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//
// This file was autogenerated.
//
RAYLIB_VERSION_MAJOR :: 5;
RAYLIB_VERSION_MINOR :: 5;
RAYLIB_VERSION_PATCH :: 0;
RAYLIB_VERSION :: "5.5";
PI :: 3.14159265358979323846;
DEG2RAD :: PI/180.0;
RAD2DEG :: 180.0/PI;
GetMouseRay :: GetScreenToWorldRay;
EPSILON :: 0.000001;
// Vector2, 2 components
Vector2 :: struct {
x: float; // Vector x component
y: float; // Vector y component
}
// Vector3, 3 components
Vector3 :: struct {
x: float; // Vector x component
y: float; // Vector y component
z: float; // Vector z component
}
// Vector4, 4 components
Vector4 :: struct {
x: float; // Vector x component
y: float; // Vector y component
z: float; // Vector z component
w: float; // Vector w component
}
// Quaternion, 4 components (Vector4 alias)
Quaternion :: Vector4;
// Matrix, 4x4 components, column major, OpenGL style, right-handed
Matrix :: struct {
m0: float; // Matrix first row (4 components)
m4: float; // Matrix first row (4 components)
m8: float; // Matrix first row (4 components)
m12: float; // Matrix first row (4 components)
m1: float; // Matrix second row (4 components)
m5: float; // Matrix second row (4 components)
m9: float; // Matrix second row (4 components)
m13: float; // Matrix second row (4 components)
m2: float; // Matrix third row (4 components)
m6: float; // Matrix third row (4 components)
m10: float; // Matrix third row (4 components)
m14: float; // Matrix third row (4 components)
m3: float; // Matrix fourth row (4 components)
m7: float; // Matrix fourth row (4 components)
m11: float; // Matrix fourth row (4 components)
m15: float; // Matrix fourth row (4 components)
}
// Color, 4 components, R8G8B8A8 (32bit)
Color :: struct {
r: u8; // Color red value
g: u8; // Color green value
b: u8; // Color blue value
a: u8; // Color alpha value
}
// Rectangle, 4 components
Rectangle :: struct {
x: float; // Rectangle top-left corner position x
y: float; // Rectangle top-left corner position y
width: float; // Rectangle width
height: float; // Rectangle height
}
// Image, pixel data stored in CPU memory (RAM)
Image :: struct {
data: *void; // Image raw data
width: s32; // Image base width
height: s32; // Image base height
mipmaps: s32; // Mipmap levels, 1 by default
format: s32; // Data format (PixelFormat type)
}
// Texture, tex data stored in GPU memory (VRAM)
Texture :: struct {
id: u32; // OpenGL texture id
width: s32; // Texture base width
height: s32; // Texture base height
mipmaps: s32; // Mipmap levels, 1 by default
format: s32; // Data format (PixelFormat type)
}
// Texture2D, same as Texture
Texture2D :: Texture;
// TextureCubemap, same as Texture
TextureCubemap :: Texture;
// RenderTexture, fbo for texture rendering
RenderTexture :: struct {
id: u32; // OpenGL framebuffer object id
texture: Texture; // Color buffer attachment texture
depth: Texture; // Depth buffer attachment texture
}
// RenderTexture2D, same as RenderTexture
RenderTexture2D :: RenderTexture;
// NPatchInfo, n-patch layout info
NPatchInfo :: struct {
source: Rectangle; // Texture source rectangle
left: s32; // Left border offset
top: s32; // Top border offset
right: s32; // Right border offset
bottom: s32; // Bottom border offset
layout: s32; // Layout of the n-patch: 3x3, 1x3 or 3x1
}
// GlyphInfo, font characters glyphs info
GlyphInfo :: struct {
value: s32; // Character value (Unicode)
offsetX: s32; // Character offset X when drawing
offsetY: s32; // Character offset Y when drawing
advanceX: s32; // Character advance position X
image: Image; // Character image data
}
// Font, font texture and GlyphInfo array data
Font :: struct {
baseSize: s32; // Base size (default chars height)
glyphCount: s32; // Number of glyph characters
glyphPadding: s32; // Padding around the glyph characters
texture: Texture2D; // Texture atlas containing the glyphs
recs: *Rectangle; // Rectangles in texture for the glyphs
glyphs: *GlyphInfo; // Glyphs info data
}
// Camera, defines position/orientation in 3d space
Camera3D :: struct {
position: Vector3; // Camera position
target: Vector3; // Camera target it looks-at
up: Vector3; // Camera up vector (rotation over its axis)
fovy: float; // Camera field-of-view aperture in Y (degrees) in perspective, used as near plane width in orthographic
projection: s32; // Camera projection: CAMERA_PERSPECTIVE or CAMERA_ORTHOGRAPHIC
}
Camera :: Camera3D;
// Camera2D, defines position/orientation in 2d space
Camera2D :: struct {
offset: Vector2; // Camera offset (displacement from target)
target: Vector2; // Camera target (rotation and zoom origin)
rotation: float; // Camera rotation in degrees
zoom: float; // Camera zoom (scaling), should be 1.0f by default
}
// Mesh, vertex data and vao/vbo
Mesh :: struct {
vertexCount: s32; // Number of vertices stored in arrays
triangleCount: s32; // Number of triangles stored (indexed or not)
vertices: *float; // Vertex position (XYZ - 3 components per vertex) (shader-location = 0)
texcoords: *float; // Vertex texture coordinates (UV - 2 components per vertex) (shader-location = 1)
texcoords2: *float; // Vertex texture second coordinates (UV - 2 components per vertex) (shader-location = 5)
normals: *float; // Vertex normals (XYZ - 3 components per vertex) (shader-location = 2)
tangents: *float; // Vertex tangents (XYZW - 4 components per vertex) (shader-location = 4)
colors: *u8; // Vertex colors (RGBA - 4 components per vertex) (shader-location = 3)
indices: *u16; // Vertex indices (in case vertex data comes indexed)
animVertices: *float; // Animated vertex positions (after bones transformations)
animNormals: *float; // Animated normals (after bones transformations)
boneIds: *u8; // Vertex bone ids, max 255 bone ids, up to 4 bones influence by vertex (skinning) (shader-location = 6)
boneWeights: *float; // Vertex bone weight, up to 4 bones influence by vertex (skinning) (shader-location = 7)
boneMatrices: *Matrix; // Bones animated transformation matrices
boneCount: s32; // Number of bones
vaoId: u32; // OpenGL Vertex Array Object id
vboId: *u32; // OpenGL Vertex Buffer Objects id (default vertex data)
}
// Shader
Shader :: struct {
id: u32; // Shader program id
locs: *s32; // Shader locations array (RL_MAX_SHADER_LOCATIONS)
}
// MaterialMap
MaterialMap :: struct {
texture: Texture2D; // Material map texture
color: Color; // Material map color
value: float; // Material map value
}
// Material, includes shader and maps
Material :: struct {
shader: Shader; // Material shader
maps: *MaterialMap; // Material maps array (MAX_MATERIAL_MAPS)
params: [4] float; // Material generic parameters (if required)
}
// Transform, vertex transformation data
Transform :: struct {
translation: Vector3; // Translation
rotation: Quaternion; // Rotation
scale: Vector3; // Scale
}
// Bone, skeletal animation bone
BoneInfo :: struct {
name: [32] u8; // Bone name
parent: s32; // Bone parent
}
// Model, meshes, materials and animation data
Model :: struct {
transform: Matrix; // Local transform matrix
meshCount: s32; // Number of meshes
materialCount: s32; // Number of materials
meshes: *Mesh; // Meshes array
materials: *Material; // Materials array
meshMaterial: *s32; // Mesh material number
boneCount: s32; // Number of bones
bones: *BoneInfo; // Bones information (skeleton)
bindPose: *Transform; // Bones base transformation (pose)
}
// ModelAnimation
ModelAnimation :: struct {
boneCount: s32; // Number of bones
frameCount: s32; // Number of animation frames
bones: *BoneInfo; // Bones information (skeleton)
framePoses: **Transform; // Poses array by frame
name: [32] u8; // Animation name
}
// Ray, ray for raycasting
Ray :: struct {
position: Vector3; // Ray position (origin)
direction: Vector3; // Ray direction (normalized)
}
// RayCollision, ray hit information
RayCollision :: struct {
hit: bool; // Did the ray hit something?
distance: float; // Distance to the nearest hit
point: Vector3; // Point of the nearest hit
normal: Vector3; // Surface normal of hit
}
// BoundingBox
BoundingBox :: struct {
min: Vector3; // Minimum vertex box-corner
max: Vector3; // Maximum vertex box-corner
}
// Wave, audio wave data
Wave :: struct {
frameCount: u32; // Total number of frames (considering channels)
sampleRate: u32; // Frequency (samples per second)
sampleSize: u32; // Bit depth (bits per sample): 8, 16, 32 (24 not supported)
channels: u32; // Number of channels (1-mono, 2-stereo, ...)
data: *void; // Buffer data pointer
}
rAudioBuffer :: struct {}
rAudioProcessor :: struct {}
// AudioStream, custom audio stream
AudioStream :: struct {
buffer: *rAudioBuffer; // Pointer to internal data used by the audio system
processor: *rAudioProcessor; // Pointer to internal data processor, useful for audio effects
sampleRate: u32; // Frequency (samples per second)
sampleSize: u32; // Bit depth (bits per sample): 8, 16, 32 (24 not supported)
channels: u32; // Number of channels (1-mono, 2-stereo, ...)
}
// Sound
Sound :: struct {
stream: AudioStream; // Audio stream
frameCount: u32; // Total number of frames (considering channels)
}
// Music, audio stream, anything longer than ~10 seconds should be streamed
Music :: struct {
stream: AudioStream; // Audio stream
frameCount: u32; // Total number of frames (considering channels)
looping: bool; // Music looping enable
ctxType: s32; // Type of music context (audio filetype)
ctxData: *void; // Audio context data, depends on type
}
// VrDeviceInfo, Head-Mounted-Display device parameters
VrDeviceInfo :: struct {
hResolution: s32; // Horizontal resolution in pixels
vResolution: s32; // Vertical resolution in pixels
hScreenSize: float; // Horizontal size in meters
vScreenSize: float; // Vertical size in meters
eyeToScreenDistance: float; // Distance between eye and display in meters
lensSeparationDistance: float; // Lens separation distance in meters
interpupillaryDistance: float; // IPD (distance between pupils) in meters
lensDistortionValues: [4] float; // Lens distortion constant parameters
chromaAbCorrection: [4] float; // Chromatic aberration correction parameters
}
// VrStereoConfig, VR stereo rendering configuration for simulator
VrStereoConfig :: struct {
projection: [2] Matrix; // VR projection matrices (per eye)
viewOffset: [2] Matrix; // VR view offset matrices (per eye)
leftLensCenter: [2] float; // VR left lens center
rightLensCenter: [2] float; // VR right lens center
leftScreenCenter: [2] float; // VR left screen center
rightScreenCenter: [2] float; // VR right screen center
scale: [2] float; // VR distortion scale
scaleIn: [2] float; // VR distortion scale in
}
// File path list
FilePathList :: struct {
capacity: u32; // Filepaths max entries
count: u32; // Filepaths entries count
paths: **u8; // Filepaths entries
}
// Automation event
AutomationEvent :: struct {
frame: u32; // Event frame
type: u32; // Event type (AutomationEventType)
params: [4] s32; // Event parameters (if required)
}
// Automation event list
AutomationEventList :: struct {
capacity: u32; // Events max entries (MAX_AUTOMATION_EVENTS)
count: u32; // Events entries count
events: *AutomationEvent; // Events entries
}
//----------------------------------------------------------------------------------
// Enumerators Definition
//----------------------------------------------------------------------------------
// System/Window config flags
// NOTE: Every bit registers one state (use it with bit masks)
// By default all flags are set to 0
ConfigFlags :: enum u32 {
VSYNC_HINT :: 64;
FULLSCREEN_MODE :: 2;
WINDOW_RESIZABLE :: 4;
WINDOW_UNDECORATED :: 8;
WINDOW_HIDDEN :: 128;
WINDOW_MINIMIZED :: 512;
WINDOW_MAXIMIZED :: 1024;
WINDOW_UNFOCUSED :: 2048;
WINDOW_TOPMOST :: 4096;
WINDOW_ALWAYS_RUN :: 256;
WINDOW_TRANSPARENT :: 16;
WINDOW_HIGHDPI :: 8192;
WINDOW_MOUSE_PASSTHROUGH :: 16384;
BORDERLESS_WINDOWED_MODE :: 32768;
MSAA_4X_HINT :: 32;
INTERLACED_HINT :: 65536;
FLAG_VSYNC_HINT :: VSYNC_HINT;
FLAG_FULLSCREEN_MODE :: FULLSCREEN_MODE;
FLAG_WINDOW_RESIZABLE :: WINDOW_RESIZABLE;
FLAG_WINDOW_UNDECORATED :: WINDOW_UNDECORATED;
FLAG_WINDOW_HIDDEN :: WINDOW_HIDDEN;
FLAG_WINDOW_MINIMIZED :: WINDOW_MINIMIZED;
FLAG_WINDOW_MAXIMIZED :: WINDOW_MAXIMIZED;
FLAG_WINDOW_UNFOCUSED :: WINDOW_UNFOCUSED;
FLAG_WINDOW_TOPMOST :: WINDOW_TOPMOST;
FLAG_WINDOW_ALWAYS_RUN :: WINDOW_ALWAYS_RUN;
FLAG_WINDOW_TRANSPARENT :: WINDOW_TRANSPARENT;
FLAG_WINDOW_HIGHDPI :: WINDOW_HIGHDPI;
FLAG_WINDOW_MOUSE_PASSTHROUGH :: WINDOW_MOUSE_PASSTHROUGH;
FLAG_BORDERLESS_WINDOWED_MODE :: BORDERLESS_WINDOWED_MODE;
FLAG_MSAA_4X_HINT :: MSAA_4X_HINT;
FLAG_INTERLACED_HINT :: INTERLACED_HINT;
}
// Trace log level
// NOTE: Organized by priority level
TraceLogLevel :: enum u32 {
ALL :: 0;
TRACE :: 1;
DEBUG :: 2;
INFO :: 3;
WARNING :: 4;
ERROR :: 5;
FATAL :: 6;
NONE :: 7;
LOG_ALL :: ALL;
LOG_TRACE :: TRACE;
LOG_DEBUG :: DEBUG;
LOG_INFO :: INFO;
LOG_WARNING :: WARNING;
LOG_ERROR :: ERROR;
LOG_FATAL :: FATAL;
LOG_NONE :: NONE;
}
// Keyboard keys (US keyboard layout)
// NOTE: Use GetKeyPressed() to allow redefining
// required keys for alternative layouts
KeyboardKey :: enum u32 {
NULL :: 0;
APOSTROPHE :: 39;
COMMA :: 44;
MINUS :: 45;
PERIOD :: 46;
SLASH :: 47;
ZERO :: 48;
ONE :: 49;
TWO :: 50;
THREE :: 51;
FOUR :: 52;
FIVE :: 53;
SIX :: 54;
SEVEN :: 55;
EIGHT :: 56;
NINE :: 57;
SEMICOLON :: 59;
EQUAL :: 61;
A :: 65;
B :: 66;
C :: 67;
D :: 68;
E :: 69;
F :: 70;
G :: 71;
H :: 72;
I :: 73;
J :: 74;
K :: 75;
L :: 76;
M :: 77;
N :: 78;
O :: 79;
P :: 80;
Q :: 81;
R :: 82;
S :: 83;
T :: 84;
U :: 85;
V :: 86;
W :: 87;
X :: 88;
Y :: 89;
Z :: 90;
LEFT_BRACKET :: 91;
BACKSLASH :: 92;
RIGHT_BRACKET :: 93;
GRAVE :: 96;
SPACE :: 32;
ESCAPE :: 256;
ENTER :: 257;
TAB :: 258;
BACKSPACE :: 259;
INSERT :: 260;
DELETE :: 261;
RIGHT :: 262;
LEFT :: 263;
DOWN :: 264;
UP :: 265;
PAGE_UP :: 266;
PAGE_DOWN :: 267;
HOME :: 268;
END :: 269;
CAPS_LOCK :: 280;
SCROLL_LOCK :: 281;
NUM_LOCK :: 282;
PRINT_SCREEN :: 283;
PAUSE :: 284;
F1 :: 290;
F2 :: 291;
F3 :: 292;
F4 :: 293;
F5 :: 294;
F6 :: 295;
F7 :: 296;
F8 :: 297;
F9 :: 298;
F10 :: 299;
F11 :: 300;
F12 :: 301;
LEFT_SHIFT :: 340;
LEFT_CONTROL :: 341;
LEFT_ALT :: 342;
LEFT_SUPER :: 343;
RIGHT_SHIFT :: 344;
RIGHT_CONTROL :: 345;
RIGHT_ALT :: 346;
RIGHT_SUPER :: 347;
KB_MENU :: 348;
KP_0 :: 320;
KP_1 :: 321;
KP_2 :: 322;
KP_3 :: 323;
KP_4 :: 324;
KP_5 :: 325;
KP_6 :: 326;
KP_7 :: 327;
KP_8 :: 328;
KP_9 :: 329;
KP_DECIMAL :: 330;
KP_DIVIDE :: 331;
KP_MULTIPLY :: 332;
KP_SUBTRACT :: 333;
KP_ADD :: 334;
KP_ENTER :: 335;
KP_EQUAL :: 336;
BACK :: 4;
MENU :: 5;
VOLUME_UP :: 24;
VOLUME_DOWN :: 25;
KEY_NULL :: NULL;
KEY_APOSTROPHE :: APOSTROPHE;
KEY_COMMA :: COMMA;
KEY_MINUS :: MINUS;
KEY_PERIOD :: PERIOD;
KEY_SLASH :: SLASH;
KEY_ZERO :: ZERO;
KEY_ONE :: ONE;
KEY_TWO :: TWO;
KEY_THREE :: THREE;
KEY_FOUR :: FOUR;
KEY_FIVE :: FIVE;
KEY_SIX :: SIX;
KEY_SEVEN :: SEVEN;
KEY_EIGHT :: EIGHT;
KEY_NINE :: NINE;
KEY_SEMICOLON :: SEMICOLON;
KEY_EQUAL :: EQUAL;
KEY_A :: A;
KEY_B :: B;
KEY_C :: C;
KEY_D :: D;
KEY_E :: E;
KEY_F :: F;
KEY_G :: G;
KEY_H :: H;
KEY_I :: I;
KEY_J :: J;
KEY_K :: K;
KEY_L :: L;
KEY_M :: M;
KEY_N :: N;
KEY_O :: O;
KEY_P :: P;
KEY_Q :: Q;
KEY_R :: R;
KEY_S :: S;
KEY_T :: T;
KEY_U :: U;
KEY_V :: V;
KEY_W :: W;
KEY_X :: X;
KEY_Y :: Y;
KEY_Z :: Z;
KEY_LEFT_BRACKET :: LEFT_BRACKET;
KEY_BACKSLASH :: BACKSLASH;
KEY_RIGHT_BRACKET :: RIGHT_BRACKET;
KEY_GRAVE :: GRAVE;
KEY_SPACE :: SPACE;
KEY_ESCAPE :: ESCAPE;
KEY_ENTER :: ENTER;
KEY_TAB :: TAB;
KEY_BACKSPACE :: BACKSPACE;
KEY_INSERT :: INSERT;
KEY_DELETE :: DELETE;
KEY_RIGHT :: RIGHT;
KEY_LEFT :: LEFT;
KEY_DOWN :: DOWN;
KEY_UP :: UP;
KEY_PAGE_UP :: PAGE_UP;
KEY_PAGE_DOWN :: PAGE_DOWN;
KEY_HOME :: HOME;
KEY_END :: END;
KEY_CAPS_LOCK :: CAPS_LOCK;
KEY_SCROLL_LOCK :: SCROLL_LOCK;
KEY_NUM_LOCK :: NUM_LOCK;
KEY_PRINT_SCREEN :: PRINT_SCREEN;
KEY_PAUSE :: PAUSE;
KEY_F1 :: F1;
KEY_F2 :: F2;
KEY_F3 :: F3;
KEY_F4 :: F4;
KEY_F5 :: F5;
KEY_F6 :: F6;
KEY_F7 :: F7;
KEY_F8 :: F8;
KEY_F9 :: F9;
KEY_F10 :: F10;
KEY_F11 :: F11;
KEY_F12 :: F12;
KEY_LEFT_SHIFT :: LEFT_SHIFT;
KEY_LEFT_CONTROL :: LEFT_CONTROL;
KEY_LEFT_ALT :: LEFT_ALT;
KEY_LEFT_SUPER :: LEFT_SUPER;
KEY_RIGHT_SHIFT :: RIGHT_SHIFT;
KEY_RIGHT_CONTROL :: RIGHT_CONTROL;
KEY_RIGHT_ALT :: RIGHT_ALT;
KEY_RIGHT_SUPER :: RIGHT_SUPER;
KEY_KB_MENU :: KB_MENU;
KEY_KP_0 :: KP_0;
KEY_KP_1 :: KP_1;
KEY_KP_2 :: KP_2;
KEY_KP_3 :: KP_3;
KEY_KP_4 :: KP_4;
KEY_KP_5 :: KP_5;
KEY_KP_6 :: KP_6;
KEY_KP_7 :: KP_7;
KEY_KP_8 :: KP_8;
KEY_KP_9 :: KP_9;
KEY_KP_DECIMAL :: KP_DECIMAL;
KEY_KP_DIVIDE :: KP_DIVIDE;
KEY_KP_MULTIPLY :: KP_MULTIPLY;
KEY_KP_SUBTRACT :: KP_SUBTRACT;
KEY_KP_ADD :: KP_ADD;
