/************************************************************************************************** "POLYMOST" code written by Ken Silverman Ken Silverman's official web site: http://www.advsys.net/ken Motivation: When 3D Realms released the Duke Nukem 3D source code, I thought somebody would do a OpenGL or Direct3D port. Well, after a few months passed, I saw no sign of somebody working on a true hardware-accelerated port of Build, just people saying it wasn't possible. Eventually, I realized the only way this was going to happen was for me to do it myself. First, I needed to port Build to Windows. I could have done it myself, but instead I thought I'd ask my Australian buddy, Jonathon Fowler, if he would upgrade his Windows port to my favorite compiler (MSVC) - which he did. Once that was done, I was ready to start the "POLYMOST" project. About: This source file is basically a complete rewrite of the entire rendering part of the Build engine. There are small pieces in ENGINE.C to activate this code, and other minor hacks in other source files, but most of it is in here. If you're looking for polymost-related code in the other source files, you should find most of them by searching for either "polymost" or "rendmode". Speaking of rendmode, there are now 4 rendering modes in Build: rendmode 0: The original code I wrote from 1993-1997 rendmode 1: Solid-color rendering: my debug code before I did texture mapping rendmode 2: Software rendering before I started the OpenGL code (Note: this is just a quick hack to make testing easier - it's not optimized to my usual standards!) rendmode 3: The OpenGL code The original Build engine did hidden surface removal by using a vertical span buffer on the tops and bottoms of walls. This worked nice back in the day, but it it's not suitable for a polygon engine. So I decided to write a brand new hidden surface removal algorithm - using the same idea as the original Build - but one that worked with vectors instead of already rasterized data. Brief history: 06/20/2000: I release Build Source code 04/01/2003: 3D Realms releases Duke Nukem 3D source code 10/04/2003: Jonathon Fowler gets his Windows port working in Visual C 10/04/2003: I start writing POLYMOST.BAS, a new hidden surface removal algorithm for Build that works on a polygon level instead of spans. 10/16/2003: Ported POLYMOST.BAS to C inside JonoF KenBuild's ENGINE.C; later this code was split out of ENGINE.C and put in this file, POLYMOST.C. 12/10/2003: Started OpenGL code for POLYMOST (rendmode 3) 12/23/2003: 1st public release 01/01/2004: 2nd public release: fixed stray lines, status bar, mirrors, sky, and lots of other bugs. ---------------------------------------------------------------------------------------------------- Todo list (in approximate chronological order): High priority: * BOTH: Do accurate software sorting/chopping for sprites: drawing in wrong order is bad :/ * BOTH: Fix hall of mirrors near "zenith". Call polymost_drawrooms twice? * OPENGL: drawmapview() Low priority: * SOFT6D: Do back-face culling of sprites during up/down/tilt transformation (top of drawpoly) * SOFT6D: Fix depth shading: use saturation&LUT * SOFT6D: Optimize using hyperbolic mapping (similar to KUBE algo) * SOFT6D: Slab6-style voxel sprites. How to accelerate? :/ * OPENGL: KENBUILD: Write flipping code for floor mirrors * BOTH: KENBUILD: Parallaxing sky modes 1&2 * BOTH: Masked/1-way walls don't clip correctly to sectors of intersecting ceiling/floor slopes * BOTH: Editart x-center is not working correctly with Duke's camera/turret sprites * BOTH: Get rid of horizontal line above Duke full-screen status bar * BOTH: Combine ceilings/floors into a single triangle strip (should lower poly count by 2x) * BOTH: Optimize/clean up texture-map setup equations **************************************************************************************************/ #ifdef USE_OPENGL #include "compat.h" #include "build.h" #ifdef USE_OPENGL # include "glbuild.h" # include "mdsprite.h" #endif #include "pragmas.h" #include "baselayer.h" #include "osd.h" #include "engine_priv.h" #include "hightile.h" #include "polymost.h" #include "polymer.h" #include "scriptfile.h" #include "cache1d.h" #include "kplib.h" #ifndef _WIN32 extern int32_t filelength(int h); // kplib.c #endif extern char textfont[2048], smalltextfont[2048]; int32_t rendmode=0; int32_t usemodels=1, usehightile=1; #include //<-important! typedef struct { float x, cy[2], fy[2]; int32_t tag; int16_t n, p, ctag, ftag; } vsptyp; #define VSPMAX 4096 //<- careful! static vsptyp vsp[VSPMAX]; static int32_t gtag; static double dxb1[MAXWALLSB], dxb2[MAXWALLSB]; #define SCISDIST 1.0 //1.0: Close plane clipping distance // the following three are for the obsolete rendmodes 1 and 2: #define USEZBUFFER 1 //1:use zbuffer (slow, nice sprite rendering), 0:no zbuffer (fast, bad sprite rendering) #define LINTERPSIZ 4 //log2 of interpolation size. 4:pretty fast&acceptable quality, 0:best quality/slow! #define DEPTHDEBUG 0 //1:render distance instead of texture, for debugging only!, 0:default float shadescale = 1.0f; int32_t shadescale_unbounded = 0; int32_t r_usenewshading = 2; static double gviewxrange, ghoriz; double gyxscale, gxyaspect, ghalfx, grhalfxdown10, grhalfxdown10x; double gcosang, gsinang, gcosang2, gsinang2; double gchang, gshang, gctang, gstang, gvisibility; float gtang = 0.0; double guo, gux, guy; //Screen-based texture mapping parameters double gvo, gvx, gvy; double gdo, gdx, gdy; static int32_t preview_mouseaim=0; // when 1, displays a CROSSHAIR tsprite at the _real_ aimed position #ifdef USE_OPENGL static int32_t srepeat = 0, trepeat = 0; int32_t glredbluemode = 0; static int32_t lastglredbluemode = 0, redblueclearcnt = 0; struct glfiltermodes glfiltermodes[NUMGLFILTERMODES] = { {"GL_NEAREST",GL_NEAREST,GL_NEAREST}, {"GL_LINEAR",GL_LINEAR,GL_LINEAR}, {"GL_NEAREST_MIPMAP_NEAREST",GL_NEAREST_MIPMAP_NEAREST,GL_NEAREST}, {"GL_LINEAR_MIPMAP_NEAREST",GL_LINEAR_MIPMAP_NEAREST,GL_LINEAR}, {"GL_NEAREST_MIPMAP_LINEAR",GL_NEAREST_MIPMAP_LINEAR,GL_NEAREST}, {"GL_LINEAR_MIPMAP_LINEAR",GL_LINEAR_MIPMAP_LINEAR,GL_LINEAR} }; int32_t glanisotropy = 1; // 0 = maximum supported by card int32_t glusetexcompr = 1; int32_t gltexfiltermode = 2; // GL_NEAREST_MIPMAP_NEAREST int32_t glusetexcache = 2, glusememcache = 1; int32_t glmultisample = 0, glnvmultisamplehint = 0; int32_t gltexmaxsize = 0; // 0 means autodetection on first run int32_t gltexmiplevel = 0; // discards this many mipmap levels static int32_t lastglpolygonmode = 0; //FUK int32_t glpolygonmode = 0; // 0:GL_FILL,1:GL_LINE,2:GL_POINT //FUK int32_t glwidescreen = 0; int32_t glprojectionhacks = 1; static GLuint polymosttext = 0; int32_t glrendmode = 3; // This variable, and 'shadeforfullbrightpass' control the drawing of // fullbright tiles. Also see 'fullbrightloadingpass'. static int32_t fullbrightdrawingpass = 0; float curpolygonoffset; // internal polygon offset stack for drawing flat sprites to avoid depth fighting // Detail mapping cvar int32_t r_detailmapping = 1; // Glow mapping cvar int32_t r_glowmapping = 1; // Vertex Array model drawing cvar int32_t r_vertexarrays = 1; // Vertex Buffer Objects model drawing cvars int32_t r_vbos = 1; int32_t r_vbocount = 64; // model animation smoothing cvar int32_t r_animsmoothing = 1; // line of sight checks before mddraw() int32_t r_modelocclusionchecking = 0; // fullbright cvar int32_t r_fullbrights = 1; // texture downsizing int32_t r_downsize = 0; int32_t r_downsizevar = -1; // used for fogcalc float fogresult, fogresult2, fogcol[4], fogtable[4*MAXPALOOKUPS]; #endif static char ptempbuf[MAXWALLSB<<1]; // polymost ART sky control int32_t r_parallaxskyclamping = 1; int32_t r_parallaxskypanning = 0; #define MIN_CACHETIME_PRINT 10 static inline int32_t imod(int32_t a, int32_t b) { if (a >= 0) return(a%b); return(((a+1)%b)+b-1); } void drawline2d(float x0, float y0, float x1, float y1, char col) { float f, dx, dy, fxres, fyres; int32_t e, inc, x, y; uint32_t up16; dx = x1-x0; dy = y1-y0; if ((dx == 0) && (dy == 0)) return; fxres = (float)xdimen; fyres = (float)ydimen; if (x0 >= fxres) { if (x1 >= fxres) return; y0 += (fxres-x0)*dy/dx; x0 = fxres; } else if (x0 < 0) { if (x1 < 0) return; y0 += (0-x0)*dy/dx; x0 = 0; } if (x1 >= fxres) { y1 += (fxres-x1)*dy/dx; x1 = fxres; } else if (x1 < 0) { y1 += (0-x1)*dy/dx; x1 = 0; } if (y0 >= fyres) { if (y1 >= fyres) return; x0 += (fyres-y0)*dx/dy; y0 = fyres; } else if (y0 < 0) { if (y1 < 0) return; x0 += (0-y0)*dx/dy; y0 = 0; } if (y1 >= fyres) { x1 += (fyres-y1)*dx/dy; y1 = fyres; } else if (y1 < 0) { x1 += (0-y1)*dx/dy; y1 = 0; } if (fabs(dx) > fabs(dy)) { if (x0 > x1) { f = x0; x0 = x1; x1 = f; f = y0; y0 = y1; y1 = f; } y = (int32_t)(y0*65536.f)+32768; inc = (int32_t)(dy/dx*65536.f+.5f); x = (int32_t)(x0+.5); if (x < 0) { y -= inc*x; x = 0; } //if for safety e = (int32_t)(x1+.5); if (e > xdimen) e = xdimen; //if for safety up16 = (ydimen<<16); for (; x>16]+x+frameoffset) = col; } else { if (y0 > y1) { f = x0; x0 = x1; x1 = f; f = y0; y0 = y1; y1 = f; } x = (int32_t)(x0*65536.f)+32768; inc = (int32_t)(dx/dy*65536.f+.5f); y = (int32_t)(y0+.5); if (y < 0) { x -= inc*y; y = 0; } //if for safety e = (int32_t)(y1+.5); if (e > ydimen) e = ydimen; //if for safety up16 = (xdimen<<16); for (; y>16)+frameoffset) = col; } } #ifdef USE_OPENGL #include "md4.h" #include "quicklz.h" //-------------------------------------------------------------------------------------------------- //TEXTURE MANAGEMENT: treats same texture with different .PAL as a separate texture. This makes the // max number of virtual textures very large (MAXTILES*256). Instead of allocating a handle for // every virtual texture, I use a cache where indexing is managed through a hash table. // static int32_t cachefilehandle = -1; // texture cache file handle static FILE *cacheindexptr = NULL; static uint8_t *memcachedata = NULL; static int32_t memcachesize = -1; int32_t cachepos = 0; // Set to 1 when we failed (re)allocating space for the memcache or failing to // read into it (which would presumably generate followup errors spamming the // log otherwise): static int32_t dont_alloc_memcache = 0; static hashtable_t h_texcache = { 1024, NULL }; char TEXCACHEFILE[BMAX_PATH] = "textures"; int32_t mdtims, omdtims; float alphahackarray[MAXTILES]; static texcacheindex *firstcacheindex = NULL; static texcacheindex *curcacheindex = NULL; static texcacheindex *cacheptrs[MAXTILES<<1]; static int32_t numcacheentries = 0; #define GLTEXCACHEADSIZ 8192 static pthtyp *gltexcachead[GLTEXCACHEADSIZ]; int32_t drawingskybox = 0; static int32_t gloadtile_art(int32_t,int32_t,int32_t,pthtyp *,int32_t); static int32_t gloadtile_hi(int32_t,int32_t,int32_t,hicreplctyp *,int32_t,pthtyp *,int32_t,char); static int32_t hicprecaching = 0; pthtyp *gltexcache(int32_t dapicnum, int32_t dapalnum, int32_t dameth) { int32_t i, j; hicreplctyp *si; pthtyp *pth, *pth2; j = (dapicnum&(GLTEXCACHEADSIZ-1)); si = usehightile ? hicfindsubst(dapicnum,dapalnum,drawingskybox) : NULL; if (!si) { if (drawingskybox || dapalnum >= (MAXPALOOKUPS - RESERVEDPALS)) return NULL; goto tryart; } /* if palette > 0 && replacement found * no effects are applied to the texture * else if palette > 0 && no replacement found * effects are applied to the palette 0 texture if it exists */ // load a replacement for (pth=gltexcachead[j]; pth; pth=pth->next) { if (pth->picnum == dapicnum && pth->palnum == si->palnum && (si->palnum>0 ? 1 : (pth->effects == hictinting[dapalnum].f)) && (pth->flags & (1+2+4)) == (((dameth&4)>>2)+2+((drawingskybox>0)<<2)) && (drawingskybox>0 ? (pth->skyface == drawingskybox) : 1) ) { if (pth->flags & 128) { pth->flags &= ~128; if (gloadtile_hi(dapicnum,dapalnum,drawingskybox,si,dameth,pth,0, (si->palnum>0) ? 0 : hictinting[dapalnum].f)) // reload tile { if (drawingskybox) return NULL; goto tryart; // failed, so try for ART } } return(pth); } } pth = (pthtyp *)Bcalloc(1,sizeof(pthtyp)); if (!pth) return NULL; // possibly fetch an already loaded multitexture :_) if (dapalnum >= (MAXPALOOKUPS - RESERVEDPALS)) for (i = (GLTEXCACHEADSIZ - 1); i >= 0; i--) for (pth2=gltexcachead[i]; pth2; pth2=pth2->next) { if ((pth2->hicr) && (pth2->hicr->filename) && (Bstrcasecmp(pth2->hicr->filename, si->filename) == 0)) { Bmemcpy(pth, pth2, sizeof(pthtyp)); pth->picnum = dapicnum; pth->flags = ((dameth&4)>>2) + 2 + ((drawingskybox>0)<<2); if (pth2->flags & 8) pth->flags |= 8; //hasalpha pth->hicr = si; pth->next = gltexcachead[j]; gltexcachead[j] = pth; return(pth); } } if (gloadtile_hi(dapicnum,dapalnum,drawingskybox,si,dameth,pth,1, (si->palnum>0) ? 0 : hictinting[dapalnum].f)) { Bfree(pth); if (drawingskybox) return NULL; goto tryart; // failed, so try for ART } pth->palnum = si->palnum; pth->next = gltexcachead[j]; gltexcachead[j] = pth; return(pth); tryart: if (hicprecaching) return NULL; // load from art for (pth=gltexcachead[j]; pth; pth=pth->next) if (pth->picnum == dapicnum && pth->palnum == dapalnum && (pth->flags & (1+2)) == ((dameth&4)>>2) ) { if (pth->flags & 128) { pth->flags &= ~128; if (gloadtile_art(dapicnum,dapalnum,dameth,pth,0)) return NULL; //reload tile (for animations) } return(pth); } pth = (pthtyp *)Bcalloc(1,sizeof(pthtyp)); if (!pth) return NULL; if (gloadtile_art(dapicnum,dapalnum,dameth,pth,1)) { Bfree(pth); return NULL; } pth->next = gltexcachead[j]; gltexcachead[j] = pth; return(pth); } static inline int32_t gltexmayhavealpha(int32_t dapicnum, int32_t dapalnum) { const int32_t j = (dapicnum&(GLTEXCACHEADSIZ-1)); pthtyp *pth; for (pth=gltexcachead[j]; pth; pth=pth->next) if (pth->picnum == dapicnum && pth->palnum == dapalnum) return ((pth->flags&8) != 0); return 1; } void gltexinvalidate(int32_t dapicnum, int32_t dapalnum, int32_t dameth) { const int32_t j = (dapicnum&(GLTEXCACHEADSIZ-1)); pthtyp *pth; for (pth=gltexcachead[j]; pth; pth=pth->next) if (pth->picnum == dapicnum && pth->palnum == dapalnum && (pth->flags & 1) == ((dameth&4)>>2)) { pth->flags |= 128; if (pth->flags & 16) pth->ofb->flags |= 128; } } //Make all textures "dirty" so they reload, but not re-allocate //This should be much faster than polymost_glreset() //Use this for palette effects ... but not ones that change every frame! void gltexinvalidateall() { int32_t j; pthtyp *pth; for (j=GLTEXCACHEADSIZ-1; j>=0; j--) for (pth=gltexcachead[j]; pth; pth=pth->next) { pth->flags |= 128; if (pth->flags & 16) pth->ofb->flags |= 128; } clearskins(); #ifdef DEBUGGINGAIDS OSD_Printf("gltexinvalidateall()\n"); #endif } void gltexinvalidate8() { int32_t j; pthtyp *pth; for (j=GLTEXCACHEADSIZ-1; j>=0; j--) for (pth=gltexcachead[j]; pth; pth=pth->next) { if (pth->hicr == NULL) { pth->flags |= 128; if (pth->flags & 16) pth->ofb->flags |= 128; } } #ifdef DEBUGGINGAIDS OSD_Printf("gltexinvalidate8()\n"); #endif } static void bind_2d_texture(GLuint texture) { bglBindTexture(GL_TEXTURE_2D, texture); bglTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, glfiltermodes[gltexfiltermode].mag); bglTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, glfiltermodes[gltexfiltermode].min); if (glinfo.maxanisotropy > 1.0) bglTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAX_ANISOTROPY_EXT, glanisotropy); } void gltexapplyprops(void) { int32_t i; pthtyp *pth; if (rendmode == REND_CLASSIC) return; if (glinfo.maxanisotropy > 1.0) { if (glanisotropy <= 0 || glanisotropy > glinfo.maxanisotropy) glanisotropy = (int32_t)glinfo.maxanisotropy; } gltexfiltermode = clamp(gltexfiltermode, 0, NUMGLFILTERMODES-1); for (i=GLTEXCACHEADSIZ-1; i>=0; i--) { for (pth=gltexcachead[i]; pth; pth=pth->next) { bind_2d_texture(pth->glpic); if (r_fullbrights && pth->flags & 16) bind_2d_texture(pth->ofb->glpic); } } { int32_t j; mdskinmap_t *sk; md2model_t *m; for (i=0; imdnum < 2) continue; for (j=0; jnumskins*(HICEFFECTMASK+1); j++) { if (!m->texid[j]) continue; bind_2d_texture(m->texid[j]); } for (sk=m->skinmap; sk; sk=sk->next) for (j=0; j<(HICEFFECTMASK+1); j++) { if (!sk->texid[j]) continue; bind_2d_texture(sk->texid[j]); } } } } //-------------------------------------------------------------------------------------------------- static int32_t LoadCacheOffsets(void); float glox1, gloy1, glox2, gloy2; //Use this for both initialization and uninitialization of OpenGL. static int32_t gltexcacnum = -1; extern void freevbos(void); static void Cachefile_CloseBoth(void) { if (cachefilehandle != -1) { Bclose(cachefilehandle); cachefilehandle = -1; } if (cacheindexptr) { Bfclose(cacheindexptr); cacheindexptr = NULL; } } static void Cachefile_Free(void) { int32_t i; for (i = numcacheentries-1; i >= 0; i--) if (cacheptrs[i]) { int32_t ii; for (ii = numcacheentries-1; ii >= 0; ii--) if (i != ii && cacheptrs[ii] == cacheptrs[i]) { /*OSD_Printf("removing duplicate cacheptr %d\n",ii);*/ cacheptrs[ii] = NULL; } Bfree(cacheptrs[i]); cacheptrs[i] = NULL; } } static void clear_memcache(void) { Bfree(memcachedata); memcachedata = NULL; memcachesize = -1; } static void polymost_cachesync(void) { if (memcachedata && cachefilehandle != -1 && filelength(cachefilehandle) > memcachesize) { size_t len = filelength(cachefilehandle); memcachedata = (uint8_t *)Brealloc(memcachedata, len); if (!memcachedata) { clear_memcache(); initprintf("Failed syncing memcache to texcache, disabling memcache.\n"); dont_alloc_memcache = 1; } else { initprintf("Syncing memcache to texcache\n"); Blseek(cachefilehandle, memcachesize, BSEEK_SET); if (Bread(cachefilehandle, memcachedata + memcachesize, len - memcachesize) != (bssize_t)(len-memcachesize)) { initprintf("polymost_cachesync: Failed reading texcache into memcache!\n"); clear_memcache(); dont_alloc_memcache = 1; } else { memcachesize = len; } } } } void polymost_glreset() { int32_t i; pthtyp *pth, *next; for (i=MAXPALOOKUPS-1; i>=0; i--) { fogtable[i<<2] = palookupfog[i].r / 63.f; fogtable[(i<<2)+1] = palookupfog[i].g / 63.f; fogtable[(i<<2)+2] = palookupfog[i].b / 63.f; fogtable[(i<<2)+3] = 0; } //Reset if this is -1 (meaning 1st texture call ever), or > 0 (textures in memory) if (gltexcacnum < 0) { gltexcacnum = 0; //Hack for polymost_dorotatesprite calls before 1st polymost_drawrooms() gcosang = gcosang2 = ((double)16384)/262144.0; gsinang = gsinang2 = ((double) 0)/262144.0; } else { for (i=GLTEXCACHEADSIZ-1; i>=0; i--) { for (pth=gltexcachead[i]; pth;) { next = pth->next; if (pth->flags & 16) // fullbright textures { bglDeleteTextures(1,&pth->ofb->glpic); Bfree(pth->ofb); } bglDeleteTextures(1,&pth->glpic); Bfree(pth); pth = next; } gltexcachead[i] = NULL; } clearskins(); } if (polymosttext) bglDeleteTextures(1,&polymosttext); polymosttext=0; freevbos(); memset(gltexcachead,0,sizeof(gltexcachead)); glox1 = -1; Cachefile_Free(); polymost_cachesync(); #ifdef DEBUGGINGAIDS OSD_Printf("polymost_glreset()\n"); #endif } static void clear_cache_internal(void) { Cachefile_CloseBoth(); clear_memcache(); Cachefile_Free(); curcacheindex = firstcacheindex = (texcacheindex *)Bcalloc(1, sizeof(texcacheindex)); numcacheentries = 0; // Bmemset(&firstcacheindex, 0, sizeof(texcacheindex)); // Bmemset(&cacheptrs[0], 0, sizeof(cacheptrs)); hash_init(&h_texcache); } // one-time initialization of OpenGL for polymost void polymost_glinit() { int32_t i; if (!Bstrcmp(glinfo.vendor, "NVIDIA Corporation")) bglHint(GL_FOG_HINT, GL_NICEST); else bglHint(GL_FOG_HINT, GL_DONT_CARE); bglFogi(GL_FOG_MODE, GL_EXP2); bglBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA); bglPixelStorei(GL_PACK_ALIGNMENT, 1); bglPixelStorei(GL_UNPACK_ALIGNMENT, 1); //bglHint(GL_LINE_SMOOTH_HINT, GL_NICEST); //bglEnable(GL_LINE_SMOOTH); if (glmultisample > 0 && glinfo.multisample) { if (glinfo.nvmultisamplehint) bglHint(GL_MULTISAMPLE_FILTER_HINT_NV, glnvmultisamplehint ? GL_NICEST:GL_FASTEST); bglEnable(GL_MULTISAMPLE_ARB); } if (r_detailmapping && (!glinfo.multitex || !glinfo.envcombine)) { OSD_Printf("Your OpenGL implementation doesn't support detail mapping. Disabling...\n"); r_detailmapping = 0; } if (r_glowmapping && (!glinfo.multitex || !glinfo.envcombine)) { OSD_Printf("Your OpenGL implementation doesn't support glow mapping. Disabling...\n"); r_glowmapping = 0; } if (r_vbos && (!glinfo.vbos)) { OSD_Printf("Your OpenGL implementation doesn't support Vertex Buffer Objects. Disabling...