// stbgl - v0.04 - Sean Barrett 2008 - public domain // // Note that the gl extensions support requires glext.h. In fact, it works // if you just concatenate glext.h onto the end of this file. In that case, // this file is covered by the SGI FreeB license, and is not public domain. // // Extension usage: // // 1. Make a file called something like "extlist.txt" which contains stuff like: // GLE(ShaderSourceARB,SHADERSOURCEARB) // GLE(Uniform1iARB,UNIFORM1IARB) // GLARB(ActiveTexture,ACTIVETEXTURE) // same as GLE(ActiveTextureARB,ACTIVETEXTUREARB) // GLARB(ClientActiveTexture,CLIENTACTIVETEXTURE) // GLE(MultiTexCoord2f,MULTITEXCOORD2F) // // 2. To declare functions (to make a header file), do this: // #define STB_GLEXT_DECLARE "extlist.txt" // #include "stb_gl.h" // // A good way to do this is to define STB_GLEXT_DECLARE project-wide. // // 3. To define functions (implement), do this in some C file: // #define STB_GLEXT_DEFINE "extlist.txt" // #include "stb_gl.h" // // If you've already defined STB_GLEXT_DECLARE, you can just do: // #define STB_GLEXT_DEFINE_DECLARE // #include "stb_gl.h" // // 4. Now you need to initialize: // // stbgl_initExtensions(); #ifndef INCLUDE_STB_GL_H #define INCLUDE_STB_GL_H #define STB_GL #ifdef _WIN32 #ifndef WINGDIAPI #define CALLBACK __stdcall #define WINGDIAPI __declspec(dllimport) #define APIENTRY __stdcall #endif #endif //_WIN32 #include #include #include #ifndef M_PI #define M_PI 3.14159265358979323846f #endif #ifdef __cplusplus extern "C" { #endif // like gluPerspective, but: // fov is chosen to satisfy both hfov <= max_hfov & vfov <= max_vfov; // set one to 179 or 0 to ignore it // zoom is applied separately, so you can do linear zoom without // mucking with trig with fov; 1 -> use exact fov // 'aspect' is inferred from the current viewport, and ignores the // possibility of non-square pixels extern void stbgl_Perspective(float zoom, float max_hfov, float max_vfov, float znear, float zfar); extern void stbgl_PerspectiveViewport(int x, int y, int w, int h, float zoom, float max_hfov, float max_vfov, float znear, float zfar); extern void stbgl_initCamera_zup_facing_x(void); extern void stbgl_initCamera_zup_facing_y(void); extern void stbgl_positionCameraWithEulerAngles(float *loc, float *ang); extern void stbgl_drawRect(float x0, float y0, float x1, float y1); extern void stbgl_drawRectTC(float x0, float y0, float x1, float y1, float s0, float t0, float s1, float t1); extern void stbgl_drawBox(float x, float y, float z, float sx, float sy, float sz, int cw); extern int stbgl_hasExtension(char *ext); extern void stbgl_SimpleLight(int index, float bright, float x, float y, float z); extern void stbgl_GlobalAmbient(float r, float g, float b); extern int stbgl_LoadTexture(char *filename, char *props); // only if stb_image is available extern int stbgl_TestTexture(int w); extern int stbgl_TestTextureEx(int w, char *scale_table, int checks_log2, int r1,int g1,int b1, int r2, int b2, int g2); extern unsigned int stbgl_rand(void); // internal, but exposed just in case; LCG, so use middle bits extern int stbgl_TexImage2D(int texid, int w, int h, void *data, char *props); extern int stbgl_TexImage2D_Extra(int texid, int w, int h, void *data, int chan, char *props, int preserve_data); // "props" is a series of characters (and blocks of characters), a la fopen()'s mode, // e.g.: // GLuint texid = stbgl_LoadTexture("myfile.jpg", "mbc") // means: load the image "myfile.jpg", and do the following: // generate mipmaps // use bilinear filtering (not trilinear) // use clamp-to-edge on both channels // // input descriptor: AT MOST ONE // TEXT MEANING // 1 1 channel of input (intensity/alpha) // 2 2 channels of input (luminance, alpha) // 3 3 channels of input (RGB) // 4 4 channels of input (RGBA) // l 1 channel of input (luminance) // a 1 channel of input (alpha) // la 2 