Kart-Public/src/r_plane.c
2016-05-21 23:53:04 -04:00

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// SONIC ROBO BLAST 2
//-----------------------------------------------------------------------------
// Copyright (C) 1993-1996 by id Software, Inc.
// Copyright (C) 1998-2000 by DooM Legacy Team.
// Copyright (C) 1999-2016 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_plane.c
/// \brief Here is a core component: drawing the floors and ceilings,
/// while maintaining a per column clipping list only.
/// Moreover, the sky areas have to be determined.
#include "doomdef.h"
#include "console.h"
#include "g_game.h"
#include "r_data.h"
#include "r_local.h"
#include "r_state.h"
#include "r_splats.h" // faB(21jan):testing
#include "r_sky.h"
#include "v_video.h"
#include "w_wad.h"
#include "z_zone.h"
#include "p_tick.h"
#include "p_setup.h" // levelflats
#include "p_slopes.h"
//
// opening
//
// Quincunx antialiasing of flats!
//#define QUINCUNX
//SoM: 3/23/2000: Use Boom visplane hashing.
#define MAXVISPLANES 512
static visplane_t *visplanes[MAXVISPLANES];
static visplane_t *freetail;
static visplane_t **freehead = &freetail;
visplane_t *floorplane;
visplane_t *ceilingplane;
static visplane_t *currentplane;
planemgr_t ffloor[MAXFFLOORS];
INT32 numffloors;
//SoM: 3/23/2000: Boom visplane hashing routine.
#define visplane_hash(picnum,lightlevel,height) \
((unsigned)((picnum)*3+(lightlevel)+(height)*7) & (MAXVISPLANES-1))
//SoM: 3/23/2000: Use boom opening limit removal
size_t maxopenings;
INT16 *openings, *lastopening; /// \todo free leak
//
// Clip values are the solid pixel bounding the range.
// floorclip starts out SCREENHEIGHT
// ceilingclip starts out -1
//
INT16 floorclip[MAXVIDWIDTH], ceilingclip[MAXVIDWIDTH];
fixed_t frontscale[MAXVIDWIDTH];
//
// spanstart holds the start of a plane span
// initialized to 0 at start
//
static INT32 spanstart[MAXVIDHEIGHT];
//
// texture mapping
//
lighttable_t **planezlight;
static fixed_t planeheight;
//added : 10-02-98: yslopetab is what yslope used to be,
// yslope points somewhere into yslopetab,
// now (viewheight/2) slopes are calculated above and
// below the original viewheight for mouselook
// (this is to calculate yslopes only when really needed)
// (when mouselookin', yslope is moving into yslopetab)
// Check R_SetupFrame, R_SetViewSize for more...
fixed_t yslopetab[MAXVIDHEIGHT*4];
fixed_t *yslope;
fixed_t distscale[MAXVIDWIDTH];
fixed_t basexscale, baseyscale;
fixed_t cachedheight[MAXVIDHEIGHT];
fixed_t cacheddistance[MAXVIDHEIGHT];
fixed_t cachedxstep[MAXVIDHEIGHT];
fixed_t cachedystep[MAXVIDHEIGHT];
static fixed_t xoffs, yoffs;
//
// R_InitPlanes
// Only at game startup.
//
void R_InitPlanes(void)
{
// FIXME: unused
}
// R_PortalStoreClipValues
// Saves clipping values for later. -Red
void R_PortalStoreClipValues(INT32 start, INT32 end, INT16 *ceil, INT16 *floor, fixed_t *scale)
{
INT32 i;
for (i = 0; i < end-start; i++)
{
*ceil = ceilingclip[start+i];
ceil++;
*floor = floorclip[start+i];
floor++;
*scale = frontscale[start+i];
scale++;
}
}
// R_PortalRestoreClipValues
// Inverse of the above. Restores the old value!
