/* d_polyse.c routines for drawing sets of polygons sharing the same texture (used for Alias models) Copyright (C) 1996-1997 Id Software, Inc. 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. You should have received a copy of the GNU General Public License along with this program; if not, write to: Free Software Foundation, Inc. 59 Temple Place - Suite 330 Boston, MA 02111-1307, USA $Id$ */ #ifdef HAVE_CONFIG_H # include "config.h" #endif #include "r_local.h" #include "d_local.h" // TODO: put in span spilling to shrink list size // !!! if this is changed, it must be changed in d_polysa.s too !!! #define DPS_MAXSPANS MAXHEIGHT+1 // 1 extra for spanpackage that marks end // !!! if this is changed, it must be changed in asm_draw.h too !!! typedef struct { void *pdest; short *pz; int count; byte *ptex; int sfrac, tfrac, light, zi; } spanpackage_t; typedef struct { int isflattop; int numleftedges; int *pleftedgevert0; int *pleftedgevert1; int *pleftedgevert2; int numrightedges; int *prightedgevert0; int *prightedgevert1; int *prightedgevert2; } edgetable; int r_p0[6], r_p1[6], r_p2[6]; byte *d_pcolormap; int d_aflatcolor; int d_xdenom; edgetable *pedgetable; edgetable edgetables[12] = { {0, 1, r_p0, r_p2, NULL, 2, r_p0, r_p1, r_p2}, {0, 2, r_p1, r_p0, r_p2, 1, r_p1, r_p2, NULL}, {1, 1, r_p0, r_p2, NULL, 1, r_p1, r_p2, NULL}, {0, 1, r_p1, r_p0, NULL, 2, r_p1, r_p2, r_p0}, {0, 2, r_p0, r_p2, r_p1, 1, r_p0, r_p1, NULL}, {0, 1, r_p2, r_p1, NULL, 1, r_p2, r_p0, NULL}, {0, 1, r_p2, r_p1, NULL, 2, r_p2, r_p0, r_p1}, {0, 2, r_p2, r_p1, r_p0, 1, r_p2, r_p0, NULL}, {0, 1, r_p1, r_p0, NULL, 1, r_p1, r_p2, NULL}, {1, 1, r_p2, r_p1, NULL, 1, r_p0, r_p1, NULL}, {1, 1, r_p1, r_p0, NULL, 1, r_p2, r_p0, NULL}, {0, 1, r_p0, r_p2, NULL, 1, r_p0, r_p1, NULL}, }; // FIXME: some of these can become statics int a_sstepxfrac, a_tstepxfrac, r_lstepx, a_ststepxwhole; int r_sstepx, r_tstepx, r_lstepy, r_sstepy, r_tstepy; int r_zistepx, r_zistepy; int d_aspancount, d_countextrastep; spanpackage_t *a_spans; spanpackage_t *d_pedgespanpackage; static int ystart; byte *d_pdest, *d_ptex; short *d_pz; int d_sfrac, d_tfrac, d_light, d_zi; int d_ptexextrastep, d_sfracextrastep; int d_tfracextrastep, d_lightextrastep, d_pdestextrastep; int d_lightbasestep, d_pdestbasestep, d_ptexbasestep; int d_sfracbasestep, d_tfracbasestep; int d_ziextrastep, d_zibasestep; int d_pzextrastep, d_pzbasestep; typedef struct { int quotient; int remainder; } adivtab_t; static adivtab_t adivtab[32 * 32] = { #include "adivtab.h" }; byte *skintable[MAX_LBM_HEIGHT]; int skinwidth; byte *skinstart; void D_PolysetDrawSpans8 (spanpackage_t * pspanpackage); void D_PolysetCalcGradients (int skinwidth); void D_DrawSubdiv (void); void D_DrawNonSubdiv (void); void D_PolysetRecursiveTriangle (int *p1, int *p2, int *p3); void D_PolysetSetEdgeTable (void); void D_RasterizeAliasPolySmooth (void); void D_PolysetScanLeftEdge (int height); #ifndef USE_INTEL_ASM void D_PolysetDraw (void) { spanpackage_t spans[DPS_MAXSPANS + 1 + ((CACHE_SIZE - 1) / sizeof (spanpackage_t)) + 1]; // one extra because