channels of input (lum/alpha) // rgb 3 channels of input (RGB) // ycocg 3 channels of input (YCoCg - forces YCoCg output) // ycocgj 4 channels of input (YCoCgJunk - forces YCoCg output) // rgba 4 channels of input (RGBA) // // output descriptor: AT MOST ONE // TEXT MEANING // A 1 channel of output (alpha) // I 1 channel of output (intensity) // LA 2 channels of output (lum/alpha) // RGB 3 channels of output (RGB) // RGBA 4 channels of output (RGBA) // DXT1 encode as a DXT1 texture (RGB unless input has RGBA) // DXT3 encode as a DXT3 texture // DXT5 encode as a DXT5 texture // YCoCg encode as a DXT5 texture with Y in alpha, CoCg in RG // D GL_DEPTH_COMPONENT // NONE no input/output, don't call TexImage2D at all // // when reading from a file or using another interface with an explicit // channel count, the input descriptor is ignored and instead the channel // count is used as the input descriptor. if the file read is a DXT DDS, // then it is passed directly to OpenGL in the file format. // // if an input descriptor is supplied but no output descriptor, the output // is assumed to be the same as the input. if an output descriptor is supplied // but no input descriptor, the input is assumed to be the same as the // output. if neither is supplied, the input is assumed to be 4-channel. // If DXT1 or YCoCG output is requested with no input, the input is assumed // to be 4-channel but the alpha channel is ignored. // // filtering descriptor (default is no mipmaps) // TEXT MEANING // m generate mipmaps // M mipmaps are provided, concatenated at end of data (from largest to smallest) // t use trilinear filtering (default if mipmapped) // b use bilinear filtering (default if not-mipmapped) // n use nearest-neighbor sampling // // wrapping descriptor // TEXT MEANING // w wrap (default) // c clamp-to-edge // C GL_CLAMP (uses border color) // // If only one wrapping descriptor is supplied, it is applied to both channels. // // special: // TEXT MEANING // f input data is floats (default unsigned bytes) // F input&output data is floats (default unsigned bytes) // p explicitly pre-multiply the alpha // P pad to power-of-two (default stretches) // NP2 non-power-of-two // + can overwrite the texture data with temp data // ! free the texture data with "free" // // the properties string can also include spaces #ifdef __cplusplus } #endif #ifdef STB_GL_IMPLEMENTATION #include #include #include #include int stbgl_hasExtension(char *ext) { const char *s = glGetString(GL_EXTENSIONS); for(;;) { char *e = ext; for (;;) { if (*e == 0) { if (*s == 0 || *s == ' ') return 1; break; } if (*s != *e) break; ++s, ++e; } while (*s && *s != ' ') ++s; if (!*s) return 0; ++s; // skip space } } void stbgl_drawRect(float x0, float y0, float x1, float y1) { glBegin(GL_POLYGON); glTexCoord2f(0,0); glVertex2f(x0,y0); glTexCoord2f(1,0); glVertex2f(x1,y0); glTexCoord2f(1,1); glVertex2f(x1,y1); glTexCoord2f(0,1); glVertex2f(x0,y1); glEnd(); } void stbgl_drawRectTC(float x0, float y0, float x1, float y1, float s0, float t0, float s1, float t1) { glBegin(GL_POLYGON); glTexCoord2f(s0,t0); glVertex2f(x0,y0); glTexCoord2f(s1,t0); glVertex2f(x1,y0); glTexCoord2f(s1,t1); glVertex2f(x1,y1); glTexCoord2f(s0,t1); glVertex2f(x0,y1); glEnd(); } void stbgl_drawBox(float x, float y, float z, float sx, float sy, float sz, int cw) { float x0,y0,z0,x1,y1,z1; sx /=2, sy/=2, sz/=2; x0 = x-sx; y0 = y-sy; z0 = z-sz; x1 = x+sx; y1 = y+sy; z1 = z+sz; glBegin(GL_QUADS); if (cw) { glNormal3f(0,0,-1); glTexCoord2f(0,0); glVertex3f(x0,y0,z0); glTexCoord2f(1,0); glVertex3f(x1,y0,z0); glTexCoord2f(1,1); glVertex3f(x1,y1,z0); glTexCoord2f(0,1); glVertex3f(x0,y1,z0); glNormal3f(0,0,1); glTexCoord2f(0,0); glVertex3f(x1,y0,z1); glTexCoord2f(1,0); glVertex3f(x0,y0,z1); glTexCoord2f(1,1); glVertex3f(x0,y1,z1); glTexCoord2f(0,1); glVertex3f(x1,y1,z1); glNormal3f(-1,0,0); glTexCoord2f(0,0); glVertex3f(x0,y1,z1); glTexCoord2f(1,0); glVertex3f(x0,y0,z1); glTexCoord2f(1,1); glVertex3f(x0,y0,z0); glTexCoord2f(0,1); glVertex3f(x0,y1,z0); glNormal3f(1,0,0); glTexCoord2f(0,0); glVertex3f(x1,y0,z1); glTexCoord2f(1,0); glVertex3f(x1,y1,z1); glTexCoord2f(1,1); glVertex3f(x1,y1,z0); glTexCoord2f(0,1); glVertex3f(x1,y0,z0); glNormal3f(0,-1,0); glTexCoord2f(0,0); glVertex3f(x0,y0,z1); glTexCoord2f(1,0); glVertex3f(x1,y0,z1); glTexCoord2f(1,1); glVertex3f(x1,y0,z0); glTexCoord2f(0,1); glVertex3f(x0,y0,z0); glNormal3f(0,1,0); glTexCoord2f(0,0); glVertex3f(x1,y1,z1); glTexCoord2f(1,0); glVertex3f(x0,y1,z1); glTexCoord2f(1,1); glVertex3f(x0,y1,z0); glTexCoord2f(0,1); glVertex3f(x1,y1,z0); } else { glNormal3f(0,0,-1); glTexCoord2f(0,0); glVertex3f(x0,y0,z0); glTexCoord2f(0,1); glVertex3f(x0,y1,z0); glTexCoord2f(1,1); glVertex3f(x1,y1,z0); glTexCoord2f(1,0); glVertex3f(x1,y0,z0); glNormal3f(0,0,1); glTexCoord2f(0,0); glVertex3f(x1,y0,z1); glTexCoord2f(0,1); glVertex3f(x1,y1,z1); glTexCoord2f(1,1); glVertex3f(x0,y1,z1); glTexCoord2f(1,0); glVertex3f(x0,y0,z1); glNormal3f(-1,0,0); glTexCoord2f(0,0); glVertex3f(x0,y1,z1); glTexCoord2f(0,1); glVertex3f(x0,y1,z0); glTexCoord2f(1,1); glVertex3f(x0,y0,z0); glTexCoord2f(1,0); glVertex3f(x0,y0,z1); glNormal3f(1,0,0); glTexCoord2f(0,0); glVertex3f(x1,y0,z1); glTexCoord2f(0,1); glVertex3f(x1,y0,z0); glTexCoord2f(1,1); glVertex3f(x1,y1,z0); glTexCoord2f(1,0); glVertex3f(x1,y1,z1); glNormal3f(0,-1,0); glTexCoord2f(0,0); glVertex3f(x0,y0,z1); glTexCoord2f(0,1); glVertex3f(x0,y0,z0); glTexCoord2f(1,1); glVertex3f(x1,y0,z0); glTexCoord2f(1,0); glVertex3f(x1,y0,z1); glNormal3f(0,1,0); glTexCoord2f(0,0); glVertex3f(x1,y1,z1); glTexCoord2f(0,1); glVertex3f(x1,y1,z0); glTexCoord2f(1,1); glVertex3f(x0,y1,z0); glTexCoord2f(1,0); glVertex3f(x0,y1,z1); } glEnd(); } void stbgl_SimpleLight(int index, float bright, float x, float y, float z) { float d = (float) (1.0f/sqrt(x*x+y*y+z*z)); float dir[4] = { x*d,y*d,z*d,0 }, zero[4] = { 0,0,0,0 }; float c[4] = { bright,bright,bright,0 }; GLuint light = GL_LIGHT0 + index; glLightfv(light, GL_POSITION, dir); glLightfv(light, GL_DIFFUSE, c); glLightfv(light, GL_AMBIENT, zero); glLightfv(light, GL_SPECULAR, zero); glEnable(light); glColorMaterial(GL_FRONT, GL_AMBIENT_AND_DIFFUSE); glEnable(GL_COLOR_MATERIAL); } void stbgl_GlobalAmbient(float r, float g, float b) { float v[4] = { r,g,b,0 }; glLightModelfv(GL_LIGHT_MODEL_AMBIENT, v); } #define stbgl_rad2deg(r) ((r)*180.0f / M_PI) #define stbgl_deg2rad(r) ((r)/180.0f * M_PI) void stbgl_Perspective(float zoom, float max_hfov, float max_vfov, float znear, float zfar) { float unit_width, unit_height, aspect, vfov; int data[4],w,h; glGetIntegerv(GL_VIEWPORT, data); w = data[2]; h = data[3]; aspect = (float) w / h; if (max_hfov <= 0) max_hfov = 179; if (max_vfov <= 0) max_vfov = 179; // convert max_hfov, max_vfov to worldspace width at depth=1 unit_width = (float) tan(stbgl_deg2rad(max_hfov/2)) * 2; unit_height = (float) tan(stbgl_deg2rad(max_vfov/2)) * 2; // check if hfov = max_hfov is enough to satisfy it if (unit_width <= aspect * unit_height) { float height = unit_width / aspect; vfov = (float) atan(( height/2) / zoom); } else { vfov = (float) atan((unit_height/2) / zoom); } vfov = (float) stbgl_rad2deg(vfov * 2); gluPerspective(vfov, aspect, znear, zfar); } void stbgl_PerspectiveViewport(int x, int y, int w, int h, float zoom, float min_hfov, float min_vfov, float znear, float zfar) { if (znear <= 0.0001f) znear = 0.0001f; glViewport(x,y,w,h); glScissor(x,y,w,h); glMatrixMode(GL_PROJECTION); glLoadIdentity(); stbgl_Perspective(zoom, min_hfov, min_vfov, znear, zfar); glMatrixMode(GL_MODELVIEW); } // point the camera along the positive X axis, Z-up void stbgl_initCamera_zup_facing_x(void) { glRotatef(-90, 1,0,0); glRotatef( 90, 0,0,1); } // point the camera