// SONIC ROBO BLAST 2 //----------------------------------------------------------------------------- // Copyright (C) 1998-2000 by DooM Legacy Team. // Copyright (C) 1999-2022 by Sonic Team Junior. // // This program is free software distributed under the // terms of the GNU General Public License, version 2. // See the 'LICENSE' file for more details. //----------------------------------------------------------------------------- /// \file r_draw8_npo2.c /// \brief 8bpp span drawer functions (for non-powers-of-two flat dimensions) /// \note no includes because this is included as part of r_draw.c // ========================================================================== // SPANS // ========================================================================== #define SPANSIZE 16 #define INVSPAN 0.0625f /** \brief The R_DrawSpan_NPO2_8 function Draws the actual span. */ void R_DrawSpan_NPO2_8 (void) { fixed_t xposition; fixed_t yposition; fixed_t xstep, ystep; fixed_t x, y; fixed_t fixedwidth, fixedheight; UINT8 *source; UINT8 *colormap; UINT8 *dest; const UINT8 *deststop = screens[0] + vid.rowbytes * vid.height; size_t count = (ds_x2 - ds_x1 + 1); xposition = ds_xfrac; yposition = ds_yfrac; xstep = ds_xstep; ystep = ds_ystep; source = ds_source; colormap = ds_colormap; dest = ylookup[ds_y] + columnofs[ds_x1]; if (dest+8 > deststop) return; fixedwidth = ds_flatwidth << FRACBITS; fixedheight = ds_flatheight << FRACBITS; // Fix xposition and yposition if they are out of bounds. if (xposition < 0) xposition = fixedwidth - ((UINT32)(fixedwidth - xposition) % fixedwidth); else if (xposition >= fixedwidth) xposition %= fixedwidth; if (yposition < 0) yposition = fixedheight - ((UINT32)(fixedheight - yposition) % fixedheight); else if (yposition >= fixedheight) yposition %= fixedheight; while (count-- && dest <= deststop) { // The loops here keep the texture coordinates within the texture. // They will rarely iterate multiple times, and are cheaper than a modulo operation, // even if using libdivide. if (xstep < 0) // These if statements are hopefully hoisted by the compiler to above this loop while (xposition < 0) xposition += fixedwidth; else while (xposition >= fixedwidth) xposition -= fixedwidth; if (ystep < 0) while (yposition < 0) yposition += fixedheight; else while (yposition >= fixedheight) yposition -= fixedheight; x = (xposition >> FRACBITS); y = (yposition >> FRACBITS); *dest++ = colormap[source[((y * ds_flatwidth) + x)]]; xposition += xstep; yposition += ystep; } } /** \brief The R_DrawTiltedSpan_NPO2_8 function Draw slopes! Holy sheit! */ void R_DrawTiltedSpan_NPO2_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; struct libdivide_u32_t x_divider = libdivide_u32_gen(ds_flatwidth); struct libdivide_u32_t y_divider = libdivide_u32_gen(ds_flatheight); iz = ds_szp->z + ds_szp->y*(centery-ds_y) + ds_szp->x*(ds_x1-centerx); CALC_SLOPE_LIGHT uz = ds_sup->z + ds_sup->y*(centery-ds_y) + ds_sup->x*(ds_x1-centerx); vz = ds_svp->z + ds_svp->y*(centery-ds_y) + ds_svp->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); v = (INT64)(vz*z); colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; *dest = colormap[source[((y * ds_flatwidth) + x)]]; } dest++; iz += ds_szp->x; uz += ds_sup->x; vz += ds_svp->x; } while (--width >= 0); #else startz = 1.f/iz; startu = uz*startz; startv = vz*startz; izstep = ds_szp->x * SPANSIZE; uzstep = ds_sup->x * SPANSIZE; vzstep = ds_svp->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); v = (INT64)(startv); for (i = SPANSIZE-1; i >= 0; i--) { colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; *dest = colormap[source[((y * ds_flatwidth) + x)]]; } 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); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; *dest = colormap[source[((y * ds_flatwidth) + x)]]; } } else { double left = width; iz += ds_szp->x * left; uz += ds_sup->x * left; vz += ds_svp->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); v = (INT64)(startv); for (; width != 0; width--) { colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; *dest = colormap[source[((y * ds_flatwidth) + x)]]; } dest++; u += stepu; v += stepv; } } } #endif } /** \brief The R_DrawTiltedTranslucentSpan_NPO2_8 function Like DrawTiltedSpan_NPO2, but translucent */ void R_DrawTiltedTranslucentSpan_NPO2_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; struct libdivide_u32_t x_divider = libdivide_u32_gen(ds_flatwidth); struct libdivide_u32_t y_divider = libdivide_u32_gen(ds_flatheight); iz = ds_szp->z + ds_szp->y*(centery-ds_y) + ds_szp->x*(ds_x1-centerx); CALC_SLOPE_LIGHT uz = ds_sup->z + ds_sup->y*(centery-ds_y) + ds_sup->x*(ds_x1-centerx); vz = ds_svp->z + ds_svp->y*(centery-ds_y) + ds_svp->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); v = (INT64)(vz*z); colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; *dest = *(ds_transmap + (colormap[source[((y * ds_flatwidth) + x)]] << 8) + *dest); } dest++; iz += ds_szp->x; uz += ds_sup->x; vz += ds_svp->x; } while (--width >= 0); #else startz = 1.f/iz; startu = uz*startz; startv = vz*startz; izstep = ds_szp->x * SPANSIZE; uzstep = ds_sup->x * SPANSIZE; vzstep = ds_svp->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); v = (INT64)(startv); for (i = SPANSIZE-1; i >= 0; i--) { colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; *dest = *(ds_transmap + (colormap[source[((y * ds_flatwidth) + x)]] << 8) + *dest); } 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); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; *dest = *(ds_transmap + (colormap[source[((y * ds_flatwidth) + x)]] << 8) + *dest); } } else { double left = width; iz += ds_szp->x * left; uz += ds_sup->x * left; vz += ds_svp->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); v = (INT64)(startv); for (; width != 0; width--) { colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; *dest = *(ds_transmap + (colormap[source[((y * ds_flatwidth) + x)]] << 8) + *dest); } dest++; u += stepu; v += stepv; } } } #endif } void R_DrawTiltedSplat_NPO2_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; struct libdivide_u32_t x_divider = libdivide_u32_gen(ds_flatwidth); struct libdivide_u32_t y_divider = libdivide_u32_gen(ds_flatheight); iz = ds_szp->z + ds_szp->y*(centery-ds_y) + ds_szp->x*(ds_x1-centerx); CALC_SLOPE_LIGHT uz = ds_sup->z + ds_sup->y*(centery-ds_y) + ds_sup->x*(ds_x1-centerx); vz = ds_svp->z + ds_svp->y*(centery-ds_y) + ds_svp->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); v = (INT64)(vz*z); colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; val = source[((y * ds_flatwidth) + x)]; } if (val != TRANSPARENTPIXEL) *dest = colormap[val]; dest++; iz += ds_szp->x; uz += ds_sup->x; vz += ds_svp->x; } while (--width >= 0); #else startz = 1.f/iz; startu = uz*startz; startv = vz*startz; izstep = ds_szp->x * SPANSIZE; uzstep = ds_sup->x * SPANSIZE; vzstep = ds_svp->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); v = (INT64)(startv); for (i = SPANSIZE-1; i >= 0; i--) { colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; val = source[((y * ds_flatwidth) + x)]; } 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); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; val = source[((y * ds_flatwidth) + x)]; } if (val != TRANSPARENTPIXEL) *dest = colormap[val]; } else { double left = width; iz += ds_szp->x * left; uz += ds_sup->x * left; vz += ds_svp->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); v = (INT64)(startv); for (; width != 0; width--) { colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; val = source[((y * ds_flatwidth) + x)]; } if (val != TRANSPARENTPIXEL) *dest = colormap[val]; dest++; u += stepu; v += stepv; } } } #endif } /** \brief The R_DrawSplat_NPO2_8 function Just like R_DrawSpan_NPO2_8, but skips transparent pixels. */ void R_DrawSplat_NPO2_8 (void) { fixed_t xposition; fixed_t yposition; fixed_t xstep, ystep; fixed_t x, y; fixed_t fixedwidth, fixedheight; UINT8 *source; UINT8 *colormap; UINT8 *dest; const UINT8 *deststop = screens[0] + vid.rowbytes * vid.height; size_t count = (ds_x2 - ds_x1 + 1); UINT32 val; xposition = ds_xfrac; yposition = ds_yfrac; xstep = ds_xstep; ystep = ds_ystep; source = ds_source; colormap = ds_colormap; dest = ylookup[ds_y] + columnofs[ds_x1]; fixedwidth = ds_flatwidth << FRACBITS; fixedheight = ds_flatheight << FRACBITS; // Fix xposition and yposition if they are out of bounds. if (xposition < 0) xposition = fixedwidth - ((UINT32)(fixedwidth - xposition) % fixedwidth); else if (xposition >= fixedwidth) xposition %= fixedwidth; if (yposition < 0) yposition = fixedheight - ((UINT32)(fixedheight - yposition) % fixedheight); else if (yposition >= fixedheight) yposition %= fixedheight; while (count-- && dest <= deststop) { // The loops here keep the texture coordinates within the texture. // They will rarely iterate multiple times, and are cheaper than a modulo operation, // even if using libdivide. if (xstep < 0) // These if statements are hopefully hoisted by the compiler to above this loop while (xposition < 0) xposition += fixedwidth; else while (xposition >= fixedwidth) xposition -= fixedwidth; if (ystep < 0) while (yposition < 0) yposition += fixedheight; else while (yposition >= fixedheight) yposition -= fixedheight; x = (xposition >> FRACBITS); y = (yposition >> FRACBITS); val = source[((y * ds_flatwidth) + x)]; if (val != TRANSPARENTPIXEL) *dest = colormap[val]; dest++; xposition += xstep; yposition += ystep; } } /** \brief The R_DrawTranslucentSplat_NPO2_8 function Just like R_DrawSplat_NPO2_8, but is translucent! */ void R_DrawTranslucentSplat_NPO2_8 (void) { fixed_t xposition; fixed_t yposition; fixed_t xstep, ystep; fixed_t x, y; fixed_t fixedwidth, fixedheight; UINT8 *source; UINT8 *colormap; UINT8 *dest; const UINT8 *deststop = screens[0] + vid.rowbytes * vid.height; size_t count = (ds_x2 - ds_x1 + 1); UINT32 val; xposition = ds_xfrac; yposition = ds_yfrac; xstep = ds_xstep; ystep = ds_ystep; source = ds_source; colormap = ds_colormap; dest = ylookup[ds_y] + columnofs[ds_x1]; fixedwidth = ds_flatwidth << FRACBITS; fixedheight = ds_flatheight << FRACBITS; // Fix xposition and yposition if they are out of bounds. if (xposition < 0) xposition = fixedwidth - ((UINT32)(fixedwidth - xposition) % fixedwidth); else if (xposition >= fixedwidth) xposition %= fixedwidth; if (yposition < 0) yposition = fixedheight - ((UINT32)(fixedheight - yposition) % fixedheight); else if (yposition >= fixedheight) yposition %= fixedheight; while (count-- && dest <= deststop) { // The loops here keep the texture coordinates within the texture. // They will rarely iterate multiple times, and are cheaper than a modulo operation, // even if using libdivide. if (xstep < 0) // These if statements are hopefully hoisted by the compiler to above this loop while (xposition < 0) xposition += fixedwidth; else while (xposition >= fixedwidth) xposition -= fixedwidth; if (ystep < 0) while (yposition < 0) yposition += fixedheight; else while (yposition >= fixedheight) yposition -= fixedheight; x = (xposition >> FRACBITS); y = (yposition >> FRACBITS); val = source[((y * ds_flatwidth) + x)]; if (val != TRANSPARENTPIXEL) *dest = *(ds_transmap + (colormap[val] << 8) + *dest); dest++; xposition += xstep; yposition += ystep; } } /** \brief The R_DrawFloorSprite_NPO2_8 function Just like R_DrawSplat_NPO2_8, but for floor sprites. */ void R_DrawFloorSprite_NPO2_8 (void) { fixed_t xposition; fixed_t yposition; fixed_t xstep, ystep; fixed_t x, y; fixed_t fixedwidth, fixedheight; UINT16 *source; UINT8 *translation; UINT8 *colormap; UINT8 *dest; const UINT8 *deststop = screens[0] + vid.rowbytes * vid.height; size_t count = (ds_x2 - ds_x1 + 1); UINT32 val; xposition = ds_xfrac; yposition = ds_yfrac; xstep = ds_xstep; ystep = ds_ystep; source = (UINT16 *)ds_source; colormap = ds_colormap; translation = ds_translation; dest = ylookup[ds_y] + columnofs[ds_x1]; fixedwidth = ds_flatwidth << FRACBITS; fixedheight = ds_flatheight << FRACBITS; // Fix xposition and yposition if they are out of bounds. if (xposition < 0) xposition = fixedwidth - ((UINT32)(fixedwidth - xposition) % fixedwidth); else if (xposition >= fixedwidth) xposition %= fixedwidth; if (yposition < 0) yposition = fixedheight - ((UINT32)(fixedheight - yposition) % fixedheight); else if (yposition >= fixedheight) yposition %= fixedheight; while (count-- && dest <= deststop) { // The loops here keep the texture coordinates within the texture. // They will rarely iterate multiple times, and are cheaper than a modulo operation, // even if using libdivide. if (xstep < 0) // These if statements are hopefully hoisted by the compiler to above this loop while (xposition < 0) xposition += fixedwidth; else while (xposition >= fixedwidth) xposition -= fixedwidth; if (ystep < 0) while (yposition < 0) yposition += fixedheight; else while (yposition >= fixedheight) yposition -= fixedheight; x = (xposition >> FRACBITS); y = (yposition >> FRACBITS); val = source[((y * ds_flatwidth) + x)]; if (val & 0xFF00) *dest = colormap[translation[val & 0xFF]]; dest++; xposition += xstep; yposition += ystep; } } /** \brief The R_DrawTranslucentFloorSprite_NPO2_8 function Just like R_DrawFloorSprite_NPO2_8, but is translucent! */ void R_DrawTranslucentFloorSprite_NPO2_8 (void) { fixed_t xposition; fixed_t yposition; fixed_t xstep, ystep; fixed_t x, y; fixed_t fixedwidth, fixedheight; UINT16 *source; UINT8 *translation; UINT8 *colormap; UINT8 *dest; const UINT8 *deststop = screens[0] + vid.rowbytes * vid.height; size_t count = (ds_x2 - ds_x1 + 1); UINT32 val; xposition = ds_xfrac; yposition = ds_yfrac; xstep = ds_xstep; ystep = ds_ystep; source = (UINT16 *)ds_source; colormap = ds_colormap; translation = ds_translation; dest = ylookup[ds_y] + columnofs[ds_x1]; fixedwidth = ds_flatwidth << FRACBITS; fixedheight = ds_flatheight << FRACBITS; // Fix xposition and yposition if they are out of bounds. if (xposition < 0) xposition = fixedwidth - ((UINT32)(fixedwidth - xposition) % fixedwidth); else if (xposition >= fixedwidth) xposition %= fixedwidth; if (yposition < 0) yposition = fixedheight - ((UINT32)(fixedheight - yposition) % fixedheight); else if (yposition >= fixedheight) yposition %= fixedheight; while (count-- && dest <= deststop) { // The loops here keep the texture coordinates within the texture. // They will rarely iterate multiple times, and are cheaper than a modulo operation, // even if using libdivide. if (xstep < 0) // These if statements are hopefully hoisted by the compiler to above this loop while (xposition < 0) xposition += fixedwidth; else while (xposition >= fixedwidth) xposition -= fixedwidth; if (ystep < 0) while (yposition < 0) yposition += fixedheight; else while (yposition >= fixedheight) yposition -= fixedheight; x = (xposition >> FRACBITS); y = (yposition >> FRACBITS); val = source[((y * ds_flatwidth) + x)]; if (val & 0xFF00) *dest = *(ds_transmap + (colormap[translation[val & 0xFF]] << 8) + *dest); dest++; xposition += xstep; yposition += ystep; } } /** \brief The R_DrawTiltedFloorSprite_NPO2_8 function Draws a tilted floor sprite. */ void R_DrawTiltedFloorSprite_NPO2_8(void) { // x1, x2 = ds_x1, ds_x2 int width = ds_x2 - ds_x1; double iz, uz, vz; UINT32 u, v; int i; UINT16 *source; UINT8 *colormap; UINT8 *translation; UINT8 *dest; UINT16 val; double startz, startu, startv; double izstep, uzstep, vzstep; double endz, endu, endv; UINT32 stepu, stepv; struct libdivide_u32_t x_divider = libdivide_u32_gen(ds_flatwidth); struct libdivide_u32_t y_divider = libdivide_u32_gen(ds_flatheight); iz = ds_szp->z + ds_szp->y*(centery-ds_y) + ds_szp->x*(ds_x1-centerx); uz = ds_sup->z + ds_sup->y*(centery-ds_y) + ds_sup->x*(ds_x1-centerx); vz = ds_svp->z + ds_svp->y*(centery-ds_y) + ds_svp->x*(ds_x1-centerx); dest = ylookup[ds_y] + columnofs[ds_x1]; source = (UINT16 *)ds_source; colormap = ds_colormap; translation = ds_translation; startz = 1.f/iz; startu = uz*startz; startv = vz*startz; izstep = ds_szp->x * SPANSIZE; uzstep = ds_sup->x * SPANSIZE; vzstep = ds_svp->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); v = (INT64)(startv); for (i = SPANSIZE-1; i >= 0; i--) { // Lactozilla: Non-powers-of-two fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; val = source[((y * ds_flatwidth) + x)]; if (val & 0xFF00) *dest = colormap[translation[val & 0xFF]]; dest++; u += stepu; v += stepv; } startu = endu; startv = endv; width -= SPANSIZE; } if (width > 0) { if (width == 1) { u = (INT64)(startu); v = (INT64)(startv); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; val = source[((y * ds_flatwidth) + x)]; if (val & 0xFF00) *dest = colormap[translation[val & 0xFF]]; } } else { double left = width; iz += ds_szp->x * left; uz += ds_sup->x * left; vz += ds_svp->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); v = (INT64)(startv); for (; width != 0; width--) { // Lactozilla: Non-powers-of-two fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; val = source[((y * ds_flatwidth) + x)]; if (val & 0xFF00) *dest = colormap[translation[val & 0xFF]]; dest++; u += stepu; v += stepv; } } } } /** \brief The R_DrawTiltedTranslucentFloorSprite_NPO2_8 function Draws a tilted, translucent, floor sprite. */ void R_DrawTiltedTranslucentFloorSprite_NPO2_8(void) { // x1, x2 = ds_x1, ds_x2 int width = ds_x2 - ds_x1; double iz, uz, vz; UINT32 u, v; int i; UINT16 *source; UINT8 *colormap; UINT8 *translation; UINT8 *dest; UINT16 val; double startz, startu, startv; double izstep, uzstep, vzstep; double endz, endu, endv; UINT32 stepu, stepv; struct libdivide_u32_t x_divider = libdivide_u32_gen(ds_flatwidth); struct libdivide_u32_t y_divider = libdivide_u32_gen(ds_flatheight); iz = ds_szp->z + ds_szp->y*(centery-ds_y) + ds_szp->x*(ds_x1-centerx); uz = ds_sup->z + ds_sup->y*(centery-ds_y) + ds_sup->x*(ds_x1-centerx); vz = ds_svp->z + ds_svp->y*(centery-ds_y) + ds_svp->x*(ds_x1-centerx); dest = ylookup[ds_y] + columnofs[ds_x1]; source = (UINT16 *)ds_source; colormap = ds_colormap; translation = ds_translation; startz = 1.f/iz; startu = uz*startz; startv = vz*startz; izstep = ds_szp->x * SPANSIZE; uzstep = ds_sup->x * SPANSIZE; vzstep = ds_svp->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); v = (INT64)(startv); for (i = SPANSIZE-1; i >= 0; i--) { // Lactozilla: Non-powers-of-two fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; val = source[((y * ds_flatwidth) + x)]; if (val & 0xFF00) *dest = *(ds_transmap + (colormap[translation[val & 0xFF]] << 8) + *dest); dest++; u += stepu; v += stepv; } startu = endu; startv = endv; width -= SPANSIZE; } if (width > 0) { if (width == 1) { u = (INT64)(startu); v = (INT64)(startv); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; val = source[((y * ds_flatwidth) + x)]; if (val & 0xFF00) *dest = *(ds_transmap + (colormap[translation[val & 0xFF]] << 8) + *dest); } } else { double left = width; iz += ds_szp->x * left; uz += ds_sup->x * left; vz += ds_svp->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); v = (INT64)(startv); for (; width != 0; width--) { // Lactozilla: Non-powers-of-two fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; val = source[((y * ds_flatwidth) + x)]; if (val & 0xFF00) *dest = *(ds_transmap + (colormap[translation[val & 0xFF]] << 8) + *dest); dest++; u += stepu; v += stepv; } } } } /** \brief The R_DrawTranslucentSpan_NPO2_8 function Draws the actual span with translucency. */ void R_DrawTranslucentSpan_NPO2_8 (void) { fixed_t xposition; fixed_t yposition; fixed_t xstep, ystep; fixed_t x, y; fixed_t fixedwidth, fixedheight; UINT8 *source; UINT8 *colormap; UINT8 *dest; const UINT8 *deststop = screens[0] + vid.rowbytes * vid.height; size_t count = (ds_x2 - ds_x1 + 1); UINT32 val; xposition = ds_xfrac; yposition = ds_yfrac; xstep = ds_xstep; ystep = ds_ystep; source = ds_source; colormap = ds_colormap; dest = ylookup[ds_y] + columnofs[ds_x1]; fixedwidth = ds_flatwidth << FRACBITS; fixedheight = ds_flatheight << FRACBITS; // Fix xposition and yposition if they are out of bounds. if (xposition < 0) xposition = fixedwidth - ((UINT32)(fixedwidth - xposition) % fixedwidth); else if (xposition >= fixedwidth) xposition %= fixedwidth; if (yposition < 0) yposition = fixedheight - ((UINT32)(fixedheight - yposition) % fixedheight); else if (yposition >= fixedheight) yposition %= fixedheight; while (count-- && dest <= deststop) { // The loops here keep the texture coordinates within the texture. // They will rarely iterate multiple times, and are cheaper than a modulo operation, // even if using libdivide. if (xstep < 0) // These if statements are hopefully hoisted by the compiler to above this loop while (xposition < 0) xposition += fixedwidth; else while (xposition >= fixedwidth) xposition -= fixedwidth; if (ystep < 0) while (yposition < 0) yposition += fixedheight; else while (yposition >= fixedheight) yposition -= fixedheight; x = (xposition >> FRACBITS); y = (yposition >> FRACBITS); val = ((y * ds_flatwidth) + x); *dest = *(ds_transmap + (colormap[source[val]] << 8) + *dest); dest++; xposition += xstep; yposition += ystep; } } void R_DrawTranslucentWaterSpan_NPO2_8(void) { fixed_t xposition; fixed_t yposition; fixed_t xstep, ystep; fixed_t x, y; fixed_t fixedwidth, fixedheight; UINT8 *source; UINT8 *colormap; UINT8 *dest; UINT8 *dsrc; const UINT8 *deststop = screens[0] + vid.rowbytes * vid.height; size_t count = (ds_x2 - ds_x1 + 1); xposition = ds_xfrac; yposition = (ds_yfrac + ds_waterofs); xstep = ds_xstep; ystep = ds_ystep; source = ds_source; colormap = ds_colormap; dest = ylookup[ds_y] + columnofs[ds_x1]; dsrc = screens[1] + (ds_y+ds_bgofs)*vid.width + ds_x1; fixedwidth = ds_flatwidth << FRACBITS; fixedheight = ds_flatheight << FRACBITS; // Fix xposition and yposition if they are out of bounds. if (xposition < 0) xposition = fixedwidth - ((UINT32)(fixedwidth - xposition) % fixedwidth); else if (xposition >= fixedwidth) xposition %= fixedwidth; if (yposition < 0) yposition = fixedheight - ((UINT32)(fixedheight - yposition) % fixedheight); else if (yposition >= fixedheight) yposition %= fixedheight; while (count-- && dest <= deststop) { // The loops here keep the texture coordinates within the texture. // They will rarely iterate multiple times, and are cheaper than a modulo operation, // even if using libdivide. if (xstep < 0) // These if statements are hopefully hoisted by the compiler to above this loop while (xposition < 0) xposition += fixedwidth; else while (xposition >= fixedwidth) xposition -= fixedwidth; if (ystep < 0) while (yposition < 0) yposition += fixedheight; else while (yposition >= fixedheight) yposition -= fixedheight; x = (xposition >> FRACBITS); y = (yposition >> FRACBITS); *dest++ = colormap[*(ds_transmap + (source[((y * ds_flatwidth) + x)] << 8) + *dsrc++)]; xposition += xstep; yposition += ystep; } } /** \brief The R_DrawTiltedTranslucentWaterSpan_NPO2_8 function Like DrawTiltedTranslucentSpan_NPO2, but for water */ void R_DrawTiltedTranslucentWaterSpan_NPO2_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 *dsrc; double startz, startu, startv; double izstep, uzstep, vzstep; double endz, endu, endv; UINT32 stepu, stepv; struct libdivide_u32_t x_divider = libdivide_u32_gen(ds_flatwidth); struct libdivide_u32_t y_divider = libdivide_u32_gen(ds_flatheight); iz = ds_szp->z + ds_szp->y*(centery-ds_y) + ds_szp->x*(ds_x1-centerx); CALC_SLOPE_LIGHT uz = ds_sup->z + ds_sup->y*(centery-ds_y) + ds_sup->x*(ds_x1-centerx); vz = ds_svp->z + ds_svp->y*(centery-ds_y) + ds_svp->x*(ds_x1-centerx); dest = ylookup[ds_y] + columnofs[ds_x1]; dsrc = screens[1] + (ds_y+ds_bgofs)*vid.width + 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); v = (INT64)(vz*z); colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; *dest = *(ds_transmap + (colormap[source[((y * ds_flatwidth) + x)]] << 8) + *dsrc++); } dest++; iz += ds_szp->x; uz += ds_sup->x; vz += ds_svp->x; } while (--width >= 0); #else startz = 1.f/iz; startu = uz*startz; startv = vz*startz; izstep = ds_szp->x * SPANSIZE; uzstep = ds_sup->x * SPANSIZE; vzstep = ds_svp->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); v = (INT64)(startv); for (i = SPANSIZE-1; i >= 0; i--) { colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; *dest = *(ds_transmap + (colormap[source[((y * ds_flatwidth) + x)]] << 8) + *dsrc++); } 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); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; *dest = *(ds_transmap + (colormap[source[((y * ds_flatwidth) + x)]] << 8) + *dsrc++); } } else { double left = width; iz += ds_szp->x * left; uz += ds_sup->x * left; vz += ds_svp->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); v = (INT64)(startv); for (; width != 0; width--) { colormap = planezlight[tiltlighting[ds_x1++]] + (ds_colormap - colormaps); // Lactozilla: Non-powers-of-two { fixed_t x = (((fixed_t)u) >> FRACBITS); fixed_t y = (((fixed_t)v) >> FRACBITS); // Carefully align all of my Friends. if (x < 0) x += (libdivide_u32_do((UINT32)(-x-1), &x_divider) + 1) * ds_flatwidth; else x -= libdivide_u32_do((UINT32)x, &x_divider) * ds_flatwidth; if (y < 0) y += (libdivide_u32_do((UINT32)(-y-1), &y_divider) + 1) * ds_flatheight; else y -= libdivide_u32_do((UINT32)y, &y_divider) * ds_flatheight; *dest = *(ds_transmap + (colormap[source[((y * ds_flatwidth) + x)]] << 8) + *dsrc++); } dest++; u += stepu; v += stepv; } } } #endif }