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|
/*
* windows backend for libusb 1.0
* Copyright (c) 2009-2010 Pete Batard <pbatard@gmail.com>
* With contributions from Michael Plante, Orin Eman et al.
* Parts of this code adapted from libusb-win32-v1 by Stephan Meyer
* Major code testing contribution by Xiaofan Chen
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
// COMPILATION OPTIONS:
// - Use HidD_(G/S)et(In/Out)putReport instead of (Read/Write)File for HID
// Note that http://msdn.microsoft.com/en-us/library/ms789883.aspx:
// "In addition, some devices might not support HidD_GetInputReport,
// and will become unresponsive if this routine is used."
// => Don't blame libusb if you can't read or write HID reports when the
// option below is enabled.
#define USE_HIDD_FOR_REPORTS
// - Should libusb automatically claim (and release) the interfaces it requires?
#define AUTO_CLAIM
// - Forces instant overlapped completion on timeouts: can prevents extensive
// wait in poll, after a timeout, but might affect subsequent API calls.
// ***USE AT YOUR OWN RISKS***
//#define FORCE_INSTANT_TIMEOUTS
#include <config.h>
#include <windows.h>
#include <setupapi.h>
#include <ctype.h>
#include <errno.h>
#include <fcntl.h>
#include <process.h>
#include <stdio.h>
#include <inttypes.h>
#include <objbase.h> // for string to GUID conv. requires libole32.a
#include <libusbi.h>
#include "poll_windows.h"
#include "windows_usb.h"
// The following prevents "banned API" errors when using the MS's WDK OACR/Prefast
#if defined(_PREFAST_)
#pragma warning(disable:28719)
#endif
// The 2 macros below are used in conjunction with safe loops.
#define LOOP_CHECK(fcall) { r=fcall; if (r != LIBUSB_SUCCESS) continue; }
#define LOOP_BREAK(err) { r=err; continue; }
extern void usbi_fd_notification(struct libusb_context *ctx);
// Helper prototypes
static int windows_get_active_config_descriptor(struct libusb_device *dev, unsigned char *buffer, size_t len, int *host_endian);
static int windows_clock_gettime(int clk_id, struct timespec *tp);
unsigned __stdcall windows_clock_gettime_threaded(void* param);
// WinUSB API prototypes
static int winusb_init(struct libusb_context *ctx);
static int winusb_exit(void);
static int winusb_open(struct libusb_device_handle *dev_handle);
static void winusb_close(struct libusb_device_handle *dev_handle);
static int winusb_claim_interface(struct libusb_device_handle *dev_handle, int iface);
static int winusb_release_interface(struct libusb_device_handle *dev_handle, int iface);
static int winusb_submit_control_transfer(struct usbi_transfer *itransfer);
static int winusb_set_interface_altsetting(struct libusb_device_handle *dev_handle, int iface, int altsetting);
static int winusb_submit_bulk_transfer(struct usbi_transfer *itransfer);
static int winusb_clear_halt(struct libusb_device_handle *dev_handle, unsigned char endpoint);
static int winusb_abort_transfers(struct usbi_transfer *itransfer);
static int winusb_abort_control(struct usbi_transfer *itransfer);
static int winusb_reset_device(struct libusb_device_handle *dev_handle);
static int winusb_copy_transfer_data(struct usbi_transfer *itransfer, uint32_t io_size);
// HID API prototypes
static int hid_init(struct libusb_context *ctx);
static int hid_exit(void);
static int hid_open(struct libusb_device_handle *dev_handle);
static void hid_close(struct libusb_device_handle *dev_handle);
static int hid_claim_interface(struct libusb_device_handle *dev_handle, int iface);
static int hid_release_interface(struct libusb_device_handle *dev_handle, int iface);
static int hid_set_interface_altsetting(struct libusb_device_handle *dev_handle, int iface, int altsetting);
static int hid_submit_control_transfer(struct usbi_transfer *itransfer);
static int hid_submit_bulk_transfer(struct usbi_transfer *itransfer);
static int hid_clear_halt(struct libusb_device_handle *dev_handle, unsigned char endpoint);
static int hid_abort_transfers(struct usbi_transfer *itransfer);
static int hid_reset_device(struct libusb_device_handle *dev_handle);
static int hid_copy_transfer_data(struct usbi_transfer *itransfer, uint32_t io_size);
// Composite API prototypes
static int composite_init(struct libusb_context *ctx);
static int composite_exit(void);
static int composite_open(struct libusb_device_handle *dev_handle);
static void composite_close(struct libusb_device_handle *dev_handle);
static int composite_claim_interface(struct libusb_device_handle *dev_handle, int iface);
static int composite_set_interface_altsetting(struct libusb_device_handle *dev_handle, int iface, int altsetting);
static int composite_release_interface(struct libusb_device_handle *dev_handle, int iface);
static int composite_submit_control_transfer(struct usbi_transfer *itransfer);
static int composite_submit_bulk_transfer(struct usbi_transfer *itransfer);
static int composite_submit_iso_transfer(struct usbi_transfer *itransfer);
static int composite_clear_halt(struct libusb_device_handle *dev_handle, unsigned char endpoint);
static int composite_abort_transfers(struct usbi_transfer *itransfer);
static int composite_abort_control(struct usbi_transfer *itransfer);
static int composite_reset_device(struct libusb_device_handle *dev_handle);
static int composite_copy_transfer_data(struct usbi_transfer *itransfer, uint32_t io_size);
// Workaround for MinGW-w64 multilib bug
#if defined(_MSC_VER) || defined(_WIN64)
#define INIT_INTERLOCKEDEXCHANGE
#define INIT_INTERLOCKEDINCREMENT
#define pInterlockedExchange InterlockedExchange
#define pInterlockedIncrement InterlockedIncrement
#else
static LONG (WINAPI *pInterlockedExchange)(LONG volatile *, LONG) = NULL;
#define INIT_INTERLOCKEDEXCHANGE if (pInterlockedExchange == NULL) { \
pInterlockedExchange = (LONG (WINAPI *)(LONG volatile *, LONG)) \
GetProcAddress(GetModuleHandle("KERNEL32"), "InterlockedExchange"); \
if (pInterlockedExchange == NULL) { \
usbi_err(NULL, "InterlockedExchange is unavailable"); \
return 1; \
} \
}
static LONG (WINAPI *pInterlockedIncrement)(LONG volatile *) = NULL;
#define INIT_INTERLOCKEDINCREMENT if (pInterlockedIncrement == NULL) { \
pInterlockedIncrement = (LONG (WINAPI *)(LONG volatile *)) \
GetProcAddress(GetModuleHandle("KERNEL32"), "InterlockedIncrement");\
if (pInterlockedIncrement == NULL) { \
usbi_err(NULL, "IInterlockedIncrement is unavailable"); \
return LIBUSB_ERROR_NOT_FOUND; \
} \
}
#endif
// Global variables
struct windows_hcd_priv* hcd_root = NULL;
uint64_t hires_frequency, hires_ticks_to_ps;
const uint64_t epoch_time = UINT64_C(116444736000000000); // 1970.01.01 00:00:000 in MS Filetime
enum windows_version windows_version = WINDOWS_UNSUPPORTED;
// Concurrency
static int concurrent_usage = -1;
#if defined(AUTO_CLAIM)
usbi_mutex_t autoclaim_lock;
#endif
// Timer thread
// NB: index 0 is for monotonic and 1 is for the thread exit event
HANDLE timer_thread = NULL;
HANDLE timer_mutex = NULL;
struct timespec timer_tp;
volatile LONG request_count[2] = {0, 1}; // last one must be > 0
HANDLE timer_request[2] = { NULL, NULL };
HANDLE timer_response = NULL;
// API globals
bool api_winusb_available = false;
#define CHECK_WINUSB_AVAILABLE do { if (!api_winusb_available) return LIBUSB_ERROR_ACCESS; } while (0)
bool api_hid_available = false;
#define CHECK_HID_AVAILABLE do { if (!api_hid_available) return LIBUSB_ERROR_ACCESS; } while (0)
/*
* Converts a WCHAR string to UTF8 (allocate returned string)
* Returns NULL on error
*/
static char* wchar_to_utf8(LPCWSTR wstr)
{
int size;
char* str;
// Find out the size we need to allocate for our converted string
size = wchar_to_utf8_ms(wstr, NULL, 0);
if (size <= 1) // An empty string would be size 1
return NULL;
if ((str = malloc(size)) == NULL)
return NULL;
if (wchar_to_utf8_ms(wstr, str, size) != size) {
safe_free(str);
return NULL;
}
return str;
}
static inline BOOLEAN guid_eq(const GUID *guid1, const GUID *guid2) {
if ((guid1 != NULL) && (guid2 != NULL)) {
return (memcmp(guid1, guid2, sizeof(GUID)) == 0);
}
return false;
}
#if 0
static char* guid_to_string(const GUID guid)
{
static char guid_string[MAX_GUID_STRING_LENGTH];
sprintf(guid_string, "{%08X-%04X-%04X-%02X%02X-%02X%02X%02X%02X%02X%02X}",
(unsigned int)guid.Data1, guid.Data2, guid.Data3,
guid.Data4[0], guid.Data4[1], guid.Data4[2], guid.Data4[3],
guid.Data4[4], guid.Data4[5], guid.Data4[6], guid.Data4[7]);
return guid_string;
}
#endif
/*
* Converts a windows error to human readable string
* uses retval as errorcode, or, if 0, use GetLastError()
*/
static char *windows_error_str(uint32_t retval)
{
static char err_string[ERR_BUFFER_SIZE];
DWORD size;
size_t i;
uint32_t error_code, format_error;
error_code = retval?retval:GetLastError();
safe_sprintf(err_string, ERR_BUFFER_SIZE, "[%d] ", error_code);
size = FormatMessageA(FORMAT_MESSAGE_FROM_SYSTEM, NULL, error_code,
MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT), (LPTSTR) &err_string[safe_strlen(err_string)],
ERR_BUFFER_SIZE - (DWORD)safe_strlen(err_string), NULL);
if (size == 0) {
format_error = GetLastError();
if (format_error)
safe_sprintf(err_string, ERR_BUFFER_SIZE,
"Windows error code %u (FormatMessage error code %u)", error_code, format_error);
else
safe_sprintf(err_string, ERR_BUFFER_SIZE, "Unknown error code %u", error_code);
} else {
// Remove CR/LF terminators
for (i=safe_strlen(err_string)-1; ((err_string[i]==0x0A) || (err_string[i]==0x0D)); i--) {
err_string[i] = 0;
}
}
return err_string;
}
/*
* Sanitize Microsoft's paths: convert to uppercase, add prefix and fix backslashes.
* Return an allocated sanitized string or NULL on error.
*/
static char* sanitize_path(const char* path)
{
const char root_prefix[] = "\\\\.\\";
size_t j, size, root_size;
char* ret_path = NULL;
size_t add_root = 0;
if (path == NULL)
return NULL;
size = safe_strlen(path)+1;
root_size = sizeof(root_prefix)-1;
// Microsoft indiscriminatly uses '\\?\', '\\.\', '##?#" or "##.#" for root prefixes.
if (!((size > 3) && (((path[0] == '\\') && (path[1] == '\\') && (path[3] == '\\')) ||
((path[0] == '#') && (path[1] == '#') && (path[3] == '#'))))) {
add_root = root_size;
size += add_root;
}
if ((ret_path = (char*)calloc(size, 1)) == NULL)
return NULL;
safe_strcpy(&ret_path[add_root], size-add_root, path);
// Ensure consistancy with root prefix
for (j=0; j<root_size; j++)
ret_path[j] = root_prefix[j];
// Same goes for '\' and '#' after the root prefix. Ensure '#' is used
for(j=root_size; j<size; j++) {
ret_path[j] = (char)toupper((int)ret_path[j]); // Fix case too
if (ret_path[j] == '\\')
ret_path[j] = '#';
}
return ret_path;
}
/*
* Cfgmgr32 API functions
*/
static int Cfgmgr32_init(void)
{
DLL_LOAD(Cfgmgr32.dll, CM_Get_Parent, TRUE);
DLL_LOAD(Cfgmgr32.dll, CM_Get_Child, TRUE);
DLL_LOAD(Cfgmgr32.dll, CM_Get_Sibling, TRUE);
DLL_LOAD(Cfgmgr32.dll, CM_Get_Device_IDA, TRUE);
DLL_LOAD(Cfgmgr32.dll, CM_Get_Device_IDW, TRUE);
return LIBUSB_SUCCESS;
}
/*
* enumerate interfaces for a specific GUID
*
* Parameters:
* dev_info: a pointer to a dev_info list
* dev_info_data: a pointer to an SP_DEVINFO_DATA to be filled (or NULL if not needed)
* guid: the GUID for which to retrieve interface details
* index: zero based index of the interface in the device info list
*
* Note: it is the responsibility of the caller to free the DEVICE_INTERFACE_DETAIL_DATA
* structure returned and call this function repeatedly using the same guid (with an
* incremented index starting at zero) until all interfaces have been returned.
*/
SP_DEVICE_INTERFACE_DETAIL_DATA *get_interface_details(struct libusb_context *ctx,
HDEVINFO *dev_info, SP_DEVINFO_DATA *dev_info_data, GUID guid, unsigned index)
{
SP_DEVICE_INTERFACE_DATA dev_interface_data;
SP_DEVICE_INTERFACE_DETAIL_DATA *dev_interface_details = NULL;
DWORD size;
if (index <= 0) {
*dev_info = SetupDiGetClassDevs(&guid, NULL, NULL, DIGCF_PRESENT|DIGCF_DEVICEINTERFACE);
}
if (*dev_info == INVALID_HANDLE_VALUE) {
return NULL;
}
if (dev_info_data != NULL) {
dev_info_data->cbSize = sizeof(SP_DEVINFO_DATA);
if (!SetupDiEnumDeviceInfo(*dev_info, index, dev_info_data)) {
if (GetLastError() != ERROR_NO_MORE_ITEMS) {
usbi_err(ctx, "Could not obtain device info data for index %u: %s",
index, windows_error_str(0));
}
SetupDiDestroyDeviceInfoList(*dev_info);
*dev_info = INVALID_HANDLE_VALUE;
return NULL;
}
}
dev_interface_data.cbSize = sizeof(SP_DEVICE_INTERFACE_DATA);
if (!SetupDiEnumDeviceInterfaces(*dev_info, NULL, &guid, index, &dev_interface_data)) {
if (GetLastError() != ERROR_NO_MORE_ITEMS) {
usbi_err(ctx, "Could not obtain interface data for index %u: %s",
index, windows_error_str(0));
}
SetupDiDestroyDeviceInfoList(*dev_info);
*dev_info = INVALID_HANDLE_VALUE;
return NULL;
}
// Read interface data (dummy + actual) to access the device path
if (!SetupDiGetDeviceInterfaceDetail(*dev_info, &dev_interface_data, NULL, 0, &size, NULL)) {
// The dummy call should fail with ERROR_INSUFFICIENT_BUFFER
if (GetLastError() != ERROR_INSUFFICIENT_BUFFER) {
usbi_err(ctx, "could not access interface data (dummy) for index %u: %s",
index, windows_error_str(0));
goto err_exit;
}
}
else {
usbi_err(ctx, "program assertion failed - http://msdn.microsoft.com/en-us/library/ms792901.aspx is wrong.");
goto err_exit;
}
if ((dev_interface_details = malloc(size)) == NULL) {
usbi_err(ctx, "could not allocate interface data for index %u.", index);
goto err_exit;
}
dev_interface_details->cbSize = sizeof(SP_DEVICE_INTERFACE_DETAIL_DATA);
if (!SetupDiGetDeviceInterfaceDetail(*dev_info, &dev_interface_data,
dev_interface_details, size, &size, NULL)) {
usbi_err(ctx, "could not access interface data (actual) for index %u: %s",
index, windows_error_str(0));
}
return dev_interface_details;
err_exit:
SetupDiDestroyDeviceInfoList(*dev_info);
*dev_info = INVALID_HANDLE_VALUE;
return NULL;
}
/*
* Populate the endpoints addresses of the device_priv interface helper structs
*/
static int windows_assign_endpoints(struct libusb_device *dev, int iface, int altsetting)
{
int i, r;
struct windows_device_priv *priv = __device_priv(dev);
struct libusb_config_descriptor *conf_desc;
const struct libusb_interface_descriptor *if_desc;
r = libusb_get_config_descriptor(dev, 0, &conf_desc);
if (r != LIBUSB_SUCCESS) {
usbi_warn(NULL, "could not read config descriptor: error %d", r);
return r;
}
if_desc = &conf_desc->interface[iface].altsetting[altsetting];
safe_free(priv->usb_interface[iface].endpoint);
if (if_desc->bNumEndpoints == 0) {
usbi_dbg("no endpoints found for interface %d", iface);
return LIBUSB_SUCCESS;
}
priv->usb_interface[iface].endpoint = malloc(if_desc->bNumEndpoints);
if (priv->usb_interface[iface].endpoint == NULL) {
return LIBUSB_ERROR_NO_MEM;
}
priv->usb_interface[iface].nb_endpoints = if_desc->bNumEndpoints;
for (i=0; i<if_desc->bNumEndpoints; i++) {
priv->usb_interface[iface].endpoint[i] = if_desc->endpoint[i].bEndpointAddress;
usbi_dbg("(re)assigned endpoint %02X to interface %d", priv->usb_interface[iface].endpoint[i], iface);
}
libusb_free_config_descriptor(conf_desc);
return LIBUSB_SUCCESS;
}
// Lookup for a match in the list of API driver names
bool is_api_driver(char* driver, uint8_t api)
{
uint8_t i;
const char sep_str[2] = {LIST_SEPARATOR, 0};
char *tok, *tmp_str;
size_t len = safe_strlen(driver);
if (len == 0) return false;
tmp_str = calloc(len+1, 1);
if (tmp_str == NULL) return false;
memcpy(tmp_str, driver, len+1);
tok = strtok(tmp_str, sep_str);
while (tok != NULL) {
for (i=0; i<usb_api_backend[api].nb_driver_names; i++) {
if (safe_strcmp(tok, usb_api_backend[api].driver_name_list[i]) == 0) {
free(tmp_str);
return true;
}
}
tok = strtok(NULL, sep_str);
}
free (tmp_str);
return false;
}
/*
* auto-claiming and auto-release helper functions
*/
#if defined(AUTO_CLAIM)
static int auto_claim(struct libusb_transfer *transfer, int *interface_number, int api_type)
{
struct libusb_context *ctx = DEVICE_CTX(transfer->dev_handle->dev);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(
transfer->dev_handle);
struct windows_device_priv *priv = __device_priv(transfer->dev_handle->dev);
int current_interface = *interface_number;
int r = LIBUSB_SUCCESS;
switch(api_type) {
case USB_API_WINUSB:
case USB_API_HID:
break;
default:
return LIBUSB_ERROR_INVALID_PARAM;
}
usbi_mutex_lock(&autoclaim_lock);
if (current_interface < 0) // No serviceable interface was found
{
for (current_interface=0; current_interface<USB_MAXINTERFACES; current_interface++) {
// Must claim an interface of the same API type
if ( (priv->usb_interface[current_interface].apib == &usb_api_backend[api_type])
&& (libusb_claim_interface(transfer->dev_handle, current_interface) == LIBUSB_SUCCESS) ) {
usbi_dbg("auto-claimed interface %d for control request", current_interface);
if (handle_priv->autoclaim_count[current_interface] != 0) {
usbi_warn(ctx, "program assertion failed - autoclaim_count was nonzero");
}
handle_priv->autoclaim_count[current_interface]++;
break;
}
}
if (current_interface == USB_MAXINTERFACES) {
usbi_err(ctx, "could not auto-claim any interface");
r = LIBUSB_ERROR_NOT_FOUND;
}
} else {
// If we have a valid interface that was autoclaimed, we must increment
// its autoclaim count so that we can prevent an early release.
if (handle_priv->autoclaim_count[current_interface] != 0) {
handle_priv->autoclaim_count[current_interface]++;
}
}
usbi_mutex_unlock(&autoclaim_lock);
*interface_number = current_interface;
return r;
}
static void auto_release(struct usbi_transfer *itransfer)
{
struct windows_transfer_priv *transfer_priv = usbi_transfer_get_os_priv(itransfer);
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
libusb_device_handle *dev_handle = transfer->dev_handle;
struct windows_device_handle_priv* handle_priv = __device_handle_priv(dev_handle);
int r;
usbi_mutex_lock(&autoclaim_lock);
if (handle_priv->autoclaim_count[transfer_priv->interface_number] > 0) {
handle_priv->autoclaim_count[transfer_priv->interface_number]--;
if (handle_priv->autoclaim_count[transfer_priv->interface_number] == 0) {
r = libusb_release_interface(dev_handle, transfer_priv->interface_number);
if (r == LIBUSB_SUCCESS) {
usbi_dbg("auto-released interface %d", transfer_priv->interface_number);
} else {
usbi_dbg("failed to auto-release interface %d (%s)",
transfer_priv->interface_number, libusb_strerror(r));
}
}
}
usbi_mutex_unlock(&autoclaim_lock);
}
#endif
/*
* init: libusb backend init function
*
* This function enumerates the HCDs (Host Controller Drivers) and populates our private HCD list
* In our implementation, we equate Windows' "HCD" to LibUSB's "bus". Note that bus is zero indexed.
