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dc765cde2c
If you want more specifics, sloped FOFs are to blame it turns out: sometimes the bottom of an FOF wall blocking a segment of an in-level wall column can be considered ABOVE the top part of the FOF there (yikes), and then the dc_y* values go offscreen, and then BOOM
1402 lines
38 KiB
C
1402 lines
38 KiB
C
// SONIC ROBO BLAST 2
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//-----------------------------------------------------------------------------
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// Copyright (C) 1998-2000 by DooM Legacy Team.
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// Copyright (C) 1999-2016 by Sonic Team Junior.
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//
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// This program is free software distributed under the
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// terms of the GNU General Public License, version 2.
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// See the 'LICENSE' file for more details.
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//-----------------------------------------------------------------------------
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/// \file r_draw8.c
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/// \brief 8bpp span/column drawer functions
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/// \note no includes because this is included as part of r_draw.c
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// ==========================================================================
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// COLUMNS
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// ==========================================================================
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// A column is a vertical slice/span of a wall texture that uses
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// a has a constant z depth from top to bottom.
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//
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/** \brief The R_DrawColumn_8 function
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Experiment to make software go faster. Taken from the Boom source
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*/
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void R_DrawColumn_8(void)
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{
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INT32 count;
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register UINT8 *dest;
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register fixed_t frac;
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fixed_t fracstep;
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count = dc_yh - dc_yl;
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if (count < 0) // Zero length, column does not exceed a pixel.
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return;
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#ifdef RANGECHECK
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if ((unsigned)dc_x >= (unsigned)vid.width || dc_yl < 0 || dc_yh >= vid.height)
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return;
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#endif
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// Framebuffer destination address.
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// Use ylookup LUT to avoid multiply with ScreenWidth.
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// Use columnofs LUT for subwindows?
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//dest = ylookup[dc_yl] + columnofs[dc_x];
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dest = &topleft[dc_yl*vid.width + dc_x];
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count++;
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// Determine scaling, which is the only mapping to be done.
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fracstep = dc_iscale;
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//frac = dc_texturemid + (dc_yl - centery)*fracstep;
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frac = (dc_texturemid + FixedMul((dc_yl << FRACBITS) - centeryfrac, fracstep))*(!dc_hires);
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// Inner loop that does the actual texture mapping, e.g. a DDA-like scaling.
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// This is as fast as it gets.
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{
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register const UINT8 *source = dc_source;
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register const lighttable_t *colormap = dc_colormap;
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register INT32 heightmask = dc_texheight-1;
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if (dc_texheight & heightmask) // not a power of 2 -- killough
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{
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heightmask++;
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heightmask <<= FRACBITS;
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if (frac < 0)
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while ((frac += heightmask) < 0);
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else
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while (frac >= heightmask)
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frac -= heightmask;
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do
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{
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// Re-map color indices from wall texture column
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// using a lighting/special effects LUT.
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// heightmask is the Tutti-Frutti fix
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*dest = colormap[source[frac>>FRACBITS]];
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dest += vid.width;
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// Avoid overflow.
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if (fracstep > 0x7FFFFFFF - frac)
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frac += fracstep - heightmask;
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else
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frac += fracstep;
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while (frac >= heightmask)
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frac -= heightmask;
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} while (--count);
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}
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else
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{
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while ((count -= 2) >= 0) // texture height is a power of 2
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{
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*dest = colormap[source[(frac>>FRACBITS) & heightmask]];
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dest += vid.width;
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frac += fracstep;
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*dest = colormap[source[(frac>>FRACBITS) & heightmask]];
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dest += vid.width;
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frac += fracstep;
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}
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if (count & 1)
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*dest = colormap[source[(frac>>FRACBITS) & heightmask]];
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}
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}
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}
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#define TRANSPARENTPIXEL 247
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void R_Draw2sMultiPatchColumn_8(void)
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{
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INT32 count;
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register UINT8 *dest;
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register fixed_t frac;
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fixed_t fracstep;
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count = dc_yh - dc_yl;
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if (count < 0) // Zero length, column does not exceed a pixel.
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return;
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#ifdef RANGECHECK
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if ((unsigned)dc_x >= (unsigned)vid.width || dc_yl < 0 || dc_yh >= vid.height)
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return;
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#endif
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// Framebuffer destination address.
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// Use ylookup LUT to avoid multiply with ScreenWidth.
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// Use columnofs LUT for subwindows?
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//dest = ylookup[dc_yl] + columnofs[dc_x];
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dest = &topleft[dc_yl*vid.width + dc_x];
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count++;
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// Determine scaling, which is the only mapping to be done.
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fracstep = dc_iscale;
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//frac = dc_texturemid + (dc_yl - centery)*fracstep;
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frac = (dc_texturemid + FixedMul((dc_yl << FRACBITS) - centeryfrac, fracstep))*(!dc_hires);
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// Inner loop that does the actual texture mapping, e.g. a DDA-like scaling.
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// This is as fast as it gets.
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{
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register const UINT8 *source = dc_source;
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register const lighttable_t *colormap = dc_colormap;
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register INT32 heightmask = dc_texheight-1;
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register UINT8 val;
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if (dc_texheight & heightmask) // not a power of 2 -- killough
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{
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heightmask++;
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heightmask <<= FRACBITS;
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if (frac < 0)
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while ((frac += heightmask) < 0);
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else
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while (frac >= heightmask)
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frac -= heightmask;
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do
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{
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// Re-map color indices from wall texture column
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// using a lighting/special effects LUT.
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// heightmask is the Tutti-Frutti fix
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val = source[frac>>FRACBITS];
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if (val != TRANSPARENTPIXEL)
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*dest = colormap[val];
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dest += vid.width;
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// Avoid overflow.
