/* =========================================================================== Doom 3 BFG Edition GPL Source Code Copyright (C) 1993-2012 id Software LLC, a ZeniMax Media company. This file is part of the Doom 3 BFG Edition GPL Source Code ("Doom 3 BFG Edition Source Code"). Doom 3 BFG Edition Source Code is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. Doom 3 BFG Edition Source Code is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with Doom 3 BFG Edition Source Code. If not, see . In addition, the Doom 3 BFG Edition Source Code is also subject to certain additional terms. You should have received a copy of these additional terms immediately following the terms and conditions of the GNU General Public License which accompanied the Doom 3 BFG Edition Source Code. If not, please request a copy in writing from id Software at the address below. If you have questions concerning this license or the applicable additional terms, you may contact in writing id Software LLC, c/o ZeniMax Media Inc., Suite 120, Rockville, Maryland 20850 USA. =========================================================================== */ #include "Precompiled.h" #include "globaldata.h" #include "doomdef.h" #include "i_system.h" #include "z_zone.h" #include "w_wad.h" #include "r_local.h" // Needs access to LFB (guess what). #include "v_video.h" // State. #include "doomstat.h" // ? // status bar height at bottom of screen // // All drawing to the view buffer is accomplished in this file. // The other refresh files only know about ccordinates, // not the architecture of the frame buffer. // Conveniently, the frame buffer is a linear one, // and we need only the base address, // and the total size == width*height*depth/8., // // Color tables for different ::g->players, // translate a limited part to another // (color ramps used for suit colors). // // // R_DrawColumn // Source is the top of the column to scale. // // first pixel in a column (possibly virtual) // just for profiling // // A column is a vertical slice/span from a wall texture that, // given the DOOM style restrictions on the view orientation, // will always have constant z depth. // Thus a special case loop for very fast rendering can // be used. It has also been used with Wolfenstein 3D. // void R_DrawColumn ( lighttable_t * dc_colormap, byte * dc_source ) { int count; byte* dest; fixed_t frac; fixed_t fracstep; count = ::g->dc_yh - ::g->dc_yl; // Zero length, column does not exceed a pixel. if (count >= 0) { //return; #ifdef RANGECHECK if ((unsigned)::g->dc_x >= SCREENWIDTH || ::g->dc_yl < 0 || ::g->dc_yh >= SCREENHEIGHT) I_Error ("R_DrawColumn: %i to %i at %i", ::g->dc_yl, ::g->dc_yh, ::g->dc_x); #endif // Framebuffer destination address. // Use ::g->ylookup LUT to avoid multiply with ScreenWidth. // Use ::g->columnofs LUT for subwindows? dest = ::g->ylookup[::g->dc_yl] + ::g->columnofs[::g->dc_x]; // Determine scaling, // which is the only mapping to be done. fracstep = ::g->dc_iscale; frac = ::g->dc_texturemid + (::g->dc_yl-::g->centery)*fracstep; // Inner loop that does the actual texture mapping, // e.g. a DDA-lile scaling. // This is as fast as it gets. do { // Re-map color indices