/** * @file llviewerjoystick.cpp * @brief Joystick / NDOF device functionality. * * $LicenseInfo:firstyear=2002&license=viewerlgpl$ * Second Life Viewer Source Code * Copyright (C) 2010, Linden Research, Inc. * * 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; * version 2.1 of the License only. * * 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 * * Linden Research, Inc., 945 Battery Street, San Francisco, CA 94111 USA * $/LicenseInfo$ */ #include "llviewerprecompiledheaders.h" #include "llviewerjoystick.h" #include "llviewercontrol.h" #include "llviewerwindow.h" #include "llviewercamera.h" #include "llappviewer.h" #include "llkeyboard.h" #include "lltoolmgr.h" #include "llselectmgr.h" #include "llviewermenu.h" #include "llviewerwindow.h" #include "llwindow.h" #include "llagent.h" #include "llagentcamera.h" #include "llfocusmgr.h" #if LL_WINDOWS && !LL_MESA_HEADLESS // Require DirectInput version 8 #define DIRECTINPUT_VERSION 0x0800 #include #endif // ---------------------------------------------------------------------------- // Constants #define X_I 1 #define Y_I 2 #define Z_I 0 #define RX_I 4 #define RY_I 5 #define RZ_I 3 F32 LLViewerJoystick::sLastDelta[] = {0,0,0,0,0,0,0}; F32 LLViewerJoystick::sDelta[] = {0,0,0,0,0,0,0}; // These constants specify the maximum absolute value coming in from the device. // HACK ALERT! the value of MAX_JOYSTICK_INPUT_VALUE is not arbitrary as it // should be. It has to be equal to 3000 because the SpaceNavigator on Windows // refuses to respond to the DirectInput SetProperty call; it always returns // values in the [-3000, 3000] range. #define MAX_SPACENAVIGATOR_INPUT 3000.0f #define MAX_JOYSTICK_INPUT_VALUE MAX_SPACENAVIGATOR_INPUT #if LIB_NDOF std::ostream& operator<<(std::ostream& out, NDOF_Device* ptr) { if (! ptr) { return out << "nullptr"; } out << "NDOF_Device{ "; out << "axes ["; const char* delim = ""; for (short axis = 0; axis < ptr->axes_count; ++axis) { out << delim << ptr->axes[axis]; delim = ", "; } out << "]"; out << ", buttons ["; delim = ""; for (short button = 0; button < ptr->btn_count; ++button) { out << delim << ptr->buttons[button]; delim = ", "; } out << "]"; out << ", range " << ptr->axes_min << ':' << ptr->axes_max; // If we don't coerce these to unsigned, they're streamed as characters, // e.g. ctrl-A or nul. out << ", absolute " << unsigned(ptr->absolute); out << ", valid " << unsigned(ptr->valid); out << ", manufacturer '" << ptr->manufacturer << "'"; out << ", product '" << ptr->product << "'"; out << ", private " << ptr->private_data; out << " }"; return out; } #endif // LIB_NDOF #if LL_WINDOWS && !LL_MESA_HEADLESS // this should reflect ndof and set axises, see ndofdev_win.cpp from ndof package BOOL CALLBACK EnumObjectsCallback(const DIDEVICEOBJECTINSTANCE* inst, VOID* user_data) { if (inst->dwType & DIDFT_AXIS) { LPDIRECTINPUTDEVICE8 device = *((LPDIRECTINPUTDEVICE8 *)user_data); DIPROPRANGE diprg; diprg.diph.dwSize = sizeof(DIPROPRANGE); diprg.diph.dwHeaderSize = sizeof(DIPROPHEADER); diprg.diph.dwHow = DIPH_BYID; diprg.diph.dwObj = inst->dwType; // specify the enumerated axis // Set the range for the axis diprg.lMin = (long)-MAX_JOYSTICK_INPUT_VALUE; diprg.lMax = (long)+MAX_JOYSTICK_INPUT_VALUE; HRESULT hr = device->SetProperty(DIPROP_RANGE, &diprg.diph); if (FAILED(hr)) { return DIENUM_STOP; } } return DIENUM_CONTINUE; } BOOL CALLBACK di8_devices_callback(LPCDIDEVICEINSTANCE device_instance_ptr, LPVOID pvRef) { // Note: If a single device can function as more than one DirectInput // device type, it is enumerated as each device type that it supports. // Capable of detecting devices like Oculus Rift if (device_instance_ptr) { std::string product_name = utf16str_to_utf8str(llutf16string(device_instance_ptr->tszProductName)); LLSD guid = LLViewerJoystick::getInstance()->getDeviceUUID(); bool init_device = false; if (guid.isBinary()) { std::vector bin_bucket = guid.asBinary(); init_device = memcmp(&bin_bucket[0], &device_instance_ptr->guidInstance, sizeof(GUID)) == 0; } else { // It might be better to init space navigator here, but if system doesn't has one, // ndof will pick a random device, it is simpler to pick first device now to have an id init_device = true; } if (init_device) { LL_DEBUGS("Joystick") << "Found and attempting to use device: " << product_name << LL_ENDL; LPDIRECTINPUT8 di8_interface = *((LPDIRECTINPUT8 *)gViewerWindow->getWindow()->getDirectInput8()); LPDIRECTINPUTDEVICE8 device = NULL; HRESULT status = di8_interface->CreateDevice( device_instance_ptr->guidInstance, // REFGUID rguid, &device, // LPDIRECTINPUTDEVICE * lplpDirectInputDevice, NULL // LPUNKNOWN pUnkOuter ); if (status == DI_OK) { // prerequisite for aquire() LL_DEBUGS("Joystick") << "Device created" << LL_ENDL; status = device->SetDataFormat(&c_dfDIJoystick); // c_dfDIJoystick2 } if (status == DI_OK) { // set properties LL_DEBUGS("Joystick") << "Format set" << LL_ENDL; status = device->EnumObjects(EnumObjectsCallback, &device, DIDFT_ALL); } if (status == DI_OK) { LL_DEBUGS("Joystick") << "Properties updated" << LL_ENDL; S32 size = sizeof(GUID); LLSD::Binary data; //just an std::vector data.resize(size); memcpy(&data[0], &device_instance_ptr->guidInstance /*POD _GUID*/, size); LLViewerJoystick::getInstance()->initDevice(&device, product_name, LLSD(data)); return DIENUM_STOP; } } else { LL_DEBUGS("Joystick") << "Found device: " << product_name << LL_ENDL; } } return DIENUM_CONTINUE; } // Windows guids // This is GUID2 so teoretically it can be memcpy copied into LLUUID void guid_from_string(GUID &guid, const std::string &input) { CLSIDFromString(utf8str_to_utf16str(input).c_str(), &guid); } std::string string_from_guid(const GUID &guid) { OLECHAR* guidString; //wchat StringFromCLSID(guid, &guidString); // use guidString... std::string res = utf16str_to_utf8str(llutf16string(guidString)); // ensure memory is freed ::CoTaskMemFree(guidString); return res; } #elif LL_DARWIN bool macos_devices_callback(std::string &product_name, LLSD &data, void* userdata) { std::string product = data["product"].asString(); return LLViewerJoystick::getInstance()->initDevice(nullptr, product, data); } #endif // ----------------------------------------------------------------------------- void LLViewerJoystick::updateEnabled(bool autoenable) { if (mDriverState == JDS_UNINITIALIZED) { gSavedSettings.setBOOL("JoystickEnabled", false); } else { // autoenable if user specifically chose this device if (autoenable && (isLikeSpaceNavigator() || isDeviceUUIDSet())) { gSavedSettings.setBOOL("JoystickEnabled", true ); } } if (!gSavedSettings.getBOOL("JoystickEnabled")) { mOverrideCamera = false; } } void LLViewerJoystick::setOverrideCamera(bool val) { if (!gSavedSettings.getBOOL("JoystickEnabled")) { mOverrideCamera = false; } else { mOverrideCamera = val; } if (mOverrideCamera) { gAgentCamera.changeCameraToDefault(); } } // ----------------------------------------------------------------------------- #if LIB_NDOF NDOF_HotPlugResult LLViewerJoystick::HotPlugAddCallback(NDOF_Device *dev) { NDOF_HotPlugResult res = NDOF_DISCARD_HOTPLUGGED; LLViewerJoystick* joystick(LLViewerJoystick::getInstance()); if (joystick->mDriverState == JDS_UNINITIALIZED) { LL_INFOS("Joystick") << "HotPlugAddCallback: will use device:" << LL_ENDL; ndof_dump(stderr, dev); joystick->mNdofDev = dev; joystick->mDriverState = JDS_INITIALIZED; res = NDOF_KEEP_HOTPLUGGED; } joystick->updateEnabled(true); return res; } #endif // ----------------------------------------------------------------------------- #if LIB_NDOF void LLViewerJoystick::HotPlugRemovalCallback(NDOF_Device *dev) { LLViewerJoystick* joystick(LLViewerJoystick::getInstance()); if (joystick->mNdofDev == dev) { LL_INFOS("Joystick") << "HotPlugRemovalCallback: joystick->mNdofDev=" << joystick->mNdofDev << "; removed device:" << LL_ENDL; ndof_dump(stderr, dev); joystick->mDriverState = JDS_UNINITIALIZED; } joystick->updateEnabled(true); } #endif // ----------------------------------------------------------------------------- LLViewerJoystick::LLViewerJoystick() : mDriverState(JDS_UNINITIALIZED), mNdofDev(NULL), mResetFlag(false), mCameraUpdated(true), mOverrideCamera(false), mJoystickRun(0) { for (int i = 0; i < 6; i++) { mAxes[i] = sDelta[i] = sLastDelta[i] = 0.0f; } memset(mBtn, 0, sizeof(mBtn)); // factor in bandwidth? bandwidth = gViewerStats->mKBitStat mPerfScale = 4000.f / (F32)gSysCPU.getMHz(); // hmm. why? mLastDeviceUUID = LLSD::Integer(1); } // ----------------------------------------------------------------------------- LLViewerJoystick::~LLViewerJoystick() { if (mDriverState == JDS_INITIALIZED) { terminate(); } } // ----------------------------------------------------------------------------- void LLViewerJoystick::init(bool autoenable) { #if LIB_NDOF static bool libinit = false; mDriverState = JDS_INITIALIZING; loadDeviceIdFromSettings(); if (!libinit) { // Note: The HotPlug callbacks are not actually getting called on Windows if (ndof_libinit(HotPlugAddCallback, HotPlugRemovalCallback, gViewerWindow->getWindow()->getDirectInput8())) { mDriverState = JDS_UNINITIALIZED; } else { // NB: ndof_libinit succeeds when there's no device libinit = true; // allocate memory once for an eventual device mNdofDev = ndof_create(); } } if (libinit) { if (mNdofDev) { U32 device_type = 0; void* win_callback = nullptr; std::function osx_callback; // di8_devices_callback callback is immediate and happens in scope of getInputDevices() #if LL_WINDOWS && !LL_MESA_HEADLESS // space navigator is marked as DI8DEVCLASS_GAMECTRL in ndof lib device_type = DI8DEVCLASS_GAMECTRL; win_callback = &di8_devices_callback; #elif LL_DARWIN osx_callback = macos_devices_callback; if (mLastDeviceUUID.isMap()) { std::string manufacturer = mLastDeviceUUID["manufacturer"].asString(); std::string product = mLastDeviceUUID["product"].asString(); strncpy(mNdofDev->manufacturer, manufacturer.c_str(), sizeof(mNdofDev->manufacturer)); strncpy(mNdofDev->product, product.c_str(), sizeof(mNdofDev->product)); if (ndof_init_first(mNdofDev, nullptr)) { mDriverState = JDS_INITIALIZING; // Saved device no longer exist // No device found LL_WARNS() << "ndof_init_first FAILED" << LL_ENDL; } else { mDriverState = JDS_INITIALIZED; } } #endif if (mDriverState != JDS_INITIALIZED) { if (!gViewerWindow->getWindow()->getInputDevices(device_type, osx_callback, win_callback, NULL)) { LL_INFOS("Joystick") << "Failed to gather input devices. Falling back to ndof's init" << LL_ENDL; // Failed to gather devices, init first suitable one mLastDeviceUUID = LLSD(); void *preffered_device = NULL; initDevice(preffered_device); } } if (mDriverState == JDS_INITIALIZING) { LL_INFOS("Joystick") << "Found no matching joystick devices." << LL_ENDL; mDriverState = JDS_UNINITIALIZED; } } else { mDriverState = JDS_UNINITIALIZED; } } // Autoenable the joystick for recognized devices if nothing was connected previously if (!autoenable) { autoenable = gSavedSettings.getString("JoystickInitialized").empty(); } updateEnabled(autoenable); if (mDriverState == JDS_INITIALIZED) { // A Joystick device is plugged in if (isLikeSpaceNavigator()) { // It's a space navigator, we have defaults for it. if (gSavedSettings.getString("JoystickInitialized") != "SpaceNavigator") { // Only set the defaults if we haven't already (in case they were overridden) setSNDefaults(); gSavedSettings.setString("JoystickInitialized", "SpaceNavigator"); } } else { // It's not a Space Navigator gSavedSettings.setString("JoystickInitialized", "UnknownDevice"); } } else { // No device connected, don't change any settings } LL_INFOS("Joystick") << "ndof: mDriverState=" << mDriverState << "; mNdofDev=" << mNdofDev << "; libinit=" << libinit << LL_ENDL; #endif } void LLViewerJoystick::initDevice(LLSD &guid) { #if LIB_NDOF mLastDeviceUUID = guid; U32 device_type = 0; void* win_callback = nullptr; std::function osx_callback; mDriverState = JDS_INITIALIZING; #if LL_WINDOWS && !LL_MESA_HEADLESS // space navigator is marked as DI8DEVCLASS_GAMECTRL in ndof lib device_type = DI8DEVCLASS_GAMECTRL; win_callback = &di8_devices_callback; #elif LL_DARWIN osx_callback = macos_devices_callback; if (mLastDeviceUUID.isMap()) { std::string manufacturer = mLastDeviceUUID["manufacturer"].asString(); std::string product = mLastDeviceUUID["product"].asString(); strncpy(mNdofDev->manufacturer, manufacturer.c_str(), sizeof(mNdofDev->manufacturer)); strncpy(mNdofDev->product, product.c_str(), sizeof(mNdofDev->product)); if (ndof_init_first(mNdofDev, nullptr)) { mDriverState = JDS_INITIALIZING; // Saved device no longer exist // Np other device present LL_WARNS() << "ndof_init_first FAILED" << LL_ENDL; } else { mDriverState = JDS_INITIALIZED; } } #endif if (mDriverState != JDS_INITIALIZED) { if (!gViewerWindow->getWindow()->getInputDevices(device_type, osx_callback, win_callback, NULL)) { LL_INFOS("Joystick") << "Failed to gather input devices. Falling back to ndof's init" << LL_ENDL; // Failed to gather devices from window, init first suitable one void *preffered_device = NULL; mLastDeviceUUID = LLSD(); initDevice(preffered_device); } } if (mDriverState == JDS_INITIALIZING) { LL_INFOS("Joystick") << "Found no matching joystick devices." << LL_ENDL; mDriverState = JDS_UNINITIALIZED; } #endif } bool LLViewerJoystick::initDevice(void * preffered_device /*LPDIRECTINPUTDEVICE8*/, std::string &name, LLSD &guid) { #if LIB_NDOF mLastDeviceUUID = guid; #if LL_DARWIN if (guid.isMap()) { std::string manufacturer = mLastDeviceUUID["manufacturer"].asString(); std::string product = mLastDeviceUUID["product"].asString(); strncpy(mNdofDev->manufacturer, manufacturer.c_str(), sizeof(mNdofDev->manufacturer)); strncpy(mNdofDev->product, product.c_str(), sizeof(mNdofDev->product)); } else { mNdofDev->product[0] = '\0'; mNdofDev->manufacturer[0] = '\0'; } #else strncpy(mNdofDev->product, name.c_str(), sizeof(mNdofDev->product)); mNdofDev->manufacturer[0] = '\0'; #endif return initDevice(preffered_device); #else return false; #endif } bool LLViewerJoystick::initDevice(void * preffered_device /* LPDIRECTINPUTDEVICE8* */) { #if LIB_NDOF // Different joysticks will return different ranges of raw values. // Since we want to handle every device in the same uniform way, // we initialize the mNdofDev struct and we set the range // of values we would like to receive. // // HACK: On Windows, libndofdev passes our range to DI with a // SetProperty call. This works but with one notable exception, the // SpaceNavigator, who doesn't seem to care about the SetProperty // call. In theory, we should handle this case inside libndofdev. // However, the range we're setting here is arbitrary anyway, // so let's just use the SpaceNavigator range for our purposes. mNdofDev->axes_min = (long)-MAX_JOYSTICK_INPUT_VALUE; mNdofDev->axes_max = (long)+MAX_JOYSTICK_INPUT_VALUE; // libndofdev could be used to return deltas. Here we choose to // just have