ref: 83a811038aa9ec2ebfeb464d6267f5725b7e53da
dir: /src/strife/r_main.c/
// // Copyright(C) 1993-1996 Id Software, Inc. // Copyright(C) 2005-2014 Simon Howard // // This program 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 2 // of the License, or (at your option) any later version. // // This program 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. // // DESCRIPTION: // Rendering main loop and setup functions, // utility functions (BSP, geometry, trigonometry). // See tables.c, too. // #include <stdlib.h> #include <math.h> #include "doomdef.h" #include "doomstat.h" // villsa [STRIFE] #include "d_main.h" #include "m_bbox.h" #include "m_menu.h" #include "r_local.h" #include "r_sky.h" // Fineangles in the SCREENWIDTH wide window. #define FIELDOFVIEW 2048 int viewangleoffset; // increment every time a check is made int validcount = 1; lighttable_t* fixedcolormap; extern lighttable_t** walllights; int centerx; int centery; fixed_t centerxfrac; fixed_t centeryfrac; fixed_t projection; // just for profiling purposes int framecount; int sscount; int linecount; int loopcount; fixed_t viewx; fixed_t viewy; fixed_t viewz; int viewpitch; // villsa [STRIFE] angle_t viewangle; fixed_t viewcos; fixed_t viewsin; player_t* viewplayer; // 0 = high, 1 = low int detailshift; // // precalculated math tables // angle_t clipangle; // The viewangletox[viewangle + FINEANGLES/4] lookup // maps the visible view angles to screen X coordinates, // flattening the arc to a flat projection plane. // There will be many angles mapped to the same X. int viewangletox[FINEANGLES/2]; // The xtoviewangleangle[] table maps a screen pixel // to the lowest viewangle that maps back to x ranges // from clipangle to -clipangle. angle_t xtoviewangle[SCREENWIDTH+1]; lighttable_t* scalelight[LIGHTLEVELS][MAXLIGHTSCALE]; lighttable_t* scalelightfixed[MAXLIGHTSCALE]; lighttable_t* zlight[LIGHTLEVELS][MAXLIGHTZ]; // bumped light from gun blasts int extralight; void (*colfunc) (void); void (*basecolfunc) (void); void (*fuzzcolfunc) (void); void (*transcolfunc) (void); void (*spanfunc) (void); // // R_AddPointToBox // Expand a given bbox // so that it encloses a given point. // void R_AddPointToBox ( int x, int y, fixed_t* box ) { if (x< box[BOXLEFT]) box[BOXLEFT] = x; if (x> box[BOXRIGHT]) box[BOXRIGHT] = x; if (y< box[BOXBOTTOM]) box[BOXBOTTOM] = y; if (y> box[BOXTOP]) box[BOXTOP] = y; } // // R_PointOnSide // Traverse BSP (sub) tree, // check point against partition plane. // Returns side 0 (front) or 1 (back). // int R_PointOnSide ( fixed_t x, fixed_t y, node_t* node ) { fixed_t dx; fixed_t dy; fixed_t left; fixed_t right; if (!node->dx) { if (x <= node->x) return node->dy > 0; return node->dy < 0; } if (!node->dy) { if (y <= node->y) return node->dx < 0; return node->dx > 0; } dx = (x - node->x); dy = (y - node->y); // Try to quickly decide by looking at sign bits. if ( (node->dy ^ node->dx ^ dx ^ dy)&0x80000000 ) { if ( (node->dy ^ dx) & 0x80000000 ) { // (left is negative) return 1; } return 0; } left = FixedMul ( node->dy>>FRACBITS , dx ); right = FixedMul ( dy , node->dx>>FRACBITS ); if (right < left) { // front side return 0; } // back side return 1; } int R_PointOnSegSide ( fixed_t x, fixed_t y, seg_t* line ) { fixed_t lx; fixed_t ly; fixed_t ldx; fixed_t ldy; fixed_t dx; fixed_t dy; fixed_t left; fixed_t right; lx = line->v1->x; ly = line->v1->y; ldx = line->v2->x - lx; ldy = line->v2->y - ly; if (!ldx) { if (x <= lx) return ldy > 0; return ldy < 0; } if (!ldy) { if (y <= ly) return ldx < 0; return ldx > 0; } dx = (x - lx); dy = (y - ly); // Try to quickly decide by looking at sign bits. if ( (ldy ^ ldx ^ dx ^ dy)&0x80000000 ) { if ( (ldy ^ dx) & 0x80000000 ) { // (left is negative) return 1; } return 0; } left = FixedMul ( ldy>>FRACBITS , dx ); right = FixedMul ( dy , ldx>>FRACBITS ); if (right < left) { // front side return 0; } // back side return 1; } // // R_PointToAngle // To get a global angle from cartesian coordinates, // the coordinates are flipped until they are in // the first octant of the coordinate system, then // the y (<=x) is scaled and divided by x to get a // tangent (slope) value which is looked up in the // tantoangle[] table. // angle_t R_PointToAngle ( fixed_t x, fixed_t y ) { x -= viewx; y -= viewy; if ( (!x) && (!y) ) return 0; if (x>= 0) { // x >=0 if (y>= 0) { // y>= 0 if (x>y) { // octant 0 return tantoangle[ SlopeDiv(y,x)]; } else { // octant 1 return ANG90-1-tantoangle[ SlopeDiv(x,y)]; } } else { // y<0 y = -y; if (x>y) { // octant 8 return 0 - tantoangle[SlopeDiv(y,x)]; } else { // octant 7 return ANG270+tantoangle[ SlopeDiv(x,y)]; } } } else { // x<0 x = -x; if (y>= 0) { // y>= 0 if (x>y) { // octant 3 return ANG180-1-tantoangle[ SlopeDiv(y,x)]; } else { // octant 2 return ANG90+ tantoangle[ SlopeDiv(x,y)]; } } else { // y<0 y = -y; if (x>y) { // octant 4 return ANG180+tantoangle[ SlopeDiv(y,x)]; } else { // octant 5 return ANG270-1-tantoangle[ SlopeDiv(x,y)]; } } } return 0; } angle_t R_PointToAngle2 ( fixed_t x1, fixed_t y1, fixed_t x2, fixed_t y2 ) { viewx = x1; viewy = y1; return R_PointToAngle (x2, y2); } fixed_t R_PointToDist ( fixed_t x, fixed_t y ) { int angle; fixed_t dx; fixed_t dy; fixed_t temp; fixed_t dist; fixed_t frac; dx = abs(x - viewx); dy = abs(y - viewy); if (dy>dx) { temp = dx; dx = dy; dy = temp; } // Fix crashes in udm1.wad if (dx != 0) { frac = FixedDiv(dy, dx); } else { frac = 0; } angle = (tantoangle[frac>>DBITS]+ANG90) >> ANGLETOFINESHIFT; // use as cosine dist = FixedDiv (dx, finesine[angle] ); return dist; } // // R_InitPointToAngle // void R_InitPointToAngle (void) { // UNUSED - now getting from tables.c #if 0 int i; long t; float f; // // slope (tangent) to angle lookup // for (i=0 ; i<=SLOPERANGE ; i++) { f = atan( (float)i/SLOPERANGE )/(3.141592657*2); t = 0xffffffff*f; tantoangle[i] = t; } #endif } // // R_ScaleFromGlobalAngle // Returns the texture mapping scale // for the current line (horizontal span) // at the given angle. // rw_distance must be calculated first. // fixed_t R_ScaleFromGlobalAngle (angle_t visangle) { fixed_t scale; angle_t anglea; angle_t angleb; int sinea; int sineb; fixed_t num; int den; // UNUSED #if 0 { fixed_t dist; fixed_t z; fixed_t sinv; fixed_t cosv; sinv = finesine[(visangle-rw_normalangle)>>ANGLETOFINESHIFT]; dist = FixedDiv (rw_distance, sinv); cosv = finecosine[(viewangle-visangle)>>ANGLETOFINESHIFT]; z = abs(FixedMul (dist, cosv)); scale = FixedDiv(projection, z); return scale; } #endif anglea = ANG90 + (visangle-viewangle); angleb = ANG90 + (visangle-rw_normalangle); // both sines are allways positive sinea = finesine[anglea>>ANGLETOFINESHIFT]; sineb = finesine[angleb>>ANGLETOFINESHIFT]; num = FixedMul(projection,sineb)<<detailshift; den = FixedMul(rw_distance,sinea); if (den > num>>16) { scale = FixedDiv (num, den); if (scale > 64*FRACUNIT) scale = 64*FRACUNIT; else if (scale < 256) scale = 256; } else scale = 64*FRACUNIT; return scale; } // // R_InitTables // void R_InitTables (void) { // UNUSED: now getting from tables.c #if 0 int i; float a; float fv; int t; // viewangle tangent table for (i=0 ; i<FINEANGLES/2 ; i++) { a = (i-FINEANGLES/4+0.5)*PI*2/FINEANGLES; fv = FRACUNIT*tan (a); t = fv; finetangent[i] = t; } // finesine table for (i=0 ; i<5*FINEANGLES/4 ; i++) { // OPTIMIZE: mirror... a = (i+0.5)*PI*2/FINEANGLES; t = FRACUNIT*sin (a); finesine[i] = t; } #endif } // // R_InitTextureMapping // void R_InitTextureMapping (void) { int i; int x; int t; fixed_t focallength; // Use tangent table to generate viewangletox: // viewangletox will give the next greatest x // after the view angle. // // Calc focallength // so FIELDOFVIEW angles covers SCREENWIDTH. focallength = FixedDiv (centerxfrac, finetangent[FINEANGLES/4+FIELDOFVIEW/2] ); for (i=0 ; i<FINEANGLES/2 ; i++) { if (finetangent[i] > FRACUNIT*2) t = -1; else if (finetangent[i] < -FRACUNIT*2) t = viewwidth+1; else { t = FixedMul (finetangent[i], focallength); t = (centerxfrac - t+FRACUNIT-1)>>FRACBITS; if (t < -1) t = -1; else if (t>viewwidth+1) t = viewwidth+1; } viewangletox[i] = t; } // Scan viewangletox[] to generate xtoviewangle[]: // xtoviewangle will give the smallest view angle // that maps to x. for (x=0;x<=viewwidth;x++) { i = 0; while (viewangletox[i]>x) i++; xtoviewangle[x] = (i<<ANGLETOFINESHIFT)-ANG90; } // Take out the fencepost cases from viewangletox. for (i=0 ; i<FINEANGLES/2 ; i++) { t = FixedMul (finetangent[i], focallength); t = centerx - t; if (viewangletox[i] == -1) viewangletox[i] = 0; else if (viewangletox[i] == viewwidth+1) viewangletox[i] = viewwidth; } clipangle = xtoviewangle[0]; } // // R_InitLightTables // Only inits the zlight table, // because the scalelight table changes with view size. // #define DISTMAP 2 void R_InitLightTables (void) { int i; int j; int level; int startmap; int scale; // Calculate the light levels to use // for each level / distance combination. for (i=0 ; i< LIGHTLEVELS ; i++) { startmap = ((LIGHTLEVELS-1-i)*2)*NUMCOLORMAPS/LIGHTLEVELS; for (j=0 ; j<MAXLIGHTZ ; j++) { scale = FixedDiv ((SCREENWIDTH/2*FRACUNIT), (j+1)<<LIGHTZSHIFT); scale >>= LIGHTSCALESHIFT; level = startmap - scale/DISTMAP; if (level < 0) level = 0; if (level >= NUMCOLORMAPS) level = NUMCOLORMAPS-1; zlight[i][j] = colormaps + level*256; } } } // // R_SetViewSize // Do not really change anything here, // because it might be in the middle of a refresh. // The change will take effect next refresh. // boolean setsizeneeded; int setblocks; int setdetail; void R_SetViewSize ( int blocks, int detail ) { setsizeneeded = true; setblocks = blocks; setdetail = detail; } // // R_ExecuteSetViewSize // void R_ExecuteSetViewSize (void) { fixed_t cosadj; fixed_t dy; int i; int j; int level; int startmap; setsizeneeded = false; if (setblocks == 11) { scaledviewwidth = SCREENWIDTH; viewheight = SCREENHEIGHT; } else { scaledviewwidth = setblocks*32; viewheight = (setblocks*168/10)&~7; } detailshift = setdetail; viewwidth = scaledviewwidth>>detailshift; // villsa [STRIFE] calculate centery from player's pitch centery = (setblocks*players[consoleplayer].pitch); centery = (unsigned int)(centery/10)+viewheight/2; centerx = viewwidth/2; centerxfrac = centerx<<FRACBITS; centeryfrac = centery<<FRACBITS; projection = centerxfrac; //if (!detailshift) // villsa [STRIFE] { colfunc = basecolfunc = R_DrawColumn; fuzzcolfunc = R_DrawTLColumn; // villsa [STRIFE] transcolfunc = R_DrawTranslatedColumn; spanfunc = R_DrawSpan; } // villsa [STRIFE] unused detail stuff /*else { colfunc = basecolfunc = R_DrawColumnLow; fuzzcolfunc = R_DrawFuzzColumnLow; transcolfunc = R_DrawTranslatedColumnLow; spanfunc = R_DrawSpanLow; }*/ R_InitBuffer (scaledviewwidth, viewheight); R_InitTextureMapping (); // psprite