/********************************************************************************************** * * raylib.core - Basic functions to manage windows, OpenGL context and input on multiple platforms * * PLATFORMS SUPPORTED: * - PLATFORM_DESKTOP: Windows (Win32, Win64) * - PLATFORM_DESKTOP: Linux (X11 desktop mode) * - PLATFORM_DESKTOP: FreeBSD, OpenBSD, NetBSD, DragonFly (X11 desktop) * - PLATFORM_DESKTOP: OSX/macOS * - PLATFORM_ANDROID: Android 4.0 (ARM, ARM64) * - PLATFORM_RPI: Raspberry Pi 0,1,2,3,4 (Raspbian) * - PLATFORM_DRM: Linux native mode, including Raspberry Pi 4 with V3D fkms driver * - PLATFORM_WEB: HTML5 with asm.js (Chrome, Firefox) * - PLATFORM_UWP: Windows 10 App, Windows Phone, Xbox One * * CONFIGURATION: * * #define PLATFORM_DESKTOP * Windowing and input system configured for desktop platforms: Windows, Linux, OSX, FreeBSD, OpenBSD, NetBSD, DragonFly * NOTE: Oculus Rift CV1 requires PLATFORM_DESKTOP for mirror rendering - View [rlgl] module to enable it * * #define PLATFORM_ANDROID * Windowing and input system configured for Android device, app activity managed internally in this module. * NOTE: OpenGL ES 2.0 is required and graphic device is managed by EGL * * #define PLATFORM_RPI * Windowing and input system configured for Raspberry Pi i native mode (no X.org required, tested on Raspbian), * graphic device is managed by EGL and inputs are processed is raw mode, reading from /dev/input/ * * #define PLATFORM_WEB * Windowing and input system configured for HTML5 (run on browser), code converted from C to asm.js * using emscripten compiler. OpenGL ES 2.0 required for direct translation to WebGL equivalent code. * * #define PLATFORM_UWP * Universal Windows Platform support, using OpenGL ES 2.0 through ANGLE on multiple Windows platforms, * including Windows 10 App, Windows Phone and Xbox One platforms. * * #define SUPPORT_DEFAULT_FONT (default) * Default font is loaded on window initialization to be available for the user to render simple text. * NOTE: If enabled, uses external module functions to load default raylib font (module: text) * * #define SUPPORT_CAMERA_SYSTEM * Camera module is included (camera.h) and multiple predefined cameras are available: free, 1st/3rd person, orbital * * #define SUPPORT_GESTURES_SYSTEM * Gestures module is included (gestures.h) to support gestures detection: tap, hold, swipe, drag * * #define SUPPORT_MOUSE_GESTURES * Mouse gestures are directly mapped like touches and processed by gestures system. * * #define SUPPORT_TOUCH_AS_MOUSE * Touch input and mouse input are shared. Mouse functions also return touch information. * * #define SUPPORT_SSH_KEYBOARD_RPI (Raspberry Pi only) * Reconfigure standard input to receive key inputs, works with SSH connection. * WARNING: Reconfiguring standard input could lead to undesired effects, like breaking other running processes or * blocking the device is not restored properly. Use with care. * * #define SUPPORT_MOUSE_CURSOR_NATIVE (Raspberry Pi and DRM only) * Draw a mouse pointer on screen * * #define SUPPORT_BUSY_WAIT_LOOP * Use busy wait loop for timing sync, if not defined, a high-resolution timer is setup and used * * #define SUPPORT_HALFBUSY_WAIT_LOOP * Use a half-busy wait loop, in this case frame sleeps for some time and runs a busy-wait-loop at the end * * #define SUPPORT_EVENTS_WAITING * Wait for events passively (sleeping while no events) instead of polling them actively every frame * * #define SUPPORT_SCREEN_CAPTURE * Allow automatic screen capture of current screen pressing F12, defined in KeyCallback() * * #define SUPPORT_GIF_RECORDING * Allow automatic gif recording of current screen pressing CTRL+F12, defined in KeyCallback() * * #define SUPPORT_COMPRESSION_API * Support CompressData() and DecompressData() functions, those functions use zlib implementation * provided by stb_image and stb_image_write libraries, so, those libraries must be enabled on textures module * for linkage * * #define SUPPORT_DATA_STORAGE * Support saving binary data automatically to a generated storage.data file. This file is managed internally * * * DEPENDENCIES: * rglfw - Manage graphic device, OpenGL context and inputs on PLATFORM_DESKTOP (Windows, Linux, OSX. FreeBSD, OpenBSD, NetBSD, DragonFly) * raymath - 3D math functionality (Vector2, Vector3, Matrix, Quaternion) * camera - Multiple 3D camera modes (free, orbital, 1st person, 3rd person) * gestures - Gestures system for touch-ready devices (or simulated from mouse inputs) * * * LICENSE: zlib/libpng * * Copyright (c) 2013-2021 Ramon Santamaria (@raysan5) * * This software is provided "as-is", without any express or implied warranty. In no event * will the authors be held liable for any damages arising from the use of this software. * * Permission is granted to anyone to use this software for any purpose, including commercial * applications, and to alter it and redistribute it freely, subject to the following restrictions: * * 1. The origin of this software must not be misrepresented; you must not claim that you * wrote the original software. If you use this software in a product, an acknowledgment * in the product documentation would be appreciated but is not required. * * 2. Altered source versions must be plainly marked as such, and must not be misrepresented * as being the original software. * * 3. This notice may not be removed or altered from any source distribution. * **********************************************************************************************/ #include "raylib.h" // Declares module functions // Check if config flags have been externally provided on compilation line #if !defined(EXTERNAL_CONFIG_FLAGS) #include "config.h" // Defines module configuration flags #else #define RAYLIB_VERSION "3.7" #endif #include "utils.h" // Required for: TRACELOG macros #if (defined(__linux__) || defined(PLATFORM_WEB)) && _POSIX_C_SOURCE < 199309L #undef _POSIX_C_SOURCE #define _POSIX_C_SOURCE 199309L // Required for CLOCK_MONOTONIC if compiled with c99 without gnu ext. #endif #define RAYMATH_IMPLEMENTATION // Define external out-of-line implementation of raymath here #include "raymath.h" // Required for: Vector3 and Matrix functions #define RLGL_IMPLEMENTATION #include "rlgl.h" // raylib OpenGL abstraction layer to OpenGL 1.1, 3.3+ or ES2 #if defined(SUPPORT_GESTURES_SYSTEM) #define GESTURES_IMPLEMENTATION #include "gestures.h" // Gestures detection functionality #endif #if defined(SUPPORT_CAMERA_SYSTEM) #define CAMERA_IMPLEMENTATION #include "camera.h" // Camera system functionality #endif #if defined(SUPPORT_GIF_RECORDING) //#define MSF_GIF_MALLOC RL_MALLOC //#define MSF_GIF_FREE RL_FREE #define MSF_GIF_IMPL #include "external/msf_gif.h" // Support GIF recording #endif #if defined(SUPPORT_COMPRESSION_API) #define SINFL_IMPLEMENTATION #include "external/sinfl.h" #define SDEFL_IMPLEMENTATION #include "external/sdefl.h" #endif #include // Required for: srand(), rand(), atexit() #include // Required for: sprintf() [Used in OpenURL()] #include // Required for: strrchr(), strcmp(), strlen() #include // Required for: time() [Used in InitTimer()] #include // Required for: tan() [Used in BeginMode3D()], atan2f() [Used in LoadVrStereoConfig()] #include // Required for: stat() [Used in GetFileModTime()] #if (defined(PLATFORM_DESKTOP) || defined(PLATFORM_UWP)) && defined(_WIN32) && (defined(_MSC_VER) || defined(__TINYC__)) #define DIRENT_MALLOC RL_MALLOC #define DIRENT_FREE RL_FREE #include "external/dirent.h" // Required for: DIR, opendir(), closedir() [Used in GetDirectoryFiles()] #else #include // Required for: DIR, opendir(), closedir() [Used in GetDirectoryFiles()] #endif #if defined(_WIN32) #include // Required for: _getch(), _chdir() #define GETCWD _getcwd // NOTE: MSDN recommends not to use getcwd(), chdir() #define CHDIR _chdir #include // Required for _access() [Used in FileExists()] #else #include // Required for: getch(), chdir() (POSIX), access() #define GETCWD getcwd #define CHDIR chdir #endif #if defined(PLATFORM_DESKTOP) #define GLFW_INCLUDE_NONE // Disable the standard OpenGL header inclusion on GLFW3 // NOTE: Already provided by rlgl implementation (on glad.h) #include "GLFW/glfw3.h" // GLFW3 library: Windows, OpenGL context and Input management // NOTE: GLFW3 already includes gl.h (OpenGL) headers // Support retrieving native window handlers #if defined(_WIN32) #define GLFW_EXPOSE_NATIVE_WIN32 #include "GLFW/glfw3native.h" // WARNING: It requires customization to avoid windows.h inclusion! #if defined(SUPPORT_WINMM_HIGHRES_TIMER) && !defined(SUPPORT_BUSY_WAIT_LOOP) // NOTE: Those functions require linking with winmm library unsigned int __stdcall timeBeginPeriod(unsigned int uPeriod); unsigned int __stdcall timeEndPeriod(unsigned int uPeriod); #endif #endif #if defined(__linux__) || defined(__FreeBSD__) #include // Required for: timespec, nanosleep(), select() - POSIX //#define GLFW_EXPOSE_NATIVE_X11 // WARNING: Exposing Xlib.h > X.h results in dup symbols for Font type //#define GLFW_EXPOSE_NATIVE_WAYLAND //#define GLFW_EXPOSE_NATIVE_MIR #include "GLFW/glfw3native.h" // Required for: glfwGetX11Window() #endif #if defined(__APPLE__) #include // Required for: usleep() //#define GLFW_EXPOSE_NATIVE_COCOA // WARNING: Fails due to type redefinition #include "GLFW/glfw3native.h" // Required for: glfwGetCocoaWindow() #endif #endif #if defined(PLATFORM_ANDROID) //#include // Android sensors functions (accelerometer, gyroscope, light...) #include // Defines AWINDOW_FLAG_FULLSCREEN and others #include // Defines basic app state struct and manages activity #include // EGL library - Native platform display device control functions #include // OpenGL ES 2.0 library #endif #if defined(PLATFORM_RPI) || defined(PLATFORM_DRM) #include // POSIX file control definitions - open(), creat(), fcntl() #include // POSIX standard function definitions - read(), close(), STDIN_FILENO #include // POSIX terminal control definitions - tcgetattr(), tcsetattr() #include // POSIX threads management (inputs reading) #include // POSIX directory browsing #include // UNIX System call for device-specific input/output operations - ioctl() #include // Linux: KDSKBMODE, K_MEDIUMRAM constants definition #include // Linux: Keycodes constants definition (KEY_A, ...) #include // Linux: Joystick support library #if defined(PLATFORM_RPI) #include "bcm_host.h" // Raspberry Pi VideoCore IV access functions #endif #if defined(PLATFORM_DRM) #include // Generic Buffer Management #include // Direct Rendering Manager user-level library interface #include // Direct Rendering Manager modesetting interface #endif #include "EGL/egl.h" // EGL library - Native platform display device control functions #include "EGL/eglext.h" // EGL library - Extensions #include "GLES2/gl2.h" // OpenGL ES 2.0 library #endif #if defined(PLATFORM_UWP) #include "EGL/egl.h" // EGL library - Native platform display device control functions #include "EGL/eglext.h" // EGL library - Extensions #include "GLES2/gl2.h" // OpenGL ES 2.0 library #include "uwp_events.h" // UWP bootstrapping functions #endif #if defined(PLATFORM_WEB) #define GLFW_INCLUDE_ES2 // GLFW3: Enable OpenGL ES 2.0 (translated to WebGL) #include "GLFW/glfw3.h" // GLFW3 library: Windows, OpenGL context and Input management #include // Required for: timespec, nanosleep(), select() - POSIX #include // Emscripten library - LLVM to JavaScript compiler #include // Emscripten HTML5 library #endif #if defined(SUPPORT_COMPRESSION_API) // NOTE: Those declarations require stb_image and stb_image_write definitions, included in textures module unsigned char *stbi_zlib_compress(unsigned char *data, int data_len, int *out_len, int quality); char *stbi_zlib_decode_malloc(char const *buffer, int len, int *outlen); #endif //---------------------------------------------------------------------------------- // Defines and Macros //---------------------------------------------------------------------------------- #if defined(PLATFORM_RPI) || defined(PLATFORM_DRM) #define USE_LAST_TOUCH_DEVICE // When multiple touchscreens are connected, only use the one with the highest event number #define DEFAULT_GAMEPAD_DEV "/dev/input/js" // Gamepad input (base dev for all gamepads: js0, js1, ...) #define DEFAULT_EVDEV_PATH "/dev/input/" // Path to the linux input events #endif #ifndef MAX_FILEPATH_LENGTH #if defined(__linux__) #define MAX_FILEPATH_LENGTH 4096 // Maximum length for filepaths (Linux PATH_MAX default value) #else #define MAX_FILEPATH_LENGTH 512 // Maximum length supported for filepaths #endif #endif #ifndef MAX_GAMEPADS #define MAX_GAMEPADS 4 // Max number of gamepads supported #endif #ifndef MAX_GAMEPAD_AXIS #define MAX_GAMEPAD_AXIS 8 // Max number of axis supported (per gamepad) #endif #ifndef MAX_GAMEPAD_BUTTONS #define MAX_GAMEPAD_BUTTONS 32 // Max bumber of buttons supported (per gamepad) #endif #ifndef MAX_TOUCH_POINTS #define MAX_TOUCH_POINTS 10 // Maximum number of touch points supported #endif #ifndef MAX_KEY_PRESSED_QUEUE #define MAX_KEY_PRESSED_QUEUE 16 // Max number of keys in the key input queue #endif #ifndef MAX_CHAR_PRESSED_QUEUE #define MAX_CHAR_PRESSED_QUEUE 16 // Max number of characters in the char input queue #endif #if defined(SUPPORT_DATA_STORAGE) #ifndef STORAGE_DATA_FILE #define STORAGE_DATA_FILE "storage.data" // Automatic storage filename #endif #endif #ifndef MAX_DECOMPRESSION_SIZE #define MAX_DECOMPRESSION_SIZE 64 // Max size allocated for decompression in MB #endif // Flags operation macros #define FLAG_SET(n, f) ((n) |= (f)) #define FLAG_CLEAR(n, f) ((n) &= ~(f)) #define FLAG_TOGGLE(n, f) ((n) ^= (f)) #define FLAG_CHECK(n, f) ((n) & (f)) //---------------------------------------------------------------------------------- // Types and Structures Definition //---------------------------------------------------------------------------------- #if defined(PLATFORM_RPI) || defined(PLATFORM_DRM) typedef struct { pthread_t threadId; // Event reading thread id int fd; // File descriptor to the device it is assigned to int eventNum; // Number of 'event' device Rectangle absRange; // Range of values for absolute pointing devices (touchscreens) int touchSlot; // Hold the touch slot number of the currently being sent multitouch block bool isMouse; // True if device supports relative X Y movements bool isTouch; // True if device supports absolute X Y movements and has BTN_TOUCH bool isMultitouch; // True if device supports multiple absolute movevents and has BTN_TOUCH bool isKeyboard; // True if device has letter keycodes bool isGamepad; // True if device has gamepad buttons } InputEventWorker; #endif typedef struct { int x; int y; } Point; typedef struct { unsigned int width; unsigned int height; } Size; // Core global state context data typedef struct CoreData { struct { #if defined(PLATFORM_DESKTOP) || defined(PLATFORM_WEB) GLFWwindow *handle; // Native window handle (graphic device) #endif #if defined(PLATFORM_RPI) EGL_DISPMANX_WINDOW_T handle; // Native window handle (graphic device) #endif #if defined(PLATFORM_ANDROID) || defined(PLATFORM_RPI) || defined(PLATFORM_DRM) || defined(PLATFORM_UWP) #if defined(PLATFORM_DRM) int fd; // /dev/dri/... file descriptor drmModeConnector *connector; // Direct Rendering Manager (DRM) mode connector int modeIndex; // index of the used mode of connector->modes drmModeCrtc *crtc; // crt controller struct gbm_device *gbmDevice; // device of Generic Buffer Management (GBM, native platform for EGL on DRM) struct gbm_surface *gbmSurface; // surface of GBM struct gbm_bo *prevBO; // previous used GBM buffer object (during frame swapping) uint32_t prevFB; // previous used GBM framebufer (during frame swapping) #endif EGLDisplay device; // Native display device (physical screen connection) EGLSurface surface; // Surface to draw on, framebuffers (connected to context) EGLContext context; // Graphic context, mode in which drawing can be done EGLConfig config; // Graphic config #endif const char *title; // Window text title const pointer unsigned int flags; // Configuration flags (bit based), keeps window state bool ready; // Check if window has been initialized successfully bool fullscreen; // Check if fullscreen mode is enabled bool shouldClose; // Check if window set for closing bool resizedLastFrame; // Check if window has been resized last frame Point position; // Window position on screen (required on fullscreen toggle) Size display; // Display width and height (monitor, device-screen, LCD, ...) Size screen; // Screen width and height (used render area) Size currentFbo; // Current render width and height, it could change on BeginTextureMode() Size render; // Framebuffer width and height (render area, including black bars if required) Point renderOffset; // Offset from render area (must be divided by 2) Matrix screenScale; // Matrix to scale screen (framebuffer rendering) char **dropFilesPath; // Store dropped files paths as strings int dropFilesCount; // Count dropped files strings } Window; #if defined(PLATFORM_ANDROID) struct { bool appEnabled; // Flag to detect if app is active ** = true struct android_app *app; // Android activity struct android_poll_source *source; // Android events polling source const char *internalDataPath; // Android internal data path to write data (/data/data//files) bool contextRebindRequired; // Used to know context rebind required } Android; #endif #if defined(PLATFORM_UWP) struct { const char *internalDataPath; // UWP App data path } UWP; #endif struct { #if defined(PLATFORM_RPI) || defined(PLATFORM_DRM) InputEventWorker eventWorker[10]; // List of worker threads for every monitored "/dev/input/event" #endif struct { int exitKey; // Default exit key char currentKeyState[512]; // Registers current frame key state char previousKeyState[512]; // Registers previous frame key state int keyPressedQueue[MAX_KEY_PRESSED_QUEUE]; // Input keys queue int keyPressedQueueCount; // Input keys queue count int charPressedQueue[MAX_CHAR_PRESSED_QUEUE]; // Input characters queue int charPressedQueueCount; // Input characters queue count #if defined(PLATFORM_RPI) || defined(PLATFORM_DRM) int defaultMode; // Default keyboard mode struct termios defaultSettings; // Default keyboard settings int fd; // File descriptor for the evdev keyboard #endif } Keyboard; struct { Vector2 position; // Mouse position on screen Vector2 offset; // Mouse offset Vector2 scale; // Mouse scaling int cursor; // Tracks current mouse cursor bool cursorHidden; // Track if cursor is hidden bool cursorOnScreen; // Tracks if cursor is inside client area char currentButtonState[3]; // Registers current mouse button state char previousButtonState[3]; // Registers previous mouse button state float currentWheelMove; // Registers current mouse wheel variation float previousWheelMove; // Registers previous mouse wheel variation #if defined(PLATFORM_RPI) || defined(PLATFORM_DRM) char currentButtonStateEvdev[3]; // Holds the new mouse state for the next polling event to grab (Can't be written directly due to multithreading, app could miss the update) #endif } Mouse; struct { Vector2 position[MAX_TOUCH_POINTS]; // Touch position on screen char currentTouchState[MAX_TOUCH_POINTS]; // Registers current touch state char previousTouchState[MAX_TOUCH_POINTS]; // Registers previous touch state } Touch; struct { int lastButtonPressed; // Register last gamepad button pressed int axisCount; // Register number of available gamepad axis bool ready[MAX_GAMEPADS]; // Flag to know if gamepad is ready float axisState[MAX_GAMEPADS][MAX_GAMEPAD_AXIS]; // Gamepad axis state char currentState[MAX_GAMEPADS][MAX_GAMEPAD_BUTTONS]; // Current gamepad buttons state char previousState[MAX_GAMEPADS][MAX_GAMEPAD_BUTTONS]; // Previous gamepad buttons state #if defined(PLATFORM_RPI) || defined(PLATFORM_DRM) pthread_t threadId; // Gamepad reading thread id int streamId[MAX_GAMEPADS]; // Gamepad device file descriptor char name[64]; // Gamepad name holder #endif } Gamepad; } Input; struct { double current; // Current time measure double previous; // Previous time measure double update; // Time measure for frame update double draw; // Time measure for frame draw double frame; // Time measure for one frame double target; // Desired time for one frame, if 0 not applied #if defined(PLATFORM_ANDROID) || defined(PLATFORM_RPI) || defined(PLATFORM_DRM) || defined(PLATFORM_UWP) unsigned long long base; // Base time measure for hi-res timer #endif } Time; } CoreData; //---------------------------------------------------------------------------------- // Global Variables Definition //---------------------------------------------------------------------------------- static CoreData CORE = { 0 }; // Global CORE state context static char **dirFilesPath = NULL; // Store directory files paths as strings static int dirFilesCount = 0; // Count directory files strings #if defined(SUPPORT_SCREEN_CAPTURE) static int screenshotCounter = 0; // Screenshots counter #endif #if defined(SUPPORT_GIF_RECORDING) static int gifFramesCounter = 0; // GIF frames counter static bool gifRecording = false; // GIF recording state static MsfGifState gifState = { 0 }; // MSGIF context state #endif //----------------------------------------------------------------------------------- //---------------------------------------------------------------------------------- // Other Modules Functions Declaration (required by core) //---------------------------------------------------------------------------------- #if defined(SUPPORT_DEFAULT_FONT) extern void LoadFontDefault(void); // [Module: text] Loads default font on InitWindow() extern void UnloadFontDefault(void); // [Module: text] Unloads default font from GPU memory #endif //---------------------------------------------------------------------------------- // Module specific Functions Declaration //---------------------------------------------------------------------------------- static bool InitGraphicsDevice(int width, int height); // Initialize graphics device static void SetupFramebuffer(int width, int height); // Setup main framebuffer static void SetupViewport(int width, int height); // Set viewport for a provided width and height static void SwapBuffers(void); // Copy back buffer to front buffer static void InitTimer(void); // Initialize timer static void Wait(float ms); // Wait for some milliseconds (stop program execution) static void PollInputEvents(void); // Register user events #if defined(PLATFORM_DESKTOP) || defined(PLATFORM_WEB) static void ErrorCallback(int error, const char *description); // GLFW3 Error Callback, runs on GLFW3 error // Window callbacks events static void WindowSizeCallback(GLFWwindow *window, int width, int height); // GLFW3 WindowSize Callback, runs when window is resized #if !defined(PLATFORM_WEB) static void WindowMaximizeCallback(GLFWwindow* window, int maximized); // GLFW3 Window Maximize Callback, runs when window is maximized #endif static void WindowIconifyCallback(GLFWwindow *window, int iconified); // GLFW3 WindowIconify Callback, runs when window is minimized/restored static void WindowFocusCallback(GLFWwindow *window, int focused); // GLFW3 WindowFocus Callback, runs when window get/lose focus static void WindowDropCallback(GLFWwindow *window, int count, const char **paths); // GLFW3 Window Drop Callback, runs when drop files into window // Input callbacks events static void KeyCallback(GLFWwindow *window, int key, int scancode, int action, int mods); // GLFW3 Keyboard Callback, runs on key pressed static void CharCallback(GLFWwindow *window, unsigned int key); // GLFW3 Char Key Callback, runs on key pressed (get char value) static void MouseButtonCallback(GLFWwindow *window, int button, int action, int mods); // GLFW3 Mouse Button Callback, runs on mouse button pressed static void MouseCursorPosCallback(GLFWwindow *window, double x, double y); // GLFW3 Cursor Position Callback, runs on mouse move static void MouseScrollCallback(GLFWwindow *window, double xoffset, double yoffset); // GLFW3 Srolling Callback, runs on mouse wheel static void CursorEnterCallback(GLFWwindow *window, int enter); // GLFW3 Cursor Enter Callback, cursor enters client area #endif #if defined(PLATFORM_ANDROID) static void AndroidCommandCallback(struct android_app *app, int32_t cmd); // Process Android activity lifecycle commands static int32_t AndroidInputCallback(struct android_app *app, AInputEvent *event); // Process Android inputs #endif #if defined(PLATFORM_WEB) static EM_BOOL EmscriptenTouchCallback(int eventType, const EmscriptenTouchEvent *touchEvent, void *userData); static EM_BOOL EmscriptenGamepadCallback(int eventType, const EmscriptenGamepadEvent *gamepadEvent, void *userData); #endif #if defined(PLATFORM_RPI) || defined(PLATFORM_DRM) #if defined(SUPPORT_SSH_KEYBOARD_RPI) static void InitKeyboard(void); // Init raw keyboard system (standard input reading) static void ProcessKeyboard(void); // Process keyboard events static void RestoreKeyboard(void); // Restore keyboard system #else static void InitTerminal(void); // Init terminal (block echo and signal short cuts) static void RestoreTerminal(void); // Restore terminal #endif static void InitEvdevInput(void); // Evdev inputs initialization static void ConfigureEvdevDevice(char *device); // Identifies a input device and configures it for use if appropriate static void PollKeyboardEvents(void); // Process evdev keyboard events. static void *EventThread(void *arg); // Input device events reading thread static void InitGamepad(void); // Init raw gamepad input static void *GamepadThread(void *arg); // Mouse reading thread #if defined(PLATFORM_DRM) static int FindMatchingConnectorMode(const drmModeConnector *connector, const drmModeModeInfo *mode); // Search matching DRM mode in connector's mode list static int FindExactConnectorMode(const drmModeConnector *connector, uint width, uint height, uint fps, bool allowInterlaced); // Search exactly matching DRM connector mode in connector's list static int FindNearestConnectorMode(const drmModeConnector *connector, uint width, uint height, uint fps, bool allowInterlaced); // Search the nearest matching DRM connector mode in connector's list #endif #endif // PLATFORM_RPI || PLATFORM_DRM #if defined(_WIN32) // NOTE: We include Sleep() function signature here to avoid windows.h inclusion (kernel32 lib) void __stdcall Sleep(unsigned long msTimeout); // Required for Wait() #endif //---------------------------------------------------------------------------------- // Module Functions Definition - Window and OpenGL Context Functions //---------------------------------------------------------------------------------- #if defined(PLATFORM_ANDROID) // To allow easier porting to android, we allow the user to define a // main function which we call from android_main, defined by ourselves extern int main(int argc, char *argv[]); void android_main(struct android_app *app) { char arg0[] = "raylib"; // NOTE: argv[] are mutable CORE.Android.app = app; // TODO: Should we maybe report != 0 return codes somewhere? (void)main(1, (char *[]) { arg0, NULL }); } // TODO: Add this to header (if apps really need it) struct android_app *GetAndroidApp(void) { return CORE.Android.app; } #endif #if (defined(PLATFORM_RPI) || defined(PLATFORM_DRM)) && !defined(SUPPORT_SSH_KEYBOARD_RPI) // Init terminal (block echo and signal short cuts) static void InitTerminal(void) { TRACELOG(LOG_INFO, "RPI: Reconfiguring terminal..."); // Save terminal keyboard settings and reconfigure terminal with new settings struct termios keyboardNewSettings; tcgetattr(STDIN_FILENO, &CORE.Input.Keyboard.defaultSettings); // Get current keyboard settings keyboardNewSettings = CORE.Input.Keyboard.defaultSettings; // New terminal settings for keyboard: turn off buffering (non-canonical mode), echo // NOTE: ISIG controls if ^C and ^Z generate break signals or not keyboardNewSettings.c_lflag &= ~(ICANON | ECHO | ISIG); keyboardNewSettings.c_cc[VMIN] = 1; keyboardNewSettings.c_cc[VTIME] = 0; // Set new keyboard settings (change occurs immediately) tcsetattr(STDIN_FILENO, TCSANOW, &keyboardNewSettings); // Save old keyboard mode to restore it at the end if (ioctl(STDIN_FILENO, KDGKBMODE, &CORE.Input.Keyboard.defaultMode) < 0) { // NOTE: It could mean we are using a remote keyboard through ssh or from the desktop TRACELOG(LOG_WARNING, "RPI: Failed to change keyboard mode (not a local terminal)"); } else ioctl(STDIN_FILENO, KDSKBMODE, K_XLATE); // Register terminal restore when program finishes atexit(RestoreTerminal); } // Restore terminal static void RestoreTerminal(void) { TRACELOG(LOG_INFO, "RPI: Restoring terminal..."); // Reset to default keyboard settings tcsetattr(STDIN_FILENO, TCSANOW, &CORE.Input.Keyboard.defaultSettings); // Reconfigure keyboard to default mode