KEY_KP_ENTER :: KP_ENTER;
KEY_KP_EQUAL :: KP_EQUAL;
KEY_BACK :: BACK;
KEY_MENU :: MENU;
KEY_VOLUME_UP :: VOLUME_UP;
KEY_VOLUME_DOWN :: VOLUME_DOWN;
}
// Mouse buttons
MouseButton :: enum u32 {
LEFT :: 0;
RIGHT :: 1;
MIDDLE :: 2;
SIDE :: 3;
EXTRA :: 4;
FORWARD :: 5;
BACK :: 6;
MOUSE_BUTTON_LEFT :: LEFT;
MOUSE_BUTTON_RIGHT :: RIGHT;
MOUSE_BUTTON_MIDDLE :: MIDDLE;
MOUSE_BUTTON_SIDE :: SIDE;
MOUSE_BUTTON_EXTRA :: EXTRA;
MOUSE_BUTTON_FORWARD :: FORWARD;
MOUSE_BUTTON_BACK :: BACK;
}
// Mouse cursor
MouseCursor :: enum u32 {
DEFAULT :: 0;
ARROW :: 1;
IBEAM :: 2;
CROSSHAIR :: 3;
POINTING_HAND :: 4;
RESIZE_EW :: 5;
RESIZE_NS :: 6;
RESIZE_NWSE :: 7;
RESIZE_NESW :: 8;
RESIZE_ALL :: 9;
NOT_ALLOWED :: 10;
MOUSE_CURSOR_DEFAULT :: DEFAULT;
MOUSE_CURSOR_ARROW :: ARROW;
MOUSE_CURSOR_IBEAM :: IBEAM;
MOUSE_CURSOR_CROSSHAIR :: CROSSHAIR;
MOUSE_CURSOR_POINTING_HAND :: POINTING_HAND;
MOUSE_CURSOR_RESIZE_EW :: RESIZE_EW;
MOUSE_CURSOR_RESIZE_NS :: RESIZE_NS;
MOUSE_CURSOR_RESIZE_NWSE :: RESIZE_NWSE;
MOUSE_CURSOR_RESIZE_NESW :: RESIZE_NESW;
MOUSE_CURSOR_RESIZE_ALL :: RESIZE_ALL;
MOUSE_CURSOR_NOT_ALLOWED :: NOT_ALLOWED;
}
// Gamepad buttons
GamepadButton :: enum u32 {
UNKNOWN :: 0;
LEFT_FACE_UP :: 1;
LEFT_FACE_RIGHT :: 2;
LEFT_FACE_DOWN :: 3;
LEFT_FACE_LEFT :: 4;
RIGHT_FACE_UP :: 5;
RIGHT_FACE_RIGHT :: 6;
RIGHT_FACE_DOWN :: 7;
RIGHT_FACE_LEFT :: 8;
LEFT_TRIGGER_1 :: 9;
LEFT_TRIGGER_2 :: 10;
RIGHT_TRIGGER_1 :: 11;
RIGHT_TRIGGER_2 :: 12;
MIDDLE_LEFT :: 13;
MIDDLE :: 14;
MIDDLE_RIGHT :: 15;
LEFT_THUMB :: 16;
RIGHT_THUMB :: 17;
GAMEPAD_BUTTON_UNKNOWN :: UNKNOWN;
GAMEPAD_BUTTON_LEFT_FACE_UP :: LEFT_FACE_UP;
GAMEPAD_BUTTON_LEFT_FACE_RIGHT :: LEFT_FACE_RIGHT;
GAMEPAD_BUTTON_LEFT_FACE_DOWN :: LEFT_FACE_DOWN;
GAMEPAD_BUTTON_LEFT_FACE_LEFT :: LEFT_FACE_LEFT;
GAMEPAD_BUTTON_RIGHT_FACE_UP :: RIGHT_FACE_UP;
GAMEPAD_BUTTON_RIGHT_FACE_RIGHT :: RIGHT_FACE_RIGHT;
GAMEPAD_BUTTON_RIGHT_FACE_DOWN :: RIGHT_FACE_DOWN;
GAMEPAD_BUTTON_RIGHT_FACE_LEFT :: RIGHT_FACE_LEFT;
GAMEPAD_BUTTON_LEFT_TRIGGER_1 :: LEFT_TRIGGER_1;
GAMEPAD_BUTTON_LEFT_TRIGGER_2 :: LEFT_TRIGGER_2;
GAMEPAD_BUTTON_RIGHT_TRIGGER_1 :: RIGHT_TRIGGER_1;
GAMEPAD_BUTTON_RIGHT_TRIGGER_2 :: RIGHT_TRIGGER_2;
GAMEPAD_BUTTON_MIDDLE_LEFT :: MIDDLE_LEFT;
GAMEPAD_BUTTON_MIDDLE :: MIDDLE;
GAMEPAD_BUTTON_MIDDLE_RIGHT :: MIDDLE_RIGHT;
GAMEPAD_BUTTON_LEFT_THUMB :: LEFT_THUMB;
GAMEPAD_BUTTON_RIGHT_THUMB :: RIGHT_THUMB;
}
// Gamepad axis
GamepadAxis :: enum u32 {
LEFT_X :: 0;
LEFT_Y :: 1;
RIGHT_X :: 2;
RIGHT_Y :: 3;
LEFT_TRIGGER :: 4;
RIGHT_TRIGGER :: 5;
GAMEPAD_AXIS_LEFT_X :: LEFT_X;
GAMEPAD_AXIS_LEFT_Y :: LEFT_Y;
GAMEPAD_AXIS_RIGHT_X :: RIGHT_X;
GAMEPAD_AXIS_RIGHT_Y :: RIGHT_Y;
GAMEPAD_AXIS_LEFT_TRIGGER :: LEFT_TRIGGER;
GAMEPAD_AXIS_RIGHT_TRIGGER :: RIGHT_TRIGGER;
}
// Material map index
MaterialMapIndex :: enum u32 {
ALBEDO :: 0;
METALNESS :: 1;
NORMAL :: 2;
ROUGHNESS :: 3;
OCCLUSION :: 4;
EMISSION :: 5;
HEIGHT :: 6;
CUBEMAP :: 7;
IRRADIANCE :: 8;
PREFILTER :: 9;
BRDF :: 10;
MATERIAL_MAP_ALBEDO :: ALBEDO;
MATERIAL_MAP_METALNESS :: METALNESS;
MATERIAL_MAP_NORMAL :: NORMAL;
MATERIAL_MAP_ROUGHNESS :: ROUGHNESS;
MATERIAL_MAP_OCCLUSION :: OCCLUSION;
MATERIAL_MAP_EMISSION :: EMISSION;
MATERIAL_MAP_HEIGHT :: HEIGHT;
MATERIAL_MAP_CUBEMAP :: CUBEMAP;
MATERIAL_MAP_IRRADIANCE :: IRRADIANCE;
MATERIAL_MAP_PREFILTER :: PREFILTER;
MATERIAL_MAP_BRDF :: BRDF;
}
// Shader location index
ShaderLocationIndex :: enum u32 {
VERTEX_POSITION :: 0;
VERTEX_TEXCOORD01 :: 1;
VERTEX_TEXCOORD02 :: 2;
VERTEX_NORMAL :: 3;
VERTEX_TANGENT :: 4;
VERTEX_COLOR :: 5;
MATRIX_MVP :: 6;
MATRIX_VIEW :: 7;
MATRIX_PROJECTION :: 8;
MATRIX_MODEL :: 9;
MATRIX_NORMAL :: 10;
VECTOR_VIEW :: 11;
COLOR_DIFFUSE :: 12;
COLOR_SPECULAR :: 13;
COLOR_AMBIENT :: 14;
MAP_ALBEDO :: 15;
MAP_METALNESS :: 16;
MAP_NORMAL :: 17;
MAP_ROUGHNESS :: 18;
MAP_OCCLUSION :: 19;
MAP_EMISSION :: 20;
MAP_HEIGHT :: 21;
MAP_CUBEMAP :: 22;
MAP_IRRADIANCE :: 23;
MAP_PREFILTER :: 24;
MAP_BRDF :: 25;
VERTEX_BONEIDS :: 26;
VERTEX_BONEWEIGHTS :: 27;
BONE_MATRICES :: 28;
SHADER_LOC_VERTEX_POSITION :: VERTEX_POSITION;
SHADER_LOC_VERTEX_TEXCOORD01 :: VERTEX_TEXCOORD01;
SHADER_LOC_VERTEX_TEXCOORD02 :: VERTEX_TEXCOORD02;
SHADER_LOC_VERTEX_NORMAL :: VERTEX_NORMAL;
SHADER_LOC_VERTEX_TANGENT :: VERTEX_TANGENT;
SHADER_LOC_VERTEX_COLOR :: VERTEX_COLOR;
SHADER_LOC_MATRIX_MVP :: MATRIX_MVP;
SHADER_LOC_MATRIX_VIEW :: MATRIX_VIEW;
SHADER_LOC_MATRIX_PROJECTION :: MATRIX_PROJECTION;
SHADER_LOC_MATRIX_MODEL :: MATRIX_MODEL;
SHADER_LOC_MATRIX_NORMAL :: MATRIX_NORMAL;
SHADER_LOC_VECTOR_VIEW :: VECTOR_VIEW;
SHADER_LOC_COLOR_DIFFUSE :: COLOR_DIFFUSE;
SHADER_LOC_COLOR_SPECULAR :: COLOR_SPECULAR;
SHADER_LOC_COLOR_AMBIENT :: COLOR_AMBIENT;
SHADER_LOC_MAP_ALBEDO :: MAP_ALBEDO;
SHADER_LOC_MAP_METALNESS :: MAP_METALNESS;
SHADER_LOC_MAP_NORMAL :: MAP_NORMAL;
SHADER_LOC_MAP_ROUGHNESS :: MAP_ROUGHNESS;
SHADER_LOC_MAP_OCCLUSION :: MAP_OCCLUSION;
SHADER_LOC_MAP_EMISSION :: MAP_EMISSION;
SHADER_LOC_MAP_HEIGHT :: MAP_HEIGHT;
SHADER_LOC_MAP_CUBEMAP :: MAP_CUBEMAP;
SHADER_LOC_MAP_IRRADIANCE :: MAP_IRRADIANCE;
SHADER_LOC_MAP_PREFILTER :: MAP_PREFILTER;
SHADER_LOC_MAP_BRDF :: MAP_BRDF;
SHADER_LOC_VERTEX_BONEIDS :: VERTEX_BONEIDS;
SHADER_LOC_VERTEX_BONEWEIGHTS :: VERTEX_BONEWEIGHTS;
SHADER_LOC_BONE_MATRICES :: BONE_MATRICES;
}
// Shader uniform data type
ShaderUniformDataType :: enum u32 {
FLOAT :: 0;
VEC2 :: 1;
VEC3 :: 2;
VEC4 :: 3;
INT :: 4;
IVEC2 :: 5;
IVEC3 :: 6;
IVEC4 :: 7;
SAMPLER2D :: 8;
SHADER_UNIFORM_FLOAT :: FLOAT;
SHADER_UNIFORM_VEC2 :: VEC2;
SHADER_UNIFORM_VEC3 :: VEC3;
SHADER_UNIFORM_VEC4 :: VEC4;
SHADER_UNIFORM_INT :: INT;
SHADER_UNIFORM_IVEC2 :: IVEC2;
SHADER_UNIFORM_IVEC3 :: IVEC3;
SHADER_UNIFORM_IVEC4 :: IVEC4;
SHADER_UNIFORM_SAMPLER2D :: SAMPLER2D;
}
// Shader attribute data types
ShaderAttributeDataType :: enum u32 {
FLOAT :: 0;
VEC2 :: 1;
VEC3 :: 2;
VEC4 :: 3;
SHADER_ATTRIB_FLOAT :: FLOAT;
SHADER_ATTRIB_VEC2 :: VEC2;
SHADER_ATTRIB_VEC3 :: VEC3;
SHADER_ATTRIB_VEC4 :: VEC4;
}
// Pixel formats
// NOTE: Support depends on OpenGL version and platform
PixelFormat :: enum u32 {
UNCOMPRESSED_GRAYSCALE :: 1;
UNCOMPRESSED_GRAY_ALPHA :: 2;
UNCOMPRESSED_R5G6B5 :: 3;
UNCOMPRESSED_R8G8B8 :: 4;
UNCOMPRESSED_R5G5B5A1 :: 5;
UNCOMPRESSED_R4G4B4A4 :: 6;
UNCOMPRESSED_R8G8B8A8 :: 7;
UNCOMPRESSED_R32 :: 8;
UNCOMPRESSED_R32G32B32 :: 9;
UNCOMPRESSED_R32G32B32A32 :: 10;
UNCOMPRESSED_R16 :: 11;
UNCOMPRESSED_R16G16B16 :: 12;
UNCOMPRESSED_R16G16B16A16 :: 13;
COMPRESSED_DXT1_RGB :: 14;
COMPRESSED_DXT1_RGBA :: 15;
COMPRESSED_DXT3_RGBA :: 16;
COMPRESSED_DXT5_RGBA :: 17;
COMPRESSED_ETC1_RGB :: 18;
COMPRESSED_ETC2_RGB :: 19;
COMPRESSED_ETC2_EAC_RGBA :: 20;
COMPRESSED_PVRT_RGB :: 21;
COMPRESSED_PVRT_RGBA :: 22;
COMPRESSED_ASTC_4x4_RGBA :: 23;
COMPRESSED_ASTC_8x8_RGBA :: 24;
PIXELFORMAT_UNCOMPRESSED_GRAYSCALE :: UNCOMPRESSED_GRAYSCALE;
PIXELFORMAT_UNCOMPRESSED_GRAY_ALPHA :: UNCOMPRESSED_GRAY_ALPHA;
PIXELFORMAT_UNCOMPRESSED_R5G6B5 :: UNCOMPRESSED_R5G6B5;
PIXELFORMAT_UNCOMPRESSED_R8G8B8 :: UNCOMPRESSED_R8G8B8;
PIXELFORMAT_UNCOMPRESSED_R5G5B5A1 :: UNCOMPRESSED_R5G5B5A1;
PIXELFORMAT_UNCOMPRESSED_R4G4B4A4 :: UNCOMPRESSED_R4G4B4A4;
PIXELFORMAT_UNCOMPRESSED_R8G8B8A8 :: UNCOMPRESSED_R8G8B8A8;
PIXELFORMAT_UNCOMPRESSED_R32 :: UNCOMPRESSED_R32;
PIXELFORMAT_UNCOMPRESSED_R32G32B32 :: UNCOMPRESSED_R32G32B32;
PIXELFORMAT_UNCOMPRESSED_R32G32B32A32 :: UNCOMPRESSED_R32G32B32A32;
PIXELFORMAT_UNCOMPRESSED_R16 :: UNCOMPRESSED_R16;
PIXELFORMAT_UNCOMPRESSED_R16G16B16 :: UNCOMPRESSED_R16G16B16;
PIXELFORMAT_UNCOMPRESSED_R16G16B16A16 :: UNCOMPRESSED_R16G16B16A16;
PIXELFORMAT_COMPRESSED_DXT1_RGB :: COMPRESSED_DXT1_RGB;
PIXELFORMAT_COMPRESSED_DXT1_RGBA :: COMPRESSED_DXT1_RGBA;
PIXELFORMAT_COMPRESSED_DXT3_RGBA :: COMPRESSED_DXT3_RGBA;
PIXELFORMAT_COMPRESSED_DXT5_RGBA :: COMPRESSED_DXT5_RGBA;
PIXELFORMAT_COMPRESSED_ETC1_RGB :: COMPRESSED_ETC1_RGB;
PIXELFORMAT_COMPRESSED_ETC2_RGB :: COMPRESSED_ETC2_RGB;
PIXELFORMAT_COMPRESSED_ETC2_EAC_RGBA :: COMPRESSED_ETC2_EAC_RGBA;
PIXELFORMAT_COMPRESSED_PVRT_RGB :: COMPRESSED_PVRT_RGB;
PIXELFORMAT_COMPRESSED_PVRT_RGBA :: COMPRESSED_PVRT_RGBA;
PIXELFORMAT_COMPRESSED_ASTC_4x4_RGBA :: COMPRESSED_ASTC_4x4_RGBA;
PIXELFORMAT_COMPRESSED_ASTC_8x8_RGBA :: COMPRESSED_ASTC_8x8_RGBA;
}
// Texture parameters: filter mode
// NOTE 1: Filtering considers mipmaps if available in the texture
// NOTE 2: Filter is accordingly set for minification and magnification
TextureFilter :: enum u32 {
POINT :: 0;
BILINEAR :: 1;
TRILINEAR :: 2;
ANISOTROPIC_4X :: 3;
ANISOTROPIC_8X :: 4;
ANISOTROPIC_16X :: 5;
TEXTURE_FILTER_POINT :: POINT;
TEXTURE_FILTER_BILINEAR :: BILINEAR;
TEXTURE_FILTER_TRILINEAR :: TRILINEAR;
TEXTURE_FILTER_ANISOTROPIC_4X :: ANISOTROPIC_4X;
TEXTURE_FILTER_ANISOTROPIC_8X :: ANISOTROPIC_8X;
TEXTURE_FILTER_ANISOTROPIC_16X :: ANISOTROPIC_16X;
}
// Texture parameters: wrap mode
TextureWrap :: enum u32 {
REPEAT :: 0;
CLAMP :: 1;
MIRROR_REPEAT :: 2;
MIRROR_CLAMP :: 3;
TEXTURE_WRAP_REPEAT :: REPEAT;
TEXTURE_WRAP_CLAMP :: CLAMP;
TEXTURE_WRAP_MIRROR_REPEAT :: MIRROR_REPEAT;
TEXTURE_WRAP_MIRROR_CLAMP :: MIRROR_CLAMP;
}
// Cubemap layouts
CubemapLayout :: enum u32 {
AUTO_DETECT :: 0;
LINE_VERTICAL :: 1;
LINE_HORIZONTAL :: 2;
CROSS_THREE_BY_FOUR :: 3;
CROSS_FOUR_BY_THREE :: 4;
CUBEMAP_LAYOUT_AUTO_DETECT :: AUTO_DETECT;
CUBEMAP_LAYOUT_LINE_VERTICAL :: LINE_VERTICAL;
CUBEMAP_LAYOUT_LINE_HORIZONTAL :: LINE_HORIZONTAL;
CUBEMAP_LAYOUT_CROSS_THREE_BY_FOUR :: CROSS_THREE_BY_FOUR;
CUBEMAP_LAYOUT_CROSS_FOUR_BY_THREE :: CROSS_FOUR_BY_THREE;
}
// Font type, defines generation method
FontType :: enum u32 {
DEFAULT :: 0;
BITMAP :: 1;
SDF :: 2;
FONT_DEFAULT :: DEFAULT;
FONT_BITMAP :: BITMAP;
FONT_SDF :: SDF;
}
// Color blending modes (pre-defined)
BlendMode :: enum u32 {
ALPHA :: 0;
ADDITIVE :: 1;
MULTIPLIED :: 2;
ADD_COLORS :: 3;
SUBTRACT_COLORS :: 4;
ALPHA_PREMULTIPLY :: 5;
CUSTOM :: 6;
CUSTOM_SEPARATE :: 7;
BLEND_ALPHA :: ALPHA;
BLEND_ADDITIVE :: ADDITIVE;
BLEND_MULTIPLIED :: MULTIPLIED;
BLEND_ADD_COLORS :: ADD_COLORS;
BLEND_SUBTRACT_COLORS :: SUBTRACT_COLORS;
BLEND_ALPHA_PREMULTIPLY :: ALPHA_PREMULTIPLY;
BLEND_CUSTOM :: CUSTOM;
BLEND_CUSTOM_SEPARATE :: CUSTOM_SEPARATE;
}
// Gesture
// NOTE: Provided as bit-wise flags to enable only desired gestures
Gesture :: enum u32 {
NONE :: 0;
TAP :: 1;
DOUBLETAP :: 2;
HOLD :: 4;
DRAG :: 8;
SWIPE_RIGHT :: 16;
SWIPE_LEFT :: 32;
SWIPE_UP :: 64;
SWIPE_DOWN :: 128;
PINCH_IN :: 256;
PINCH_OUT :: 512;
GESTURE_NONE :: NONE;
GESTURE_TAP :: TAP;
GESTURE_DOUBLETAP :: DOUBLETAP;
GESTURE_HOLD :: HOLD;
GESTURE_DRAG :: DRAG;
GESTURE_SWIPE_RIGHT :: SWIPE_RIGHT;
GESTURE_SWIPE_LEFT :: SWIPE_LEFT;
GESTURE_SWIPE_UP :: SWIPE_UP;
GESTURE_SWIPE_DOWN :: SWIPE_DOWN;
GESTURE_PINCH_IN :: PINCH_IN;
GESTURE_PINCH_OUT :: PINCH_OUT;
}
// Camera system modes
CameraMode :: enum u32 {
CUSTOM :: 0;
FREE :: 1;
ORBITAL :: 2;
FIRST_PERSON :: 3;
THIRD_PERSON :: 4;
CAMERA_CUSTOM :: CUSTOM;
CAMERA_FREE :: FREE;
CAMERA_ORBITAL :: ORBITAL;
CAMERA_FIRST_PERSON :: FIRST_PERSON;
CAMERA_THIRD_PERSON :: THIRD_PERSON;
}
// Camera projection
CameraProjection :: enum u32 {
PERSPECTIVE :: 0;
ORTHOGRAPHIC :: 1;
CAMERA_PERSPECTIVE :: PERSPECTIVE;
CAMERA_ORTHOGRAPHIC :: ORTHOGRAPHIC;
}
// N-patch layout
NPatchLayout :: enum u32 {
NINE_PATCH :: 0;
THREE_PATCH_VERTICAL :: 1;
THREE_PATCH_HORIZONTAL :: 2;
NPATCH_NINE_PATCH :: NINE_PATCH;
NPATCH_THREE_PATCH_VERTICAL :: THREE_PATCH_VERTICAL;
NPATCH_THREE_PATCH_HORIZONTAL :: THREE_PATCH_HORIZONTAL;
}
// Callbacks to hook some internal functions
// WARNING: These callbacks are intended for advanced users
TraceLogCallback :: *void /* function type contained C va_list argument */;
LoadFileDataCallback :: #type (fileName: *u8, dataSize: *s32) -> *u8 #c_call;
SaveFileDataCallback :: #type (fileName: *u8, data: *void, dataSize: s32) -> bool #c_call;
LoadFileTextCallback :: #type (fileName: *u8) -> *u8 #c_call;
SaveFileTextCallback :: #type (fileName: *u8, text: *u8) -> bool #c_call;
// Window-related functions
InitWindow :: (width: s32, height: s32, title: *u8) -> void #foreign libraylib;
CloseWindow :: () -> void #foreign libraylib;
WindowShouldClose :: () -> bool #foreign libraylib;
IsWindowReady :: () -> bool #foreign libraylib;
IsWindowFullscreen :: () -> bool #foreign libraylib;
IsWindowHidden :: () -> bool #foreign libraylib;
IsWindowMinimized :: () -> bool #foreign libraylib;
IsWindowMaximized :: () -> bool #foreign libraylib;
IsWindowFocused :: () -> bool #foreign libraylib;
IsWindowResized :: () -> bool #foreign libraylib;
IsWindowState :: (flag: u32) -> bool #foreign libraylib;
SetWindowState :: (flags: ConfigFlags) -> void #foreign libraylib;
ClearWindowState :: (flags: ConfigFlags) -> void #foreign libraylib;
ToggleFullscreen :: () -> void #foreign libraylib;
ToggleBorderlessWindowed :: () -> void #foreign libraylib;
MaximizeWindow :: () -> void #foreign libraylib;
MinimizeWindow :: () -> void #foreign libraylib;
RestoreWindow :: () -> void #foreign libraylib;
SetWindowIcon :: (image: Image) -> void #foreign libraylib;
SetWindowIcons :: (images: *Image, count: s32) -> void #foreign libraylib;
SetWindowTitle :: (title: *u8) -> void #foreign libraylib;
SetWindowPosition :: (x: s32, y: s32) -> void #foreign libraylib;
SetWindowMonitor :: (monitor: s32) -> void #foreign libraylib;
SetWindowMinSize :: (width: s32, height: s32) -> void #foreign libraylib;
SetWindowMaxSize :: (width: s32, height: s32) -> void #foreign libraylib;
SetWindowSize :: (width: s32, height: s32) -> void #foreign libraylib;
SetWindowOpacity :: (opacity: float) -> void #foreign libraylib;
SetWindowFocused :: () -> void #foreign libraylib;
GetWindowHandle :: () -> *void #foreign libraylib;
GetScreenWidth :: () -> s32 #foreign libraylib;
GetScreenHeight :: () -> s32 #foreign libraylib;
GetRenderWidth :: () -> s32 #foreign libraylib;
GetRenderHeight :: () -> s32 #foreign libraylib;
GetMonitorCount :: () -> s32 #foreign libraylib;
GetCurrentMonitor :: () -> s32 #foreign libraylib;
GetMonitorPosition :: (monitor: s32) -> Vector2 #foreign libraylib;
GetMonitorWidth :: (monitor: s32) -> s32 #foreign libraylib;
GetMonitorHeight :: (monitor: s32) -> s32 #foreign libraylib;
GetMonitorPhysicalWidth :: (monitor: s32) -> s32 #foreign libraylib;
GetMonitorPhysicalHeight :: (monitor: s32) -> s32 #foreign libraylib;
GetMonitorRefreshRate :: (monitor: s32) -> s32 #foreign libraylib;
GetWindowPosition :: () -> Vector2 #foreign libraylib;
GetWindowScaleDPI :: () -> Vector2 #foreign libraylib;
GetMonitorName :: (monitor: s32) -> *u8 #foreign libraylib;
SetClipboardText :: (text: *u8) -> void #foreign libraylib;
GetClipboardText :: () -> *u8 #foreign libraylib;
GetClipboardImage :: () -> Image #foreign libraylib;
EnableEventWaiting :: () -> void #foreign libraylib;
DisableEventWaiting :: () -> void #foreign libraylib;
// Cursor-related functions
ShowCursor :: () -> void #foreign libraylib;
HideCursor :: () -> void #foreign libraylib;
IsCursorHidden :: () -> bool #foreign libraylib;
EnableCursor :: () -> void #foreign libraylib;
DisableCursor :: () -> void #foreign libraylib;
IsCursorOnScreen :: () -> bool #foreign libraylib;
// Drawing-related functions
ClearBackground :: (color: Color) -> void #foreign libraylib;
BeginDrawing :: () -> void #foreign libraylib;
EndDrawing :: () -> void #foreign libraylib;
BeginMode2D :: (camera: Camera2D) -> void #foreign libraylib;
EndMode2D :: () -> void #foreign libraylib;
BeginMode3D :: (camera: Camera3D) -> void #foreign libraylib;
EndMode3D :: () -> void #foreign libraylib;
BeginTextureMode :: (target: RenderTexture2D) -> void #foreign libraylib;
EndTextureMode :: () -> void #foreign libraylib;
BeginShaderMode :: (shader: Shader) -> void #foreign libraylib;
EndShaderMode :: () -> void #foreign libraylib;
BeginBlendMode :: (mode: s32) -> void #foreign libraylib;
EndBlendMode :: () -> void #foreign libraylib;
BeginScissorMode :: (x: s32, y: s32, width: s32, height: s32) -> void #foreign libraylib;
EndScissorMode :: () -> void #foreign libraylib;
BeginVrStereoMode :: (config: VrStereoConfig) -> void #foreign libraylib;
EndVrStereoMode :: () -> void #foreign libraylib;
// VR stereo config functions for VR simulator
LoadVrStereoConfig :: (device: VrDeviceInfo) -> VrStereoConfig #foreign libraylib;
UnloadVrStereoConfig :: (config: VrStereoConfig) -> void #foreign libraylib;
// Shader management functions
// NOTE: Shader functionality is not available on OpenGL 1.1
LoadShader :: (vsFileName: *u8, fsFileName: *u8) -> Shader #foreign libraylib;
LoadShaderFromMemory :: (vsCode: *u8, fsCode: *u8) -> Shader #foreign libraylib;
IsShaderValid :: (shader: Shader) -> bool #foreign libraylib;
GetShaderLocation :: (shader: Shader, uniformName: *u8) -> s32 #foreign libraylib;