from wall texture column // using a lighting/special effects LUT. const int truncated1 = frac >> FRACBITS; const int wrapped1 = truncated1 & 127; *dest = dc_colormap[dc_source[wrapped1]]; frac += fracstep; dest += SCREENWIDTH; } while (count--); } } // UNUSED. // Loop unrolled. #if 0 void R_DrawColumn (void) { int count; byte* source; byte* dest; byte* colormap; unsigned frac; unsigned fracstep; unsigned fracstep2; unsigned fracstep3; unsigned fracstep4; count = ::g->dc_yh - ::g->dc_yl + 1; source = ::g->dc_source; colormap = ::g->dc_colormap; dest = ::g->ylookup[::g->dc_yl] + ::g->columnofs[::g->dc_x]; fracstep = ::g->dc_iscale<<9; frac = (::g->dc_texturemid + (::g->dc_yl-::g->centery)*::g->dc_iscale)<<9; fracstep2 = fracstep+fracstep; fracstep3 = fracstep2+fracstep; fracstep4 = fracstep3+fracstep; while (count >= 8) { dest[0] = colormap[source[frac>>25]]; dest[SCREENWIDTH] = colormap[source[(frac+fracstep)>>25]]; dest[SCREENWIDTH*2] = colormap[source[(frac+fracstep2)>>25]]; dest[SCREENWIDTH*3] = colormap[source[(frac+fracstep3)>>25]]; frac += fracstep4; dest[SCREENWIDTH*4] = colormap[source[frac>>25]]; dest[SCREENWIDTH*5] = colormap[source[(frac+fracstep)>>25]]; dest[SCREENWIDTH*6] = colormap[source[(frac+fracstep2)>>25]]; dest[SCREENWIDTH*7] = colormap[source[(frac+fracstep3)>>25]]; frac += fracstep4; dest += SCREENWIDTH*8; count -= 8; } while (count > 0) { *dest = colormap[source[frac>>25]]; dest += SCREENWIDTH; frac += fracstep; count--; } } #endif void R_DrawColumnLow ( lighttable_t * dc_colormap, byte * dc_source ) { int count; byte* dest; byte* dest2; fixed_t frac; fixed_t fracstep; count = ::g->dc_yh - ::g->dc_yl; // Zero length. if (count < 0) return; #ifdef RANGECHECK if ((unsigned)::g->dc_x >= SCREENWIDTH || ::g->dc_yl < 0 || ::g->dc_yh >= SCREENHEIGHT) { I_Error ("R_DrawColumn: %i to %i at %i", ::g->dc_yl, ::g->dc_yh, ::g->dc_x); } // ::g->dccount++; #endif // Blocky mode, need to multiply by 2. ::g->dc_x <<= 1; dest = ::g->ylookup[::g->dc_yl] + ::g->columnofs[::g->dc_x]; dest2 = ::g->ylookup[::g->dc_yl] + ::g->columnofs[::g->dc_x+1]; fracstep = ::g->dc_iscale; frac = ::g->dc_texturemid + (::g->dc_yl-::g->centery)*fracstep; do { // Hack. Does not work corretly. *dest2 = *dest = ::g->dc_colormap[::g->dc_source[(frac>>FRACBITS)&127]]; dest += SCREENWIDTH; dest2 += SCREENWIDTH; frac += fracstep; } while (count--); } // // Spectre/Invisibility. // // // Framebuffer postprocessing. // Creates a fuzzy image by copying pixels // from adjacent ones to left and right. // Used with an all black colormap, this // could create the SHADOW effect, // i.e. spectres and invisible ::g->players. // void R_DrawFuzzColumn ( lighttable_t * dc_colormap, byte * dc_source ) { int count; byte* dest; fixed_t frac; fixed_t fracstep; // Adjust borders. Low... if (!::g->dc_yl) ::g->dc_yl = 1; // .. and high. if (::g->dc_yh == ::g->viewheight-1) ::g->dc_yh = ::g->viewheight - 2; count = ::g->dc_yh - ::g->dc_yl; // Zero length. if (count < 0) return; #ifdef RANGECHECK if ((unsigned)::g->dc_x >= SCREENWIDTH || ::g->dc_yl < 0 || ::g->dc_yh >= SCREENHEIGHT) { I_Error ("R_DrawFuzzColumn: %i to %i at %i", ::g->dc_yl, ::g->dc_yh, ::g->dc_x); } #endif // Keep till ::g->detailshift bug in blocky mode fixed, // or blocky mode removed. /* WATCOM code if (::g->detailshift) { if (::g->dc_x & 1) { outpw (GC_INDEX,GC_READMAP+(2<<8) ); outp (SC_INDEX+1,12); } else { outpw (GC_INDEX,GC_READMAP); outp (SC_INDEX+1,3); } dest = destview + ::g->dc_yl*80 + (::g->dc_x>>1); } else { outpw (GC_INDEX,GC_READMAP+((::g->dc_x&3)<<8) ); outp (SC_INDEX+1,1<<(::g->dc_x&3)); dest = destview + ::g->dc_yl*80 + (::g->dc_x>>2); }*/ // Does not work with blocky mode. dest = ::g->ylookup[::g->dc_yl] + ::g->columnofs[::g->dc_x]; // Looks familiar. fracstep = ::g->dc_iscale; frac = ::g->dc_texturemid + (::g->dc_yl-::g->centery)*fracstep; // Looks like an attempt at dithering, // using the colormap #6 (of 0-31, a bit // brighter than average). do { // Lookup framebuffer, and retrieve // a pixel that is either one column // left or right of the current one. // Add index from colormap to index. *dest = ::g->colormaps[6*256+dest[::g->fuzzoffset[::g->fuzzpos]]]; // Clamp table lookup index. if (++::g->fuzzpos == FUZZTABLE) ::g->fuzzpos = 0; dest += SCREENWIDTH; frac += fracstep; } while (count--); } // // R_DrawTranslatedColumn // Used to draw player ::g->sprites // with the green colorramp mapped to others. // Could be used with different translation // tables, e.g. the lighter colored version // of the BaronOfHell, the HellKnight, uses // identical ::g->sprites, kinda brightened up. // void R_DrawTranslatedColumn ( lighttable_t * dc_colormap, byte * dc_source ) { int count; byte* dest; fixed_t frac; fixed_t fracstep; count = ::g->dc_yh - ::g->dc_yl; if (count < 0) return; #ifdef RANGECHECK if ((unsigned)::g->dc_x >= SCREENWIDTH || ::g->dc_yl < 0 || ::g->dc_yh >= SCREENHEIGHT) { I_Error ( "R_DrawColumn: %i to %i at %i", ::g->dc_yl, ::g->dc_yh, ::g->dc_x); } #endif // WATCOM VGA specific. /* Keep for fixing. if (::g->detailshift) { if (::g->dc_x & 1) outp (SC_INDEX+1,12); else outp (SC_INDEX+1,3); dest = destview + ::g->dc_yl*80 + (::g->dc_x>>1); } else { outp (SC_INDEX+1,1<<(::g->dc_x&3)); dest = destview + ::g->dc_yl*80 + (::g->dc_x>>2); }*/ // FIXME. As above. dest = ::g->ylookup[::g->dc_yl] + ::g->columnofs[::g->dc_x]; // Looks familiar. fracstep = ::g->dc_iscale; frac = ::g->dc_texturemid + (::g->dc_yl-::g->centery)*fracstep; // Here we do an additional index re-mapping. do { // Translation tables are used // to map certain colorramps to other ones, // used with PLAY ::g->sprites. // Thus the "green" ramp of the player 0 sprite // is mapped to gray, red, black/indigo. *dest = dc_colormap[::g->dc_translation[dc_source[frac>>FRACBITS]]]; dest += SCREENWIDTH; frac += fracstep; } while (count--); } // // R_InitTranslationTables // Creates the translation tables to map // the green color ramp to gray, brown, red. // Assumes a given structure of the PLAYPAL. // Could be read from a lump instead. // void R_InitTranslationTables (void) { int i; ::g->translationtables = (byte*)DoomLib::Z_Malloc (256*3+255, PU_STATIC, 0); ::g->translationtables = (byte *)(( (intptr_t)::g->translationtables + 255 )& ~255); // translate just the 16 green colors for (i=0 ; i<256 ; i++) { if (i >= 0x70 && i<= 0x7f) { // map green ramp