ioctl(STDIN_FILENO, KDSKBMODE, CORE.Input.Keyboard.defaultMode); } #endif // Initialize window and OpenGL context // NOTE: data parameter could be used to pass any kind of required data to the initialization void InitWindow(int width, int height, const char *title) { #if defined(PLATFORM_UWP) if (!UWPIsConfigured()) { TRACELOG(LOG_ERROR, "UWP Functions have not been set yet, please set these before initializing raylib!"); return; } #endif TRACELOG(LOG_INFO, "Initializing raylib %s", RAYLIB_VERSION); if ((title != NULL) && (title[0] != 0)) CORE.Window.title = title; // Initialize required global values different than 0 CORE.Input.Keyboard.exitKey = KEY_ESCAPE; CORE.Input.Mouse.scale = (Vector2){ 1.0f, 1.0f }; CORE.Input.Mouse.cursor = MOUSE_CURSOR_ARROW; CORE.Input.Gamepad.lastButtonPressed = -1; #if defined(PLATFORM_UWP) // The axis count is 6 (2 thumbsticks and left and right trigger) CORE.Input.Gamepad.axisCount = 6; #endif #if defined(PLATFORM_ANDROID) CORE.Window.screen.width = width; CORE.Window.screen.height = height; CORE.Window.currentFbo.width = width; CORE.Window.currentFbo.height = height; // Input data is android app pointer CORE.Android.internalDataPath = CORE.Android.app->activity->internalDataPath; // Set desired windows flags before initializing anything ANativeActivity_setWindowFlags(CORE.Android.app->activity, AWINDOW_FLAG_FULLSCREEN, 0); //AWINDOW_FLAG_SCALED, AWINDOW_FLAG_DITHER int orientation = AConfiguration_getOrientation(CORE.Android.app->config); if (orientation == ACONFIGURATION_ORIENTATION_PORT) TRACELOG(LOG_INFO, "ANDROID: Window orientation set as portrait"); else if (orientation == ACONFIGURATION_ORIENTATION_LAND) TRACELOG(LOG_INFO, "ANDROID: Window orientation set as landscape"); // TODO: Automatic orientation doesn't seem to work if (width <= height) { AConfiguration_setOrientation(CORE.Android.app->config, ACONFIGURATION_ORIENTATION_PORT); TRACELOG(LOG_WARNING, "ANDROID: Window orientation changed to portrait"); } else { AConfiguration_setOrientation(CORE.Android.app->config, ACONFIGURATION_ORIENTATION_LAND); TRACELOG(LOG_WARNING, "ANDROID: Window orientation changed to landscape"); } //AConfiguration_getDensity(CORE.Android.app->config); //AConfiguration_getKeyboard(CORE.Android.app->config); //AConfiguration_getScreenSize(CORE.Android.app->config); //AConfiguration_getScreenLong(CORE.Android.app->config); CORE.Android.app->onAppCmd = AndroidCommandCallback; CORE.Android.app->onInputEvent = AndroidInputCallback; InitAssetManager(CORE.Android.app->activity->assetManager, CORE.Android.app->activity->internalDataPath); TRACELOG(LOG_INFO, "ANDROID: App initialized successfully"); // Android ALooper_pollAll() variables int pollResult = 0; int pollEvents = 0; // Wait for window to be initialized (display and context) while (!CORE.Window.ready) { // Process events loop while ((pollResult = ALooper_pollAll(0, NULL, &pollEvents, (void**)&CORE.Android.source)) >= 0) { // Process this event if (CORE.Android.source != NULL) CORE.Android.source->process(CORE.Android.app, CORE.Android.source); // NOTE: Never close window, native activity is controlled by the system! //if (CORE.Android.app->destroyRequested != 0) CORE.Window.shouldClose = true; } } #endif #if defined(PLATFORM_DESKTOP) || defined(PLATFORM_WEB) || defined(PLATFORM_RPI) || defined(PLATFORM_UWP) || defined(PLATFORM_DRM) // Init graphics device (display device and OpenGL context) // NOTE: returns true if window and graphic device has been initialized successfully CORE.Window.ready = InitGraphicsDevice(width, height); if (!CORE.Window.ready) return; // Init hi-res timer InitTimer(); #if defined(SUPPORT_DEFAULT_FONT) // Load default font // NOTE: External functions (defined in module: text) LoadFontDefault(); Rectangle rec = GetFontDefault().recs[95]; // NOTE: We setup a 1px padding on char rectangle to avoid pixel bleeding on MSAA filtering SetShapesTexture(GetFontDefault().texture, (Rectangle){ rec.x + 1, rec.y + 1, rec.width - 2, rec.height - 2 }); #else // Set default internal texture (1px white) and rectangle to be used for shapes drawing SetShapesTexture(rlGetTextureDefault(), (Rectangle){ 0.0f, 0.0f, 1.0f, 1.0f }); #endif #if defined(PLATFORM_DESKTOP) if ((CORE.Window.flags & FLAG_WINDOW_HIGHDPI) > 0) { // Set default font texture filter for HighDPI (blurry) SetTextureFilter(GetFontDefault().texture, TEXTURE_FILTER_BILINEAR); } #endif #if defined(PLATFORM_RPI) || defined(PLATFORM_DRM) // Init raw input system InitEvdevInput(); // Evdev inputs initialization InitGamepad(); // Gamepad init #if defined(SUPPORT_SSH_KEYBOARD_RPI) InitKeyboard(); // Keyboard init #else InitTerminal(); // Terminal init #endif #endif #if defined(PLATFORM_WEB) // Detect fullscreen change events //emscripten_set_fullscreenchange_callback("#canvas", NULL, 1, EmscriptenFullscreenChangeCallback); //emscripten_set_resize_callback("#canvas", NULL, 1, EmscriptenResizeCallback); // Support keyboard events //emscripten_set_keypress_callback("#canvas", NULL, 1, EmscriptenKeyboardCallback); //emscripten_set_keydown_callback("#canvas", NULL, 1, EmscriptenKeyboardCallback); // Support touch events emscripten_set_touchstart_callback("#canvas", NULL, 1, EmscriptenTouchCallback); emscripten_set_touchend_callback("#canvas", NULL, 1, EmscriptenTouchCallback); emscripten_set_touchmove_callback("#canvas", NULL, 1, EmscriptenTouchCallback); emscripten_set_touchcancel_callback("#canvas", NULL, 1, EmscriptenTouchCallback); // Support gamepad events (not provided by GLFW3 on emscripten) emscripten_set_gamepadconnected_callback(NULL, 1, EmscriptenGamepadCallback); emscripten_set_gamepaddisconnected_callback(NULL, 1, EmscriptenGamepadCallback); #endif CORE.Input.Mouse.position.x = (float)CORE.Window.screen.width/2.0f; CORE.Input.Mouse.position.y = (float)CORE.Window.screen.height/2.0f; #endif // PLATFORM_ANDROID } // Close window and unload OpenGL context void CloseWindow(void) { #if defined(SUPPORT_GIF_RECORDING) if (gifRecording) { MsfGifResult result = msf_gif_end(&gifState); msf_gif_free(result); gifRecording = false; } #endif #if defined(SUPPORT_DEFAULT_FONT) UnloadFontDefault(); #endif rlglClose(); // De-init rlgl #if defined(PLATFORM_DESKTOP) || defined(PLATFORM_WEB) glfwDestroyWindow(CORE.Window.handle); glfwTerminate(); #endif #if defined(_WIN32) && defined(SUPPORT_WINMM_HIGHRES_TIMER) && !defined(SUPPORT_BUSY_WAIT_LOOP) && !defined(PLATFORM_UWP) timeEndPeriod(1); // Restore time period #endif #if defined(PLATFORM_ANDROID) || defined(PLATFORM_RPI) || defined(PLATFORM_DRM) || defined(PLATFORM_UWP) #if defined(PLATFORM_DRM) if (CORE.Window.prevFB) { drmModeRmFB(CORE.Window.fd, CORE.Window.prevFB); CORE.Window.prevFB = 0; } if (CORE.Window.prevBO) { gbm_surface_release_buffer(CORE.Window.gbmSurface, CORE.Window.prevBO); CORE.Window.prevBO = NULL; } if (CORE.Window.gbmSurface) { gbm_surface_destroy(CORE.Window.gbmSurface); CORE.Window.gbmSurface = NULL; } if (CORE.Window.gbmDevice) { gbm_device_destroy(CORE.Window.gbmDevice); CORE.Window.gbmDevice = NULL; } if (CORE.Window.crtc) { if (CORE.Window.connector) { drmModeSetCrtc(CORE.Window.fd, CORE.Window.crtc->crtc_id, CORE.Window.crtc->buffer_id, CORE.Window.crtc->x, CORE.Window.crtc->y, &CORE.Window.connector->connector_id, 1, &CORE.Window.crtc->mode); drmModeFreeConnector(CORE.Window.connector); CORE.Window.connector = NULL; } drmModeFreeCrtc(CORE.Window.crtc); CORE.Window.crtc = NULL; } if (CORE.Window.fd != -1) { close(CORE.Window.fd); CORE.Window.fd = -1; } #endif // Close surface, context and display if (CORE.Window.device != EGL_NO_DISPLAY) { #if !defined(PLATFORM_DRM) eglMakeCurrent(CORE.Window.device, EGL_NO_SURFACE, EGL_NO_SURFACE, EGL_NO_CONTEXT); #endif if (CORE.Window.surface != EGL_NO_SURFACE) { eglDestroySurface(CORE.Window.device, CORE.Window.surface); CORE.Window.surface = EGL_NO_SURFACE; } if (CORE.Window.context != EGL_NO_CONTEXT) { eglDestroyContext(CORE.Window.device, CORE.Window.context); CORE.Window.context = EGL_NO_CONTEXT; } eglTerminate(CORE.Window.device); CORE.Window.device = EGL_NO_DISPLAY; } #endif #if defined(PLATFORM_RPI) || defined(PLATFORM_DRM) // Wait for mouse and gamepad threads to finish before closing // NOTE: Those threads should already have finished at this point // because they are controlled by CORE.Window.shouldClose variable CORE.Window.shouldClose = true; // Added to force threads to exit when the close window is called // Close the evdev keyboard if (CORE.Input.Keyboard.fd != -1) { close(CORE.Input.Keyboard.fd); CORE.Input.Keyboard.fd = -1; } for (int i = 0; i < sizeof(CORE.Input.eventWorker)/sizeof(InputEventWorker); ++i) { if (CORE.Input.eventWorker[i].threadId) { pthread_join(CORE.Input.eventWorker[i].threadId, NULL); } } if (CORE.Input.Gamepad.threadId) pthread_join(CORE.Input.Gamepad.threadId, NULL); #endif TRACELOG(LOG_INFO, "Window closed successfully"); } // Check if KEY_ESCAPE pressed or Close icon pressed bool WindowShouldClose(void) { #if defined(PLATFORM_WEB) // Emterpreter-Async required to run sync code // https://github.com/emscripten-core/emscripten/wiki/Emterpreter#emterpreter-async-run-synchronous-code // By default, this function is never called on a web-ready raylib example because we encapsulate // frame code in a UpdateDrawFrame() function, to allow browser manage execution asynchronously // but now emscripten allows sync code to be executed in an interpreted way, using emterpreter! emscripten_sleep(16); return false; #endif #if defined(PLATFORM_DESKTOP) if (CORE.Window.ready) { // While window minimized, stop loop execution while (IsWindowState(FLAG_WINDOW_MINIMIZED) && !IsWindowState(FLAG_WINDOW_ALWAYS_RUN)) glfwWaitEvents(); CORE.Window.shouldClose = glfwWindowShouldClose(CORE.Window.handle); // Reset close status for next frame glfwSetWindowShouldClose(CORE.Window.handle, GLFW_FALSE); return CORE.Window.shouldClose; } else return true; #endif #if defined(PLATFORM_ANDROID) || defined(PLATFORM_RPI) || defined(PLATFORM_DRM) || defined(PLATFORM_UWP) if (CORE.Window.ready) return CORE.Window.shouldClose; else return true; #endif } // Check if window has been initialized successfully bool IsWindowReady(void) { return CORE.Window.ready; } // Check if window is currently fullscreen bool IsWindowFullscreen(void) { return CORE.Window.fullscreen; } // Check if window is currently hidden bool IsWindowHidden(void) { #if defined(PLATFORM_DESKTOP) return ((CORE.Window.flags & FLAG_WINDOW_HIDDEN) > 0); #endif return false; } // Check if window has been minimized bool IsWindowMinimized(void) { #if defined(PLATFORM_DESKTOP) || defined(PLATFORM_WEB) || defined(PLATFORM_UWP) return ((CORE.Window.flags & FLAG_WINDOW_MINIMIZED) > 0); #else return false; #endif } // Check if window has been maximized (only PLATFORM_DESKTOP) bool IsWindowMaximized(void) { #if defined(PLATFORM_DESKTOP) return ((CORE.Window.flags & FLAG_WINDOW_MAXIMIZED) > 0); #else return false; #endif } // Check if window has the focus bool IsWindowFocused(void) { #if defined(PLATFORM_DESKTOP) || defined(PLATFORM_WEB) || defined(PLATFORM_UWP) return ((CORE.Window.flags & FLAG_WINDOW_UNFOCUSED) == 0); // TODO! #else return true; #endif } // Check if window has been resizedLastFrame bool IsWindowResized(void) { #if defined(PLATFORM_DESKTOP) || defined(PLATFORM_WEB) || defined(PLATFORM_UWP) return CORE.Window.resizedLastFrame; #else return false; #endif } // Check if one specific window flag is enabled bool IsWindowState(unsigned int flag) { return ((CORE.Window.flags & flag) > 0); } // Toggle fullscreen mode (only PLATFORM_DESKTOP) void ToggleFullscreen(void) { #if defined(PLATFORM_DESKTOP) // NOTE: glfwSetWindowMonitor() doesn't work properly (bugs) if (!CORE.Window.fullscreen) { // Store previous window position (in case we exit fullscreen) glfwGetWindowPos(CORE.Window.handle, &CORE.Window.position.x, &CORE.Window.position.y); int monitorCount = 0; GLFWmonitor** monitors = glfwGetMonitors(&monitorCount); int monitorIndex = GetCurrentMonitor(); // Use current monitor, so we correctly get the display the window is on GLFWmonitor* monitor = monitorIndex < monitorCount ? monitors[monitorIndex] : NULL; if (!monitor) { TRACELOG(LOG_WARNING, "GLFW: Failed to get monitor"); CORE.Window.fullscreen = false; // Toggle fullscreen flag CORE.Window.flags &= ~FLAG_FULLSCREEN_MODE; glfwSetWindowMonitor(CORE.Window.handle, NULL, 0, 0, CORE.Window.screen.width, CORE.Window.screen.height, GLFW_DONT_CARE); return; } CORE.Window.fullscreen = true; // Toggle fullscreen flag CORE.Window.flags |= FLAG_FULLSCREEN_MODE; glfwSetWindowMonitor(CORE.Window.handle, monitor, 0, 0, CORE.Window.screen.width, CORE.Window.screen.height, GLFW_DONT_CARE); } else { CORE.Window.fullscreen = false; // Toggle fullscreen flag CORE.Window.flags &= ~FLAG_FULLSCREEN_MODE; glfwSetWindowMonitor(CORE.Window.handle, NULL, CORE.Window.position.x, CORE.Window.position.y, CORE.Window.screen.width, CORE.Window.screen.height, GLFW_DONT_CARE); } // Try to enable GPU V-Sync, so frames are limited to screen refresh rate (60Hz -> 60 FPS) // NOTE: V-Sync can be enabled by graphic driver configuration if (CORE.Window.flags & FLAG_VSYNC_HINT) glfwSwapInterval(1); #endif #if defined(PLATFORM_WEB) EM_ASM ( // This strategy works well while using raylib minimal web shell for emscripten, // it re-scales the canvas to fullscreen using monitor resolution, for tools this // is a good strategy but maybe games prefer to keep current canvas resolution and // display it in fullscreen, adjusting monitor resolution if possible if (document.fullscreenElement) document.exitFullscreen(); else Module.requestFullscreen(false, true); ); /* if (!CORE.Window.fullscreen) { // Option 1: Request fullscreen for the canvas element // This option does not seem to work at all //emscripten_request_fullscreen("#canvas", false); // Option 2: Request fullscreen for the canvas element with strategy // This option does not seem to work at all // Ref: https://github.com/emscripten-core/emscripten/issues/5124 // EmscriptenFullscreenStrategy strategy = { // .scaleMode = EMSCRIPTEN_FULLSCREEN_SCALE_STRETCH, //EMSCRIPTEN_FULLSCREEN_SCALE_ASPECT, // .canvasResolutionScaleMode = EMSCRIPTEN_FULLSCREEN_CANVAS_SCALE_STDDEF, // .filteringMode = EMSCRIPTEN_FULLSCREEN_FILTERING_DEFAULT, // .canvasResizedCallback = EmscriptenWindowResizedCallback, // .canvasResizedCallbackUserData = NULL // }; //emscripten_request_fullscreen_strategy("#canvas", EM_FALSE, &strategy); // Option 3: Request fullscreen for the canvas element with strategy // It works as expected but only inside the browser (client area) EmscriptenFullscreenStrategy strategy = { .scaleMode = EMSCRIPTEN_FULLSCREEN_SCALE_ASPECT, .canvasResolutionScaleMode = EMSCRIPTEN_FULLSCREEN_CANVAS_SCALE_STDDEF, .filteringMode = EMSCRIPTEN_FULLSCREEN_FILTERING_DEFAULT, .canvasResizedCallback = EmscriptenWindowResizedCallback, .canvasResizedCallbackUserData = NULL }; emscripten_enter_soft_fullscreen("#canvas", &strategy); int width, height; emscripten_get_canvas_element_size("#canvas", &width, &height); TRACELOG(LOG_WARNING, "Emscripten: Enter fullscreen: Canvas size: %i x %i", width, height); } else { //emscripten_exit_fullscreen(); emscripten_exit_soft_fullscreen(); int width, height; emscripten_get_canvas_element_size("#canvas", &width, &height); TRACELOG(LOG_WARNING, "Emscripten: Exit fullscreen: Canvas size: %i x %i", width, height); } */ CORE.Window.fullscreen = !CORE.Window.fullscreen; // Toggle fullscreen flag CORE.Window.flags ^= FLAG_FULLSCREEN_MODE; #endif #if defined(PLATFORM_ANDROID) || defined(PLATFORM_RPI) || defined(PLATFORM_DRM) TRACELOG(LOG_WARNING, "SYSTEM: Failed to toggle to windowed mode"); #endif } // Set window state: maximized, if resizable (only PLATFORM_DESKTOP) void MaximizeWindow(void) { #if defined(PLATFORM_DESKTOP) if (glfwGetWindowAttrib(CORE.Window.handle, GLFW_RESIZABLE) == GLFW_TRUE) { glfwMaximizeWindow(CORE.Window.handle); CORE.Window.flags |= FLAG_WINDOW_MAXIMIZED; } #endif } // Set window state: minimized (only PLATFORM_DESKTOP) void MinimizeWindow(void) { #if defined(PLATFORM_DESKTOP) // NOTE: Following function launches callback that sets appropiate flag! glfwIconifyWindow(CORE.Window.handle); #endif } // Set window state: not minimized/maximized (only PLATFORM_DESKTOP) void RestoreWindow(void) { #if defined(PLATFORM_DESKTOP) if (glfwGetWindowAttrib(CORE.Window.handle, GLFW_RESIZABLE) == GLFW_TRUE) { // Restores the specified window if it was previously iconified (minimized) or maximized glfwRestoreWindow(CORE.Window.handle); CORE.Window.flags &= ~FLAG_WINDOW_MINIMIZED; CORE.Window.flags &= ~FLAG_WINDOW_MAXIMIZED; } #endif } // Set window configuration state using flags void SetWindowState(unsigned int flags) { #if defined(PLATFORM_DESKTOP) // Check previous state and requested state to apply required changes // NOTE: In most cases the functions already change the flags internally // State change: FLAG_VSYNC_HINT if (((CORE.Window.flags & FLAG_VSYNC_HINT) != (flags & FLAG_VSYNC_HINT)) && ((flags & FLAG_VSYNC_HINT) > 0)) { glfwSwapInterval(1); CORE.Window.flags |= FLAG_VSYNC_HINT; } // State change: FLAG_FULLSCREEN_MODE if ((CORE.Window.flags & FLAG_FULLSCREEN_MODE) != (flags & FLAG_FULLSCREEN_MODE)) { ToggleFullscreen(); // NOTE: Window state flag updated inside function } // State change: FLAG_WINDOW_RESIZABLE if (((CORE.Window.flags & FLAG_WINDOW_RESIZABLE) != (flags & FLAG_WINDOW_RESIZABLE)) && ((flags & FLAG_WINDOW_RESIZABLE) > 0)) { glfwSetWindowAttrib(CORE.Window.handle, GLFW_RESIZABLE, GLFW_TRUE); CORE.Window.flags |= FLAG_WINDOW_RESIZABLE; } // State change: FLAG_WINDOW_UNDECORATED if (((CORE.Window.flags & FLAG_WINDOW_UNDECORATED) != (flags & FLAG_WINDOW_UNDECORATED)) && (flags & FLAG_WINDOW_UNDECORATED)) { glfwSetWindowAttrib(CORE.Window.handle, GLFW_DECORATED, GLFW_FALSE); CORE.Window.flags |= FLAG_WINDOW_UNDECORATED; } // State change: FLAG_WINDOW_HIDDEN if (((CORE.Window.flags & FLAG_WINDOW_HIDDEN) != (flags & FLAG_WINDOW_HIDDEN)) && ((flags & FLAG_WINDOW_HIDDEN) > 0)) { glfwHideWindow(CORE.Window.handle); CORE.Window.flags |= FLAG_WINDOW_HIDDEN; } // State change: FLAG_WINDOW_MINIMIZED if (((CORE.Window.flags & FLAG_WINDOW_MINIMIZED) != (flags & FLAG_WINDOW_MINIMIZED)) && ((flags & FLAG_WINDOW_MINIMIZED) > 0)) { //GLFW_ICONIFIED MinimizeWindow(); // NOTE: Window state flag updated inside function } // State change: FLAG_WINDOW_MAXIMIZED if (((CORE.Window.flags & FLAG_WINDOW_MAXIMIZED) != (flags & FLAG_WINDOW_MAXIMIZED)) && ((flags & FLAG_WINDOW_MAXIMIZED) > 0)) { //GLFW_MAXIMIZED MaximizeWindow(); // NOTE: Window state flag updated inside function } // State change: FLAG_WINDOW_UNFOCUSED if (((CORE.Window.flags & FLAG_WINDOW_UNFOCUSED) != (flags & FLAG_WINDOW_UNFOCUSED)) && ((flags & FLAG_WINDOW_UNFOCUSED) > 0)) { glfwSetWindowAttrib(CORE.Window.handle, GLFW_FOCUS_ON_SHOW, GLFW_FALSE); CORE.Window.flags |= FLAG_WINDOW_UNFOCUSED; } // State change: FLAG_WINDOW_TOPMOST if (((CORE.Window.flags & FLAG_WINDOW_TOPMOST) != (flags & FLAG_WINDOW_TOPMOST)) && ((flags & FLAG_WINDOW_TOPMOST) > 0)) { glfwSetWindowAttrib(CORE.Window.handle, GLFW_FLOATING, GLFW_TRUE); CORE.Window.flags |= FLAG_WINDOW_TOPMOST; } // State change: FLAG_WINDOW_ALWAYS_RUN if (((CORE.Window.flags & FLAG_WINDOW_ALWAYS_RUN) != (flags & FLAG_WINDOW_ALWAYS_RUN)) && ((flags & FLAG_WINDOW_ALWAYS_RUN) > 0)) { CORE.Window.flags |= FLAG_WINDOW_ALWAYS_RUN; } // The following states can not be changed after window creation // State change: FLAG_WINDOW_TRANSPARENT if (((CORE.Window.flags & FLAG_WINDOW_TRANSPARENT) != (flags & FLAG_WINDOW_TRANSPARENT)) && ((flags & FLAG_WINDOW_TRANSPARENT) > 0)) { TRACELOG(LOG_WARNING, "WINDOW: Framebuffer transparency can only by configured before window initialization"); } // State change: FLAG_WINDOW_HIGHDPI if (((CORE.Window.flags & FLAG_WINDOW_HIGHDPI) != (flags & FLAG_WINDOW_HIGHDPI)) && ((flags & FLAG_WINDOW_HIGHDPI) > 0)) { TRACELOG(LOG_WARNING, "WINDOW: High DPI can only by configured before window initialization"); } // State change: FLAG_MSAA_4X_HINT if (((CORE.Window.flags & FLAG_MSAA_4X_HINT) != (flags & FLAG_MSAA_4X_HINT)) && ((flags & FLAG_MSAA_4X_HINT) > 0)) { TRACELOG(LOG_WARNING, "WINDOW: MSAA can only by configured before window initialization"); } // State change: FLAG_INTERLACED_HINT if (((CORE.Window.flags & FLAG_INTERLACED_HINT) != (flags & FLAG_INTERLACED_HINT)) && ((flags & FLAG_INTERLACED_HINT) > 0)) { TRACELOG(LOG_WARNING, "RPI: Interlaced mode can only by configured before window initialization"); } #endif } // Clear window configuration state flags void ClearWindowState(unsigned int flags) { #if defined(PLATFORM_DESKTOP) // Check previous state and requested state to apply required changes // NOTE: In most cases the functions already change the flags internally // State change: FLAG_VSYNC_HINT if (((CORE.Window.flags & FLAG_VSYNC_HINT) > 0) && ((flags & FLAG_VSYNC_HINT) > 0)) { glfwSwapInterval(0); CORE.Window.flags &= ~FLAG_VSYNC_HINT; } // State change: FLAG_FULLSCREEN_MODE if (((CORE.Window.flags & FLAG_FULLSCREEN_MODE) > 0) && ((flags & FLAG_FULLSCREEN_MODE) > 0)) { ToggleFullscreen(); // NOTE: Window state flag updated inside function } // State change: FLAG_WINDOW_RESIZABLE if (((CORE.Window.flags & FLAG_WINDOW_RESIZABLE) > 0) && ((flags & FLAG_WINDOW_RESIZABLE) > 0)) { glfwSetWindowAttrib(CORE.Window.handle, GLFW_RESIZABLE, GLFW_FALSE); CORE.Window.flags &= ~FLAG_WINDOW_RESIZABLE; } // State change: FLAG_WINDOW_UNDECORATED if (((CORE.Window.flags & FLAG_WINDOW_UNDECORATED) > 0) && ((flags & FLAG_WINDOW_UNDECORATED) > 0)) { glfwSetWindowAttrib(CORE.Window.handle, GLFW_DECORATED, GLFW_TRUE); CORE.Window.flags &= ~FLAG_WINDOW_UNDECORATED; } // State change: FLAG_WINDOW_HIDDEN if (((CORE.Window.flags & FLAG_WINDOW_HIDDEN) > 0) && ((flags & FLAG_WINDOW_HIDDEN) > 0)) { glfwShowWindow(CORE.Window.handle); CORE.Window.flags &= ~FLAG_WINDOW_HIDDEN; } // State change: FLAG_WINDOW_MINIMIZED if (((CORE.Window.flags & FLAG_WINDOW_MINIMIZED) > 0) && ((flags & FLAG_WINDOW_MINIMIZED) > 0)) { RestoreWindow(); // NOTE: Window state flag updated inside function } // State change: FLAG_WINDOW_MAXIMIZED if (((CORE.Window.flags & FLAG_WINDOW_MAXIMIZED) > 0) && ((flags & FLAG_WINDOW_MAXIMIZED) > 0)) { RestoreWindow(); // NOTE: Window state flag updated inside function } // State change: FLAG_WINDOW_UNFOCUSED if (((CORE.Window.flags & FLAG_WINDOW_UNFOCUSED) > 0) && ((flags & FLAG_WINDOW_UNFOCUSED) > 0)) { glfwSetWindowAttrib(CORE.Window.handle, GLFW_FOCUS_ON_SHOW, GLFW_TRUE); CORE.Window.flags &= ~FLAG_WINDOW_UNFOCUSED; } // State change: FLAG_WINDOW_TOPMOST if (((CORE.Window.flags & FLAG_WINDOW_TOPMOST) > 0) && ((flags & FLAG_WINDOW_TOPMOST) > 0)) { glfwSetWindowAttrib(CORE.Window.handle, GLFW_FLOATING, GLFW_FALSE); CORE.Window.flags &= ~FLAG_WINDOW_TOPMOST; } // State change: FLAG_WINDOW_ALWAYS_RUN if (((CORE.Window.flags & FLAG_WINDOW_ALWAYS_RUN) > 0) && ((flags & FLAG_WINDOW_ALWAYS_RUN) > 0)) { CORE.Window.flags &= ~FLAG_WINDOW_ALWAYS_RUN; } // The following states can not be changed after window creation // State change: FLAG_WINDOW_TRANSPARENT if (((CORE.Window.flags & FLAG_WINDOW_TRANSPARENT) > 0) && ((flags & FLAG_WINDOW_TRANSPARENT) > 0)) { TRACELOG(LOG_WARNING, "WINDOW: Framebuffer transparency can only by configured before window initialization"); } // State change: FLAG_WINDOW_HIGHDPI if (((CORE.Window.flags & FLAG_WINDOW_HIGHDPI) > 0) && ((flags & FLAG_WINDOW_HIGHDPI) > 0)) { TRACELOG(LOG_WARNING, "WINDOW: High DPI can only by configured before window initialization"); } // State change: FLAG_MSAA_4X_HINT if (((CORE.Window.flags & FLAG_MSAA_4X_HINT) > 0) && ((flags & FLAG_MSAA_4X_HINT) > 0)) { TRACELOG(LOG_WARNING, "WINDOW: MSAA can only by configured before window initialization"); } // State change: FLAG_INTERLACED_HINT if (((CORE.Window.flags & FLAG_INTERLACED_HINT) > 0) && ((flags & FLAG_INTERLACED_HINT) > 0)) { TRACELOG(LOG_WARNING, "RPI: Interlaced mode can only by configured before window initialization"); } #endif } // Set icon for window (only PLATFORM_DESKTOP) // NOTE: Image must be in RGBA format, 8bit per channel void SetWindowIcon(Image image) { #if defined(PLATFORM_DESKTOP) if (image.format == PIXELFORMAT_UNCOMPRESSED_R8G8B8A8) { GLFWimage icon[1] = { 0 }; icon[0].width = image.width; icon[0].height = image.height; icon[0].pixels = (unsigned char *)image.data; // NOTE 1: We only support one image icon // NOTE 2: The specified image data is copied before this function returns glfwSetWindowIcon(CORE.Window.handle, 1, icon); } else TRACELOG(LOG_WARNING, "GLFW: Window icon image must be in R8G8B8A8 pixel format"); #endif } // Set title for window (only PLATFORM_DESKTOP) void SetWindowTitle(const char *title) { CORE.Window.title = title; #if defined(PLATFORM_DESKTOP) glfwSetWindowTitle(CORE.Window.handle, title); #endif } // Set window position on screen (windowed mode) void SetWindowPosition(int x, int y) { #if defined(PLATFORM_DESKTOP) glfwSetWindowPos(CORE.Window.handle, x, y); #endif } // Set monitor for the current window (fullscreen mode) void SetWindowMonitor(int monitor) { #if defined(PLATFORM_DESKTOP) int monitorCount = 0; GLFWmonitor **monitors = glfwGetMonitors(&monitorCount); if ((monitor >= 0) && (monitor < monitorCount)) { TRACELOG(LOG_INFO, "GLFW: Selected fullscreen monitor: [%i] %s", monitor, glfwGetMonitorName(monitors[monitor])); const GLFWvidmode *mode = glfwGetVideoMode(monitors[monitor]); glfwSetWindowMonitor(CORE.Window.handle, monitors[monitor], 0, 0, mode->width, mode->height, mode->refreshRate); } else TRACELOG(LOG_WARNING, "GLFW: Failed to find selected monitor"); #endif } // Set window minimum dimensions (FLAG_WINDOW_RESIZABLE) void SetWindowMinSize(int width, int height) { #if defined(PLATFORM_DESKTOP) const GLFWvidmode *mode = glfwGetVideoMode(glfwGetPrimaryMonitor()); glfwSetWindowSizeLimits(CORE.Window.handle, width, height, mode->width, mode->height); #endif } // Set window dimensions // TODO: Issues on HighDPI scaling void SetWindowSize(int width, int height) { #if defined(PLATFORM_DESKTOP) glfwSetWindowSize(CORE.Window.handle, width, height); #endif #if defined(PLATFORM_WEB) //emscripten_set_canvas_size(width, height); // DEPRECATED! // TODO: Below functions should be used to replace previous one but // they do not seem to work properly //emscripten_set_canvas_element_size("canvas", width, height); //emscripten_set_element_css_size("canvas", width, height); #endif } // Get current screen width int GetScreenWidth(void) { return CORE.Window.currentFbo.width; } // Get current screen height int GetScreenHeight(void) { return CORE.Window.currentFbo.height; } // Get native window handle void *GetWindowHandle(void) { #if defined(PLATFORM_DESKTOP) && defined(_WIN32) // NOTE: Returned handle is: void *HWND (windows.h) return glfwGetWin32Window(CORE.Window.handle); #endif #if defined(__linux__) // NOTE: Returned handle is: unsigned long Window (X.h) // typedef unsigned long XID; // typedef XID Window; //unsigned long id = (unsigned long)glfwGetX11Window(window); return NULL; // TODO: Find a way to return value... cast to void *? #endif #if defined(__APPLE__) // NOTE: Returned handle is: (objc_object *) return NULL; // TODO: return (void *)glfwGetCocoaWindow(window); #endif return NULL; } // Get number of monitors int GetMonitorCount(void) { #if defined(PLATFORM_DESKTOP) int monitorCount; glfwGetMonitors(&monitorCount); return monitorCount; #else return 1; #endif } // Get number of monitors int GetCurrentMonitor(void) { #if defined(PLATFORM_DESKTOP) int monitorCount; GLFWmonitor** monitors = glfwGetMonitors(&monitorCount); GLFWmonitor* monitor = NULL; if (monitorCount == 1) // easy out return 0; if (IsWindowFullscreen()) { monitor = glfwGetWindowMonitor(CORE.Window.handle); for (int i = 0; i < monitorCount; i++) { if (monitors[i] == monitor) return i; } return 0; } else { int x = 0; int y = 0; glfwGetWindowPos(CORE.Window.handle, &x, &y); for (int i = 0; i < monitorCount; i++) { int mx = 0; int my = 0; int width = 0; int height = 0; monitor = monitors[i]; glfwGetMonitorWorkarea(monitor, &mx, &my, &width, &height); if (x >= mx && x <= (mx + width) && y >= my && y <= (my + height)) return i; } } return 0; #else return 0; #endif } // Get selected monitor width Vector2 GetMonitorPosition(int monitor) { #if defined(PLATFORM_DESKTOP) int monitorCount; GLFWmonitor** monitors = glfwGetMonitors(&monitorCount); if ((monitor >= 0) && (monitor < monitorCount)) { int x, y; glfwGetMonitorPos(monitors[monitor], &x, &y); return (Vector2){ (float)x, (float)y }; } else TRACELOG(LOG_WARNING, "GLFW: Failed to find selected monitor"); #endif return (Vector2){ 0, 0 }; } // Get selected monitor width (max available by monitor) int GetMonitorWidth(int monitor) { #if defined(PLATFORM_DESKTOP) int monitorCount; GLFWmonitor **monitors = glfwGetMonitors(&monitorCount); if ((monitor >= 0) && (monitor < monitorCount)) { int count = 0; const GLFWvidmode *modes = glfwGetVideoModes(monitors[monitor], &count); // We return the maximum resolution available, the last one in the modes array if (count > 0) return modes[count - 1].width; else TRACELOG(LOG_WARNING, "GLFW: Failed to find video mode for selected monitor"); } else TRACELOG(LOG_WARNING, "GLFW: Failed to find selected monitor"); #endif return 0; } // Get selected monitor width (max available by monitor) int GetMonitorHeight(int monitor) { #if defined(PLATFORM_DESKTOP) int monitorCount; GLFWmonitor **monitors = glfwGetMonitors(&monitorCount); if ((monitor >= 0) && (monitor < monitorCount)) { int count = 0; const GLFWvidmode *modes = glfwGetVideoModes(monitors[monitor], &count); // We return the maximum resolution available, the last one in the modes array if (count > 0) return modes[count - 1].height; else TRACELOG(LOG_WARNING, "GLFW: Failed to find video mode for selected monitor"); } else TRACELOG(LOG_WARNING, "GLFW: Failed to find selected monitor"); #endif return 0; } // Get selected monitor physical width in millimetres int GetMonitorPhysicalWidth(int monitor) { #if defined(PLATFORM_DESKTOP) int monitorCount; GLFWmonitor **monitors = glfwGetMonitors(&monitorCount); if ((monitor >= 0) && (monitor < monitorCount)) { int physicalWidth; glfwGetMonitorPhysicalSize(monitors[monitor], &physicalWidth, NULL); return physicalWidth; } else TRACELOG(LOG_WARNING, "GLFW: Failed to find selected monitor"); #endif return 0; } // Get primary monitor physical height in millimetres int GetMonitorPhysicalHeight(int monitor) { #if defined(PLATFORM_DESKTOP) int monitorCount; GLFWmonitor **monitors = glfwGetMonitors(&monitorCount); if ((monitor >= 0) && (monitor < monitorCount)) { int physicalHeight; glfwGetMonitorPhysicalSize(monitors[monitor], NULL, &physicalHeight); return physicalHeight; } else TRACELOG(LOG_WARNING, "GLFW: Failed to find selected monitor"); #endif return 0; } int GetMonitorRefreshRate(int monitor) { #if defined(PLATFORM_DESKTOP) int monitorCount; GLFWmonitor **monitors = glfwGetMonitors(&monitorCount); if ((monitor >= 0) && (monitor < monitorCount)) { const GLFWvidmode *vidmode = glfwGetVideoMode(monitors[monitor]); return vidmode->refreshRate; } else TRACELOG(LOG_WARNING, "GLFW: Failed to find selected monitor"); #endif #if defined(PLATFORM_DRM) if ((CORE.Window.connector) && (CORE.Window.modeIndex >= 0)) { return CORE.Window.connector->modes[CORE.Window.modeIndex].vrefresh; } #endif return 0; } // Get window position XY on monitor Vector2 GetWindowPosition(void) { int x = 0; int y = 0; #if defined(PLATFORM_DESKTOP) glfwGetWindowPos(CORE.Window.handle, &x, &y); #endif return (Vector2){ (float)x, (float)y }; } // Get window scale DPI factor Vector2 GetWindowScaleDPI(void) { Vector2 scale = { 1.0f, 1.0f }; #if defined(PLATFORM_DESKTOP) float xdpi = 1.0; float ydpi = 1.0; Vector2 windowPos = GetWindowPosition(); int monitorCount = 0; GLFWmonitor **monitors = glfwGetMonitors(&monitorCount); // Check window monitor for (int i = 0; i < monitorCount; i++) { glfwGetMonitorContentScale(monitors[i], &xdpi, &ydpi); int xpos, ypos, width, height; glfwGetMonitorWorkarea(monitors[i], &xpos, &ypos, &width, &height); if ((windowPos.x >= xpos) && (windowPos.x < xpos + width) && (windowPos.y >= ypos) && (windowPos.y < ypos + height)) { scale.x = xdpi; scale.y = ydpi; break; } } #endif return scale; } // Get the human-readable, UTF-8 encoded name of the primary monitor const char *GetMonitorName(int monitor) { #if defined(PLATFORM_DESKTOP) int monitorCount; GLFWmonitor **monitors = glfwGetMonitors(&monitorCount); if ((monitor >= 0) && (monitor < monitorCount)) { return glfwGetMonitorName(monitors[monitor]); } else TRACELOG(LOG_WARNING, "GLFW: Failed to find selected monitor"); #endif return ""; } // Get clipboard text content // NOTE: returned string is allocated and freed by GLFW const char *GetClipboardText(void) { #if defined(PLATFORM_DESKTOP) return glfwGetClipboardString(CORE.Window.handle); #else return NULL; #endif } // Set clipboard text content void SetClipboardText(const char *text) { #if defined(PLATFORM_DESKTOP) glfwSetClipboardString(CORE.Window.handle, text); #endif } // Show mouse cursor void ShowCursor(void) { #if defined(PLATFORM_DESKTOP) glfwSetInputMode(CORE.Window.handle, GLFW_CURSOR, GLFW_CURSOR_NORMAL); #endif #if defined(PLATFORM_UWP) UWPGetMouseShowFunc()(); #endif CORE.Input.Mouse.cursorHidden = false; } // Hides mouse cursor void HideCursor(void) { #if defined(PLATFORM_DESKTOP) glfwSetInputMode(CORE.Window.handle, GLFW_CURSOR, GLFW_CURSOR_HIDDEN); #endif #if defined(PLATFORM_UWP) UWPGetMouseHideFunc()(); #endif CORE.Input.Mouse.cursorHidden = true; } // Check if cursor is not visible bool IsCursorHidden(void) { return CORE.Input.Mouse.cursorHidden; } // Enables cursor (unlock cursor) void EnableCursor(void) { #if defined(PLATFORM_DESKTOP) glfwSetInputMode(CORE.Window.handle, GLFW_CURSOR, GLFW_CURSOR_NORMAL); #endif #if defined(PLATFORM_WEB) emscripten_exit_pointerlock(); #endif #if defined(PLATFORM_UWP) UWPGetMouseUnlockFunc()(); #endif CORE.Input.Mouse.cursorHidden = false; } // Disables cursor (lock cursor) void DisableCursor(void) { #if defined(PLATFORM_DESKTOP) glfwSetInputMode(CORE.Window.handle, GLFW_CURSOR, GLFW_CURSOR_DISABLED); #endif #if defined(PLATFORM_WEB) emscripten_request_pointerlock("#canvas", 1); #endif #if defined(PLATFORM_UWP) UWPGetMouseLockFunc()(); #endif CORE.Input.Mouse.cursorHidden = true; } // Check if cursor is on the current screen. bool IsCursorOnScreen(void) { return CORE.Input.Mouse.cursorOnScreen; } // Set background color (framebuffer clear color) void ClearBackground(Color color) { rlClearColor(color.r, color.g, color.b, color.a); // Set clear color rlClearScreenBuffers(); // Clear current framebuffers } // Setup canvas (framebuffer) to start drawing void BeginDrawing(void) { CORE.Time.current = GetTime(); // Number of elapsed seconds since InitTimer() CORE.Time.update = CORE.Time.current - CORE.Time.previous; CORE.Time.previous = CORE.Time.current; rlLoadIdentity(); // Reset current matrix (modelview) rlMultMatrixf(MatrixToFloat(CORE.Window.screenScale)); // Apply screen scaling //rlTranslatef(0.375, 0.375, 0); // HACK to have 2D pixel-perfect drawing on OpenGL 1.1 // NOTE: Not required with OpenGL 3.3+ } // End canvas drawing and swap buffers (double buffering) void EndDrawing(void) { #if (defined(PLATFORM_RPI) || defined(PLATFORM_DRM)) && defined(SUPPORT_MOUSE_CURSOR_NATIVE) // On native mode we have no system mouse cursor, so, // we draw a small rectangle for user reference if (!CORE.Input.Mouse.cursorHidden) { DrawRectangle(CORE.Input.Mouse.position.x, CORE.Input.Mouse.position.y, 3, 3, MAROON); } #endif rlDrawRenderBatchActive(); // Update and draw internal render batch #if defined(SUPPORT_GIF_RECORDING) #define GIF_RECORD_FRAMERATE 10 if (gifRecording) { gifFramesCounter++; // NOTE: We record one gif frame every 10 game frames if ((gifFramesCounter%GIF_RECORD_FRAMERATE) == 0) { // Get image data for the current frame (from backbuffer) // NOTE: This process is quite slow... :( unsigned char *screenData = rlReadScreenPixels(CORE.Window.screen.width, CORE.Window.screen.height); msf_gif_frame(&gifState, screenData, 10, 16, CORE.Window.screen.width*4); RL_FREE(screenData); // Free image data } if (((gifFramesCounter/15)%2) == 1) { DrawCircle(30, CORE.Window.screen.height - 20, 10, RED); DrawText("RECORDING", 50, CORE.Window.screen.height - 25, 10, MAROON); } rlDrawRenderBatchActive(); // Update and draw internal render batch } #endif SwapBuffers(); // Copy back buffer to front buffer // Frame time control system CORE.Time.current = GetTime(); CORE.Time.draw = CORE.Time.current - CORE.Time.previous; CORE.Time.previous = CORE.Time.current; CORE.Time.frame = CORE.Time.update + CORE.Time.draw; // Wait for some milliseconds... if (CORE.Time.frame < CORE.Time.target) { Wait((float)(CORE.Time.target - CORE.Time.frame)*1000.0f); CORE.Time.current = GetTime(); double waitTime = CORE.Time.current - CORE.Time.previous; CORE.Time.previous = CORE.Time.current; CORE.Time.frame += waitTime; // Total frame time: update + draw + wait } PollInputEvents(); // Poll user events } // Initialize 2D mode with custom camera (2D) void BeginMode2D(Camera2D camera) { rlDrawRenderBatchActive(); // Update and draw internal render batch rlLoadIdentity(); // Reset current matrix (modelview) // Apply 2d camera transformation to modelview rlMultMatrixf(MatrixToFloat(GetCameraMatrix2D(camera))); // Apply screen scaling if required rlMultMatrixf(MatrixToFloat(CORE.Window.screenScale)); } // Ends 2D mode with custom camera void EndMode2D(void) { rlDrawRenderBatchActive(); // Update and draw internal render batch rlLoadIdentity(); // Reset current matrix (modelview) rlMultMatrixf(MatrixToFloat(CORE.Window.screenScale)); // Apply screen scaling if required } // Initializes 3D mode with custom camera (3D) void BeginMode3D(Camera3D camera) { rlDrawRenderBatchActive(); // Update and draw internal render batch rlMatrixMode(RL_PROJECTION); // Switch to projection matrix rlPushMatrix(); // Save previous matrix, which contains the settings for the 2d ortho projection rlLoadIdentity(); // Reset current matrix (projection) float aspect = (float)CORE.Window.currentFbo.width/(float)CORE.Window.currentFbo.height; // NOTE: zNear and zFar values are important when computing depth buffer values if (camera.projection == CAMERA_PERSPECTIVE) { // Setup perspective projection double top = RL_CULL_DISTANCE_NEAR*tan(camera.fovy*0.5*DEG2RAD); double right = top*aspect; rlFrustum(-right, right, -top, top, RL_CULL_DISTANCE_NEAR, RL_CULL_DISTANCE_FAR); } else if (camera.projection == CAMERA_ORTHOGRAPHIC) { // Setup orthographic projection double top = camera.fovy/2.0; double right = top*aspect; rlOrtho(-right, right, -top,top, RL_CULL_DISTANCE_NEAR, RL_CULL_DISTANCE_FAR); } rlMatrixMode(RL_MODELVIEW); // Switch back to modelview matrix rlLoadIdentity(); // Reset current matrix (modelview) // Setup Camera view Matrix matView = MatrixLookAt(camera.position, camera.target, camera.up); rlMultMatrixf(MatrixToFloat(matView)); // Multiply modelview matrix by view matrix (camera) rlEnableDepthTest(); // Enable DEPTH_TEST for 3D } // Ends 3D mode and returns to default 2D orthographic mode void EndMode3D(void) { rlDrawRenderBatchActive(); // Update and draw internal render batch rlMatrixMode(RL_PROJECTION); // Switch to projection matrix rlPopMatrix(); // Restore previous matrix (projection) from matrix stack rlMatrixMode(RL_MODELVIEW); // Switch back to modelview matrix rlLoadIdentity(); // Reset current matrix (modelview) rlMultMatrixf(MatrixToFloat(CORE.Window.screenScale)); // Apply screen scaling if required rlDisableDepthTest(); // Disable DEPTH_TEST for 2D } // Initializes render texture for drawing void BeginTextureMode(RenderTexture2D target) { rlDrawRenderBatchActive(); // Update and draw internal render batch rlEnableFramebuffer(target.id); // Enable render target // Set viewport to framebuffer size rlViewport(0, 0, target.texture.width, target.texture.height); rlMatrixMode(RL_PROJECTION); // Switch to projection matrix rlLoadIdentity(); // Reset current matrix (projection) // Set orthographic projection to current framebuffer size // NOTE: Configured top-left corner as (0, 0) rlOrtho(0, target.texture.width, target.texture.height, 0, 0.0f, 1.0f); rlMatrixMode(RL_MODELVIEW); // Switch back to modelview matrix rlLoadIdentity(); // Reset current matrix (modelview) //rlScalef(0.0f, -1.0f, 0.0f); // Flip Y-drawing (?) // Setup current width/height for proper aspect ratio // calculation when using BeginMode3D() CORE.Window.currentFbo.width = target.texture.width; CORE.Window.currentFbo.height = target.texture.height; } // Ends drawing to render texture void EndTextureMode(void) { rlDrawRenderBatchActive(); // Update and draw internal render batch rlDisableFramebuffer(); // Disable render target (fbo) // Set viewport to default framebuffer size SetupViewport(CORE.Window.render.width, CORE.Window.render.height); // Reset current fbo to screen size CORE.Window.currentFbo.width = CORE.Window.screen.width; CORE.Window.currentFbo.height = CORE.Window.screen.height; } // Begin custom shader mode void BeginShaderMode(Shader shader) { rlSetShader(shader); } // End custom shader mode (returns to default shader) void EndShaderMode(void) { rlSetShader(rlGetShaderDefault()); } // Begin blending mode (alpha, additive, multiplied) // NOTE: Only 3 blending modes supported, default blend mode is alpha void BeginBlendMode(int mode) { rlSetBlendMode(mode); } // End blending mode (reset to default: alpha blending) void EndBlendMode(void) { rlSetBlendMode(BLEND_ALPHA); } // Begin scissor mode (define screen area for following drawing) // NOTE: Scissor rec refers to bottom-left corner, we change it to upper-left void BeginScissorMode(int x, int y, int width, int height) { rlDrawRenderBatchActive(); // Update and draw internal render batch rlEnableScissorTest(); rlScissor(x, CORE.Window.currentFbo.height - (y + height), width, height); } // End scissor mode void EndScissorMode(void) { rlDrawRenderBatchActive(); // Update and draw internal render batch rlDisableScissorTest(); } // Begin VR drawing configuration void BeginVrStereoMode(VrStereoConfig config) { rlEnableStereoRender(); // Set stereo render matrices rlSetMatrixProjectionStereo(config.projection[0], config.projection[1]); rlSetMatrixViewOffsetStereo(config.viewOffset[0], config.viewOffset[1]); } // End VR drawing process (and desktop mirror) void EndVrStereoMode(void) { rlDisableStereoRender(); } // Load VR stereo config for VR simulator device parameters VrStereoConfig LoadVrStereoConfig(VrDeviceInfo device) { VrStereoConfig config = { 0 }; #if defined(GRAPHICS_API_OPENGL_33) || defined(GRAPHICS_API_OPENGL_ES2) // Compute aspect ratio float aspect = ((float)device.hResolution*0.5f)/(float)device.vResolution; // Compute lens parameters float lensShift = (device.hScreenSize*0.25f - device.lensSeparationDistance*0.5f)/device.hScreenSize; config.leftLensCenter[0] = 0.25f + lensShift; config.leftLensCenter[1] = 0.5f; config.rightLensCenter[0] = 0.75f - lensShift; config.rightLensCenter[1] = 0.5f; config.leftScreenCenter[0] = 0.25f; config.leftScreenCenter[1] = 0.5f; config.rightScreenCenter[0] = 0.75f; config.rightScreenCenter[1] = 0.5f; // Compute distortion scale parameters // NOTE: To get lens max radius, lensShift must be normalized to [-1..1] float lensRadius = fabsf(-1.0f - 4.0f*lensShift); float lensRadiusSq = lensRadius*lensRadius; float distortionScale = device.lensDistortionValues[0] + device.lensDistortionValues[1]*lensRadiusSq + device.lensDistortionValues[2]*lensRadiusSq*lensRadiusSq + device.lensDistortionValues[3]*lensRadiusSq*lensRadiusSq*lensRadiusSq; float normScreenWidth = 0.5f; float normScreenHeight = 1.0f; config.scaleIn[0] = 2.0f/normScreenWidth; config.scaleIn[1] = 2.0f/normScreenHeight/aspect; config.scale[0] = normScreenWidth*0.5f/distortionScale; config.scale[1] = normScreenHeight*0.5f*aspect/distortionScale; // Fovy is normally computed with: 2*atan2f(device.vScreenSize, 2*device.eyeToScreenDistance) // ...but with lens distortion it is increased (see Oculus SDK Documentation) //float fovy = 2.0f*atan2f(device.vScreenSize*0.5f*distortionScale, device.eyeToScreenDistance); // Really need distortionScale? float fovy = 2.0f*(float)atan2f(device.vScreenSize*0.5f, device.eyeToScreenDistance); // Compute camera projection matrices float projOffset = 4.0f*lensShift; // Scaled to projection space coordinates [-1..1] Matrix proj = MatrixPerspective(fovy, aspect, RL_CULL_DISTANCE_NEAR, RL_CULL_DISTANCE_FAR); config.projection[0] = MatrixMultiply(proj, MatrixTranslate(projOffset, 0.0f, 0.0f)); config.projection[1] = MatrixMultiply(proj, MatrixTranslate(-projOffset, 0.0f, 0.0f)); // Compute camera transformation matrices // NOTE: Camera movement might seem more natural if we model the head. // Our axis of rotation is the base of our head, so we might want to add // some y (base of head to eye level) and -z (center of head to eye protrusion) to the camera positions. config.viewOffset[0] = MatrixTranslate(-device.interpupillaryDistance*0.5f, 0.075f, 0.045f); config.viewOffset[1] = MatrixTranslate(device.interpupillaryDistance*0.5f, 0.075f, 0.045f); // Compute eyes Viewports /* config.eyeViewportRight[0] = 0; config.eyeViewportRight[1] = 0; config.eyeViewportRight[2] = device.hResolution/2; config.eyeViewportRight[3] = device.vResolution; config.eyeViewportLeft[0] = device.hResolution/2; config.eyeViewportLeft[1] = 0; config.eyeViewportLeft[2] = device.hResolution/2; config.eyeViewportLeft[3] = device.vResolution; */ #else TRACELOG(LOG_WARNING, "RLGL: VR Simulator not supported on OpenGL 1.1"); #endif return config; } // Unload VR stereo config properties void UnloadVrStereoConfig(VrStereoConfig config) { //... } // Load shader from files and bind default locations // NOTE: If shader string is NULL, using default vertex/fragment shaders Shader LoadShader(const char *vsFileName, const char *fsFileName) { Shader shader = { 0 }; shader.locs = (int *)RL_CALLOC(MAX_SHADER_LOCATIONS, sizeof(int)); // NOTE: All locations must be reseted to -1 (no location) for (int i = 0; i < MAX_SHADER_LOCATIONS; i++) shader.locs[i] = -1; char *vShaderStr = NULL; char *fShaderStr = NULL; if (vsFileName != NULL) vShaderStr = LoadFileText(vsFileName); if (fsFileName != NULL) fShaderStr = LoadFileText(fsFileName); shader.id = rlLoadShaderCode(vShaderStr, fShaderStr); if (vShaderStr != NULL) RL_FREE(vShaderStr); if (fShaderStr != NULL) RL_FREE(fShaderStr); // After shader loading, we TRY to set default location names if (shader.id > 0) { // Default shader attrib locations have been fixed before linking: // vertex position location = 0 // vertex texcoord location = 1 // vertex normal location = 2 // vertex color location = 3 // vertex tangent location = 4 // vertex texcoord2 location = 5 // NOTE: If any location is not found, loc point becomes -1 // Get handles to GLSL input attibute locations shader.locs[SHADER_LOC_VERTEX_POSITION] = rlGetLocationAttrib(shader.id, DEFAULT_SHADER_ATTRIB_NAME_POSITION); shader.locs[SHADER_LOC_VERTEX_TEXCOORD01] = rlGetLocationAttrib(shader.id, DEFAULT_SHADER_ATTRIB_NAME_TEXCOORD); shader.locs[SHADER_LOC_VERTEX_TEXCOORD02] = rlGetLocationAttrib(shader.id, DEFAULT_SHADER_ATTRIB_NAME_TEXCOORD2); shader.locs[SHADER_LOC_VERTEX_NORMAL] = rlGetLocationAttrib(shader.id, DEFAULT_SHADER_ATTRIB_NAME_NORMAL); shader.locs[SHADER_LOC_VERTEX_TANGENT] = rlGetLocationAttrib(shader.id, DEFAULT_SHADER_ATTRIB_NAME_TANGENT); shader.locs[SHADER_LOC_VERTEX_COLOR] = rlGetLocationAttrib(shader.id, DEFAULT_SHADER_ATTRIB_NAME_COLOR); // Get handles to GLSL uniform locations (vertex shader) shader.locs[SHADER_LOC_MATRIX_MVP] = rlGetLocationUniform(shader.id, "mvp"); shader.locs[SHADER_LOC_MATRIX_VIEW] = rlGetLocationUniform(shader.id, "view"); shader.locs[SHADER_LOC_MATRIX_PROJECTION] = rlGetLocationUniform(shader.id, "projection"); shader.locs[SHADER_LOC_MATRIX_NORMAL] = rlGetLocationUniform(shader.id, "matNormal"); // Get handles to GLSL uniform locations (fragment shader) shader.locs[SHADER_LOC_COLOR_DIFFUSE] = rlGetLocationUniform(shader.id, "colDiffuse"); shader.locs[SHADER_LOC_MAP_DIFFUSE] = rlGetLocationUniform(shader.id, "texture0"); shader.locs[SHADER_LOC_MAP_SPECULAR] = rlGetLocationUniform(shader.id, "texture1"); shader.locs[SHADER_LOC_MAP_NORMAL] = rlGetLocationUniform(shader.id, "texture2"); } return shader; } // Load shader from code strings and bind default locations RLAPI Shader LoadShaderFromMemory(const char *vsCode, const char *fsCode) { Shader shader = { 0 }; shader.locs = (int *)RL_CALLOC(MAX_SHADER_LOCATIONS, sizeof(int)); shader.id = rlLoadShaderCode(vsCode, fsCode); // After shader loading, we TRY to set default location names if (shader.id > 0) { // Default shader attrib locations have been fixed before linking: // vertex position location = 0 // vertex texcoord location = 1 // vertex normal location = 2 // vertex color location = 3 // vertex tangent location = 4 // vertex texcoord2 location = 5 // NOTE: If any location is not found, loc point becomes -1 // Get handles to GLSL input attibute locations shader.locs[SHADER_LOC_VERTEX_POSITION] = rlGetLocationAttrib(shader.id, DEFAULT_SHADER_ATTRIB_NAME_POSITION); shader.locs[SHADER_LOC_VERTEX_TEXCOORD01] = rlGetLocationAttrib(shader.id, DEFAULT_SHADER_ATTRIB_NAME_TEXCOORD); shader.locs[SHADER_LOC_VERTEX_TEXCOORD02] = rlGetLocationAttrib(shader.id, DEFAULT_SHADER_ATTRIB_NAME_TEXCOORD2); shader.locs[SHADER_LOC_VERTEX_NORMAL] = rlGetLocationAttrib(shader.id, DEFAULT_SHADER_ATTRIB_NAME_NORMAL); shader.locs[SHADER_LOC_VERTEX_TANGENT] = rlGetLocationAttrib(shader.id, DEFAULT_SHADER_ATTRIB_NAME_TANGENT); shader.locs[SHADER_LOC_VERTEX_COLOR] = rlGetLocationAttrib(shader.id, DEFAULT_SHADER_ATTRIB_NAME_COLOR); // Get handles to GLSL uniform locations (vertex shader) shader.locs[SHADER_LOC_MATRIX_MVP] = rlGetLocationUniform(shader.id, "mvp"); shader.locs[SHADER_LOC_MATRIX_PROJECTION] = rlGetLocationUniform(shader.id, "projection"); shader.locs[SHADER_LOC_MATRIX_VIEW] = rlGetLocationUniform(shader.id, "view"); // Get handles to GLSL uniform locations (fragment shader) shader.locs[SHADER_LOC_COLOR_DIFFUSE] = rlGetLocationUniform(shader.id, "colDiffuse"); shader.locs[SHADER_LOC_MAP_DIFFUSE] = rlGetLocationUniform(shader.id, "texture0"); shader.locs[SHADER_LOC_MAP_SPECULAR] = rlGetLocationUniform(shader.id, "texture1"); shader.locs[SHADER_LOC_MAP_NORMAL] = rlGetLocationUniform(shader.id, "texture2"); } return shader; } // Unload shader from GPU memory (VRAM) void UnloadShader(Shader shader) { if (shader.id != rlGetShaderDefault().id) { rlUnloadShaderProgram(shader.id); RL_FREE(shader.locs); } } // Get shader uniform location int GetShaderLocation(Shader shader, const char *uniformName) { return rlGetLocationUniform(shader.id, uniformName); } // Get shader attribute location int GetShaderLocationAttrib(Shader shader, const char *attribName) { return rlGetLocationAttrib(shader.id, attribName); } // Set shader uniform value void SetShaderValue(Shader shader, int locIndex, const void *value, int uniformType) { SetShaderValueV(shader, locIndex, value, uniformType, 1); } // Set shader uniform value vector void SetShaderValueV(Shader shader, int locIndex, const void *value, int uniformType, int count) { rlEnableShader(shader.id); rlSetUniform(locIndex, value, uniformType, count); //rlDisableShader(); // Avoid reseting current shader program, in case other uniforms are set } // Set shader uniform value (matrix 4x4) void SetShaderValueMatrix(Shader shader, int locIndex, Matrix mat) { rlEnableShader(shader.id); rlSetUniformMatrix(locIndex, mat); //rlDisableShader(); } // Set shader uniform value for texture void SetShaderValueTexture(Shader shader, int locIndex, Texture2D texture) { rlEnableShader(shader.id); rlSetUniformSampler(locIndex, texture.id); //rlDisableShader(); } // Returns a ray trace from mouse position Ray GetMouseRay(Vector2 mouse, Camera camera) { Ray ray; // Calculate normalized device coordinates // NOTE: y value is negative float x = (2.0f*mouse.x)/(float)GetScreenWidth() - 1.0f; float y = 1.0f - (2.0f*mouse.y)/(float)GetScreenHeight(); float z = 1.0f; // Store values in a vector Vector3 deviceCoords = { x, y, z }; // Calculate view matrix from camera look at Matrix matView = MatrixLookAt(camera.position, camera.target, camera.up); Matrix matProj = MatrixIdentity(); if (camera.projection == CAMERA_PERSPECTIVE) { // Calculate projection matrix from perspective matProj = MatrixPerspective(camera.fovy*DEG2RAD, ((double)GetScreenWidth()/(double)GetScreenHeight()), RL_CULL_DISTANCE_NEAR, RL_CULL_DISTANCE_FAR); } else if (camera.projection == CAMERA_ORTHOGRAPHIC) { float aspect = (float)CORE.Window.screen.width/(float)CORE.Window.screen.height; double top = camera.fovy/2.0; double right = top*aspect; // Calculate projection matrix from orthographic matProj = MatrixOrtho(-right, right, -top, top, 0.01, 1000.0); } // Unproject far/near points Vector3 nearPoint = Vector3Unproject((Vector3){ deviceCoords.x, deviceCoords.y, 0.0f }, matProj, matView); Vector3 farPoint = Vector3Unproject((Vector3){ deviceCoords.x, deviceCoords.y, 1.0f }, matProj, matView); // Unproject the mouse cursor in the near plane. // We need this as the source position because orthographic projects, compared to perspect doesn't have a // convergence point, meaning that the "eye" of the camera is more like a plane than a point. Vector3 cameraPlanePointerPos = Vector3Unproject((Vector3){ deviceCoords.x, deviceCoords.y, -1.0f }, matProj, matView); // Calculate normalized direction vector Vector3 direction = Vector3Normalize(Vector3Subtract(farPoint, nearPoint)); if (camera.projection == CAMERA_PERSPECTIVE) ray.position = camera.position; else if (camera.projection == CAMERA_ORTHOGRAPHIC) ray.position = cameraPlanePointerPos; // Apply calculated vectors to ray ray.direction = direction; return ray; } // Get transform matrix for camera Matrix GetCameraMatrix(Camera camera) { return MatrixLookAt(camera.position, camera.target, camera.up); } // Returns camera 2d transform matrix Matrix GetCameraMatrix2D(Camera2D camera) { Matrix matTransform = { 0 }; // The camera in world-space is set by // 1. Move it to target // 2. Rotate by -rotation and scale by (1/zoom) // When setting higher scale, it's more intuitive for the world to become bigger (= camera become smaller), // not for the camera getting bigger, hence the invert. Same deal with rotation. // 3. Move it by (-offset); // Offset defines target transform relative to screen, but since we're effectively "moving" screen (camera) // we need to do it into opposite direction (inverse transform) // Having camera transform in world-space, inverse of it gives the modelview transform. // Since (A*B*C)' = C'*B'*A', the modelview is // 1. Move to offset // 2. Rotate and Scale // 3. Move by -target Matrix matOrigin = MatrixTranslate(-camera.target.x, -camera.target.y, 0.0f); Matrix matRotation = MatrixRotate((Vector3){ 0.0f, 0.0f, 1.0f }, camera.rotation*DEG2RAD); Matrix matScale = MatrixScale(camera.zoom, camera.zoom, 1.0f); Matrix matTranslation = MatrixTranslate(camera.offset.x, camera.offset.y, 0.0f); matTransform = MatrixMultiply(MatrixMultiply(matOrigin, MatrixMultiply(matScale, matRotation)), matTranslation); return matTransform; } // Returns the screen space position from a 3d world space position Vector2 GetWorldToScreen(Vector3 position, Camera camera) { Vector2 screenPosition = GetWorldToScreenEx(position, camera, GetScreenWidth(), GetScreenHeight()); return screenPosition; } // Returns size position for a 3d world space position (useful for texture drawing) Vector2 GetWorldToScreenEx(Vector3 position, Camera camera, int width, int height) { // Calculate projection matrix (from perspective instead of frustum Matrix matProj = MatrixIdentity(); if (camera.projection == CAMERA_PERSPECTIVE) { // Calculate projection matrix from perspective matProj = MatrixPerspective(camera.fovy*DEG2RAD, ((double)width/(double)height), RL_CULL_DISTANCE_NEAR, RL_CULL_DISTANCE_FAR); } else if (camera.projection == CAMERA_ORTHOGRAPHIC) { float aspect = (float)CORE.Window.screen.width/(float)CORE.Window.screen.height; double top = camera.fovy/2.0; double right = top*aspect; // Calculate projection matrix from orthographic matProj = MatrixOrtho(-right, right, -top, top, RL_CULL_DISTANCE_NEAR, RL_CULL_DISTANCE_FAR); } // Calculate view matrix from camera look at (and transpose it) Matrix matView = MatrixLookAt(camera.position, camera.target, camera.up); // Convert world position vector to quaternion Quaternion worldPos = { position.x, position.y, position.z, 1.0f }; // Transform world position to view worldPos = QuaternionTransform(worldPos, matView); // Transform result to projection (clip space position) worldPos = QuaternionTransform(worldPos, matProj); // Calculate normalized device coordinates (inverted y) Vector3 ndcPos = { worldPos.x/worldPos.w, -worldPos.y/worldPos.w, worldPos.z/worldPos.w }; // Calculate 2d screen position vector Vector2 screenPosition = { (ndcPos.x + 1.0f)/2.0f*(float)width, (ndcPos.y + 1.0f)/2.0f*(float)height }; return screenPosition; } // Returns the screen space position for a 2d camera world space position Vector2 GetWorldToScreen2D(Vector2 position, Camera2D camera) { Matrix matCamera = GetCameraMatrix2D(camera); Vector3 transform = Vector3Transform((Vector3){ position.x, position.y, 0 }, matCamera); return (Vector2){ transform.x, transform.y }; } // Returns the world space position for a 2d camera screen space position Vector2 GetScreenToWorld2D(Vector2 position, Camera2D camera) { Matrix invMatCamera = MatrixInvert(GetCameraMatrix2D(camera)); Vector3 transform = Vector3Transform((Vector3){ position.x, position.y, 0 }, invMatCamera); return (Vector2){ transform.x, transform.y }; } // Set target FPS (maximum) void SetTargetFPS(int fps) { if (fps < 1) CORE.Time.target = 0.0; else CORE.Time.target = 1.0/(double)fps; TRACELOG(LOG_INFO, "TIMER: Target time per frame: %02.03f milliseconds", (float)CORE.Time.target*1000); } // Returns current FPS // NOTE: We calculate an average framerate int GetFPS(void) { #define FPS_CAPTURE_FRAMES_COUNT 30 // 30 captures #define FPS_AVERAGE_TIME_SECONDS 0.5f // 500 millisecondes #define FPS_STEP (FPS_AVERAGE_TIME_SECONDS/FPS_CAPTURE_FRAMES_COUNT) static int index = 0; static float history[FPS_CAPTURE_FRAMES_COUNT] = { 0 }; static float average = 0, last = 0; float fpsFrame = GetFrameTime(); if (fpsFrame == 0) return 0; if ((GetTime() - last) > FPS_STEP) { last = (float)GetTime(); index = (index + 1)%FPS_CAPTURE_FRAMES_COUNT; average -= history[index]; history[index] = fpsFrame/FPS_CAPTURE_FRAMES_COUNT; average += history[index]; } return (int)roundf(1.0f/average); } // Returns time in seconds for last frame drawn (delta time) float GetFrameTime(void) { return (float)CORE.Time.frame; } // Get elapsed time measure in seconds since InitTimer() // NOTE: On PLATFORM_DESKTOP InitTimer() is called on InitWindow() // NOTE: On PLATFORM_DESKTOP, timer is initialized on glfwInit() double GetTime(void) { #if defined(PLATFORM_DESKTOP) || defined(PLATFORM_WEB) return glfwGetTime(); // Elapsed time since glfwInit() #endif #if defined(PLATFORM_ANDROID) || defined(PLATFORM_RPI) || defined(PLATFORM_DRM) struct timespec ts; clock_gettime(CLOCK_MONOTONIC, &ts); unsigned long long int time = (unsigned long long int)ts.tv_sec*1000000000LLU + (unsigned long long int)ts.tv_nsec; return (double)(time - CORE.Time.base)*1e-9; // Elapsed time since InitTimer() #endif #if defined(PLATFORM_UWP) return UWPGetQueryTimeFunc()(); #endif } // Setup window configuration flags (view FLAGS) // NOTE: This function is expected to be called before window creation, // because it setups some flags for the window creation process. // To configure window states after creation, just use SetWindowState() void SetConfigFlags(unsigned int flags) { // Selected flags are set but not evaluated at this point, // flag evaluation happens at InitWindow() or SetWindowState() CORE.Window.flags |= flags; } // NOTE TRACELOG() function is located in [utils.h] // Takes a screenshot of current screen (saved a .png) // NOTE: This function could work in any platform but some platforms: PLATFORM_ANDROID and PLATFORM_WEB // have their own internal file-systems, to dowload image to user file-system some additional mechanism is required void TakeScreenshot(const char *fileName) { unsigned char *imgData = rlReadScreenPixels(CORE.Window.render.width, CORE.Window.render.height); Image image = { imgData, CORE.Window.render.width, CORE.Window.render.height, 1, PIXELFORMAT_UNCOMPRESSED_R8G8B8A8 }; char path[512] = { 0 }; #if defined(PLATFORM_ANDROID) strcpy(path, CORE.Android.internalDataPath); strcat(path, "/"); strcat(path, fileName); #elif defined(PLATFORM_UWP) strcpy(path, CORE.UWP.internalDataPath); strcat(path, "/"); strcat(path, fileName); #else strcpy(path, fileName); #endif ExportImage(image, path); RL_FREE(imgData); #if defined(PLATFORM_WEB) // Download file from MEMFS (emscripten memory filesystem) // saveFileFromMEMFSToDisk() function is defined in raylib/src/shell.html emscripten_run_script(TextFormat("saveFileFromMEMFSToDisk('%s','%s')", GetFileName(path), GetFileName(path))); #endif // TODO: Verification required for log TRACELOG(LOG_INFO, "SYSTEM: [%s] Screenshot taken successfully", path); } // Returns a random value between min and max (both included) int GetRandomValue(int min, int max) { if (min > max) { int tmp = max; max = min; min = tmp; } return (rand()%(abs(max - min) + 1) + min); } // Check if the file exists bool FileExists(const char *fileName) { bool result = false; #if defined(_WIN32) if (_access(fileName, 0) != -1) result = true; #else if (access(fileName, F_OK) != -1) result = true; #endif return result; } // Check file extension // NOTE: Extensions checking is not case-sensitive bool IsFileExtension(const char *fileName, const char *ext) { bool result = false; const char *fileExt = GetFileExtension(fileName); if (fileExt != NULL) { #if defined(SUPPORT_TEXT_MANIPULATION) int extCount = 0; const char **checkExts = TextSplit(ext, ';', &extCount); char fileExtLower[16] = { 0 }; strcpy(fileExtLower, TextToLower(fileExt)); for (int i = 0; i < extCount; i++) { if (TextIsEqual(fileExtLower, TextToLower(checkExts[i]))) { result = true; break; } } #else if (strcmp(fileExt, ext) == 0) result = true; #endif } return result; } // Check if a directory path exists bool DirectoryExists(const char *dirPath) { bool result = false; DIR *dir = opendir(dirPath); if (dir != NULL) { result = true; closedir(dir); } return result; } // Get pointer to extension for a filename string (includes the dot: .png) const char *GetFileExtension(const char *fileName) { const char *dot = strrchr(fileName, '.'); if (!dot || dot == fileName) return NULL; return dot; } // String pointer reverse break: returns right-most occurrence of charset in s static const char *strprbrk(const char *s, const char *charset) { const char *latestMatch = NULL; for (; s = strpbrk(s, charset), s != NULL; latestMatch = s++) { } return latestMatch; } // Get pointer to filename for a path string const char *GetFileName(const char *filePath) { const char *fileName = NULL; if (filePath != NULL) fileName = strprbrk(filePath, "\\/"); if (!fileName) return filePath; return fileName + 1; } // Get filename string without extension (uses static string) const char *GetFileNameWithoutExt(const char *filePath) { #define MAX_FILENAMEWITHOUTEXT_LENGTH 128 static char fileName[MAX_FILENAMEWITHOUTEXT_LENGTH]; memset(fileName, 0, MAX_FILENAMEWITHOUTEXT_LENGTH); if (filePath != NULL) strcpy(fileName, GetFileName(filePath)); // Get filename with extension int len = (int)strlen(fileName); for (int i = 0; (i < len) && (i < MAX_FILENAMEWITHOUTEXT_LENGTH); i++) { if (fileName[i] == '.') { // NOTE: We break on first '.' found fileName[i] = '\0'; break; } } return fileName; } // Get directory for a given filePath const char *GetDirectoryPath(const char *filePath) { /* // NOTE: Directory separator is different in Windows and other platforms, // fortunately, Windows also support the '/' separator, that's the one should be used #if defined(_WIN32) char separator = '\\'; #else char separator = '/'; #endif */ const char *lastSlash = NULL; static char dirPath[MAX_FILEPATH_LENGTH]; memset(dirPath, 0, MAX_FILEPATH_LENGTH); // In case provided path does not contain a root drive letter (C:\, D:\) nor leading path separator (\, /), // we add the current directory path to dirPath if (filePath[1] != ':' && filePath[0] != '\\' && filePath[0] != '/') { // For security, we set starting path to current directory, // obtained path will be concated to this dirPath[0] = '.'; dirPath[1] = '/'; } lastSlash = strprbrk(filePath, "\\/"); if (lastSlash) { if (lastSlash == filePath) { // The last and only slash is the leading one: path is in a root directory dirPath[0] = filePath[0]; dirPath[1] = '\0'; } else { // NOTE: Be careful, strncpy() is not safe, it does not care about '\0' memcpy(dirPath + (filePath[1] != ':' && filePath[0] != '\\' && filePath[0] != '/' ? 2 : 0), filePath, strlen(filePath) - (strlen(lastSlash) - 1)); dirPath[strlen(filePath) - strlen(lastSlash) + (filePath[1] != ':' && filePath[0] != '\\' && filePath[0] != '/' ? 2 : 0)] = '\0'; // Add '\0' manually } } return dirPath; } // Get previous directory path for a given path const char *GetPrevDirectoryPath(const char *dirPath) { static char prevDirPath[MAX_FILEPATH_LENGTH]; memset(prevDirPath, 0, MAX_FILEPATH_LENGTH); int pathLen = (int)strlen(dirPath); if (pathLen <= 3) strcpy(prevDirPath, dirPath); for (int i = (pathLen - 1); (i >= 0) && (pathLen > 3); i--) { if ((dirPath[i] == '\\') || (dirPath[i] == '/')) { // Check for root: "C:\" or "/" if (((i == 2) && (dirPath[1] ==':')) || (i == 0)) i++; strncpy(prevDirPath, dirPath, i); break; } } return prevDirPath; } // Get current working directory const char *GetWorkingDirectory(void) { static char currentDir[MAX_FILEPATH_LENGTH]; memset(currentDir, 0, MAX_FILEPATH_LENGTH); char *ptr = GETCWD(currentDir, MAX_FILEPATH_LENGTH - 1); return ptr; } // Get filenames in a directory path (max 512 files) // NOTE: Files count is returned by parameters pointer char **GetDirectoryFiles(const char *dirPath, int *fileCount) { #define MAX_DIRECTORY_FILES 512 ClearDirectoryFiles(); // Memory allocation for MAX_DIRECTORY_FILES dirFilesPath = (char **)RL_MALLOC(sizeof(char *)*MAX_DIRECTORY_FILES); for (int i = 0; i < MAX_DIRECTORY_FILES; i++) dirFilesPath[i] = (char *)RL_MALLOC(sizeof(char)*MAX_FILEPATH_LENGTH); int counter = 0; struct dirent *entity; DIR *dir = opendir(dirPath); if (dir != NULL) // It's a directory { // TODO: Reading could be done in two passes, // first one to count files and second one to read names // That way we can allocate required memory, instead of a limited pool while ((entity = readdir(dir)) != NULL) { strcpy(dirFilesPath[counter], entity->d_name); counter++; } closedir(dir); } else TRACELOG(LOG_WARNING, "FILEIO: Failed to open requested directory"); // Maybe it's a file... dirFilesCount = counter; *fileCount = dirFilesCount; return dirFilesPath; } // Clear directory files paths buffers void ClearDirectoryFiles(void) { if (dirFilesCount > 0) { for (int i = 0; i < MAX_DIRECTORY_FILES; i++) RL_FREE(dirFilesPath[i]); RL_FREE(dirFilesPath); } dirFilesCount = 0; } // Change working directory, returns true on success bool ChangeDirectory(const char *dir) { bool result = CHDIR(dir); if (result != 0) TRACELOG(LOG_WARNING, "SYSTEM: Failed to change to directory: %s", dir); return (result == 0); } // Check if a file has been dropped into window bool IsFileDropped(void) { if (CORE.Window.dropFilesCount > 0) return true; else return false; } // Get dropped files names char **GetDroppedFiles(int *count) { *count = CORE.Window.dropFilesCount; return CORE.Window.dropFilesPath; } // Clear dropped files paths buffer void ClearDroppedFiles(void) { if (CORE.Window.dropFilesCount > 0) { for (int i = 0; i < CORE.Window.dropFilesCount; i++) RL_FREE(CORE.Window.dropFilesPath[i]); RL_FREE(CORE.Window.dropFilesPath); CORE.Window.dropFilesCount = 0; } } // Get file modification time (last write time) long GetFileModTime(const char *fileName) { struct stat result = { 0 }; if (stat(fileName, &result) == 0) { time_t mod = result.st_mtime; return (long)mod; } return 0; } // Compress data (DEFLATE algorythm) unsigned char *CompressData(unsigned char *data, int dataLength, int *compDataLength) { #define COMPRESSION_QUALITY_DEFLATE 8 unsigned char *compData = NULL; #if defined(SUPPORT_COMPRESSION_API) // Compress data and generate a valid DEFLATE stream struct sdefl sdefl = { 0 }; int bounds = sdefl_bound(dataLength); compData = (unsigned char *)RL_CALLOC(bounds, 1); *compDataLength = sdeflate(&sdefl, compData, data, dataLength, COMPRESSION_QUALITY_DEFLATE); // Compression level 8, same as stbwi TraceLog(LOG_INFO, "SYSTEM: Compress data: Original size: %i -> Comp. size: %i", dataLength, compDataLength); #endif return compData; } // Decompress data (DEFLATE algorythm) unsigned char *DecompressData(unsigned char *compData, int compDataLength, int *dataLength) { unsigned char *data = NULL; #if defined(SUPPORT_COMPRESSION_API) // Decompress data from a valid DEFLATE stream data = RL_CALLOC(MAX_DECOMPRESSION_SIZE*1024*1024, 1); int length = sinflate(data, compData, compDataLength); unsigned char *temp = RL_REALLOC(data, length); if (temp != NULL) data = temp; else TRACELOG(LOG_WARNING, "SYSTEM: Failed to re-allocate required decompression memory"); *dataLength = length; TraceLog(LOG_INFO, "SYSTEM: Decompress data: Comp. size: %i -> Original size: %i", compDataLength, dataLength); #endif return data; } // Save integer value to storage file (to defined position) // NOTE: Storage positions is directly related to file memory layout (4 bytes each integer) bool SaveStorageValue(unsigned int position, int value) { bool success = false; #if defined(SUPPORT_DATA_STORAGE) char path[512] = { 0 }; #if defined(PLATFORM_ANDROID) strcpy(path, CORE.Android.internalDataPath); strcat(path, "/"); strcat(path, STORAGE_DATA_FILE); #elif defined(PLATFORM_UWP) strcpy(path, CORE.UWP.internalDataPath); strcat(path, "/"); strcat(path, STORAGE_DATA_FILE); #else strcpy(path, STORAGE_DATA_FILE); #endif unsigned int dataSize = 0; unsigned int newDataSize = 0; unsigned char *fileData = LoadFileData(path, &dataSize); unsigned char *newFileData = NULL; if (fileData != NULL) { if (dataSize <= (position*sizeof(int))) { // Increase data size up to position and store value newDataSize = (position + 1)*sizeof(int); newFileData = (unsigned char *)RL_REALLOC(fileData, newDataSize); if (newFileData != NULL) { // RL_REALLOC succeded int *dataPtr = (int *)newFileData; dataPtr[position] = value; } else { // RL_REALLOC failed TRACELOG(LOG_WARNING, "FILEIO: [%s] Failed to realloc data (%u), position in bytes (%u) bigger than actual file size", path, dataSize, position*sizeof(int)); // We store the old size of the file newFileData = fileData; newDataSize = dataSize; } } else { // Store the old size of the file newFileData = fileData; newDataSize = dataSize; // Replace value on selected position int *dataPtr = (int *)newFileData; dataPtr[position] = value; } success = SaveFileData(path, newFileData, newDataSize); RL_FREE(newFileData); } else { TRACELOG(LOG_INFO, "FILEIO: [%s] File not found, creating it", path); dataSize = (position + 1)*sizeof(int); fileData = (unsigned char *)RL_MALLOC(dataSize); int *dataPtr = (int *)fileData; dataPtr[position] = value; success = SaveFileData(path, fileData, dataSize); UnloadFileData(fileData); } #endif return success; } // Load integer value from storage file (from defined position) // NOTE: If requested position could not be found, value 0 is returned int LoadStorageValue(unsigned int position) { int value = 0; #if defined(SUPPORT_DATA_STORAGE) char path[512] = { 0 }; #if defined(PLATFORM_ANDROID) strcpy(path, CORE.Android.internalDataPath); strcat(path, "/"); strcat(path, STORAGE_DATA_FILE); #elif defined(PLATFORM_UWP) strcpy(path, CORE.UWP.internalDataPath); strcat(path, "/"); strcat(path, STORAGE_DATA_FILE); #else strcpy(path, STORAGE_DATA_FILE); #endif unsigned int dataSize = 0; unsigned char *fileData = LoadFileData(path, &dataSize); if (fileData != NULL) { if (dataSize < (position*4)) TRACELOG(LOG_WARNING, "SYSTEM: Failed to find storage position"); else { int *dataPtr = (int *)fileData; value = dataPtr[position]; } UnloadFileData(fileData); } #endif return value; } // Open URL with default system browser (if available) // NOTE: This function is only safe to use if you control the URL given. // A user could craft a malicious string performing another action. // Only call this function yourself not with user input or make sure to check the string yourself. // Ref: https://github.com/raysan5/raylib/issues/686 void OpenURL(const char *url) { // Small security check trying to avoid (partially) malicious code... // sorry for the inconvenience when you hit this point... if (strchr(url, '\'') != NULL) { TRACELOG(LOG_WARNING, "SYSTEM: Provided URL is not valid"); } else { #if defined(PLATFORM_DESKTOP) char *cmd = (char *)RL_CALLOC(strlen(url) + 10, sizeof(char)); #if defined(_WIN32) sprintf(cmd, "explorer %s", url); #endif #if defined(__linux__) || defined(__FreeBSD__) sprintf(cmd, "xdg-open '%s'", url); // Alternatives: firefox, x-www-browser #endif #if defined(__APPLE__) sprintf(cmd, "open '%s'", url); #endif system(cmd); RL_FREE(cmd); #endif #if defined(PLATFORM_WEB) emscripten_run_script(TextFormat("window.open('%s', '_blank')", url)); #endif } } //---------------------------------------------------------------------------------- // Module Functions Definition - Input (Keyboard, Mouse, Gamepad) Functions //---------------------------------------------------------------------------------- // Detect if a key has been pressed once bool IsKeyPressed(int key) { bool pressed = false; if ((CORE.Input.Keyboard.previousKeyState[key] == 0) && (CORE.Input.Keyboard.currentKeyState[key] == 1)) pressed = true; else pressed = false; return pressed; } // Detect if a key is being pressed (key held down) bool IsKeyDown(int key) { if (CORE.Input.Keyboard.currentKeyState[key] == 1) return true; else return false; } // Detect if a key has been released once bool IsKeyReleased(int key) { bool released = false; if ((CORE.Input.Keyboard.previousKeyState[key] == 1) && (CORE.Input.Keyboard.currentKeyState[key] == 0)) released = true; else released = false; return released; } // Detect if a key is NOT being pressed (key not held down) bool IsKeyUp(int key) { if (CORE.Input.Keyboard.currentKeyState[key] == 0) return true; else return false; } // Get the last key pressed int GetKeyPressed(void) { int value = 0; if (CORE.Input.Keyboard.keyPressedQueueCount > 0) { // Get character from the queue head value = CORE.Input.Keyboard.keyPressedQueue[0]; // Shift elements 1 step toward the head. for (int i = 0; i < (CORE.Input.Keyboard.keyPressedQueueCount - 1); i++) CORE.Input.Keyboard.keyPressedQueue[i] = CORE.Input.Keyboard.keyPressedQueue[i + 1]; // Reset last character in the queue CORE.Input.Keyboard.keyPressedQueue[CORE.Input.Keyboard.keyPressedQueueCount] = 0; CORE.Input.Keyboard.keyPressedQueueCount--; } return value; } // Get the last char pressed int GetCharPressed(void) { int value = 0; if (CORE.Input.Keyboard.charPressedQueueCount > 0) { // Get character from the queue head value = CORE.Input.Keyboard.charPressedQueue[0]; // Shift elements 1 step toward the head. for (int i = 0; i < (CORE.Input.Keyboard.charPressedQueueCount - 1); i++) CORE.Input.Keyboard.charPressedQueue[i] = CORE.Input.Keyboard.charPressedQueue[i + 1]; // Reset last character in the queue CORE.Input.Keyboard.charPressedQueue[CORE.Input.Keyboard.charPressedQueueCount] = 0; CORE.Input.Keyboard.charPressedQueueCount--; } return value; } // Set a custom key to exit program // NOTE: default exitKey is ESCAPE void SetExitKey(int key) { #if !defined(PLATFORM_ANDROID) CORE.Input.Keyboard.exitKey = key; #endif } // NOTE: Gamepad support not implemented in emscripten GLFW3 (PLATFORM_WEB) // Detect if a gamepad is available bool IsGamepadAvailable(int gamepad) { bool result = false; if ((gamepad < MAX_GAMEPADS) && CORE.Input.Gamepad.ready[gamepad]) result = true; return result; } // Check gamepad name (if available) bool IsGamepadName(int gamepad, const char *name) { bool result = false; const char *currentName = NULL; if (CORE.Input.Gamepad.ready[gamepad]) currentName = GetGamepadName(gamepad); if ((name != NULL) && (currentName != NULL)) result = (strcmp(name, currentName) == 0); return result; } // Return gamepad internal name id const char *GetGamepadName(int gamepad) { #if defined(PLATFORM_DESKTOP) if (CORE.Input.Gamepad.ready[gamepad]) return glfwGetJoystickName(gamepad); else return NULL; #endif #if defined(PLATFORM_RPI) || defined(PLATFORM_DRM) if (CORE.Input.Gamepad.ready[gamepad]) ioctl(CORE.Input.Gamepad.streamId[gamepad], JSIOCGNAME(64), &CORE.Input.Gamepad.name); return CORE.Input.Gamepad.name; #endif return NULL; } // Return gamepad axis count int GetGamepadAxisCount(int gamepad) { #if defined(PLATFORM_RPI) || defined(PLATFORM_DRM) int axisCount = 0; if (CORE.Input.Gamepad.ready[gamepad]) ioctl(CORE.Input.Gamepad.streamId[gamepad], JSIOCGAXES, &axisCount); CORE.Input.Gamepad.axisCount = axisCount; #endif return CORE.Input.Gamepad.axisCount; } // Return axis movement vector for a gamepad float GetGamepadAxisMovement(int gamepad, int axis) { float value = 0; if ((gamepad < MAX_GAMEPADS) && CORE.Input.Gamepad.ready[gamepad] && (axis < MAX_GAMEPAD_AXIS) && (fabsf(CORE.Input.Gamepad.axisState[gamepad][axis]) > 0.1f)) value = CORE.Input.Gamepad.axisState[gamepad][axis]; // 0.1f = GAMEPAD_AXIS_MINIMUM_DRIFT/DELTA return value; } // Detect if a gamepad button has been pressed once bool IsGamepadButtonPressed(int gamepad, int button) { bool pressed = false; if ((gamepad < MAX_GAMEPADS) && CORE.Input.Gamepad.ready[gamepad] && (button < MAX_GAMEPAD_BUTTONS) && (CORE.Input.Gamepad.previousState[gamepad][button] == 0) && (CORE.Input.Gamepad.currentState[gamepad][button] == 1)) pressed = true; else pressed = false; return pressed; } // Detect if a gamepad button is being pressed bool IsGamepadButtonDown(int gamepad, int button) { bool result = false; if ((gamepad < MAX_GAMEPADS) && CORE.Input.Gamepad.ready[gamepad] && (button < MAX_GAMEPAD_BUTTONS) && (CORE.Input.Gamepad.currentState[gamepad][button] == 1)) result = true; return result; } // Detect if a gamepad button has NOT been pressed once bool IsGamepadButtonReleased(int gamepad, int button) { bool released = false; if ((gamepad < MAX_GAMEPADS) && CORE.Input.Gamepad.ready[gamepad] && (button < MAX_GAMEPAD_BUTTONS) && (CORE.Input.Gamepad.previousState[gamepad][button] == 1) && (CORE.Input.Gamepad.currentState[gamepad][button] == 0)) released = true; else released = false; return released; } // Detect if a gamepad button is NOT being pressed bool IsGamepadButtonUp(int gamepad, int button) { bool result = false; if ((gamepad < MAX_GAMEPADS) && CORE.Input.Gamepad.ready[gamepad] && (button < MAX_GAMEPAD_BUTTONS) && (CORE.Input.Gamepad.currentState[gamepad][button] == 0)) result = true; return result; } // Get the last gamepad button pressed int GetGamepadButtonPressed(void) { return CORE.Input.Gamepad.lastButtonPressed; } // Set internal gamepad mappings int SetGamepadMappings(const char *mappings) { int result = 0; #if defined(PLATFORM_DESKTOP) result = glfwUpdateGamepadMappings(mappings); #endif return result; } // Detect if a mouse button has been pressed once bool IsMouseButtonPressed(int button) { bool pressed = false; if ((CORE.Input.Mouse.currentButtonState[button] == 1) && (CORE.Input.Mouse.previousButtonState[button] == 0)) pressed = true; // Map touches to mouse buttons checking if ((CORE.Input.Touch.currentTouchState[button] == 1) && (CORE.Input.Touch.previousTouchState[button] == 0)) pressed = true; return pressed; } // Detect if a mouse button is being pressed bool IsMouseButtonDown(int button) { bool down = false; if (CORE.Input.Mouse.currentButtonState[button] == 1) down = true; // Map touches to mouse buttons checking if (CORE.Input.Touch.currentTouchState[button] == 1) down = true; return down; } // Detect if a mouse button has been released once bool IsMouseButtonReleased(int button) { bool released = false; if ((CORE.Input.Mouse.currentButtonState[button] == 0) && (CORE.Input.Mouse.previousButtonState[button] == 1)) released = true; // Map touches to mouse buttons checking if ((CORE.Input.Touch.currentTouchState[button] == 0) && (CORE.Input.Touch.previousTouchState[button] == 1)) released = true; return released; } // Detect if a mouse button is NOT being pressed bool IsMouseButtonUp(int button) { return !IsMouseButtonDown(button); } // Returns mouse position X int GetMouseX(void) { #if defined(PLATFORM_ANDROID) return (int)CORE.Input.Touch.position[0].x; #else return (int)((CORE.Input.Mouse.position.x + CORE.Input.Mouse.offset.x)*CORE.Input.Mouse.scale.x); #endif } // Returns mouse position Y int GetMouseY(void) { #if defined(PLATFORM_ANDROID) return (int)CORE.Input.Touch.position[0].y; #else return (int)((CORE.Input.Mouse.position.y + CORE.Input.Mouse.offset.y)*CORE.Input.Mouse.scale.y); #endif } // Returns mouse position XY Vector2 GetMousePosition(void) { Vector2 position = { 0 }; #if defined(PLATFORM_ANDROID) || defined(PLATFORM_WEB) position = GetTouchPosition(0); #else position.x = (CORE.Input.Mouse.position.x + CORE.Input.Mouse.offset.x)*CORE.Input.Mouse.scale.x; position.y = (CORE.Input.Mouse.position.y + CORE.Input.Mouse.offset.y)*CORE.Input.Mouse.scale.y; #endif return position; } // Set mouse position XY void SetMousePosition(int x, int y) { CORE.Input.Mouse.position = (Vector2){ (float)x, (float)y }; #if defined(PLATFORM_DESKTOP) || defined(PLATFORM_WEB) // NOTE: emscripten not implemented glfwSetCursorPos(CORE.Window.handle, CORE.Input.Mouse.position.x, CORE.Input.Mouse.position.y); #endif #if defined(PLATFORM_UWP) UWPGetMouseSetPosFunc()(x, y); #endif } // Set mouse offset // NOTE: Useful when rendering to different size targets void SetMouseOffset(int offsetX, int offsetY) { CORE.Input.Mouse.offset = (Vector2){ (float)offsetX, (float)offsetY }; } // Set mouse scaling // NOTE: Useful when rendering to different size targets void SetMouseScale(float scaleX, float scaleY) { CORE.Input.Mouse.scale = (Vector2){ scaleX, scaleY }; } // Returns mouse wheel movement Y float GetMouseWheelMove(void) { #if defined(PLATFORM_ANDROID) return 0.0f; #endif #if defined(PLATFORM_WEB) return CORE.Input.Mouse.previousWheelMove/100.0f; #endif return CORE.Input.Mouse.previousWheelMove; } // Set mouse cursor // NOTE: This is a no-op on platforms other than PLATFORM_DESKTOP void SetMouseCursor(int cursor) { #if defined(PLATFORM_DESKTOP) CORE.Input.Mouse.cursor = cursor; if (cursor == MOUSE_CURSOR_DEFAULT) glfwSetCursor(CORE.Window.handle, NULL); else { // NOTE: We are relating internal GLFW enum values to our MouseCursor enum values glfwSetCursor(CORE.Window.handle, glfwCreateStandardCursor(0x00036000 + cursor)); } #endif } // Returns touch position X for touch point 0 (relative to screen size) int GetTouchX(void) { #if defined(PLATFORM_ANDROID) || defined(PLATFORM_WEB) || defined(PLATFORM_UWP) return (int)CORE.Input.Touch.position[0].x; #else // PLATFORM_DESKTOP, PLATFORM_RPI, PLATFORM_DRM return GetMouseX(); #endif } // Returns touch position Y for touch point 0 (relative to screen size) int GetTouchY(void) { #if defined(PLATFORM_ANDROID) || defined(PLATFORM_WEB) || defined(PLATFORM_UWP) return (int)CORE.Input.Touch.position[0].y; #else // PLATFORM_DESKTOP, PLATFORM_RPI, PLATFORM_DRM return GetMouseY(); #endif } // Returns touch position XY for a touch point index (relative to screen size) // TODO: Touch position should be scaled depending on display size and render size Vector2 GetTouchPosition(int index) { Vector2 position = { -1.0f, -1.0f }; #if defined(PLATFORM_DESKTOP) // TODO: GLFW does not support multi-touch input just yet // https://www.codeproject.com/Articles/668404/Programming-for-Multi-Touch // https://docs.microsoft.com/en-us/windows/win32/wintouch/getting-started-with-multi-touch-messages if (index == 0) position = GetMousePosition(); #endif #if defined(PLATFORM_ANDROID) if (index < MAX_TOUCH_POINTS) position = CORE.Input.Touch.position[index]; else TRACELOG(LOG_WARNING, "INPUT: Required touch point out of range (Max touch points: %i)", MAX_TOUCH_POINTS); if ((CORE.Window.screen.width > CORE.Window.display.width) || (CORE.Window.screen.height > CORE.Window.display.height)) { position.x = position.x*((float)CORE.Window.screen.width/(float)(CORE.Window.display.width - CORE.Window.renderOffset.x)) - CORE.Window.renderOffset.x/2; position.y = position.y*((float)CORE.Window.screen.height/(float)(CORE.Window.display.height - CORE.Window.renderOffset.y)) - CORE.Window.renderOffset.y/2; } else { position.x = position.x*((float)CORE.Window.render.width/(float)CORE.Window.display.width) - CORE.Window.renderOffset.x/2; position.y = position.y*((float)CORE.Window.render.height/(float)CORE.Window.display.height) - CORE.Window.renderOffset.y/2; } #endif #if defined(PLATFORM_WEB) || defined(PLATFORM_RPI) || defined(PLATFORM_DRM) || defined(PLATFORM_UWP) if (index < MAX_TOUCH_POINTS) position = CORE.Input.Touch.position[index]; else TRACELOG(LOG_WARNING, "INPUT: Required touch point out of range (Max touch points: %i)", MAX_TOUCH_POINTS); // TODO: Touch position scaling required? #endif return position; } //---------------------------------------------------------------------------------- // Module specific Functions Definition //---------------------------------------------------------------------------------- // Initialize display device and framebuffer // NOTE: width and height represent the screen (framebuffer) desired size, not actual display size // If width or height are 0, default display size will be used for framebuffer size // NOTE: returns false in case graphic device could not be created static bool InitGraphicsDevice(int width, int height) { CORE.Window.screen.width = width; // User desired width CORE.Window.screen.height = height; // User desired height CORE.Window.screenScale = MatrixIdentity(); // No draw scaling required by default // NOTE: Framebuffer (render area - CORE.Window.render.width, CORE.Window.render.height) could include black bars... // ...in top-down or left-right to match display aspect ratio (no weird scalings) #if defined(PLATFORM_DESKTOP) || defined(PLATFORM_WEB) glfwSetErrorCallback(ErrorCallback); #if defined(__APPLE__) glfwInitHint(GLFW_COCOA_CHDIR_RESOURCES, GLFW_FALSE); #endif if (!glfwInit()) { TRACELOG(LOG_WARNING, "GLFW: Failed to initialize GLFW"); return false; } // NOTE: Getting video modes is not implemented in emscripten GLFW3 version #if defined(PLATFORM_DESKTOP) // Find monitor resolution GLFWmonitor *monitor = glfwGetPrimaryMonitor(); if (!monitor) { TRACELOG(LOG_WARNING, "GLFW: Failed to get primary monitor"); return false; } const GLFWvidmode *mode = glfwGetVideoMode(monitor); CORE.Window.display.width = mode->width; CORE.Window.display.height = mode->height; // Screen size security check if (CORE.Window.screen.width == 0) CORE.Window.screen.width = CORE.Window.display.width; if (CORE.Window.screen.height == 0) CORE.Window.screen.height = CORE.Window.display.height; #endif // PLATFORM_DESKTOP #if defined(PLATFORM_WEB) CORE.Window.display.width = CORE.Window.screen.width; CORE.Window.display.height = CORE.Window.screen.height; #endif // PLATFORM_WEB glfwDefaultWindowHints(); // Set default windows hints //glfwWindowHint(GLFW_RED_BITS, 8); // Framebuffer red color component bits //glfwWindowHint(GLFW_GREEN_BITS, 8); // Framebuffer green color component bits //glfwWindowHint(GLFW_BLUE_BITS, 8); // Framebuffer blue color component bits //glfwWindowHint(GLFW_ALPHA_BITS, 8); // Framebuffer alpha color component bits //glfwWindowHint(GLFW_DEPTH_BITS, 24); // Depthbuffer bits //glfwWindowHint(GLFW_REFRESH_RATE, 0); // Refresh rate for fullscreen window //glfwWindowHint(GLFW_CLIENT_API, GLFW_OPENGL_API); // OpenGL API to use. Alternative: GLFW_OPENGL_ES_API //glfwWindowHint(GLFW_AUX_BUFFERS, 0); // Number of auxiliar buffers // Check window creation flags if ((CORE.Window.flags & FLAG_FULLSCREEN_MODE) > 0) CORE.Window.fullscreen = true; if ((CORE.Window.flags & FLAG_WINDOW_HIDDEN) > 0) glfwWindowHint(GLFW_VISIBLE, GLFW_FALSE); // Visible window else glfwWindowHint(GLFW_VISIBLE, GLFW_TRUE); // Window initially hidden if ((CORE.Window.flags & FLAG_WINDOW_UNDECORATED) > 0) glfwWindowHint(GLFW_DECORATED, GLFW_FALSE); // Border and buttons on Window else glfwWindowHint(GLFW_DECORATED, GLFW_TRUE); // Decorated window if ((CORE.Window.flags & FLAG_WINDOW_RESIZABLE) > 0) glfwWindowHint(GLFW_RESIZABLE, GLFW_TRUE); // Resizable window else glfwWindowHint(GLFW_RESIZABLE, GLFW_FALSE); // Avoid window being resizable // Disable FLAG_WINDOW_MINIMIZED, not supported on initialization if ((CORE.Window.flags & FLAG_WINDOW_MINIMIZED) > 0) CORE.Window.flags &= ~FLAG_WINDOW_MINIMIZED; // Disable FLAG_WINDOW_MAXIMIZED, not supported on initialization if ((CORE.Window.flags & FLAG_WINDOW_MAXIMIZED) > 0) CORE.Window.flags &= ~FLAG_WINDOW_MAXIMIZED; if ((CORE.Window.flags & FLAG_WINDOW_UNFOCUSED) > 0) glfwWindowHint(GLFW_FOCUSED, GLFW_FALSE); else glfwWindowHint(GLFW_FOCUSED, GLFW_TRUE); if ((CORE.Window.flags & FLAG_WINDOW_TOPMOST) > 0) glfwWindowHint(GLFW_FLOATING, GLFW_TRUE); else glfwWindowHint(GLFW_FLOATING, GLFW_FALSE); // NOTE: Some GLFW flags are not supported on HTML5 #if defined(PLATFORM_DESKTOP) if ((CORE.Window.flags & FLAG_WINDOW_TRANSPARENT) > 0) glfwWindowHint(GLFW_TRANSPARENT_FRAMEBUFFER, GLFW_TRUE); // Transparent framebuffer else glfwWindowHint(GLFW_TRANSPARENT_FRAMEBUFFER, GLFW_FALSE); // Opaque framebuffer if ((CORE.Window.flags & FLAG_WINDOW_HIGHDPI) > 0) { // Resize window content area based on the monitor content scale. // NOTE: This hint only has an effect on platforms where screen coordinates and pixels always map 1:1 such as Windows and X11. // On platforms like macOS the resolution of the framebuffer is changed independently of the window size. glfwWindowHint(GLFW_SCALE_TO_MONITOR, GLFW_TRUE); // Scale content area based on the monitor content scale where window is placed on #if defined(__APPLE__) glfwWindowHint(GLFW_COCOA_RETINA_FRAMEBUFFER, GLFW_TRUE); #endif } else glfwWindowHint(GLFW_SCALE_TO_MONITOR, GLFW_FALSE); #endif if (CORE.Window.flags & FLAG_MSAA_4X_HINT) { // NOTE: MSAA is only enabled for main framebuffer, not user-created FBOs TRACELOG(LOG_INFO, "DISPLAY: Trying to enable MSAA x4"); glfwWindowHint(GLFW_SAMPLES, 4); // Tries to enable multisampling x4 (MSAA), default is 0 } // NOTE: When asking for an OpenGL context version, most drivers provide highest supported version // with forward compatibility to older OpenGL versions. // For example, if using OpenGL 1.1, driver can provide a 4.3 context forward compatible. // Check selection OpenGL version if (rlGetVersion() == OPENGL_21) { glfwWindowHint(GLFW_CONTEXT_VERSION_MAJOR, 2); // Choose OpenGL major version (just hint) glfwWindowHint(GLFW_CONTEXT_VERSION_MINOR, 1); // Choose OpenGL minor version (just hint) } else if (rlGetVersion() == OPENGL_33) { glfwWindowHint(GLFW_CONTEXT_VERSION_MAJOR, 3); // Choose OpenGL major version (just hint) glfwWindowHint(GLFW_CONTEXT_VERSION_MINOR, 3); // Choose OpenGL minor version (just hint) glfwWindowHint(GLFW_OPENGL_PROFILE, GLFW_OPENGL_CORE_PROFILE); // Profiles Hint: Only 3.3 and above! // Values: GLFW_OPENGL_CORE_PROFILE, GLFW_OPENGL_ANY_PROFILE, GLFW_OPENGL_COMPAT_PROFILE #if defined(__APPLE__) glfwWindowHint(GLFW_OPENGL_FORWARD_COMPAT, GLFW_TRUE); // OSX Requires fordward compatibility #else glfwWindowHint(GLFW_OPENGL_FORWARD_COMPAT, GLFW_FALSE); // Fordward Compatibility Hint: Only 3.3 and above! #endif //glfwWindowHint(GLFW_OPENGL_DEBUG_CONTEXT, GLFW_TRUE); // Request OpenGL DEBUG context } else if (rlGetVersion() == OPENGL_ES_20) // Request OpenGL ES 2.0 context { glfwWindowHint(GLFW_CONTEXT_VERSION_MAJOR, 2); glfwWindowHint(GLFW_CONTEXT_VERSION_MINOR, 0); glfwWindowHint(GLFW_CLIENT_API, GLFW_OPENGL_ES_API); #if defined(PLATFORM_DESKTOP) glfwWindowHint(GLFW_CONTEXT_CREATION_API, GLFW_EGL_CONTEXT_API); #else glfwWindowHint(GLFW_CONTEXT_CREATION_API, GLFW_NATIVE_CONTEXT_API); #endif } #if defined(PLATFORM_DESKTOP) // NOTE: GLFW 3.4+ defers initialization of the Joystick subsystem on the first call to any Joystick related functions. // Forcing this initialization here avoids doing it on `PollInputEvents` called by `EndDrawing` after first frame has been just drawn. // The initialization will still happen and possible delays still occur, but before the window is shown, which is a nicer experience. // REF: https://github.com/raysan5/raylib/issues/1554 if (MAX_GAMEPADS > 0) glfwSetJoystickCallback(NULL); #endif if (CORE.Window.fullscreen) { // remember center for switchinging from fullscreen to window CORE.Window.position.x = CORE.Window.display.width/2 - CORE.Window.screen.width/2; CORE.Window.position.y = CORE.Window.display.height/2 - CORE.Window.screen.height/2; if (CORE.Window.position.x < 0) CORE.Window.position.x = 0; if (CORE.Window.position.y < 0) CORE.Window.position.y = 0; // Obtain recommended CORE.Window.display.width/CORE.Window.display.height from a valid videomode for the monitor int count = 0; const GLFWvidmode *modes = glfwGetVideoModes(glfwGetPrimaryMonitor(), &count); // Get closest video mode to desired CORE.Window.screen.width/CORE.Window.screen.height for (int i = 0; i < count; i++) { if ((unsigned int)modes[i].width >= CORE.Window.screen.width) { if ((unsigned int)modes[i].height >= CORE.Window.screen.height) { CORE.Window.display.width = modes[i].width; CORE.Window.display.height = modes[i].height; break; } } } #if defined(PLATFORM_DESKTOP) // If we are windowed fullscreen, ensures that window does not minimize when focus is lost if ((CORE.Window.screen.height == CORE.Window.display.height) && (CORE.Window.screen.width == CORE.Window.display.width)) { glfwWindowHint(GLFW_AUTO_ICONIFY, 0); } #endif TRACELOG(LOG_WARNING, "SYSTEM: Closest fullscreen videomode: %i x %i", CORE.Window.display.width, CORE.Window.display.height); // NOTE: ISSUE: Closest videomode could not match monitor aspect-ratio, for example, // for a desired screen size of 800x450 (16:9), closest supported videomode is 800x600 (4:3), // framebuffer is rendered correctly but once displayed on a 16:9 monitor, it gets stretched // by the sides to fit all monitor space... // Try to setup the most appropiate fullscreen framebuffer for the requested screenWidth/screenHeight // It considers device display resolution mode and setups a framebuffer with black bars if required (render size/offset) // Modified global variables: CORE.Window.screen.width/CORE.Window.screen.height - CORE.Window.render.width/CORE.Window.render.height - CORE.Window.renderOffset.x/CORE.Window.renderOffset.y - CORE.Window.screenScale // TODO: It is a quite cumbersome solution to display size vs requested size, it should be reviewed or removed... // HighDPI monitors are properly considered in a following similar function: SetupViewport() SetupFramebuffer(CORE.Window.display.width, CORE.Window.display.height); CORE.Window.handle = glfwCreateWindow(CORE.Window.display.width, CORE.Window.display.height, (CORE.Window.title != 0)? CORE.Window.title : " ", glfwGetPrimaryMonitor(), NULL); // NOTE: Full-screen change, not working properly... //glfwSetWindowMonitor(CORE.Window.handle, glfwGetPrimaryMonitor(), 0, 0, CORE.Window.screen.width, CORE.Window.screen.height, GLFW_DONT_CARE); } else { // No-fullscreen window creation CORE.Window.handle = glfwCreateWindow(CORE.Window.screen.width, CORE.Window.screen.height, (CORE.Window.title != 0)? CORE.Window.title : " ", NULL, NULL); if (CORE.Window.handle) { #if defined(PLATFORM_DESKTOP) // Center window on screen int windowPosX = CORE.Window.display.width/2 - CORE.Window.screen.width/2; int windowPosY = CORE.Window.display.height/2 - CORE.Window.screen.height/2; if (windowPosX < 0) windowPosX = 0; if (windowPosY < 0) windowPosY = 0; glfwSetWindowPos(CORE.Window.handle, windowPosX, windowPosY); #endif CORE.Window.render.width = CORE.Window.screen.width; CORE.Window.render.height = CORE.Window.screen.height; } } if (!CORE.Window.handle) { glfwTerminate(); TRACELOG(LOG_WARNING, "GLFW: Failed to initialize Window"); return false; } else { TRACELOG(LOG_INFO, "DISPLAY: Device initialized successfully"); #if defined(PLATFORM_DESKTOP) TRACELOG(LOG_INFO, " > Display size: %i x %i", CORE.Window.display.width, CORE.Window.display.height); #endif TRACELOG(LOG_INFO, " > Render size: %i x %i", CORE.Window.render.width, CORE.Window.render.height); TRACELOG(LOG_INFO, " > Screen size: %i x %i", CORE.Window.screen.width, CORE.Window.screen.height); TRACELOG(LOG_INFO, " > Viewport offsets: %i, %i", CORE.Window.renderOffset.x, CORE.Window.renderOffset.y); } // Set window callback events glfwSetWindowSizeCallback(CORE.Window.handle, WindowSizeCallback); // NOTE: Resizing not allowed by default! #if !defined(PLATFORM_WEB) glfwSetWindowMaximizeCallback(CORE.Window.handle, WindowMaximizeCallback); #endif glfwSetWindowIconifyCallback(CORE.Window.handle, WindowIconifyCallback); glfwSetWindowFocusCallback(CORE.Window.handle, WindowFocusCallback); glfwSetDropCallback(CORE.Window.handle, WindowDropCallback); // Set input callback events glfwSetKeyCallback(CORE.Window.handle, KeyCallback); glfwSetCharCallback(CORE.Window.handle, CharCallback); glfwSetMouseButtonCallback(CORE.Window.handle, MouseButtonCallback); glfwSetCursorPosCallback(CORE.Window.handle, MouseCursorPosCallback); // Track mouse position changes glfwSetScrollCallback(CORE.Window.handle, MouseScrollCallback); glfwSetCursorEnterCallback(CORE.Window.handle, CursorEnterCallback); glfwMakeContextCurrent(CORE.Window.handle); #if !defined(PLATFORM_WEB) glfwSwapInterval(0); // No V-Sync by default #endif // Try to enable GPU V-Sync, so frames are limited to screen refresh rate (60Hz -> 60 FPS) // NOTE: V-Sync can be enabled by graphic driver configuration if (CORE.Window.flags & FLAG_VSYNC_HINT) { // WARNING: It seems to hits a critical render path in Intel HD Graphics glfwSwapInterval(1); TRACELOG(LOG_INFO, "DISPLAY: Trying to enable VSYNC"); } #endif // PLATFORM_DESKTOP || PLATFORM_WEB #if defined(PLATFORM_ANDROID) || defined(PLATFORM_RPI) || defined(PLATFORM_DRM) || defined(PLATFORM_UWP) CORE.Window.fullscreen = true; CORE.Window.flags &= FLAG_FULLSCREEN_MODE; #if defined(PLATFORM_RPI) bcm_host_init(); DISPMANX_ELEMENT_HANDLE_T dispmanElement; DISPMANX_DISPLAY_HANDLE_T dispmanDisplay; DISPMANX_UPDATE_HANDLE_T dispmanUpdate; VC_RECT_T dstRect; VC_RECT_T srcRect; #endif #if defined(PLATFORM_DRM) CORE.Window.fd = -1; CORE.Window.connector = NULL; CORE.Window.modeIndex = -1; CORE.Window.crtc = NULL; CORE.Window.gbmDevice = NULL; CORE.Window.gbmSurface = NULL; CORE.Window.prevBO = NULL; CORE.Window.prevFB = 0; #if defined(DEFAULT_GRAPHIC_DEVICE_DRM) CORE.Window.fd = open(DEFAULT_GRAPHIC_DEVICE_DRM, O_RDWR); #else TRACELOG(LOG_INFO, "DISPLAY: No graphic card set, trying card1"); CORE.Window.fd = open("/dev/dri/card1", O_RDWR); // VideoCore VI (Raspberry Pi 4) if ((-1 == CORE.Window.fd) || (drmModeGetResources(CORE.Window.fd) == NULL)) { TRACELOG(LOG_INFO, "DISPLAY: Failed to open graphic card1, trying card0"); CORE.Window.fd = open("/dev/dri/card0", O_RDWR); // VideoCore IV (Raspberry Pi 1-3) } #endif if (-1 == CORE.Window.fd) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to open graphic card"); return false; } drmModeRes *res = drmModeGetResources(CORE.Window.fd); if (!res) { TRACELOG(LOG_WARNING, "DISPLAY: Failed get DRM resources"); return false; } TRACELOG(LOG_TRACE, "DISPLAY: Connectors found: %i", res->count_connectors); for (size_t i = 0; i < res->count_connectors; i++) { TRACELOG(LOG_TRACE, "DISPLAY: Connector index %i", i); drmModeConnector *con = drmModeGetConnector(CORE.Window.fd, res->connectors[i]); TRACELOG(LOG_TRACE, "DISPLAY: Connector modes detected: %i", con->count_modes); if ((con->connection == DRM_MODE_CONNECTED) && (con->encoder_id)) { TRACELOG(LOG_TRACE, "DISPLAY: DRM mode connected"); CORE.Window.connector = con; break; } else { TRACELOG(LOG_TRACE, "DISPLAY: DRM mode NOT connected (deleting)"); drmModeFreeConnector(con); } } if (!CORE.Window.connector) { TRACELOG(LOG_WARNING, "DISPLAY: No suitable DRM connector found"); drmModeFreeResources(res); return false; } drmModeEncoder *enc = drmModeGetEncoder(CORE.Window.fd, CORE.Window.connector->encoder_id); if (!enc) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to get DRM mode encoder"); drmModeFreeResources(res); return false; } CORE.Window.crtc = drmModeGetCrtc(CORE.Window.fd, enc->crtc_id); if (!CORE.Window.crtc) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to get DRM mode crtc"); drmModeFreeEncoder(enc); drmModeFreeResources(res); return false; } // If InitWindow should use the current mode find it in the connector's mode list if ((CORE.Window.screen.width <= 0) || (CORE.Window.screen.height <= 0)) { TRACELOG(LOG_TRACE, "DISPLAY: Selecting DRM connector mode for current used mode..."); CORE.Window.modeIndex = FindMatchingConnectorMode(CORE.Window.connector, &CORE.Window.crtc->mode); if (CORE.Window.modeIndex < 0) { TRACELOG(LOG_WARNING, "DISPLAY: No matching DRM connector mode found"); drmModeFreeEncoder(enc); drmModeFreeResources(res); return false; } CORE.Window.screen.width = CORE.Window.display.width; CORE.Window.screen.height = CORE.Window.display.height; } const bool allowInterlaced = CORE.Window.flags & FLAG_INTERLACED_HINT; const int fps = (CORE.Time.target > 0) ? (1.0/CORE.Time.target) : 60; // try to find an exact matching mode CORE.Window.modeIndex = FindExactConnectorMode(CORE.Window.connector, CORE.Window.screen.width, CORE.Window.screen.height, fps, allowInterlaced); // if nothing found, try to find a nearly matching mode if (CORE.Window.modeIndex < 0) CORE.Window.modeIndex = FindNearestConnectorMode(CORE.Window.connector, CORE.Window.screen.width, CORE.Window.screen.height, fps, allowInterlaced); // if nothing found, try to find an exactly matching mode including interlaced if (CORE.Window.modeIndex < 0) CORE.Window.modeIndex = FindExactConnectorMode(CORE.Window.connector, CORE.Window.screen.width, CORE.Window.screen.height, fps, true); // if nothing found, try to find a nearly matching mode including interlaced if (CORE.Window.modeIndex < 0) CORE.Window.modeIndex = FindNearestConnectorMode(CORE.Window.connector, CORE.Window.screen.width, CORE.Window.screen.height, fps, true); // if nothing found, there is no suitable mode if (CORE.Window.modeIndex < 0) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to find a suitable DRM connector mode"); drmModeFreeEncoder(enc); drmModeFreeResources(res); return false; } CORE.Window.display.width = CORE.Window.connector->modes[CORE.Window.modeIndex].hdisplay; CORE.Window.display.height = CORE.Window.connector->modes[CORE.Window.modeIndex].vdisplay; TRACELOG(LOG_INFO, "DISPLAY: Selected DRM connector mode %s (%ux%u%c@%u)", CORE.Window.connector->modes[CORE.Window.modeIndex].name, CORE.Window.connector->modes[CORE.Window.modeIndex].hdisplay, CORE.Window.connector->modes[CORE.Window.modeIndex].vdisplay, (CORE.Window.connector->modes[CORE.Window.modeIndex].flags & DRM_MODE_FLAG_INTERLACE) ? 'i' : 'p', CORE.Window.connector->modes[CORE.Window.modeIndex].vrefresh); // Use the width and height of the surface for render CORE.Window.render.width = CORE.Window.screen.width; CORE.Window.render.height = CORE.Window.screen.height; drmModeFreeEncoder(enc); enc = NULL; drmModeFreeResources(res); res = NULL; CORE.Window.gbmDevice = gbm_create_device(CORE.Window.fd); if (!CORE.Window.gbmDevice) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to create GBM device"); return false; } CORE.Window.gbmSurface = gbm_surface_create(CORE.Window.gbmDevice, CORE.Window.connector->modes[CORE.Window.modeIndex].hdisplay, CORE.Window.connector->modes[CORE.Window.modeIndex].vdisplay, GBM_FORMAT_ARGB8888, GBM_BO_USE_SCANOUT | GBM_BO_USE_RENDERING); if (!CORE.Window.gbmSurface) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to create GBM surface"); return false; } #endif EGLint samples = 0; EGLint sampleBuffer = 0; if (CORE.Window.flags & FLAG_MSAA_4X_HINT) { samples = 4; sampleBuffer = 1; TRACELOG(LOG_INFO, "DISPLAY: Trying to enable MSAA x4"); } const EGLint framebufferAttribs[] = { EGL_RENDERABLE_TYPE, EGL_OPENGL_ES2_BIT, // Type of context support -> Required on RPI? #if defined(PLATFORM_DRM) EGL_SURFACE_TYPE, EGL_WINDOW_BIT, // Don't use it on Android! #endif EGL_RED_SIZE, 8, // RED color bit depth (alternative: 5) EGL_GREEN_SIZE, 8, // GREEN color bit depth (alternative: 6) EGL_BLUE_SIZE, 8, // BLUE color bit depth (alternative: 5) #if defined(PLATFORM_DRM) EGL_ALPHA_SIZE, 8, // ALPHA bit depth (required for transparent framebuffer) #endif //EGL_TRANSPARENT_TYPE, EGL_NONE, // Request transparent framebuffer (EGL_TRANSPARENT_RGB does not work on RPI) EGL_DEPTH_SIZE, 16, // Depth buffer size (Required to use Depth testing!) //EGL_STENCIL_SIZE, 8, // Stencil buffer size EGL_SAMPLE_BUFFERS, sampleBuffer, // Activate MSAA EGL_SAMPLES, samples, // 4x Antialiasing if activated (Free on MALI GPUs) EGL_NONE }; const EGLint contextAttribs[] = { EGL_CONTEXT_CLIENT_VERSION, 2, EGL_NONE }; #if defined(PLATFORM_UWP) const EGLint surfaceAttributes[] = { // EGL_ANGLE_SURFACE_RENDER_TO_BACK_BUFFER is part of the same optimization as EGL_ANGLE_DISPLAY_ALLOW_RENDER_TO_BACK_BUFFER (see above). // If you have compilation issues with it then please update your Visual Studio templates. EGL_ANGLE_SURFACE_RENDER_TO_BACK_BUFFER, EGL_TRUE, EGL_NONE }; const EGLint defaultDisplayAttributes[] = { // These are the default display attributes, used to request ANGLE's D3D11 renderer. // eglInitialize will only succeed with these attributes if the hardware supports D3D11 Feature Level 10_0+. EGL_PLATFORM_ANGLE_TYPE_ANGLE, EGL_PLATFORM_ANGLE_TYPE_D3D11_ANGLE, // EGL_ANGLE_DISPLAY_ALLOW_RENDER_TO_BACK_BUFFER is an optimization that can have large performance benefits on mobile devices. // Its syntax is subject to change, though. Please update your Visual Studio templates if you experience compilation issues with it. EGL_ANGLE_DISPLAY_ALLOW_RENDER_TO_BACK_BUFFER, EGL_TRUE, // EGL_PLATFORM_ANGLE_ENABLE_AUTOMATIC_TRIM_ANGLE is an option that enables ANGLE to automatically call // the IDXGIDevice3::Trim method on behalf of the application when it gets suspended. // Calling IDXGIDevice3::Trim when an application is suspended is a Windows Store application certification requirement. EGL_PLATFORM_ANGLE_ENABLE_AUTOMATIC_TRIM_ANGLE, EGL_TRUE, EGL_NONE, }; const EGLint fl9_3DisplayAttributes[] = { // These can be used to request ANGLE's D3D11 renderer, with D3D11 Feature Level 9_3. // These attributes are used if the call to eglInitialize fails with the default display attributes. EGL_PLATFORM_ANGLE_TYPE_ANGLE, EGL_PLATFORM_ANGLE_TYPE_D3D11_ANGLE, EGL_PLATFORM_ANGLE_MAX_VERSION_MAJOR_ANGLE, 9, EGL_PLATFORM_ANGLE_MAX_VERSION_MINOR_ANGLE, 3, EGL_ANGLE_DISPLAY_ALLOW_RENDER_TO_BACK_BUFFER, EGL_TRUE, EGL_PLATFORM_ANGLE_ENABLE_AUTOMATIC_TRIM_ANGLE, EGL_TRUE, EGL_NONE, }; const EGLint warpDisplayAttributes[] = { // These attributes can be used to request D3D11 WARP. // They are used if eglInitialize fails with both the default display attributes and the 9_3 display attributes. EGL_PLATFORM_ANGLE_TYPE_ANGLE, EGL_PLATFORM_ANGLE_TYPE_D3D11_ANGLE, EGL_PLATFORM_ANGLE_DEVICE_TYPE_ANGLE, EGL_PLATFORM_ANGLE_DEVICE_TYPE_WARP_ANGLE, EGL_ANGLE_DISPLAY_ALLOW_RENDER_TO_BACK_BUFFER, EGL_TRUE, EGL_PLATFORM_ANGLE_ENABLE_AUTOMATIC_TRIM_ANGLE, EGL_TRUE, EGL_NONE, }; // eglGetPlatformDisplayEXT is an alternative to eglGetDisplay. It allows us to pass in display attributes, used to configure D3D11. PFNEGLGETPLATFORMDISPLAYEXTPROC eglGetPlatformDisplayEXT = (PFNEGLGETPLATFORMDISPLAYEXTPROC)(eglGetProcAddress("eglGetPlatformDisplayEXT")); if (!eglGetPlatformDisplayEXT) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to get function pointer: eglGetPlatformDisplayEXT()"); return false; } // // To initialize the display, we make three sets of calls to eglGetPlatformDisplayEXT and eglInitialize, with varying // parameters passed to eglGetPlatformDisplayEXT: // 1) The first calls uses "defaultDisplayAttributes" as a parameter. This corresponds to D3D11 Feature Level 10_0+. // 2) If eglInitialize fails for step 1 (e.g. because 10_0+ isn't supported by the default GPU), then we try again // using "fl9_3DisplayAttributes". This corresponds to D3D11 Feature Level 9_3. // 3) If eglInitialize fails for step 2 (e.g. because 9_3+ isn't supported by the default GPU), then we try again // using "warpDisplayAttributes". This corresponds to D3D11 Feature Level 11_0 on WARP, a D3D11 software rasterizer. // // This tries to initialize EGL to D3D11 Feature Level 10_0+. See above comment for details. CORE.Window.device = eglGetPlatformDisplayEXT(EGL_PLATFORM_ANGLE_ANGLE, EGL_DEFAULT_DISPLAY, defaultDisplayAttributes); if (CORE.Window.device == EGL_NO_DISPLAY) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to initialize EGL device"); return false; } if (eglInitialize(CORE.Window.device, NULL, NULL) == EGL_FALSE) { // This tries to initialize EGL to D3D11 Feature Level 9_3, if 10_0+ is unavailable (e.g. on some mobile devices). CORE.Window.device = eglGetPlatformDisplayEXT(EGL_PLATFORM_ANGLE_ANGLE, EGL_DEFAULT_DISPLAY, fl9_3DisplayAttributes); if (CORE.Window.device == EGL_NO_DISPLAY) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to initialize EGL device"); return false; } if (eglInitialize(CORE.Window.device, NULL, NULL) == EGL_FALSE) { // This initializes EGL to D3D11 Feature Level 11_0 on WARP, if 9_3+ is unavailable on the default GPU. CORE.Window.device = eglGetPlatformDisplayEXT(EGL_PLATFORM_ANGLE_ANGLE, EGL_DEFAULT_DISPLAY, warpDisplayAttributes); if (CORE.Window.device == EGL_NO_DISPLAY) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to initialize EGL device"); return false; } if (eglInitialize(CORE.Window.device, NULL, NULL) == EGL_FALSE) { // If all of the calls to eglInitialize returned EGL_FALSE then an error has occurred. TRACELOG(LOG_WARNING, "DISPLAY: Failed to initialize EGL device"); return false; } } } EGLint numConfigs = 0; if ((eglChooseConfig(CORE.Window.device, framebufferAttribs, &CORE.Window.config, 1, &numConfigs) == EGL_FALSE) || (numConfigs == 0)) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to choose first EGL configuration"); return false; } // Create a PropertySet and initialize with the EGLNativeWindowType. //PropertySet^ surfaceCreationProperties = ref new PropertySet(); //surfaceCreationProperties->Insert(ref new String(EGLNativeWindowTypeProperty), window); // CoreWindow^ window // You can configure the surface to render at a lower resolution and be scaled up to // the full window size. The scaling is often free on mobile hardware. // // One way to configure the SwapChainPanel is to specify precisely which resolution it should render at. // Size customRenderSurfaceSize = Size(800, 600); // surfaceCreationProperties->Insert(ref new String(EGLRenderSurfaceSizeProperty), PropertyValue::CreateSize(customRenderSurfaceSize)); // // Another way is to tell the SwapChainPanel to render at a certain scale factor compared to its size. // e.g. if the SwapChainPanel is 1920x1280 then setting a factor of 0.5f will make the app render at 960x640 // float customResolutionScale = 0.5f; // surfaceCreationProperties->Insert(ref new String(EGLRenderResolutionScaleProperty), PropertyValue::CreateSingle(customResolutionScale)); // eglCreateWindowSurface() requires a EGLNativeWindowType parameter, // In Windows platform: typedef HWND EGLNativeWindowType; // Property: EGLNativeWindowTypeProperty // Type: IInspectable // Description: Set this property to specify the window type to use for creating a surface. // If this property is missing, surface creation will fail. // //const wchar_t EGLNativeWindowTypeProperty[] = L"EGLNativeWindowTypeProperty"; //https://stackoverflow.com/questions/46550182/how-to-create-eglsurface-using-c-winrt-and-angle //CORE.Window.surface = eglCreateWindowSurface(CORE.Window.device, CORE.Window.config, reinterpret_cast(surfaceCreationProperties), surfaceAttributes); CORE.Window.surface = eglCreateWindowSurface(CORE.Window.device, CORE.Window.config, (EGLNativeWindowType) UWPGetCoreWindowPtr(), surfaceAttributes); if (CORE.Window.surface == EGL_NO_SURFACE) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to create EGL fullscreen surface"); return false; } CORE.Window.context = eglCreateContext(CORE.Window.device, CORE.Window.config, EGL_NO_CONTEXT, contextAttribs); if (CORE.Window.context == EGL_NO_CONTEXT) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to create EGL context"); return false; } // Get EGL device window size eglQuerySurface(CORE.Window.device, CORE.Window.surface, EGL_WIDTH, &CORE.Window.screen.width); eglQuerySurface(CORE.Window.device, CORE.Window.surface, EGL_HEIGHT, &CORE.Window.screen.height); // Get display size UWPGetDisplaySizeFunc()(&CORE.Window.display.width, &CORE.Window.display.height); // Use the width and height of the surface for render CORE.Window.render.width = CORE.Window.screen.width; CORE.Window.render.height = CORE.Window.screen.height; #endif // PLATFORM_UWP #if defined(PLATFORM_ANDROID) || defined(PLATFORM_RPI) || defined(PLATFORM_DRM) EGLint numConfigs = 0; // Get an EGL device connection #if defined(PLATFORM_DRM) CORE.Window.device = eglGetDisplay((EGLNativeDisplayType)CORE.Window.gbmDevice); #else CORE.Window.device = eglGetDisplay(EGL_DEFAULT_DISPLAY); #endif if (CORE.Window.device == EGL_NO_DISPLAY) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to initialize EGL device"); return false; } // Initialize the EGL device connection if (eglInitialize(CORE.Window.device, NULL, NULL) == EGL_FALSE) { // If all of the calls to eglInitialize returned EGL_FALSE then an error has occurred. TRACELOG(LOG_WARNING, "DISPLAY: Failed to initialize EGL device"); return false; } #if defined(PLATFORM_DRM) if (!eglChooseConfig(CORE.Window.device, NULL, NULL, 0, &numConfigs)) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to get EGL config count: 0x%x", eglGetError()); return false; } TRACELOG(LOG_TRACE, "DISPLAY: EGL configs available: %d", numConfigs); EGLConfig *configs = RL_CALLOC(numConfigs, sizeof(*configs)); if (!configs) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to get memory for EGL configs"); return false; } EGLint matchingNumConfigs = 0; if (!eglChooseConfig(CORE.Window.device, framebufferAttribs, configs, numConfigs, &matchingNumConfigs)) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to choose EGL config: 0x%x", eglGetError()); free(configs); return false; } TRACELOG(LOG_TRACE, "DISPLAY: EGL matching configs available: %d", matchingNumConfigs); // find the EGL config that matches the previously setup GBM format int found = 0; for (EGLint i = 0; i < matchingNumConfigs; ++i) { EGLint id = 0; if (!eglGetConfigAttrib(CORE.Window.device, configs[i], EGL_NATIVE_VISUAL_ID, &id)) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to get EGL config attribute: 0x%x", eglGetError()); continue; } if (GBM_FORMAT_ARGB8888 == id) { TRACELOG(LOG_TRACE, "DISPLAY: Using EGL config: %d", i); CORE.Window.config = configs[i]; found = 1; break; } } RL_FREE(configs); if (!found) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to find a suitable EGL config"); return false; } #else // Get an appropriate EGL framebuffer configuration eglChooseConfig(CORE.Window.device, framebufferAttribs, &CORE.Window.config, 1, &numConfigs); #endif // Set rendering API eglBindAPI(EGL_OPENGL_ES_API); // Create an EGL rendering context CORE.Window.context = eglCreateContext(CORE.Window.device, CORE.Window.config, EGL_NO_CONTEXT, contextAttribs); if (CORE.Window.context == EGL_NO_CONTEXT) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to create EGL context"); return false; } #endif // Create an EGL window surface //--------------------------------------------------------------------------------- #if defined(PLATFORM_ANDROID) EGLint displayFormat = 0; // EGL_NATIVE_VISUAL_ID is an attribute of the EGLConfig that is guaranteed to be accepted by ANativeWindow_setBuffersGeometry() // As soon as we picked a EGLConfig, we can safely reconfigure the ANativeWindow buffers to match, using EGL_NATIVE_VISUAL_ID eglGetConfigAttrib(CORE.Window.device, CORE.Window.config, EGL_NATIVE_VISUAL_ID, &displayFormat); // At this point we need to manage render size vs screen size // NOTE: This function use and modify global module variables: // -> CORE.Window.screen.width/CORE.Window.screen.height // -> CORE.Window.render.width/CORE.Window.render.height // -> CORE.Window.screenScale SetupFramebuffer(CORE.Window.display.width, CORE.Window.display.height); ANativeWindow_setBuffersGeometry(CORE.Android.app->window, CORE.Window.render.width, CORE.Window.render.height, displayFormat); //ANativeWindow_setBuffersGeometry(CORE.Android.app->window, 0, 0, displayFormat); // Force use of native display size CORE.Window.surface = eglCreateWindowSurface(CORE.Window.device, CORE.Window.config, CORE.Android.app->window, NULL); #endif // PLATFORM_ANDROID #if defined(PLATFORM_RPI) graphics_get_display_size(0, &CORE.Window.display.width, &CORE.Window.display.height); // Screen size security check if (CORE.Window.screen.width <= 0) CORE.Window.screen.width = CORE.Window.display.width; if (CORE.Window.screen.height <= 0) CORE.Window.screen.height = CORE.Window.display.height; // At this point we need to manage render size vs screen size // NOTE: This function use and modify global module variables: // -> CORE.Window.screen.width/CORE.Window.screen.height // -> CORE.Window.render.width/CORE.Window.render.height // -> CORE.Window.screenScale SetupFramebuffer(CORE.Window.display.width, CORE.Window.display.height); dstRect.x = 0; dstRect.y = 0; dstRect.width = CORE.Window.display.width; dstRect.height = CORE.Window.display.height; srcRect.x = 0; srcRect.y = 0; srcRect.width = CORE.Window.render.width << 16; srcRect.height = CORE.Window.render.height << 16; // NOTE: RPI dispmanx windowing system takes care of source rectangle scaling to destination rectangle by hardware (no cost) // Take care that renderWidth/renderHeight fit on displayWidth/displayHeight aspect ratio VC_DISPMANX_ALPHA_T alpha; alpha.flags = DISPMANX_FLAGS_ALPHA_FIXED_ALL_PIXELS; //alpha.flags = DISPMANX_FLAGS_ALPHA_FROM_SOURCE; // TODO: Allow transparent framebuffer! -> FLAG_WINDOW_TRANSPARENT alpha.opacity = 255; // Set transparency level for framebuffer, requires EGLAttrib: EGL_TRANSPARENT_TYPE alpha.mask = 0; dispmanDisplay = vc_dispmanx_display_open(0); // LCD dispmanUpdate = vc_dispmanx_update_start(0); dispmanElement = vc_dispmanx_element_add(dispmanUpdate, dispmanDisplay, 0/*layer*/, &dstRect, 0/*src*/, &srcRect, DISPMANX_PROTECTION_NONE, &alpha, 0/*clamp*/, DISPMANX_NO_ROTATE); CORE.Window.handle.element = dispmanElement; CORE.Window.handle.width = CORE.Window.render.width; CORE.Window.handle.height = CORE.Window.render.height; vc_dispmanx_update_submit_sync(dispmanUpdate); CORE.Window.surface = eglCreateWindowSurface(CORE.Window.device, CORE.Window.config, &CORE.Window.handle, NULL); const unsigned char *const renderer = glGetString(GL_RENDERER); if (renderer) TRACELOG(LOG_INFO, "DISPLAY: Renderer name is: %s", renderer); else TRACELOG(LOG_WARNING, "DISPLAY: Failed to get renderer name"); //--------------------------------------------------------------------------------- #endif // PLATFORM_RPI #if defined(PLATFORM_DRM) CORE.Window.surface = eglCreateWindowSurface(CORE.Window.device, CORE.Window.config, (EGLNativeWindowType)CORE.Window.gbmSurface, NULL); if (EGL_NO_SURFACE == CORE.Window.surface) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to create EGL window surface: 0x%04x", eglGetError()); return false; } // At this point we need to manage render size vs screen size // NOTE: This function use and modify global module variables: // -> CORE.Window.screen.width/CORE.Window.screen.height // -> CORE.Window.render.width/CORE.Window.render.height // -> CORE.Window.screenScale SetupFramebuffer(CORE.Window.display.width, CORE.Window.display.height); #endif // PLATFORM_DRM // There must be at least one frame displayed before the buffers are swapped //eglSwapInterval(CORE.Window.device, 1); if (eglMakeCurrent(CORE.Window.device, CORE.Window.surface, CORE.Window.surface, CORE.Window.context) == EGL_FALSE) { TRACELOG(LOG_WARNING, "DISPLAY: Failed to attach EGL rendering context to EGL surface"); return false; } else { TRACELOG(LOG_INFO, "DISPLAY: Device initialized successfully"); TRACELOG(LOG_INFO, " > Display size: %i x %i", CORE.Window.display.width, CORE.Window.display.height); TRACELOG(LOG_INFO, " > Render size: %i x %i", CORE.Window.render.width, CORE.Window.render.height); TRACELOG(LOG_INFO, " > Screen size: %i x %i", CORE.Window.screen.width, CORE.Window.screen.height); TRACELOG(LOG_INFO, " > Viewport offsets: %i, %i", CORE.Window.renderOffset.x, CORE.Window.renderOffset.y); } #endif // PLATFORM_ANDROID || PLATFORM_RPI || PLATFORM_DRM || PLATFORM_UWP // Load OpenGL extensions // NOTE: GLFW loader function is required by GLAD but only used for OpenGL 2.1 and 3.3, // OpenGL ES 2.0 extensions (and entry points) are loaded manually using eglGetProcAddress() rlLoadExtensions(glfwGetProcAddress); // Initialize OpenGL context (states and resources) // NOTE: CORE.Window.screen.width and CORE.Window.screen.height not used, just stored as globals in rlgl rlglInit(CORE.Window.screen.width, CORE.Window.screen.height); int fbWidth = CORE.Window.render.width; int fbHeight = CORE.Window.render.height; #if defined(PLATFORM_DESKTOP) if ((CORE.Window.flags & FLAG_WINDOW_HIGHDPI) > 0) { // NOTE: On APPLE platforms system should manage window/input scaling and also framebuffer scaling // Framebuffer scaling should be activated with: glfwWindowHint(GLFW_COCOA_RETINA_FRAMEBUFFER, GLFW_TRUE); #if !defined(__APPLE__) glfwGetFramebufferSize(CORE.Window.handle, &fbWidth, &fbHeight); // Screen scaling matrix is required in case desired screen area is different than display area CORE.Window.screenScale = MatrixScale((float)fbWidth/CORE.Window.screen.width, (float)fbHeight/CORE.Window.screen.height, 1.0f); // Mouse input scaling for the new screen size SetMouseScale((float)CORE.Window.screen.width/fbWidth, (float)CORE.Window.screen.height/fbHeight); #endif } #endif // Setup default viewport SetupViewport(fbWidth, fbHeight); CORE.Window.currentFbo.width = CORE.Window.screen.width; CORE.Window.currentFbo.height = CORE.Window.screen.height; ClearBackground(RAYWHITE); // Default background color for raylib games :P #if defined(PLATFORM_ANDROID) || defined(PLATFORM_UWP) CORE.Window.ready = true; #endif if ((CORE.Window.flags & FLAG_WINDOW_MINIMIZED) > 0) MinimizeWindow(); return true; } // Set viewport for a provided width and height static void SetupViewport(int width, int height) { CORE.Window.render.width = width; CORE.Window.render.height = height; // Set viewport width and height // NOTE: We consider render size (scaled) and offset in case black bars are required and // render area does not match full display area (this situation is only applicable on fullscreen mode) #if defined(__APPLE__) float xScale = 1.0f, yScale = 1.0f; glfwGetWindowContentScale(CORE.Window.handle, &xScale, &yScale); rlViewport(CORE.Window.renderOffset.x/2*xScale, CORE.Window.renderOffset.y/2*yScale, (CORE.Window.render.width - CORE.Window.renderOffset.x)*xScale, (CORE.Window.render.height - CORE.Window.renderOffset.y)*yScale); #else rlViewport(CORE.Window.renderOffset.x/2, CORE.Window.renderOffset.y/2, CORE.Window.render.width - CORE.Window.renderOffset.x, CORE.Window.render.height - CORE.Window.renderOffset.y); #endif rlMatrixMode(RL_PROJECTION); // Switch to projection matrix rlLoadIdentity(); // Reset current matrix (projection) // Set orthographic projection to current framebuffer size // NOTE: Configured top-left corner as (0, 0) rlOrtho(0, CORE.Window.render.width, CORE.Window.render.height, 0, 0.0f, 1.0f); rlMatrixMode(RL_MODELVIEW); // Switch back to modelview matrix rlLoadIdentity(); // Reset current matrix (modelview) } // Compute framebuffer size relative to screen size and display size // NOTE: Global variables CORE.Window.render.width/CORE.Window.render.height and CORE.Window.renderOffset.x/CORE.Window.renderOffset.y can be modified static void SetupFramebuffer(int width, int height) { // Calculate CORE.Window.render.width and CORE.Window.render.height, we have the display size (input params) and the desired screen size (global var) if ((CORE.Window.screen.width > CORE.Window.display.width) || (CORE.Window.screen.height > CORE.Window.display.height)) { TRACELOG(LOG_WARNING, "DISPLAY: Downscaling required: Screen size (%ix%i) is bigger than display size (%ix%i)", CORE.Window.screen.width, CORE.Window.screen.height, CORE.Window.display.width, CORE.Window.display.height); // Downscaling to fit display with border-bars float widthRatio = (float)CORE.Window.display.width/(float)CORE.Window.screen.width; float heightRatio = (float)CORE.Window.display.height/(float)CORE.Window.screen.height; if (widthRatio <= heightRatio) { CORE.Window.render.width = CORE.Window.display.width; CORE.Window.render.height = (int)round((float)CORE.Window.screen.height*widthRatio); CORE.Window.renderOffset.x = 0; CORE.Window.renderOffset.y = (CORE.Window.display.height - CORE.Window.render.height); } else { CORE.Window.render.width = (int)round((float)CORE.Window.screen.width*heightRatio); CORE.Window.render.height = CORE.Window.display.height; CORE.Window.renderOffset.x = (CORE.Window.display.width - CORE.Window.render.width); CORE.Window.renderOffset.y = 0; } // Screen scaling required float scaleRatio = (float)CORE.Window.render.width/(float)CORE.Window.screen.width; CORE.Window.screenScale = MatrixScale(scaleRatio, scaleRatio, 1.0f); // NOTE: We render to full display resolution! // We just need to calculate above parameters for downscale matrix and offsets CORE.Window.render.width = CORE.Window.display.width; CORE.Window.render.height = CORE.Window.display.height; TRACELOG(LOG_WARNING, "DISPLAY: Downscale matrix generated, content will be rendered at (%ix%i)", CORE.Window.render.width, CORE.Window.render.height); } else if ((CORE.Window.screen.width < CORE.Window.display.width) || (CORE.Window.screen.height < CORE.Window.display.height)) { // Required screen size is smaller than display size TRACELOG(LOG_INFO, "DISPLAY: Upscaling required: Screen size (%ix%i) smaller than display size (%ix%i)", CORE.Window.screen.width, CORE.Window.screen.height, CORE.Window.display.width, CORE.Window.display.height); if ((CORE.Window.screen.width == 0) || (CORE.Window.screen.height == 0)) { CORE.Window.screen.width = CORE.Window.display.width; CORE.Window.screen.height = CORE.Window.display.height; } // Upscaling to fit display with border-bars float displayRatio = (float)CORE.Window.display.width/(float)CORE.Window.display.height; float screenRatio = (float)CORE.Window.screen.width/(float)CORE.Window.screen.height; if (displayRatio <= screenRatio) { CORE.Window.render.width = CORE.Window.screen.width; CORE.Window.render.height = (int)round((float)CORE.Window.screen.width/displayRatio); CORE.Window.renderOffset.x = 0; CORE.Window.renderOffset.y = (CORE.Window.render.height - CORE.Window.screen.height); } else { CORE.Window.render.width = (int)round((float)CORE.Window.screen.height*displayRatio); CORE.Window.render.height = CORE.Window.screen.height; CORE.Window.renderOffset.x = (CORE.Window.render.width - CORE.Window.screen.width); CORE.Window.renderOffset.y = 0; } } else { CORE.Window.render.width = CORE.Window.screen.width; CORE.Window.render.height = CORE.Window.screen.height; CORE.Window.renderOffset.x = 0; CORE.Window.renderOffset.y = 0; } } // Initialize hi-resolution timer static void InitTimer(void) { srand((unsigned int)time(NULL)); // Initialize random seed // Setting a higher resolution can improve the accuracy of time-out intervals in wait functions. // However, it can also reduce overall system performance, because the thread scheduler switches tasks more often. // High resolutions can also prevent the CPU power management system from entering power-saving modes. // Setting a higher resolution does not improve the accuracy of the high-resolution performance counter. #if defined(_WIN32) && defined(SUPPORT_WINMM_HIGHRES_TIMER) && !defined(SUPPORT_BUSY_WAIT_LOOP) && !defined(PLATFORM_UWP) timeBeginPeriod(1); // Setup high-resolution timer to 1ms (granularity of 1-2 ms) #endif #if defined(PLATFORM_ANDROID) || defined(PLATFORM_RPI) || defined(PLATFORM_DRM) struct timespec now = { 0 }; if (clock_gettime(CLOCK_MONOTONIC, &now) == 0) // Success { CORE.Time.base = (unsigned long long int)now.tv_sec*1000000000LLU + (unsigned long long int)now.tv_nsec; } else TRACELOG(LOG_WARNING, "TIMER: Hi-resolution timer not available"); #endif CORE.Time.previous = GetTime(); // Get time as double } // Wait for some milliseconds (stop program execution) // NOTE: Sleep() granularity could be around 10 ms, it means, Sleep() could // take longer than expected... for that reason we use the busy wait loop // Ref: http://stackoverflow.com/questions/43057578/c-programming-win32-games-sleep-taking-longer-than-expected // Ref: http://www.geisswerks.com/ryan/FAQS/timing.html --> All about timming on Win32! static void Wait(float ms) { #if defined(PLATFORM_UWP) UWPGetSleepFunc()(ms/1000); return; #endif #if defined(SUPPORT_BUSY_WAIT_LOOP) double prevTime = GetTime(); double nextTime = 0.0; // Busy wait loop while ((nextTime - prevTime) < ms/1000.0f) nextTime = GetTime(); #else #if defined(SUPPORT_HALFBUSY_WAIT_LOOP) #define MAX_HALFBUSY_WAIT_TIME 4 double destTime = GetTime() + ms/1000; if (ms > MAX_HALFBUSY_WAIT_TIME) ms -= MAX_HALFBUSY_WAIT_TIME; #endif #if defined(_WIN32) Sleep((unsigned int)ms); #endif #if defined(__linux__) || defined(__FreeBSD__) || defined(__EMSCRIPTEN__) struct timespec req = { 0 }; time_t sec = (int)(ms/1000.0f); ms -= (sec*1000); req.tv_sec = sec; req.tv_nsec = ms*1000000L; // NOTE: Use nanosleep() on Unix platforms... usleep() it's deprecated. while (nanosleep(&req, &req) == -1) continue; #endif #if defined(__APPLE__) usleep(ms*1000.0f); #endif #if defined(SUPPORT_HALFBUSY_WAIT_LOOP) while (GetTime() < destTime) { } #endif #endif } // Poll (store) all input events static void PollInputEvents(void) { #if defined(SUPPORT_GESTURES_SYSTEM) // NOTE: Gestures update must be called every frame to reset gestures correctly // because ProcessGestureEvent() is just called on an event, not every frame UpdateGestures(); #endif // Reset keys/chars pressed registered CORE.Input.Keyboard.keyPressedQueueCount = 0; CORE.Input.Keyboard.charPressedQueueCount = 0; #if !(defined(PLATFORM_RPI) || defined(PLATFORM_DRM)) // Reset last gamepad button/axis registered state CORE.Input.Gamepad.lastButtonPressed = -1; CORE.Input.Gamepad.axisCount = 0; #endif #if defined(PLATFORM_RPI) || defined(PLATFORM_DRM) // Register previous keys states for (int i = 0; i < 512; i++) CORE.Input.Keyboard.previousKeyState[i] = CORE.Input.Keyboard.currentKeyState[i]; PollKeyboardEvents(); // Register previous mouse states CORE.Input.Mouse.previousWheelMove = CORE.Input.Mouse.currentWheelMove; CORE.Input.Mouse.currentWheelMove = 0.0f; for (int i = 0; i < 3; i++) { CORE.Input.Mouse.previousButtonState[i] = CORE.Input.Mouse.currentButtonState[i]; CORE.Input.Mouse.currentButtonState[i] = CORE.Input.Mouse.currentButtonStateEvdev[i]; } // Register gamepads buttons events for (int i = 0; i < MAX_GAMEPADS; i++) { if (CORE.Input.Gamepad.ready[i]) // Check if gamepad is available { // Register previous gamepad states for (int k = 0; k < MAX_GAMEPAD_BUTTONS; k++) CORE.Input.Gamepad.previousState[i][k] = CORE.Input.Gamepad.currentState[i][k]; } } #endif #if defined(PLATFORM_UWP) // Register previous keys states for (int i = 0; i < 512; i++) CORE.Input.Keyboard.previousKeyState[i] = CORE.Input.Keyboard.currentKeyState[i]; for (int i = 0; i < MAX_GAMEPADS; i++) { if (CORE.Input.Gamepad.ready[i]) { for (int k = 0; k < MAX_GAMEPAD_BUTTONS; k++) CORE.Input.Gamepad.previousState[i][k] = CORE.Input.Gamepad.currentState[i][k]; } } // Register previous mouse states CORE.Input.Mouse.previousWheelMove = CORE.Input.Mouse.currentWheelMove; CORE.Input.Mouse.currentWheelMove = 0.0f; for (int i = 0; i < 3; i++) CORE.Input.Mouse.previousButtonState[i] = CORE.Input.Mouse.currentButtonState[i]; #endif // PLATFORM_UWP #if defined(PLATFORM_DESKTOP) || defined(PLATFORM_WEB) // Keyboard/Mouse input polling (automatically managed by GLFW3 through callback) // Register previous keys states for (int i = 0; i < 512; i++) CORE.Input.Keyboard.previousKeyState[i] = CORE.Input.Keyboard.currentKeyState[i]; // Register previous mouse states for (int i = 0; i < 3; i++) CORE.Input.Mouse.previousButtonState[i] = CORE.Input.Mouse.currentButtonState[i]; // Register previous mouse wheel state CORE.Input.Mouse.previousWheelMove = CORE.Input.Mouse.currentWheelMove; CORE.Input.Mouse.currentWheelMove = 0.0f; #endif // Register previous touch states for (int i = 0; i < MAX_TOUCH_POINTS; i++) CORE.Input.Touch.previousTouchState[i] = CORE.Input.Touch.currentTouchState[i]; #if defined(PLATFORM_DESKTOP) // Check if gamepads are ready // NOTE: We do it here in case of disconnection for (int i = 0; i < MAX_GAMEPADS; i++) { if (glfwJoystickPresent(i)) CORE.Input.Gamepad.ready[i] = true; else CORE.Input.Gamepad.ready[i] = false; } // Register gamepads buttons events for (int i = 0; i < MAX_GAMEPADS; i++) { if (CORE.Input.Gamepad.ready[i]) // Check if gamepad is available { // Register previous gamepad states for (int k = 0; k < MAX_GAMEPAD_BUTTONS; k++) CORE.Input.Gamepad.previousState[i][k] = CORE.Input.Gamepad.currentState[i][k]; // Get current gamepad state // NOTE: There is no callback available, so we get it manually // Get remapped buttons GLFWgamepadstate state = { 0 }; glfwGetGamepadState(i, &state); // This remapps all gamepads so they have their buttons mapped like an xbox controller const unsigned char *buttons = state.buttons; for (int k = 0; (buttons != NULL) && (k < GLFW_GAMEPAD_BUTTON_DPAD_LEFT + 1) && (k < MAX_GAMEPAD_BUTTONS); k++) { GamepadButton button = -1; switch (k) { case GLFW_GAMEPAD_BUTTON_Y: button = GAMEPAD_BUTTON_RIGHT_FACE_UP; break; case GLFW_GAMEPAD_BUTTON_B: button = GAMEPAD_BUTTON_RIGHT_FACE_RIGHT; break; case GLFW_GAMEPAD_BUTTON_A: button = GAMEPAD_BUTTON_RIGHT_FACE_DOWN; break; case GLFW_GAMEPAD_BUTTON_X: button = GAMEPAD_BUTTON_RIGHT_FACE_LEFT; break; case GLFW_GAMEPAD_BUTTON_LEFT_BUMPER: button = GAMEPAD_BUTTON_LEFT_TRIGGER_1; break; case GLFW_GAMEPAD_BUTTON_RIGHT_BUMPER: button = GAMEPAD_BUTTON_RIGHT_TRIGGER_1; break; case GLFW_GAMEPAD_BUTTON_BACK: button = GAMEPAD_BUTTON_MIDDLE_LEFT; break; case GLFW_GAMEPAD_BUTTON_GUIDE: button = GAMEPAD_BUTTON_MIDDLE; break; case GLFW_GAMEPAD_BUTTON_START: button = GAMEPAD_BUTTON_MIDDLE_RIGHT; break; case GLFW_GAMEPAD_BUTTON_DPAD_UP: button = GAMEPAD_BUTTON_LEFT_FACE_UP; break; case GLFW_GAMEPAD_BUTTON_DPAD_RIGHT: button = GAMEPAD_BUTTON_LEFT_FACE_RIGHT; break; case GLFW_GAMEPAD_BUTTON_DPAD_DOWN: button = GAMEPAD_BUTTON_LEFT_FACE_DOWN; break; case GLFW_GAMEPAD_BUTTON_DPAD_LEFT: button = GAMEPAD_BUTTON_LEFT_FACE_LEFT; break; case GLFW_GAMEPAD_BUTTON_LEFT_THUMB: button = GAMEPAD_BUTTON_LEFT_THUMB; break; case GLFW_GAMEPAD_BUTTON_RIGHT_THUMB: button = GAMEPAD_BUTTON_RIGHT_THUMB; break; default: break; } if (button != -1) // Check for valid button { if (buttons[k] == GLFW_PRESS) { CORE.Input.Gamepad.currentState[i][button] = 1; CORE.Input.Gamepad.lastButtonPressed = button; } else CORE.Input.Gamepad.currentState[i][button] = 0; } } // Get current axis state const float *axes = state.axes; for (int k = 0; (axes != NULL) && (k < GLFW_GAMEPAD_AXIS_LAST + 1) && (k < MAX_GAMEPAD_AXIS); k++) { CORE.Input.Gamepad.axisState[i][k] = axes[k]; } // Register buttons for 2nd triggers (because GLFW doesn't count these as buttons but rather axis) CORE.Input.Gamepad.currentState[i][GAMEPAD_BUTTON_LEFT_TRIGGER_2] = (char)(CORE.Input.Gamepad.axisState[i][GAMEPAD_AXIS_LEFT_TRIGGER] > 0.1); CORE.Input.Gamepad.currentState[i][GAMEPAD_BUTTON_RIGHT_TRIGGER_2] = (char)(CORE.Input.Gamepad.axisState[i][GAMEPAD_AXIS_RIGHT_TRIGGER] > 0.1); CORE.Input.Gamepad.axisCount = GLFW_GAMEPAD_AXIS_LAST + 1; } } CORE.Window.resizedLastFrame = false; #if defined(SUPPORT_EVENTS_WAITING) glfwWaitEvents(); #else glfwPollEvents(); // Register keyboard/mouse events (callbacks)... and window events! #endif #endif // PLATFORM_DESKTOP // Gamepad support using emscripten API // NOTE: GLFW3 joystick functionality not available in web #if defined(PLATFORM_WEB) // Get number of gamepads connected int numGamepads = 0; if (emscripten_sample_gamepad_data() == EMSCRIPTEN_RESULT_SUCCESS) numGamepads = emscripten_get_num_gamepads(); for (int i = 0; (i < numGamepads) && (i < MAX_GAMEPADS); i++) { // Register previous gamepad button states for (int k = 0; k < MAX_GAMEPAD_BUTTONS; k++) CORE.Input.Gamepad.previousState[i][k] = CORE.Input.Gamepad.currentState[i][k]; EmscriptenGamepadEvent gamepadState; int result = emscripten_get_gamepad_status(i, &gamepadState); if (result == EMSCRIPTEN_RESULT_SUCCESS) { // Register buttons data for every connected gamepad for (int j = 0; (j < gamepadState.numButtons) && (j < MAX_GAMEPAD_BUTTONS); j++) { GamepadButton button = -1; // Gamepad Buttons reference: https://www.w3.org/TR/gamepad/#gamepad-interface switch (j) { case 0: button = GAMEPAD_BUTTON_RIGHT_FACE_DOWN; break; case 1: button = GAMEPAD_BUTTON_RIGHT_FACE_RIGHT; break; case 2: button = GAMEPAD_BUTTON_RIGHT_FACE_LEFT; break; case 3: button = GAMEPAD_BUTTON_RIGHT_FACE_UP; break; case 4: button = GAMEPAD_BUTTON_LEFT_TRIGGER_1; break; case 5: button = GAMEPAD_BUTTON_RIGHT_TRIGGER_1; break; case 6: button = GAMEPAD_BUTTON_LEFT_TRIGGER_2; break; case 7: button = GAMEPAD_BUTTON_RIGHT_TRIGGER_2; break; case 8: button = GAMEPAD_BUTTON_MIDDLE_LEFT; break; case 9: button = GAMEPAD_BUTTON_MIDDLE_RIGHT; break; case 10: button = GAMEPAD_BUTTON_LEFT_THUMB; break; case 11: button = GAMEPAD_BUTTON_RIGHT_THUMB; break; case 12: button = GAMEPAD_BUTTON_LEFT_FACE_UP; break; case 13: button = GAMEPAD_BUTTON_LEFT_FACE_DOWN; break; case 14: button = GAMEPAD_BUTTON_LEFT_FACE_LEFT; break; case 15: button = GAMEPAD_BUTTON_LEFT_FACE_RIGHT; break; default: break; } if (button != -1) // Check for valid button { if (gamepadState.digitalButton[j] == 1) { CORE.Input.Gamepad.currentState[i][button] = 1; CORE.Input.Gamepad.lastButtonPressed = button; } else CORE.Input.Gamepad.currentState[i][button] = 0; } //TRACELOGD("INPUT: Gamepad %d, button %d: Digital: %d, Analog: %g", gamepadState.index, j, gamepadState.digitalButton[j], gamepadState.analogButton[j]); } // Register axis data for every connected gamepad for (int j = 0; (j < gamepadState.numAxes) && (j < MAX_GAMEPAD_AXIS); j++) { CORE.Input.Gamepad.axisState[i][j] = gamepadState.axis[j]; } CORE.Input.Gamepad.axisCount = gamepadState.numAxes; } } #endif #if defined(PLATFORM_ANDROID) // Register previous keys states // NOTE: Android supports up to 260 keys for (int i = 0; i < 260; i++) CORE.Input.Keyboard.previousKeyState[i] = CORE.Input.Keyboard.currentKeyState[i]; // Android ALooper_pollAll() variables int pollResult = 0; int pollEvents = 0; // Poll Events (registered events) // NOTE: Activity is paused if not enabled (CORE.Android.appEnabled) while ((pollResult = ALooper_pollAll(CORE.Android.appEnabled? 0 : -1, NULL, &pollEvents, (void**)&CORE.Android.source)) >= 0) { // Process this event if (CORE.Android.source != NULL) CORE.Android.source->process(CORE.Android.app, CORE.Android.source); // NOTE: Never close window, native activity is controlled by the system! if (CORE.Android.app->destroyRequested != 0) { //CORE.Window.shouldClose = true; //ANativeActivity_finish(CORE.Android.app->activity); } } #endif #if (defined(PLATFORM_RPI) || defined(PLATFORM_DRM)) && defined(SUPPORT_SSH_KEYBOARD_RPI) // NOTE: Keyboard reading could be done using input_event(s) reading or just read from stdin, // we now use both methods inside here. 2nd method is still used for legacy purposes (Allows for input trough SSH console) ProcessKeyboard(); // NOTE: Mouse input events polling is done asynchronously in another pthread - EventThread() // NOTE: Gamepad (Joystick) input events polling is done asynchonously in another pthread - GamepadThread() #endif } // Copy back buffer to front buffers static void SwapBuffers(void) { #if defined(PLATFORM_DESKTOP) || defined(PLATFORM_WEB) glfwSwapBuffers(CORE.Window.handle); #endif #if defined(PLATFORM_ANDROID) || defined(PLATFORM_RPI) || defined(PLATFORM_DRM) || defined(PLATFORM_UWP) eglSwapBuffers(CORE.Window.device, CORE.Window.surface); #if defined(PLATFORM_DRM) if (!CORE.Window.gbmSurface || (-1 == CORE.Window.fd) || !CORE.Window.connector || !CORE.Window.crtc) { TRACELOG(LOG_ERROR, "DISPLAY: DRM initialization failed to swap"); abort(); } struct gbm_bo *bo = gbm_surface_lock_front_buffer(CORE.Window.gbmSurface); if (!bo) { TRACELOG(LOG_ERROR, "DISPLAY: Failed GBM to lock front buffer"); abort(); } uint32_t fb = 0; int result = drmModeAddFB(CORE.Window.fd, CORE.Window.connector->modes[CORE.Window.modeIndex].hdisplay, CORE.Window.connector->modes[CORE.Window.modeIndex].vdisplay, 24, 32, gbm_bo_get_stride(bo), gbm_bo_get_handle(bo).u32, &fb); if (0 != result) { TRACELOG(LOG_ERROR, "DISPLAY: drmModeAddFB() failed with result: %d", result); abort(); } result = drmModeSetCrtc(CORE.Window.fd, CORE.Window.crtc->crtc_id, fb, 0, 0, &CORE.Window.connector->connector_id, 1, &CORE.Window.connector->modes[CORE.Window.modeIndex]); if (0 != result) { TRACELOG(LOG_ERROR, "DISPLAY: drmModeSetCrtc() failed with result: %d", result); abort(); } if (CORE.Window.prevFB) { result = drmModeRmFB(CORE.Window.fd, CORE.Window.prevFB); if (0 != result) { TRACELOG(LOG_ERROR, "DISPLAY: drmModeRmFB() failed with result: %d", result); abort(); } } CORE.Window.prevFB = fb; if (CORE.Window.prevBO) { gbm_surface_release_buffer(CORE.Window.gbmSurface, CORE.Window.prevBO); } CORE.Window.prevBO = bo; #endif // PLATFORM_DRM #endif // PLATFORM_ANDROID || PLATFORM_RPI || PLATFORM_DRM || PLATFORM_UWP } #if defined(PLATFORM_DESKTOP) || defined(PLATFORM_WEB) // GLFW3 Error Callback, runs on GLFW3 error static void ErrorCallback(int error, const char *description) { TRACELOG(LOG_WARNING, "GLFW: Error: %i Description: %s", error, description); } // GLFW3 WindowSize Callback, runs when window is resizedLastFrame // NOTE: Window resizing not allowed by default static void WindowSizeCallback(GLFWwindow *window, int width, int height) { SetupViewport(width, height); // Reset viewport and projection matrix for new size CORE.Window.currentFbo.width = width; CORE.Window.currentFbo.height = height; CORE.Window.resizedLastFrame = true; if (IsWindowFullscreen()) return; // Set current screen size CORE.Window.screen.width = width; CORE.Window.screen.height = height; // NOTE: Postprocessing texture is not scaled to new size } // GLFW3 WindowIconify Callback, runs when window is minimized/restored static void WindowIconifyCallback(GLFWwindow *window, int iconified) { if (iconified) CORE.Window.flags |= FLAG_WINDOW_MINIMIZED; // The window was iconified else CORE.Window.flags &= ~FLAG_WINDOW_MINIMIZED; // The window was restored } #if !defined(PLATFORM_WEB) // GLFW3 WindowMaximize Callback, runs when window is maximized/restored static void WindowMaximizeCallback(GLFWwindow *window, int maximized) { if (maximized) CORE.Window.flags |= FLAG_WINDOW_MAXIMIZED; // The window was maximized else CORE.Window.flags &= ~FLAG_WINDOW_MAXIMIZED; // The window was restored } #endif // GLFW3 WindowFocus Callback, runs when window get/lose focus static void WindowFocusCallback(GLFWwindow *window, int focused) { if (focused) CORE.Window.flags &= ~FLAG_WINDOW_UNFOCUSED; // The window was focused else CORE.Window.flags |= FLAG_WINDOW_UNFOCUSED; // The window lost focus } // GLFW3 Keyboard Callback, runs on key pressed static void KeyCallback(GLFWwindow *window, int key, int scancode, int action, int mods) { //TRACELOG(LOG_DEBUG, "Key Callback: KEY:%i(%c) - SCANCODE:%i (STATE:%i)", key, key, scancode, action); if (key == CORE.Input.Keyboard.exitKey && action == GLFW_PRESS) { glfwSetWindowShouldClose(CORE.Window.handle, GLFW_TRUE); // NOTE: Before closing window, while loop must be left! } #if defined(SUPPORT_SCREEN_CAPTURE) else if (key == GLFW_KEY_F12 && action == GLFW_PRESS) { #if defined(SUPPORT_GIF_RECORDING) if (mods == GLFW_MOD_CONTROL) { if (gifRecording) { gifRecording = false; MsfGifResult result = msf_gif_end(&gifState); char path[512] = { 0 }; #if defined(PLATFORM_ANDROID) strcpy(path, CORE.Android.internalDataPath); strcat(path, TextFormat("./screenrec%03i.gif", screenshotCounter)); #else strcpy(path, TextFormat("./screenrec%03i.gif", screenshotCounter)); #endif SaveFileData(path, result.data, (unsigned int)result.dataSize); msf_gif_free(result); #if defined(PLATFORM_WEB) // Download file from MEMFS (emscripten memory filesystem) // saveFileFromMEMFSToDisk() function is defined in raylib/templates/web_shel/shell.html emscripten_run_script(TextFormat("saveFileFromMEMFSToDisk('%s','%s')", TextFormat("screenrec%03i.gif", screenshotCounter - 1), TextFormat("screenrec%03i.gif", screenshotCounter - 1))); #endif TRACELOG(LOG_INFO, "SYSTEM: Finish animated GIF recording"); } else { gifRecording = true; gifFramesCounter = 0; msf_gif_begin(&gifState, CORE.Window.screen.width, CORE.Window.screen.height); screenshotCounter++; TRACELOG(LOG_INFO, "SYSTEM: Start animated GIF recording: %s", TextFormat("screenrec%03i.gif", screenshotCounter)); } } else #endif // SUPPORT_GIF_RECORDING { TakeScreenshot(TextFormat("screenshot%03i.png", screenshotCounter)); screenshotCounter++; } } #endif // SUPPORT_SCREEN_CAPTURE else { // WARNING: GLFW could return GLFW_REPEAT, we need to consider it as 1 // to work properly with our implementation (IsKeyDown/IsKeyUp checks) if (action == GLFW_RELEASE) CORE.Input.Keyboard.currentKeyState[key] = 0; else CORE.Input.Keyboard.currentKeyState[key] = 1; // Check if there is space available in the key queue if ((CORE.Input.Keyboard.keyPressedQueueCount < MAX_KEY_PRESSED_QUEUE) && (action == GLFW_PRESS)) { // Add character to the queue CORE.Input.Keyboard.keyPressedQueue[CORE.Input.Keyboard.keyPressedQueueCount] = key; CORE.Input.Keyboard.keyPressedQueueCount++; } } } // GLFW3 Char Key Callback, runs on key down (gets equivalent unicode char value) static void CharCallback(GLFWwindow *window, unsigned int key) { //TRACELOG(LOG_DEBUG, "Char Callback: KEY:%i(%c)", key, key); // NOTE: Registers any key down considering OS keyboard layout but // do not detects action events, those should be managed by user... // Ref: https://github.com/glfw/glfw/issues/668#issuecomment-166794907 // Ref: https://www.glfw.org/docs/latest/input_guide.html#input_char // Check if there is space available in the queue if (CORE.Input.Keyboard.charPressedQueueCount < MAX_KEY_PRESSED_QUEUE) { // Add character to the queue CORE.Input.Keyboard.charPressedQueue[CORE.Input.Keyboard.charPressedQueueCount] = key; CORE.Input.Keyboard.charPressedQueueCount++; } } // GLFW3 Mouse Button Callback, runs on mouse button pressed static void MouseButtonCallback(GLFWwindow *window, int button, int action, int mods) { // WARNING: GLFW could only return GLFW_PRESS (1) or GLFW_RELEASE (0) for now, // but future releases may add more actions (i.e. GLFW_REPEAT) CORE.Input.Mouse.currentButtonState[button] = action; #if defined(SUPPORT_GESTURES_SYSTEM) && defined(SUPPORT_MOUSE_GESTURES) // Process mouse events as touches to be able to use mouse-gestures GestureEvent gestureEvent = { 0 }; // Register touch actions if ((CORE.Input.Mouse.currentButtonState[button] == 1) && (CORE.Input.Mouse.previousButtonState[button] == 0)) gestureEvent.touchAction = TOUCH_DOWN; else if ((CORE.Input.Mouse.currentButtonState[button] == 0) && (CORE.Input.Mouse.previousButtonState[button] == 1)) gestureEvent.touchAction = TOUCH_UP; // NOTE: TOUCH_MOVE event is registered in MouseCursorPosCallback() // Assign a pointer ID gestureEvent.pointerId[0] = 0; // Register touch points count gestureEvent.pointCount = 1; // Register touch points position, only one point registered gestureEvent.position[0] = GetMousePosition(); // Normalize gestureEvent.position[0] for CORE.Window.screen.width and CORE.Window.screen.height gestureEvent.position[0].x /= (float)GetScreenWidth(); gestureEvent.position[0].y /= (float)GetScreenHeight(); // Gesture data is sent to gestures system for processing ProcessGestureEvent(gestureEvent); #endif } // GLFW3 Cursor Position Callback, runs on mouse move static void MouseCursorPosCallback(GLFWwindow *window, double x, double y) { CORE.Input.Mouse.position.x = (float)x; CORE.Input.Mouse.position.y = (float)y; CORE.Input.Touch.position[0] = CORE.Input.Mouse.position; #if defined(SUPPORT_GESTURES_SYSTEM) && defined(SUPPORT_MOUSE_GESTURES) // Process mouse events as touches to be able to use mouse-gestures GestureEvent gestureEvent = { 0 }; gestureEvent.touchAction = TOUCH_MOVE; // Assign a pointer ID gestureEvent.pointerId[0] = 0; // Register touch points count gestureEvent.pointCount = 1; // Register touch points position, only one point registered gestureEvent.position[0] = CORE.Input.Touch.position[0]; // Normalize gestureEvent.position[0] for CORE.Window.screen.width and CORE.Window.screen.height gestureEvent.position[0].x /= (float)GetScreenWidth(); gestureEvent.position[0].y /= (float)GetScreenHeight(); // Gesture data is sent to gestures system for processing ProcessGestureEvent(gestureEvent); #endif } // GLFW3 Srolling Callback, runs on mouse wheel static void MouseScrollCallback(GLFWwindow *window, double xoffset, double yoffset) { CORE.Input.Mouse.currentWheelMove = (float)yoffset; } // GLFW3 CursorEnter Callback, when cursor enters the window static void CursorEnterCallback(GLFWwindow *window, int enter) { if (enter == true) CORE.Input.Mouse.cursorOnScreen = true; else CORE.Input.Mouse.cursorOnScreen = false; } // GLFW3 Window Drop Callback, runs when drop files into window // NOTE: Paths are stored in dynamic memory for further retrieval // Everytime new files are dropped, old ones are discarded static void WindowDropCallback(GLFWwindow *window, int count, const char **paths) { ClearDroppedFiles(); CORE.Window.dropFilesPath = (char **)RL_MALLOC(sizeof(char *)*count); for (int i = 0; i < count; i++) { CORE.Window.dropFilesPath[i] = (char *)RL_MALLOC(sizeof(char)*MAX_FILEPATH_LENGTH); strcpy(CORE.Window.dropFilesPath[i], paths[i]); } CORE.Window.dropFilesCount = count; } #endif #if defined(PLATFORM_ANDROID) // ANDROID: Process activity lifecycle commands static void AndroidCommandCallback(struct android_app *app, int32_t cmd) { switch (cmd) { case APP_CMD_START: { //rendering = true; } break; case APP_CMD_RESUME: break; case APP_CMD_INIT_WINDOW: { if (app->window != NULL) { if (CORE.Android.contextRebindRequired) { // Reset screen scaling to full display size EGLint displayFormat; eglGetConfigAttrib(CORE.Window.device, CORE.Window.config, EGL_NATIVE_VISUAL_ID, &displayFormat); ANativeWindow_setBuffersGeometry(app->window, CORE.Window.render.width, CORE.Window.render.height, displayFormat); // Recreate display surface and re-attach OpenGL context CORE.Window.surface = eglCreateWindowSurface(CORE.Window.device, CORE.Window.config, app->window, NULL); eglMakeCurrent(CORE.Window.device, CORE.Window.surface, CORE.Window.surface, CORE.Window.context); CORE.Android.contextRebindRequired = false; } else { CORE.Window.display.width = ANativeWindow_getWidth(CORE.Android.app->window); CORE.Window.display.height = ANativeWindow_getHeight(CORE.Android.app->window); // Init graphics device (display device and OpenGL context) InitGraphicsDevice(CORE.Window.screen.width, CORE.Window.screen.height); // Init hi-res timer InitTimer(); #if defined(SUPPORT_DEFAULT_FONT) // Load default font // NOTE: External function (defined in module: text) LoadFontDefault(); Rectangle rec = GetFontDefault().recs[95]; // NOTE: We setup a 1px padding on char rectangle to avoid pixel bleeding on MSAA filtering SetShapesTexture(GetFontDefault().texture, (Rectangle){ rec.x + 1, rec.y + 1, rec.width - 2, rec.height - 2 }); #endif // TODO: GPU assets reload in case of lost focus (lost context) // NOTE: This problem has been solved just unbinding and rebinding context from display /* if (assetsReloadRequired) { for (int i = 0; i < assetsCount; i++) { // TODO: Unload old asset if required // Load texture again to pointed texture (*textureAsset + i) = LoadTexture(assetPath[i]); } } */ } } } break; case APP_CMD_GAINED_FOCUS: { CORE.Android.appEnabled = true; //ResumeMusicStream(); } break; case APP_CMD_PAUSE: break; case APP_CMD_LOST_FOCUS: { CORE.Android.appEnabled = false; //PauseMusicStream(); } break; case APP_CMD_TERM_WINDOW: { // Dettach OpenGL context and destroy display surface // NOTE 1: Detaching context before destroying display surface avoids losing our resources (textures, shaders, VBOs...) // NOTE 2: In some cases (too many context loaded), OS could unload context automatically... :( eglMakeCurrent(CORE.Window.device, EGL_NO_SURFACE, EGL_NO_SURFACE, EGL_NO_CONTEXT); eglDestroySurface(CORE.Window.device, CORE.Window.surface); CORE.Android.contextRebindRequired = true; } break; case APP_CMD_SAVE_STATE: break; case APP_CMD_STOP: break; case APP_CMD_DESTROY: { // TODO: Finish activity? //ANativeActivity_finish(CORE.Android.app->activity); } break; case APP_CMD_CONFIG_CHANGED: { //AConfiguration_fromAssetManager(CORE.Android.app->config, CORE.Android.app->activity->assetManager); //print_cur_config(CORE.Android.app); // Check screen orientation here! } break; default: break; } } // ANDROID: Get input events static int32_t AndroidInputCallback(struct android_app *app, AInputEvent *event) { // If additional inputs are required check: // https://developer.android.com/ndk/reference/group/input // https://developer.android.com/training/game-controllers/controller-input int type = AInputEvent_getType(event); int source = AInputEvent_getSource(event); if (type == AINPUT_EVENT_TYPE_MOTION) { if (((source & AINPUT_SOURCE_JOYSTICK) == AINPUT_SOURCE_JOYSTICK) || ((source & AINPUT_SOURCE_GAMEPAD) == AINPUT_SOURCE_GAMEPAD)) { // Get first touch position CORE.Input.Touch.position[0].x = AMotionEvent_getX(event, 0); CORE.Input.Touch.position[0].y = AMotionEvent_getY(event, 0); // Get second touch position CORE.Input.Touch.position[1].x = AMotionEvent_getX(event, 1); CORE.Input.Touch.position[1].y = AMotionEvent_getY(event, 1); int32_t keycode = AKeyEvent_getKeyCode(event); if (AKeyEvent_getAction(event) == AKEY_EVENT_ACTION_DOWN) { CORE.Input.Keyboard.currentKeyState[keycode] = 1; // Key down CORE.Input.Keyboard.keyPressedQueue[CORE.Input.Keyboard.keyPressedQueueCount] = keycode; CORE.Input.Keyboard.keyPressedQueueCount++; } else CORE.Input.Keyboard.currentKeyState[keycode] = 0; // Key up // Stop processing gamepad buttons return 1; } } else if (type == AINPUT_EVENT_TYPE_KEY) { int32_t keycode = AKeyEvent_getKeyCode(event); //int32_t AKeyEvent_getMetaState(event); // Save current button and its state // NOTE: Android key action is 0 for down and 1 for up if (AKeyEvent_getAction(event) == AKEY_EVENT_ACTION_DOWN) { CORE.Input.Keyboard.currentKeyState[keycode] = 1; // Key down CORE.Input.Keyboard.keyPressedQueue[CORE.Input.Keyboard.keyPressedQueueCount] = keycode; CORE.Input.Keyboard.keyPressedQueueCount++; } else CORE.Input.Keyboard.currentKeyState[keycode] = 0; // Key up if (keycode == AKEYCODE_POWER) { // Let the OS handle input to avoid app stuck. Behaviour: CMD_PAUSE -> CMD_SAVE_STATE -> CMD_STOP -> CMD_CONFIG_CHANGED -> CMD_LOST_FOCUS // Resuming Behaviour: CMD_START -> CMD_RESUME -> CMD_CONFIG_CHANGED -> CMD_CONFIG_CHANGED -> CMD_GAINED_FOCUS // It seems like locking mobile, screen size (CMD_CONFIG_CHANGED) is affected. // NOTE: AndroidManifest.xml must have // Before that change, activity was calling CMD_TERM_WINDOW and CMD_DESTROY when locking mobile, so that was not a normal behaviour return 0; } else if ((keycode == AKEYCODE_BACK) || (keycode == AKEYCODE_MENU)) { // Eat BACK_BUTTON and AKEYCODE_MENU, just do nothing... and don't let to be handled by OS! return 1; } else if ((keycode == AKEYCODE_VOLUME_UP) || (keycode == AKEYCODE_VOLUME_DOWN)) { // Set default OS behaviour return 0; } return 0; } CORE.Input.Touch.position[0].x = AMotionEvent_getX(event, 0); CORE.Input.Touch.position[0].y = AMotionEvent_getY(event, 0); int32_t action = AMotionEvent_getAction(event); unsigned int flags = action & AMOTION_EVENT_ACTION_MASK; if (flags == AMOTION_EVENT_ACTION_DOWN || flags == AMOTION_EVENT_ACTION_MOVE) { CORE.Input.Touch.currentTouchState[MOUSE_LEFT_BUTTON] = 1; } else if (flags == AMOTION_EVENT_ACTION_UP) { CORE.Input.Touch.currentTouchState[MOUSE_LEFT_BUTTON] = 0; } #if defined(SUPPORT_GESTURES_SYSTEM) GestureEvent gestureEvent; // Register touch actions if (flags == AMOTION_EVENT_ACTION_DOWN) gestureEvent.touchAction = TOUCH_DOWN; else if (flags == AMOTION_EVENT_ACTION_UP) gestureEvent.touchAction = TOUCH_UP; else if (flags == AMOTION_EVENT_ACTION_MOVE) gestureEvent.touchAction = TOUCH_MOVE; // Register touch points count // NOTE: Documentation says pointerCount is Always >= 1, // but in practice it can be 0 or over a million gestureEvent.pointCount = AMotionEvent_getPointerCount(event); // Only enable gestures for 1-3 touch points if ((gestureEvent.pointCount > 0) && (gestureEvent.pointCount < 4)) { // Register touch points id // NOTE: Only two points registered gestureEvent.pointerId[0] = AMotionEvent_getPointerId(event, 0); gestureEvent.pointerId[1] = AMotionEvent_getPointerId(event, 1); // Register touch points position gestureEvent.position[0] = (Vector2){ AMotionEvent_getX(event, 0), AMotionEvent_getY(event, 0) }; gestureEvent.position[1] = (Vector2){ AMotionEvent_getX(event, 1), AMotionEvent_getY(event, 1) }; // Normalize gestureEvent.position[x] for screenWidth and screenHeight gestureEvent.position[0].x /= (float)GetScreenWidth(); gestureEvent.position[0].y /= (float)GetScreenHeight(); gestureEvent.position[1].x /= (float)GetScreenWidth(); gestureEvent.position[1].y /= (float)GetScreenHeight(); // Gesture data is sent to gestures system for processing ProcessGestureEvent(gestureEvent); } #endif return 0; } #endif #if defined(PLATFORM_WEB) // Register touch input events static EM_BOOL EmscriptenTouchCallback(int eventType, const EmscriptenTouchEvent *touchEvent, void *userData) { for (int i = 0; i < touchEvent->numTouches; i++) { if (eventType == EMSCRIPTEN_EVENT_TOUCHSTART) CORE.Input.Touch.currentTouchState[i] = 1; else if (eventType == EMSCRIPTEN_EVENT_TOUCHEND) CORE.Input.Touch.currentTouchState[i] = 0; } #if defined(SUPPORT_GESTURES_SYSTEM) GestureEvent gestureEvent = { 0 }; // Register touch actions if (eventType == EMSCRIPTEN_EVENT_TOUCHSTART) gestureEvent.touchAction = TOUCH_DOWN; else if (eventType == EMSCRIPTEN_EVENT_TOUCHEND) gestureEvent.touchAction = TOUCH_UP; else if (eventType == EMSCRIPTEN_EVENT_TOUCHMOVE) gestureEvent.touchAction = TOUCH_MOVE; // Register touch points count gestureEvent.pointCount = touchEvent->numTouches; // Register touch points id gestureEvent.pointerId[0] = touchEvent->touches[0].identifier; gestureEvent.pointerId[1] = touchEvent->touches[1].identifier; // Register touch points position // NOTE: Only two points registered gestureEvent.position[0] = (Vector2){ touchEvent->touches[0].targetX, touchEvent->touches[0].targetY }; gestureEvent.position[1] = (Vector2){ touchEvent->touches[1].targetX, touchEvent->touches[1].targetY }; double canvasWidth, canvasHeight; // NOTE: emscripten_get_canvas_element_size() returns canvas.width and canvas.height but // we are looking for actual CSS size: canvas.style.width and canvas.style.height //EMSCRIPTEN_RESULT res = emscripten_get_canvas_element_size("#canvas", &canvasWidth, &canvasHeight); emscripten_get_element_css_size("#canvas", &canvasWidth, &canvasHeight); // Normalize gestureEvent.position[x] for CORE.Window.screen.width and CORE.Window.screen.height gestureEvent.position[0].x *= ((float)GetScreenWidth()/(float)canvasWidth); gestureEvent.position[0].y *= ((float)GetScreenHeight()/(float)canvasHeight); gestureEvent.position[1].x *= ((float)GetScreenWidth()/(float)canvasWidth); gestureEvent.position[1].y *= ((float)GetScreenHeight()/(float)canvasHeight); CORE.Input.Touch.position[0] = gestureEvent.position[0]; CORE.Input.Touch.position[1] = gestureEvent.position[1]; // Gesture data is sent to gestures system for processing ProcessGestureEvent(gestureEvent); #else // Support only simple touch position if (eventType == EMSCRIPTEN_EVENT_TOUCHSTART) { // Get first touch position CORE.Input.Touch.position[0] = (Vector2){ touchEvent->touches[0].targetX, touchEvent->touches[0].targetY }; double canvasWidth, canvasHeight; //EMSCRIPTEN_RESULT res = emscripten_get_canvas_element_size("#canvas", &canvasWidth, &canvasHeight); emscripten_get_element_css_size("#canvas", &canvasWidth, &canvasHeight); // Normalize gestureEvent.position[x] for screenWidth and screenHeight CORE.Input.Touch.position[0].x *= ((float)GetScreenWidth()/(float)canvasWidth); CORE.Input.Touch.position[0].y *= ((float)GetScreenHeight()/(float)canvasHeight); } #endif return 1; } // Register connected/disconnected gamepads events static EM_BOOL EmscriptenGamepadCallback(int eventType, const EmscriptenGamepadEvent *gamepadEvent, void *userData) { /* TRACELOGD("%s: timeStamp: %g, connected: %d, index: %ld, numAxes: %d, numButtons: %d, id: \"%s\", mapping: \"%s\"", eventType != 0? emscripten_event_type_to_string(eventType) : "Gamepad state", gamepadEvent->timestamp, gamepadEvent->connected, gamepadEvent->index, gamepadEvent->numAxes, gamepadEvent->numButtons, gamepadEvent->id, gamepadEvent->mapping); for (int i = 0; i < gamepadEvent->numAxes; ++i) TRACELOGD("Axis %d: %g", i, gamepadEvent->axis[i]); for (int i = 0; i < gamepadEvent->numButtons; ++i) TRACELOGD("Button %d: Digital: %d, Analog: %g", i, gamepadEvent->digitalButton[i], gamepadEvent->analogButton[i]); */ if ((gamepadEvent->connected) && (gamepadEvent->index < MAX_GAMEPADS)) CORE.Input.Gamepad.ready[gamepadEvent->index] = true; else CORE.Input.Gamepad.ready[gamepadEvent->index] = false; // TODO: Test gamepadEvent->index return 0; } #endif #if defined(PLATFORM_RPI) || defined(PLATFORM_DRM) #if defined(SUPPORT_SSH_KEYBOARD_RPI) // Initialize Keyboard system (using standard input) static void InitKeyboard(void) { // NOTE: We read directly from Standard Input (stdin) - STDIN_FILENO file descriptor // Make stdin non-blocking (not enough, need to configure to non-canonical mode) int flags = fcntl(STDIN_FILENO, F_GETFL, 0); // F_GETFL: Get the file access mode and the file status flags fcntl(STDIN_FILENO, F_SETFL, flags | O_NONBLOCK); // F_SETFL: Set the file status flags to the value specified // Save terminal keyboard settings and reconfigure terminal with new settings struct termios keyboardNewSettings; tcgetattr(STDIN_FILENO, &CORE.Input.Keyboard.defaultSettings); // Get current keyboard settings keyboardNewSettings = CORE.Input.Keyboard.defaultSettings; // New terminal settings for keyboard: turn off buffering (non-canonical mode), echo and key processing // NOTE: ISIG controls if ^C and ^Z generate break signals or not keyboardNewSettings.c_lflag &= ~(ICANON | ECHO | ISIG); //keyboardNewSettings.c_iflag &= ~(ISTRIP | INLCR | ICRNL | IGNCR | IXON | IXOFF); keyboardNewSettings.c_cc[VMIN] = 1; keyboardNewSettings.c_cc[VTIME] = 0; // Set new keyboard settings (change occurs immediately) tcsetattr(STDIN_FILENO, TCSANOW, &keyboardNewSettings); // NOTE: Reading directly from stdin will give chars already key-mapped by kernel to ASCII or UNICODE // Save old keyboard mode to restore it at the end if (ioctl(STDIN_FILENO, KDGKBMODE, &CORE.Input.Keyboard.defaultMode) < 0) { // NOTE: It could mean we are using a remote keyboard through ssh! TRACELOG(LOG_WARNING, "RPI: Failed to change keyboard mode (SSH keyboard?)"); } else { // We reconfigure keyboard mode to get: // - scancodes (K_RAW) // - keycodes (K_MEDIUMRAW) // - ASCII chars (K_XLATE) // - UNICODE chars (K_UNICODE) ioctl(STDIN_FILENO, KDSKBMODE, K_XLATE); } // Register keyboard restore when program finishes atexit(RestoreKeyboard); } // Process keyboard inputs // TODO: Most probably input reading and processing should be in a separate thread static void ProcessKeyboard(void) { #define MAX_KEYBUFFER_SIZE 32 // Max size in bytes to read // Keyboard input polling (fill keys[256] array with status) int bufferByteCount = 0; // Bytes available on the buffer char keysBuffer[MAX_KEYBUFFER_SIZE]; // Max keys to be read at a time // Read availables keycodes from stdin bufferByteCount = read(STDIN_FILENO, keysBuffer, MAX_KEYBUFFER_SIZE); // POSIX system call // Reset pressed keys array (it will be filled below) if (bufferByteCount > 0) for (int i = 0; i < 512; i++) CORE.Input.Keyboard.currentKeyState[i] = 0; // Check keys from event input workers (This is the new keyboard reading method) //for (int i = 0; i < 512; i++) CORE.Input.Keyboard.currentKeyState[i] = CORE.Input.Keyboard.currentKeyStateEvdev[i]; // Fill all read bytes (looking for keys) for (int i = 0; i < bufferByteCount; i++) { // NOTE: If (key == 0x1b), depending on next key, it could be a special keymap code! // Up -> 1b 5b 41 / Left -> 1b 5b 44 / Right -> 1b 5b 43 / Down -> 1b 5b 42 if (keysBuffer[i] == 0x1b) { // Detect ESC to stop program if (bufferByteCount == 1) CORE.Input.Keyboard.currentKeyState[CORE.Input.Keyboard.exitKey] = 1; else { if (keysBuffer[i + 1] == 0x5b) // Special function key { if ((keysBuffer[i + 2] == 0x5b) || (keysBuffer[i + 2] == 0x31) || (keysBuffer[i + 2] == 0x32)) { // Process special function keys (F1 - F12) switch (keysBuffer[i + 3]) { case 0x41: CORE.Input.Keyboard.currentKeyState[290] = 1; break; // raylib KEY_F1 case 0x42: CORE.Input.Keyboard.currentKeyState[291] = 1; break; // raylib KEY_F2 case 0x43: CORE.Input.Keyboard.currentKeyState[292] = 1; break; // raylib KEY_F3 case 0x44: CORE.Input.Keyboard.currentKeyState[293] = 1; break; // raylib KEY_F4 case 0x45: CORE.Input.Keyboard.currentKeyState[294] = 1; break; // raylib KEY_F5 case 0x37: CORE.Input.Keyboard.currentKeyState[295] = 1; break; // raylib KEY_F6 case 0x38: CORE.Input.Keyboard.currentKeyState[296] = 1; break; // raylib KEY_F7 case 0x39: CORE.Input.Keyboard.currentKeyState[297] = 1; break; // raylib KEY_F8 case 0x30: CORE.Input.Keyboard.currentKeyState[298] = 1; break; // raylib KEY_F9 case 0x31: CORE.Input.Keyboard.currentKeyState[299] = 1; break; // raylib KEY_F10 case 0x33: CORE.Input.Keyboard.currentKeyState[300] = 1; break; // raylib KEY_F11 case 0x34: CORE.Input.Keyboard.currentKeyState[301] = 1; break; // raylib KEY_F12 default: break; } if (keysBuffer[i + 2] == 0x5b) i += 4; else if ((keysBuffer[i + 2] == 0x31) || (keysBuffer[i + 2] == 0x32)) i += 5; } else { switch (keysBuffer[i + 2]) { case 0x41: CORE.Input.Keyboard.currentKeyState[265] = 1; break; // raylib KEY_UP case 0x42: CORE.Input.Keyboard.currentKeyState[264] = 1; break; // raylib KEY_DOWN case 0x43: CORE.Input.Keyboard.currentKeyState[262] = 1; break; // raylib KEY_RIGHT case 0x44: CORE.Input.Keyboard.currentKeyState[263] = 1; break; // raylib KEY_LEFT default: break; } i += 3; // Jump to next key } // NOTE: Some keys are not directly keymapped (CTRL, ALT, SHIFT) } } } else if (keysBuffer[i] == 0x0a) // raylib KEY_ENTER (don't mix with KEY_*) { CORE.Input.Keyboard.currentKeyState[257] = 1; CORE.Input.Keyboard.keyPressedQueue[CORE.Input.Keyboard.keyPressedQueueCount] = 257; // Add keys pressed into queue CORE.Input.Keyboard.keyPressedQueueCount++; } else if (keysBuffer[i] == 0x7f) // raylib KEY_BACKSPACE { CORE.Input.Keyboard.currentKeyState[259] = 1; CORE.Input.Keyboard.keyPressedQueue[CORE.Input.Keyboard.keyPressedQueueCount] = 257; // Add keys pressed into queue CORE.Input.Keyboard.keyPressedQueueCount++; } else { // Translate lowercase a-z letters to A-Z if ((keysBuffer[i] >= 97) && (keysBuffer[i] <= 122)) { CORE.Input.Keyboard.currentKeyState[(int)keysBuffer[i] - 32] = 1; } else CORE.Input.Keyboard.currentKeyState[(int)keysBuffer[i]] = 1; CORE.Input.Keyboard.keyPressedQueue[CORE.Input.Keyboard.keyPressedQueueCount] = keysBuffer[i]; // Add keys pressed into queue CORE.Input.Keyboard.keyPressedQueueCount++; } } // Check exit key (same functionality as GLFW3 KeyCallback()) if (CORE.Input.Keyboard.currentKeyState[CORE.Input.Keyboard.exitKey] == 1) CORE.Window.shouldClose = true; #if defined(SUPPORT_SCREEN_CAPTURE) // Check screen capture key (raylib key: KEY_F12) if (CORE.Input.Keyboard.currentKeyState[301] == 1) { TakeScreenshot(TextFormat("screenshot%03i.png", screenshotCounter)); screenshotCounter++; } #endif } // Restore default keyboard input static void RestoreKeyboard(void) { // Reset to default keyboard settings tcsetattr(STDIN_FILENO, TCSANOW, &CORE.Input.Keyboard.defaultSettings); // Reconfigure keyboard to default mode ioctl(STDIN_FILENO, KDSKBMODE, CORE.Input.Keyboard.defaultMode); } #endif // SUPPORT_SSH_KEYBOARD_RPI // Initialise user input from evdev(/dev/input/event) this means mouse, keyboard or gamepad devices static void InitEvdevInput(void) { char path[MAX_FILEPATH_LENGTH]; DIR *directory; struct dirent *entity; // Initialise keyboard file descriptor CORE.Input.Keyboard.fd = -1; // Reset variables for (int i = 0; i < MAX_TOUCH_POINTS; ++i) { CORE.Input.Touch.position[i].x = -1; CORE.Input.Touch.position[i].y = -1; } // Reset keyboard key state for (int i = 0; i < 512; i++) CORE.Input.Keyboard.currentKeyState[i] = 0; // Open the linux directory of "/dev/input" directory = opendir(DEFAULT_EVDEV_PATH); if (directory) { while ((entity = readdir(directory)) != NULL) { if (strncmp("event", entity->d_name, strlen("event")) == 0) // Search for devices named "event*" { sprintf(path, "%s%s", DEFAULT_EVDEV_PATH, entity->d_name); ConfigureEvdevDevice(path); // Configure the device if appropriate } } closedir(directory); } else TRACELOG(LOG_WARNING, "RPI: Failed to open linux event directory: %s", DEFAULT_EVDEV_PATH); } // Identifies a input device and configures it for use if appropriate static void ConfigureEvdevDevice(char *device) { #define BITS_PER_LONG (8*sizeof(long)) #define NBITS(x) ((((x) - 1)/BITS_PER_LONG) + 1) #define OFF(x) ((x)%BITS_PER_LONG) #define BIT(x) (1UL<> OFF(bit)) & 1) struct input_absinfo absinfo; unsigned long evBits[NBITS(EV_MAX)]; unsigned long absBits[NBITS(ABS_MAX)]; unsigned long relBits[NBITS(REL_MAX)]; unsigned long keyBits[NBITS(KEY_MAX)]; bool hasAbs = false; bool hasRel = false; bool hasAbsMulti = false; int freeWorkerId = -1; int fd = -1; InputEventWorker *worker; // Open the device and allocate worker //------------------------------------------------------------------------------------------------------- // Find a free spot in the workers array for (int i = 0; i < sizeof(CORE.Input.eventWorker)/sizeof(InputEventWorker); ++i) { if (CORE.Input.eventWorker[i].threadId == 0) { freeWorkerId = i; break; } } // Select the free worker from array if (freeWorkerId >= 0) { worker = &(CORE.Input.eventWorker[freeWorkerId]); // Grab a pointer to the worker memset(worker, 0, sizeof(InputEventWorker)); // Clear the worker } else { TRACELOG(LOG_WARNING, "RPI: Failed to create input device thread for %s, out of worker slots", device); return; } // Open the device fd = open(device, O_RDONLY | O_NONBLOCK); if (fd < 0) { TRACELOG(LOG_WARNING, "RPI: Failed to open input device %s", device); return; } worker->fd = fd; // Grab number on the end of the devices name "event" int devNum = 0; char *ptrDevName = strrchr(device, 't'); worker->eventNum = -1; if (ptrDevName != NULL) { if (sscanf(ptrDevName, "t%d", &devNum) == 1) worker->eventNum = devNum; } // At this point we have a connection to the device, but we don't yet know what the device is. // It could be many things, even as simple as a power button... //------------------------------------------------------------------------------------------------------- // Identify the device //------------------------------------------------------------------------------------------------------- ioctl(fd, EVIOCGBIT(0, sizeof(evBits)), evBits); // Read a bitfield of the available device properties // Check for absolute input devices if (TEST_BIT(evBits, EV_ABS)) { ioctl(fd, EVIOCGBIT(EV_ABS, sizeof(absBits)), absBits); // Check for absolute movement support (usualy touchscreens, but also joysticks) if (TEST_BIT(absBits, ABS_X) && TEST_BIT(absBits, ABS_Y)) { hasAbs = true; // Get the scaling values ioctl(fd, EVIOCGABS(ABS_X), &absinfo); worker->absRange.x = absinfo.minimum; worker->absRange.width = absinfo.maximum - absinfo.minimum; ioctl(fd, EVIOCGABS(ABS_Y), &absinfo); worker->absRange.y = absinfo.minimum; worker->absRange.height = absinfo.maximum - absinfo.minimum; } // Check for multiple absolute movement support (usualy multitouch touchscreens) if (TEST_BIT(absBits, ABS_MT_POSITION_X) && TEST_BIT(absBits, ABS_MT_POSITION_Y)) { hasAbsMulti = true; // Get the scaling values ioctl(fd, EVIOCGABS(ABS_X), &absinfo); worker->absRange.x = absinfo.minimum; worker->absRange.width = absinfo.maximum - absinfo.minimum; ioctl(fd, EVIOCGABS(ABS_Y), &absinfo); worker->absRange.y = absinfo.minimum; worker->absRange.height = absinfo.maximum - absinfo.minimum; } } // Check for relative movement support (usualy mouse) if (TEST_BIT(evBits, EV_REL)) { ioctl(fd, EVIOCGBIT(EV_REL, sizeof(relBits)), relBits); if (TEST_BIT(relBits, REL_X) && TEST_BIT(relBits, REL_Y)) hasRel = true; } // Check for button support to determine the device type(usualy on all input devices) if (TEST_BIT(evBits, EV_KEY)) { ioctl(fd, EVIOCGBIT(EV_KEY, sizeof(keyBits)), keyBits); if (hasAbs || hasAbsMulti) { if (TEST_BIT(keyBits, BTN_TOUCH)) worker->isTouch = true; // This is a touchscreen if (TEST_BIT(keyBits, BTN_TOOL_FINGER)) worker->isTouch = true; // This is a drawing tablet if (TEST_BIT(keyBits, BTN_TOOL_PEN)) worker->isTouch = true; // This is a drawing tablet if (TEST_BIT(keyBits, BTN_STYLUS)) worker->isTouch = true; // This is a drawing tablet if (worker->isTouch || hasAbsMulti) worker->isMultitouch = true; // This is a multitouch capable device } if (hasRel) { if (TEST_BIT(keyBits, BTN_LEFT)) worker->isMouse = true; // This is a mouse if (TEST_BIT(keyBits, BTN_RIGHT)) worker->isMouse = true; // This is a mouse } if (TEST_BIT(keyBits, BTN_A)) worker->isGamepad = true; // This is a gamepad if (TEST_BIT(keyBits, BTN_TRIGGER)) worker->isGamepad = true; // This is a gamepad if (TEST_BIT(keyBits, BTN_START)) worker->isGamepad = true; // This is a gamepad if (TEST_BIT(keyBits, BTN_TL)) worker->isGamepad = true; // This is a gamepad if (TEST_BIT(keyBits, BTN_TL)) worker->isGamepad = true; // This is a gamepad if (TEST_BIT(keyBits, KEY_SPACE)) worker->isKeyboard = true; // This is a keyboard } //------------------------------------------------------------------------------------------------------- // Decide what to do with the device //------------------------------------------------------------------------------------------------------- if (worker->isKeyboard && CORE.Input.Keyboard.fd == -1) { // Use the first keyboard encountered. This assumes that a device that says it's a keyboard is just a // keyboard. The keyboard is polled synchronously, whereas other input devices are polled in separate // threads so that they don't drop events when the frame rate is slow. TRACELOG(LOG_INFO, "RPI: Opening keyboard device: %s", device); CORE.Input.Keyboard.fd = worker->fd; } else if (worker->isTouch || worker->isMouse) { // Looks like an interesting device TRACELOG(LOG_INFO, "RPI: Opening input device: %s (%s%s%s%s)", device, worker->isMouse? "mouse " : "", worker->isMultitouch? "multitouch " : "", worker->isTouch? "touchscreen " : "", worker->isGamepad? "gamepad " : ""); // Create a thread for this device int error = pthread_create(&worker->threadId, NULL, &EventThread, (void *)worker); if (error != 0) { TRACELOG(LOG_WARNING, "RPI: Failed to create input device thread: %s (error: %d)", device, error); worker->threadId = 0; close(fd); } #if defined(USE_LAST_TOUCH_DEVICE) // Find touchscreen with the highest index int maxTouchNumber = -1; for (int i = 0; i < sizeof(CORE.Input.eventWorker)/sizeof(InputEventWorker); ++i) { if (CORE.Input.eventWorker[i].isTouch && (CORE.Input.eventWorker[i].eventNum > maxTouchNumber)) maxTouchNumber = CORE.Input.eventWorker[i].eventNum; } // Find touchscreens with lower indexes for (int i = 0; i < sizeof(CORE.Input.eventWorker)/sizeof(InputEventWorker); ++i) { if (CORE.Input.eventWorker[i].isTouch && (CORE.Input.eventWorker[i].eventNum < maxTouchNumber)) { if (CORE.Input.eventWorker[i].threadId != 0) { TRACELOG(LOG_WARNING, "RPI: Found duplicate touchscreen, killing touchscreen on event: %d", i); pthread_cancel(CORE.Input.eventWorker[i].threadId); close(CORE.Input.eventWorker[i].fd); } } } #endif } else close(fd); // We are not interested in this device //------------------------------------------------------------------------------------------------------- } static void PollKeyboardEvents(void) { // Scancode to keycode mapping for US keyboards // TODO: Probably replace this with a keymap from the X11 to get the correct regional map for the keyboard: // Currently non US keyboards will have the wrong mapping for some keys static const int keymap_US[] = { 0,256,49,50,51,52,53,54,55,56,57,48,45,61,259,258,81,87,69,82,84, 89,85,73,79,80,91,93,257,341,65,83,68,70,71,72,74,75,76,59,39,96, 340,92,90,88,67,86,66,78,77,44,46,47,344,332,342,32,280,290,291, 292,293,294,295,296,297,298,299,282,281,327,328,329,333,324,325, 326,334,321,322,323,320,330,0,85,86,300,301,89,90,91,92,93,94,95, 335,345,331,283,346,101,268,265,266,263,262,269,264,267,260,261, 112,113,114,115,116,117,118,119,120,121,122,123,124,125,347,127, 128,129,130,131,132,133,134,135,136,137,138,139,140,141,142,143, 144,145,146,147,148,149,150,151,152,153,154,155,156,157,158,159, 160,161,162,163,164,165,166,167,168,169,170,171,172,173,174,175, 176,177,178,179,180,181,182,183,184,185,186,187,188,189,190,191, 192,193,194,0,0,0,0,0,200,201,202,203,204,205,206,207,208,209,210, 211,212,213,214,215,216,217,218,219,220,221,222,223,224,225,226, 227,228,229,230,231,232,233,234,235,236,237,238,239,240,241,242, 243,244,245,246,247,248,0,0,0,0,0,0,0, }; int fd = CORE.Input.Keyboard.fd; if (fd == -1) return; struct input_event event; int keycode; // Try to read data from the keyboard and only continue if successful while (read(fd, &event, sizeof(event)) == (int)sizeof(event)) { // Button parsing if (event.type == EV_KEY) { // Keyboard button parsing if ((event.code >= 1) && (event.code <= 255)) //Keyboard keys appear for codes 1 to 255 { keycode = keymap_US[event.code & 0xFF]; // The code we get is a scancode so we look up the apropriate keycode // Make sure we got a valid keycode if ((keycode > 0) && (keycode < sizeof(CORE.Input.Keyboard.currentKeyState))) { // WARNING: https://www.kernel.org/doc/Documentation/input/input.txt // Event interface: 'value' is the value the event carries. Either a relative change for EV_REL, // absolute new value for EV_ABS (joysticks ...), or 0 for EV_KEY for release, 1 for keypress and 2 for autorepeat CORE.Input.Keyboard.currentKeyState[keycode] = (event.value >= 1)? 1 : 0; if (event.value >= 1) { CORE.Input.Keyboard.keyPressedQueue[CORE.Input.Keyboard.keyPressedQueueCount] = keycode; // Register last key pressed CORE.Input.Keyboard.keyPressedQueueCount++; } #if defined(SUPPORT_SCREEN_CAPTURE) // Check screen capture key (raylib key: KEY_F12) if (CORE.Input.Keyboard.currentKeyState[301] == 1) { TakeScreenshot(TextFormat("screenshot%03i.png", screenshotCounter)); screenshotCounter++; } #endif if (CORE.Input.Keyboard.currentKeyState[CORE.Input.Keyboard.exitKey] == 1) CORE.Window.shouldClose = true; TRACELOGD("RPI: KEY_%s ScanCode: %4i KeyCode: %4i", event.value == 0 ? "UP":"DOWN", event.code, keycode); } } } } } // Input device events reading thread static void *EventThread(void *arg) { struct input_event event; InputEventWorker *worker = (InputEventWorker *)arg; int touchAction = -1; bool gestureUpdate = false; while (!CORE.Window.shouldClose) { // Try to read data from the device and only continue if successful while (read(worker->fd, &event, sizeof(event)) == (int)sizeof(event)) { // Relative movement parsing if (event.type == EV_REL) { if (event.code == REL_X) { CORE.Input.Mouse.position.x += event.value; CORE.Input.Touch.position[0].x = CORE.Input.Mouse.position.x; #if defined(SUPPORT_GESTURES_SYSTEM) touchAction = TOUCH_MOVE; gestureUpdate = true; #endif } if (event.code == REL_Y) { CORE.Input.Mouse.position.y += event.value; CORE.Input.Touch.position[0].y = CORE.Input.Mouse.position.y; #if defined(SUPPORT_GESTURES_SYSTEM) touchAction = TOUCH_MOVE; gestureUpdate = true; #endif } if (event.code == REL_WHEEL) CORE.Input.Mouse.currentWheelMove += event.value; } // Absolute movement parsing if (event.type == EV_ABS) { // Basic movement if (event.code == ABS_X) { CORE.Input.Mouse.position.x = (event.value - worker->absRange.x)*CORE.Window.screen.width/worker->absRange.width; // Scale acording to absRange CORE.Input.Touch.position[0].x = (event.value - worker->absRange.x)*CORE.Window.screen.width/worker->absRange.width; // Scale acording to absRange #if defined(SUPPORT_GESTURES_SYSTEM) touchAction = TOUCH_MOVE; gestureUpdate = true; #endif } if (event.code == ABS_Y) { CORE.Input.Mouse.position.y = (event.value - worker->absRange.y)*CORE.Window.screen.height/worker->absRange.height; // Scale acording to absRange CORE.Input.Touch.position[0].y = (event.value - worker->absRange.y)*CORE.Window.screen.height/worker->absRange.height; // Scale acording to absRange #if defined(SUPPORT_GESTURES_SYSTEM) touchAction = TOUCH_MOVE; gestureUpdate = true; #endif } // Multitouch movement if (event.code == ABS_MT_SLOT) worker->touchSlot = event.value; // Remember the slot number for the folowing events if (event.code == ABS_MT_POSITION_X) { if (worker->touchSlot < MAX_TOUCH_POINTS) CORE.Input.Touch.position[worker->touchSlot].x = (event.value - worker->absRange.x)*CORE.Window.screen.width/worker->absRange.width; // Scale acording to absRange } if (event.code == ABS_MT_POSITION_Y) { if (worker->touchSlot < MAX_TOUCH_POINTS) CORE.Input.Touch.position[worker->touchSlot].y = (event.value - worker->absRange.y)*CORE.Window.screen.height/worker->absRange.height; // Scale acording to absRange } if (event.code == ABS_MT_TRACKING_ID) { if ((event.value < 0) && (worker->touchSlot < MAX_TOUCH_POINTS)) { // Touch has ended for this point CORE.Input.Touch.position[worker->touchSlot].x = -1; CORE.Input.Touch.position[worker->touchSlot].y = -1; } } // Touchscreen tap if (event.code == ABS_PRESSURE) { int previousMouseLeftButtonState = CORE.Input.Mouse.currentButtonStateEvdev[MOUSE_LEFT_BUTTON]; if (!event.value && previousMouseLeftButtonState) { CORE.Input.Mouse.currentButtonStateEvdev[MOUSE_LEFT_BUTTON] = 0; #if defined(SUPPORT_GESTURES_SYSTEM) touchAction = TOUCH_UP; gestureUpdate = true; #endif } if (event.value && !previousMouseLeftButtonState) { CORE.Input.Mouse.currentButtonStateEvdev[MOUSE_LEFT_BUTTON] = 1; #if defined(SUPPORT_GESTURES_SYSTEM) touchAction = TOUCH_DOWN; gestureUpdate = true; #endif } } } // Button parsing if (event.type == EV_KEY) { // Mouse button parsing if ((event.code == BTN_TOUCH) || (event.code == BTN_LEFT)) { CORE.Input.Mouse.currentButtonStateEvdev[MOUSE_LEFT_BUTTON] = event.value; #if defined(SUPPORT_GESTURES_SYSTEM) if (event.value > 0) touchAction = TOUCH_DOWN; else touchAction = TOUCH_UP; gestureUpdate = true; #endif } if (event.code == BTN_RIGHT) CORE.Input.Mouse.currentButtonStateEvdev[MOUSE_RIGHT_BUTTON] = event.value; if (event.code == BTN_MIDDLE) CORE.Input.Mouse.currentButtonStateEvdev[MOUSE_MIDDLE_BUTTON] = event.value; } // Screen confinement if (!CORE.Input.Mouse.cursorHidden) { if (CORE.Input.Mouse.position.x < 0) CORE.Input.Mouse.position.x = 0; if (CORE.Input.Mouse.position.x > CORE.Window.screen.width/CORE.Input.Mouse.scale.x) CORE.Input.Mouse.position.x = CORE.Window.screen.width/CORE.Input.Mouse.scale.x; if (CORE.Input.Mouse.position.y < 0) CORE.Input.Mouse.position.y = 0; if (CORE.Input.Mouse.position.y > CORE.Window.screen.height/CORE.Input.Mouse.scale.y) CORE.Input.Mouse.position.y = CORE.Window.screen.height/CORE.Input.Mouse.scale.y; } // Gesture update if (gestureUpdate) { #if defined(SUPPORT_GESTURES_SYSTEM) GestureEvent gestureEvent = { 0 }; gestureEvent.pointCount = 0; gestureEvent.touchAction = touchAction; if (CORE.Input.Touch.position[0].x >= 0) gestureEvent.pointCount++; if (CORE.Input.Touch.position[1].x >= 0) gestureEvent.pointCount++; if (CORE.Input.Touch.position[2].x >= 0) gestureEvent.pointCount++; if (CORE.Input.Touch.position[3].x >= 0) gestureEvent.pointCount++; gestureEvent.pointerId[0] = 0; gestureEvent.pointerId[1] = 1; gestureEvent.pointerId[2] = 2; gestureEvent.pointerId[3] = 3; gestureEvent.position[0] = CORE.Input.Touch.position[0]; gestureEvent.position[1] = CORE.Input.Touch.position[1]; gestureEvent.position[2] = CORE.Input.Touch.position[2]; gestureEvent.position[3] = CORE.Input.Touch.position[3]; ProcessGestureEvent(gestureEvent); #endif } } Wait(5); // Sleep for 5ms to avoid hogging CPU time } close(worker->fd); return NULL; } // Init gamepad system static void InitGamepad(void) { char gamepadDev[128] = ""; for (int i = 0; i < MAX_GAMEPADS; i++) { sprintf(gamepadDev, "%s%i", DEFAULT_GAMEPAD_DEV, i); if ((CORE.Input.Gamepad.streamId[i] = open(gamepadDev, O_RDONLY|O_NONBLOCK)) < 0) { // NOTE: Only show message for first gamepad if (i == 0) TRACELOG(LOG_WARNING, "RPI: Failed to open Gamepad device, no gamepad available"); } else { CORE.Input.Gamepad.ready[i] = true; // NOTE: Only create one thread if (i == 0) { int error = pthread_create(&CORE.Input.Gamepad.threadId, NULL, &GamepadThread, NULL); if (error != 0) TRACELOG(LOG_WARNING, "RPI: Failed to create gamepad input event thread"); else TRACELOG(LOG_INFO, "RPI: Gamepad device initialized successfully"); } } } } // Process Gamepad (/dev/input/js0) static void *GamepadThread(void *arg) { #define JS_EVENT_BUTTON 0x01 // Button pressed/released #define JS_EVENT_AXIS 0x02 // Joystick axis moved #define JS_EVENT_INIT 0x80 // Initial state of device struct js_event { unsigned int time; // event timestamp in milliseconds short value; // event value unsigned char type; // event type unsigned char number; // event axis/button number }; // Read gamepad event struct js_event gamepadEvent; while (!CORE.Window.shouldClose) { for (int i = 0; i < MAX_GAMEPADS; i++) { if (read(CORE.Input.Gamepad.streamId[i], &gamepadEvent, sizeof(struct js_event)) == (int)sizeof(struct js_event)) { gamepadEvent.type &= ~JS_EVENT_INIT; // Ignore synthetic events // Process gamepad events by type if (gamepadEvent.type == JS_EVENT_BUTTON) { //TRACELOG(LOG_WARNING, "RPI: Gamepad button: %i, value: %i", gamepadEvent.number, gamepadEvent.value); if (gamepadEvent.number < MAX_GAMEPAD_BUTTONS) { // 1 - button pressed, 0 - button released CORE.Input.Gamepad.currentState[i][gamepadEvent.number] = (int)gamepadEvent.value; if ((int)gamepadEvent.value == 1) CORE.Input.Gamepad.lastButtonPressed = gamepadEvent.number; else CORE.Input.Gamepad.lastButtonPressed = -1; } } else if (gamepadEvent.type == JS_EVENT_AXIS) { //TRACELOG(LOG_WARNING, "RPI: Gamepad axis: %i, value: %i", gamepadEvent.number, gamepadEvent.value); if (gamepadEvent.number < MAX_GAMEPAD_AXIS) { // NOTE: Scaling of gamepadEvent.value to get values between -1..1 CORE.Input.Gamepad.axisState[i][gamepadEvent.number] = (float)gamepadEvent.value/32768; } } } else Wait(1); // Sleep for 1 ms to avoid hogging CPU time } } return NULL; } #endif // PLATFORM_RPI || PLATFORM_DRM #if defined(PLATFORM_UWP) // UWP function pointers // NOTE: Those pointers are set by UWP App static UWPQueryTimeFunc uwpQueryTimeFunc = NULL; static UWPSleepFunc uwpSleepFunc = NULL; static UWPDisplaySizeFunc uwpDisplaySizeFunc = NULL; static UWPMouseFunc uwpMouseLockFunc = NULL; static UWPMouseFunc uwpMouseUnlockFunc = NULL; static UWPMouseFunc uwpMouseShowFunc = NULL; static UWPMouseFunc uwpMouseHideFunc = NULL; static UWPMouseSetPosFunc uwpMouseSetPosFunc = NULL; static void *uwpCoreWindow = NULL; // Check all required UWP function pointers have been set bool UWPIsConfigured() { bool pass = true; if (uwpQueryTimeFunc == NULL) { TRACELOG(LOG_ERROR, "UWP: UWPSetQueryTimeFunc() must be called with a valid function before InitWindow()"); pass = false; } if (uwpSleepFunc == NULL) { TRACELOG(LOG_ERROR, "UWP: UWPSetSleepFunc() must be called with a valid function before InitWindow()"); pass = false; } if (uwpDisplaySizeFunc == NULL) { TRACELOG(LOG_ERROR, "UWP: UWPSetDisplaySizeFunc() must be called with a valid function before InitWindow()"); pass = false; } if (uwpMouseLockFunc == NULL) { TRACELOG(LOG_ERROR, "UWP: UWPSetMouseLockFunc() must be called with a valid function before InitWindow()"); pass = false; } if (uwpMouseUnlockFunc == NULL) { TRACELOG(LOG_ERROR, "UWP: UWPSetMouseUnlockFunc() must be called with a valid function before InitWindow()"); pass = false; } if (uwpMouseShowFunc == NULL) { TRACELOG(LOG_ERROR, "UWP: UWPSetMouseShowFunc() must be called with a valid function before InitWindow()"); pass = false; } if (uwpMouseHideFunc == NULL) { TRACELOG(LOG_ERROR, "UWP: UWPSetMouseHideFunc() must be called with a valid function before InitWindow()"); pass = false; } if (uwpMouseSetPosFunc == NULL) { TRACELOG(LOG_ERROR, "UWP: UWPSetMouseSetPosFunc() must be called with a valid function before InitWindow()"); pass = false; } if (uwpCoreWindow == NULL) { TRACELOG(LOG_ERROR, "UWP: A pointer to the UWP core window must be set before InitWindow()"); pass = false; } return pass; } // UWP function handlers get/set void UWPSetDataPath(const char* path) { CORE.UWP.internalDataPath = path; } UWPQueryTimeFunc UWPGetQueryTimeFunc(void) { return uwpQueryTimeFunc; } void UWPSetQueryTimeFunc(UWPQueryTimeFunc func) { uwpQueryTimeFunc = func; } UWPSleepFunc UWPGetSleepFunc(void) { return uwpSleepFunc; } void UWPSetSleepFunc(UWPSleepFunc func) { uwpSleepFunc = func; } UWPDisplaySizeFunc UWPGetDisplaySizeFunc(void) { return uwpDisplaySizeFunc; } void UWPSetDisplaySizeFunc(UWPDisplaySizeFunc func) { uwpDisplaySizeFunc = func; } UWPMouseFunc UWPGetMouseLockFunc() { return uwpMouseLockFunc; } void UWPSetMouseLockFunc(UWPMouseFunc func) { uwpMouseLockFunc = func; } UWPMouseFunc UWPGetMouseUnlockFunc() { return uwpMouseUnlockFunc; } void UWPSetMouseUnlockFunc(UWPMouseFunc func) { uwpMouseUnlockFunc = func; } UWPMouseFunc UWPGetMouseShowFunc() { return uwpMouseShowFunc; } void UWPSetMouseShowFunc(UWPMouseFunc func) { uwpMouseShowFunc = func; } UWPMouseFunc UWPGetMouseHideFunc() { return uwpMouseHideFunc; } void UWPSetMouseHideFunc(UWPMouseFunc func) { uwpMouseHideFunc = func; } UWPMouseSetPosFunc UWPGetMouseSetPosFunc() { return uwpMouseSetPosFunc; } void UWPSetMouseSetPosFunc(UWPMouseSetPosFunc func) { uwpMouseSetPosFunc = func; } void *UWPGetCoreWindowPtr() { return uwpCoreWindow; } void UWPSetCoreWindowPtr(void* ptr) { uwpCoreWindow = ptr; } void UWPMouseWheelEvent(int deltaY) { CORE.Input.Mouse.currentWheelMove = (float)deltaY; } void UWPKeyDownEvent(int key, bool down, bool controlKey) { if (key == CORE.Input.Keyboard.exitKey && down) { // Time to close the window. CORE.Window.shouldClose = true; } #if defined(SUPPORT_SCREEN_CAPTURE) else if (key == KEY_F12 && down) { #if defined(SUPPORT_GIF_RECORDING) if (controlKey) { if (gifRecording) { gifRecording = false; MsfGifResult result = msf_gif_end(&gifState); SaveFileData(TextFormat("%s/screenrec%03i.gif", CORE.UWP.internalDataPath, screenshotCounter), result.data, result.dataSize); msf_gif_free(result); #if defined(PLATFORM_WEB) // Download file from MEMFS (emscripten memory filesystem) // saveFileFromMEMFSToDisk() function is defined in raylib/templates/web_shel/shell.html emscripten_run_script(TextFormat("saveFileFromMEMFSToDisk('%s','%s')", TextFormat("screenrec%03i.gif", screenshotCounter - 1), TextFormat("screenrec%03i.gif", screenshotCounter - 1))); #endif TRACELOG(LOG_INFO, "SYSTEM: Finish animated GIF recording"); } else { gifRecording = true; gifFramesCounter = 0; msf_gif_begin(&gifState, CORE.Window.screen.width, CORE.Window.screen.height); screenshotCounter++; TRACELOG(LOG_INFO, "SYSTEM: Start animated GIF recording: %s", TextFormat("screenrec%03i.gif", screenshotCounter)); } } else #endif // SUPPORT_GIF_RECORDING { TakeScreenshot(TextFormat("screenshot%03i.png", screenshotCounter)); screenshotCounter++; } } #endif // SUPPORT_SCREEN_CAPTURE else { CORE.Input.Keyboard.currentKeyState[key] = down; } } void UWPKeyCharEvent(int key) { if (CORE.Input.Keyboard.keyPressedQueueCount < MAX_KEY_PRESSED_QUEUE) { // Add character to the queue CORE.Input.Keyboard.keyPressedQueue[CORE.Input.Keyboard.keyPressedQueueCount] = key; CORE.Input.Keyboard.keyPressedQueueCount++; } } void UWPMouseButtonEvent(int button, bool down) { CORE.Input.Mouse.currentButtonState[button] = down; #if defined(SUPPORT_GESTURES_SYSTEM) && defined(SUPPORT_MOUSE_GESTURES) // Process mouse events as touches to be able to use mouse-gestures GestureEvent gestureEvent = { 0 }; // Register touch actions if ((CORE.Input.Mouse.currentButtonState[button] == 1) && (CORE.Input.Mouse.previousButtonState[button] == 0)) gestureEvent.touchAction = TOUCH_DOWN; else if ((CORE.Input.Mouse.currentButtonState[button] == 0) && (CORE.Input.Mouse.previousButtonState[button] == 1)) gestureEvent.touchAction = TOUCH_UP; // NOTE: TOUCH_MOVE event is registered in MouseCursorPosCallback() // Assign a pointer ID gestureEvent.pointerId[0] = 0; // Register touch points count gestureEvent.pointCount = 1; // Register touch points position, only one point registered gestureEvent.position[0] = GetMousePosition(); // Normalize gestureEvent.position[0] for CORE.Window.screen.width and CORE.Window.screen.height gestureEvent.position[0].x /= (float)GetScreenWidth(); gestureEvent.position[0].y /= (float)GetScreenHeight(); // Gesture data is sent to gestures system for processing ProcessGestureEvent(gestureEvent); #endif } void UWPMousePosEvent(double x, double y) { CORE.Input.Mouse.position.x = (float)x; CORE.Input.Mouse.position.y = (float)y; CORE.Input.Touch.position[0] = CORE.Input.Mouse.position; #if defined(SUPPORT_GESTURES_SYSTEM) && defined(SUPPORT_MOUSE_GESTURES) // Process mouse events as touches to be able to use mouse-gestures GestureEvent gestureEvent = { 0 }; gestureEvent.touchAction = TOUCH_MOVE; // Assign a pointer ID gestureEvent.pointerId[0] = 0; // Register touch points count gestureEvent.pointCount = 1; // Register touch points position, only one point registered gestureEvent.position[0] = CORE.Input.Mouse.position; // Normalize gestureEvent.position[0] for CORE.Window.screen.width and CORE.Window.screen.height gestureEvent.position[0].x /= (float)GetScreenWidth(); gestureEvent.position[0].y /= (float)GetScreenHeight(); // Gesture data is sent to gestures system for processing ProcessGestureEvent(gestureEvent); #endif } void UWPResizeEvent(int width, int height) { SetupViewport(width, height); // Reset viewport and projection matrix for new size // Set current screen size CORE.Window.screen.width = width; CORE.Window.screen.height = height; CORE.Window.currentFbo.width = width; CORE.Window.currentFbo.height = height; // NOTE: Postprocessing texture is not scaled to new size CORE.Window.resizedLastFrame = true; } void UWPActivateGamepadEvent(int gamepad, bool active) { if (gamepad < MAX_GAMEPADS) CORE.Input.Gamepad.ready[gamepad] = active; } void UWPRegisterGamepadButton(int gamepad, int button, bool down) { if (gamepad < MAX_GAMEPADS) { if (button < MAX_GAMEPAD_BUTTONS) { CORE.Input.Gamepad.currentState[gamepad][button] = down; CORE.Input.Gamepad.lastButtonPressed = button; } } } void UWPRegisterGamepadAxis(int gamepad, int axis, float value) { if (gamepad < MAX_GAMEPADS) { if (axis < MAX_GAMEPAD_AXIS) CORE.Input.Gamepad.axisState[gamepad][axis] = value; } } void UWPGestureMove(int pointer, float x, float y) { #if defined(SUPPORT_GESTURES_SYSTEM) GestureEvent gestureEvent = { 0 }; // Assign the pointer ID and touch action gestureEvent.pointerId[0] = pointer; gestureEvent.touchAction = TOUCH_MOVE; // Register touch points count gestureEvent.pointCount = 1; // Register touch points position, only one point registered gestureEvent.position[0].x = x; gestureEvent.position[0].y = y; // Normalize gestureEvent.position[0] for CORE.Window.screen.width and CORE.Window.screen.height gestureEvent.position[0].x /= (float)GetScreenWidth(); gestureEvent.position[0].y /= (float)GetScreenHeight(); // Gesture data is sent to gestures system for processing ProcessGestureEvent(gestureEvent); #endif } void UWPGestureTouch(int pointer, float x, float y, bool touch) { #if defined(SUPPORT_GESTURES_SYSTEM) GestureEvent gestureEvent = { 0 }; // Assign the pointer ID and touch action gestureEvent.pointerId[0] = pointer; gestureEvent.touchAction = touch ? TOUCH_DOWN : TOUCH_UP; // Register touch points count gestureEvent.pointCount = 1; // Register touch points position, only one point registered gestureEvent.position[0].x = x; gestureEvent.position[0].y = y; // Normalize gestureEvent.position[0] for CORE.Window.screen.width and CORE.Window.screen.height gestureEvent.position[0].x /= (float)GetScreenWidth(); gestureEvent.position[0].y /= (float)GetScreenHeight(); // Gesture data is sent to gestures system for processing ProcessGestureEvent(gestureEvent); #endif } #endif // PLATFORM_UWP #if defined(PLATFORM_DRM) // Search matching DRM mode in connector's mode list static int FindMatchingConnectorMode(const drmModeConnector *connector, const drmModeModeInfo *mode) { if (NULL == connector) return -1; if (NULL == mode) return -1; // safe bitwise comparison of two modes #define BINCMP(a, b) memcmp((a), (b), (sizeof(a) < sizeof(b)) ? sizeof(a) : sizeof(b)) for (size_t i = 0; i < connector->count_modes; i++) { TRACELOG(LOG_TRACE, "DISPLAY: DRM mode: %d %ux%u@%u %s", i, connector->modes[i].hdisplay, connector->modes[i].vdisplay, connector->modes[i].vrefresh, (connector->modes[i].flags & DRM_MODE_FLAG_INTERLACE) ? "interlaced" : "progressive"); if (0 == BINCMP(&CORE.Window.crtc->mode, &CORE.Window.connector->modes[i])) return i; } return -1; #undef BINCMP } // Search exactly matching DRM connector mode in connector's list static int FindExactConnectorMode(const drmModeConnector *connector, uint width, uint height, uint fps, bool allowInterlaced) { TRACELOG(LOG_TRACE, "DISPLAY: Searching exact connector mode for %ux%u@%u, selecting an interlaced mode is allowed: %s", width, height, fps, allowInterlaced ? "yes" : "no"); if (NULL == connector) return -1; for (int i = 0; i < CORE.Window.connector->count_modes; i++) { const drmModeModeInfo *const mode = &CORE.Window.connector->modes[i]; TRACELOG(LOG_TRACE, "DISPLAY: DRM Mode %d %ux%u@%u %s", i, mode->hdisplay, mode->vdisplay, mode->vrefresh, (mode->flags & DRM_MODE_FLAG_INTERLACE) ? "interlaced" : "progressive"); if ((mode->flags & DRM_MODE_FLAG_INTERLACE) && (!allowInterlaced)) continue; if ((mode->hdisplay == width) && (mode->vdisplay == height) && (mode->vrefresh == fps)) return i; } TRACELOG(LOG_TRACE, "DISPLAY: No DRM exact matching mode found"); return -1; } // Search the nearest matching DRM connector mode in connector's list static int FindNearestConnectorMode(const drmModeConnector *connector, uint width, uint height, uint fps, bool allowInterlaced) { TRACELOG(LOG_TRACE, "DISPLAY: Searching nearest connector mode for %ux%u@%u, selecting an interlaced mode is allowed: %s", width, height, fps, allowInterlaced ? "yes" : "no"); if (NULL == connector) return -1; int nearestIndex = -1; for (int i = 0; i < CORE.Window.connector->count_modes; i++) { const drmModeModeInfo *const mode = &CORE.Window.connector->modes[i]; TRACELOG(LOG_TRACE, "DISPLAY: DRM mode: %d %ux%u@%u %s", i, mode->hdisplay, mode->vdisplay, mode->vrefresh, (mode->flags & DRM_MODE_FLAG_INTERLACE) ? "interlaced" : "progressive"); if ((mode->hdisplay < width) || (mode->vdisplay < height) | (mode->vrefresh < fps)) { TRACELOG(LOG_TRACE, "DISPLAY: DRM mode is too small"); continue; } if ((mode->flags & DRM_MODE_FLAG_INTERLACE) && (!allowInterlaced)) { TRACELOG(LOG_TRACE, "DISPLAY: DRM shouldn't choose an interlaced mode"); continue; } if ((mode->hdisplay >= width) && (mode->vdisplay >= height) && (mode->vrefresh >= fps)) { const int widthDiff = mode->hdisplay - width; const int heightDiff = mode->vdisplay - height; const int fpsDiff = mode->vrefresh - fps; if (nearestIndex < 0) { nearestIndex = i; continue; } const int nearestWidthDiff = CORE.Window.connector->modes[nearestIndex].hdisplay - width; const int nearestHeightDiff = CORE.Window.connector->modes[nearestIndex].vdisplay - height; const int nearestFpsDiff = CORE.Window.connector->modes[nearestIndex].vrefresh - fps; if ((widthDiff < nearestWidthDiff) || (heightDiff < nearestHeightDiff) || (fpsDiff < nearestFpsDiff)) nearestIndex = i; } } return nearestIndex; } #endif