* HCDs are not expected to change after init (might not hold true for hot pluggable USB PCI card?)
*/
static int windows_init(struct libusb_context *ctx)
{
HDEVINFO dev_info;
SP_DEVICE_INTERFACE_DETAIL_DATA *dev_interface_details = NULL;
GUID guid;
libusb_bus_t bus;
int i, r = LIBUSB_ERROR_OTHER;
OSVERSIONINFO os_version;
HANDLE semaphore;
struct windows_hcd_priv** _hcd_cur;
TCHAR sem_name[11+1+8]; // strlen(libusb_init)+'\0'+(32-bit hex PID)
sprintf(sem_name, "libusb_init%08X", (unsigned int)GetCurrentProcessId()&0xFFFFFFFF);
semaphore = CreateSemaphore(NULL, 1, 1, sem_name);
if (semaphore == NULL) {
usbi_err(ctx, "could not create semaphore: %s", windows_error_str(0));
return LIBUSB_ERROR_NO_MEM;
}
// A successful wait brings our semaphore count to 0 (unsignaled)
// => any concurent wait stalls until the semaphore's release
if (WaitForSingleObject(semaphore, INFINITE) != WAIT_OBJECT_0) {
usbi_err(ctx, "failure to access semaphore: %s", windows_error_str(0));
CloseHandle(semaphore);
return LIBUSB_ERROR_NO_MEM;
}
// NB: concurrent usage supposes that init calls are equally balanced with
// exit calls. If init is called more than exit, we will not exit properly
if ( ++concurrent_usage == 0 ) { // First init?
_hcd_cur = &hcd_root;
// Detect OS version
memset(&os_version, 0, sizeof(OSVERSIONINFO));
os_version.dwOSVersionInfoSize = sizeof(OSVERSIONINFO);
windows_version = WINDOWS_UNSUPPORTED;
if ((GetVersionEx(&os_version) != 0) && (os_version.dwPlatformId == VER_PLATFORM_WIN32_NT)) {
if ((os_version.dwMajorVersion == 5) && (os_version.dwMinorVersion == 1)) {
windows_version = WINDOWS_XP;
} else if ((os_version.dwMajorVersion == 5) && (os_version.dwMinorVersion == 2)) {
windows_version = WINDOWS_2003; // also includes XP 64
} else if (os_version.dwMajorVersion >= 6) {
windows_version = WINDOWS_VISTA_AND_LATER;
}
}
if (windows_version == WINDOWS_UNSUPPORTED) {
usbi_err(ctx, "This version of Windows is NOT supported");
r = LIBUSB_ERROR_NOT_SUPPORTED;
goto init_exit;
}
#if defined(AUTO_CLAIM)
// We need a lock for proper auto-release
usbi_mutex_init(&autoclaim_lock, NULL);
#endif
// Initialize pollable file descriptors
init_polling();
// Load missing CFGMGR32.DLL imports
if (Cfgmgr32_init() != LIBUSB_SUCCESS) {
usbi_err(ctx, "could not resolve Cfgmgr32.dll functions");
return LIBUSB_ERROR_NOT_FOUND;
}
// Initialize the low level APIs (we don't care about errors at this stage)
for (i=0; i<USB_API_MAX; i++) {
usb_api_backend[i].init(ctx);
}
// Because QueryPerformanceCounter might report different values when
// running on different cores, we create a separate thread for the timer
// calls, which we glue to the first core always to prevent timing discrepancies.
r = LIBUSB_ERROR_NO_MEM;
for (i = 0; i < 2; i++) {
timer_request[i] = CreateEvent(NULL, TRUE, FALSE, NULL);
if (timer_request[i] == NULL) {
usbi_err(ctx, "could not create timer request event %d - aborting", i);
goto init_exit;
}
}
timer_response = CreateSemaphore(NULL, 0, MAX_TIMER_SEMAPHORES, NULL);
if (timer_response == NULL) {
usbi_err(ctx, "could not create timer response semaphore - aborting");
goto init_exit;
}
timer_mutex = CreateMutex(NULL, FALSE, NULL);
if (timer_mutex == NULL) {
usbi_err(ctx, "could not create timer mutex - aborting");
goto init_exit;
}
timer_thread = (HANDLE)_beginthreadex(NULL, 0, windows_clock_gettime_threaded, NULL, 0, NULL);
if (timer_thread == NULL) {
usbi_err(ctx, "Unable to create timer thread - aborting");
goto init_exit;
}
SetThreadAffinityMask(timer_thread, 0);
guid = GUID_DEVINTERFACE_USB_HOST_CONTROLLER;
r = LIBUSB_SUCCESS;
for (bus = 0; ; bus++)
{
// safe loop: free up any (unprotected) dynamic resource
// NB: this is always executed before breaking the loop
safe_free(dev_interface_details);
safe_free(*_hcd_cur);
dev_interface_details = get_interface_details(ctx, &dev_info, NULL, guid, bus);
// safe loop: end of loop condition
if ((dev_interface_details == NULL) || (r != LIBUSB_SUCCESS))
break;
// Will need to change storage and size of libusb_bus_t if this ever occurs
if (bus == LIBUSB_BUS_MAX) {
usbi_warn(ctx, "program assertion failed - found more than %d buses, skipping the rest.", LIBUSB_BUS_MAX);
continue;
}
// Allocate and init a new priv structure to hold our data
if ((*_hcd_cur = malloc(sizeof(struct windows_hcd_priv))) == NULL) {
usbi_err(ctx, "could not allocate private structure for bus %u. aborting.", bus);
LOOP_BREAK(LIBUSB_ERROR_NO_MEM);
}
windows_hcd_priv_init(*_hcd_cur);
(*_hcd_cur)->path = sanitize_path(dev_interface_details->DevicePath);
_hcd_cur = &((*_hcd_cur)->next);
}
// TODO (2nd official release): thread for hotplug (see darwin source)
}
if (hcd_root == NULL)
r = LIBUSB_ERROR_NO_DEVICE;
else
r = LIBUSB_SUCCESS;
init_exit: // Holds semaphore here.
if(!concurrent_usage && r != LIBUSB_SUCCESS) { // First init failed?
if (timer_thread) {
SetEvent(timer_request[1]); // actually the signal to quit the thread.
if (WAIT_OBJECT_0 != WaitForSingleObject(timer_thread, INFINITE)) {
usbi_warn(ctx, "could not wait for timer thread to quit");
TerminateThread(timer_thread, 1); // shouldn't happen, but we're destroying
// all objects it might have held anyway.
}
CloseHandle(timer_thread);
timer_thread = NULL;
}
for (i = 0; i < 2; i++) {
if (timer_request[i]) {
CloseHandle(timer_request[i]);
timer_request[i] = NULL;
}
}
if (timer_response) {
CloseHandle(timer_response);
timer_response = NULL;
}
if (timer_mutex) {
CloseHandle(timer_mutex);
timer_mutex = NULL;
}
}
if (r != LIBUSB_SUCCESS)
--concurrent_usage; // Not expected to call libusb_exit if we failed.
ReleaseSemaphore(semaphore, 1, NULL); // increase count back to 1
CloseHandle(semaphore);
return r;
}
/*
* Initialize device structure, including active config
*/
static int initialize_device(struct libusb_device *dev, libusb_bus_t busnum,
libusb_devaddr_t devaddr, char *path, int connection_index, uint8_t active_config,
struct libusb_device *parent_dev)
{
struct windows_device_priv *priv = __device_priv(dev);
windows_device_priv_init(priv);
dev->bus_number = busnum;
dev->device_address = devaddr;
priv->path = path;
priv->connection_index = connection_index;
priv->parent_dev = parent_dev;
priv->active_config = active_config;
if (priv->active_config != 0) {
usbi_dbg("active config: %d", priv->active_config);
} else {
// USB devices that don't have a config value are usually missing a driver
// TODO (after first official release): use this for automated driver installation
// NB: SetupDiGetDeviceRegistryProperty w/ SPDRP_INSTALL_STATE would tell us
// if the driver is properly installed, but driverless devices don't seem to
// be enumerable by SetupDi...
usbi_dbg("* This device has no driver => libusb will not be able to access it *");
}
return LIBUSB_SUCCESS;
}
/*
* HCD (root) hubs need to have their device descriptor manually populated
*
* Note that we follow the Linux convention and use the "Linux Foundation root hub"
* vendor ID as well as the product ID to indicate the hub speed
*/
static int force_hcd_device_descriptor(struct libusb_device *dev, HANDLE handle)
{
DWORD size;
USB_HUB_CAPABILITIES hub_caps;
USB_HUB_CAPABILITIES_EX hub_caps_ex;
struct windows_device_priv *priv = __device_priv(dev);
struct libusb_context *ctx = DEVICE_CTX(dev);
priv->dev_descriptor.bLength = sizeof(USB_DEVICE_DESCRIPTOR);
priv->dev_descriptor.bDescriptorType = USB_DEVICE_DESCRIPTOR_TYPE;
dev->num_configurations = priv->dev_descriptor.bNumConfigurations = 1;
// The following is used to set the VIS:PID of root HUBs similarly to what
// Linux does: 1d6b:0001 is for 1x root hubs, 1d6b:0002 for 2x
priv->dev_descriptor.idVendor = 0x1d6b; // Linux Foundation root hub
if (windows_version >= WINDOWS_VISTA_AND_LATER) {
size = sizeof(USB_HUB_CAPABILITIES_EX);
if (DeviceIoControl(handle, IOCTL_USB_GET_HUB_CAPABILITIES_EX, &hub_caps_ex,
size, &hub_caps_ex, size, &size, NULL)) {
// Sanity check. HCD hub should always be root
if (!hub_caps_ex.CapabilityFlags.HubIsRoot) {
usbi_warn(ctx, "program assertion failed - HCD hub is not reported as root hub.");
}
priv->dev_descriptor.idProduct = hub_caps_ex.CapabilityFlags.HubIsHighSpeedCapable?2:1;
}
} else {
size = sizeof(USB_HUB_CAPABILITIES);
if (!DeviceIoControl(handle, IOCTL_USB_GET_HUB_CAPABILITIES, &hub_caps,
size, &hub_caps, size, &size, NULL)) {
usbi_warn(ctx, "could not read hub capabilities (std) for hub %s: %s",
priv->path, windows_error_str(0));
priv->dev_descriptor.idProduct = 1; // Indicate 1x speed
} else {
priv->dev_descriptor.idProduct = hub_caps.HubIs2xCapable?2:1;
}
}
return LIBUSB_SUCCESS;
}
/*
* fetch and cache all the config descriptors through I/O
*/
static int cache_config_descriptors(struct libusb_device *dev, HANDLE hub_handle)
{
DWORD size, ret_size;
struct libusb_context *ctx = DEVICE_CTX(dev);
struct windows_device_priv *priv = __device_priv(dev);
int r;
uint8_t i;
USB_CONFIGURATION_DESCRIPTOR_SHORT cd_buf_short; // dummy request
PUSB_DESCRIPTOR_REQUEST cd_buf_actual = NULL; // actual request
PUSB_CONFIGURATION_DESCRIPTOR cd_data = NULL;
if (dev->num_configurations == 0)
return LIBUSB_ERROR_INVALID_PARAM;
priv->config_descriptor = malloc(dev->num_configurations * sizeof(PUSB_CONFIGURATION_DESCRIPTOR));
if (priv->config_descriptor == NULL)
return LIBUSB_ERROR_NO_MEM;
for (i=0; i<dev->num_configurations; i++)
priv->config_descriptor[i] = NULL;
for (i=0, r=LIBUSB_SUCCESS; ; i++)
{
// safe loop: release all dynamic resources
safe_free(cd_buf_actual);
// safe loop: end of loop condition
if ((i >= dev->num_configurations) || (r != LIBUSB_SUCCESS))
break;
size = sizeof(USB_CONFIGURATION_DESCRIPTOR_SHORT);
memset(&cd_buf_short, 0, size);
cd_buf_short.req.ConnectionIndex = priv->connection_index;
cd_buf_short.req.SetupPacket.bmRequest = LIBUSB_ENDPOINT_IN;
cd_buf_short.req.SetupPacket.bRequest = USB_REQUEST_GET_DESCRIPTOR;
cd_buf_short.req.SetupPacket.wValue = (USB_CONFIGURATION_DESCRIPTOR_TYPE << 8) | i;
cd_buf_short.req.SetupPacket.wIndex = i;
cd_buf_short.req.SetupPacket.wLength = (USHORT)(size - sizeof(USB_DESCRIPTOR_REQUEST));
// Dummy call to get the required data size
if (!DeviceIoControl(hub_handle, IOCTL_USB_GET_DESCRIPTOR_FROM_NODE_CONNECTION, &cd_buf_short, size,
&cd_buf_short, size, &ret_size, NULL)) {
usbi_err(ctx, "could not access configuration descriptor (dummy): %s", windows_error_str(0));
LOOP_BREAK(LIBUSB_ERROR_IO);
}
if ((ret_size != size) || (cd_buf_short.data.wTotalLength < sizeof(USB_CONFIGURATION_DESCRIPTOR))) {
usbi_err(ctx, "unexpected configuration descriptor size (dummy).");
LOOP_BREAK(LIBUSB_ERROR_IO);
}
size = sizeof(USB_DESCRIPTOR_REQUEST) + cd_buf_short.data.wTotalLength;
if ((cd_buf_actual = (PUSB_DESCRIPTOR_REQUEST)malloc(size)) == NULL) {
usbi_err(ctx, "could not allocate configuration descriptor buffer. aborting.");
LOOP_BREAK(LIBUSB_ERROR_NO_MEM);
}
memset(cd_buf_actual, 0, size);
// Actual call
cd_buf_actual->ConnectionIndex = priv->connection_index;
cd_buf_actual->SetupPacket.bmRequest = LIBUSB_ENDPOINT_IN;
cd_buf_actual->SetupPacket.bRequest = USB_REQUEST_GET_DESCRIPTOR;
cd_buf_actual->SetupPacket.wValue = (USB_CONFIGURATION_DESCRIPTOR_TYPE << 8) | i;
cd_buf_actual->SetupPacket.wIndex = i;
cd_buf_actual->SetupPacket.wLength = (USHORT)(size - sizeof(USB_DESCRIPTOR_REQUEST));
if (!DeviceIoControl(hub_handle, IOCTL_USB_GET_DESCRIPTOR_FROM_NODE_CONNECTION, cd_buf_actual, size,
cd_buf_actual, size, &ret_size, NULL)) {
usbi_err(ctx, "could not access configuration descriptor (actual): %s", windows_error_str(0));
LOOP_BREAK(LIBUSB_ERROR_IO);
}
cd_data = (PUSB_CONFIGURATION_DESCRIPTOR)((UCHAR*)cd_buf_actual+sizeof(USB_DESCRIPTOR_REQUEST));
if ((size != ret_size) || (cd_data->wTotalLength != cd_buf_short.data.wTotalLength)) {
usbi_err(ctx, "unexpected configuration descriptor size (actual).");
LOOP_BREAK(LIBUSB_ERROR_IO);
}
if (cd_data->bDescriptorType != USB_CONFIGURATION_DESCRIPTOR_TYPE) {
usbi_err(ctx, "not a configuration descriptor");
LOOP_BREAK(LIBUSB_ERROR_IO);
}
usbi_dbg("cached config descriptor %d (bConfigurationValue=%d, %d bytes)",
i, cd_data->bConfigurationValue, cd_data->wTotalLength);
// Cache the descriptor
priv->config_descriptor[i] = malloc(cd_data->wTotalLength);
if (priv->config_descriptor[i] == NULL)
return LIBUSB_ERROR_NO_MEM;
memcpy(priv->config_descriptor[i], cd_data, cd_data->wTotalLength);
}
return LIBUSB_SUCCESS;
}
/*
* Recursively enumerates and finds all hubs & devices
*/
static int usb_enumerate_hub(struct libusb_context *ctx, struct discovered_devs **_discdevs,
HANDLE hub_handle, libusb_bus_t busnum, struct libusb_device *parent_dev, uint8_t nb_ports)
{
struct discovered_devs *discdevs = *_discdevs;
struct libusb_device *dev = NULL;
DWORD size, size_initial, size_fixed, getname_ioctl;
HANDLE handle = INVALID_HANDLE_VALUE;
USB_HUB_NAME_FIXED s_hubname;
USB_NODE_CONNECTION_INFORMATION conn_info;
USB_NODE_INFORMATION hub_node;
bool is_hcd, need_unref = false;
int i, r;
LPCWSTR wstr;
char *tmp_str = NULL, *path_str = NULL;
unsigned long session_id;
libusb_devaddr_t devaddr = 0;
struct windows_device_priv *priv, *parent_priv;
// obviously, root (HCD) hubs have no parent
is_hcd = (parent_dev == NULL);
if (is_hcd)
{
if (nb_ports != 1) {
usbi_warn(ctx, "program assertion failed - invalid number of ports for HCD.");
return LIBUSB_ERROR_INVALID_PARAM;
}
parent_priv = NULL;
size_initial = sizeof(USB_ROOT_HUB_NAME);
size_fixed = sizeof(USB_ROOT_HUB_NAME_FIXED);
getname_ioctl = IOCTL_USB_GET_ROOT_HUB_NAME;
}
else
{
parent_priv = __device_priv(parent_dev);
size_initial = sizeof(USB_NODE_CONNECTION_NAME);
size_fixed = sizeof(USB_NODE_CONNECTION_NAME_FIXED);
getname_ioctl = IOCTL_USB_GET_NODE_CONNECTION_NAME;
}
// Loop through all the ports on this hub
for (i = 1, r = LIBUSB_SUCCESS; ; i++)
{
// safe loop: release all dynamic resources
if (need_unref) {
safe_unref_device(dev);
need_unref = false;
}
safe_free(tmp_str);
safe_free(path_str);
safe_closehandle(handle);
// safe loop: end of loop condition
if ((i > nb_ports) || (r != LIBUSB_SUCCESS))
break;
memset(&conn_info, 0, sizeof(conn_info));
// For non HCDs, check if the node on this port is a hub or a regular device
if (!is_hcd) {
size = sizeof(USB_NODE_CONNECTION_INFORMATION);
conn_info.ConnectionIndex = i;
if (!DeviceIoControl(hub_handle, IOCTL_USB_GET_NODE_CONNECTION_INFORMATION, &conn_info, size,
&conn_info, size, &size, NULL)) {
usbi_warn(ctx, "could not get node connection information: %s", windows_error_str(0));
continue;
}
if (conn_info.ConnectionStatus == NoDeviceConnected) {
continue;
}
if (conn_info.DeviceAddress == LIBUSB_DEVADDR_MAX) {
usbi_warn(ctx, "program assertion failed - device address is %d "
"(conflicts with root hub), ignoring device", LIBUSB_DEVADDR_MAX);
continue;
}
s_hubname.u.node.ConnectionIndex = i; // Only used for non HCDs (s_hubname is an union)
}
else
{
// HCDs have only 1 node, and it's always a hub
conn_info.DeviceAddress = LIBUSB_DEVADDR_MAX; // using 0 can conflict with driverless devices
conn_info.DeviceIsHub = true;
conn_info.CurrentConfigurationValue = 1;
}
// If this node is a hub (HCD or not), open it
if (conn_info.DeviceIsHub) {
size = size_initial;
if (!DeviceIoControl(hub_handle, getname_ioctl, &s_hubname, size,
&s_hubname, size, &size, NULL)) {
usbi_warn(ctx, "could not get hub path (dummy): %s", windows_error_str(0));
continue;
}
size = is_hcd?s_hubname.u.root.ActualLength:s_hubname.u.node.ActualLength;
if (size > size_fixed) {
usbi_warn(ctx, "program assertion failed - hub path is too long");
continue;
}
if (!is_hcd) {
// previous call trashes some of the data
s_hubname.u.node.ConnectionIndex = i;
}
if (!DeviceIoControl(hub_handle, getname_ioctl, &s_hubname, size,
&s_hubname, size, &size, NULL)) {
usbi_warn(ctx, "could not get hub path (actual): %s", windows_error_str(0));
continue;
}
// Add prefix
wstr = is_hcd?s_hubname.u.root.RootHubName:s_hubname.u.node.NodeName;
tmp_str = wchar_to_utf8(wstr);
if (tmp_str == NULL) {
usbi_err(ctx, "could not convert hub path string.");
LOOP_BREAK(LIBUSB_ERROR_NO_MEM);
}
path_str = sanitize_path(tmp_str);
if (path_str == NULL) {
usbi_err(ctx, "could not sanitize hub path string.");
LOOP_BREAK(LIBUSB_ERROR_NO_MEM);
}
// Open Hub
handle = CreateFileA(path_str, GENERIC_WRITE, FILE_SHARE_WRITE, NULL, OPEN_EXISTING,
FILE_FLAG_OVERLAPPED, NULL);
if(handle == INVALID_HANDLE_VALUE) {
usbi_warn(ctx, "could not open hub %s: %s", path_str, windows_error_str(0));
continue;
}
}
// Generate a session ID
// Will need to change the session_id computation if this assertion fails
if (conn_info.DeviceAddress > LIBUSB_DEVADDR_MAX) {
usbi_warn(ctx, "program assertion failed - device address is greater than %d, ignoring device",
LIBUSB_DEVADDR_MAX);
continue;
} else {
devaddr = (uint8_t)conn_info.DeviceAddress;
}
// Same trick as linux for session_id, with same caveat
session_id = busnum << (sizeof(libusb_devaddr_t)*8) | devaddr;
usbi_dbg("busnum %d devaddr %d session_id %ld", busnum, devaddr, session_id);
// Allocate device if needed
dev = usbi_get_device_by_session_id(ctx, session_id);
if (dev) {
usbi_dbg("using existing device for session %ld", session_id);
priv = __device_priv(dev);
// Because we are rebuilding the list, there's no guarantee
// the parent device pointer is still the same.