void R_PortalRestoreClipValues(INT32 start, INT32 end, INT16 *ceil, INT16 *floor, fixed_t *scale)
{
INT32 i;
for (i = 0; i < end-start; i++)
{
ceilingclip[start+i] = *ceil;
ceil++;
floorclip[start+i] = *floor;
floor++;
frontscale[start+i] = *scale;
scale++;
}
// HACKS FOLLOW
for (i = 0; i < start; i++)
{
floorclip[i] = -1;
ceilingclip[i] = (INT16)viewheight;
}
for (i = end; i < vid.width; i++)
{
floorclip[i] = -1;
ceilingclip[i] = (INT16)viewheight;
}
}
//profile stuff ---------------------------------------------------------
//#define TIMING
#ifdef TIMING
#include "p5prof.h"
INT64 mycount;
INT64 mytotal = 0;
UINT32 nombre = 100000;
#endif
//profile stuff ---------------------------------------------------------
//
// R_MapPlane
//
// Uses global vars:
// planeheight
// ds_source
// basexscale
// baseyscale
// viewx
// viewy
// xoffs
// yoffs
// planeangle
//
// BASIC PRIMITIVE
//
#ifndef NOWATER
static INT32 bgofs;
static INT32 wtofs=0;
static INT32 waterofs;
static boolean itswater;
#endif
#ifdef __mips__
//#define NOWATER
#endif
#ifndef NOWATER
static void R_DrawTranslucentWaterSpan_8(void)
{
UINT32 xposition;
UINT32 yposition;
UINT32 xstep, ystep;
UINT8 *source;
UINT8 *colormap;
UINT8 *dest;
UINT8 *dsrc;
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 + waterofs) << nflatshiftup;
xstep = ds_xstep << nflatshiftup; ystep = ds_ystep << nflatshiftup;
source = ds_source;
colormap = ds_colormap;
dest = ylookup[ds_y] + columnofs[ds_x1];
dsrc = screens[1] + (ds_y+bgofs)*vid.width + 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) + *dsrc++)];
xposition += xstep;
yposition += ystep;
dest[1] = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + *dsrc++)];
xposition += xstep;
yposition += ystep;
dest[2] = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + *dsrc++)];
xposition += xstep;
yposition += ystep;
dest[3] = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + *dsrc++)];
xposition += xstep;
yposition += ystep;
dest[4] = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + *dsrc++)];
xposition += xstep;
yposition += ystep;
dest[5] = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + *dsrc++)];
xposition += xstep;
yposition += ystep;
dest[6] = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + *dsrc++)];
xposition += xstep;
yposition += ystep;
dest[7] = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + *dsrc++)];
xposition += xstep;
yposition += ystep;
dest += 8;
count -= 8;
}
while (count--)
{
*dest++ = colormap[*(ds_transmap + (source[((yposition >> nflatyshift) & nflatmask) | (xposition >> nflatxshift)] << 8) + *dsrc++)];
xposition += xstep;
yposition += ystep;
}
}
#endif
void R_MapPlane(INT32 y, INT32 x1, INT32 x2)
{
angle_t angle;
fixed_t distance, length;
size_t pindex;
#ifdef RANGECHECK
if (x2 < x1 || x1 < 0 || x2 >= viewwidth || y > viewheight)
I_Error("R_MapPlane: %d, %d at %d", x1, x2, y);
#endif
// from r_splats's R_RenderFloorSplat
if (x1 >= vid.width) x1 = vid.width - 1;
if (planeheight != cachedheight[y])
{
cachedheight[y] = planeheight;
distance = cacheddistance[y] = FixedMul(planeheight, yslope[y]);
ds_xstep = cachedxstep[y] = FixedMul(distance, basexscale);
ds_ystep = cachedystep[y] = FixedMul(distance, baseyscale);
}
else
{
distance = cacheddistance[y];
ds_xstep = cachedxstep[y];
ds_ystep = cachedystep[y];
}
length = FixedMul (distance,distscale[x1]);
angle = (currentplane->viewangle + currentplane->plangle + xtoviewangle[x1])>>ANGLETOFINESHIFT;
/// \note Wouldn't it be faster just to add viewx and viewy
// to the plane's x/yoffs anyway??
