/*************************************************************************/ /* display_server_x11.cpp */ /*************************************************************************/ /* This file is part of: */ /* GODOT ENGINE */ /* https://godotengine.org */ /*************************************************************************/ /* Copyright (c) 2007-2022 Juan Linietsky, Ariel Manzur. */ /* Copyright (c) 2014-2022 Godot Engine contributors (cf. AUTHORS.md). */ /* */ /* Permission is hereby granted, free of charge, to any person obtaining */ /* a copy of this software and associated documentation files (the */ /* "Software"), to deal in the Software without restriction, including */ /* without limitation the rights to use, copy, modify, merge, publish, */ /* distribute, sublicense, and/or sell copies of the Software, and to */ /* permit persons to whom the Software is furnished to do so, subject to */ /* the following conditions: */ /* */ /* The above copyright notice and this permission notice shall be */ /* included in all copies or substantial portions of the Software. */ /* */ /* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */ /* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */ /* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.*/ /* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */ /* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */ /* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */ /* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ /*************************************************************************/ #include "display_server_x11.h" #ifdef X11_ENABLED #include "core/config/project_settings.h" #include "core/math/math_funcs.h" #include "core/string/print_string.h" #include "core/string/ustring.h" #include "detect_prime_x11.h" #include "key_mapping_x11.h" #include "main/main.h" #include "scene/resources/texture.h" #if defined(VULKAN_ENABLED) #include "servers/rendering/renderer_rd/renderer_compositor_rd.h" #endif #if defined(GLES3_ENABLED) #include "drivers/gles3/rasterizer_gles3.h" #endif #include #include #include #include #include #include #include #include #include #include #include #include // ICCCM #define WM_NormalState 1L // window normal state #define WM_IconicState 3L // window minimized // EWMH #define _NET_WM_STATE_REMOVE 0L // remove/unset property #define _NET_WM_STATE_ADD 1L // add/set property #undef CursorShape #include // 2.2 is the first release with multitouch #define XINPUT_CLIENT_VERSION_MAJOR 2 #define XINPUT_CLIENT_VERSION_MINOR 2 #define VALUATOR_ABSX 0 #define VALUATOR_ABSY 1 #define VALUATOR_PRESSURE 2 #define VALUATOR_TILTX 3 #define VALUATOR_TILTY 4 //#define DISPLAY_SERVER_X11_DEBUG_LOGS_ENABLED #ifdef DISPLAY_SERVER_X11_DEBUG_LOGS_ENABLED #define DEBUG_LOG_X11(...) printf(__VA_ARGS__) #else #define DEBUG_LOG_X11(...) #endif static const double abs_resolution_mult = 10000.0; static const double abs_resolution_range_mult = 10.0; // Hints for X11 fullscreen struct Hints { unsigned long flags = 0; unsigned long functions = 0; unsigned long decorations = 0; long inputMode = 0; unsigned long status = 0; }; static String get_atom_name(Display *p_disp, Atom p_atom) { char *name = XGetAtomName(p_disp, p_atom); ERR_FAIL_NULL_V_MSG(name, String(), "Atom is invalid."); String ret; ret.parse_utf8(name); XFree(name); return ret; } bool DisplayServerX11::has_feature(Feature p_feature) const { switch (p_feature) { case FEATURE_SUBWINDOWS: #ifdef TOUCH_ENABLED case FEATURE_TOUCHSCREEN: #endif case FEATURE_MOUSE: case FEATURE_MOUSE_WARP: case FEATURE_CLIPBOARD: case FEATURE_CURSOR_SHAPE: case FEATURE_CUSTOM_CURSOR_SHAPE: case FEATURE_IME: case FEATURE_WINDOW_TRANSPARENCY: //case FEATURE_HIDPI: case FEATURE_ICON: //case FEATURE_NATIVE_ICON: case FEATURE_SWAP_BUFFERS: #ifdef DBUS_ENABLED case FEATURE_KEEP_SCREEN_ON: #endif case FEATURE_CLIPBOARD_PRIMARY: case FEATURE_TEXT_TO_SPEECH: return true; default: { } } return false; } String DisplayServerX11::get_name() const { return "X11"; } void DisplayServerX11::_update_real_mouse_position(const WindowData &wd) { Window root_return, child_return; int root_x, root_y, win_x, win_y; unsigned int mask_return; Bool xquerypointer_result = XQueryPointer(x11_display, wd.x11_window, &root_return, &child_return, &root_x, &root_y, &win_x, &win_y, &mask_return); if (xquerypointer_result) { if (win_x > 0 && win_y > 0 && win_x <= wd.size.width && win_y <= wd.size.height) { last_mouse_pos.x = win_x; last_mouse_pos.y = win_y; last_mouse_pos_valid = true; Input::get_singleton()->set_mouse_position(last_mouse_pos); } } } bool DisplayServerX11::_refresh_device_info() { int event_base, error_base; print_verbose("XInput: Refreshing devices."); if (!XQueryExtension(x11_display, "XInputExtension", &xi.opcode, &event_base, &error_base)) { print_verbose("XInput extension not available. Please upgrade your distribution."); return false; } int xi_major_query = XINPUT_CLIENT_VERSION_MAJOR; int xi_minor_query = XINPUT_CLIENT_VERSION_MINOR; if (XIQueryVersion(x11_display, &xi_major_query, &xi_minor_query) != Success) { print_verbose(vformat("XInput 2 not available (server supports %d.%d).", xi_major_query, xi_minor_query)); xi.opcode = 0; return false; } if (xi_major_query < XINPUT_CLIENT_VERSION_MAJOR || (xi_major_query == XINPUT_CLIENT_VERSION_MAJOR && xi_minor_query < XINPUT_CLIENT_VERSION_MINOR)) { print_verbose(vformat("XInput %d.%d not available (server supports %d.%d). Touch input unavailable.", XINPUT_CLIENT_VERSION_MAJOR, XINPUT_CLIENT_VERSION_MINOR, xi_major_query, xi_minor_query)); } xi.absolute_devices.clear(); xi.touch_devices.clear(); xi.pen_inverted_devices.clear(); int dev_count; XIDeviceInfo *info = XIQueryDevice(x11_display, XIAllDevices, &dev_count); for (int i = 0; i < dev_count; i++) { XIDeviceInfo *dev = &info[i]; if (!dev->enabled) { continue; } if (!(dev->use == XISlavePointer || dev->use == XIFloatingSlave)) { continue; } bool direct_touch = false; bool absolute_mode = false; int resolution_x = 0; int resolution_y = 0; double abs_x_min = 0; double abs_x_max = 0; double abs_y_min = 0; double abs_y_max = 0; double pressure_min = 0; double pressure_max = 0; double tilt_x_min = 0; double tilt_x_max = 0; double tilt_y_min = 0; double tilt_y_max = 0; for (int j = 0; j < dev->num_classes; j++) { #ifdef TOUCH_ENABLED if (dev->classes[j]->type == XITouchClass && ((XITouchClassInfo *)dev->classes[j])->mode == XIDirectTouch) { direct_touch = true; } #endif if (dev->classes[j]->type == XIValuatorClass) { XIValuatorClassInfo *class_info = (XIValuatorClassInfo *)dev->classes[j]; if (class_info->number == VALUATOR_ABSX && class_info->mode == XIModeAbsolute) { resolution_x = class_info->resolution; abs_x_min = class_info->min; abs_x_max = class_info->max; absolute_mode = true; } else if (class_info->number == VALUATOR_ABSY && class_info->mode == XIModeAbsolute) { resolution_y = class_info->resolution; abs_y_min = class_info->min; abs_y_max = class_info->max; absolute_mode = true; } else if (class_info->number == VALUATOR_PRESSURE && class_info->mode == XIModeAbsolute) { pressure_min = class_info->min; pressure_max = class_info->max; } else if (class_info->number == VALUATOR_TILTX && class_info->mode == XIModeAbsolute) { tilt_x_min = class_info->min; tilt_x_max = class_info->max; } else if (class_info->number == VALUATOR_TILTY && class_info->mode == XIModeAbsolute) { tilt_y_min = class_info->min; tilt_y_max = class_info->max; } } } if (direct_touch) { xi.touch_devices.push_back(dev->deviceid); print_verbose("XInput: Using touch device: " + String(dev->name)); } if (absolute_mode) { // If no resolution was reported, use the min/max ranges. if (resolution_x <= 0) { resolution_x = (abs_x_max - abs_x_min) * abs_resolution_range_mult; } if (resolution_y <= 0) { resolution_y = (abs_y_max - abs_y_min) * abs_resolution_range_mult; } xi.absolute_devices[dev->deviceid] = Vector2(abs_resolution_mult / resolution_x, abs_resolution_mult / resolution_y); print_verbose("XInput: Absolute pointing device: " + String(dev->name)); } xi.pressure = 0; xi.pen_pressure_range[dev->deviceid] = Vector2(pressure_min, pressure_max); xi.pen_tilt_x_range[dev->deviceid] = Vector2(tilt_x_min, tilt_x_max); xi.pen_tilt_y_range[dev->deviceid] = Vector2(tilt_y_min, tilt_y_max); xi.pen_inverted_devices[dev->deviceid] = String(dev->name).findn("eraser") > 0; } XIFreeDeviceInfo(info); #ifdef TOUCH_ENABLED if (!xi.touch_devices.size()) { print_verbose("XInput: No touch devices found."); } #endif return true; } void DisplayServerX11::_flush_mouse_motion() { // Block events polling while flushing motion events. MutexLock mutex_lock(events_mutex); for (uint32_t event_index = 0; event_index < polled_events.size(); ++event_index) { XEvent &event = polled_events[event_index]; if (XGetEventData(x11_display, &event.xcookie) && event.xcookie.type == GenericEvent && event.xcookie.extension == xi.opcode) { XIDeviceEvent *event_data = (XIDeviceEvent *)event.xcookie.data; if (event_data->evtype == XI_RawMotion) { XFreeEventData(x11_display, &event.xcookie); polled_events.remove_at(event_index--); continue; } XFreeEventData(x11_display, &event.xcookie); break; } } xi.relative_motion.x = 0; xi.relative_motion.y = 0; } #ifdef SPEECHD_ENABLED bool DisplayServerX11::tts_is_speaking() const { ERR_FAIL_COND_V(!tts, false); return tts->is_speaking(); } bool DisplayServerX11::tts_is_paused() const { ERR_FAIL_COND_V(!tts, false); return tts->is_paused(); } TypedArray DisplayServerX11::tts_get_voices() const { ERR_FAIL_COND_V(!tts, TypedArray()); return tts->get_voices(); } void DisplayServerX11::tts_speak(const String &p_text, const String &p_voice, int p_volume, float p_pitch, float p_rate, int p_utterance_id, bool p_interrupt) { ERR_FAIL_COND(!tts); tts->speak(p_text, p_voice, p_volume, p_pitch, p_rate, p_utterance_id, p_interrupt); } void DisplayServerX11::tts_pause() { ERR_FAIL_COND(!tts); tts->pause(); } void DisplayServerX11::tts_resume() { ERR_FAIL_COND(!tts); tts->resume(); } void DisplayServerX11::tts_stop() { ERR_FAIL_COND(!tts); tts->stop(); } #endif #ifdef DBUS_ENABLED bool DisplayServerX11::is_dark_mode_supported() const { return portal_desktop->is_supported(); } bool DisplayServerX11::is_dark_mode() const { switch (portal_desktop->get_appearance_color_scheme()) { case 1: // Prefers dark theme. return true; case 2: // Prefers light theme. return false; default: // Preference unknown. return false; } } #endif void DisplayServerX11::mouse_set_mode(MouseMode p_mode) { _THREAD_SAFE_METHOD_ if (p_mode == mouse_mode) { return; } if (mouse_mode == MOUSE_MODE_CAPTURED || mouse_mode == MOUSE_MODE_CONFINED || mouse_mode == MOUSE_MODE_CONFINED_HIDDEN) { XUngrabPointer(x11_display, CurrentTime); } // The only modes that show a cursor are VISIBLE and CONFINED bool showCursor = (p_mode == MOUSE_MODE_VISIBLE || p_mode == MOUSE_MODE_CONFINED); for (const KeyValue &E : windows) { if (showCursor) { XDefineCursor(x11_display, E.value.x11_window, cursors[current_cursor]); // show cursor } else { XDefineCursor(x11_display, E.value.x11_window, null_cursor); // hide cursor } } mouse_mode = p_mode; if (mouse_mode == MOUSE_MODE_CAPTURED || mouse_mode == MOUSE_MODE_CONFINED || mouse_mode == MOUSE_MODE_CONFINED_HIDDEN) { //flush pending motion events _flush_mouse_motion(); WindowID window_id = _get_focused_window_or_popup(); if (!windows.has(window_id)) { window_id = MAIN_WINDOW_ID; } WindowData &window = windows[window_id]; if (XGrabPointer( x11_display, window.x11_window, True, ButtonPressMask | ButtonReleaseMask | PointerMotionMask, GrabModeAsync, GrabModeAsync, window.x11_window, None, CurrentTime) != GrabSuccess) { ERR_PRINT("NO GRAB"); } if (mouse_mode == MOUSE_MODE_CAPTURED) { center.x = window.size.width / 2; center.y = window.size.height / 2; XWarpPointer(x11_display, None, window.x11_window, 0, 0, 0, 0, (int)center.x, (int)center.y); Input::get_singleton()->set_mouse_position(center); } } else { do_mouse_warp = false; } XFlush(x11_display); } DisplayServerX11::MouseMode DisplayServerX11::mouse_get_mode() const { return mouse_mode; } void DisplayServerX11::warp_mouse(const Point2i &p_position) { _THREAD_SAFE_METHOD_ if (mouse_mode == MOUSE_MODE_CAPTURED) { last_mouse_pos = p_position; } else { WindowID window_id = _get_focused_window_or_popup(); if (!windows.has(window_id)) { window_id = MAIN_WINDOW_ID; } XWarpPointer(x11_display, None, windows[window_id].x11_window, 0, 0, 0, 0, (int)p_position.x, (int)p_position.y); } } Point2i DisplayServerX11::mouse_get_position() const { int number_of_screens = XScreenCount(x11_display); for (int i = 0; i < number_of_screens; i++) { Window root, child; int root_x, root_y, win_x, win_y; unsigned int mask; if (XQueryPointer(x11_display, XRootWindow(x11_display, i), &root, &child, &root_x, &root_y, &win_x, &win_y, &mask)) { XWindowAttributes root_attrs; XGetWindowAttributes(x11_display, root, &root_attrs); return Vector2i(root_attrs.x + root_x, root_attrs.y + root_y); } } return Vector2i(); } MouseButton DisplayServerX11::mouse_get_button_state() const { return last_button_state; } void DisplayServerX11::clipboard_set(const String &p_text) { _THREAD_SAFE_METHOD_ { // The clipboard content can be accessed while polling for events. MutexLock mutex_lock(events_mutex); internal_clipboard = p_text; } XSetSelectionOwner(x11_display, XA_PRIMARY, windows[MAIN_WINDOW_ID].x11_window, CurrentTime); XSetSelectionOwner(x11_display, XInternAtom(x11_display, "CLIPBOARD", 0), windows[MAIN_WINDOW_ID].x11_window, CurrentTime); } void DisplayServerX11::clipboard_set_primary(const String &p_text) { _THREAD_SAFE_METHOD_ if (!p_text.is_empty()) { { // The clipboard content can be accessed while polling for events. MutexLock mutex_lock(events_mutex); internal_clipboard_primary = p_text; } XSetSelectionOwner(x11_display, XA_PRIMARY, windows[MAIN_WINDOW_ID].x11_window, CurrentTime); XSetSelectionOwner(x11_display, XInternAtom(x11_display, "PRIMARY", 0), windows[MAIN_WINDOW_ID].x11_window, CurrentTime); } } Bool DisplayServerX11::_predicate_clipboard_selection(Display *display, XEvent *event, XPointer arg) { if (event->type == SelectionNotify && event->xselection.requestor == *(Window *)arg) { return True; } else { return False; } } Bool DisplayServerX11::_predicate_clipboard_incr(Display *display, XEvent *event, XPointer arg) { if (event->type == PropertyNotify && event->xproperty.state == PropertyNewValue) { return True; } else { return False; } } String DisplayServerX11::_clipboard_get_impl(Atom p_source, Window x11_window, Atom target) const { String ret; Window selection_owner = XGetSelectionOwner(x11_display, p_source); if (selection_owner == x11_window) { static const char *target_type = "PRIMARY"; if (p_source != None && get_atom_name(x11_display, p_source) == target_type) { return internal_clipboard_primary; } else { return internal_clipboard; } } if (selection_owner != None) { // Block events polling while processing selection events. MutexLock mutex_lock(events_mutex); Atom selection = XA_PRIMARY; XConvertSelection(x11_display, p_source, target, selection, x11_window, CurrentTime); XFlush(x11_display); // Blocking wait for predicate to be True and remove the event from the queue. XEvent event; XIfEvent(x11_display, &event, _predicate_clipboard_selection, (XPointer)&x11_window); // Do not get any data, see how much data is there. Atom type; int format, result; unsigned long len, bytes_left, dummy; unsigned char *data; XGetWindowProperty(x11_display, x11_window, selection, // Tricky.. 0, 0, // offset - len 0, // Delete 0==FALSE AnyPropertyType, // flag &type, // return type &format, // return format &len, &bytes_left, // data length &data); if (data) { XFree(data); } if (type == XInternAtom(x11_display, "INCR", 0)) { // Data is going to be received incrementally. DEBUG_LOG_X11("INCR selection started.\n"); LocalVector incr_data; uint32_t data_size = 0; bool success = false; // Delete INCR property to notify the owner. XDeleteProperty(x11_display, x11_window, type); // Process events from the queue. bool done = false; while (!done) { if (!_wait_for_events()) { // Error or timeout, abort. break; } // Non-blocking wait for next event and remove it from the queue. XEvent ev; while (XCheckIfEvent(x11_display, &ev, _predicate_clipboard_incr, nullptr)) { result = XGetWindowProperty(x11_display, x11_window, selection, // selection type 0, LONG_MAX, // offset - len True, // delete property to notify the owner AnyPropertyType, // flag &type, // return type &format, // return format &len, &bytes_left, // data length &data); DEBUG_LOG_X11("PropertyNotify: len=%lu, format=%i\n", len, format); if (result == Success) { if (data && (len > 0)) { uint32_t prev_size = incr_data.size(); if (prev_size == 0) { // First property contains initial data size. unsigned long initial_size = *(unsigned long *)data; incr_data.resize(initial_size); } else { // New chunk, resize to be safe and append data. incr_data.resize(MAX(data_size + len, prev_size)); memcpy(incr_data.ptr() + data_size, data, len); data_size += len; } } else { // Last chunk, process finished. done = true; success = true; } } else { printf("Failed to get selection data chunk.\n"); done = true; } if (data) { XFree(data); } if (done) { break; } } } if (success && (data_size > 0)) { ret.parse_utf8((const char *)incr_data.ptr(), data_size); } } else if (bytes_left > 0) { // Data is ready and can be processed all at once. result = XGetWindowProperty(x11_display, x11_window, selection, 0, bytes_left, 0, AnyPropertyType, &type, &format, &len, &dummy, &data); if (result == Success) { ret.parse_utf8((const char *)data); } else { printf("Failed to get selection data.