\n"); r_vbos = 0; } bglEnableClientState(GL_VERTEX_ARRAY); bglEnableClientState(GL_TEXTURE_COORD_ARRAY); clear_cache_internal(); LoadCacheOffsets(); Bstrcpy(ptempbuf,TEXCACHEFILE); Bstrcat(ptempbuf,".cache"); cacheindexptr = Bfopen(ptempbuf, "at+"); if (!cacheindexptr) { glusetexcache = 0; initprintf("Unable to open cache index \"%s\": %s\n", ptempbuf, strerror(errno)); return; } fseek(cacheindexptr, 0, BSEEK_END); if (!ftell(cacheindexptr)) { rewind(cacheindexptr); Bfprintf(cacheindexptr,"// automatically generated by EDuke32, DO NOT MODIFY!\n"); } else rewind(cacheindexptr); cachefilehandle = Bopen(TEXCACHEFILE, BO_BINARY|BO_CREAT|BO_APPEND|BO_RDWR, BS_IREAD|BS_IWRITE); if (cachefilehandle < 0) { initprintf("Unable to open cache file \"%s\": %s\n", TEXCACHEFILE, strerror(errno)); glusetexcache = 0; return; } initprintf("Opened \"%s\" as cache file\n", TEXCACHEFILE); if (glusememcache && !dont_alloc_memcache) { memcachesize = filelength(cachefilehandle); if (memcachesize > 0) { memcachedata = (uint8_t *)Brealloc(memcachedata, memcachesize); if (!memcachedata) { initprintf("Failed allocating %d bytes for memcache, disabling memcache.\n", memcachesize); clear_memcache(); dont_alloc_memcache = 1; } else { if (Bread(cachefilehandle, memcachedata, memcachesize) != memcachesize) { initprintf("Failed reading texcache into memcache!\n"); clear_memcache(); dont_alloc_memcache = 1; } } } } i = 0; curcacheindex = firstcacheindex; while (curcacheindex->next) { i += curcacheindex->len; curcacheindex = curcacheindex->next; } i = Blseek(cachefilehandle, 0, BSEEK_END)-i; if (i) initprintf("Cache contains %d bytes of garbage data\n",i); // Blseek(cachefilehandle, 0, BSEEK_SET); } ////////// VISIBILITY FOG ROUTINES ////////// extern char nofog; // in windows/SDL layers // For GL_LINEAR fog: #define FOGDISTCONST 600 #define FULLVIS_BEGIN 2.9e38 #define FULLVIS_END 3.0e38 static inline void fogcalc(int32_t shade, int32_t vis, int32_t pal) { Bmemcpy(fogcol, &fogtable[pal<<2], sizeof(fogcol)); if (r_usenewshading==2) { float combvis = (float)globalvisibility * (uint8_t)(vis+16); bglFogi(GL_FOG_MODE, GL_LINEAR); if (combvis == 0) { fogresult = FULLVIS_BEGIN; fogresult2 = FULLVIS_END; return; } fogresult = -(FOGDISTCONST * shade)/combvis; fogresult2 = (FOGDISTCONST * (numshades-1-shade))/combvis; } else { float f; bglFogi(GL_FOG_MODE, GL_EXP2); if (r_usenewshading==1) { f = 0.9f * shade; f = (vis > 239) ? (float)(gvisibility*((vis-240+f))) : (float)(gvisibility*(vis+16+f)); } else { f = (shade < 0) ? shade * 3.5f : shade * .66f; f = (vis > 239) ? (float)(gvisibility*((vis-240+f)/(klabs(vis-256)))) : (float)(gvisibility*(vis+16+f)); } if (f < 0.001f) f = 0.001f; else if (f > 100.0f) f = 100.0f; fogresult = f; } } void calc_and_apply_fog(int32_t shade, int32_t vis, int32_t pal) { if (!nofog) { fogcalc(shade, vis, pal); bglFogfv(GL_FOG_COLOR, fogcol); if (r_usenewshading==2) { bglFogf(GL_FOG_START, fogresult); bglFogf(GL_FOG_END, fogresult2); } else { bglFogf(GL_FOG_DENSITY, fogresult); } } } void calc_and_apply_fog_factor(int32_t shade, int32_t vis, int32_t pal, float factor) { if (!nofog) { fogcalc(shade, vis, pal); bglFogfv(GL_FOG_COLOR, fogcol); if (r_usenewshading==2) { bglFogf(GL_FOG_START, FULLVIS_BEGIN); bglFogf(GL_FOG_END, FULLVIS_END); } else { bglFogf(GL_FOG_DENSITY, fogresult*factor); } } } //////////////////// void invalidatecache(void) { #ifdef DEBUGGINGAIDS OSD_Printf("invalidatecache()\n"); #endif r_downsizevar = r_downsize; // update the cvar representation when the menu changes r_downsize polymost_glreset(); clear_cache_internal(); // LoadCacheOffsets(); Bstrcpy(ptempbuf,TEXCACHEFILE); unlink(ptempbuf); Bstrcat(ptempbuf,".cache"); unlink(ptempbuf); cacheindexptr = Bfopen(ptempbuf, "at+"); if (!cacheindexptr) { glusetexcache = 0; initprintf("Unable to open cache index \"%s\": %s\n", ptempbuf, strerror(errno)); return; } Bfprintf(cacheindexptr,"// automatically generated by EDuke32, DO NOT MODIFY!\n"); cachefilehandle = Bopen(TEXCACHEFILE,BO_BINARY|BO_CREAT|BO_TRUNC|BO_APPEND|BO_RDWR,BS_IREAD|BS_IWRITE); if (cachefilehandle < 0) { initprintf("Unable to open cache file \"%s\": %s\n", TEXCACHEFILE, strerror(errno)); glusetexcache = 0; return; } else initprintf("Deleted and reopened \"%s\" as cache file\n", TEXCACHEFILE); } static float get_projhack_ratio(void) { // Legacy widescreen if (glwidescreen && !r_usenewaspect) return 1.2f; if (glprojectionhacks == 1) { double mul = (gshang*gshang); return 1.05f + mul*mul*mul*mul; } if (glprojectionhacks == 2) { float abs_shang = fabs(gshang); if (abs_shang > 0.7f) return 1.05f + 4.f*(abs_shang-0.7f); } // No projection hacks (legacy or new-aspect) return 1.0f; } static void resizeglcheck(void) { float m[4][4]; if (glredbluemode < lastglredbluemode) { glox1 = -1; bglColorMask(1,1,1,1); } else if (glredbluemode != lastglredbluemode) { redblueclearcnt = 0; } lastglredbluemode = glredbluemode; //FUK if (lastglpolygonmode != glpolygonmode) { lastglpolygonmode = glpolygonmode; switch (glpolygonmode) { default: case 0: bglPolygonMode(GL_FRONT_AND_BACK,GL_FILL); break; case 1: bglPolygonMode(GL_FRONT_AND_BACK,GL_LINE); break; case 2: bglPolygonMode(GL_FRONT_AND_BACK,GL_POINT); break; } } if (glpolygonmode) //FUK { bglClearColor(1.0,1.0,1.0,0.0); bglClear(GL_COLOR_BUFFER_BIT|GL_DEPTH_BUFFER_BIT); bglDisable(GL_TEXTURE_2D); } if ((glox1 != windowx1) || (gloy1 != windowy1) || (glox2 != windowx2) || (gloy2 != windowy2)) { const int32_t ourxdimen = (windowx2-windowx1+1); const float ratio = get_projhack_ratio(); const int32_t fovcorrect = (ratio==0) ? 0 : (int32_t)(ourxdimen*ratio - ourxdimen); glox1 = (float)windowx1; gloy1 = (float)windowy1; glox2 = (float)windowx2; gloy2 = (float)windowy2; bglViewport(windowx1-(fovcorrect/2), yres-(windowy2+1), ourxdimen+fovcorrect, windowy2-windowy1+1); bglMatrixMode(GL_PROJECTION); memset(m,0,sizeof(m)); m[0][0] = (float)ydimen / ratio; m[0][2] = 1.0; m[1][1] = (float)xdimen; m[1][2] = 1.0; m[2][2] = 1.0; m[2][3] = (float)ydimen / ratio; m[3][2] =-1.0; bglLoadMatrixf(&m[0][0]); bglMatrixMode(GL_MODELVIEW); bglLoadIdentity(); #ifdef USE_OPENGL if (!nofog) bglEnable(GL_FOG); #endif //bglEnable(GL_TEXTURE_2D); } } // NOTE: must not use DAPICNUM for indexing into tile arrays. static void fixtransparency(int32_t dapicnum, coltype *dapic, int32_t daxsiz, int32_t daysiz, int32_t daxsiz2, int32_t daysiz2, int32_t dameth) { coltype *wpptr; int32_t j, x, y, r, g, b, dox, doy, naxsiz2; UNREFERENCED_PARAMETER(dapicnum); dox = daxsiz2-1; doy = daysiz2-1; if (dameth&4) { dox = min(dox,daxsiz); doy = min(doy,daysiz); } else { daxsiz = daxsiz2; daysiz = daysiz2; } //Make repeating textures duplicate top/left parts daxsiz--; daysiz--; naxsiz2 = -daxsiz2; //Hacks for optimization inside loop //Set transparent pixels to average color of neighboring opaque pixels //Doing this makes bilinear filtering look much better for masked textures (I.E. sprites) for (y=doy; y>=0; y--) { wpptr = &dapic[y*daxsiz2+dox]; for (x=dox; x>=0; x--,wpptr--) { if (wpptr->a) continue; r = g = b = j = 0; if ((x> 0) && (wpptr[ -1].a)) { r += wpptr[ -1].r; g += wpptr[ -1].g; b += wpptr[ -1].b; j++; } if ((x 0) && (wpptr[naxsiz2].a)) { r += wpptr[naxsiz2].r; g += wpptr[naxsiz2].g; b += wpptr[naxsiz2].b; j++; } if ((yr = r ; wpptr->g = g ; wpptr->b = b ; break; case 2: wpptr->r = ((r + 1)>>1); wpptr->g = ((g + 1)>>1); wpptr->b = ((b + 1)>>1); break; case 3: wpptr->r = ((r*85+128)>>8); wpptr->g = ((g*85+128)>>8); wpptr->b = ((b*85+128)>>8); break; case 4: wpptr->r = ((r + 2)>>2); wpptr->g = ((g + 2)>>2); wpptr->b = ((b + 2)>>2); break; default: break; } } } } void uploadtexture(int32_t doalloc, int32_t xsiz, int32_t ysiz, int32_t intexfmt, int32_t texfmt, coltype *pic, int32_t tsizx, int32_t tsizy, int32_t dameth) { coltype *wpptr, *rpptr; int32_t x2, y2, j, js=0, x3, y3, y, x, r, g, b, a, k; int32_t hi = (dameth&8192)?1:0; int32_t nocompress = (dameth&4096)?1:0; dameth &= ~(8192|4096); if (gltexmaxsize <= 0) { GLint i = 0; bglGetIntegerv(GL_MAX_TEXTURE_SIZE, &i); if (!i) gltexmaxsize = 6; // 2^6 = 64 == default GL max texture size else { gltexmaxsize = 0; for (; i>1; i>>=1) gltexmaxsize++; } } js = max(0,min(gltexmaxsize-1,gltexmiplevel)); gltexmiplevel = js; while ((xsiz>>js) > (1<>js) > (1< 1) || (y2 > 1); j++) { //x3 = ((x2+1)>>1); y3 = ((y2+1)>>1); x3 = max(1, x2 >> 1); y3 = max(1, y2 >> 1); // this came from the GL_ARB_texture_non_power_of_two spec for (y=0; yr = r; wpptr->g = g; wpptr->b = b; wpptr->a = a; break; case 2: wpptr->r = ((r+1)>>1); wpptr->g = ((g+1)>>1); wpptr->b = ((b+1)>>1); wpptr->a = ((a+1)>>1); break; case 3: wpptr->r = ((r*85+128)>>8); wpptr->g = ((g*85+128)>>8); wpptr->b = ((b*85+128)>>8); wpptr->a = ((a*85+128)>>8); break; case 4: wpptr->r = ((r+2)>>2); wpptr->g = ((g+2)>>2); wpptr->b = ((b+2)>>2); wpptr->a = ((a+2)>>2); break; default: break; } //if (wpptr->a) wpptr->a = 255; } } if (tsizx >= 0) fixtransparency(-1, pic,(tsizx+(1<>j,(tsizy+(1<>j,x3,y3,dameth); if (j >= js) { if (doalloc&1) bglTexImage2D(GL_TEXTURE_2D,j-js,intexfmt,x3,y3,0,texfmt,GL_UNSIGNED_BYTE,pic); //loading 1st time else bglTexSubImage2D(GL_TEXTURE_2D,j-js,0,0,x3,y3,texfmt,GL_UNSIGNED_BYTE,pic); //overwrite old texture } x2 = x3; y2 = y3; } #endif } #if 0 // TODO: make configurable static int32_t tile_is_sky(int32_t tilenum) { return return (tilenum >= 78 /*CLOUDYOCEAN*/ && tilenum <= 99 /*REDSKY2*/); } #else # define tile_is_sky(x) (0) #endif static void texture_setup(int32_t dameth) { gltexfiltermode = clamp(gltexfiltermode, 0, NUMGLFILTERMODES-1); bglTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, glfiltermodes[gltexfiltermode].mag); bglTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, glfiltermodes[gltexfiltermode].min); if (glinfo.maxanisotropy > 1.0) { if (glanisotropy <= 0 || glanisotropy > glinfo.maxanisotropy) glanisotropy = (int32_t)glinfo.maxanisotropy; bglTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAX_ANISOTROPY_EXT, glanisotropy); } if (!(dameth&4)) { bglTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, !tile_is_sky(dapic) ? GL_REPEAT: (glinfo.clamptoedge?GL_CLAMP_TO_EDGE:GL_CLAMP)); bglTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_REPEAT); } else { //For sprite textures, clamping looks better than wrapping bglTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, glinfo.clamptoedge?GL_CLAMP_TO_EDGE:GL_CLAMP); bglTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, glinfo.clamptoedge?GL_CLAMP_TO_EDGE:GL_CLAMP); } } static int32_t gloadtile_art(int32_t dapic, int32_t dapal, int32_t dameth, pthtyp *pth, int32_t doalloc) { coltype *pic; int32_t xsiz, ysiz; char hasalpha = 0, hasfullbright = 0; static int32_t fullbrightloadingpass = 0; int32_t tsizx = tilesizx[dapic]; int32_t tsizy = tilesizy[dapic]; if (!glinfo.texnpot) { for (xsiz=1; xsiz= tsizx || y >= tsizy)) //Clamp texture { wpptr->r = wpptr->g = wpptr->b = wpptr->a = 0; continue; } if (x < tsizx) x2 = x; else x2 = x-tsizx; dacol = *(char *)(waloff[dapic]+x2*tsizy+y2); if (!fullbrightloadingpass) { // regular texture if (dacol > 239 && dacol != 255 && dofullbright) hasfullbright = 1; wpptr->a = 255; } else { // texture with only fullbright areas if (dacol < 240) // regular colors { wpptr->a = 0; hasalpha = 1; } else // fullbright { wpptr->a = 255; } } if (dacol != 255) { dacol = (uint8_t)palookup[dapal][dacol]; } else { wpptr->a = 0; hasalpha = 1; } bricolor((palette_t *)wpptr, dacol); } } } if (doalloc) bglGenTextures(1,(GLuint *)&pth->glpic); //# of textures (make OpenGL allocate structure) bglBindTexture(GL_TEXTURE_2D,pth->glpic); fixtransparency(dapic, pic,tsizx,tsizy,xsiz,ysiz,dameth); uploadtexture(doalloc,xsiz,ysiz,hasalpha?GL_RGBA:GL_RGB,GL_RGBA,pic,tsizx,tsizy,dameth); texture_setup(dameth); Bfree(pic); pth->picnum = dapic; pth->palnum = dapal; pth->effects = 0; pth->flags = ((dameth&4)>>2) | (hasalpha<<3); pth->hicr = NULL; if (hasfullbright && !fullbrightloadingpass) { // Load the ONLY texture that'll be assembled with the regular one to // make the final texture with fullbright pixels. fullbrightloadingpass = 1; pth->ofb = (pthtyp *)Bcalloc(1,sizeof(pthtyp)); if (!pth->ofb) return 1; pth->flags |= (1<<4); if (gloadtile_art(dapic, dapal, dameth, pth->ofb, 1)) return 1; fullbrightloadingpass = 0; } return 0; } // JONOF'S COMPRESSED TEXTURE CACHE STUFF --------------------------------------------------- static int32_t LoadCacheOffsets(void) { int32_t foffset, fsize, i; char *fname; scriptfile *script; Bstrcpy(ptempbuf,TEXCACHEFILE); Bstrcat(ptempbuf,".cache"); script = scriptfile_fromfile(ptempbuf); if (!script) return -1; while (!scriptfile_eof(script)) { if (scriptfile_getstring(script, &fname)) break; // hashed filename if (scriptfile_getnumber(script, &foffset)) break; // offset in cache if (scriptfile_getnumber(script, &fsize)) break; // size i = hash_find(&h_texcache,fname); if (i > -1) { // update an existing entry texcacheindex *t = cacheptrs[i]; t->offset = foffset; t->len = fsize; /*initprintf("%s %d got a match for %s offset %d\n",__FILE__, __LINE__, fname,foffset);*/ } else { Bstrncpyz(curcacheindex->name, fname, BMAX_PATH); curcacheindex->offset = foffset; curcacheindex->len = fsize; curcacheindex->next = (texcacheindex *)Bcalloc(1, sizeof(texcacheindex)); hash_add(&h_texcache, fname, numcacheentries, 1); cacheptrs[numcacheentries++] = curcacheindex; curcacheindex = curcacheindex->next; } } scriptfile_close(script); return 0; } static void phex(char v, char *s) { int32_t x; x = v>>4; s[0] = x<10 ? (x+'0') : (x-10+'a'); x = v&15; s[1] = x<10 ? (x+'0') : (x-10+'a'); } // Read from on-disk texcache or its in-memory cache. static int32_t read_from_cache(void *dest, int32_t len) { const int32_t ocachepos = cachepos; cachepos += len; if (memcachedata && memcachesize >= ocachepos+len) { // initprintf("using memcache!\n"); Bmemcpy(dest, memcachedata+ocachepos, len); } else { Blseek(cachefilehandle, ocachepos, BSEEK_SET); if (Bread(cachefilehandle, dest, len) < len) return 1; } return 0; } int32_t polymost_trytexcache(const char *fn, int32_t len, int32_t dameth, char effect, texcacheheader *head, int32_t modelp) { int32_t fp, err=0; char cachefn[BMAX_PATH], *cp; uint8_t mdsum[16]; // in the former mdloadskin_trytexcache, glinfo.texcompr used to be in the first check if (!glusetexcompr || !glusetexcache || !cacheindexptr || cachefilehandle < 0) return -1; if (!glinfo.texcompr || !bglCompressedTexImage2DARB || !bglGetCompressedTexImageARB) { // lacking the necessary extensions to do this OSD_Printf("Warning: the GL driver lacks necessary functions to use caching\n"); glusetexcache = 0; return -1; } md4once((const uint8_t *)fn, strlen(fn), mdsum); // for (cp = cachefn, fp = 0; (*cp = TEXCACHEFILE[fp]); cp++,fp++); // *(cp++) = '/'; cp = cachefn; for (fp = 0; fp < 16; phex(mdsum[fp++], cp), cp+=2); Bsprintf(cp, "-%x-%x%x", len, dameth, effect); { int32_t i = hash_find(&h_texcache,cachefn); if (i < 0 || !cacheptrs[i]) return -1; // didn't find it cachepos = cacheptrs[i]->offset; // initprintf("%s %d got a match for %s offset %d\n",__FILE__, __LINE__, cachefn,offset); } // initprintf("Loading cached tex: %s\n", cachefn); if (read_from_cache(head, sizeof(texcacheheader))) { err = 0; goto failure; } // checks... if (Bmemcmp(head->magic, TEXCACHEMAGIC, 4)) { err=1; goto failure; } // native (little-endian) -> internal head->xdim = B_LITTLE32(head->xdim); head->ydim = B_LITTLE32(head->ydim); head->flags = B_LITTLE32(head->flags); head->quality = B_LITTLE32(head->quality); if (modelp) if (head->quality != r_downsize) { err=2; goto failure; } if ((head->flags & 4) && glusetexcache != 2) { err=3; goto failure; } if (!(head->flags & 4) && glusetexcache == 2) { err=4; goto failure; } if (!modelp) // handle nocompress if (!(head->flags & 8) && head->quality != r_downsize) return -1; if (gltexmaxsize && (head->xdim > (1<ydim > (1<flags & 1)) { err=6; goto failure; } return cachefilehandle; failure: { static const char *error_msgs[] = { "failed reading texture cache header", // 0 "header magic string doesn't match", // 1 "r_downsize doesn't match", // 2 (skins only) "compression doesn't match: cache contains compressed tex", // 3 "compression doesn't match: cache contains uncompressed tex", // 4 "texture in cache exceeds maximum supported size", // 5 "texture in cache has non-power-of-two size, unsupported", // 6 }; initprintf("%s cache miss: %s\n", modelp?"Skin":"Texture", error_msgs[err]); } return -1; } void writexcache(const char *fn, int32_t len, int32_t dameth, char effect, texcacheheader *head) { char cachefn[BMAX_PATH]; uint8_t mdsum[16]; char *pic = NULL, *packbuf = NULL; void *midbuf = NULL; uint32_t alloclen=0, level; uint32_t padx=0, pady=0; GLint gi; int32_t offset = 0; if (!glinfo.texcompr || !glusetexcompr || !glusetexcache) return; if (!bglCompressedTexImage2DARB || !bglGetCompressedTexImageARB) { // lacking the necessary extensions to do this OSD_Printf("Warning: the GL driver lacks necessary functions to use caching\n"); glusetexcache = 0; return; } if (!cacheindexptr || cachefilehandle < 0) { OSD_Printf("Warning: no active cache!\n"); return; } gi = GL_FALSE; bglGetTexLevelParameteriv(GL_TEXTURE_2D, 0, GL_TEXTURE_COMPRESSED_ARB, &gi); if (gi != GL_TRUE) { OSD_Printf("Error: glGetTexLevelParameteriv returned GL_FALSE!\n"); return; } md4once((const uint8_t *)fn, strlen(fn), mdsum); { int32_t fp; char *cp = cachefn; for (fp = 0; fp < 16; phex(mdsum[fp++], cp), cp+=2); Bsprintf(cp, "-%x-%x%x", len, dameth, effect); } Blseek(cachefilehandle, 0, BSEEK_END); offset = Blseek(cachefilehandle, 0, BSEEK_CUR); // OSD_Printf("Caching %s, offset 0x%x\n", cachefn, offset); Bmemcpy(head->magic, TEXCACHEMAGIC, 4); // sizes are set by caller if (glusetexcache == 2) head->flags |= 4; // native -> external (little-endian) head->xdim = B_LITTLE32(head->xdim); head->ydim = B_LITTLE32(head->ydim); head->flags = B_LITTLE32(head->flags); head->quality = B_LITTLE32(head->quality); if (Bwrite(cachefilehandle, head, sizeof(texcacheheader)) != sizeof(texcacheheader)) goto failure; while (bglGetError() != GL_NO_ERROR) { /* no-op*/ } for (level = 0; level==0 || (padx > 1 || pady > 1); level++) { uint32_t miplen; texcachepicture pict; bglGetTexLevelParameteriv(GL_TEXTURE_2D, level, GL_TEXTURE_COMPRESSED_ARB, &gi); if (bglGetError() != GL_NO_ERROR) goto failure; if (gi != GL_TRUE) goto failure; // an uncompressed mipmap bglGetTexLevelParameteriv(GL_TEXTURE_2D, level, GL_TEXTURE_INTERNAL_FORMAT, &gi); if (bglGetError() != GL_NO_ERROR) goto failure; #ifdef __APPLE__ if (pr_ati_textureformat_one && gi == 1) gi = GL_COMPRESSED_RGBA_S3TC_DXT1_EXT; #endif // native -> external (little endian) pict.format = B_LITTLE32(gi); bglGetTexLevelParameteriv(GL_TEXTURE_2D, level, GL_TEXTURE_WIDTH, &gi); if (bglGetError() != GL_NO_ERROR) goto failure; padx = gi; pict.xdim = B_LITTLE32(gi); bglGetTexLevelParameteriv(GL_TEXTURE_2D, level, GL_TEXTURE_HEIGHT, &gi); if (bglGetError() != GL_NO_ERROR) goto failure; pady = gi; pict.ydim = B_LITTLE32(gi); bglGetTexLevelParameteriv(GL_TEXTURE_2D, level, GL_TEXTURE_BORDER, &gi); if (bglGetError() != GL_NO_ERROR) goto failure; pict.border = B_LITTLE32(gi); bglGetTexLevelParameteriv(GL_TEXTURE_2D, level, GL_TEXTURE_DEPTH, &gi); if (bglGetError() != GL_NO_ERROR) goto failure; pict.depth = B_LITTLE32(gi); bglGetTexLevelParameteriv(GL_TEXTURE_2D, level, GL_TEXTURE_COMPRESSED_IMAGE_SIZE_ARB, &gi); if (bglGetError() != GL_NO_ERROR) goto failure; miplen = gi; pict.size = B_LITTLE32(gi); if (alloclen < miplen) { pic = (char *)Brealloc(pic, miplen); if (!pic) goto failure; alloclen = miplen; packbuf = (char *)Brealloc(packbuf, alloclen+400); if (!packbuf) goto failure; midbuf = Brealloc(midbuf, miplen); if (!midbuf) goto failure; } bglGetCompressedTexImageARB(GL_TEXTURE_2D, level, pic); if (bglGetError() != GL_NO_ERROR) goto failure; if (Bwrite(cachefilehandle, &pict, sizeof(texcachepicture)) != sizeof(texcachepicture)) goto failure; if (dxtfilter(cachefilehandle, &pict, pic, midbuf, packbuf, miplen)) goto failure; } { int32_t i = hash_find(&h_texcache,cachefn); if (i > -1) { // update an existing entry texcacheindex *t = cacheptrs[i]; t->offset = offset; t->len = Blseek(cachefilehandle, 0, BSEEK_CUR) - t->offset; /*initprintf("%s %d got a match for %s offset %d\n",__FILE__, __LINE__, cachefn,offset);*/ if (cacheindexptr) { fseek(cacheindexptr, 0, BSEEK_END); Bfprintf(cacheindexptr, "%s %d %d\n", t->name, t->offset, t->len); } else OSD_Printf("wtf?\n"); } else { Bstrcpy(curcacheindex->name, cachefn); curcacheindex->offset = offset; curcacheindex->len = Blseek(cachefilehandle, 0, BSEEK_CUR) - curcacheindex->offset; curcacheindex->next = (texcacheindex *)Bcalloc(1, sizeof(texcacheindex)); if (cacheindexptr) { fseek(cacheindexptr, 0, BSEEK_END); Bfprintf(cacheindexptr, "%s %d %d\n", curcacheindex->name, curcacheindex->offset, curcacheindex->len); } else OSD_Printf("wtf?