to gray, brown, red ::g->translationtables[i] = 0x60 + (i&0xf); ::g->translationtables [i+256] = 0x40 + (i&0xf); ::g->translationtables [i+512] = 0x20 + (i&0xf); } else { // Keep all other colors as is. ::g->translationtables[i] = ::g->translationtables[i+256] = ::g->translationtables[i+512] = i; } } } // // R_DrawSpan // With DOOM style restrictions on view orientation, // the floors and ceilings consist of horizontal slices // or spans with constant z depth. // However, rotation around the world z axis is possible, // thus this mapping, while simpler and faster than // perspective correct texture mapping, has to traverse // the texture at an angle in all but a few cases. // In consequence, flats are not stored by column (like walls), // and the inner loop has to step in texture space u and v. // // start of a 64*64 tile image // just for profiling // // Draws the actual span. void R_DrawSpan ( fixed_t xfrac, fixed_t yfrac, fixed_t ds_y, int ds_x1, int ds_x2, fixed_t ds_xstep, fixed_t ds_ystep, lighttable_t * ds_colormap, byte * ds_source ) { byte* dest; int count; int spot; #ifdef RANGECHECK if (::g->ds_x2 < ::g->ds_x1 || ::g->ds_x1<0 || ::g->ds_x2>=SCREENWIDTH || (unsigned)::g->ds_y>SCREENHEIGHT) { I_Error( "R_DrawSpan: %i to %i at %i", ::g->ds_x1,::g->ds_x2,::g->ds_y); } // ::g->dscount++; #endif dest = ::g->ylookup[::g->ds_y] + ::g->columnofs[::g->ds_x1]; // We do not check for zero spans here? count = ds_x2 - g->ds_x1; if ( ds_x2 < ds_x1 ) { return; // SMF - think this is the sky } do { // Current texture index in u,v. spot = ((yfrac>>(16-6))&(63*64)) + ((xfrac>>16)&63); // Lookup pixel from flat texture tile, // re-index using light/colormap. *dest++ = ds_colormap[ds_source[spot]]; // Next step in u,v. xfrac += ds_xstep; yfrac += ds_ystep; } while (count--); } // UNUSED. // Loop unrolled by 4. #if 0 void R_DrawSpan (void) { unsigned position, step; byte* source; byte* colormap; byte* dest; unsigned count; usingned spot; unsigned value; unsigned temp; unsigned xtemp; unsigned ytemp; position = ((::g->ds_xfrac<<10)&0xffff0000) | ((::g->ds_yfrac>>6)&0xffff); step = ((::g->ds_xstep<<10)&0xffff0000) | ((::g->ds_ystep>>6)&0xffff); source = ::g->ds_source; colormap = ::g->ds_colormap; dest = ::g->ylookup[::g->ds_y] + ::g->columnofs[::g->ds_x1]; count = ::g->ds_x2 - ::g->ds_x1 + 1; while (count >= 4) { ytemp = position>>4; ytemp = ytemp & 4032; xtemp = position>>26; spot = xtemp | ytemp; position += step; dest[0] = colormap[source[spot]]; ytemp = position>>4; ytemp = ytemp & 4032; xtemp = position>>26; spot = xtemp | ytemp; position += step; dest[1] = colormap[source[spot]]; ytemp = position>>4; ytemp = ytemp & 4032; xtemp = position>>26; spot = xtemp | ytemp; position += step; dest[2] = colormap[source[spot]]; ytemp = position>>4; ytemp = ytemp & 4032; xtemp = position>>26; spot = xtemp | ytemp; position += step; dest[3] = colormap[source[spot]]; count -= 4; dest += 4; } while (count > 0) { ytemp = position>>4; ytemp = ytemp & 4032; xtemp = position>>26; spot = xtemp | ytemp; position += step; *dest++ = colormap[source[spot]]; count--; } } #endif // // Again.. // void R_DrawSpanLow ( fixed_t xfrac, fixed_t yfrac, fixed_t ds_y, int