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if (fracstep > 0x7FFFFFFF - frac)
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frac += fracstep - heightmask;
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else
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frac += fracstep;
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while (frac >= heightmask)
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frac -= heightmask;
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} while (--count);
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}
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else
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{
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while ((count -= 2) >= 0) // texture height is a power of 2
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{
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val = source[(frac>>FRACBITS) & heightmask];
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if (val != TRANSPARENTPIXEL)
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*dest = colormap[val];
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dest += vid.width;
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frac += fracstep;
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val = source[(frac>>FRACBITS) & heightmask];
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if (val != TRANSPARENTPIXEL)
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*dest = colormap[val];
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dest += vid.width;
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frac += fracstep;
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}
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if (count & 1)
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{
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val = source[(frac>>FRACBITS) & heightmask];
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if (val != TRANSPARENTPIXEL)
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*dest = colormap[val];
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}
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}
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}
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}
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/** \brief The R_DrawShadeColumn_8 function
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Experiment to make software go faster. Taken from the Boom source
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*/
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void R_DrawShadeColumn_8(void)
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{
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register INT32 count;
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register UINT8 *dest;
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register fixed_t frac, fracstep;
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// check out coords for src*
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if ((dc_yl < 0) || (dc_x >= vid.width))
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return;
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count = dc_yh - dc_yl;
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if (count < 0)
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return;
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#ifdef RANGECHECK
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if ((unsigned)dc_x >= (unsigned)vid.width || dc_yl < 0 || dc_yh >= vid.height)
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I_Error("R_DrawShadeColumn_8: %d to %d at %d", dc_yl, dc_yh, dc_x);
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#endif
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// FIXME. As above.
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//dest = ylookup[dc_yl] + columnofs[dc_x];
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dest = &topleft[dc_yl*vid.width + dc_x];
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// Looks familiar.
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fracstep = dc_iscale;
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//frac = dc_texturemid + (dc_yl - centery)*fracstep;
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frac = (dc_texturemid + FixedMul((dc_yl << FRACBITS) - centeryfrac, fracstep))*(!dc_hires);
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// Here we do an additional index re-mapping.
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do
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{
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*dest = colormaps[(dc_source[frac>>FRACBITS] <<8) + (*dest)];
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dest += vid.width;
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frac += fracstep;
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} while (count--);
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}
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/** \brief The R_DrawTranslucentColumn_8 function
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I've made an asm routine for the transparency, because it slows down
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a lot in 640x480 with big sprites (bfg on all screen, or transparent
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walls on fullscreen)
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*/
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void R_DrawTranslucentColumn_8(void)
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{
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register INT32 count;
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register UINT8 *dest;
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register fixed_t frac, fracstep;
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count = dc_yh - dc_yl + 1;
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if (count <= 0) // Zero length, column does not exceed a pixel.
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return;
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#ifdef RANGECHECK
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if ((unsigned)dc_x >= (unsigned)vid.width || dc_yl < 0 || dc_yh >= vid.height)
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I_Error("R_DrawTranslucentColumn_8: %d to %d at %d", dc_yl, dc_yh, dc_x);
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#endif
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// FIXME. As above.
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//dest = ylookup[dc_yl] + columnofs[dc_x];
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dest = &topleft[dc_yl*vid.width + dc_x];
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// Looks familiar.
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fracstep = dc_iscale;
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//frac = dc_texturemid + (dc_yl - centery)*fracstep;
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frac = (dc_texturemid + FixedMul((dc_yl << FRACBITS) - centeryfrac, fracstep))*(!dc_hires);
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// Inner loop that does the actual texture mapping, e.g. a DDA-like scaling.
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// This is as fast as it gets.
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{
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register const UINT8 *source = dc_source;
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register const UINT8 *transmap = dc_transmap;
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register const lighttable_t *colormap = dc_colormap;
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register INT32 heightmask = dc_texheight - 1;
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if (dc_texheight & heightmask)
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{
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heightmask++;
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heightmask <<= FRACBITS;
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if (frac < 0)
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while ((frac += heightmask) < 0)
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;
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else
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while (frac >= heightmask)
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frac -= heightmask;
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do
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{
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// Re-map color indices from wall texture column
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// using a lighting/special effects LUT.
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// heightmask is the Tutti-Frutti fix
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*dest = colormap[*(transmap + (source[frac>>FRACBITS]<<8) + (*dest))];
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dest += vid.width;
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if ((frac += fracstep) >= heightmask)
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frac -= heightmask;
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}
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while (--count);
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}
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else
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{
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while ((count -= 2) >= 0) // texture height is a power of 2
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{
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*dest = colormap[*(transmap + ((source[(frac>>FRACBITS)&heightmask]<<8)) + (*dest))];
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dest += vid.width;
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frac += fracstep;
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*dest = colormap[*(transmap + ((source[(frac>>FRACBITS)&heightmask]<<8)) + (*dest))];
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dest += vid.width;
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frac += fracstep;
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}
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if (count & 1)
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*dest = colormap[*(transmap + ((source[(frac>>FRACBITS)&heightmask]<<8)) + (*dest))];
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}
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}
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}
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/** \brief The R_DrawTranslatedTranslucentColumn_8 function
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Spiffy function. Not only does it colormap a sprite, but does translucency as well.
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Uber-kudos to Cyan Helkaraxe
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*/
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void R_DrawTranslatedTranslucentColumn_8(void)
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{
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register INT32 count;
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register UINT8 *dest;
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register fixed_t frac, fracstep;
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count = dc_yh - dc_yl + 1;
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if (count <= 0) // Zero length, column does not exceed a pixel.
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return;
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// FIXME. As above.
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//dest = ylookup[dc_yl] + columnofs[dc_x];
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dest = &topleft[dc_yl*vid.width + dc_x];
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// Looks familiar.
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fracstep = dc_iscale;
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//frac = dc_texturemid + (dc_yl - centery)*fracstep;
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frac = (dc_texturemid + FixedMul((dc_yl << FRACBITS) - centeryfrac, fracstep))*(!dc_hires);
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// Inner loop that does the actual texture mapping, e.g. a DDA-like scaling.
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// This is as fast as it gets.
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{
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register INT32 heightmask = dc_texheight - 1;
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if (dc_texheight & heightmask)
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{
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heightmask++;
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heightmask <<= FRACBITS;
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if (frac < 0)
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while ((frac += heightmask) < 0)
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;
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else
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while (frac >= heightmask)
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frac -= heightmask;
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do
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{
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// Re-map color indices from wall texture column
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// using a lighting/special effects LUT.