// Other device data should still be reusable
priv->parent_dev = parent_dev;
} else {
usbi_dbg("allocating new device for session %ld", session_id);
if ((dev = usbi_alloc_device(ctx, session_id)) == NULL) {
LOOP_BREAK(LIBUSB_ERROR_NO_MEM);
}
need_unref = true;
LOOP_CHECK(initialize_device(dev, busnum, devaddr, path_str, i,
conn_info.CurrentConfigurationValue, parent_dev));
priv = __device_priv(dev);
path_str = NULL; // protect our path from being freed
// Setup the cached descriptors. Note that only non HCDs can fetch descriptors
if (!is_hcd) {
// The device descriptor has been read with conn_info
memcpy(&priv->dev_descriptor, &(conn_info.DeviceDescriptor), sizeof(USB_DEVICE_DESCRIPTOR));
dev->num_configurations = priv->dev_descriptor.bNumConfigurations;
// If we can't read the config descriptors, just set the number of confs to zero
if (cache_config_descriptors(dev, hub_handle) != LIBUSB_SUCCESS) {
dev->num_configurations = 0;
priv->dev_descriptor.bNumConfigurations = 0;
}
} else {
LOOP_CHECK(force_hcd_device_descriptor(dev, handle));
}
LOOP_CHECK(usbi_sanitize_device(dev));
}
discdevs = discovered_devs_append(*_discdevs, dev);
if (!discdevs) {
LOOP_BREAK(LIBUSB_ERROR_NO_MEM);
}
*_discdevs = discdevs;
// Finally, if device is a hub, recurse
if (conn_info.DeviceIsHub) {
// Find number of ports for this hub
size = sizeof(USB_NODE_INFORMATION);
if (!DeviceIoControl(handle, IOCTL_USB_GET_NODE_INFORMATION, &hub_node, size,
&hub_node, size, &size, NULL)) {
usbi_warn(ctx, "could not retreive information for hub %s: %s",
priv->path, windows_error_str(0));
continue;
}
if (hub_node.NodeType != UsbHub) {
usbi_warn(ctx, "unexpected hub type (%d) for hub %s", hub_node.NodeType, priv->path);
continue;
}
usbi_dbg("%d ports Hub: %s", hub_node.u.HubInformation.HubDescriptor.bNumberOfPorts, priv->path);
usb_enumerate_hub(ctx, _discdevs, handle, busnum, dev,
hub_node.u.HubInformation.HubDescriptor.bNumberOfPorts);
}
}
return r;
}
/*
* Composite device interfaces are not enumerated using GUID_DEVINTERFACE_USB_DEVICE,
* but instead require a different lookup mechanism
*/
static int set_composite_device(struct libusb_context *ctx, DEVINST devinst, struct windows_device_priv *priv)
{
// indexes for additional interface GUIDs, not available from "USB"
// SetupDiGetClassDevs enumeration should go here. Typically, these are
// device interfaces that begin with something else than "\\?\usb\"
enum libusb_hid_report_type {
HID_DEVICE_INTERFACE_GUID_INDEX = 0,
MAX_DEVICE_INTERFACE_GUID_INDEX = 1
};
DEVINST child_devinst, parent_devinst;
unsigned i, j, max_guids, nb_paths, interface_number;
uint8_t api;
bool found;
DWORD type, size;
CONFIGRET r;
HDEVINFO dev_info;
SP_DEVINFO_DATA dev_info_data;
SP_DEVICE_INTERFACE_DETAIL_DATA *dev_interface_details = NULL;
HKEY key;
WCHAR guid_string_w[MAX_GUID_STRING_LENGTH];
GUID guid, class_guid;
GUID guid_table[MAX_USB_DEVICES];
char* sanitized_path[MAX_USB_DEVICES];
char* hid_path[MAX_USB_DEVICES]; // An extra path is needed for HID
uint8_t api_type[MAX_USB_DEVICES];
char* sanitized_short = NULL;
char path[MAX_PATH_LENGTH];
char driver[MAX_KEY_LENGTH];
dev_info = SetupDiGetClassDevs(NULL, "USB", NULL, DIGCF_PRESENT|DIGCF_ALLCLASSES);
if (dev_info == INVALID_HANDLE_VALUE) {
return LIBUSB_ERROR_NOT_FOUND;
}
// Manually add the HID GUID as it cannot be read with DeviceInterfaceGUIDs reg key)
// NB the value returned by HidD_GetHidGuid, which is for interface class is different
// from GUID_HID, which is the device class GUID
HidD_GetHidGuid(&guid_table[HID_DEVICE_INTERFACE_GUID_INDEX]);
// NB: for other interface guids, SetupDiClassGuidsFromName can be used
max_guids = MAX_DEVICE_INTERFACE_GUID_INDEX;
// First, retrieve all the device interface GUIDs
for (i = 0; ; i++)
{
dev_info_data.cbSize = sizeof(dev_info_data);
if (!SetupDiEnumDeviceInfo(dev_info, i, &dev_info_data)) {
break;
}
key = SetupDiOpenDevRegKey(dev_info, &dev_info_data, DICS_FLAG_GLOBAL, 0, DIREG_DEV, KEY_READ);
if (key == INVALID_HANDLE_VALUE) {
usbi_dbg("could not open registry key");
continue;
}
size = sizeof(guid_string_w);
r = RegQueryValueExW(key, L"DeviceInterfaceGUIDs", NULL, &type,
(BYTE*)guid_string_w, &size);
RegCloseKey(key);
if (r != ERROR_SUCCESS) {
continue;
}
CLSIDFromString(guid_string_w, &guid);
// identical device interface GUIDs are not supposed to happen, but are a real possibility
// => check and ignore duplicates
found = false;
for (j=0; j<max_guids; j++) {
if (memcmp(&guid_table[j], &guid, sizeof(GUID)) == 0) {
found = true;
break;
}
}
if (!found) {
guid_table[max_guids++] = guid;
if (max_guids > MAX_USB_DEVICES) {
usbi_warn(ctx, "more than %d devices - ignoring the rest", MAX_USB_DEVICES);
break;
}
}
}
SetupDiDestroyDeviceInfoList(dev_info);
// Now let's find the device interface paths for all these devices
nb_paths = 0;
for (j=0; j<max_guids; j++)
{
guid = guid_table[j];
for (i = 0; ; i++)
{
safe_free(dev_interface_details);
dev_interface_details = get_interface_details(ctx, &dev_info, &dev_info_data, guid, i);
if (dev_interface_details == NULL)
break;
// HID devices (and possibly other classes) have an extra indirection
// for an USB path we can recognize
if (j == HID_DEVICE_INTERFACE_GUID_INDEX) {
if (CM_Get_Parent(&parent_devinst, dev_info_data.DevInst, 0) != CR_SUCCESS) {
usbi_warn(ctx, "could not retrieve HID parent info data for device %s, skipping: %s",
dev_interface_details->DevicePath, windows_error_str(0));
continue;
}
if (CM_Get_Device_ID(parent_devinst, path, MAX_PATH_LENGTH, 0) != CR_SUCCESS) {
usbi_warn(ctx, "could not retrieve HID parent's path for device %s, skipping: %s",
dev_interface_details->DevicePath, windows_error_str(0));
continue;
}
}
// In case we can't read the driver string through SPDRP_SERVICE (which is
// the case for HID), we need the ClassGUID for comparison.
if(!SetupDiGetDeviceRegistryPropertyW(dev_info, &dev_info_data, SPDRP_CLASSGUID,
NULL, (BYTE*)guid_string_w, sizeof(guid_string_w), &size)) {
usbi_warn(ctx, "could not read class GUID for device %s, skipping: %s",
dev_interface_details->DevicePath, windows_error_str(0));
continue;
}
CLSIDFromString(guid_string_w, &class_guid);
// Attempt to read the driver string
if(!SetupDiGetDeviceRegistryProperty(dev_info, &dev_info_data, SPDRP_SERVICE,
NULL, (BYTE*)driver, MAX_KEY_LENGTH, &size)) {
driver[0] = 0;
}
for (api=USB_API_WINUSB; api<USB_API_MAX; api++) {
if ( (is_api_driver(driver, api))
|| (guid_eq(&class_guid, usb_api_backend[api].class_guid)) ) {
api_type[nb_paths] = api;
if (j == HID_DEVICE_INTERFACE_GUID_INDEX) {
hid_path[nb_paths] = sanitize_path(path);
} else {
hid_path[nb_paths] = NULL;
}
sanitized_path[nb_paths++] = sanitize_path(dev_interface_details->DevicePath);
if (nb_paths > MAX_USB_DEVICES) {
usbi_warn(ctx, "more than %d devices - ignoring the rest", MAX_USB_DEVICES);
break;
}
}
}
}
}
// Finally, match the interface paths with the interfaces. We do that
// by looking at the children of the composite device
// NB: if the interfaces are not found in their expected position,
// claim_interface will issue a warning
found = false;
memset(&child_devinst, 0, sizeof(DEVINST)); // prevents /W4 warning
for (i = 0; i<USB_MAXINTERFACES; i++)
{
if (i == 0) {
r = CM_Get_Child(&child_devinst, devinst, 0);
} else {
r = CM_Get_Sibling(&child_devinst, child_devinst, 0);
}
if (r == CR_NO_SUCH_DEVNODE) { // end of the siblings
break;
} else if (r != CR_SUCCESS) {
usbi_dbg("unable to find interface sibling #%d, error = %X", i, r);
break;
}
r = CM_Get_Device_ID(child_devinst, path, MAX_PATH_LENGTH, 0);
if (r != CR_SUCCESS) {
usbi_err(ctx, "could not retrieve simple path for interface %d: CR error %d",
i, r);
continue;
}
sanitized_short = sanitize_path(path);
if (sanitized_short == NULL) {
usbi_err(ctx, "could not sanitize path for interface %d", i);
continue;
}
// Because MI_## are not necessarily in sequential order (some composite HID
// devices will have only MI_00 & MI_03 for instance), we retrieve the actual
// interface number from the path's MI value
interface_number = i;
for (j=0; sanitized_short[j] != 0; ) {
if ( (sanitized_short[j++] == 'M') && (sanitized_short[j++] == 'I')
&& (sanitized_short[j++] == '_') ) {
interface_number = (sanitized_short[j++] - '0')*10;
interface_number += sanitized_short[j] - '0';
break;
}
}
if (sanitized_short[j] == 0) {
usbi_warn(ctx, "failure to read interface number for %s. Using default value %d",
sanitized_short, interface_number);
}
for (j=0; j<nb_paths; j++) {
if ( (safe_strncmp(sanitized_path[j], sanitized_short, safe_strlen(sanitized_short)) == 0)
|| (safe_strcmp(hid_path[j], sanitized_short) == 0 ) ) {
// HID devices can have multiple collections (COL##) for each MI_## interface
if (priv->usb_interface[interface_number].path != NULL) {
usbi_dbg("interface_path[%d] already set - ignoring HID collection: %s",
interface_number, sanitized_path[j]);
if (api_type[j] != USB_API_HID) {
usbi_warn(ctx, "program assertion failed - not an HID collection");
}
} else {
priv->usb_interface[interface_number].path = sanitized_path[j];
priv->usb_interface[interface_number].apib = &usb_api_backend[api_type[j]];
if ((api_type[j] == USB_API_HID) && (priv->hid == NULL)) {
priv->hid = calloc(1, sizeof(struct hid_device_priv));
}
priv->composite_api_flags |= 1<<api_type[j];
sanitized_path[j] = NULL;
}
}
}
safe_free(sanitized_short);
if (priv->usb_interface[interface_number].path == NULL) {
usbi_warn(ctx, "interface_path[%d]: unhandled API - interface will be disabled",
interface_number);
continue;
}
usbi_dbg("interface_path[%d]: %s", interface_number, priv->usb_interface[interface_number].path);
found = true;
}
for (j=0; j<nb_paths; j++) {
safe_free(sanitized_path[j]);
safe_free(hid_path[j]);
}
if (found == 0) {
usbi_warn(ctx, "composite device: no interfaces were found");
return LIBUSB_ERROR_NOT_FOUND;
}
return LIBUSB_SUCCESS;
}
/*
* Likewise, HID device interfaces's path (\\.\HID\...) are not enumerated through the
* generic USB devices GUID, but are actually children of one such device
*/
static int set_hid_device(struct libusb_context *ctx, struct windows_device_priv *priv)
{
char path[MAX_PATH_LENGTH];
char *sanitized_path = NULL;
HDEVINFO dev_info;
SP_DEVICE_INTERFACE_DETAIL_DATA *dev_interface_details = NULL;
SP_DEVINFO_DATA dev_info_data;
DEVINST parent_devinst;
GUID guid;
int r = LIBUSB_SUCCESS;
unsigned i, interface_number;
interface_number = 0;
HidD_GetHidGuid(&guid);
for (i = 0; ; i++)
{
// safe loop: free up any (unprotected) dynamic resource
safe_free(dev_interface_details);
safe_free(sanitized_path);
dev_interface_details = get_interface_details(ctx, &dev_info, &dev_info_data, guid, i);
// safe loop: end of loop condition
if ( (dev_interface_details == NULL)
|| (r != LIBUSB_SUCCESS) )
break;
// Retrieve parent's path using PnP Configuration Manager (CM)
if (CM_Get_Parent(&parent_devinst, dev_info_data.DevInst, 0) != CR_SUCCESS) {
usbi_warn(ctx, "could not retrieve parent info data for device %s, skipping: %s",
dev_interface_details->DevicePath, windows_error_str(0));
continue;
}
if (CM_Get_Device_ID(parent_devinst, path, MAX_PATH_LENGTH, 0) != CR_SUCCESS) {
usbi_warn(ctx, "could not retrieve parent's path for device %s, skipping: %s",
dev_interface_details->DevicePath, windows_error_str(0));
continue;
}
// Fix parent's path inconsistencies before attempting to compare
sanitized_path = sanitize_path(path);
if (sanitized_path == NULL) {
usbi_warn(ctx, "could not sanitize parent's path for device %s, skipping.",
dev_interface_details->DevicePath);
continue;
}
// NB: we compare strings of different lengths below => strncmp
if (safe_strncmp(priv->path, sanitized_path, safe_strlen(sanitized_path)) == 0) {
priv->usb_interface[interface_number].path = sanitize_path(dev_interface_details->DevicePath);
priv->usb_interface[interface_number].apib = &usb_api_backend[USB_API_HID];
usbi_dbg("interface_path[%d]: %s", interface_number, priv->usb_interface[interface_number].path);
interface_number++;
}
}
return LIBUSB_SUCCESS;
}
/*
* This function retrieves and sets the paths of all non-hub devices
* NB: No I/O with device is required during this call
*/
static int set_device_paths(struct libusb_context *ctx, struct discovered_devs *discdevs)
{
// Precedence for filter drivers vs driver is in the order of this array
struct driver_lookup lookup[3] = {
{"\0\0", SPDRP_SERVICE, "driver"},
{"\0\0", SPDRP_UPPERFILTERS, "upper filter driver"},
{"\0\0", SPDRP_LOWERFILTERS, "lower filter driver"}
};
struct windows_device_priv *priv;
struct windows_device_priv *parent_priv;
char path[MAX_PATH_LENGTH];
char *sanitized_path = NULL;
HDEVINFO dev_info;
SP_DEVICE_INTERFACE_DETAIL_DATA *dev_interface_details = NULL;
SP_DEVINFO_DATA dev_info_data;
DEVINST parent_devinst;
GUID guid;
DWORD size, reg_type, install_state, port_nr;
int r = LIBUSB_SUCCESS;
unsigned i, j, k, l;
uint8_t api;
bool found;
// TODO (after first official release): MI_## automated driver installation
guid = GUID_DEVINTERFACE_USB_DEVICE;
for (i = 0; ; i++)
{
// safe loop: free up any (unprotected) dynamic resource
safe_free(dev_interface_details);
safe_free(sanitized_path);
dev_interface_details = get_interface_details(ctx, &dev_info, &dev_info_data, guid, i);
// safe loop: end of loop condition
if ( (dev_interface_details == NULL)
|| (r != LIBUSB_SUCCESS) )
break;
// Check that the driver installation is OK
if ( (!SetupDiGetDeviceRegistryProperty(dev_info, &dev_info_data, SPDRP_INSTALL_STATE,
®_type, (BYTE*)&install_state, 4, &size))
&& (size != 4) ){
usbi_warn(ctx, "could not detect installation state of driver for %s: %s",
dev_interface_details->DevicePath, windows_error_str(0));
} else if (install_state != 0) {
usbi_warn(ctx, "driver for device %s is reporting an issue (code: %d) - skipping",
dev_interface_details->DevicePath, install_state);
continue;
}
// The SPDRP_ADDRESS for USB devices should be the device port number on the hub
if ( (!SetupDiGetDeviceRegistryProperty(dev_info, &dev_info_data, SPDRP_ADDRESS,
®_type, (BYTE*)&port_nr, 4, &size))
&& (size != 4) ){
usbi_warn(ctx, "could not retrieve port number for device %s, skipping: %s",
dev_interface_details->DevicePath, windows_error_str(0));
continue;
}
// Retrieve parent's path using PnP Configuration Manager (CM)
if (CM_Get_Parent(&parent_devinst, dev_info_data.DevInst, 0) != CR_SUCCESS) {
usbi_warn(ctx, "could not retrieve parent info data for device %s, skipping: %s",
dev_interface_details->DevicePath, windows_error_str(0));
continue;
}
if (CM_Get_Device_ID(parent_devinst, path, MAX_PATH_LENGTH, 0) != CR_SUCCESS) {
usbi_warn(ctx, "could not retrieve parent's path for device %s, skipping: %s",
dev_interface_details->DevicePath, windows_error_str(0));
continue;
}
// Fix parent's path inconsistencies before attempting to compare
sanitized_path = sanitize_path(path);
if (sanitized_path == NULL) {
usbi_warn(ctx, "could not sanitize parent's path for device %s, skipping.",
dev_interface_details->DevicePath);
continue;
}
// With the parent path and port number, we should be able to locate our device
// by comparing these values to the ones we got when enumerating hubs
found = false;
for (j=0; j<discdevs->len; j++) {
priv = __device_priv(discdevs->devices[j]);
if (priv->parent_dev == NULL) {
continue; // ignore HCDs
}
parent_priv = __device_priv(priv->parent_dev);
// NB: we compare strings of different lengths below => strncmp
if ( (safe_strncmp(parent_priv->path, sanitized_path, safe_strlen(sanitized_path)) == 0)
&& (port_nr == priv->connection_index) ) {
priv->path = sanitize_path(dev_interface_details->DevicePath);
usbi_dbg("path (%d:%d): %s", discdevs->devices[j]->bus_number,
discdevs->devices[j]->device_address, priv->path);
// Check the service & filter names to know the API we should use
for (k=0; k<3; k++) {
if (SetupDiGetDeviceRegistryPropertyA(dev_info, &dev_info_data, lookup[k].reg_prop,
®_type, (BYTE*)lookup[k].list, MAX_KEY_LENGTH, &size)) {
// Turn the REG_SZ SPDRP_SERVICE into REG_MULTI_SZ
if (lookup[k].reg_prop == SPDRP_SERVICE) {
// our buffers are MAX_KEY_LENGTH+1 so we can overflow if needed
lookup[k].list[safe_strlen(lookup[k].list)+1] = 0;
}
// MULTI_SZ is a pain to work with. Turn it into something much more manageable
// NB: none of the driver names we check against contain LIST_SEPARATOR,
// (currently ';'), so even if an unsuported one does, it's not an issue
for (l=0; (lookup[k].list[l] != 0) || (lookup[k].list[l+1] != 0); l++) {
if (lookup[k].list[l] == 0) {
lookup[k].list[l] = LIST_SEPARATOR;
}
}
upperize(lookup[k].list);
usbi_dbg("%s(s): %s", lookup[k].designation, lookup[k].list);
found = true;
} else {
if (GetLastError() != ERROR_INVALID_DATA) {
usbi_dbg("could not access %s: %s", lookup[k].designation, windows_error_str(0));
}
lookup[k].list[0] = 0;
}
}
for (api=0; api<USB_API_MAX; api++) {
for (k=0; k<3; k++) {
if (is_api_driver(lookup[k].list, api)) {
usbi_dbg("matched %s name against %s", lookup[k].designation, usb_api_backend[api].designation);
break;
}
}
if (k >= 3) continue;
priv->apib = &usb_api_backend[api];
switch(api) {
case USB_API_COMPOSITE:
set_composite_device(ctx, dev_info_data.DevInst, priv);
break;
case USB_API_HID:
safe_free(priv->hid);
priv->hid = calloc(1, sizeof(struct hid_device_priv));
if (priv->hid == NULL) {
usbi_err(ctx, "could not allocate HID data for %s, skipping",
dev_interface_details->DevicePath);
priv->apib = &usb_api_backend[USB_API_UNSUPPORTED];
safe_free(priv->path);
} else {
set_hid_device(ctx, priv);
}
break;
default:
// For other devices, the first interface is the same as the device
priv->usb_interface[0].path = malloc(safe_strlen(priv->path)+1);
if (priv->usb_interface[0].path != NULL) {
safe_strcpy(priv->usb_interface[0].path, safe_strlen(priv->path)+1, priv->path);
}
// The following is needed if we want to API calls to work for both simple
// and composite devices, as
for(k=0; k<USB_MAXINTERFACES; k++) {
priv->usb_interface[k].apib = &usb_api_backend[api];
}
break;
}
}
break;
}
}
if (!found) {
usbi_warn(ctx, "could not match %s with a libusb device.", dev_interface_details->DevicePath);
continue;
}
}
return LIBUSB_SUCCESS;
}
/*
* get_device_list: libusb backend device enumeration function
*/
static int windows_get_device_list(struct libusb_context *ctx, struct discovered_devs **_discdevs)
{
struct windows_hcd_priv* hcd;
HANDLE handle = INVALID_HANDLE_VALUE;
int r = LIBUSB_SUCCESS;
libusb_bus_t bus;
// Use the index of the HCD in the chained list as bus #
for (hcd = hcd_root, bus = 0; ; hcd = hcd->next, bus++)
{
safe_closehandle(handle);
if ( (hcd == NULL) || (r != LIBUSB_SUCCESS) )
break;
if (bus == LIBUSB_BUS_MAX) {
usbi_warn(ctx, "program assertion failed - got more than %d buses, skipping the rest.", LIBUSB_BUS_MAX);
continue;
}
handle = CreateFileA(hcd->path, GENERIC_WRITE, FILE_SHARE_WRITE,
NULL, OPEN_EXISTING, FILE_FLAG_OVERLAPPED, NULL);
if (handle == INVALID_HANDLE_VALUE) {
usbi_warn(ctx, "could not open bus %u, skipping: %s", bus, windows_error_str(0));
continue;
}
LOOP_CHECK(usb_enumerate_hub(ctx, _discdevs, handle, bus, NULL, 1));
}
// Set the interface path for non-hubs
r = set_device_paths(ctx, *_discdevs);
return r;
}
/*
* exit: libusb backend deinitialization function
*/
static void windows_exit(void)
{
struct windows_hcd_priv* hcd_tmp;
int i;
HANDLE semaphore;
TCHAR sem_name[11+1+8]; // strlen(libusb_init)+'\0'+(32-bit hex PID)
sprintf(sem_name, "libusb_init%08X", (unsigned int)GetCurrentProcessId()&0xFFFFFFFF);
semaphore = CreateSemaphore(NULL, 1, 1, sem_name);
if (semaphore == NULL) {
return;
}
// A successful wait brings our semaphore count to 0 (unsignaled)
// => any concurent wait stalls until the semaphore release
if (WaitForSingleObject(semaphore, INFINITE) != WAIT_OBJECT_0) {
CloseHandle(semaphore);
return;
}
// Only works if exits and inits are balanced exactly
if (--concurrent_usage < 0) { // Last exit
while (hcd_root != NULL)
{
hcd_tmp = hcd_root; // Keep a copy for free
hcd_root = hcd_root->next;
windows_hcd_priv_release(hcd_tmp);
safe_free(hcd_tmp);
}
for (i=0; i<USB_API_MAX; i++) {
usb_api_backend[i].exit();
}
exit_polling();
if (timer_thread) {
SetEvent(timer_request[1]); // actually the signal to quit the thread.