along the positive Y axis, Z-up void stbgl_initCamera_zup_facing_y(void) { glRotatef(-90, 1,0,0); } // setup a camera using Euler angles void stbgl_positionCameraWithEulerAngles(float *loc, float *ang) { glRotatef(-ang[1], 0,1,0); glRotatef(-ang[0], 1,0,0); glRotatef(-ang[2], 0,0,1); glTranslatef(-loc[0], -loc[1], -loc[2]); } static int stbgl_m(char *a, char *b) { // skip first character do { ++a,++b; } while (*b && *a == *b); return *b == 0; } #ifdef STBI_VERSION #ifndef STBI_NO_STDIO int stbgl_LoadTexture(char *filename, char *props) { // @TODO: handle DDS files directly int res; void *data; int w,h,c; #ifndef STBI_NO_HDR if (stbi_is_hdr(filename)) { data = stbi_loadf(filename, &w, &h, &c, 0); if (!data) return 0; res = stbgl_TexImage2D_Extra(0, w,h,data, -c, props, 0); free(data); return res; } #endif data = stbi_load(filename, &w, &h, &c, 0); if (!data) return 0; res = stbgl_TexImage2D_Extra(0, w,h,data, c, props, 0); free(data); return res; } #endif #endif // STBI_VERSION int stbgl_TexImage2D(int texid, int w, int h, void *data, char *props) { return stbgl_TexImage2D_Extra(texid, w, h, data, 0, props,1); } int stbgl_TestTexture(int w) { char scale_table[] = { 10,20,30,30,35,40,5,18,25,13,7,5,3,3,2,2,2,2,1,1,1,1,1,0,0,0,0,0,0,0,0,0,0 }; return stbgl_TestTextureEx(w, scale_table, 2, 140,130,200, 180,200,170); } unsigned int stbgl_rand(void) { static unsigned int stbgl__rand_seed = 3248980923; // random typing return stbgl__rand_seed = stbgl__rand_seed * 2147001325 + 715136305; // BCPL generator } // wish this could be smaller, since it's so frivolous int stbgl_TestTextureEx(int w, char *scale_table, int checks_log2, int r1,int g1,int b1, int r2, int b2, int g2) { int rt[2] = {r1,r2}, gt[2] = {g1,g2}, bt[2] = {b1,b2}; signed char modded[256]; int i,j, m = w-1, s,k,scale; unsigned char *data = (unsigned char *) malloc(w*w*3); assert((m & w) == 0); data[0] = 128; for (s=0; s < 16; ++s) if ((1 << s) == w) break; assert(w == (1 << s)); // plasma fractal noise for (k=s-1; k >= 0; --k) { int step = 1 << k; // interpolate from "parents" for (j=0; j < w; j += step*2) { for (i=0; i < w; i += step*2) { int i1 = i+step, j1=j+step; int i2 = (i+step*2)&m, j2 = (j+step*2)&m; int p00 = data[(j*w+i )*3], p01 = data[(j2*w+i )*3]; int p10 = data[(j*w+i2)*3], p11 = data[(j2*w+i2)*3]; data[(j*w+i1)*3] = (p00+p10)>>1; data[(j1*w+i)*3] = (p00+p01)>>1; data[(j1*w+i1)*3]= (p00+p01+p10+p11)>>2; } } scale = scale_table[s-k+1]; if (!scale) continue; // just interpolate down the remaining data for (j=0,i=0; i < 256; i += 2, j == scale ? j=0 : ++j) modded[i] = j, modded[i+1] = -j; // precompute i%scale (plus sign) for (j=0; j < w; j += step) for (i=0; i < w; i += step) { int x = data[(j*w+i)*3] + modded[(stbgl_rand() >> 12) & 255]; data[(j*w+i)*3] = x < 0 ? 0 : x > 255 ? 255 : x; } } for (j=0; j < w; ++j) for (i=0; i < w; ++i) { int check = ((i^j) & (1 << (s-checks_log2))) == 0; int v = data[(j*w+i)*3] >> 2; data[(j*w+i)*3+0] = rt[check]-v; data[(j*w+i)*3+1] = gt[check]-v; data[(j*w+i)*3+2] = bt[check]-v; } return stbgl_TexImage2D(0, w, w, data, "3m!"); // 3 channels, mipmap, free } #ifdef _WIN32 #ifndef WINGDIAPI typedef int (__stdcall *stbgl__voidfunc)(void); __declspec(dllimport) stbgl__voidfunc wglGetProcAddress(char *); #endif #define STB__HAS_WGLPROC static void (__stdcall *stbgl__CompressedTexImage2DARB)(int target, int level, int internalformat, int width, int height, int border, int imageSize, void *data); static void stbgl__initCompTex(void) { *((void **) &stbgl__CompressedTexImage2DARB) = (void *) wglGetProcAddress("glCompressedTexImage2DARB"); } #else static void (*stbgl__CompressedTexImage2DARB)(int target, int level, int internalformat, int width, int height, int border, int imageSize, void *data); static void stbgl__initCompTex(void) { } #endif // _WIN32 #define STBGL_COMPRESSED_RGB_S3TC_DXT1 0x83F0 #define STBGL_COMPRESSED_RGBA_S3TC_DXT1 0x83F1 #define STBGL_COMPRESSED_RGBA_S3TC_DXT3 0x83F2 #define STBGL_COMPRESSED_RGBA_S3TC_DXT5 0x83F3 #ifdef STB_COMPRESS_DXT_BLOCK static void stbgl__convert(uint8 *p, uint8 *q, int n, int input_desc, uint8 *end) { int i; switch (input_desc) { case GL_RED: case GL_LUMINANCE: for (i=0; i < n; ++i,p+=4) p[0] = p[1] = p[2] = q[0], p[3]=255, q+=1; break; case GL_ALPHA: for (i=0; i < n; ++i,p+=4) p[0] = p[1] = p[2] = 0, p[3] = q[0], q+=1; break; case GL_LUMINANCE_ALPHA: for (i=0; i < n; ++i,p+=4) p[0] = p[1] = p[2] = q[0], p[3]=q[1], q+=2; break; case GL_RGB: for (i=0; i < n; ++i,p+=4) p[0]=q[0],p[1]=q[1],p[2]=q[2],p[3]=255,q+=3; break; case GL_RGBA: memcpy(p, q, n*4); break; case GL_INTENSITY: for (i=0; i < n; ++i,p+=4) p[0] = p[1] = p[2] = p[3] = q[0], q+=1; break; } assert(p <= end); } static void stbgl__compress(uint8 *p, uint8 *rgba, int w, int h, int output_desc, uint8 *end) { int i,j,y,y2; int alpha = (output_desc == STBGL_COMPRESSED_RGBA_S3TC_DXT5); for (j=0; j < w; j += 4) { int x=4; for (i=0; i < h; i += 4) { uint8 block[16*4]; if (i+3 >= w) x = w-i; for (y=0; y < 4; ++y) { if (j+y >= h) break; memcpy(block+y*16, rgba + w*4*(j+y) + i*4, x*4); } if (x < 4) { switch (x) { case 0: assert(0); case 1: for (y2=0; y2 < y; ++y2) { memcpy(block+y2*16+1*4, block+y2*16+0*4, 4); memcpy(block+y2*16+2*4, block+y2*16+0*4, 8); } break; case 2: for (y2=0; y2 < y; ++y2) memcpy(block+y2*16+2*4, block+y2*16+0*4, 8); break; case 3: for (y2=0; y2 < y; ++y2) memcpy(block+y2*16+3*4, block+y2*16+1*4, 4); break; } } y2 = 0; for(; y<4; ++y,++y2) memcpy(block+y*16, block+y2*16, 4*4); stb_compress_dxt_block(p, block, alpha, 10); p += alpha ? 16 : 8; } } assert(p <= end); } #endif // STB_COMPRESS_DXT_BLOCK // use the reserved temporary-use enumerant range, since no // OpenGL enumerants should fall in that range enum { STBGL_UNDEFINED = 0x6000, STBGL_YCOCG, STBGL_YCOCGJ, STBGL_GEN_MIPMAPS, STBGL_MIPMAPS, STBGL_NO_DOWNLOAD, }; #define STBGL_CLAMP_TO_EDGE 0x812F #define STBGL_CLAMP_TO_BORDER 0x812D #define STBGL_DEPTH_COMPONENT16 0x81A5 #define STBGL_DEPTH_COMPONENT24 0x81A6 #define STBGL_DEPTH_COMPONENT32 0x81A7 int stbgl_TexImage2D_Extra(int texid, int w, int h, void *data, int chan, char *props, int preserve_data) { static int has_s3tc = -1; // haven't checked yet int free_data = 0, is_compressed = 0; int pad_to_power_of_two = 0, non_power_of_two = 0; int premultiply_alpha = 0; // @TODO int float_tex = 0; // @TODO int input_type = GL_UNSIGNED_BYTE; int input_desc = STBGL_UNDEFINED; int output_desc = STBGL_UNDEFINED; int mipmaps = STBGL_UNDEFINED; int filter = STBGL_UNDEFINED, mag_filter; int wrap_s = STBGL_UNDEFINED, wrap_t = STBGL_UNDEFINED; // parse out the properties if (props == NULL) props = ""; while (*props) { switch (*props) { case '1' : input_desc = GL_LUMINANCE; break; case '2' : input_desc = GL_LUMINANCE_ALPHA; break; case '3' : input_desc = GL_RGB; break; case '4' : input_desc = GL_RGBA; break; case 'l' : if (props[1] == 'a') { input_desc = GL_LUMINANCE_ALPHA; ++props; } else input_desc = GL_LUMINANCE; break; case 'a' : input_desc = GL_ALPHA; break; case 'r' : if (stbgl_m(props, "rgba")) { input_desc = GL_RGBA; props += 3; break; } if (stbgl_m(props, "rgb")) { input_desc = GL_RGB; props += 2; break; } input_desc = GL_RED; break; case 'y' : if (stbgl_m(props, "ycocg")) { if (props[5] == 'j') { props += 5; input_desc = STBGL_YCOCGJ; } else { props += 4; input_desc = STBGL_YCOCG; } break; } return 0; case 'L' : if (props[1] == 'A') { output_desc = GL_LUMINANCE_ALPHA; ++props; } else output_desc = GL_LUMINANCE; break; case 'I' : output_desc = GL_INTENSITY; break; case 'A' : output_desc = GL_ALPHA; break; case 'R' : if (stbgl_m(props, "RGBA")) { output_desc = GL_RGBA; props += 3; break; } if (stbgl_m(props, "RGB")) { output_desc = GL_RGB; props += 2; break; } output_desc = GL_RED; break; case 'Y' : if (stbgl_m(props, "YCoCg") || stbgl_m(props, "YCOCG")) { props += 4; output_desc = STBGL_YCOCG; break; } return 0; case 'D' : if (stbgl_m(props, "DXT")) { switch (props[3]) { case '1': output_desc = STBGL_COMPRESSED_RGB_S3TC_DXT1; break; case '3': output_desc = STBGL_COMPRESSED_RGBA_S3TC_DXT3; break; case '5': output_desc = STBGL_COMPRESSED_RGBA_S3TC_DXT5; break; default: return 0; } props += 3; } else if (stbgl_m(props, "D16")) { output_desc = STBGL_DEPTH_COMPONENT16; input_desc = GL_DEPTH_COMPONENT; props += 2; } else if (stbgl_m(props, "D24")) { output_desc = STBGL_DEPTH_COMPONENT24; input_desc = GL_DEPTH_COMPONENT; props += 2; } else if (stbgl_m(props, "D32")) { output_desc = STBGL_DEPTH_COMPONENT32; input_desc = GL_DEPTH_COMPONENT; props += 2; } else { output_desc = GL_DEPTH_COMPONENT; input_desc = GL_DEPTH_COMPONENT; } break; case 'N' : if (stbgl_m(props, "NONE")) { props += 3; input_desc = STBGL_NO_DOWNLOAD; output_desc = STBGL_NO_DOWNLOAD; break; } if (stbgl_m(props, "NP2")) { non_power_of_two = 1; props += 2; break; } return 0; case 'm' : mipmaps = STBGL_GEN_MIPMAPS; break; case 'M' : mipmaps = STBGL_MIPMAPS; break; case 't' : filter = GL_LINEAR_MIPMAP_LINEAR; break; case 'b' : filter = GL_LINEAR; break; case 'n' : filter = GL_NEAREST; break; case 'w' : if (wrap_s == STBGL_UNDEFINED) wrap_s = GL_REPEAT; else wrap_t = GL_REPEAT; break; case 'C' : if (wrap_s == STBGL_UNDEFINED) wrap_s = STBGL_CLAMP_TO_BORDER; else wrap_t = STBGL_CLAMP_TO_BORDER; break; case 'c' : if (wrap_s == STBGL_UNDEFINED) wrap_s = STBGL_CLAMP_TO_EDGE; else wrap_t = STBGL_CLAMP_TO_EDGE; break; case 'f' : input_type = GL_FLOAT; break; case 'F' : input_type = GL_FLOAT; float_tex = 1; break; case 'p' : premultiply_alpha = 1; break; case 'P' : pad_to_power_of_two = 1; break; case '+' : preserve_data = 0; break; case '!' : preserve_data = 0; free_data = 1; break; case ' ' : break; case '-' : break; default : if (free_data) free(data); return 0; } ++props; } // override input_desc based on channel count if (output_desc != STBGL_NO_DOWNLOAD) { switch (abs(chan)) { case 1: input_desc = GL_LUMINANCE; break; case 2: input_desc = GL_LUMINANCE_ALPHA; break; case 3: input_desc = GL_RGB; break; case 4: input_desc = GL_RGBA; break; case 0: break; default: return 0; } } // override input_desc based on channel info if (chan > 0) { input_type = GL_UNSIGNED_BYTE; } if (chan < 0) { input_type = GL_FLOAT; } if (output_desc == GL_ALPHA) { if (input_desc == GL_LUMINANCE) input_desc = GL_ALPHA; if (input_desc == GL_RGB) { // force a presumably-mono image to alpha // @TODO handle 'preserve_data' case? if (data && !preserve_data && input_type == GL_UNSIGNED_BYTE) { int i; unsigned char *p = (unsigned char *) data, *q = p; for (i=0; i < w*h; ++i) { *q = (p[0] + 2*p[1] + p[2]) >> 2; p += 3; q += 1; } input_desc = GL_ALPHA; } } } // set undefined input/output based on the other if (input_desc == STBGL_UNDEFINED && output_desc == STBGL_UNDEFINED) { input_desc = output_desc = GL_RGBA; } else if (output_desc == STBGL_UNDEFINED) { switch (input_desc) { case GL_LUMINANCE: case GL_ALPHA: case GL_LUMINANCE_ALPHA: case GL_RGB: case GL_RGBA: output_desc = input_desc; break; case GL_RED: output_desc = GL_INTENSITY; break; case STBGL_YCOCG: case STBGL_YCOCGJ: output_desc = STBGL_YCOCG; break; default: assert(0); return 0; } } else if (input_desc == STBGL_UNDEFINED) { switch (output_desc) { case GL_LUMINANCE: case GL_ALPHA: case GL_LUMINANCE_ALPHA: case GL_RGB: case GL_RGBA: input_desc = output_desc; break; case GL_INTENSITY: input_desc = GL_RED; break; case STBGL_YCOCG: case STBGL_COMPRESSED_RGB_S3TC_DXT1: case STBGL_COMPRESSED_RGBA_S3TC_DXT3: case STBGL_COMPRESSED_RGBA_S3TC_DXT5: input_desc = GL_RGBA; break; } } else { if (output_desc == STBGL_COMPRESSED_RGB_S3TC_DXT1) { // if input has alpha, force output