/* * Raw Input * * Copyright 2012 Henri Verbeet * Copyright 2018 Zebediah Figura for CodeWeavers * * 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 St, Fifth Floor, Boston, MA 02110-1301, USA */ #if 0 #pragma makedep unix #endif #include #include #include "win32u_private.h" #include "ntuser_private.h" #define WIN32_NO_STATUS #include "winioctl.h" #include "ddk/hidclass.h" #include "wine/hid.h" #include "wine/server.h" #include "wine/debug.h" WINE_DEFAULT_DEBUG_CHANNEL(rawinput); #define WINE_MOUSE_HANDLE ((HANDLE)1) #define WINE_KEYBOARD_HANDLE ((HANDLE)2) #ifdef _WIN64 typedef RAWINPUTHEADER RAWINPUTHEADER64; typedef RAWINPUT RAWINPUT64; #else typedef struct { DWORD dwType; DWORD dwSize; ULONGLONG hDevice; ULONGLONG wParam; } RAWINPUTHEADER64; typedef struct { RAWINPUTHEADER64 header; union { RAWMOUSE mouse; RAWKEYBOARD keyboard; RAWHID hid; } data; } RAWINPUT64; #endif static struct rawinput_thread_data *get_rawinput_thread_data(void) { struct user_thread_info *thread_info = get_user_thread_info(); struct rawinput_thread_data *data = thread_info->rawinput; if (data) return data; data = thread_info->rawinput = calloc( 1, RAWINPUT_BUFFER_SIZE + sizeof(struct user_thread_info) ); return data; } static bool rawinput_from_hardware_message( RAWINPUT *rawinput, const struct hardware_msg_data *msg_data ) { SIZE_T size; rawinput->header.dwType = msg_data->rawinput.type; if (msg_data->rawinput.type == RIM_TYPEMOUSE) { static const unsigned int button_flags[] = { 0, /* MOUSEEVENTF_MOVE */ RI_MOUSE_LEFT_BUTTON_DOWN, /* MOUSEEVENTF_LEFTDOWN */ RI_MOUSE_LEFT_BUTTON_UP, /* MOUSEEVENTF_LEFTUP */ RI_MOUSE_RIGHT_BUTTON_DOWN, /* MOUSEEVENTF_RIGHTDOWN */ RI_MOUSE_RIGHT_BUTTON_UP, /* MOUSEEVENTF_RIGHTUP */ RI_MOUSE_MIDDLE_BUTTON_DOWN, /* MOUSEEVENTF_MIDDLEDOWN */ RI_MOUSE_MIDDLE_BUTTON_UP, /* MOUSEEVENTF_MIDDLEUP */ }; unsigned int i; rawinput->header.dwSize = FIELD_OFFSET(RAWINPUT, data) + sizeof(RAWMOUSE); rawinput->header.hDevice = WINE_MOUSE_HANDLE; rawinput->header.wParam = 0; rawinput->data.mouse.usFlags = MOUSE_MOVE_RELATIVE; rawinput->data.mouse.usButtonFlags = 0; rawinput->data.mouse.usButtonData = 0; for (i = 1; i < ARRAY_SIZE(button_flags); ++i) { if (msg_data->flags & (1 << i)) rawinput->data.mouse.usButtonFlags |= button_flags[i]; } if (msg_data->flags & MOUSEEVENTF_WHEEL) { rawinput->data.mouse.usButtonFlags |= RI_MOUSE_WHEEL; rawinput->data.mouse.usButtonData = msg_data->rawinput.mouse.data; } if (msg_data->flags & MOUSEEVENTF_HWHEEL) { rawinput->data.mouse.usButtonFlags |= RI_MOUSE_HORIZONTAL_WHEEL; rawinput->data.mouse.usButtonData = msg_data->rawinput.mouse.data; } if (msg_data->flags & MOUSEEVENTF_XDOWN) { if (msg_data->rawinput.mouse.data == XBUTTON1) rawinput->data.mouse.usButtonFlags |= RI_MOUSE_BUTTON_4_DOWN; else if (msg_data->rawinput.mouse.data == XBUTTON2) rawinput->data.mouse.usButtonFlags |= RI_MOUSE_BUTTON_5_DOWN; } if (msg_data->flags & MOUSEEVENTF_XUP) { if (msg_data->rawinput.mouse.data == XBUTTON1) rawinput->data.mouse.usButtonFlags |= RI_MOUSE_BUTTON_4_UP; else if (msg_data->rawinput.mouse.data == XBUTTON2) rawinput->data.mouse.usButtonFlags |= RI_MOUSE_BUTTON_5_UP; } rawinput->data.mouse.ulRawButtons = 0; rawinput->data.mouse.lLastX = msg_data->rawinput.mouse.x; rawinput->data.mouse.lLastY = msg_data->rawinput.mouse.y; rawinput->data.mouse.ulExtraInformation = msg_data->info; } else if (msg_data->rawinput.type == RIM_TYPEKEYBOARD) { rawinput->header.dwSize = FIELD_OFFSET(RAWINPUT, data) + sizeof(RAWKEYBOARD); rawinput->header.hDevice = WINE_KEYBOARD_HANDLE; rawinput->header.wParam = 0; rawinput->data.keyboard.MakeCode = msg_data->rawinput.kbd.scan; rawinput->data.keyboard.Flags = (msg_data->flags & KEYEVENTF_KEYUP) ? RI_KEY_BREAK : RI_KEY_MAKE; if (msg_data->flags & KEYEVENTF_EXTENDEDKEY) rawinput->data.keyboard.Flags |= RI_KEY_E0; rawinput->data.keyboard.Reserved = 0; switch (msg_data->rawinput.kbd.vkey) { case VK_LSHIFT: case VK_RSHIFT: rawinput->data.keyboard.VKey = VK_SHIFT; rawinput->data.keyboard.Flags &= ~RI_KEY_E0; break; case VK_LCONTROL: case VK_RCONTROL: rawinput->data.keyboard.VKey = VK_CONTROL; break; case VK_LMENU: case VK_RMENU: rawinput->data.keyboard.VKey = VK_MENU; break; default: rawinput->data.keyboard.VKey = msg_data->rawinput.kbd.vkey; break; } rawinput->data.keyboard.Message = msg_data->rawinput.kbd.message; rawinput->data.keyboard.ExtraInformation = msg_data->info; } else if (msg_data->rawinput.type == RIM_TYPEHID) { size = msg_data->size - sizeof(*msg_data); if (size > rawinput->header.dwSize - sizeof(*rawinput)) return false; rawinput->header.dwSize = FIELD_OFFSET( RAWINPUT, data.hid.bRawData ) + size; rawinput->header.hDevice = ULongToHandle( msg_data->rawinput.hid.device ); rawinput->header.wParam = 0; rawinput->data.hid.dwCount = msg_data->rawinput.hid.count; rawinput->data.hid.dwSizeHid = msg_data->rawinput.hid.length; memcpy( rawinput->data.hid.bRawData, msg_data + 1, size ); } else { FIXME( "Unhandled rawinput type %#x.\n", msg_data->rawinput.type ); return false; } return true; } struct device { HANDLE file; HANDLE handle; struct list entry; WCHAR path[MAX_PATH]; RID_DEVICE_INFO info; struct hid_preparsed_data *data; }; static RAWINPUTDEVICE *registered_devices; static unsigned int registered_device_count; static struct list devices = LIST_INIT( devices ); static pthread_mutex_t rawinput_mutex = PTHREAD_MUTEX_INITIALIZER; static struct device *add_device( HKEY key, DWORD type ) { static const WCHAR symbolic_linkW[] = {'S','y','m','b','o','l','i','c','L','i','n','k',0}; char value_buffer[offsetof(KEY_VALUE_PARTIAL_INFORMATION, Data[MAX_PATH * sizeof(WCHAR)])]; KEY_VALUE_PARTIAL_INFORMATION *value = (KEY_VALUE_PARTIAL_INFORMATION *)value_buffer; static const RID_DEVICE_INFO_KEYBOARD keyboard_info = {0, 0, 1, 12, 3, 101}; static const RID_DEVICE_INFO_MOUSE mouse_info = {1, 5, 0, FALSE}; struct hid_preparsed_data *preparsed = NULL; HID_COLLECTION_INFORMATION hid_info; IO_STATUS_BLOCK io = {{0}}; OBJECT_ATTRIBUTES attr; UNICODE_STRING string; struct device *device; RID_DEVICE_INFO info; unsigned int status; UINT32 handle; void *buffer; SIZE_T size; HANDLE file; WCHAR *path; if (!query_reg_value( key, symbolic_linkW, value, sizeof(value_buffer) - sizeof(WCHAR) )) { ERR( "failed to get symbolic link value\n" ); return NULL; } memset( value->Data + value->DataLength, 0, sizeof(WCHAR) ); /* upper case everything but the GUID */ for (path = (WCHAR *)value->Data; *path && *path != '{'; path++) *path = towupper( *path ); path = (WCHAR *)value->Data; /* path is in DOS format and begins with \\?\ prefix */ path[1] = '?'; RtlInitUnicodeString( &string, path ); InitializeObjectAttributes( &attr, &string, OBJ_CASE_INSENSITIVE, NULL, NULL ); if ((status = NtOpenFile( &file, GENERIC_READ | GENERIC_WRITE | SYNCHRONIZE, &attr, &io, FILE_SHARE_READ | FILE_SHARE_WRITE, FILE_SYNCHRONOUS_IO_NONALERT ))) { WARN( "Failed to open device file %s, status %#x.