ds_xfrac = FixedMul(FINECOSINE(angle), length) + xoffs;
ds_yfrac = yoffs - FixedMul(FINESINE(angle), length);
#ifndef NOWATER
if (itswater)
{
const INT32 yay = (wtofs + (distance>>9) ) & 8191;
// ripples da water texture
bgofs = FixedDiv(FINESINE(yay), (1<<12) + (distance>>11))>>FRACBITS;
angle = (angle + 2048) & 8191; //90<39>
ds_xfrac += FixedMul(FINECOSINE(angle), (bgofs<<FRACBITS));
ds_yfrac += FixedMul(FINESINE(angle), (bgofs<<FRACBITS));
if (y+bgofs>=viewheight)
bgofs = viewheight-y-1;
if (y+bgofs<0)
bgofs = -y;
}
#endif
pindex = distance >> LIGHTZSHIFT;
if (pindex >= MAXLIGHTZ)
pindex = MAXLIGHTZ - 1;
#ifdef ESLOPE
if (currentplane->slope)
ds_colormap = colormaps;
else
#endif
ds_colormap = planezlight[pindex];
if (currentplane->extra_colormap)
ds_colormap = currentplane->extra_colormap->colormap + (ds_colormap - colormaps);
ds_y = y;
ds_x1 = x1;
ds_x2 = x2;
// profile drawer
#ifdef TIMING
ProfZeroTimer();
#endif
spanfunc();
#ifdef TIMING
RDMSR(0x10, &mycount);
mytotal += mycount; // 64bit add
if (!(nombre--))
I_Error("spanfunc() CPU Spy reports: 0x%d %d\n", *((INT32 *)&mytotal+1), (INT32)mytotal);
#endif
}
//
// R_ClearPlanes
// At begining of frame.
//
// NOTE: Uses con_clipviewtop, so that when console is on,
// we don't draw the part of the view hidden under the console.
void R_ClearPlanes(void)
{
INT32 i, p;
angle_t angle;
// opening / clipping determination
for (i = 0; i < viewwidth; i++)
{
floorclip[i] = (INT16)viewheight;
ceilingclip[i] = (INT16)con_clipviewtop;
frontscale[i] = INT32_MAX;
for (p = 0; p < MAXFFLOORS; p++)
{
ffloor[p].f_clip[i] = (INT16)viewheight;
ffloor[p].c_clip[i] = (INT16)con_clipviewtop;
}
}
numffloors = 0;
for (i = 0; i < MAXVISPLANES; i++)
for (*freehead = visplanes[i], visplanes[i] = NULL;
freehead && *freehead ;)
{
freehead = &(*freehead)->next;
}
lastopening = openings;
// texture calculation
memset(cachedheight, 0, sizeof (cachedheight));
// left to right mapping
angle = (viewangle-ANGLE_90)>>ANGLETOFINESHIFT;
// scale will be unit scale at SCREENWIDTH/2 distance
basexscale = FixedDiv (FINECOSINE(angle),centerxfrac);
baseyscale = -FixedDiv (FINESINE(angle),centerxfrac);
}
static visplane_t *new_visplane(unsigned hash)
{
visplane_t *check = freetail;
if (!check)
{
check = calloc(2, sizeof (*check));
if (check == NULL) I_Error("%s: Out of memory", "new_visplane"); // FIXME: ugly
}
else
{
freetail = freetail->next;
if (!freetail)
freehead = &freetail;
}
check->next = visplanes[hash];
visplanes[hash] = check;
return check;
}
//
// R_FindPlane: Seek a visplane having the identical values:
// Same height, same flattexture, same lightlevel.
// If not, allocates another of them.
//
visplane_t *R_FindPlane(fixed_t height, INT32 picnum, INT32 lightlevel,
fixed_t xoff, fixed_t yoff, angle_t plangle, extracolormap_t *planecolormap,
ffloor_t *pfloor
#ifdef ESLOPE
, pslope_t *slope
#endif
)
{
visplane_t *check;
unsigned hash;
#ifdef ESLOPE
if (slope); else // Don't mess with this right now if a slope is involved
#endif
if (plangle != 0)
{
// Add the view offset, rotated by the plane angle.
angle_t angle = plangle>>ANGLETOFINESHIFT;
xoff += FixedMul(viewx,FINECOSINE(angle))-FixedMul(viewy,FINESINE(angle));
yoff += -FixedMul(viewx,FINESINE(angle))-FixedMul(viewy,FINECOSINE(angle));
}
else
{
xoff += viewx;
yoff -= viewy;
}
// This appears to fix the Nimbus Ruins sky bug.
