#include #include #include "streaming/session.h" #include "settings/mappingmanager.h" #include "path.h" #include #include #define VK_0 0x30 #define VK_A 0x41 // These are real Windows VK_* codes #ifndef VK_F1 #define VK_F1 0x70 #define VK_F13 0x7C #define VK_NUMPAD0 0x60 #endif #define MOUSE_POLLING_INTERVAL 5 // How long the mouse button will be pressed for a tap to click gesture #define TAP_BUTTON_RELEASE_DELAY 100 // How long the fingers must be stationary to start a drag #define DRAG_ACTIVATION_DELAY 650 // How far the finger can move before it cancels a drag or tap #define DEAD_ZONE_DELTA 0.1f const int SdlInputHandler::k_ButtonMap[] = { A_FLAG, B_FLAG, X_FLAG, Y_FLAG, BACK_FLAG, SPECIAL_FLAG, PLAY_FLAG, LS_CLK_FLAG, RS_CLK_FLAG, LB_FLAG, RB_FLAG, UP_FLAG, DOWN_FLAG, LEFT_FLAG, RIGHT_FLAG }; SdlInputHandler::SdlInputHandler(StreamingPreferences& prefs, NvComputer*, int streamWidth, int streamHeight) : m_MultiController(prefs.multiController), m_MouseMoveTimer(0), m_LeftButtonReleaseTimer(0), m_RightButtonReleaseTimer(0), m_DragTimer(0), m_DragButton(0), m_NumFingersDown(0), m_StreamWidth(streamWidth), m_StreamHeight(streamHeight) { // Allow gamepad input when the app doesn't have focus SDL_SetHint(SDL_HINT_JOYSTICK_ALLOW_BACKGROUND_EVENTS, "1"); // If mouse acceleration is enabled, use relative mode warp (which // is via normal motion events that are influenced by mouse acceleration). // Otherwise, we'll use raw input capture which is straight from the device // without modification by the OS. SDL_SetHintWithPriority(SDL_HINT_MOUSE_RELATIVE_MODE_WARP, prefs.mouseAcceleration ? "1" : "0", SDL_HINT_OVERRIDE); // We must initialize joystick explicitly before gamecontroller in order // to ensure we receive gamecontroller attach events for gamepads where // SDL doesn't have a built-in mapping. By starting joystick first, we // can allow mapping manager to update the mappings before GC attach // events are generated. SDL_assert(!SDL_WasInit(SDL_INIT_JOYSTICK)); if (SDL_InitSubSystem(SDL_INIT_JOYSTICK) != 0) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "SDL_InitSubSystem(SDL_INIT_JOYSTICK) failed: %s", SDL_GetError()); } MappingManager mappingManager; mappingManager.applyMappings(); // We need to reinit this each time, since you only get // an initial set of gamepad arrival events once per init. SDL_assert(!SDL_WasInit(SDL_INIT_GAMECONTROLLER)); if (SDL_InitSubSystem(SDL_INIT_GAMECONTROLLER) != 0) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "SDL_InitSubSystem(SDL_INIT_GAMECONTROLLER) failed: %s", SDL_GetError()); } SDL_assert(!SDL_WasInit(SDL_INIT_HAPTIC)); if (SDL_InitSubSystem(SDL_INIT_HAPTIC) != 0) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "SDL_InitSubSystem(SDL_INIT_HAPTIC) failed: %s", SDL_GetError()); } // Initialize the gamepad mask with currently attached gamepads to avoid // causing gamepads to unexpectedly disappear and reappear on the host // during stream startup as we detect currently attached gamepads one at a time. m_GamepadMask = getAttachedGamepadMask(); SDL_zero(m_GamepadState); SDL_zero(m_TouchDownEvent); SDL_zero(m_CumulativeDelta); SDL_AtomicSet(&m_MouseDeltaX, 0); SDL_AtomicSet(&m_MouseDeltaY, 0); m_MouseMoveTimer = SDL_AddTimer(MOUSE_POLLING_INTERVAL, SdlInputHandler::mouseMoveTimerCallback, this); } SdlInputHandler::~SdlInputHandler() { for (int i = 0; i < MAX_GAMEPADS; i++) { if (m_GamepadState[i].haptic != nullptr) { SDL_HapticClose(m_GamepadState[i].haptic); } if (m_GamepadState[i].controller != nullptr) { SDL_GameControllerClose(m_GamepadState[i].controller); } } SDL_RemoveTimer(m_MouseMoveTimer); SDL_RemoveTimer(m_LeftButtonReleaseTimer); SDL_RemoveTimer(m_RightButtonReleaseTimer); SDL_RemoveTimer(m_DragTimer); SDL_QuitSubSystem(SDL_INIT_HAPTIC); SDL_assert(!SDL_WasInit(SDL_INIT_HAPTIC)); SDL_QuitSubSystem(SDL_INIT_GAMECONTROLLER); SDL_assert(!SDL_WasInit(SDL_INIT_GAMECONTROLLER)); SDL_QuitSubSystem(SDL_INIT_JOYSTICK); SDL_assert(!SDL_WasInit(SDL_INIT_JOYSTICK)); // Return