the absolute values instead. mNdofDev->absolute = 1; // init & use the first suitable NDOF device found on the USB chain // On windows preffered_device needs to be a pointer to LPDIRECTINPUTDEVICE8 if (ndof_init_first(mNdofDev, preffered_device)) { mDriverState = JDS_UNINITIALIZED; LL_WARNS() << "ndof_init_first FAILED" << LL_ENDL; } else { mDriverState = JDS_INITIALIZED; return true; } #endif return false; } // ----------------------------------------------------------------------------- void LLViewerJoystick::terminate() { #if LIB_NDOF if (mNdofDev != NULL) { ndof_libcleanup(); // frees alocated memory in mNdofDev mDriverState = JDS_UNINITIALIZED; mNdofDev = NULL; LL_INFOS("Joystick") << "Terminated connection with NDOF device." << LL_ENDL; } #endif } // ----------------------------------------------------------------------------- void LLViewerJoystick::updateStatus() { #if LIB_NDOF ndof_update(mNdofDev); for (int i=0; i<6; i++) { mAxes[i] = (F32) mNdofDev->axes[i] / mNdofDev->axes_max; } for (int i=0; i<16; i++) { mBtn[i] = mNdofDev->buttons[i]; } #endif } // ----------------------------------------------------------------------------- F32 LLViewerJoystick::getJoystickAxis(U32 axis) const { if (axis < 6) { return mAxes[axis]; } return 0.f; } // ----------------------------------------------------------------------------- U32 LLViewerJoystick::getJoystickButton(U32 button) const { if (button < 16) { return mBtn[button]; } return 0; } // ----------------------------------------------------------------------------- void LLViewerJoystick::handleRun(F32 inc) { // Decide whether to walk or run by applying a threshold, with slight // hysteresis to avoid oscillating between the two with input spikes. // Analog speed control would be better, but not likely any time soon. if (inc > gSavedSettings.getF32("JoystickRunThreshold")) { if (1 == mJoystickRun) { ++mJoystickRun; gAgent.setRunning(); gAgent.sendWalkRun(gAgent.getRunning()); } else if (0 == mJoystickRun) { // hysteresis - respond NEXT frame ++mJoystickRun; } } else { if (mJoystickRun > 0) { --mJoystickRun; if (0 == mJoystickRun) { gAgent.clearRunning(); gAgent.sendWalkRun(gAgent.getRunning()); } } } } // ----------------------------------------------------------------------------- void LLViewerJoystick::agentJump() { gAgent.moveUp(1); } // ----------------------------------------------------------------------------- void LLViewerJoystick::agentSlide(F32 inc) { if (inc < 0.f) { gAgent.moveLeft(1); } else if (inc > 0.f) { gAgent.moveLeft(-1); } } // ----------------------------------------------------------------------------- void LLViewerJoystick::agentPush(F32 inc) { if (inc < 0.f) // forward { gAgent.moveAt(1, false); } else if (inc > 0.f) // backward { gAgent.moveAt(-1, false); } } // ----------------------------------------------------------------------------- void LLViewerJoystick::agentFly(F32 inc) { if (inc < 0.f) { if (! (gAgent.getFlying() || !gAgent.canFly() || gAgent.upGrabbed() || !gSavedSettings.getBOOL("AutomaticFly")) ) { gAgent.setFlying(true); } gAgent.moveUp(1); } else if (inc > 0.f) { // crouch gAgent.moveUp(-1); } } // ----------------------------------------------------------------------------- void LLViewerJoystick::agentPitch(F32 pitch_inc) { if (pitch_inc < 0) { gAgent.setControlFlags(AGENT_CONTROL_PITCH_POS); } else if (pitch_inc > 0) { gAgent.setControlFlags(AGENT_CONTROL_PITCH_NEG); } gAgent.pitch(-pitch_inc); } // ----------------------------------------------------------------------------- void LLViewerJoystick::agentYaw(F32 yaw_inc) { // Cannot steer some vehicles in mouselook if the script grabs the controls if (gAgentCamera.cameraMouselook() && !gSavedSettings.getBOOL("JoystickMouselookYaw")) { gAgent.rotate(-yaw_inc, gAgent.getReferenceUpVector()); } else { if (yaw_inc < 0) { gAgent.setControlFlags(AGENT_CONTROL_YAW_POS); } else if (yaw_inc > 0) { gAgent.setControlFlags(AGENT_CONTROL_YAW_NEG); } gAgent.yaw(-yaw_inc); } } // ----------------------------------------------------------------------------- void LLViewerJoystick::resetDeltas(S32 axis[]) { for (U32 i = 0; i < 6; i++) { sLastDelta[i] = -mAxes[axis[i]]; sDelta[i] = 0.f; } sLastDelta[6] = sDelta[6] = 0.f; mResetFlag = false; } // ----------------------------------------------------------------------------- void LLViewerJoystick::moveObjects(bool reset) { static bool toggle_send_to_sim = false; if (!gFocusMgr.getAppHasFocus() || mDriverState != JDS_INITIALIZED || !gSavedSettings.getBOOL("JoystickEnabled") || !gSavedSettings.getBOOL("JoystickBuildEnabled")) { return; } S32 axis[] = { gSavedSettings.getS32("JoystickAxis0"), gSavedSettings.getS32("JoystickAxis1"), gSavedSettings.getS32("JoystickAxis2"), gSavedSettings.getS32("JoystickAxis3"), gSavedSettings.getS32("JoystickAxis4"), gSavedSettings.getS32("JoystickAxis5"), }; if (reset || mResetFlag) { resetDeltas(axis); return; } F32 