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// heightmask is the Tutti-Frutti fix
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*dest = dc_colormap[*(dc_transmap
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+ (dc_colormap[dc_translation[dc_source[frac>>FRACBITS]]]<<8) + (*dest))];
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dest += vid.width;
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if ((frac += fracstep) >= heightmask)
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frac -= heightmask;
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}
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while (--count);
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}
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else
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{
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while ((count -= 2) >= 0) // texture height is a power of 2
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{
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*dest = dc_colormap[*(dc_transmap
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+ (dc_colormap[dc_translation[dc_source[frac>>FRACBITS]]]<<8) + (*dest))];
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dest += vid.width;
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frac += fracstep;
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*dest = dc_colormap[*(dc_transmap
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+ (dc_colormap[dc_translation[dc_source[frac>>FRACBITS]]]<<8) + (*dest))];
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dest += vid.width;
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frac += fracstep;
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}
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if (count & 1)
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*dest = dc_colormap[*(dc_transmap + (dc_colormap[dc_translation[dc_source[frac>>FRACBITS]]] <<8) + (*dest))];
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}
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}
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}
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/** \brief The R_DrawTranslatedColumn_8 function
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Draw columns up to 128 high but remap the green ramp to other colors
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\warning STILL NOT IN ASM, TO DO..
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*/
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void R_DrawTranslatedColumn_8(void)
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{
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register INT32 count;
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register UINT8 *dest;
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register fixed_t frac, fracstep;
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count = dc_yh - dc_yl;
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if (count < 0)
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return;
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#ifdef RANGECHECK
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if ((unsigned)dc_x >= (unsigned)vid.width || dc_yl < 0 || dc_yh >= vid.height)
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I_Error("R_DrawTranslatedColumn_8: %d to %d at %d", dc_yl, dc_yh, dc_x);
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#endif
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// FIXME. As above.
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//dest = ylookup[dc_yl] + columnofs[dc_x];
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dest = &topleft[dc_yl*vid.width + dc_x];
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// Looks familiar.
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fracstep = dc_iscale;
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//frac = dc_texturemid + (dc_yl-centery)*fracstep;
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frac = (dc_texturemid + FixedMul((dc_yl << FRACBITS) - centeryfrac, fracstep))*(!dc_hires);
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// Here we do an additional index re-mapping.
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do
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{
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// Translation tables are used
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// to map certain colorramps to other ones,
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// used with PLAY sprites.
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// Thus the "green" ramp of the player 0 sprite
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// is mapped to gray, red, black/indigo.
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*dest = dc_colormap[dc_translation[dc_source[frac>>FRACBITS]]];
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dest += vid.width;
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frac += fracstep;
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} while (count--);
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}
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// ==========================================================================
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// SPANS
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// ==========================================================================
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/** \brief The R_DrawSpan_8 function
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Draws the actual span.
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*/
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void R_DrawSpan_8 (void)
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{
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UINT32 xposition;
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UINT32 yposition;
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UINT32 xstep, ystep;
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UINT8 *source;
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UINT8 *colormap;
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UINT8 *dest;
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const UINT8 *deststop = screens[0] + vid.rowbytes * vid.height;
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size_t count;
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// SoM: we only need 6 bits for the integer part (0 thru 63) so the rest
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// can be used for the fraction part. This allows calculation of the memory address in the
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// texture with two shifts, an OR and one AND. (see below)
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// for texture sizes > 64 the amount of precision we can allow will decrease, but only by one
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// bit per power of two (obviously)
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// Ok, because I was able to eliminate the variable spot below, this function is now FASTER
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// than the original span renderer. Whodathunkit?
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xposition = ds_xfrac << nflatshiftup; yposition = ds_yfrac << nflatshiftup;
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xstep = ds_xstep << nflatshiftup; ystep = ds_ystep << nflatshiftup;
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source = ds_source;
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colormap = ds_colormap;
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dest = ylookup[ds_y] + columnofs[ds_x1];
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count = ds_x2 - ds_x1 + 1;
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if (dest+8 > deststop)
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return;
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while (count >= 8)
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{
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// SoM: Why didn't I see this earlier? the spot variable is a waste now because we don't
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// have the uber complicated math to calculate it now, so that was a memory write we didn't
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// need!
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dest[0] = colormap[source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)]];
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xposition += xstep;
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yposition += ystep;
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dest[1] = colormap[source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)]];
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xposition += xstep;
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yposition += ystep;
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dest[2] = colormap[source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)]];
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xposition += xstep;
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yposition += ystep;
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dest[3] = colormap[source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)]];
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xposition += xstep;
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yposition += ystep;
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dest[4] = colormap[source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)]];
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xposition += xstep;
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yposition += ystep;
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|
|
dest[5] = colormap[source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)]];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
dest[6] = colormap[source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)]];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
dest[7] = colormap[source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)]];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
dest += 8;
|
|
count -= 8;
|
|
}
|
|
while (count-- && dest <= deststop)
|
|
{
|
|
*dest++ = colormap[source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)]];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
}
|
|
}
|
|
|
|
#ifdef ESLOPE
|
|
// R_CalcTiltedLighting
|
|
// Exactly what it says on the tin. I wish I wasn't too lazy to explain things properly.
|
|
static INT32 tiltlighting[MAXVIDWIDTH];
|
|
void R_CalcTiltedLighting(fixed_t start, fixed_t end)
|
|
{
|
|
// ZDoom uses a different lighting setup to us, and I couldn't figure out how to adapt their version
|
|
// of this function. Here's my own.
|
|
INT32 left = ds_x1, right = ds_x2;
|
|
fixed_t step = (end-start)/(ds_x2-ds_x1+1);
|
|
INT32 i;
|
|
|
|
// I wanna do some optimizing by checking for out-of-range segments on either side to fill in all at once,
|
|
// but I'm too bad at coding to not crash the game trying to do that. I guess this is fast enough for now...
|
|
|
|
for (i = left; i <= right; i++) {
|
|
tiltlighting[i] = (start += step) >> FRACBITS;
|
|
if (tiltlighting[i] < 0)
|
|
tiltlighting[i] = 0;
|
|
else if (tiltlighting[i] >= MAXLIGHTSCALE)
|
|
tiltlighting[i] = MAXLIGHTSCALE-1;
|
|
}
|
|
}
|
|
|
|
|
|
/** \brief The R_DrawTiltedSpan_8 function
|
|
Draw slopes! Holy sheit!