\n", debugstr_w(path), status ); return NULL; } path[1] = '\\'; status = NtDeviceIoControlFile( file, NULL, NULL, NULL, &io, IOCTL_HID_GET_WINE_RAWINPUT_HANDLE, NULL, 0, &handle, sizeof(handle) ); if (status) { ERR( "Failed to get raw input handle, status %#x.\n", status ); goto fail; } LIST_FOR_EACH_ENTRY( device, &devices, struct device, entry ) { if (device->handle == UlongToHandle( handle )) { TRACE( "Ignoring already added device %#x / %s.\n", handle, debugstr_w(path) ); goto fail; } } memset( &info, 0, sizeof(info) ); info.cbSize = sizeof(info); info.dwType = type; switch (type) { case RIM_TYPEHID: status = NtDeviceIoControlFile( file, NULL, NULL, NULL, &io, IOCTL_HID_GET_COLLECTION_INFORMATION, NULL, 0, &hid_info, sizeof(hid_info) ); if (status) { ERR( "Failed to get collection information, status %#x.\n", status ); goto fail; } info.hid.dwVendorId = hid_info.VendorID; info.hid.dwProductId = hid_info.ProductID; info.hid.dwVersionNumber = hid_info.VersionNumber; if (!(preparsed = malloc( hid_info.DescriptorSize ))) { ERR( "Failed to allocate memory.\n" ); goto fail; } /* NtDeviceIoControlFile checks that the output buffer is writable using ntdll virtual * memory protection information, we need an NtAllocateVirtualMemory allocated buffer. */ buffer = NULL; size = hid_info.DescriptorSize; if (!(status = NtAllocateVirtualMemory( GetCurrentProcess(), &buffer, 0, &size, MEM_RESERVE|MEM_COMMIT, PAGE_READWRITE ))) { size = 0; status = NtDeviceIoControlFile( file, NULL, NULL, NULL, &io, IOCTL_HID_GET_COLLECTION_DESCRIPTOR, NULL, 0, buffer, hid_info.DescriptorSize ); if (!status) memcpy( preparsed, buffer, hid_info.DescriptorSize ); NtFreeVirtualMemory( GetCurrentProcess(), &buffer, &size, MEM_RELEASE ); } if (status) { ERR( "Failed to get collection descriptor, status %#x.\n", status ); goto fail; } info.hid.usUsagePage = preparsed->usage_page; info.hid.usUsage = preparsed->usage; break; case RIM_TYPEMOUSE: info.mouse = mouse_info; break; case RIM_TYPEKEYBOARD: info.keyboard = keyboard_info; break; } if (!(device = calloc( 1, sizeof(*device) ))) { ERR( "Failed to allocate memory.\n" ); goto fail; } TRACE( "Adding device %#x / %s.\n", handle, debugstr_w(path) ); wcscpy( device->path, path ); device->file = file; device->handle = ULongToHandle(handle); device->info = info; device->data = preparsed; list_add_tail( &devices, &device->entry ); return device; fail: free( preparsed ); NtClose( file ); return NULL; } static const WCHAR device_classesW[] = { '\\','R','e','g','i','s','t','r','y', '\\','M','a','c','h','i','n','e', '\\','S','y','s','t','e','m', '\\','C','u','r','r','e','n','t','C','o','n','t','r','o','l','S','e','t', '\\','C','o','n','t','r','o','l', '\\','D','e','v','i','c','e','C','l','a','s','s','e','s','\\',0 }; static const WCHAR guid_devinterface_hidW[] = { '{','4','d','1','e','5','5','b','2','-','f','1','6','f','-','1','1','c','f', '-','8','8','c','b','-','0','0','1','1','1','1','0','0','0','0','3','0','}',0 }; static const WCHAR guid_devinterface_keyboardW[] = { '{','8','8','4','b','9','6','c','3','-','5','6','e','f','-','1','1','d','1', '-','b','c','8','c','-','0','0','a','0','c','9','1','4','0','5','d','d','}',0 }; static const WCHAR guid_devinterface_mouseW[] = { '{','3','7','8','d','e','4','4','c','-','5','6','e','f','-','1','1','d','1', '-','b','c','8','c','-','0','0','a','0','c','9','1','4','0','5','d','d','}',0 }; static void enumerate_devices( DWORD type, const WCHAR *class ) { WCHAR buffer[1024]; KEY_NODE_INFORMATION *subkey_info = (void *)buffer; HKEY class_key, device_key, iface_key; unsigned int i, j; DWORD size; wcscpy( buffer, device_classesW ); wcscat( buffer, class ); if (!