\n"); } if (data) { XFree(data); } } } return ret; } String DisplayServerX11::_clipboard_get(Atom p_source, Window x11_window) const { String ret; Atom utf8_atom = XInternAtom(x11_display, "UTF8_STRING", True); if (utf8_atom != None) { ret = _clipboard_get_impl(p_source, x11_window, utf8_atom); } if (ret.is_empty()) { ret = _clipboard_get_impl(p_source, x11_window, XA_STRING); } return ret; } String DisplayServerX11::clipboard_get() const { _THREAD_SAFE_METHOD_ String ret; ret = _clipboard_get(XInternAtom(x11_display, "CLIPBOARD", 0), windows[MAIN_WINDOW_ID].x11_window); if (ret.is_empty()) { ret = _clipboard_get(XA_PRIMARY, windows[MAIN_WINDOW_ID].x11_window); } return ret; } String DisplayServerX11::clipboard_get_primary() const { _THREAD_SAFE_METHOD_ String ret; ret = _clipboard_get(XInternAtom(x11_display, "PRIMARY", 0), windows[MAIN_WINDOW_ID].x11_window); if (ret.is_empty()) { ret = _clipboard_get(XA_PRIMARY, windows[MAIN_WINDOW_ID].x11_window); } return ret; } Bool DisplayServerX11::_predicate_clipboard_save_targets(Display *display, XEvent *event, XPointer arg) { if (event->xany.window == *(Window *)arg) { return (event->type == SelectionRequest) || (event->type == SelectionNotify); } else { return False; } } void DisplayServerX11::_clipboard_transfer_ownership(Atom p_source, Window x11_window) const { _THREAD_SAFE_METHOD_ Window selection_owner = XGetSelectionOwner(x11_display, p_source); if (selection_owner != x11_window) { return; } // Block events polling while processing selection events. MutexLock mutex_lock(events_mutex); Atom clipboard_manager = XInternAtom(x11_display, "CLIPBOARD_MANAGER", False); Atom save_targets = XInternAtom(x11_display, "SAVE_TARGETS", False); XConvertSelection(x11_display, clipboard_manager, save_targets, None, x11_window, CurrentTime); // Process events from the queue. while (true) { if (!_wait_for_events()) { // Error or timeout, abort. break; } // Non-blocking wait for next event and remove it from the queue. XEvent ev; while (XCheckIfEvent(x11_display, &ev, _predicate_clipboard_save_targets, (XPointer)&x11_window)) { switch (ev.type) { case SelectionRequest: _handle_selection_request_event(&(ev.xselectionrequest)); break; case SelectionNotify: { if (ev.xselection.target == save_targets) { // Once SelectionNotify is received, we're done whether it succeeded or not. return; } break; } } } } } int DisplayServerX11::get_screen_count() const { _THREAD_SAFE_METHOD_ int count = 0; // Using Xinerama Extension int event_base, error_base; if (XineramaQueryExtension(x11_display, &event_base, &error_base)) { XineramaScreenInfo *xsi = XineramaQueryScreens(x11_display, &count); XFree(xsi); } else { count = XScreenCount(x11_display); } return count; } Rect2i DisplayServerX11::_screen_get_rect(int p_screen) const { Rect2i rect(0, 0, 0, 0); if (p_screen == SCREEN_OF_MAIN_WINDOW) { p_screen = window_get_current_screen(); } ERR_FAIL_COND_V(p_screen < 0, rect); // Using Xinerama Extension. int event_base, error_base; if (XineramaQueryExtension(x11_display, &event_base, &error_base)) { int count; XineramaScreenInfo *xsi = XineramaQueryScreens(x11_display, &count); // Check if screen is valid. if (p_screen < count) { rect.position.x = xsi[p_screen].x_org; rect.position.y = xsi[p_screen].y_org; rect.size.width = xsi[p_screen].width; rect.size.height = xsi[p_screen].height; } else { ERR_PRINT("Invalid screen index: " + itos(p_screen) + "(count: " + itos(count) + ")."); } if (xsi) { XFree(xsi); } } else { int count = XScreenCount(x11_display); if (p_screen < count) { Window root = XRootWindow(x11_display, p_screen); XWindowAttributes xwa; XGetWindowAttributes(x11_display, root, &xwa); rect.position.x = xwa.x; rect.position.y = xwa.y; rect.size.width = xwa.width; rect.size.height = xwa.height; } else { ERR_PRINT("Invalid screen index: " + itos(p_screen) + "(count: " + itos(count) + ")."); } } return rect; } Point2i DisplayServerX11::screen_get_position(int p_screen) const { _THREAD_SAFE_METHOD_ return _screen_get_rect(p_screen).position; } Size2i DisplayServerX11::screen_get_size(int p_screen) const { _THREAD_SAFE_METHOD_ return _screen_get_rect(p_screen).size; } bool g_bad_window = false; int bad_window_error_handler(Display *display, XErrorEvent *error) { if (error->error_code == BadWindow) { g_bad_window = true; } else { ERR_PRINT("Unhandled XServer error code: " + itos(error->error_code)); } return 0; } Rect2i DisplayServerX11::screen_get_usable_rect(int p_screen) const { _THREAD_SAFE_METHOD_ if (p_screen == SCREEN_OF_MAIN_WINDOW) { p_screen = window_get_current_screen(); } int screen_count = get_screen_count(); // Check if screen is valid. ERR_FAIL_INDEX_V(p_screen, screen_count, Rect2i(0, 0, 0, 0)); bool is_multiscreen = screen_count > 1; // Use full monitor size as fallback. Rect2i rect = _screen_get_rect(p_screen); // There's generally only one screen reported by xlib even in multi-screen setup, // in this case it's just one virtual screen composed of all physical monitors. int x11_screen_count = ScreenCount(x11_display); Window x11_window = RootWindow(x11_display, p_screen < x11_screen_count ? p_screen : 0); Atom type; int format = 0; unsigned long remaining = 0; // Find active desktop for the root window. unsigned int desktop_index = 0; Atom desktop_prop = XInternAtom(x11_display, "_NET_CURRENT_DESKTOP", True); if (desktop_prop != None) { unsigned long desktop_len = 0; unsigned char *desktop_data = nullptr; if (XGetWindowProperty(x11_display, x11_window, desktop_prop, 0, LONG_MAX, False, XA_CARDINAL, &type, &format, &desktop_len, &remaining, &desktop_data) == Success) { if ((format == 32) && (desktop_len > 0) && desktop_data) { desktop_index = (unsigned int)desktop_data[0]; } if (desktop_data) { XFree(desktop_data); } } } bool use_simple_method = true; // First check for GTK work area, which is more accurate for multi-screen setup. if (is_multiscreen) { // Use already calculated work area when available. Atom gtk_workareas_prop = XInternAtom(x11_display, "_GTK_WORKAREAS", False); if (gtk_workareas_prop != None) { char gtk_workarea_prop_name[32]; snprintf(gtk_workarea_prop_name, 32, "_GTK_WORKAREAS_D%d", desktop_index); Atom gtk_workarea_prop = XInternAtom(x11_display, gtk_workarea_prop_name, True); if (gtk_workarea_prop != None) { unsigned long workarea_len = 0; unsigned char *workarea_data = nullptr; if (XGetWindowProperty(x11_display, x11_window, gtk_workarea_prop, 0, LONG_MAX, False, XA_CARDINAL, &type, &format, &workarea_len, &remaining, &workarea_data) == Success) { if ((format == 32) && (workarea_len % 4 == 0) && workarea_data) { long *rect_data = (long *)workarea_data; for (uint32_t data_offset = 0; data_offset < workarea_len; data_offset += 4) { Rect2i workarea_rect; workarea_rect.position.x = rect_data[data_offset]; workarea_rect.position.y = rect_data[data_offset + 1]; workarea_rect.size.x = rect_data[data_offset + 2]; workarea_rect.size.y = rect_data[data_offset + 3]; // Intersect with actual monitor size to find the correct area, // because areas are not in the same order as screens from Xinerama. if (rect.grow(-1).intersects(workarea_rect)) { rect = rect.intersection(workarea_rect); XFree(workarea_data); return rect; } } } } if (workarea_data) { XFree(workarea_data); } } } // Fallback to calculating work area by hand from struts. Atom client_list_prop = XInternAtom(x11_display, "_NET_CLIENT_LIST", True); if (client_list_prop != None) { unsigned long clients_len = 0; unsigned char *clients_data = nullptr; if (XGetWindowProperty(x11_display, x11_window, client_list_prop, 0, LONG_MAX, False, XA_WINDOW, &type, &format, &clients_len, &remaining, &clients_data) == Success) { if ((format == 32) && (clients_len > 0) && clients_data) { Window *windows_data = (Window *)clients_data; Rect2i desktop_rect; bool desktop_valid = false; // Get full desktop size. { Atom desktop_geometry_prop = XInternAtom(x11_display, "_NET_DESKTOP_GEOMETRY", True); if (desktop_geometry_prop != None) { unsigned long geom_len = 0; unsigned char *geom_data = nullptr; if (XGetWindowProperty(x11_display, x11_window, desktop_geometry_prop, 0, LONG_MAX, False, XA_CARDINAL, &type, &format, &geom_len, &remaining, &geom_data) == Success) { if ((format == 32) && (geom_len >= 2) && geom_data) { desktop_valid = true; long *size_data = (long *)geom_data; desktop_rect.size.x = size_data[0]; desktop_rect.size.y = size_data[1]; } } if (geom_data) { XFree(geom_data); } } } // Get full desktop position. if (desktop_valid) { Atom desktop_viewport_prop = XInternAtom(x11_display, "_NET_DESKTOP_VIEWPORT", True); if (desktop_viewport_prop != None) { unsigned long viewport_len = 0; unsigned char *viewport_data = nullptr; if (XGetWindowProperty(x11_display, x11_window, desktop_viewport_prop, 0, LONG_MAX, False, XA_CARDINAL, &type, &format, &viewport_len, &remaining, &viewport_data) == Success) { if ((format == 32) && (viewport_len >= 2) && viewport_data) { desktop_valid = true; long *pos_data = (long *)viewport_data; desktop_rect.position.x = pos_data[0]; desktop_rect.position.y = pos_data[1]; } } if (viewport_data) { XFree(viewport_data); } } } if (desktop_valid) { use_simple_method = false; // Handle bad window errors silently because there's no other way to check // that one of the windows has been destroyed in the meantime. int (*oldHandler)(Display *, XErrorEvent *) = XSetErrorHandler(&bad_window_error_handler); for (unsigned long win_index = 0; win_index < clients_len; ++win_index) { g_bad_window = false; // Remove strut size from desktop size to get a more accurate result. bool strut_found = false; unsigned long strut_len = 0; unsigned char *strut_data = nullptr; Atom strut_partial_prop = XInternAtom(x11_display, "_NET_WM_STRUT_PARTIAL", True); if (strut_partial_prop != None) { if (XGetWindowProperty(x11_display, windows_data[win_index], strut_partial_prop, 0, LONG_MAX, False, XA_CARDINAL, &type, &format, &strut_len, &remaining, &strut_data) == Success) { strut_found = true; } } // Fallback to older strut property. if (!g_bad_window && !strut_found) { Atom strut_prop = XInternAtom(x11_display, "_NET_WM_STRUT", True); if (strut_prop != None) { if (XGetWindowProperty(x11_display, windows_data[win_index], strut_prop, 0, LONG_MAX, False, XA_CARDINAL, &type, &format, &strut_len, &remaining, &strut_data) == Success) { strut_found = true; } } } if (!g_bad_window && strut_found && (format == 32) && (strut_len >= 4) && strut_data) { long *struts = (long *)strut_data; long left = struts[0]; long right = struts[1]; long top = struts[2]; long bottom = struts[3]; long left_start_y, left_end_y, right_start_y, right_end_y; long top_start_x, top_end_x, bottom_start_x, bottom_end_x; if (strut_len >= 12) { left_start_y = struts[4]; left_end_y = struts[5]; right_start_y = struts[6]; right_end_y = struts[7]; top_start_x = struts[8]; top_end_x = struts[9]; bottom_start_x = struts[10]; bottom_end_x = struts[11]; } else { left_start_y = 0; left_end_y = desktop_rect.size.y; right_start_y = 0; right_end_y = desktop_rect.size.y; top_start_x = 0; top_end_x = desktop_rect.size.x; bottom_start_x = 0; bottom_end_x = desktop_rect.size.x; } const Point2i &pos = desktop_rect.position; const Size2i &size = desktop_rect.size; Rect2i left_rect(pos.x, pos.y + left_start_y, left, left_end_y - left_start_y); if (left_rect.size.x > 0) { Rect2i intersection = rect.intersection(left_rect); if (intersection.has_area() && intersection.size.x < rect.size.x) { rect.position.x = left_rect.size.x; rect.size.x = rect.size.x - intersection.size.x; } } Rect2i right_rect(pos.x + size.x - right, pos.y + right_start_y, right, right_end_y - right_start_y); if (right_rect.size.x > 0) { Rect2i intersection = rect.intersection(right_rect); if (intersection.has_area() && right_rect.size.x < rect.size.x) { rect.size.x = intersection.position.x - rect.position.x; } } Rect2i top_rect(pos.x + top_start_x, pos.y, top_end_x - top_start_x, top); if (top_rect.size.y > 0) { Rect2i intersection = rect.intersection(top_rect); if (intersection.has_area() && intersection.size.y < rect.size.y) { rect.position.y = top_rect.size.y; rect.size.y = rect.size.y - intersection.size.y; } } Rect2i bottom_rect(pos.x + bottom_start_x, pos.y + size.y - bottom, bottom_end_x - bottom_start_x, bottom); if (bottom_rect.size.y > 0) { Rect2i intersection = rect.intersection(bottom_rect); if (intersection.has_area() && right_rect.size.y < rect.size.y) { rect.size.y = intersection.position.y - rect.position.y; } } } if (strut_data) { XFree(strut_data); } } // Restore default error handler. XSetErrorHandler(oldHandler); } } } if (clients_data) { XFree(clients_data); } } } // Single screen or fallback for multi screen. if (use_simple_method) { // Get desktop available size from the global work area. Atom workarea_prop = XInternAtom(x11_display, "_NET_WORKAREA", True); if (workarea_prop != None) { unsigned long workarea_len = 0; unsigned char *workarea_data = nullptr; if (XGetWindowProperty(x11_display, x11_window, workarea_prop, 0, LONG_MAX, False, XA_CARDINAL, &type, &format, &workarea_len, &remaining, &workarea_data) == Success) { if ((format == 32) && (workarea_len >= ((desktop_index + 1) * 4)) && workarea_data) { long *rect_data = (long *)workarea_data; int data_offset = desktop_index * 4; Rect2i workarea_rect; workarea_rect.position.x = rect_data[data_offset]; workarea_rect.position.y = rect_data[data_offset + 1]; workarea_rect.size.x = rect_data[data_offset + 2]; workarea_rect.size.y = rect_data[data_offset + 3]; // Intersect with actual monitor size to get a proper approximation in multi-screen setup. if (!is_multiscreen) { rect = workarea_rect; } else if (rect.intersects(workarea_rect)) { rect = rect.intersection(workarea_rect); } } } if (workarea_data) { XFree(workarea_data); } } } return rect; } int DisplayServerX11::screen_get_dpi(int p_screen) const { _THREAD_SAFE_METHOD_ if (p_screen == SCREEN_OF_MAIN_WINDOW) { p_screen = window_get_current_screen(); } //invalid screen? ERR_FAIL_INDEX_V(p_screen, get_screen_count(), 0); //Get physical monitor Dimensions through XRandR and calculate dpi Size2i sc = screen_get_size(p_screen); if (xrandr_ext_ok) { int count = 0; if (xrr_get_monitors) { xrr_monitor_info *monitors = xrr_get_monitors(x11_display, windows[MAIN_WINDOW_ID].x11_window, true, &count); if (p_screen < count) { double xdpi = sc.width / (double)monitors[p_screen].mwidth * 25.4; double ydpi = sc.height / (double)monitors[p_screen].mheight * 25.4; xrr_free_monitors(monitors); return (xdpi + ydpi) / 2; } xrr_free_monitors(monitors); } else if (p_screen == 0) { XRRScreenSize *sizes = XRRSizes(x11_display, 0, &count); if (sizes) { double xdpi = sc.width / (double)sizes[0].mwidth * 25.4; double ydpi = sc.height / (double)sizes[0].mheight * 25.4; return (xdpi + ydpi) / 2; } } } int width_mm = DisplayWidthMM(x11_display, p_screen); int height_mm = DisplayHeightMM(x11_display, p_screen); double xdpi = (width_mm ? sc.width / (double)width_mm * 25.4 : 0); double ydpi = (height_mm ? sc.height / (double)height_mm * 25.4 : 0); if (xdpi || ydpi) { return (xdpi + ydpi) / (xdpi && ydpi ? 2 : 1); } //could not get dpi return 96; } float DisplayServerX11::screen_get_refresh_rate(int p_screen) const { _THREAD_SAFE_METHOD_ if (p_screen == SCREEN_OF_MAIN_WINDOW) { p_screen = window_get_current_screen(); } //invalid screen? ERR_FAIL_INDEX_V(p_screen, get_screen_count(), SCREEN_REFRESH_RATE_FALLBACK); //Use xrandr to get screen refresh rate. if (xrandr_ext_ok) { XRRScreenResources *screen_info = XRRGetScreenResources(x11_display, windows[MAIN_WINDOW_ID].x11_window); if (screen_info) { RRMode current_mode = 0; xrr_monitor_info *monitors = nullptr; if (xrr_get_monitors) { int count = 0; monitors = xrr_get_monitors(x11_display, windows[MAIN_WINDOW_ID].x11_window, true, &count); ERR_FAIL_INDEX_V(p_screen, count, SCREEN_REFRESH_RATE_FALLBACK); } else { ERR_PRINT("An error occurred while trying to get the screen refresh rate."); return SCREEN_REFRESH_RATE_FALLBACK; } bool found_active_mode = false; for (int crtc = 0; crtc < screen_info->ncrtc; crtc++) { // Loop through outputs to find which one is currently outputting. XRRCrtcInfo *monitor_info = XRRGetCrtcInfo(x11_display, screen_info, screen_info->crtcs[crtc]); if (monitor_info->x != monitors[p_screen].x || monitor_info->y != monitors[p_screen].y) { // If X and Y aren't the same as the monitor we're looking for, this isn't the right monitor. Continue. continue; } if (monitor_info->mode != None) { current_mode = monitor_info->mode; found_active_mode = true; break; } } if (found_active_mode) { for (int mode = 0; mode < screen_info->nmode; mode++) { XRRModeInfo m_info = screen_info->modes[mode]; if (m_info.id == current_mode) { // Snap to nearest 0.01 to stay consistent with other platforms. return Math::snapped((float)m_info.dotClock / ((float)m_info.hTotal * (float)m_info.vTotal), 0.01); } } } ERR_PRINT("An error occurred while trying to get the screen refresh rate."); // We should have returned the refresh rate by now. An error must have occurred. return SCREEN_REFRESH_RATE_FALLBACK; } else { ERR_PRINT("An error occurred while trying to get the screen refresh rate."); return SCREEN_REFRESH_RATE_FALLBACK; } } ERR_PRINT("An error occurred while trying to get the screen refresh rate."); return SCREEN_REFRESH_RATE_FALLBACK; } #ifdef DBUS_ENABLED void DisplayServerX11::screen_set_keep_on(bool p_enable) { if (screen_is_kept_on() == p_enable) { return; } if (p_enable) { screensaver->inhibit(); } else { screensaver->uninhibit(); } keep_screen_on = p_enable; } bool DisplayServerX11::screen_is_kept_on() const { return keep_screen_on; } #endif Vector DisplayServerX11::get_window_list() const { _THREAD_SAFE_METHOD_ Vector ret; for (const KeyValue &E : windows) { ret.push_back(E.key); } return ret; } DisplayServer::WindowID DisplayServerX11::create_sub_window(WindowMode p_mode, VSyncMode p_vsync_mode, uint32_t p_flags, const Rect2i &p_rect) { _THREAD_SAFE_METHOD_ WindowID id = _create_window(p_mode, p_vsync_mode, p_flags, p_rect); for (int i = 0; i < WINDOW_FLAG_MAX; i++) { if (p_flags & (1 << i)) { window_set_flag(WindowFlags(i), true, id); } } return id; } void DisplayServerX11::show_window(WindowID p_id) { _THREAD_SAFE_METHOD_ const WindowData &wd = windows[p_id]; popup_open(p_id); DEBUG_LOG_X11("show_window: %lu (%u) \n", wd.x11_window, p_id); XMapWindow(x11_display, wd.x11_window); } void DisplayServerX11::delete_sub_window(WindowID p_id) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_id)); ERR_FAIL_COND_MSG(p_id == MAIN_WINDOW_ID, "Main window can't be deleted"); popup_close(p_id); WindowData &wd = windows[p_id]; DEBUG_LOG_X11("delete_sub_window: %lu (%u) \n", wd.x11_window, p_id); while (wd.transient_children.size()) { window_set_transient(*wd.transient_children.begin(), INVALID_WINDOW_ID); } if (wd.transient_parent != INVALID_WINDOW_ID) { window_set_transient(p_id, INVALID_WINDOW_ID); } #ifdef VULKAN_ENABLED if (context_vulkan) { context_vulkan->window_destroy(p_id); } #endif #ifdef GLES3_ENABLED if (gl_manager) { gl_manager->window_destroy(p_id); } #endif XUnmapWindow(x11_display, wd.x11_window); XDestroyWindow(x11_display, wd.x11_window); if (wd.xic) { XDestroyIC(wd.xic); wd.xic = nullptr; } windows.erase(p_id); } int64_t DisplayServerX11::window_get_native_handle(HandleType p_handle_type, WindowID p_window) const { ERR_FAIL_COND_V(!windows.has(p_window), 0); switch (p_handle_type) { case DISPLAY_HANDLE: { return (int64_t)x11_display; } case WINDOW_HANDLE: { return (int64_t)windows[p_window].x11_window; } case WINDOW_VIEW: { return 0; // Not supported. } #ifdef GLES3_ENABLED case OPENGL_CONTEXT: { return (int64_t)gl_manager->get_glx_context(p_window); } #endif default: { return 0; } } } void DisplayServerX11::window_attach_instance_id(ObjectID p_instance, WindowID p_window) { ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; wd.instance_id = p_instance; } ObjectID DisplayServerX11::window_get_attached_instance_id(WindowID p_window) const { ERR_FAIL_COND_V(!windows.has(p_window), ObjectID()); const WindowData &wd = windows[p_window]; return wd.instance_id; } DisplayServerX11::WindowID DisplayServerX11::get_window_at_screen_position(const Point2i &p_position) const { WindowID found_window = INVALID_WINDOW_ID; WindowID parent_window = INVALID_WINDOW_ID; unsigned int focus_order = 0; for (const KeyValue &E : windows) { const WindowData &wd = E.value; // Discard windows with no focus. if (wd.focus_order == 0) { continue; } // Find topmost window which contains the given position. WindowID window_id = E.key; Rect2i win_rect = Rect2i(window_get_position(window_id), window_get_size(window_id)); if (win_rect.has_point(p_position)) { // For siblings, pick the window which was focused last. if ((parent_window != wd.transient_parent) || (wd.focus_order > focus_order)) { found_window = window_id; parent_window = wd.transient_parent; focus_order = wd.focus_order; } } } return found_window; } void DisplayServerX11::window_set_title(const String &p_title, WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; XStoreName(x11_display, wd.x11_window, p_title.utf8().get_data()); Atom _net_wm_name = XInternAtom(x11_display, "_NET_WM_NAME", false); Atom utf8_string = XInternAtom(x11_display, "UTF8_STRING", false); if (_net_wm_name != None && utf8_string != None) { XChangeProperty(x11_display, wd.x11_window, _net_wm_name, utf8_string, 8, PropModeReplace, (unsigned char *)p_title.utf8().get_data(), p_title.utf8().length()); } } void DisplayServerX11::window_set_mouse_passthrough(const Vector &p_region, WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); const WindowData &wd = windows[p_window]; int event_base, error_base; const Bool ext_okay = XShapeQueryExtension(x11_display, &event_base, &error_base); if (ext_okay) { Region region; if (p_region.size() == 0) { region = XCreateRegion(); XRectangle rect; rect.x = 0; rect.y = 0; rect.width = window_get_real_size(p_window).x; rect.height = window_get_real_size(p_window).y; XUnionRectWithRegion(&rect, region, region); } else { XPoint *points = (XPoint *)memalloc(sizeof(XPoint) * p_region.size()); for (int i = 0; i < p_region.size(); i++) { points[i].x = p_region[i].x; points[i].y = p_region[i].y; } region = XPolygonRegion(points, p_region.size(), EvenOddRule); memfree(points); } XShapeCombineRegion(x11_display, wd.x11_window, ShapeInput, 0, 0, region, ShapeSet); XDestroyRegion(region); } } void DisplayServerX11::window_set_rect_changed_callback(const Callable &p_callable, WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; wd.rect_changed_callback = p_callable; } void DisplayServerX11::window_set_window_event_callback(const Callable &p_callable, WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; wd.event_callback = p_callable; } void DisplayServerX11::window_set_input_event_callback(const Callable &p_callable, WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; wd.input_event_callback = p_callable; } void DisplayServerX11::window_set_input_text_callback(const Callable &p_callable, WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; wd.input_text_callback = p_callable; } void DisplayServerX11::window_set_drop_files_callback(const Callable &p_callable, WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; wd.drop_files_callback = p_callable; } int DisplayServerX11::window_get_current_screen(WindowID p_window) const { _THREAD_SAFE_METHOD_ int count = get_screen_count(); if (count < 2) { // Early exit with single monitor. return 0; } ERR_FAIL_COND_V(!windows.has(p_window), 0); const WindowData &wd = windows[p_window]; const Rect2i window_rect(wd.position, wd.size); // Find which monitor has the largest overlap with the given window. int screen_index = 0; int max_area = 0; for (int i = 0; i < count; i++) { Rect2i screen_rect = _screen_get_rect(i); Rect2i intersection = screen_rect.intersection(window_rect); int area = intersection.get_area(); if (area > max_area) { max_area = area; screen_index = i; } } return screen_index; } void DisplayServerX11::gl_window_make_current(DisplayServer::WindowID p_window_id) { #if defined(GLES3_ENABLED) if (gl_manager) { gl_manager->window_make_current(p_window_id); } #endif } void DisplayServerX11::window_set_current_screen(int p_screen, WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; if (p_screen == SCREEN_OF_MAIN_WINDOW) { p_screen = window_get_current_screen(); } // Check if screen is valid ERR_FAIL_INDEX(p_screen, get_screen_count()); if (window_get_mode(p_window) == WINDOW_MODE_FULLSCREEN) { Point2i position = screen_get_position(p_screen); Size2i size = screen_get_size(p_screen); XMoveResizeWindow(x11_display, wd.x11_window, position.x, position.y, size.x, size.y); } else { if (p_screen != window_get_current_screen(p_window)) { Vector2 ofs = window_get_position(p_window) - screen_get_position(window_get_current_screen(p_window)); window_set_position(ofs + screen_get_position(p_screen), p_window); } } } void DisplayServerX11::window_set_transient(WindowID p_window, WindowID p_parent) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(p_window == p_parent); ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd_window = windows[p_window]; WindowID prev_parent = wd_window.transient_parent; ERR_FAIL_COND(prev_parent == p_parent); DEBUG_LOG_X11("window_set_transient: %lu (%u), prev_parent=%u, parent=%u\n", wd_window.x11_window, p_window, prev_parent, p_parent); ERR_FAIL_COND_MSG(wd_window.on_top, "Windows with the 'on top' can't become transient."); if (p_parent == INVALID_WINDOW_ID) { //remove transient ERR_FAIL_COND(prev_parent == INVALID_WINDOW_ID); ERR_FAIL_COND(!windows.has(prev_parent)); WindowData &wd_parent = windows[prev_parent]; wd_window.transient_parent = INVALID_WINDOW_ID; wd_parent.transient_children.erase(p_window); XSetTransientForHint(x11_display, wd_window.x11_window, None); XWindowAttributes xwa; XSync(x11_display, False); XGetWindowAttributes(x11_display, wd_parent.x11_window, &xwa); // Set focus to parent sub window to avoid losing all focus when closing a nested sub-menu. // RevertToPointerRoot is used to make sure we don't lose all focus in case // a subwindow and its parent are both destroyed. if (!wd_window.no_focus && !wd_window.is_popup && wd_window.focused) { if ((xwa.map_state == IsViewable) && !wd_parent.no_focus && !wd_window.is_popup) { XSetInputFocus(x11_display, wd_parent.x11_window, RevertToPointerRoot, CurrentTime); } } } else { ERR_FAIL_COND(!windows.has(p_parent)); ERR_FAIL_COND_MSG(prev_parent != INVALID_WINDOW_ID, "Window already has a transient parent"); WindowData &wd_parent = windows[p_parent]; wd_window.transient_parent = p_parent; wd_parent.transient_children.insert(p_window); XSetTransientForHint(x11_display, wd_window.x11_window, wd_parent.x11_window); } } // Helper method. Assumes that the window id has already been checked and exists. void DisplayServerX11::_update_size_hints(WindowID p_window) { WindowData &wd = windows[p_window]; WindowMode window_mode = window_get_mode(p_window); XSizeHints *xsh = XAllocSizeHints(); // Always set the position and size hints - they should be synchronized with the actual values after the window is mapped anyway xsh->flags |= PPosition | PSize; xsh->x = wd.position.x; xsh->y = wd.position.y; xsh->width = wd.size.width; xsh->height = wd.size.height; if (window_mode == WINDOW_MODE_FULLSCREEN) { // Do not set any other hints to prevent the window manager from ignoring the fullscreen flags } else if (window_get_flag(WINDOW_FLAG_RESIZE_DISABLED, p_window)) { // If resizing is disabled, use the forced size xsh->flags |= PMinSize | PMaxSize; xsh->min_width = wd.size.x; xsh->max_width = wd.size.x; xsh->min_height = wd.size.y; xsh->max_height = wd.size.y; } else { // Otherwise, just respect min_size and max_size if (wd.min_size != Size2i()) { xsh->flags |= PMinSize; xsh->min_width = wd.min_size.x; xsh->min_height = wd.min_size.y; } if (wd.max_size != Size2i()) { xsh->flags |= PMaxSize; xsh->max_width = wd.max_size.x; xsh->max_height = wd.max_size.y; } } XSetWMNormalHints(x11_display, wd.x11_window, xsh); XFree(xsh); } Point2i DisplayServerX11::window_get_position(WindowID p_window) const { _THREAD_SAFE_METHOD_ ERR_FAIL_COND_V(!windows.has(p_window), Point2i()); const WindowData &wd = windows[p_window]; return wd.position; } void DisplayServerX11::window_set_position(const Point2i &p_position, WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; int x = 0; int y = 0; if (!window_get_flag(WINDOW_FLAG_BORDERLESS, p_window)) { //exclude window decorations XSync(x11_display, False); Atom prop = XInternAtom(x11_display, "_NET_FRAME_EXTENTS", True); if (prop != None) { Atom type; int format; unsigned long len; unsigned long remaining; unsigned char *data = nullptr; if (XGetWindowProperty(x11_display, wd.x11_window, prop, 0, 4, False, AnyPropertyType, &type, &format, &len, &remaining, &data) == Success) { if (format == 32 && len == 4 && data) { long *extents = (long *)data; x = extents[0]; y = extents[2]; } XFree(data); } } } XMoveWindow(x11_display, wd.x11_window, p_position.x - x, p_position.y - y); _update_real_mouse_position(wd); } void DisplayServerX11::window_set_max_size(const Size2i p_size, WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; if ((p_size != Size2i()) && ((p_size.x < wd.min_size.x) || (p_size.y < wd.min_size.y))) { ERR_PRINT("Maximum window size can't be smaller than minimum window size!"); return; } wd.max_size = p_size; _update_size_hints(p_window); XFlush(x11_display); } Size2i DisplayServerX11::window_get_max_size(WindowID p_window) const { _THREAD_SAFE_METHOD_ ERR_FAIL_COND_V(!windows.has(p_window), Size2i()); const WindowData &wd = windows[p_window]; return wd.max_size; } void DisplayServerX11::window_set_min_size(const Size2i p_size, WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; if ((p_size != Size2i()) && (wd.max_size != Size2i()) && ((p_size.x > wd.max_size.x) || (p_size.y > wd.max_size.y))) { ERR_PRINT("Minimum window size can't be larger than maximum window size!"); return; } wd.min_size = p_size; _update_size_hints(p_window); XFlush(x11_display); } Size2i DisplayServerX11::window_get_min_size(WindowID p_window) const { _THREAD_SAFE_METHOD_ ERR_FAIL_COND_V(!windows.has(p_window), Size2i()); const WindowData &wd = windows[p_window]; return wd.min_size; } void DisplayServerX11::window_set_size(const Size2i p_size, WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); Size2i size = p_size; size.x = MAX(1, size.x); size.y = MAX(1, size.y); WindowData &wd = windows[p_window]; if (wd.size.width == size.width && wd.size.height == size.height) { return; } XWindowAttributes xwa; XSync(x11_display, False); XGetWindowAttributes(x11_display, wd.x11_window, &xwa); int old_w = xwa.width; int old_h = xwa.height; // Update our videomode width and height wd.size = size; // Update the size hints first to make sure the window size can be set _update_size_hints(p_window); // Resize the window XResizeWindow(x11_display, wd.x11_window, size.x, size.y); for (int timeout = 0; timeout < 50; ++timeout) { XSync(x11_display, False); XGetWindowAttributes(x11_display, wd.x11_window, &xwa); if (old_w != xwa.width || old_h != xwa.height) { break; } usleep(10000); } // Keep rendering context window size in sync #if defined(VULKAN_ENABLED) if (context_vulkan) { context_vulkan->window_resize(p_window, xwa.width, xwa.height); } #endif #if defined(GLES3_ENABLED) if (gl_manager) { gl_manager->window_resize(p_window, xwa.width, xwa.height); } #endif } Size2i DisplayServerX11::window_get_size(WindowID p_window) const { _THREAD_SAFE_METHOD_ ERR_FAIL_COND_V(!windows.has(p_window), Size2i()); const WindowData &wd = windows[p_window]; return wd.size; } Size2i DisplayServerX11::window_get_real_size(WindowID p_window) const { _THREAD_SAFE_METHOD_ ERR_FAIL_COND_V(!windows.has(p_window), Size2i()); const WindowData &wd = windows[p_window]; XWindowAttributes xwa; XSync(x11_display, False); XGetWindowAttributes(x11_display, wd.x11_window, &xwa); int w = xwa.width; int h = xwa.height; Atom prop = XInternAtom(x11_display, "_NET_FRAME_EXTENTS", True); if (prop != None) { Atom type; int format; unsigned long len; unsigned long remaining; unsigned char *data = nullptr; if (XGetWindowProperty(x11_display, wd.x11_window, prop, 0, 4, False, AnyPropertyType, &type, &format, &len, &remaining, &data) == Success) { if (format == 32 && len == 4 && data) { long *extents = (long *)data; w += extents[0] + extents[1]; // left, right h += extents[2] + extents[3]; // top, bottom } XFree(data); } } return Size2i(w, h); } // Just a helper to reduce code duplication in `window_is_maximize_allowed` // and `_set_wm_maximized`. bool DisplayServerX11::_window_maximize_check(WindowID p_window, const char *p_atom_name) const { ERR_FAIL_COND_V(!windows.has(p_window), false); const WindowData &wd = windows[p_window]; Atom property = XInternAtom(x11_display, p_atom_name, False); Atom type; int format; unsigned long len; unsigned long remaining; unsigned char *data = nullptr; bool retval = false; if (property == None) { return false; } int result = XGetWindowProperty( x11_display, wd.x11_window, property, 0, 1024, False, XA_ATOM, &type, &format, &len, &remaining, &data); if (result == Success && data) { Atom *atoms = (Atom *)data; Atom wm_act_max_horz; Atom wm_act_max_vert; if (strcmp(p_atom_name, "_NET_WM_STATE") == 0) { wm_act_max_horz = XInternAtom(x11_display, "_NET_WM_STATE_MAXIMIZED_HORZ", False); wm_act_max_vert = XInternAtom(x11_display, "_NET_WM_STATE_MAXIMIZED_VERT", False); } else { wm_act_max_horz = XInternAtom(x11_display, "_NET_WM_ACTION_MAXIMIZE_HORZ", False); wm_act_max_vert = XInternAtom(x11_display, "_NET_WM_ACTION_MAXIMIZE_VERT", False); } bool found_wm_act_max_horz = false; bool found_wm_act_max_vert = false; for (uint64_t i = 0; i < len; i++) { if (atoms[i] == wm_act_max_horz) { found_wm_act_max_horz = true; } if (atoms[i] == wm_act_max_vert) { found_wm_act_max_vert = true; } if (found_wm_act_max_horz || found_wm_act_max_vert) { retval = true; break; } } XFree(data); } return retval; } bool DisplayServerX11::_window_minimize_check(WindowID p_window) const { const WindowData &wd = windows[p_window]; // Using ICCCM -- Inter-Client Communication Conventions Manual Atom property = XInternAtom(x11_display, "WM_STATE", True); if (property == None) { return false; } Atom type; int format; unsigned long len; unsigned long remaining; unsigned char *data = nullptr; int result = XGetWindowProperty( x11_display, wd.x11_window, property, 0, 32, False, AnyPropertyType, &type, &format, &len, &remaining, &data); if (result == Success && data) { long *state = (long *)data; if (state[0] == WM_IconicState) { XFree(data); return true; } XFree(data); } return false; } bool DisplayServerX11::_window_fullscreen_check(WindowID p_window) const { ERR_FAIL_COND_V(!windows.has(p_window), false); const WindowData &wd = windows[p_window]; // Using EWMH -- Extended Window Manager Hints Atom property = XInternAtom(x11_display, "_NET_WM_STATE", False); Atom type; int format; unsigned long len; unsigned long remaining; unsigned char *data = nullptr; bool retval = false; if (property == None) { return retval; } int result = XGetWindowProperty( x11_display, wd.x11_window, property, 0, 1024, False, XA_ATOM, &type, &format, &len, &remaining, &data); if (result == Success) { Atom *atoms = (Atom *)data; Atom wm_fullscreen = XInternAtom(x11_display, "_NET_WM_STATE_FULLSCREEN", False); for (uint64_t i = 0; i < len; i++) { if (atoms[i] == wm_fullscreen) { retval = true; break; } } XFree(data); } return retval; } void DisplayServerX11::_validate_mode_on_map(WindowID p_window) { // Check if we applied any window modes that didn't take effect while unmapped const WindowData &wd = windows[p_window]; if (wd.fullscreen && !_window_fullscreen_check(p_window)) { _set_wm_fullscreen(p_window, true); } else if (wd.maximized && !_window_maximize_check(p_window, "_NET_WM_STATE")) { _set_wm_maximized(p_window, true); } else if (wd.minimized && !_window_minimize_check(p_window)) { _set_wm_minimized(p_window, true); } } bool DisplayServerX11::window_is_maximize_allowed(WindowID p_window) const { _THREAD_SAFE_METHOD_ return _window_maximize_check(p_window, "_NET_WM_ALLOWED_ACTIONS"); } void DisplayServerX11::_set_wm_maximized(WindowID p_window, bool p_enabled) { ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; // Using EWMH -- Extended Window Manager Hints XEvent xev; Atom wm_state = XInternAtom(x11_display, "_NET_WM_STATE", False); Atom wm_max_horz = XInternAtom(x11_display, "_NET_WM_STATE_MAXIMIZED_HORZ", False); Atom wm_max_vert = XInternAtom(x11_display, "_NET_WM_STATE_MAXIMIZED_VERT", False); memset(&xev, 0, sizeof(xev)); xev.type = ClientMessage; xev.xclient.window = wd.x11_window; xev.xclient.message_type = wm_state; xev.xclient.format = 32; xev.xclient.data.l[0] = p_enabled ? _NET_WM_STATE_ADD : _NET_WM_STATE_REMOVE; xev.xclient.data.l[1] = wm_max_horz; xev.xclient.data.l[2] = wm_max_vert; XSendEvent(x11_display, DefaultRootWindow(x11_display), False, SubstructureRedirectMask | SubstructureNotifyMask, &xev); if (p_enabled && window_is_maximize_allowed(p_window)) { // Wait for effective resizing (so the GLX context is too). // Give up after 0.5s, it's not going to happen on this WM. // https://github.com/godotengine/godot/issues/19978 for (int attempt = 0; window_get_mode(p_window) != WINDOW_MODE_MAXIMIZED && attempt < 50; attempt++) { usleep(10000); } } wd.maximized = p_enabled; } void DisplayServerX11::_set_wm_minimized(WindowID p_window, bool p_enabled) { WindowData &wd = windows[p_window]; // Using ICCCM -- Inter-Client Communication Conventions Manual XEvent xev; Atom wm_change = XInternAtom(x11_display, "WM_CHANGE_STATE", False); memset(&xev, 0, sizeof(xev)); xev.type = ClientMessage; xev.xclient.window = wd.x11_window; xev.xclient.message_type = wm_change; xev.xclient.format = 32; xev.xclient.data.l[0] = p_enabled ? WM_IconicState : WM_NormalState; XSendEvent(x11_display, DefaultRootWindow(x11_display), False, SubstructureRedirectMask | SubstructureNotifyMask, &xev); Atom wm_state = XInternAtom(x11_display, "_NET_WM_STATE", False); Atom wm_hidden = XInternAtom(x11_display, "_NET_WM_STATE_HIDDEN", False); memset(&xev, 0, sizeof(xev)); xev.type = ClientMessage; xev.xclient.window = wd.x11_window; xev.xclient.message_type = wm_state; xev.xclient.format = 32; xev.xclient.data.l[0] = p_enabled ? _NET_WM_STATE_ADD : _NET_WM_STATE_REMOVE; xev.xclient.data.l[1] = wm_hidden; XSendEvent(x11_display, DefaultRootWindow(x11_display), False, SubstructureRedirectMask | SubstructureNotifyMask, &xev); wd.minimized = p_enabled; } void DisplayServerX11::_set_wm_fullscreen(WindowID p_window, bool p_enabled) { ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; if (p_enabled && !window_get_flag(WINDOW_FLAG_BORDERLESS, p_window)) { // remove decorations if the window is not already borderless Hints hints; Atom property; hints.flags = 2; hints.decorations = 0; property = XInternAtom(x11_display, "_MOTIF_WM_HINTS", True); if (property != None) { XChangeProperty(x11_display, wd.x11_window, property, property, 32, PropModeReplace, (unsigned char *)&hints, 5); } } if (p_enabled) { // Set the window as resizable to prevent window managers to ignore the fullscreen state flag. _update_size_hints(p_window); } // Using EWMH -- Extended Window Manager Hints XEvent xev; Atom wm_state = XInternAtom(x11_display, "_NET_WM_STATE", False); Atom wm_fullscreen = XInternAtom(x11_display, "_NET_WM_STATE_FULLSCREEN", False); memset(&xev, 0, sizeof(xev)); xev.type = ClientMessage; xev.xclient.window = wd.x11_window; xev.xclient.message_type = wm_state; xev.xclient.format = 32; xev.xclient.data.l[0] = p_enabled ? _NET_WM_STATE_ADD : _NET_WM_STATE_REMOVE; xev.xclient.data.l[1] = wm_fullscreen; xev.xclient.data.l[2] = 0; XSendEvent(x11_display, DefaultRootWindow(x11_display), False, SubstructureRedirectMask | SubstructureNotifyMask, &xev); // set bypass compositor hint Atom bypass_compositor = XInternAtom(x11_display, "_NET_WM_BYPASS_COMPOSITOR", False); unsigned long compositing_disable_on = p_enabled ? 1 : 0; if (bypass_compositor != None) { XChangeProperty(x11_display, wd.x11_window, bypass_compositor, XA_CARDINAL, 32, PropModeReplace, (unsigned char *)&compositing_disable_on, 1); } XFlush(x11_display); if (!p_enabled) { // Reset the non-resizable flags if we un-set these before. _update_size_hints(p_window); // put back or remove decorations according to the last set borderless state Hints hints; Atom property; hints.flags = 2; hints.decorations = wd.borderless ? 0 : 1; property = XInternAtom(x11_display, "_MOTIF_WM_HINTS", True); if (property != None) { XChangeProperty(x11_display, wd.x11_window, property, property, 32, PropModeReplace, (unsigned char *)&hints, 5); } } } void DisplayServerX11::window_set_mode(WindowMode p_mode, WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; WindowMode old_mode = window_get_mode(p_window); if (old_mode == p_mode) { return; // do nothing } //remove all "extra" modes switch (old_mode) { case WINDOW_MODE_WINDOWED: { //do nothing } break; case WINDOW_MODE_MINIMIZED: { _set_wm_minimized(p_window, false); } break; case WINDOW_MODE_EXCLUSIVE_FULLSCREEN: case WINDOW_MODE_FULLSCREEN: { //Remove full-screen wd.fullscreen = false; _set_wm_fullscreen(p_window, false); //un-maximize required for always on top bool on_top = window_get_flag(WINDOW_FLAG_ALWAYS_ON_TOP, p_window); window_set_position(wd.last_position_before_fs, p_window); if (on_top) { _set_wm_maximized(p_window, false); } } break; case WINDOW_MODE_MAXIMIZED: { _set_wm_maximized(p_window, false); } break; } switch (p_mode) { case WINDOW_MODE_WINDOWED: { //do nothing } break; case WINDOW_MODE_MINIMIZED: { _set_wm_minimized(p_window, true); } break; case WINDOW_MODE_EXCLUSIVE_FULLSCREEN: case WINDOW_MODE_FULLSCREEN: { wd.last_position_before_fs = wd.position; if (window_get_flag(WINDOW_FLAG_ALWAYS_ON_TOP, p_window)) { _set_wm_maximized(p_window, true); } wd.fullscreen = true; _set_wm_fullscreen(p_window, true); } break; case WINDOW_MODE_MAXIMIZED: { _set_wm_maximized(p_window, true); } break; } } DisplayServer::WindowMode DisplayServerX11::window_get_mode(WindowID p_window) const { _THREAD_SAFE_METHOD_ ERR_FAIL_COND_V(!windows.has(p_window), WINDOW_MODE_WINDOWED); const WindowData &wd = windows[p_window]; if (wd.fullscreen) { //if fullscreen, it's not in another mode return WINDOW_MODE_FULLSCREEN; } // Test maximized. // Using EWMH -- Extended Window Manager Hints if (_window_maximize_check(p_window, "_NET_WM_STATE")) { return WINDOW_MODE_MAXIMIZED; } { if (_window_minimize_check(p_window)) { return WINDOW_MODE_MINIMIZED; } } // All other discarded, return windowed. return WINDOW_MODE_WINDOWED; } void DisplayServerX11::window_set_flag(WindowFlags p_flag, bool p_enabled, WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; switch (p_flag) { case WINDOW_FLAG_RESIZE_DISABLED: { wd.resize_disabled = p_enabled; _update_size_hints(p_window); XFlush(x11_display); } break; case WINDOW_FLAG_BORDERLESS: { Hints hints; Atom property; hints.flags = 2; hints.decorations = p_enabled ? 0 : 1; property = XInternAtom(x11_display, "_MOTIF_WM_HINTS", True); if (property != None) { XChangeProperty(x11_display, wd.x11_window, property, property, 32, PropModeReplace, (unsigned char *)&hints, 5); } // Preserve window size window_set_size(window_get_size(p_window), p_window); wd.borderless = p_enabled; } break; case WINDOW_FLAG_ALWAYS_ON_TOP: { ERR_FAIL_COND_MSG(wd.transient_parent != INVALID_WINDOW_ID, "Can't make a window transient if the 'on top' flag is active."); if (p_enabled && wd.fullscreen) { _set_wm_maximized(p_window, true); } Atom wm_state = XInternAtom(x11_display, "_NET_WM_STATE", False); Atom wm_above = XInternAtom(x11_display, "_NET_WM_STATE_ABOVE", False); XClientMessageEvent xev; memset(&xev, 0, sizeof(xev)); xev.type = ClientMessage; xev.window = wd.x11_window; xev.message_type = wm_state; xev.format = 32; xev.data.l[0] = p_enabled ? _NET_WM_STATE_ADD : _NET_WM_STATE_REMOVE; xev.data.l[1] = wm_above; xev.data.l[3] = 1; XSendEvent(x11_display, DefaultRootWindow(x11_display), False, SubstructureRedirectMask | SubstructureNotifyMask, (XEvent *)&xev); if (!p_enabled && !wd.fullscreen) { _set_wm_maximized(p_window, false); } wd.on_top = p_enabled; } break; case WINDOW_FLAG_TRANSPARENT: { wd.layered_window = p_enabled; } break; case WINDOW_FLAG_NO_FOCUS: { wd.no_focus = p_enabled; } break; case WINDOW_FLAG_POPUP: { XWindowAttributes xwa; XSync(x11_display, False); XGetWindowAttributes(x11_display, wd.x11_window, &xwa); ERR_FAIL_COND_MSG(p_window == MAIN_WINDOW_ID, "Main window can't be popup."); ERR_FAIL_COND_MSG((xwa.map_state == IsViewable) && (wd.is_popup != p_enabled), "Popup flag can't changed while window is opened."); wd.is_popup = p_enabled; } break; default: { } } } bool DisplayServerX11::window_get_flag(WindowFlags p_flag, WindowID p_window) const { _THREAD_SAFE_METHOD_ ERR_FAIL_COND_V(!windows.has(p_window), false); const WindowData &wd = windows[p_window]; switch (p_flag) { case WINDOW_FLAG_RESIZE_DISABLED: { return wd.resize_disabled; } break; case WINDOW_FLAG_BORDERLESS: { bool borderless = wd.borderless; Atom prop = XInternAtom(x11_display, "_MOTIF_WM_HINTS", True); if (prop != None) { Atom type; int format; unsigned long len; unsigned long remaining; unsigned char *data = nullptr; if (XGetWindowProperty(x11_display, wd.x11_window, prop, 0, sizeof(Hints), False, AnyPropertyType, &type, &format, &len, &remaining, &data) == Success) { if (data && (format == 32) && (len >= 5)) { borderless = !(reinterpret_cast(data)->decorations); } if (data) { XFree(data); } } } return borderless; } break; case WINDOW_FLAG_ALWAYS_ON_TOP: { return wd.on_top; } break; case WINDOW_FLAG_TRANSPARENT: { return wd.layered_window; } break; case WINDOW_FLAG_NO_FOCUS: { return wd.no_focus; } break; case WINDOW_FLAG_POPUP: { return wd.is_popup; } break; default: { } } return false; } void DisplayServerX11::window_request_attention(WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); const WindowData &wd = windows[p_window]; // Using EWMH -- Extended Window Manager Hints // // Sets the _NET_WM_STATE_DEMANDS_ATTENTION atom for WM_STATE // Will be unset by the window manager after user react on the request for attention XEvent xev; Atom wm_state = XInternAtom(x11_display, "_NET_WM_STATE", False); Atom wm_attention = XInternAtom(x11_display, "_NET_WM_STATE_DEMANDS_ATTENTION", False); memset(&xev, 0, sizeof(xev)); xev.type = ClientMessage; xev.xclient.window = wd.x11_window; xev.xclient.message_type = wm_state; xev.xclient.format = 32; xev.xclient.data.l[0] = _NET_WM_STATE_ADD; xev.xclient.data.l[1] = wm_attention; XSendEvent(x11_display, DefaultRootWindow(x11_display), False, SubstructureRedirectMask | SubstructureNotifyMask, &xev); XFlush(x11_display); } void DisplayServerX11::window_move_to_foreground(WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); const WindowData &wd = windows[p_window]; XEvent xev; Atom net_active_window = XInternAtom(x11_display, "_NET_ACTIVE_WINDOW", False); memset(&xev, 0, sizeof(xev)); xev.type = ClientMessage; xev.xclient.window = wd.x11_window; xev.xclient.message_type = net_active_window; xev.xclient.format = 32; xev.xclient.data.l[0] = 1; xev.xclient.data.l[1] = CurrentTime; XSendEvent(x11_display, DefaultRootWindow(x11_display), False, SubstructureRedirectMask | SubstructureNotifyMask, &xev); XFlush(x11_display); } bool DisplayServerX11::window_can_draw(WindowID p_window) const { //this seems to be all that is provided by X11 return window_get_mode(p_window) != WINDOW_MODE_MINIMIZED; } bool DisplayServerX11::can_any_window_draw() const { _THREAD_SAFE_METHOD_ for (const KeyValue &E : windows) { if (window_get_mode(E.key) != WINDOW_MODE_MINIMIZED) { return true; } } return false; } void DisplayServerX11::window_set_ime_active(const bool p_active, WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; wd.im_active = p_active; if (!wd.xic) { return; } // Block events polling while changing input focus // because it triggers some event polling internally. if (p_active) { { MutexLock mutex_lock(events_mutex); XSetICFocus(wd.xic); } window_set_ime_position(wd.im_position, p_window); } else { MutexLock mutex_lock(events_mutex); XUnsetICFocus(wd.xic); } } void DisplayServerX11::window_set_ime_position(const Point2i &p_pos, WindowID p_window) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; wd.im_position = p_pos; if (!wd.xic) { return; } ::XPoint spot; spot.x = short(p_pos.x); spot.y = short(p_pos.y); XVaNestedList preedit_attr = XVaCreateNestedList(0, XNSpotLocation, &spot, nullptr); { // Block events polling during this call // because it triggers some event polling internally. MutexLock mutex_lock(events_mutex); XSetICValues(wd.xic, XNPreeditAttributes, preedit_attr, nullptr); } XFree(preedit_attr); } void DisplayServerX11::cursor_set_shape(CursorShape p_shape) { _THREAD_SAFE_METHOD_ ERR_FAIL_INDEX(p_shape, CURSOR_MAX); if (p_shape == current_cursor) { return; } if (mouse_mode == MOUSE_MODE_VISIBLE || mouse_mode == MOUSE_MODE_CONFINED) { if (cursors[p_shape] != None) { for (const KeyValue &E : windows) { XDefineCursor(x11_display, E.value.x11_window, cursors[p_shape]); } } else if (cursors[CURSOR_ARROW] != None) { for (const KeyValue &E : windows) { XDefineCursor(x11_display, E.value.x11_window, cursors[CURSOR_ARROW]); } } } current_cursor = p_shape; } DisplayServerX11::CursorShape DisplayServerX11::cursor_get_shape() const { return current_cursor; } void DisplayServerX11::cursor_set_custom_image(const Ref &p_cursor, CursorShape p_shape, const Vector2 &p_hotspot) { _THREAD_SAFE_METHOD_ if (p_cursor.is_valid()) { HashMap>::Iterator cursor_c = cursors_cache.find(p_shape); if (cursor_c) { if (cursor_c->value[0] == p_cursor && cursor_c->value[1] == p_hotspot) { cursor_set_shape(p_shape); return; } cursors_cache.erase(p_shape); } Ref texture = p_cursor; Ref atlas_texture = p_cursor; Ref image; Size2i texture_size; Rect2i atlas_rect; if (texture.is_valid()) { image = texture->get_image(); } if (!image.is_valid() && atlas_texture.is_valid()) { texture = atlas_texture->get_atlas(); atlas_rect.size.width = texture->get_width(); atlas_rect.size.height = texture->get_height(); atlas_rect.position.x = atlas_texture->get_region().position.x; atlas_rect.position.y = atlas_texture->get_region().position.y; texture_size.width = atlas_texture->get_region().size.x; texture_size.height = atlas_texture->get_region().size.y; } else if (image.is_valid()) { texture_size.width = texture->get_width(); texture_size.height = texture->get_height(); } ERR_FAIL_COND(!texture.is_valid()); ERR_FAIL_COND(p_hotspot.x < 0 || p_hotspot.y < 0); ERR_FAIL_COND(texture_size.width > 256 || texture_size.height > 256); ERR_FAIL_COND(p_hotspot.x > texture_size.width || p_hotspot.y > texture_size.height); image = texture->get_image(); ERR_FAIL_COND(!image.is_valid()); // Create the cursor structure XcursorImage *cursor_image = XcursorImageCreate(texture_size.width, texture_size.height); XcursorUInt image_size = texture_size.width * texture_size.height; XcursorDim size = sizeof(XcursorPixel) * image_size; cursor_image->version = 1; cursor_image->size = size; cursor_image->xhot = p_hotspot.x; cursor_image->yhot = p_hotspot.y; // allocate memory to contain the whole file cursor_image->pixels = (XcursorPixel *)memalloc(size); for (XcursorPixel index = 0; index < image_size; index++) { int row_index = floor(index / texture_size.width) + atlas_rect.position.y; int column_index = (index % int(texture_size.width)) + atlas_rect.position.x; if (atlas_texture.is_valid()) { column_index = MIN(column_index, atlas_rect.size.width - 1); row_index = MIN(row_index, atlas_rect.size.height - 1); } *(cursor_image->pixels + index) = image->get_pixel(column_index, row_index).to_argb32(); } ERR_FAIL_COND(cursor_image->pixels == nullptr); // Save it for a further usage cursors[p_shape] = XcursorImageLoadCursor(x11_display, cursor_image); Vector params; params.push_back(p_cursor); params.push_back(p_hotspot); cursors_cache.insert(p_shape, params); if (p_shape == current_cursor) { if (mouse_mode == MOUSE_MODE_VISIBLE || mouse_mode == MOUSE_MODE_CONFINED) { for (const KeyValue &E : windows) { XDefineCursor(x11_display, E.value.x11_window, cursors[p_shape]); } } } memfree(cursor_image->pixels); XcursorImageDestroy(cursor_image); } else { // Reset to default system cursor if (img[p_shape]) { cursors[p_shape] = XcursorImageLoadCursor(x11_display, img[p_shape]); } CursorShape c = current_cursor; current_cursor = CURSOR_MAX; cursor_set_shape(c); cursors_cache.erase(p_shape); } } int DisplayServerX11::keyboard_get_layout_count() const { int _group_count = 0; XkbDescRec *kbd = XkbAllocKeyboard(); if (kbd) { kbd->dpy = x11_display; XkbGetControls(x11_display, XkbAllControlsMask, kbd); XkbGetNames(x11_display, XkbSymbolsNameMask, kbd); const Atom *groups = kbd->names->groups; if (kbd->ctrls != nullptr) { _group_count = kbd->ctrls->num_groups; } else { while (_group_count < XkbNumKbdGroups && groups[_group_count] != None) { _group_count++; } } XkbFreeKeyboard(kbd, 0, true); } return _group_count; } int DisplayServerX11::keyboard_get_current_layout() const { XkbStateRec state; XkbGetState(x11_display, XkbUseCoreKbd, &state); return state.group; } void DisplayServerX11::keyboard_set_current_layout(int p_index) { ERR_FAIL_INDEX(p_index, keyboard_get_layout_count()); XkbLockGroup(x11_display, XkbUseCoreKbd, p_index); } String DisplayServerX11::keyboard_get_layout_language(int p_index) const { String ret; XkbDescRec *kbd = XkbAllocKeyboard(); if (kbd) { kbd->dpy = x11_display; XkbGetControls(x11_display, XkbAllControlsMask, kbd); XkbGetNames(x11_display, XkbSymbolsNameMask, kbd); XkbGetNames(x11_display, XkbGroupNamesMask, kbd); int _group_count = 0; const Atom *groups = kbd->names->groups; if (kbd->ctrls != nullptr) { _group_count = kbd->ctrls->num_groups; } else { while (_group_count < XkbNumKbdGroups && groups[_group_count] != None) { _group_count++; } } Atom names = kbd->names->symbols; if (names != None) { Vector info = get_atom_name(x11_display, names).split("+"); if (p_index >= 0 && p_index < _group_count) { if (p_index + 1 < info.size()) { ret = info[p_index + 1]; // Skip "pc" at the start and "inet"/"group" at the end of symbols. } else { ret = "en"; // No symbol for layout fallback to "en". } } else { ERR_PRINT("Index " + itos(p_index) + "is out of bounds (" + itos(_group_count) + ")."); } } XkbFreeKeyboard(kbd, 0, true); } return ret.substr(0, 2); } String DisplayServerX11::keyboard_get_layout_name(int p_index) const { String ret; XkbDescRec *kbd = XkbAllocKeyboard(); if (kbd) { kbd->dpy = x11_display; XkbGetControls(x11_display, XkbAllControlsMask, kbd); XkbGetNames(x11_display, XkbSymbolsNameMask, kbd); XkbGetNames(x11_display, XkbGroupNamesMask, kbd); int _group_count = 0; const Atom *groups = kbd->names->groups; if (kbd->ctrls != nullptr) { _group_count = kbd->ctrls->num_groups; } else { while (_group_count < XkbNumKbdGroups && groups[_group_count] != None) { _group_count++; } } if (p_index >= 0 && p_index < _group_count) { ret = get_atom_name(x11_display, groups[p_index]); } else { ERR_PRINT("Index " + itos(p_index) + "is out of bounds (" + itos(_group_count) + ")."); } XkbFreeKeyboard(kbd, 0, true); } return ret; } Key DisplayServerX11::keyboard_get_keycode_from_physical(Key p_keycode) const { Key modifiers = p_keycode & KeyModifierMask::MODIFIER_MASK; Key keycode_no_mod = p_keycode & KeyModifierMask::CODE_MASK; unsigned int xkeycode = KeyMappingX11::get_xlibcode(keycode_no_mod); KeySym xkeysym = XkbKeycodeToKeysym(x11_display, xkeycode, 0, 0); if (is_ascii_lower_case(xkeysym)) { xkeysym -= ('a' - 'A'); } Key key = KeyMappingX11::get_keycode(xkeysym); // If not found, fallback to QWERTY. // This should match the behavior of the event pump if (key == Key::NONE) { return p_keycode; } return (Key)(key | modifiers); } DisplayServerX11::Property DisplayServerX11::_read_property(Display *p_display, Window p_window, Atom p_property) { Atom actual_type = None; int actual_format = 0; unsigned long nitems = 0; unsigned long bytes_after = 0; unsigned char *ret = nullptr; // Keep trying to read the property until there are no bytes unread. if (p_property != None) { int read_bytes = 1024; do { if (ret != nullptr) { XFree(ret); } XGetWindowProperty(p_display, p_window, p_property, 0, read_bytes, False, AnyPropertyType, &actual_type, &actual_format, &nitems, &bytes_after, &ret); read_bytes *= 2; } while (bytes_after != 0); } Property p = { ret, actual_format, (int)nitems, actual_type }; return p; } static Atom pick_target_from_list(Display *p_display, const Atom *p_list, int p_count) { static const char *target_type = "text/uri-list"; for (int i = 0; i < p_count; i++) { Atom atom = p_list[i]; if (atom != None && get_atom_name(p_display, atom) == target_type) { return atom; } } return None; } static Atom pick_target_from_atoms(Display *p_disp, Atom p_t1, Atom p_t2, Atom p_t3) { static const char *target_type = "text/uri-list"; if (p_t1 != None && get_atom_name(p_disp, p_t1) == target_type) { return p_t1; } if (p_t2 != None && get_atom_name(p_disp, p_t2) == target_type) { return p_t2; } if (p_t3 != None && get_atom_name(p_disp, p_t3) == target_type) { return p_t3; } return None; } void DisplayServerX11::_get_key_modifier_state(unsigned int p_x11_state, Ref state) { state->set_shift_pressed((p_x11_state & ShiftMask)); state->set_ctrl_pressed((p_x11_state & ControlMask)); state->set_alt_pressed((p_x11_state & Mod1Mask /*|| p_x11_state&Mod5Mask*/)); //altgr should not count as alt state->set_meta_pressed((p_x11_state & Mod4Mask)); } MouseButton DisplayServerX11::_get_mouse_button_state(MouseButton p_x11_button, int p_x11_type) { MouseButton mask = mouse_button_to_mask(p_x11_button); if (p_x11_type == ButtonPress) { last_button_state |= mask; } else { last_button_state &= ~mask; } return last_button_state; } void DisplayServerX11::_handle_key_event(WindowID p_window, XKeyEvent *p_event, LocalVector &p_events, uint32_t &p_event_index, bool p_echo) { WindowData wd = windows[p_window]; // X11 functions don't know what const is XKeyEvent *xkeyevent = p_event; // This code was pretty difficult to write. // The docs stink and every toolkit seems to // do it in a different way. /* Phase 1, obtain a proper keysym */ // This was also very difficult to figure out. // You'd expect you could just use Keysym provided by // XKeycodeToKeysym to obtain internationalized // input.. WRONG!! // you must use XLookupString (???) which not only wastes // cycles generating an unnecessary string, but also // still works in half the cases. (won't handle deadkeys) // For more complex input methods (deadkeys and more advanced) // you have to use XmbLookupString (??). // So then you have to choose which of both results // you want to keep. // This is a real bizarreness and cpu waster. KeySym keysym_keycode = 0; // keysym used to find a keycode KeySym keysym_unicode = 0; // keysym used to find unicode // XLookupString returns keysyms usable as nice keycodes. char str[256 + 1]; XKeyEvent xkeyevent_no_mod = *xkeyevent; xkeyevent_no_mod.state &= ~ShiftMask; xkeyevent_no_mod.state &= ~ControlMask; XLookupString(xkeyevent, str, 256, &keysym_unicode, nullptr); XLookupString(&xkeyevent_no_mod, nullptr, 0, &keysym_keycode, nullptr); // Meanwhile, XLookupString returns keysyms useful for unicode. if (!xmbstring) { // keep a temporary buffer for the string xmbstring = (char *)memalloc(sizeof(char) * 8); xmblen = 8; } if (xkeyevent->type == KeyPress && wd.xic) { Status status; #ifdef X_HAVE_UTF8_STRING int utf8len = 8; char *utf8string = (char *)memalloc(sizeof(char) * utf8len); int utf8bytes = Xutf8LookupString(wd.xic, xkeyevent, utf8string, utf8len - 1, &keysym_unicode, &status); if (status == XBufferOverflow) { utf8len = utf8bytes + 1; utf8string = (char *)memrealloc(utf8string, utf8len); utf8bytes = Xutf8LookupString(wd.xic, xkeyevent, utf8string, utf8len - 1, &keysym_unicode, &status); } utf8string[utf8bytes] = '\0'; if (status == XLookupChars) { bool keypress = xkeyevent->type == KeyPress; Key keycode = KeyMappingX11::get_keycode(keysym_keycode); Key physical_keycode = KeyMappingX11::get_scancode(xkeyevent->keycode); if (keycode >= Key::A + 32 && keycode <= Key::Z + 32) { keycode -= 'a' - 'A'; } String tmp; tmp.parse_utf8(utf8string, utf8bytes); for (int i = 0; i < tmp.length(); i++) { Ref k; k.instantiate(); if (physical_keycode == Key::NONE && keycode == Key::NONE && tmp[i] == 0) { continue; } if (keycode == Key::NONE) { keycode = (Key)physical_keycode; } _get_key_modifier_state(xkeyevent->state, k); k->set_window_id(p_window); k->set_unicode(tmp[i]); k->set_pressed(keypress); k->set_keycode(keycode); k->set_physical_keycode((Key)physical_keycode); k->set_echo(false); if (k->get_keycode() == Key::BACKTAB) { //make it consistent across platforms. k->set_keycode(Key::TAB); k->set_physical_keycode(Key::TAB); k->set_shift_pressed(true); } Input::get_singleton()->parse_input_event(k); } memfree(utf8string); return; } memfree(utf8string); #else do { int mnbytes = XmbLookupString(xic, xkeyevent, xmbstring, xmblen - 1, &keysym_unicode, &status); xmbstring[mnbytes] = '\0'; if (status == XBufferOverflow) { xmblen = mnbytes + 1; xmbstring = (char *)memrealloc(xmbstring, xmblen); } } while (status == XBufferOverflow); #endif } /* Phase 2, obtain a Godot keycode from the keysym */ // KeyMappingX11 just translated the X11 keysym to a PIGUI // keysym, so it works in all platforms the same. Key keycode = KeyMappingX11::get_keycode(keysym_keycode); Key physical_keycode = KeyMappingX11::get_scancode(xkeyevent->keycode); /* Phase 3, obtain a unicode character from the keysym */ // KeyMappingX11 also translates keysym to unicode. // It does a binary search on a table to translate // most properly. unsigned int unicode = keysym_unicode > 0 ? KeyMappingX11::get_unicode_from_keysym(keysym_unicode) : 0; /* Phase 4, determine if event must be filtered */ // This seems to be a side-effect of using XIM. // XFilterEvent looks like a core X11 function, // but it's actually just used to see if we must // ignore a deadkey, or events XIM determines // must not reach the actual gui. // Guess it was a design problem of the extension bool keypress = xkeyevent->type == KeyPress; if (physical_keycode == Key::NONE && keycode == Key::NONE && unicode == 0) { return; } if (keycode == Key::NONE) { keycode = (Key)physical_keycode; } /* Phase 5, determine modifier mask */ // No problems here, except I had no way to // know Mod1 was ALT and Mod4 was META (applekey/winkey) // just tried Mods until i found them. //print_verbose("mod1: "+itos(xkeyevent->state&Mod1Mask)+" mod 5: "+itos(xkeyevent->state&Mod5Mask)); Ref k; k.instantiate(); k->set_window_id(p_window); _get_key_modifier_state(xkeyevent->state, k); /* Phase 6, determine echo character */ // Echo characters in X11 are a keyrelease and a keypress // one after the other with the (almot) same timestamp. // To detect them, i compare to the next event in list and // check that their difference in time is below a threshold. if (xkeyevent->type != KeyPress) { p_echo = false; // make sure there are events pending, // so this call won't block. if (p_event_index + 1 < p_events.size()) { XEvent &peek_event = p_events[p_event_index + 1]; // I'm using a threshold of 5 msecs, // since sometimes there seems to be a little // jitter. I'm still not convinced that all this approach // is correct, but the xorg developers are // not very helpful today. #define ABSDIFF(x, y) (((x) < (y)) ? ((y) - (x)) : ((x) - (y))) ::Time threshold = ABSDIFF(peek_event.xkey.time, xkeyevent->time); #undef ABSDIFF if (peek_event.type == KeyPress && threshold < 5) { KeySym rk; XLookupString((XKeyEvent *)&peek_event, str, 256, &rk, nullptr); if (rk == keysym_keycode) { // Consume to next event. ++p_event_index; _handle_key_event(p_window, (XKeyEvent *)&peek_event, p_events, p_event_index, true); return; //ignore current, echo next } } // use the time from peek_event so it always works } // save the time to check for echo when keypress happens } /* Phase 7, send event to Window */ k->set_pressed(keypress); if (keycode >= Key::A + 32 && keycode <= Key::Z + 32) { keycode -= int('a' - 'A'); } k->set_keycode(keycode); k->set_physical_keycode((Key)physical_keycode); k->set_unicode(unicode); k->set_echo(p_echo); if (k->get_keycode() == Key::BACKTAB) { //make it consistent across platforms. k->set_keycode(Key::TAB); k->set_physical_keycode(Key::TAB); k->set_shift_pressed(true); } //don't set mod state if modifier keys are released by themselves //else event.is_action() will not work correctly here if (!k->is_pressed()) { if (k->get_keycode() == Key::SHIFT) { k->set_shift_pressed(false); } else if (k->get_keycode() == Key::CTRL) { k->set_ctrl_pressed(false); } else if (k->get_keycode() == Key::ALT) { k->set_alt_pressed(false); } else if (k->get_keycode() == Key::META) { k->set_meta_pressed(false); } } bool last_is_pressed = Input::get_singleton()->is_key_pressed(k->get_keycode()); if (k->is_pressed()) { if (last_is_pressed) { k->set_echo(true); } } Input::get_singleton()->parse_input_event(k); } Atom DisplayServerX11::_process_selection_request_target(Atom p_target, Window p_requestor, Atom p_property, Atom p_selection) const { if (p_target == XInternAtom(x11_display, "TARGETS", 0)) { // Request to list all supported targets. Atom data[9]; data[0] = XInternAtom(x11_display, "TARGETS", 0); data[1] = XInternAtom(x11_display, "SAVE_TARGETS", 0); data[2] = XInternAtom(x11_display, "MULTIPLE", 0); data[3] = XInternAtom(x11_display, "UTF8_STRING", 0); data[4] = XInternAtom(x11_display, "COMPOUND_TEXT", 0); data[5] = XInternAtom(x11_display, "TEXT", 0); data[6] = XA_STRING; data[7] = XInternAtom(x11_display, "text/plain;charset=utf-8", 0); data[8] = XInternAtom(x11_display, "text/plain", 0); XChangeProperty(x11_display, p_requestor, p_property, XA_ATOM, 32, PropModeReplace, (unsigned char *)&data, sizeof(data) / sizeof(data[0])); return p_property; } else if (p_target == XInternAtom(x11_display, "SAVE_TARGETS", 0)) { // Request to check if SAVE_TARGETS is supported, nothing special to do. XChangeProperty(x11_display, p_requestor, p_property, XInternAtom(x11_display, "NULL", False), 32, PropModeReplace, nullptr, 0); return p_property; } else if (p_target == XInternAtom(x11_display, "UTF8_STRING", 0) || p_target == XInternAtom(x11_display, "COMPOUND_TEXT", 0) || p_target == XInternAtom(x11_display, "TEXT", 0) || p_target == XA_STRING || p_target == XInternAtom(x11_display, "text/plain;charset=utf-8", 0) || p_target == XInternAtom(x11_display, "text/plain", 0)) { // Directly using internal clipboard because we know our window // is the owner during a selection request. CharString clip; static const char *target_type = "PRIMARY"; if (p_selection != None && get_atom_name(x11_display, p_selection) == target_type) { clip = internal_clipboard_primary.utf8(); } else { clip = internal_clipboard.utf8(); } XChangeProperty(x11_display, p_requestor, p_property, p_target, 8, PropModeReplace, (unsigned char *)clip.get_data(), clip.length()); return p_property; } else { char *target_name = XGetAtomName(x11_display, p_target); printf("Target '%s' not supported.\n", target_name); if (target_name) { XFree(target_name); } return None; } } void DisplayServerX11::_handle_selection_request_event(XSelectionRequestEvent *p_event) const { XEvent respond; if (p_event->target == XInternAtom(x11_display, "MULTIPLE", 0)) { // Request for multiple target conversions at once. Atom atom_pair = XInternAtom(x11_display, "ATOM_PAIR", False); respond.xselection.property = None; Atom type; int format; unsigned long len; unsigned long remaining; unsigned char *data = nullptr; if (XGetWindowProperty(x11_display, p_event->requestor, p_event->property, 0, LONG_MAX, False, atom_pair, &type, &format, &len, &remaining, &data) == Success) { if ((len >= 2) && data) { Atom *targets = (Atom *)data; for (uint64_t i = 0; i < len; i += 2) { Atom target = targets[i]; Atom &property = targets[i + 1]; property = _process_selection_request_target(target, p_event->requestor, property, p_event->selection); } XChangeProperty(x11_display, p_event->requestor, p_event->property, atom_pair, 32, PropModeReplace, (unsigned char *)targets, len); respond.xselection.property = p_event->property; } XFree(data); } } else { // Request for target conversion. respond.xselection.property = _process_selection_request_target(p_event->target, p_event->requestor, p_event->property, p_event->selection); } respond.xselection.type = SelectionNotify; respond.xselection.display = p_event->display; respond.xselection.requestor = p_event->requestor; respond.xselection.selection = p_event->selection; respond.xselection.target = p_event->target; respond.xselection.time = p_event->time; XSendEvent(x11_display, p_event->requestor, True, NoEventMask, &respond); XFlush(x11_display); } void DisplayServerX11::_xim_destroy_callback(::XIM im, ::XPointer client_data, ::XPointer call_data) { WARN_PRINT("Input method stopped"); DisplayServerX11 *ds = reinterpret_cast(client_data); ds->xim = nullptr; for (KeyValue &E : ds->windows) { E.value.xic = nullptr; } } void DisplayServerX11::_window_changed(XEvent *event) { WindowID window_id = MAIN_WINDOW_ID; // Assign the event to the relevant window for (const KeyValue &E : windows) { if (event->xany.window == E.value.x11_window) { window_id = E.key; break; } } Rect2i new_rect; WindowData &wd = windows[window_id]; if (wd.x11_window != event->xany.window) { // Check if the correct window, in case it was not main window or anything else return; } // Query display server about a possible new window state. wd.fullscreen = _window_fullscreen_check(window_id); wd.minimized = _window_minimize_check(window_id); wd.maximized = _window_maximize_check(window_id, "_NET_WM_STATE"); { //the position in xconfigure is not useful here, obtain it manually int x = 0, y = 0; Window child; XTranslateCoordinates(x11_display, wd.x11_window, DefaultRootWindow(x11_display), 0, 0, &x, &y, &child); new_rect.position.x = x; new_rect.position.y = y; new_rect.size.width = event->xconfigure.width; new_rect.size.height = event->xconfigure.height; } if (new_rect == Rect2i(wd.position, wd.size)) { return; } if (wd.xic) { // Not portable. window_set_ime_position(Point2(0, 1)); } wd.position = new_rect.position; wd.size = new_rect.size; #if defined(VULKAN_ENABLED) if (context_vulkan) { context_vulkan->window_resize(window_id, wd.size.width, wd.size.height); } #endif #if defined(GLES3_ENABLED) if (gl_manager) { gl_manager->window_resize(window_id, wd.size.width, wd.size.height); } #endif if (!wd.rect_changed_callback.is_null()) { Rect2i r = new_rect; Variant rect = r; Variant *rectp = ▭ Variant ret; Callable::CallError ce; wd.rect_changed_callback.callp((const Variant **)&rectp, 1, ret, ce); } } DisplayServer::WindowID DisplayServerX11::_get_focused_window_or_popup() const { const List::Element *E = popup_list.back(); if (E) { return E->get(); } return last_focused_window; } void DisplayServerX11::_dispatch_input_events(const Ref &p_event) { static_cast(get_singleton())->_dispatch_input_event(p_event); } void DisplayServerX11::_dispatch_input_event(const Ref &p_event) { Variant ev = p_event; Variant *evp = &ev; Variant ret; Callable::CallError ce; { List::Element *E = popup_list.back(); if (E && Object::cast_to(*p_event)) { // Redirect keyboard input to active popup. if (windows.has(E->get())) { Callable callable = windows[E->get()].input_event_callback; if (callable.is_valid()) { callable.callp((const Variant **)&evp, 1, ret, ce); } } return; } } Ref event_from_window = p_event; if (event_from_window.is_valid() && event_from_window->get_window_id() != INVALID_WINDOW_ID) { // Send to a single window. if (windows.has(event_from_window->get_window_id())) { Callable callable = windows[event_from_window->get_window_id()].input_event_callback; if (callable.is_valid()) { callable.callp((const Variant **)&evp, 1, ret, ce); } } } else { // Send to all windows. for (KeyValue &E : windows) { Callable callable = E.value.input_event_callback; if (callable.is_valid()) { callable.callp((const Variant **)&evp, 1, ret, ce); } } } } void DisplayServerX11::_send_window_event(const WindowData &wd, WindowEvent p_event) { if (!wd.event_callback.is_null()) { Variant event = int(p_event); Variant *eventp = &event; Variant ret; Callable::CallError ce; wd.event_callback.callp((const Variant **)&eventp, 1, ret, ce); } } void DisplayServerX11::_poll_events_thread(void *ud) { DisplayServerX11 *display_server = static_cast(ud); display_server->_poll_events(); } Bool DisplayServerX11::_predicate_all_events(Display *display, XEvent *event, XPointer arg) { // Just accept all events. return True; } bool DisplayServerX11::_wait_for_events() const { int x11_fd = ConnectionNumber(x11_display); fd_set in_fds; XFlush(x11_display); FD_ZERO(&in_fds); FD_SET(x11_fd, &in_fds); struct timeval tv; tv.tv_usec = 0; tv.tv_sec = 1; // Wait for next event or timeout. int num_ready_fds = select(x11_fd + 1, &in_fds, nullptr, nullptr, &tv); if (num_ready_fds > 0) { // Event received. return true; } else { // Error or timeout. if (num_ready_fds < 0) { ERR_PRINT("_wait_for_events: select error: " + itos(errno)); } return false; } } void DisplayServerX11::_poll_events() { while (!events_thread_done.is_set()) { _wait_for_events(); // Process events from the queue. { MutexLock mutex_lock(events_mutex); _check_pending_events(polled_events); } } } void DisplayServerX11::_check_pending_events(LocalVector &r_events) { // Flush to make sure to gather all pending events. XFlush(x11_display); // Non-blocking wait for next event and remove it from the queue. XEvent ev = {}; while (XCheckIfEvent(x11_display, &ev, _predicate_all_events, nullptr)) { // Check if the input manager wants to process the event. if (XFilterEvent(&ev, None)) { // Event has been filtered by the Input Manager, // it has to be ignored and a new one will be received. continue; } // Handle selection request events directly in the event thread, because // communication through the x server takes several events sent back and forth // and we don't want to block other programs while processing only one each frame. if (ev.type == SelectionRequest) { _handle_selection_request_event(&(ev.xselectionrequest)); continue; } r_events.push_back(ev); } } DisplayServer::WindowID DisplayServerX11::window_get_active_popup() const { const List::Element *E = popup_list.back(); if (E) { return E->get(); } else { return INVALID_WINDOW_ID; } } void DisplayServerX11::window_set_popup_safe_rect(WindowID p_window, const Rect2i &p_rect) { _THREAD_SAFE_METHOD_ ERR_FAIL_COND(!windows.has(p_window)); WindowData &wd = windows[p_window]; wd.parent_safe_rect = p_rect; } Rect2i DisplayServerX11::window_get_popup_safe_rect(WindowID p_window) const { _THREAD_SAFE_METHOD_ ERR_FAIL_COND_V(!windows.has(p_window), Rect2i()); const WindowData &wd = windows[p_window]; return wd.parent_safe_rect; } void DisplayServerX11::popup_open(WindowID p_window) { _THREAD_SAFE_METHOD_ WindowData &wd = windows[p_window]; if (wd.is_popup) { // Find current popup parent, or root popup if new window is not transient. List::Element *C = nullptr; List::Element *E = popup_list.back(); while (E) { if (wd.transient_parent != E->get() || wd.transient_parent == INVALID_WINDOW_ID) { C = E; E = E->prev(); } else { break; } } if (C) { _send_window_event(windows[C->get()], DisplayServerX11::WINDOW_EVENT_CLOSE_REQUEST); } time_since_popup = OS::get_singleton()->get_ticks_msec(); popup_list.push_back(p_window); } } void DisplayServerX11::popup_close(WindowID p_window) { _THREAD_SAFE_METHOD_ List::Element *E = popup_list.find(p_window); while (E) { List::Element *F = E->next(); WindowID win_id = E->get(); popup_list.erase(E); _send_window_event(windows[win_id], DisplayServerX11::WINDOW_EVENT_CLOSE_REQUEST); E = F; } } bool DisplayServerX11::mouse_process_popups() { _THREAD_SAFE_METHOD_ if (popup_list.is_empty()) { return false; } uint64_t delta = OS::get_singleton()->get_ticks_msec() - time_since_popup; if (delta < 250) { return false; } int number_of_screens = XScreenCount(x11_display); bool closed = false; for (int i = 0; i < number_of_screens; i++) { Window root, child; int root_x, root_y, win_x, win_y; unsigned int mask; if (XQueryPointer(x11_display, XRootWindow(x11_display, i), &root, &child, &root_x, &root_y, &win_x, &win_y, &mask)) { XWindowAttributes root_attrs; XGetWindowAttributes(x11_display, root, &root_attrs); Vector2i pos = Vector2i(root_attrs.x + root_x, root_attrs.y + root_y); if (mask != last_mouse_monitor_mask) { if (((mask & Button1Mask) || (mask & Button2Mask) || (mask & Button3Mask) || (mask & Button4Mask) || (mask & Button5Mask))) { List::Element *C = nullptr; List::Element *E = popup_list.back(); // Find top popup to close. while (E) { // Popup window area. Rect2i win_rect = Rect2i(window_get_position(E->get()), window_get_size(E->get())); // Area of the parent window, which responsible for opening sub-menu. Rect2i safe_rect = window_get_popup_safe_rect(E->get()); if (win_rect.has_point(pos)) { break; } else if (safe_rect != Rect2i() && safe_rect.has_point(pos)) { break; } else { C = E; E = E->prev(); } } if (C) { _send_window_event(windows[C->get()], DisplayServerX11::WINDOW_EVENT_CLOSE_REQUEST); closed = true; } } } last_mouse_monitor_mask = mask; } } return closed; } void DisplayServerX11::process_events() { _THREAD_SAFE_METHOD_ #ifdef DISPLAY_SERVER_X11_DEBUG_LOGS_ENABLED static int frame = 0; ++frame; #endif bool ignore_events = mouse_process_popups(); if (app_focused) { //verify that one of the windows has focus, else send focus out notification bool focus_found = false; for (const KeyValue &E : windows) { if (E.value.focused) { focus_found = true; break; } } if (!focus_found) { uint64_t delta = OS::get_singleton()->get_ticks_msec() - time_since_no_focus; if (delta > 250) { //X11 can go between windows and have no focus for a while, when creating them or something else. Use this as safety to avoid unnecessary focus in/outs. if (OS::get_singleton()->get_main_loop()) { DEBUG_LOG_X11("All focus lost, triggering NOTIFICATION_APPLICATION_FOCUS_OUT\n"); OS::get_singleton()->get_main_loop()->notification(MainLoop::NOTIFICATION_APPLICATION_FOCUS_OUT); } app_focused = false; } } else { time_since_no_focus = OS::get_singleton()->get_ticks_msec(); } } do_mouse_warp = false; // Is the current mouse mode one where it needs to be grabbed. bool mouse_mode_grab = mouse_mode == MOUSE_MODE_CAPTURED || mouse_mode == MOUSE_MODE_CONFINED || mouse_mode == MOUSE_MODE_CONFINED_HIDDEN; xi.pressure = 0; xi.tilt = Vector2(); xi.pressure_supported = false; LocalVector events; { // Block events polling while flushing events. MutexLock mutex_lock(events_mutex); events = polled_events; polled_events.clear(); // Check for more pending events to avoid an extra frame delay. _check_pending_events(events); } for (uint32_t event_index = 0; event_index < events.size(); ++event_index) { XEvent &event = events[event_index]; if (ignore_events) { XFreeEventData(x11_display, &event.xcookie); continue; } WindowID window_id = MAIN_WINDOW_ID; // Assign the event to the relevant window for (const KeyValue &E : windows) { if (event.xany.window == E.value.x11_window) { window_id = E.key; break; } } if (XGetEventData(x11_display, &event.xcookie)) { if (event.xcookie.type == GenericEvent && event.xcookie.extension == xi.opcode) { XIDeviceEvent *event_data = (XIDeviceEvent *)event.xcookie.data; int index = event_data->detail; Vector2 pos = Vector2(event_data->event_x, event_data->event_y); switch (event_data->evtype) { case XI_HierarchyChanged: case XI_DeviceChanged: { _refresh_device_info(); } break; case XI_RawMotion: { XIRawEvent *raw_event = (XIRawEvent *)event_data; int device_id = raw_event->sourceid; // Determine the axis used (called valuators in XInput for some forsaken reason) // Mask is a bitmask indicating which axes are involved. // We are interested in the values of axes 0 and 1. if (raw_event->valuators.mask_len <= 0) { break; } const double *values = raw_event->raw_values; double rel_x = 0.0; double rel_y = 0.0; if (XIMaskIsSet(raw_event->valuators.mask, VALUATOR_ABSX)) { rel_x = *values; values++; } if (XIMaskIsSet(raw_event->valuators.mask, VALUATOR_ABSY)) { rel_y = *values; values++; } if (XIMaskIsSet(raw_event->valuators.mask, VALUATOR_PRESSURE)) { HashMap::Iterator pen_pressure = xi.pen_pressure_range.find(device_id); if (pen_pressure) { Vector2 pen_pressure_range = pen_pressure->value; if (pen_pressure_range != Vector2()) { xi.pressure_supported = true; xi.pressure = (*values - pen_pressure_range[0]) / (pen_pressure_range[1] - pen_pressure_range[0]); } } values++; } if (XIMaskIsSet(raw_event->valuators.mask, VALUATOR_TILTX)) { HashMap::Iterator pen_tilt_x = xi.pen_tilt_x_range.find(device_id); if (pen_tilt_x) { Vector2 pen_tilt_x_range = pen_tilt_x->value; if (pen_tilt_x_range[0] != 0 && *values < 0) { xi.tilt.x = *values / -pen_tilt_x_range[0]; } else if (pen_tilt_x_range[1] != 0) { xi.tilt.x = *values / pen_tilt_x_range[1]; } } values++; } if (XIMaskIsSet(raw_event->valuators.mask, VALUATOR_TILTY)) { HashMap::Iterator pen_tilt_y = xi.pen_tilt_y_range.find(device_id); if (pen_tilt_y) { Vector2 pen_tilt_y_range = pen_tilt_y->value; if (pen_tilt_y_range[0] != 0 && *values < 0) { xi.tilt.y = *values / -pen_tilt_y_range[0]; } else if (pen_tilt_y_range[1] != 0) { xi.tilt.y = *values / pen_tilt_y_range[1]; } } values++; } HashMap::Iterator pen_inverted = xi.pen_inverted_devices.find(device_id); if (pen_inverted) { xi.pen_inverted = pen_inverted->value; } // https://bugs.freedesktop.org/show_bug.cgi?id=71609 // http://lists.libsdl.org/pipermail/commits-libsdl.org/2015-June/000282.html if (raw_event->time == xi.last_relative_time && rel_x == xi.relative_motion.x && rel_y == xi.relative_motion.y) { break; // Flush duplicate to avoid overly fast motion } xi.old_raw_pos.x = xi.raw_pos.x; xi.old_raw_pos.y = xi.raw_pos.y; xi.raw_pos.x = rel_x; xi.raw_pos.y = rel_y; HashMap::Iterator abs_info = xi.absolute_devices.find(device_id); if (abs_info) { // Absolute mode device Vector2 mult = abs_info->value; xi.relative_motion.x += (xi.raw_pos.x - xi.old_raw_pos.x) * mult.x; xi.relative_motion.y += (xi.raw_pos.y - xi.old_raw_pos.y) * mult.y; } else { // Relative mode device xi.relative_motion.x = xi.raw_pos.x; xi.relative_motion.y = xi.raw_pos.y; } xi.last_relative_time = raw_event->time; } break; #ifdef TOUCH_ENABLED case XI_TouchBegin: case XI_TouchEnd: { bool is_begin = event_data->evtype == XI_TouchBegin; Ref st; st.instantiate(); st->set_window_id(window_id); st->set_index(index); st->set_position(pos); st->set_pressed(is_begin); if (is_begin) { if (xi.state.has(index)) { // Defensive break; } xi.state[index] = pos; if (xi.state.size() == 1) { // X11 may send a motion event when a touch gesture begins, that would result // in a spurious mouse motion event being sent to Godot; remember it to be able to filter it out xi.mouse_pos_to_filter = pos; } Input::get_singleton()->parse_input_event(st); } else { if (!xi.state.has(index)) { // Defensive break; } xi.state.erase(index); Input::get_singleton()->parse_input_event(st); } } break; case XI_TouchUpdate: { HashMap::Iterator curr_pos_elem = xi.state.find(index); if (!curr_pos_elem) { // Defensive break; } if (curr_pos_elem->value != pos) { Ref sd; sd.instantiate(); sd->set_window_id(window_id); sd->set_index(index); sd->set_position(pos); sd->set_relative(pos - curr_pos_elem->value); Input::get_singleton()->parse_input_event(sd); curr_pos_elem->value = pos; } } break; #endif } } } XFreeEventData(x11_display, &event.xcookie); switch (event.type) { case MapNotify: { DEBUG_LOG_X11("[%u] MapNotify window=%lu (%u) \n", frame, event.xmap.window, window_id); const WindowData &wd = windows[window_id]; XWindowAttributes xwa; XSync(x11_display, False); XGetWindowAttributes(x11_display, wd.x11_window, &xwa); // Set focus when menu window is started. // RevertToPointerRoot is used to make sure we don't lose all focus in case // a subwindow and its parent are both destroyed. if ((xwa.map_state == IsViewable) && !wd.no_focus && !wd.is_popup) { XSetInputFocus(x11_display, wd.x11_window, RevertToPointerRoot, CurrentTime); } // Have we failed to set fullscreen while the window was unmapped? _validate_mode_on_map(window_id); } break; case Expose: { DEBUG_LOG_X11("[%u] Expose window=%lu (%u), count='%u' \n", frame, event.xexpose.window, window_id, event.xexpose.count); windows[window_id].fullscreen = _window_fullscreen_check(window_id); Main::force_redraw(); } break; case NoExpose: { DEBUG_LOG_X11("[%u] NoExpose drawable=%lu (%u) \n", frame, event.xnoexpose.drawable, window_id); windows[window_id].minimized = true; } break; case VisibilityNotify: { DEBUG_LOG_X11("[%u] VisibilityNotify window=%lu (%u), state=%u \n", frame, event.xvisibility.window, window_id, event.xvisibility.state); windows[window_id].minimized = _window_minimize_check(window_id); } break; case LeaveNotify: { DEBUG_LOG_X11("[%u] LeaveNotify window=%lu (%u), mode='%u' \n", frame, event.xcrossing.window, window_id, event.xcrossing.mode); if (!mouse_mode_grab) { _send_window_event(windows[window_id], WINDOW_EVENT_MOUSE_EXIT); } } break; case EnterNotify: { DEBUG_LOG_X11("[%u] EnterNotify window=%lu (%u), mode='%u' \n", frame, event.xcrossing.window, window_id, event.xcrossing.mode); if (!mouse_mode_grab) { _send_window_event(windows[window_id], WINDOW_EVENT_MOUSE_ENTER); } } break; case FocusIn: { DEBUG_LOG_X11("[%u] FocusIn window=%lu (%u), mode='%u' \n", frame, event.xfocus.window, window_id, event.xfocus.mode); WindowData &wd = windows[window_id]; last_focused_window = window_id; wd.focused = true; if (wd.xic) { // Block events polling while changing input focus // because it triggers some event polling internally. MutexLock mutex_lock(events_mutex); XSetICFocus(wd.xic); } // Keep track of focus order for overlapping windows. static unsigned int focus_order = 0; wd.focus_order = ++focus_order; _send_window_event(wd, WINDOW_EVENT_FOCUS_IN); if (mouse_mode_grab) { // Show and update the cursor if confined and the window regained focus. for (const KeyValue &E : windows) { if (mouse_mode == MOUSE_MODE_CONFINED) { XUndefineCursor(x11_display, E.value.x11_window); } else if (mouse_mode == MOUSE_MODE_CAPTURED || mouse_mode == MOUSE_MODE_CONFINED_HIDDEN) { // Or re-hide it. XDefineCursor(x11_display, E.value.x11_window, null_cursor); } XGrabPointer( x11_display, E.value.x11_window, True, ButtonPressMask | ButtonReleaseMask | PointerMotionMask, GrabModeAsync, GrabModeAsync, E.value.x11_window, None, CurrentTime); } } #ifdef TOUCH_ENABLED // Grab touch devices to avoid OS gesture interference /*for (int i = 0; i < xi.touch_devices.size(); ++i) { XIGrabDevice(x11_display, xi.touch_devices[i], x11_window, CurrentTime, None, XIGrabModeAsync, XIGrabModeAsync, False, &xi.touch_event_mask); }*/ #endif if (!app_focused) { if (OS::get_singleton()->get_main_loop()) { OS::get_singleton()->get_main_loop()->notification(MainLoop::NOTIFICATION_APPLICATION_FOCUS_IN); } app_focused = true; } } break; case FocusOut: { DEBUG_LOG_X11("[%u] FocusOut window=%lu (%u), mode='%u' \n", frame, event.xfocus.window, window_id, event.xfocus.mode); WindowData &wd = windows[window_id]; wd.focused = false; if (wd.xic) { // Block events polling while changing input focus // because it triggers some event polling internally. MutexLock mutex_lock(events_mutex); XUnsetICFocus(wd.xic); } Input::get_singleton()->release_pressed_events(); _send_window_event(wd, WINDOW_EVENT_FOCUS_OUT); if (mouse_mode_grab) { for (const KeyValue &E : windows) { //dear X11, I try, I really try, but you never work, you do whatever you want. if (mouse_mode == MOUSE_MODE_CAPTURED) { // Show the cursor if we're in captured mode so it doesn't look weird. XUndefineCursor(x11_display, E.value.x11_window); } } XUngrabPointer(x11_display, CurrentTime); } #ifdef TOUCH_ENABLED // Ungrab touch devices so input works as usual while we are unfocused /*for (int i = 0; i < xi.touch_devices.size(); ++i) { XIUngrabDevice(x11_display, xi.touch_devices[i], CurrentTime); }*/ // Release every pointer to avoid sticky points for (const KeyValue &E : xi.state) { Ref st; st.instantiate(); st->set_index(E.key); st->set_window_id(window_id); st->set_position(E.value); Input::get_singleton()->parse_input_event(st); } xi.state.clear(); #endif } break; case ConfigureNotify: { DEBUG_LOG_X11("[%u] ConfigureNotify window=%lu (%u), event=%lu, above=%lu, override_redirect=%u \n", frame, event.xconfigure.window, window_id, event.xconfigure.event, event.xconfigure.above, event.xconfigure.override_redirect); const WindowData &wd = windows[window_id]; XWindowAttributes xwa; XSync(x11_display, False); XGetWindowAttributes(x11_display, wd.x11_window, &xwa); // Set focus when menu window is re-used. // RevertToPointerRoot is used to make sure we don't lose all focus in case // a subwindow and its parent are both destroyed. if ((xwa.map_state == IsViewable) && !wd.no_focus && !wd.is_popup) { XSetInputFocus(x11_display, wd.x11_window, RevertToPointerRoot, CurrentTime); } _window_changed(&event); } break; case ButtonPress: case ButtonRelease: { /* exit in case of a mouse button press */ last_timestamp = event.xbutton.time; if (mouse_mode == MOUSE_MODE_CAPTURED) { event.xbutton.x = last_mouse_pos.x; event.xbutton.y = last_mouse_pos.y; } Ref mb; mb.instantiate(); mb->set_window_id(window_id); _get_key_modifier_state(event.xbutton.state, mb); mb->set_button_index((MouseButton)event.xbutton.button); if (mb->get_button_index() == MouseButton::RIGHT) { mb->set_button_index(MouseButton::MIDDLE); } else if (mb->get_button_index() == MouseButton::MIDDLE) { mb->set_button_index(MouseButton::RIGHT); } mb->set_button_mask(_get_mouse_button_state(mb->get_button_index(), event.xbutton.type)); mb->set_position(Vector2(event.xbutton.x, event.xbutton.y)); mb->set_global_position(mb->get_position()); mb->set_pressed((event.type == ButtonPress)); const WindowData &wd = windows[window_id]; if (event.type == ButtonPress) { DEBUG_LOG_X11("[%u] ButtonPress window=%lu (%u), button_index=%u \n", frame, event.xbutton.window, window_id, mb->get_button_index()); // Ensure window focus on click. // RevertToPointerRoot is used to make sure we don't lose all focus in case // a subwindow and its parent are both destroyed. if (!wd.no_focus && !wd.is_popup) { XSetInputFocus(x11_display, wd.x11_window, RevertToPointerRoot, CurrentTime); } uint64_t diff = OS::get_singleton()->get_ticks_usec() / 1000 - last_click_ms; if (mb->get_button_index() == last_click_button_index) { if (diff < 400 && Vector2(last_click_pos).distance_to(Vector2(event.xbutton.x, event.xbutton.y)) < 5) { last_click_ms = 0; last_click_pos = Point2i(-100, -100); last_click_button_index = MouseButton::NONE; mb->set_double_click(true); } } else if (mb->get_button_index() < MouseButton::WHEEL_UP || mb->get_button_index() > MouseButton::WHEEL_RIGHT) { last_click_button_index = mb->get_button_index(); } if (!mb->is_double_click()) { last_click_ms += diff; last_click_pos = Point2i(event.xbutton.x, event.xbutton.y); } } else { DEBUG_LOG_X11("[%u] ButtonRelease window=%lu (%u), button_index=%u \n", frame, event.xbutton.window, window_id, mb->get_button_index()); if (!wd.focused) { // Propagate the event to the focused window, // because it's received only on the topmost window. // Note: This is needed for drag & drop to work between windows, // because the engine expects events to keep being processed // on the same window dragging started. for (const KeyValue &E : windows) { const WindowData &wd_other = E.value; WindowID window_id_other = E.key; if (wd_other.focused) { if (window_id_other != window_id) { int x, y; Window child; XTranslateCoordinates(x11_display, wd.x11_window, wd_other.x11_window, event.xbutton.x, event.xbutton.y, &x, &y, &child); mb->set_window_id(window_id_other); mb->set_position(Vector2(x, y)); mb->set_global_position(mb->get_position()); Input::get_singleton()->parse_input_event(mb); } break; } } } } Input::get_singleton()->parse_input_event(mb); } break; case MotionNotify: { // The X11 API requires filtering one-by-one through the motion // notify events, in order to figure out which event is the one // generated by warping the mouse pointer. WindowID focused_window_id = _get_focused_window_or_popup(); if (!windows.has(focused_window_id)) { focused_window_id = MAIN_WINDOW_ID; } while (true) { if (mouse_mode == MOUSE_MODE_CAPTURED && event.xmotion.x == windows[focused_window_id].size.width / 2 && event.xmotion.y == windows[focused_window_id].size.height / 2) { //this is likely the warp event since it was warped here center = Vector2(event.xmotion.x, event.xmotion.y); break; } if (event_index + 1 < events.size()) { const XEvent &next_event = events[event_index + 1]; if (next_event.type == MotionNotify) { ++event_index; event = next_event; } else { break; } } else { break; } } last_timestamp = event.xmotion.time; // Motion is also simple. // A little hack is in order // to be able to send relative motion events. Point2i pos(event.xmotion.x, event.xmotion.y); // Avoidance of spurious mouse motion (see handling of touch) bool filter = false; // Adding some tolerance to match better Point2i to Vector2 if (xi.state.size() && Vector2(pos).distance_squared_to(xi.mouse_pos_to_filter) < 2) { filter = true; } // Invalidate to avoid filtering a possible legitimate similar event coming later xi.mouse_pos_to_filter = Vector2(1e10, 1e10); if (filter) { break; } const WindowData &wd = windows[window_id]; bool focused = wd.focused; if (mouse_mode == MOUSE_MODE_CAPTURED) { if (xi.relative_motion.x == 0 && xi.relative_motion.y == 0) { break; } Point2i new_center = pos; pos = last_mouse_pos + xi.relative_motion; center = new_center; do_mouse_warp = focused; // warp the cursor if we're focused in } if (!last_mouse_pos_valid) { last_mouse_pos = pos; last_mouse_pos_valid = true; } // Hackish but relative mouse motion is already handled in the RawMotion event. // RawMotion does not provide the absolute mouse position (whereas MotionNotify does). // Therefore, RawMotion cannot be the authority on absolute mouse position. // RawMotion provides more precision than MotionNotify, which doesn't sense subpixel motion. // Therefore, MotionNotify cannot be the authority on relative mouse motion. // This means we need to take a combined approach... Point2i rel; // Only use raw input if in capture mode. Otherwise use the classic behavior. if (mouse_mode == MOUSE_MODE_CAPTURED) { rel = xi.relative_motion; } else { rel = pos - last_mouse_pos; } // Reset to prevent lingering motion xi.relative_motion.x = 0; xi.relative_motion.y = 0; if (mouse_mode == MOUSE_MODE_CAPTURED) { pos = Point2i(windows[focused_window_id].size.width / 2, windows[focused_window_id].size.height / 2); } Ref mm; mm.instantiate(); mm->set_window_id(window_id); if (xi.pressure_supported) { mm->set_pressure(xi.pressure); } else { mm->set_pressure(bool(mouse_get_button_state() & MouseButton::MASK_LEFT) ? 1.0f : 0.0f); } mm->set_tilt(xi.tilt); mm->set_pen_inverted(xi.pen_inverted); _get_key_modifier_state(event.xmotion.state, mm); mm->set_button_mask((MouseButton)mouse_get_button_state()); mm->set_position(pos); mm->set_global_position(pos); mm->set_velocity(Input::get_singleton()->get_last_mouse_velocity()); mm->set_relative(rel); last_mouse_pos = pos; // printf("rel: %d,%d\n", rel.x, rel.y ); // Don't propagate the motion event unless we have focus // this is so that the relative motion doesn't get messed up // after we regain focus. if (focused) { Input::get_singleton()->parse_input_event(mm); } else { // Propagate the event to the focused window, // because it's received only on the topmost window. // Note: This is needed for drag & drop to work between windows, // because the engine expects events to keep being processed // on the same window dragging started. for (const KeyValue &E : windows) { const WindowData &wd_other = E.value; if (wd_other.focused) { int x, y; Window child; XTranslateCoordinates(x11_display, wd.x11_window, wd_other.x11_window, event.xmotion.x, event.xmotion.y, &x, &y, &child); Point2i pos_focused(x, y); mm->set_window_id(E.key); mm->set_position(pos_focused); mm->set_global_position(pos_focused); mm->set_velocity(Input::get_singleton()->get_last_mouse_velocity()); Input::get_singleton()->parse_input_event(mm); break; } } } } break; case KeyPress: case KeyRelease: { #ifdef DISPLAY_SERVER_X11_DEBUG_LOGS_ENABLED if (event.type == KeyPress) { DEBUG_LOG_X11("[%u] KeyPress window=%lu (%u), keycode=%u, time=%lu \n", frame, event.xkey.window, window_id, event.xkey.keycode, event.xkey.time); } else { DEBUG_LOG_X11("[%u] KeyRelease window=%lu (%u), keycode=%u, time=%lu \n", frame, event.xkey.window, window_id, event.xkey.keycode, event.xkey.time); } #endif last_timestamp = event.xkey.time; // key event is a little complex, so // it will be handled in its own function. _handle_key_event(window_id, &event.xkey, events, event_index); } break; case SelectionNotify: if (event.xselection.target == requested) { Property p = _read_property(x11_display, windows[window_id].x11_window, XInternAtom(x11_display, "PRIMARY", 0)); Vector files = String((char *)p.data).split("\r\n", false); XFree(p.data); for (int i = 0; i < files.size(); i++) { files.write[i] = files[i].replace("file://", "").uri_decode(); } if (!windows[window_id].drop_files_callback.is_null()) { Variant v = files; Variant *vp = &v; Variant ret; Callable::CallError ce; windows[window_id].drop_files_callback.callp((const Variant **)&vp, 1, ret, ce); } //Reply that all is well. XClientMessageEvent m; memset(&m, 0, sizeof(m)); m.type = ClientMessage; m.display = x11_display; m.window = xdnd_source_window; m.message_type = xdnd_finished; m.format = 32; m.data.l[0] = windows[window_id].x11_window; m.data.l[1] = 1; m.data.l[2] = xdnd_action_copy; //We only ever copy. XSendEvent(x11_display, xdnd_source_window, False, NoEventMask, (XEvent *)&m); } break; case ClientMessage: if ((unsigned int)event.xclient.data.l[0] == (unsigned int)wm_delete) { _send_window_event(windows[window_id], WINDOW_EVENT_CLOSE_REQUEST); } else if ((unsigned int)event.xclient.message_type == (unsigned int)xdnd_enter) { //File(s) have been dragged over the window, check for supported target (text/uri-list) xdnd_version = (event.xclient.data.l[1] >> 24); Window source = event.xclient.data.l[0]; bool more_than_3 = event.xclient.data.l[1] & 1; if (more_than_3) { Property p = _read_property(x11_display, source, XInternAtom(x11_display, "XdndTypeList", False)); requested = pick_target_from_list(x11_display, (Atom *)p.data, p.nitems); XFree(p.data); } else { requested = pick_target_from_atoms(x11_display, event.xclient.data.l[2], event.xclient.data.l[3], event.xclient.data.l[4]); } } else if ((unsigned int)event.xclient.message_type == (unsigned int)xdnd_position) { //xdnd position event, reply with an XDND status message //just depending on type of data for now XClientMessageEvent m; memset(&m, 0, sizeof(m)); m.type = ClientMessage; m.display = event.xclient.display; m.window = event.xclient.data.l[0]; m.message_type = xdnd_status; m.format = 32; m.data.l[0] = windows[window_id].x11_window; m.data.l[1] = (requested != None); m.data.l[2] = 0; //empty rectangle m.data.l[3] = 0; m.data.l[4] = xdnd_action_copy; XSendEvent(x11_display, event.xclient.data.l[0], False, NoEventMask, (XEvent *)&m); XFlush(x11_display); } else if ((unsigned int)event.xclient.message_type == (unsigned int)xdnd_drop) { if (requested != None) { xdnd_source_window = event.xclient.data.l[0]; if (xdnd_version >= 1) { XConvertSelection(x11_display, xdnd_selection, requested, XInternAtom(x11_display, "PRIMARY", 0), windows[window_id].x11_window, event.xclient.data.l[2]); } else { XConvertSelection(x11_display, xdnd_selection, requested, XInternAtom(x11_display, "PRIMARY", 0), windows[window_id].x11_window, CurrentTime); } } else { //Reply that we're not interested. XClientMessageEvent m; memset(&m, 0, sizeof(m)); m.type = ClientMessage; m.display = event.xclient.display; m.window = event.xclient.data.l[0]; m.message_type = xdnd_finished; m.format = 32; m.data.l[0] = windows[window_id].x11_window; m.data.l[1] = 0; m.data.l[2] = None; //Failed. XSendEvent(x11_display, event.xclient.data.l[0], False, NoEventMask, (XEvent *)&m); } } break; default: break; } } XFlush(x11_display); if (do_mouse_warp) { XWarpPointer(x11_display, None, windows[MAIN_WINDOW_ID].x11_window, 0, 0, 0, 0, (int)windows[MAIN_WINDOW_ID].size.width / 2, (int)windows[MAIN_WINDOW_ID].size.height / 2); /* Window root, child; int root_x, root_y; int win_x, win_y; unsigned int mask; XQueryPointer( x11_display, x11_window, &root, &child, &root_x, &root_y, &win_x, &win_y, &mask ); printf("Root: %d,%d\n", root_x, root_y); printf("Win: %d,%d\n", win_x, win_y); */ } Input::get_singleton()->flush_buffered_events(); } void DisplayServerX11::release_rendering_thread() { #if defined(GLES3_ENABLED) if (gl_manager) { gl_manager->release_current(); } #endif } void DisplayServerX11::make_rendering_thread() { #if defined(GLES3_ENABLED) if (gl_manager) { gl_manager->make_current(); } #endif } void DisplayServerX11::swap_buffers() { #if defined(GLES3_ENABLED) if (gl_manager) { gl_manager->swap_buffers(); } #endif } void DisplayServerX11::_update_context(WindowData &wd) { XClassHint *classHint = XAllocClassHint(); if (classHint) { CharString name_str; switch (context) { case CONTEXT_EDITOR: name_str = "Godot_Editor"; break; case CONTEXT_PROJECTMAN: name_str = "Godot_ProjectList"; break; case CONTEXT_ENGINE: name_str = "Godot_Engine"; break; } CharString class_str; if (context == CONTEXT_ENGINE) { String config_name = GLOBAL_GET("application/config/name"); if (config_name.length() == 0) { class_str = "Godot_Engine"; } else { class_str = config_name.utf8(); } } else { class_str = "Godot"; } classHint->res_class = class_str.ptrw(); classHint->res_name = name_str.ptrw(); XSetClassHint(x11_display, wd.x11_window, classHint); XFree(classHint); } } void DisplayServerX11::set_context(Context p_context) { _THREAD_SAFE_METHOD_ context = p_context; for (KeyValue &E : windows) { _update_context(E.value); } } void DisplayServerX11::set_native_icon(const String &p_filename) { WARN_PRINT("Native icon not supported by this display server."); } bool g_set_icon_error = false; int set_icon_errorhandler(Display *dpy, XErrorEvent *ev) { g_set_icon_error = true; return 0; } void DisplayServerX11::set_icon(const Ref &p_icon) { _THREAD_SAFE_METHOD_ WindowData &wd = windows[MAIN_WINDOW_ID]; int (*oldHandler)(Display *, XErrorEvent *) = XSetErrorHandler(&set_icon_errorhandler); Atom net_wm_icon = XInternAtom(x11_display, "_NET_WM_ICON", False); if (p_icon.is_valid()) { Ref img = p_icon->duplicate(); img->convert(Image::FORMAT_RGBA8); while (true) { int w = img->get_width(); int h = img->get_height(); if (g_set_icon_error) { g_set_icon_error = false; WARN_PRINT("Icon too large, attempting to resize icon."); int new_width, new_height; if (w > h) { new_width = w / 2; new_height = h * new_width / w; } else { new_height = h / 2; new_width = w * new_height / h; } w = new_width; h = new_height; if (!w || !h) { WARN_PRINT("Unable to set icon."); break; } img->resize(w, h, Image::INTERPOLATE_CUBIC); } // We're using long to have wordsize (32Bit build -> 32 Bits, 64 Bit build -> 64 Bits Vector pd; pd.resize(2 + w * h); pd.write[0] = w; pd.write[1] = h; const uint8_t *r = img->get_data().ptr(); long *wr = &pd.write[2]; uint8_t const *pr = r; for (int i = 0; i < w * h; i++) { long v = 0; // A R G B v |= pr[3] << 24 | pr[0] << 16 | pr[1] << 8 | pr[2]; *wr++ = v; pr += 4; } if (net_wm_icon != None) { XChangeProperty(x11_display, wd.x11_window, net_wm_icon, XA_CARDINAL, 32, PropModeReplace, (unsigned char *)pd.ptr(), pd.size()); } if (!g_set_icon_error) { break; } } } else { XDeleteProperty(x11_display, wd.x11_window, net_wm_icon); } XFlush(x11_display); XSetErrorHandler(oldHandler); } void DisplayServerX11::window_set_vsync_mode(DisplayServer::VSyncMode p_vsync_mode, WindowID p_window) { _THREAD_SAFE_METHOD_ #if defined(VULKAN_ENABLED) if (context_vulkan) { context_vulkan->set_vsync_mode(p_window, p_vsync_mode); } #endif #if defined(GLES3_ENABLED) if (gl_manager) { gl_manager->set_use_vsync(p_vsync_mode == DisplayServer::VSYNC_ENABLED); } #endif } DisplayServer::VSyncMode DisplayServerX11::window_get_vsync_mode(WindowID p_window) const { _THREAD_SAFE_METHOD_ #if defined(VULKAN_ENABLED) if (context_vulkan) { return context_vulkan->get_vsync_mode(p_window); } #endif #if defined(GLES3_ENABLED) if (gl_manager) { return gl_manager->is_using_vsync() ? DisplayServer::VSYNC_ENABLED : DisplayServer::VSYNC_DISABLED; } #endif return DisplayServer::VSYNC_ENABLED; } Vector DisplayServerX11::get_rendering_drivers_func() { Vector drivers; #ifdef VULKAN_ENABLED drivers.push_back("vulkan"); #endif #ifdef GLES3_ENABLED drivers.push_back("opengl3"); #endif return drivers; } DisplayServer *DisplayServerX11::create_func(const String &p_rendering_driver, WindowMode p_mode, VSyncMode p_vsync_mode, uint32_t p_flags, const Vector2i *p_position, const Vector2i &p_resolution, Error &r_error) { DisplayServer *ds = memnew(DisplayServerX11(p_rendering_driver, p_mode, p_vsync_mode, p_flags, p_position, p_resolution, r_error)); if (r_error != OK) { if (p_rendering_driver == "vulkan") { String executable_name = OS::get_singleton()->get_executable_path().get_file(); OS::get_singleton()->alert("Your video card driver does not support the selected Vulkan version.\n" "Please try updating your GPU driver or try using the OpenGL 3 driver.\n" "You can enable the OpenGL 3 driver by starting the engine from the\n" "command line with the command:\n'./" + executable_name + " --rendering-driver opengl3'.\n " "If you have updated your graphics drivers recently, try rebooting.", "Unable to initialize Video driver"); } else { OS::get_singleton()->alert("Your video card driver does not support the selected OpenGL version.\n" "Please try updating your GPU driver.\n" "If you have updated your graphics drivers recently, try rebooting.", "Unable to initialize Video driver"); } } return ds; } DisplayServerX11::WindowID DisplayServerX11::_create_window(WindowMode p_mode, VSyncMode p_vsync_mode, uint32_t p_flags, const Rect2i &p_rect) { //Create window XVisualInfo visualInfo; bool vi_selected = false; #ifdef GLES3_ENABLED if (gl_manager) { visualInfo = gl_manager->get_vi(x11_display); vi_selected = true; } #endif if (!vi_selected) { long visualMask = VisualScreenMask; int numberOfVisuals; XVisualInfo vInfoTemplate = {}; vInfoTemplate.screen = DefaultScreen(x11_display); XVisualInfo *vi_list = XGetVisualInfo(x11_display, visualMask, &vInfoTemplate, &numberOfVisuals); ERR_FAIL_COND_V(!vi_list, INVALID_WINDOW_ID); visualInfo = vi_list[0]; if (OS::get_singleton()->is_layered_allowed()) { for (int i = 0; i < numberOfVisuals; i++) { XRenderPictFormat *pict_format = XRenderFindVisualFormat(x11_display, vi_list[i].visual); if (!pict_format) { continue; } visualInfo = vi_list[i]; if (pict_format->direct.alphaMask > 0) { break; } } } XFree(vi_list); } Colormap colormap = XCreateColormap(x11_display, RootWindow(x11_display, visualInfo.screen), visualInfo.visual, AllocNone); XSetWindowAttributes windowAttributes = {}; windowAttributes.colormap = colormap; windowAttributes.background_pixel = 0xFFFFFFFF; windowAttributes.border_pixel = 0; windowAttributes.event_mask = KeyPressMask | KeyReleaseMask | StructureNotifyMask | ExposureMask; unsigned long valuemask = CWBorderPixel | CWColormap | CWEventMask; if (OS::get_singleton()->is_layered_allowed()) { windowAttributes.background_pixmap = None; windowAttributes.background_pixel = 0; windowAttributes.border_pixmap = None; valuemask |= CWBackPixel; } WindowID id = window_id_counter++; WindowData &wd = windows[id]; if (p_flags & WINDOW_FLAG_NO_FOCUS_BIT) { wd.no_focus = true; } if (p_flags & WINDOW_FLAG_POPUP_BIT) { wd.is_popup = true; } // Setup for menu subwindows: // - override_redirect forces the WM not to interfere with the window, to avoid delays due to // handling decorations and placement. // On the other hand, focus changes need to be handled manually when this is set. // - save_under is a hint for the WM to keep the content of windows behind to avoid repaint. if (wd.is_popup || wd.no_focus) { windowAttributes.override_redirect = True; windowAttributes.save_under = True; valuemask |= CWOverrideRedirect | CWSaveUnder; } { wd.x11_window = XCreateWindow(x11_display, RootWindow(x11_display, visualInfo.screen), p_rect.position.x, p_rect.position.y, p_rect.size.width > 0 ? p_rect.size.width : 1, p_rect.size.height > 0 ? p_rect.size.height : 1, 0, visualInfo.depth, InputOutput, visualInfo.visual, valuemask, &windowAttributes); // Enable receiving notification when the window is initialized (MapNotify) // so the focus can be set at the right time. if (!wd.no_focus && !wd.is_popup) { XSelectInput(x11_display, wd.x11_window, StructureNotifyMask); } //associate PID // make PID known to X11 { const long pid = OS::get_singleton()->get_process_id(); Atom net_wm_pid = XInternAtom(x11_display, "_NET_WM_PID", False); if (net_wm_pid != None) { XChangeProperty(x11_display, wd.x11_window, net_wm_pid, XA_CARDINAL, 32, PropModeReplace, (unsigned char *)&pid, 1); } } long im_event_mask = 0; { XIEventMask all_event_mask; XSetWindowAttributes new_attr; new_attr.event_mask = KeyPressMask | KeyReleaseMask | ButtonPressMask | ButtonReleaseMask | EnterWindowMask | LeaveWindowMask | PointerMotionMask | Button1MotionMask | Button2MotionMask | Button3MotionMask | Button4MotionMask | Button5MotionMask | ButtonMotionMask | KeymapStateMask | ExposureMask | VisibilityChangeMask | StructureNotifyMask | SubstructureNotifyMask | SubstructureRedirectMask | FocusChangeMask | PropertyChangeMask | ColormapChangeMask | OwnerGrabButtonMask | im_event_mask; XChangeWindowAttributes(x11_display, wd.x11_window, CWEventMask, &new_attr); static unsigned char all_mask_data[XIMaskLen(XI_LASTEVENT)] = {}; all_event_mask.deviceid = XIAllDevices; all_event_mask.mask_len = sizeof(all_mask_data); all_event_mask.mask = all_mask_data; XISetMask(all_event_mask.mask, XI_HierarchyChanged); #ifdef TOUCH_ENABLED if (xi.touch_devices.size()) { XISetMask(all_event_mask.mask, XI_TouchBegin); XISetMask(all_event_mask.mask, XI_TouchUpdate); XISetMask(all_event_mask.mask, XI_TouchEnd); XISetMask(all_event_mask.mask, XI_TouchOwnership); } #endif XISelectEvents(x11_display, wd.x11_window, &all_event_mask, 1); } /* set the titlebar name */ XStoreName(x11_display, wd.x11_window, "Godot"); XSetWMProtocols(x11_display, wd.x11_window, &wm_delete, 1); if (xdnd_aware != None) { XChangeProperty(x11_display, wd.x11_window, xdnd_aware, XA_ATOM, 32, PropModeReplace, (unsigned char *)&xdnd_version, 1); } if (xim && xim_style) { // Block events polling while changing input focus // because it triggers some event polling internally. MutexLock mutex_lock(events_mutex); wd.xic = XCreateIC(xim, XNInputStyle, xim_style, XNClientWindow, wd.x11_window, XNFocusWindow, wd.x11_window, (char *)nullptr); if (XGetICValues(wd.xic, XNFilterEvents, &im_event_mask, nullptr) != nullptr) { WARN_PRINT("XGetICValues couldn't obtain XNFilterEvents value"); XDestroyIC(wd.xic); wd.xic = nullptr; } if (wd.xic) { XUnsetICFocus(wd.xic); } else { WARN_PRINT("XCreateIC couldn't create wd.xic"); } } else { wd.xic = nullptr; WARN_PRINT("XCreateIC couldn't create wd.xic"); } _update_context(wd); if (p_flags & WINDOW_FLAG_BORDERLESS_BIT) { Hints hints; Atom property; hints.flags = 2; hints.decorations = 0; property = XInternAtom(x11_display, "_MOTIF_WM_HINTS", True); if (property != None) { XChangeProperty(x11_display, wd.x11_window, property, property, 32, PropModeReplace, (unsigned char *)&hints, 5); } } if (wd.is_popup || wd.no_focus) { // Set Utility type to disable fade animations. Atom type_atom = XInternAtom(x11_display, "_NET_WM_WINDOW_TYPE_UTILITY", False); Atom wt_atom = XInternAtom(x11_display, "_NET_WM_WINDOW_TYPE", False); if (wt_atom != None && type_atom != None) { XChangeProperty(x11_display, wd.x11_window, wt_atom, XA_ATOM, 32, PropModeReplace, (unsigned char *)&type_atom, 1); } } else { Atom type_atom = XInternAtom(x11_display, "_NET_WM_WINDOW_TYPE_NORMAL", False); Atom wt_atom = XInternAtom(x11_display, "_NET_WM_WINDOW_TYPE", False); if (wt_atom != None && type_atom != None) { XChangeProperty(x11_display, wd.x11_window, wt_atom, XA_ATOM, 32, PropModeReplace, (unsigned char *)&type_atom, 1); } } _update_size_hints(id); #if defined(VULKAN_ENABLED) if (context_vulkan) { Error err = context_vulkan->window_create(id, p_vsync_mode, wd.x11_window, x11_display, p_rect.size.width, p_rect.size.height); ERR_FAIL_COND_V_MSG(err != OK, INVALID_WINDOW_ID, "Can't create a Vulkan window"); } #endif #ifdef GLES3_ENABLED if (gl_manager) { Error err = gl_manager->window_create(id, wd.x11_window, x11_display, p_rect.size.width, p_rect.size.height); ERR_FAIL_COND_V_MSG(err != OK, INVALID_WINDOW_ID, "Can't create an OpenGL window"); } #endif //set_class_hint(x11_display, wd.x11_window); XFlush(x11_display); XSync(x11_display, False); //XSetErrorHandler(oldHandler); } window_set_mode(p_mode, id); //sync size { XWindowAttributes xwa; XSync(x11_display, False); XGetWindowAttributes(x11_display, wd.x11_window, &xwa); wd.position.x = xwa.x; wd.position.y = xwa.y; wd.size.width = xwa.width; wd.size.height = xwa.height; } //set cursor if (cursors[current_cursor] != None) { XDefineCursor(x11_display, wd.x11_window, cursors[current_cursor]); } return id; } DisplayServerX11::DisplayServerX11(const String &p_rendering_driver, WindowMode p_mode, VSyncMode p_vsync_mode, uint32_t p_flags, const Vector2i *p_position, const Vector2i &p_resolution, Error &r_error) { Input::get_singleton()->set_event_dispatch_function(_dispatch_input_events); r_error = OK; for (int i = 0; i < CURSOR_MAX; i++) { cursors[i] = None; img[i] = nullptr; } XInitThreads(); //always use threads /** XLIB INITIALIZATION **/ x11_display = XOpenDisplay(nullptr); if (!x11_display) { ERR_PRINT("X11 Display is not available"); r_error = ERR_UNAVAILABLE; return; } char *modifiers = nullptr; Bool xkb_dar = False; XAutoRepeatOn(x11_display); xkb_dar = XkbSetDetectableAutoRepeat(x11_display, True, nullptr); // Try to support IME if detectable auto-repeat is supported if (xkb_dar == True) { #ifdef X_HAVE_UTF8_STRING // Xutf8LookupString will be used later instead of XmbLookupString before // the multibyte sequences can be converted to unicode string. modifiers = XSetLocaleModifiers(""); #endif } if (modifiers == nullptr) { if (OS::get_singleton()->is_stdout_verbose()) { WARN_PRINT("IME is disabled"); } XSetLocaleModifiers("@im=none"); WARN_PRINT("Error setting locale modifiers"); } const char *err; int xrandr_major = 0; int xrandr_minor = 0; int event_base, error_base; xrandr_ext_ok = XRRQueryExtension(x11_display, &event_base, &error_base); xrandr_handle = dlopen("libXrandr.so.2", RTLD_LAZY); if (!xrandr_handle) { err = dlerror(); // For some arcane reason, NetBSD now ships libXrandr.so.3 while the rest of the world has libXrandr.so.2... // In case this happens for other X11 platforms in the future, let's give it a try too before failing. xrandr_handle = dlopen("libXrandr.so.3", RTLD_LAZY); if (!xrandr_handle) { fprintf(stderr, "could not load libXrandr.so.2, Error: %s\n", err); } } else { XRRQueryVersion(x11_display, &xrandr_major, &xrandr_minor); if (((xrandr_major << 8) | xrandr_minor) >= 0x0105) { xrr_get_monitors = (xrr_get_monitors_t)dlsym(xrandr_handle, "XRRGetMonitors"); if (!xrr_get_monitors) { err = dlerror(); fprintf(stderr, "could not find symbol XRRGetMonitors\nError: %s\n", err); } else { xrr_free_monitors = (xrr_free_monitors_t)dlsym(xrandr_handle, "XRRFreeMonitors"); if (!xrr_free_monitors) { err = dlerror(); fprintf(stderr, "could not find XRRFreeMonitors\nError: %s\n", err); xrr_get_monitors = nullptr; } } } } if (!_refresh_device_info()) { OS::get_singleton()->alert("Your system does not support XInput 2.\n" "Please upgrade your distribution.", "Unable to initialize XInput"); r_error = ERR_UNAVAILABLE; return; } xim = XOpenIM(x11_display, nullptr, nullptr, nullptr); if (xim == nullptr) { WARN_PRINT("XOpenIM failed"); xim_style = 0L; } else { ::XIMCallback im_destroy_callback; im_destroy_callback.client_data = (::XPointer)(this); im_destroy_callback.callback = (::XIMProc)(_xim_destroy_callback); if (XSetIMValues(xim, XNDestroyCallback, &im_destroy_callback, nullptr) != nullptr) { WARN_PRINT("Error setting XIM destroy callback"); } ::XIMStyles *xim_styles = nullptr; xim_style = 0L; char *imvalret = XGetIMValues(xim, XNQueryInputStyle, &xim_styles, nullptr); if (imvalret != nullptr || xim_styles == nullptr) { fprintf(stderr, "Input method doesn't support any styles\n"); } if (xim_styles) { xim_style = 0L; for (int i = 0; i < xim_styles->count_styles; i++) { if (xim_styles->supported_styles[i] == (XIMPreeditNothing | XIMStatusNothing)) { xim_style = xim_styles->supported_styles[i]; break; } } XFree(xim_styles); } XFree(imvalret); } /* Atom internment */ wm_delete = XInternAtom(x11_display, "WM_DELETE_WINDOW", true); // Set Xdnd (drag & drop) support. xdnd_aware = XInternAtom(x11_display, "XdndAware", False); xdnd_enter = XInternAtom(x11_display, "XdndEnter", False); xdnd_position = XInternAtom(x11_display, "XdndPosition", False); xdnd_status = XInternAtom(x11_display, "XdndStatus", False); xdnd_action_copy = XInternAtom(x11_display, "XdndActionCopy", False); xdnd_drop = XInternAtom(x11_display, "XdndDrop", False); xdnd_finished = XInternAtom(x11_display, "XdndFinished", False); xdnd_selection = XInternAtom(x11_display, "XdndSelection", False); #ifdef SPEECHD_ENABLED // Init TTS tts = memnew(TTS_Linux); #endif //!!!!!!!!!!!!!!!!!!!!!!!!!! //TODO - do Vulkan and OpenGL support checks, driver selection and fallback rendering_driver = p_rendering_driver; bool driver_found = false; #if defined(VULKAN_ENABLED) if (rendering_driver == "vulkan") { context_vulkan = memnew(VulkanContextX11); if (context_vulkan->initialize() != OK) { memdelete(context_vulkan); context_vulkan = nullptr; r_error = ERR_CANT_CREATE; ERR_FAIL_MSG("Could not initialize Vulkan"); } driver_found = true; } #endif // Initialize context and rendering device. #if defined(GLES3_ENABLED) if (rendering_driver == "opengl3") { if (getenv("DRI_PRIME") == nullptr) { int use_prime = -1; if (getenv("PRIMUS_DISPLAY") || getenv("PRIMUS_libGLd") || getenv("PRIMUS_libGLa") || getenv("PRIMUS_libGL") || getenv("PRIMUS_LOAD_GLOBAL") || getenv("BUMBLEBEE_SOCKET")) { print_verbose("Optirun/primusrun detected. Skipping GPU detection"); use_prime = 0; } // Some tools use fake libGL libraries and have them override the real one using // LD_LIBRARY_PATH, so we skip them. *But* Steam also sets LD_LIBRARY_PATH for its // runtime and includes system `/lib` and `/lib64`... so ignore Steam. if (use_prime == -1 && getenv("LD_LIBRARY_PATH") && !getenv("STEAM_RUNTIME_LIBRARY_PATH")) { String ld_library_path(getenv("LD_LIBRARY_PATH")); Vector libraries = ld_library_path.split(":"); for (int i = 0; i < libraries.size(); ++i) { if (FileAccess::exists(libraries[i] + "/libGL.so.1") || FileAccess::exists(libraries[i] + "/libGL.so")) { print_verbose("Custom libGL override detected. Skipping GPU detection"); use_prime = 0; } } } if (use_prime == -1) { print_verbose("Detecting GPUs, set DRI_PRIME in the environment to override GPU detection logic."); use_prime = detect_prime(); } if (use_prime) { print_line("Found discrete GPU, setting DRI_PRIME=1 to use it."); print_line("Note: Set DRI_PRIME=0 in the environment to disable Godot from using the discrete GPU."); setenv("DRI_PRIME", "1", 1); } } GLManager_X11::ContextType opengl_api_type = GLManager_X11::GLES_3_0_COMPATIBLE; gl_manager = memnew(GLManager_X11(p_resolution, opengl_api_type)); if (gl_manager->initialize() != OK) { memdelete(gl_manager); gl_manager = nullptr; r_error = ERR_UNAVAILABLE; return; } driver_found = true; if (true) { RasterizerGLES3::make_current(); } else { memdelete(gl_manager); gl_manager = nullptr; r_error = ERR_UNAVAILABLE; return; } } #endif if (!driver_found) { r_error = ERR_UNAVAILABLE; ERR_FAIL_MSG("Video driver not found"); } Point2i window_position( (screen_get_size(0).width - p_resolution.width) / 2, (screen_get_size(0).height - p_resolution.height) / 2); if (p_position != nullptr) { window_position = *p_position; } WindowID main_window = _create_window(p_mode, p_vsync_mode, p_flags, Rect2i(window_position, p_resolution)); if (main_window == INVALID_WINDOW_ID) { r_error = ERR_CANT_CREATE; return; } for (int i = 0; i < WINDOW_FLAG_MAX; i++) { if (p_flags & (1 << i)) { window_set_flag(WindowFlags(i), true, main_window); } } show_window(main_window); XSync(x11_display, False); _validate_mode_on_map(main_window); #if defined(VULKAN_ENABLED) if (rendering_driver == "vulkan") { //temporary rendering_device_vulkan = memnew(RenderingDeviceVulkan); rendering_device_vulkan->initialize(context_vulkan); RendererCompositorRD::make_current(); } #endif { //set all event master mask XIEventMask all_master_event_mask; static unsigned char all_master_mask_data[XIMaskLen(XI_LASTEVENT)] = {}; all_master_event_mask.deviceid = XIAllMasterDevices; all_master_event_mask.mask_len = sizeof(all_master_mask_data); all_master_event_mask.mask = all_master_mask_data; XISetMask(all_master_event_mask.mask, XI_DeviceChanged); XISetMask(all_master_event_mask.mask, XI_RawMotion); XISelectEvents(x11_display, DefaultRootWindow(x11_display), &all_master_event_mask, 1); } cursor_size = XcursorGetDefaultSize(x11_display); cursor_theme = XcursorGetTheme(x11_display); if (!cursor_theme) { print_verbose("XcursorGetTheme could not get cursor theme"); cursor_theme = "default"; } for (int i = 0; i < CURSOR_MAX; i++) { static const char *cursor_file[] = { "left_ptr", "xterm", "hand2", "cross", "watch", "left_ptr_watch", "fleur", "dnd-move", "crossed_circle", "v_double_arrow", "h_double_arrow", "size_bdiag", "size_fdiag", "move", "row_resize", "col_resize", "question_arrow" }; img[i] = XcursorLibraryLoadImage(cursor_file[i], cursor_theme, cursor_size); if (!img[i]) { const char *fallback = nullptr; switch (i) { case CURSOR_POINTING_HAND: fallback = "pointer"; break; case CURSOR_CROSS: fallback = "crosshair"; break; case CURSOR_WAIT: fallback = "wait"; break; case CURSOR_BUSY: fallback = "progress"; break; case CURSOR_DRAG: fallback = "grabbing"; break; case CURSOR_CAN_DROP: fallback = "hand1"; break; case CURSOR_FORBIDDEN: fallback = "forbidden"; break; case CURSOR_VSIZE: fallback = "ns-resize"; break; case CURSOR_HSIZE: fallback = "ew-resize"; break; case CURSOR_BDIAGSIZE: fallback = "fd_double_arrow"; break; case CURSOR_FDIAGSIZE: fallback = "bd_double_arrow"; break; case CURSOR_MOVE: img[i] = img[CURSOR_DRAG]; break; case CURSOR_VSPLIT: fallback = "sb_v_double_arrow"; break; case CURSOR_HSPLIT: fallback = "sb_h_double_arrow"; break; case CURSOR_HELP: fallback = "help"; break; } if (fallback != nullptr) { img[i] = XcursorLibraryLoadImage(fallback, cursor_theme, cursor_size); } } if (img[i]) { cursors[i] = XcursorImageLoadCursor(x11_display, img[i]); } else { print_verbose("Failed loading custom cursor: " + String(cursor_file[i])); } } { // Creating an empty/transparent cursor // Create 1x1 bitmap Pixmap cursormask = XCreatePixmap(x11_display, RootWindow(x11_display, DefaultScreen(x11_display)), 1, 1, 1); // Fill with zero XGCValues xgc; xgc.function = GXclear; GC gc = XCreateGC(x11_display, cursormask, GCFunction, &xgc); XFillRectangle(x11_display, cursormask, gc, 0, 0, 1, 1); // Color value doesn't matter. Mask zero means no foreground or background will be drawn XColor col = {}; Cursor cursor = XCreatePixmapCursor(x11_display, cursormask, // source (using cursor mask as placeholder, since it'll all be ignored) cursormask, // mask &col, &col, 0, 0); XFreePixmap(x11_display, cursormask); XFreeGC(x11_display, gc); if (cursor == None) { ERR_PRINT("FAILED CREATING CURSOR"); } null_cursor = cursor; } cursor_set_shape(CURSOR_BUSY); // Search the X11 event queue for ConfigureNotify events and process all // that are currently queued early, so we can get the final window size // for correctly drawing of the bootsplash. XEvent config_event; while (XCheckTypedEvent(x11_display, ConfigureNotify, &config_event)) { _window_changed(&config_event); } events_thread.start(_poll_events_thread, this); _update_real_mouse_position(windows[MAIN_WINDOW_ID]); #ifdef DBUS_ENABLED screensaver = memnew(FreeDesktopScreenSaver); screen_set_keep_on(GLOBAL_GET("display/window/energy_saving/keep_screen_on")); portal_desktop = memnew(FreeDesktopPortalDesktop); #endif r_error = OK; } DisplayServerX11::~DisplayServerX11() { // Send owned clipboard data to clipboard manager before exit. Window x11_main_window = windows[MAIN_WINDOW_ID].x11_window; _clipboard_transfer_ownership(XA_PRIMARY, x11_main_window); _clipboard_transfer_ownership(XInternAtom(x11_display, "CLIPBOARD", 0), x11_main_window); events_thread_done.set(); events_thread.wait_to_finish(); //destroy all windows for (KeyValue &E : windows) { #ifdef VULKAN_ENABLED if (context_vulkan) { context_vulkan->window_destroy(E.key); } #endif #ifdef GLES3_ENABLED if (gl_manager) { gl_manager->window_destroy(E.key); } #endif WindowData &wd = E.value; if (wd.xic) { XDestroyIC(wd.xic); wd.xic = nullptr; } XUnmapWindow(x11_display, wd.x11_window); XDestroyWindow(x11_display, wd.x11_window); } //destroy drivers #if defined(VULKAN_ENABLED) if (rendering_device_vulkan) { rendering_device_vulkan->finalize(); memdelete(rendering_device_vulkan); rendering_device_vulkan = nullptr; } if (context_vulkan) { memdelete(context_vulkan); context_vulkan = nullptr; } #endif #ifdef GLES3_ENABLED if (gl_manager) { memdelete(gl_manager); gl_manager = nullptr; } #endif if (xrandr_handle) { dlclose(xrandr_handle); } for (int i = 0; i < CURSOR_MAX; i++) { if (cursors[i] != None) { XFreeCursor(x11_display, cursors[i]); } if (img[i] != nullptr) { XcursorImageDestroy(img[i]); } } if (xim) { XCloseIM(xim); } XCloseDisplay(x11_display); if (xmbstring) { memfree(xmbstring); } #ifdef SPEECHD_ENABLED memdelete(tts); #endif #ifdef DBUS_ENABLED memdelete(screensaver); memdelete(portal_desktop); #endif } void DisplayServerX11::register_x11_driver() { register_create_function("x11", create_func, get_rendering_drivers_func); } #endif // X11 enabled