|
|
*/
|
|
void R_DrawTiltedSpan_8(void)
|
|
{
|
|
// x1, x2 = ds_x1, ds_x2
|
|
int width = ds_x2 - ds_x1;
|
|
double iz, uz, vz;
|
|
UINT32 u, v;
|
|
int i;
|
|
|
|
UINT8 *source;
|
|
UINT8 *colormap;
|
|
UINT8 *dest;
|
|
|
|
double startz, startu, startv;
|
|
double izstep, uzstep, vzstep;
|
|
double endz, endu, endv;
|
|
UINT32 stepu, stepv;
|
|
|
|
iz = ds_sz.z + ds_sz.y*(centery-ds_y) + ds_sz.x*(ds_x1-centerx);
|
|
|
|
// Lighting is simple. It's just linear interpolation from start to end
|
|
{
|
|
float planelightfloat = BASEVIDWIDTH*BASEVIDWIDTH/vid.width / (zeroheight - FIXED_TO_FLOAT(viewz)) / 21.0f;
|
|
float lightstart, lightend;
|
|
|
|
lightend = (iz + ds_sz.x*width) * planelightfloat;
|
|
lightstart = iz * planelightfloat;
|
|
|
|
R_CalcTiltedLighting(FLOAT_TO_FIXED(lightstart), FLOAT_TO_FIXED(lightend));
|
|
//CONS_Printf("tilted lighting %f to %f (foc %f)\n", lightstart, lightend, focallengthf);
|
|
}
|
|
|
|
uz = ds_su.z + ds_su.y*(centery-ds_y) + ds_su.x*(ds_x1-centerx);
|
|
vz = ds_sv.z + ds_sv.y*(centery-ds_y) + ds_sv.x*(ds_x1-centerx);
|
|
|
|
dest = ylookup[ds_y] + columnofs[ds_x1];
|
|
source = ds_source;
|
|
//colormap = ds_colormap;
|
|
|
|
#if 0 // The "perfect" reference version of this routine. Pretty slow.
|
|
// Use it only to see how things are supposed to look.
|
|
i = 0;
|
|
do
|
|
{
|
|
double z = 1.f/iz;
|
|
u = (INT64)(uz*z) + viewx;
|
|
v = (INT64)(vz*z) + viewy;
|
|
|
|
colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps);
|
|
|
|
*dest = colormap[source[((v >> nflatyshift) & nflatmask) | (u >> nflatxshift)]];
|
|
dest++;
|
|
iz += ds_sz.x;
|
|
uz += ds_su.x;
|
|
vz += ds_sv.x;
|
|
} while (--width >= 0);
|
|
#else
|
|
#define SPANSIZE 16
|
|
#define INVSPAN 0.0625f
|
|
|
|
startz = 1.f/iz;
|
|
startu = uz*startz;
|
|
startv = vz*startz;
|
|
|
|
izstep = ds_sz.x * SPANSIZE;
|
|
uzstep = ds_su.x * SPANSIZE;
|
|
vzstep = ds_sv.x * SPANSIZE;
|
|
//x1 = 0;
|
|
width++;
|
|
|
|
while (width >= SPANSIZE)
|
|
{
|
|
iz += izstep;
|
|
uz += uzstep;
|
|
vz += vzstep;
|
|
|
|
endz = 1.f/iz;
|
|
endu = uz*endz;
|
|
endv = vz*endz;
|
|
stepu = (INT64)((endu - startu) * INVSPAN);
|
|
stepv = (INT64)((endv - startv) * INVSPAN);
|
|
u = (INT64)(startu) + viewx;
|
|
v = (INT64)(startv) + viewy;
|
|
|
|
for (i = SPANSIZE-1; i >= 0; i--)
|
|
{
|
|
colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps);
|
|
*dest = colormap[source[((v >> nflatyshift) & nflatmask) | (u >> nflatxshift)]];
|
|
dest++;
|
|
u += stepu;
|
|
v += stepv;
|
|
}
|
|
startu = endu;
|
|
startv = endv;
|
|
width -= SPANSIZE;
|
|
}
|
|
if (width > 0)
|
|
{
|
|
if (width == 1)
|
|
{
|
|
u = (INT64)(startu);
|
|
v = (INT64)(startv);
|
|
colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps);
|
|
*dest = colormap[source[((v >> nflatyshift) & nflatmask) | (u >> nflatxshift)]];
|
|
}
|
|
else
|
|
{
|
|
double left = width;
|
|
iz += ds_sz.x * left;
|
|
uz += ds_su.x * left;
|
|
vz += ds_sv.x * left;
|
|
|
|
endz = 1.f/iz;
|
|
endu = uz*endz;
|
|
endv = vz*endz;
|
|
left = 1.f/left;
|
|
stepu = (INT64)((endu - startu) * left);
|
|
stepv = (INT64)((endv - startv) * left);
|
|
u = (INT64)(startu) + viewx;
|
|
v = (INT64)(startv) + viewy;
|
|
|
|
for (; width != 0; width--)
|
|
{
|
|
colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps);
|
|
*dest = colormap[source[((v >> nflatyshift) & nflatmask) | (u >> nflatxshift)]];
|
|
dest++;
|
|
u += stepu;
|
|
v += stepv;
|
|
}
|
|
}
|
|
}
|
|
#endif
|
|
}
|
|
|
|
/** \brief The R_DrawTiltedTranslucentSpan_8 function
|
|
Like DrawTiltedSpan, but translucent
|
|
*/
|
|
void R_DrawTiltedTranslucentSpan_8(void)
|
|
{
|
|
// x1, x2 = ds_x1, ds_x2
|
|
int width = ds_x2 - ds_x1;
|
|
double iz, uz, vz;
|
|
UINT32 u, v;
|
|
int i;
|
|
|
|
UINT8 *source;
|
|
UINT8 *colormap;
|
|
UINT8 *dest;
|
|
|
|
double startz, startu, startv;
|
|
double izstep, uzstep, vzstep;
|
|
double endz, endu, endv;
|
|
UINT32 stepu, stepv;
|
|
|
|
iz = ds_sz.z + ds_sz.y*(centery-ds_y) + ds_sz.x*(ds_x1-centerx);
|
|
|
|
// Lighting is simple. It's just linear interpolation from start to end
|
|
{
|
|
float planelightfloat = BASEVIDWIDTH*BASEVIDWIDTH/vid.width / (zeroheight - FIXED_TO_FLOAT(viewz)) / 21.0f;
|
|
float lightstart, lightend;
|
|
|
|
lightend = (iz + ds_sz.x*width) * planelightfloat;
|
|
lightstart = iz * planelightfloat;
|
|
|
|
R_CalcTiltedLighting(FLOAT_TO_FIXED(lightstart), FLOAT_TO_FIXED(lightend));
|
|
//CONS_Printf("tilted lighting %f to %f (foc %f)\n", lightstart, lightend, focallengthf);
|
|
}
|
|
|
|
uz = ds_su.z + ds_su.y*(centery-ds_y) + ds_su.x*(ds_x1-centerx);
|
|
vz = ds_sv.z + ds_sv.y*(centery-ds_y) + ds_sv.x*(ds_x1-centerx);
|
|
|
|
dest = ylookup[ds_y] + columnofs[ds_x1];
|
|
source = ds_source;
|
|
//colormap = ds_colormap;
|
|
|
|
#if 0 // The "perfect" reference version of this routine. Pretty slow.