GetShaderLocationAttrib :: (shader: Shader, attribName: *u8) -> s32 #foreign libraylib;
SetShaderValue :: (shader: Shader, locIndex: s32, value: *void, uniformType: s32) -> void #foreign libraylib;
SetShaderValueV :: (shader: Shader, locIndex: s32, value: *void, uniformType: s32, count: s32) -> void #foreign libraylib;
SetShaderValueMatrix :: (shader: Shader, locIndex: s32, mat: Matrix) -> void #foreign libraylib;
SetShaderValueTexture :: (shader: Shader, locIndex: s32, texture: Texture2D) -> void #foreign libraylib;
UnloadShader :: (shader: Shader) -> void #foreign libraylib;
GetScreenToWorldRay :: (position: Vector2, camera: Camera) -> Ray #foreign libraylib;
GetScreenToWorldRayEx :: (position: Vector2, camera: Camera, width: s32, height: s32) -> Ray #foreign libraylib;
GetWorldToScreen :: (position: Vector3, camera: Camera) -> Vector2 #foreign libraylib;
GetWorldToScreenEx :: (position: Vector3, camera: Camera, width: s32, height: s32) -> Vector2 #foreign libraylib;
GetWorldToScreen2D :: (position: Vector2, camera: Camera2D) -> Vector2 #foreign libraylib;
GetScreenToWorld2D :: (position: Vector2, camera: Camera2D) -> Vector2 #foreign libraylib;
GetCameraMatrix :: (camera: Camera) -> Matrix #foreign libraylib;
GetCameraMatrix2D :: (camera: Camera2D) -> Matrix #foreign libraylib;
// Timing-related functions
SetTargetFPS :: (fps: s32) -> void #foreign libraylib;
GetFrameTime :: () -> float #foreign libraylib;
GetTime :: () -> float64 #foreign libraylib;
GetFPS :: () -> s32 #foreign libraylib;
// Custom frame control functions
// NOTE: Those functions are intended for advanced users that want full control over the frame processing
// By default EndDrawing() does this job: draws everything + SwapScreenBuffer() + manage frame timing + PollInputEvents()
// To avoid that behaviour and control frame processes manually, enable in config.h: SUPPORT_CUSTOM_FRAME_CONTROL
SwapScreenBuffer :: () -> void #foreign libraylib;
PollInputEvents :: () -> void #foreign libraylib;
WaitTime :: (seconds: float64) -> void #foreign libraylib;
// Random values generation functions
SetRandomSeed :: (seed: u32) -> void #foreign libraylib;
GetRandomValue :: (min: s32, max: s32) -> s32 #foreign libraylib;
LoadRandomSequence :: (count: u32, min: s32, max: s32) -> *s32 #foreign libraylib;
UnloadRandomSequence :: (sequence: *s32) -> void #foreign libraylib;
// Misc. functions
TakeScreenshot :: (fileName: *u8) -> void #foreign libraylib;
SetConfigFlags :: (flags: ConfigFlags) -> void #foreign libraylib;
OpenURL :: (url: *u8) -> void #foreign libraylib;
// NOTE: Following functions implemented in module [utils]
//------------------------------------------------------------------
TraceLog_CFormat :: (logLevel: s32, text: *u8, __args: ..Any) -> void #foreign libraylib "TraceLog";
TraceLog :: (logLevel: s32, text: string, __args: ..Any) {
push_allocator(temp);
formatted_text_builder: String_Builder;
print_to_builder(*formatted_text_builder, text, ..__args);
append(*formatted_text_builder, "\0");
formatted_text := builder_to_string(*formatted_text_builder);
TraceLog_CFormat(logLevel, "%s", formatted_text.data);
} @PrintLike
SetTraceLogLevel :: (logLevel: s32) -> void #foreign libraylib;
MemAlloc :: (size: u32) -> *void #foreign libraylib;
MemRealloc :: (ptr: *void, size: u32) -> *void #foreign libraylib;
MemFree :: (ptr: *void) -> void #foreign libraylib;
// Set custom callbacks
// WARNING: Callbacks setup is intended for advanced users
SetTraceLogCallback :: (callback: TraceLogCallback) -> void #foreign libraylib;
SetLoadFileDataCallback :: (callback: LoadFileDataCallback) -> void #foreign libraylib;
SetSaveFileDataCallback :: (callback: SaveFileDataCallback) -> void #foreign libraylib;
SetLoadFileTextCallback :: (callback: LoadFileTextCallback) -> void #foreign libraylib;
SetSaveFileTextCallback :: (callback: SaveFileTextCallback) -> void #foreign libraylib;
// Files management functions
LoadFileData :: (fileName: *u8, dataSize: *s32) -> *u8 #foreign libraylib;
UnloadFileData :: (data: *u8) -> void #foreign libraylib;
SaveFileData :: (fileName: *u8, data: *void, dataSize: s32) -> bool #foreign libraylib;
ExportDataAsCode :: (data: *u8, dataSize: s32, fileName: *u8) -> bool #foreign libraylib;
LoadFileText :: (fileName: *u8) -> *u8 #foreign libraylib;
UnloadFileText :: (text: *u8) -> void #foreign libraylib;
SaveFileText :: (fileName: *u8, text: *u8) -> bool #foreign libraylib;
// File system functions
FileExists :: (fileName: *u8) -> bool #foreign libraylib;
DirectoryExists :: (dirPath: *u8) -> bool #foreign libraylib;
IsFileExtension :: (fileName: *u8, ext: *u8) -> bool #foreign libraylib;
GetFileLength :: (fileName: *u8) -> s32 #foreign libraylib;
GetFileExtension :: (fileName: *u8) -> *u8 #foreign libraylib;
GetFileName :: (filePath: *u8) -> *u8 #foreign libraylib;
GetFileNameWithoutExt :: (filePath: *u8) -> *u8 #foreign libraylib;
GetDirectoryPath :: (filePath: *u8) -> *u8 #foreign libraylib;
GetPrevDirectoryPath :: (dirPath: *u8) -> *u8 #foreign libraylib;
GetWorkingDirectory :: () -> *u8 #foreign libraylib;
GetApplicationDirectory :: () -> *u8 #foreign libraylib;
MakeDirectory :: (dirPath: *u8) -> s32 #foreign libraylib;
ChangeDirectory :: (dir: *u8) -> bool #foreign libraylib;
IsPathFile :: (path: *u8) -> bool #foreign libraylib;
IsFileNameValid :: (fileName: *u8) -> bool #foreign libraylib;
LoadDirectoryFiles :: (dirPath: *u8) -> FilePathList #foreign libraylib;
LoadDirectoryFilesEx :: (basePath: *u8, filter: *u8, scanSubdirs: bool) -> FilePathList #foreign libraylib;
UnloadDirectoryFiles :: (files: FilePathList) -> void #foreign libraylib;
IsFileDropped :: () -> bool #foreign libraylib;
LoadDroppedFiles :: () -> FilePathList #foreign libraylib;
UnloadDroppedFiles :: (files: FilePathList) -> void #foreign libraylib;
GetFileModTime :: (fileName: *u8) -> s64 #foreign libraylib;
// Compression/Encoding functionality
CompressData :: (data: *u8, dataSize: s32, compDataSize: *s32) -> *u8 #foreign libraylib;
DecompressData :: (compData: *u8, compDataSize: s32, dataSize: *s32) -> *u8 #foreign libraylib;
EncodeDataBase64 :: (data: *u8, dataSize: s32, outputSize: *s32) -> *u8 #foreign libraylib;
DecodeDataBase64 :: (data: *u8, outputSize: *s32) -> *u8 #foreign libraylib;
ComputeCRC32 :: (data: *u8, dataSize: s32) -> u32 #foreign libraylib;
ComputeMD5 :: (data: *u8, dataSize: s32) -> *u32 #foreign libraylib;
ComputeSHA1 :: (data: *u8, dataSize: s32) -> *u32 #foreign libraylib;
// Automation events functionality
LoadAutomationEventList :: (fileName: *u8) -> AutomationEventList #foreign libraylib;
UnloadAutomationEventList :: (list: AutomationEventList) -> void #foreign libraylib;
ExportAutomationEventList :: (list: AutomationEventList, fileName: *u8) -> bool #foreign libraylib;
SetAutomationEventList :: (list: *AutomationEventList) -> void #foreign libraylib;
SetAutomationEventBaseFrame :: (frame: s32) -> void #foreign libraylib;
StartAutomationEventRecording :: () -> void #foreign libraylib;
StopAutomationEventRecording :: () -> void #foreign libraylib;
PlayAutomationEvent :: (event: AutomationEvent) -> void #foreign libraylib;
// Input-related functions: keyboard
IsKeyPressed :: (key: KeyboardKey) -> bool #foreign libraylib;
IsKeyPressedRepeat :: (key: KeyboardKey) -> bool #foreign libraylib;
IsKeyDown :: (key: KeyboardKey) -> bool #foreign libraylib;
IsKeyReleased :: (key: KeyboardKey) -> bool #foreign libraylib;
IsKeyUp :: (key: KeyboardKey) -> bool #foreign libraylib;
GetKeyPressed :: () -> s32 #foreign libraylib;
GetCharPressed :: () -> s32 #foreign libraylib;
SetExitKey :: (key: KeyboardKey) -> void #foreign libraylib;
// Input-related functions: gamepads
IsGamepadAvailable :: (gamepad: s32) -> bool #foreign libraylib;
GetGamepadName :: (gamepad: s32) -> *u8 #foreign libraylib;
IsGamepadButtonPressed :: (gamepad: s32, button: GamepadButton) -> bool #foreign libraylib;
IsGamepadButtonDown :: (gamepad: s32, button: GamepadButton) -> bool #foreign libraylib;
IsGamepadButtonReleased :: (gamepad: s32, button: GamepadButton) -> bool #foreign libraylib;
IsGamepadButtonUp :: (gamepad: s32, button: GamepadButton) -> bool #foreign libraylib;
GetGamepadButtonPressed :: () -> s32 #foreign libraylib;
GetGamepadAxisCount :: (gamepad: s32) -> s32 #foreign libraylib;
GetGamepadAxisMovement :: (gamepad: s32, axis: GamepadAxis) -> float #foreign libraylib;
SetGamepadMappings :: (mappings: *u8) -> s32 #foreign libraylib;
SetGamepadVibration :: (gamepad: s32, leftMotor: float, rightMotor: float, duration: float) -> void #foreign libraylib;
// Input-related functions: mouse
IsMouseButtonPressed :: (button: MouseButton) -> bool #foreign libraylib;
IsMouseButtonDown :: (button: MouseButton) -> bool #foreign libraylib;
IsMouseButtonReleased :: (button: MouseButton) -> bool #foreign libraylib;
IsMouseButtonUp :: (button: MouseButton) -> bool #foreign libraylib;
GetMouseX :: () -> s32 #foreign libraylib;
GetMouseY :: () -> s32 #foreign libraylib;
GetMousePosition :: () -> Vector2 #foreign libraylib;
GetMouseDelta :: () -> Vector2 #foreign libraylib;
SetMousePosition :: (x: s32, y: s32) -> void #foreign libraylib;
SetMouseOffset :: (offsetX: s32, offsetY: s32) -> void #foreign libraylib;
SetMouseScale :: (scaleX: float, scaleY: float) -> void #foreign libraylib;
GetMouseWheelMove :: () -> float #foreign libraylib;
GetMouseWheelMoveV :: () -> Vector2 #foreign libraylib;
SetMouseCursor :: (cursor: s32) -> void #foreign libraylib;
// Input-related functions: touch
GetTouchX :: () -> s32 #foreign libraylib;
GetTouchY :: () -> s32 #foreign libraylib;
GetTouchPosition :: (index: s32) -> Vector2 #foreign libraylib;
GetTouchPointId :: (index: s32) -> s32 #foreign libraylib;
GetTouchPointCount :: () -> s32 #foreign libraylib;
//------------------------------------------------------------------------------------
// Gestures and Touch Handling Functions (Module: rgestures)
//------------------------------------------------------------------------------------
SetGesturesEnabled :: (flags: Gesture) -> void #foreign libraylib;
IsGestureDetected :: (gesture: Gesture) -> bool #foreign libraylib;
GetGestureDetected :: () -> Gesture #foreign libraylib;
GetGestureHoldDuration :: () -> float #foreign libraylib;
GetGestureDragVector :: () -> Vector2 #foreign libraylib;
GetGestureDragAngle :: () -> float #foreign libraylib;
GetGesturePinchVector :: () -> Vector2 #foreign libraylib;
GetGesturePinchAngle :: () -> float #foreign libraylib;
//------------------------------------------------------------------------------------
// Camera System Functions (Module: rcamera)
//------------------------------------------------------------------------------------
UpdateCamera :: (camera: *Camera, mode: CameraMode) -> void #foreign libraylib;
UpdateCameraPro :: (camera: *Camera, movement: Vector3, rotation: Vector3, zoom: float) -> void #foreign libraylib;
//------------------------------------------------------------------------------------
// Basic Shapes Drawing Functions (Module: shapes)
//------------------------------------------------------------------------------------
// Set texture and rectangle to be used on shapes drawing
// NOTE: It can be useful when using basic shapes and one single font,
// defining a font char white rectangle would allow drawing everything in a single draw call
SetShapesTexture :: (texture: Texture2D, source: Rectangle) -> void #foreign libraylib;
GetShapesTexture :: () -> Texture2D #foreign libraylib;
GetShapesTextureRectangle :: () -> Rectangle #foreign libraylib;
// Basic shapes drawing functions
DrawPixel :: (posX: s32, posY: s32, color: Color) -> void #foreign libraylib;
DrawPixelV :: (position: Vector2, color: Color) -> void #foreign libraylib;
DrawLine :: (startPosX: s32, startPosY: s32, endPosX: s32, endPosY: s32, color: Color) -> void #foreign libraylib;
DrawLineV :: (startPos: Vector2, endPos: Vector2, color: Color) -> void #foreign libraylib;
DrawLineEx :: (startPos: Vector2, endPos: Vector2, thick: float, color: Color) -> void #foreign libraylib;
DrawLineStrip :: (points: *Vector2, pointCount: s32, color: Color) -> void #foreign libraylib;
DrawLineBezier :: (startPos: Vector2, endPos: Vector2, thick: float, color: Color) -> void #foreign libraylib;
DrawCircle :: (centerX: s32, centerY: s32, radius: float, color: Color) -> void #foreign libraylib;
DrawCircleSector :: (center: Vector2, radius: float, startAngle: float, endAngle: float, segments: s32, color: Color) -> void #foreign libraylib;
DrawCircleSectorLines :: (center: Vector2, radius: float, startAngle: float, endAngle: float, segments: s32, color: Color) -> void #foreign libraylib;
DrawCircleGradient :: (centerX: s32, centerY: s32, radius: float, inner: Color, outer: Color) -> void #foreign libraylib;
DrawCircleV :: (center: Vector2, radius: float, color: Color) -> void #foreign libraylib;
DrawCircleLines :: (centerX: s32, centerY: s32, radius: float, color: Color) -> void #foreign libraylib;
DrawCircleLinesV :: (center: Vector2, radius: float, color: Color) -> void #foreign libraylib;
DrawEllipse :: (centerX: s32, centerY: s32, radiusH: float, radiusV: float, color: Color) -> void #foreign libraylib;
DrawEllipseLines :: (centerX: s32, centerY: s32, radiusH: float, radiusV: float, color: Color) -> void #foreign libraylib;
DrawRing :: (center: Vector2, innerRadius: float, outerRadius: float, startAngle: float, endAngle: float, segments: s32, color: Color) -> void #foreign libraylib;
DrawRingLines :: (center: Vector2, innerRadius: float, outerRadius: float, startAngle: float, endAngle: float, segments: s32, color: Color) -> void #foreign libraylib;
DrawRectangle :: (posX: s32, posY: s32, width: s32, height: s32, color: Color) -> void #foreign libraylib;
DrawRectangleV :: (position: Vector2, size: Vector2, color: Color) -> void #foreign libraylib;
DrawRectangleRec :: (rec: Rectangle, color: Color) -> void #foreign libraylib;
DrawRectanglePro :: (rec: Rectangle, origin: Vector2, rotation: float, color: Color) -> void #foreign libraylib;
DrawRectangleGradientV :: (posX: s32, posY: s32, width: s32, height: s32, top: Color, bottom: Color) -> void #foreign libraylib;
DrawRectangleGradientH :: (posX: s32, posY: s32, width: s32, height: s32, left: Color, right: Color) -> void #foreign libraylib;
DrawRectangleGradientEx :: (rec: Rectangle, topLeft: Color, bottomLeft: Color, topRight: Color, bottomRight: Color) -> void #foreign libraylib;
DrawRectangleLines :: (posX: s32, posY: s32, width: s32, height: s32, color: Color) -> void #foreign libraylib;
DrawRectangleLinesEx :: (rec: Rectangle, lineThick: float, color: Color) -> void #foreign libraylib;
DrawRectangleRounded :: (rec: Rectangle, roundness: float, segments: s32, color: Color) -> void #foreign libraylib;
DrawRectangleRoundedLines :: (rec: Rectangle, roundness: float, segments: s32, color: Color) -> void #foreign libraylib;
DrawRectangleRoundedLinesEx :: (rec: Rectangle, roundness: float, segments: s32, lineThick: float, color: Color) -> void #foreign libraylib;
DrawTriangle :: (v1: Vector2, v2: Vector2, v3: Vector2, color: Color) -> void #foreign libraylib;
DrawTriangleLines :: (v1: Vector2, v2: Vector2, v3: Vector2, color: Color) -> void #foreign libraylib;
DrawTriangleFan :: (points: *Vector2, pointCount: s32, color: Color) -> void #foreign libraylib;
DrawTriangleStrip :: (points: *Vector2, pointCount: s32, color: Color) -> void #foreign libraylib;
DrawPoly :: (center: Vector2, sides: s32, radius: float, rotation: float, color: Color) -> void #foreign libraylib;
DrawPolyLines :: (center: Vector2, sides: s32, radius: float, rotation: float, color: Color) -> void #foreign libraylib;
DrawPolyLinesEx :: (center: Vector2, sides: s32, radius: float, rotation: float, lineThick: float, color: Color) -> void #foreign libraylib;
// Splines drawing functions
DrawSplineLinear :: (points: *Vector2, pointCount: s32, thick: float, color: Color) -> void #foreign libraylib;
DrawSplineBasis :: (points: *Vector2, pointCount: s32, thick: float, color: Color) -> void #foreign libraylib;
DrawSplineCatmullRom :: (points: *Vector2, pointCount: s32, thick: float, color: Color) -> void #foreign libraylib;
DrawSplineBezierQuadratic :: (points: *Vector2, pointCount: s32, thick: float, color: Color) -> void #foreign libraylib;
DrawSplineBezierCubic :: (points: *Vector2, pointCount: s32, thick: float, color: Color) -> void #foreign libraylib;
DrawSplineSegmentLinear :: (p1: Vector2, p2: Vector2, thick: float, color: Color) -> void #foreign libraylib;