scales pspritescale = FRACUNIT*viewwidth/SCREENWIDTH; pspriteiscale = FRACUNIT*SCREENWIDTH/viewwidth; // thing clipping for (i=0 ; i<viewwidth ; i++) screenheightarray[i] = viewheight; // planes for (i=0 ; i<viewheight ; i++) { // haleyjd 20120208: [STRIFE] viewheight/2 -> centery, accounts for up/down look dy = ((i - centery)<<FRACBITS) + FRACUNIT/2; dy = abs(dy); yslope[i] = FixedDiv ( (viewwidth<<detailshift)/2*FRACUNIT, dy); } for (i=0 ; i<viewwidth ; i++) { cosadj = abs(finecosine[xtoviewangle[i]>>ANGLETOFINESHIFT]); distscale[i] = FixedDiv (FRACUNIT,cosadj); } // Calculate the light levels to use // for each level / scale combination. for (i=0 ; i< LIGHTLEVELS ; i++) { startmap = ((LIGHTLEVELS-1-i)*2)*NUMCOLORMAPS/LIGHTLEVELS; for (j=0 ; j<MAXLIGHTSCALE ; j++) { level = startmap - j*SCREENWIDTH/(viewwidth<<detailshift)/DISTMAP; if (level < 0) level = 0; if (level >= NUMCOLORMAPS) level = NUMCOLORMAPS-1; scalelight[i][j] = colormaps + level*256; } } } // // R_Init // void R_Init (void) { R_InitData (); if(devparm) printf ("."); else D_IntroTick(); // [STRIFE] tick intro R_InitPointToAngle (); if(devparm) printf ("."); R_InitTables (); // viewwidth / viewheight / detailLevel are set by the defaults if(devparm) printf ("."); R_SetViewSize (screenblocks, detailLevel); R_InitPlanes (); if(devparm) printf ("."); R_InitLightTables (); if(devparm) printf ("."); else D_IntroTick(); R_InitSkyMap (); if(!devparm) D_IntroTick(); R_InitTranslationTables (); if(devparm) printf ("."); else D_IntroTick(); framecount = 0; } // // R_PointInSubsector // subsector_t* R_PointInSubsector ( fixed_t x, fixed_t y ) { node_t* node; int side; int nodenum; // single subsector is a special case if (!numnodes) return subsectors; nodenum = numnodes-1; while (! (nodenum & NF_SUBSECTOR) ) { node = &nodes[nodenum]; side = R_PointOnSide (x, y, node); nodenum = node->children[side]; } return &subsectors[nodenum & ~NF_SUBSECTOR]; } // // R_SetupPitch // villsa [STRIFE] new function // Calculate centery/centeryfrac for player viewpitch // void R_SetupPitch(player_t* player) { int pitchfrac; int i = 0; if(viewpitch != player->pitch) { viewpitch = player->pitch; pitchfrac = (setblocks * player->pitch) / 10; centery = pitchfrac + viewheight / 2; centeryfrac = centery << FRACBITS; for(i = 0; i < viewheight; i++) { yslope[i] = FixedDiv(viewwidth / 2 * FRACUNIT, abs(((i - centery) << FRACBITS) + (FRACUNIT/2))); } } } // // R_SetupFrame // void R_SetupFrame (player_t* player) { int i; R_SetupPitch(player); // villsa [STRIFE] viewplayer = player; viewx = player->mo->x; viewy = player->mo->y; viewangle = player->mo->angle + viewangleoffset; extralight = player->extralight; viewz = player->viewz; viewsin = finesine[viewangle>>ANGLETOFINESHIFT]; viewcos = finecosine[viewangle>>ANGLETOFINESHIFT]; sscount = 0; if (player->fixedcolormap) { fixedcolormap = colormaps + player->fixedcolormap*256*sizeof(lighttable_t); walllights = scalelightfixed; for (i=0 ; i<MAXLIGHTSCALE ; i++) scalelightfixed[i] = fixedcolormap; } else fixedcolormap = 0; framecount++; validcount++; } // // R_RenderView // void R_RenderPlayerView (player_t* player) { R_SetupFrame (player); // Clear buffers. R_ClearClipSegs (); R_ClearDrawSegs (); R_ClearPlanes (); R_ClearSprites (); // check for new console commands. NetUpdate (); // The head node is the last node output. R_RenderBSPNode (numnodes-1); // Check for new console commands. NetUpdate (); R_DrawPlanes (); // Check for new console commands. NetUpdate (); R_DrawMasked (); // Check for new console commands. NetUpdate (); }