|
|
// Use it only to see how things are supposed to look.
|
|
i = 0;
|
|
do
|
|
{
|
|
double z = 1.f/iz;
|
|
u = (INT64)(uz*z) + viewx;
|
|
v = (INT64)(vz*z) + viewy;
|
|
|
|
colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps);
|
|
|
|
*dest = colormap[*(ds_transmap + (source[((v >> nflatyshift) & nflatmask) | (u >> nflatxshift)] << 8) + dest[0])];
|
|
dest++;
|
|
iz += ds_sz.x;
|
|
uz += ds_su.x;
|
|
vz += ds_sv.x;
|
|
} while (--width >= 0);
|
|
#else
|
|
#define SPANSIZE 16
|
|
#define INVSPAN 0.0625f
|
|
|
|
startz = 1.f/iz;
|
|
startu = uz*startz;
|
|
startv = vz*startz;
|
|
|
|
izstep = ds_sz.x * SPANSIZE;
|
|
uzstep = ds_su.x * SPANSIZE;
|
|
vzstep = ds_sv.x * SPANSIZE;
|
|
//x1 = 0;
|
|
width++;
|
|
|
|
while (width >= SPANSIZE)
|
|
{
|
|
iz += izstep;
|
|
uz += uzstep;
|
|
vz += vzstep;
|
|
|
|
endz = 1.f/iz;
|
|
endu = uz*endz;
|
|
endv = vz*endz;
|
|
stepu = (INT64)((endu - startu) * INVSPAN);
|
|
stepv = (INT64)((endv - startv) * INVSPAN);
|
|
u = (INT64)(startu) + viewx;
|
|
v = (INT64)(startv) + viewy;
|
|
|
|
for (i = SPANSIZE-1; i >= 0; i--)
|
|
{
|
|
colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps);
|
|
*dest = colormap[*(ds_transmap + (source[((v >> nflatyshift) & nflatmask) | (u >> nflatxshift)] << 8) + dest[0])];
|
|
dest++;
|
|
u += stepu;
|
|
v += stepv;
|
|
}
|
|
startu = endu;
|
|
startv = endv;
|
|
width -= SPANSIZE;
|
|
}
|
|
if (width > 0)
|
|
{
|
|
if (width == 1)
|
|
{
|
|
u = (INT64)(startu);
|
|
v = (INT64)(startv);
|
|
colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps);
|
|
*dest = colormap[*(ds_transmap + (source[((v >> nflatyshift) & nflatmask) | (u >> nflatxshift)] << 8) + dest[0])];
|
|
}
|
|
else
|
|
{
|
|
double left = width;
|
|
iz += ds_sz.x * left;
|
|
uz += ds_su.x * left;
|
|
vz += ds_sv.x * left;
|
|
|
|
endz = 1.f/iz;
|
|
endu = uz*endz;
|
|
endv = vz*endz;
|
|
left = 1.f/left;
|
|
stepu = (INT64)((endu - startu) * left);
|
|
stepv = (INT64)((endv - startv) * left);
|
|
u = (INT64)(startu) + viewx;
|
|
v = (INT64)(startv) + viewy;
|
|
|
|
for (; width != 0; width--)
|
|
{
|
|
colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps);
|
|
*dest = colormap[*(ds_transmap + (source[((v >> nflatyshift) & nflatmask) | (u >> nflatxshift)] << 8) + dest[0])];
|
|
dest++;
|
|
u += stepu;
|
|
v += stepv;
|
|
}
|
|
}
|
|
}
|
|
#endif
|
|
}
|
|
|
|
void R_DrawTiltedSplat_8(void)
|
|
{
|
|
// x1, x2 = ds_x1, ds_x2
|
|
int width = ds_x2 - ds_x1;
|
|
double iz, uz, vz;
|
|
UINT32 u, v;
|
|
int i;
|
|
|
|
UINT8 *source;
|
|
UINT8 *colormap;
|
|
UINT8 *dest;
|
|
|
|
UINT8 val;
|
|
|
|
double startz, startu, startv;
|
|
double izstep, uzstep, vzstep;
|
|
double endz, endu, endv;
|
|
UINT32 stepu, stepv;
|
|
|
|
iz = ds_sz.z + ds_sz.y*(centery-ds_y) + ds_sz.x*(ds_x1-centerx);
|
|
|
|
// Lighting is simple. It's just linear interpolation from start to end
|
|
{
|
|
float planelightfloat = BASEVIDWIDTH*BASEVIDWIDTH/vid.width / (zeroheight - FIXED_TO_FLOAT(viewz)) / 21.0f;
|
|
float lightstart, lightend;
|
|
|
|
lightend = (iz + ds_sz.x*width) * planelightfloat;
|
|
lightstart = iz * planelightfloat;
|
|
|
|
R_CalcTiltedLighting(FLOAT_TO_FIXED(lightstart), FLOAT_TO_FIXED(lightend));
|
|
//CONS_Printf("tilted lighting %f to %f (foc %f)\n", lightstart, lightend, focallengthf);
|
|
}
|
|
|
|
uz = ds_su.z + ds_su.y*(centery-ds_y) + ds_su.x*(ds_x1-centerx);
|
|
vz = ds_sv.z + ds_sv.y*(centery-ds_y) + ds_sv.x*(ds_x1-centerx);
|
|
|
|
dest = ylookup[ds_y] + columnofs[ds_x1];
|
|
source = ds_source;
|
|
//colormap = ds_colormap;
|
|
|
|
#if 0 // The "perfect" reference version of this routine. Pretty slow.
|
|
// Use it only to see how things are supposed to look.
|
|
i = 0;
|
|
do
|
|
{
|
|
double z = 1.f/iz;
|
|
u = (INT64)(uz*z) + viewx;
|
|
v = (INT64)(vz*z) + viewy;
|
|
|
|
colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps);
|
|
|
|
val = source[((v >> nflatyshift) & nflatmask) | (u >> nflatxshift)];
|
|
if (val != TRANSPARENTPIXEL)
|
|
*dest = colormap[val];
|
|
dest++;
|
|
iz += ds_sz.x;
|
|
uz += ds_su.x;
|
|
vz += ds_sv.x;
|
|
} while (--width >= 0);
|
|
#else
|
|
#define SPANSIZE 16
|
|
#define INVSPAN 0.0625f
|
|
|
|
startz = 1.f/iz;
|
|
startu = uz*startz;
|
|
startv = vz*startz;
|
|
|
|
izstep = ds_sz.x * SPANSIZE;
|
|
uzstep = ds_su.x * SPANSIZE;
|
|
vzstep = ds_sv.x * SPANSIZE;
|
|
//x1 = 0;
|
|
width++;
|
|
|
|
while (width >= SPANSIZE)
|
|
{
|
|
iz += izstep;
|
|
uz += uzstep;
|
|
vz += vzstep;
|
|
|
|
endz = 1.f/iz;
|
|
endu = uz*endz;
|
|
endv = vz*endz;
|
|
stepu = (INT64)((endu - startu) * INVSPAN);
|
|
stepv = (INT64)((endv - startv) * INVSPAN);
|
|
u = (INT64)(startu) + viewx;
|
|
v = (INT64)(startv) + viewy;
|
|
|
|
for (i = SPANSIZE-1; i >= 0; i--)
|
|
{
|
|
colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps);
|
|
val = source[((v >> nflatyshift) & nflatmask) | (u >> nflatxshift)];
|
|
if (val != TRANSPARENTPIXEL)
|
|
*dest = colormap[val];
|
|
dest++;
|
|
u += stepu;
|
|
v += stepv;
|
|
}
|
|
startu = endu;
|
|
startv = endv;
|
|
width -= SPANSIZE;
|
|
}
|
|
if (width > 0)
|
|
{
|
|
if (width == 1)
|
|
{
|
|
u = (INT64)(startu);
|
|
v = (INT64)(startv);
|
|
colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps);
|
|
val = source[((v >> nflatyshift) & nflatmask) | (u >> nflatxshift)];
|
|
if (val != TRANSPARENTPIXEL)
|
|
*dest = colormap[val];
|
|
}
|
|
else
|
|
{
|
|
double left = width;
|
|
iz += ds_sz.x * left;
|
|
uz += ds_su.x * left;
|
|
vz += ds_sv.x * left;
|
|
|
|
endz = 1.f/iz;
|
|
endu = uz*endz;
|
|
endv = vz*endz;
|
|
left = 1.f/left;
|
|
stepu = (INT64)((endu - startu) * left);
|
|
stepv = (INT64)((endv - startv) * left);
|
|
u = (INT64)(startu) + viewx;
|
|
v = (INT64)(startv) + viewy;
|
|
|
|
for (; width != 0; width--)
|
|
{
|
|
colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps);
|
|
val = source[((v >> nflatyshift) & nflatmask) | (u >> nflatxshift)];
|
|
if (val != TRANSPARENTPIXEL)
|
|
*dest = colormap[val];
|
|
dest++;
|
|
u += stepu;
|
|
v += stepv;
|
|
}
|
|
}
|
|
}
|
|
#endif
|
|
}
|
|
#endif // ESLOPE
|
|
|
|
/** \brief The R_DrawSplat_8 function
|
|
Just like R_DrawSpan_8, but skips transparent pixels.
|
|
*/
|
|
void R_DrawSplat_8 (void)
|
|
{
|
|
UINT32 xposition;
|
|
UINT32 yposition;
|
|
UINT32 xstep, ystep;
|
|
|
|
UINT8 *source;
|
|
UINT8 *colormap;
|
|
UINT8 *dest;
|
|
|
|
size_t count;
|
|
UINT32 val;
|
|
|
|
// SoM: we only need 6 bits for the integer part (0 thru 63) so the rest
|
|
// can be used for the fraction part. This allows calculation of the memory address in the
|
|
// texture with two shifts, an OR and one AND. (see below)
|
|
// for texture sizes > 64 the amount of precision we can allow will decrease, but only by one
|
|
// bit per power of two (obviously)
|
|
// Ok, because I was able to eliminate the variable spot below, this function is now FASTER
|
|
// than the original span renderer. Whodathunkit?
|
|
xposition = ds_xfrac << nflatshiftup; yposition = ds_yfrac << nflatshiftup;
|
|
xstep = ds_xstep << nflatshiftup; ystep = ds_ystep << nflatshiftup;
|
|
|
|
source = ds_source;
|
|
colormap = ds_colormap;
|
|
dest = ylookup[ds_y] + columnofs[ds_x1];
|
|
count = ds_x2 - ds_x1 + 1;
|
|
|
|
while (count >= 8)
|
|
{
|
|
// SoM: Why didn't I see this earlier? the spot variable is a waste now because we don't
|
|
// have the uber complicated math to calculate it now, so that was a memory write we didn't
|
|
// need!