DrawSplineSegmentBasis :: (p1: Vector2, p2: Vector2, p3: Vector2, p4: Vector2, thick: float, color: Color) -> void #foreign libraylib;
DrawSplineSegmentCatmullRom :: (p1: Vector2, p2: Vector2, p3: Vector2, p4: Vector2, thick: float, color: Color) -> void #foreign libraylib;
DrawSplineSegmentBezierQuadratic :: (p1: Vector2, c2: Vector2, p3: Vector2, thick: float, color: Color) -> void #foreign libraylib;
DrawSplineSegmentBezierCubic :: (p1: Vector2, c2: Vector2, c3: Vector2, p4: Vector2, thick: float, color: Color) -> void #foreign libraylib;
// Spline segment point evaluation functions, for a given t [0.0f .. 1.0f]
GetSplinePointLinear :: (startPos: Vector2, endPos: Vector2, t: float) -> Vector2 #foreign libraylib;
GetSplinePointBasis :: (p1: Vector2, p2: Vector2, p3: Vector2, p4: Vector2, t: float) -> Vector2 #foreign libraylib;
GetSplinePointCatmullRom :: (p1: Vector2, p2: Vector2, p3: Vector2, p4: Vector2, t: float) -> Vector2 #foreign libraylib;
GetSplinePointBezierQuad :: (p1: Vector2, c2: Vector2, p3: Vector2, t: float) -> Vector2 #foreign libraylib;
GetSplinePointBezierCubic :: (p1: Vector2, c2: Vector2, c3: Vector2, p4: Vector2, t: float) -> Vector2 #foreign libraylib;
// Basic shapes collision detection functions
CheckCollisionRecs :: (rec1: Rectangle, rec2: Rectangle) -> bool #foreign libraylib;
CheckCollisionCircles :: (center1: Vector2, radius1: float, center2: Vector2, radius2: float) -> bool #foreign libraylib;
CheckCollisionCircleRec :: (center: Vector2, radius: float, rec: Rectangle) -> bool #foreign libraylib;
CheckCollisionCircleLine :: (center: Vector2, radius: float, p1: Vector2, p2: Vector2) -> bool #foreign libraylib;
CheckCollisionPointRec :: (point: Vector2, rec: Rectangle) -> bool #foreign libraylib;
CheckCollisionPointCircle :: (point: Vector2, center: Vector2, radius: float) -> bool #foreign libraylib;
CheckCollisionPointTriangle :: (point: Vector2, p1: Vector2, p2: Vector2, p3: Vector2) -> bool #foreign libraylib;
CheckCollisionPointLine :: (point: Vector2, p1: Vector2, p2: Vector2, threshold: s32) -> bool #foreign libraylib;
CheckCollisionPointPoly :: (point: Vector2, points: *Vector2, pointCount: s32) -> bool #foreign libraylib;
CheckCollisionLines :: (startPos1: Vector2, endPos1: Vector2, startPos2: Vector2, endPos2: Vector2, collisionPoint: *Vector2) -> bool #foreign libraylib;
GetCollisionRec :: (rec1: Rectangle, rec2: Rectangle) -> Rectangle #foreign libraylib;
// Image loading functions
// NOTE: These functions do not require GPU access
LoadImage :: (fileName: *u8) -> Image #foreign libraylib;
LoadImageRaw :: (fileName: *u8, width: s32, height: s32, format: PixelFormat, headerSize: s32) -> Image #foreign libraylib;
LoadImageAnim :: (fileName: *u8, frames: *s32) -> Image #foreign libraylib;
LoadImageAnimFromMemory :: (fileType: *u8, fileData: *u8, dataSize: s32, frames: *s32) -> Image #foreign libraylib;
LoadImageFromMemory :: (fileType: *u8, fileData: *u8, dataSize: s32) -> Image #foreign libraylib;
LoadImageFromTexture :: (texture: Texture2D) -> Image #foreign libraylib;
LoadImageFromScreen :: () -> Image #foreign libraylib;
IsImageValid :: (image: Image) -> bool #foreign libraylib;
UnloadImage :: (image: Image) -> void #foreign libraylib;
ExportImage :: (image: Image, fileName: *u8) -> bool #foreign libraylib;
ExportImageToMemory :: (image: Image, fileType: *u8, fileSize: *s32) -> *u8 #foreign libraylib;
ExportImageAsCode :: (image: Image, fileName: *u8) -> bool #foreign libraylib;
// Image generation functions
GenImageColor :: (width: s32, height: s32, color: Color) -> Image #foreign libraylib;
GenImageGradientLinear :: (width: s32, height: s32, direction: s32, start: Color, end: Color) -> Image #foreign libraylib;
GenImageGradientRadial :: (width: s32, height: s32, density: float, inner: Color, outer: Color) -> Image #foreign libraylib;
GenImageGradientSquare :: (width: s32, height: s32, density: float, inner: Color, outer: Color) -> Image #foreign libraylib;
GenImageChecked :: (width: s32, height: s32, checksX: s32, checksY: s32, col1: Color, col2: Color) -> Image #foreign libraylib;
GenImageWhiteNoise :: (width: s32, height: s32, factor: float) -> Image #foreign libraylib;
GenImagePerlinNoise :: (width: s32, height: s32, offsetX: s32, offsetY: s32, scale: float) -> Image #foreign libraylib;
GenImageCellular :: (width: s32, height: s32, tileSize: s32) -> Image #foreign libraylib;
GenImageText :: (width: s32, height: s32, text: *u8) -> Image #foreign libraylib;
// Image manipulation functions
ImageCopy :: (image: Image) -> Image #foreign libraylib;
ImageFromImage :: (image: Image, rec: Rectangle) -> Image #foreign libraylib;
ImageFromChannel :: (image: Image, selectedChannel: s32) -> Image #foreign libraylib;
ImageText :: (text: *u8, fontSize: s32, color: Color) -> Image #foreign libraylib;
ImageTextEx :: (font: Font, text: *u8, fontSize: float, spacing: float, tint: Color) -> Image #foreign libraylib;
ImageFormat :: (image: *Image, newFormat: PixelFormat) -> void #foreign libraylib;
ImageToPOT :: (image: *Image, fill: Color) -> void #foreign libraylib;
ImageCrop :: (image: *Image, crop: Rectangle) -> void #foreign libraylib;
ImageAlphaCrop :: (image: *Image, threshold: float) -> void #foreign libraylib;
ImageAlphaClear :: (image: *Image, color: Color, threshold: float) -> void #foreign libraylib;
ImageAlphaMask :: (image: *Image, alphaMask: Image) -> void #foreign libraylib;
ImageAlphaPremultiply :: (image: *Image) -> void #foreign libraylib;
ImageBlurGaussian :: (image: *Image, blurSize: s32) -> void #foreign libraylib;
ImageKernelConvolution :: (image: *Image, kernel: *float, kernelSize: s32) -> void #foreign libraylib;
ImageResize :: (image: *Image, newWidth: s32, newHeight: s32) -> void #foreign libraylib;
ImageResizeNN :: (image: *Image, newWidth: s32, newHeight: s32) -> void #foreign libraylib;
ImageResizeCanvas :: (image: *Image, newWidth: s32, newHeight: s32, offsetX: s32, offsetY: s32, fill: Color) -> void #foreign libraylib;
ImageMipmaps :: (image: *Image) -> void #foreign libraylib;
ImageDither :: (image: *Image, rBpp: s32, gBpp: s32, bBpp: s32, aBpp: s32) -> void #foreign libraylib;
ImageFlipVertical :: (image: *Image) -> void #foreign libraylib;
ImageFlipHorizontal :: (image: *Image) -> void #foreign libraylib;
ImageRotate :: (image: *Image, degrees: s32) -> void #foreign libraylib;
ImageRotateCW :: (image: *Image) -> void #foreign libraylib;
ImageRotateCCW :: (image: *Image) -> void #foreign libraylib;
ImageColorTint :: (image: *Image, color: Color) -> void #foreign libraylib;
ImageColorInvert :: (image: *Image) -> void #foreign libraylib;
ImageColorGrayscale :: (image: *Image) -> void #foreign libraylib;
ImageColorContrast :: (image: *Image, contrast: float) -> void #foreign libraylib;
ImageColorBrightness :: (image: *Image, brightness: s32) -> void #foreign libraylib;
ImageColorReplace :: (image: *Image, color: Color, replace: Color) -> void #foreign libraylib;
LoadImageColors :: (image: Image) -> *Color #foreign libraylib;
LoadImagePalette :: (image: Image, maxPaletteSize: s32, colorCount: *s32) -> *Color #foreign libraylib;
UnloadImageColors :: (colors: *Color) -> void #foreign libraylib;
UnloadImagePalette :: (colors: *Color) -> void #foreign libraylib;
GetImageAlphaBorder :: (image: Image, threshold: float) -> Rectangle #foreign libraylib;
GetImageColor :: (image: Image, x: s32, y: s32) -> Color #foreign libraylib;
// Image drawing functions
// NOTE: Image software-rendering functions (CPU)
ImageClearBackground :: (dst: *Image, color: Color) -> void #foreign libraylib;
ImageDrawPixel :: (dst: *Image, posX: s32, posY: s32, color: Color) -> void #foreign libraylib;
ImageDrawPixelV :: (dst: *Image, position: Vector2, color: Color) -> void #foreign libraylib;
ImageDrawLine :: (dst: *Image, startPosX: s32, startPosY: s32, endPosX: s32, endPosY: s32, color: Color) -> void #foreign libraylib;
ImageDrawLineV :: (dst: *Image, start: Vector2, end: Vector2, color: Color) -> void #foreign libraylib;
ImageDrawLineEx :: (dst: *Image, start: Vector2, end: Vector2, thick: s32, color: Color) -> void #foreign libraylib;
ImageDrawCircle :: (dst: *Image, centerX: s32, centerY: s32, radius: s32, color: Color) -> void #foreign libraylib;
ImageDrawCircleV :: (dst: *Image, center: Vector2, radius: s32, color: Color) -> void #foreign libraylib;
ImageDrawCircleLines :: (dst: *Image, centerX: s32, centerY: s32, radius: s32, color: Color) -> void #foreign libraylib;
ImageDrawCircleLinesV :: (dst: *Image, center: Vector2, radius: s32, color: Color) -> void #foreign libraylib;
ImageDrawRectangle :: (dst: *Image, posX: s32, posY: s32, width: s32, height: s32, color: Color) -> void #foreign libraylib;
ImageDrawRectangleV :: (dst: *Image, position: Vector2, size: Vector2, color: Color) -> void #foreign libraylib;
ImageDrawRectangleRec :: (dst: *Image, rec: Rectangle, color: Color) -> void #foreign libraylib;
ImageDrawRectangleLines :: (dst: *Image, rec: Rectangle, thick: s32, color: Color) -> void #foreign libraylib;
ImageDrawTriangle :: (dst: *Image, v1: Vector2, v2: Vector2, v3: Vector2, color: Color) -> void #foreign libraylib;
ImageDrawTriangleEx :: (dst: *Image, v1: Vector2, v2: Vector2, v3: Vector2, c1: Color, c2: Color, c3: Color) -> void #foreign libraylib;
ImageDrawTriangleLines :: (dst: *Image, v1: Vector2, v2: Vector2, v3: Vector2, color: Color) -> void #foreign libraylib;
ImageDrawTriangleFan :: (dst: *Image, points: *Vector2, pointCount: s32, color: Color) -> void #foreign libraylib;
ImageDrawTriangleStrip :: (dst: *Image, points: *Vector2, pointCount: s32, color: Color) -> void #foreign libraylib;
ImageDraw :: (dst: *Image, src: Image, srcRec: Rectangle, dstRec: Rectangle, tint: Color) -> void #foreign libraylib;
ImageDrawText :: (dst: *Image, text: *u8, posX: s32, posY: s32, fontSize: s32, color: Color) -> void #foreign libraylib;
ImageDrawTextEx :: (dst: *Image, font: Font, text: *u8, position: Vector2, fontSize: float, spacing: float, tint: Color) -> void #foreign libraylib;
// Texture loading functions
// NOTE: These functions require GPU access
LoadTexture :: (fileName: *u8) -> Texture2D #foreign libraylib;
LoadTextureFromImage :: (image: Image) -> Texture2D #foreign libraylib;
LoadTextureCubemap :: (image: Image, layout: CubemapLayout) -> TextureCubemap #foreign libraylib;
LoadRenderTexture :: (width: s32, height: s32) -> RenderTexture2D #foreign libraylib;
IsTextureValid :: (texture: Texture2D) -> bool #foreign libraylib;
UnloadTexture :: (texture: Texture2D) -> void #foreign libraylib;
IsRenderTextureValid :: (target: RenderTexture2D) -> bool #foreign libraylib;
UnloadRenderTexture :: (target: RenderTexture2D) -> void #foreign libraylib;
UpdateTexture :: (texture: Texture2D, pixels: *void) -> void #foreign libraylib;
UpdateTextureRec :: (texture: Texture2D, rec: Rectangle, pixels: *void) -> void #foreign libraylib;
// Texture configuration functions
GenTextureMipmaps :: (texture: *Texture2D) -> void #foreign libraylib;
SetTextureFilter :: (texture: Texture2D, filter: TextureFilter) -> void #foreign libraylib;
SetTextureWrap :: (texture: Texture2D, wrap: TextureWrap) -> void #foreign libraylib;
// Texture drawing functions
DrawTexture :: (texture: Texture2D, posX: s32, posY: s32, tint: Color) -> void #foreign libraylib;
DrawTextureV :: (texture: Texture2D, position: Vector2, tint: Color) -> void #foreign libraylib;
DrawTextureEx :: (texture: Texture2D, position: Vector2, rotation: float, scale: float, tint: Color) -> void #foreign libraylib;
DrawTextureRec :: (texture: Texture2D, source: Rectangle, position: Vector2, tint: Color) -> void #foreign libraylib;
DrawTexturePro :: (texture: Texture2D, source: Rectangle, dest: Rectangle, origin: Vector2, rotation: float, tint: Color) -> void #foreign libraylib;
DrawTextureNPatch :: (texture: Texture2D, nPatchInfo: NPatchInfo, dest: Rectangle, origin: Vector2, rotation: float, tint: Color) -> void #foreign libraylib;
// Color/pixel related functions
ColorIsEqual :: (col1: Color, col2: Color) -> bool #foreign libraylib;
Fade :: (color: Color, alpha: float) -> Color #foreign libraylib;
ColorToInt :: (color: Color) -> s32 #foreign libraylib;
ColorNormalize :: (color: Color) -> Vector4 #foreign libraylib;
ColorFromNormalized :: (normalized: Vector4) -> Color #foreign libraylib;
ColorToHSV :: (color: Color) -> Vector3 #foreign libraylib;
ColorFromHSV :: (hue: float, saturation: float, value: float) -> Color #foreign libraylib;
ColorTint :: (color: Color, tint: Color) -> Color #foreign libraylib;
ColorBrightness :: (color: Color, factor: float) -> Color #foreign libraylib;
ColorContrast :: (color: Color, contrast: float) -> Color #foreign libraylib;
ColorAlpha :: (color: Color, alpha: float) -> Color #foreign libraylib;
ColorAlphaBlend :: (dst: Color, src: Color, tint: Color) -> Color #foreign libraylib;
ColorLerp :: (color1: Color, color2: Color, factor: float) -> Color #foreign libraylib;
GetColor :: (hexValue: u32) -> Color #foreign libraylib;
GetPixelColor :: (srcPtr: *void, format: PixelFormat) -> Color #foreign libraylib;
SetPixelColor :: (dstPtr: *void, color: Color, format: PixelFormat) -> void #foreign libraylib;
GetPixelDataSize :: (width: s32, height: s32, format: PixelFormat) -> s32 #foreign libraylib;
// Font loading/unloading functions
GetFontDefault :: () -> Font #foreign libraylib;
LoadFont :: (fileName: *u8) -> Font #foreign libraylib;
LoadFontEx :: (fileName: *u8, fontSize: s32, codepoints: *s32, codepointCount: s32) -> Font #foreign libraylib;
LoadFontFromImage :: (image: Image, key: Color, firstChar: s32) -> Font #foreign libraylib;
LoadFontFromMemory :: (fileType: *u8, fileData: *u8, dataSize: s32, fontSize: s32, codepoints: *s32, codepointCount: s32) -> Font #foreign libraylib;
IsFontValid :: (font: Font) -> bool #foreign libraylib;
LoadFontData :: (fileData: *u8, dataSize: s32, fontSize: s32, codepoints: *s32, codepointCount: s32, type: s32) -> *GlyphInfo #foreign libraylib;
GenImageFontAtlas :: (glyphs: *GlyphInfo, glyphRecs: **Rectangle, glyphCount: s32, fontSize: s32, padding: s32, packMethod: s32) -> Image #foreign libraylib;
UnloadFontData :: (glyphs: *GlyphInfo, glyphCount: s32) -> void #foreign libraylib;
UnloadFont :: (font: Font) -> void #foreign libraylib;
ExportFontAsCode :: (font: Font, fileName: *u8) -> bool #foreign libraylib;
// Text drawing functions
DrawFPS :: (posX: s32, posY: s32) -> void #foreign libraylib;
DrawText :: (text: *u8, posX: s32, posY: s32, fontSize: s32, color: Color) -> void #foreign libraylib;
DrawTextEx :: (font: Font, text: *u8, position: Vector2, fontSize: float, spacing: float, tint: Color) -> void #foreign libraylib;
DrawTextPro :: (font: Font, text: *u8, position: Vector2, origin: Vector2, rotation: float, fontSize: float, spacing: float, tint: Color) -> void #foreign libraylib;
DrawTextCodepoint :: (font: Font, codepoint: s32, position: Vector2, fontSize: float, tint: Color) -> void #foreign libraylib;
DrawTextCodepoints :: (font: Font, codepoints: *s32, codepointCount: s32, position: Vector2, fontSize: float, spacing: float, tint: Color) -> void #foreign libraylib;
// Text font info functions
SetTextLineSpacing :: (spacing: s32) -> void #foreign libraylib;
MeasureText :: (text: *u8, fontSize: s32) -> s32 #foreign libraylib;
MeasureTextEx :: (font: Font, text: *u8, fontSize: float, spacing: float) -> Vector2 #foreign libraylib;
GetGlyphIndex :: (font: Font, codepoint: s32) -> s32 #foreign libraylib;
GetGlyphInfo :: (font: Font, codepoint: s32) -> GlyphInfo #foreign libraylib;
GetGlyphAtlasRec :: (font: Font, codepoint: s32) -> Rectangle #foreign libraylib;
// Text codepoints management functions (unicode characters)
LoadUTF8 :: (codepoints: *s32, length: s32) -> *u8 #foreign libraylib;
UnloadUTF8 :: (text: *u8) -> void #foreign libraylib;
LoadCodepoints :: (text: *u8, count: *s32) -> *s32 #foreign libraylib;
UnloadCodepoints :: (codepoints: *s32) -> void #foreign libraylib;
GetCodepointCount :: (text: *u8) -> s32 #foreign libraylib;
GetCodepoint :: (text: *u8, codepointSize: *s32) -> s32 #foreign libraylib;
GetCodepointNext :: (text: *u8, codepointSize: *s32) -> s32 #foreign libraylib;
GetCodepointPrevious :: (text: *u8, codepointSize: *s32) -> s32 #foreign libraylib;
CodepointToUTF8 :: (codepoint: s32, utf8Size: *s32) -> *u8 #foreign libraylib;
// Text strings management functions (no UTF-8 strings, only byte chars)
// NOTE: Some strings allocate memory internally for returned strings, just be careful!