background event handling to off SDL_SetHint(SDL_HINT_JOYSTICK_ALLOW_BACKGROUND_EVENTS, "0"); } void SdlInputHandler::handleKeyEvent(SDL_KeyboardEvent* event) { short keyCode; char modifiers; // Check for our special key combos if ((event->state == SDL_PRESSED) && (event->keysym.mod & KMOD_CTRL) && (event->keysym.mod & KMOD_ALT) && (event->keysym.mod & KMOD_SHIFT)) { // First we test the SDLK combos for matches, // that way we ensure that latin keyboard users // can match to the key they see on their keyboards. // If nothing matches that, we'll then go on to // checking scancodes so non-latin keyboard users // can have working hotkeys (though possibly in // odd positions). We must do all SDLK tests before // any scancode tests to avoid issues in cases // where the SDLK for one shortcut collides with // the scancode of another. // Check for quit combo (Ctrl+Alt+Shift+Q) if (event->keysym.sym == SDLK_q) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Detected quit key combo (SDLK)"); // Push a quit event to the main loop SDL_Event event; event.type = SDL_QUIT; event.quit.timestamp = SDL_GetTicks(); SDL_PushEvent(&event); return; } // Check for the unbind combo (Ctrl+Alt+Shift+Z) else if (event->keysym.sym == SDLK_z) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Detected mouse capture toggle combo (SDLK)"); // Stop handling future input SDL_SetRelativeMouseMode((SDL_bool)!SDL_GetRelativeMouseMode()); // Force raise all keys to ensure they aren't stuck, // since we won't get their key up events. raiseAllKeys(); return; } else if (event->keysym.sym == SDLK_x) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Detected full-screen toggle combo (SDLK)"); Session::s_ActiveSession->toggleFullscreen(); // Force raise all keys just be safe across this full-screen/windowed // transition just in case key events get lost. raiseAllKeys(); return; } else if (event->keysym.sym == SDLK_s) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Detected stats toggle combo (SDLK)"); // Toggle the stats overlay Session::get()->getOverlayManager().setOverlayState(Overlay::OverlayDebug, !Session::get()->getOverlayManager().isOverlayEnabled(Overlay::OverlayDebug)); // Force raise all keys just be safe across this full-screen/windowed // transition just in case key events get lost. raiseAllKeys(); return; } // Check for quit combo (Ctrl+Alt+Shift+Q) else if (event->keysym.scancode == SDL_SCANCODE_Q) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Detected quit key combo (scancode)"); // Push a quit event to the main loop SDL_Event event; event.type = SDL_QUIT; event.quit.timestamp = SDL_GetTicks(); SDL_PushEvent(&event); return; } // Check for the unbind combo (Ctrl+Alt+Shift+Z) else if (event->keysym.scancode == SDL_SCANCODE_Z) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Detected mouse capture toggle combo (scancode)"); // Stop handling future input SDL_SetRelativeMouseMode((SDL_bool)!SDL_GetRelativeMouseMode()); // Force raise all keys to ensure they aren't stuck, // since we won't get their key up events. raiseAllKeys(); return; } // Check for the full-screen combo (Ctrl+Alt+Shift+X) else if (event->keysym.scancode == SDL_SCANCODE_X) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Detected full-screen toggle combo (scancode)"); Session::s_ActiveSession->toggleFullscreen(); // Force raise all keys just be safe across this full-screen/windowed // transition just in case key events get lost. raiseAllKeys(); return; } else if (event->keysym.scancode == SDL_SCANCODE_S) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Detected stats toggle combo (scancode)"); // Toggle the stats overlay