gzdoom-gles/src/p_slopes.cpp
Christoph Oelckers 3e8435e22c - added Gez's Plane_Copy submission with some extensions and improvements.
This line special is the last of the slope creation methods being processed so it can copy any other type of slope.


SVN r2147 (trunk)
2010-01-30 22:53:37 +00:00

627 lines
17 KiB
C++

/*
** p_slopes.cpp
** Slope creation
**
**---------------------------------------------------------------------------
** Copyright 1998-2008 Randy Heit
** All rights reserved.
**
** Redistribution and use in source and binary forms, with or without
** modification, are permitted provided that the following conditions
** are met:
**
** 1. Redistributions of source code must retain the above copyright
** notice, this list of conditions and the following disclaimer.
** 2. Redistributions in binary form must reproduce the above copyright
** notice, this list of conditions and the following disclaimer in the
** documentation and/or other materials provided with the distribution.
** 3. The name of the author may not be used to endorse or promote products
** derived from this software without specific prior written permission.
**
** THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
** IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
** OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
** IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
** INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
** NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
** DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
** THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
** (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
** THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
**---------------------------------------------------------------------------
**
*/
#include "doomtype.h"
#include "p_local.h"
#include "r_data.h"
#include "cmdlib.h"
#include "p_lnspec.h"
//===========================================================================
//
// P_SpawnSlopeMakers
//
//===========================================================================
static void P_SlopeLineToPoint (int lineid, fixed_t x, fixed_t y, fixed_t z, bool slopeCeil)
{
int linenum = -1;
while ((linenum = P_FindLineFromID (lineid, linenum)) != -1)
{
const line_t *line = &lines[linenum];
sector_t *sec;
secplane_t *plane;
if (P_PointOnLineSide (x, y, line) == 0)
{
sec = line->frontsector;
}
else
{
sec = line->backsector;
}
if (sec == NULL)
{
continue;
}
if (slopeCeil)
{
plane = &sec->ceilingplane;
}
else
{
plane = &sec->floorplane;
}
FVector3 p, v1, v2, cross;
p[0] = FIXED2FLOAT (line->v1->x);
p[1] = FIXED2FLOAT (line->v1->y);
p[2] = FIXED2FLOAT (plane->ZatPoint (line->v1->x, line->v1->y));
v1[0] = FIXED2FLOAT (line->dx);
v1[1] = FIXED2FLOAT (line->dy);
v1[2] = FIXED2FLOAT (plane->ZatPoint (line->v2->x, line->v2->y)) - p[2];
v2[0] = FIXED2FLOAT (x - line->v1->x);
v2[1] = FIXED2FLOAT (y - line->v1->y);
v2[2] = FIXED2FLOAT (z) - p[2];
cross = v1 ^ v2;
double len = cross.Length();
if (len == 0)
{
Printf ("Slope thing at (%d,%d) lies directly on its target line.\n", int(x>>16), int(y>>16));
return;
}
cross /= len;
// Fix backward normals
if ((cross.Z < 0 && !slopeCeil) || (cross.Z > 0 && slopeCeil))
{
cross = -cross;
}
plane->a = FLOAT2FIXED (cross[0]);
plane->b = FLOAT2FIXED (cross[1]);
plane->c = FLOAT2FIXED (cross[2]);
//plane->ic = FLOAT2FIXED (1.f/cross[2]);
plane->ic = DivScale32 (1, plane->c);
plane->d = -TMulScale16 (plane->a, x,
plane->b, y,
plane->c, z);
}
}
//===========================================================================
//
// P_CopyPlane
//
//===========================================================================
static void P_CopyPlane (int tag, sector_t *dest, bool copyCeil)
{
sector_t *source;
int secnum;
size_t planeofs;
secnum = P_FindSectorFromTag (tag, -1);
if (secnum == -1)
{
return;
}
source = &sectors[secnum];
if (copyCeil)
{
planeofs = myoffsetof(sector_t, ceilingplane);
}
else
{
planeofs = myoffsetof(sector_t, floorplane);
}
*(secplane_t *)((BYTE *)dest + planeofs) = *(secplane_t *)((BYTE *)source + planeofs);
}
static void P_CopyPlane (int tag, fixed_t x, fixed_t y, bool copyCeil)
{
sector_t *dest = P_PointInSector (x, y);
P_CopyPlane(tag, dest, copyCeil);
}
//===========================================================================
//
// P_SetSlope
//
//===========================================================================
void P_SetSlope (secplane_t *plane, bool setCeil, int xyangi, int zangi,
fixed_t x, fixed_t y, fixed_t z)
{
angle_t xyang;
angle_t zang;
if (zangi >= 180)
{
zang = ANGLE_180-ANGLE_1;
}
else if (zangi <= 0)
{
zang = ANGLE_1;
}
else
{
zang = Scale (zangi, ANGLE_90, 90);
}
if (setCeil)
{
zang += ANGLE_180;
}
zang >>= ANGLETOFINESHIFT;
xyang = (angle_t)Scale (xyangi, ANGLE_90, 90 << ANGLETOFINESHIFT);
FVector3 norm;
if (ib_compatflags & BCOMPATF_SETSLOPEOVERFLOW)
{
norm[0] = float(finecosine[zang] * finecosine[xyang]);
norm[1] = float(finecosine[zang] * finesine[xyang]);
}
else
{
norm[0] = float(finecosine[zang]) * float(finecosine[xyang]);
norm[1] = float(finecosine[zang]) * float(finesine[xyang]);
}
norm[2] = float(finesine[zang]) * 65536.f;
norm.MakeUnit();
plane->a = (int)(norm[0] * 65536.f);
plane->b = (int)(norm[1] * 65536.f);
plane->c = (int)(norm[2] * 65536.f);
//plane->ic = (int)(65536.f / norm[2]);
plane->ic = DivScale32 (1, plane->c);
plane->d = -TMulScale16 (plane->a, x,
plane->b, y,
plane->c, z);
}
//===========================================================================
//
// P_VavoomSlope
//
//===========================================================================
void P_VavoomSlope(sector_t * sec, int id, fixed_t x, fixed_t y, fixed_t z, int which)
{
for (int i=0;i<sec->linecount;i++)
{
line_t * l=sec->lines[i];
if (l->args[0]==id)
{
FVector3 v1, v2, cross;
secplane_t *srcplane = (which == 0) ? &sec->floorplane : &sec->ceilingplane;
fixed_t srcheight = (which == 0) ? sec->GetPlaneTexZ(sector_t::floor) : sec->GetPlaneTexZ(sector_t::ceiling);
v1[0] = FIXED2FLOAT (x - l->v2->x);
v1[1] = FIXED2FLOAT (y - l->v2->y);
v1[2] = FIXED2FLOAT (z - srcheight);
v2[0] = FIXED2FLOAT (x - l->v1->x);
v2[1] = FIXED2FLOAT (y - l->v1->y);
v2[2] = FIXED2FLOAT (z - srcheight);
cross = v1 ^ v2;
double len = cross.Length();
if (len == 0)
{
Printf ("Slope thing at (%d,%d) lies directly on its target line.\n", int(x>>16), int(y>>16));
return;
}
cross /= len;
// Fix backward normals
if ((cross.Z < 0 && which == 0) || (cross.Z > 0 && which == 1))
{
cross = -cross;
}
srcplane->a = FLOAT2FIXED (cross[0]);
srcplane->b = FLOAT2FIXED (cross[1]);
srcplane->c = FLOAT2FIXED (cross[2]);
//plane->ic = FLOAT2FIXED (1.f/cross[2]);
srcplane->ic = DivScale32 (1, srcplane->c);
srcplane->d = -TMulScale16 (srcplane->a, x,
srcplane->b, y,
srcplane->c, z);
return;
}
}
}
enum
{
THING_SlopeFloorPointLine = 9500,
THING_SlopeCeilingPointLine = 9501,
THING_SetFloorSlope = 9502,
THING_SetCeilingSlope = 9503,
THING_CopyFloorPlane = 9510,
THING_CopyCeilingPlane = 9511,
THING_VavoomFloor=1500,
THING_VavoomCeiling=1501,
THING_VertexFloorZ=1504,
THING_VertexCeilingZ=1505,
};
//==========================================================================
//
// P_SetSlopesFromVertexHeights
//
//==========================================================================
static void P_SetSlopesFromVertexHeights(FMapThing *firstmt, FMapThing *lastmt)
{
TMap<int, fixed_t> vt_heights[2];
FMapThing *mt;
bool vt_found = false;
for (mt = firstmt; mt < lastmt; ++mt)
{
if (mt->type == THING_VertexFloorZ || mt->type == THING_VertexCeilingZ)
{
for(int i=0; i<numvertexes; i++)
{
if (vertexes[i].x == mt->x && vertexes[i].y == mt->y)
{
if (mt->type == THING_VertexFloorZ)
{
vt_heights[0][i] = mt->z;
}
else
{
vt_heights[1][i] = mt->z;
}
vt_found = true;
}
}
mt->type = 0;
}
}
if (vt_found)
{
for (int i = 0; i < numsectors; i++)
{
sector_t *sec = &sectors[i];
if (sec->linecount != 3) continue; // only works with triangular sectors
FVector3 vt1, vt2, vt3, cross;
FVector3 vec1, vec2;
int vi1, vi2, vi3;
vi1 = int(sec->lines[0]->v1 - vertexes);
vi2 = int(sec->lines[0]->v2 - vertexes);
vi3 = (sec->lines[1]->v1 == sec->lines[0]->v1 || sec->lines[1]->v1 == sec->lines[0]->v2)?
int(sec->lines[1]->v2 - vertexes) : int(sec->lines[1]->v1 - vertexes);
vt1.X = FIXED2FLOAT(vertexes[vi1].x);
vt1.Y = FIXED2FLOAT(vertexes[vi1].y);
vt2.X = FIXED2FLOAT(vertexes[vi2].x);
vt2.Y = FIXED2FLOAT(vertexes[vi2].y);
vt3.X = FIXED2FLOAT(vertexes[vi3].x);
vt3.Y = FIXED2FLOAT(vertexes[vi3].y);
for(int j=0; j<2; j++)
{
fixed_t *h1 = vt_heights[j].CheckKey(vi1);
fixed_t *h2 = vt_heights[j].CheckKey(vi2);
fixed_t *h3 = vt_heights[j].CheckKey(vi3);
fixed_t z3;
if (h1==NULL && h2==NULL && h3==NULL) continue;
vt1.Z = FIXED2FLOAT(h1? *h1 : j==0? sec->GetPlaneTexZ(sector_t::floor) : sec->GetPlaneTexZ(sector_t::ceiling));
vt2.Z = FIXED2FLOAT(h2? *h2 : j==0? sec->GetPlaneTexZ(sector_t::floor) : sec->GetPlaneTexZ(sector_t::ceiling));
z3 = h3? *h3 : j==0? sec->GetPlaneTexZ(sector_t::floor) : sec->GetPlaneTexZ(sector_t::ceiling);
vt3.Z = FIXED2FLOAT(z3);
if (P_PointOnLineSide(vertexes[vi3].x, vertexes[vi3].y, sec->lines[0]) == 0)
{
vec1 = vt2 - vt3;
vec2 = vt1 - vt3;
}
else
{
vec1 = vt1 - vt3;
vec2 = vt2 - vt3;
}
FVector3 cross = vec1 ^ vec2;
double len = cross.Length();
if (len == 0)
{
// Only happens when all vertices in this sector are on the same line.
// Let's just ignore this case.
continue;
}
cross /= len;
// Fix backward normals
if ((cross.Z < 0 && j == 0) || (cross.Z > 0 && j == 1))
{
cross = -cross;
}
secplane_t *srcplane = j==0? &sec->floorplane : &sec->ceilingplane;
srcplane->a = FLOAT2FIXED (cross[0]);
srcplane->b = FLOAT2FIXED (cross[1]);
srcplane->c = FLOAT2FIXED (cross[2]);
srcplane->ic = DivScale32 (1, srcplane->c);
srcplane->d = -TMulScale16 (srcplane->a, vertexes[vi3].x,
srcplane->b, vertexes[vi3].y,
srcplane->c, z3);
}
}
}
}
//===========================================================================
//
// P_SpawnSlopeMakers
//
//===========================================================================
void P_SpawnSlopeMakers (FMapThing *firstmt, FMapThing *lastmt)
{
FMapThing *mt;
for (mt = firstmt; mt < lastmt; ++mt)
{
if ((mt->type >= THING_SlopeFloorPointLine &&
mt->type <= THING_SetCeilingSlope) ||
mt->type==THING_VavoomFloor || mt->type==THING_VavoomCeiling)
{
fixed_t x, y, z;
secplane_t *refplane;
sector_t *sec;
x = mt->x;
y = mt->y;
sec = P_PointInSector (x, y);
if (mt->type & 1)
{
refplane = &sec->ceilingplane;
}
else
{
refplane = &sec->floorplane;
}
z = refplane->ZatPoint (x, y) + (mt->z);
if (mt->type==THING_VavoomFloor || mt->type==THING_VavoomCeiling)
{
P_VavoomSlope(sec, mt->thingid, x, y, mt->z, mt->type & 1);
}
else if (mt->type <= THING_SlopeCeilingPointLine)
{
P_SlopeLineToPoint (mt->args[0], x, y, z, mt->type & 1);
}
else
{
P_SetSlope (refplane, mt->type & 1, mt->angle, mt->args[0], x, y, z);
}
mt->type = 0;
}
}
for (mt = firstmt; mt < lastmt; ++mt)
{
if (mt->type == THING_CopyFloorPlane ||
mt->type == THING_CopyCeilingPlane)
{
P_CopyPlane (mt->args[0], mt->x, mt->y, mt->type & 1);
mt->type = 0;
}
}
P_SetSlopesFromVertexHeights(firstmt, lastmt);
}
//===========================================================================
//
// [RH] Set slopes for sectors, based on line specials
//
// P_AlignPlane
//
// Aligns the floor or ceiling of a sector to the corresponding plane
// on the other side of the reference line. (By definition, line must be
// two-sided.)
//
// If (which & 1), sets floor.
// If (which & 2), sets ceiling.
//
//===========================================================================
static void P_AlignPlane (sector_t *sec, line_t *line, int which)
{
sector_t *refsec;
double bestdist;
vertex_t *refvert = (*sec->lines)->v1; // Shut up, GCC
int i;
line_t **probe;
if (line->backsector == NULL)
return;
// Find furthest vertex from the reference line. It, along with the two ends
// of the line, will define the plane.
bestdist = 0;
for (i = sec->linecount*2, probe = sec->lines; i > 0; i--)
{
double dist;
vertex_t *vert;
if (i & 1)
vert = (*probe++)->v2;
else
vert = (*probe)->v1;
dist = fabs((double(line->v1->y) - vert->y) * line->dx -
(double(line->v1->x) - vert->x) * line->dy);
if (dist > bestdist)
{
bestdist = dist;
refvert = vert;
}
}
refsec = line->frontsector == sec ? line->backsector : line->frontsector;
FVector3 p, v1, v2, cross;
const secplane_t *refplane;
secplane_t *srcplane;
fixed_t srcheight, destheight;
refplane = (which == 0) ? &refsec->floorplane : &refsec->ceilingplane;
srcplane = (which == 0) ? &sec->floorplane : &sec->ceilingplane;
srcheight = (which == 0) ? sec->GetPlaneTexZ(sector_t::floor) : sec->GetPlaneTexZ(sector_t::ceiling);
destheight = (which == 0) ? refsec->GetPlaneTexZ(sector_t::floor) : refsec->GetPlaneTexZ(sector_t::ceiling);
p[0] = FIXED2FLOAT (line->v1->x);
p[1] = FIXED2FLOAT (line->v1->y);
p[2] = FIXED2FLOAT (destheight);
v1[0] = FIXED2FLOAT (line->dx);
v1[1] = FIXED2FLOAT (line->dy);
v1[2] = 0;
v2[0] = FIXED2FLOAT (refvert->x - line->v1->x);
v2[1] = FIXED2FLOAT (refvert->y - line->v1->y);
v2[2] = FIXED2FLOAT (srcheight - destheight);
cross = (v1 ^ v2).Unit();
// Fix backward normals
if ((cross.Z < 0 && which == 0) || (cross.Z > 0 && which == 1))
{
cross = -cross;
}
srcplane->a = FLOAT2FIXED (cross[0]);
srcplane->b = FLOAT2FIXED (cross[1]);
srcplane->c = FLOAT2FIXED (cross[2]);
//srcplane->ic = FLOAT2FIXED (1.f/cross[2]);
srcplane->ic = DivScale32 (1, srcplane->c);
srcplane->d = -TMulScale16 (srcplane->a, line->v1->x,
srcplane->b, line->v1->y,
srcplane->c, destheight);
}
//===========================================================================
//
// P_SetSlopes
//
//===========================================================================
void P_SetSlopes ()
{
int i, s;
for (i = 0; i < numlines; i++)
{
if (lines[i].special == Plane_Align)
{
lines[i].special = 0;
if (lines[i].backsector != NULL)
{
// args[0] is for floor, args[1] is for ceiling
//
// As a special case, if args[1] is 0,
// then args[0], bits 2-3 are for ceiling.
for (s = 0; s < 2; s++)
{
int bits = lines[i].args[s] & 3;
if (s == 1 && bits == 0)
bits = (lines[i].args[0] >> 2) & 3;
if (bits == 1) // align front side to back
P_AlignPlane (lines[i].frontsector, lines + i, s);
else if (bits == 2) // align back side to front
P_AlignPlane (lines[i].backsector, lines + i, s);
}
}
}
}
}
//===========================================================================
//
// P_CopySlopes
//
//===========================================================================
void P_CopySlopes()
{
for (int i = 0; i < numlines; i++)
{
if (lines[i].special == Plane_Copy)
{
// The args are used for the tags of sectors to copy:
// args[0]: front floor
// args[1]: front ceiling
// args[2]: back floor
// args[3]: back ceiling
// args[4]: copy slopes from one side of the line to the other.
lines[i].special = 0;
for (int s = 0; s < (lines[i].backsector ? 4 : 2); s++)
{
if (lines[i].args[s])
P_CopyPlane(lines[i].args[s],
(s & 2 ? lines[i].backsector : lines[i].frontsector), s & 1);
}
if (lines[i].backsector != NULL)
{
if ((lines[i].args[4] & 3) == 1)
{
lines[i].backsector->floorplane = lines[i].frontsector->floorplane;
}
else if ((lines[i].args[4] & 3) == 2)
{
lines[i].frontsector->floorplane = lines[i].backsector->floorplane;
}
if ((lines[i].args[4] & 12) == 4)
{
lines[i].backsector->ceilingplane = lines[i].frontsector->ceilingplane;
}
else if ((lines[i].args[4] & 12) == 8)
{
lines[i].frontsector->ceilingplane = lines[i].backsector->ceilingplane;
}
}
}
}
}