TextCopy :: (dst: *u8, src: *u8) -> s32 #foreign libraylib;
TextIsEqual :: (text1: *u8, text2: *u8) -> bool #foreign libraylib;
TextLength :: (text: *u8) -> u32 #foreign libraylib;
TextFormat_CFormat :: (text: *u8, __args: ..Any) -> *u8 #foreign libraylib "TextFormat";
TextFormat :: (text: string, __args: ..Any) -> *u8 {
push_allocator(temp);
formatted_text_builder: String_Builder;
print_to_builder(*formatted_text_builder, text, ..__args);
append(*formatted_text_builder, "\0");
formatted_text := builder_to_string(*formatted_text_builder);
return TextFormat_CFormat("%s", formatted_text.data);
} @PrintLike
TextSubtext :: (text: *u8, position: s32, length: s32) -> *u8 #foreign libraylib;
TextReplace :: (text: *u8, replace: *u8, by: *u8) -> *u8 #foreign libraylib;
TextInsert :: (text: *u8, insert: *u8, position: s32) -> *u8 #foreign libraylib;
TextJoin :: (textList: **u8, count: s32, delimiter: *u8) -> *u8 #foreign libraylib;
TextSplit :: (text: *u8, delimiter: u8, count: *s32) -> **u8 #foreign libraylib;
TextAppend :: (text: *u8, append: *u8, position: *s32) -> void #foreign libraylib;
TextFindIndex :: (text: *u8, find: *u8) -> s32 #foreign libraylib;
TextToUpper :: (text: *u8) -> *u8 #foreign libraylib;
TextToLower :: (text: *u8) -> *u8 #foreign libraylib;
TextToPascal :: (text: *u8) -> *u8 #foreign libraylib;
TextToSnake :: (text: *u8) -> *u8 #foreign libraylib;
TextToCamel :: (text: *u8) -> *u8 #foreign libraylib;
TextToInteger :: (text: *u8) -> s32 #foreign libraylib;
TextToFloat :: (text: *u8) -> float #foreign libraylib;
// Basic geometric 3D shapes drawing functions
DrawLine3D :: (startPos: Vector3, endPos: Vector3, color: Color) -> void #foreign libraylib;
DrawPoint3D :: (position: Vector3, color: Color) -> void #foreign libraylib;
DrawCircle3D :: (center: Vector3, radius: float, rotationAxis: Vector3, rotationAngle: float, color: Color) -> void #foreign libraylib;
DrawTriangle3D :: (v1: Vector3, v2: Vector3, v3: Vector3, color: Color) -> void #foreign libraylib;
DrawTriangleStrip3D :: (points: *Vector3, pointCount: s32, color: Color) -> void #foreign libraylib;
DrawCube :: (position: Vector3, width: float, height: float, length: float, color: Color) -> void #foreign libraylib;
DrawCubeV :: (position: Vector3, size: Vector3, color: Color) -> void #foreign libraylib;
DrawCubeWires :: (position: Vector3, width: float, height: float, length: float, color: Color) -> void #foreign libraylib;
DrawCubeWiresV :: (position: Vector3, size: Vector3, color: Color) -> void #foreign libraylib;
DrawSphere :: (centerPos: Vector3, radius: float, color: Color) -> void #foreign libraylib;
DrawSphereEx :: (centerPos: Vector3, radius: float, rings: s32, slices: s32, color: Color) -> void #foreign libraylib;
DrawSphereWires :: (centerPos: Vector3, radius: float, rings: s32, slices: s32, color: Color) -> void #foreign libraylib;
DrawCylinder :: (position: Vector3, radiusTop: float, radiusBottom: float, height: float, slices: s32, color: Color) -> void #foreign libraylib;
DrawCylinderEx :: (startPos: Vector3, endPos: Vector3, startRadius: float, endRadius: float, sides: s32, color: Color) -> void #foreign libraylib;
DrawCylinderWires :: (position: Vector3, radiusTop: float, radiusBottom: float, height: float, slices: s32, color: Color) -> void #foreign libraylib;
DrawCylinderWiresEx :: (startPos: Vector3, endPos: Vector3, startRadius: float, endRadius: float, sides: s32, color: Color) -> void #foreign libraylib;
DrawCapsule :: (startPos: Vector3, endPos: Vector3, radius: float, slices: s32, rings: s32, color: Color) -> void #foreign libraylib;
DrawCapsuleWires :: (startPos: Vector3, endPos: Vector3, radius: float, slices: s32, rings: s32, color: Color) -> void #foreign libraylib;
DrawPlane :: (centerPos: Vector3, size: Vector2, color: Color) -> void #foreign libraylib;
DrawRay :: (ray: Ray, color: Color) -> void #foreign libraylib;
DrawGrid :: (slices: s32, spacing: float) -> void #foreign libraylib;
// Model management functions
LoadModel :: (fileName: *u8) -> Model #foreign libraylib;
LoadModelFromMesh :: (mesh: Mesh) -> Model #foreign libraylib;
IsModelValid :: (model: Model) -> bool #foreign libraylib;
UnloadModel :: (model: Model) -> void #foreign libraylib;
GetModelBoundingBox :: (model: Model) -> BoundingBox #foreign libraylib;
// Model drawing functions
DrawModel :: (model: Model, position: Vector3, scale: float, tint: Color) -> void #foreign libraylib;
DrawModelEx :: (model: Model, position: Vector3, rotationAxis: Vector3, rotationAngle: float, scale: Vector3, tint: Color) -> void #foreign libraylib;
DrawModelWires :: (model: Model, position: Vector3, scale: float, tint: Color) -> void #foreign libraylib;
DrawModelWiresEx :: (model: Model, position: Vector3, rotationAxis: Vector3, rotationAngle: float, scale: Vector3, tint: Color) -> void #foreign libraylib;
DrawModelPoints :: (model: Model, position: Vector3, scale: float, tint: Color) -> void #foreign libraylib;
DrawModelPointsEx :: (model: Model, position: Vector3, rotationAxis: Vector3, rotationAngle: float, scale: Vector3, tint: Color) -> void #foreign libraylib;
DrawBoundingBox :: (box: BoundingBox, color: Color) -> void #foreign libraylib;
DrawBillboard :: (camera: Camera, texture: Texture2D, position: Vector3, scale: float, tint: Color) -> void #foreign libraylib;
DrawBillboardRec :: (camera: Camera, texture: Texture2D, source: Rectangle, position: Vector3, size: Vector2, tint: Color) -> void #foreign libraylib;
DrawBillboardPro :: (camera: Camera, texture: Texture2D, source: Rectangle, position: Vector3, up: Vector3, size: Vector2, origin: Vector2, rotation: float, tint: Color) -> void #foreign libraylib;
// Mesh management functions
UploadMesh :: (mesh: *Mesh, dynamic: bool) -> void #foreign libraylib;
UpdateMeshBuffer :: (mesh: Mesh, index: s32, data: *void, dataSize: s32, offset: s32) -> void #foreign libraylib;
UnloadMesh :: (mesh: Mesh) -> void #foreign libraylib;
DrawMesh :: (mesh: Mesh, material: Material, transform: Matrix) -> void #foreign libraylib;
DrawMeshInstanced :: (mesh: Mesh, material: Material, transforms: *Matrix, instances: s32) -> void #foreign libraylib;
GetMeshBoundingBox :: (mesh: Mesh) -> BoundingBox #foreign libraylib;
GenMeshTangents :: (mesh: *Mesh) -> void #foreign libraylib;
ExportMesh :: (mesh: Mesh, fileName: *u8) -> bool #foreign libraylib;
ExportMeshAsCode :: (mesh: Mesh, fileName: *u8) -> bool #foreign libraylib;
// Mesh generation functions
GenMeshPoly :: (sides: s32, radius: float) -> Mesh #foreign libraylib;
GenMeshPlane :: (width: float, length: float, resX: s32, resZ: s32) -> Mesh #foreign libraylib;
GenMeshCube :: (width: float, height: float, length: float) -> Mesh #foreign libraylib;
GenMeshSphere :: (radius: float, rings: s32, slices: s32) -> Mesh #foreign libraylib;
GenMeshHemiSphere :: (radius: float, rings: s32, slices: s32) -> Mesh #foreign libraylib;
GenMeshCylinder :: (radius: float, height: float, slices: s32) -> Mesh #foreign libraylib;
GenMeshCone :: (radius: float, height: float, slices: s32) -> Mesh #foreign libraylib;
GenMeshTorus :: (radius: float, size: float, radSeg: s32, sides: s32) -> Mesh #foreign libraylib;
GenMeshKnot :: (radius: float, size: float, radSeg: s32, sides: s32) -> Mesh #foreign libraylib;
GenMeshHeightmap :: (heightmap: Image, size: Vector3) -> Mesh #foreign libraylib;
GenMeshCubicmap :: (cubicmap: Image, cubeSize: Vector3) -> Mesh #foreign libraylib;
// Material loading/unloading functions
LoadMaterials :: (fileName: *u8, materialCount: *s32) -> *Material #foreign libraylib;
LoadMaterialDefault :: () -> Material #foreign libraylib;
IsMaterialValid :: (material: Material) -> bool #foreign libraylib;
UnloadMaterial :: (material: Material) -> void #foreign libraylib;
SetMaterialTexture :: (material: *Material, mapType: MaterialMapIndex, texture: Texture2D) -> void #foreign libraylib;
SetModelMeshMaterial :: (model: *Model, meshId: s32, materialId: s32) -> void #foreign libraylib;
// Model animations loading/unloading functions
LoadModelAnimations :: (fileName: *u8, animCount: *s32) -> *ModelAnimation #foreign libraylib;
UpdateModelAnimation :: (model: Model, anim: ModelAnimation, frame: s32) -> void #foreign libraylib;
UpdateModelAnimationBones :: (model: Model, anim: ModelAnimation, frame: s32) -> void #foreign libraylib;
UnloadModelAnimation :: (anim: ModelAnimation) -> void #foreign libraylib;
UnloadModelAnimations :: (animations: *ModelAnimation, animCount: s32) -> void #foreign libraylib;
IsModelAnimationValid :: (model: Model, anim: ModelAnimation) -> bool #foreign libraylib;
// Collision detection functions
CheckCollisionSpheres :: (center1: Vector3, radius1: float, center2: Vector3, radius2: float) -> bool #foreign libraylib;
CheckCollisionBoxes :: (box1: BoundingBox, box2: BoundingBox) -> bool #foreign libraylib;
CheckCollisionBoxSphere :: (box: BoundingBox, center: Vector3, radius: float) -> bool #foreign libraylib;
GetRayCollisionSphere :: (ray: Ray, center: Vector3, radius: float) -> RayCollision #foreign libraylib;
GetRayCollisionBox :: (ray: Ray, box: BoundingBox) -> RayCollision #foreign libraylib;
GetRayCollisionMesh :: (ray: Ray, mesh: Mesh, transform: Matrix) -> RayCollision #foreign libraylib;
GetRayCollisionTriangle :: (ray: Ray, p1: Vector3, p2: Vector3, p3: Vector3) -> RayCollision #foreign libraylib;
GetRayCollisionQuad :: (ray: Ray, p1: Vector3, p2: Vector3, p3: Vector3, p4: Vector3) -> RayCollision #foreign libraylib;
//------------------------------------------------------------------------------------
// Audio Loading and Playing Functions (Module: audio)
//------------------------------------------------------------------------------------
AudioCallback :: #type (bufferData: *void, frames: u32) -> void #c_call;
// Audio device management functions
InitAudioDevice :: () -> void #foreign libraylib;
CloseAudioDevice :: () -> void #foreign libraylib;
IsAudioDeviceReady :: () -> bool #foreign libraylib;
SetMasterVolume :: (volume: float) -> void #foreign libraylib;
GetMasterVolume :: () -> float #foreign libraylib;
// Wave/Sound loading/unloading functions
LoadWave :: (fileName: *u8) -> Wave #foreign libraylib;
LoadWaveFromMemory :: (fileType: *u8, fileData: *u8, dataSize: s32) -> Wave #foreign libraylib;
IsWaveValid :: (wave: Wave) -> bool #foreign libraylib;
LoadSound :: (fileName: *u8) -> Sound #foreign libraylib;
LoadSoundFromWave :: (wave: Wave) -> Sound #foreign libraylib;
LoadSoundAlias :: (source: Sound) -> Sound #foreign libraylib;
IsSoundValid :: (sound: Sound) -> bool #foreign libraylib;
UpdateSound :: (sound: Sound, data: *void, sampleCount: s32) -> void #foreign libraylib;
UnloadWave :: (wave: Wave) -> void #foreign libraylib;
UnloadSound :: (sound: Sound) -> void #foreign libraylib;
UnloadSoundAlias :: (alias: Sound) -> void #foreign libraylib;
ExportWave :: (wave: Wave, fileName: *u8) -> bool #foreign libraylib;
ExportWaveAsCode :: (wave: Wave, fileName: *u8) -> bool #foreign libraylib;
// Wave/Sound management functions
PlaySound :: (sound: Sound) -> void #foreign libraylib;
StopSound :: (sound: Sound) -> void #foreign libraylib;
PauseSound :: (sound: Sound) -> void #foreign libraylib;
ResumeSound :: (sound: Sound) -> void #foreign libraylib;
IsSoundPlaying :: (sound: Sound) -> bool #foreign libraylib;
SetSoundVolume :: (sound: Sound, volume: float) -> void #foreign libraylib;
SetSoundPitch :: (sound: Sound, pitch: float) -> void #foreign libraylib;
SetSoundPan :: (sound: Sound, pan: float) -> void #foreign libraylib;
WaveCopy :: (wave: Wave) -> Wave #foreign libraylib;
WaveCrop :: (wave: *Wave, initFrame: s32, finalFrame: s32) -> void #foreign libraylib;
WaveFormat :: (wave: *Wave, sampleRate: s32, sampleSize: s32, channels: s32) -> void #foreign libraylib;
LoadWaveSamples :: (wave: Wave) -> *float #foreign libraylib;
UnloadWaveSamples :: (samples: *float) -> void #foreign libraylib;
// Music management functions
LoadMusicStream :: (fileName: *u8) -> Music #foreign libraylib;
LoadMusicStreamFromMemory :: (fileType: *u8, data: *u8, dataSize: s32) -> Music #foreign libraylib;
IsMusicValid :: (music: Music) -> bool #foreign libraylib;
UnloadMusicStream :: (music: Music) -> void #foreign libraylib;
PlayMusicStream :: (music: Music) -> void #foreign libraylib;
IsMusicStreamPlaying :: (music: Music) -> bool #foreign libraylib;
UpdateMusicStream :: (music: Music) -> void #foreign libraylib;
StopMusicStream :: (music: Music) -> void #foreign libraylib;
PauseMusicStream :: (music: Music) -> void #foreign libraylib;
ResumeMusicStream :: (music: Music) -> void #foreign libraylib;
SeekMusicStream :: (music: Music, position: float) -> void #foreign libraylib;
SetMusicVolume :: (music: Music, volume: float) -> void #foreign libraylib;
SetMusicPitch :: (music: Music, pitch: float) -> void #foreign libraylib;
SetMusicPan :: (music: Music, pan: float) -> void #foreign libraylib;
GetMusicTimeLength :: (music: Music) -> float #foreign libraylib;
GetMusicTimePlayed :: (music: Music) -> float #foreign libraylib;
// AudioStream management functions
LoadAudioStream :: (sampleRate: u32, sampleSize: u32, channels: u32) -> AudioStream #foreign libraylib;
IsAudioStreamValid :: (stream: AudioStream) -> bool #foreign libraylib;
UnloadAudioStream :: (stream: AudioStream) -> void #foreign libraylib;
UpdateAudioStream :: (stream: AudioStream, data: *void, frameCount: s32) -> void #foreign libraylib;
IsAudioStreamProcessed :: (stream: AudioStream) -> bool #foreign libraylib;
PlayAudioStream :: (stream: AudioStream) -> void #foreign libraylib;
PauseAudioStream :: (stream: AudioStream) -> void #foreign libraylib;
ResumeAudioStream :: (stream: AudioStream) -> void #foreign libraylib;
IsAudioStreamPlaying :: (stream: AudioStream) -> bool #foreign libraylib;
StopAudioStream :: (stream: AudioStream) -> void #foreign libraylib;
SetAudioStreamVolume :: (stream: AudioStream, volume: float) -> void #foreign libraylib;
SetAudioStreamPitch :: (stream: AudioStream, pitch: float) -> void #foreign libraylib;
SetAudioStreamPan :: (stream: AudioStream, pan: float) -> void #foreign libraylib;
SetAudioStreamBufferSizeDefault :: (size: s32) -> void #foreign libraylib;
SetAudioStreamCallback :: (stream: AudioStream, callback: AudioCallback) -> void #foreign libraylib;
AttachAudioStreamProcessor :: (stream: AudioStream, processor: AudioCallback) -> void #foreign libraylib;
DetachAudioStreamProcessor :: (stream: AudioStream, processor: AudioCallback) -> void #foreign libraylib;
AttachAudioMixedProcessor :: (processor: AudioCallback) -> void #foreign libraylib;
DetachAudioMixedProcessor :: (processor: AudioCallback) -> void #foreign libraylib;
// NOTE: Helper types to be used instead of array return types for *ToFloat functions
float3 :: struct {
v: [3] float;
}
float16 :: struct {
v: [16] float;
}
// Clamp float value
Clamp :: (value: float, min: float, max: float) -> float #foreign libraylib;
// Calculate linear interpolation between two floats
Lerp :: (start: float, end: float, amount: float) -> float #foreign libraylib;
// Normalize input value within input range
Normalize :: (value: float, start: float, end: float) -> float #foreign libraylib;
// Remap input value within input range to output range
Remap :: (value: float, inputStart: float, inputEnd: float, outputStart: float, outputEnd: float) -> float #foreign libraylib;
// Wrap input value from min to max
Wrap :: (value: float, min: float, max: float) -> float #foreign libraylib;
// Check whether two given floats are almost equal
FloatEquals :: (x: float, y: float) -> s32 #foreign libraylib;
// Vector with components value 0.0f
Vector2Zero :: () -> Vector2 #foreign libraylib;
// Vector with components value 1.0f
Vector2One :: () -> Vector2 #foreign libraylib;
// Add two vectors (v1 + v2)
Vector2Add :: (v1: Vector2, v2: Vector2) -> Vector2 #foreign libraylib;
// Add vector and float value
Vector2AddValue :: (v: Vector2, add: float) -> Vector2 #foreign libraylib;
// Subtract two vectors (v1 - v2)
Vector2Subtract :: (v1: Vector2, v2: Vector2) -> Vector2 #foreign libraylib;
// Subtract vector by float value
Vector2SubtractValue :: (v: Vector2, sub: float) -> Vector2 #foreign libraylib;
// Calculate vector length
Vector2Length :: (v: Vector2) -> float #foreign libraylib;
// Calculate vector square length
Vector2LengthSqr :: (v: Vector2) -> float #foreign libraylib;
// Calculate two vectors dot product
Vector2DotProduct :: (v1: Vector2, v2: Vector2) -> float #foreign libraylib;
// Calculate distance between two vectors
Vector2Distance :: (v1: Vector2, v2: Vector2) -> float #foreign libraylib;
// Calculate square distance between two vectors
Vector2DistanceSqr :: (v1: Vector2, v2: Vector2) -> float #foreign libraylib;
// Calculate angle between two vectors
// NOTE: Angle is calculated from origin point (0, 0)
Vector2Angle :: (v1: Vector2, v2: Vector2) -> float #foreign libraylib;
// Calculate angle defined by a two vectors line
// NOTE: Parameters need to be normalized
// Current implementation should be aligned with glm::angle
Vector2LineAngle :: (start: Vector2, end: Vector2) -> float #foreign libraylib;
// Scale vector (multiply by value)
Vector2Scale :: (v: Vector2, scale: float) -> Vector2 #foreign libraylib;
// Multiply vector by vector
Vector2Multiply :: (v1: Vector2, v2: Vector2) -> Vector2 #foreign libraylib;
// Negate vector
Vector2Negate :: (v: Vector2) -> Vector2 #foreign libraylib;
// Divide vector by vector
Vector2Divide :: (v1: Vector2, v2: Vector2) -> Vector2 #foreign libraylib;
// Normalize provided vector
Vector2Normalize :: (v: Vector2) -> Vector2 #foreign libraylib;
// Transforms a Vector2 by a given Matrix
Vector2Transform :: (v: Vector2, mat: Matrix) -> Vector2 #foreign libraylib;
// Calculate linear interpolation between two vectors
Vector2Lerp :: (v1: Vector2, v2: Vector2, amount: float) -> Vector2 #foreign libraylib;
// Calculate reflected vector to normal
Vector2Reflect :: (v: Vector2, normal: Vector2) -> Vector2 #foreign libraylib;
// Get min value for each pair of components
Vector2Min :: (v1: Vector2, v2: Vector2) -> Vector2 #foreign libraylib;
// Get max value for each pair of components
Vector2Max :: (v1: Vector2, v2: Vector2) -> Vector2 #foreign libraylib;
// Rotate vector by angle
Vector2Rotate :: (v: Vector2, angle: float) -> Vector2 #foreign libraylib;
// Move Vector towards target
Vector2MoveTowards :: (v: Vector2, target: Vector2, maxDistance: float) -> Vector2 #foreign libraylib;
// Invert the given vector
Vector2Invert :: (v: Vector2) -> Vector2 #foreign libraylib;
// Clamp the components of the vector between
// min and max values specified by the given vectors
Vector2Clamp :: (v: Vector2, min: Vector2, max: Vector2) -> Vector2 #foreign libraylib;
// Clamp the magnitude of the vector between two min and max values
Vector2ClampValue :: (v: Vector2, min: float, max: float) -> Vector2 #foreign libraylib;
// Check whether two given vectors are almost equal
Vector2Equals :: (p: Vector2, q: Vector2) -> s32 #foreign libraylib;
// Compute the direction of a refracted ray
// v: normalized direction of the incoming ray
// n: normalized normal vector of the interface of two optical media
// r: ratio of the refractive index of the medium from where the ray comes
// to the refractive index of the medium on the other side of the surface
Vector2Refract :: (v: Vector2, n: Vector2, r: float) -> Vector2 #foreign libraylib;
// Vector with components value 0.0f
Vector3Zero :: () -> Vector3 #foreign libraylib;
// Vector with components value 1.0f
Vector3One :: () -> Vector3 #foreign libraylib;
// Add two vectors
Vector3Add :: (v1: Vector3, v2: Vector3) -> Vector3 #foreign libraylib;
// Add vector and float value
Vector3AddValue :: (v: Vector3, add: float) -> Vector3 #foreign libraylib;
// Subtract two vectors
Vector3Subtract :: (v1: Vector3, v2: Vector3) -> Vector3 #foreign libraylib;
// Subtract vector by float value
Vector3SubtractValue :: (v: Vector3, sub: float) -> Vector3 #foreign libraylib;
// Multiply vector by scalar
Vector3Scale :: (v: Vector3, scalar: float) -> Vector3 #foreign libraylib;
// Multiply vector by vector
Vector3Multiply :: (v1: Vector3, v2: Vector3) -> Vector3 #foreign libraylib;
// Calculate two vectors cross product
Vector3CrossProduct :: (v1: Vector3, v2: Vector3) -> Vector3 #foreign libraylib;
// Calculate one vector perpendicular vector
Vector3Perpendicular :: (v: Vector3) -> Vector3 #foreign libraylib;
// Calculate vector length
Vector3Length :: (v: Vector3) -> float #foreign libraylib;
// Calculate vector square length
Vector3LengthSqr :: (v: Vector3) -> float #foreign libraylib;
// Calculate two vectors dot product
Vector3DotProduct :: (v1: Vector3, v2: Vector3) -> float #foreign libraylib;
// Calculate distance between two vectors
Vector3Distance :: (v1: Vector3, v2: Vector3) -> float #foreign libraylib;
// Calculate square distance between two vectors
Vector3DistanceSqr :: (v1: Vector3, v2: Vector3) -> float #foreign libraylib;
// Calculate angle between two vectors
Vector3Angle :: (v1: Vector3, v2: Vector3) -> float #foreign libraylib;
// Negate provided vector (invert direction)
Vector3Negate :: (v: Vector3) -> Vector3 #foreign libraylib;
// Divide vector by vector
Vector3Divide :: (v1: Vector3, v2: Vector3) -> Vector3 #foreign libraylib;
// Normalize provided vector
Vector3Normalize :: (v: Vector3) -> Vector3 #foreign libraylib;
//Calculate the projection of the vector v1 on to v2
Vector3Project :: (v1: Vector3, v2: Vector3) -> Vector3 #foreign libraylib;
//Calculate the rejection of the vector v1 on to v2
Vector3Reject :: (v1: Vector3, v2: Vector3) -> Vector3 #foreign libraylib;
// Orthonormalize provided vectors
// Makes vectors normalized and orthogonal to each other
// Gram-Schmidt function implementation
Vector3OrthoNormalize :: (v1: *Vector3, v2: *Vector3) -> void #foreign libraylib;
// Transforms a Vector3 by a given Matrix
Vector3Transform :: (v: Vector3, mat: Matrix) -> Vector3 #foreign libraylib;
// Transform a vector by quaternion rotation
Vector3RotateByQuaternion :: (v: Vector3, q: Quaternion) -> Vector3 #foreign libraylib;
// Rotates a vector around an axis
Vector3RotateByAxisAngle :: (v: Vector3, axis: Vector3, angle: float) -> Vector3 #foreign libraylib;
// Move Vector towards target
Vector3MoveTowards :: (v: Vector3, target: Vector3, maxDistance: float) -> Vector3 #foreign libraylib;
// Calculate linear interpolation between two vectors
Vector3Lerp :: (v1: Vector3, v2: Vector3, amount: float) -> Vector3 #foreign libraylib;
// Calculate cubic hermite interpolation between two vectors and their tangents
// as described in the GLTF 2.0 specification: https://registry.khronos.org/glTF/specs/2.0/glTF-2.0.html#interpolation-cubic
Vector3CubicHermite :: (v1: Vector3, tangent1: Vector3, v2: Vector3, tangent2: Vector3, amount: float) -> Vector3 #foreign libraylib;
// Calculate reflected vector to normal
Vector3Reflect :: (v: Vector3, normal: Vector3) -> Vector3 #foreign libraylib;
// Get min value for each pair of components
Vector3Min :: (v1: Vector3, v2: Vector3) -> Vector3 #foreign libraylib;
// Get max value for each pair of components
Vector3Max :: (v1: Vector3, v2: Vector3) -> Vector3 #foreign libraylib;
// Compute barycenter coordinates (u, v, w) for point p with respect to triangle (a, b, c)
// NOTE: Assumes P is on the plane of the triangle
Vector3Barycenter :: (p: Vector3, a: Vector3, b: Vector3, c: Vector3) -> Vector3 #foreign libraylib;
// Projects a Vector3 from screen space into object space
// NOTE: We are avoiding calling other raymath functions despite available
Vector3Unproject :: (source: Vector3, projection: Matrix, view: Matrix) -> Vector3 #foreign libraylib;
// Get Vector3 as float array
Vector3ToFloatV :: (v: Vector3) -> float3 #foreign libraylib;
// Invert the given vector
Vector3Invert :: (v: Vector3) -> Vector3 #foreign libraylib;
// Clamp the components of the vector between
// min and max values specified by the given vectors
Vector3Clamp :: (v: Vector3, min: Vector3, max: Vector3) -> Vector3 #foreign libraylib;
// Clamp the magnitude of the vector between two values
Vector3ClampValue :: (v: Vector3, min: float, max: float) -> Vector3 #foreign libraylib;
// Check whether two given vectors are almost equal
Vector3Equals :: (p: Vector3, q: Vector3) -> s32 #foreign libraylib;
// Compute the direction of a refracted ray
// v: normalized direction of the incoming ray
// n: normalized normal vector of the interface of two optical media
// r: ratio of the refractive index of the medium from where the ray comes
// to the refractive index of the medium on the other side of the surface
Vector3Refract :: (v: Vector3, n: Vector3, r: float) -> Vector3 #foreign libraylib;
//----------------------------------------------------------------------------------
// Module Functions Definition - Vector4 math
//----------------------------------------------------------------------------------
Vector4Zero :: () -> Vector4 #foreign libraylib;
Vector4One :: () -> Vector4 #foreign libraylib;
Vector4Add :: (v1: Vector4, v2: Vector4) -> Vector4 #foreign libraylib;
Vector4AddValue :: (v: Vector4, add: float) -> Vector4 #foreign libraylib;
Vector4Subtract :: (v1: Vector4, v2: Vector4) -> Vector4 #foreign libraylib;
Vector4SubtractValue :: (v: Vector4, add: float) -> Vector4 #foreign libraylib;
Vector4Length :: (v: Vector4) -> float #foreign libraylib;
Vector4LengthSqr :: (v: Vector4) -> float #foreign libraylib;
Vector4DotProduct :: (v1: Vector4, v2: Vector4) -> float #foreign libraylib;
// Calculate distance between two vectors
Vector4Distance :: (v1: Vector4, v2: Vector4) -> float #foreign libraylib;
// Calculate square distance between two vectors
Vector4DistanceSqr :: (v1: Vector4, v2: Vector4) -> float #foreign libraylib;
Vector4Scale :: (v: Vector4, scale: float) -> Vector4 #foreign libraylib;
// Multiply vector by vector
Vector4Multiply :: (v1: Vector4, v2: Vector4) -> Vector4 #foreign libraylib;
// Negate vector
Vector4Negate :: (v: Vector4) -> Vector4 #foreign libraylib;
// Divide vector by vector
Vector4Divide :: (v1: Vector4, v2: Vector4) -> Vector4 #foreign libraylib;
// Normalize provided vector
Vector4Normalize :: (v: Vector4) -> Vector4 #foreign libraylib;
// Get min value for each pair of components
Vector4Min :: (v1: Vector4, v2: Vector4) -> Vector4 #foreign libraylib;
// Get max value for each pair of components
Vector4Max :: (v1: Vector4, v2: Vector4) -> Vector4 #foreign libraylib;
// Calculate linear interpolation between two vectors
Vector4Lerp :: (v1: Vector4, v2: Vector4, amount: float) -> Vector4 #foreign libraylib;
// Move Vector towards target
Vector4MoveTowards :: (v: Vector4, target: Vector4, maxDistance: float) -> Vector4 #foreign libraylib;
// Invert the given vector
Vector4Invert :: (v: Vector4) -> Vector4 #foreign libraylib;
// Check whether two given vectors are almost equal
Vector4Equals :: (p: Vector4, q: Vector4) -> s32 #foreign libraylib;
// Compute matrix determinant
MatrixDeterminant :: (mat: Matrix) -> float #foreign libraylib;
// Get the trace of the matrix (sum of the values along the diagonal)
MatrixTrace :: (mat: Matrix) -> float #foreign libraylib;
// Transposes provided matrix
MatrixTranspose :: (mat: Matrix) -> Matrix #foreign libraylib;
// Invert provided matrix
MatrixInvert :: (mat: Matrix) -> Matrix #foreign libraylib;
// Get identity matrix
MatrixIdentity :: () -> Matrix #foreign libraylib;
// Add two matrices
MatrixAdd :: (left: Matrix, right: Matrix) -> Matrix #foreign libraylib;
// Subtract two matrices (left - right)
MatrixSubtract :: (left: Matrix, right: Matrix) -> Matrix #foreign libraylib;
// Get two matrix multiplication
// NOTE: When multiplying matrices... the order matters!
MatrixMultiply :: (left: Matrix, right: Matrix) -> Matrix #foreign libraylib;
// Get translation matrix
MatrixTranslate :: (x: float, y: float, z: float) -> Matrix #foreign libraylib;
// Create rotation matrix from axis and angle
// NOTE: Angle should be provided in radians
MatrixRotate :: (axis: Vector3, angle: float) -> Matrix #foreign libraylib;
// Get x-rotation matrix
// NOTE: Angle must be provided in radians
MatrixRotateX :: (angle: float) -> Matrix #foreign libraylib;
// Get y-rotation matrix
// NOTE: Angle must be provided in radians
MatrixRotateY :: (angle: float) -> Matrix #foreign libraylib;
// Get z-rotation matrix
// NOTE: Angle must be provided in radians
MatrixRotateZ :: (angle: float) -> Matrix #foreign libraylib;
// Get xyz-rotation matrix
// NOTE: Angle must be provided in radians
MatrixRotateXYZ :: (angle: Vector3) -> Matrix #foreign libraylib;
// Get zyx-rotation matrix
// NOTE: Angle must be provided in radians
MatrixRotateZYX :: (angle: Vector3) -> Matrix #foreign libraylib;
// Get scaling matrix
MatrixScale :: (x: float, y: float, z: float) -> Matrix #foreign libraylib;
// Get perspective projection matrix
MatrixFrustum :: (left: float64, right: float64, bottom: float64, top: float64, nearPlane: float64, farPlane: float64) -> Matrix #foreign libraylib;
// Get perspective projection matrix
// NOTE: Fovy angle must be provided in radians
MatrixPerspective :: (fovY: float64, aspect: float64, nearPlane: float64, farPlane: float64) -> Matrix #foreign libraylib;
// Get orthographic projection matrix
MatrixOrtho :: (left: float64, right: float64, bottom: float64, top: float64, nearPlane: float64, farPlane: float64) -> Matrix #foreign libraylib;
// Get camera look-at matrix (view matrix)
MatrixLookAt :: (eye: Vector3, target: Vector3, up: Vector3) -> Matrix #foreign libraylib;
// Get float array of matrix data
MatrixToFloatV :: (mat: Matrix) -> float16 #foreign libraylib;
// Add two quaternions
QuaternionAdd :: (q1: Quaternion, q2: Quaternion) -> Quaternion #foreign libraylib;
// Add quaternion and float value
QuaternionAddValue :: (q: Quaternion, add: float) -> Quaternion #foreign libraylib;
// Subtract two quaternions
QuaternionSubtract :: (q1: Quaternion, q2: Quaternion) -> Quaternion #foreign libraylib;
// Subtract quaternion and float value
QuaternionSubtractValue :: (q: Quaternion, sub: float) -> Quaternion #foreign libraylib;
// Get identity quaternion
QuaternionIdentity :: () -> Quaternion #foreign libraylib;
// Computes the length of a quaternion
QuaternionLength :: (q: Quaternion) -> float #foreign libraylib;
// Normalize provided quaternion
QuaternionNormalize :: (q: Quaternion) -> Quaternion #foreign libraylib;
// Invert provided quaternion
QuaternionInvert :: (q: Quaternion) -> Quaternion #foreign libraylib;
// Calculate two quaternion multiplication
QuaternionMultiply :: (q1: Quaternion, q2: Quaternion) -> Quaternion #foreign libraylib;
// Scale quaternion by float value
QuaternionScale :: (q: Quaternion, mul: float) -> Quaternion #foreign libraylib;
// Divide two quaternions
QuaternionDivide :: (q1: Quaternion, q2: Quaternion) -> Quaternion #foreign libraylib;
// Calculate linear interpolation between two quaternions
QuaternionLerp :: (q1: Quaternion, q2: Quaternion, amount: float) -> Quaternion #foreign libraylib;
// Calculate slerp-optimized interpolation between two quaternions
QuaternionNlerp :: (q1: Quaternion, q2: Quaternion, amount: float) -> Quaternion #foreign libraylib;
// Calculates spherical linear interpolation between two quaternions
QuaternionSlerp :: (q1: Quaternion, q2: Quaternion, amount: float) -> Quaternion #foreign libraylib;
// Calculate quaternion cubic spline interpolation using Cubic Hermite Spline algorithm
// as described in the GLTF 2.0 specification: https://registry.khronos.org/glTF/specs/2.0/glTF-2.0.html#interpolation-cubic
QuaternionCubicHermiteSpline :: (q1: Quaternion, outTangent1: Quaternion, q2: Quaternion, inTangent2: Quaternion, t: float) -> Quaternion #foreign libraylib;
// Calculate quaternion based on the rotation from one vector to another
QuaternionFromVector3ToVector3 :: (from: Vector3, to: Vector3) -> Quaternion #foreign libraylib;
// Get a quaternion for a given rotation matrix
QuaternionFromMatrix :: (mat: Matrix) -> Quaternion #foreign libraylib;
// Get a matrix for a given quaternion
QuaternionToMatrix :: (q: Quaternion) -> Matrix #foreign libraylib;
// Get rotation quaternion for an angle and axis
// NOTE: Angle must be provided in radians
QuaternionFromAxisAngle :: (axis: Vector3, angle: float) -> Quaternion #foreign libraylib;
// Get the rotation angle and axis for a given quaternion
QuaternionToAxisAngle :: (q: Quaternion, outAxis: *Vector3, outAngle: *float) -> void #foreign libraylib;
// Get the quaternion equivalent to Euler angles
// NOTE: Rotation order is ZYX
QuaternionFromEuler :: (pitch: float, yaw: float, roll: float) -> Quaternion #foreign libraylib;
// Get the Euler angles equivalent to quaternion (roll, pitch, yaw)
// NOTE: Angles are returned in a Vector3 struct in radians
QuaternionToEuler :: (q: Quaternion) -> Vector3 #foreign libraylib;
// Transform a quaternion given a transformation matrix
QuaternionTransform :: (q: Quaternion, mat: Matrix) -> Quaternion #foreign libraylib;
// Check whether two given quaternions are almost equal
QuaternionEquals :: (p: Quaternion, q: Quaternion) -> s32 #foreign libraylib;
// Decompose a transformation matrix into its rotational, translational and scaling components
MatrixDecompose :: (mat: Matrix, translation: *Vector3, rotation: *Quaternion, scale: *Vector3) -> void #foreign libraylib;
#scope_file
#import "Basic"; // For assert, push_context
#run {
{
info := type_info(Vector2);
for info.members {
if it.name == {
case "x";
assert(it.offset_in_bytes == 0, "Vector2.x has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Vector2.x has unexpected size % instead of 4", it.type.runtime_size);
case "y";
assert(it.offset_in_bytes == 4, "Vector2.y has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Vector2.y has unexpected size % instead of 4", it.type.runtime_size);
}
}
assert(size_of(Vector2) == 8, "Vector2 has size % instead of 8", size_of(Vector2));
}
{
info := type_info(Vector3);
for info.members {
if it.name == {
case "x";
assert(it.offset_in_bytes == 0, "Vector3.x has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Vector3.x has unexpected size % instead of 4", it.type.runtime_size);
case "y";
assert(it.offset_in_bytes == 4, "Vector3.y has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Vector3.y has unexpected size % instead of 4", it.type.runtime_size);
case "z";
assert(it.offset_in_bytes == 8, "Vector3.z has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Vector3.z has unexpected size % instead of 4", it.type.runtime_size);
}
}
assert(size_of(Vector3) == 12, "Vector3 has size % instead of 12", size_of(Vector3));
}
{
info := type_info(Vector4);
for info.members {
if it.name == {
case "x";
assert(it.offset_in_bytes == 0, "Vector4.x has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Vector4.x has unexpected size % instead of 4", it.type.runtime_size);
case "y";
assert(it.offset_in_bytes == 4, "Vector4.y has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Vector4.y has unexpected size % instead of 4", it.type.runtime_size);
case "z";
assert(it.offset_in_bytes == 8, "Vector4.z has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Vector4.z has unexpected size % instead of 4", it.type.runtime_size);
case "w";
assert(it.offset_in_bytes == 12, "Vector4.w has unexpected offset % instead of 12", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Vector4.w has unexpected size % instead of 4", it.type.runtime_size);
}
}
assert(size_of(Vector4) == 16, "Vector4 has size % instead of 16", size_of(Vector4));
}
{
info := type_info(Matrix);
for info.members {
if it.name == {
case "m0";
assert(it.offset_in_bytes == 0, "Matrix.m0 has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Matrix.m0 has unexpected size % instead of 4", it.type.runtime_size);
case "m4";
assert(it.offset_in_bytes == 4, "Matrix.m4 has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Matrix.m4 has unexpected size % instead of 4", it.type.runtime_size);
case "m8";
assert(it.offset_in_bytes == 8, "Matrix.m8 has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Matrix.m8 has unexpected size % instead of 4", it.type.runtime_size);
case "m12";
assert(it.offset_in_bytes == 12, "Matrix.m12 has unexpected offset % instead of 12", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Matrix.m12 has unexpected size % instead of 4", it.type.runtime_size);
case "m1";
assert(it.offset_in_bytes == 16, "Matrix.m1 has unexpected offset % instead of 16", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Matrix.m1 has unexpected size % instead of 4", it.type.runtime_size);
case "m5";
assert(it.offset_in_bytes == 20, "Matrix.m5 has unexpected offset % instead of 20", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Matrix.m5 has unexpected size % instead of 4", it.type.runtime_size);
case "m9";
assert(it.offset_in_bytes == 24, "Matrix.m9 has unexpected offset % instead of 24", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Matrix.m9 has unexpected size % instead of 4", it.type.runtime_size);
case "m13";
assert(it.offset_in_bytes == 28, "Matrix.m13 has unexpected offset % instead of 28", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Matrix.m13 has unexpected size % instead of 4", it.type.runtime_size);
case "m2";
assert(it.offset_in_bytes == 32, "Matrix.m2 has unexpected offset % instead of 32", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Matrix.m2 has unexpected size % instead of 4", it.type.runtime_size);
case "m6";
assert(it.offset_in_bytes == 36, "Matrix.m6 has unexpected offset % instead of 36", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Matrix.m6 has unexpected size % instead of 4", it.type.runtime_size);
case "m10";
assert(it.offset_in_bytes == 40, "Matrix.m10 has unexpected offset % instead of 40", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Matrix.m10 has unexpected size % instead of 4", it.type.runtime_size);
case "m14";
assert(it.offset_in_bytes == 44, "Matrix.m14 has unexpected offset % instead of 44", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Matrix.m14 has unexpected size % instead of 4", it.type.runtime_size);
case "m3";
assert(it.offset_in_bytes == 48, "Matrix.m3 has unexpected offset % instead of 48", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Matrix.m3 has unexpected size % instead of 4", it.type.runtime_size);
case "m7";
assert(it.offset_in_bytes == 52, "Matrix.m7 has unexpected offset % instead of 52", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Matrix.m7 has unexpected size % instead of 4", it.type.runtime_size);
case "m11";
assert(it.offset_in_bytes == 56, "Matrix.m11 has unexpected offset % instead of 56", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Matrix.m11 has unexpected size % instead of 4", it.type.runtime_size);
case "m15";
assert(it.offset_in_bytes == 60, "Matrix.m15 has unexpected offset % instead of 60", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Matrix.m15 has unexpected size % instead of 4", it.type.runtime_size);
}
}
assert(size_of(Matrix) == 64, "Matrix has size % instead of 64", size_of(Matrix));
}
{
info := type_info(Color);
for info.members {
if it.name == {
case "r";
assert(it.offset_in_bytes == 0, "Color.r has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 1, "Color.r has unexpected size % instead of 1", it.type.runtime_size);
case "g";
assert(it.offset_in_bytes == 1, "Color.g has unexpected offset % instead of 1", it.offset_in_bytes);
assert(it.type.runtime_size == 1, "Color.g has unexpected size % instead of 1", it.type.runtime_size);
case "b";
assert(it.offset_in_bytes == 2, "Color.b has unexpected offset % instead of 2", it.offset_in_bytes);
assert(it.type.runtime_size == 1, "Color.b has unexpected size % instead of 1", it.type.runtime_size);
case "a";
assert(it.offset_in_bytes == 3, "Color.a has unexpected offset % instead of 3", it.offset_in_bytes);
assert(it.type.runtime_size == 1, "Color.a has unexpected size % instead of 1", it.type.runtime_size);
}
}
assert(size_of(Color) == 4, "Color has size % instead of 4", size_of(Color));
}
{
info := type_info(Rectangle);
for info.members {
if it.name == {
case "x";
assert(it.offset_in_bytes == 0, "Rectangle.x has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Rectangle.x has unexpected size % instead of 4", it.type.runtime_size);
case "y";
assert(it.offset_in_bytes == 4, "Rectangle.y has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Rectangle.y has unexpected size % instead of 4", it.type.runtime_size);
case "width";
assert(it.offset_in_bytes == 8, "Rectangle.width has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Rectangle.width has unexpected size % instead of 4", it.type.runtime_size);
case "height";
assert(it.offset_in_bytes == 12, "Rectangle.height has unexpected offset % instead of 12", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Rectangle.height has unexpected size % instead of 4", it.type.runtime_size);
}
}
assert(size_of(Rectangle) == 16, "Rectangle has size % instead of 16", size_of(Rectangle));
}
{
info := type_info(Image);
for info.members {
if it.name == {
case "data";
assert(it.offset_in_bytes == 0, "Image.data has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Image.data has unexpected size % instead of 8", it.type.runtime_size);
case "width";
assert(it.offset_in_bytes == 8, "Image.width has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Image.width has unexpected size % instead of 4", it.type.runtime_size);
case "height";
assert(it.offset_in_bytes == 12, "Image.height has unexpected offset % instead of 12", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Image.height has unexpected size % instead of 4", it.type.runtime_size);
case "mipmaps";
assert(it.offset_in_bytes == 16, "Image.mipmaps has unexpected offset % instead of 16", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Image.mipmaps has unexpected size % instead of 4", it.type.runtime_size);
case "format";
assert(it.offset_in_bytes == 20, "Image.format has unexpected offset % instead of 20", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Image.format has unexpected size % instead of 4", it.type.runtime_size);
}
}
assert(size_of(Image) == 24, "Image has size % instead of 24", size_of(Image));
}
{
info := type_info(Texture);
for info.members {
if it.name == {
case "id";
assert(it.offset_in_bytes == 0, "Texture.id has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Texture.id has unexpected size % instead of 4", it.type.runtime_size);
case "width";
assert(it.offset_in_bytes == 4, "Texture.width has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Texture.width has unexpected size % instead of 4", it.type.runtime_size);
case "height";
assert(it.offset_in_bytes == 8, "Texture.height has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Texture.height has unexpected size % instead of 4", it.type.runtime_size);
case "mipmaps";
assert(it.offset_in_bytes == 12, "Texture.mipmaps has unexpected offset % instead of 12", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Texture.mipmaps has unexpected size % instead of 4", it.type.runtime_size);
case "format";
assert(it.offset_in_bytes == 16, "Texture.format has unexpected offset % instead of 16", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Texture.format has unexpected size % instead of 4", it.type.runtime_size);
}
}
assert(size_of(Texture) == 20, "Texture has size % instead of 20", size_of(Texture));
}
{
info := type_info(RenderTexture);
for info.members {
if it.name == {
case "id";
assert(it.offset_in_bytes == 0, "RenderTexture.id has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "RenderTexture.id has unexpected size % instead of 4", it.type.runtime_size);
case "texture";
assert(it.offset_in_bytes == 4, "RenderTexture.texture has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 20, "RenderTexture.texture has unexpected size % instead of 20", it.type.runtime_size);
case "depth";
assert(it.offset_in_bytes == 24, "RenderTexture.depth has unexpected offset % instead of 24", it.offset_in_bytes);
assert(it.type.runtime_size == 20, "RenderTexture.depth has unexpected size % instead of 20", it.type.runtime_size);
}
}
assert(size_of(RenderTexture) == 44, "RenderTexture has size % instead of 44", size_of(RenderTexture));
}
{
info := type_info(NPatchInfo);
for info.members {
if it.name == {
case "source";
assert(it.offset_in_bytes == 0, "NPatchInfo.source has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 16, "NPatchInfo.source has unexpected size % instead of 16", it.type.runtime_size);
case "left";
assert(it.offset_in_bytes == 16, "NPatchInfo.left has unexpected offset % instead of 16", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "NPatchInfo.left has unexpected size % instead of 4", it.type.runtime_size);
case "top";
assert(it.offset_in_bytes == 20, "NPatchInfo.top has unexpected offset % instead of 20", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "NPatchInfo.top has unexpected size % instead of 4", it.type.runtime_size);
case "right";
assert(it.offset_in_bytes == 24, "NPatchInfo.right has unexpected offset % instead of 24", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "NPatchInfo.right has unexpected size % instead of 4", it.type.runtime_size);
case "bottom";
assert(it.offset_in_bytes == 28, "NPatchInfo.bottom has unexpected offset % instead of 28", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "NPatchInfo.bottom has unexpected size % instead of 4", it.type.runtime_size);
case "layout";
assert(it.offset_in_bytes == 32, "NPatchInfo.layout has unexpected offset % instead of 32", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "NPatchInfo.layout has unexpected size % instead of 4", it.type.runtime_size);
}
}
assert(size_of(NPatchInfo) == 36, "NPatchInfo has size % instead of 36", size_of(NPatchInfo));
}
{
info := type_info(GlyphInfo);
for info.members {
if it.name == {
case "value";
assert(it.offset_in_bytes == 0, "GlyphInfo.value has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "GlyphInfo.value has unexpected size % instead of 4", it.type.runtime_size);
case "offsetX";
assert(it.offset_in_bytes == 4, "GlyphInfo.offsetX has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "GlyphInfo.offsetX has unexpected size % instead of 4", it.type.runtime_size);
case "offsetY";
assert(it.offset_in_bytes == 8, "GlyphInfo.offsetY has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "GlyphInfo.offsetY has unexpected size % instead of 4", it.type.runtime_size);
case "advanceX";
assert(it.offset_in_bytes == 12, "GlyphInfo.advanceX has unexpected offset % instead of 12", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "GlyphInfo.advanceX has unexpected size % instead of 4", it.type.runtime_size);
case "image";
assert(it.offset_in_bytes == 16, "GlyphInfo.image has unexpected offset % instead of 16", it.offset_in_bytes);
assert(it.type.runtime_size == 24, "GlyphInfo.image has unexpected size % instead of 24", it.type.runtime_size);
}
}
assert(size_of(GlyphInfo) == 40, "GlyphInfo has size % instead of 40", size_of(GlyphInfo));
}
{
info := type_info(Font);
for info.members {
if it.name == {
case "baseSize";
assert(it.offset_in_bytes == 0, "Font.baseSize has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Font.baseSize has unexpected size % instead of 4", it.type.runtime_size);
case "glyphCount";
assert(it.offset_in_bytes == 4, "Font.glyphCount has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Font.glyphCount has unexpected size % instead of 4", it.type.runtime_size);
case "glyphPadding";
assert(it.offset_in_bytes == 8, "Font.glyphPadding has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Font.glyphPadding has unexpected size % instead of 4", it.type.runtime_size);
case "texture";
assert(it.offset_in_bytes == 12, "Font.texture has unexpected offset % instead of 12", it.offset_in_bytes);
assert(it.type.runtime_size == 20, "Font.texture has unexpected size % instead of 20", it.type.runtime_size);
case "recs";
assert(it.offset_in_bytes == 32, "Font.recs has unexpected offset % instead of 32", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Font.recs has unexpected size % instead of 8", it.type.runtime_size);
case "glyphs";
assert(it.offset_in_bytes == 40, "Font.glyphs has unexpected offset % instead of 40", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Font.glyphs has unexpected size % instead of 8", it.type.runtime_size);
}
}
assert(size_of(Font) == 48, "Font has size % instead of 48", size_of(Font));
}
{
info := type_info(Camera3D);
for info.members {
if it.name == {
case "position";
assert(it.offset_in_bytes == 0, "Camera3D.position has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 12, "Camera3D.position has unexpected size % instead of 12", it.type.runtime_size);
case "target";
assert(it.offset_in_bytes == 12, "Camera3D.target has unexpected offset % instead of 12", it.offset_in_bytes);
assert(it.type.runtime_size == 12, "Camera3D.target has unexpected size % instead of 12", it.type.runtime_size);
case "up";
assert(it.offset_in_bytes == 24, "Camera3D.up has unexpected offset % instead of 24", it.offset_in_bytes);
assert(it.type.runtime_size == 12, "Camera3D.up has unexpected size % instead of 12", it.type.runtime_size);
case "fovy";
assert(it.offset_in_bytes == 36, "Camera3D.fovy has unexpected offset % instead of 36", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Camera3D.fovy has unexpected size % instead of 4", it.type.runtime_size);
case "projection";
assert(it.offset_in_bytes == 40, "Camera3D.projection has unexpected offset % instead of 40", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Camera3D.projection has unexpected size % instead of 4", it.type.runtime_size);
}
}
assert(size_of(Camera3D) == 44, "Camera3D has size % instead of 44", size_of(Camera3D));
}
{
info := type_info(Camera2D);
for info.members {
if it.name == {
case "offset";
assert(it.offset_in_bytes == 0, "Camera2D.offset has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Camera2D.offset has unexpected size % instead of 8", it.type.runtime_size);
case "target";
assert(it.offset_in_bytes == 8, "Camera2D.target has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Camera2D.target has unexpected size % instead of 8", it.type.runtime_size);
case "rotation";
assert(it.offset_in_bytes == 16, "Camera2D.rotation has unexpected offset % instead of 16", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Camera2D.rotation has unexpected size % instead of 4", it.type.runtime_size);
case "zoom";
assert(it.offset_in_bytes == 20, "Camera2D.zoom has unexpected offset % instead of 20", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Camera2D.zoom has unexpected size % instead of 4", it.type.runtime_size);
}
}
assert(size_of(Camera2D) == 24, "Camera2D has size % instead of 24", size_of(Camera2D));
}
{
info := type_info(Mesh);
for info.members {
if it.name == {
case "vertexCount";
assert(it.offset_in_bytes == 0, "Mesh.vertexCount has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Mesh.vertexCount has unexpected size % instead of 4", it.type.runtime_size);
case "triangleCount";
assert(it.offset_in_bytes == 4, "Mesh.triangleCount has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Mesh.triangleCount has unexpected size % instead of 4", it.type.runtime_size);
case "vertices";
assert(it.offset_in_bytes == 8, "Mesh.vertices has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Mesh.vertices has unexpected size % instead of 8", it.type.runtime_size);
case "texcoords";
assert(it.offset_in_bytes == 16, "Mesh.texcoords has unexpected offset % instead of 16", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Mesh.texcoords has unexpected size % instead of 8", it.type.runtime_size);
case "texcoords2";
assert(it.offset_in_bytes == 24, "Mesh.texcoords2 has unexpected offset % instead of 24", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Mesh.texcoords2 has unexpected size % instead of 8", it.type.runtime_size);
case "normals";
assert(it.offset_in_bytes == 32, "Mesh.normals has unexpected offset % instead of 32", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Mesh.normals has unexpected size % instead of 8", it.type.runtime_size);
case "tangents";
assert(it.offset_in_bytes == 40, "Mesh.tangents has unexpected offset % instead of 40", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Mesh.tangents has unexpected size % instead of 8", it.type.runtime_size);
case "colors";
assert(it.offset_in_bytes == 48, "Mesh.colors has unexpected offset % instead of 48", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Mesh.colors has unexpected size % instead of 8", it.type.runtime_size);
case "indices";
assert(it.offset_in_bytes == 56, "Mesh.indices has unexpected offset % instead of 56", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Mesh.indices has unexpected size % instead of 8", it.type.runtime_size);
case "animVertices";
assert(it.offset_in_bytes == 64, "Mesh.animVertices has unexpected offset % instead of 64", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Mesh.animVertices has unexpected size % instead of 8", it.type.runtime_size);
case "animNormals";
assert(it.offset_in_bytes == 72, "Mesh.animNormals has unexpected offset % instead of 72", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Mesh.animNormals has unexpected size % instead of 8", it.type.runtime_size);
case "boneIds";
assert(it.offset_in_bytes == 80, "Mesh.boneIds has unexpected offset % instead of 80", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Mesh.boneIds has unexpected size % instead of 8", it.type.runtime_size);
case "boneWeights";
assert(it.offset_in_bytes == 88, "Mesh.boneWeights has unexpected offset % instead of 88", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Mesh.boneWeights has unexpected size % instead of 8", it.type.runtime_size);
case "boneMatrices";
assert(it.offset_in_bytes == 96, "Mesh.boneMatrices has unexpected offset % instead of 96", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Mesh.boneMatrices has unexpected size % instead of 8", it.type.runtime_size);
case "boneCount";
assert(it.offset_in_bytes == 104, "Mesh.boneCount has unexpected offset % instead of 104", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Mesh.boneCount has unexpected size % instead of 4", it.type.runtime_size);
case "vaoId";
assert(it.offset_in_bytes == 108, "Mesh.vaoId has unexpected offset % instead of 108", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Mesh.vaoId has unexpected size % instead of 4", it.type.runtime_size);
case "vboId";
assert(it.offset_in_bytes == 112, "Mesh.vboId has unexpected offset % instead of 112", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Mesh.vboId has unexpected size % instead of 8", it.type.runtime_size);
}
}
assert(size_of(Mesh) == 120, "Mesh has size % instead of 120", size_of(Mesh));
}
{
info := type_info(Shader);
for info.members {
if it.name == {
case "id";
assert(it.offset_in_bytes == 0, "Shader.id has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Shader.id has unexpected size % instead of 4", it.type.runtime_size);
case "locs";
assert(it.offset_in_bytes == 8, "Shader.locs has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Shader.locs has unexpected size % instead of 8", it.type.runtime_size);
}
}
assert(size_of(Shader) == 16, "Shader has size % instead of 16", size_of(Shader));
}
{
info := type_info(MaterialMap);
for info.members {
if it.name == {
case "texture";
assert(it.offset_in_bytes == 0, "MaterialMap.texture has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 20, "MaterialMap.texture has unexpected size % instead of 20", it.type.runtime_size);
case "color";
assert(it.offset_in_bytes == 20, "MaterialMap.color has unexpected offset % instead of 20", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "MaterialMap.color has unexpected size % instead of 4", it.type.runtime_size);
case "value";
assert(it.offset_in_bytes == 24, "MaterialMap.value has unexpected offset % instead of 24", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "MaterialMap.value has unexpected size % instead of 4", it.type.runtime_size);
}
}
assert(size_of(MaterialMap) == 28, "MaterialMap has size % instead of 28", size_of(MaterialMap));
}
{
info := type_info(Material);
for info.members {
if it.name == {
case "shader";
assert(it.offset_in_bytes == 0, "Material.shader has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 16, "Material.shader has unexpected size % instead of 16", it.type.runtime_size);
case "maps";
assert(it.offset_in_bytes == 16, "Material.maps has unexpected offset % instead of 16", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Material.maps has unexpected size % instead of 8", it.type.runtime_size);
case "params";
assert(it.offset_in_bytes == 24, "Material.params has unexpected offset % instead of 24", it.offset_in_bytes);
assert(it.type.runtime_size == 16, "Material.params has unexpected size % instead of 16", it.type.runtime_size);
}
}
assert(size_of(Material) == 40, "Material has size % instead of 40", size_of(Material));
}
{
info := type_info(Transform);
for info.members {
if it.name == {
case "translation";
assert(it.offset_in_bytes == 0, "Transform.translation has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 12, "Transform.translation has unexpected size % instead of 12", it.type.runtime_size);
case "rotation";
assert(it.offset_in_bytes == 12, "Transform.rotation has unexpected offset % instead of 12", it.offset_in_bytes);
assert(it.type.runtime_size == 16, "Transform.rotation has unexpected size % instead of 16", it.type.runtime_size);
case "scale";
assert(it.offset_in_bytes == 28, "Transform.scale has unexpected offset % instead of 28", it.offset_in_bytes);
assert(it.type.runtime_size == 12, "Transform.scale has unexpected size % instead of 12", it.type.runtime_size);
}
}
assert(size_of(Transform) == 40, "Transform has size % instead of 40", size_of(Transform));
}
{
info := type_info(BoneInfo);
for info.members {
if it.name == {
case "name";
assert(it.offset_in_bytes == 0, "BoneInfo.name has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 32, "BoneInfo.name has unexpected size % instead of 32", it.type.runtime_size);
case "parent";
assert(it.offset_in_bytes == 32, "BoneInfo.parent has unexpected offset % instead of 32", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "BoneInfo.parent has unexpected size % instead of 4", it.type.runtime_size);
}
}
assert(size_of(BoneInfo) == 36, "BoneInfo has size % instead of 36", size_of(BoneInfo));
}
{
info := type_info(Model);
for info.members {
if it.name == {
case "transform";
assert(it.offset_in_bytes == 0, "Model.transform has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 64, "Model.transform has unexpected size % instead of 64", it.type.runtime_size);
case "meshCount";
assert(it.offset_in_bytes == 64, "Model.meshCount has unexpected offset % instead of 64", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Model.meshCount has unexpected size % instead of 4", it.type.runtime_size);
case "materialCount";
assert(it.offset_in_bytes == 68, "Model.materialCount has unexpected offset % instead of 68", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Model.materialCount has unexpected size % instead of 4", it.type.runtime_size);
case "meshes";
assert(it.offset_in_bytes == 72, "Model.meshes has unexpected offset % instead of 72", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Model.meshes has unexpected size % instead of 8", it.type.runtime_size);
case "materials";
assert(it.offset_in_bytes == 80, "Model.materials has unexpected offset % instead of 80", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Model.materials has unexpected size % instead of 8", it.type.runtime_size);
case "meshMaterial";
assert(it.offset_in_bytes == 88, "Model.meshMaterial has unexpected offset % instead of 88", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Model.meshMaterial has unexpected size % instead of 8", it.type.runtime_size);
case "boneCount";
assert(it.offset_in_bytes == 96, "Model.boneCount has unexpected offset % instead of 96", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Model.boneCount has unexpected size % instead of 4", it.type.runtime_size);
case "bones";
assert(it.offset_in_bytes == 104, "Model.bones has unexpected offset % instead of 104", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Model.bones has unexpected size % instead of 8", it.type.runtime_size);
case "bindPose";
assert(it.offset_in_bytes == 112, "Model.bindPose has unexpected offset % instead of 112", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Model.bindPose has unexpected size % instead of 8", it.type.runtime_size);
}
}
assert(size_of(Model) == 120, "Model has size % instead of 120", size_of(Model));
}
{
info := type_info(ModelAnimation);
for info.members {
if it.name == {
case "boneCount";
assert(it.offset_in_bytes == 0, "ModelAnimation.boneCount has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "ModelAnimation.boneCount has unexpected size % instead of 4", it.type.runtime_size);
case "frameCount";
assert(it.offset_in_bytes == 4, "ModelAnimation.frameCount has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "ModelAnimation.frameCount has unexpected size % instead of 4", it.type.runtime_size);
case "bones";
assert(it.offset_in_bytes == 8, "ModelAnimation.bones has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "ModelAnimation.bones has unexpected size % instead of 8", it.type.runtime_size);
case "framePoses";
assert(it.offset_in_bytes == 16, "ModelAnimation.framePoses has unexpected offset % instead of 16", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "ModelAnimation.framePoses has unexpected size % instead of 8", it.type.runtime_size);
case "name";
assert(it.offset_in_bytes == 24, "ModelAnimation.name has unexpected offset % instead of 24", it.offset_in_bytes);
assert(it.type.runtime_size == 32, "ModelAnimation.name has unexpected size % instead of 32", it.type.runtime_size);
}
}
assert(size_of(ModelAnimation) == 56, "ModelAnimation has size % instead of 56", size_of(ModelAnimation));
}
{
info := type_info(Ray);
for info.members {
if it.name == {
case "position";
assert(it.offset_in_bytes == 0, "Ray.position has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 12, "Ray.position has unexpected size % instead of 12", it.type.runtime_size);
case "direction";
assert(it.offset_in_bytes == 12, "Ray.direction has unexpected offset % instead of 12", it.offset_in_bytes);
assert(it.type.runtime_size == 12, "Ray.direction has unexpected size % instead of 12", it.type.runtime_size);
}
}
assert(size_of(Ray) == 24, "Ray has size % instead of 24", size_of(Ray));
}
{
info := type_info(RayCollision);
for info.members {
if it.name == {
case "hit";
assert(it.offset_in_bytes == 0, "RayCollision.hit has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 1, "RayCollision.hit has unexpected size % instead of 1", it.type.runtime_size);
case "distance";
assert(it.offset_in_bytes == 4, "RayCollision.distance has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "RayCollision.distance has unexpected size % instead of 4", it.type.runtime_size);
case "point";
assert(it.offset_in_bytes == 8, "RayCollision.point has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 12, "RayCollision.point has unexpected size % instead of 12", it.type.runtime_size);
case "normal";
assert(it.offset_in_bytes == 20, "RayCollision.normal has unexpected offset % instead of 20", it.offset_in_bytes);
assert(it.type.runtime_size == 12, "RayCollision.normal has unexpected size % instead of 12", it.type.runtime_size);
}
}
assert(size_of(RayCollision) == 32, "RayCollision has size % instead of 32", size_of(RayCollision));
}
{
info := type_info(BoundingBox);
for info.members {
if it.name == {
case "min";
assert(it.offset_in_bytes == 0, "BoundingBox.min has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 12, "BoundingBox.min has unexpected size % instead of 12", it.type.runtime_size);
case "max";
assert(it.offset_in_bytes == 12, "BoundingBox.max has unexpected offset % instead of 12", it.offset_in_bytes);
assert(it.type.runtime_size == 12, "BoundingBox.max has unexpected size % instead of 12", it.type.runtime_size);
}
}
assert(size_of(BoundingBox) == 24, "BoundingBox has size % instead of 24", size_of(BoundingBox));
}
{
info := type_info(Wave);
for info.members {
if it.name == {
case "frameCount";
assert(it.offset_in_bytes == 0, "Wave.frameCount has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Wave.frameCount has unexpected size % instead of 4", it.type.runtime_size);
case "sampleRate";
assert(it.offset_in_bytes == 4, "Wave.sampleRate has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Wave.sampleRate has unexpected size % instead of 4", it.type.runtime_size);
case "sampleSize";
assert(it.offset_in_bytes == 8, "Wave.sampleSize has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Wave.sampleSize has unexpected size % instead of 4", it.type.runtime_size);
case "channels";
assert(it.offset_in_bytes == 12, "Wave.channels has unexpected offset % instead of 12", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Wave.channels has unexpected size % instead of 4", it.type.runtime_size);
case "data";
assert(it.offset_in_bytes == 16, "Wave.data has unexpected offset % instead of 16", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Wave.data has unexpected size % instead of 8", it.type.runtime_size);
}
}
assert(size_of(Wave) == 24, "Wave has size % instead of 24", size_of(Wave));
}
{
info := type_info(AudioStream);
for info.members {
if it.name == {
case "buffer";
assert(it.offset_in_bytes == 0, "AudioStream.buffer has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "AudioStream.buffer has unexpected size % instead of 8", it.type.runtime_size);
case "processor";
assert(it.offset_in_bytes == 8, "AudioStream.processor has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "AudioStream.processor has unexpected size % instead of 8", it.type.runtime_size);
case "sampleRate";
assert(it.offset_in_bytes == 16, "AudioStream.sampleRate has unexpected offset % instead of 16", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "AudioStream.sampleRate has unexpected size % instead of 4", it.type.runtime_size);
case "sampleSize";
assert(it.offset_in_bytes == 20, "AudioStream.sampleSize has unexpected offset % instead of 20", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "AudioStream.sampleSize has unexpected size % instead of 4", it.type.runtime_size);
case "channels";
assert(it.offset_in_bytes == 24, "AudioStream.channels has unexpected offset % instead of 24", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "AudioStream.channels has unexpected size % instead of 4", it.type.runtime_size);
}
}
assert(size_of(AudioStream) == 32, "AudioStream has size % instead of 32", size_of(AudioStream));
}
{
info := type_info(Sound);
for info.members {
if it.name == {
case "stream";
assert(it.offset_in_bytes == 0, "Sound.stream has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 32, "Sound.stream has unexpected size % instead of 32", it.type.runtime_size);
case "frameCount";
assert(it.offset_in_bytes == 32, "Sound.frameCount has unexpected offset % instead of 32", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Sound.frameCount has unexpected size % instead of 4", it.type.runtime_size);
}
}
assert(size_of(Sound) == 40, "Sound has size % instead of 40", size_of(Sound));
}
{
info := type_info(Music);
for info.members {
if it.name == {
case "stream";
assert(it.offset_in_bytes == 0, "Music.stream has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 32, "Music.stream has unexpected size % instead of 32", it.type.runtime_size);
case "frameCount";
assert(it.offset_in_bytes == 32, "Music.frameCount has unexpected offset % instead of 32", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Music.frameCount has unexpected size % instead of 4", it.type.runtime_size);
case "looping";
assert(it.offset_in_bytes == 36, "Music.looping has unexpected offset % instead of 36", it.offset_in_bytes);
assert(it.type.runtime_size == 1, "Music.looping has unexpected size % instead of 1", it.type.runtime_size);
case "ctxType";
assert(it.offset_in_bytes == 40, "Music.ctxType has unexpected offset % instead of 40", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "Music.ctxType has unexpected size % instead of 4", it.type.runtime_size);
case "ctxData";
assert(it.offset_in_bytes == 48, "Music.ctxData has unexpected offset % instead of 48", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "Music.ctxData has unexpected size % instead of 8", it.type.runtime_size);
}
}
assert(size_of(Music) == 56, "Music has size % instead of 56", size_of(Music));
}
{
info := type_info(VrDeviceInfo);
for info.members {
if it.name == {
case "hResolution";
assert(it.offset_in_bytes == 0, "VrDeviceInfo.hResolution has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "VrDeviceInfo.hResolution has unexpected size % instead of 4", it.type.runtime_size);
case "vResolution";
assert(it.offset_in_bytes == 4, "VrDeviceInfo.vResolution has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "VrDeviceInfo.vResolution has unexpected size % instead of 4", it.type.runtime_size);
case "hScreenSize";
assert(it.offset_in_bytes == 8, "VrDeviceInfo.hScreenSize has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "VrDeviceInfo.hScreenSize has unexpected size % instead of 4", it.type.runtime_size);
case "vScreenSize";
assert(it.offset_in_bytes == 12, "VrDeviceInfo.vScreenSize has unexpected offset % instead of 12", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "VrDeviceInfo.vScreenSize has unexpected size % instead of 4", it.type.runtime_size);
case "eyeToScreenDistance";
assert(it.offset_in_bytes == 16, "VrDeviceInfo.eyeToScreenDistance has unexpected offset % instead of 16", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "VrDeviceInfo.eyeToScreenDistance has unexpected size % instead of 4", it.type.runtime_size);
case "lensSeparationDistance";
assert(it.offset_in_bytes == 20, "VrDeviceInfo.lensSeparationDistance has unexpected offset % instead of 20", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "VrDeviceInfo.lensSeparationDistance has unexpected size % instead of 4", it.type.runtime_size);
case "interpupillaryDistance";
assert(it.offset_in_bytes == 24, "VrDeviceInfo.interpupillaryDistance has unexpected offset % instead of 24", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "VrDeviceInfo.interpupillaryDistance has unexpected size % instead of 4", it.type.runtime_size);
case "lensDistortionValues";
assert(it.offset_in_bytes == 28, "VrDeviceInfo.lensDistortionValues has unexpected offset % instead of 28", it.offset_in_bytes);
assert(it.type.runtime_size == 16, "VrDeviceInfo.lensDistortionValues has unexpected size % instead of 16", it.type.runtime_size);
case "chromaAbCorrection";
assert(it.offset_in_bytes == 44, "VrDeviceInfo.chromaAbCorrection has unexpected offset % instead of 44", it.offset_in_bytes);
assert(it.type.runtime_size == 16, "VrDeviceInfo.chromaAbCorrection has unexpected size % instead of 16", it.type.runtime_size);
}
}
assert(size_of(VrDeviceInfo) == 60, "VrDeviceInfo has size % instead of 60", size_of(VrDeviceInfo));
}
{
info := type_info(VrStereoConfig);
for info.members {
if it.name == {
case "projection";
assert(it.offset_in_bytes == 0, "VrStereoConfig.projection has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 128, "VrStereoConfig.projection has unexpected size % instead of 128", it.type.runtime_size);
case "viewOffset";
assert(it.offset_in_bytes == 128, "VrStereoConfig.viewOffset has unexpected offset % instead of 128", it.offset_in_bytes);
assert(it.type.runtime_size == 128, "VrStereoConfig.viewOffset has unexpected size % instead of 128", it.type.runtime_size);
case "leftLensCenter";
assert(it.offset_in_bytes == 256, "VrStereoConfig.leftLensCenter has unexpected offset % instead of 256", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "VrStereoConfig.leftLensCenter has unexpected size % instead of 8", it.type.runtime_size);
case "rightLensCenter";
assert(it.offset_in_bytes == 264, "VrStereoConfig.rightLensCenter has unexpected offset % instead of 264", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "VrStereoConfig.rightLensCenter has unexpected size % instead of 8", it.type.runtime_size);
case "leftScreenCenter";
assert(it.offset_in_bytes == 272, "VrStereoConfig.leftScreenCenter has unexpected offset % instead of 272", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "VrStereoConfig.leftScreenCenter has unexpected size % instead of 8", it.type.runtime_size);
case "rightScreenCenter";
assert(it.offset_in_bytes == 280, "VrStereoConfig.rightScreenCenter has unexpected offset % instead of 280", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "VrStereoConfig.rightScreenCenter has unexpected size % instead of 8", it.type.runtime_size);
case "scale";
assert(it.offset_in_bytes == 288, "VrStereoConfig.scale has unexpected offset % instead of 288", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "VrStereoConfig.scale has unexpected size % instead of 8", it.type.runtime_size);
case "scaleIn";
assert(it.offset_in_bytes == 296, "VrStereoConfig.scaleIn has unexpected offset % instead of 296", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "VrStereoConfig.scaleIn has unexpected size % instead of 8", it.type.runtime_size);
}
}
assert(size_of(VrStereoConfig) == 304, "VrStereoConfig has size % instead of 304", size_of(VrStereoConfig));
}
{
info := type_info(FilePathList);
for info.members {
if it.name == {
case "capacity";
assert(it.offset_in_bytes == 0, "FilePathList.capacity has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "FilePathList.capacity has unexpected size % instead of 4", it.type.runtime_size);
case "count";
assert(it.offset_in_bytes == 4, "FilePathList.count has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "FilePathList.count has unexpected size % instead of 4", it.type.runtime_size);
case "paths";
assert(it.offset_in_bytes == 8, "FilePathList.paths has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "FilePathList.paths has unexpected size % instead of 8", it.type.runtime_size);
}
}
assert(size_of(FilePathList) == 16, "FilePathList has size % instead of 16", size_of(FilePathList));
}
{
info := type_info(AutomationEvent);
for info.members {
if it.name == {
case "frame";
assert(it.offset_in_bytes == 0, "AutomationEvent.frame has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "AutomationEvent.frame has unexpected size % instead of 4", it.type.runtime_size);
case "type";
assert(it.offset_in_bytes == 4, "AutomationEvent.type has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "AutomationEvent.type has unexpected size % instead of 4", it.type.runtime_size);
case "params";
assert(it.offset_in_bytes == 8, "AutomationEvent.params has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 16, "AutomationEvent.params has unexpected size % instead of 16", it.type.runtime_size);
}
}
assert(size_of(AutomationEvent) == 24, "AutomationEvent has size % instead of 24", size_of(AutomationEvent));
}
{
info := type_info(AutomationEventList);
for info.members {
if it.name == {
case "capacity";
assert(it.offset_in_bytes == 0, "AutomationEventList.capacity has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "AutomationEventList.capacity has unexpected size % instead of 4", it.type.runtime_size);
case "count";
assert(it.offset_in_bytes == 4, "AutomationEventList.count has unexpected offset % instead of 4", it.offset_in_bytes);
assert(it.type.runtime_size == 4, "AutomationEventList.count has unexpected size % instead of 4", it.type.runtime_size);
case "events";
assert(it.offset_in_bytes == 8, "AutomationEventList.events has unexpected offset % instead of 8", it.offset_in_bytes);
assert(it.type.runtime_size == 8, "AutomationEventList.events has unexpected size % instead of 8", it.type.runtime_size);
}
}
assert(size_of(AutomationEventList) == 16, "AutomationEventList has size % instead of 16", size_of(AutomationEventList));
}
{
info := type_info(float3);
for info.members {
if it.name == {
case "v";
assert(it.offset_in_bytes == 0, "float3.v has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 12, "float3.v has unexpected size % instead of 12", it.type.runtime_size);
}
}
assert(size_of(float3) == 12, "float3 has size % instead of 12", size_of(float3));
}
{
info := type_info(float16);
for info.members {
if it.name == {
case "v";
assert(it.offset_in_bytes == 0, "float16.v has unexpected offset % instead of 0", it.offset_in_bytes);
assert(it.type.runtime_size == 64, "float16.v has unexpected size % instead of 64", it.type.runtime_size);
}
}
assert(size_of(float16) == 64, "float16 has size % instead of 64", size_of(float16));
}
}
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