axis_scale[] = { gSavedSettings.getF32("BuildAxisScale0"), gSavedSettings.getF32("BuildAxisScale1"), gSavedSettings.getF32("BuildAxisScale2"), gSavedSettings.getF32("BuildAxisScale3"), gSavedSettings.getF32("BuildAxisScale4"), gSavedSettings.getF32("BuildAxisScale5"), }; F32 dead_zone[] = { gSavedSettings.getF32("BuildAxisDeadZone0"), gSavedSettings.getF32("BuildAxisDeadZone1"), gSavedSettings.getF32("BuildAxisDeadZone2"), gSavedSettings.getF32("BuildAxisDeadZone3"), gSavedSettings.getF32("BuildAxisDeadZone4"), gSavedSettings.getF32("BuildAxisDeadZone5"), }; F32 cur_delta[6]; F32 time = gFrameIntervalSeconds.value(); // avoid making ridicously big movements if there's a big drop in fps if (time > .2f) { time = .2f; } // max feather is 32 F32 feather = gSavedSettings.getF32("BuildFeathering"); bool is_zero = true, absolute = gSavedSettings.getBOOL("Cursor3D"); for (U32 i = 0; i < 6; i++) { cur_delta[i] = -mAxes[axis[i]]; F32 tmp = cur_delta[i]; if (absolute) { cur_delta[i] = cur_delta[i] - sLastDelta[i]; } sLastDelta[i] = tmp; is_zero = is_zero && (cur_delta[i] == 0.f); if (cur_delta[i] > 0) { cur_delta[i] = llmax(cur_delta[i]-dead_zone[i], 0.f); } else { cur_delta[i] = llmin(cur_delta[i]+dead_zone[i], 0.f); } cur_delta[i] *= axis_scale[i]; if (!absolute) { cur_delta[i] *= time; } sDelta[i] = sDelta[i] + (cur_delta[i]-sDelta[i])*time*feather; } U32 upd_type = UPD_NONE; LLVector3 v; if (!is_zero) { // Clear AFK state if moved beyond the deadzone if (gAwayTimer.getElapsedTimeF32() > LLAgent::MIN_AFK_TIME) { gAgent.clearAFK(); } if (sDelta[0] || sDelta[1] || sDelta[2]) { upd_type |= UPD_POSITION; v.setVec(sDelta[0], sDelta[1], sDelta[2]); } if (sDelta[3] || sDelta[4] || sDelta[5]) { upd_type |= UPD_ROTATION; } // the selection update could fail, so we won't send if (LLSelectMgr::getInstance()->selectionMove(v, sDelta[3],sDelta[4],sDelta[5], upd_type)) { toggle_send_to_sim = true; } } else if (toggle_send_to_sim) { LLSelectMgr::getInstance()->sendSelectionMove(); toggle_send_to_sim = false; } } // ----------------------------------------------------------------------------- void LLViewerJoystick::moveAvatar(bool reset) { if (!gFocusMgr.getAppHasFocus() || mDriverState != JDS_INITIALIZED || !gSavedSettings.getBOOL("JoystickEnabled") || !gSavedSettings.getBOOL("JoystickAvatarEnabled")) { return; } S32 axis[] = { // [1 0 2 4 3 5] // [Z X Y RZ RX RY] gSavedSettings.getS32("JoystickAxis0"), gSavedSettings.getS32("JoystickAxis1"), gSavedSettings.getS32("JoystickAxis2"), gSavedSettings.getS32("JoystickAxis3"), gSavedSettings.getS32("JoystickAxis4"), gSavedSettings.getS32("JoystickAxis5") }; if (reset || mResetFlag) { resetDeltas(axis); if (reset) { // Note: moving the agent triggers agent camera mode; // don't do this every time we set mResetFlag (e.g. because we gained focus) gAgent.moveAt(0, true); } return; } bool is_zero = true; static bool button_held = false; if (mBtn[1] == 1) { // If AutomaticFly is enabled, then button1 merely causes a // jump (as the up/down axis already controls flying) if on the // ground, or cease flight if already flying. // If AutomaticFly is disabled, then button1 toggles flying. if (gSavedSettings.getBOOL("AutomaticFly")) { if (!gAgent.getFlying()) { gAgent.moveUp(1); } else if (!button_held) { button_held = true; gAgent.setFlying(false); } } else if (!button_held) { button_held = true; gAgent.setFlying(!gAgent.getFlying()); } is_zero = false; } else { button_held = false; } F32 axis_scale[] = { gSavedSettings.getF32("AvatarAxisScale0"), gSavedSettings.getF32("AvatarAxisScale1"), gSavedSettings.getF32("AvatarAxisScale2"), gSavedSettings.getF32("AvatarAxisScale3"), gSavedSettings.getF32("AvatarAxisScale4"), gSavedSettings.getF32("AvatarAxisScale5") }; F32 dead_zone[] = { gSavedSettings.getF32("AvatarAxisDeadZone0"), gSavedSettings.getF32("AvatarAxisDeadZone1"), gSavedSettings.getF32("AvatarAxisDeadZone2"), gSavedSettings.getF32("AvatarAxisDeadZone3"), gSavedSettings.getF32("AvatarAxisDeadZone4"), gSavedSettings.getF32("AvatarAxisDeadZone5") }; // time interval in seconds between this frame and the previous F32 time = gFrameIntervalSeconds.value(); // avoid making ridicously big movements if there's a big drop in fps if (time > .2f) { time = .2f; } // note: max feather is 32.0 F32 feather = gSavedSettings.getF32("AvatarFeathering"); F32 cur_delta[6]; F32 val, dom_mov = 0.f; U32 dom_axis = Z_I; #if LIB_NDOF bool absolute = (gSavedSettings.getBOOL("Cursor3D") && mNdofDev->absolute); #else bool absolute = false; #endif // remove dead zones and determine biggest movement on the joystick for (U32 i = 0; i < 6; i++) { cur_delta[i] = -mAxes[axis[i]]; if (absolute) { F32 tmp = cur_delta[i]; cur_delta[i] = cur_delta[i] - sLastDelta[i]; sLastDelta[i] = tmp; } if (cur_delta[i] > 0) { cur_delta[i] = llmax(cur_delta[i]-dead_zone[i], 0.f); } else { cur_delta[i] = llmin(cur_delta[i]+dead_zone[i], 0.f); } // we don't care about Roll (RZ) and Z is calculated after the loop if (i != Z_I && i != RZ_I) { // find out the axis with the