\n"); hash_add(&h_texcache, cachefn, numcacheentries, 0); cacheptrs[numcacheentries++] = curcacheindex; curcacheindex = curcacheindex->next; } } goto success; failure: initprintf("ERROR: cache failure!\n"); curcacheindex->offset = 0; Bmemset(curcacheindex->name,0,sizeof(curcacheindex->name)); success: Bfree(midbuf); Bfree(pic); Bfree(packbuf); } static int32_t gloadtile_cached(int32_t fil, const texcacheheader *head, int32_t *doalloc, pthtyp *pth,int32_t dapalnum) { int32_t level; texcachepicture pict; char *pic = NULL, *packbuf = NULL; void *midbuf = NULL; int32_t alloclen=0; int32_t err=0; GLenum glerr=GL_NO_ERROR; UNREFERENCED_PARAMETER(dapalnum); if (*doalloc&1) { bglGenTextures(1,(GLuint *)&pth->glpic); //# of textures (make OpenGL allocate structure) *doalloc |= 2; // prevents bglGenTextures being called again if we fail in here } bglBindTexture(GL_TEXTURE_2D,pth->glpic); pth->sizx = head->xdim; pth->sizy = head->ydim; while (bglGetError() != GL_NO_ERROR) { /* no-op*/ } // load the mipmaps for (level = 0; level==0 || (pict.xdim > 1 || pict.ydim > 1); level++) { if (read_from_cache(&pict, sizeof(texcachepicture))) { err=1; goto failure; } // external (little endian) -> native pict.size = B_LITTLE32(pict.size); pict.format = B_LITTLE32(pict.format); pict.xdim = B_LITTLE32(pict.xdim); pict.ydim = B_LITTLE32(pict.ydim); pict.border = B_LITTLE32(pict.border); pict.depth = B_LITTLE32(pict.depth); if (alloclen < pict.size) { pic = (char *)Brealloc(pic, pict.size); if (!pic) goto failure; alloclen = pict.size; packbuf = (char *)Brealloc(packbuf, alloclen+16); if (!packbuf) goto failure; midbuf = Brealloc(midbuf, pict.size); if (!midbuf) goto failure; } if (dedxtfilter(fil, &pict, pic, midbuf, packbuf, (head->flags&4)==4)) { err=2; goto failure; } bglCompressedTexImage2DARB(GL_TEXTURE_2D,level,pict.format,pict.xdim,pict.ydim,pict.border, pict.size,pic); if ((glerr=bglGetError()) != GL_NO_ERROR) { err=3; goto failure; } { GLint format; bglGetTexLevelParameteriv(GL_TEXTURE_2D, level, GL_TEXTURE_INTERNAL_FORMAT, &format); if ((glerr = bglGetError()) != GL_NO_ERROR) { err=4; goto failure; } if (pict.format != format) { OSD_Printf("gloadtile_cached: invalid texture cache file format %d %d\n", pict.format, format); err = -1; goto failure; } } } Bfree(midbuf); Bfree(pic); Bfree(packbuf); return 0; failure: { static const char *errmsgs[5] = { "out of memory!", "read too few bytes from cache file", "dedxtfilter failed", "bglCompressedTexImage2DARB failed", "bglGetTexLevelParameteriv failed", }; if (err >= 0) initprintf("gloadtile_cached: %s (glerr=%x)\n", errmsgs[err], glerr); } Bfree(midbuf); Bfree(pic); Bfree(packbuf); return -1; } // --------------------------------------------------- JONOF'S COMPRESSED TEXTURE CACHE STUFF static int32_t gloadtile_hi(int32_t dapic,int32_t dapalnum, int32_t facen, hicreplctyp *hicr, int32_t dameth, pthtyp *pth, int32_t doalloc, char effect) { coltype *pic = NULL, *rpptr; int32_t j, x, y, xsiz=0, ysiz=0, tsizx, tsizy; char *picfil = NULL, *fn, hasalpha = 255; int32_t picfillen, texfmt = GL_RGBA, intexfmt = GL_RGBA, filh; int32_t cachefil = -1; texcacheheader cachead; static coltype *lastpic = NULL; static char *lastfn = NULL; static int32_t lastsize = 0; int32_t startticks=0, willprint=0; if (!hicr) return -1; if (facen > 0) { if (!hicr->skybox) return -1; if (facen > 6) return -1; if (!hicr->skybox->face[facen-1]) return -1; fn = hicr->skybox->face[facen-1]; } else { if (!hicr->filename) return -1; fn = hicr->filename; } if ((filh = kopen4load(fn, 0)) < 0) { OSD_Printf("hightile: %s (pic %d) not found\n", fn, dapic); if (facen > 0) hicr->skybox->ignore = 1; else hicr->ignore = 1; return -1; } picfillen = kfilelength(filh); kclose(filh); // FIXME: shouldn't have to do this. bug in cache1d.c cachefil = polymost_trytexcache(fn, picfillen+(dapalnum<<8), dameth, effect, &cachead, 0); if (cachefil >= 0 && !gloadtile_cached(cachefil, &cachead, &doalloc, pth, dapalnum)) { tsizx = cachead.xdim; tsizy = cachead.ydim; hasalpha = (cachead.flags & 2) ? 0 : 255; } else { int32_t r, g, b; cachefil = -1; // the compressed version will be saved to disk if ((filh = kopen4load(fn, 0)) < 0) return -1; picfil = (char *)Bmalloc(picfillen+1); if (!picfil) { kclose(filh); return 1; } if (kread(filh, picfil, picfillen) != picfillen) initprintf("warning: didn't fully read %s\n", fn); // prevent // Conditional jump or move depends on uninitialised value(s) // at kpegrend (kplib.c:1655) picfil[picfillen] = 0; kclose(filh); // tsizx/y = replacement texture's natural size // xsiz/y = 2^x size of replacement kpgetdim(picfil,picfillen,&tsizx,&tsizy); if (tsizx == 0 || tsizy == 0) { Bfree(picfil); return -1; } pth->sizx = tsizx; pth->sizy = tsizy; if (!glinfo.texnpot) { for (xsiz=1; xsiz tsizx) //Copy left to right { int32_t *lptr = (int32_t *)pic; for (y=0; y tsizy) //Copy top to bottom Bmemcpy(&pic[xsiz*tsizy],pic,(ysiz-tsizy)*xsiz<<2); } if (!glinfo.bgra) { for (j=xsiz*ysiz-1; j>=0; j--) { swapchar(&pic[j].r, &pic[j].b); } } else texfmt = GL_BGRA; Bfree(picfil); picfil = 0; if (tsizx>>r_downsize <= tilesizx[dapic] || tsizy>>r_downsize <= tilesizy[dapic]) hicr->flags |= 17; if (glinfo.texcompr && glusetexcompr && !(hicr->flags & 1)) intexfmt = (hasalpha == 255) ? GL_COMPRESSED_RGB_ARB : GL_COMPRESSED_RGBA_ARB; else if (hasalpha == 255) intexfmt = GL_RGB; if ((doalloc&3)==1) bglGenTextures(1, &pth->glpic); //# of textures (make OpenGL allocate structure) bglBindTexture(GL_TEXTURE_2D,pth->glpic); fixtransparency(-1, pic,tsizx,tsizy,xsiz,ysiz,dameth); uploadtexture(doalloc,xsiz,ysiz,intexfmt,texfmt,pic,-1,tsizy,dameth|8192|(hicr->flags & 16?4096:0)); } // precalculate scaling parameters for replacement if (facen > 0) { pth->scalex = ((float)tsizx) / 64.0; pth->scaley = ((float)tsizy) / 64.0; } else { pth->scalex = ((float)tsizx) / ((float)tilesizx[dapic]); pth->scaley = ((float)tsizy) / ((float)tilesizy[dapic]); } texture_setup(dameth); Bfree(pic); pic=NULL; if (tsizx>>r_downsize <= tilesizx[dapic] || tsizy>>r_downsize <= tilesizy[dapic]) hicr->flags |= (16+1); pth->picnum = dapic; pth->effects = effect; pth->flags = ((dameth&4)>>2) + 2 + ((facen>0)<<2); if (hasalpha != 255) pth->flags |= 8; pth->skyface = facen; pth->hicr = hicr; if (glinfo.texcompr && glusetexcompr && glusetexcache && !(hicr->flags & 1)) if (cachefil < 0) { // save off the compressed version if (hicr->flags & 16) cachead.quality = 0; else cachead.quality = r_downsize; cachead.xdim = tsizx>>cachead.quality; cachead.ydim = tsizy>>cachead.quality; x = 0; for (j=0; j<31; j++) { if (xsiz == pow2long[j]) { x |= 1; } if (ysiz == pow2long[j]) { x |= 2; } } cachead.flags = (x!=3) | (hasalpha != 255 ? 2 : 0) | (hicr->flags&16 ? 8 : 0); // handle nocompress /// OSD_Printf("Caching \"%s\"\n", fn); writexcache(fn, picfillen+(dapalnum<<8), dameth, effect, &cachead); if (willprint) { int32_t etime = getticks()-startticks; if (etime>=MIN_CACHETIME_PRINT) OSD_Printf("Load tile %4d: p%d-m%d-e%d %s... cached... %d ms\n", dapic, dapalnum, dameth, effect, willprint==2 ? fn : "", etime); willprint = 0; } else OSD_Printf("Cached \"%s\"\n", fn); } if (willprint) { int32_t etime = getticks()-startticks; if (etime>=MIN_CACHETIME_PRINT) OSD_Printf("Load tile %4d: p%d-m%d-e%d %s... %d ms\n", dapic, dapalnum, dameth, effect, willprint==2 ? fn : "", etime); } return 0; } #endif //(dpx,dpy) specifies an n-sided polygon. The polygon must be a convex clockwise loop. // n must be <= 8 (assume clipping can double number of vertices) //method: 0:solid, 1:masked(255 is transparent), 2:transluscent #1, 3:transluscent #2 // +4 means it's a sprite, so wraparound isn't needed // drawpoly's hack globals static int32_t pow2xsplit = 0, skyclamphack = 0; static float alpha = 0.f; void drawpoly(double *dpx, double *dpy, int32_t n, int32_t method) { double ngdx = 0.0, ngdy = 0.0, ngdo = 0.0, ngux = 0.0, nguy = 0.0, nguo = 0.0; double ngvx = 0.0, ngvy = 0.0, ngvo = 0.0, dp, up, vp, du0 = 0.0, du1 = 0.0, dui, duj; double f, r, ox, oy, oz, ox2, oy2, oz2, dd[16], uu[16], vv[16], px[16], py[16], uoffs; int32_t i, j, k, nn, ix0, ix1, tsizx, tsizy; int32_t xx, yy, dorot; #ifdef USE_OPENGL pthtyp *pth, *detailpth, *glowpth; int32_t texunits = GL_TEXTURE0_ARB; #endif // backup of the n for possible redrawing of fullbright int32_t n_ = n, method_ = method; if (method == -1) return; #ifdef YAX_ENABLE if (g_nodraw) return; #endif if (n == 3) { if ((dpx[0]-dpx[1])*(dpy[2]-dpy[1]) >= (dpx[2]-dpx[1])*(dpy[0]-dpy[1])) return; //for triangle } else { f = 0; //f is area of polygon / 2 for (i=n-2,j=n-1,k=0; k= MAXTILES) globalpicnum = 0; setgotpic(globalpicnum); tsizx = tilesizx[globalpicnum]; tsizy = tilesizy[globalpicnum]; if (palookup[globalpal] == NULL) globalpal = 0; if (!waloff[globalpicnum]) { loadtile(globalpicnum); if (!waloff[globalpicnum]) { if (rendmode < 3) return; tsizx = tsizy = 1; method = 1; //Hack to update Z-buffer for invalid mirror textures } } j = 0; dorot = ((gchang != 1.0) || (gctang != 1.0)); if (dorot) { for (i=0; i= 3) && (px[j-1] == px[0]) && (py[j-1] == py[0])) j--; if (j < 3) return; n = j; #ifdef USE_OPENGL if (rendmode >= 3) { float hackscx, hackscy; if (skyclamphack) method |= 4; pth = gltexcache(globalpicnum,globalpal,method&(~3)); if (!pth) { if (editstatus) { Bsprintf(ptempbuf, "pth==NULL! (bad pal?) pic=%d pal=%d", globalpicnum, globalpal); polymost_printext256(8,8, editorcolors[15],editorcolors[5], ptempbuf, 0); } return; } if (r_fullbrights && pth->flags & 16) if (indrawroomsandmasks) { if (!fullbrightdrawingpass) fullbrightdrawingpass = 1; else if (fullbrightdrawingpass == 2) pth = pth->ofb; } // If we aren't rendmode 3, we're in Polymer, which means this code is // used for rotatesprite only. Polymer handles all the material stuff, // just submit the geometry and don't mess with textures. if (rendmode == 3) { bglBindTexture(GL_TEXTURE_2D, pth ? pth->glpic : 0); if (srepeat) bglTexParameteri(GL_TEXTURE_2D,GL_TEXTURE_WRAP_S,GL_REPEAT); if (trepeat) bglTexParameteri(GL_TEXTURE_2D,GL_TEXTURE_WRAP_T,GL_REPEAT); } // texture scale by parkar request if (pth && pth->hicr && ((pth->hicr->xscale != 1.0f) || (pth->hicr->yscale != 1.0f)) && !drawingskybox) { bglMatrixMode(GL_TEXTURE); bglLoadIdentity(); bglScalef(pth->hicr->xscale, pth->hicr->yscale, 1.0f); bglMatrixMode(GL_MODELVIEW); } // detail texture detailpth = NULL; if (r_detailmapping && usehightile && !drawingskybox && hicfindsubst(globalpicnum, DETAILPAL, 0)) detailpth = gltexcache(globalpicnum, DETAILPAL, method&(~3)); if (detailpth && detailpth->hicr && (detailpth->hicr->palnum == DETAILPAL)) { bglActiveTextureARB(++texunits); bglEnable(GL_TEXTURE_2D); bglBindTexture(GL_TEXTURE_2D, detailpth ? detailpth->glpic : 0); bglTexEnvf(GL_TEXTURE_ENV, GL_TEXTURE_ENV_MODE, GL_COMBINE_ARB); bglTexEnvf(GL_TEXTURE_ENV, GL_COMBINE_RGB_ARB, GL_MODULATE); bglTexEnvf(GL_TEXTURE_ENV, GL_SOURCE0_RGB_ARB, GL_PREVIOUS_ARB); bglTexEnvf(GL_TEXTURE_ENV, GL_OPERAND0_RGB_ARB, GL_SRC_COLOR); bglTexEnvf(GL_TEXTURE_ENV, GL_SOURCE1_RGB_ARB, GL_TEXTURE); bglTexEnvf(GL_TEXTURE_ENV, GL_OPERAND1_RGB_ARB, GL_SRC_COLOR); bglTexEnvf(GL_TEXTURE_ENV, GL_COMBINE_ALPHA_ARB, GL_REPLACE); bglTexEnvf(GL_TEXTURE_ENV, GL_SOURCE0_ALPHA_ARB, GL_PREVIOUS_ARB); bglTexEnvf(GL_TEXTURE_ENV, GL_OPERAND0_ALPHA_ARB, GL_SRC_ALPHA); bglTexEnvf(GL_TEXTURE_ENV, GL_RGB_SCALE_ARB, 2.0f); bglTexParameteri(GL_TEXTURE_2D,GL_TEXTURE_WRAP_S,GL_REPEAT); bglTexParameteri(GL_TEXTURE_2D,GL_TEXTURE_WRAP_T,GL_REPEAT); f = detailpth ? detailpth->hicr->xscale : 1.0; bglMatrixMode(GL_TEXTURE); bglLoadIdentity(); if (pth && pth->hicr && ((pth->hicr->xscale != 1.0f) || (pth->hicr->yscale != 1.0f))) bglScalef(pth->hicr->xscale, pth->hicr->yscale, 1.0f); if (detailpth && detailpth->hicr && ((detailpth->hicr->xscale != 1.0f) || (detailpth->hicr->yscale != 1.0f))) bglScalef(detailpth->hicr->xscale, detailpth->hicr->yscale, 1.0f); bglMatrixMode(GL_MODELVIEW); } // glow texture glowpth = NULL; if (r_glowmapping && usehightile && !drawingskybox && hicfindsubst(globalpicnum, GLOWPAL, 0)) glowpth = gltexcache(globalpicnum, GLOWPAL, method&(~3)); if (glowpth && glowpth->hicr && (glowpth->hicr->palnum == GLOWPAL)) { bglActiveTextureARB(++texunits); bglEnable(GL_TEXTURE_2D); bglBindTexture(GL_TEXTURE_2D, glowpth ? glowpth->glpic : 0); bglTexEnvf(GL_TEXTURE_ENV, GL_TEXTURE_ENV_MODE, GL_COMBINE_ARB); bglTexEnvf(GL_TEXTURE_ENV, GL_COMBINE_RGB_ARB, GL_INTERPOLATE_ARB); bglTexEnvf(GL_TEXTURE_ENV, GL_SOURCE0_RGB_ARB, GL_PREVIOUS_ARB); bglTexEnvf(GL_TEXTURE_ENV, GL_OPERAND0_RGB_ARB, GL_SRC_COLOR); bglTexEnvf(GL_TEXTURE_ENV, GL_SOURCE1_RGB_ARB, GL_TEXTURE); bglTexEnvf(GL_TEXTURE_ENV, GL_OPERAND1_RGB_ARB, GL_SRC_COLOR); bglTexEnvf(GL_TEXTURE_ENV, GL_SOURCE2_RGB_ARB, GL_TEXTURE); bglTexEnvf(GL_TEXTURE_ENV, GL_OPERAND2_RGB_ARB, GL_ONE_MINUS_SRC_ALPHA); bglTexEnvf(GL_TEXTURE_ENV, GL_COMBINE_ALPHA_ARB, GL_REPLACE); bglTexEnvf(GL_TEXTURE_ENV, GL_SOURCE0_ALPHA_ARB, GL_PREVIOUS_ARB); bglTexEnvf(GL_TEXTURE_ENV, GL_OPERAND0_ALPHA_ARB, GL_SRC_ALPHA); bglTexParameteri(GL_TEXTURE_2D,GL_TEXTURE_WRAP_S,GL_REPEAT); bglTexParameteri(GL_TEXTURE_2D,GL_TEXTURE_WRAP_T,GL_REPEAT); } if (pth && (pth->flags & 2)) { hackscx = pth->scalex; hackscy = pth->scaley; tsizx = pth->sizx; tsizy = pth->sizy; } else { hackscx = 1.0; hackscy = 1.0; } if (!glinfo.texnpot) { for (xx=1; xxhicr && pth->hicr->alphacut >= 0.0) al = pth->hicr->alphacut; if (alphahackarray[globalpicnum]) al=alphahackarray[globalpicnum]; if (!waloff[globalpicnum]) al = 0.0; // invalid textures ignore the alpha cutoff settings bglEnable(GL_BLEND); bglEnable(GL_ALPHA_TEST); bglAlphaFunc(GL_GREATER,al); } if (!dorot) { for (i=n-1; i>=0; i--) { dd[i] = px[i]*gdx + py[i]*gdy + gdo; uu[i] = px[i]*gux + py[i]*guy + guo; vv[i] = px[i]*gvx + py[i]*gvy + gvo; } } { float pc[4]; pc[0] = pc[1] = pc[2] = getshadefactor(globalshade); switch (method&3) { default: case 0: pc[3] = 1.0f; break; case 1: pc[3] = 1.0f; break; case 2: pc[3] = 0.66f; break; case 3: pc[3] = 0.33f; break; } // spriteext full alpha control pc[3] *= 1.0f - alpha; // tinting happens only to hightile textures, and only if the texture we're // rendering isn't for the same palette as what we asked for if (!(hictinting[globalpal].f&4)) { if (pth && (pth->flags & 2)) { if (pth->palnum != globalpal) { // apply tinting for replaced textures pc[0] *= (float)hictinting[globalpal].r / 255.0; pc[1] *= (float)hictinting[globalpal].g / 255.0; pc[2] *= (float)hictinting[globalpal].b / 255.0; } if (hictinting[MAXPALOOKUPS-1].r != 255 || hictinting[MAXPALOOKUPS-1].g != 255 || hictinting[MAXPALOOKUPS-1].b != 255) { pc[0] *= (float)hictinting[MAXPALOOKUPS-1].r / 255.0; pc[1] *= (float)hictinting[MAXPALOOKUPS-1].g / 255.0; pc[2] *= (float)hictinting[MAXPALOOKUPS-1].b / 255.0; } } // hack: this is for drawing the 8-bit crosshair recolored in polymost else if (hictinting[globalpal].f & 8) { pc[0] *= (float)hictinting[globalpal].r / 255.0; pc[1] *= (float)hictinting[globalpal].g / 255.0; pc[2] *= (float)hictinting[globalpal].b / 255.0; } } bglColor4f(pc[0],pc[1],pc[2],pc[3]); } //Hack for walls&masked walls which use textures that are not a power of 2 if ((pow2xsplit) && (tsizx != xx)) { if (!dorot) { ngdx = gdx; ngdy = gdy; ngdo = gdo+(ngdx+ngdy)*.5; ngux = gux; nguy = guy; nguo = guo+(ngux+nguy)*.5; ngvx = gvx; ngvy = gvy; ngvo = gvo+(ngvx+ngvy)*.5; } else { ox = py[1]-py[2]; oy = py[2]-py[0]; oz = py[0]-py[1]; r = 1.0 / (ox*px[0] + oy*px[1] + oz*px[2]); ngdx = (ox*dd[0] + oy*dd[1] + oz*dd[2])*r; ngux = (ox*uu[0] + oy*uu[1] + oz*uu[2])*r; ngvx = (ox*vv[0] + oy*vv[1] + oz*vv[2])*r; ox = px[2]-px[1]; oy = px[0]-px[2]; oz = px[1]-px[0]; ngdy = (ox*dd[0] + oy*dd[1] + oz*dd[2])*r; nguy = (ox*uu[0] + oy*uu[1] + oz*uu[2])*r; ngvy = (ox*vv[0] + oy*vv[1] + oz*vv[2])*r; ox = px[0]-.5; oy = py[0]-.5; //.5 centers texture nicely ngdo = dd[0] - ox*ngdx - oy*ngdy; nguo = uu[0] - ox*ngux - oy*nguy; ngvo = vv[0] - ox*ngvx - oy*ngvy; } ngux *= hackscx; nguy *= hackscx; nguo *= hackscx; ngvx *= hackscy; ngvy *= hackscy; ngvo *= hackscy; uoffs = ((double)(xx-tsizx)*.5); ngux -= ngdx*uoffs; nguy -= ngdy*uoffs; nguo -= ngdo*uoffs; //Find min&max u coordinates (du0...du1) for (i=0; i du1) du1 = f; } f = 1.0/(double)tsizx; ix0 = (int32_t)floor(du0*f); ix1 = (int32_t)floor(du1*f); for (; ix0<=ix1; ix0++) { du0 = (double)((ix0)*tsizx); // + uoffs; du1 = (double)((ix0+1)*tsizx); // + uoffs; i = 0; nn = 0; duj = (px[i]*ngux + py[i]*nguy + nguo) / (px[i]*ngdx + py[i]*ngdy + ngdo); do { j = i+1; if (j == n) j = 0; dui = duj; duj = (px[j]*ngux + py[j]*nguy + nguo) / (px[j]*ngdx + py[j]*ngdy + ngdo); if ((du0 <= dui) && (dui <= du1)) { uu[nn] = px[i]; vv[nn] = py[i]; nn++; } if (duj <= dui) { if ((du1 < duj) != (du1 < dui)) { //ox*(ngux-ngdx*du1) + oy*(nguy-ngdy*du1) + (nguo-ngdo*du1) = 0 //(px[j]-px[i])*f + px[i] = ox //(py[j]-py[i])*f + py[i] = oy ///Solve for f //((px[j]-px[i])*f + px[i])*(ngux-ngdx*du1) + //((py[j]-py[i])*f + py[i])*(nguy-ngdy*du1) + (nguo-ngdo*du1) = 0 f = -(px[i] *(ngux-ngdx*du1) + py[i] *(nguy-ngdy*du1) + (nguo-ngdo*du1)) / ((px[j]-px[i])*(ngux-ngdx*du1) + (py[j]-py[i])*(nguy-ngdy*du1)); uu[nn] = (px[j]-px[i])*f + px[i]; vv[nn] = (py[j]-py[i])*f + py[i]; nn++; } if ((du0 < duj) != (du0 < dui)) { f = -(px[i] *(ngux-ngdx*du0) + py[i] *(nguy-ngdy*du0) + (nguo-ngdo*du0)) / ((px[j]-px[i])*(ngux-ngdx*du0) + (py[j]-py[i])*(nguy-ngdy*du0)); uu[nn] = (px[j]-px[i])*f + px[i]; vv[nn] = (py[j]-py[i])*f + py[i]; nn++; } } else { if ((du0 < duj) != (du0 < dui)) { f = -(px[i] *(ngux-ngdx*du0) + py[i] *(nguy-ngdy*du0) + (nguo-ngdo*du0)) / ((px[j]-px[i])*(ngux-ngdx*du0) + (py[j]-py[i])*(nguy-ngdy*du0)); uu[nn] = (px[j]-px[i])*f + px[i]; vv[nn] = (py[j]-py[i])*f + py[i]; nn++; } if ((du1 < duj) != (du1 < dui)) { f = -(px[i] *(ngux-ngdx*du1) + py[i] *(nguy-ngdy*du1) + (nguo-ngdo*du1)) / ((px[j]-px[i])*(ngux-ngdx*du1) + (py[j]-py[i])*(nguy-ngdy*du1)); uu[nn] = (px[j]-px[i])*f + px[i]; vv[nn] = (py[j]-py[i])*f + py[i]; nn++; } } i = j; } while (i); if (nn < 3) continue; bglBegin(GL_TRIANGLE_FAN); for (i=0; i GL_TEXTURE0_ARB) { j = GL_TEXTURE0_ARB; while (j <= texunits) bglMultiTexCoord2dARB(j++, (up*r-du0+uoffs)*ox2,vp*r*oy2); } else bglTexCoord2d((up*r-du0+uoffs)*ox2,vp*r*oy2); bglVertex3d((ox-ghalfx)*r*grhalfxdown10x,(ghoriz-oy)*r*grhalfxdown10,r*(1.0/1024.0)); } bglEnd(); } } else { ox2 *= hackscx; oy2 *= hackscy; bglBegin(GL_TRIANGLE_FAN); for (i=0; i GL_TEXTURE0_ARB) { j = GL_TEXTURE0_ARB; while (j <= texunits) bglMultiTexCoord2dARB(j++, uu[i]*r*ox2,vv[i]*r*oy2); } else bglTexCoord2d(uu[i]*r*ox2,vv[i]*r*oy2); bglVertex3d((px[i]-ghalfx)*r*grhalfxdown10x,(ghoriz-py[i])*r*grhalfxdown10,r*(1.0/1024.0)); } bglEnd(); } while (texunits >= GL_TEXTURE0_ARB) { bglActiveTextureARB(texunits); bglMatrixMode(GL_TEXTURE); bglLoadIdentity(); bglMatrixMode(GL_MODELVIEW); if (texunits > GL_TEXTURE0_ARB) { bglTexEnvf(GL_TEXTURE_ENV, GL_RGB_SCALE_ARB, 1.0f); bglDisable(GL_TEXTURE_2D); } texunits--; } if (rendmode == 3) { if (srepeat) bglTexParameteri(GL_TEXTURE_2D,GL_TEXTURE_WRAP_S,glinfo.clamptoedge?GL_CLAMP_TO_EDGE:GL_CLAMP); if (trepeat) bglTexParameteri(GL_TEXTURE_2D,GL_TEXTURE_WRAP_T,glinfo.clamptoedge?GL_CLAMP_TO_EDGE:GL_CLAMP); } if (fullbrightdrawingpass == 1) // tile has fullbright colors ? { int32_t shadeforfullbrightpass = globalshade; // save the current shade fullbrightdrawingpass = 2; globalshade = -128; // fullbright bglDisable(GL_FOG); drawpoly(dpx, dpy, n_, method_); // draw them afterwards, then. :) bglEnable(GL_FOG); globalshade = shadeforfullbrightpass; fullbrightdrawingpass = 0; } return; } #endif if (rendmode == 1) { if (method&3) //Only draw border around sprites/maskwalls { for (i=0,j=n-1; i=2; i--) if (px[i] < px[imin]) imin = i; vsp[vcnt].x = px[imin]; vsp[vcnt].cy[0] = vsp[vcnt].fy[0] = py[imin]; vcnt++; i = imin+1; if (i >= n) i = 0; j = imin-1; if (j < 0) j = n-1; do { if (px[i] < px[j]) { if ((vcnt > 1) && (px[i] <= vsp[vcnt-1].x)) vcnt--; vsp[vcnt].x = px[i]; vsp[vcnt].cy[0] = py[i]; k = j+1; if (k >= n) k = 0; //(px[k],py[k]) //(px[i],?) //(px[j],py[j]) vsp[vcnt].fy[0] = (px[i]-px[k])*(py[j]-py[k])/(px[j]-px[k]) + py[k]; vcnt++; i++; if (i >= n) i = 0; } else if (px[j] < px[i]) { if ((vcnt > 1) && (px[j] <= vsp[vcnt-1].x)) vcnt--; vsp[vcnt].x = px[j]; vsp[vcnt].fy[0] = py[j]; k = i-1; if (k < 0) k = n-1; //(px[k],py[k]) //(px[j],?) //(px[i],py[i]) vsp[vcnt].cy[0] = (px[j]-px[k])*(py[i]-py[k])/(px[i]-px[k]) + py[k]; vcnt++; j--; if (j < 0) j = n-1; } else { if ((vcnt > 1) && (px[i] <= vsp[vcnt-1].x)) vcnt--; vsp[vcnt].x = px[i]; vsp[vcnt].cy[0] = py[i]; vsp[vcnt].fy[0] = py[j]; vcnt++; i++; if (i >= n) i = 0; if (i == j) break; j--; if (j < 0) j = n-1; } } while (i != j); if (px[i] > vsp[vcnt-1].x) { vsp[vcnt].x = px[i]; vsp[vcnt].cy[0] = vsp[vcnt].fy[0] = py[i]; vcnt++; } vsp_finalize_init(vsp, vcnt); gtag = vcnt; } static inline void vsdel(vsptyp *vsp, int32_t i) { int32_t pi, ni; //Delete i pi = vsp[i].p; ni = vsp[i].n; vsp[ni].p = pi; vsp[pi].n = ni; //Add i to empty list vsp[i].n = vsp[VSPMAX-1].n; vsp[i].p = VSPMAX-1; vsp[vsp[VSPMAX-1].n].p = i; vsp[VSPMAX-1].n = i; } static inline int32_t vsinsaft(vsptyp *vsp, int32_t i) { int32_t r; //i = next element from empty list r = vsp[VSPMAX-1].n; vsp[vsp[r].n].p = VSPMAX-1; vsp[VSPMAX-1].n = vsp[r].n; vsp[r] = vsp[i]; //copy i to r //insert r after i vsp[r].p = i; vsp[r].n = vsp[i].n; vsp[vsp[i].n].p = r; vsp[i].n = r; return(r); } static inline int32_t testvisiblemost(float x0, float x1) { int32_t i, newi; for (i=vsp[0].n; i; i=newi) { newi = vsp[i].n; if ((x0 < vsp[newi].x) && (vsp[i].x < x1) && (vsp[i].ctag >= 0)) return(1); } return(0); } static int32_t domostpolymethod = 0; void domost(float x0, float y0, float x1, float y1) { double dpx[4], dpy[4]; float d, f, n, t, slop, dx, dx0, dx1, nx, nx0, ny0, nx1, ny1; float spx[4], /*spy[4],*/ cy[2], cv[2]; int32_t i, j, k, z, ni, vcnt = 0, scnt, newi, dir, spt[4]; alpha = 0.f; if (x0 < x1) { dir = 1; //clip dmost (floor) y0 -= .01f; y1 -= .01f; } else { if (x0 == x1) return; f = x0; x0 = x1; x1 = f; f = y0; y0 = y1; y1 = f; dir = 0; //clip umost (ceiling) //y0 += .01; y1 += .01; //necessary? } slop = (y1-y0)/(x1-x0); for (i=vsp[0].n; i; i=newi) { newi = vsp[i].n; nx0 = vsp[i].x; nx1 = vsp[newi].x; if ((x0 >= nx1) || (nx0 >= x1) || (vsp[i].ctag <= 0)) continue; dx = nx1-nx0; cy[0] = vsp[i].cy[0]; cv[0] = vsp[i].cy[1]-cy[0]; cy[1] = vsp[i].fy[0]; cv[1] = vsp[i].fy[1]-cy[1]; scnt = 0; //Test if left edge requires split (x0,y0) (nx0,cy(0)), if ((x0 > nx0) && (x0 < nx1)) { t = (x0-nx0)*cv[dir] - (y0-cy[dir])*dx; if (((!dir) && (t < 0)) || ((dir) && (t > 0))) { spx[scnt] = x0; /*spy[scnt] = y0;*/ spt[scnt] = -1; scnt++; } } //Test for intersection on umost (j == 0) and dmost (j == 1) for (j=0; j<2; j++) { d = (y0-y1)*dx - (x0-x1)*cv[j]; n = (y0-cy[j])*dx - (x0-nx0)*cv[j]; if ((fabs(n) <= fabs(d)) && (d *n >= 0) && (d != 0)) { t = n/d; nx = (x1-x0)*t + x0; if ((nx > nx0) && (nx < nx1)) { spx[scnt] = nx; /* spy[scnt] = (y1-y0)*t + y0; */ spt[scnt] = j; scnt++; } } } //Nice hack to avoid full sort later :) if ((scnt >= 2) && (spx[scnt-1] < spx[scnt-2])) { f = spx[scnt-1]; spx[scnt-1] = spx[scnt-2]; spx[scnt-2] = f; /* f = spy[scnt-1]; spy[scnt-1] = spy[scnt-2]; spy[scnt-2] = f; */ j = spt[scnt-1]; spt[scnt-1] = spt[scnt-2]; spt[scnt-2] = j; } //Test if right edge requires split if ((x1 > nx0) && (x1 < nx1)) { t = (x1-nx0)*cv[dir] - (y1-cy[dir])*dx; if (((!dir) && (t < 0)) || ((dir) && (t > 0))) { spx[scnt] = x1; /* spy[scnt] = y1; */ spt[scnt] = -1; scnt++; } } vsp[i].tag = vsp[newi].tag = -1; for (z=0; z<=scnt; z++,i=vcnt) { if (z < scnt) { vcnt = vsinsaft(vsp, i); t = (spx[z]-nx0)/dx; vsp[i].cy[1] = t*cv[0] + cy[0]; vsp[i].fy[1] = t*cv[1] + cy[1]; vsp[vcnt].x = spx[z]; vsp[vcnt].cy[0] = vsp[i].cy[1]; vsp[vcnt].fy[0] = vsp[i].fy[1]; vsp[vcnt].tag = spt[z]; } ni = vsp[i].n; if (!ni) continue; //this 'if' fixes many bugs! dx0 = vsp[i].x; if (x0 > dx0) continue; dx1 = vsp[ni].x; if (x1 < dx1) continue; ny0 = (dx0-x0)*slop + y0; ny1 = (dx1-x0)*slop + y0; // dx0 dx1 // ~ ~ //---------------------------- // t0+=0 t1+=0 // vsp[i].cy[0] vsp[i].cy[1] //============================ // t0+=1 t1+=3 //============================ // vsp[i].fy[0] vsp[i].fy[1] // t0+=2 t1+=6 // // ny0 ? ny1 ? k = 1+3; if ((vsp[i].tag == 0) || (ny0 <= vsp[i].cy[0]+.01)) k--; if ((vsp[i].tag == 1) || (ny0 >= vsp[i].fy[0]-.01)) k++; if ((vsp[ni].tag == 0) || (ny1 <= vsp[i].cy[1]+.01)) k -= 3; if ((vsp[ni].tag == 1) || (ny1 >= vsp[i].fy[1]-.01)) k += 3; if (!dir) { dpx[0] = dx0; dpy[0] = vsp[i].cy[0]; dpx[1] = dx1; dpy[1] = vsp[i].cy[1]; switch (k) { case 1: case 2: dpx[2] = dx0; dpy[2] = ny0; drawpoly(dpx,dpy,3,domostpolymethod); vsp[i].cy[0] = ny0; vsp[i].ctag = gtag; break; case 3: case 6: dpx[2] = dx1; dpy[2] = ny1; drawpoly(dpx,dpy,3,domostpolymethod); vsp[i].cy[1] = ny1; vsp[i].ctag = gtag; break; case 4: case 5: case 7: dpx[2] = dx1; dpy[2] = ny1; dpx[3] = dx0; dpy[3] = ny0; drawpoly(dpx,dpy,4,domostpolymethod); vsp[i].cy[0] = ny0; vsp[i].cy[1] = ny1; vsp[i].ctag = gtag; break; case 8: dpx[2] = dx1; dpy[2] = vsp[i].fy[1]; dpx[3] = dx0; dpy[3] = vsp[i].fy[0]; drawpoly(dpx,dpy,4,domostpolymethod); vsp[i].ctag = vsp[i].ftag = -1; break; default: break; } } else { switch (k) { case 7: case 6: dpx[0] = dx0; dpy[0] = ny0; dpx[1] = dx1; dpy[1] = vsp[i].fy[1]; dpx[2] = dx0; dpy[2] = vsp[i].fy[0]; drawpoly(dpx,dpy,3,domostpolymethod); vsp[i].fy[0] = ny0; vsp[i].ftag = gtag; break; case 5: case 2: dpx[0] = dx0; dpy[0] = vsp[i].fy[0]; dpx[1] = dx1; dpy[1] = ny1; dpx[2] = dx1; dpy[2] = vsp[i].fy[1]; drawpoly(dpx,dpy,3,domostpolymethod); vsp[i].fy[1] = ny1; vsp[i].ftag = gtag; break; case 4: case 3: case 1: dpx[0] = dx0; dpy[0] = ny0; dpx[1] = dx1; dpy[1] = ny1; dpx[2] = dx1; dpy[2] = vsp[i].fy[1]; dpx[3] = dx0; dpy[3] = vsp[i].fy[0]; drawpoly(dpx,dpy,4,domostpolymethod); vsp[i].fy[0] = ny0; vsp[i].fy[1] = ny1; vsp[i].ftag = gtag; break; case 0: dpx[0] = dx0; dpy[0] = vsp[i].cy[0]; dpx[1] = dx1; dpy[1] = vsp[i].cy[1]; dpx[2] = dx1; dpy[2] = vsp[i].fy[1]; dpx[3] = dx0; dpy[3] = vsp[i].fy[0]; drawpoly(dpx,dpy,4,domostpolymethod); vsp[i].ctag = vsp[i].ftag = -1; break; default: break; } } } } gtag++; //Combine neighboring vertical strips with matching collinear top&bottom edges //This prevents x-splits from propagating through the entire scan i = vsp[0].n; while (i) { ni = vsp[i].n; if ((vsp[i].cy[0] >= vsp[i].fy[0]) && (vsp[i].cy[1] >= vsp[i].fy[1])) vsp[i].ctag = vsp[i].ftag = -1; if ((vsp[i].ctag == vsp[ni].ctag) && (vsp[i].ftag == vsp[ni].ftag)) { vsp[i].cy[1] = vsp[ni].cy[1]; vsp[i].fy[1] = vsp[ni].fy[1]; vsdel(vsp, ni); } else i = ni; } } void polymost_scansector(int32_t sectnum); // variables that are set to ceiling- or floor-members, depending // on which one is processed right now static int32_t global_cf_z; static float global_cf_xpanning, global_cf_ypanning, global_cf_heinum; static int32_t global_cf_shade, global_cf_pal; static int32_t (*global_getzofslope_func)(int16_t, int32_t, int32_t); static void polymost_internal_nonparallaxed(double nx0, double ny0, double nx1, double ny1, double ryp0, double ryp1, double x0, double x1, double cf_y0, double cf_y1, int32_t have_floor, int32_t sectnum) { double ft[4], fx, fy, ox, oy, oz, ox2, oy2; double px[3], py[3], dd[3], uu[3], vv[3], r; int32_t i; const sectortype *sec = §or[sectnum]; // comments from floor code: //(singlobalang/-16384*(sx-ghalfx) + 0*(sy-ghoriz) + (cosviewingrangeglobalang/16384)*ghalfx)*d + globalposx = u*16 //(cosglobalang/ 16384*(sx-ghalfx) + 0*(sy-ghoriz) + (sinviewingrangeglobalang/16384)*ghalfx)*d + globalposy = v*16 //( 0*(sx-ghalfx) + 1*(sy-ghoriz) + ( 0)*ghalfx)*d + globalposz/16 = (sec->floorz/16) if (!(globalorientation&64)) { ft[0] = globalposx; ft[1] = globalposy; ft[2] = cosglobalang; ft[3] = singlobalang; } else { //relative alignment fx = (double)(wall[wall[sec->wallptr].point2].x-wall[sec->wallptr].x); fy = (double)(wall[wall[sec->wallptr].point2].y-wall[sec->wallptr].y); r = 1.0/sqrt(fx*fx+fy*fy); fx *= r; fy *= r; ft[2] = cosglobalang*fx + singlobalang*fy; ft[3] = singlobalang*fx - cosglobalang*fy; ft[0] = ((double)(globalposx-wall[sec->wallptr].x))*fx + ((double)(globalposy-wall[sec->wallptr].y))*fy; ft[1] = ((double)(globalposy-wall[sec->wallptr].y))*fx - ((double)(globalposx-wall[sec->wallptr].x))*fy; if (!(globalorientation&4)) globalorientation ^= 32; else globalorientation ^= 16; } gdx = 0; gdy = gxyaspect; if (!(globalorientation&2)) if (global_cf_z-globalposz) // PK 2012: don't allow div by zero gdy /= (double)(global_cf_z-globalposz); gdo = -ghoriz*gdy; if (globalorientation&8) { ft[0] /= 8; ft[1] /= -8; ft[2] /= 2097152; ft[3] /= 2097152; } else { ft[0] /= 16; ft[1] /= -16; ft[2] /= 4194304; ft[3] /= 4194304; } gux = (double)ft[3]*((double)viewingrange)/-65536.0; gvx = (double)ft[2]*((double)viewingrange)/-65536.0; guy = (double)ft[0]*gdy; gvy = (double)ft[1]*gdy; guo = (double)ft[0]*gdo; gvo = (double)ft[1]*gdo; guo += (double)(ft[2]-gux)*ghalfx; gvo -= (double)(ft[3]+gvx)*ghalfx; //Texture flipping if (globalorientation&4) { r = gux; gux = gvx; gvx = r; r = guy; guy = gvy; gvy = r; r = guo; guo = gvo; gvo = r; } if (globalorientation&16) { gux = -gux; guy = -guy; guo = -guo; } if (globalorientation&32) { gvx = -gvx; gvy = -gvy; gvo = -gvo; } //Texture panning fx = global_cf_xpanning*((float)(1<<(picsiz[globalpicnum]&15)))/256.0; fy = global_cf_ypanning*((float)(1<<(picsiz[globalpicnum]>>4)))/256.0; if ((globalorientation&(2+64)) == (2+64)) //Hack for panning for slopes w/ relative alignment { r = global_cf_heinum / 4096.0; r = 1.0/sqrt(r*r+1); if (!(globalorientation&4)) fy *= r; else fx *= r; } guy += gdy*fx; guo += gdo*fx; gvy += gdy*fy; gvo += gdo*fy; if (globalorientation&2) //slopes { px[0] = x0; py[0] = ryp0 + ghoriz; px[1] = x1; py[1] = ryp1 + ghoriz; //Pick some point guaranteed to be not collinear to the 1st two points ox = nx0 + (ny1-ny0); oy = ny0 + (nx0-nx1); ox2 = (double)(oy-globalposy)*gcosang - (double)(ox-globalposx)*gsinang ; oy2 = (double)(ox-globalposx)*gcosang2 + (double)(oy-globalposy)*gsinang2; oy2 = 1.0/oy2; px[2] = ghalfx*ox2*oy2 + ghalfx; oy2 *= gyxscale; py[2] = oy2 + ghoriz; for (i=0; i<3; i++) { dd[i] = px[i]*gdx + py[i]*gdy + gdo; uu[i] = px[i]*gux + py[i]*guy + guo; vv[i] = px[i]*gvx + py[i]*gvy + gvo; } py[0] = cf_y0; py[1] = cf_y1; py[2] = (global_getzofslope_func(sectnum,(int32_t)ox,(int32_t)oy)-globalposz)*oy2 + ghoriz; ox = py[1]-py[2]; oy = py[2]-py[0]; oz = py[0]-py[1]; r = 1.0 / (ox*px[0] + oy*px[1] + oz*px[2]); gdx = (ox*dd[0] + oy*dd[1] + oz*dd[2])*r; gux = (ox*uu[0] + oy*uu[1] + oz*uu[2])*r; gvx = (ox*vv[0] + oy*vv[1] + oz*vv[2])*r; ox = px[2]-px[1]; oy = px[0]-px[2]; oz = px[1]-px[0]; gdy = (ox*dd[0] + oy*dd[1] + oz*dd[2])*r; guy = (ox*uu[0] + oy*uu[1] + oz*uu[2])*r; gvy = (ox*vv[0] + oy*vv[1] + oz*vv[2])*r; gdo = dd[0] - px[0]*gdx - py[0]*gdy; guo = uu[0] - px[0]*gux - py[0]*guy; gvo = vv[0] - px[0]*gvx - py[0]*gvy; if (globalorientation&64) //Hack for relative alignment on slopes { r = global_cf_heinum / 4096.0; r = sqrt(r*r+1); if (!(globalorientation&4)) { gvx *= r; gvy *= r; gvo *= r; } else { gux *= r; guy *= r; guo *= r; } } } domostpolymethod = (globalorientation>>7)&3; if (have_floor) { if (globalposz >= getflorzofslope(sectnum,globalposx,globalposy)) domostpolymethod = -1; //Back-face culling } else { if (globalposz <= getceilzofslope(sectnum,globalposx,globalposy)) domostpolymethod = -1; //Back-face culling } calc_and_apply_fog(global_cf_shade, sec->visibility, global_cf_pal); pow2xsplit = 0; alpha = 0.f; if (have_floor) domost(x0,cf_y0,x1,cf_y1); //flor else domost(x1,cf_y1,x0,cf_y0); //ceil domostpolymethod = 0; } static void calc_ypanning(int32_t refposz, double ryp0, double ryp1, double x0, double x1, uint8_t ypan, uint8_t yrepeat, int32_t dopancor) { int32_t i; double t0, t1, t, fy; int32_t yoffs; // for panning "correction" t0 = ((float)(refposz-globalposz))*ryp0 + ghoriz; t1 = ((float)(refposz-globalposz))*ryp1 + ghoriz; t = ((gdx*x0 + gdo) * (float)yrepeat) / ((x1-x0) * ryp0 * 2048.f); i = (1<<(picsiz[globalpicnum]>>4)); if (i < tilesizy[globalpicnum]) i <<= 1; if (dopancor) { ftol((i-tilesizy[globalpicnum])*(255.f/i), &yoffs); if (ypan>256-yoffs) { ypan-=yoffs; } } else { // (1) // not hacked yet // (2) // Still need a hack, depending on the wall(height,ypanning,yrepeat,tilesizy) // it should do "ypan-=yoffs" or "ypan+=yoffs" or [nothing]. // Example: the film projector in the E1L1.map needs "ypan-=yoffs" } fy = (float)ypan * ((float)i) / 256.0; gvx = (t0-t1)*t; gvy = (x1-x0)*t; gvo = -gvx*x0 - gvy*t0 + fy*gdo; gvx += fy*gdx; gvy += fy*gdy; } static void polymost_drawalls(int32_t bunch) { sectortype *sec, *nextsec; walltype *wal, *wal2, *nwal; double ox, oy, oz, dd[3], vv[3]; double fx, x0, x1, cy0, cy1, fy0, fy1, xp0, yp0, xp1, yp1, ryp0, ryp1, nx0, ny0, nx1, ny1; double t, r, t0, t1, ocy0, ocy1, ofy0, ofy1, oxp0, oyp0, ft[4]; double oguo, ogux, oguy; int32_t i, x, y, z, cz, fz, wallnum, sectnum, nextsectnum; int16_t dapskybits; static const int16_t zeropskyoff[MAXPSKYTILES] = { 0 }; const int16_t *dapskyoff; alpha = 0.f; sectnum = thesector[bunchfirst[bunch]]; sec = §or[sectnum]; //DRAW WALLS SECTION! for (z=bunchfirst[bunch]; z>=0; z=p2[z]) { wallnum = thewall[z]; wal = &wall[wallnum]; wal2 = &wall[wal->point2]; nextsectnum = wal->nextsector; nextsec = nextsectnum>=0 ? §or[nextsectnum] : NULL; #ifdef YAX_ENABLE if (yax_nomaskpass==1 && yax_isislandwall(wallnum, !yax_globalcf) && (yax_nomaskdidit=1)) continue; #endif //Offset&Rotate 3D coordinates to screen 3D space x = wal->x-globalposx; y = wal->y-globalposy; xp0 = (double)y*gcosang - (double)x*gsinang; yp0 = (double)x*gcosang2 + (double)y*gsinang2; x = wal2->x-globalposx; y = wal2->y-globalposy; xp1 = (double)y*gcosang - (double)x*gsinang; yp1 = (double)x*gcosang2 + (double)y*gsinang2; oxp0 = xp0; oyp0 = yp0; //Clip to close parallel-screen plane if (yp0 < SCISDIST) { if (yp1 < SCISDIST) continue; t0 = (SCISDIST-yp0)/(yp1-yp0); xp0 = (xp1-xp0)*t0+xp0; yp0 = SCISDIST; nx0 = (wal2->x-wal->x)*t0+wal->x; ny0 = (wal2->y-wal->y)*t0+wal->y; } else { t0 = 0.f; nx0 = wal->x; ny0 = wal->y; } if (yp1 < SCISDIST) { t1 = (SCISDIST-oyp0)/(yp1-oyp0); xp1 = (xp1-oxp0)*t1+oxp0; yp1 = SCISDIST; nx1 = (wal2->x-wal->x)*t1+wal->x; ny1 = (wal2->y-wal->y)*t1+wal->y; } else { t1 = 1.f; nx1 = wal2->x; ny1 = wal2->y; } ryp0 = 1.f/yp0; ryp1 = 1.f/yp1; //Generate screen coordinates for front side of wall x0 = ghalfx*xp0*ryp0 + ghalfx; x1 = ghalfx*xp1*ryp1 + ghalfx; if (x1 <= x0) continue; ryp0 *= gyxscale; ryp1 *= gyxscale; getzsofslope(sectnum,(int32_t)nx0,(int32_t)ny0,&cz,&fz); cy0 = ((float)(cz-globalposz))*ryp0 + ghoriz; fy0 = ((float)(fz-globalposz))*ryp0 + ghoriz; getzsofslope(sectnum,(int32_t)nx1,(int32_t)ny1,&cz,&fz); cy1 = ((float)(cz-globalposz))*ryp1 + ghoriz; fy1 = ((float)(fz-globalposz))*ryp1 + ghoriz; globalpicnum = sec->floorpicnum; globalshade = sec->floorshade; globalpal = (int32_t)((uint8_t)sec->floorpal); globalorientation = sec->floorstat; DO_TILE_ANIM(globalpicnum, sectnum); // multi-psky stuff dapskyoff = zeropskyoff; dapskybits = pskybits; for (i=0; ifloorshade, global_cf_pal = sec->floorpal; global_cf_z = sec->floorz; // REFACT global_cf_xpanning = sec->floorxpanning; global_cf_ypanning = sec->floorypanning, global_cf_heinum = sec->floorheinum; global_getzofslope_func = &getflorzofslope; if (!(globalorientation&1)) { #ifdef YAX_ENABLE if (globalposz <= sec->floorz || yax_getbunch(sectnum, YAX_FLOOR) < 0 || yax_getnextwall(wallnum, YAX_FLOOR) >= 0) #endif polymost_internal_nonparallaxed(nx0, ny0, nx1, ny1, ryp0, ryp1, x0, x1, fy0, fy1, 1, sectnum); } else if ((nextsectnum < 0) || (!(sector[nextsectnum].floorstat&1))) { //Parallaxing sky... hacked for Ken's mountain texture; paper-sky only :/ #ifdef USE_OPENGL if (rendmode >= 3) { calc_and_apply_fog_factor(sec->floorshade, sec->visibility, sec->floorpal, 0.005); //Use clamping for tiled sky textures for (i=(1<0; i--) if (dapskyoff[i] != dapskyoff[i-1]) { skyclamphack = r_parallaxskyclamping; break; } } #endif if (bpp == 8 || !usehightile || !hicfindsubst(globalpicnum,globalpal,1)) { dd[0] = (float)xdimen*.0000001; //Adjust sky depth based on screen size! t = (double)((1<<(picsiz[globalpicnum]&15))<>1)+parallaxyoffs)) - vv[1]*ghoriz; i = (1<<(picsiz[globalpicnum]>>4)); if (i != tilesizy[globalpicnum]) i += i; //Hack to draw black rectangle below sky when looking down... gdx = 0; gdy = gxyaspect / 262144.0; gdo = -ghoriz*gdy; gux = 0; guy = 0; guo = 0; gvx = 0; gvy = (double)(tilesizy[globalpicnum]-1)*gdy; gvo = (double)(tilesizy[globalpicnum-1])*gdo; oy = (((double)tilesizy[globalpicnum])*dd[0]-vv[0])/vv[1]; if ((oy > fy0) && (oy > fy1)) domost(x0,oy,x1,oy); else if ((oy > fy0) != (oy > fy1)) { // fy0 fy1 // \ / //oy---------- oy---------- // \ / // fy1 fy0 ox = (oy-fy0)*(x1-x0)/(fy1-fy0) + x0; if (oy > fy0) { domost(x0,oy,ox,oy); domost(ox,oy,x1,fy1); } else { domost(x0,fy0,ox,oy); domost(ox,oy,x1,oy); } } else domost(x0,fy0,x1,fy1); if (r_parallaxskypanning) vv[0] += dd[0]*((double)sec->floorypanning)*((double)i)/256.0; gdx = 0; gdy = 0; gdo = dd[0]; gux = gdo*(t*((double)xdimscale)*((double)yxaspect)*((double)viewingrange))/(16384.0*65536.0*65536.0*5.0*1024.0); guy = 0; //guo calculated later gvx = 0; gvy = vv[1]; gvo = vv[0]; i = globalpicnum; r = (fy1-fy0)/(x1-x0); //slope of line oy = ((double)viewingrange)/(ghalfx*256.0); oz = 1/oy; y = ((((int32_t)((x0-ghalfx)*oy))+globalang)>>(11-dapskybits)); fx = x0; do { globalpicnum = dapskyoff[y&((1<floorxpanning:0)) - gux*ghalfx; y++; ox = fx; fx = ((double)((y<<(11-dapskybits))-globalang))*oz+ghalfx; if (fx > x1) { fx = x1; i = -1; } pow2xsplit = 0; domost(ox,(ox-x0)*r+fy0,fx,(fx-x0)*r+fy0); //flor } while (i >= 0); } else //NOTE: code copied from ceiling code... lots of duplicated stuff :/ { //Skybox code for parallax ceiling! double _xp0, _yp0, _xp1, _yp1, _oxp0, _oyp0, _t0, _t1; // _nx0, _ny0, _nx1, _ny1; double _ryp0, _ryp1, _x0, _x1, _cy0, _fy0, _cy1, _fy1, _ox0, _ox1; double nfy0, nfy1; int32_t skywalx[4] = {-512,512,512,-512}, skywaly[4] = {-512,-512,512,512}; pow2xsplit = 0; skyclamphack = 1; for (i=0; i<4; i++) { x = skywalx[i&3]; y = skywaly[i&3]; _xp0 = (double)y*gcosang - (double)x*gsinang; _yp0 = (double)x*gcosang2 + (double)y*gsinang2; x = skywalx[(i+1)&3]; y = skywaly[(i+1)&3]; _xp1 = (double)y*gcosang - (double)x*gsinang; _yp1 = (double)x*gcosang2 + (double)y*gsinang2; _oxp0 = _xp0; _oyp0 = _yp0; //Clip to close parallel-screen plane if (_yp0 < SCISDIST) { if (_yp1 < SCISDIST) continue; _t0 = (SCISDIST-_yp0)/(_yp1-_yp0); _xp0 = (_xp1-_xp0)*_t0+_xp0; _yp0 = SCISDIST; // _nx0 = (skywalx[(i+1)&3]-skywalx[i&3])*_t0+skywalx[i&3]; // _ny0 = (skywaly[(i+1)&3]-skywaly[i&3])*_t0+skywaly[i&3]; } else { _t0 = 0.f; /*_nx0 = skywalx[i&3]; _ny0 = skywaly[i&3];*/ } if (_yp1 < SCISDIST) { _t1 = (SCISDIST-_oyp0)/(_yp1-_oyp0); _xp1 = (_xp1-_oxp0)*_t1+_oxp0; _yp1 = SCISDIST; // _nx1 = (skywalx[(i+1)&3]-skywalx[i&3])*_t1+skywalx[i&3]; // _ny1 = (skywaly[(i+1)&3]-skywaly[i&3])*_t1+skywaly[i&3]; } else { _t1 = 1.f; /*_nx1 = skywalx[(i+1)&3]; _ny1 = skywaly[(i+1)&3];*/ } _ryp0 = 1.f/_yp0; _ryp1 = 1.f/_yp1; //Generate screen coordinates for front side of wall _x0 = ghalfx*_xp0*_ryp0 + ghalfx; _x1 = ghalfx*_xp1*_ryp1 + ghalfx; if (_x1 <= _x0) continue; if ((_x0 >= x1) || (x0 >= _x1)) continue; _ryp0 *= gyxscale; _ryp1 *= gyxscale; _cy0 = -8192.f*_ryp0 + ghoriz; _fy0 = 8192.f*_ryp0 + ghoriz; _cy1 = -8192.f*_ryp1 + ghoriz; _fy1 = 8192.f*_ryp1 + ghoriz; _ox0 = _x0; _ox1 = _x1; //Make sure: x0<=_x0<_x1<=_x1 nfy0 = fy0; nfy1 = fy1; if (_x0 < x0) { t = (x0-_x0)/(_x1-_x0); _cy0 += (_cy1-_cy0)*t; _fy0 += (_fy1-_fy0)*t; _x0 = x0; } else if (_x0 > x0) nfy0 += (_x0-x0)*(fy1-fy0)/(x1-x0); if (_x1 > x1) { t = (x1-_x1)/(_x1-_x0); _cy1 += (_cy1-_cy0)*t; _fy1 += (_fy1-_fy0)*t; _x1 = x1; } else if (_x1 < x1) nfy1 += (_x1-x1)*(fy1-fy0)/(x1-x0); // (skybox floor) //(_x0,_fy0)-(_x1,_fy1) // (skybox wall) //(_x0,_cy0)-(_x1,_cy1) // (skybox ceiling) //(_x0,nfy0)-(_x1,nfy1) //ceiling of skybox ft[0] = 512/16; ft[1] = 512/-16; ft[2] = ((float)cosglobalang)*(1.f/2147483648.f); ft[3] = ((float)singlobalang)*(1.f/2147483648.f); gdx = 0; gdy = gxyaspect*(1.f/4194304.f); gdo = -ghoriz*gdy; gux = (double)ft[3]*((double)viewingrange)/-65536.0; gvx = (double)ft[2]*((double)viewingrange)/-65536.0; guy = (double)ft[0]*gdy; gvy = (double)ft[1]*gdy; guo = (double)ft[0]*gdo; gvo = (double)ft[1]*gdo; guo += (double)(ft[2]-gux)*ghalfx; gvo -= (double)(ft[3]+gvx)*ghalfx; gvx = -gvx; gvy = -gvy; gvo = -gvo; //y-flip skybox floor #ifdef USE_OPENGL drawingskybox = 6; //ceiling/5th texture/index 4 of skybox #endif if ((_fy0 > nfy0) && (_fy1 > nfy1)) domost(_x0,_fy0,_x1,_fy1); else if ((_fy0 > nfy0) != (_fy1 > nfy1)) { //(ox,oy) is intersection of: (_x0,_cy0)-(_x1,_cy1) // (_x0,nfy0)-(_x1,nfy1) //ox = _x0 + (_x1-_x0)*t //oy = _cy0 + (_cy1-_cy0)*t //oy = nfy0 + (nfy1-nfy0)*t t = (_fy0-nfy0)/(nfy1-nfy0-_fy1+_fy0); ox = _x0 + (_x1-_x0)*t; oy = _fy0 + (_fy1-_fy0)*t; if (nfy0 > _fy0) { domost(_x0,nfy0,ox,oy); domost(ox,oy,_x1,_fy1); } else { domost(_x0,_fy0,ox,oy); domost(ox,oy,_x1,nfy1); } } else domost(_x0,nfy0,_x1,nfy1); //wall of skybox #ifdef USE_OPENGL drawingskybox = i+1; //i+1th texture/index i of skybox #endif gdx = (_ryp0-_ryp1)*gxyaspect*(1.f/512.f) / (_ox0-_ox1); gdy = 0; gdo = _ryp0*gxyaspect*(1.f/512.f) - gdx*_ox0; gux = (_t0*_ryp0 - _t1*_ryp1)*gxyaspect*(64.f/512.f) / (_ox0-_ox1); guo = _t0*_ryp0*gxyaspect*(64.f/512.f) - gux*_ox0; guy = 0; _t0 = -8192.0*_ryp0 + ghoriz; _t1 = -8192.0*_ryp1 + ghoriz; t = ((gdx*_ox0 + gdo)*8.f) / ((_ox1-_ox0) * _ryp0 * 2048.f); gvx = (_t0-_t1)*t; gvy = (_ox1-_ox0)*t; gvo = -gvx*_ox0 - gvy*_t0; if ((_cy0 > nfy0) && (_cy1 > nfy1)) domost(_x0,_cy0,_x1,_cy1); else if ((_cy0 > nfy0) != (_cy1 > nfy1)) { //(ox,oy) is intersection of: (_x0,_fy0)-(_x1,_fy1) // (_x0,nfy0)-(_x1,nfy1) //ox = _x0 + (_x1-_x0)*t //oy = _fy0 + (_fy1-_fy0)*t //oy = nfy0 + (nfy1-nfy0)*t t = (_cy0-nfy0)/(nfy1-nfy0-_cy1+_cy0); ox = _x0 + (_x1-_x0)*t; oy = _cy0 + (_cy1-_cy0)*t; if (nfy0 > _cy0) { domost(_x0,nfy0,ox,oy); domost(ox,oy,_x1,_cy1); } else { domost(_x0,_cy0,ox,oy); domost(ox,oy,_x1,nfy1); } } else domost(_x0,nfy0,_x1,nfy1); } //Floor of skybox #ifdef USE_OPENGL drawingskybox = 5; //floor/6th texture/index 5 of skybox #endif ft[0] = 512/16; ft[1] = -512/-16; ft[2] = ((float)cosglobalang)*(1.f/2147483648.f); ft[3] = ((float)singlobalang)*(1.f/2147483648.f); gdx = 0; gdy = gxyaspect*(-1.f/4194304.f); gdo = -ghoriz*gdy; gux = (double)ft[3]*((double)viewingrange)/-65536.0; gvx = (double)ft[2]*((double)viewingrange)/-65536.0; guy = (double)ft[0]*gdy; gvy = (double)ft[1]*gdy; guo = (double)ft[0]*gdo; gvo = (double)ft[1]*gdo; guo += (double)(ft[2]-gux)*ghalfx; gvo -= (double)(ft[3]+gvx)*ghalfx; domost(x0,fy0,x1,fy1); skyclamphack = 0; #ifdef USE_OPENGL drawingskybox = 0; #endif } #ifdef USE_OPENGL if (rendmode >= 3) { skyclamphack = 0; if (!nofog) bglEnable(GL_FOG); } #endif } globalpicnum = sec->ceilingpicnum; globalshade = sec->ceilingshade; globalpal = (int32_t)((uint8_t)sec->ceilingpal); globalorientation = sec->ceilingstat; DO_TILE_ANIM(globalpicnum, sectnum); // multi-psky stuff dapskyoff = zeropskyoff; dapskybits = pskybits; for (i=0; iceilingshade, global_cf_pal = sec->ceilingpal; global_cf_z = sec->ceilingz; // REFACT global_cf_xpanning = sec->ceilingxpanning; global_cf_ypanning = sec->ceilingypanning, global_cf_heinum = sec->ceilingheinum; global_getzofslope_func = &getceilzofslope; if (!