to reinitialize a device. The system will attempt
   1318  * to restore the previous configuration and alternate settings after the
   1319  * reset has completed.
   1320  *
   1321  * If the reset fails, the descriptors change, or the previous state cannot be
   1322  * restored, the device will appear to be disconnected and reconnected. This
   1323  * means that the device handle is no longer valid (you should close it) and
   1324  * rediscover the device. A return code of LIBUSB_ERROR_NOT_FOUND indicates
   1325  * when this is the case.
   1326  *
   1327  * This is a blocking function which usually incurs a noticeable delay.
   1328  *
   1329  * \param dev a handle of the device to reset
   1330  * \returns 0 on success
   1331  * \returns LIBUSB_ERROR_NOT_FOUND if re-enumeration is required, or if the
   1332  * device has been disconnected
   1333  * \returns another LIBUSB_ERROR code on other failure
   1334  */
   1335 API_EXPORTED int libusb_reset_device(libusb_device_handle *dev)
   1336 {
   1337 	usbi_dbg("");
   1338 	return usbi_backend->reset_device(dev);
   1339 }
   1340 
   1341 /** \ingroup dev
   1342  * Determine if a kernel driver is active on an interface. If a kernel driver
   1343  * is active, you cannot claim the interface, and libusb will be unable to
   1344  * perform I/O.
   1345  *
   1346  * \param dev a device handle
   1347  * \param interface the interface to check
   1348  * \returns 0 if no kernel driver is active
   1349  * \returns 1 if a kernel driver is active
   1350  * \returns LIBUSB_ERROR_NO_DEVICE if the device has been disconnected
   1351  * \returns another LIBUSB_ERROR code on other failure
   1352  * \see libusb_detach_kernel_driver()
   1353  */
   1354 API_EXPORTED int libusb_kernel_driver_active(libusb_device_handle *dev,
   1355 	int interface)
   1356 {
   1357 	usbi_dbg("interface %d", interface);
   1358 	if (usbi_backend->kernel_driver_active)
   1359 		return usbi_backend->kernel_driver_active(dev, interface);
   1360 	else
   1361 		return LIBUSB_ERROR_NOT_SUPPORTED;
   1362 }
   1363 
   1364 /** \ingroup dev
   1365  * Detach a kernel driver from an interface. If successful, you will then be
   1366  * able to claim the interface and perform I/O.
   1367  *
   1368  * \param dev a device handle
   1369  * \param interface the interface to detach the driver from
   1370  * \returns 0 on success
   1371  * \returns LIBUSB_ERROR_NOT_FOUND if no kernel driver was active
   1372  * \returns LIBUSB_ERROR_INVALID_PARAM if the interface does not exist
   1373  * \returns LIBUSB_ERROR_NO_DEVICE if the device has been disconnected
   1374  * \returns another LIBUSB_ERROR code on other failure
   1375  * \see libusb_kernel_driver_active()
   1376  */
   1377 API_EXPORTED int libusb_detach_kernel_driver(libusb_device_handle *dev,
   1378 	int interface)
   1379 {
   1380 	usbi_dbg("interface %d", interface);
   1381 	if (usbi_backend->detach_kernel_driver)
   1382 		return usbi_backend->detach_kernel_driver(dev, interface);
   1383 	else
   1384 		return LIBUSB_ERROR_NOT_SUPPORTED;
   1385 }
   1386 
   1387 /** \ingroup dev
   1388  * Re-attach an interface's kernel driver, which was previously detached
   1389  * using libusb_detach_kernel_driver().
   1390  *
   1391  * \param dev a device handle
   1392  * \param interface the interface to attach the driver from
   1393  * \returns 0 on success
   1394  * \returns LIBUSB_ERROR_NOT_FOUND if no kernel driver was active
   1395  * \returns LIBUSB_ERROR_INVALID_PARAM if the interface does not exist
   1396  * \returns LIBUSB_ERROR_NO_DEVICE if the device has been disconnected
   1397  * \returns LIBUSB_ERROR_BUSY if the driver cannot be attached because the
   1398  * interface is claimed by a program or driver
   1399  * \returns another LIBUSB_ERROR code on other failure
   1400  * \see libusb_kernel_driver_active()
   1401  */
   1402 API_EXPORTED int libusb_attach_kernel_driver(libusb_device_handle *dev,
   1403 	int interface)
   1404 {
   1405 	usbi_dbg("interface %d", interface);
   1406 	if (usbi_backend->attach_kernel_driver)
   1407 		return usbi_backend->attach_kernel_driver(dev, interface);
   1408 	else
   1409 		return LIBUSB_ERROR_NOT_SUPPORTED;
   1410 }
   1411 
   1412 /** \ingroup lib
   1413  * Set message verbosity.
   1414  *  - Level 0: no messages ever printed by the library (default)
   1415  *  - Level 1: error messages are printed to stderr
   1416  *  - Level 2: warning and error messages are printed to stderr
   1417  *  - Level 3: informational messages are printed to stdout, warning and error
   1418  *    messages are printed to stderr
   1419  *
   1420  * The default level is 0, which means no messages are ever printed. If you
   1421  * choose to increase the message verbosity level, ensure that your
   1422  * application does not close the stdout/stderr file descriptors.
   1423  *
   1424  * You are advised to set level 3. libusb is conservative with its message
   1425  * logging and most of the time, will only log messages that explain error
   1426  * conditions and other oddities. This will help you debug your software.
   1427  *
   1428  * If the LIBUSB_DEBUG environment variable was set when libusb was
   1429  * initialized, this function does nothing: the message verbosity is fixed
   1430  * to the value in the environment variable.
   1431  *
   1432  * If libusb was compiled without any message logging, this function does
   1433  * nothing: you'll never get any messages.
   1434  *
   1435  * If libusb was compiled with verbose debug message logging, this function
   1436  * does nothing: you'll always get messages from all levels.
   1437  *
   1438  * \param ctx the context to operate on, or NULL for the default context
   1439  * \param level debug level to set
   1440  */
   1441 API_EXPORTED void libusb_set_debug(libusb_context *ctx, int level)
   1442 {
   1443 	USBI_GET_CONTEXT(ctx);
   1444 	if (!ctx->debug_fixed)
   1445 		ctx->debug = level;
   1446 }
   1447 
   1448 /** \ingroup lib
   1449  * Initialize libusb. This function must be called before calling any other
   1450  * libusb function.
   1451  * \param context Optional output location for context pointer.
   1452  * Only valid on return code 0.
   1453  * \returns 0 on success, or a LIBUSB_ERROR code on failure
   1454  */
   1455 API_EXPORTED int libusb_init(libusb_context **context)
   1456 {
   1457 	char *dbg = getenv("LIBUSB_DEBUG");
   1458 	struct libusb_context *ctx = malloc(sizeof(*ctx));
   1459 	int r;
   1460 
   1461 	if (!ctx)
   1462 		return LIBUSB_ERROR_NO_MEM;
   1463 	memset(ctx, 0, sizeof(*ctx));
   1464 
   1465 	if (dbg) {
   1466 		ctx->debug = atoi(dbg);
   1467 		if (ctx->debug)
   1468 			ctx->debug_fixed = 1;
   1469 	}
   1470 
   1471 	usbi_dbg("");
   1472 
   1473 	if (usbi_backend->init) {
   1474 		r = usbi_backend->init(ctx);
   1475 		if (r)
   1476 			goto err;
   1477 	}
   1478 
   1479 	pthread_mutex_init(&ctx->usb_devs_lock, NULL);
   1480 	pthread_mutex_init(&ctx->open_devs_lock, NULL);
   1481 	list_init(&ctx->usb_devs);
   1482 	list_init(&ctx->open_devs);
   1483 
   1484 	r = usbi_io_init(ctx);
   1485 	if (r < 0) {
   1486 		if (usbi_backend->exit)
   1487 			usbi_backend->exit();
   1488 		goto err;
   1489 	}
   1490 
   1491 	pthread_mutex_lock(&default_context_lock);
   1492 	if (!usbi_default_context) {
   1493 		usbi_dbg("created default context");
   1494 		usbi_default_context = ctx;
   1495 	}
   1496 	pthread_mutex_unlock(&default_context_lock);
   1497 
   1498 	if (context)
   1499 		*context = ctx;
   1500 	return 0;
   1501 
   1502 err:
   1503 	free(ctx);
   1504 	return r;
   1505 }
   1506 
   1507 /** \ingroup lib
   1508  * Deinitialize libusb. Should be called after closing all open devices and
   1509  * before your application terminates.
   1510  * \param ctx the context to deinitialize, or NULL for the default context
   1511  */
   1512 API_EXPORTED void libusb_exit(struct libusb_context *ctx)
   1513 {
   1514 	USBI_GET_CONTEXT(ctx);
   1515 	usbi_dbg("");
   1516 
   1517 	/* a little sanity check. doesn't bother with open_devs locking because
   1518 	 * unless there is an application bug, nobody will be accessing this. */
   1519 	if (!list_empty(&ctx->open_devs))
   1520 		usbi_warn(ctx, "application left some devices open");
   1521 
   1522 	usbi_io_exit(ctx);
   1523 	if (usbi_backend->exit)
   1524 		usbi_backend->exit();
   1525 
   1526 	pthread_mutex_lock(&default_context_lock);
   1527 	if (ctx == usbi_default_context) {
   1528 		usbi_dbg("freeing default context");
   1529 		usbi_default_context = NULL;
   1530 	}
   1531 	pthread_mutex_unlock(&default_context_lock);
   1532 
   1533 	free(ctx);
   1534 }
   1535 
   1536 void usbi_log(struct libusb_context *ctx, enum usbi_log_level level,
   1537 	const char *function, const char *format, ...)
   1538 {
   1539 	va_list args;
   1540 	FILE *stream = stdout;
   1541 	const char *prefix;
   1542 
   1543 #ifndef ENABLE_DEBUG_LOGGING
   1544 	USBI_GET_CONTEXT(ctx);
   1545 	if (!ctx->debug)
   1546 		return;
   1547 	if (level == LOG_LEVEL_WARNING && ctx->debug < 2)
   1548 		return;
   1549 	if (level == LOG_LEVEL_INFO && ctx->debug < 3)
   1550 		return;
   1551 #endif
   1552 
   1553 	switch (level) {
   1554 	case LOG_LEVEL_INFO:
   1555 		prefix = "info";
   1556 		break;
   1557 	case LOG_LEVEL_WARNING:
   1558 		stream = stderr;
   1559 		prefix = "warning";
   1560 		break;
   1561 	case LOG_LEVEL_ERROR:
   1562 		stream = stderr;
   1563 		prefix = "error";
   1564 		break;
   1565 	case LOG_LEVEL_DEBUG:
   1566 		stream = stderr;
   1567 		prefix = "debug";
   1568 		break;
   1569 	default:
   1570 		stream = stderr;
   1571 		prefix = "unknown";
   1572 		break;
   1573 	}
   1574 
   1575 	fprintf(stream, "libusb:%s [%s] ", prefix, function);
   1576 
   1577 	va_start (args, format);
   1578 	vfprintf(stream, format, args);
   1579 	va_end (args);
   1580 
   1581 	fprintf(stream, "\n");
   1582 }
   1583 
   1584