of cache line pretouching a_spans = (spanpackage_t *) (((long) &spans[0] + CACHE_SIZE - 1) & ~(CACHE_SIZE - 1)); if (r_affinetridesc.drawtype) { D_DrawSubdiv (); } else { D_DrawNonSubdiv (); } } void D_PolysetDrawFinalVerts (finalvert_t *fv, int numverts) { int i, z; short *zbuf; for (i = 0; i < numverts; i++, fv++) { // valid triangle coordinates for filling can include the bottom and // right clip edges, due to the fill rule; these shouldn't be drawn if ((fv->v[0] < r_refdef.vrectright) && (fv->v[1] < r_refdef.vrectbottom)) { z = fv->v[5] >> 16; zbuf = zspantable[fv->v[1]] + fv->v[0]; if (z >= *zbuf) { int pix; *zbuf = z; pix = skintable[fv->v[3] >> 16][fv->v[2] >> 16]; pix = ((byte *) acolormap)[pix + (fv->v[4] & 0xFF00)]; d_viewbuffer[d_scantable[fv->v[1]] + fv->v[0]] = pix; } } } } void D_DrawSubdiv (void) { mtriangle_t *ptri; finalvert_t *pfv, *index0, *index1, *index2; int i; int lnumtriangles; pfv = r_affinetridesc.pfinalverts; ptri = r_affinetridesc.ptriangles; lnumtriangles = r_affinetridesc.numtriangles; for (i = 0; i < lnumtriangles; i++) { index0 = pfv + ptri[i].vertindex[0]; index1 = pfv + ptri[i].vertindex[1]; index2 = pfv + ptri[i].vertindex[2]; if (((index0->v[1] - index1->v[1]) * (index0->v[0] - index2->v[0]) - (index0->v[0] - index1->v[0]) * (index0->v[1] - index2->v[1])) >= 0) { continue; } d_pcolormap = &((byte *) acolormap)[index0->v[4] & 0xFF00]; if (ptri[i].facesfront) { D_PolysetRecursiveTriangle (index0->v, index1->v, index2->v); } else { int s0, s1, s2; s0 = index0->v[2]; s1 = index1->v[2]; s2 = index2->v[2]; if (index0->flags & ALIAS_ONSEAM) index0->v[2] += r_affinetridesc.seamfixupX16; if (index1->flags & ALIAS_ONSEAM) index1->v[2] += r_affinetridesc.seamfixupX16; if (index2->flags & ALIAS_ONSEAM) index2->v[2] += r_affinetridesc.seamfixupX16; D_PolysetRecursiveTriangle (index0->v, index1->v, index2->v); index0->v[2] = s0; index1->v[2] = s1; index2->v[2] = s2; } } } void D_DrawNonSubdiv (void) { mtriangle_t *ptri; finalvert_t *pfv, *index0, *index1, *index2; int i; int lnumtriangles; pfv = r_affinetridesc.pfinalverts; ptri = r_affinetridesc.ptriangles; lnumtriangles = r_affinetridesc.numtriangles; for (i = 0; i < lnumtriangles; i++, ptri++) { index0 = pfv + ptri->vertindex[0]; index1 = pfv + ptri->vertindex[1]; index2 = pfv + ptri->vertindex[2]; d_xdenom = (index0->v[1] - index1->v[1]) * (index0->v[0] - index2->v[0]) - (index0->v[0] - index1->v[0]) * (index0->v[1] - index2->v[1]); if (d_xdenom >= 0) { continue; } r_p0[0] = index0->v[0]; // u r_p0[1] = index0->v[1]; // v r_p0[2] = index0->v[2]; // s r_p0[3] = index0->v[3]; // t r_p0[4] = index0->v[4]; // light r_p0[5] = index0->v[5]; // iz r_p1[0] = index1->v[0]; r_p1[1] = index1->v[1]; r_p1[2] = index1->v[2]; r_p1[3] = index1->v[3]; r_p1[4] = index1->v[4]; r_p1[5] = index1->v[5]; r_p2[0] = index2->v[0]; r_p2[1] = index2->v[1]; r_p2[2] = index2->v[2]; r_p2[3] = index2->v[3]; r_p2[4] = index2->v[4]; r_p2[5] = index2->v[5]; if (!ptri->facesfront) { if (index0->flags & ALIAS_ONSEAM) r_p0[2] += r_affinetridesc.seamfixupX16; if (index1->flags & ALIAS_ONSEAM) r_p1[2] += r_affinetridesc.seamfixupX16; if (index2->flags & ALIAS_ONSEAM) r_p2[2] += r_affinetridesc.seamfixupX16; } D_PolysetSetEdgeTable (); D_RasterizeAliasPolySmooth (); } } void D_PolysetRecursiveTriangle (int *lp1, int *lp2, int *lp3) { int *temp; int d; int new[6]; int z; short *zbuf; d = lp2[0] - lp1[0]; if (d < -1 || d > 1) goto split; d = lp2[1] - lp1[1]; if (d < -1 || d > 1) goto split; d = lp3[0] - lp2[0]; if (d < -1 || d > 1) goto split2; d = lp3[1] - lp2[1]; if (d < -1 || d > 1) goto split2; d = lp1[0] - lp3[0]; if (d < -1 || d > 1) goto split3; d = lp1[1] - lp3[1]; if (d < -1 || d > 1) { split3: temp = lp1; lp1 = lp3; lp3 = lp2; lp2 = temp; goto split; } return; // entire tri is filled split2: temp = lp1; lp1 = lp2; lp2 = lp3; lp3 = temp; split: // split this edge new[0] = (lp1[0] + lp2[0]) >> 1; new[1] = (lp1[1] + lp2[1]) >> 1; new[2] = (lp1[2] + lp2[2]) >> 1; new[3] = (lp1[3] + lp2[3]) >> 1; new[5] = (lp1[5] + lp2[5]) >> 1; // draw the point if splitting a leading edge if (lp2[1] > lp1[1]) goto nodraw; if ((lp2[1] == lp1[1]) && (lp2[0] < lp1[0])) goto nodraw; z = new[5] >> 16; zbuf = zspantable[new[1]] + new[0]; if (z >= *zbuf) { int pix; *zbuf = z; pix = d_pcolormap[skintable[new[3] >> 16][new[2] >> 16]]; d_viewbuffer[d_scantable[new[1]] + new[0]] = pix; } nodraw: // recursively continue D_PolysetRecursiveTriangle (lp3, lp1, new); D_PolysetRecursiveTriangle (lp3, new, lp2); } #endif // !USE_INTEL_ASM void D_PolysetUpdateTables (void) { int i; byte *s; if (r_affinetridesc.skinwidth != skinwidth || r_affinetridesc.pskin != skinstart) { skinwidth = r_affinetridesc.skinwidth; skinstart = r_affinetridesc.pskin; s = skinstart; for (i = 0; i < MAX_LBM_HEIGHT; i++, s += skinwidth) skintable[i] = s; } } #ifndef USE_INTEL_ASM void D_PolysetScanLeftEdge (int height) { do { d_pedgespanpackage->pdest = d_pdest; d_pedgespanpackage->pz = d_pz; d_pedgespanpackage->count = d_aspancount; d_pedgespanpackage->ptex = d_ptex; d_pedgespanpackage->sfrac = d_sfrac; d_pedgespanpackage->tfrac = d_tfrac; // FIXME: need to clamp l, s, t, at both ends? d_pedgespanpackage->light = d_light; d_pedgespanpackage->zi = d_zi; d_pedgespanpackage++; errorterm += erroradjustup; if (errorterm >= 0) { d_pdest += d_pdestextrastep; d_pz += d_pzextrastep; d_aspancount += d_countextrastep; d_ptex += d_ptexextrastep; d_sfrac += d_sfracextrastep; d_ptex += d_sfrac >> 16; d_sfrac &= 0xFFFF; d_tfrac += d_tfracextrastep; if (d_tfrac & 0x10000) { d_ptex += r_affinetridesc.skinwidth; d_tfrac &= 0xFFFF; } d_light += d_lightextrastep; d_zi += d_ziextrastep; errorterm -= erroradjustdown; } else { d_pdest += d_pdestbasestep; d_pz += d_pzbasestep; d_aspancount += ubasestep; d_ptex += d_ptexbasestep; d_sfrac += d_sfracbasestep; d_ptex += d_sfrac >> 16; d_sfrac &= 0xFFFF; d_tfrac += d_tfracbasestep; if (d_tfrac & 0x10000) { d_ptex += r_affinetridesc.skinwidth; d_tfrac &= 0xFFFF; } d_light += d_lightbasestep; d_zi += d_zibasestep; } } while (--height); } #endif // !USE_INTEL_ASM void D_PolysetSetUpForLineScan (fixed8_t startvertu, fixed8_t startvertv, fixed8_t