if (picnum == skyflatnum && pfloor)
{
height = 0; // all skies map together
lightlevel = 0;
}
// New visplane algorithm uses hash table
hash = visplane_hash(picnum, lightlevel, height);
for (check = visplanes[hash]; check; check = check->next)
{
#ifdef POLYOBJECTS_PLANES
if (check->polyobj && pfloor)
continue;
#endif
if (height == check->height && picnum == check->picnum
&& lightlevel == check->lightlevel
&& xoff == check->xoffs && yoff == check->yoffs
&& planecolormap == check->extra_colormap
&& !pfloor && !check->ffloor
&& check->viewx == viewx && check->viewy == viewy && check->viewz == viewz
&& check->viewangle == viewangle
#ifdef ESLOPE
&& check->slope == slope
#endif
)
{
return check;
}
}
check = new_visplane(hash);
check->height = height;
check->picnum = picnum;
check->lightlevel = lightlevel;
check->minx = vid.width;
check->maxx = -1;
check->xoffs = xoff;
check->yoffs = yoff;
check->extra_colormap = planecolormap;
check->ffloor = pfloor;
check->viewx = viewx;
check->viewy = viewy;
check->viewz = viewz;
check->viewangle = viewangle;
check->plangle = plangle;
#ifdef POLYOBJECTS_PLANES
check->polyobj = NULL;
#endif
#ifdef ESLOPE
check->slope = slope;
#endif
memset(check->top, 0xff, sizeof (check->top));
memset(check->bottom, 0x00, sizeof (check->bottom));
return check;
}
//
// R_CheckPlane: return same visplane or alloc a new one if needed
//
visplane_t *R_CheckPlane(visplane_t *pl, INT32 start, INT32 stop)
{
INT32 intrl, intrh;
INT32 unionl, unionh;
INT32 x;
if (start < pl->minx)
{
intrl = pl->minx;
unionl = start;
}
else
{
unionl = pl->minx;
intrl = start;
}
if (stop > pl->maxx)
{
intrh = pl->maxx;
unionh = stop;
}
else
{
unionh = pl->maxx;
intrh = stop;
}
// 0xff is not equal to -1 with shorts...
for (x = intrl; x <= intrh; x++)
if (pl->top[x] != 0xffff || pl->bottom[x] != 0x0000)
break;
if (x > intrh) /* Can use existing plane; extend range */
{
pl->minx = unionl;
pl->maxx = unionh;
}
else /* Cannot use existing plane; create a new one */
{
unsigned hash =
visplane_hash(pl->picnum, pl->lightlevel, pl->height);
visplane_t *new_pl = new_visplane(hash);
new_pl->height = pl->height;
new_pl->picnum = pl->picnum;
new_pl->lightlevel = pl->lightlevel;
new_pl->xoffs = pl->xoffs;
new_pl->yoffs = pl->yoffs;
new_pl->extra_colormap = pl->extra_colormap;
new_pl->ffloor = pl->ffloor;
new_pl->viewx = pl->viewx;
new_pl->viewy = pl->viewy;
new_pl->viewz = pl->viewz;
new_pl->viewangle = pl->viewangle;
new_pl->plangle = pl->plangle;
#ifdef POLYOBJECTS_PLANES
new_pl->polyobj = pl->polyobj;
#endif
#ifdef ESLOPE
new_pl->slope = pl->slope;
#endif
pl = new_pl;
pl->minx = start;
pl->maxx = stop;
memset(pl->top, 0xff, sizeof pl->top);
memset(pl->bottom, 0x00, sizeof pl->bottom);
}
return pl;
}
//
// R_ExpandPlane
//
// This function basically expands the visplane or I_Errors.
// The reason for this is that when creating 3D floor planes, there is no
// need to create new ones with R_CheckPlane, because 3D floor planes
// are created by subsector and there is no way a subsector can graphically
// overlap.
void R_ExpandPlane(visplane_t *pl, INT32 start, INT32 stop)
{
INT32 unionl, unionh;
// INT32 x;
#ifdef POLYOBJECTS_PLANES
// Don't expand polyobject planes here - we do that on our own.