if (WAIT_OBJECT_0 != WaitForSingleObject(timer_thread, INFINITE)) {
usbi_dbg("could not wait for timer thread to quit");
TerminateThread(timer_thread, 1);
}
CloseHandle(timer_thread);
timer_thread = NULL;
}
for (i = 0; i < 2; i++) {
if (timer_request[i]) {
CloseHandle(timer_request[i]);
timer_request[i] = NULL;
}
}
if (timer_response) {
CloseHandle(timer_response);
timer_response = NULL;
}
if (timer_mutex) {
CloseHandle(timer_mutex);
timer_mutex = NULL;
}
}
ReleaseSemaphore(semaphore, 1, NULL); // increase count back to 1
CloseHandle(semaphore);
}
static int windows_get_device_descriptor(struct libusb_device *dev, unsigned char *buffer, int *host_endian)
{
struct windows_device_priv *priv = __device_priv(dev);
memcpy(buffer, &(priv->dev_descriptor), DEVICE_DESC_LENGTH);
*host_endian = 0;
return LIBUSB_SUCCESS;
}
static int windows_get_config_descriptor(struct libusb_device *dev, uint8_t config_index, unsigned char *buffer, size_t len, int *host_endian)
{
struct windows_device_priv *priv = __device_priv(dev);
PUSB_CONFIGURATION_DESCRIPTOR config_header;
size_t size;
// config index is zero based
if (config_index >= dev->num_configurations)
return LIBUSB_ERROR_INVALID_PARAM;
if ((priv->config_descriptor == NULL) || (priv->config_descriptor[config_index] == NULL))
return LIBUSB_ERROR_NOT_FOUND;
config_header = (PUSB_CONFIGURATION_DESCRIPTOR)priv->config_descriptor[config_index];
size = min(config_header->wTotalLength, len);
memcpy(buffer, priv->config_descriptor[config_index], size);
return LIBUSB_SUCCESS;
}
/*
* return the cached copy of the active config descriptor
*/
static int windows_get_active_config_descriptor(struct libusb_device *dev, unsigned char *buffer, size_t len, int *host_endian)
{
struct windows_device_priv *priv = __device_priv(dev);
if (priv->active_config == 0)
return LIBUSB_ERROR_NOT_FOUND;
// config index is zero based
return windows_get_config_descriptor(dev, (uint8_t)(priv->active_config-1), buffer, len, host_endian);
}
static int windows_open(struct libusb_device_handle *dev_handle)
{
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
struct libusb_context *ctx = DEVICE_CTX(dev_handle->dev);
if (priv->apib == NULL) {
usbi_err(ctx, "program assertion failed - device is not initialized");
return LIBUSB_ERROR_NO_DEVICE;
}
return priv->apib->open(dev_handle);
}
static void windows_close(struct libusb_device_handle *dev_handle)
{
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
priv->apib->close(dev_handle);
}
static int windows_get_configuration(struct libusb_device_handle *dev_handle, int *config)
{
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
if (priv->active_config == 0) {
*config = 0;
return LIBUSB_ERROR_NOT_FOUND;
}
*config = priv->active_config;
return LIBUSB_SUCCESS;
}
/*
* from http://msdn.microsoft.com/en-us/library/ms793522.aspx: "The port driver
* does not currently expose a service that allows higher-level drivers to set
* the configuration."
*/
static int windows_set_configuration(struct libusb_device_handle *dev_handle, int config)
{
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
int r = LIBUSB_SUCCESS;
if (config >= USB_MAXCONFIG)
return LIBUSB_ERROR_INVALID_PARAM;
r = libusb_control_transfer(dev_handle, LIBUSB_ENDPOINT_OUT |
LIBUSB_REQUEST_TYPE_STANDARD | LIBUSB_RECIPIENT_DEVICE,
LIBUSB_REQUEST_SET_CONFIGURATION, (uint16_t)config,
0, NULL, 0, 1000);
if (r == LIBUSB_SUCCESS) {
priv->active_config = (uint8_t)config;
}
return r;
}
static int windows_claim_interface(struct libusb_device_handle *dev_handle, int iface)
{
int r = LIBUSB_SUCCESS;
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
if (iface >= USB_MAXINTERFACES)
return LIBUSB_ERROR_INVALID_PARAM;
safe_free(priv->usb_interface[iface].endpoint);
priv->usb_interface[iface].nb_endpoints= 0;
r = priv->apib->claim_interface(dev_handle, iface);
if (r == LIBUSB_SUCCESS) {
r = windows_assign_endpoints(dev_handle->dev, iface, 0);
}
return r;
}
static int windows_set_interface_altsetting(struct libusb_device_handle *dev_handle, int iface, int altsetting)
{
int r = LIBUSB_SUCCESS;
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
safe_free(priv->usb_interface[iface].endpoint);
priv->usb_interface[iface].nb_endpoints= 0;
r = priv->apib->set_interface_altsetting(dev_handle, iface, altsetting);
if (r == LIBUSB_SUCCESS) {
r = windows_assign_endpoints(dev_handle->dev, iface, altsetting);
}
return r;
}
static int windows_release_interface(struct libusb_device_handle *dev_handle, int iface)
{
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
windows_set_interface_altsetting(dev_handle, iface, 0);
return priv->apib->release_interface(dev_handle, iface);
}
static int windows_clear_halt(struct libusb_device_handle *dev_handle, unsigned char endpoint)
{
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
return priv->apib->clear_halt(dev_handle, endpoint);
}
static int windows_reset_device(struct libusb_device_handle *dev_handle)
{
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
return priv->apib->reset_device(dev_handle);
}
// The 3 functions below are unlikely to ever get supported on Windows
static int windows_kernel_driver_active(struct libusb_device_handle *dev_handle, int iface)
{
return LIBUSB_ERROR_NOT_SUPPORTED;
}
static int windows_attach_kernel_driver(struct libusb_device_handle *dev_handle, int iface)
{
return LIBUSB_ERROR_NOT_SUPPORTED;
}
static int windows_detach_kernel_driver(struct libusb_device_handle *dev_handle, int iface)
{
return LIBUSB_ERROR_NOT_SUPPORTED;
}
static void windows_destroy_device(struct libusb_device *dev)
{
struct windows_device_priv *priv = __device_priv(dev);
windows_device_priv_release(priv, dev->num_configurations);
}
static void windows_clear_transfer_priv(struct usbi_transfer *itransfer)
{
struct windows_transfer_priv *transfer_priv = usbi_transfer_get_os_priv(itransfer);
usbi_free_fd(transfer_priv->pollable_fd.fd);
safe_free(transfer_priv->hid_buffer);
#if defined(AUTO_CLAIM)
// When auto claim is in use, attempt to release the auto-claimed interface
auto_release(itransfer);
#endif
}
static int submit_bulk_transfer(struct usbi_transfer *itransfer)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct libusb_context *ctx = DEVICE_CTX(transfer->dev_handle->dev);
struct windows_transfer_priv *transfer_priv = usbi_transfer_get_os_priv(itransfer);
struct windows_device_priv *priv = __device_priv(transfer->dev_handle->dev);
int r;
r = priv->apib->submit_bulk_transfer(itransfer);
if (r != LIBUSB_SUCCESS) {
return r;
}
usbi_add_pollfd(ctx, transfer_priv->pollable_fd.fd,
(short)((transfer->endpoint & LIBUSB_ENDPOINT_IN)?POLLIN:POLLOUT));
#if !defined(DYNAMIC_FDS)
usbi_fd_notification(ctx);
#endif
return LIBUSB_SUCCESS;
}
static int submit_iso_transfer(struct usbi_transfer *itransfer)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct libusb_context *ctx = DEVICE_CTX(transfer->dev_handle->dev);
struct windows_transfer_priv *transfer_priv = usbi_transfer_get_os_priv(itransfer);
struct windows_device_priv *priv = __device_priv(transfer->dev_handle->dev);
int r;
r = priv->apib->submit_iso_transfer(itransfer);
if (r != LIBUSB_SUCCESS) {
return r;
}
usbi_add_pollfd(ctx, transfer_priv->pollable_fd.fd,
(short)((transfer->endpoint & LIBUSB_ENDPOINT_IN)?POLLIN:POLLOUT));
#if !defined(DYNAMIC_FDS)
usbi_fd_notification(ctx);
#endif
return LIBUSB_SUCCESS;
}
static int submit_control_transfer(struct usbi_transfer *itransfer)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct libusb_context *ctx = DEVICE_CTX(transfer->dev_handle->dev);
struct windows_transfer_priv *transfer_priv = usbi_transfer_get_os_priv(itransfer);
struct windows_device_priv *priv = __device_priv(transfer->dev_handle->dev);
int r;
r = priv->apib->submit_control_transfer(itransfer);
if (r != LIBUSB_SUCCESS) {
return r;
}
usbi_add_pollfd(ctx, transfer_priv->pollable_fd.fd, POLLIN);
#if !defined(DYNAMIC_FDS)
usbi_fd_notification(ctx);
#endif
return LIBUSB_SUCCESS;
}
static int windows_submit_transfer(struct usbi_transfer *itransfer)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
switch (transfer->type) {
case LIBUSB_TRANSFER_TYPE_CONTROL:
return submit_control_transfer(itransfer);
case LIBUSB_TRANSFER_TYPE_BULK:
case LIBUSB_TRANSFER_TYPE_INTERRUPT:
return submit_bulk_transfer(itransfer);
case LIBUSB_TRANSFER_TYPE_ISOCHRONOUS:
return submit_iso_transfer(itransfer);
default:
usbi_err(TRANSFER_CTX(transfer), "unknown endpoint type %d", transfer->type);
return LIBUSB_ERROR_INVALID_PARAM;
}
}
static int windows_abort_control(struct usbi_transfer *itransfer)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct windows_device_priv *priv = __device_priv(transfer->dev_handle->dev);
return priv->apib->abort_control(itransfer);
}
static int windows_abort_transfers(struct usbi_transfer *itransfer)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct windows_device_priv *priv = __device_priv(transfer->dev_handle->dev);
return priv->apib->abort_transfers(itransfer);
}
static int windows_cancel_transfer(struct usbi_transfer *itransfer)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
#if defined(FORCE_INSTANT_TIMEOUTS)
struct windows_transfer_priv *transfer_priv = usbi_transfer_get_os_priv(itransfer);
// Forces instant overlapped completion on timeouts - use at your own risks
if (itransfer->flags & USBI_TRANSFER_TIMED_OUT) {
transfer_priv->pollable_fd.overlapped->Internal &= ~STATUS_PENDING;
}
#endif
switch (transfer->type) {
case LIBUSB_TRANSFER_TYPE_CONTROL:
return windows_abort_control(itransfer);
case LIBUSB_TRANSFER_TYPE_BULK:
case LIBUSB_TRANSFER_TYPE_INTERRUPT:
case LIBUSB_TRANSFER_TYPE_ISOCHRONOUS:
return windows_abort_transfers(itransfer);
default:
usbi_err(ITRANSFER_CTX(itransfer), "unknown endpoint type %d", transfer->type);
return LIBUSB_ERROR_INVALID_PARAM;
}
}
static void windows_transfer_callback(struct usbi_transfer *itransfer, uint32_t io_result, uint32_t io_size)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct windows_device_priv *priv = __device_priv(transfer->dev_handle->dev);
int status;
usbi_dbg("handling I/O completion with errcode %d", io_result);
switch(io_result) {
case NO_ERROR:
status = priv->apib->copy_transfer_data(itransfer, io_size);
break;
case ERROR_GEN_FAILURE:
usbi_dbg("detected endpoint stall");
status = LIBUSB_TRANSFER_STALL;
break;
case ERROR_SEM_TIMEOUT:
usbi_dbg("detected semaphore timeout");
status = LIBUSB_TRANSFER_TIMED_OUT;
break;
case ERROR_OPERATION_ABORTED:
if (itransfer->flags & USBI_TRANSFER_TIMED_OUT) {
usbi_dbg("detected timeout");
status = LIBUSB_TRANSFER_TIMED_OUT;
} else {
usbi_dbg("detected operation aborted");
status = LIBUSB_TRANSFER_CANCELLED;
}
break;
default:
usbi_err(ITRANSFER_CTX(itransfer), "detected I/O error: %s", windows_error_str(0));
status = LIBUSB_TRANSFER_ERROR;
break;
}
windows_clear_transfer_priv(itransfer); // Cancel polling
usbi_handle_transfer_completion(itransfer, status);
}
static void windows_handle_callback (struct usbi_transfer *itransfer, uint32_t io_result, uint32_t io_size)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
switch (transfer->type) {
case LIBUSB_TRANSFER_TYPE_CONTROL:
case LIBUSB_TRANSFER_TYPE_BULK:
case LIBUSB_TRANSFER_TYPE_INTERRUPT:
case LIBUSB_TRANSFER_TYPE_ISOCHRONOUS:
windows_transfer_callback (itransfer, io_result, io_size);
break;
default:
usbi_err(ITRANSFER_CTX(itransfer), "unknown endpoint type %d", transfer->type);
}
}
static int windows_handle_events(struct libusb_context *ctx, struct pollfd *fds, nfds_t nfds, int num_ready)
{
struct windows_transfer_priv* transfer_priv = NULL;
nfds_t i = 0;
bool found = false;
struct usbi_transfer *transfer;
DWORD io_size, io_result;
usbi_mutex_lock(&ctx->open_devs_lock);
for (i = 0; i < nfds && num_ready > 0; i++) {
usbi_dbg("checking fd %d with revents = %04x", fds[i].fd, fds[i].revents);
if (!fds[i].revents) {
continue;
}
num_ready--;
// Because a Windows OVERLAPPED is used for poll emulation,
// a pollable fd is created and stored with each transfer
usbi_mutex_lock(&ctx->flying_transfers_lock);
list_for_each_entry(transfer, &ctx->flying_transfers, list, struct usbi_transfer) {
transfer_priv = usbi_transfer_get_os_priv(transfer);
if (transfer_priv->pollable_fd.fd == fds[i].fd) {
found = true;
break;
}
}
usbi_mutex_unlock(&ctx->flying_transfers_lock);
if (found) {
// Handle async requests that completed synchronously first
if (HasOverlappedIoCompletedSync(transfer_priv->pollable_fd.overlapped)) {
io_result = NO_ERROR;
io_size = (DWORD)transfer_priv->pollable_fd.overlapped->InternalHigh;
// Regular async overlapped
} else if (GetOverlappedResult(transfer_priv->pollable_fd.handle,
transfer_priv->pollable_fd.overlapped, &io_size, false)) {
io_result = NO_ERROR;
} else {
io_result = GetLastError();
}
usbi_remove_pollfd(ctx, transfer_priv->pollable_fd.fd);
// let handle_callback free the event using the transfer wfd
// If you don't use the transfer wfd, you run a risk of trying to free a
// newly allocated wfd that took the place of the one from the transfer.