endvertu, fixed8_t endvertv) { double dm, dn; int tm, tn; adivtab_t *ptemp; // TODO: implement x86 version errorterm = -1; tm = endvertu - startvertu; tn = endvertv - startvertv; if (((tm <= 16) && (tm >= -15)) && ((tn <= 16) && (tn >= -15))) { ptemp = &adivtab[((tm + 15) << 5) + (tn + 15)]; ubasestep = ptemp->quotient; erroradjustup = ptemp->remainder; erroradjustdown = tn; } else { dm = (double) tm; dn = (double) tn; FloorDivMod (dm, dn, &ubasestep, &erroradjustup); erroradjustdown = dn; } } #ifndef USE_INTEL_ASM void D_PolysetCalcGradients (int skinwidth) { float xstepdenominv, ystepdenominv, t0, t1; float p01_minus_p21, p11_minus_p21, p00_minus_p20, p10_minus_p20; p00_minus_p20 = r_p0[0] - r_p2[0]; p01_minus_p21 = r_p0[1] - r_p2[1]; p10_minus_p20 = r_p1[0] - r_p2[0]; p11_minus_p21 = r_p1[1] - r_p2[1]; xstepdenominv = 1.0 / (float) d_xdenom; ystepdenominv = -xstepdenominv; // ceil () for light so positive steps are exaggerated, negative steps // diminished, pushing us away from underflow toward overflow. Underflow is // very visible, overflow is very unlikely, because of ambient lighting t0 = r_p0[4] - r_p2[4]; t1 = r_p1[4] - r_p2[4]; r_lstepx = (int) ceil ((t1 * p01_minus_p21 - t0 * p11_minus_p21) * xstepdenominv); r_lstepy = (int) ceil ((t1 * p00_minus_p20 - t0 * p10_minus_p20) * ystepdenominv); t0 = r_p0[2] - r_p2[2]; t1 = r_p1[2] - r_p2[2]; r_sstepx = (int) ((t1 * p01_minus_p21 - t0 * p11_minus_p21) * xstepdenominv); r_sstepy = (int) ((t1 * p00_minus_p20 - t0 * p10_minus_p20) * ystepdenominv); t0 = r_p0[3] - r_p2[3]; t1 = r_p1[3] - r_p2[3]; r_tstepx = (int) ((t1 * p01_minus_p21 - t0 * p11_minus_p21) * xstepdenominv); r_tstepy = (int) ((t1 * p00_minus_p20 - t0 * p10_minus_p20) * ystepdenominv); t0 = r_p0[5] - r_p2[5]; t1 = r_p1[5] - r_p2[5]; r_zistepx = (int) ((t1 * p01_minus_p21 - t0 * p11_minus_p21) * xstepdenominv); r_zistepy = (int) ((t1 * p00_minus_p20 - t0 * p10_minus_p20) * ystepdenominv); #ifdef USE_INTEL_ASM a_sstepxfrac = r_sstepx << 16; a_tstepxfrac = r_tstepx << 16; #else a_sstepxfrac = r_sstepx & 0xFFFF; a_tstepxfrac = r_tstepx & 0xFFFF; #endif a_ststepxwhole = skinwidth * (r_tstepx >> 16) + (r_sstepx >> 16); } #endif // !USE_INTEL_ASM byte gelmap[256]; void InitGel (byte * palette) { int i; int r; for (i = 0; i < 256; i++) { // r = (palette[i*3]>>4); r = (palette[i * 3] + palette[i * 3 + 1] + palette[i * 3 + 2]) / (16 * 3); gelmap[i] = /* 64 */ 0 + r; } } #ifndef USE_INTEL_ASM void D_PolysetDrawSpans8 (spanpackage_t * pspanpackage) { int lcount; byte *lpdest; byte *lptex; int lsfrac, ltfrac; int llight; int lzi; short *lpz; do { lcount = d_aspancount - pspanpackage->count; errorterm += erroradjustup; if (errorterm >= 0) { d_aspancount += d_countextrastep; errorterm -= erroradjustdown; } else { d_aspancount += ubasestep; } if (lcount) { lpdest = pspanpackage->pdest; lptex = pspanpackage->ptex; lpz = pspanpackage->pz; lsfrac = pspanpackage->sfrac; ltfrac = pspanpackage->tfrac; llight = pspanpackage->light; lzi = pspanpackage->zi; do { if ((lzi >> 16) >= *lpz) { *lpdest = ((byte *) acolormap)[*lptex + (llight & 0xFF00)]; // gel mapping *lpdest = gelmap[*lpdest]; *lpz = lzi >> 16; } lpdest++; lzi += r_zistepx; lpz++; llight += r_lstepx; lptex += a_ststepxwhole; lsfrac += a_sstepxfrac; lptex += lsfrac >> 16; lsfrac &= 0xFFFF; ltfrac += a_tstepxfrac; if (ltfrac & 0x10000) { lptex += r_affinetridesc.skinwidth; ltfrac &= 0xFFFF; } } while (--lcount); } pspanpackage++; } while (pspanpackage->count != -999999); } #endif // !USE_INTEL_ASM void D_PolysetFillSpans8 (spanpackage_t * pspanpackage) { int color; // FIXME: do z buffering color = d_aflatcolor++; while (1) { int lcount; byte *lpdest; lcount = pspanpackage->count; if (lcount == -1) return; if (lcount) { lpdest = pspanpackage->pdest; do { *lpdest++ = color; } while (--lcount); } pspanpackage++; } } void D_RasterizeAliasPolySmooth (void) { int initialleftheight, initialrightheight; int *plefttop, *prighttop, *pleftbottom, *prightbottom; int working_lstepx, originalcount; plefttop = pedgetable->pleftedgevert0; prighttop = pedgetable->prightedgevert0; pleftbottom = pedgetable->pleftedgevert1; prightbottom = pedgetable->prightedgevert1; initialleftheight = pleftbottom[1] - plefttop[1]; initialrightheight = prightbottom[1] - prighttop[1]; // set the s, t, and light gradients, which are consistent across the // triangle, because being a triangle, things are affine D_PolysetCalcGradients (r_affinetridesc.skinwidth); // rasterize the polygon // scan out the top (and possibly only) part of the left edge D_PolysetSetUpForLineScan (plefttop[0], plefttop[1], pleftbottom[0], pleftbottom[1]); d_pedgespanpackage = a_spans; ystart = plefttop[1]; d_aspancount = plefttop[0] - prighttop[0]; d_ptex = (byte *) r_affinetridesc.pskin + (plefttop[2] >> 16) + (plefttop[3] >> 16) * r_affinetridesc.skinwidth; #ifdef USE_INTEL_ASM d_sfrac = (plefttop[2] & 0xFFFF) << 16; d_tfrac = (plefttop[3] & 0xFFFF) << 16; d_pzbasestep = (d_zwidth + ubasestep) << 1; d_pzextrastep = d_pzbasestep + 2; #else d_sfrac = plefttop[2] & 0xFFFF; d_tfrac = plefttop[3] & 0xFFFF; d_pzbasestep = d_zwidth + ubasestep; d_pzextrastep = d_pzbasestep + 1; #endif d_light = plefttop[4]; d_zi = plefttop[5]; d_pdestbasestep = screenwidth + ubasestep; d_pdestextrastep = d_pdestbasestep + 1; d_pdest = (byte *) d_viewbuffer + ystart * screenwidth + plefttop[0]; d_pz = d_pzbuffer + ystart * d_zwidth + plefttop[0]; // TODO: can reuse partial expressions here // for negative steps in x along left edge, bias toward overflow rather // than underflow (sort of turning the floor () we did in the gradient // calcs into ceil (), but plus a little bit) if (ubasestep < 0) working_lstepx = r_lstepx - 1; else working_lstepx = r_lstepx; d_countextrastep = ubasestep + 1; d_ptexbasestep = ((r_sstepy + r_sstepx * ubasestep) >> 16) + ((r_tstepy + r_tstepx * ubasestep) >> 16) * r_affinetridesc.skinwidth; #ifdef USE_INTEL_ASM d_sfracbasestep = (r_sstepy + r_sstepx * ubasestep) << 16; d_tfracbasestep = (r_tstepy + r_tstepx * ubasestep) << 16; #else d_sfracbasestep = (r_sstepy + r_sstepx * ubasestep) & 0xFFFF; d_tfracbasestep = (r_tstepy + r_tstepx * ubasestep) & 