if (pl->polyobj)
return;
#endif
if (start < pl->minx)
{
unionl = start;
}
else
{
unionl = pl->minx;
}
if (stop > pl->maxx)
{
unionh = stop;
}
else
{
unionh = pl->maxx;
}
/*
for (x = start; x <= stop; x++)
if (pl->top[x] != 0xffff || pl->bottom[x] != 0x0000)
break;
if (x <= stop)
I_Error("R_ExpandPlane: planes in same subsector overlap?!\nminx: %d, maxx: %d, start: %d, stop: %d\n", pl->minx, pl->maxx, start, stop);
*/
pl->minx = unionl, pl->maxx = unionh;
}
//
// R_MakeSpans
//
void R_MakeSpans(INT32 x, INT32 t1, INT32 b1, INT32 t2, INT32 b2)
{
// Alam: from r_splats's R_RenderFloorSplat
if (t1 >= vid.height) t1 = vid.height-1;
if (b1 >= vid.height) b1 = vid.height-1;
if (t2 >= vid.height) t2 = vid.height-1;
if (b2 >= vid.height) b2 = vid.height-1;
if (x-1 >= vid.width) x = vid.width;
while (t1 < t2 && t1 <= b1)
{
R_MapPlane(t1, spanstart[t1], x - 1);
t1++;
}
while (b1 > b2 && b1 >= t1)
{
R_MapPlane(b1, spanstart[b1], x - 1);
b1--;
}
while (t2 < t1 && t2 <= b2)
spanstart[t2++] = x;
while (b2 > b1 && b2 >= t2)
spanstart[b2--] = x;
}
void R_DrawPlanes(void)
{
visplane_t *pl;
INT32 x;
INT32 angle;
INT32 i;
spanfunc = basespanfunc;
wallcolfunc = walldrawerfunc;
for (i = 0; i < MAXVISPLANES; i++, pl++)
{
for (pl = visplanes[i]; pl; pl = pl->next)
{
// sky flat
if (pl->picnum == skyflatnum)
{
if (!viewsky)
{
skyVisible = true;
continue;
}
// use correct aspect ratio scale
dc_iscale = skyscale;
// Sky is always drawn full bright,
// i.e. colormaps[0] is used.
// Because of this hack, sky is not affected
// by INVUL inverse mapping.
dc_colormap = colormaps;
dc_texturemid = skytexturemid;
dc_texheight = textureheight[skytexture]
>>FRACBITS;
for (x = pl->minx; x <= pl->maxx; x++)
{
dc_yl = pl->top[x];
dc_yh = pl->bottom[x];
if (dc_yl <= dc_yh)
{
angle = (pl->viewangle + xtoviewangle[x])>>ANGLETOSKYSHIFT;
dc_x = x;
dc_source =
R_GetColumn(skytexture,
angle);
wallcolfunc();
}
}
continue;
}
if (pl->ffloor != NULL)
continue;
R_DrawSinglePlane(pl);
}
}
#ifndef NOWATER
waterofs = (leveltime & 1)*16384;
wtofs = leveltime * 140;
#endif
}
void R_DrawSinglePlane(visplane_t *pl)
{
INT32 light = 0;
INT32 x;
INT32 stop, angle;
size_t size;
ffloor_t *rover;
if (!(pl->minx <= pl->maxx))
return;
#ifndef NOWATER
itswater = false;
#endif
spanfunc = basespanfunc;
#ifdef POLYOBJECTS_PLANES
if (pl->polyobj && pl->polyobj->translucency != 0) {
spanfunc = R_DrawTranslucentSpan_8;
// Hacked up support for alpha value in software mode Tails 09-24-2002 (sidenote: ported to polys 10-15-2014, there was no time travel involved -Red)
if (pl->polyobj->translucency >= 10)
return; // Don't even draw it
else if (pl->polyobj->translucency > 0)
ds_transmap = transtables + ((pl->polyobj->translucency-1)<<FF_TRANSSHIFT);
else // Opaque, but allow transparent flat pixels
spanfunc = splatfunc;
if (pl->extra_colormap && pl->extra_colormap->fog)
light = (pl->lightlevel >> LIGHTSEGSHIFT);
else
light = LIGHTLEVELS-1;
} else
#endif
if (pl->ffloor)
{
// Don't draw planes that shouldn't be drawn.
for (rover = pl->ffloor->target->ffloors; rover; rover = rover->next)
{
if ((pl->ffloor->flags & FF_CUTEXTRA) && (rover->flags & FF_EXTRA))
{
if (pl->ffloor->flags & FF_EXTRA)
{
// The plane is from an extra 3D floor... Check the flags so
// there are no undesired cuts.