windows_handle_callback(transfer, io_result, io_size);
} else {
usbi_err(ctx, "could not find a matching transfer for fd %x", fds[i]);
return LIBUSB_ERROR_NOT_FOUND;
}
}
usbi_mutex_unlock(&ctx->open_devs_lock);
return LIBUSB_SUCCESS;
}
/*
* Monotonic and real time functions
*/
unsigned __stdcall windows_clock_gettime_threaded(void* param)
{
LARGE_INTEGER hires_counter, li_frequency;
LONG nb_responses;
int timer_index;
// Init - find out if we have access to a monotonic (hires) timer
if (!QueryPerformanceFrequency(&li_frequency)) {
usbi_dbg("no hires timer available on this platform");
hires_frequency = 0;
hires_ticks_to_ps = UINT64_C(0);
} else {
hires_frequency = li_frequency.QuadPart;
// The hires frequency can go as high as 4 GHz, so we'll use a conversion
// to picoseconds to compute the tv_nsecs part in clock_gettime
hires_ticks_to_ps = UINT64_C(1000000000000) / hires_frequency;
usbi_dbg("hires timer available (Frequency: %"PRIu64" Hz)", hires_frequency);
}
// Main loop - wait for requests
while (1) {
timer_index = WaitForMultipleObjects(2, timer_request, FALSE, INFINITE) - WAIT_OBJECT_0;
if ( (timer_index != 0) && (timer_index != 1) ) {
usbi_dbg("failure to wait on requests: %s", windows_error_str(0));
continue;
}
if (request_count[timer_index] == 0) {
// Request already handled
ResetEvent(timer_request[timer_index]);
// There's still a possiblity that a thread sends a request between the
// time we test request_count[] == 0 and we reset the event, in which case
// the request would be ignored. The simple solution to that is to test
// request_count again and process requests if non zero.
if (request_count[timer_index] == 0)
continue;
}
switch (timer_index) {
case 0:
WaitForSingleObject(timer_mutex, INFINITE);
// Requests to this thread are for hires always
if (QueryPerformanceCounter(&hires_counter) != 0) {
timer_tp.tv_sec = (long)(hires_counter.QuadPart / hires_frequency);
timer_tp.tv_nsec = (long)(((hires_counter.QuadPart % hires_frequency)/1000) * hires_ticks_to_ps);
} else {
// Fallback to real-time if we can't get monotonic value
// Note that real-time clock does not wait on the mutex or this thread.
windows_clock_gettime(USBI_CLOCK_REALTIME, &timer_tp);
}
ReleaseMutex(timer_mutex);
INIT_INTERLOCKEDEXCHANGE;
nb_responses = pInterlockedExchange((LONG*)&request_count[0], 0);
if ( (nb_responses)
&& (ReleaseSemaphore(timer_response, nb_responses, NULL) == 0) ) {
usbi_dbg("unable to release timer semaphore %d: %s", windows_error_str(0));
}
continue;
case 1: // time to quit
usbi_dbg("timer thread quitting");
return 0;
}
}
usbi_dbg("ERROR: broken timer thread");
return 1;
}
static int windows_clock_gettime(int clk_id, struct timespec *tp)
{
FILETIME filetime;
ULARGE_INTEGER rtime;
DWORD r;
switch(clk_id) {
case USBI_CLOCK_MONOTONIC:
if (hires_frequency != 0) {
INIT_INTERLOCKEDINCREMENT;
while (1) {
pInterlockedIncrement((LONG*)&request_count[0]);
SetEvent(timer_request[0]);
r = WaitForSingleObject(timer_response, TIMER_REQUEST_RETRY_MS);
switch(r) {
case WAIT_OBJECT_0:
WaitForSingleObject(timer_mutex, INFINITE);
*tp = timer_tp;
ReleaseMutex(timer_mutex);
return LIBUSB_SUCCESS;
case WAIT_TIMEOUT:
usbi_dbg("could not obtain a timer value within reasonable timeframe - too much load?");
break; // Retry until successful
default:
usbi_dbg("WaitForSingleObject failed: %s", windows_error_str(0));
return LIBUSB_ERROR_OTHER;
}
}
}
// Fall through and return real-time if monotonic was not detected @ timer init
case USBI_CLOCK_REALTIME:
// We follow http://msdn.microsoft.com/en-us/library/ms724928%28VS.85%29.aspx
// with a predef epoch_time to have an epoch that starts at 1970.01.01 00:00
// Note however that our resolution is bounded by the Windows system time
// functions and is at best of the order of 1 ms (or, usually, worse)
GetSystemTimeAsFileTime(&filetime);
rtime.LowPart = filetime.dwLowDateTime;
rtime.HighPart = filetime.dwHighDateTime;
rtime.QuadPart -= epoch_time;
tp->tv_sec = (long)(rtime.QuadPart / 10000000);
tp->tv_nsec = (long)((rtime.QuadPart % 10000000)*100);
return LIBUSB_SUCCESS;
default:
return LIBUSB_ERROR_INVALID_PARAM;
}
}
// NB: MSVC6 does not support named initializers.
const struct usbi_os_backend windows_backend = {
"Windows",
windows_init,
windows_exit,
windows_get_device_list,
windows_open,
windows_close,
windows_get_device_descriptor,
windows_get_active_config_descriptor,
windows_get_config_descriptor,
windows_get_configuration,
windows_set_configuration,
windows_claim_interface,
windows_release_interface,
windows_set_interface_altsetting,
windows_clear_halt,
windows_reset_device,
windows_kernel_driver_active,
windows_detach_kernel_driver,
windows_attach_kernel_driver,
windows_destroy_device,
windows_submit_transfer,
windows_cancel_transfer,
windows_clear_transfer_priv,
windows_handle_events,
windows_clock_gettime,
#if defined(USBI_TIMERFD_AVAILABLE)
NULL,
#endif
sizeof(struct windows_device_priv),
sizeof(struct windows_device_handle_priv),
sizeof(struct windows_transfer_priv),
0,
};
/*
* USB API backends
*/
static int unsupported_init(struct libusb_context *ctx) {
return LIBUSB_SUCCESS;
}
static int unsupported_exit(void) {
return LIBUSB_SUCCESS;
}
static int unsupported_open(struct libusb_device_handle *dev_handle) {
PRINT_UNSUPPORTED_API(open);
}
static void unsupported_close(struct libusb_device_handle *dev_handle) {
usbi_dbg("unsupported API call for 'close'");
}
static int unsupported_claim_interface(struct libusb_device_handle *dev_handle, int iface) {
PRINT_UNSUPPORTED_API(claim_interface);
}
static int unsupported_set_interface_altsetting(struct libusb_device_handle *dev_handle, int iface, int altsetting) {
PRINT_UNSUPPORTED_API(set_interface_altsetting);
}
static int unsupported_release_interface(struct libusb_device_handle *dev_handle, int iface) {
PRINT_UNSUPPORTED_API(release_interface);
}
static int unsupported_clear_halt(struct libusb_device_handle *dev_handle, unsigned char endpoint) {
PRINT_UNSUPPORTED_API(clear_halt);
}
static int unsupported_reset_device(struct libusb_device_handle *dev_handle) {
PRINT_UNSUPPORTED_API(reset_device);
}
static int unsupported_submit_bulk_transfer(struct usbi_transfer *itransfer) {
PRINT_UNSUPPORTED_API(submit_bulk_transfer);
}
static int unsupported_submit_iso_transfer(struct usbi_transfer *itransfer) {
PRINT_UNSUPPORTED_API(submit_iso_transfer);
}
static int unsupported_submit_control_transfer(struct usbi_transfer *itransfer) {
PRINT_UNSUPPORTED_API(submit_control_transfer);
}
static int unsupported_abort_control(struct usbi_transfer *itransfer) {
PRINT_UNSUPPORTED_API(abort_control);
}
static int unsupported_abort_transfers(struct usbi_transfer *itransfer) {
PRINT_UNSUPPORTED_API(abort_transfers);
}
static int unsupported_copy_transfer_data(struct usbi_transfer *itransfer, uint32_t io_size) {
PRINT_UNSUPPORTED_API(copy_transfer_data);
}
// These names must be uppercase
const char* composite_driver_names[] = {"USBCCGP"};
const char* winusb_driver_names[] = {"WINUSB"};
const char* hid_driver_names[] = {"HIDUSB", "MOUHID", "KBDHID"};
const struct windows_usb_api_backend usb_api_backend[USB_API_MAX] = {
{
USB_API_UNSUPPORTED,
"Unsupported API",
&CLASS_GUID_UNSUPPORTED,
NULL,
0,
unsupported_init,
unsupported_exit,
unsupported_open,
unsupported_close,
unsupported_claim_interface,
unsupported_set_interface_altsetting,
unsupported_release_interface,
unsupported_clear_halt,
unsupported_reset_device,
unsupported_submit_bulk_transfer,
unsupported_submit_iso_transfer,
unsupported_submit_control_transfer,
unsupported_abort_control,
unsupported_abort_transfers,
unsupported_copy_transfer_data,
}, {
USB_API_COMPOSITE,
"Composite API",
&CLASS_GUID_COMPOSITE,
composite_driver_names,
sizeof(composite_driver_names)/sizeof(composite_driver_names[0]),
composite_init,
composite_exit,
composite_open,
composite_close,
composite_claim_interface,
composite_set_interface_altsetting,
composite_release_interface,
composite_clear_halt,
composite_reset_device,
composite_submit_bulk_transfer,
composite_submit_iso_transfer,
composite_submit_control_transfer,
composite_abort_control,
composite_abort_transfers,
composite_copy_transfer_data,
}, {
USB_API_WINUSB,
"WinUSB API",
&CLASS_GUID_LIBUSB_WINUSB,
winusb_driver_names,
sizeof(winusb_driver_names)/sizeof(winusb_driver_names[0]),
winusb_init,
winusb_exit,
winusb_open,
winusb_close,
winusb_claim_interface,
winusb_set_interface_altsetting,
winusb_release_interface,
winusb_clear_halt,
winusb_reset_device,
winusb_submit_bulk_transfer,
unsupported_submit_iso_transfer,
winusb_submit_control_transfer,
winusb_abort_control,
winusb_abort_transfers,
winusb_copy_transfer_data,
}, {
USB_API_HID,
"HID API",
&CLASS_GUID_HID,
hid_driver_names,
sizeof(hid_driver_names)/sizeof(hid_driver_names[0]),
hid_init,
hid_exit,
hid_open,
hid_close,
hid_claim_interface,
hid_set_interface_altsetting,
hid_release_interface,
hid_clear_halt,
hid_reset_device,
hid_submit_bulk_transfer,
unsupported_submit_iso_transfer,
hid_submit_control_transfer,
hid_abort_transfers,
hid_abort_transfers,
hid_copy_transfer_data,
},
};
/*
* WinUSB API functions
*/
static int winusb_init(struct libusb_context *ctx)
{
DLL_LOAD(winusb.dll, WinUsb_Initialize, TRUE);
DLL_LOAD(winusb.dll, WinUsb_Free, TRUE);
DLL_LOAD(winusb.dll, WinUsb_GetAssociatedInterface, TRUE);
DLL_LOAD(winusb.dll, WinUsb_GetDescriptor, TRUE);
DLL_LOAD(winusb.dll, WinUsb_QueryInterfaceSettings, TRUE);
DLL_LOAD(winusb.dll, WinUsb_QueryDeviceInformation, TRUE);
DLL_LOAD(winusb.dll, WinUsb_SetCurrentAlternateSetting, TRUE);
DLL_LOAD(winusb.dll, WinUsb_GetCurrentAlternateSetting, TRUE);
DLL_LOAD(winusb.dll, WinUsb_QueryPipe, TRUE);
DLL_LOAD(winusb.dll, WinUsb_SetPipePolicy, TRUE);
DLL_LOAD(winusb.dll, WinUsb_GetPipePolicy, TRUE);
DLL_LOAD(winusb.dll, WinUsb_ReadPipe, TRUE);
DLL_LOAD(winusb.dll, WinUsb_WritePipe, TRUE);
DLL_LOAD(winusb.dll, WinUsb_ControlTransfer, TRUE);
DLL_LOAD(winusb.dll, WinUsb_ResetPipe, TRUE);
DLL_LOAD(winusb.dll, WinUsb_AbortPipe, TRUE);
DLL_LOAD(winusb.dll, WinUsb_FlushPipe, TRUE);
api_winusb_available = true;
return LIBUSB_SUCCESS;
}
static int winusb_exit(void)
{
return LIBUSB_SUCCESS;
}
// NB: open and close must ensure that they only handle interface of
// the right API type, as these functions can be called wholesale from
// composite_open(), with interfaces belonging to different APIs
static int winusb_open(struct libusb_device_handle *dev_handle)
{
struct libusb_context *ctx = DEVICE_CTX(dev_handle->dev);
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(dev_handle);
HANDLE file_handle;
int i;
CHECK_WINUSB_AVAILABLE;
// WinUSB requires a seperate handle for each interface
for (i = 0; i < USB_MAXINTERFACES; i++) {
if ( (priv->usb_interface[i].path != NULL)
&& (priv->usb_interface[i].apib->id == USB_API_WINUSB) ) {
file_handle = CreateFileA(priv->usb_interface[i].path, GENERIC_WRITE | GENERIC_READ, FILE_SHARE_WRITE | FILE_SHARE_READ,
NULL, OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL | FILE_FLAG_OVERLAPPED, NULL);
if (file_handle == INVALID_HANDLE_VALUE) {
usbi_err(ctx, "could not open device %s (interface %d): %s", priv->usb_interface[i].path, i, windows_error_str(0));
switch(GetLastError()) {
case ERROR_FILE_NOT_FOUND: // The device was disconnected
return LIBUSB_ERROR_NO_DEVICE;
case ERROR_ACCESS_DENIED:
return LIBUSB_ERROR_ACCESS;
default:
return LIBUSB_ERROR_IO;
}
}
handle_priv->interface_handle[i].dev_handle = file_handle;
}
}
return LIBUSB_SUCCESS;
}
static void winusb_close(struct libusb_device_handle *dev_handle)
{
struct windows_device_handle_priv *handle_priv = __device_handle_priv(dev_handle);
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
HANDLE file_handle;
int i;
if (!api_winusb_available)
return;
for (i = 0; i < USB_MAXINTERFACES; i++) {
if (priv->usb_interface[i].apib->id == USB_API_WINUSB) {
file_handle = handle_priv->interface_handle[i].dev_handle;
if ( (file_handle != 0) && (file_handle != INVALID_HANDLE_VALUE)) {
CloseHandle(file_handle);
}
}
}
}
static int winusb_claim_interface(struct libusb_device_handle *dev_handle, int iface)
{
struct libusb_context *ctx = DEVICE_CTX(dev_handle->dev);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(dev_handle);
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
bool is_using_usbccgp = (priv->apib->id == USB_API_COMPOSITE);
HANDLE file_handle, winusb_handle;
UCHAR policy;
uint8_t endpoint_address;
int i;
CHECK_WINUSB_AVAILABLE;
// If the device is composite, but using the default Windows composite parent driver (usbccgp)
// or if it's the first WinUSB interface, we get a handle through WinUsb_Initialize().