(class_key = reg_open_key( NULL, buffer, wcslen( buffer ) * sizeof(WCHAR) ))) return; for (i = 0; !NtEnumerateKey( class_key, i, KeyNodeInformation, buffer, sizeof(buffer), &size ); ++i) { if (!(device_key = reg_open_key( class_key, subkey_info->Name, subkey_info->NameLength ))) { ERR( "failed to open %s\n", debugstr_wn(subkey_info->Name, subkey_info->NameLength / sizeof(WCHAR)) ); continue; } for (j = 0; !NtEnumerateKey( device_key, j, KeyNodeInformation, buffer, sizeof(buffer), &size ); ++j) { if (!(iface_key = reg_open_key( device_key, subkey_info->Name, subkey_info->NameLength ))) { ERR( "failed to open %s\n", debugstr_wn(subkey_info->Name, subkey_info->NameLength / sizeof(WCHAR)) ); continue; } add_device( iface_key, type ); NtClose( iface_key ); } NtClose( device_key ); } NtClose( class_key ); } static void rawinput_update_device_list(void) { struct device *device, *next; TRACE( "\n" ); LIST_FOR_EACH_ENTRY_SAFE( device, next, &devices, struct device, entry ) { list_remove( &device->entry ); NtClose( device->file ); free( device->data ); free( device ); } enumerate_devices( RIM_TYPEMOUSE, guid_devinterface_mouseW ); enumerate_devices( RIM_TYPEKEYBOARD, guid_devinterface_keyboardW ); enumerate_devices( RIM_TYPEHID, guid_devinterface_hidW ); } static struct device *find_device_from_handle( HANDLE handle ) { struct device *device; LIST_FOR_EACH_ENTRY( device, &devices, struct device, entry ) if (device->handle == handle) return device; rawinput_update_device_list(); LIST_FOR_EACH_ENTRY( device, &devices, struct device, entry ) if (device->handle == handle) return device; return NULL; } BOOL rawinput_device_get_usages( HANDLE handle, USAGE *usage_page, USAGE *usage ) { struct device *device; pthread_mutex_lock( &rawinput_mutex ); if (!(device = find_device_from_handle( handle )) || device->info.dwType != RIM_TYPEHID) *usage_page = *usage = 0; else { *usage_page = device->info.hid.usUsagePage; *usage = device->info.hid.usUsage; } pthread_mutex_unlock( &rawinput_mutex ); return *usage_page || *usage; } /********************************************************************** * NtUserGetRawInputDeviceList (win32u.@) */ UINT WINAPI NtUserGetRawInputDeviceList( RAWINPUTDEVICELIST *device_list, UINT *device_count, UINT size ) { unsigned int count = 0, ticks = NtGetTickCount(); static unsigned int last_check; struct device *device; TRACE( "device_list %p, device_count %p, size %u.\n", device_list, device_count, size ); if (size != sizeof(*device_list)) { RtlSetLastWin32Error( ERROR_INVALID_PARAMETER ); return ~0u; } if (!device_count) { RtlSetLastWin32Error( ERROR_NOACCESS ); return ~0u; } pthread_mutex_lock( &rawinput_mutex ); if (ticks - last_check > 2000) { last_check = ticks; rawinput_update_device_list(); } LIST_FOR_EACH_ENTRY( device, &devices, struct device, entry ) { if (*device_count < ++count || !device_list) continue; device_list->hDevice = device->handle; device_list->dwType = device->info.dwType; device_list++; } pthread_mutex_unlock( &rawinput_mutex ); if (!device_list) { *device_count = count; return 0; } if (*device_count < count) { RtlSetLastWin32Error( ERROR_INSUFFICIENT_BUFFER ); *device_count = count; return ~0u; } return count; } /********************************************************************** * NtUserGetRawInputDeviceInfo (win32u.