if (((pl->ffloor->flags & (FF_FOG|FF_SWIMMABLE)) == (rover->flags & (FF_FOG|FF_SWIMMABLE)))
&& pl->height < *rover->topheight
&& pl->height > *rover->bottomheight)
return;
}
}
}
if (pl->ffloor->flags & FF_TRANSLUCENT)
{
spanfunc = R_DrawTranslucentSpan_8;
// Hacked up support for alpha value in software mode Tails 09-24-2002
if (pl->ffloor->alpha < 12)
return; // Don't even draw it
else if (pl->ffloor->alpha < 38)
ds_transmap = transtables + ((tr_trans90-1)<<FF_TRANSSHIFT);
else if (pl->ffloor->alpha < 64)
ds_transmap = transtables + ((tr_trans80-1)<<FF_TRANSSHIFT);
else if (pl->ffloor->alpha < 89)
ds_transmap = transtables + ((tr_trans70-1)<<FF_TRANSSHIFT);
else if (pl->ffloor->alpha < 115)
ds_transmap = transtables + ((tr_trans60-1)<<FF_TRANSSHIFT);
else if (pl->ffloor->alpha < 140)
ds_transmap = transtables + ((tr_trans50-1)<<FF_TRANSSHIFT);
else if (pl->ffloor->alpha < 166)
ds_transmap = transtables + ((tr_trans40-1)<<FF_TRANSSHIFT);
else if (pl->ffloor->alpha < 192)
ds_transmap = transtables + ((tr_trans30-1)<<FF_TRANSSHIFT);
else if (pl->ffloor->alpha < 217)
ds_transmap = transtables + ((tr_trans20-1)<<FF_TRANSSHIFT);
else if (pl->ffloor->alpha < 243)
ds_transmap = transtables + ((tr_trans10-1)<<FF_TRANSSHIFT);
else // Opaque, but allow transparent flat pixels
spanfunc = splatfunc;
if (pl->extra_colormap && pl->extra_colormap->fog)
light = (pl->lightlevel >> LIGHTSEGSHIFT);
else
light = LIGHTLEVELS-1;
}
else if (pl->ffloor->flags & FF_FOG)
{
spanfunc = R_DrawFogSpan_8;
light = (pl->lightlevel >> LIGHTSEGSHIFT);
}
else light = (pl->lightlevel >> LIGHTSEGSHIFT);
#ifndef NOWATER
if (pl->ffloor->flags & FF_RIPPLE
#ifdef ESLOPE
&& !pl->slope
#endif
)
{
INT32 top, bottom;
itswater = true;
if (spanfunc == R_DrawTranslucentSpan_8)
{
spanfunc = R_DrawTranslucentWaterSpan_8;
// Copy the current scene, ugh
top = pl->high-8;
bottom = pl->low+8;
if (top < 0)
top = 0;
if (bottom > vid.height)
bottom = vid.height;
// Only copy the part of the screen we need
VID_BlitLinearScreen((splitscreen && viewplayer == &players[secondarydisplayplayer]) ? screens[0] + (top+(vid.height>>1))*vid.width : screens[0]+((top)*vid.width), screens[1]+((top)*vid.width),
vid.width, bottom-top,
vid.width, vid.width);
}
}
#endif
}
else light = (pl->lightlevel >> LIGHTSEGSHIFT);
#ifdef ESLOPE
if (!pl->slope) // Don't mess with angle on slopes! We'll handle this ourselves later
#endif
if (viewangle != pl->viewangle+pl->plangle)
{
memset(cachedheight, 0, sizeof (cachedheight));
angle = (pl->viewangle+pl->plangle-ANGLE_90)>>ANGLETOFINESHIFT;
basexscale = FixedDiv(FINECOSINE(angle),centerxfrac);
baseyscale = -FixedDiv(FINESINE(angle),centerxfrac);
viewangle = pl->viewangle+pl->plangle;
}
currentplane = pl;
ds_source = (UINT8 *)
W_CacheLumpNum(levelflats[pl->picnum].lumpnum,
PU_STATIC); // Stay here until Z_ChangeTag
size = W_LumpLength(levelflats[pl->picnum].lumpnum);
switch (size)
{
case 4194304: // 2048x2048 lump
nflatmask = 0x3FF800;
nflatxshift = 21;
nflatyshift = 10;
nflatshiftup = 5;
break;
case 1048576: // 1024x1024 lump
nflatmask = 0xFFC00;
nflatxshift = 22;
nflatyshift = 12;
nflatshiftup = 6;
break;
case 262144:// 512x512 lump'
nflatmask = 0x3FE00;
nflatxshift = 23;
nflatyshift = 14;
nflatshiftup = 7;
break;
case 65536: // 256x256 lump
nflatmask = 0xFF00;
nflatxshift = 24;
nflatyshift = 16;
nflatshiftup = 8;
break;
case 16384: // 128x128 lump
nflatmask = 0x3F80;
nflatxshift = 25;
nflatyshift = 18;
nflatshiftup = 9;
break;
case 1024: // 32x32 lump
nflatmask = 0x3E0;
nflatxshift = 27;
nflatyshift = 22;
nflatshiftup = 11;
break;
default: // 64x64 lump
nflatmask = 0xFC0;
nflatxshift = 26;
nflatyshift = 20;
nflatshiftup = 10;
break;
}
xoffs = pl->xoffs;
yoffs = pl->yoffs;
planeheight = abs(pl->height - pl->viewz);
if (light >= LIGHTLEVELS)
light = LIGHTLEVELS-1;
if (light < 0)
light = 0;
#ifdef ESLOPE
if (pl->slope) {
// Potentially override other stuff for now cus we're mean. :< But draw a slope plane!