(globalorientation&1)) { #ifdef YAX_ENABLE if (globalposz >= sec->ceilingz || yax_getbunch(sectnum, YAX_CEILING) < 0 || yax_getnextwall(wallnum, YAX_CEILING) >= 0) #endif polymost_internal_nonparallaxed(nx0, ny0, nx1, ny1, ryp0, ryp1, x0, x1, cy0, cy1, 0, sectnum); } else if ((nextsectnum < 0) || (!(sector[nextsectnum].ceilingstat&1))) { #ifdef USE_OPENGL if (rendmode >= 3) { calc_and_apply_fog_factor(sec->ceilingshade, sec->visibility, sec->ceilingpal, 0.005); //Use clamping for tiled sky textures for (i=(1<0; i--) if (dapskyoff[i] != dapskyoff[i-1]) { skyclamphack = r_parallaxskyclamping; break; } } #endif //Parallaxing sky... if (bpp == 8 || !usehightile || !hicfindsubst(globalpicnum,globalpal,1)) { //Render for parallaxtype == 0 / paper-sky dd[0] = (float)xdimen*.0000001; //Adjust sky depth based on screen size! t = (double)((1<<(picsiz[globalpicnum]&15))<>1)+parallaxyoffs)) - vv[1]*ghoriz; i = (1<<(picsiz[globalpicnum]>>4)); if (i != tilesizy[globalpicnum]) i += i; //Hack to draw black rectangle below sky when looking down... gdx = 0; gdy = gxyaspect / -262144.0; gdo = -ghoriz*gdy; gux = 0; guy = 0; guo = 0; gvx = 0; gvy = 0; gvo = 0; oy = -vv[0]/vv[1]; if ((oy < cy0) && (oy < cy1)) domost(x1,oy,x0,oy); else if ((oy < cy0) != (oy < cy1)) { /* cy1 cy0 // / \ //oy---------- oy--------- // / \ // cy0 cy1 */ ox = (oy-cy0)*(x1-x0)/(cy1-cy0) + x0; if (oy < cy0) { domost(ox,oy,x0,oy); domost(x1,cy1,ox,oy); } else { domost(ox,oy,x0,cy0); domost(x1,oy,ox,oy); } } else domost(x1,cy1,x0,cy0); if (r_parallaxskypanning) vv[0] += dd[0]*((double)sec->ceilingypanning)*((double)i)/256.0; gdx = 0; gdy = 0; gdo = dd[0]; gux = gdo*(t*((double)xdimscale)*((double)yxaspect)*((double)viewingrange))/(16384.0*65536.0*65536.0*5.0*1024.0); guy = 0; //guo calculated later gvx = 0; gvy = vv[1]; gvo = vv[0]; i = globalpicnum; r = (cy1-cy0)/(x1-x0); //slope of line oy = ((double)viewingrange)/(ghalfx*256.0); oz = 1/oy; y = ((((int32_t)((x0-ghalfx)*oy))+globalang)>>(11-dapskybits)); fx = x0; do { globalpicnum = dapskyoff[y&((1<ceilingxpanning:0)) - gux*ghalfx; y++; ox = fx; fx = ((double)((y<<(11-dapskybits))-globalang))*oz+ghalfx; if (fx > x1) { fx = x1; i = -1; } pow2xsplit = 0; domost(fx,(fx-x0)*r+cy0,ox,(ox-x0)*r+cy0); //ceil } while (i >= 0); } else { //Skybox code for parallax ceiling! double _xp0, _yp0, _xp1, _yp1, _oxp0, _oyp0, _t0, _t1; // _nx0, _ny0, _nx1, _ny1; double _ryp0, _ryp1, _x0, _x1, _cy0, _fy0, _cy1, _fy1, _ox0, _ox1; double ncy0, ncy1; int32_t skywalx[4] = {-512,512,512,-512}, skywaly[4] = {-512,-512,512,512}; pow2xsplit = 0; skyclamphack = 1; for (i=0; i<4; i++) { x = skywalx[i&3]; y = skywaly[i&3]; _xp0 = (double)y*gcosang - (double)x*gsinang; _yp0 = (double)x*gcosang2 + (double)y*gsinang2; x = skywalx[(i+1)&3]; y = skywaly[(i+1)&3]; _xp1 = (double)y*gcosang - (double)x*gsinang; _yp1 = (double)x*gcosang2 + (double)y*gsinang2; _oxp0 = _xp0; _oyp0 = _yp0; //Clip to close parallel-screen plane if (_yp0 < SCISDIST) { if (_yp1 < SCISDIST) continue; _t0 = (SCISDIST-_yp0)/(_yp1-_yp0); _xp0 = (_xp1-_xp0)*_t0+_xp0; _yp0 = SCISDIST; // _nx0 = (skywalx[(i+1)&3]-skywalx[i&3])*_t0+skywalx[i&3]; // _ny0 = (skywaly[(i+1)&3]-skywaly[i&3])*_t0+skywaly[i&3]; } else { _t0 = 0.f; /*_nx0 = skywalx[i&3]; _ny0 = skywaly[i&3];*/ } if (_yp1 < SCISDIST) { _t1 = (SCISDIST-_oyp0)/(_yp1-_oyp0); _xp1 = (_xp1-_oxp0)*_t1+_oxp0; _yp1 = SCISDIST; // _nx1 = (skywalx[(i+1)&3]-skywalx[i&3])*_t1+skywalx[i&3]; // _ny1 = (skywaly[(i+1)&3]-skywaly[i&3])*_t1+skywaly[i&3]; } else { _t1 = 1.f; /*_nx1 = skywalx[(i+1)&3]; _ny1 = skywaly[(i+1)&3];*/ } _ryp0 = 1.f/_yp0; _ryp1 = 1.f/_yp1; //Generate screen coordinates for front side of wall _x0 = ghalfx*_xp0*_ryp0 + ghalfx; _x1 = ghalfx*_xp1*_ryp1 + ghalfx; if (_x1 <= _x0) continue; if ((_x0 >= x1) || (x0 >= _x1)) continue; _ryp0 *= gyxscale; _ryp1 *= gyxscale; _cy0 = -8192.f*_ryp0 + ghoriz; _fy0 = 8192.f*_ryp0 + ghoriz; _cy1 = -8192.f*_ryp1 + ghoriz; _fy1 = 8192.f*_ryp1 + ghoriz; _ox0 = _x0; _ox1 = _x1; //Make sure: x0<=_x0<_x1<=_x1 ncy0 = cy0; ncy1 = cy1; if (_x0 < x0) { t = (x0-_x0)/(_x1-_x0); _cy0 += (_cy1-_cy0)*t; _fy0 += (_fy1-_fy0)*t; _x0 = x0; } else if (_x0 > x0) ncy0 += (_x0-x0)*(cy1-cy0)/(x1-x0); if (_x1 > x1) { t = (x1-_x1)/(_x1-_x0); _cy1 += (_cy1-_cy0)*t; _fy1 += (_fy1-_fy0)*t; _x1 = x1; } else if (_x1 < x1) ncy1 += (_x1-x1)*(cy1-cy0)/(x1-x0); // (skybox ceiling) //(_x0,_cy0)-(_x1,_cy1) // (skybox wall) //(_x0,_fy0)-(_x1,_fy1) // (skybox floor) //(_x0,ncy0)-(_x1,ncy1) //ceiling of skybox #ifdef USE_OPENGL drawingskybox = 5; //ceiling/5th texture/index 4 of skybox #endif ft[0] = 512/16; ft[1] = -512/-16; ft[2] = ((float)cosglobalang)*(1.f/2147483648.f); ft[3] = ((float)singlobalang)*(1.f/2147483648.f); gdx = 0; gdy = gxyaspect*-(1.f/4194304.f); gdo = -ghoriz*gdy; gux = (double)ft[3]*((double)viewingrange)/-65536.0; gvx = (double)ft[2]*((double)viewingrange)/-65536.0; guy = (double)ft[0]*gdy; gvy = (double)ft[1]*gdy; guo = (double)ft[0]*gdo; gvo = (double)ft[1]*gdo; guo += (double)(ft[2]-gux)*ghalfx; gvo -= (double)(ft[3]+gvx)*ghalfx; if ((_cy0 < ncy0) && (_cy1 < ncy1)) domost(_x1,_cy1,_x0,_cy0); else if ((_cy0 < ncy0) != (_cy1 < ncy1)) { //(ox,oy) is intersection of: (_x0,_cy0)-(_x1,_cy1) // (_x0,ncy0)-(_x1,ncy1) //ox = _x0 + (_x1-_x0)*t //oy = _cy0 + (_cy1-_cy0)*t //oy = ncy0 + (ncy1-ncy0)*t t = (_cy0-ncy0)/(ncy1-ncy0-_cy1+_cy0); ox = _x0 + (_x1-_x0)*t; oy = _cy0 + (_cy1-_cy0)*t; if (ncy0 < _cy0) { domost(ox,oy,_x0,ncy0); domost(_x1,_cy1,ox,oy); } else { domost(ox,oy,_x0,_cy0); domost(_x1,ncy1,ox,oy); } } else domost(_x1,ncy1,_x0,ncy0); //wall of skybox #ifdef USE_OPENGL drawingskybox = i+1; //i+1th texture/index i of skybox #endif gdx = (_ryp0-_ryp1)*gxyaspect*(1.f/512.f) / (_ox0-_ox1); gdy = 0; gdo = _ryp0*gxyaspect*(1.f/512.f) - gdx*_ox0; gux = (_t0*_ryp0 - _t1*_ryp1)*gxyaspect*(64.f/512.f) / (_ox0-_ox1); guo = _t0*_ryp0*gxyaspect*(64.f/512.f) - gux*_ox0; guy = 0; _t0 = -8192.0*_ryp0 + ghoriz; _t1 = -8192.0*_ryp1 + ghoriz; t = ((gdx*_ox0 + gdo)*8.f) / ((_ox1-_ox0) * _ryp0 * 2048.f); gvx = (_t0-_t1)*t; gvy = (_ox1-_ox0)*t; gvo = -gvx*_ox0 - gvy*_t0; if ((_fy0 < ncy0) && (_fy1 < ncy1)) domost(_x1,_fy1,_x0,_fy0); else if ((_fy0 < ncy0) != (_fy1 < ncy1)) { //(ox,oy) is intersection of: (_x0,_fy0)-(_x1,_fy1) // (_x0,ncy0)-(_x1,ncy1) //ox = _x0 + (_x1-_x0)*t //oy = _fy0 + (_fy1-_fy0)*t //oy = ncy0 + (ncy1-ncy0)*t t = (_fy0-ncy0)/(ncy1-ncy0-_fy1+_fy0); ox = _x0 + (_x1-_x0)*t; oy = _fy0 + (_fy1-_fy0)*t; if (ncy0 < _fy0) { domost(ox,oy,_x0,ncy0); domost(_x1,_fy1,ox,oy); } else { domost(ox,oy,_x0,_fy0); domost(_x1,ncy1,ox,oy); } } else domost(_x1,ncy1,_x0,ncy0); } //Floor of skybox #ifdef USE_OPENGL drawingskybox = 6; //floor/6th texture/index 5 of skybox #endif ft[0] = 512/16; ft[1] = 512/-16; ft[2] = ((float)cosglobalang)*(1.f/2147483648.f); ft[3] = ((float)singlobalang)*(1.f/2147483648.f); gdx = 0; gdy = gxyaspect*(1.f/4194304.f); gdo = -ghoriz*gdy; gux = (double)ft[3]*((double)viewingrange)/-65536.0; gvx = (double)ft[2]*((double)viewingrange)/-65536.0; guy = (double)ft[0]*gdy; gvy = (double)ft[1]*gdy; guo = (double)ft[0]*gdo; gvo = (double)ft[1]*gdo; guo += (double)(ft[2]-gux)*ghalfx; gvo -= (double)(ft[3]+gvx)*ghalfx; gvx = -gvx; gvy = -gvy; gvo = -gvo; //y-flip skybox floor domost(x1,cy1,x0,cy0); skyclamphack = 0; #ifdef USE_OPENGL drawingskybox = 0; #endif } #ifdef USE_OPENGL if (rendmode >= 3) { skyclamphack = 0; if (!nofog) bglEnable(GL_FOG); } #endif } //(x0,cy0) == (u= 0,v=0,d=) //(x1,cy0) == (u=wal->xrepeat*8,v=0) //(x0,fy0) == (u= 0,v=v) // u = (gux*sx + guy*sy + guo) / (gdx*sx + gdy*sy + gdo) // v = (gvx*sx + gvy*sy + gvo) / (gdx*sx + gdy*sy + gdo) // 0 = (gux*x0 + guy*cy0 + guo) / (gdx*x0 + gdy*cy0 + gdo) //wal->xrepeat*8 = (gux*x1 + guy*cy0 + guo) / (gdx*x1 + gdy*cy0 + gdo) // 0 = (gvx*x0 + gvy*cy0 + gvo) / (gdx*x0 + gdy*cy0 + gdo) // v = (gvx*x0 + gvy*fy0 + gvo) / (gdx*x0 + gdy*fy0 + gdo) //sx = x0, u = t0*wal->xrepeat*8, d = yp0; //sx = x1, u = t1*wal->xrepeat*8, d = yp1; //d = gdx*sx + gdo //u = (gux*sx + guo) / (gdx*sx + gdo) //yp0 = gdx*x0 + gdo //yp1 = gdx*x1 + gdo //t0*wal->xrepeat*8 = (gux*x0 + guo) / (gdx*x0 + gdo) //t1*wal->xrepeat*8 = (gux*x1 + guo) / (gdx*x1 + gdo) //gdx*x0 + gdo = yp0 //gdx*x1 + gdo = yp1 gdx = (ryp0-ryp1)*gxyaspect / (x0-x1); gdy = 0; gdo = ryp0*gxyaspect - gdx*x0; //gux*x0 + guo = t0*wal->xrepeat*8*yp0 //gux*x1 + guo = t1*wal->xrepeat*8*yp1 gux = (t0*ryp0 - t1*ryp1)*gxyaspect*(float)wal->xrepeat*8.f / (x0-x1); guo = t0*ryp0*gxyaspect*(float)wal->xrepeat*8.f - gux*x0; guo += (float)wal->xpanning*gdo; gux += (float)wal->xpanning*gdx; guy = 0; //Derivation for u: // (gvx*x0 + gvy*cy0 + gvo) / (gdx*x0 + gdy*cy0 + gdo) = 0 // (gvx*x1 + gvy*cy1 + gvo) / (gdx*x1 + gdy*cy1 + gdo) = 0 // (gvx*x0 + gvy*fy0 + gvo) / (gdx*x0 + gdy*fy0 + gdo) = v // (gvx*x1 + gvy*fy1 + gvo) / (gdx*x1 + gdy*fy1 + gdo) = v // (gvx*x0 + gvy*cy0 + gvo*1) = 0 // (gvx*x1 + gvy*cy1 + gvo*1) = 0 // (gvx*x0 + gvy*fy0 + gvo*1) = t ogux = gux; oguy = guy; oguo = guo; if (nextsectnum >= 0) { getzsofslope(nextsectnum,(int32_t)nx0,(int32_t)ny0,&cz,&fz); ocy0 = ((float)(cz-globalposz))*ryp0 + ghoriz; ofy0 = ((float)(fz-globalposz))*ryp0 + ghoriz; getzsofslope(nextsectnum,(int32_t)nx1,(int32_t)ny1,&cz,&fz); ocy1 = ((float)(cz-globalposz))*ryp1 + ghoriz; ofy1 = ((float)(fz-globalposz))*ryp1 + ghoriz; if ((wal->cstat&48) == 16) maskwall[maskwallcnt++] = z; if (((cy0 < ocy0) || (cy1 < ocy1)) && (!((sec->ceilingstat§or[nextsectnum].ceilingstat)&1))) { globalpicnum = wal->picnum; globalshade = wal->shade; globalpal = (int32_t)((uint8_t)wal->pal); DO_TILE_ANIM(globalpicnum, wallnum+16384); if (!(wal->cstat&4)) i = sector[nextsectnum].ceilingz; else i = sec->ceilingz; // over calc_ypanning(i, ryp0, ryp1, x0, x1, wal->ypanning, wal->yrepeat, wal->cstat&4); if (wal->cstat&8) //xflip { t = (float)(wal->xrepeat*8 + wal->xpanning*2); gux = gdx*t - gux; guy = gdy*t - guy; guo = gdo*t - guo; } if (wal->cstat&256) { gvx = -gvx; gvy = -gvy; gvo = -gvo; } //yflip calc_and_apply_fog(wal->shade, sec->visibility, sec->floorpal); pow2xsplit = 1; domost(x1,ocy1,x0,ocy0); if (wal->cstat&8) { gux = ogux; guy = oguy; guo = oguo; } } if (((ofy0 < fy0) || (ofy1 < fy1)) && (!((sec->floorstat§or[nextsectnum].floorstat)&1))) { if (!(wal->cstat&2)) nwal = wal; else { nwal = &wall[wal->nextwall]; guo += (float)(nwal->xpanning-wal->xpanning)*gdo; gux += (float)(nwal->xpanning-wal->xpanning)*gdx; guy += (float)(nwal->xpanning-wal->xpanning)*gdy; } globalpicnum = nwal->picnum; globalshade = nwal->shade; globalpal = (int32_t)((uint8_t)nwal->pal); DO_TILE_ANIM(globalpicnum, wallnum+16384); if (!(nwal->cstat&4)) i = sector[nextsectnum].floorz; else i = sec->ceilingz; // under calc_ypanning(i, ryp0, ryp1, x0, x1, nwal->ypanning, wal->yrepeat, !(nwal->cstat&4)); if (wal->cstat&8) //xflip { t = (float)(wal->xrepeat*8 + nwal->xpanning*2); gux = gdx*t - gux; guy = gdy*t - guy; guo = gdo*t - guo; } if (nwal->cstat&256) { gvx = -gvx; gvy = -gvy; gvo = -gvo; } //yflip calc_and_apply_fog(nwal->shade, sec->visibility, sec->floorpal); pow2xsplit = 1; domost(x0,ofy0,x1,ofy1); if (wal->cstat&(2+8)) { guo = oguo; gux = ogux; guy = oguy; } } } if ((nextsectnum < 0) || (wal->cstat&32)) //White/1-way wall { if (nextsectnum < 0) globalpicnum = wal->picnum; else globalpicnum = wal->overpicnum; globalshade = wal->shade; globalpal = (int32_t)((uint8_t)wal->pal); DO_TILE_ANIM(globalpicnum, wallnum+16384); if (nextsectnum >= 0) { if (!(wal->cstat&4)) i = nextsec->ceilingz; else i = sec->ceilingz; } else { if (!(wal->cstat&4)) i = sec->ceilingz; else i = sec->floorz; } // white calc_ypanning(i, ryp0, ryp1, x0, x1, wal->ypanning, wal->yrepeat, !(wal->cstat&4)); if (wal->cstat&8) //xflip { t = (float)(wal->xrepeat*8 + wal->xpanning*2); gux = gdx*t - gux; guy = gdy*t - guy; guo = gdo*t - guo; } if (wal->cstat&256) { gvx = -gvx; gvy = -gvy; gvo = -gvo; } //yflip calc_and_apply_fog(wal->shade, sec->visibility, sec->floorpal); pow2xsplit = 1; domost(x0,-10000,x1,-10000); } if (nextsectnum >= 0) if ((!(gotsector[nextsectnum>>3]&pow2char[nextsectnum&7])) && (testvisiblemost(x0,x1))) polymost_scansector(nextsectnum); } } static int32_t polymost_bunchfront(int32_t b1, int32_t b2) { double x1b1, x1b2, x2b1, x2b2; int32_t b1f, b2f, i; b1f = bunchfirst[b1]; x1b1 = dxb1[b1f]; x2b2 = dxb2[bunchlast[b2]]; if (x1b1 >= x2b2) return(-1); b2f = bunchfirst[b2]; x1b2 = dxb1[b2f]; x2b1 = dxb2[bunchlast[b1]]; if (x1b2 >= x2b1) return(-1); if (x1b1 >= x1b2) { for (i=b2f; dxb2[i]<=x1b1; i=p2[i]); return(wallfront(b1f,i)); } for (i=b1f; dxb2[i]<=x1b2; i=p2[i]); return(wallfront(i,b2f)); } void polymost_scansector(int32_t sectnum) { double d, xp1, yp1, xp2, yp2; walltype *wal, *wal2; spritetype *spr; int32_t z, zz, startwall, endwall, numscansbefore, scanfirst, bunchfrst, nextsectnum; int32_t xs, ys, x1, y1, x2, y2; if (sectnum < 0) return; sectorborder[0] = sectnum, sectorbordercnt = 1; do { sectnum = sectorborder[--sectorbordercnt]; for (z=headspritesect[sectnum]; z>=0; z=nextspritesect[z]) { spr = &sprite[z]; if ((((spr->cstat&0x8000) == 0) || (showinvisibility)) && (spr->xrepeat > 0) && (spr->yrepeat > 0)) { xs = spr->x-globalposx; ys = spr->y-globalposy; if ((spr->cstat&48) || (xs*gcosang+ys*gsinang > 0) || (usemodels && tile2model[spr->picnum].modelid>=0)) { if ((spr->cstat&(64+48))!=(64+16) || dmulscale6(sintable[(spr->ang+512)&2047],-xs, sintable[spr->ang&2047],-ys) > 0) if (engine_addtsprite(z, sectnum)) break; } } } gotsector[sectnum>>3] |= pow2char[sectnum&7]; bunchfrst = numbunches; numscansbefore = numscans; startwall = sector[sectnum].wallptr; endwall = sector[sectnum].wallnum+startwall; scanfirst = numscans; xp2 = 0; yp2 = 0; for (z=startwall,wal=&wall[z]; zpoint2]; x1 = wal->x-globalposx; y1 = wal->y-globalposy; x2 = wal2->x-globalposx; y2 = wal2->y-globalposy; nextsectnum = wal->nextsector; //Scan close sectors #ifdef YAX_ENABLE if (yax_nomaskpass==0 || !yax_isislandwall(z, !yax_globalcf) || (yax_nomaskdidit=1, 0)) #endif if ((nextsectnum >= 0) && (!(wal->cstat&32)) && (!(gotsector[nextsectnum>>3]&pow2char[nextsectnum&7]))) { d = (double)x1*(double)y2 - (double)x2*(double)y1; xp1 = (double)(x2-x1); yp1 = (double)(y2-y1); if (d*d <= (xp1*xp1 + yp1*yp1)*(SCISDIST*SCISDIST*260.0)) sectorborder[sectorbordercnt++] = nextsectnum; } if ((z == startwall) || (wall[z-1].point2 != z)) { xp1 = ((double)y1*(double)cosglobalang - (double)x1*(double)singlobalang)/64.0; yp1 = ((double)x1*(double)cosviewingrangeglobalang + (double)y1*(double)sinviewingrangeglobalang)/64.0; } else { xp1 = xp2; yp1 = yp2; } xp2 = ((double)y2*(double)cosglobalang - (double)x2*(double)singlobalang)/64.0; yp2 = ((double)x2*(double)cosviewingrangeglobalang + (double)y2*(double)sinviewingrangeglobalang)/64.0; if ((yp1 >= SCISDIST) || (yp2 >= SCISDIST)) if ((double)xp1*(double)yp2 < (double)xp2*(double)yp1) //if wall is facing you... { if (yp1 >= SCISDIST) dxb1[numscans] = (double)xp1*ghalfx/(double)yp1 + ghalfx; else dxb1[numscans] = -1e32; if (yp2 >= SCISDIST) dxb2[numscans] = (double)xp2*ghalfx/(double)yp2 + ghalfx; else dxb2[numscans] = 1e32; if (dxb1[numscans] < dxb2[numscans]) { thesector[numscans] = sectnum; thewall[numscans] = z; p2[numscans] = numscans+1; numscans++; } } if ((wall[z].point2 < z) && (scanfirst < numscans)) { p2[numscans-1] = scanfirst; scanfirst = numscans; } } for (z=numscansbefore; z dxb1[p2[z]])) { bunchfirst[numbunches++] = p2[z]; p2[z] = -1; #ifdef YAX_ENABLE if (scansector_retfast) return; #endif } for (z=bunchfrst; z=0; zz=p2[zz]); bunchlast[z] = zz; } } while (sectorbordercnt > 0); } void polymost_drawrooms() { int32_t i, j, n, n2, closest; double ox, oy, oz, ox2, oy2, oz2, r, px[6], py[6], pz[6], px2[6], py2[6], pz2[6], sx[6], sy[6]; if (!rendmode) return; begindrawing(); frameoffset = frameplace + windowy1*bytesperline + windowx1; #ifdef USE_OPENGL if (rendmode >= 3) { resizeglcheck(); #ifdef YAX_ENABLE if (numyaxbunches==0) #endif if (editstatus) bglClear(GL_COLOR_BUFFER_BIT|GL_DEPTH_BUFFER_BIT); bglDisable(GL_BLEND); bglEnable(GL_TEXTURE_2D); //bglTexEnvf(GL_TEXTURE_ENV,GL_TEXTURE_ENV_MODE,GL_MODULATE); //default anyway bglEnable(GL_DEPTH_TEST); bglDepthFunc(GL_ALWAYS); //NEVER,LESS,(,L)EQUAL,GREATER,(NOT,G)EQUAL,ALWAYS //bglPolygonOffset(1,1); //Supposed to make sprites pasted on walls or floors not disappear bglDepthRange(0.00001,1.0); //<- this is more widely supported than glPolygonOffset //Enable this for OpenGL red-blue glasses mode :) if (glredbluemode) { static int32_t grbfcnt = 0; grbfcnt++; if (redblueclearcnt < numpages) { redblueclearcnt++; bglColorMask(1,1,1,1); bglClear(GL_COLOR_BUFFER_BIT); } if (grbfcnt&1) { bglViewport(windowx1-16,yres-(windowy2+1),windowx2-(windowx1-16)+1,windowy2-windowy1+1); bglColorMask(1,0,0,1); globalposx += singlobalang/1024; globalposy -= cosglobalang/1024; } else { bglViewport(windowx1,yres-(windowy2+1),windowx2+16-windowx1+1,windowy2-windowy1+1); bglColorMask(0,1,1,1); globalposx -= singlobalang/1024; globalposy += cosglobalang/1024; } } } #endif //Polymost supports true look up/down :) Here, we convert horizon to angle. //gchang&gshang are cos&sin of this angle (respectively) gyxscale = ((double)xdimenscale)/131072.0; gxyaspect = ((double)xyaspect*(double)viewingrange)*(5.0/(65536.0*262144.0)); gviewxrange = ((double)viewingrange)*((double)xdimen)/(32768.0*1024.0); gcosang = ((double)cosglobalang)/262144.0; gsinang = ((double)singlobalang)/262144.0; gcosang2 = gcosang*((double)viewingrange)/65536.0; gsinang2 = gsinang*((double)viewingrange)/65536.0; ghalfx = (double)halfxdimen; grhalfxdown10 = 1.0/(((double)ghalfx)*1024); ghoriz = (double)globalhoriz; gvisibility = ((float)globalvisibility)*FOGSCALE; //global cos/sin height angle r = (double)((ydimen>>1)-ghoriz); gshang = r/sqrt(r*r+ghalfx*ghalfx); gchang = sqrt(1.0-gshang*gshang); ghoriz = (double)(ydimen>>1); //global cos/sin tilt angle gctang = cos(gtang); gstang = sin(gtang); if (fabs(gstang) < .001) //This hack avoids nasty precision bugs in domost() { gstang = 0; if (gctang > 0) gctang = 1.0; else gctang = -1.0; } if (inpreparemirror) gstang = -gstang; //Generate viewport trapezoid (for handling screen up/down) px[0] = px[3] = 0-1; px[1] = px[2] = windowx2+1-windowx1+2; py[0] = py[1] = 0-1; py[2] = py[3] = windowy2+1-windowy1+2; n = 4; for (i=0; i= n) j = 0; if (pz[i] >= SCISDIST) { px2[n2] = px[i]; py2[n2] = py[i]; pz2[n2] = pz[i]; n2++; } if ((pz[i] >= SCISDIST) != (pz[j] >= SCISDIST)) { r = (SCISDIST-pz[i])/(pz[j]-pz[i]); px2[n2] = (px[j]-px[i])*r + px[i]; py2[n2] = (py[j]-py[i])*r + py[i]; pz2[n2] = SCISDIST; n2++; } } if (n2 < 3) { enddrawing(); return; } for (i=0; i>1) here oz2 = ghalfx; //Tilt rotation ox = ox2*gctang + oy2*gstang; oy = oy2*gctang - ox2*gstang; oz = oz2; //Up/down rotation ox2 = oz*gchang - oy*gshang; oy2 = ox; oz2 = oy*gchang + oz*gshang; //Standard Left/right rotation vx = (int32_t)(ox2*((float)cosglobalang) - oy2*((float)singlobalang)); vy = (int32_t)(ox2*((float)singlobalang) + oy2*((float)cosglobalang)); vz = (int32_t)(oz2*16384.0); vect.x = globalposx; vect.y = globalposy; vect.z = globalposz; hitallsprites = 1; hitscan((const vec3_t *)&vect,globalcursectnum, //Start position vx>>10,vy>>10,vz>>6,&hit,0xffff0030); if (hit.sect != -1) // if hitsect is -1, hitscan overflowed somewhere { getzsofslope(hit.sect,hit.pos.x,hit.pos.y,&cz,&fz); hitallsprites = 0; searchsector = hit.sect; if (hit.pos.zfz) searchstat = 2; else if (hit.wall >= 0) { searchbottomwall = searchwall = hit.wall; searchstat = 0; if (wall[hit.wall].nextwall >= 0) { int32_t cz, fz; getzsofslope(wall[hit.wall].nextsector,hit.pos.x,hit.pos.y,&cz,&fz); if (hit.pos.z > fz) { searchisbottom = 1; if (wall[hit.wall].cstat&2) //'2' bottoms of walls searchbottomwall = wall[hit.wall].nextwall; } else { searchisbottom = 0; if ((hit.pos.z > cz) && (wall[hit.wall].cstat&(16+32))) //masking or 1-way searchstat = 4; } } } else if (hit.sprite >= 0) { searchwall = hit.sprite; searchstat = 3; } else { int32_t cz, fz; getzsofslope(hit.sect,hit.pos.x,hit.pos.y,&cz,&fz); if ((hit.pos.z<<1) < cz+fz) searchstat = 1; else searchstat = 2; //if (vz < 0) searchstat = 1; else searchstat = 2; //Won't work for slopes :/ } if (preview_mouseaim && spritesortcnt < MAXSPRITESONSCREEN) { spritetype *tsp = &tsprite[spritesortcnt]; double dadist, x,y,z; Bmemcpy(tsp, &hit.pos, sizeof(vec3_t)); x = tsp->x-globalposx; y=tsp->y-globalposy; z=(tsp->z-globalposz)/16.0; dadist = sqrt(x*x + y*y + z*z); tsp->sectnum = hit.sect; tsp->picnum = 2523; // CROSSHAIR tsp->cstat = 128; tsp->owner = MAXSPRITES-1; tsp->xrepeat = tsp->yrepeat = min(max(1, (int32_t)(dadist*48.0/3200.0)), 255); sprite[tsp->owner].xoffset = sprite[tsp->owner].yoffset = 0; tspriteptr[spritesortcnt++] = tsp; } if ((searchstat==1 || searchstat==2) && searchsector>=0) { int32_t scrv[2] = {(vx>>12), (vy>>12)}; int32_t scrv_r[2] = {scrv[1], -scrv[0]}; walltype *wal = &wall[sector[searchsector].wallptr]; uint64_t wdistsq, bestwdistsq=0x7fffffff; int32_t k, bestk=-1; for (k=0; k= 0) searchwall = sector[searchsector].wallptr + bestk; } } searchit = 0; } numscans = numbunches = 0; // MASKWALL_BAD_ACCESS // Fixes access of stale maskwall[maskwallcnt] (a "scan" index, in BUILD lingo): maskwallcnt = 0; if (globalcursectnum >= MAXSECTORS) globalcursectnum -= MAXSECTORS; else { i = globalcursectnum; updatesector(globalposx,globalposy,&globalcursectnum); if (globalcursectnum < 0) globalcursectnum = i; } polymost_scansector(globalcursectnum); if (inpreparemirror) { grhalfxdown10x = -grhalfxdown10; inpreparemirror = 0; // see engine.c: INPREPAREMIRROR_NO_BUNCHES if (numbunches > 0) { polymost_drawalls(0); numbunches--; bunchfirst[0] = bunchfirst[numbunches]; bunchlast[0] = bunchlast[numbunches]; } } else grhalfxdown10x = grhalfxdown10; while (numbunches > 0) { memset(ptempbuf,0,numbunches+3); ptempbuf[0] = 1; closest = 0; //Almost works, but not quite :( for (i=1; i= 3) { bglDepthFunc(GL_LEQUAL); //NEVER,LESS,(,L)EQUAL,GREATER,(NOT,G)EQUAL,ALWAYS //bglPolygonOffset(0,0); bglDepthRange(0.0,0.99999); //<- this is more widely supported than glPolygonOffset } #endif enddrawing(); } void polymost_drawmaskwall(int32_t damaskwallcnt) { double dpx[8], dpy[8], dpx2[8], dpy2[8]; float x0, x1, sx0, sy0, sx1, sy1, xp0, yp0, xp1, yp1, oxp0, oyp0, ryp0, ryp1; float r, t, t0, t1, csy[4], fsy[4]; int32_t i, j, n, n2, z, sectnum, z1, z2, cz[4], fz[4], method; int32_t m0, m1; sectortype *sec, *nsec; walltype *wal, *wal2; z = maskwall[damaskwallcnt]; wal = &wall[thewall[z]]; wal2 = &wall[wal->point2]; sectnum = thesector[z]; sec = §or[sectnum]; // if (wal->nextsector < 0) return; // Without MASKWALL_BAD_ACCESS fix: // wal->nextsector is -1, WGR2 SVN Lochwood Hollow (Til' Death L1) (or trueror1.map) nsec = §or[wal->nextsector]; z1 = max(nsec->ceilingz,sec->ceilingz); z2 = min(nsec->floorz,sec->floorz); globalpicnum = wal->overpicnum; if ((uint32_t)globalpicnum >= MAXTILES) globalpicnum = 0; DO_TILE_ANIM(globalpicnum, (int16_t)thewall[z]+16384); globalshade = (int32_t)wal->shade; globalpal = (int32_t)((uint8_t)wal->pal); globalorientation = (int32_t)wal->cstat; sx0 = (float)(wal->x-globalposx); sx1 = (float)(wal2->x-globalposx); sy0 = (float)(wal->y-globalposy); sy1 = (float)(wal2->y-globalposy); yp0 = sx0*gcosang2 + sy0*gsinang2; yp1 = sx1*gcosang2 + sy1*gsinang2; if ((yp0 < SCISDIST) && (yp1 < SCISDIST)) return; xp0 = sy0*gcosang - sx0*gsinang; xp1 = sy1*gcosang - sx1*gsinang; //Clip to close parallel-screen plane oxp0 = xp0; oyp0 = yp0; if (yp0 < SCISDIST) { t0 = (SCISDIST-yp0)/(yp1-yp0); xp0 = (xp1-xp0)*t0+xp0; yp0 = SCISDIST; } else t0 = 0.f; if (yp1 < SCISDIST) { t1 = (SCISDIST-oyp0)/(yp1-oyp0); xp1 = (xp1-oxp0)*t1+oxp0; yp1 = SCISDIST; } else { t1 = 1.f; } m0 = (int32_t)((wal2->x-wal->x)*t0+wal->x); m1 = (int32_t)((wal2->y-wal->y)*t0+wal->y); getzsofslope(sectnum,m0,m1,&cz[0],&fz[0]); getzsofslope(wal->nextsector,m0,m1,&cz[1],&fz[1]); m0 = (int32_t)((wal2->x-wal->x)*t1+wal->x); m1 = (int32_t)((wal2->y-wal->y)*t1+wal->y); getzsofslope(sectnum,m0,m1,&cz[2],&fz[2]); getzsofslope(wal->nextsector,m0,m1,&cz[3],&fz[3]); ryp0 = 1.f/yp0; ryp1 = 1.f/yp1; //Generate screen coordinates for front side of wall x0 = ghalfx*xp0*ryp0 + ghalfx; x1 = ghalfx*xp1*ryp1 + ghalfx; if (x1 <= x0) return; ryp0 *= gyxscale; ryp1 *= gyxscale; gdx = (ryp0-ryp1)*gxyaspect / (x0-x1); gdy = 0; gdo = ryp0*gxyaspect - gdx*x0; //gux*x0 + guo = t0*wal->xrepeat*8*yp0 //gux*x1 + guo = t1*wal->xrepeat*8*yp1 gux = (t0*ryp0 - t1*ryp1)*gxyaspect*(float)wal->xrepeat*8.f / (x0-x1); guo = t0*ryp0*gxyaspect*(float)wal->xrepeat*8.f - gux*x0; guo += (float)wal->xpanning*gdo; gux += (float)wal->xpanning*gdx; guy = 0; if (!(wal->cstat&4)) i = z1; else i = z2; // mask calc_ypanning(i, ryp0, ryp1, x0, x1, wal->ypanning, wal->yrepeat, 0); if (wal->cstat&8) //xflip { t = (float)(wal->xrepeat*8 + wal->xpanning*2); gux = gdx*t - gux; guy = gdy*t - guy; guo = gdo*t - guo; } if (wal->cstat&256) { gvx = -gvx; gvy = -gvy; gvo = -gvo; } //yflip method = 1; pow2xsplit = 1; if (wal->cstat&128) { if (!(wal->cstat&512)) method = 2; else method = 3; } calc_and_apply_fog(wal->shade, sec->visibility, sec->floorpal); for (i=0; i<2; i++) { csy[i] = ((float)(cz[i]-globalposz))*ryp0 + ghoriz; fsy[i] = ((float)(fz[i]-globalposz))*ryp0 + ghoriz; csy[i+2] = ((float)(cz[i+2]-globalposz))*ryp1 + ghoriz; fsy[i+2] = ((float)(fz[i+2]-globalposz))*ryp1 + ghoriz; } //Clip 2 quadrilaterals // /csy3 // / | // csy0------/----csy2 // | /xxxxxxx| // | /xxxxxxxxx| // csy1/xxxxxxxxxxx| // |xxxxxxxxxxx/fsy3 // |xxxxxxxxx/ | // |xxxxxxx/ | // fsy0----/------fsy2 // | / // fsy1/ dpx[0] = x0; dpy[0] = csy[1]; dpx[1] = x1; dpy[1] = csy[3]; dpx[2] = x1; dpy[2] = fsy[3]; dpx[3] = x0; dpy[3] = fsy[1]; n = 4; //Clip to (x0,csy[0])-(x1,csy[2]) n2 = 0; t1 = -((dpx[0]-x0)*(csy[2]-csy[0]) - (dpy[0]-csy[0])*(x1-x0)); for (i=0; i= n) j = 0; t0 = t1; t1 = -((dpx[j]-x0)*(csy[2]-csy[0]) - (dpy[j]-csy[0])*(x1-x0)); if (t0 >= 0) { dpx2[n2] = dpx[i]; dpy2[n2] = dpy[i]; n2++; } if ((t0 >= 0) != (t1 >= 0)) { r = t0/(t0-t1); dpx2[n2] = (dpx[j]-dpx[i])*r + dpx[i]; dpy2[n2] = (dpy[j]-dpy[i])*r + dpy[i]; n2++; } } if (n2 < 3) return; //Clip to (x1,fsy[2])-(x0,fsy[0]) n = 0; t1 = -((dpx2[0]-x1)*(fsy[0]-fsy[2]) - (dpy2[0]-fsy[2])*(x0-x1)); for (i=0; i= n2) j = 0; t0 = t1; t1 = -((dpx2[j]-x1)*(fsy[0]-fsy[2]) - (dpy2[j]-fsy[2])*(x0-x1)); if (t0 >= 0) { dpx[n] = dpx2[i]; dpy[n] = dpy2[i]; n++; } if ((t0 >= 0) != (t1 >= 0)) { r = t0/(t0-t1); dpx[n] = (dpx2[j]-dpx2[i])*r + dpx2[i]; dpy[n] = (dpy2[j]-dpy2[i])*r + dpy2[i]; n++; } } if (n < 3) return; pow2xsplit = 0; skyclamphack = 0; alpha = 0.f; drawpoly(dpx,dpy,n,method); } #ifdef MODEL_OCCLUSION_CHECKING int32_t lastcullcheck = 0; char cullmodel[MAXSPRITES]; int32_t cullcheckcnt = 0; static int32_t polymost_checkcoordinates(int32_t x, int32_t y, const spritetype *tspr) { int16_t datempsectnum = tspr->sectnum; int32_t oldx = x, i, j = (tilesizy[tspr->picnum]*tspr->yrepeat); RECHECK: updatesectorz(tspr->x+x,tspr->y+y,tspr->z,&datempsectnum); if (datempsectnum == -1) { if (x == y || x != oldx) return 0; swaplong(&x,&y); updatesector(tspr->x+x,tspr->y+y,&datempsectnum); } i = 4; do { cullcheckcnt += 2; if (cansee(globalposx, globalposy, globalposz, globalcursectnum, tspr->x+x, tspr->y+y, tspr->z-(j*i)-512, datempsectnum)) return 1; if (cansee(globalposx, globalposy, globalposz, globalcursectnum, tspr->x+x, tspr->y+y, tspr->z-(j*(i-1))-512, datempsectnum)) return 1; i -= 2; } while (i); cullcheckcnt++; if (cansee(globalposx, globalposy, globalposz, globalcursectnum, tspr->x+x, tspr->y+y, tspr->z-512, datempsectnum)) return 1; if (x != y && x == oldx) { swaplong(&x,&y); goto RECHECK; } return 0; } #endif void polymost_drawsprite(int32_t snum) { double px[6], py[6]; float f, c, s, fx, fy, sx0, sy0, sx1, xp0, yp0, xp1, yp1, oxp0, oyp0, ryp0, ryp1, ft[4]; float x0, y0, x1, y1, sc0, sf0, sc1, sf1, px2[6], py2[6], xv, yv, t0, t1; int32_t i, j, spritenum, xoff=0, yoff=0, method, npoints; int32_t posx,posy; int32_t oldsizx, oldsizy; int32_t tsizx, tsizy; spritetype *const tspr = tspriteptr[snum]; if (bad_tspr(tspr)) return; spritenum = tspr->owner; DO_TILE_ANIM(tspr->picnum, spritenum+32768); globalpicnum = tspr->picnum; globalshade = tspr->shade; globalpal = tspr->pal; globalorientation = tspr->cstat; if ((globalorientation&48) != 48) // only non-voxel sprites should do this { int32_t flag; flag = usehightile && h_xsize[globalpicnum]; xoff = (int32_t)tspr->xoffset; yoff = (int32_t)tspr->yoffset; xoff += flag ? h_xoffs[globalpicnum] : picanm[globalpicnum].xofs; yoff += flag ? h_yoffs[globalpicnum] : picanm[globalpicnum].yofs; } method = 1+4; if (tspr->cstat&2) { if (!(tspr->cstat&512)) method = 2+4; else method = 3+4; } alpha = spriteext[spritenum].alpha; #ifdef USE_OPENGL calc_and_apply_fog(globalshade, sector[tspr->sectnum].visibility, sector[tspr->sectnum].floorpal); while (rendmode >= 3 && !(spriteext[spritenum].flags&SPREXT_NOTMD)) { if (usemodels && tile2model[Ptile2tile(tspr->picnum,tspr->pal)].modelid >= 0 && tile2model[Ptile2tile(tspr->picnum,tspr->pal)].framenum >= 0) { if (spritenum >= MAXSPRITES || tspr->statnum == TSPR_MIRROR) { if (mddraw(tspr)) return; break; // else, render as flat sprite } # ifdef MODEL_OCCLUSION_CHECKING if (r_modelocclusionchecking) { const int32_t spic = sprite[spritenum].picnum; if (totalclock >= lastcullcheck + CULL_DELAY && cullcheckcnt < MAXCULLCHECKS && (/*modelptr->usesalpha ||*/ tspr->yrepeat*tilesizy[spic] > 1536 || tspr->xrepeat*tilesizx[spic] > 1536)) { do // this is so gay { uint32_t t = getticks()+4; // don't bother with shadows because processing its owner will take care of it if (tspr->statnum == TSPR_TEMP) break; cullmodel[spritenum] = 1; cullcheckcnt++; if (cansee(globalposx, globalposy, globalposz, globalcursectnum, tspr->x, tspr->y, tspr->z,tspr->sectnum)) { cullmodel[spritenum] = 0; break; } if (polymost_checkcoordinates(-CULL_OFFSET, 0, tspr) || getticks() > t || cullcheckcnt >= MAXCULLCHECKS) { cullmodel[spritenum] = 0; break; } if (polymost_checkcoordinates(-CULL_OFFSET, -CULL_OFFSET, tspr) || getticks() > t || cullcheckcnt >= MAXCULLCHECKS) { cullmodel[spritenum] = 0; break; } if (polymost_checkcoordinates(CULL_OFFSET, 0, tspr) || getticks() > t || cullcheckcnt >= MAXCULLCHECKS) { cullmodel[spritenum] = 0; break; } if (polymost_checkcoordinates(CULL_OFFSET, CULL_OFFSET, tspr) || getticks() > t || cullcheckcnt >= MAXCULLCHECKS) { cullmodel[spritenum] = 0; break; } if (polymost_checkcoordinates(-CULL_OFFSET, CULL_OFFSET, tspr) || getticks() > t || cullcheckcnt >= MAXCULLCHECKS) { cullmodel[spritenum] = 0; break; } if (polymost_checkcoordinates(0, 0, tspr) || getticks() > t || cullcheckcnt >= MAXCULLCHECKS) { cullmodel[spritenum] = 0; break; } break; } while (1); } } else cullmodel[spritenum] = 0; if (cullmodel[spritenum]) break; # endif if (mddraw(tspr)) return; break; // else, render as flat sprite } if (usevoxels && (tspr->cstat&48)!=48 && tiletovox[tspr->picnum] >= 0 && voxmodels[tiletovox[tspr->picnum]]) { if (voxdraw(voxmodels[tiletovox[tspr->picnum]], tspr)) return; break; // else, render as flat sprite } if ((tspr->cstat&48)==48 && voxmodels[tspr->picnum]) { voxdraw(voxmodels[tspr->picnum], tspr); return; } break; } if (((tspr->cstat&2) || (gltexmayhavealpha(tspr->picnum,tspr->pal)))) { curpolygonoffset += 0.01f; bglEnable(GL_POLYGON_OFFSET_FILL); bglPolygonOffset(-curpolygonoffset, -curpolygonoffset); } #endif posx=tspr->x; posy=tspr->y; if (spriteext[spritenum].flags&SPREXT_AWAY1) { posx+=(sintable[(tspr->ang+512)&2047]>>13); posy+=(sintable[(tspr->ang)&2047]>>13); } else if (spriteext[spritenum].flags&SPREXT_AWAY2) { posx-=(sintable[(tspr->ang+512)&2047]>>13); posy-=(sintable[(tspr->ang)&2047]>>13); } oldsizx=tsizx=tilesizx[globalpicnum]; oldsizy=tsizy=tilesizy[globalpicnum]; if (usehightile && h_xsize[globalpicnum]) { tsizx = h_xsize[globalpicnum]; tsizy = h_ysize[globalpicnum]; } if (tsizx<=0 || tsizy<=0) return; switch ((globalorientation>>4)&3) { case 0: //Face sprite //Project 3D to 2D if (globalorientation&4) xoff = -xoff; if (globalorientation&8) yoff = -yoff; sx0 = (float)(tspr->x-globalposx); sy0 = (float)(tspr->y-globalposy); xp0 = sy0*gcosang - sx0*gsinang; yp0 = sx0*gcosang2 + sy0*gsinang2; if (yp0 <= SCISDIST) return; ryp0 = 1/yp0; sx0 = ghalfx*xp0*ryp0 + ghalfx; sy0 = ((float)(tspr->z-globalposz))*gyxscale*ryp0 + ghoriz; f = ryp0*(float)xdimen/160.0; fx = ((float)tspr->xrepeat)*f; fy = ((float)tspr->yrepeat)*f*((float)yxaspect/65536.0); sx0 -= fx*(float)xoff; if (tsizx&1) sx0 += fx*.5; sy0 -= fy*(float)yoff; fx *= ((float)tsizx); fy *= ((float)tsizy); px[0] = px[3] = sx0-fx*.5; px[1] = px[2] = sx0+fx*.5; if (!(globalorientation&128)) { py[0] = py[1] = sy0-fy; py[2] = py[3] = sy0; } else { py[0] = py[1] = sy0-fy*.5; py[2] = py[3] = sy0+fy*.5; } gdx = gdy = guy = gvx = 0; gdo = ryp0*gviewxrange; if (!(globalorientation&4)) { gux = (float)tsizx*gdo/(px[1]-px[0]+.002); guo = -gux*(px[0]-.001); } else { gux = (float)tsizx*gdo/(px[0]-px[1]-.002); guo = -gux*(px[1]+.001); } if (!(globalorientation&8)) { gvy = (float)tsizy*gdo/(py[3]-py[0]+.002); gvo = -gvy*(py[0]-.001); } else { gvy = (float)tsizy*gdo/(py[0]-py[3]-.002); gvo = -gvy*(py[3]+.001); } // sprite panning guy -= gdy*((float)(spriteext[spritenum].xpanning)/255.f)*tsizx; guo -= gdo*((float)(spriteext[spritenum].xpanning)/255.f)*tsizx; gvy -= gdy*((float)(spriteext[spritenum].ypanning)/255.f)*tsizy; gvo -= gdo*((float)(spriteext[spritenum].ypanning)/255.f)*tsizy; //Clip sprites to ceilings/floors when no parallaxing and not sloped if (!(sector[tspr->sectnum].ceilingstat&3)) { sy0 = ((float)(sector[tspr->sectnum].ceilingz-globalposz))*gyxscale*ryp0 + ghoriz; if (py[0] < sy0) py[0] = py[1] = sy0; } if (!(sector[tspr->sectnum].floorstat&3)) { sy0 = ((float)(sector[tspr->sectnum].floorz-globalposz))*gyxscale*ryp0 + ghoriz; if (py[2] > sy0) py[2] = py[3] = sy0; } #ifdef USE_OPENGL if (spriteext[spritenum].xpanning) srepeat = 1; if (spriteext[spritenum].ypanning) trepeat = 1; #endif tilesizx[globalpicnum] = tsizx; tilesizy[globalpicnum] = tsizy; pow2xsplit = 0; drawpoly(px,py,4,method); #ifdef USE_OPENGL if (spriteext[spritenum].xpanning) srepeat = 0; if (spriteext[spritenum].ypanning) trepeat = 0; #endif break; case 1: //Wall sprite //Project 3D to 2D if (globalorientation&4) xoff = -xoff; if (globalorientation&8) yoff = -yoff; xv = (float)tspr->xrepeat * (float)sintable[(tspr->ang)&2047] / 65536.0; yv = (float)tspr->xrepeat * (float)sintable[(tspr->ang+1536)&2047] / 65536.0; f = (float)(tsizx>>1) + (float)xoff; x0 = (float)(posx-globalposx) - xv*f; x1 = xv*(float)tsizx + x0; y0 = (float)(posy-globalposy) - yv*f; y1 = yv*(float)tsizx + y0; yp0 = x0*gcosang2 + y0*gsinang2; yp1 = x1*gcosang2 + y1*gsinang2; if ((yp0 <= SCISDIST) && (yp1 <= SCISDIST)) return; xp0 = y0*gcosang - x0*gsinang; xp1 = y1*gcosang - x1*gsinang; //Clip to close parallel-screen plane oxp0 = xp0; oyp0 = yp0; if (yp0 < SCISDIST) { t0 = (SCISDIST-yp0)/(yp1-yp0); xp0 = (xp1-xp0)*t0+xp0; yp0 = SCISDIST; } else { t0 = 0.f; } if (yp1 < SCISDIST) { t1 = (SCISDIST-oyp0)/(yp1-oyp0); xp1 = (xp1-oxp0)*t1+oxp0; yp1 = SCISDIST; } else { t1 = 1.f; } f = ((float)tspr->yrepeat) * (float)tsizy * 4; ryp0 = 1.0/yp0; ryp1 = 1.0/yp1; sx0 = ghalfx*xp0*ryp0 + ghalfx; sx1 = ghalfx*xp1*ryp1 + ghalfx; ryp0 *= gyxscale; ryp1 *= gyxscale; tspr->z -= ((yoff*tspr->yrepeat)<<2); if (globalorientation&128) { tspr->z += ((tsizy*tspr->yrepeat)<<1); if (tsizy&1) tspr->z += (tspr->yrepeat<<1); //Odd yspans } sc0 = ((float)(tspr->z-globalposz-f))*ryp0 + ghoriz; sc1 = ((float)(tspr->z-globalposz-f))*ryp1 + ghoriz; sf0 = ((float)(tspr->z-globalposz))*ryp0 + ghoriz; sf1 = ((float)(tspr->z-globalposz))*ryp1 + ghoriz; gdx = (ryp0-ryp1)*gxyaspect / (sx0-sx1); gdy = 0; gdo = ryp0*gxyaspect - gdx*sx0; //Original equations: //(gux*sx0 + guo)/(gdx*sx1 + gdo) = tsizx*t0 //(gux*sx1 + guo)/(gdx*sx1 + gdo) = tsizx*t1 // // gvx*sx0 + gvy*sc0 + gvo = 0 // gvy*sx1 + gvy*sc1 + gvo = 0 //(gvx*sx0 + gvy*sf0 + gvo)/(gdx*sx0 + gdo) = tsizy //(gvx*sx1 + gvy*sf1 + gvo)/(gdx*sx1 + gdo) = tsizy //gux*sx0 + guo = t0*tsizx*yp0 //gux*sx1 + guo = t1*tsizx*yp1 if (globalorientation&4) { t0 = 1.f-t0; t1 = 1.f-t1; } //sprite panning t0 -= ((float)(spriteext[spritenum].xpanning)/255.f); t1 -= ((float)(spriteext[spritenum].xpanning)/255.f); gux = (t0*ryp0 - t1*ryp1)*gxyaspect*(float)tsizx / (sx0-sx1); guy = 0; guo = t0*ryp0*gxyaspect*(float)tsizx - gux*sx0; //gvx*sx0 + gvy*sc0 + gvo = 0 //gvx*sx1 + gvy*sc1 + gvo = 0 //gvx*sx0 + gvy*sf0 + gvo = tsizy*(gdx*sx0 + gdo) f = ((float)tsizy)*(gdx*sx0 + gdo) / ((sx0-sx1)*(sc0-sf0)); if (!(globalorientation&8)) { gvx = (sc0-sc1)*f; gvy = (sx1-sx0)*f; gvo = -gvx*sx0 - gvy*sc0; } else { gvx = (sf1-sf0)*f; gvy = (sx0-sx1)*f; gvo = -gvx*sx0 - gvy*sf0; } // sprite panning gvx -= gdx*((float)(spriteext[spritenum].ypanning)/255.f)*tsizy; gvy -= gdy*((float)(spriteext[spritenum].ypanning)/255.f)*tsizy; gvo -= gdo*((float)(spriteext[spritenum].ypanning)/255.f)*tsizy; //Clip sprites to ceilings/floors when no parallaxing if (!(sector[tspr->sectnum].ceilingstat&1)) { f = ((float)tspr->yrepeat) * (float)tsizy * 4; if (sector[tspr->sectnum].ceilingz > tspr->z-f) { sc0 = ((float)(sector[tspr->sectnum].ceilingz-globalposz))*ryp0 + ghoriz; sc1 = ((float)(sector[tspr->sectnum].ceilingz-globalposz))*ryp1 + ghoriz; } } if (!(sector[tspr->sectnum].floorstat&1)) { if (sector[tspr->sectnum].floorz < tspr->z) { sf0 = ((float)(sector[tspr->sectnum].floorz-globalposz))*ryp0 + ghoriz; sf1 = ((float)(sector[tspr->sectnum].floorz-globalposz))*ryp1 + ghoriz; } } if (sx0 > sx1) { if (globalorientation&64) return; //1-sided sprite f = sx0; sx0 = sx1; sx1 = f; f = sc0; sc0 = sc1; sc1 = f; f = sf0; sf0 = sf1; sf1 = f; } px[0] = sx0; py[0] = sc0; px[1] = sx1; py[1] = sc1; px[2] = sx1; py[2] = sf1; px[3] = sx0; py[3] = sf0; #ifdef USE_OPENGL if (spriteext[spritenum].xpanning) srepeat = 1; if (spriteext[spritenum].ypanning) trepeat = 1; #endif tilesizx[globalpicnum] = tsizx; tilesizy[globalpicnum] = tsizy; pow2xsplit = 0; drawpoly(px,py,4,method); #ifdef USE_OPENGL if (spriteext[spritenum].xpanning) srepeat = 0; if (spriteext[spritenum].ypanning) trepeat = 0; #endif break; case 2: //Floor sprite if ((globalorientation&64) != 0) if ((globalposz > tspr->z) == (!