ds_x1, int ds_x2, fixed_t ds_xstep, fixed_t ds_ystep, lighttable_t * ds_colormap, byte * ds_source ) { byte* dest; int count; int spot; #ifdef RANGECHECK if (::g->ds_x2 < ::g->ds_x1 || ::g->ds_x1<0 || ::g->ds_x2>=SCREENWIDTH || (unsigned)::g->ds_y>SCREENHEIGHT) { I_Error( "R_DrawSpan: %i to %i at %i", ::g->ds_x1,::g->ds_x2,::g->ds_y); } // ::g->dscount++; #endif // Blocky mode, need to multiply by 2. ::g->ds_x1 <<= 1; ::g->ds_x2 <<= 1; dest = ::g->ylookup[::g->ds_y] + ::g->columnofs[::g->ds_x1]; count = ::g->ds_x2 - ::g->ds_x1; do { spot = ((yfrac>>(16-6))&(63*64)) + ((xfrac>>16)&63); // Lowres/blocky mode does it twice, // while scale is adjusted appropriately. *dest++ = ::g->ds_colormap[::g->ds_source[spot]]; *dest++ = ::g->ds_colormap[::g->ds_source[spot]]; xfrac += ::g->ds_xstep; yfrac += ::g->ds_ystep; } while (count--); } // // R_InitBuffer // Creats lookup tables that avoid // multiplies and other hazzles // for getting the framebuffer address // of a pixel to draw. // void R_InitBuffer ( int width, int height ) { int i; // Handle resize, // e.g. smaller view windows // with border and/or status bar. ::g->viewwindowx = (SCREENWIDTH-width) >> 1; // Column offset. For windows. for (i=0 ; icolumnofs[i] = ::g->viewwindowx + i; // Samw with base row offset. if (width == SCREENWIDTH) ::g->viewwindowy = 0; else ::g->viewwindowy = (SCREENHEIGHT-SBARHEIGHT-height) >> 1; // Preclaculate all row offsets. for (i=0 ; iylookup[i] = ::g->screens[0] + (i+::g->viewwindowy)*SCREENWIDTH; } // // R_FillBackScreen // Fills the back screen with a pattern // for variable screen sizes // Also draws a beveled edge. // void R_FillBackScreen (void) { byte* src; byte* dest; int x; int y; int width, height, windowx, windowy; patch_t* patch; // DOOM border patch. char name1[] = "FLOOR7_2"; // DOOM II border patch. char name2[] = "GRNROCK"; char* name; if (::g->scaledviewwidth == SCREENWIDTH) return; if ( ::g->gamemode == commercial) name = name2; else name = name1; src = (byte*)W_CacheLumpName (name, PU_CACHE_SHARED); dest = ::g->screens[1]; for (y=0 ; yscaledviewwidth / GLOBAL_IMAGE_SCALER; height = ::g->viewheight / GLOBAL_IMAGE_SCALER; windowx = ::g->viewwindowx / GLOBAL_IMAGE_SCALER; windowy = ::g->viewwindowy / GLOBAL_IMAGE_SCALER; patch = (patch_t*)W_CacheLumpName ("brdr_t",PU_CACHE_SHARED); for (x=0 ; xscreens[0]+ofs, ::g->screens[1]+ofs, count); } // // R_DrawViewBorder // Draws the border around the view // for different size windows? // void V_MarkRect ( int x, int y, int width, int height ); void R_DrawViewBorder (void) { int top; int side; int ofs; int i; if (::g->scaledviewwidth == SCREENWIDTH) return; top = ((SCREENHEIGHT-SBARHEIGHT)-::g->viewheight)/2; side = (SCREENWIDTH-::g->scaledviewwidth)/2; // copy top and one line of left side R_VideoErase (0, top*SCREENWIDTH+side); // copy one line of right side and bottom ofs = (::g->viewheight+top)*SCREENWIDTH-side; R_VideoErase (ofs, top*SCREENWIDTH+side); // copy ::g->sides using wraparound ofs = top*SCREENWIDTH + SCREENWIDTH-side; side <<= 1; for (i=1 ; i < ::g->viewheight ; i++) { R_VideoErase (ofs, side); ofs += SCREENWIDTH; } // ? V_MarkRect (0,0,SCREENWIDTH, SCREENHEIGHT-SBARHEIGHT); }