if ((is_using_usbccgp) || (iface == 0)) {
// composite device (independent interfaces) or interface 0
winusb_handle = handle_priv->interface_handle[iface].api_handle;
file_handle = handle_priv->interface_handle[iface].dev_handle;
if ((file_handle == 0) || (file_handle == INVALID_HANDLE_VALUE)) {
return LIBUSB_ERROR_NOT_FOUND;
}
if (!WinUsb_Initialize(file_handle, &winusb_handle)) {
usbi_err(ctx, "could not access interface %d: %s", iface, windows_error_str(0));
handle_priv->interface_handle[iface].api_handle = INVALID_HANDLE_VALUE;
switch(GetLastError()) {
case ERROR_BAD_COMMAND: // The device was disconnected
return LIBUSB_ERROR_NO_DEVICE;
default:
usbi_err(ctx, "could not claim interface %d: %s", iface, windows_error_str(0));
return LIBUSB_ERROR_ACCESS;
}
}
handle_priv->interface_handle[iface].api_handle = winusb_handle;
} else {
// For all other interfaces, use WinUsb_GetAssociatedInterface()
winusb_handle = handle_priv->interface_handle[0].api_handle;
// It is a requirement for multiple interface devices on Windows that, to you
// must first claim the first interface before you claim the others
if ((winusb_handle == 0) || (winusb_handle == INVALID_HANDLE_VALUE)) {
#if defined(AUTO_CLAIM)
file_handle = handle_priv->interface_handle[0].dev_handle;
if (WinUsb_Initialize(file_handle, &winusb_handle)) {
handle_priv->interface_handle[0].api_handle = winusb_handle;
usbi_warn(ctx, "auto-claimed interface 0 (required to claim %d with WinUSB)", iface);
} else {
usbi_warn(ctx, "failed to auto-claim interface 0 (required to claim %d with WinUSB)", iface);
return LIBUSB_ERROR_ACCESS;
}
#else
usbi_warn(ctx, "you must claim interface 0 before you can claim %d with WinUSB", iface);
return LIBUSB_ERROR_ACCESS;
#endif
}
if (!WinUsb_GetAssociatedInterface(winusb_handle, (UCHAR)(iface-1),
&handle_priv->interface_handle[iface].api_handle)) {
handle_priv->interface_handle[iface].api_handle = INVALID_HANDLE_VALUE;
switch(GetLastError()) {
case ERROR_NO_MORE_ITEMS: // invalid iface
return LIBUSB_ERROR_NOT_FOUND;
case ERROR_BAD_COMMAND: // The device was disconnected
return LIBUSB_ERROR_NO_DEVICE;
case ERROR_ALREADY_EXISTS: // already claimed
return LIBUSB_ERROR_BUSY;
default:
usbi_err(ctx, "could not claim interface %d: %s", iface, windows_error_str(0));
return LIBUSB_ERROR_ACCESS;
}
}
}
usbi_dbg("claimed interface %d", iface);
handle_priv->active_interface = iface;
// With handle and enpoints set (in parent), we can setup the default
// pipe properties (copied from libusb-win32-v1)
// see http://download.microsoft.com/download/D/1/D/D1DD7745-426B-4CC3-A269-ABBBE427C0EF/DVC-T705_DDC08.pptx
for (i=0; i<priv->usb_interface[iface].nb_endpoints; i++) {
endpoint_address = priv->usb_interface[iface].endpoint[i];
policy = false;
if (!WinUsb_SetPipePolicy(winusb_handle, endpoint_address,
SHORT_PACKET_TERMINATE, sizeof(UCHAR), &policy)) {
usbi_dbg("failed to disable SHORT_PACKET_TERMINATE for endpoint %02X", endpoint_address);
}
if (!WinUsb_SetPipePolicy(winusb_handle, endpoint_address,
IGNORE_SHORT_PACKETS, sizeof(UCHAR), &policy)) {
usbi_dbg("failed to disable IGNORE_SHORT_PACKETS for endpoint %02X", endpoint_address);
}
if (!WinUsb_SetPipePolicy(winusb_handle, endpoint_address,
ALLOW_PARTIAL_READS, sizeof(UCHAR), &policy)) {
usbi_dbg("failed to disable ALLOW_PARTIAL_READS for endpoint %02X", endpoint_address);
}
policy = true;
if (!WinUsb_SetPipePolicy(winusb_handle, endpoint_address,
AUTO_CLEAR_STALL, sizeof(UCHAR), &policy)) {
usbi_dbg("failed to enable AUTO_CLEAR_STALL for endpoint %02X", endpoint_address);
}
}
return LIBUSB_SUCCESS;
}
static int winusb_release_interface(struct libusb_device_handle *dev_handle, int iface)
{
struct windows_device_handle_priv *handle_priv = __device_handle_priv(dev_handle);
HANDLE winusb_handle;
CHECK_WINUSB_AVAILABLE;
winusb_handle = handle_priv->interface_handle[iface].api_handle;
if ((winusb_handle == 0) || (winusb_handle == INVALID_HANDLE_VALUE)) {
return LIBUSB_ERROR_NOT_FOUND;
}
WinUsb_Free(winusb_handle);
handle_priv->interface_handle[iface].api_handle = INVALID_HANDLE_VALUE;
return LIBUSB_SUCCESS;
}
/*
* Return the first valid interface (of the same API type), for control transfers
*/
static int get_valid_interface(struct libusb_device_handle *dev_handle, int api_id)
{
struct windows_device_handle_priv *handle_priv = __device_handle_priv(dev_handle);
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
int i;
if ((api_id < USB_API_WINUSB) || (api_id > USB_API_HID)) {
usbi_dbg("unsupported API ID");
return -1;
}
for (i=0; i<USB_MAXINTERFACES; i++) {
if ( (handle_priv->interface_handle[i].dev_handle != 0)
&& (handle_priv->interface_handle[i].dev_handle != INVALID_HANDLE_VALUE)
&& (handle_priv->interface_handle[i].api_handle != 0)
&& (handle_priv->interface_handle[i].api_handle != INVALID_HANDLE_VALUE)
&& (priv->usb_interface[i].apib == &usb_api_backend[api_id]) ) {
return i;
}
}
return -1;
}
/*
* Lookup interface by endpoint address. -1 if not found
*/
static int interface_by_endpoint(struct windows_device_priv *priv,
struct windows_device_handle_priv *handle_priv, uint8_t endpoint_address)
{
int i, j;
for (i=0; i<USB_MAXINTERFACES; i++) {
if (handle_priv->interface_handle[i].api_handle == INVALID_HANDLE_VALUE)
continue;
if (handle_priv->interface_handle[i].api_handle == 0)
continue;
if (priv->usb_interface[i].endpoint == NULL)
continue;
for (j=0; j<priv->usb_interface[i].nb_endpoints; j++) {
if (priv->usb_interface[i].endpoint[j] == endpoint_address) {
return i;
}
}
}
return -1;
}
static int winusb_submit_control_transfer(struct usbi_transfer *itransfer)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct libusb_context *ctx = DEVICE_CTX(transfer->dev_handle->dev);
struct windows_transfer_priv *transfer_priv = usbi_transfer_get_os_priv(itransfer);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(
transfer->dev_handle);
WINUSB_SETUP_PACKET *setup = (WINUSB_SETUP_PACKET *) transfer->buffer;
ULONG size;
HANDLE winusb_handle;
int current_interface;
struct winfd wfd;
CHECK_WINUSB_AVAILABLE;
transfer_priv->pollable_fd = INVALID_WINFD;
size = transfer->length - LIBUSB_CONTROL_SETUP_SIZE;
if (size > MAX_CTRL_BUFFER_LENGTH)
return LIBUSB_ERROR_INVALID_PARAM;
current_interface = get_valid_interface(transfer->dev_handle, USB_API_WINUSB);
if (current_interface < 0) {
#if defined(AUTO_CLAIM)
if (auto_claim(transfer, ¤t_interface, USB_API_WINUSB) != LIBUSB_SUCCESS) {
return LIBUSB_ERROR_NOT_FOUND;
}
#else
usbi_warn(ctx, "no interface available for control transfer");
return LIBUSB_ERROR_NOT_FOUND;
#endif
}
usbi_dbg("will use interface %d", current_interface);
winusb_handle = handle_priv->interface_handle[current_interface].api_handle;
wfd = usbi_create_fd(winusb_handle, _O_RDONLY);
// Always use the handle returned from usbi_create_fd (wfd.handle)
if (wfd.fd < 0) {
return LIBUSB_ERROR_NO_MEM;
}
if (!WinUsb_ControlTransfer(wfd.handle, *setup, transfer->buffer + LIBUSB_CONTROL_SETUP_SIZE, size, NULL, wfd.overlapped)) {
if(GetLastError() != ERROR_IO_PENDING) {
usbi_err(ctx, "WinUsb_ControlTransfer failed: %s", windows_error_str(0));
usbi_free_fd(wfd.fd);
return LIBUSB_ERROR_IO;
}
} else {
wfd.overlapped->Internal = STATUS_COMPLETED_SYNCHRONOUSLY;
wfd.overlapped->InternalHigh = (DWORD)size;
}
// Use priv_transfer to store data needed for async polling
transfer_priv->pollable_fd = wfd;
transfer_priv->interface_number = (uint8_t)current_interface;
return LIBUSB_SUCCESS;
}
static int winusb_set_interface_altsetting(struct libusb_device_handle *dev_handle, int iface, int altsetting)
{
struct libusb_context *ctx = DEVICE_CTX(dev_handle->dev);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(dev_handle);
HANDLE winusb_handle;
CHECK_WINUSB_AVAILABLE;
if (altsetting > 255) {
return LIBUSB_ERROR_INVALID_PARAM;
}
winusb_handle = handle_priv->interface_handle[iface].api_handle;
if ((winusb_handle == 0) || (winusb_handle == INVALID_HANDLE_VALUE)) {
usbi_err(ctx, "interface must be claimed first");
return LIBUSB_ERROR_NOT_FOUND;
}
if (!WinUsb_SetCurrentAlternateSetting(winusb_handle, (UCHAR)altsetting)) {
usbi_err(ctx, "WinUsb_SetCurrentAlternateSetting failed: %s", windows_error_str(0));
return LIBUSB_ERROR_IO;
}
return LIBUSB_SUCCESS;
}
static int winusb_submit_bulk_transfer(struct usbi_transfer *itransfer)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct libusb_context *ctx = DEVICE_CTX(transfer->dev_handle->dev);
struct windows_transfer_priv *transfer_priv = usbi_transfer_get_os_priv(itransfer);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(transfer->dev_handle);
struct windows_device_priv *priv = __device_priv(transfer->dev_handle->dev);
HANDLE winusb_handle;
bool direction_in, ret;
int current_interface;
struct winfd wfd;
CHECK_WINUSB_AVAILABLE;
transfer_priv->pollable_fd = INVALID_WINFD;
current_interface = interface_by_endpoint(priv, handle_priv, transfer->endpoint);
if (current_interface < 0) {
usbi_err(ctx, "unable to match endpoint to an open interface - cancelling transfer");
return LIBUSB_ERROR_NOT_FOUND;
}
usbi_dbg("matched endpoint %02X with interface %d", transfer->endpoint, current_interface);
winusb_handle = handle_priv->interface_handle[current_interface].api_handle;
direction_in = transfer->endpoint & LIBUSB_ENDPOINT_IN;
wfd = usbi_create_fd(winusb_handle, direction_in?_O_RDONLY:_O_WRONLY);
// Always use the handle returned from usbi_create_fd (wfd.handle)
if (wfd.fd < 0) {
return LIBUSB_ERROR_NO_MEM;
}
if (direction_in) {
usbi_dbg("reading %d bytes", transfer->length);
ret = WinUsb_ReadPipe(wfd.handle, transfer->endpoint, transfer->buffer, transfer->length, NULL, wfd.overlapped);
} else {
usbi_dbg("writing %d bytes", transfer->length);
ret = WinUsb_WritePipe(wfd.handle, transfer->endpoint, transfer->buffer, transfer->length, NULL, wfd.overlapped);
}
if (!ret) {
if(GetLastError() != ERROR_IO_PENDING) {
usbi_err(ctx, "WinUsb_Pipe Transfer failed: %s", windows_error_str(0));
usbi_free_fd(wfd.fd);
return LIBUSB_ERROR_IO;
}
} else {
wfd.overlapped->Internal = STATUS_COMPLETED_SYNCHRONOUSLY;
wfd.overlapped->InternalHigh = (DWORD)transfer->length;
}
transfer_priv->pollable_fd = wfd;
transfer_priv->interface_number = (uint8_t)current_interface;
return LIBUSB_SUCCESS;
}
static int winusb_clear_halt(struct libusb_device_handle *dev_handle, unsigned char endpoint)
{
struct libusb_context *ctx = DEVICE_CTX(dev_handle->dev);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(dev_handle);
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
HANDLE winusb_handle;
int current_interface;
CHECK_WINUSB_AVAILABLE;
current_interface = interface_by_endpoint(priv, handle_priv, endpoint);
if (current_interface < 0) {
usbi_err(ctx, "unable to match endpoint to an open interface - cannot clear");
return LIBUSB_ERROR_NOT_FOUND;
}
usbi_dbg("matched endpoint %02X with interface %d", endpoint, current_interface);
winusb_handle = handle_priv->interface_handle[current_interface].api_handle;
if (!WinUsb_ResetPipe(winusb_handle, endpoint)) {
usbi_err(ctx, "WinUsb_ResetPipe failed: %s", windows_error_str(0));
return LIBUSB_ERROR_NO_DEVICE;
}
return LIBUSB_SUCCESS;
}
/*
* from http://www.winvistatips.com/winusb-bugchecks-t335323.html (confirmed
* through testing as well):
* "You can not call WinUsb_AbortPipe on control pipe. You can possibly cancel
* the control transfer using CancelIo"
*/
static int winusb_abort_control(struct usbi_transfer *itransfer)
{
// Cancelling of the I/O is done in the parent
return LIBUSB_SUCCESS;
}
static int winusb_abort_transfers(struct usbi_transfer *itransfer)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct libusb_context *ctx = DEVICE_CTX(transfer->dev_handle->dev);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(transfer->dev_handle);
struct windows_transfer_priv *transfer_priv = usbi_transfer_get_os_priv(itransfer);
HANDLE winusb_handle;
int current_interface;
CHECK_WINUSB_AVAILABLE;
current_interface = transfer_priv->interface_number;
if ((current_interface < 0) || (current_interface >= USB_MAXINTERFACES)) {
usbi_err(ctx, "program assertion failed: invalid interface_number");
return LIBUSB_ERROR_NOT_FOUND;
}
usbi_dbg("will use interface %d", current_interface);
winusb_handle = handle_priv->interface_handle[current_interface].api_handle;
if (!WinUsb_AbortPipe(winusb_handle, transfer->endpoint)) {
usbi_err(ctx, "WinUsb_AbortPipe failed: %s", windows_error_str(0));
return LIBUSB_ERROR_NO_DEVICE;
}
return LIBUSB_SUCCESS;
}
/*
* from the "How to Use WinUSB to Communicate with a USB Device" Microsoft white paper
* (http://www.microsoft.com/whdc/connect/usb/winusb_howto.mspx):
* "WinUSB does not support host-initiated reset port and cycle port operations" and
* IOCTL_INTERNAL_USB_CYCLE_PORT is only available in kernel mode and the
* IOCTL_USB_HUB_CYCLE_PORT ioctl was removed from Vista => the best we can do is
* cycle the pipes (and even then, the control pipe can not be reset using WinUSB)
*/
// TODO (2nd official release): see if we can force eject the device and redetect it (reuse hotplug?)
static int winusb_reset_device(struct libusb_device_handle *dev_handle)
{
struct libusb_context *ctx = DEVICE_CTX(dev_handle->dev);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(dev_handle);
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
struct winfd wfd;
HANDLE winusb_handle;
int i, j;
CHECK_WINUSB_AVAILABLE;
// Reset any available pipe (except control)
for (i=0; i<USB_MAXINTERFACES; i++) {
winusb_handle = handle_priv->interface_handle[i].api_handle;
for (wfd = handle_to_winfd(winusb_handle); wfd.fd > 0;)
{
// Cancel any pollable I/O
usbi_remove_pollfd(ctx, wfd.fd);
usbi_free_fd(wfd.fd);
wfd = handle_to_winfd(winusb_handle);
}
if ( (winusb_handle != 0) && (winusb_handle != INVALID_HANDLE_VALUE)) {
for (j=0; j<priv->usb_interface[i].nb_endpoints; j++) {
usbi_dbg("resetting ep %02X", priv->usb_interface[i].endpoint[j]);
if (!WinUsb_AbortPipe(winusb_handle, priv->usb_interface[i].endpoint[j])) {
usbi_err(ctx, "WinUsb_AbortPipe (pipe address %02X) failed: %s",
priv->usb_interface[i].endpoint[j], windows_error_str(0));
}
// FlushPipe seems to fail on OUT pipes
if ( (priv->usb_interface[i].endpoint[j] & LIBUSB_ENDPOINT_IN)
&& (!WinUsb_FlushPipe(winusb_handle, priv->usb_interface[i].endpoint[j])) ) {
usbi_err(ctx, "WinUsb_FlushPipe (pipe address %02X) failed: %s",
priv->usb_interface[i].endpoint[j], windows_error_str(0));
}
if (!WinUsb_ResetPipe(winusb_handle, priv->usb_interface[i].endpoint[j])) {
usbi_err(ctx, "WinUsb_ResetPipe (pipe address %02X) failed: %s",
priv->usb_interface[i].endpoint[j], windows_error_str(0));
}
}
}
}
return LIBUSB_SUCCESS;
}
static int winusb_copy_transfer_data(struct usbi_transfer *itransfer, uint32_t io_size)
{
itransfer->transferred += io_size;
return LIBUSB_TRANSFER_COMPLETED;
}
/*
* Internal HID Support functions (from libusb-win32)
* Note that functions that complete data transfer synchronously must return
* LIBUSB_COMPLETED instead of LIBUSB_SUCCESS
*/
static int _hid_get_hid_descriptor(struct hid_device_priv* dev, void *data, size_t *size);
static int _hid_get_report_descriptor(struct hid_device_priv* dev, void *data, size_t *size);
static int _hid_wcslen(WCHAR *str)
{
int i = 0;
while (str[i] && (str[i] != 0x409)) {
i++;
}
return i;
}
static int _hid_get_device_descriptor(struct hid_device_priv* dev, void *data, size_t *size)
{
struct libusb_device_descriptor d;
d.bLength = LIBUSB_DT_DEVICE_SIZE;
d.bDescriptorType = LIBUSB_DT_DEVICE;
d.bcdUSB = 0x0200; /* 2.00 */
d.bDeviceClass = 0;
d.bDeviceSubClass = 0;
d.bDeviceProtocol = 0;
d.bMaxPacketSize0 = 64; /* fix this! */
d.idVendor = (uint16_t)dev->vid;
d.idProduct = (uint16_t)dev->pid;
d.bcdDevice = 0x0100;
d.iManufacturer = dev->string_index[0];
d.iProduct = dev->string_index[1];
d.iSerialNumber = dev->string_index[2];
d.bNumConfigurations = 1;
if (*size > LIBUSB_DT_DEVICE_SIZE)
*size = LIBUSB_DT_DEVICE_SIZE;
memcpy(data, &d, *size);
return LIBUSB_COMPLETED;
}
static int _hid_get_config_descriptor(struct hid_device_priv* dev, void *data, size_t *size)
{
char num_endpoints = 0;
size_t config_total_len = 0;
char tmp[HID_MAX_CONFIG_DESC_SIZE];
struct libusb_config_descriptor *cd;
struct libusb_interface_descriptor *id;
struct libusb_hid_descriptor *hd;
struct libusb_endpoint_descriptor *ed;
size_t tmp_size;
if (dev->input_report_size)
num_endpoints++;
if (dev->output_report_size)
num_endpoints++;
config_total_len = LIBUSB_DT_CONFIG_SIZE + LIBUSB_DT_INTERFACE_SIZE
+ LIBUSB_DT_HID_SIZE + num_endpoints * LIBUSB_DT_ENDPOINT_SIZE;
cd = (struct libusb_config_descriptor *)tmp;
id = (struct libusb_interface_descriptor *)(tmp + LIBUSB_DT_CONFIG_SIZE);
hd = (struct libusb_hid_descriptor *)(tmp + LIBUSB_DT_CONFIG_SIZE
+ LIBUSB_DT_INTERFACE_SIZE);
ed = (struct libusb_endpoint_descriptor *)(tmp + LIBUSB_DT_CONFIG_SIZE
+ LIBUSB_DT_INTERFACE_SIZE
+ LIBUSB_DT_HID_SIZE);
cd->bLength = LIBUSB_DT_CONFIG_SIZE;
cd->bDescriptorType = LIBUSB_DT_CONFIG;
cd->wTotalLength = (uint16_t) config_total_len;
cd->bNumInterfaces = 1;
cd->bConfigurationValue = 1;
cd->iConfiguration = 0;
cd->bmAttributes = 1 << 7; /* bus powered */
cd->MaxPower = 50;
id->bLength = LIBUSB_DT_INTERFACE_SIZE;
id->bDescriptorType = LIBUSB_DT_INTERFACE;
id->bInterfaceNumber = 0;
id->bAlternateSetting = 0;
id->bNumEndpoints = num_endpoints;
id->bInterfaceClass = 3;
id->bInterfaceSubClass = 0;
id->bInterfaceProtocol = 0;
id->iInterface = 0;
tmp_size = LIBUSB_DT_HID_SIZE;
_hid_get_hid_descriptor(dev, hd, &tmp_size);
if (dev->input_report_size) {
ed->bLength = LIBUSB_DT_ENDPOINT_SIZE;
ed->bDescriptorType = LIBUSB_DT_ENDPOINT;
ed->bEndpointAddress = HID_IN_EP;
ed->bmAttributes = 3;
ed->wMaxPacketSize = dev->input_report_size - 1;
ed->bInterval = 10;
ed++;
}
if (dev->output_report_size) {
ed->bLength = LIBUSB_DT_ENDPOINT_SIZE;
ed->bDescriptorType = LIBUSB_DT_ENDPOINT;
ed->bEndpointAddress = HID_OUT_EP;
ed->bmAttributes = 3;
ed->wMaxPacketSize = dev->output_report_size - 1;
ed->bInterval = 10;
}
if (*size > config_total_len)
*size = config_total_len;
memcpy(data, tmp, *size);
return LIBUSB_COMPLETED;
}
static int _hid_get_string_descriptor(struct hid_device_priv* dev, int index,
void *data, size_t *size)
{
void *tmp = NULL;
size_t tmp_size = 0;
int i;
/* language ID, EN-US */
char string_langid[] = {
0x09,
0x04
};
if ((*size < 2) || (*size > 255)) {
return LIBUSB_ERROR_OVERFLOW;
}
if (index == 0) {
tmp = string_langid;
tmp_size = sizeof(string_langid)+2;
} else {
for (i=0; i<3; i++) {
if (index == (dev->string_index[i])) {
tmp = dev->string[i];
tmp_size = (_hid_wcslen(dev->string[i])+1) * sizeof(WCHAR);
break;
}
}
if (i == 3) { // not found
return LIBUSB_ERROR_INVALID_PARAM;
}
}
if(!tmp_size) {
return LIBUSB_ERROR_INVALID_PARAM;
}
if (tmp_size < *size) {
*size = tmp_size;
}
// 2 byte header
((uint8_t*)data)[0] = (uint8_t)*size;
((uint8_t*)data)[1] = LIBUSB_DT_STRING;
memcpy((uint8_t*)data+2, tmp, *size-2);
return LIBUSB_COMPLETED;
}
static int _hid_get_hid_descriptor(struct hid_device_priv* dev, void *data, size_t *size)
{
struct libusb_hid_descriptor d;
uint8_t tmp[MAX_HID_DESCRIPTOR_SIZE];
size_t report_len = MAX_HID_DESCRIPTOR_SIZE;
_hid_get_report_descriptor(dev, tmp, &report_len);
d.bLength = LIBUSB_DT_HID_SIZE;
d.bDescriptorType = LIBUSB_DT_HID;
d.bcdHID = 0x0110; /* 1.10 */
d.bCountryCode = 0;
d.bNumDescriptors = 1;
d.bClassDescriptorType = LIBUSB_DT_REPORT;
d.wClassDescriptorLength = (uint16_t)report_len;
if (*size > LIBUSB_DT_HID_SIZE)
*size = LIBUSB_DT_HID_SIZE;
memcpy(data, &d, *size);
return LIBUSB_COMPLETED;
}
static int _hid_get_report_descriptor(struct hid_device_priv* dev, void *data, size_t *size)
{
uint8_t d[MAX_HID_DESCRIPTOR_SIZE];
size_t i = 0;
/* usage page (0xFFA0 == vendor defined) */
d[i++] = 0x06; d[i++] = 0xA0; d[i++] = 0xFF;
/* usage (vendor defined) */
d[i++] = 0x09; d[i++] = 0x01;
/* start collection (application) */
d[i++] = 0xA1; d[i++] = 0x01;
/* input report */
if (dev->input_report_size) {
/* usage (vendor defined) */
d[i++] = 0x09; d[i++] = 0x01;
/* logical minimum (0) */
d[i++] = 0x15; d[i++] = 0x00;
/* logical maximum (255) */
d[i++] = 0x25; d[i++] = 0xFF;
/* report size (8 bits) */
d[i++] = 0x75; d[i++] = 0x08;
/* report count */
d[i++] = 0x95; d[i++] = (uint8_t)dev->input_report_size - 1;
/* input (data, variable, absolute) */
d[i++] = 0x81; d[i++] = 0x00;
}
/* output report */
if (dev->output_report_size) {
/* usage (vendor defined) */
d[i++] = 0x09; d[i++] = 0x02;
/* logical minimum (0) */
d[i++] = 0x15; d[i++] = 0x00;
/* logical maximum (255) */
d[i++] = 0x25; d[i++] = 0xFF;
/* report size (8 bits) */
d[i++] = 0x75; d[i++] = 0x08;
/* report count */
d[i++] = 0x95; d[i++] = (uint8_t)dev->output_report_size - 1;
/* output (data, variable, absolute) */
d[i++] = 0x91; d[i++] = 0x00;
}
/* feature report */
if (dev->feature_report_size) {
/* usage (vendor defined) */
d[i++] = 0x09; d[i++] = 0x03;
/* logical minimum (0) */
d[i++] = 0x15; d[i++] = 0x00;
/* logical maximum (255) */
d[i++] = 0x25; d[i++] = 0xFF;
/* report size (8 bits) */
d[i++] = 0x75; d[i++] = 0x08;
/* report count */
d[i++] = 0x95; d[i++] = (uint8_t)dev->feature_report_size - 1;
/* feature (data, variable, absolute) */
d[i++] = 0xb2; d[i++] = 0x02; d[i++] = 0x01;
}
/* end collection */
d[i++] = 0xC0;
if (*size > i)
*size = i;
memcpy(data, d, *size);
return LIBUSB_COMPLETED;
}
static int _hid_get_descriptor(struct hid_device_priv* dev, HANDLE hid_handle, int recipient,
int type, int index, void *data, size_t *size)
{
switch(type) {
case LIBUSB_DT_DEVICE:
usbi_dbg("LIBUSB_DT_DEVICE");
return _hid_get_device_descriptor(dev, data, size);
case LIBUSB_DT_CONFIG:
usbi_dbg("LIBUSB_DT_CONFIG");
if (!index)
return _hid_get_config_descriptor(dev, data, size);
return LIBUSB_ERROR_INVALID_PARAM;
case LIBUSB_DT_STRING:
usbi_dbg("LIBUSB_DT_STRING");
return _hid_get_string_descriptor(dev, index, data, size);
case LIBUSB_DT_HID:
usbi_dbg("LIBUSB_DT_HID");
if (!index)
return _hid_get_hid_descriptor(dev, data, size);
return LIBUSB_ERROR_INVALID_PARAM;
case LIBUSB_DT_REPORT:
usbi_dbg("LIBUSB_DT_REPORT");
if (!index)
return _hid_get_report_descriptor(dev, data, size);
return LIBUSB_ERROR_INVALID_PARAM;
case LIBUSB_DT_PHYSICAL:
usbi_dbg("LIBUSB_DT_PHYSICAL");
if (HidD_GetPhysicalDescriptor(hid_handle, data, (ULONG)*size))
return LIBUSB_COMPLETED;
return LIBUSB_ERROR_OTHER;
}
usbi_dbg("unsupported");
return LIBUSB_ERROR_INVALID_PARAM;
}
static int _hid_get_report(struct hid_device_priv* dev, HANDLE hid_handle, int id, void *data,
struct windows_transfer_priv *tp, size_t *size, OVERLAPPED* overlapped)
{
uint8_t *buf;
DWORD read_size, expected_size = (DWORD)*size;
int r = LIBUSB_SUCCESS;
if (tp->hid_buffer != NULL) {
usbi_dbg("program assertion failed: hid_buffer is not NULL");
}
if ((*size == 0) || (*size > MAX_HID_REPORT_SIZE)) {
usbi_dbg("invalid size (%d)", *size);
return LIBUSB_ERROR_INVALID_PARAM;
}
// When report IDs are not in use, add an extra byte for the report ID
if (id==0) {
expected_size++;
}
// Add a trailing byte to detect overflows
buf = (uint8_t*)calloc(expected_size+1, 1);
if (buf == NULL) {
return LIBUSB_ERROR_NO_MEM;
}
buf[0] = (uint8_t)id; // Must be set always
usbi_dbg("report ID: 0x%02X", buf[0]);
// NB: HidD_GetInputReport sends an request to the device for the Input Report
// (and blocks until response) whereas ReadFile waits for input to be generated
// asynchronously
#if !defined(USE_HIDD_FOR_REPORTS)
// Use ReadFile instead of HidD_GetInputReport for async I/O
// TODO: send a request paquet?
tp->hid_expected_size = expected_size;
if (!ReadFile(hid_handle, buf, expected_size+1, &read_size, overlapped)) {
if (GetLastError() != ERROR_IO_PENDING) {
usbi_dbg("Failed to Read HID Input Report: %s", windows_error_str(0));
safe_free(buf);
return LIBUSB_ERROR_IO;
}
// Asynchronous wait
tp->hid_buffer = buf;
tp->hid_dest = data; // copy dest, as not necessarily the start of the transfer buffer
return LIBUSB_SUCCESS;
}
#else
// Synchronous request for the Input Report
if (!HidD_GetInputReport(hid_handle, buf, expected_size)) {
usbi_dbg("Failed to Read HID Input Report: %s", windows_error_str(0));
safe_free(buf);
return LIBUSB_ERROR_IO;
}
read_size = expected_size; // Can't detect overflows with this API
#endif
// Transfer completed synchronously => copy and discard extra buffer
if (read_size == 0) {
usbi_dbg("program assertion failed - read completed synchronously, but no data was read");
*size = 0;
} else {
if (buf[0] != id) {
usbi_warn(NULL, "mismatched report ID (data is %02X, parameter is %02X)", buf[0], id);
}
if ((size_t)read_size > expected_size) {
r = LIBUSB_ERROR_OVERFLOW;
usbi_dbg("OVERFLOW!");
} else {
r = LIBUSB_COMPLETED;
}
if (id == 0) {
// Discard report ID
*size = MIN((size_t)read_size-1, *size);
memcpy(data, buf+1, *size);
} else {
*size = MIN((size_t)read_size, *size);
memcpy(data, buf, *size);
}
}
safe_free(buf);
return r;
}
static int _hid_set_report(struct hid_device_priv* dev, HANDLE hid_handle, int id, void *data,
struct windows_transfer_priv *tp, size_t *size, OVERLAPPED* overlapped)
{
uint8_t *buf = NULL;
DWORD write_size= (DWORD)*size;
if (tp->hid_buffer != NULL) {
usbi_dbg("program assertion failed: hid_buffer is not NULL");
}
if ((*size == 0) || (*size > MAX_HID_REPORT_SIZE)) {
usbi_dbg("invalid size (%d)", *size);
return LIBUSB_ERROR_INVALID_PARAM;
}
usbi_dbg("report ID: 0x%02X", id);
// When report IDs are not used (i.e. when id == 0), we must add
// a null report ID. Otherwise, we just use original data buffer
if (id == 0) {
write_size++;
}
buf = malloc(write_size);
if (buf == NULL) {
return LIBUSB_ERROR_NO_MEM;
}
if (id == 0) {
buf[0] = 0;
memcpy(buf + 1, data, *size);
} else {
// This seems like a waste, but if we don't duplicate the
// data, we'll get issues when freeing hid_buffer
memcpy(buf, data, *size);
if (buf[0] != id) {
usbi_warn(NULL, "mismatched report ID (data is %02X, parameter is %02X)", buf[0], id);
}
}
#if !defined(USE_HIDD_FOR_REPORTS)
// Une WriteFile instead of HidD_SetOutputReport for async I/O
if (!WriteFile(hid_handle, buf, write_size, &write_size, overlapped)) {
if (GetLastError() != ERROR_IO_PENDING) {
usbi_dbg("Failed to Write HID Output Report: %s", windows_error_str(0));
safe_free(buf);
return LIBUSB_ERROR_IO;
}
tp->hid_buffer = buf;
tp->hid_dest = NULL;
return LIBUSB_SUCCESS;
}
#else
if (!HidD_SetOutputReport(hid_handle, buf, write_size)) {
usbi_dbg("Failed to Write HID Output Report: %s", windows_error_str(0));
if (id == 0) {
safe_free(buf);
}
return LIBUSB_ERROR_IO;
}
#endif
// Transfer completed synchronously
if (write_size == 0) {
usbi_dbg("program assertion failed - write completed synchronously, but no data was written");
*size = 0;
} else {
*size = write_size - ((id == 0)?1:0);
}
safe_free(buf);
return LIBUSB_COMPLETED;
}
static int _hid_get_feature(struct hid_device_priv* dev, HANDLE hid_handle, int id, void *data, size_t *size)
{
uint8_t *buf = (uint8_t*)data; // default with report ID is to use data
ULONG read_size = (ULONG)*size;
int r = LIBUSB_ERROR_OTHER;
uint32_t err;
if ((*size == 0) || (*size > MAX_HID_REPORT_SIZE)) {
usbi_dbg("invalid size (%d)", *size);
return LIBUSB_ERROR_INVALID_PARAM;
}
// When report IDs are not in use, we must prefix an extra zero ID
if (id == 0) {
read_size++;
buf = (uint8_t*)calloc(1, read_size);
if (buf == NULL) {
return LIBUSB_ERROR_NO_MEM;
}
}
buf[0] = (uint8_t)id;
usbi_dbg("report ID: 0x%02X", buf[0]);
if (HidD_GetFeature(hid_handle, buf, read_size)) {
if (buf[0] != id) {
usbi_warn(NULL, "mismatched report ID (data is %02X, parameter is %02X)", buf[0], id);
}
if (id == 0) {
memcpy(data, buf+1, *size);
}
r = LIBUSB_COMPLETED;
} else {
err = GetLastError();
switch (err) {
case ERROR_INVALID_FUNCTION:
r = LIBUSB_ERROR_NOT_FOUND;
break;
default:
usbi_dbg("error %s", windows_error_str(err));
r = LIBUSB_ERROR_OTHER;
break;
}
}
if (id == 0) {
safe_free(buf);
}
return r;
}
static int _hid_set_feature(struct hid_device_priv* dev, HANDLE hid_handle, int id, void *data, size_t *size)
{
uint8_t *buf = (uint8_t*)data;
uint32_t err;
int r = LIBUSB_ERROR_OTHER;
ULONG write_size = (ULONG)*size;
if ((*size == 0) || (*size > MAX_HID_REPORT_SIZE)) {
usbi_dbg("invalid size (%d)", *size);
return LIBUSB_ERROR_INVALID_PARAM;
}
if (id == 0) {
write_size++;
buf = (uint8_t*)calloc(write_size, 1);
if (buf == NULL) {
return LIBUSB_ERROR_NO_MEM;
}
memcpy(buf+1, data, *size);
buf[0] = (uint8_t)id;
} else if (buf[0] != id) {
usbi_warn(NULL, "mismatched report ID (data is %02X, parameter is %02X)", buf[0], id);
return LIBUSB_ERROR_INVALID_PARAM;
}
usbi_dbg("report ID: 0x%02X", buf[0]);
if (HidD_SetFeature(hid_handle, buf, write_size)) {
r = LIBUSB_COMPLETED;
} else {
err = GetLastError();
switch (err) {
case ERROR_INVALID_FUNCTION:
r = LIBUSB_ERROR_NOT_FOUND;
default:
usbi_dbg("error %s", windows_error_str(err));
r = LIBUSB_ERROR_OTHER;
}
}
if (id == 0) {
safe_free(buf);
}
return r;
}
static int _hid_class_request(struct hid_device_priv* dev, HANDLE hid_handle, int request_type,
int request, int value, int index, void *data, struct windows_transfer_priv *tp,
size_t *size, OVERLAPPED* overlapped)
{
int report_type = (value >> 8) & 0xFF;
int report_id = value & 0xFF;
if ( (LIBUSB_REQ_RECIPIENT(request_type) != LIBUSB_RECIPIENT_INTERFACE)
&& (LIBUSB_REQ_RECIPIENT(request_type) != LIBUSB_RECIPIENT_DEVICE) )
return LIBUSB_ERROR_INVALID_PARAM;
if (LIBUSB_REQ_OUT(request_type)
&& request == HID_REQ_SET_REPORT
&& report_type == HID_REPORT_TYPE_OUTPUT)
return _hid_set_report(dev, hid_handle, report_id, data, tp, size, overlapped);
if (LIBUSB_REQ_IN(request_type)
&& request == HID_REQ_GET_REPORT
&& report_type == HID_REPORT_TYPE_INPUT)
return _hid_get_report(dev, hid_handle, report_id, data, tp, size, overlapped);
if (LIBUSB_REQ_OUT(request_type)
&& request == HID_REQ_SET_REPORT
&& report_type == HID_REPORT_TYPE_FEATURE)
return _hid_set_feature(dev, hid_handle, report_id, data, size);
if (LIBUSB_REQ_IN(request_type)
&& request == HID_REQ_GET_REPORT
&& report_type == HID_REPORT_TYPE_FEATURE)
return _hid_get_feature(dev, hid_handle, report_id, data, size);
return LIBUSB_ERROR_INVALID_PARAM;
}
/*
* HID API functions
*/
static int hid_init(struct libusb_context *ctx)
{
DLL_LOAD(hid.dll, HidD_GetAttributes, TRUE);
DLL_LOAD(hid.dll, HidD_GetHidGuid, TRUE);
DLL_LOAD(hid.dll, HidD_GetPreparsedData, TRUE);
DLL_LOAD(hid.dll, HidD_FreePreparsedData, TRUE);
DLL_LOAD(hid.dll, HidD_GetManufacturerString, TRUE);
DLL_LOAD(hid.dll, HidD_GetProductString, TRUE);
DLL_LOAD(hid.dll, HidD_GetSerialNumberString, TRUE);
DLL_LOAD(hid.dll, HidP_GetCaps, TRUE);
DLL_LOAD(hid.dll, HidD_SetNumInputBuffers, TRUE);
DLL_LOAD(hid.dll, HidD_SetFeature, TRUE);
DLL_LOAD(hid.dll, HidD_GetFeature, TRUE);
DLL_LOAD(hid.dll, HidD_GetPhysicalDescriptor, TRUE);
DLL_LOAD(hid.dll, HidD_GetInputReport, FALSE);
DLL_LOAD(hid.dll, HidD_SetOutputReport, FALSE);
DLL_LOAD(hid.dll, HidD_FlushQueue, TRUE);
DLL_LOAD(hid.dll, HidP_GetValueCaps, TRUE);
api_hid_available = true;
return LIBUSB_SUCCESS;
}
static int hid_exit(void)
{
return LIBUSB_SUCCESS;
}
// NB: open and close must ensure that they only handle interface of
// the right API type, as these functions can be called wholesale from
// composite_open(), with interfaces belonging to different APIs
static int hid_open(struct libusb_device_handle *dev_handle)
{
struct libusb_context *ctx = DEVICE_CTX(dev_handle->dev);
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(dev_handle);
HIDD_ATTRIBUTES hid_attributes;
PHIDP_PREPARSED_DATA preparsed_data = NULL;
HIDP_CAPS capabilities;
HIDP_VALUE_CAPS *value_caps;
HANDLE hid_handle = INVALID_HANDLE_VALUE;
int i, j;
// report IDs handling
ULONG size[3];
char* type[3] = {"input", "output", "feature"};
int nb_ids[2]; // zero and nonzero report IDs
CHECK_HID_AVAILABLE;
if (priv->hid == NULL) {
usbi_err(ctx, "program assertion failed - private HID structure is unitialized");
return LIBUSB_ERROR_NOT_FOUND;
}
for (i = 0; i < USB_MAXINTERFACES; i++) {
if ( (priv->usb_interface[i].path != NULL)
&& (priv->usb_interface[i].apib->id == USB_API_HID) ) {
hid_handle = CreateFileA(priv->usb_interface[i].path, GENERIC_WRITE | GENERIC_READ, FILE_SHARE_WRITE | FILE_SHARE_READ,
NULL, OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL | FILE_FLAG_OVERLAPPED, NULL);
/*
* http://www.lvr.com/hidfaq.htm: Why do I receive "Access denied" when attempting to access my HID?
* "Windows 2000 and later have exclusive read/write access to HIDs that are configured as a system
* keyboards or mice. An application can obtain a handle to a system keyboard or mouse by not
* requesting READ or WRITE access with CreateFile. Applications can then use HidD_SetFeature and
* HidD_GetFeature (if the device supports Feature reports)."
*/
if (hid_handle == INVALID_HANDLE_VALUE) {
usbi_warn(ctx, "could not open HID device in R/W mode (keyboard or mouse?) - trying without");
hid_handle = CreateFileA(priv->usb_interface[i].path, 0, FILE_SHARE_WRITE | FILE_SHARE_READ,
NULL, OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL | FILE_FLAG_OVERLAPPED, NULL);
if (hid_handle == INVALID_HANDLE_VALUE) {
usbi_err(ctx, "could not open device %s (interface %d): %s", priv->path, i, windows_error_str(0));
switch(GetLastError()) {
case ERROR_FILE_NOT_FOUND: // The device was disconnected
return LIBUSB_ERROR_NO_DEVICE;
case ERROR_ACCESS_DENIED:
return LIBUSB_ERROR_ACCESS;
default:
return LIBUSB_ERROR_IO;
}
}
priv->usb_interface[i].restricted_functionality = true;
}
handle_priv->interface_handle[i].api_handle = hid_handle;
}
}
hid_attributes.Size = sizeof(hid_attributes);
do {
if (!HidD_GetAttributes(hid_handle, &hid_attributes)) {
usbi_err(ctx, "could not gain access to HID top collection (HidD_GetAttributes)");
break;
}
priv->hid->vid = hid_attributes.VendorID;
priv->hid->pid = hid_attributes.ProductID;
// Set the maximum available input buffer size
for (i=32; HidD_SetNumInputBuffers(hid_handle, i); i*=2);
usbi_dbg("set maximum input buffer size to %d", i/2);
// Get the maximum input and output report size
if (!HidD_GetPreparsedData(hid_handle, &preparsed_data) || !preparsed_data) {
usbi_err(ctx, "could not read HID preparsed data (HidD_GetPreparsedData)");
break;
}
if (HidP_GetCaps(preparsed_data, &capabilities) != HIDP_STATUS_SUCCESS) {
usbi_err(ctx, "could not parse HID capabilities (HidP_GetCaps)");
break;
}
// Find out if interrupt will need report IDs
size[0] = capabilities.NumberInputValueCaps;
size[1] = capabilities.NumberOutputValueCaps;
size[2] = capabilities.NumberFeatureValueCaps;
for (j=0; j<3; j++) {
usbi_dbg("%d HID %s report value(s) found", size[j], type[j]);
priv->hid->uses_report_ids[j] = false;
if (size[j] > 0) {
value_caps = malloc(size[j] * sizeof(HIDP_VALUE_CAPS));
if ( (value_caps != NULL)
&& (HidP_GetValueCaps(j, value_caps, &size[j], preparsed_data) == HIDP_STATUS_SUCCESS)
&& (size[j] >= 1) ) {
nb_ids[0] = 0;
nb_ids[1] = 0;
for (i=0; i<(int)size[j]; i++) {
usbi_dbg(" Report ID: 0x%02X", value_caps[i].ReportID);
if (value_caps[i].ReportID != 0) {
nb_ids[1]++;
} else {
nb_ids[0]++;
}
}
if (nb_ids[1] != 0) {
if (nb_ids[0] != 0) {
usbi_warn(ctx, "program assertion failed: zero and nonzero report IDs used for %s",
type[j]);
}
priv->hid->uses_report_ids[j] = true;
}
} else {
usbi_warn(ctx, " could not process %s report IDs", type[j]);
}
safe_free(value_caps);
}
}
// Set the report sizes
priv->hid->input_report_size = capabilities.InputReportByteLength;
priv->hid->output_report_size = capabilities.OutputReportByteLength;
priv->hid->feature_report_size = capabilities.FeatureReportByteLength;
// Fetch string descriptors
priv->hid->string_index[0] = priv->dev_descriptor.iManufacturer;
if (priv->hid->string_index[0] != 0) {
HidD_GetManufacturerString(hid_handle, priv->hid->string[0],
sizeof(priv->hid->string[0]));
} else {
priv->hid->string[0][0] = 0;
}
priv->hid->string_index[1] = priv->dev_descriptor.iProduct;
if (priv->hid->string_index[1] != 0) {
HidD_GetProductString(hid_handle, priv->hid->string[1],
sizeof(priv->hid->string[1]));
} else {
priv->hid->string[1][0] = 0;
}
priv->hid->string_index[2] = priv->dev_descriptor.iSerialNumber;
if (priv->hid->string_index[2] != 0) {
HidD_GetSerialNumberString(hid_handle, priv->hid->string[2],
sizeof(priv->hid->string[2]));
} else {
priv->hid->string[2][0] = 0;
}
} while(0);
if (preparsed_data) {
HidD_FreePreparsedData(preparsed_data);
}
return LIBUSB_SUCCESS;
}
static void hid_close(struct libusb_device_handle *dev_handle)
{
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(dev_handle);
HANDLE file_handle;
int i;
if (!api_hid_available)
return;
for (i = 0; i < USB_MAXINTERFACES; i++) {
if (priv->usb_interface[i].apib->id == USB_API_HID) {
file_handle = handle_priv->interface_handle[i].api_handle;
if ( (file_handle != 0) && (file_handle != INVALID_HANDLE_VALUE)) {
CloseHandle(file_handle);
}
}
}
}
static int hid_claim_interface(struct libusb_device_handle *dev_handle, int iface)
{
struct windows_device_handle_priv *handle_priv = __device_handle_priv(dev_handle);
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
CHECK_HID_AVAILABLE;
// NB: Disconnection detection is not possible in this function
if (priv->usb_interface[iface].path == NULL) {
return LIBUSB_ERROR_NOT_FOUND; // invalid iface
}
// We use dev_handle as a flag for interface claimed
if (handle_priv->interface_handle[iface].dev_handle == INTERFACE_CLAIMED) {
return LIBUSB_ERROR_BUSY; // already claimed
}
handle_priv->interface_handle[iface].dev_handle = INTERFACE_CLAIMED;
usbi_dbg("claimed interface %d", iface);
handle_priv->active_interface = iface;
return LIBUSB_SUCCESS;
}
static int hid_release_interface(struct libusb_device_handle *dev_handle, int iface)
{
struct windows_device_handle_priv *handle_priv = __device_handle_priv(dev_handle);
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
CHECK_HID_AVAILABLE;
if (priv->usb_interface[iface].path == NULL) {
return LIBUSB_ERROR_NOT_FOUND; // invalid iface
}
if (handle_priv->interface_handle[iface].dev_handle != INTERFACE_CLAIMED) {
return LIBUSB_ERROR_NOT_FOUND; // invalid iface
}
handle_priv->interface_handle[iface].dev_handle = INVALID_HANDLE_VALUE;
return LIBUSB_SUCCESS;
}
static int hid_set_interface_altsetting(struct libusb_device_handle *dev_handle, int iface, int altsetting)
{
struct libusb_context *ctx = DEVICE_CTX(dev_handle->dev);
CHECK_HID_AVAILABLE;
if (altsetting > 255) {
return LIBUSB_ERROR_INVALID_PARAM;
}
if (altsetting != 0) {
usbi_err(ctx, "set interface altsetting not supported for altsetting >0");
return LIBUSB_ERROR_NOT_SUPPORTED;
}
return LIBUSB_SUCCESS;
}
static int hid_submit_control_transfer(struct usbi_transfer *itransfer)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct windows_transfer_priv *transfer_priv = usbi_transfer_get_os_priv(itransfer);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(transfer->dev_handle);
struct windows_device_priv *priv = __device_priv(transfer->dev_handle->dev);
struct libusb_context *ctx = DEVICE_CTX(transfer->dev_handle->dev);
WINUSB_SETUP_PACKET *setup = (WINUSB_SETUP_PACKET *) transfer->buffer;
HANDLE hid_handle;
struct winfd wfd;
int current_interface, config;
size_t size;
int r = LIBUSB_ERROR_INVALID_PARAM;
CHECK_HID_AVAILABLE;
transfer_priv->pollable_fd = INVALID_WINFD;
safe_free(transfer_priv->hid_buffer);
transfer_priv->hid_dest = NULL;
size = transfer->length - LIBUSB_CONTROL_SETUP_SIZE;
if (size > MAX_CTRL_BUFFER_LENGTH) {
return LIBUSB_ERROR_INVALID_PARAM;
}
current_interface = get_valid_interface(transfer->dev_handle, USB_API_HID);
if (current_interface < 0) {
#if defined(AUTO_CLAIM)
if (auto_claim(transfer, ¤t_interface, USB_API_HID) != LIBUSB_SUCCESS) {
return LIBUSB_ERROR_NOT_FOUND;
}
#else
usbi_warn(ctx, "no interface available for control transfer");
return LIBUSB_ERROR_NOT_FOUND;
#endif
}
usbi_dbg("will use interface %d", current_interface);
hid_handle = handle_priv->interface_handle[current_interface].api_handle;
// Always use the handle returned from usbi_create_fd (wfd.handle)
wfd = usbi_create_fd(hid_handle, _O_RDONLY);
if (wfd.fd < 0) {
return LIBUSB_ERROR_NO_MEM;
}
switch(LIBUSB_REQ_TYPE(setup->request_type)) {
case LIBUSB_REQUEST_TYPE_STANDARD:
switch(setup->request) {
case LIBUSB_REQUEST_GET_DESCRIPTOR:
r = _hid_get_descriptor(priv->hid, wfd.handle, LIBUSB_REQ_RECIPIENT(setup->request_type),
(setup->value >> 8) & 0xFF, setup->value & 0xFF, transfer->buffer + LIBUSB_CONTROL_SETUP_SIZE, &size);
break;
case LIBUSB_REQUEST_GET_CONFIGURATION:
r = windows_get_configuration(transfer->dev_handle, &config);
if (r == LIBUSB_SUCCESS) {
size = 1;
((uint8_t*)transfer->buffer)[LIBUSB_CONTROL_SETUP_SIZE] = (uint8_t)config;
r = LIBUSB_COMPLETED;
}
break;
case LIBUSB_REQUEST_SET_CONFIGURATION:
if (setup->value == priv->active_config) {
r = LIBUSB_COMPLETED;
} else {
usbi_warn(ctx, "cannot set configuration other than the default one");
r = LIBUSB_ERROR_INVALID_PARAM;
}
break;
case LIBUSB_REQUEST_GET_INTERFACE:
size = 1;
((uint8_t*)transfer->buffer)[LIBUSB_CONTROL_SETUP_SIZE] = 0;
r = LIBUSB_COMPLETED;
break;
case LIBUSB_REQUEST_SET_INTERFACE:
r = hid_set_interface_altsetting(transfer->dev_handle, setup->index, setup->value);
if (r == LIBUSB_SUCCESS) {
r = LIBUSB_COMPLETED;
}
break;
default:
usbi_warn(ctx, "unsupported HID control request");
r = LIBUSB_ERROR_INVALID_PARAM;
break;
}
break;
case LIBUSB_REQUEST_TYPE_CLASS:
r =_hid_class_request(priv->hid, wfd.handle, setup->request_type, setup->request, setup->value,
setup->index, transfer->buffer + LIBUSB_CONTROL_SETUP_SIZE, transfer_priv,
&size, wfd.overlapped);
break;
default:
usbi_warn(ctx, "unsupported HID control request");
r = LIBUSB_ERROR_INVALID_PARAM;
break;
}
if (r == LIBUSB_COMPLETED) {
// Force request to be completed synchronously. Transferred size has been set by previous call
wfd.overlapped->Internal = STATUS_COMPLETED_SYNCHRONOUSLY;
// http://msdn.microsoft.com/en-us/library/ms684342%28VS.85%29.aspx
// set InternalHigh to the number of bytes transferred
wfd.overlapped->InternalHigh = (DWORD)size;
r = LIBUSB_SUCCESS;
}
if (r == LIBUSB_SUCCESS) {
// Use priv_transfer to store data needed for async polling
transfer_priv->pollable_fd = wfd;
transfer_priv->interface_number = (uint8_t)current_interface;
} else {
usbi_free_fd(wfd.fd);
}
return r;
}
static int hid_submit_bulk_transfer(struct usbi_transfer *itransfer) {
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct windows_transfer_priv *transfer_priv = usbi_transfer_get_os_priv(itransfer);
struct libusb_context *ctx = DEVICE_CTX(transfer->dev_handle->dev);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(transfer->dev_handle);
struct windows_device_priv *priv = __device_priv(transfer->dev_handle->dev);
struct winfd wfd;
HANDLE hid_handle;
bool direction_in, ret;
int current_interface, length;
DWORD size;
int r = LIBUSB_SUCCESS;
CHECK_HID_AVAILABLE;
transfer_priv->pollable_fd = INVALID_WINFD;
transfer_priv->hid_dest = NULL;
safe_free(transfer_priv->hid_buffer);
current_interface = interface_by_endpoint(priv, handle_priv, transfer->endpoint);
if (current_interface < 0) {
usbi_err(ctx, "unable to match endpoint to an open interface - cancelling transfer");
return LIBUSB_ERROR_NOT_FOUND;
}
usbi_dbg("matched endpoint %02X with interface %d", transfer->endpoint, current_interface);
hid_handle = handle_priv->interface_handle[current_interface].api_handle;
direction_in = transfer->endpoint & LIBUSB_ENDPOINT_IN;
wfd = usbi_create_fd(hid_handle, direction_in?_O_RDONLY:_O_WRONLY);
// Always use the handle returned from usbi_create_fd (wfd.handle)
if (wfd.fd < 0) {
return LIBUSB_ERROR_NO_MEM;
}
// If report IDs are not in use, an extra prefix byte must be added
if ( ((direction_in) && (!priv->hid->uses_report_ids[0]))
|| ((!direction_in) && (!priv->hid->uses_report_ids[1])) ) {
length = transfer->length+1;
} else {
length = transfer->length;
}
// Add a trailing byte to detect overflows on input
transfer_priv->hid_buffer = (uint8_t*)calloc(length+1, 1);
if (transfer_priv->hid_buffer == NULL) {
return LIBUSB_ERROR_NO_MEM;
}
transfer_priv->hid_expected_size = length;
if (direction_in) {
transfer_priv->hid_dest = transfer->buffer;
usbi_dbg("reading %d bytes (report ID: 0x%02X)", length, transfer_priv->hid_buffer[0]);
ret = ReadFile(wfd.handle, transfer_priv->hid_buffer, length+1, &size, wfd.overlapped);
} else {
if (!priv->hid->uses_report_ids[1]) {
memcpy(transfer_priv->hid_buffer+1, transfer->buffer, transfer->length);
} else {
// We could actually do without the calloc and memcpy in this case
memcpy(transfer_priv->hid_buffer, transfer->buffer, transfer->length);
}
usbi_dbg("writing %d bytes (report ID: 0x%02X)", length, transfer_priv->hid_buffer[0]);
ret = WriteFile(wfd.handle, transfer_priv->hid_buffer, length, &size, wfd.overlapped);
}
if (!ret) {
if (GetLastError() != ERROR_IO_PENDING) {
usbi_err(ctx, "HID transfer failed: %s", windows_error_str(0));
usbi_free_fd(wfd.fd);
safe_free(transfer_priv->hid_buffer);
return LIBUSB_ERROR_IO;
}
} else {
// Only write operations that completed synchronously need to free up
// hid_buffer. For reads, copy_transfer_data() handles that process.
if (!direction_in) {
safe_free(transfer_priv->hid_buffer);
}
if (size == 0) {
usbi_err(ctx, "program assertion failed - no data was transferred");
size = 1;
}
if (size > (size_t)length) {
usbi_err(ctx, "OVERFLOW!");
r = LIBUSB_ERROR_OVERFLOW;
}
wfd.overlapped->Internal = STATUS_COMPLETED_SYNCHRONOUSLY;
wfd.overlapped->InternalHigh = size;
}
transfer_priv->pollable_fd = wfd;
transfer_priv->interface_number = (uint8_t)current_interface;
return r;
}
static int hid_abort_transfers(struct usbi_transfer *itransfer)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct windows_transfer_priv *transfer_priv = usbi_transfer_get_os_priv(itransfer);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(transfer->dev_handle);
HANDLE hid_handle;
int current_interface;
CHECK_HID_AVAILABLE;
current_interface = transfer_priv->interface_number;
hid_handle = handle_priv->interface_handle[current_interface].api_handle;
CancelIo(hid_handle);
return LIBUSB_SUCCESS;
}
static int hid_reset_device(struct libusb_device_handle *dev_handle)
{
struct windows_device_handle_priv *handle_priv = __device_handle_priv(dev_handle);
HANDLE hid_handle;
int current_interface;
CHECK_HID_AVAILABLE;
// Flushing the queues on all interfaces is the best we can achieve
for (current_interface = 0; current_interface < USB_MAXINTERFACES; current_interface++) {
hid_handle = handle_priv->interface_handle[current_interface].api_handle;
if ((hid_handle != 0) && (hid_handle != INVALID_HANDLE_VALUE)) {
HidD_FlushQueue(hid_handle);
}
}
return LIBUSB_SUCCESS;
}
static int hid_clear_halt(struct libusb_device_handle *dev_handle, unsigned char endpoint)
{
struct libusb_context *ctx = DEVICE_CTX(dev_handle->dev);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(dev_handle);
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
HANDLE hid_handle;
int current_interface;
CHECK_HID_AVAILABLE;
current_interface = interface_by_endpoint(priv, handle_priv, endpoint);
if (current_interface < 0) {
usbi_err(ctx, "unable to match endpoint to an open interface - cannot clear");
return LIBUSB_ERROR_NOT_FOUND;
}
usbi_dbg("matched endpoint %02X with interface %d", endpoint, current_interface);
hid_handle = handle_priv->interface_handle[current_interface].api_handle;
// No endpoint selection with Microsoft's implementation, so we try to flush the
// whole interface. Should be OK for most case scenarios
if (!HidD_FlushQueue(hid_handle)) {
usbi_err(ctx, "Flushing of HID queue failed: %s", windows_error_str(0));
// Device was probably disconnected
return LIBUSB_ERROR_NO_DEVICE;
}
return LIBUSB_SUCCESS;
}
// This extra function is only needed for HID
static int hid_copy_transfer_data(struct usbi_transfer *itransfer, uint32_t io_size) {
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct libusb_context *ctx = DEVICE_CTX(transfer->dev_handle->dev);
struct windows_transfer_priv *transfer_priv = usbi_transfer_get_os_priv(itransfer);
int r = LIBUSB_TRANSFER_COMPLETED;
uint32_t corrected_size = io_size;
if (transfer_priv->hid_buffer != NULL) {
// If we have a valid hid_buffer, it means the transfer was async
if (transfer_priv->hid_dest != NULL) { // Data readout
// First, check for overflow
if (corrected_size > transfer_priv->hid_expected_size) {
usbi_err(ctx, "OVERFLOW!");
corrected_size = (uint32_t)transfer_priv->hid_expected_size;
r = LIBUSB_TRANSFER_OVERFLOW;
}
if (transfer_priv->hid_buffer[0] == 0) {
// Discard the 1 byte report ID prefix
corrected_size--;
memcpy(transfer_priv->hid_dest, transfer_priv->hid_buffer+1, corrected_size);
} else {
memcpy(transfer_priv->hid_dest, transfer_priv->hid_buffer, corrected_size);
}
transfer_priv->hid_dest = NULL;
}
// For write, we just need to free the hid buffer
safe_free(transfer_priv->hid_buffer);
}
itransfer->transferred += corrected_size;
return r;
}
/*
* Composite API functions
*/
static int composite_init(struct libusb_context *ctx)
{
return LIBUSB_SUCCESS;
}
static int composite_exit(void)
{
return LIBUSB_SUCCESS;
}
static int composite_open(struct libusb_device_handle *dev_handle)
{
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
unsigned api;
int r;
uint8_t flag = 1<<USB_API_WINUSB;
for (api=USB_API_WINUSB; api<USB_API_MAX; api++) {
if (priv->composite_api_flags & flag) {
r = usb_api_backend[api].open(dev_handle);
if (r != LIBUSB_SUCCESS) {
return r;
}
}
flag <<= 1;
}
return LIBUSB_SUCCESS;
}
static void composite_close(struct libusb_device_handle *dev_handle)
{
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
unsigned api;
uint8_t flag = 1<<USB_API_WINUSB;
for (api=USB_API_WINUSB; api<USB_API_MAX; api++) {
if (priv->composite_api_flags & flag) {
usb_api_backend[api].close(dev_handle);
}
flag <<= 1;
}
}
static int composite_claim_interface(struct libusb_device_handle *dev_handle, int iface)
{
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
return priv->usb_interface[iface].apib->claim_interface(dev_handle, iface);
}
static int composite_set_interface_altsetting(struct libusb_device_handle *dev_handle, int iface, int altsetting)
{
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
return priv->usb_interface[iface].apib->set_interface_altsetting(dev_handle, iface, altsetting);
}
static int composite_release_interface(struct libusb_device_handle *dev_handle, int iface)
{
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
return priv->usb_interface[iface].apib->release_interface(dev_handle, iface);
}
static int composite_submit_control_transfer(struct usbi_transfer *itransfer)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct libusb_context *ctx = DEVICE_CTX(transfer->dev_handle->dev);
struct windows_device_priv *priv = __device_priv(transfer->dev_handle->dev);
int i, pass;
// Interface shouldn't matter for control, but it does in practice, with Windows'
// restrictions with regards to accessing HID keyboards and mice. Try a 2 pass approach
for (pass = 0; pass < 2; pass++) {
for (i=0; i<USB_MAXINTERFACES; i++) {
if (priv->usb_interface[i].path != NULL) {
if ((pass == 0) && (priv->usb_interface[i].restricted_functionality)) {
usbi_dbg("trying to skip restricted interface #%d (HID keyboard or mouse?)", i);
continue;
}
usbi_dbg("using interface %d", i);
return priv->usb_interface[i].apib->submit_control_transfer(itransfer);
}
}
}
usbi_err(ctx, "no libusb supported interfaces to complete request");
return LIBUSB_ERROR_NOT_FOUND;
}
static int composite_submit_bulk_transfer(struct usbi_transfer *itransfer) {
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct libusb_context *ctx = DEVICE_CTX(transfer->dev_handle->dev);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(transfer->dev_handle);
struct windows_device_priv *priv = __device_priv(transfer->dev_handle->dev);
int current_interface;
current_interface = interface_by_endpoint(priv, handle_priv, transfer->endpoint);
if (current_interface < 0) {
usbi_err(ctx, "unable to match endpoint to an open interface - cancelling transfer");
return LIBUSB_ERROR_NOT_FOUND;
}
return priv->usb_interface[current_interface].apib->submit_bulk_transfer(itransfer);
}
static int composite_submit_iso_transfer(struct usbi_transfer *itransfer) {
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct libusb_context *ctx = DEVICE_CTX(transfer->dev_handle->dev);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(transfer->dev_handle);
struct windows_device_priv *priv = __device_priv(transfer->dev_handle->dev);
int current_interface;
current_interface = interface_by_endpoint(priv, handle_priv, transfer->endpoint);
if (current_interface < 0) {
usbi_err(ctx, "unable to match endpoint to an open interface - cancelling transfer");
return LIBUSB_ERROR_NOT_FOUND;
}
return priv->usb_interface[current_interface].apib->submit_iso_transfer(itransfer);
}
static int composite_clear_halt(struct libusb_device_handle *dev_handle, unsigned char endpoint)
{
struct libusb_context *ctx = DEVICE_CTX(dev_handle->dev);
struct windows_device_handle_priv *handle_priv = __device_handle_priv(dev_handle);
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
int current_interface;
current_interface = interface_by_endpoint(priv, handle_priv, endpoint);
if (current_interface < 0) {
usbi_err(ctx, "unable to match endpoint to an open interface - cannot clear");
return LIBUSB_ERROR_NOT_FOUND;
}
return priv->usb_interface[current_interface].apib->clear_halt(dev_handle, endpoint);
}
static int composite_abort_control(struct usbi_transfer *itransfer)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct windows_transfer_priv *transfer_priv = usbi_transfer_get_os_priv(itransfer);
struct windows_device_priv *priv = __device_priv(transfer->dev_handle->dev);
return priv->usb_interface[transfer_priv->interface_number].apib->abort_control(itransfer);
}
static int composite_abort_transfers(struct usbi_transfer *itransfer)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct windows_transfer_priv *transfer_priv = usbi_transfer_get_os_priv(itransfer);
struct windows_device_priv *priv = __device_priv(transfer->dev_handle->dev);
return priv->usb_interface[transfer_priv->interface_number].apib->abort_transfers(itransfer);
}
static int composite_reset_device(struct libusb_device_handle *dev_handle)
{
struct windows_device_priv *priv = __device_priv(dev_handle->dev);
unsigned api;
int r;
uint8_t flag = 1<<USB_API_WINUSB;
for (api=USB_API_WINUSB; api<USB_API_MAX; api++) {
if (priv->composite_api_flags & flag) {
r = usb_api_backend[api].reset_device(dev_handle);
if (r != LIBUSB_SUCCESS) {
return r;
}
}
flag <<= 1;
}
return LIBUSB_SUCCESS;
}
static int composite_copy_transfer_data(struct usbi_transfer *itransfer, uint32_t io_size)
{
struct libusb_transfer *transfer = __USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
struct windows_transfer_priv *transfer_priv = usbi_transfer_get_os_priv(itransfer);
struct windows_device_priv *priv = __device_priv(transfer->dev_handle->dev);
return priv->usb_interface[transfer_priv->interface_number].apib->copy_transfer_data(itransfer, io_size);
}
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