biggest joystick motion val = fabs(cur_delta[i]); if (val > dom_mov) { dom_axis = i; dom_mov = val; } } is_zero = is_zero && (cur_delta[i] == 0.f); } if (!is_zero) { // Clear AFK state if moved beyond the deadzone if (gAwayTimer.getElapsedTimeF32() > LLAgent::MIN_AFK_TIME) { gAgent.clearAFK(); } setCameraNeedsUpdate(true); } // forward|backward movements overrule the real dominant movement if // they're bigger than its 20%. This is what you want 'cos moving forward // is what you do most. We also added a special (even more lenient) case // for RX|RY to allow walking while pitching and turning if (fabs(cur_delta[Z_I]) > .2f * dom_mov || ((dom_axis == RX_I || dom_axis == RY_I) && fabs(cur_delta[Z_I]) > .05f * dom_mov)) { dom_axis = Z_I; } sDelta[X_I] = -cur_delta[X_I] * axis_scale[X_I]; sDelta[Y_I] = -cur_delta[Y_I] * axis_scale[Y_I]; sDelta[Z_I] = -cur_delta[Z_I] * axis_scale[Z_I]; cur_delta[RX_I] *= -axis_scale[RX_I] * mPerfScale; cur_delta[RY_I] *= -axis_scale[RY_I] * mPerfScale; if (!absolute) { cur_delta[RX_I] *= time; cur_delta[RY_I] *= time; } sDelta[RX_I] += (cur_delta[RX_I] - sDelta[RX_I]) * time * feather; sDelta[RY_I] += (cur_delta[RY_I] - sDelta[RY_I]) * time * feather; handleRun((F32) sqrt(sDelta[Z_I]*sDelta[Z_I] + sDelta[X_I]*sDelta[X_I])); // Allow forward/backward movement some priority if (dom_axis == Z_I) { agentPush(sDelta[Z_I]); // forward/back if (fabs(sDelta[X_I]) > .1f) { agentSlide(sDelta[X_I]); // move sideways } if (fabs(sDelta[Y_I]) > .1f) { agentFly(sDelta[Y_I]); // up/down & crouch } // too many rotations during walking can be confusing, so apply // the deadzones one more time (quick & dirty), at 50%|30% power F32 eff_rx = .3f * dead_zone[RX_I]; F32 eff_ry = .3f * dead_zone[RY_I]; if (sDelta[RX_I] > 0) { eff_rx = llmax(sDelta[RX_I] - eff_rx, 0.f); } else { eff_rx = llmin(sDelta[RX_I] + eff_rx, 0.f); } if (sDelta[RY_I] > 0) { eff_ry = llmax(sDelta[RY_I] - eff_ry, 0.f); } else { eff_ry = llmin(sDelta[RY_I] + eff_ry, 0.f); } if (fabs(eff_rx) > 0.f || fabs(eff_ry) > 0.f) { if (gAgent.getFlying()) { agentPitch(eff_rx); agentYaw(eff_ry); } else { agentPitch(eff_rx); agentYaw(2.f * eff_ry); } } } else { agentSlide(sDelta[X_I]); // move sideways agentFly(sDelta[Y_I]); // up/down & crouch agentPush(sDelta[Z_I]); // forward/back agentPitch(sDelta[RX_I]); // pitch agentYaw(sDelta[RY_I]); // turn } } // ----------------------------------------------------------------------------- void LLViewerJoystick::moveFlycam(bool reset) { static LLQuaternion sFlycamRotation; static LLVector3 sFlycamPosition; static F32 sFlycamZoom; if (!gFocusMgr.getAppHasFocus() || mDriverState != JDS_INITIALIZED || !gSavedSettings.getBOOL("JoystickEnabled") || !gSavedSettings.getBOOL("JoystickFlycamEnabled")) { return; } S32 axis[] = { gSavedSettings.getS32("JoystickAxis0"), gSavedSettings.getS32("JoystickAxis1"), gSavedSettings.getS32("JoystickAxis2"), gSavedSettings.getS32("JoystickAxis3"), gSavedSettings.getS32("JoystickAxis4"), gSavedSettings.getS32("JoystickAxis5"), gSavedSettings.getS32("JoystickAxis6") }; bool in_build_mode = LLToolMgr::getInstance()->inBuildMode(); if (reset || mResetFlag) { sFlycamPosition = LLViewerCamera::getInstance()->getOrigin(); sFlycamRotation = LLViewerCamera::getInstance()->getQuaternion(); sFlycamZoom = LLViewerCamera::getInstance()->getView(); resetDeltas(axis); return; } F32 axis_scale[] = { gSavedSettings.getF32("FlycamAxisScale0"), gSavedSettings.getF32("FlycamAxisScale1"), gSavedSettings.getF32("FlycamAxisScale2"), gSavedSettings.getF32("FlycamAxisScale3"), gSavedSettings.getF32("FlycamAxisScale4"), gSavedSettings.getF32("FlycamAxisScale5"), gSavedSettings.getF32("FlycamAxisScale6") }; F32 dead_zone[] = { gSavedSettings.getF32("FlycamAxisDeadZone0"), gSavedSettings.getF32("FlycamAxisDeadZone1"), gSavedSettings.getF32("FlycamAxisDeadZone2"), gSavedSettings.getF32("FlycamAxisDeadZone3"), gSavedSettings.getF32("FlycamAxisDeadZone4"), gSavedSettings.getF32("FlycamAxisDeadZone5"), gSavedSettings.getF32("FlycamAxisDeadZone6") }; F32 time = gFrameIntervalSeconds.value(); // avoid making ridiculously big movements if there's a big drop in fps if (time > .2f) { time = .2f; } F32 cur_delta[7]; F32 feather = gSavedSettings.getF32("FlycamFeathering"); bool absolute = gSavedSettings.getBOOL("Cursor3D"); bool is_zero = true; for (U32 i = 0; i < 7; i++) { cur_delta[i] = -getJoystickAxis(axis[i]); F32 tmp = cur_delta[i]; if (absolute) { cur_delta[i] = cur_delta[i] - sLastDelta[i]; } sLastDelta[i] = tmp; if (cur_delta[i] > 0) { cur_delta[i] = llmax(cur_delta[i]-dead_zone[i], 0.f); } else { cur_delta[i] = llmin(cur_delta[i]+dead_zone[i], 0.f); } // We may want to scale camera movements up or down in build mode. // NOTE: this needs to remain after the deadzone calculation, otherwise // we have issues with flycam "jumping" when the build dialog is opened/closed -Nyx if (in_build_mode) { if (i == X_I || i == Y_I || i == Z_I) { static LLCachedControl