// I copied ZDoom's code and adapted it to SRB2... -Red
floatv3_t p, m, n;
float ang;
float vx, vy, vz;
float fudge;
// compiler complains when P_GetZAt is used in FLOAT_TO_FIXED directly
// use this as a temp var to store P_GetZAt's return value each time
fixed_t temp;
xoffs &= ((1 << (32-nflatshiftup))-1);
yoffs &= ((1 << (32-nflatshiftup))-1);
xoffs -= (pl->slope->o.x + (1 << (31-nflatshiftup))) & ~((1 << (32-nflatshiftup))-1);
yoffs += (pl->slope->o.y + (1 << (31-nflatshiftup))) & ~((1 << (32-nflatshiftup))-1);
// Okay, look, don't ask me why this works, but without this setup there's a disgusting-looking misalignment with the textures. -Red
fudge = ((1<<nflatshiftup)+1.0f)/(1<<nflatshiftup);
xoffs = (fixed_t)(xoffs*fudge);
yoffs = (fixed_t)(yoffs/fudge);
vx = FIXED_TO_FLOAT(pl->viewx+xoffs);
vy = FIXED_TO_FLOAT(pl->viewy-yoffs);
vz = FIXED_TO_FLOAT(pl->viewz);
temp = P_GetZAt(pl->slope, pl->viewx, pl->viewy);
zeroheight = FIXED_TO_FLOAT(temp);
#define ANG2RAD(angle) ((float)((angle)*M_PI)/ANGLE_180)
// p is the texture origin in view space
// Don't add in the offsets at this stage, because doing so can result in
// errors if the flat is rotated.
ang = ANG2RAD(ANGLE_270 - pl->viewangle);
p.x = vx * cos(ang) - vy * sin(ang);
p.z = vx * sin(ang) + vy * cos(ang);
temp = P_GetZAt(pl->slope, -xoffs, yoffs);
p.y = FIXED_TO_FLOAT(temp) - vz;
// m is the v direction vector in view space
ang = ANG2RAD(ANGLE_180 - (pl->viewangle + pl->plangle));
m.x = cos(ang);
m.z = sin(ang);
// n is the u direction vector in view space
n.x = sin(ang);
n.z = -cos(ang);
ang = ANG2RAD(pl->plangle);
temp = P_GetZAt(pl->slope, pl->viewx + FLOAT_TO_FIXED(sin(ang)), pl->viewy + FLOAT_TO_FIXED(cos(ang)));
m.y = FIXED_TO_FLOAT(temp) - zeroheight;
temp = P_GetZAt(pl->slope, pl->viewx + FLOAT_TO_FIXED(cos(ang)), pl->viewy - FLOAT_TO_FIXED(sin(ang)));
n.y = FIXED_TO_FLOAT(temp) - zeroheight;
m.x /= fudge;
m.y /= fudge;
m.z /= fudge;
n.x *= fudge;
n.y *= fudge;
n.z *= fudge;
// Eh. I tried making this stuff fixed-point and it exploded on me. Here's a macro for the only floating-point vector function I recall using.
