/* d_scan.c Portable C scan-level rasterization code, all pixel depths. 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 */ #ifdef HAVE_CONFIG_H # include "config.h" #endif #define NH_DEFINE #include "namehack.h" #include "QF/qendian.h" #include "QF/render.h" #include "QF/sys.h" #include "QF/ui/view.h" #include "compat.h" #include "d_local.h" #include "r_internal.h" #include "vid_internal.h" static byte *r_turb_pbase; static void *r_turb_pdest; static fixed16_t r_turb_s, r_turb_t, r_turb_sstep, r_turb_tstep; static int *r_turb_turb; static int r_turb_spancount; /* D_WarpScreen this performs a slight compression of the screen at the same time as the sine warp, to keep the edges from wrapping */ void sw32_D_WarpScreen (void) { switch(sw32_r_pixbytes) { case 1: { int w, h; int u, v; int scr_x = vr_data.scr_view->xpos; int scr_y = vr_data.scr_view->ylen; int scr_w = vr_data.scr_view->xpos; int scr_h = vr_data.scr_view->ylen; byte *dest; int *turb; int *col; byte **row; byte *rowptr[MAXHEIGHT]; int column[MAXWIDTH]; float wratio, hratio; w = r_refdef.vrect.width; h = r_refdef.vrect.height; wratio = w / (float) scr_w; hratio = h / (float) scr_h; for (v = 0; v < scr_h + AMP2 * 2; v++) { rowptr[v] = (byte *) sw32_d_viewbuffer + (r_refdef.vrect.y * sw32_screenwidth) + (sw32_screenwidth * (int) ((float) v * hratio * h / (h + AMP2 * 2))); } for (u = 0; u < scr_w + AMP2 * 2; u++) { column[u] = r_refdef.vrect.x + (int) ((float) u * wratio * w / (w + AMP2 * 2)); } turb = sw32_intsintable + ((int) (vr_data.realtime * SPEED) & (CYCLE - 1)); dest = (byte *)vid.buffer + scr_y * vid.rowbytes + scr_x; for (v = 0; v < scr_h; v++, dest += vid.rowbytes) { col = &column[turb[v]]; row = &rowptr[v]; for (u = 0; u < scr_w; u += 4) { dest[u + 0] = row[turb[u + 0]][col[u + 0]]; dest[u + 1] = row[turb[u + 1]][col[u + 1]]; dest[u + 2] = row[turb[u + 2]][col[u + 2]]; dest[u + 3] = row[turb[u + 3]][col[u + 3]]; } } } break; case 2: { int w, h; int u, v; int scr_x = vr_data.scr_view->xpos; int scr_y = vr_data.scr_view->ylen; int scr_w = vr_data.scr_view->xpos; int scr_h = vr_data.scr_view->ylen; short *dest; int *turb; int *col; short **row; short *rowptr[MAXHEIGHT]; int column[MAXWIDTH]; float wratio, hratio; w = r_refdef.vrect.width; h = r_refdef.vrect.height; wratio = w / (float) scr_w; hratio = h / (float) scr_h; for (v = 0; v < scr_h + AMP2 * 2; v++) { rowptr[v] = (short *) sw32_d_viewbuffer + (r_refdef.vrect.y * sw32_screenwidth) + (sw32_screenwidth * (int) ((float) v * hratio * h / (h + AMP2 * 2))); } for (u = 0; u < scr_w + AMP2 * 2; u++) { column[u] = r_refdef.vrect.x + (int) ((float) u * wratio * w / (w + AMP2 * 2)); } turb = sw32_intsintable + ((int) (vr_data.realtime * SPEED) & (CYCLE - 1)); dest = (short *) vid.buffer + scr_y * (vid.rowbytes >> 1) + scr_x; for (v = 0; v < scr_h; v++, dest += (vid.rowbytes >> 1)) { col = &column[turb[v]]; row = &rowptr[v]; for (u = 0; u < scr_w; u += 4) { dest[u + 0] = row[turb[u + 0]][col[u + 0]]; dest[u + 1] = row[turb[u + 1]][col[u + 1]]; dest[u + 2] = row[turb[u + 2]][col[u + 2]]; dest[u + 3] = row[turb[u + 3]][col[u + 3]]; } } } break; case 4: { int w, h; int u, v; int scr_x = vr_data.scr_view->xpos; int scr_y = vr_data.scr_view->ylen; int scr_w = vr_data.scr_view->xpos; int scr_h = vr_data.scr_view->ylen; int *dest; int *turb; int *col; int **row; int *rowptr[MAXHEIGHT]; int column[MAXWIDTH]; float wratio, hratio; w = r_refdef.vrect.width; h = r_refdef.vrect.height; wratio = w / (float) scr_w; hratio = h / (float) scr_h; for (v = 0; v < scr_h + AMP2 * 2; v++) { rowptr[v] = (int *) sw32_d_viewbuffer + (r_refdef.vrect.y * sw32_screenwidth) + (sw32_screenwidth * (int) ((float) v * hratio * h / (h + AMP2 * 2))); } for (u = 0; u < scr_w + AMP2 * 2; u++) { column[u] = r_refdef.vrect.x + (int) ((float) u * wratio * w / (w + AMP2 * 2)); } turb = sw32_intsintable + ((int) (vr_data.realtime * SPEED) & (CYCLE - 1)); dest = (int *) vid.buffer + scr_y * (vid.rowbytes >> 2) + scr_x; for (v = 0; v < scr_h; v++, dest += (vid.rowbytes >> 2)) { col = &column[turb[v]]; row = &rowptr[v]; for (u = 0; u < scr_w; u += 4) { dest[u + 0] = row[turb[u + 0]][col[u + 0]]; dest[u + 1] = row[turb[u + 1]][col[u + 1]]; dest[u + 2] = row[turb[u + 2]][col[u + 2]]; dest[u + 3] = row[turb[u + 3]][col[u + 3]]; } } } break; default: Sys_Error("D_WarpScreen: unsupported r_pixbytes %i", sw32_r_pixbytes); } } static void D_DrawTurbulentSpan (void) { int sturb, tturb; switch (sw32_r_pixbytes) { case 1: { byte *pdest = (byte *) r_turb_pdest; do { sturb = ((r_turb_s + r_turb_turb[(r_turb_t >> 16) & (CYCLE - 1)]) >> 16) & 63; tturb = ((r_turb_t + r_turb_turb[(r_turb_s >> 16) & (CYCLE - 1)]) >> 16) & 63; *pdest++ = r_turb_pbase[(tturb << 6) + sturb]; r_turb_s += r_turb_sstep; r_turb_t += r_turb_tstep; } while (--r_turb_spancount > 0); r_turb_pdest = (byte *)pdest; } break; case 2: { short *pdest = (short *) r_turb_pdest; do { sturb = ((r_turb_s + r_turb_turb[(r_turb_t >> 16) & (CYCLE - 1)]) >> 16) & 63; tturb = ((r_turb_t + r_turb_turb[(r_turb_s >> 16) & (CYCLE - 1)]) >> 16) & 63; *pdest++ = sw32_8to16table[r_turb_pbase[(tturb << 6) + sturb]]; r_turb_s += r_turb_sstep; r_turb_t += r_turb_tstep; } while (--r_turb_spancount > 0); r_turb_pdest = (byte *)pdest; } break; case 4: { int *pdest = (int *) r_turb_pdest; do { sturb = ((r_turb_s + r_turb_turb[(r_turb_t >> 16) & (CYCLE - 1)]) >> 16) & 63; tturb = ((r_turb_t + r_turb_turb[(r_turb_s >> 16) & (CYCLE - 1)]) >> 16) & 63; *pdest++ = d_8to24table[r_turb_pbase[(tturb << 6) + sturb]]; r_turb_s += r_turb_sstep; r_turb_t += r_turb_tstep; } while (--r_turb_spancount > 0); r_turb_pdest = (byte *)pdest; } break; default: Sys_Error("D_DrawTurbulentSpan: unsupported r_pixbytes %i", sw32_r_pixbytes); } } void sw32_Turbulent (espan_t *pspan) { int count; fixed16_t snext, tnext; float sdivz, tdivz, zi, z, du, dv, spancountminus1; float sdivz16stepu, tdivz16stepu, zi16stepu; r_turb_turb = sw32_sintable + ((int) (vr_data.realtime * SPEED) & (CYCLE - 1)); r_turb_sstep = 0; // keep compiler happy r_turb_tstep = 0; // ditto r_turb_pbase = (byte *) sw32_cacheblock; sdivz16stepu = sw32_d_sdivzstepu * 16; tdivz16stepu = sw32_d_tdivzstepu * 16; zi16stepu = d_zistepu * 16 * 65536; do { r_turb_pdest = (byte *) sw32_d_viewbuffer + ((sw32_screenwidth * pspan->v) + pspan->u) * sw32_r_pixbytes; count = pspan->count; // calculate the initial s/z, t/z, 1/z, s, and t and clamp du = (float) pspan->u; dv = (float) pspan->v; sdivz = sw32_d_sdivzorigin + dv * sw32_d_sdivzstepv + du * sw32_d_sdivzstepu; tdivz = sw32_d_tdivzorigin + dv * sw32_d_tdivzstepv + du * sw32_d_tdivzstepu; zi = (d_ziorigin + dv * d_zistepv + du * d_zistepu) * 65536.0f; z = sw32_d_zitable[(unsigned short) zi]; r_turb_s = (int) (sdivz * z) + sw32_sadjust; if (r_turb_s > sw32_bbextents) r_turb_s = sw32_bbextents; else if (r_turb_s < 0) r_turb_s = 0; r_turb_t = (int) (tdivz * z) + sw32_tadjust; if (r_turb_t > sw32_bbextentt) r_turb_t = sw32_bbextentt; else if (r_turb_t < 0) r_turb_t = 0; do { // calculate s and t at