alpha switch (input_desc) { case GL_ALPHA: case GL_LUMINANCE_ALPHA: case GL_RGBA: output_desc = STBGL_COMPRESSED_RGBA_S3TC_DXT5; break; } } } switch(input_desc) { case GL_LUMINANCE: case GL_RED: case GL_ALPHA: chan = 1; break; case GL_LUMINANCE_ALPHA: chan = 2; break; case GL_RGB: chan = 3; break; case GL_RGBA: chan = 4; break; } if (pad_to_power_of_two && ((w & (w-1)) || (h & (h-1)))) { if (output_desc != STBGL_NO_DOWNLOAD && input_type == GL_UNSIGNED_BYTE && chan > 0) { unsigned char *new_data; int w2 = w, h2 = h, j; while (w & (w-1)) w = (w | (w>>1))+1; while (h & (h-1)) h = (h | (h>>1))+1; new_data = malloc(w * h * chan); for (j=0; j < h2; ++j) { memcpy(new_data + j * w * chan, (char *) data+j*w2*chan, w2*chan); memset(new_data + (j * w+w2) * chan, 0, (w-w2)*chan); } for (; j < h; ++j) memset(new_data + j*w*chan, 0, w*chan); if (free_data) free(data); data = new_data; free_data = 1; } } switch (output_desc) { case STBGL_COMPRESSED_RGB_S3TC_DXT1: case STBGL_COMPRESSED_RGBA_S3TC_DXT1: case STBGL_COMPRESSED_RGBA_S3TC_DXT3: case STBGL_COMPRESSED_RGBA_S3TC_DXT5: is_compressed = 1; if (has_s3tc == -1) { has_s3tc = stbgl_hasExtension("GL_EXT_texture_compression_s3tc"); if (has_s3tc) stbgl__initCompTex(); } if (!has_s3tc) { is_compressed = 0; if (output_desc == STBGL_COMPRESSED_RGB_S3TC_DXT1) output_desc = GL_RGB; else output_desc = GL_RGBA; } } if (output_desc == STBGL_YCOCG) { assert(0); output_desc = GL_RGB; // @TODO! if (free_data) free(data); return 0; } mag_filter = 0; if (mipmaps != STBGL_UNDEFINED) { switch (filter) { case STBGL_UNDEFINED: filter = GL_LINEAR_MIPMAP_LINEAR; break; case GL_NEAREST : mag_filter = GL_NEAREST; filter = GL_LINEAR_MIPMAP_LINEAR; break; case GL_LINEAR : filter = GL_LINEAR_MIPMAP_NEAREST; break; } } else { if (filter == STBGL_UNDEFINED) filter = GL_LINEAR; } // update filtering if (!mag_filter) { if (filter == GL_NEAREST) mag_filter = GL_NEAREST; else mag_filter = GL_LINEAR; } // update wrap/clamp if (wrap_s == STBGL_UNDEFINED) wrap_s = GL_REPEAT; if (wrap_t == STBGL_UNDEFINED) wrap_t = wrap_s; // if no texture id, generate one if (texid == 0) { GLuint tex; glGenTextures(1, &tex); if (tex == 0) { if (free_data) free(data); return 0; } texid = tex; } if (data == NULL && mipmaps == STBGL_GEN_MIPMAPS) mipmaps = STBGL_MIPMAPS; if (output_desc == STBGL_NO_DOWNLOAD) mipmaps = STBGL_NO_DOWNLOAD; glBindTexture(GL_TEXTURE_2D, texid); #ifdef STB_COMPRESS_DXT_BLOCK if (!is_compressed || !stbgl__CompressedTexImage2DARB || output_desc == STBGL_COMPRESSED_RGBA_S3TC_DXT3 || data == NULL) #endif { switch (mipmaps) { case STBGL_NO_DOWNLOAD: break; case STBGL_UNDEFINED: // check if actually power-of-two if (non_power_of_two || ((w & (w-1)) == 0 && (h & (h-1)) == 0)) glTexImage2D(GL_TEXTURE_2D, 0, output_desc, w, h, 0, input_desc, input_type, data); else gluBuild2DMipmaps(GL_TEXTURE_2D, output_desc, w, h, input_desc, input_type, data); // not power of two, so use glu to resize (generates mipmaps needlessly) break; case STBGL_MIPMAPS: { int level = 0; int size = input_type == GL_FLOAT ? sizeof(float) : 1; if (data == NULL) size = 0; // reuse same block of memory for all mipmaps assert((w & (w-1)) == 0 && (h & (h-1)) == 0); // verify power-of-two while (w > 1 && h > 1) { glTexImage2D(GL_TEXTURE_2D, level, output_desc, w, h, 0, input_desc, input_type, data); data = (void *) ((char *) data + w * h * size * chan); if (w > 1) w >>= 1; if (h > 1) h >>= 1; ++level; } break; } case STBGL_GEN_MIPMAPS: gluBuild2DMipmaps(GL_TEXTURE_2D, output_desc, w, h, input_desc, input_type, data); break; default: assert(0); if (free_data) free(data); return 0; } #ifdef STB_COMPRESS_DXT_BLOCK } else { uint8 *out, *rgba=0, *end_out, *end_rgba; int level = 0, alpha = (output_desc != STBGL_COMPRESSED_RGB_S3TC_DXT1); int size = input_type == GL_FLOAT ? sizeof(float) : 1; int osize = alpha ? 