(globalorientation&8))) return; if ((globalorientation&4) > 0) xoff = -xoff; if ((globalorientation&8) > 0) yoff = -yoff; i = (tspr->ang&2047); c = sintable[(i+512)&2047]/65536.0; s = sintable[i]/65536.0; x0 = (float)((tsizx>>1)-xoff)*tspr->xrepeat; y0 = (float)((tsizy>>1)-yoff)*tspr->yrepeat; x1 = (float)((tsizx>>1)+xoff)*tspr->xrepeat; y1 = (float)((tsizy>>1)+yoff)*tspr->yrepeat; //Project 3D to 2D for (j=0; j<4; j++) { sx0 = (float)(tspr->x-globalposx); sy0 = (float)(tspr->y-globalposy); if ((j+0)&2) { sy0 -= s*y0; sx0 -= c*y0; } else { sy0 += s*y1; sx0 += c*y1; } if ((j+1)&2) { sx0 -= s*x0; sy0 += c*x0; } else { sx0 += s*x1; sy0 -= c*x1; } px[j] = sy0*gcosang - sx0*gsinang; py[j] = sx0*gcosang2 + sy0*gsinang2; } if (tspr->z < globalposz) //if floor sprite is above you, reverse order of points { f = px[0]; px[0] = px[1]; px[1] = f; f = py[0]; py[0] = py[1]; py[1] = f; f = px[2]; px[2] = px[3]; px[3] = f; f = py[2]; py[2] = py[3]; py[3] = f; } //Clip to SCISDIST plane npoints = 0; for (i=0; i<4; i++) { j = ((i+1)&3); if (py[i] >= SCISDIST) { px2[npoints] = px[i]; py2[npoints] = py[i]; npoints++; } if ((py[i] >= SCISDIST) != (py[j] >= SCISDIST)) { f = (SCISDIST-py[i])/(py[j]-py[i]); px2[npoints] = (px[j]-px[i])*f + px[i]; py2[npoints] = (py[j]-py[i])*f + py[i]; npoints++; } } if (npoints < 3) return; //Project rotated 3D points to screen f = ((float)(tspr->z-globalposz))*gyxscale; for (j=0; jz-globalposz); gdo = -ghoriz*gdy; //copied&modified from relative alignment xv = (float)tspr->x + s*x1 + c*y1; fx = (double)-(x0+x1)*s; yv = (float)tspr->y + s*y1 - c*x1; fy = (double)+(x0+x1)*c; f = 1.0/sqrt(fx*fx+fy*fy); fx *= f; fy *= f; ft[2] = singlobalang*fy + cosglobalang*fx; ft[3] = singlobalang*fx - cosglobalang*fy; ft[0] = ((double)(globalposy-yv))*fy + ((double)(globalposx-xv))*fx; ft[1] = ((double)(globalposx-xv))*fy - ((double)(globalposy-yv))*fx; gux = (double)ft[3]*((double)viewingrange)/(-65536.0*262144.0); gvx = (double)ft[2]*((double)viewingrange)/(-65536.0*262144.0); guy = (double)ft[0]*gdy; gvy = (double)ft[1]*gdy; guo = (double)ft[0]*gdo; gvo = (double)ft[1]*gdo; guo += (double)(ft[2]/262144.0-gux)*ghalfx; gvo -= (double)(ft[3]/262144.0+gvx)*ghalfx; f = 4.0/(float)tspr->xrepeat; gux *= f; guy *= f; guo *= f; f =-4.0/(float)tspr->yrepeat; gvx *= f; gvy *= f; gvo *= f; if (globalorientation&4) { gux = ((float)tsizx)*gdx - gux; guy = ((float)tsizx)*gdy - guy; guo = ((float)tsizx)*gdo - guo; } // sprite panning guy -= gdy*((float)(spriteext[spritenum].xpanning)/255.f)*tsizx; guo -= gdo*((float)(spriteext[spritenum].xpanning)/255.f)*tsizx; gvy -= gdy*((float)(spriteext[spritenum].ypanning)/255.f)*tsizy; gvo -= gdo*((float)(spriteext[spritenum].ypanning)/255.f)*tsizy; #ifdef USE_OPENGL if (spriteext[spritenum].xpanning) srepeat = 1; if (spriteext[spritenum].ypanning) trepeat = 1; #endif tilesizx[globalpicnum] = tsizx; tilesizy[globalpicnum] = tsizy; pow2xsplit = 0; drawpoly(px,py,npoints,method); #ifdef USE_OPENGL if (spriteext[spritenum].xpanning) srepeat = 0; if (spriteext[spritenum].ypanning) trepeat = 0; #endif break; case 3: //Voxel sprite break; } tilesizx[globalpicnum]=oldsizx; tilesizy[globalpicnum]=oldsizy; } //sx,sy center of sprite; screen coords*65536 //z zoom*65536. > is zoomed in //a angle (0 is default) //dastat&1 1:translucence //dastat&2 1:auto-scale mode (use 320*200 coordinates) //dastat&4 1:y-flip //dastat&8 1:don't clip to startumost/startdmost //dastat&16 1:force point passed to be top-left corner, 0:Editart center //dastat&32 1:reverse translucence //dastat&64 1:non-masked, 0:masked //dastat&128 1:draw all pages (permanent) //cx1,... clip window (actual screen coords) void polymost_dorotatesprite(int32_t sx, int32_t sy, int32_t z, int16_t a, int16_t picnum, int8_t dashade, char dapalnum, int32_t dastat, uint8_t daalpha, int32_t cx1, int32_t cy1, int32_t cx2, int32_t cy2, int32_t uniqid) { static int32_t onumframes = 0; int32_t n, nn, xoff, yoff, xsiz, ysiz, method; int32_t ogpicnum, ogshade, ogpal, ofoffset; double ogchang, ogshang, ogctang, ogstang, oghalfx, oghoriz; double ogrhalfxdown10, ogrhalfxdown10x; double d, cosang, sinang, cosang2, sinang2, px[8], py[8], px2[8], py2[8]; float m[4][4]; int32_t ourxyaspect; #if defined(USE_OPENGL) && defined(POLYMER) int32_t olddetailmapping = r_detailmapping, oldglowmapping = r_glowmapping; #endif #ifdef USE_OPENGL if (rendmode >= 3 && usemodels && hudmem[(dastat&4)>>2][picnum].angadd) { const int32_t tilenum = Ptile2tile(picnum,dapalnum); if (tile2model[tilenum].modelid >= 0 && tile2model[tilenum].framenum >= 0) { int32_t oldviewingrange; double ogxyaspect; double x1, y1, z1; spritetype tspr; memset(&tspr,0,sizeof(spritetype)); if (hudmem[(dastat&4)>>2][picnum].flags&1) return; //"HIDE" is specified in DEF ogchang = gchang; gchang = 1.0; ogshang = gshang; gshang = 0.0; d = (double)z/(65536.0*16384.0); ogctang = gctang; gctang = (double)sintable[(a+512)&2047]*d; ogstang = gstang; gstang = (double)sintable[a&2047]*d; ogshade = globalshade; globalshade = dashade; ogpal = globalpal; globalpal = (int32_t)((uint8_t)dapalnum); ogxyaspect = gxyaspect; gxyaspect = 1.0; oldviewingrange = viewingrange; viewingrange = 65536; x1 = hudmem[(dastat&4)>>2][picnum].xadd; y1 = hudmem[(dastat&4)>>2][picnum].yadd; z1 = hudmem[(dastat&4)>>2][picnum].zadd; #ifdef POLYMER if (pr_overridehud) { x1 = pr_hudxadd; y1 = pr_hudyadd; z1 = pr_hudzadd; } #endif if (!(hudmem[(dastat&4)>>2][picnum].flags&2)) //"NOBOB" is specified in DEF { double fx = ((double)sx)*(1.0/65536.0); double fy = ((double)sy)*(1.0/65536.0); if (dastat&16) { xsiz = tilesizx[picnum]; ysiz = tilesizy[picnum]; xoff = picanm[picnum].xofs + (xsiz>>1); yoff = picanm[picnum].yofs + (ysiz>>1); d = (double)z/(65536.0*16384.0); cosang2 = cosang = (double)sintable[(a+512)&2047]*d; sinang2 = sinang = (double)sintable[a&2047]*d; if ((dastat&2) || (!(dastat&8))) //Don't aspect unscaled perms { d = (double)xyaspect/65536.0; cosang2 *= d; sinang2 *= d; } fx += -(double)xoff*cosang2+ (double)yoff*sinang2; fy += -(double)xoff*sinang - (double)yoff*cosang; } if (!(dastat&2)) { x1 += fx/((double)(xdim<<15))-1.0; //-1: left of screen, +1: right of screen y1 += fy/((double)(ydim<<15))-1.0; //-1: top of screen, +1: bottom of screen } else { x1 += fx/160.0-1.0; //-1: left of screen, +1: right of screen y1 += fy/100.0-1.0; //-1: top of screen, +1: bottom of screen } } tspr.ang = hudmem[(dastat&4)>>2][picnum].angadd+globalang; #ifdef POLYMER if (pr_overridehud) { tspr.ang = pr_hudangadd + globalang; } #endif if (dastat&4) { x1 = -x1; y1 = -y1; } // In Polymost, we don't care if the model is very big if (rendmode < 4) { tspr.xrepeat = tspr.yrepeat = 32; tspr.x = (int32_t)(((double)gcosang*z1 - (double)gsinang*x1)*16384.0 + globalposx); tspr.y = (int32_t)(((double)gsinang*z1 + (double)gcosang*x1)*16384.0 + globalposy); tspr.z = (int32_t)(globalposz + y1*16384.0*0.8); } else { float x, y, z; tspr.xrepeat = tspr.yrepeat = 5; x = (float)(((double)gcosang*z1 - (double)gsinang*x1)*2560.0 + globalposx); y = (float)(((double)gsinang*z1 + (double)gcosang*x1)*2560.0 + globalposy); z = (float)(globalposz + y1*2560.0*0.8); memcpy(&tspr.x, &x, sizeof(float)); memcpy(&tspr.y, &y, sizeof(float)); memcpy(&tspr.z, &z, sizeof(float)); } tspr.picnum = picnum; tspr.shade = dashade; tspr.pal = dapalnum; tspr.owner = uniqid+MAXSPRITES; globalorientation = (dastat&1)+((dastat&32)<<4)+((dastat&4)<<1); tspr.cstat = globalorientation; if ((dastat&10) == 2) bglViewport(windowx1,yres-(windowy2+1),windowx2-windowx1+1,windowy2-windowy1+1); else { bglViewport(0,0,xdim,ydim); glox1 = -1; //Force fullscreen (glox1=-1 forces it to restore) } if (rendmode < 4) { bglMatrixMode(GL_PROJECTION); memset(m,0,sizeof(m)); if ((dastat&10) == 2) { float ratioratio = (float)xdim/ydim; m[0][0] = (float)ydimen*(ratioratio >= 1.6?1.2:1); m[0][2] = 1.0; m[1][1] = (float)xdimen; m[1][2] = 1.0; m[2][2] = 1.0; m[2][3] = (float)ydimen*(ratioratio >= 1.6?1.2:1); m[3][2] =-1.0; } else { m[0][0] = m[2][3] = 1.0f; m[1][1] = ((float)xdim)/((float)ydim); m[2][2] = 1.0001f; m[3][2] = 1-m[2][2]; } bglLoadMatrixf(&m[0][0]); bglMatrixMode(GL_MODELVIEW); bglLoadIdentity(); } if (hudmem[(dastat&4)>>2][picnum].flags&8) //NODEPTH flag bglDisable(GL_DEPTH_TEST); else { bglEnable(GL_DEPTH_TEST); if (onumframes != numframes) { onumframes = numframes; bglClear(GL_DEPTH_BUFFER_BIT); } } #ifdef USE_OPENGL spriteext[tspr.owner].alpha = daalpha / 255.0f; if (!nofog) bglDisable(GL_FOG); if (rendmode < 4) mddraw(&tspr); # ifdef POLYMER else { int32_t fov; tspriteptr[MAXSPRITESONSCREEN] = &tspr; bglEnable(GL_ALPHA_TEST); bglEnable(GL_BLEND); spriteext[tspr.owner].roll = a; spriteext[tspr.owner].zoff = z; fov = hudmem[(dastat&4)>>2][picnum].fov; if (fov == -1) { fov = pr_fov; } if (pr_overridehud) { fov = pr_hudfov; } polymer_setaspect(fov); polymer_drawsprite(MAXSPRITESONSCREEN); polymer_setaspect(pr_fov); spriteext[tspr.owner].zoff = 0; spriteext[tspr.owner].roll = 0; bglDisable(GL_BLEND); bglDisable(GL_ALPHA_TEST); } # endif if (!nofog) bglEnable(GL_FOG); #else mddraw(&tspr); spriteext[tspr.owner].alpha = 0.f; #endif viewingrange = oldviewingrange; gxyaspect = ogxyaspect; globalshade = ogshade; globalpal = ogpal; gchang = ogchang; gshang = ogshang; gctang = ogctang; gstang = ogstang; return; } } #endif ogpicnum = globalpicnum; globalpicnum = picnum; ogshade = globalshade; globalshade = dashade; ogpal = globalpal; globalpal = (int32_t)((uint8_t)dapalnum); oghalfx = ghalfx; ghalfx = (double)(xdim>>1); ogrhalfxdown10 = grhalfxdown10; grhalfxdown10 = 1.0/(((double)ghalfx)*1024); ogrhalfxdown10x = grhalfxdown10x; grhalfxdown10x = grhalfxdown10; oghoriz = ghoriz; ghoriz = (double)(ydim>>1); ofoffset = frameoffset; frameoffset = frameplace; ogchang = gchang; gchang = 1.0; ogshang = gshang; gshang = 0.0; ogctang = gctang; gctang = 1.0; ogstang = gstang; gstang = 0.0; #ifdef USE_OPENGL if (rendmode >= 3) { bglViewport(0,0,xdim,ydim); glox1 = -1; //Force fullscreen (glox1=-1 forces it to restore) bglMatrixMode(GL_PROJECTION); memset(m,0,sizeof(m)); m[0][0] = m[2][3] = 1.0f; m[1][1] = ((float)xdim)/((float)ydim); m[2][2] = 1.0001f; m[3][2] = 1-m[2][2]; bglPushMatrix(); bglLoadMatrixf(&m[0][0]); bglMatrixMode(GL_MODELVIEW); bglPushMatrix(); bglLoadIdentity(); bglDisable(GL_DEPTH_TEST); bglDisable(GL_ALPHA_TEST); bglEnable(GL_TEXTURE_2D); # ifdef POLYMER if (rendmode >= 4) { polymer_inb4rotatesprite(picnum, dapalnum, dashade); r_detailmapping = 0; r_glowmapping = 0; } # endif } #endif method = 0; if (!(dastat&64)) { method = 1; if (dastat&1) { if (!(dastat&32)) method = 2; else method = 3; } } method |= 4; //Use OpenGL clamping - dorotatesprite never repeats alpha = daalpha / 255.0f; xsiz = tilesizx[globalpicnum]; ysiz = tilesizy[globalpicnum]; if (dastat&16) { xoff = 0; yoff = 0; } else { xoff = picanm[globalpicnum].xofs + (xsiz>>1); yoff = picanm[globalpicnum].yofs + (ysiz>>1); } if (dastat&4) yoff = ysiz-yoff; { int32_t temp; dorotspr_handle_bit2(&sx, &sy, &z, dastat, cx1+cx2, cy1+cy2, &temp, &ourxyaspect); } d = (double)z/(65536.0*16384.0); cosang2 = cosang = (double)sintable[(a+512)&2047]*d; sinang2 = sinang = (double)sintable[a&2047]*d; if ((dastat&2) || (!(dastat&8))) //Don't aspect unscaled perms { d = (double)ourxyaspect/65536.0; cosang2 *= d; sinang2 *= d; } px[0] = (double)sx/65536.0 - (double)xoff*cosang2+ (double)yoff*sinang2; py[0] = (double)sy/65536.0 - (double)xoff*sinang - (double)yoff*cosang; px[1] = px[0] + (double)xsiz*cosang2; py[1] = py[0] + (double)xsiz*sinang; px[3] = px[0] - (double)ysiz*sinang2; py[3] = py[0] + (double)ysiz*cosang; px[2] = px[1]+px[3]-px[0]; py[2] = py[1]+py[3]-py[0]; n = 4; gdx = 0; gdy = 0; gdo = 1.0; //px[0]*gux + py[0]*guy + guo = 0 //px[1]*gux + py[1]*guy + guo = xsiz-.0001 //px[3]*gux + py[3]*guy + guo = 0 d = 1.0/(px[0]*(py[1]-py[3]) + px[1]*(py[3]-py[0]) + px[3]*(py[0]-py[1])); gux = (py[3]-py[0])*((double)xsiz-.0001)*d; guy = (px[0]-px[3])*((double)xsiz-.0001)*d; guo = 0 - px[0]*gux - py[0]*guy; if (!(dastat&4)) { //px[0]*gvx + py[0]*gvy + gvo = 0 //px[1]*gvx + py[1]*gvy + gvo = 0 //px[3]*gvx + py[3]*gvy + gvo = ysiz-.0001 gvx = (py[0]-py[1])*((double)ysiz-.0001)*d; gvy = (px[1]-px[0])*((double)ysiz-.0001)*d; gvo = 0 - px[0]*gvx - py[0]*gvy; } else { //px[0]*gvx + py[0]*gvy + gvo = ysiz-.0001 //px[1]*gvx + py[1]*gvy + gvo = ysiz-.0001 //px[3]*gvx + py[3]*gvy + gvo = 0 gvx = (py[1]-py[0])*((double)ysiz-.0001)*d; gvy = (px[0]-px[1])*((double)ysiz-.0001)*d; gvo = (double)ysiz-.0001 - px[0]*gvx - py[0]*gvy; } cx2++; cy2++; //Clippoly4 (converted from int32_t to double) nn = z = 0; do { double fx, x1, x2; int32_t zz = z+1; if (zz == n) zz = 0; x1 = px[z]; x2 = px[zz]-x1; if ((cx1 <= x1) && (x1 <= cx2)) { px2[nn] = x1; py2[nn] = py[z]; nn++; } if (x2 <= 0) fx = cx2; else fx = cx1; d = fx-x1; if ((d < x2) != (d < 0)) { px2[nn] = fx; py2[nn] = (py[zz]-py[z])*d/x2 + py[z]; nn++; } if (x2 <= 0) fx = cx1; else fx = cx2; d = fx-x1; if ((d < x2) != (d < 0)) { px2[nn] = fx; py2[nn] = (py[zz]-py[z])*d/x2 + py[z]; nn++; } z = zz; } while (z); if (nn >= 3) { n = z = 0; do { double fy, y1, y2; int32_t zz = z+1; if (zz == nn) zz = 0; y1 = py2[z]; y2 = py2[zz]-y1; if ((cy1 <= y1) && (y1 <= cy2)) { py[n] = y1; px[n] = px2[z]; n++; } if (y2 <= 0) fy = cy2; else fy = cy1; d = fy-y1; if ((d < y2) != (d < 0)) { py[n] = fy; px[n] = (px2[zz]-px2[z])*d/y2 + px2[z]; n++; } if (y2 <= 0) fy = cy1; else fy = cy2; d = fy-y1; if ((d < y2) != (d < 0)) { py[n] = fy; px[n] = (px2[zz]-px2[z])*d/y2 + px2[z]; n++; } z = zz; } while (z); #ifdef USE_OPENGL if (!nofog) bglDisable(GL_FOG); pow2xsplit = 0; drawpoly(px,py,n,method); if (!nofog) bglEnable(GL_FOG); #else pow2xsplit = 0; drawpoly(px,py,n,method); #endif } #ifdef USE_OPENGL if (rendmode >= 3) { # ifdef POLYMER if (rendmode >= 4) { r_detailmapping = olddetailmapping; r_glowmapping = oldglowmapping; polymer_postrotatesprite(); } # endif bglMatrixMode(GL_PROJECTION); bglPopMatrix(); bglMatrixMode(GL_MODELVIEW); bglPopMatrix(); } #endif globalpicnum = ogpicnum; globalshade = ogshade; globalpal = ogpal; ghalfx = oghalfx; grhalfxdown10 = ogrhalfxdown10; grhalfxdown10x = ogrhalfxdown10x; ghoriz = oghoriz; frameoffset = ofoffset; gchang = ogchang; gshang = ogshang; gctang = ogctang; gstang = ogstang; } #ifdef USE_OPENGL static float trapextx[2]; static void drawtrap(float x0, float x1, float y0, float x2, float x3, float y1) { float px[4], py[4]; int32_t i, n; if (y0 == y1) return; px[0] = x0; py[0] = y0; py[2] = y1; if (x0 == x1) { px[1] = x3; py[1] = y1; px[2] = x2; n = 3; } else if (x2 == x3) { px[1] = x1; py[1] = y0; px[2] = x3; n = 3; } else { px[1] = x1; py[1] = y0; px[2] = x3; px[3] = x2; py[3] = y1; n = 4; } bglBegin(GL_TRIANGLE_FAN); for (i=0; i allocpoints) //16 for safety { allocpoints = numpoints+16; rst = (raster *)Brealloc(rst,allocpoints*sizeof(raster)); slist = (int32_t *)Brealloc(slist,allocpoints*sizeof(int32_t)); npoint2 = (int32_t *)Brealloc(npoint2,allocpoints*sizeof(int32_t)); } //Remove unnecessary collinear points: for (i=0; i m1) { z |= 2; continue; } npoint2[i] = k; npoint2[j] = -1; npoints--; i--; //collinear } if (!z) return; trapextx[0] = trapextx[1] = px[0]; for (i=j=0; i trapextx[1]) trapextx[1] = px[i]; slist[j++] = i; } if (z != 3) //Simple polygon... early out { bglBegin(GL_TRIANGLE_FAN); for (i=0; i>1); gap; gap>>=1) for (i=0; i=0; j-=gap) { if (py[npoint2[slist[j]]] <= py[npoint2[slist[j+gap]]]) break; k = slist[j]; slist[j] = slist[j+gap]; slist[j+gap] = k; } numrst = 0; for (z=0; z0; i--) { if (rst[i-1].xi*(py[i1]-rst[i-1].y) + rst[i-1].x < px[i1]) break; rst[i+1] = rst[i-1]; } numrst += 2; if (i&1) //split inside area { j = i-1; x0 = (py[i1] - rst[j ].y)*rst[j ].xi + rst[j ].x; x1 = (py[i1] - rst[j+1].y)*rst[j+1].xi + rst[j+1].x; drawtrap(rst[j].x,rst[j+1].x,rst[j].y,x0,x1,py[i1]); rst[j ].x = x0; rst[j ].y = py[i1]; rst[j+3].x = x1; rst[j+3].y = py[i1]; } m0 = (px[i0]-px[i1]) / (py[i0]-py[i1]); m1 = (px[i3]-px[i2]) / (py[i3]-py[i2]); j = ((px[i1] > px[i2]) || ((i1 == i2) && (m0 >= m1))) + i; k = (i<<1)+1 - j; rst[j].i = i0; rst[j].xi = m0; rst[j].x = px[i1]; rst[j].y = py[i1]; rst[k].i = i3; rst[k].xi = m1; rst[k].x = px[i2]; rst[k].y = py[i2]; } else { //NOTE:don't count backwards! if (i1 == i2) { for (i=0; i py[i0]) && (py[i2] > py[i3])) //Delete raster { for (; j<=i+1; j+=2) { x0 = (py[i1] - rst[j ].y)*rst[j ].xi + rst[j ].x; if ((i == j) && (i1 == i2)) x1 = x0; else x1 = (py[i1] - rst[j+1].y)*rst[j+1].xi + rst[j+1].x; drawtrap(rst[j].x,rst[j+1].x,rst[j].y,x0,x1,py[i1]); rst[j ].x = x0; rst[j ].y = py[i1]; rst[j+1].x = x1; rst[j+1].y = py[i1]; } numrst -= 2; for (; i=0; i--) { ((float *)rx1)[i] = ((float)rx1[i])/4096.0; ((float *)ry1)[i] = ((float)ry1[i])/4096.0; } if (gloy1 != -1) setpolymost2dview(); //disables blending, texturing, and depth testing bglEnable(GL_ALPHA_TEST); bglEnable(GL_TEXTURE_2D); pth = gltexcache(globalpicnum,globalpal,0); bglBindTexture(GL_TEXTURE_2D, pth ? pth->glpic : 0); f = getshadefactor(globalshade); switch ((globalorientation>>7)&3) { case 0: case 1: a = 1.0f; bglDisable(GL_BLEND); break; case 2: a = 0.66f; bglEnable(GL_BLEND); break; case 3: a = 0.33f; bglEnable(GL_BLEND); break; } bglColor4f(f,f,f,a); tessectrap((float *)rx1,(float *)ry1,xb1,npoints); } #endif int32_t polymost_drawtilescreen(int32_t tilex, int32_t tiley, int32_t wallnum, int32_t dimen, int32_t tilezoom, int32_t usehitile, uint8_t *loadedhitile) { #ifdef USE_OPENGL float xdime, ydime, xdimepad, ydimepad, scx, scy, ratio = 1.0; int32_t i; pthtyp *pth; if ((rendmode < 3) || (qsetmode != 200)) return(-1); if (!glinfo.texnpot) { i = (1<<(picsiz[wallnum]&15)); if (i < tilesizx[wallnum]) i += i; xdimepad = (float)i; i = (1<<(picsiz[wallnum]>>4)); if (i < tilesizy[wallnum]) i += i; ydimepad = (float)i; } else { xdimepad = (float)tilesizx[wallnum]; ydimepad = (float)tilesizy[wallnum]; } xdime = (float)tilesizx[wallnum]; xdimepad = xdime/xdimepad; ydime = (float)tilesizy[wallnum]; ydimepad = ydime/ydimepad; if ((xdime <= dimen) && (ydime <= dimen)) { scx = xdime; scy = ydime; } else { scx = (float)dimen; scy = (float)dimen; if (xdime < ydime) scx *= xdime/ydime; else scy *= ydime/xdime; } { int32_t ousehightile = usehightile; usehightile = usehitile && usehightile; pth = gltexcache(wallnum,0,4); if (usehightile) loadedhitile[wallnum>>3] |= (1<<(wallnum&7)); usehightile = ousehightile; } bglBindTexture(GL_TEXTURE_2D, pth ? pth->glpic : 0); bglDisable(GL_ALPHA_TEST); if (tilezoom) { if (scx > scy) ratio = dimen/scx; else ratio = dimen/scy; } if (!pth || (pth->flags & 8)) { bglDisable(GL_TEXTURE_2D); bglBegin(GL_TRIANGLE_FAN); if (gammabrightness) bglColor4f((float)curpalette[255].r/255.0, (float)curpalette[255].g/255.0, (float)curpalette[255].b/255.0, 1); else bglColor4f((float)britable[curbrightness][ curpalette[255].r ] / 255.0, (float)britable[curbrightness][ curpalette[255].g ] / 255.0, (float)britable[curbrightness][ curpalette[255].b ] / 255.0, 1); bglVertex2f((float)tilex ,(float)tiley); bglVertex2f((float)tilex+(scx*ratio),(float)tiley); bglVertex2f((float)tilex+(scx*ratio),(float)tiley+(scy*ratio)); bglVertex2f((float)tilex ,(float)tiley+(scy*ratio)); bglEnd(); } bglColor4f(1,1,1,1); bglEnable(GL_TEXTURE_2D); bglEnable(GL_BLEND); bglBegin(GL_TRIANGLE_FAN); bglTexCoord2f(0, 0); bglVertex2f((float)tilex ,(float)tiley); bglTexCoord2f(xdimepad, 0); bglVertex2f((float)tilex+(scx*ratio),(float)tiley); bglTexCoord2f(xdimepad,ydimepad); bglVertex2f((float)tilex+(scx*ratio),(float)tiley+(scy*ratio)); bglTexCoord2f(0, ydimepad); bglVertex2f((float)tilex ,(float)tiley+(scy*ratio)); bglEnd(); return(0); #else return -1; #endif } static int32_t gen_font_glyph_tex(void) { // construct a 256x128 8-bit alpha-only texture for the font glyph matrix char *tbuf, *cptr, *tptr; int32_t h,i,j; bglGenTextures(1,&polymosttext); if (!polymosttext) return -1; tbuf = (char *)Bmalloc(256*128); if (!tbuf) { bglDeleteTextures(1,&polymosttext); polymosttext = 0; return -1; } Bmemset(tbuf, 0, 256*128); cptr = (char *)textfont; for (h=0; h<256; h++) { tptr = tbuf + (h%32)*8 + (h/32)*256*8; for (i=0; i<8; i++) { for (j=0; j<8; j++) { if (cptr[h*8+i] & pow2char[7-j]) tptr[j] = 255; } tptr += 256; } } cptr = (char *)smalltextfont; for (h=0; h<256; h++) { tptr = tbuf + 256*64 + (h%32)*8 + (h/32)*256*8; for (i=1; i<7; i++) { for (j=2; j<6; j++) { if (cptr[h*8+i] & pow2char[7-j]) tptr[j-2] = 255; } tptr += 256; } } bglBindTexture(GL_TEXTURE_2D, polymosttext); bglTexImage2D(GL_TEXTURE_2D,0,GL_ALPHA,256,128,0,GL_ALPHA,GL_UNSIGNED_BYTE,(GLvoid *)tbuf); bglTexParameteri(GL_TEXTURE_2D,GL_TEXTURE_MAG_FILTER,GL_NEAREST); bglTexParameteri(GL_TEXTURE_2D,GL_TEXTURE_MIN_FILTER,GL_NEAREST); Bfree(tbuf); return 