|
|
//
|
|
// <Callum> 4194303 = (2048x2048)-1 (2048x2048 is maximum flat size)
|
|
val = ((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift);
|
|
val &= 4194303;
|
|
val = source[val];
|
|
if (val != TRANSPARENTPIXEL)
|
|
dest[0] = colormap[val];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
val = ((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift);
|
|
val &= 4194303;
|
|
val = source[val];
|
|
if (val != TRANSPARENTPIXEL)
|
|
dest[1] = colormap[val];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
val = ((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift);
|
|
val &= 4194303;
|
|
val = source[val];
|
|
if (val != TRANSPARENTPIXEL)
|
|
dest[2] = colormap[val];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
val = ((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift);
|
|
val &= 4194303;
|
|
val = source[val];
|
|
if (val != TRANSPARENTPIXEL)
|
|
dest[3] = colormap[val];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
val = ((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift);
|
|
val &= 4194303;
|
|
val = source[val];
|
|
if (val != TRANSPARENTPIXEL)
|
|
dest[4] = colormap[val];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
val = ((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift);
|
|
val &= 4194303;
|
|
val = source[val];
|
|
if (val != TRANSPARENTPIXEL)
|
|
dest[5] = colormap[val];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
val = ((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift);
|
|
val &= 4194303;
|
|
val = source[val];
|
|
if (val != TRANSPARENTPIXEL)
|
|
dest[6] = colormap[val];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
val = ((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift);
|
|
val &= 4194303;
|
|
val = source[val];
|
|
if (val != TRANSPARENTPIXEL)
|
|
dest[7] = colormap[val];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
dest += 8;
|
|
count -= 8;
|
|
}
|
|
while (count--)
|
|
{
|
|
val = ((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift);
|
|
val &= 4194303;
|
|
val = source[val];
|
|
if (val != TRANSPARENTPIXEL)
|
|
*dest = colormap[val];
|
|
|
|
dest++;
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
}
|
|
}
|
|
|
|
/** \brief The R_DrawTranslucentSplat_8 function
|
|
Just like R_DrawSplat_8, but is translucent!
|
|
*/
|
|
void R_DrawTranslucentSplat_8 (void)
|
|
{
|
|
UINT32 xposition;
|
|
UINT32 yposition;
|
|
UINT32 xstep, ystep;
|
|
|
|
UINT8 *source;
|
|
UINT8 *colormap;
|
|
UINT8 *dest;
|
|
|
|
size_t count;
|
|
UINT8 val;
|
|
|
|
// SoM: we only need 6 bits for the integer part (0 thru 63) so the rest
|
|
// can be used for the fraction part. This allows calculation of the memory address in the
|
|
// texture with two shifts, an OR and one AND. (see below)
|
|
// for texture sizes > 64 the amount of precision we can allow will decrease, but only by one
|
|
// bit per power of two (obviously)
|
|
// Ok, because I was able to eliminate the variable spot below, this function is now FASTER
|
|
// than the original span renderer. Whodathunkit?
|
|
xposition = ds_xfrac << nflatshiftup; yposition = ds_yfrac << nflatshiftup;
|
|
xstep = ds_xstep << nflatshiftup; ystep = ds_ystep << nflatshiftup;
|
|
|
|
source = ds_source;
|
|
colormap = ds_colormap;
|
|
dest = ylookup[ds_y] + columnofs[ds_x1];
|
|
count = ds_x2 - ds_x1 + 1;
|
|
|
|
while (count >= 8)
|
|
{
|
|
// SoM: Why didn't I see this earlier? the spot variable is a waste now because we don't
|
|
// have the uber complicated math to calculate it now, so that was a memory write we didn't
|
|
// need!
|
|
val = source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)];
|
|
if (val != TRANSPARENTPIXEL)
|
|
dest[0] = colormap[*(ds_transmap + (val << 8) + dest[0])];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
val = source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)];
|
|
if (val != TRANSPARENTPIXEL)
|
|
dest[1] = colormap[*(ds_transmap + (val << 8) + dest[1])];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
val = source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)];
|
|
if (val != TRANSPARENTPIXEL)
|
|
dest[2] = colormap[*(ds_transmap + (val << 8) + dest[2])];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
val = source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)];
|
|
if (val != TRANSPARENTPIXEL)
|
|
dest[3] = colormap[*(ds_transmap + (val << 8) + dest[3])];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
val = source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)];
|
|
if (val != TRANSPARENTPIXEL)
|
|
dest[4] = colormap[*(ds_transmap + (val << 8) + dest[4])];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
val = source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)];
|
|
if (val != TRANSPARENTPIXEL)
|
|
dest[5] = colormap[*(ds_transmap + (val << 8) + dest[5])];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
val = source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)];
|
|
if (val != TRANSPARENTPIXEL)
|
|
dest[6] = colormap[*(ds_transmap + (val << 8) + dest[6])];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
val = source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)];
|
|
if (val != TRANSPARENTPIXEL)
|
|
dest[7] = colormap[*(ds_transmap + (val << 8) + dest[7])];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
dest += 8;
|
|
count -= 8;
|
|
}
|
|
while (count--)
|
|
{
|
|
val = source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)];
|
|
if (val != TRANSPARENTPIXEL)
|
|
*dest = colormap[*(ds_transmap + (val << 8) + *dest)];
|
|
|
|
dest++;
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
}
|
|
}
|
|
|
|
/** \brief The R_DrawTranslucentSpan_8 function
|
|
Draws the actual span with translucent.
|
|
*/
|
|
void R_DrawTranslucentSpan_8 (void)
|
|
{
|
|
UINT32 xposition;
|
|
UINT32 yposition;
|
|
UINT32 xstep, ystep;
|
|
|
|
UINT8 *source;
|
|
UINT8 *colormap;
|
|
UINT8 *dest;
|
|
|
|
size_t count;
|
|
|
|
// SoM: we only need 6 bits for the integer part (0 thru 63) so the rest
|
|
// can be used for the fraction part. This allows calculation of the memory address in the
|
|
// texture with two shifts, an OR and one AND. (see below)
|
|
// for texture sizes > 64 the amount of precision we can allow will decrease, but only by one
|
|
// bit per power of two (obviously)
|
|
// Ok, because I was able to eliminate the variable spot below, this function is now FASTER
|
|
// than the original span renderer. Whodathunkit?