@) */ UINT WINAPI NtUserGetRawInputDeviceInfo( HANDLE handle, UINT command, void *data, UINT *data_size ) { const struct hid_preparsed_data *preparsed; struct device *device; RID_DEVICE_INFO info; DWORD len, data_len; TRACE( "handle %p, command %#x, data %p, data_size %p.\n", handle, command, data, data_size ); if (!data_size) { RtlSetLastWin32Error( ERROR_NOACCESS ); return ~0u; } if (command != RIDI_DEVICENAME && command != RIDI_DEVICEINFO && command != RIDI_PREPARSEDDATA) { FIXME( "Command %#x not implemented!\n", command ); RtlSetLastWin32Error( ERROR_INVALID_PARAMETER ); return ~0u; } pthread_mutex_lock( &rawinput_mutex ); if (!(device = find_device_from_handle( handle ))) { pthread_mutex_unlock( &rawinput_mutex ); RtlSetLastWin32Error( ERROR_INVALID_HANDLE ); return ~0u; } len = data_len = *data_size; switch (command) { case RIDI_DEVICENAME: if ((len = wcslen( device->path ) + 1) <= data_len && data) memcpy( data, device->path, len * sizeof(WCHAR) ); *data_size = len; break; case RIDI_DEVICEINFO: if ((len = sizeof(info)) <= data_len && data) memcpy( data, &device->info, len ); *data_size = len; break; case RIDI_PREPARSEDDATA: if (!(preparsed = device->data)) len = 0; else len = preparsed->caps_size + FIELD_OFFSET(struct hid_preparsed_data, value_caps[0]) + preparsed->number_link_collection_nodes * sizeof(struct hid_collection_node); if (preparsed && len <= data_len && data) memcpy( data, preparsed, len ); *data_size = len; break; } pthread_mutex_unlock( &rawinput_mutex ); if (!data) return 0; if (data_len < len) { RtlSetLastWin32Error( ERROR_INSUFFICIENT_BUFFER ); return ~0u; } return *data_size; } /********************************************************************** * NtUserGetRawInputBuffer (win32u.@) */ UINT WINAPI NtUserGetRawInputBuffer( RAWINPUT *data, UINT *data_size, UINT header_size ) { unsigned int count = 0, remaining, rawinput_size, next_size, overhead; struct rawinput_thread_data *thread_data; struct hardware_msg_data *msg_data; RAWINPUT *rawinput; int i; if (NtCurrentTeb()->WowTebOffset) rawinput_size = sizeof(RAWINPUT64); else rawinput_size = sizeof(RAWINPUT); overhead = rawinput_size - sizeof(RAWINPUT); if (header_size != sizeof(RAWINPUTHEADER)) { WARN( "Invalid structure size %u.\n", header_size ); RtlSetLastWin32Error( ERROR_INVALID_PARAMETER ); return ~0u; } if (!data_size) { RtlSetLastWin32Error( ERROR_INVALID_PARAMETER ); return ~0u; } if (!data) { TRACE( "data %p, data_size %p (%u), header_size %u\n", data, data_size, *data_size, header_size ); SERVER_START_REQ( get_rawinput_buffer ) { req->rawinput_size = rawinput_size; req->buffer_size = 0; if (wine_server_call( req )) return ~0u; *data_size = reply->next_size; } SERVER_END_REQ; return 0; } if (!(thread_data = get_rawinput_thread_data())) return ~0u; rawinput = thread_data->buffer; /* first RAWINPUT block in the buffer is used for WM_INPUT message data */ msg_data = (struct hardware_msg_data *)NEXTRAWINPUTBLOCK(rawinput); SERVER_START_REQ( get_rawinput_buffer ) { req->rawinput_size = rawinput_size; req->buffer_size = *data_size; wine_server_set_reply( req, msg_data, RAWINPUT_BUFFER_SIZE - rawinput->header.dwSize ); if (wine_server_call( req )) return ~0u; next_size = reply->next_size; count = reply->count; } SERVER_END_REQ; remaining = *data_size; for (i = 0; i < count; ++i) { data->header.dwSize = remaining; if (!rawinput_from_hardware_message( data, msg_data )) break; if (overhead) { /* Under WoW64, GetRawInputBuffer always gives 64-bit RAWINPUT structs. */ RAWINPUT64 *ri64 = (RAWINPUT64 *)data; memmove( (char *)&data->data + overhead, &data->data, data->header.dwSize - sizeof(RAWINPUTHEADER) ); ri64->header.dwSize += overhead; /* Need to copy wParam before hDevice so it's not overwritten. */ ri64->header.wParam = data->header.wParam; #ifdef _WIN64 ri64->header.hDevice = data->header.hDevice; #else ri64->header.hDevice = HandleToULong(data->header.hDevice); #endif } remaining -= data->header.dwSize; data = NEXTRAWINPUTBLOCK(data); msg_data = (struct hardware_msg_data *)((char *)msg_data + msg_data->size); } if (!next_size) { if (!count) *data_size = 0; else next_size = rawinput_size; } if (next_size && *data_size <= next_size) { RtlSetLastWin32Error( ERROR_INSUFFICIENT_BUFFER ); *data_size = next_size; count = ~0u; } TRACE( "data %p, data_size %p (%u), header_size %u, count %u\n", data, data_size, *data_size, header_size, count ); return count; } /********************************************************************** * NtUserGetRawInputData (win32u.@) */ UINT WINAPI NtUserGetRawInputData( HRAWINPUT rawinput, UINT command, void *data, UINT *data_size, UINT header_size ) { struct rawinput_thread_data *thread_data; UINT size; TRACE( "rawinput %p, command %#x, data %p, data_size %p, header_size %u.\n", rawinput, command, data, data_size, header_size ); if (!(thread_data = get_rawinput_thread_data())) { RtlSetLastWin32Error( ERROR_OUTOFMEMORY ); return ~0u; } if (!rawinput || thread_data->hw_id != (UINT_PTR)rawinput) { RtlSetLastWin32Error( ERROR_INVALID_HANDLE ); return ~0u; } if (header_size != sizeof(RAWINPUTHEADER)) { WARN( "Invalid structure size %u.\n", header_size ); RtlSetLastWin32Error( ERROR_INVALID_PARAMETER ); return ~0u; } switch (command) { case RID_INPUT: size = thread_data->buffer->header.dwSize; break; case RID_HEADER: size = sizeof(RAWINPUTHEADER); break; default: RtlSetLastWin32Error( ERROR_INVALID_PARAMETER ); return ~0u; } if (!data) { *data_size = size; return 0; } if (*data_size < size) { RtlSetLastWin32Error( ERROR_INSUFFICIENT_BUFFER ); return ~0u; } memcpy( data, thread_data->buffer, size ); return size; } BOOL process_rawinput_message( MSG *msg, UINT hw_id, const struct hardware_msg_data *msg_data ) { struct rawinput_thread_data *thread_data; if (!(thread_data = get_rawinput_thread_data())) return FALSE; if (msg->message == WM_INPUT_DEVICE_CHANGE) { pthread_mutex_lock( &rawinput_mutex ); rawinput_update_device_list(); pthread_mutex_unlock( &rawinput_mutex ); } else { thread_data->buffer->header.dwSize = RAWINPUT_BUFFER_SIZE; if (!rawinput_from_hardware_message( thread_data->buffer, msg_data )) return FALSE; thread_data->hw_id = hw_id; msg->lParam = (LPARAM)hw_id; } msg->pt = point_phys_to_win_dpi( msg->hwnd, msg->pt ); return TRUE; } static void register_rawinput_device( const RAWINPUTDEVICE *device ) { RAWINPUTDEVICE *pos, *end; for (pos = registered_devices, end = pos + registered_device_count; pos != end; pos++) { if (pos->usUsagePage < device->usUsagePage) continue; if (pos->usUsagePage > device->usUsagePage) break; if (pos->usUsage >= device->usUsage) break; } if (device->dwFlags & RIDEV_REMOVE) { if (pos != end && pos->usUsagePage == device->usUsagePage && pos->usUsage == device->usUsage) { memmove( pos, pos + 1, (char *)end - (char *)(pos + 1) ); registered_device_count--; } } else { if (pos == end || pos->usUsagePage != device->usUsagePage || pos->usUsage != device->usUsage) { memmove( pos + 1, pos, (char *)end - (char *)pos ); registered_device_count++; } *pos = *device; } } /********************************************************************** * NtUserRegisterRawInputDevices (win32u.