Session::get()->getOverlayManager().setOverlayState(Overlay::OverlayDebug, !Session::get()->getOverlayManager().isOverlayEnabled(Overlay::OverlayDebug)); // Force raise all keys just be safe across this full-screen/windowed // transition just in case key events get lost. raiseAllKeys(); return; } } if (!SDL_GetRelativeMouseMode()) { // Not capturing return; } // Set modifier flags modifiers = 0; if (event->keysym.mod & KMOD_CTRL) { modifiers |= MODIFIER_CTRL; } if (event->keysym.mod & KMOD_ALT) { modifiers |= MODIFIER_ALT; } if (event->keysym.mod & KMOD_SHIFT) { modifiers |= MODIFIER_SHIFT; } // Set keycode. We explicitly use scancode here because GFE will try to correct // for AZERTY layouts on the host but it depends on receiving VK_ values matching // a QWERTY layout to work. if (event->keysym.scancode >= SDL_SCANCODE_1 && event->keysym.scancode <= SDL_SCANCODE_9) { // SDL defines SDL_SCANCODE_0 > SDL_SCANCODE_9, so we need to handle that manually keyCode = (event->keysym.scancode - SDL_SCANCODE_1) + VK_0 + 1; } else if (event->keysym.scancode >= SDL_SCANCODE_A && event->keysym.scancode <= SDL_SCANCODE_Z) { keyCode = (event->keysym.scancode - SDL_SCANCODE_A) + VK_A; } else if (event->keysym.scancode >= SDL_SCANCODE_F1 && event->keysym.scancode <= SDL_SCANCODE_F12) { keyCode = (event->keysym.scancode - SDL_SCANCODE_F1) + VK_F1; } else if (event->keysym.scancode >= SDL_SCANCODE_F13 && event->keysym.scancode <= SDL_SCANCODE_F24) { keyCode = (event->keysym.scancode - SDL_SCANCODE_F13) + VK_F13; } else if (event->keysym.scancode >= SDL_SCANCODE_KP_1 && event->keysym.scancode <= SDL_SCANCODE_KP_9) { // SDL defines SDL_SCANCODE_KP_0 > SDL_SCANCODE_KP_9, so we need to handle that manually keyCode = (event->keysym.scancode - SDL_SCANCODE_KP_1) + VK_NUMPAD0 + 1; } else { switch (event->keysym.scancode) { case SDL_SCANCODE_BACKSPACE: keyCode = 0x08; break; case SDL_SCANCODE_TAB: keyCode = 0x09; break; case SDL_SCANCODE_CLEAR: keyCode = 0x0C; break; case SDL_SCANCODE_KP_ENTER: // FIXME: Is this correct? case SDL_SCANCODE_RETURN: keyCode = 0x0D; break; case SDL_SCANCODE_PAUSE: keyCode = 0x13; break; case SDL_SCANCODE_CAPSLOCK: keyCode = 0x14; break; case SDL_SCANCODE_ESCAPE: keyCode = 0x1B; break; case SDL_SCANCODE_SPACE: keyCode = 0x20; break; case SDL_SCANCODE_PAGEUP: keyCode = 0x21; break; case SDL_SCANCODE_PAGEDOWN: keyCode = 0x22; break; case SDL_SCANCODE_END: keyCode = 0x23; break; case SDL_SCANCODE_HOME: keyCode = 0x24; break; case SDL_SCANCODE_LEFT: keyCode = 0x25; break; case SDL_SCANCODE_UP: keyCode = 0x26; break; case SDL_SCANCODE_RIGHT: keyCode = 0x27; break; case SDL_SCANCODE_DOWN: keyCode = 0x28; break; case SDL_SCANCODE_SELECT: keyCode = 0x29; break; case SDL_SCANCODE_EXECUTE: keyCode = 0x2B; break; case SDL_SCANCODE_PRINTSCREEN: keyCode = 0x2C; break; case SDL_SCANCODE_INSERT: keyCode = 0x2D; break; case SDL_SCANCODE_DELETE: keyCode = 0x2E; break; case SDL_SCANCODE_HELP: keyCode = 0x2F; break; case SDL_SCANCODE_KP_0: // See comment above about why we only handle SDL_SCANCODE_KP_0 here keyCode = VK_NUMPAD0; break; case SDL_SCANCODE_0: // See comment above about why we only handle SDL_SCANCODE_0 here keyCode = VK_0; break; case SDL_SCANCODE_KP_MULTIPLY: keyCode = 0x6A; break; case SDL_SCANCODE_KP_PLUS: keyCode = 0x6B; break; case SDL_SCANCODE_KP_COMMA: keyCode = 0x6C; break; case SDL_SCANCODE_KP_MINUS: keyCode = 0x6D; break; case SDL_SCANCODE_KP_PERIOD: keyCode = 0x6E; break; case SDL_SCANCODE_KP_DIVIDE: keyCode = 0x6F; break; case SDL_SCANCODE_NUMLOCKCLEAR: keyCode = 0x90; break; case SDL_SCANCODE_SCROLLLOCK: keyCode = 0x91; break; case SDL_SCANCODE_LSHIFT: keyCode = 0xA0; break; case SDL_SCANCODE_RSHIFT: keyCode = 0xA1; break; case SDL_SCANCODE_LCTRL: keyCode = 0xA2; break; case SDL_SCANCODE_RCTRL: keyCode = 0xA3; break; case SDL_SCANCODE_LALT: keyCode = 0xA4; break; case SDL_SCANCODE_RALT: keyCode = 0xA5; break; case SDL_SCANCODE_AC_BACK: keyCode = 0xA6; break; case SDL_SCANCODE_AC_FORWARD: keyCode = 0xA7; break; case SDL_SCANCODE_AC_REFRESH: keyCode = 0xA8; break; case SDL_SCANCODE_AC_STOP: keyCode = 0xA9; break; case SDL_SCANCODE_AC_SEARCH: keyCode = 0xAA; break; case SDL_SCANCODE_AC_BOOKMARKS: keyCode = 0xAB; break; case SDL_SCANCODE_AC_HOME: keyCode = 0xAC; break; case SDL_SCANCODE_SEMICOLON: keyCode = 0xBA; break; case SDL_SCANCODE_EQUALS: keyCode = 0xBB; break; case SDL_SCANCODE_COMMA: keyCode = 0xBC; break; case SDL_SCANCODE_MINUS: keyCode = 0xBD; break; case SDL_SCANCODE_PERIOD: keyCode = 0xBE; break; case SDL_SCANCODE_SLASH: keyCode = 0xBF; break; case SDL_SCANCODE_GRAVE: keyCode = 0xC0; break; case SDL_SCANCODE_LEFTBRACKET: keyCode = 0xDB; break; case SDL_SCANCODE_BACKSLASH: keyCode = 0xDC; break; case SDL_SCANCODE_RIGHTBRACKET: keyCode = 0xDD; break; case SDL_SCANCODE_APOSTROPHE: keyCode = 0xDE; break; case SDL_SCANCODE_NONUSBACKSLASH: keyCode = 0xE2; break; default: SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Unhandled button event: %d", event->keysym.scancode); return; } } // Track the key state so we always know which keys are down if (event->state == SDL_PRESSED) { m_KeysDown.insert(keyCode); } else { m_KeysDown.remove(keyCode); } LiSendKeyboardEvent(keyCode, event->state == SDL_PRESSED ? KEY_ACTION_DOWN : KEY_ACTION_UP, modifiers); } void SdlInputHandler::handleMouseButtonEvent(SDL_MouseButtonEvent* event) { int button; // Capture the mouse again if clicked when unbound. // We start capture on left button released instead of // pressed to avoid sending an errant mouse button released // event to the host when clicking into our window (since // the pressed event was consumed by this code). if (event->button == SDL_BUTTON_LEFT && event->state == SDL_RELEASED && !SDL_GetRelativeMouseMode()) { SDL_SetRelativeMouseMode(SDL_TRUE); return; } else if (!SDL_GetRelativeMouseMode()) { // Not capturing return; } else if (event->which == SDL_TOUCH_MOUSEID) { // Ignore synthetic mouse events return; } switch (event->button) { case SDL_BUTTON_LEFT: button = BUTTON_LEFT; break; case SDL_BUTTON_MIDDLE: button = BUTTON_MIDDLE; break; case SDL_BUTTON_RIGHT: button = BUTTON_RIGHT; break; case SDL_BUTTON_X1: button = BUTTON_X1; break; case SDL_BUTTON_X2: button = BUTTON_X2; break; default: SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Unhandled button event: %d", event->button); return; } LiSendMouseButtonEvent(event->state == SDL_PRESSED ? BUTTON_ACTION_PRESS : BUTTON_ACTION_RELEASE, button); } void SdlInputHandler::handleMouseMotionEvent(SDL_MouseMotionEvent* event) { if (!SDL_GetRelativeMouseMode()) { // Not capturing return; } else if (event->which == SDL_TOUCH_MOUSEID) { // Ignore synthetic mouse events return; } // Batch until the next mouse polling window or we'll get awful // input lag everything except GFE 3.14 and 3.15. SDL_AtomicAdd(&m_MouseDeltaX, event->xrel); SDL_AtomicAdd(&m_MouseDeltaY, event->yrel); } void SdlInputHandler::handleMouseWheelEvent(SDL_MouseWheelEvent* event) { if (!SDL_GetRelativeMouseMode()) { // Not capturing return; } else if (event->which == SDL_TOUCH_MOUSEID) { // Ignore synthetic mouse events return; } if (event->y != 0) { LiSendScrollEvent((signed char)event->y); } } GamepadState* SdlInputHandler::findStateForGamepad(SDL_JoystickID id) { int i; for (i = 0; i < MAX_GAMEPADS; i++) { if (m_GamepadState[i].jsId == id) { SDL_assert(!m_MultiController || m_GamepadState[i].index == i); return &m_GamepadState[i]; } } // This should only happen with > 4 gamepads SDL_assert(SDL_NumJoysticks() > 4); return nullptr; } void SdlInputHandler::sendGamepadState(GamepadState* state) { SDL_assert(m_GamepadMask == 0x1 || m_MultiController); LiSendMultiControllerEvent(state->index, m_GamepadMask, state->buttons, state->lt, state->rt, state->lsX, state->lsY, state->rsX, state->rsY); } Uint32 