the far end of the span if (count >= 16) r_turb_spancount = 16; else r_turb_spancount = count; count -= r_turb_spancount; if (count) { // calculate s/z, t/z, zi->fixed s and t at far end of span, // calculate s and t steps across span by shifting sdivz += sdivz16stepu; tdivz += tdivz16stepu; zi += zi16stepu; z = sw32_d_zitable[(unsigned short) zi]; snext = (int) (sdivz * z) + sw32_sadjust; if (snext > sw32_bbextents) snext = sw32_bbextents; else if (snext < 16) snext = 16; // prevent round-off error on <0 // steps from // from causing overstepping & running off the // edge of the texture tnext = (int) (tdivz * z) + sw32_tadjust; if (tnext > sw32_bbextentt) tnext = sw32_bbextentt; else if (tnext < 16) tnext = 16; // guard against round-off error on // <0 steps r_turb_sstep = (snext - r_turb_s) >> 4; r_turb_tstep = (tnext - r_turb_t) >> 4; } else { // calculate s/z, t/z, zi->fixed s and t at last pixel in // span (so can't step off polygon), clamp, calculate s and t // steps across span by division, biasing steps low so we // don't run off the texture spancountminus1 = (float) (r_turb_spancount - 1); sdivz += sw32_d_sdivzstepu * spancountminus1; tdivz += sw32_d_tdivzstepu * spancountminus1; zi += d_zistepu * 65536.0f * spancountminus1; z = sw32_d_zitable[(unsigned short) zi]; snext = (int) (sdivz * z) + sw32_sadjust; if (snext > sw32_bbextents) snext = sw32_bbextents; else if (snext < 16) snext = 16; // prevent round-off error on <0 steps // from causing overstepping & running // off the edge of the texture tnext = (int) (tdivz * z) + sw32_tadjust; if (tnext > sw32_bbextentt) tnext = sw32_bbextentt; else if (tnext < 16) tnext = 16; // guard against round-off error on // <0 steps if (r_turb_spancount > 1) { r_turb_sstep = (snext - r_turb_s) / (r_turb_spancount - 1); r_turb_tstep = (tnext - r_turb_t) / (r_turb_spancount - 1); } } r_turb_s = r_turb_s & ((CYCLE << 16) - 1); r_turb_t = r_turb_t & ((CYCLE << 16) - 1); D_DrawTurbulentSpan (); r_turb_s = snext; r_turb_t = tnext; } while (count > 0); } while ((pspan = pspan->pnext) != NULL); } void sw32_D_DrawSpans (espan_t *pspan) { switch(sw32_r_pixbytes) { case 1: { byte *pbase = (byte *) sw32_cacheblock, *pdest; int count; fixed16_t s, t, snext, tnext, sstep, tstep; float sdivz, tdivz, zi, z, du, dv; float sdivz8stepu, tdivz8stepu, zi8stepu; sstep = 0; // keep compiler happy tstep = 0; // ditto sdivz8stepu = sw32_d_sdivzstepu * 8; tdivz8stepu = sw32_d_tdivzstepu * 8; zi8stepu = d_zistepu * 8 * 65536; do { pdest = (byte *) sw32_d_viewbuffer + (sw32_screenwidth * pspan->v) + pspan->u; count = pspan->count; // calculate the initial s/z, t/z, 1/z, s, and t and clamp du = (float) pspan->u; dv = (float) pspan->v; sdivz = sw32_d_sdivzorigin + dv * sw32_d_sdivzstepv + du * sw32_d_sdivzstepu; tdivz = sw32_d_tdivzorigin + dv * sw32_d_tdivzstepv + du * sw32_d_tdivzstepu; zi = (d_ziorigin + dv * d_zistepv + du * d_zistepu) * 65536.0f; z = sw32_d_zitable[(unsigned short) zi]; s = (int) (sdivz * z) + sw32_sadjust; s = bound(0, s, sw32_bbextents); t = (int) (tdivz * z) + sw32_tadjust; t = bound(0, t, sw32_bbextentt); while(count >= 8) { count -= 8; // calculate s/z, t/z, zi->fixed s and t at far end of span, // calculate s and t steps across span by shifting sdivz += sdivz8stepu; tdivz += tdivz8stepu; zi += zi8stepu; z = sw32_d_zitable[(unsigned short) zi]; // prevent round-off error on <0 steps from from causing // overstepping & running off the edge of the texture snext = (int) (sdivz * z) + sw32_sadjust; snext = bound(8, snext, sw32_bbextents); tnext = (int) (tdivz * z) + sw32_tadjust; tnext = bound(8, tnext, sw32_bbextentt); sstep = (snext - s) >> 3; tstep = (tnext - t) >> 3; pdest[0] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep;t += tstep; pdest[1] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[2] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[3] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[4] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[5] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[6] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[7] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s = snext; t = tnext; pdest += 8; } if (count) { // calculate s/z, t/z, zi->fixed s and t at last pixel in span // (so can't step off polygon), clamp, calculate s and t steps // across span by division, biasing steps low so we don't run // off the texture //countminus1 = (float) (count - 1); sdivz += sw32_d_sdivzstepu * count; //minus1; tdivz += sw32_d_tdivzstepu * count; //minus1; zi += d_zistepu * 65536.0f * count; //minus1; z = sw32_d_zitable[(unsigned short) zi]; // prevent round-off error on <0 steps from from causing // overstepping & running off the edge of the texture snext = (int) (sdivz * z) + sw32_sadjust; snext = bound(count, snext, sw32_bbextents); tnext = (int) (tdivz * z) + sw32_tadjust; tnext = bound(count, tnext, sw32_bbextentt); if (count > 1) { sstep = (snext - s) / count; //(count - 1); tstep = (tnext - t) / count; //(count - 1); if (count & 4) { pdest[0] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[1] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[2] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[3] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest += 4; } if (count & 2) { pdest[0] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[1] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest += 2; } if (count & 1) pdest[0] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; } else { pdest[0] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; } } } while ((pspan = pspan->pnext) != NULL); } break; case 2: { short *pbase = (short *) sw32_cacheblock, *pdest; int count; fixed16_t s, t, snext, tnext, sstep, tstep; float sdivz, tdivz, zi, z, du, dv; float sdivz8stepu, tdivz8stepu, zi8stepu; sstep = 0; // keep compiler happy tstep = 0; // ditto sdivz8stepu = sw32_d_sdivzstepu * 8; tdivz8stepu = sw32_d_tdivzstepu * 8; zi8stepu = d_zistepu * 8 * 65536; do { pdest = (short *) sw32_d_viewbuffer + (sw32_screenwidth * pspan->v) + pspan->u; count = pspan->count; // calculate the initial s/z, t/z, 1/z, s, and t and clamp du = (float) pspan->u; dv = (float) pspan->v; sdivz = sw32_d_sdivzorigin + dv * sw32_d_sdivzstepv + du * sw32_d_sdivzstepu; tdivz = sw32_d_tdivzorigin + dv * sw32_d_tdivzstepv + du * sw32_d_tdivzstepu; zi = (d_ziorigin + dv * d_zistepv + du * d_zistepu) * 65536.0f; z = sw32_d_zitable[(unsigned short) zi]; s = (int) (sdivz * z) + sw32_sadjust; s = bound(0, s, sw32_bbextents); t = (int) (tdivz * z) + sw32_tadjust; t = bound(0, t, sw32_bbextentt); while(count >= 8) { count -= 8; // calculate s/z, t/z, zi->fixed s and t at far end of span, // calculate s and t steps across span by shifting sdivz += sdivz8stepu; tdivz += tdivz8stepu; zi += zi8stepu; z = sw32_d_zitable[(unsigned short) zi]; // prevent round-off error on <0 steps from from causing // overstepping & running off the edge of the texture snext = (int) (sdivz * z) + sw32_sadjust; snext = bound(8, snext, sw32_bbextents); tnext = (int) (tdivz * z) + sw32_tadjust; tnext = bound(8, tnext, sw32_bbextentt); sstep = (snext - s) >> 3; tstep = (tnext - t) >> 3; pdest[0] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[1] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[2] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[3] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[4] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[5] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[6] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[7] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s = snext;t = tnext; pdest += 8; } if (count) { // calculate s/z, t/z, zi->fixed s and t at last pixel in span // (so can't step off polygon), clamp, calculate s and t steps // across span by division, biasing steps low so we don't run // off the texture //countminus1 = (float) (count - 1); sdivz += sw32_d_sdivzstepu * count; //minus1; tdivz += sw32_d_tdivzstepu * count; //minus1; zi += d_zistepu * 65536.0f * count; //minus1; z = sw32_d_zitable[(unsigned short) zi]; // prevent round-off error on <0 steps from from causing // overstepping & running off the edge of the texture snext = (int) (sdivz * z) + sw32_sadjust; snext = bound(count, snext, sw32_bbextents); tnext = (int) (tdivz * z) + sw32_tadjust; tnext = bound(count, tnext, sw32_bbextentt); if (count > 1) { sstep = (snext - s) / count; //(count - 1); tstep = (tnext - t) / count; //(count - 1); if (count & 4) { pdest[0] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[1] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[2] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[3] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep;t += tstep; pdest += 4; } if (count & 2) { pdest[0] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[1] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest += 2; } if (count & 1) pdest[0] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; } else { pdest[0] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; } } } while ((pspan = pspan->pnext) != NULL); } break; case 4: { int *pbase = (int *) sw32_cacheblock, *pdest; int count; fixed16_t s, t, snext, tnext, sstep, tstep; float sdivz, tdivz, zi, z, du, dv; float sdivz8stepu, tdivz8stepu, zi8stepu; sstep = 0; // keep compiler happy tstep = 0; // ditto sdivz8stepu = sw32_d_sdivzstepu * 8; tdivz8stepu = sw32_d_tdivzstepu * 8; zi8stepu = d_zistepu * 8 * 65536; do { pdest = (int *) sw32_d_viewbuffer + (sw32_screenwidth * pspan->v) + pspan->u; count = pspan->count; // calculate the initial s/z, t/z, 1/z, s, and t and clamp du = (float) pspan->u; dv = (float) pspan->v; sdivz = sw32_d_sdivzorigin + dv * sw32_d_sdivzstepv + du * sw32_d_sdivzstepu; tdivz = sw32_d_tdivzorigin + dv * sw32_d_tdivzstepv + du * sw32_d_tdivzstepu; zi = (d_ziorigin + dv * d_zistepv + du * d_zistepu) * 65536.0f; z = sw32_d_zitable[(unsigned short) zi]; s = (int) (sdivz * z) + sw32_sadjust; s = bound(0, s, sw32_bbextents); t = (int) (tdivz * z) + sw32_tadjust; t = bound(0, t, sw32_bbextentt); while(count >= 8) { count -= 8; // calculate s/z, t/z, zi->fixed s and t at far end of span, // calculate s and t steps across span by shifting sdivz += sdivz8stepu; tdivz += tdivz8stepu; zi += zi8stepu; z = sw32_d_zitable[(unsigned short) zi]; // prevent round-off error on <0 steps from from causing // overstepping & running off the edge of the texture snext = (int) (sdivz * z) + sw32_sadjust; snext = bound(8, snext, sw32_bbextents); tnext = (int) (tdivz * z) + sw32_tadjust; tnext = bound(8, tnext, sw32_bbextentt); sstep = (snext - s) >> 3; tstep = (tnext - t) >> 3; pdest[0] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[1] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[2] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[3] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[4] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[5] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[6] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[7] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s = snext; t = tnext; pdest += 8; } if (count) { // calculate s/z, t/z, zi->fixed s and t at last pixel in span // (so can't step off polygon), clamp, calculate s and t steps // across span by division, biasing steps low so we don't run // off the texture //countminus1 = (float) (count - 1); sdivz += sw32_d_sdivzstepu * count; //minus1; tdivz += sw32_d_tdivzstepu * count; //minus1; zi += d_zistepu * 65536.0f * count; //minus1; z = sw32_d_zitable[(unsigned short) zi]; // prevent round-off error on <0 steps from from causing // overstepping & running off the edge of the texture snext = (int) (sdivz * z) + sw32_sadjust; snext = bound(count, snext, sw32_bbextents); tnext = (int) (tdivz * z) + sw32_tadjust; tnext = bound(count, tnext, sw32_bbextentt); if (count > 1) { sstep = (snext - s) / count; //(count - 1); tstep = (tnext - t) / count; //(count - 1); if (count & 4) { pdest[0] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[1] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[2] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[3] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest += 4; } if (count & 2) { pdest[0] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest[1] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; s += sstep; t += tstep; pdest += 2; } if (count & 1) pdest[0] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; } else { pdest[0] = pbase[(t >> 16) * sw32_cachewidth + (s >> 16)]; } } } while ((pspan = pspan->pnext) != NULL); } break; default: Sys_Error("D_DrawSpans: unsupported r_pixbytes %i", sw32_r_pixbytes); } } void sw32_D_DrawZSpans (espan_t *pspan) { int count, doublecount, izistep; int izi; short *pdest; unsigned int ltemp; double zi; float du, dv; // FIXME: check for clamping/range problems // we count on FP exceptions being turned off to avoid range problems izistep = (int) (d_zistepu * 0x8000 * 0x10000); do { pdest = sw32_d_pzbuffer + (sw32_d_zwidth * pspan->v) + pspan->u; count = pspan->count; // calculate the initial 1/z du = (float) pspan->u; dv = (float) pspan->v; zi = d_ziorigin + dv * d_zistepv + du * d_zistepu; // we count on FP exceptions being turned off to avoid range problems izi = (int) (zi * 0x8000 * 0x10000); // LordHavoc: added big endian case, the old code is not correct on // big-endian (results in swapped depth pairs), and is tuned more for // x86, PowerPC compilers can probably do a good job with raw loop // unrolling if it is even necessary... if (bigendien) { do { *pdest++ = (short) (izi >> 16); izi += izistep; } while(--count); } else { if ((intptr_t) pdest & 0x02) { *pdest++ = (short) (izi >> 16); izi += izistep; count--; } if ((doublecount = count >> 1) > 0) { do { ltemp = izi >> 16; izi += izistep; ltemp |= izi & 0xFFFF0000; izi += izistep; *(int *) pdest = ltemp; pdest += 2; } while (--doublecount > 0); } if (count & 1) *pdest = (short) (izi >> 16); } } while ((pspan = pspan->pnext) != NULL); }