|
|
xposition = ds_xfrac << nflatshiftup; yposition = ds_yfrac << nflatshiftup;
|
|
xstep = ds_xstep << nflatshiftup; ystep = ds_ystep << nflatshiftup;
|
|
|
|
source = ds_source;
|
|
colormap = ds_colormap;
|
|
dest = ylookup[ds_y] + columnofs[ds_x1];
|
|
count = ds_x2 - ds_x1 + 1;
|
|
|
|
while (count >= 8)
|
|
{
|
|
// SoM: Why didn't I see this earlier? the spot variable is a waste now because we don't
|
|
// have the uber complicated math to calculate it now, so that was a memory write we didn't
|
|
// need!
|
|
dest[0] = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + dest[0])];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
dest[1] = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + dest[1])];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
dest[2] = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + dest[2])];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
dest[3] = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + dest[3])];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
dest[4] = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + dest[4])];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
dest[5] = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + dest[5])];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
dest[6] = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + dest[6])];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
dest[7] = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + dest[7])];
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
|
|
dest += 8;
|
|
count -= 8;
|
|
}
|
|
while (count--)
|
|
{
|
|
*dest = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + *dest)];
|
|
dest++;
|
|
xposition += xstep;
|
|
yposition += ystep;
|
|
}
|
|
}
|
|
|
|
/** \brief The R_DrawFogSpan_8 function
|
|
Draws the actual span with fogging.
|
|
*/
|
|
void R_DrawFogSpan_8(void)
|
|
{
|
|
UINT8 *colormap;
|
|
UINT8 *dest;
|
|
|
|
size_t count;
|
|
|
|
colormap = ds_colormap;
|
|
//dest = ylookup[ds_y] + columnofs[ds_x1];
|
|
dest = &topleft[ds_y *vid.width + ds_x1];
|
|
|
|
count = ds_x2 - ds_x1 + 1;
|
|
|
|
while (count >= 4)
|
|
{
|
|
dest[0] = colormap[dest[0]];
|
|
dest[1] = colormap[dest[1]];
|
|
dest[2] = colormap[dest[2]];
|
|
dest[3] = colormap[dest[3]];
|
|
|
|
dest += 4;
|
|
count -= 4;
|
|
}
|
|
|
|
while (count--)
|
|
{
|
|
*dest = colormap[*dest];
|
|
dest++;
|
|
}
|
|
}
|
|
|
|
/** \brief The R_DrawFogColumn_8 function
|
|
Fog wall.
|
|
*/
|
|
void R_DrawFogColumn_8(void)
|
|
{
|
|
INT32 count;
|
|
UINT8 *dest;
|
|
|
|
count = dc_yh - dc_yl;
|
|
|
|
// Zero length, column does not exceed a pixel.
|
|
if (count < 0)
|
|
return;
|
|
|
|
#ifdef RANGECHECK
|
|
if ((unsigned)dc_x >= (unsigned)vid.width || dc_yl < 0 || dc_yh >= vid.height)
|
|
I_Error("R_DrawFogColumn_8: %d to %d at %d", dc_yl, dc_yh, dc_x);
|
|
#endif
|
|
|
|
// Framebuffer destination address.
|
|
// Use ylookup LUT to avoid multiply with ScreenWidth.
|
|
// Use columnofs LUT for subwindows?
|
|
//dest = ylookup[dc_yl] + columnofs[dc_x];
|
|
dest = &topleft[dc_yl*vid.width + dc_x];
|
|
|
|
// Determine scaling, which is the only mapping to be done.
|
|
do
|
|
{
|
|
// Simple. Apply the colormap to what's already on the screen.
|
|
*dest = dc_colormap[*dest];
|
|
dest += vid.width;
|
|
} while (count--);
|
|
}
|
|
|
|
/** \brief The R_DrawShadeColumn_8 function
|
|
This is for 3D floors that cast shadows on walls.
|
|
|
|
This function just cuts the column up into sections and calls R_DrawColumn_8
|
|
*/
|
|
void R_DrawColumnShadowed_8(void)
|
|
{
|
|
INT32 count, realyh, i, height, bheight = 0, solid = 0;
|
|
|
|
realyh = dc_yh;
|
|
|
|
count = dc_yh - dc_yl;
|
|
|
|
// Zero length, column does not exceed a pixel.
|
|
if (count < 0)
|
|
return;
|
|
|
|
#ifdef RANGECHECK
|
|
if ((unsigned)dc_x >= (unsigned)vid.width || dc_yl < 0 || dc_yh >= vid.height)
|
|
I_Error("R_DrawColumnShadowed_8: %d to %d at %d", dc_yl, dc_yh, dc_x);
|
|
#endif
|
|
|
|
// This runs through the lightlist from top to bottom and cuts up the column accordingly.
|
|
for (i = 0; i < dc_numlights; i++)
|
|
{
|
|
// If the height of the light is above the column, get the colormap
|
|
// anyway because the lighting of the top should be affected.
|
|
solid = dc_lightlist[i].flags & FF_CUTSOLIDS;
|
|
|
|
height = dc_lightlist[i].height >> LIGHTSCALESHIFT;
|
|
if (solid)
|
|
{
|
|
bheight = dc_lightlist[i].botheight >> LIGHTSCALESHIFT;
|
|
if (bheight < height)
|
|
{
|
|
// confounded slopes sometimes allow partial invertedness,
|
|
// even including cases where the top and bottom heights
|
|
// should actually be the same!
|
|
// swap the height values as a workaround for this quirk
|
|
INT32 temp = height;
|
|
height = bheight;
|
|
bheight = temp;
|
|
}
|
|
}
|
|
if (height <= dc_yl)
|
|
{
|
|
dc_colormap = dc_lightlist[i].rcolormap;
|
|
if (solid && dc_yl < bheight)
|
|
dc_yl = bheight;
|
|
continue;
|
|
}
|
|
// Found a break in the column!
|
|
dc_yh = height;
|
|
|
|
if (dc_yh > realyh)
|
|
dc_yh = realyh;
|
|
basecolfunc(); // R_DrawColumn_8 for the appropriate architecture
|
|
if (solid)
|
|
dc_yl = bheight;
|
|
else
|
|
dc_yl = dc_yh + 1;
|
|
|
|
dc_colormap = dc_lightlist[i].rcolormap;
|
|
}
|
|
dc_yh = realyh;
|
|
if (dc_yl <= realyh)
|
|
walldrawerfunc(); // R_DrawWallColumn_8 for the appropriate architecture
|
|
}
|