SdlInputHandler::releaseLeftButtonTimerCallback(Uint32, void*) { LiSendMouseButtonEvent(BUTTON_ACTION_RELEASE, BUTTON_LEFT); return 0; } Uint32 SdlInputHandler::releaseRightButtonTimerCallback(Uint32, void*) { LiSendMouseButtonEvent(BUTTON_ACTION_RELEASE, BUTTON_RIGHT); return 0; } Uint32 SdlInputHandler::dragTimerCallback(Uint32, void *param) { auto me = reinterpret_cast(param); // Check how many fingers are down now to decide // which button to hold down if (me->m_NumFingersDown == 2) { me->m_DragButton = BUTTON_RIGHT; } else if (me->m_NumFingersDown == 1) { me->m_DragButton = BUTTON_LEFT; } LiSendMouseButtonEvent(BUTTON_ACTION_PRESS, me->m_DragButton); return 0; } Uint32 SdlInputHandler::mouseMoveTimerCallback(Uint32 interval, void *param) { auto me = reinterpret_cast(param); short deltaX = (short)SDL_AtomicSet(&me->m_MouseDeltaX, 0); short deltaY = (short)SDL_AtomicSet(&me->m_MouseDeltaY, 0); if (deltaX != 0 || deltaY != 0) { LiSendMouseMoveEvent(deltaX, deltaY); } return interval; } void SdlInputHandler::handleControllerAxisEvent(SDL_ControllerAxisEvent* event) { GamepadState* state = findStateForGamepad(event->which); if (state == NULL) { return; } switch (event->axis) { case SDL_CONTROLLER_AXIS_LEFTX: state->lsX = event->value; break; case SDL_CONTROLLER_AXIS_LEFTY: // Signed values have one more negative value than // positive value, so inverting the sign on -32768 // could actually cause the value to overflow and // wrap around to be negative again. Avoid that by // capping the value at 32767. state->lsY = -qMax(event->value, (short)-32767); break; case SDL_CONTROLLER_AXIS_RIGHTX: state->rsX = event->value; break; case SDL_CONTROLLER_AXIS_RIGHTY: state->rsY = -qMax(event->value, (short)-32767); break; case SDL_CONTROLLER_AXIS_TRIGGERLEFT: state->lt = (unsigned char)(event->value * 255UL / 32767); break; case SDL_CONTROLLER_AXIS_TRIGGERRIGHT: state->rt = (unsigned char)(event->value * 255UL / 32767); break; default: SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Unhandled controller axis: %d", event->axis); return; } sendGamepadState(state); } void SdlInputHandler::handleControllerButtonEvent(SDL_ControllerButtonEvent* event) { GamepadState* state = findStateForGamepad(event->which); if (state == NULL) { return; } if (event->state == SDL_PRESSED) { state->buttons |= k_ButtonMap[event->button]; } else { state->buttons &= ~k_ButtonMap[event->button]; } // Handle Start+Select+L1+R1 as a gamepad quit combo if (state->buttons == (PLAY_FLAG | BACK_FLAG | LB_FLAG | RB_FLAG)) { SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Detected quit gamepad button combo"); // Push a quit event to the main loop SDL_Event event; event.type = SDL_QUIT; event.quit.timestamp = SDL_GetTicks(); SDL_PushEvent(&event); // Clear buttons down on this gameapd LiSendMultiControllerEvent(state->index, m_GamepadMask, 0, 0, 0, 0, 0, 0, 0); return; } sendGamepadState(state); } void SdlInputHandler::handleControllerDeviceEvent(SDL_ControllerDeviceEvent* event) { GamepadState* state; if (event->type == SDL_CONTROLLERDEVICEADDED) { int i; const char* name; SDL_GameController* controller; const char* mapping; char guidStr[33]; controller = SDL_GameControllerOpen(event->which); if (controller == NULL) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "Failed to open gamepad: %s", SDL_GetError()); return; } // We used to use SDL_GameControllerGetPlayerIndex() here but that // can lead to strange issues due to bugs in Windows where an Xbox // controller will join as player 2, even though no player 1 controller // is connected at all. This pretty much screws any attempt to use // the gamepad in single player games, so just assign them in order from 0. i = 0; for (; i < MAX_GAMEPADS; i++) { if (m_GamepadState[i].controller == NULL) { // Found an empty slot break; } } if (i == MAX_GAMEPADS) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "No open gamepad slots found!"); SDL_GameControllerClose(controller); return; } state = &m_GamepadState[i]; if (m_MultiController) { state->index = i; } else { // Always player 1 in single controller mode state->index = 0; } state->controller = controller; state->jsId = SDL_JoystickInstanceID(SDL_GameControllerGetJoystick(state->controller)); state->haptic = SDL_HapticOpenFromJoystick(SDL_GameControllerGetJoystick(state->controller)); state->hapticEffectId = -1; state->hapticMethod = GAMEPAD_HAPTIC_METHOD_NONE; if (state->haptic != nullptr) { if ((SDL_HapticQuery(state->haptic) & SDL_HAPTIC_LEFTRIGHT) == 0) { if (SDL_HapticRumbleSupported(state->haptic)) { if (SDL_HapticRumbleInit(state->haptic) == 0) { state->hapticMethod = GAMEPAD_HAPTIC_METHOD_SIMPLERUMBLE; } } if (state->hapticMethod == GAMEPAD_HAPTIC_METHOD_NONE) { SDL_HapticClose(state->haptic); state->haptic = nullptr; } } else { state->hapticMethod = GAMEPAD_HAPTIC_METHOD_LEFTRIGHT; } } SDL_JoystickGetGUIDString(SDL_JoystickGetGUID(SDL_GameControllerGetJoystick(state->controller)), guidStr, sizeof(guidStr)); mapping = SDL_GameControllerMapping(state->controller); name = SDL_GameControllerName(state->controller); SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Gamepad %d (player %d) is: %s (%s -> %s)", i, state->index, name != nullptr ? name : "", guidStr, mapping != nullptr ? mapping : ""); if (mapping != nullptr) { SDL_free((void*)mapping); } // Add this gamepad to the gamepad mask if (m_MultiController) { // NB: Don't assert that it's unset here because we will already // have the mask set for initially attached gamepads to avoid confusing // apps running on the host. m_GamepadMask |= (1 << state->index); } else { SDL_assert(m_GamepadMask == 0x1); } // Send an empty event to tell the PC we've arrived sendGamepadState(state); } else if (event->type == SDL_CONTROLLERDEVICEREMOVED) { state = findStateForGamepad(event->which); if (state != NULL) { SDL_GameControllerClose(state->controller); if (state->haptic != nullptr) { SDL_HapticClose(state->haptic); } // Remove this from the gamepad mask in MC-mode if (m_MultiController) { SDL_assert(m_GamepadMask & (1 << state->index)); m_GamepadMask &= ~(1 << state->index); } else { SDL_assert(m_GamepadMask == 0x1); } SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Gamepad %d is gone", state->index); // Send a final event to let the PC know this gamepad is gone LiSendMultiControllerEvent(state->index, m_GamepadMask, 0, 0, 0, 0, 0, 0, 0); // Clear all remaining state from this slot SDL_memset(state, 0, sizeof(*state)); } } } void SdlInputHandler::handleJoystickArrivalEvent(SDL_JoyDeviceEvent* event) { SDL_assert(event->type == SDL_JOYDEVICEADDED); if (!SDL_IsGameController(event->which)) { char guidStr[33]; SDL_JoystickGetGUIDString(SDL_JoystickGetDeviceGUID(event->which), guidStr, sizeof(guidStr)); const char* name = SDL_JoystickNameForIndex(event->which); SDL_LogWarn(SDL_LOG_CATEGORY_APPLICATION, "Joystick discovered with no mapping: %s %s", name ? name : "", guidStr); SDL_Joystick* joy = SDL_JoystickOpen(event->which); if (joy != nullptr) { SDL_LogWarn(SDL_LOG_CATEGORY_APPLICATION, "Number of axes: %d | Number of buttons: %d | Number of hats: %d", SDL_JoystickNumAxes(joy), SDL_JoystickNumButtons(joy), SDL_JoystickNumHats(joy)); SDL_JoystickClose(joy); } else { SDL_LogWarn(SDL_LOG_CATEGORY_APPLICATION, "Unable to open joystick for query: %s", SDL_GetError()); } } } void SdlInputHandler::rumble(unsigned short controllerNumber, unsigned short lowFreqMotor, unsigned short highFreqMotor) { // Make sure the controller number is within our supported count if (controllerNumber >= MAX_GAMEPADS) { return; } // Check if the controller supports haptics (and if the controller exists at all) SDL_Haptic* haptic = m_GamepadState[controllerNumber].haptic; if (haptic == nullptr) { return; } // Stop the last effect we played if (m_GamepadState[controllerNumber].hapticMethod == GAMEPAD_HAPTIC_METHOD_LEFTRIGHT) { if (m_GamepadState[controllerNumber].hapticEffectId >= 0) { SDL_HapticDestroyEffect(haptic, m_GamepadState[controllerNumber].hapticEffectId); } } else if (m_GamepadState[controllerNumber].hapticMethod == GAMEPAD_HAPTIC_METHOD_SIMPLERUMBLE) { SDL_HapticRumbleStop(haptic); } // If this callback is telling us to stop both motors, don't bother queuing a new effect if (lowFreqMotor == 0 && highFreqMotor == 0) { return; } if (m_GamepadState[controllerNumber].hapticMethod == GAMEPAD_HAPTIC_METHOD_LEFTRIGHT) { SDL_HapticEffect effect; SDL_memset(&effect, 0, sizeof(effect)); effect.type = SDL_HAPTIC_LEFTRIGHT; // The effect should last until we are instructed to stop or change it effect.leftright.length = SDL_HAPTIC_INFINITY; // SDL haptics range from 0-32767 but XInput uses 0-65535, so divide by 2 to correct for SDL's scaling effect.leftright.large_magnitude = lowFreqMotor / 2; effect.leftright.small_magnitude = highFreqMotor / 2; // Play the new effect m_GamepadState[controllerNumber].hapticEffectId = SDL_HapticNewEffect(haptic, &effect); if (m_GamepadState[controllerNumber].hapticEffectId >= 0) { SDL_HapticRunEffect(haptic, m_GamepadState[controllerNumber].hapticEffectId, 1); } } else if (m_GamepadState[controllerNumber].hapticMethod == GAMEPAD_HAPTIC_METHOD_SIMPLERUMBLE) { SDL_HapticRumblePlay(haptic, std::min(1.0, (GAMEPAD_HAPTIC_SIMPLE_HIFREQ_MOTOR_WEIGHT*highFreqMotor + GAMEPAD_HAPTIC_SIMPLE_LOWFREQ_MOTOR_WEIGHT*lowFreqMotor) / 65535.0), SDL_HAPTIC_INFINITY); } } void SdlInputHandler::handleTouchFingerEvent(SDL_TouchFingerEvent* event) { int fingerIndex = -1; // Observations on Windows 10: x and y appear to be relative to 0,0 of the window client area. // Although SDL documentation states they are 0.0 - 1.0 float values, they can actually be higher // or lower than those values as touch events continue for touches started within the client area that // leave the client area during a drag motion. // dx and dy are deltas from the last touch event, not the first touch down. // Determine the index of this finger using our list // of fingers that are currently active on screen. // This is also required to handle finger up which // where the finger will not be in SDL_GetTouchFinger() // anymore. if (event->type != SDL_FINGERDOWN) { for (int i = 0; i < MAX_FINGERS; i++) { if (event->fingerId == m_TouchDownEvent[i].fingerId) { fingerIndex = i; break; } } } else { // Resolve the new finger by determining the ID of each // finger on the display. int numTouchFingers = SDL_GetNumTouchFingers(event->touchId); for (int i = 0; i < numTouchFingers; i++) { SDL_Finger* finger = SDL_GetTouchFinger(event->touchId, i); SDL_assert(finger != nullptr); if (finger != nullptr) { if (finger->id == event->fingerId) { fingerIndex = i; break; } } } } if (fingerIndex < 0 || fingerIndex >= MAX_FINGERS) { // Too many fingers return; } // Handle cursor motion based on the position of the // primary finger on screen if (fingerIndex == 0) { // The event x and y values are relative to our window width // and height. However, we want to scale them to be relative // to the host resolution. Fortunately this is easy since we // already have normalized values. We'll just multiply them // by the stream dimensions to get real X and Y values rather // than the client window dimensions. short deltaX = static_cast(event->dx * m_StreamWidth); short deltaY = static_cast(event->dy * m_StreamHeight); if (deltaX != 0 || deltaY != 0) { LiSendMouseMoveEvent(deltaX, deltaY); } } // Start a drag timer when primary or secondary // fingers go down if (event->type == SDL_FINGERDOWN && (fingerIndex == 0 || fingerIndex == 1)) { SDL_RemoveTimer(m_DragTimer); m_DragTimer = SDL_AddTimer(DRAG_ACTIVATION_DELAY, dragTimerCallback, this); } if (event->type == SDL_FINGERMOTION) { // Count the total cumulative dx/dy that the finger // has moved. m_CumulativeDelta[fingerIndex] += qAbs(event->x); m_CumulativeDelta[fingerIndex] += qAbs(event->y); // If it's outside the deadzone delta, cancel drags and taps if (m_CumulativeDelta[fingerIndex] > DEAD_ZONE_DELTA) { SDL_RemoveTimer(m_DragTimer); m_DragTimer = 0; // This effectively cancels the tap logic below m_TouchDownEvent[fingerIndex].timestamp = 0; } } if (event->type == SDL_FINGERUP) { // Cancel the drag timer on finger up SDL_RemoveTimer(m_DragTimer); m_DragTimer = 0; // Release any drag if (m_DragButton != 0) { LiSendMouseButtonEvent(BUTTON_ACTION_RELEASE, m_DragButton); m_DragButton = 0; } // 2 finger tap else if (event->timestamp - m_TouchDownEvent[1].timestamp < 250) { // Zero timestamp of the primary finger to ensure we won't // generate a left click if the primary finger comes up soon. m_TouchDownEvent[0].timestamp = 0; // Press down the right mouse button LiSendMouseButtonEvent(BUTTON_ACTION_PRESS, BUTTON_RIGHT); // Queue a timer to release it in 100 ms SDL_RemoveTimer(m_RightButtonReleaseTimer); m_RightButtonReleaseTimer = SDL_AddTimer(TAP_BUTTON_RELEASE_DELAY, releaseRightButtonTimerCallback, nullptr); } // 1 finger tap else if (event->timestamp - m_TouchDownEvent[0].timestamp < 250) { // Press down the left mouse button LiSendMouseButtonEvent(BUTTON_ACTION_PRESS, BUTTON_LEFT); // Queue a timer to release it in 100 ms SDL_RemoveTimer(m_LeftButtonReleaseTimer); m_LeftButtonReleaseTimer = SDL_AddTimer(TAP_BUTTON_RELEASE_DELAY, releaseLeftButtonTimerCallback, nullptr); } } m_NumFingersDown = SDL_GetNumTouchFingers(event->touchId); if (event->type == SDL_FINGERDOWN) { m_TouchDownEvent[fingerIndex] = *event; m_CumulativeDelta[fingerIndex] = 0; } else if (event->type == SDL_FINGERUP) { m_TouchDownEvent[fingerIndex] = {}; } } int SdlInputHandler::getAttachedGamepadMask() { int count; int mask; if (!m_MultiController) { // Player 1 is always present in non-MC mode return 0x1; } count = mask = 0; for (int i = 0; i < SDL_NumJoysticks(); i++) { if (SDL_IsGameController(i)) { mask |= (1 << count++); } } return mask; } void SdlInputHandler::raiseAllKeys() { if (m_KeysDown.isEmpty()) { return; } SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Raising %d keys", m_KeysDown.count()); for (auto keyDown : m_KeysDown) { LiSendKeyboardEvent(keyDown, KEY_ACTION_UP, 0); } m_KeysDown.clear(); } QString SdlInputHandler::getUnmappedGamepads() { QString ret; if (SDL_InitSubSystem(SDL_INIT_GAMECONTROLLER) != 0) { SDL_LogError(SDL_LOG_CATEGORY_APPLICATION, "SDL_InitSubSystem(SDL_INIT_GAMECONTROLLER) failed: %s", SDL_GetError()); } MappingManager mappingManager; mappingManager.applyMappings(); for (int i = 0; i < SDL_NumJoysticks(); i++) { if (!SDL_IsGameController(i)) { char guidStr[33]; SDL_JoystickGetGUIDString(SDL_JoystickGetDeviceGUID(i), guidStr, sizeof(guidStr)); const char* name = SDL_JoystickNameForIndex(i); SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Unmapped joystick: %s %s", name ? name : "", guidStr); SDL_Joystick* joy = SDL_JoystickOpen(i); if (joy != nullptr) { int numButtons = SDL_JoystickNumButtons(joy); int numHats = SDL_JoystickNumHats(joy); int numAxes = SDL_JoystickNumAxes(joy); SDL_LogInfo(SDL_LOG_CATEGORY_APPLICATION, "Number of axes: %d | Number of buttons: %d | Number of hats: %d", numAxes, numButtons, numHats); if ((numAxes >= 4 && numAxes <= 8) && numButtons >= 8 && numHats <= 1) { SDL_LogWarn(SDL_LOG_CATEGORY_APPLICATION, "Joystick likely to be an unmapped game controller"); if (!ret.isEmpty()) { ret += ", "; } ret += name; } SDL_JoystickClose(joy); } else { SDL_LogWarn(SDL_LOG_CATEGORY_APPLICATION, "Unable to open joystick for query: %s", SDL_GetError()); } } } SDL_QuitSubSystem(SDL_INIT_GAMECONTROLLER); return ret; }