0; } int32_t polymost_printext256(int32_t xpos, int32_t ypos, int16_t col, int16_t backcol, const char *name, char fontsize) { #ifndef USE_OPENGL return -1; #else GLfloat tx, ty, txc, tyc; int32_t c; palette_t p,b; int32_t arbackcol = (unsigned)backcol < 256 ? backcol : 0; // FIXME? if (col < 0) col = 0; bricolor(&p, col); bricolor(&b, arbackcol); if ((rendmode < 3) || (qsetmode != 200)) return(-1); if (!polymosttext) { if (gen_font_glyph_tex() < 0) return -1; } else { bglBindTexture(GL_TEXTURE_2D, polymosttext); } setpolymost2dview(); // disables blending, texturing, and depth testing bglDisable(GL_ALPHA_TEST); bglDepthMask(GL_FALSE); // disable writing to the z-buffer bglPushAttrib(GL_POLYGON_BIT|GL_ENABLE_BIT); // XXX: Don't fogify the OSD text in Mapster32 with r_usenewshading=2. bglDisable(GL_FOG); // We want to have readable text in wireframe mode, too: bglPolygonMode(GL_FRONT_AND_BACK, GL_FILL); if (backcol >= 0) { bglColor4ub(b.r,b.g,b.b,255); c = Bstrlen(name); bglBegin(GL_QUADS); bglVertex2i(xpos,ypos); bglVertex2i(xpos,ypos+(fontsize?6:8)); bglVertex2i(xpos+(c<<(3-fontsize)),ypos+(fontsize?6:8)); bglVertex2i(xpos+(c<<(3-fontsize)),ypos); bglEnd(); } bglEnable(GL_TEXTURE_2D); bglEnable(GL_BLEND); bglColor4ub(p.r,p.g,p.b,255); txc = fontsize ? (4.0/256.0) : (8.0/256.0); tyc = fontsize ? (6.0/128.0) : (8.0/128.0); bglBegin(GL_QUADS); for (c=0; name[c]; c++) { if (name[c] == '^' && isdigit(name[c+1])) { char smallbuf[8]; int32_t bi=0; while (isdigit(name[c+1]) && bi<3) { smallbuf[bi++]=name[c+1]; c++; } smallbuf[bi++]=0; if (col)col = Batol(smallbuf); if ((unsigned)col >= 256) col = 0; bricolor(&p, col); bglColor4ub(p.r,p.g,p.b,255); continue; } tx = (float)(name[c]%32)/32.0; ty = (float)((name[c]/32) + (fontsize*8))/16.0; bglTexCoord2f(tx,ty); bglVertex2i(xpos,ypos); bglTexCoord2f(tx+txc,ty); bglVertex2i(xpos+(8>>fontsize),ypos); bglTexCoord2f(tx+txc,ty+tyc); bglVertex2i(xpos+(8>>fontsize),ypos+(fontsize?6:8)); bglTexCoord2f(tx,ty+tyc); bglVertex2i(xpos,ypos+(fontsize?6:8)); xpos += (8>>fontsize); } bglEnd(); bglDepthMask(GL_TRUE); // re-enable writing to the z-buffer bglPopAttrib(); return 0; #endif } // Console commands by JBF #ifdef USE_OPENGL static int32_t gltexturemode(const osdfuncparm_t *parm) { int32_t m; const char *p; if (parm->numparms != 1) { OSD_Printf("Current texturing mode is %s\n", glfiltermodes[gltexfiltermode].name); OSD_Printf(" Vaild modes are:\n"); for (m = 0; m < NUMGLFILTERMODES; m++) OSD_Printf(" %d - %s\n", m, glfiltermodes[m].name); return OSDCMD_OK; } m = Bstrtoul(parm->parms[0], (char **)&p, 10); if (p == parm->parms[0]) { // string for (m = 0; m < NUMGLFILTERMODES; m++) { if (!Bstrcasecmp(parm->parms[0], glfiltermodes[m].name)) break; } if (m == NUMGLFILTERMODES) m = gltexfiltermode; // no change } else { m = clamp(m, 0, NUMGLFILTERMODES-1); } gltexfiltermode = m; gltexapplyprops(); OSD_Printf("Texture filtering mode changed to %s\n", glfiltermodes[gltexfiltermode].name); return OSDCMD_OK; } #endif static int32_t osdcmd_cvar_set_polymost(const osdfuncparm_t *parm) { int32_t r = osdcmd_cvar_set(parm); if (xdim == 0 || ydim == 0 || bpp == 0) // video not set up yet { if (r == OSDCMD_OK) { #ifdef POLYMER if (!Bstrcasecmp(parm->name, "r_pr_maxlightpasses")) { pr_maxlightpasses = r_pr_maxlightpasses; return r; } #endif } return r; } #ifdef USE_OPENGL if (r == OSDCMD_OK) { if (!Bstrcasecmp(parm->name, "r_swapinterval")) { setvsync(vsync); return r; } else if (!Bstrcasecmp(parm->name, "r_downsize")) { if (r_downsize != r_downsizevar && r_downsizevar != -1) { invalidatecache(); resetvideomode(); if (setgamemode(fullscreen,xdim,ydim,bpp)) OSD_Printf("restartvid: Reset failed...\n"); } else r_downsizevar = r_downsize; return r; } else if (!Bstrcasecmp(parm->name, "r_textureanisotropy")) { gltexapplyprops(); return r; } else if (!Bstrcasecmp(parm->name, "r_texturemode")) { gltexturemode(parm); return r; } #ifdef POLYMER else if (!Bstrcasecmp(parm->name, "r_pr_maxlightpasses")) { if (pr_maxlightpasses != r_pr_maxlightpasses) { polymer_invalidatelights(); pr_maxlightpasses = r_pr_maxlightpasses; } return r; } #endif } #endif return r; } void polymost_initosdfuncs(void) { uint32_t i; cvar_t cvars_polymost[] = { #ifdef USE_OPENGL { "r_animsmoothing","r_animsmoothing: enable/disable model animation smoothing",(void *) &r_animsmoothing, CVAR_BOOL, 0, 1 }, { "r_modelocclusionchecking","r_modelocclusionchecking: enable/disable hack to cull \"obstructed\" models",(void *) &r_modelocclusionchecking, CVAR_INT, 0, 2 }, { "r_detailmapping","r_detailmapping: enable/disable detail mapping",(void *) &r_detailmapping, CVAR_BOOL, 0, 1 }, { "r_downsize","r_downsize: controls downsizing factor for hires textures",(void *) &r_downsize, CVAR_INT|CVAR_FUNCPTR, 0, 5 }, { "r_fullbrights","r_fullbrights: enable/disable fullbright textures",(void *) &r_fullbrights, CVAR_BOOL, 0, 1 }, { "r_glowmapping","r_glowmapping: enable/disable glow mapping",(void *) &r_glowmapping, CVAR_BOOL, 0, 1 }, /* { "r_multisample","r_multisample: sets the number of samples used for antialiasing (0 = off)",(void *)&glmultisample, CVAR_BOOL, 0, 1 }, { "r_nvmultisamplehint","r_nvmultisamplehint: enable/disable Nvidia multisampling hinting",(void *)&glnvmultisamplehint, CVAR_BOOL, 0, 1 }, */ { "r_parallaxskyclamping","r_parallaxskyclamping: enable/disable parallaxed floor/ceiling sky texture clamping", (void *) &r_parallaxskyclamping, CVAR_BOOL, 0, 1 }, { "r_parallaxskypanning","r_parallaxskypanning: enable/disable parallaxed floor/ceiling panning when drawing a parallaxed sky", (void *) &r_parallaxskypanning, CVAR_BOOL, 0, 1 }, { "r_polygonmode","r_polygonmode: debugging feature",(void *) &glpolygonmode, CVAR_INT | CVAR_NOSAVE, 0, 3 }, { "r_redbluemode","r_redbluemode: enable/disable experimental OpenGL red-blue glasses mode",(void *) &glredbluemode, CVAR_BOOL, 0, 1 }, { "r_shadescale","r_shadescale: multiplier for shading",(void *) &shadescale, CVAR_FLOAT, 0, 10 }, { "r_shadescale_unbounded","r_shadescale_unbounded: enable/disable allowance of complete blackness",(void *) &shadescale_unbounded, CVAR_BOOL, 0, 1 }, { "r_swapinterval","r_swapinterval: sets the GL swap interval (VSync)",(void *) &vsync, CVAR_INT|CVAR_FUNCPTR, -1, 1 }, { "r_texcache","r_texcache: enable/disable OpenGL compressed texture cache",(void *) &glusetexcache, CVAR_INT, 0, 2 }, { "r_memcache","r_memcache: enable/disable texture cache memory cache",(void *) &glusememcache, CVAR_BOOL, 0, 1 }, { "r_texcompr","r_texcompr: enable/disable OpenGL texture compression",(void *) &glusetexcompr, CVAR_BOOL, 0, 1 }, { "r_textureanisotropy", "r_textureanisotropy: changes the OpenGL texture anisotropy setting", (void *) &glanisotropy, CVAR_INT|CVAR_FUNCPTR, 0, 16 }, { "r_texturemaxsize","r_texturemaxsize: changes the maximum OpenGL texture size limit",(void *) &gltexmaxsize, CVAR_INT | CVAR_NOSAVE, 0, 4096 }, { "r_texturemiplevel","r_texturemiplevel: changes the highest OpenGL mipmap level used",(void *) &gltexmiplevel, CVAR_INT, 0, 6 }, { "r_texturemode", "r_texturemode: changes the texture filtering settings", (void *) &gltexfiltermode, CVAR_INT|CVAR_FUNCPTR, 0, 5 }, { "r_usenewshading", "r_usenewshading: visibility code: 0: Polymost, 2: Classic", (void *) &r_usenewshading, CVAR_INT, 0, 2 }, { "r_vbocount","r_vbocount: sets the number of Vertex Buffer Objects to use when drawing models",(void *) &r_vbocount, CVAR_INT, 1, 256 }, { "r_vbos","r_vbos: enable/disable using Vertex Buffer Objects when drawing models",(void *) &r_vbos, CVAR_BOOL, 0, 1 }, { "r_vertexarrays","r_vertexarrays: enable/disable using vertex arrays when drawing models",(void *) &r_vertexarrays, CVAR_BOOL, 0, 1 }, { "r_anamorphic", "r_anamorphic: enable/disable widescreen mode", (void *) &glwidescreen, CVAR_BOOL, 0, 1 }, { "r_projectionhack", "r_projectionhack: enable/disable projection hack", (void *) &glprojectionhacks, CVAR_INT, 0, 2 }, #ifdef POLYMER // polymer cvars { "r_pr_lighting", "r_pr_lighting: enable/disable dynamic lights - restarts renderer", (void *) &pr_lighting, CVAR_BOOL | CVAR_RESTARTVID, 0, 1 }, { "r_pr_normalmapping", "r_pr_normalmapping: enable/disable virtual displacement mapping", (void *) &pr_normalmapping, CVAR_BOOL, 0, 1 }, { "r_pr_specularmapping", "r_pr_specularmapping: enable/disable specular mapping", (void *) &pr_specularmapping, CVAR_BOOL, 0, 1 }, { "r_pr_shadows", "r_pr_shadows: enable/disable dynamic shadows", (void *) &pr_shadows, CVAR_BOOL, 0, 1 }, { "r_pr_shadowcount", "r_pr_shadowcount: maximal amount of shadow emitting lights on screen - you need to restart the renderer for it to take effect", (void *) &pr_shadowcount, CVAR_INT, 0, 64 }, { "r_pr_shadowdetail", "r_pr_shadowdetail: sets the shadow map resolution - you need to restart the renderer for it to take effect", (void *) &pr_shadowdetail, CVAR_INT, 0, 5 }, { "r_pr_shadowfiltering", "r_pr_shadowfiltering: enable/disable shadow edges filtering - you need to restart the renderer for it to take effect", (void *) &pr_shadowfiltering, CVAR_BOOL, 0, 1 }, { "r_pr_maxlightpasses", "r_pr_maxlightpasses: the maximal amount of lights a single object can by affected by", (void *) &r_pr_maxlightpasses, CVAR_INT|CVAR_FUNCPTR, 0, PR_MAXLIGHTS }, { "r_pr_maxlightpriority", "r_pr_maxlightpriority: lowering that value removes less meaningful lights from the scene", (void *) &pr_maxlightpriority, CVAR_INT, 0, PR_MAXLIGHTPRIORITY }, { "r_pr_fov", "r_pr_fov: sets the field of vision in build angle", (void *) &pr_fov, CVAR_INT, 0, 1023}, { "r_pr_customaspect", "r_pr_customaspect: if non-zero, forces the 3D view aspect ratio", (void *) &pr_customaspect, CVAR_FLOAT, 0, 3 }, { "r_pr_billboardingmode", "r_pr_billboardingmode: face sprite display method. 0: classic mode; 1: polymost mode", (void *) &pr_billboardingmode, CVAR_INT, 0, 1 }, { "r_pr_verbosity", "r_pr_verbosity: verbosity level of the polymer renderer", (void *) &pr_verbosity, CVAR_INT, 0, 3 }, { "r_pr_wireframe", "r_pr_wireframe: toggles wireframe mode", (void *) &pr_wireframe, CVAR_INT | CVAR_NOSAVE, 0, 1 }, { "r_pr_vbos", "r_pr_vbos: contols Vertex Buffer Object usage. 0: no VBOs. 1: VBOs for map data. 2: VBOs for model data.", (void *) &pr_vbos, CVAR_INT | CVAR_RESTARTVID, 0, 2 }, { "r_pr_gpusmoothing", "r_pr_gpusmoothing: toggles model animation interpolation", (void *) &pr_gpusmoothing, CVAR_INT, 0, 1 }, { "r_pr_overrideparallax", "r_pr_overrideparallax: overrides parallax mapping scale and bias values with values from the pr_parallaxscale and pr_parallaxbias cvars; use it to fine-tune DEF tokens", (void *) &pr_overrideparallax, CVAR_BOOL | CVAR_NOSAVE, 0, 1 }, { "r_pr_parallaxscale", "r_pr_parallaxscale: overriden parallax mapping offset scale", (void *) &pr_parallaxscale, CVAR_FLOAT | CVAR_NOSAVE, -10, 10 }, { "r_pr_parallaxbias", "r_pr_parallaxbias: overriden parallax mapping offset bias", (void *) &pr_parallaxbias, CVAR_FLOAT | CVAR_NOSAVE, -10, 10 }, { "r_pr_overridespecular", "r_pr_overridespecular: overrides specular material power and factor values with values from the pr_specularpower and pr_specularfactor cvars; use it to fine-tune DEF tokens", (void *) &pr_overridespecular, CVAR_BOOL | CVAR_NOSAVE, 0, 1 }, { "r_pr_specularpower", "r_pr_specularpower: overriden specular material power", (void *) &pr_specularpower, CVAR_FLOAT | CVAR_NOSAVE, -10, 1000 }, { "r_pr_specularfactor", "r_pr_specularfactor: overriden specular material factor", (void *) &pr_specularfactor, CVAR_FLOAT | CVAR_NOSAVE, -10, 1000 }, { "r_pr_highpalookups", "r_pr_highpalookups: enable/disable highpalookups", (void *) &pr_highpalookups, CVAR_BOOL, 0, 1 }, { "r_pr_artmapping", "r_pr_artmapping: enable/disable art mapping", (void *) &pr_artmapping, CVAR_BOOL | CVAR_INVALIDATE8, 0, 1 }, { "r_pr_overridehud", "r_pr_overridehud: overrides hud model parameters with values from the pr_hud* cvars; use it to fine-tune DEF tokens", (void *) &pr_overridehud, CVAR_BOOL | CVAR_NOSAVE, 0, 1 }, { "r_pr_hudxadd", "r_pr_hudxadd: overriden HUD xadd; see r_pr_overridehud", (void *) &pr_hudxadd, CVAR_FLOAT | CVAR_NOSAVE, -100, 100 }, { "r_pr_hudyadd", "r_pr_hudyadd: overriden HUD yadd; see r_pr_overridehud", (void *) &pr_hudyadd, CVAR_FLOAT | CVAR_NOSAVE, -100, 100 }, { "r_pr_hudzadd", "r_pr_hudzadd: overriden HUD zadd; see r_pr_overridehud", (void *) &pr_hudzadd, CVAR_FLOAT | CVAR_NOSAVE, -100, 100 }, { "r_pr_hudangadd", "r_pr_hudangadd: overriden HUD angadd; see r_pr_overridehud", (void *) &pr_hudangadd, CVAR_INT | CVAR_NOSAVE, -512, 512 }, { "r_pr_hudfov", "r_pr_hudfov: overriden HUD fov; see r_pr_overridehud", (void *) &pr_hudfov, CVAR_INT | CVAR_NOSAVE, 0, 1023 }, { "r_pr_overridemodelscale", "r_pr_overridemodelscale: overrides model scale if non-zero; use it to fine-tune DEF tokens", (void *) &pr_overridemodelscale, CVAR_FLOAT | CVAR_NOSAVE, 0, 500 }, { "r_pr_ati_fboworkaround", "r_pr_ati_fboworkaround: enable this to workaround an ATI driver bug that causes sprite shadows to be square - you need to restart the renderer for it to take effect", (void *) &pr_ati_fboworkaround, CVAR_BOOL | CVAR_NOSAVE, 0, 1 }, { "r_pr_ati_nodepthoffset", "r_pr_ati_nodepthoffset: enable this to workaround an ATI driver bug that causes sprite drawing to freeze the game on Radeon X1x00 hardware - you need to restart the renderer for it to take effect", (void *) &pr_ati_nodepthoffset, CVAR_BOOL | CVAR_NOSAVE, 0, 1 }, #endif { "r_models","r_models: enable/disable model rendering",(void *) &usemodels, CVAR_BOOL, 0, 1 }, { "r_hightile","r_hightile: enable/disable hightile texture rendering",(void *) &usehightile, CVAR_BOOL, 0, 1 }, { "r_preview_mouseaim", "r_preview_mouseaim: toggles mouse aiming preview, use this to calibrate yxaspect in Polymost Mapster32", (void *) &preview_mouseaim, CVAR_BOOL, 0, 1 }, #endif }; for (i=0; imdnum < 2) return; { int32_t i,j=0; if (models[mid]->mdnum == 3) j = ((md3model_t *)models[mid])->head.numsurfs; for (i=0; i<=j; i++) { mdloadskin((md2model_t *)models[mid], 0, dapalnum, i); } } #endif } #ifdef USE_OPENGL static uint16_t hicosub(uint16_t c) { int32_t r, g, b; g = ((c>> 5)&63); r = ((c>>11)-(g>>1))&31; b = ((c>> 0)-(g>>1))&31; return((r<<11)+(g<<5)+b); } static uint16_t hicoadd(uint16_t c) { int32_t r, g, b; g = ((c>> 5)&63); r = ((c>>11)+(g>>1))&31; b = ((c>> 0)+(g>>1))&31; return((r<<11)+(g<<5)+b); } static void dxt_handle_io(int32_t fil, int32_t len, void *midbuf, char *packbuf) { void *writebuf; int32_t j, cleng; if (glusetexcache == 2) { cleng = qlz_compress(midbuf, packbuf, len, state_compress); if (cleng == 0 || cleng > len-1) { cleng = len; writebuf = midbuf; } else writebuf = packbuf; } else { cleng = len; writebuf = midbuf; } // native -> external (little endian) j = B_LITTLE32(cleng); Bwrite(fil, &j, sizeof(j)); Bwrite(fil, writebuf, cleng); } static int32_t dedxt_handle_io(int32_t fil, int32_t j /* TODO: better name */, void *midbuf, char *packbuf, int32_t ispacked) { void *inbuf; int32_t cleng; if (read_from_cache(&cleng, sizeof(int32_t))) return -1; // external (little endian) -> native cleng = B_LITTLE32(cleng); inbuf = (ispacked && cleng < j) ? packbuf : midbuf; if (memcachedata && memcachesize >= cachepos + cleng) { if (ispacked && cleng < j) { if (qlz_decompress((const char *)memcachedata + cachepos, midbuf, state_decompress) == 0) { cachepos += cleng; return -1; } } else Bmemcpy(inbuf, memcachedata + cachepos, cleng); cachepos += cleng; } else { Blseek(fil, cachepos, BSEEK_SET); cachepos += cleng; if (Bread(fil, inbuf, cleng) < cleng) return -1; if (ispacked && cleng < j) if (qlz_decompress(packbuf, midbuf, state_decompress) == 0) return -1; } return 0; } /* Description of Ken's filter to improve LZW compression of DXT1 format by ~15%: (as tested with the HRP) To increase LZW patterns, I store each field of the DXT block structure separately. Here are the 3 DXT fields: 1. __int64 alpha_4x4; //DXT3 only (16 byte structure size when included) 2. short rgb0, rgb1; 3. int32_t index_4x4; Each field is then stored with its own specialized algorithm. 1. I haven't done much testing with this field - I just copy it raw without any transform for now. 2. For rgb0 and rgb1, I use a "green" filter like this: g = g; r = r-g; b = b-g; For grayscale, this makes the stream: x,0,0,x,0,0,x,0,0,... instead of x,x,x,x,x,x,x,x,... Q:what was the significance of choosing green? A:largest/most dominant component Believe it or not, this gave 1% better compression :P I tried subtracting each componenet with the previous pixel, but strangely it hurt compression. Oh, the joy of trial & error. :) 3. For index_4x4, I transform the ordering of 2-bit indices in the DXT blocks from this: 0123 0123 0123 ---- ---- ---- 4567 4567 4567 ---- ---- ---- 89ab 89ab 89ab ---- ---- ---- cdef cdef cdef ---- ---- ---- To this: (I swap x & y axes) 048c 048c 048c |||| |||| |||| 159d 159d 159d |||| |||| |||| 26ae 26ae 26ae |||| |||| |||| 37bf 37bf 37bf |||| |||| |||| The trick is: going from the bottom of the 4th line to the top of the 5th line is the exact same jump (geometrically) as from 5th to 6th, etc.. This is not true in the top case. These silly tricks will increase patterns and therefore make LZW compress better. I think this improved compression by a few % :) */ // NOTE: members are in external (little) endianness. int32_t dxtfilter(int32_t fil, const texcachepicture *pict, const char *pic, void *midbuf, char *packbuf, uint32_t miplen) { uint32_t j, k, offs, stride; char *cptr; if ((pict->format == (signed) B_LITTLE32(GL_COMPRESSED_RGB_S3TC_DXT1_EXT)) || (pict->format == (signed) B_LITTLE32(GL_COMPRESSED_RGBA_S3TC_DXT1_EXT))) { offs = 0; stride = 8; } else if ((pict->format == (signed) B_LITTLE32(GL_COMPRESSED_RGBA_S3TC_DXT3_EXT)) || (pict->format == (signed) B_LITTLE32(GL_COMPRESSED_RGBA_S3TC_DXT5_EXT))) { offs = 8; stride = 16; } else { offs = 0; stride = 8; } if (stride == 16) //If DXT3... { //alpha_4x4 cptr = (char *)midbuf; for (k=0; k<8; k++) *cptr++ = pic[k]; for (j=stride; (unsigned)j>0)&3) + (((c2[1]>>0)&3)<<2) + (((c2[2]>>0)&3)<<4) + (((c2[3]>>0)&3)<<6); cptr[1] = ((c2[0]>>2)&3) + (((c2[1]>>2)&3)<<2) + (((c2[2]>>2)&3)<<4) + (((c2[3]>>2)&3)<<6); cptr[2] = ((c2[0]>>4)&3) + (((c2[1]>>4)&3)<<2) + (((c2[2]>>4)&3)<<4) + (((c2[3]>>4)&3)<<6); cptr[3] = ((c2[0]>>6)&3) + (((c2[1]>>6)&3)<<2) + (((c2[2]>>6)&3)<<4) + (((c2[3]>>6)&3)<<6); cptr += 4; } dxt_handle_io(fil, (miplen/stride)<<2, midbuf, packbuf); return 0; } // NOTE: members are in native endianness. int32_t dedxtfilter(int32_t fil, const texcachepicture *pict, char *pic, void *midbuf, char *packbuf, int32_t ispacked) { int32_t j, k, offs, stride; char *cptr; if ((pict->format == GL_COMPRESSED_RGB_S3TC_DXT1_EXT) || (pict->format == GL_COMPRESSED_RGBA_S3TC_DXT1_EXT)) { offs = 0; stride = 8; } else if ((pict->format == GL_COMPRESSED_RGBA_S3TC_DXT3_EXT) || (pict->format == GL_COMPRESSED_RGBA_S3TC_DXT5_EXT)) { offs = 8; stride = 16; } else { offs = 0; stride = 8; } if (stride == 16) //If DXT3... { //alpha_4x4 if (dedxt_handle_io(fil, (pict->size/stride)*8, midbuf, packbuf, ispacked)) return -1; cptr = (char *)midbuf; for (k=0; k<8; k++) pic[k] = *cptr++; for (j=stride; jsize; j+=stride) for (k=0; k<8; k++) pic[j+k] = (*cptr++); } //rgb0,rgb1 if (dedxt_handle_io(fil, (pict->size/stride)*4, midbuf, packbuf, ispacked)) return -1; cptr = (char *)midbuf; for (k=0; k<=2; k+=2) { for (j=0; jsize; j+=stride) { *(int16_t *)(&pic[offs+j+k]) = hicoadd(*(int16_t *)cptr); cptr += 2; } } //index_4x4: if (dedxt_handle_io(fil, (pict->size/stride)*4, midbuf, packbuf, ispacked)) return -1; cptr = (char *)midbuf; for (j=0; jsize; j+=stride) { pic[j+offs+4] = ((cptr[0]>>0)&3) + (((cptr[1]>>0)&3)<<2) + (((cptr[2]>>0)&3)<<4) + (((cptr[3]>>0)&3)<<6); pic[j+offs+5] = ((cptr[0]>>2)&3) + (((cptr[1]>>2)&3)<<2) + (((cptr[2]>>2)&3)<<4) + (((cptr[3]>>2)&3)<<6); pic[j+offs+6] = ((cptr[0]>>4)&3) + (((cptr[1]>>4)&3)<<2) + (((cptr[2]>>4)&3)<<4) + (((cptr[3]>>4)&3)<<6); pic[j+offs+7] = ((cptr[0]>>6)&3) + (((cptr[1]>>6)&3)<<2) + (((cptr[2]>>6)&3)<<4) + (((cptr[3]>>6)&3)<<6); cptr += 4; } return 0; } #endif #else /* if !defined USE_OPENGL */ #include "compat.h" int32_t polymost_drawtilescreen(int32_t tilex, int32_t tiley, int32_t wallnum, int32_t dimen, int32_t usehitile, uint8_t *loadedhitile) { UNREFERENCED_PARAMETER(tilex); UNREFERENCED_PARAMETER(tiley); UNREFERENCED_PARAMETER(wallnum); UNREFERENCED_PARAMETER(dimen); UNREFERENCED_PARAMETER(usehitile); UNREFERENCED_PARAMETER(loadedhitile); return -1; } #endif // vim:ts=4:sw=4: