gzdoom-gles/src/r_plane.cpp

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// Emacs style mode select -*- C++ -*-
//-----------------------------------------------------------------------------
//
// $Id:$
//
// Copyright (C) 1993-1996 by id Software, Inc.
//
// This source is available for distribution and/or modification
// only under the terms of the DOOM Source Code License as
// published by id Software. All rights reserved.
//
// The source is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// FITNESS FOR A PARTICULAR PURPOSE. See the DOOM Source Code License
// for more details.
//
// $Log:$
//
// DESCRIPTION:
// 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.
//
// MAXVISPLANES is no longer a limit on the number of visplanes,
// but a limit on the number of hash slots; larger numbers mean
// better performance usually but after a point they are wasted,
// and memory and time overheads creep in.
//
// Lee Killough
//
// [RH] Further modified to significantly increase accuracy and add slopes.
//
//-----------------------------------------------------------------------------
#include <stdlib.h>
#include <float.h>
#include "templates.h"
#include "i_system.h"
#include "w_wad.h"
#include "doomdef.h"
#include "doomstat.h"
#include "r_local.h"
#include "r_sky.h"
#include "stats.h"
#include "m_alloc.h"
#include "v_video.h"
#include "vectors.h"
#include "a_sharedglobal.h"
EXTERN_CVAR (Int, tx)
EXTERN_CVAR (Int, ty)
static void R_DrawSkyStriped (visplane_t *pl);
EXTERN_CVAR (Bool, r_particles);
planefunction_t floorfunc;
planefunction_t ceilingfunc;
// Here comes the obnoxious "visplane".
#define MAXVISPLANES 128 /* must be a power of 2 */
// Avoid infinite recursion with stacked sectors by limiting them.
#define MAX_SKYBOX_PLANES 100
// [RH] Allocate one extra for sky box planes.
static visplane_t *visplanes[MAXVISPLANES+1]; // killough
static visplane_t *freetail; // killough
static visplane_t **freehead = &freetail; // killough
- Yay! We now seem to be free of memory leaks! The next step will be to merge a lot of these static destructor-only structs into regular functions added to the exit chain with atterm so that they can be called in a deterministic order and not whatever order the linker decides to put them in. (Interestingly, the amount of memory used when repeatedly executing the same map command at the console varies up and down, but it now stays relatively stable rather than increasing unbounded.) - Fixed: The list of resolutions in the video modes menu was not freed at exit. - Fixed: mus_playing.name was not freed at exit. - Fixed: SN_StopAllSequences() should be called at the start of P_FreeLevelData(), not just before the call to P_SetupLevel() in G_DoLoadLevel(), so it can run even at exit. And C_FullConsole() can call P_FreeLevelData() to free more memory too. - Fixed: StatusBar was not freed at exit. - Fixed: spritesorter was not freed at exit. - Fixed: Bad things happened if FString's data pool was destroyed before all C_RemoveTabCommand() calls were made. - Added an overload for FArchive << FString. - Fixed: The players' log text was not freed at exit. - Fixed: Bot information was not freed at exit. - Fixed: doomcom was not freed at exit. But since it's always created, there's no reason why it needs to be allocated from the heap. My guess is that in the DOS days, the external packet driver was responsible for allocating doomcom and passed its location with the -net parameter. - Fixed: FBlockNodes were not freed at exit. - Fixed: Openings were not freed at exit. - Fixed: Drawsegs were not freed at exit. - Fixed: Vissprites were not freed at exit. - Fixed: Console command history was not freed at exit. - Fixed: Visplanes were not freed at exit. - Fixed: Call P_FreeLevelData() at exit. - Fixed: Channel, SoundCurve, and PlayList in s_sound.cpp were not freed at exit. - Fixed: Sound sequences were not freed at exit. - Fixed: DSeqNode::Serialize() did not resize the m_SequenceChoices array when loading. SVN r106 (trunk)
2006-05-11 04:00:58 +00:00
static struct VisPlaneFree
{
~VisPlaneFree()
{
R_ClearPlanes(false);
for (visplane_t *pl = freetail; pl != NULL; )
{
visplane_t *next = pl->next;
free (pl);
pl = next;
}
}
} VisPlaneFree_er;
visplane_t *floorplane;
visplane_t *ceilingplane;
// killough -- hash function for visplanes
// Empirically verified to be fairly uniform:
#define visplane_hash(picnum,lightlevel,height) \
((unsigned)((picnum)*3+(lightlevel)+((height).d)*7) & (MAXVISPLANES-1))
// These are copies of the main parameters used when drawing stacked sectors.
// When you change the main parameters, you should copy them here too *unless*
// you are changing them to draw a stacked sector. Otherwise, stacked sectors
// won't draw in skyboxes properly.
int stacked_extralight;
float stacked_visibility;
fixed_t stacked_viewx, stacked_viewy, stacked_viewz;
angle_t stacked_angle;
//
// opening
//
size_t maxopenings;
short *openings;
ptrdiff_t lastopening;
- Yay! We now seem to be free of memory leaks! The next step will be to merge a lot of these static destructor-only structs into regular functions added to the exit chain with atterm so that they can be called in a deterministic order and not whatever order the linker decides to put them in. (Interestingly, the amount of memory used when repeatedly executing the same map command at the console varies up and down, but it now stays relatively stable rather than increasing unbounded.) - Fixed: The list of resolutions in the video modes menu was not freed at exit. - Fixed: mus_playing.name was not freed at exit. - Fixed: SN_StopAllSequences() should be called at the start of P_FreeLevelData(), not just before the call to P_SetupLevel() in G_DoLoadLevel(), so it can run even at exit. And C_FullConsole() can call P_FreeLevelData() to free more memory too. - Fixed: StatusBar was not freed at exit. - Fixed: spritesorter was not freed at exit. - Fixed: Bad things happened if FString's data pool was destroyed before all C_RemoveTabCommand() calls were made. - Added an overload for FArchive << FString. - Fixed: The players' log text was not freed at exit. - Fixed: Bot information was not freed at exit. - Fixed: doomcom was not freed at exit. But since it's always created, there's no reason why it needs to be allocated from the heap. My guess is that in the DOS days, the external packet driver was responsible for allocating doomcom and passed its location with the -net parameter. - Fixed: FBlockNodes were not freed at exit. - Fixed: Openings were not freed at exit. - Fixed: Drawsegs were not freed at exit. - Fixed: Vissprites were not freed at exit. - Fixed: Console command history was not freed at exit. - Fixed: Visplanes were not freed at exit. - Fixed: Call P_FreeLevelData() at exit. - Fixed: Channel, SoundCurve, and PlayList in s_sound.cpp were not freed at exit. - Fixed: Sound sequences were not freed at exit. - Fixed: DSeqNode::Serialize() did not resize the m_SequenceChoices array when loading. SVN r106 (trunk)
2006-05-11 04:00:58 +00:00
static struct OpeningsFree
{
~OpeningsFree()
{
if (openings != NULL)
{
free (openings);
openings = NULL;
}
}
} FreeOpenings;
//
// Clip values are the solid pixel bounding the range.
// floorclip starts out SCREENHEIGHT and is just outside the range
// ceilingclip starts out 0 and is just inside the range
//
short floorclip[MAXWIDTH];
short ceilingclip[MAXWIDTH];
//
// texture mapping
//
static fixed_t planeheight;
extern "C" {
//
// spanend holds the end of a plane span in each screen row
//
short spanend[MAXHEIGHT];
byte *tiltlighting[MAXWIDTH];
int planeshade;
vec3_t plane_sz, plane_su, plane_sv;
float planelightfloat;
bool plane_shade;
fixed_t pviewx, pviewy;
void R_DrawTiltedPlane_ASM (int y, int x1);
}
fixed_t yslope[MAXHEIGHT];
static fixed_t xscale, yscale;
static DWORD xstepscale, ystepscale;
static DWORD basexfrac, baseyfrac;
#ifdef USEASM
extern "C" void R_SetSpanSource_ASM (const byte *flat);
extern "C" void STACK_ARGS R_SetSpanSize_ASM (int xbits, int ybits);
extern "C" void R_SetSpanColormap_ASM (byte *colormap);
extern "C" void R_SetTiltedSpanSource_ASM (const byte *flat);
extern "C" byte *ds_curcolormap, *ds_cursource, *ds_curtiltedsource;
#endif
void R_DrawSinglePlane (visplane_t *, fixed_t alpha, bool masked);
//==========================================================================
//
// R_InitPlanes
//
// Called at game startup.
//
//==========================================================================
void R_InitPlanes ()
{
}
//==========================================================================
//
// R_MapPlane
//
// Globals used: planeheight, ds_source, basexscale, baseyscale,
// pviewx, pviewy, xoffs, yoffs, basecolormap, xscale, yscale.
//
//==========================================================================
void R_MapPlane (int y, int x1)
{
int x2 = spanend[y];
fixed_t distance;
#ifdef RANGECHECK
if (x2 < x1 || x1<0 || x2>=viewwidth || (unsigned)y>=(unsigned)viewheight)
{
I_FatalError ("R_MapPlane: %i, %i at %i", x1, x2, y);
}
#endif
// [RH] Notice that I dumped the caching scheme used by Doom.
// It did not offer any appreciable speedup.
distance = FixedMul (planeheight, yslope[y]);
ds_xstep = FixedMul (distance, xstepscale);
ds_ystep = FixedMul (distance, ystepscale);
ds_xfrac = FixedMul (distance, basexfrac) + pviewx;
ds_yfrac = FixedMul (distance, baseyfrac) + pviewy;
if (plane_shade)
{
// Determine lighting based on the span's distance from the viewer.
ds_colormap = basecolormap + (GETPALOOKUP (
FixedMul (GlobVis, abs (centeryfrac - (y << FRACBITS))), planeshade) << COLORMAPSHIFT);
}
#ifdef USEASM
if (ds_colormap != ds_curcolormap)
R_SetSpanColormap_ASM (ds_colormap);
#endif
ds_y = y;
ds_x1 = x1;
ds_x2 = x2;
spanfunc ();
}
//==========================================================================
//
// R_CalcTiltedLighting
//
// Calculates the lighting for one row of a tilted plane. If the definition
// of GETPALOOKUP changes, this needs to change, too.
//
//==========================================================================
extern "C" {
void STACK_ARGS R_CalcTiltedLighting (fixed_t lval, fixed_t lend, int width)
{
fixed_t lstep;
byte *lightfiller;
int i = 0;
lval = planeshade - lval;
lend = planeshade - lend;
if (width == 0 || lval == lend)
{ // Constant lighting
lightfiller = basecolormap + (GETPALOOKUP (-lval, 0) << COLORMAPSHIFT);
}
else if ((lstep = (lend - lval) / width) < 0)
{ // Going from dark to light
if (lval < FRACUNIT)
{ // All bright
lightfiller = basecolormap;
}
else
{
if (lval >= NUMCOLORMAPS*FRACUNIT)
{ // Starts beyond the dark end
byte *clight = basecolormap + ((NUMCOLORMAPS-1) << COLORMAPSHIFT);
while (lval >= NUMCOLORMAPS*FRACUNIT && i <= width)
{
tiltlighting[i++] = clight;
lval += lstep;
}
if (i > width)
return;
}
while (i <= width && lval >= 0)
{
tiltlighting[i++] = basecolormap + ((lval >> FRACBITS) << COLORMAPSHIFT);
lval += lstep;
}
lightfiller = basecolormap;
}
}
else
{ // Going from light to dark
if (lval >= (NUMCOLORMAPS-1)*FRACUNIT)
{ // All dark
lightfiller = basecolormap + ((NUMCOLORMAPS-1) << COLORMAPSHIFT);
}
else
{
while (lval < 0 && i <= width)
{
tiltlighting[i++] = basecolormap;
lval += lstep;
}
if (i > width)
return;
while (i <= width && lval < (NUMCOLORMAPS-1)*FRACUNIT)
{
tiltlighting[i++] = basecolormap + ((lval >> FRACBITS) << COLORMAPSHIFT);
lval += lstep;
}
lightfiller = basecolormap + ((NUMCOLORMAPS-1) << COLORMAPSHIFT);
}
}
for (; i <= width; i++)
{
tiltlighting[i] = lightfiller;
}
}
} // extern "C"
//==========================================================================
//
// R_MapTiltedPlane
//
//==========================================================================
void R_MapTiltedPlane (int y, int x1)
{
int x2 = spanend[y];
int width = x2 - x1;
float iz, uz, vz;
byte *fb;
DWORD u, v;
int i;
iz = plane_sz[2] + plane_sz[1]*(centery-y) + plane_sz[0]*(x1-centerx);
// Lighting is simple. It's just linear interpolation from start to end
if (plane_shade)
{
uz = (iz + plane_sz[0]*width) * planelightfloat;
vz = iz * planelightfloat;
R_CalcTiltedLighting (toint (vz), toint (uz), width);
}
uz = plane_su[2] + plane_su[1]*(centery-y) + plane_su[0]*(x1-centerx);
vz = plane_sv[2] + plane_sv[1]*(centery-y) + plane_sv[0]*(x1-centerx);
fb = ylookup[y] + x1 + dc_destorg;
BYTE vshift = 32 - ds_ybits;
BYTE ushift = vshift - ds_xbits;
int umask = ((1 << ds_xbits) - 1) << ds_ybits;
#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
{
float z = 1.f/iz;
u = toint (uz*z) + pviewx;
v = toint (vz*z) + pviewy;
ds_colormap = tiltlighting[i];
fb[i++] = ds_colormap[ds_source[(v >> vshift) | ((u >> ushift) & umask)]];
iz += plane_sz[0];
uz += plane_su[0];
vz += plane_sv[0];
} while (--width >= 0);
#else
//#define SPANSIZE 32
//#define INVSPAN 0.03125f
//#define SPANSIZE 8
//#define INVSPAN 0.125f
#define SPANSIZE 16
#define INVSPAN 0.0625f
float startz = 1.f/iz;
float startu = uz*startz;
float startv = vz*startz;
float izstep, uzstep, vzstep;
izstep = plane_sz[0] * SPANSIZE;
uzstep = plane_su[0] * SPANSIZE;
vzstep = plane_sv[0] * SPANSIZE;
x1 = 0;
width++;
while (width >= SPANSIZE)
{
iz += izstep;
uz += uzstep;
vz += vzstep;
float endz = 1.f/iz;
float endu = uz*endz;
float endv = vz*endz;
DWORD stepu = toint ((endu - startu) * INVSPAN);
DWORD stepv = toint ((endv - startv) * INVSPAN);
u = toint (startu) + pviewx;
v = toint (startv) + pviewy;
for (i = SPANSIZE-1; i >= 0; i--)
{
fb[x1] = *(tiltlighting[x1] + ds_source[(v >> vshift) | ((u >> ushift) & umask)]);
x1++;
u += stepu;
v += stepv;
}
startu = endu;
startv = endv;
startz = endz;
width -= SPANSIZE;
}
if (width > 0)
{
if (width == 1)
{
u = toint (startu);
v = toint (startv);
fb[x1] = *(tiltlighting[x1] + ds_source[(v >> vshift) | ((u >> ushift) & umask)]);
}
else
{
float left = (float)width;
iz += plane_sz[0] * left;
uz += plane_su[0] * left;
vz += plane_sv[0] * left;
float endz = 1.f/iz;
float endu = uz*endz;
float endv = vz*endz;
left = 1.f/left;
DWORD stepu = toint ((endu - startu) * left);
DWORD stepv = toint ((endv - startv) * left);
u = toint (startu) + pviewx;
v = toint (startv) + pviewy;
for (; width != 0; width--)
{
fb[x1] = *(tiltlighting[x1] + ds_source[(v >> vshift) | ((u >> ushift) & umask)]);
x1++;
u += stepu;
v += stepv;
}
}
}
#endif
}
//==========================================================================
//
// R_MapColoredPlane
//
//==========================================================================
void R_MapColoredPlane (int y, int x1)
{
memset (ylookup[y] + x1 + dc_destorg, ds_color, spanend[y] - x1 + 1);
}
//==========================================================================
//
// R_ClearPlanes
//
// Called at the beginning of each frame.
//
//==========================================================================
extern int ConBottom;
void R_ClearPlanes (bool fullclear)
{
int i;
for (i = 0; i < MAXVISPLANES; i++) // new code -- killough
for (*freehead = visplanes[i], visplanes[i] = NULL; *freehead; )
freehead = &(*freehead)->next;
if (fullclear)
{
// opening / clipping determination
clearbufshort (floorclip, viewwidth, viewheight);
// [RH] clip ceiling to console bottom
clearbufshort (ceilingclip, viewwidth,
ConBottom > viewwindowy && !bRenderingToCanvas
? ((ConBottom - viewwindowy) >> detailyshift) : 0);
lastopening = 0;
}
}
//==========================================================================
//
// new_visplane
//
// New function, by Lee Killough
// [RH] top and bottom buffers get allocated immediately after the visplane.
//
//==========================================================================
static visplane_t *new_visplane (unsigned hash)
{
visplane_t *check = freetail;
if (check == NULL)
{
check = (visplane_t *)M_Calloc (1, sizeof(*check) + sizeof(*check->top)*(MAXWIDTH*2));
check->bottom = &check->top[MAXWIDTH+2];
}
else if (NULL == (freetail = freetail->next))
{
freehead = &freetail;
}
check->next = visplanes[hash];
visplanes[hash] = check;
return check;
}
//==========================================================================
//
// R_FindPlane
//
// killough 2/28/98: Add offsets
//==========================================================================
visplane_t *R_FindPlane (const secplane_t &height, int picnum, int lightlevel,
fixed_t xoffs, fixed_t yoffs,
fixed_t xscale, fixed_t yscale, angle_t angle,
ASkyViewpoint *skybox)
{
secplane_t plane;
visplane_t *check;
unsigned hash; // killough
bool isskybox;
if (picnum == skyflatnum || picnum & PL_SKYFLAT) // killough 10/98
{ // most skies map together
lightlevel = 0;
xoffs = 0;
yoffs = 0;
xscale = 0;
yscale = 0;
angle = 0;
plane.a = plane.b = plane.d = 0;
// [RH] Map floor skies and ceiling skies to separate visplanes. This isn't
// always necessary, but it is needed if a floor and ceiling sky are in the
// same column but separated by a wall. If they both try to reside in the
// same visplane, then only the floor sky will be drawn.
plane.c = height.c;
plane.ic = height.ic;
isskybox = skybox != NULL && !skybox->bInSkybox &&
(skybox->bAlways || picnum == skyflatnum);
}
else if (skybox != NULL && skybox->bAlways && !skybox->bInSkybox)
{
plane = height;
isskybox = true;
}
else
{
plane = height;
isskybox = false;
}
// New visplane algorithm uses hash table -- killough
hash = isskybox ? MAXVISPLANES : visplane_hash (picnum, lightlevel, height);
for (check = visplanes[hash]; check; check = check->next) // killough
{
if (isskybox)
{
if (skybox == check->skybox && plane == check->height)
{
if (skybox->Mate != NULL)
{ // This skybox is really a stacked sector, so we need to
// check even more.
if (check->extralight == stacked_extralight &&
check->visibility == stacked_visibility &&
check->viewx == stacked_viewx &&
check->viewy == stacked_viewy &&
check->viewz == stacked_viewz &&
check->viewangle == stacked_angle)
{
return check;
}
}
else
{
return check;
}
}
}
else
if (plane == check->height &&
picnum == check->picnum &&
lightlevel == check->lightlevel &&
xoffs == check->xoffs && // killough 2/28/98: Add offset checks
yoffs == check->yoffs &&
basecolormap == check->colormap && // [RH] Add more checks
xscale == check->xscale &&
yscale == check->yscale &&
angle == check->angle
)
{
return check;
}
}
check = new_visplane (hash); // killough
check->height = plane;
check->picnum = picnum;
check->lightlevel = lightlevel;
check->xoffs = xoffs; // killough 2/28/98: Save offsets
check->yoffs = yoffs;
check->xscale = xscale;
check->yscale = yscale;
check->angle = angle;
check->colormap = basecolormap; // [RH] Save colormap
check->skybox = skybox;
check->minx = viewwidth; // Was SCREENWIDTH -- killough 11/98
check->maxx = -1;
check->extralight = stacked_extralight;
check->visibility = stacked_visibility;
check->viewx = stacked_viewx;
check->viewy = stacked_viewy;
check->viewz = stacked_viewz;
check->viewangle = stacked_angle;
clearbufshort (check->top, viewwidth, 0x7fff);
return check;
}
//==========================================================================
//
// R_CheckPlane
//
//==========================================================================
visplane_t *R_CheckPlane (visplane_t *pl, int start, int stop)
{
int intrl, intrh;
int unionl, unionh;
int 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;
}
for (x = intrl; x <= intrh && pl->top[x] == 0x7fff; x++)
;
if (x > intrh)
{
// use the same visplane
pl->minx = unionl;
pl->maxx = unionh;
}
else
{
// make a new visplane
unsigned hash;
if (pl->skybox != NULL && !pl->skybox->bInSkybox && (pl->picnum == skyflatnum || pl->skybox->bAlways) && viewactive)
{
hash = MAXVISPLANES;
}
else
{
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; // killough 2/28/98
new_pl->yoffs = pl->yoffs;
new_pl->xscale = pl->xscale; // [RH] copy these, too
new_pl->yscale = pl->yscale;
new_pl->angle = pl->angle;
new_pl->colormap = pl->colormap;
new_pl->skybox = pl->skybox;
new_pl->extralight = pl->extralight;
new_pl->visibility = pl->visibility;
new_pl->viewx = pl->viewx;
new_pl->viewy = pl->viewy;
new_pl->viewz = pl->viewz;
new_pl->viewangle = pl->viewangle;
pl = new_pl;
pl->minx = start;
pl->maxx = stop;
clearbufshort (pl->top, viewwidth, 0x7fff);
}
return pl;
}
//==========================================================================
//
// R_MakeSpans
//
//
//==========================================================================
inline void R_MakeSpans (int x, int t1, int b1, int t2, int b2, void (*mapfunc)(int y, int x1))
{
}
//==========================================================================
//
// R_DrawSky
//
// Can handle overlapped skies. Note that the front sky is *not* masked in
// in the normal convention for patches, but uses color 0 as a transparent
// color instead.
//
//==========================================================================
static FTexture *frontskytex, *backskytex;
static angle_t skyflip;
static int frontpos, backpos;
static int frontxscale, backxscale;
static int frontyscale, frontiscale;
extern fixed_t swall[MAXWIDTH];
extern fixed_t lwall[MAXWIDTH];
extern fixed_t rw_offset;
extern FTexture *rw_pic;
// Allow for layer skies up to 512 pixels tall. This is overkill,
// since the most anyone can ever see of the sky is 500 pixels.
// We need 4 skybufs because wallscan can draw up to 4 columns at a time.
static BYTE skybuf[4][512];
static DWORD lastskycol[4];
static int skycolplace;
// Get a column of sky when there is only one sky texture.
static const BYTE *R_GetOneSkyColumn (FTexture *fronttex, int x)
{
angle_t column = MulScale3 (frontxscale, viewangle + xtoviewangle[x]);
return fronttex->GetColumn ((((column^skyflip) >> sky1shift) + frontpos) >> FRACBITS, NULL);
}
// Get a column of sky when there are two overlapping sky textures
static const BYTE *R_GetTwoSkyColumns (FTexture *fronttex, int x)
{
DWORD ang = (viewangle + xtoviewangle[x])^skyflip;
DWORD angle1 = (((DWORD)MulScale3 (frontxscale, ang) >> sky1shift) + frontpos) >> FRACBITS;
DWORD angle2 = (((DWORD)MulScale3 (backxscale, ang) >> sky2shift) + backpos) >> FRACBITS;
// Check if this column has already been built. If so, there's
// no reason to waste time building it again.
DWORD skycol = (angle1 << 16) | angle2;
int i;
for (i = 0; i < 4; ++i)
{
if (lastskycol[i] == skycol)
{
return skybuf[i];
}
}
lastskycol[skycolplace] = skycol;
BYTE *composite = skybuf[skycolplace];
skycolplace = (skycolplace + 1) & 3;
// The ordering of the following code has been tuned to allow VC++ to optimize
// it well. In particular, this arrangement lets it keep count in a register
// instead of on the stack.
const BYTE *front = fronttex->GetColumn (angle1, NULL);
const BYTE *back = backskytex->GetColumn (angle2, NULL);
int count = MIN<int> (512, MIN (backskytex->GetHeight(), fronttex->GetHeight()));
i = 0;
do
{
if (front[i])
{
composite[i] = front[i];
}
else
{
composite[i] = back[i];
}
} while (++i, --count);
return composite;
}
static void R_DrawSky (visplane_t *pl)
{
int x;
if (pl->minx > pl->maxx)
return;
dc_iscale = skyiscale >> skystretch;
clearbuf (swall+pl->minx, pl->maxx-pl->minx+1, dc_iscale<<2);
rw_offset = frontpos;
if (MirrorFlags & RF_XFLIP)
{
for (x = pl->minx; x <= pl->maxx; ++x)
{
lwall[x] = (viewwidth - x) << FRACBITS;
}
}
else
{
for (x = pl->minx; x <= pl->maxx; ++x)
{
lwall[x] = x << FRACBITS;
}
}
for (x = 0; x < 4; ++x)
{
lastskycol[x] = 0xffffffff;
}
rw_pic = frontskytex;
rw_offset = 0;
frontxscale = rw_pic->ScaleX ? rw_pic->ScaleX : tx;
if (backskytex != NULL)
{
backxscale = backskytex->ScaleX ? backskytex->ScaleX : tx;
}
frontyscale = rw_pic->ScaleY ? rw_pic->ScaleY : ty;
dc_texturemid = MulScale3 (skytexturemid/*-viewz*/, frontyscale);
if (1 << frontskytex->HeightBits == frontskytex->GetHeight())
{ // The texture tiles nicely
for (x = 0; x < 4; ++x)
{
lastskycol[x] = 0xffffffff;
}
wallscan (pl->minx, pl->maxx, (short *)pl->top, (short *)pl->bottom, swall, lwall,
backskytex == NULL ? R_GetOneSkyColumn : R_GetTwoSkyColumns);
}
else
{ // The texture does not tile nicely
frontyscale = DivScale3 (skyscale << skystretch, frontyscale);
frontiscale = DivScale32 (1, frontyscale);
R_DrawSkyStriped (pl);
}
}
static void R_DrawSkyStriped (visplane_t *pl)
{
fixed_t centerysave = centeryfrac;
short drawheight = (short)MulScale16 (frontskytex->GetHeight(), frontyscale);
fixed_t topfrac;
fixed_t iscale = frontiscale;
short top[MAXWIDTH], bot[MAXWIDTH];
short yl, yh;
int x;
// So that I don't have to worry about fractional precision, chop off the
// fractional part of centeryfrac.
centeryfrac = centery << FRACBITS;
topfrac = (skytexturemid + iscale * (1-centery)) % (frontskytex->GetHeight() << FRACBITS);
if (topfrac < 0) topfrac += frontskytex->GetHeight() << FRACBITS;
yl = 0;
yh = (short)MulScale32 ((frontskytex->GetHeight() << FRACBITS) - topfrac, frontyscale);
dc_texturemid = topfrac - iscale * (1-centery);
while (yl < viewheight)
{
for (x = pl->minx; x <= pl->maxx; ++x)
{
top[x] = MAX (yl, (short)pl->top[x]);
bot[x] = MIN (yh, (short)pl->bottom[x]);
}
for (x = 0; x < 4; ++x)
{
lastskycol[x] = 0xffffffff;
}
wallscan (pl->minx, pl->maxx, top, bot, swall, lwall,
backskytex == NULL ? R_GetOneSkyColumn : R_GetTwoSkyColumns);
yl = yh;
yh += drawheight;
dc_texturemid = iscale * (centery-yl-1);
}
centeryfrac = centerysave;
}
//==========================================================================
//
// R_DrawPlanes
//
// At the end of each frame.
//
//==========================================================================
CVAR (Bool, tilt, false, 0);
//CVAR (Int, pa, 0, 0)
void R_DrawPlanes ()
{
visplane_t *pl;
int i;
int vpcount;
ds_color = 3;
for (i = vpcount = 0; i < MAXVISPLANES; i++)
{
for (pl = visplanes[i]; pl; pl = pl->next)
{
vpcount++;
R_DrawSinglePlane (pl, OPAQUE, false);
}
}
}
//==========================================================================
//
// R_DrawSinglePlane
//
// Draws a single visplane.
//
//==========================================================================
void R_DrawSinglePlane (visplane_t *pl, fixed_t alpha, bool masked)
{
// pl->angle = pa<<ANGLETOFINESHIFT;
if (pl->minx > pl->maxx)
return;
if (r_drawflat)
{ // [RH] no texture mapping
ds_color += 4;
R_MapVisPlane (pl, R_MapColoredPlane);
}
else if (pl->picnum == skyflatnum || pl->picnum & PL_SKYFLAT)
{ // sky flat
R_DrawSkyPlane (pl);
}
else
{ // regular flat
FTexture *tex = TexMan(pl->picnum);
if (tex->UseType == FTexture::TEX_Null)
{
return;
}
if (!masked)
{ // If we're not supposed to see through this plane, draw it opaque.
alpha = OPAQUE;
}
else if (!tex->bMasked)
{ // Don't waste time on a masked texture if it isn't really masked.
masked = false;
}
tex->GetWidth ();
ds_xbits = tex->WidthBits;
ds_ybits = tex->HeightBits;
if ((1 << ds_xbits) > tex->GetWidth())
{
ds_xbits--;
}
if ((1 << ds_ybits) > tex->GetHeight())
{
ds_ybits--;
}
pl->xscale = MulScale3 (pl->xscale, tex->ScaleX ? tex->ScaleX : 8);
pl->yscale = MulScale3 (pl->yscale, tex->ScaleY ? tex->ScaleY : 8);
#ifdef USEASM
R_SetSpanSize_ASM (ds_xbits, ds_ybits);
#endif
ds_source = tex->GetPixels ();
basecolormap = pl->colormap;
planeshade = LIGHT2SHADE(pl->lightlevel);
if (r_drawflat || (pl->height.a == 0 && pl->height.b == 0) && !tilt)
{
R_DrawNormalPlane (pl, alpha, masked);
}
else
{
R_DrawTiltedPlane (pl, alpha, masked);
}
}
NetUpdate ();
}
//==========================================================================
//
// R_DrawSkyBoxes
//
// Draws any recorded sky boxes and then frees them.
//
// The process:
// 1. Move the camera to coincide with the SkyViewpoint.
// 2. Clear out the old planes. (They have already been drawn.)
// 3. Clear a window out of the ClipSegs just large enough for the plane.
// 4. Pretend the existing vissprites and drawsegs aren't there.
// 5. Create a drawseg at 0 distance to clip sprites to the visplane. It
// doesn't need to be associated with a line in the map, since there
// will never be any sprites in front of it.
// 6. Render the BSP, then planes, then masked stuff.
// 7. Restore the previous vissprites and drawsegs.
// 8. Repeat for any other sky boxes.
// 9. Put the camera back where it was to begin with.
//
//==========================================================================
CVAR (Bool, r_skyboxes, true, 0)
static int numskyboxes;
struct VisplaneAndAlpha
{
visplane_t *Visplane;
fixed_t Alpha;
};
void R_DrawSkyBoxes ()
{
static TArray<size_t> interestingStack;
static TArray<ptrdiff_t> drawsegStack;
static TArray<ptrdiff_t> visspriteStack;
static TArray<fixed_t> viewxStack, viewyStack, viewzStack;
static TArray<VisplaneAndAlpha> visplaneStack;
numskyboxes = 0;
if (visplanes[MAXVISPLANES] == NULL)
return;
VisplaneAndAlpha vaAdder;
int savedextralight = extralight;
fixed_t savedx = viewx;
fixed_t savedy = viewy;
fixed_t savedz = viewz;
angle_t savedangle = viewangle;
ptrdiff_t savedvissprite_p = vissprite_p - vissprites;
ptrdiff_t savedds_p = ds_p - drawsegs;
ptrdiff_t savedlastopening = lastopening;
size_t savedinteresting = FirstInterestingDrawseg;
float savedvisibility = R_GetVisibility ();
AActor *savedcamera = camera;
sector_t *savedsector = viewsector;
int i;
visplane_t *pl;
for (pl = visplanes[MAXVISPLANES]; pl != NULL; pl = visplanes[MAXVISPLANES])
{
// Pop the visplane off the list now so that if this skybox adds more
// skyboxes to the list, they will be drawn instead of skipped (because
// new skyboxes go to the beginning of the list instead of the end).
visplanes[MAXVISPLANES] = pl->next;
pl->next = NULL;
if (pl->maxx < pl->minx || !r_skyboxes || numskyboxes == MAX_SKYBOX_PLANES)
{
R_DrawSinglePlane (pl, OPAQUE, false);
*freehead = pl;
freehead = &pl->next;
continue;
}
numskyboxes++;
ASkyViewpoint *sky = pl->skybox;
ASkyViewpoint *mate = sky->Mate;
if (mate == NULL)
{
// Don't let gun flashes brighten the sky box
extralight = 0;
R_SetVisibility (sky->args[0] * 0.25f);
viewx = sky->x;
viewy = sky->y;
viewz = sky->z;
viewangle = savedangle + sky->angle;
R_CopyStackedViewParameters();
}
else
{
extralight = pl->extralight;
R_SetVisibility (pl->visibility);
viewx = pl->viewx - sky->Mate->x + sky->x;
viewy = pl->viewy - sky->Mate->y + sky->y;
viewz = pl->viewz;
viewangle = pl->viewangle;
}
sky->bInSkybox = true;
if (mate != NULL) mate->bInSkybox = true;
camera = sky;
viewsector = sky->Sector;
R_SetViewAngle ();
validcount++; // Make sure we see all sprites
R_ClearPlanes (false);
R_ClearClipSegs (pl->minx, pl->maxx + 1);
WindowLeft = pl->minx;
WindowRight = pl->maxx;
for (i = pl->minx; i <= pl->maxx; i++)
{
if (pl->top[i] == 0x7fff)
{
ceilingclip[i] = viewheight;
floorclip[i] = -1;
}
else
{
ceilingclip[i] = pl->top[i];
floorclip[i] = pl->bottom[i];
}
}
// Create a drawseg to clip sprites to the sky plane
R_CheckDrawSegs ();
R_CheckOpenings ((pl->maxx - pl->minx + 1)*2);
ds_p->siz1 = INT_MAX;
ds_p->siz2 = INT_MAX;
ds_p->sz1 = 0;
ds_p->sz2 = 0;
ds_p->x1 = pl->minx;
ds_p->x2 = pl->maxx;
ds_p->silhouette = SIL_BOTH;
ds_p->sprbottomclip = R_NewOpening (pl->maxx - pl->minx + 1);
ds_p->sprtopclip = R_NewOpening (pl->maxx - pl->minx + 1);
ds_p->maskedtexturecol = ds_p->swall = -1;
ds_p->bFogBoundary = false;
memcpy (openings + ds_p->sprbottomclip, floorclip + pl->minx, (pl->maxx - pl->minx + 1)*sizeof(short));
memcpy (openings + ds_p->sprtopclip, ceilingclip + pl->minx, (pl->maxx - pl->minx + 1)*sizeof(short));
firstvissprite = vissprite_p;
firstdrawseg = ds_p++;
FirstInterestingDrawseg = InterestingDrawsegs.Size();
interestingStack.Push (FirstInterestingDrawseg);
drawsegStack.Push (firstdrawseg - drawsegs);
visspriteStack.Push (firstvissprite - vissprites);
viewxStack.Push (viewx);
viewyStack.Push (viewy);
viewzStack.Push (viewz);
vaAdder.Visplane = pl;
vaAdder.Alpha = sky->PlaneAlpha;
visplaneStack.Push (vaAdder);
R_RenderBSPNode (nodes + numnodes - 1);
R_DrawPlanes ();
sky->bInSkybox = false;
if (mate != NULL) mate->bInSkybox = false;
}
// Draw all the masked textures in a second pass, in the reverse order they
// were added. This must be done separately from the previous step for the
// sake of nested skyboxes.
while (interestingStack.Pop (FirstInterestingDrawseg))
{
ptrdiff_t pd;
drawsegStack.Pop (pd);
firstdrawseg = drawsegs + pd;
visspriteStack.Pop (pd);
firstvissprite = vissprites + pd;
viewxStack.Pop (viewx); // Masked textures and planes need the view
viewyStack.Pop (viewy); // coordinates restored for proper positioning.
viewzStack.Pop (viewz);
R_DrawMasked ();
ds_p = firstdrawseg;
vissprite_p = firstvissprite;
visplaneStack.Pop (vaAdder);
if (vaAdder.Alpha > 0)
{
R_DrawSinglePlane (vaAdder.Visplane, vaAdder.Alpha, true);
}
*freehead = vaAdder.Visplane;
freehead = &vaAdder.Visplane->next;
}
firstvissprite = vissprites;
vissprite_p = vissprites + savedvissprite_p;
firstdrawseg = drawsegs;
ds_p = drawsegs + savedds_p;
InterestingDrawsegs.Resize ((unsigned int)FirstInterestingDrawseg);
FirstInterestingDrawseg = savedinteresting;
lastopening = savedlastopening;
camera = savedcamera;
viewsector = savedsector;
viewx = savedx;
viewy = savedy;
viewz = savedz;
R_SetVisibility (savedvisibility);
extralight = savedextralight;
viewangle = savedangle;
R_SetViewAngle ();
for (*freehead = visplanes[MAXVISPLANES], visplanes[MAXVISPLANES] = NULL; *freehead; )
freehead = &(*freehead)->next;
}
ADD_STAT(skyboxes, out)
{
sprintf (out, "%d skybox planes", numskyboxes);
}
//==========================================================================
//
// R_DrawSkyPlane
//
//==========================================================================
void R_DrawSkyPlane (visplane_t *pl)
{
int sky1tex, sky2tex;
if ((level.flags & LEVEL_SWAPSKIES) && !(level.flags & LEVEL_DOUBLESKY))
{
sky1tex = sky2texture;
}
else
{
sky1tex = sky1texture;
}
sky2tex = sky2texture;
if (pl->picnum == skyflatnum)
{ // use sky1
sky1:
frontskytex = TexMan(sky1tex);
if (level.flags & LEVEL_DOUBLESKY)
backskytex = TexMan(sky2tex);
else
backskytex = NULL;
skyflip = 0;
frontpos = sky1pos;
backpos = sky2pos;
}
else if (pl->picnum == PL_SKYFLAT)
{ // use sky2
frontskytex = TexMan(sky2tex);
backskytex = NULL;
skyflip = 0;
frontpos = sky2pos;
}
else
{ // MBF's linedef-controlled skies
// Sky Linedef
const line_t *l = &lines[(pl->picnum & ~PL_SKYFLAT)-1];
// Sky transferred from first sidedef
const side_t *s = *l->sidenum + sides;
// Texture comes from upper texture of reference sidedef
// [RH] If swapping skies, then use the lower sidedef
if (level.flags & LEVEL_SWAPSKIES && s->bottomtexture != 0)
{
frontskytex = TexMan(s->bottomtexture);
}
else
{
frontskytex = TexMan(s->toptexture);
}
if (frontskytex->UseType == FTexture::TEX_Null)
{ // [RH] The blank texture: Use normal sky instead.
goto sky1;
}
backskytex = NULL;
// Horizontal offset is turned into an angle offset,
// to allow sky rotation as well as careful positioning.
// However, the offset is scaled very small, so that it
// allows a long-period of sky rotation.
frontpos = (-s->textureoffset) >> 6;
// Vertical offset allows careful sky positioning.
dc_texturemid = s->rowoffset - 28*FRACUNIT;
// We sometimes flip the picture horizontally.
//
// Doom always flipped the picture, so we make it optional,
// to make it easier to use the new feature, while to still
// allow old sky textures to be used.
skyflip = l->args[2] ? 0u : ~0u;
}
bool fakefixed = false;
if (fixedcolormap)
{
dc_colormap = fixedcolormap;
}
else if (!fixedcolormap)
{
fakefixed = true;
fixedcolormap = dc_colormap = NormalLight.Maps;
}
R_DrawSky (pl);
if (fakefixed)
fixedcolormap = NULL;
}
//==========================================================================
//
// R_DrawNormalPlane
//
//==========================================================================
void R_DrawNormalPlane (visplane_t *pl, fixed_t alpha, bool masked)
{
#ifdef USEASM
if (ds_source != ds_cursource)
{
R_SetSpanSource_ASM (ds_source);
}
#endif
if (alpha <= 0)
{
return;
}
angle_t planeang = pl->angle;
xscale = pl->xscale << (16 - ds_xbits);
yscale = pl->yscale << (16 - ds_ybits);
if (planeang != 0)
{
fixed_t cosine = finecosine[planeang >> ANGLETOFINESHIFT];
fixed_t sine = finesine[planeang >> ANGLETOFINESHIFT];
pviewx = pl->xoffs + FixedMul (viewx, cosine) - FixedMul (viewy, sine);
pviewy = pl->yoffs - FixedMul (viewx, sine) - FixedMul (viewy, cosine);
}
else
{
pviewx = pl->xoffs + viewx;
pviewy = pl->yoffs - viewy;
}
pviewx = FixedMul (xscale, pviewx);
pviewy = FixedMul (yscale, pviewy);
// left to right mapping
planeang = (viewangle - ANG90 + planeang) >> ANGLETOFINESHIFT;
// Scale will be unit scale at FocalLengthX (normally SCREENWIDTH/2) distance
xstepscale = Scale (xscale, finecosine[planeang], FocalLengthX);
ystepscale = Scale (yscale, -finesine[planeang], FocalLengthX);
// [RH] flip for mirrors
if (MirrorFlags & RF_XFLIP)
{
xstepscale = (DWORD)(-(SDWORD)xstepscale);
ystepscale = (DWORD)(-(SDWORD)ystepscale);
}
int x = pl->maxx - halfviewwidth;
planeang = (planeang + (ANG90 >> ANGLETOFINESHIFT)) & FINEMASK;
basexfrac = FixedMul (xscale, finecosine[planeang]) + x*xstepscale;
baseyfrac = FixedMul (yscale, -finesine[planeang]) + x*ystepscale;
planeheight = abs (FixedMul (pl->height.d, -pl->height.ic) - viewz);
GlobVis = FixedDiv (r_FloorVisibility, planeheight);
if (fixedlightlev)
ds_colormap = basecolormap + fixedlightlev, plane_shade = false;
else if (fixedcolormap)
ds_colormap = fixedcolormap, plane_shade = false;
else
plane_shade = true;
if (spanfunc != R_FillSpan)
{
if (masked)
{
if (alpha < OPAQUE)
{
spanfunc = R_DrawSpanMaskedTranslucent;
dc_srcblend = Col2RGB8[alpha>>10];
dc_destblend = Col2RGB8[(OPAQUE-alpha)>>10];
}
else
{
spanfunc = R_DrawSpanMasked;
}
}
else
{
if (alpha < OPAQUE)
{
spanfunc = R_DrawSpanTranslucent;
dc_srcblend = Col2RGB8[alpha>>10];
dc_destblend = Col2RGB8[(OPAQUE-alpha)>>10];
}
else
{
spanfunc = R_DrawSpan;
}
}
}
R_MapVisPlane (pl, R_MapPlane);
}
//==========================================================================
//
// R_DrawTiltedPlane
//
//==========================================================================
void R_DrawTiltedPlane (visplane_t *pl, fixed_t alpha, bool masked)
{
static const float ifloatpow2[16] =
{
// ifloatpow2[i] = 1 / (1 << i)
64.f, 32.f, 16.f, 8.f, 4.f, 2.f, 1.f, 0.5f,
0.25f, 0.125f, 0.0625f, 0.03125f, 0.015625f, 0.0078125f,
0.00390625f, 0.001953125f
/*, 0.0009765625f, 0.00048828125f, 0.000244140625f,
1.220703125e-4f, 6.103515625e-5, 3.0517578125e-5*/
};
float lxscale, lyscale;
float xscale, yscale;
fixed_t ixscale, iyscale;
angle_t ang;
vec3_t p, m, n;
fixed_t zeroheight;
if (alpha <= 0)
{
return;
}
// 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.
lxscale = FIXED2FLOAT(pl->xscale) * ifloatpow2[ds_xbits];
lyscale = FIXED2FLOAT(pl->yscale) * ifloatpow2[ds_ybits];
xscale = 64.f / lxscale;
yscale = 64.f / lyscale;
ixscale = quickertoint(xscale*65536.f);
iyscale = quickertoint(yscale*65536.f);
zeroheight = pl->height.ZatPoint (viewx, viewy);
pviewx = MulScale (pl->xoffs, pl->xscale, ds_xbits);
pviewy = MulScale (pl->yoffs, pl->yscale, ds_ybits);
ang = (ANG270 - viewangle) >> ANGLETOFINESHIFT;
p[0] = FIXED2FLOAT(DMulScale16 (viewx, finecosine[ang], -viewy, finesine[ang]));
p[2] = FIXED2FLOAT(DMulScale16 (viewx, finesine[ang], viewy, finecosine[ang]));
p[1] = FIXED2FLOAT(pl->height.ZatPoint (0, 0) - viewz);
// m is the v direction vector in view space
ang = (ANG180 - viewangle - pl->angle) >> ANGLETOFINESHIFT;
m[0] = yscale * FIXED2FLOAT(finecosine[ang]);
m[2] = yscale * FIXED2FLOAT(finesine[ang]);
// m[1] = FIXED2FLOAT(pl->height.ZatPoint (0, iyscale) - pl->height.ZatPoint (0,0));
// VectorScale2 (m, 64.f/VectorLength(m));
// n is the u direction vector in view space
ang = (ang + (ANG90>>ANGLETOFINESHIFT)) & FINEMASK;
n[0] = -xscale * FIXED2FLOAT(finecosine[ang]);
n[2] = -xscale * FIXED2FLOAT(finesine[ang]);
// n[1] = FIXED2FLOAT(pl->height.ZatPoint (ixscale, 0) - pl->height.ZatPoint (0,0));
// VectorScale2 (n, 64.f/VectorLength(n));
ang = pl->angle >> ANGLETOFINESHIFT;
m[1] = FIXED2FLOAT(pl->height.ZatPoint (
viewx + MulScale16 (iyscale, finesine[ang]),
viewy + MulScale16 (iyscale, finecosine[ang])) - zeroheight);
ang = (pl->angle + ANGLE_90) >> ANGLETOFINESHIFT;
n[1] = FIXED2FLOAT(pl->height.ZatPoint (
viewx + MulScale16 (ixscale, finesine[ang]),
viewy + MulScale16 (ixscale, finecosine[ang])) - zeroheight);
CrossProduct (p, m, plane_su);
CrossProduct (p, n, plane_sv);
CrossProduct (m, n, plane_sz);
plane_su[2] *= FocalLengthXfloat;
plane_sv[2] *= FocalLengthXfloat;
plane_sz[2] *= FocalLengthXfloat;
plane_su[1] *= iyaspectmulfloat;
plane_sv[1] *= iyaspectmulfloat;
plane_sz[1] *= iyaspectmulfloat;
// Premultiply the texture vectors with the scale factors
VectorScale2 (plane_su, 4294967296.f);
VectorScale2 (plane_sv, 4294967296.f);
if (MirrorFlags & RF_XFLIP)
{
plane_su[0] = -plane_su[0];
plane_sv[0] = -plane_sv[0];
plane_sz[0] = -plane_sz[0];
}
planelightfloat = (r_TiltVisibility * lxscale * lyscale) / (float)(abs(pl->height.ZatPoint (viewx, viewy) - viewz));
if (pl->height.c > 0)
planelightfloat = -planelightfloat;
if (fixedlightlev)
ds_colormap = basecolormap + fixedlightlev, plane_shade = false;
else if (fixedcolormap)
ds_colormap = fixedcolormap, plane_shade = false;
else
ds_colormap = basecolormap, plane_shade = true;
if (!plane_shade)
{
for (int i = 0; i < viewwidth; ++i)
{
tiltlighting[i] = ds_colormap;
}
}
#if defined(USEASM)
if (ds_source != ds_curtiltedsource)
R_SetTiltedSpanSource_ASM (ds_source);
R_MapVisPlane (pl, R_DrawTiltedPlane_ASM);
#else
R_MapVisPlane (pl, R_MapTiltedPlane);
#endif
}
//==========================================================================
//
// R_MapVisPlane
//
// t1/b1 are at x
// t2/b2 are at x+1
// spanend[y] is at the right edge
//
//==========================================================================
void R_MapVisPlane (visplane_t *pl, void (*mapfunc)(int y, int x1))
{
int x = pl->maxx;
int t2 = pl->top[x];
int b2 = pl->bottom[x];
if (b2 > t2)
{
clearbufshort (spanend+t2, b2-t2, x);
}
for (--x; x >= pl->minx; --x)
{
int t1 = pl->top[x];
int b1 = pl->bottom[x];
const int xr = x+1;
int stop;
// Draw any spans that have just closed
stop = MIN (t1, b2);
while (t2 < stop)
{
mapfunc (t2++, xr);
}
stop = MAX (b1, t2);
while (b2 > stop)
{
mapfunc (--b2, xr);
}
// Mark any spans that have just opened
stop = MIN (t2, b1);
while (t1 < stop)
{
spanend[t1++] = x;
}
stop = MAX (b2, t2);
while (b1 > stop)
{
spanend[--b1] = x;
}
t2 = pl->top[x];
b2 = pl->bottom[x];
basexfrac -= xstepscale;
baseyfrac -= ystepscale;
}
// Draw any spans that are still open
while (t2 < b2)
{
mapfunc (--b2, pl->minx);
}
}
//==========================================================================
//
// R_PlaneInitData
//
//==========================================================================
BOOL R_PlaneInitData ()
{
int i;
visplane_t *pl;
// Free all visplanes and let them be re-allocated as needed.
pl = freetail;
while (pl)
{
visplane_t *next = pl->next;
free (pl);
pl = next;
}
freetail = NULL;
freehead = &freetail;
for (i = 0; i < MAXVISPLANES; i++)
{
pl = visplanes[i];
visplanes[i] = NULL;
while (pl)
{
visplane_t *next = pl->next;
free (pl);
pl = next;
}
}
return true;
}
//==========================================================================
//
// R_AlignFlat
//
//==========================================================================
bool R_AlignFlat (int linenum, int side, int fc)
{
line_t *line = lines + linenum;
sector_t *sec = side ? line->backsector : line->frontsector;
if (!sec)
return false;
fixed_t x = line->v1->x;
fixed_t y = line->v1->y;
angle_t angle = R_PointToAngle2 (x, y, line->v2->x, line->v2->y);
angle_t norm = (angle-ANGLE_90) >> ANGLETOFINESHIFT;
fixed_t dist = -FixedMul (finecosine[norm], x) - FixedMul (finesine[norm], y);
if (side)
{
angle = angle + ANGLE_180;
dist = -dist;
}
if (fc)
{
sec->base_ceiling_angle = 0-angle;
sec->base_ceiling_yoffs = dist & ((1<<(FRACBITS+8))-1);
}
else
{
sec->base_floor_angle = 0-angle;
sec->base_floor_yoffs = dist & ((1<<(FRACBITS+8))-1);
}
return true;
}