@) */ BOOL WINAPI NtUserRegisterRawInputDevices( const RAWINPUTDEVICE *devices, UINT device_count, UINT device_size ) { struct rawinput_device *server_devices; RAWINPUTDEVICE *new_registered_devices; SIZE_T size; BOOL ret; UINT i; TRACE( "devices %p, device_count %u, device_size %u.\n", devices, device_count, device_size ); if (device_size != sizeof(RAWINPUTDEVICE)) { RtlSetLastWin32Error( ERROR_INVALID_PARAMETER ); return FALSE; } for (i = 0; i < device_count; ++i) { TRACE( "device %u: page %#x, usage %#x, flags %#x, target %p.\n", i, devices[i].usUsagePage, devices[i].usUsage, (int)devices[i].dwFlags, devices[i].hwndTarget ); if ((devices[i].dwFlags & RIDEV_INPUTSINK) && !devices[i].hwndTarget) { RtlSetLastWin32Error( ERROR_INVALID_PARAMETER ); return FALSE; } if ((devices[i].dwFlags & RIDEV_REMOVE) && devices[i].hwndTarget) { RtlSetLastWin32Error( ERROR_INVALID_PARAMETER ); return FALSE; } if (devices[i].dwFlags & ~(RIDEV_REMOVE|RIDEV_NOLEGACY|RIDEV_INPUTSINK|RIDEV_DEVNOTIFY)) FIXME( "Unhandled flags %#x for device %u.\n", (int)devices[i].dwFlags, i ); } pthread_mutex_lock( &rawinput_mutex ); if (!registered_device_count && !device_count) { pthread_mutex_unlock( &rawinput_mutex ); return TRUE; } size = (SIZE_T)device_size * (registered_device_count + device_count); if (!(new_registered_devices = realloc( registered_devices, size ))) { pthread_mutex_unlock( &rawinput_mutex ); RtlSetLastWin32Error( ERROR_OUTOFMEMORY ); return FALSE; } registered_devices = new_registered_devices; for (i = 0; i < device_count; ++i) register_rawinput_device( devices + i ); if (!(device_count = registered_device_count)) server_devices = NULL; else if (!(server_devices = malloc( device_count * sizeof(*server_devices) ))) { pthread_mutex_unlock( &rawinput_mutex ); RtlSetLastWin32Error( ERROR_OUTOFMEMORY ); return FALSE; } for (i = 0; i < device_count; ++i) { server_devices[i].usage_page = registered_devices[i].usUsagePage; server_devices[i].usage = registered_devices[i].usUsage; server_devices[i].flags = registered_devices[i].dwFlags; server_devices[i].target = wine_server_user_handle( registered_devices[i].hwndTarget ); } SERVER_START_REQ( update_rawinput_devices ) { wine_server_add_data( req, server_devices, device_count * sizeof(*server_devices) ); ret = !wine_server_call_err( req ); } SERVER_END_REQ; free( server_devices ); pthread_mutex_unlock( &rawinput_mutex ); return ret; } /********************************************************************** * NtUserGetRegisteredRawInputDevices (win32u.@) */ UINT WINAPI NtUserGetRegisteredRawInputDevices( RAWINPUTDEVICE *devices, UINT *device_count, UINT device_size ) { SIZE_T size, capacity; TRACE( "devices %p, device_count %p, device_size %u\n", devices, device_count, device_size ); if (device_size != sizeof(RAWINPUTDEVICE) || !device_count || (devices && !*device_count)) { RtlSetLastWin32Error( ERROR_INVALID_PARAMETER ); return ~0u; } pthread_mutex_lock( &rawinput_mutex ); capacity = *device_count * device_size; *device_count = registered_device_count; size = (SIZE_T)device_size * *device_count; if (devices && capacity >= size) memcpy( devices, registered_devices, size ); pthread_mutex_unlock( &rawinput_mutex ); if (!devices) return 0; if (capacity < size) { RtlSetLastWin32Error( ERROR_INSUFFICIENT_BUFFER ); return ~0u; } return *device_count; }