#define CROSS(d, v1, v2) \
d.x = (v1.y * v2.z) - (v1.z * v2.y);\
d.y = (v1.z * v2.x) - (v1.x * v2.z);\
d.z = (v1.x * v2.y) - (v1.y * v2.x)
CROSS(ds_su, p, m);
CROSS(ds_sv, p, n);
CROSS(ds_sz, m, n);
#undef CROSS
ds_su.z *= focallengthf;
ds_sv.z *= focallengthf;
ds_sz.z *= focallengthf;
// Premultiply the texture vectors with the scale factors
#define SFMULT 65536.f*(1<<nflatshiftup)
ds_su.x *= SFMULT;
ds_su.y *= SFMULT;
ds_su.z *= SFMULT;
ds_sv.x *= SFMULT;
ds_sv.y *= SFMULT;
ds_sv.z *= SFMULT;
#undef SFMULT
if (spanfunc == R_DrawTranslucentSpan_8)
spanfunc = R_DrawTiltedTranslucentSpan_8;
else if (spanfunc == splatfunc)
spanfunc = R_DrawTiltedSplat_8;
else
spanfunc = R_DrawTiltedSpan_8;
planezlight = scalelight[light];
} else
#endif // ESLOPE
planezlight = zlight[light];
// set the maximum value for unsigned
pl->top[pl->maxx+1] = 0xffff;
pl->top[pl->minx-1] = 0xffff;
pl->bottom[pl->maxx+1] = 0x0000;
pl->bottom[pl->minx-1] = 0x0000;
stop = pl->maxx + 1;
if (viewx != pl->viewx || viewy != pl->viewy)
{
viewx = pl->viewx;
viewy = pl->viewy;
}
if (viewz != pl->viewz)
viewz = pl->viewz;
for (x = pl->minx; x <= stop; x++)
{
R_MakeSpans(x, pl->top[x-1], pl->bottom[x-1],
pl->top[x], pl->bottom[x]);
}
/*
QUINCUNX anti-aliasing technique (sort of)
Normally, Quincunx antialiasing staggers pixels
in a 5-die pattern like so:
o o
o
o o
To simulate this, we offset the plane by
FRACUNIT/4 in each direction, and draw
at 50% translucency. The result is
a 'smoothing' of the texture while
using the palette colors.
*/
#ifdef QUINCUNX
if (spanfunc == R_DrawSpan_8)
{
INT32 i;
ds_transmap = transtables + ((tr_trans50-1)<<FF_TRANSSHIFT);
spanfunc = R_DrawTranslucentSpan_8;
for (i=0; i<4; i++)
{
xoffs = pl->xoffs;
yoffs = pl->yoffs;
switch(i)
{
case 0:
xoffs -= FRACUNIT/4;
yoffs -= FRACUNIT/4;
break;
case 1:
xoffs -= FRACUNIT/4;
yoffs += FRACUNIT/4;
break;
case 2:
xoffs += FRACUNIT/4;
yoffs -= FRACUNIT/4;
break;
case 3:
xoffs += FRACUNIT/4;
yoffs += FRACUNIT/4;
break;
}
planeheight = abs(pl->height - pl->viewz);
if (light >= LIGHTLEVELS)
light = LIGHTLEVELS-1;
if (light < 0)
light = 0;
planezlight = zlight[light];
// set the maximum value for unsigned
pl->top[pl->maxx+1] = 0xffff;
pl->top[pl->minx-1] = 0xffff;
pl->bottom[pl->maxx+1] = 0x0000;
pl->bottom[pl->minx-1] = 0x0000;
stop = pl->maxx + 1;
for (x = pl->minx; x <= stop; x++)
R_MakeSpans(x, pl->top[x-1], pl->bottom[x-1],
pl->top[x], pl->bottom[x]);
}
}
#endif
Z_ChangeTag(ds_source, PU_CACHE);
}
void R_PlaneBounds(visplane_t *plane)
{
INT32 i;
INT32 hi, low;
hi = plane->top[plane->minx];
low = plane->bottom[plane->minx];
for (i = plane->minx + 1; i <= plane->maxx; i++)
{
if (plane->top[i] < hi)
hi = plane->top[i];
if (plane->bottom[i] > low)
low = plane->bottom[i];
}
plane->high = hi;
plane->low = low;
}