0xFFFF; #endif d_lightbasestep = r_lstepy + working_lstepx * ubasestep; d_zibasestep = r_zistepy + r_zistepx * ubasestep; d_ptexextrastep = ((r_sstepy + r_sstepx * d_countextrastep) >> 16) + ((r_tstepy + r_tstepx * d_countextrastep) >> 16) * r_affinetridesc.skinwidth; #ifdef USE_INTEL_ASM d_sfracextrastep = (r_sstepy + r_sstepx * d_countextrastep) << 16; d_tfracextrastep = (r_tstepy + r_tstepx * d_countextrastep) << 16; #else d_sfracextrastep = (r_sstepy + r_sstepx * d_countextrastep) & 0xFFFF; d_tfracextrastep = (r_tstepy + r_tstepx * d_countextrastep) & 0xFFFF; #endif d_lightextrastep = d_lightbasestep + working_lstepx; d_ziextrastep = d_zibasestep + r_zistepx; D_PolysetScanLeftEdge (initialleftheight); // scan out the bottom part of the left edge, if it exists if (pedgetable->numleftedges == 2) { int height; plefttop = pleftbottom; pleftbottom = pedgetable->pleftedgevert2; D_PolysetSetUpForLineScan (plefttop[0], plefttop[1], pleftbottom[0], pleftbottom[1]); height = pleftbottom[1] - plefttop[1]; // TODO: make this a function; modularize this function in general ystart = plefttop[1]; d_aspancount = plefttop[0] - prighttop[0]; d_ptex = (byte *) r_affinetridesc.pskin + (plefttop[2] >> 16) + (plefttop[3] >> 16) * r_affinetridesc.skinwidth; d_sfrac = 0; d_tfrac = 0; d_light = plefttop[4]; d_zi = plefttop[5]; d_pdestbasestep = screenwidth + ubasestep; d_pdestextrastep = d_pdestbasestep + 1; d_pdest = (byte *) d_viewbuffer + ystart * screenwidth + plefttop[0]; #ifdef USE_INTEL_ASM d_pzbasestep = (d_zwidth + ubasestep) << 1; d_pzextrastep = d_pzbasestep + 2; #else d_pzbasestep = d_zwidth + ubasestep; d_pzextrastep = d_pzbasestep + 1; #endif d_pz = d_pzbuffer + ystart * d_zwidth + plefttop[0]; if (ubasestep < 0) working_lstepx = r_lstepx - 1; else working_lstepx = r_lstepx; d_countextrastep = ubasestep + 1; d_ptexbasestep = ((r_sstepy + r_sstepx * ubasestep) >> 16) + ((r_tstepy + r_tstepx * ubasestep) >> 16) * r_affinetridesc.skinwidth; #ifdef USE_INTEL_ASM d_sfracbasestep = (r_sstepy + r_sstepx * ubasestep) << 16; d_tfracbasestep = (r_tstepy + r_tstepx * ubasestep) << 16; #else d_sfracbasestep = (r_sstepy + r_sstepx * ubasestep) & 0xFFFF; d_tfracbasestep = (r_tstepy + r_tstepx * ubasestep) & 0xFFFF; #endif d_lightbasestep = r_lstepy + working_lstepx * ubasestep; d_zibasestep = r_zistepy + r_zistepx * ubasestep; d_ptexextrastep = ((r_sstepy + r_sstepx * d_countextrastep) >> 16) + ((r_tstepy + r_tstepx * d_countextrastep) >> 16) * r_affinetridesc.skinwidth; #ifdef USE_INTEL_ASM d_sfracextrastep = ((r_sstepy + r_sstepx * d_countextrastep) & 0xFFFF) << 16; d_tfracextrastep = ((r_tstepy + r_tstepx * d_countextrastep) & 0xFFFF) << 16; #else d_sfracextrastep = (r_sstepy + r_sstepx * d_countextrastep) & 0xFFFF; d_tfracextrastep = (r_tstepy + r_tstepx * d_countextrastep) & 0xFFFF; #endif d_lightextrastep = d_lightbasestep + working_lstepx; d_ziextrastep = d_zibasestep + r_zistepx; D_PolysetScanLeftEdge (height); } // scan out the top (and possibly only) part of the right edge, updating // the count field d_pedgespanpackage = a_spans; D_PolysetSetUpForLineScan (prighttop[0], prighttop[1], prightbottom[0], prightbottom[1]); d_aspancount = 0; d_countextrastep = ubasestep + 1; originalcount = a_spans[initialrightheight].count; a_spans[initialrightheight].count = -999999; // mark end of the // spanpackages D_PolysetDrawSpans8 (a_spans); // scan out the bottom part of the right edge, if it exists if (pedgetable->numrightedges == 2) { int height; spanpackage_t *pstart; pstart = a_spans + initialrightheight; pstart->count = originalcount; d_aspancount = prightbottom[0] - prighttop[0]; prighttop = prightbottom; prightbottom = pedgetable->prightedgevert2; height = prightbottom[1] - prighttop[1]; D_PolysetSetUpForLineScan (prighttop[0], prighttop[1], prightbottom[0], prightbottom[1]); d_countextrastep = ubasestep + 1; a_spans[initialrightheight + height].count = -999999; // mark end of the spanpackages D_PolysetDrawSpans8 (pstart); } } void D_PolysetSetEdgeTable (void) { int edgetableindex; edgetableindex = 0; // assume the vertices are already in // top to bottom order // determine which edges are right & left, and the order in which // to rasterize them if (r_p0[1] >= r_p1[1]) { if (r_p0[1] == r_p1[1]) { if (r_p0[1] < r_p2[1]) pedgetable = &edgetables[2]; else pedgetable = &edgetables[5]; return; } else { edgetableindex = 1; } } if (r_p0[1] == r_p2[1]) { if (edgetableindex) pedgetable = &edgetables[8]; else pedgetable = &edgetables[9]; return; } else if (r_p1[1] == r_p2[1]) { if (edgetableindex) pedgetable = &edgetables[10]; else pedgetable = &edgetables[11]; return; } if (r_p0[1] > r_p2[1]) edgetableindex += 2; if (r_p1[1] > r_p2[1]) edgetableindex += 4; pedgetable = &edgetables[edgetableindex]; } #if 0 void D_PolysetRecursiveDrawLine (int *lp1, int *lp2) { int d; int new[6]; int ofs; d = lp2[0] - lp1[0]; if (d < -1 || d > 1) goto split; d = lp2[1] - lp1[1]; if (d < -1 || d > 1) goto split; return; // line is completed split: // split this edge new[0] = (lp1[0] + lp2[0]) >> 1; new[1] = (lp1[1] + lp2[1]) >> 1; new[5] = (lp1[5] + lp2[5]) >> 1; new[2] = (lp1[2] + lp2[2]) >> 1; new[3] = (lp1[3] + lp2[3]) >> 1; new[4] = (lp1[4] + lp2[4]) >> 1; // draw the point ofs = d_scantable[new[1]] + new[0]; if (new[5] > d_pzbuffer[ofs]) { int pix; d_pzbuffer[ofs] = new[5]; pix = skintable[new[3] >> 16][new[2] >> 16]; // pix = ((byte *)acolormap)[pix + (new[4] & 0xFF00)]; d_viewbuffer[ofs] = pix; } // recursively continue D_PolysetRecursiveDrawLine (lp1, new); D_PolysetRecursiveDrawLine (new, lp2); } void D_PolysetRecursiveTriangle2 (int *lp1, int *lp2, int *lp3) { int d; int new[4]; d = lp2[0] - lp1[0]; if (d < -1 || d > 1) goto split; d = lp2[1] - lp1[1]; if (d < -1 || d > 1) goto split; return; split: // split this edge new[0] = (lp1[0] + lp2[0]) >> 1; new[1] = (lp1[1] + lp2[1]) >> 1; new[5] = (lp1[5] + lp2[5]) >> 1; new[2] = (lp1[2] + lp2[2]) >> 1; new[3] = (lp1[3] + lp2[3]) >> 1; new[4] = (lp1[4] + lp2[4]) >> 1; D_PolysetRecursiveDrawLine (new, lp3); // recursively continue D_PolysetRecursiveTriangle (lp1, new, lp3); D_PolysetRecursiveTriangle (new, lp2, lp3); } #endif