16 : 8; if (!free_data && mipmaps == STBGL_GEN_MIPMAPS) { uint8 *temp = malloc(w*h*chan); if (!temp) { if (free_data) free(data); return 0; } memcpy(temp, data, w*h*chan); if (free_data) free(data); free_data = 1; data = temp; } if (chan != 4 || size != 1) { rgba = malloc(w*h*4); if (!rgba) return 0; end_rgba = rgba+w*h*4; } out = malloc((w+3)*(h+3)/16*osize); // enough storage for the s3tc data if (!out) return 0; end_out = out + ((w+3)*(h+3))/16*osize; for(;;) { if (chan != 4) stbgl__convert(rgba, data, w*h, input_desc, end_rgba); stbgl__compress(out, rgba ? rgba : data, w, h, output_desc, end_out); stbgl__CompressedTexImage2DARB(GL_TEXTURE_2D, level, output_desc, w, h, 0, ((w+3)&~3)*((h+3)&~3)/16*osize, out); //glTexImage2D(GL_TEXTURE_2D, level, alpha?GL_RGBA:GL_RGB, w, h, 0, GL_RGBA, GL_UNSIGNED_BYTE, rgba ? rgba : data); if (mipmaps == STBGL_UNDEFINED) break; if (w <= 1 && h <= 1) break; if (mipmaps == STBGL_MIPMAPS) data = (void *) ((char *) data + w * h * size * chan); if (mipmaps == STBGL_GEN_MIPMAPS) { int w2 = w>>1, h2=h>>1, i,j,k, s=w*chan; uint8 *p = data, *q=data; if (w == 1) { for (j=0; j < h2; ++j) { for (k=0; k < chan; ++k) *p++ = (q[k] + q[s+k] + 1) >> 1; q += s*2; } } else if (h == 1) { for (i=0; i < w2; ++i) { for (k=0; k < chan; ++k) *p++ = (q[k] + q[k+chan] + 1) >> 1; q += chan*2; } } else { for (j=0; j < h2; ++j) { for (i=0; i < w2; ++i) { for (k=0; k < chan; ++k) *p++ = (q[k] + q[k+chan] + q[s+k] + q[s+k+chan] + 2) >> 2; q += chan*2; } q += s; } } } if (w > 1) w >>= 1; if (h > 1) h >>= 1; ++level; } if (out) free(out); if (rgba) free(rgba); #endif // STB_COMPRESS_DXT_BLOCK } glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, wrap_s); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, wrap_t); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, mag_filter); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, filter); if (free_data) free(data); return texid; } #endif // STB_DEFINE #undef STB_EXTERN #endif //INCLUDE_STB_GL_H // Extension handling... must be outside the INCLUDE_ brackets #if defined(STB_GLEXT_DEFINE) || defined(STB_GLEXT_DECLARE) #ifndef STB_GLEXT_SKIP_DURING_RECURSION #ifndef GL_GLEXT_VERSION // First check if glext.h is concatenated on the end of this file // (if it's concatenated on the beginning, we'll have GL_GLEXT_VERSION) #define STB_GLEXT_SKIP_DURING_RECURSION #include __FILE__ #undef STB_GLEXT_SKIP_DURING_RECURSION // now check if it's still undefined; if so, try going for it by name; // if this errors, that's fine, since we can't compile without it #ifndef GL_GLEXT_VERSION #include "glext.h" #endif #endif #define GLARB(a,b) GLE(a##ARB,b##ARB) #define GLEXT(a,b) GLE(a##EXT,b##EXT) #define GLNV(a,b) GLE(a##NV ,b##NV) #define GLATI(a,b) GLE(a##ATI,b##ATI) #define GLCORE(a,b) GLE(a,b) #ifdef STB_GLEXT_DEFINE_DECLARE #define STB_GLEXT_DEFINE STB_GLEXT_DECLARE #endif #if defined(STB_GLEXT_DECLARE) && defined(STB_GLEXT_DEFINE) #undef STB_GLEXT_DECLARE #endif #if defined(STB_GLEXT_DECLARE) && !defined(STB_GLEXT_DEFINE) #define GLE(a,b) extern PFNGL##b##PROC gl##a; #ifdef __cplusplus extern "C" { #endif extern void stbgl_initExtensions(void); #include STB_GLEXT_DECLARE #ifdef __cplusplus }; #endif #else #ifndef STB_GLEXT_DEFINE #error "Header file is screwed up somehow" #endif #ifdef _WIN32 #ifndef WINGDIAPI #ifndef STB__HAS_WGLPROC typedef int (__stdcall *stbgl__voidfunc)(void); __declspec(dllimport) stbgl__voidfunc wglGetProcAddress(char *); #endif #endif #define STBGL__GET_FUNC(x) wglGetProcAddress(x) #endif #ifdef GLE #undef GLE #endif #define GLE(a,b) PFNGL##b##PROC gl##a; #include STB_GLEXT_DEFINE #undef GLE #define GLE(a,b) gl##a = (PFNGL##b##PROC) STBGL__GET_FUNC("gl" #a ); void stbgl_initExtensions(void) { #include STB_GLEXT_DEFINE } #undef GLE #endif // STB_GLEXT_DECLARE #endif // STB_GLEXT_SKIP #endif // STB_GLEXT_DEFINE || STB_GLEXT_DECLARE