build_mode_scale(gSavedSettings,"FlycamBuildModeScale", 1.0); cur_delta[i] *= build_mode_scale; } } cur_delta[i] *= axis_scale[i]; if (!absolute) { cur_delta[i] *= time; } sDelta[i] = sDelta[i] + (cur_delta[i]-sDelta[i])*time*feather; is_zero = is_zero && (cur_delta[i] == 0.f); } // Clear AFK state if moved beyond the deadzone if (!is_zero && gAwayTimer.getElapsedTimeF32() > LLAgent::MIN_AFK_TIME) { gAgent.clearAFK(); } sFlycamPosition += LLVector3(sDelta) * sFlycamRotation; LLMatrix3 rot_mat(sDelta[3], sDelta[4], sDelta[5]); sFlycamRotation = LLQuaternion(rot_mat)*sFlycamRotation; if (gSavedSettings.getBOOL("AutoLeveling")) { LLMatrix3 level(sFlycamRotation); LLVector3 x = LLVector3(level.mMatrix[0]); LLVector3 y = LLVector3(level.mMatrix[1]); LLVector3 z = LLVector3(level.mMatrix[2]); y.mV[2] = 0.f; y.normVec(); level.setRows(x,y,z); level.orthogonalize(); LLQuaternion quat(level); sFlycamRotation = nlerp(llmin(feather*time,1.f), sFlycamRotation, quat); } if (gSavedSettings.getBOOL("ZoomDirect")) { sFlycamZoom = sLastDelta[6]*axis_scale[6]+dead_zone[6]; } else { sFlycamZoom += sDelta[6]; } LLMatrix3 mat(sFlycamRotation); LLViewerCamera::getInstance()->setView(sFlycamZoom); LLViewerCamera::getInstance()->setOrigin(sFlycamPosition); LLViewerCamera::getInstance()->mXAxis = LLVector3(mat.mMatrix[0]); LLViewerCamera::getInstance()->mYAxis = LLVector3(mat.mMatrix[1]); LLViewerCamera::getInstance()->mZAxis = LLVector3(mat.mMatrix[2]); } // ----------------------------------------------------------------------------- bool LLViewerJoystick::toggleFlycam() { if (!gSavedSettings.getBOOL("JoystickEnabled") || !gSavedSettings.getBOOL("JoystickFlycamEnabled")) { mOverrideCamera = false; return false; } if (!mOverrideCamera) { gAgentCamera.changeCameraToDefault(); } if (gAwayTimer.getElapsedTimeF32() > LLAgent::MIN_AFK_TIME) { gAgent.clearAFK(); } mOverrideCamera = !mOverrideCamera; if (mOverrideCamera) { moveFlycam(true); } else { // Exiting from the flycam mode: since we are going to keep the flycam POV for // the main camera until the avatar moves, we need to track this situation. setCameraNeedsUpdate(false); setNeedsReset(true); } return true; } void LLViewerJoystick::scanJoystick() { if (mDriverState != JDS_INITIALIZED || !gSavedSettings.getBOOL("JoystickEnabled")) { return; } #if LL_WINDOWS // On windows, the flycam is updated syncronously with a timer, so there is // no need to update the status of the joystick here. if (!mOverrideCamera) #endif updateStatus(); // App focus check Needs to happen AFTER updateStatus in case the joystick // is not centred when the app loses focus. if (!gFocusMgr.getAppHasFocus()) { return; } static long toggle_flycam = 0; if (mBtn[0] == 1) { if (mBtn[0] != toggle_flycam) { toggle_flycam = toggleFlycam() ? 1 : 0; } } else { toggle_flycam = 0; } if (!mOverrideCamera && !(LLToolMgr::getInstance()->inBuildMode() && gSavedSettings.getBOOL("JoystickBuildEnabled"))) { moveAvatar(); } } // ----------------------------------------------------------------------------- bool LLViewerJoystick::isDeviceUUIDSet() { #if LL_WINDOWS && !LL_MESA_HEADLESS // for ease of comparison and to dial less with platform specific variables, we store id as LLSD binary return mLastDeviceUUID.isBinary(); #elif LL_DARWIN return mLastDeviceUUID.isMap(); #else return false; #endif } LLSD LLViewerJoystick::getDeviceUUID() { return mLastDeviceUUID; } std::string LLViewerJoystick::getDeviceUUIDString() { #if LL_WINDOWS && !LL_MESA_HEADLESS // Might be simpler to just convert _GUID into string everywhere, store and compare as string if (mLastDeviceUUID.isBinary()) { S32 size = sizeof(GUID); LLSD::Binary data = mLastDeviceUUID.asBinary(); GUID guid; memcpy(&guid, &data[0], size); return string_from_guid(guid); } else { return std::string(); } #elif LL_DARWIN if (mLastDeviceUUID.isMap()) { std::string manufacturer = mLastDeviceUUID["manufacturer"].asString(); std::string product = mLastDeviceUUID["product"].asString(); return manufacturer + ":" + product; } else { return std::string(); } #else return std::string(); #endif } void LLViewerJoystick::saveDeviceIdToSettings() { #if LL_WINDOWS && !LL_MESA_HEADLESS // can't save as binary directly, // someone editing the xml will corrupt it // so convert to string first std::string device_string = getDeviceUUIDString(); gSavedSettings.setLLSD("JoystickDeviceUUID", LLSD(device_string)); #else LLSD device_id = getDeviceUUID(); gSavedSettings.setLLSD("JoystickDeviceUUID", device_id); #endif } void LLViewerJoystick::loadDeviceIdFromSettings() { LLSD dev_id = gSavedSettings.getLLSD("JoystickDeviceUUID"); #if LL_WINDOWS && !LL_MESA_HEADLESS // We can't save binary data to gSavedSettings, somebody editing the file will corrupt it, // so _GUID data gets converted to string (we probably can convert it to LLUUID with memcpy) // and here we need to convert it back to binary from string std::string device_string; if (dev_id.isString()) { device_string = dev_id.asString(); } if (device_string.empty()) { mLastDeviceUUID = LLSD(); } else { LL_DEBUGS("Joystick") << "Looking for device by id: " << device_string << LL_ENDL; GUID guid; guid_from_string(guid, device_string); S32 size = sizeof(GUID); LLSD::Binary data; //just an std::vector data.resize(size); memcpy(&data[0], &guid /*POD _GUID*/, size); // We store this data in LLSD since it can handle both GUID2 and long mLastDeviceUUID = LLSD(data); } #elif LL_DARWIN if (!dev_id.isMap()) { mLastDeviceUUID = LLSD(); } else { std::string manufacturer = mLastDeviceUUID["manufacturer"].asString(); std::string product = mLastDeviceUUID["product"].asString(); LL_DEBUGS("Joystick") << "Looking for device by manufacturer: " << manufacturer << " and product: " << product << LL_ENDL; // We store this data in LLSD since it can handle both GUID2 and long mLastDeviceUUID = dev_id; } #else mLastDeviceUUID = LLSD(); //mLastDeviceUUID = gSavedSettings.getLLSD("JoystickDeviceUUID"); #endif } // ----------------------------------------------------------------------------- std::string LLViewerJoystick::getDescription() { std::string res; #if LIB_NDOF if (mDriverState == JDS_INITIALIZED && mNdofDev) { res = ll_safe_string(mNdofDev->product); } #endif return res; } bool LLViewerJoystick::isLikeSpaceNavigator() const { #if LIB_NDOF return (isJoystickInitialized() && (strncmp(mNdofDev->product, "SpaceNavigator", 14) == 0 || strncmp(mNdofDev->product, "SpaceExplorer", 13) == 0 || strncmp(mNdofDev->product, "SpaceTraveler", 13) == 0 || strncmp(mNdofDev->product, "SpacePilot", 10) == 0)); #else return false; #endif } // ----------------------------------------------------------------------------- void LLViewerJoystick::setSNDefaults() { #if LL_DARWIN || LL_LINUX const float platformScale = 20.f; const float platformScaleAvXZ = 1.f; // The SpaceNavigator doesn't act as a 3D cursor on macOS / Linux. const bool is_3d_cursor = false; #else const float platformScale = 1.f; const float platformScaleAvXZ = 2.f; const bool is_3d_cursor = true; #endif //gViewerWindow->alertXml("CacheWillClear"); LL_INFOS("Joystick") << "restoring SpaceNavigator defaults..." << LL_ENDL; gSavedSettings.setS32("JoystickAxis0", 1); // z (at) gSavedSettings.setS32("JoystickAxis1", 0); // x (slide) gSavedSettings.setS32("JoystickAxis2", 2); // y (up) gSavedSettings.setS32("JoystickAxis3", 4); // pitch gSavedSettings.setS32("JoystickAxis4", 3); // roll gSavedSettings.setS32("JoystickAxis5", 5); // yaw gSavedSettings.setS32("JoystickAxis6", -1); gSavedSettings.setBOOL("Cursor3D", is_3d_cursor); gSavedSettings.setBOOL("AutoLeveling", true); gSavedSettings.setBOOL("ZoomDirect", false); gSavedSettings.setF32("AvatarAxisScale0", 1.f * platformScaleAvXZ); gSavedSettings.setF32("AvatarAxisScale1", 1.f * platformScaleAvXZ); gSavedSettings.setF32("AvatarAxisScale2", 1.f); gSavedSettings.setF32("AvatarAxisScale4", .1f * platformScale); gSavedSettings.setF32("AvatarAxisScale5", .1f * platformScale); gSavedSettings.setF32("AvatarAxisScale3", 0.f * platformScale); gSavedSettings.setF32("BuildAxisScale1", .3f * platformScale); gSavedSettings.setF32("BuildAxisScale2", .3f * platformScale); gSavedSettings.setF32("BuildAxisScale0", .3f * platformScale); gSavedSettings.setF32("BuildAxisScale4", .3f * platformScale); gSavedSettings.setF32("BuildAxisScale5", .3f * platformScale); gSavedSettings.setF32("BuildAxisScale3", .3f * platformScale); gSavedSettings.setF32("FlycamAxisScale1", 2.f * platformScale); gSavedSettings.setF32("FlycamAxisScale2", 2.f * platformScale); gSavedSettings.setF32("FlycamAxisScale0", 2.1f * platformScale); gSavedSettings.setF32("FlycamAxisScale4", .1f * platformScale); gSavedSettings.setF32("FlycamAxisScale5", .15f * platformScale); gSavedSettings.setF32("FlycamAxisScale3", 0.f * platformScale); gSavedSettings.setF32("FlycamAxisScale6", 0.f * platformScale); gSavedSettings.setF32("AvatarAxisDeadZone0", .1f); gSavedSettings.setF32("AvatarAxisDeadZone1", .1f); gSavedSettings.setF32("AvatarAxisDeadZone2", .1f); gSavedSettings.setF32("AvatarAxisDeadZone3", 1.f); gSavedSettings.setF32("AvatarAxisDeadZone4", .02f); gSavedSettings.setF32("AvatarAxisDeadZone5", .01f); gSavedSettings.setF32("BuildAxisDeadZone0", .01f); gSavedSettings.setF32("BuildAxisDeadZone1", .01f); gSavedSettings.setF32("BuildAxisDeadZone2", .01f); gSavedSettings.setF32("BuildAxisDeadZone3", .01f); gSavedSettings.setF32("BuildAxisDeadZone4", .01f); gSavedSettings.setF32("BuildAxisDeadZone5", .01f); gSavedSettings.setF32("FlycamAxisDeadZone0", .01f); gSavedSettings.setF32("FlycamAxisDeadZone1", .01f); gSavedSettings.setF32("FlycamAxisDeadZone2", .01f); gSavedSettings.setF32("FlycamAxisDeadZone3", .01f); gSavedSettings.setF32("FlycamAxisDeadZone4", .01f); gSavedSettings.setF32("FlycamAxisDeadZone5", .01f); gSavedSettings.setF32("FlycamAxisDeadZone6", 1.f); gSavedSettings.setF32("AvatarFeathering", 6.f); gSavedSettings.setF32("BuildFeathering", 12.f); gSavedSettings.setF32("FlycamFeathering", 5.f); }