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fteqw/engine/sw/r_draw.c
Spoike 6e3f69f504 d3d rendering is diabled (framestate, read later - merged will compile just sw+gl for now). 
fte particle scripts are disabled (classic works).
I'll fix these in the new year.
Redid framestate stuff again. Slightly better now, but this is the bulk of the changes here.
Reworked the renderqueue to provide batches of items instead of individual items. This cleans up the particle rendering code significantly, and is a step towards multiple concurrent particle systems. fte's scripted particles are broken as I'm trying to find a way to rework them to batch types together, rather than having to restart each batch after each particle when you have two particles in a trail. I'll fix it some time.
Reworked some alias model code regarding skeletal models. Added some conceptual skeletal bone control builtins available to csqc. Currently it can query the bone names and save off animation states, but can't animate - its just not complete.
Added more info to glsl custom shaders.
Updated surface sorting on halflife maps to properly cope with alphaed entities, rather than just texture-based blends (q2-style).

git-svn-id: https://svn.code.sf.net/p/fteqw/code/trunk@3095 fc73d0e0-1445-4013-8a0c-d673dee63da5
2008-12-23 02:55:20 +00:00

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/*
Copyright (C) 1996-1997 Id Software, Inc.
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License
as published by the Free Software Foundation; either version 2
of the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*/
// r_draw.c
#include "quakedef.h"
#include "r_local.h"
#include "d_local.h" // FIXME: shouldn't need to include this
#define MAXLEFTCLIPEDGES 100
// !!! if these are changed, they must be changed in asm_draw.h too !!!
#define FULLY_CLIPPED_CACHED 0x80000000
#define FRAMECOUNT_MASK 0x7FFFFFFF
unsigned int cacheoffset;
int c_faceclip; // number of faces clipped
zpointdesc_t r_zpointdesc;
polydesc_t r_polydesc;
clipplane_t *entity_clipplanes;
clipplane_t view_clipplanes[4];
clipplane_t world_clipplanes[16];
medge_t *r_pedge;
qboolean r_leftclipped, r_rightclipped;
static qboolean makeleftedge, makerightedge;
qboolean r_nearzionly;
int sintable[SINTABLESIZE];
int intsintable[SINTABLESIZE];
mvertex_t r_leftenter, r_leftexit;
mvertex_t r_rightenter, r_rightexit;
typedef struct
{
float u,v;
int ceilv;
} evert_t;
int r_emitted;
float r_nearzi;
float r_u1, r_v1, r_lzi1;
int r_ceilv1;
qboolean r_lastvertvalid;
msurface_t *r_alpha_surfaces;
int r_skyframe;
msurface_t *r_skyfaces;
mplane_t r_skyplanes[6];
mtexinfo_t r_skytexinfo[6];
mvertex_t *r_skyverts;
medge_t *r_skyedges;
int *r_skysurfedges;
// I just copied this code from q2...
int skybox_planes[12] = {2,-128, 0,-128, 2,128, 1,128, 0,128, 1,-128};
int box_surfedges[24] = { 1,2,3,4, -1,5,6,7, 8,9,-6,10, -2,-7,-9,11,
12,-3,-11,-8, -12,-10,-5,-4};
int box_edges[24] = { 1,2, 2,3, 3,4, 4,1, 1,5, 5,6, 6,2, 7,8, 8,6, 5,7, 8,3, 7,4};
int box_faces[6] = {0,0,2,2,2,0};
vec3_t box_vecs[6][2] = {
{ {0,-1,0}, {-1,0,0} },
{ {0,1,0}, {0,0,-1} },
{ {0,-1,0}, {1,0,0} },
{ {1,0,0}, {0,0,-1} },
{ {0,-1,0}, {0,0,-1} },
{ {-1,0,0}, {0,0,-1} }
};
float box_verts[8][3] = {
{-1,-1,-1},
{-1,1,-1},
{1,1,-1},
{1,-1,-1},
{-1,-1,1},
{-1,1,1},
{1,-1,1},
{1,1,1}
};
// down, west, up, north, east, south
// {"rt", "bk", "lf", "ft", "up", "dn"};
static char *suf[6] = {"rt", "bk", "lf", "ft", "up", "dn"};
int r_skysideimage[6] = {5, 2, 4, 1, 0, 3};
extern mtexinfo_t r_skytexinfo[6];
char skyname[64];
/*
================
R_LoadSkyBox
================
*/
void SWR_LoadSkyBox (void)
{
#ifdef Q2BSPS
void *Mod_LoadWall(char *name);
int i;
char pathname[MAX_QPATH];
for (i=0 ; i<6 ; i++)
{
snprintf (pathname, MAX_QPATH-1, "env/%s%s.tga", skyname, suf[r_skysideimage[i]]);
r_skytexinfo[i].texture = Mod_LoadWall (pathname); //preferable
if (!r_skytexinfo[i].texture)
{
snprintf (pathname, MAX_QPATH-1, "env/%s%s.pcx", skyname, suf[r_skysideimage[i]]);
r_skytexinfo[i].texture = Mod_LoadWall (pathname); //q2 fall back
}
if (!r_skytexinfo[i].texture)
{
// break out and erase skyname so renderer won't render it
skyname[0] = '\0';
return;
}
}
#endif
}
void SWR_SetSky (char *name, float rotate, vec3_t axis)
{
int i;
Q_strncpyz (skyname, name, sizeof(skyname));
// skyrotate = rotate;
// VectorCopy (axis, skyaxis);
for (i=0 ; i<6 ; i++)
{
r_skytexinfo[i].texture = NULL;
}
SWR_LoadSkyBox();
}
qboolean SWR_CheckSky (void)
{
int i;
char pathname[MAX_QPATH];
if (!*skyname)
return true;
for (i=0 ; i<6 ; i++)
{
sprintf (pathname, "env/%s%s.pcx", skyname, suf[r_skysideimage[i]]);
if (COM_FCheckExists(pathname))
{
continue;// it exists, don't bother going for a tga version
}
sprintf (pathname, "env/%s%s.tga", skyname, suf[r_skysideimage[i]]);
if (!COM_FCheckExists(pathname))
return false;
// if (!CL_CheckOrDownloadFile(pathname, NULL, -1))
// return false;
}
return true;
}
/*
================
R_InitSkyBox
================
*/
void R_InitSkyBox (void)
{
int i;
model_t *wm;
wm = cl.worldmodel;
if (wm->numsurfaces+6 > MAX_MAP_FACES
|| wm->numvertexes+8 > MAX_MAP_VERTS
|| wm->numedges+12 > MAX_MAP_EDGES)
Host_Error ("InitSkyBox: map overflow");
r_skyfaces = wm->surfaces + wm->numsurfaces;
// wm->numsurfaces += 6;
r_skyverts = wm->vertexes + wm->numvertexes;
// wm->numvertexes += 8;
r_skyedges = wm->edges + wm->numedges;
// wm->numedges += 12;
r_skysurfedges = wm->surfedges + wm->numsurfedges;
// wm->numsurfedges += 24;
memset (r_skyfaces, 0, 6*sizeof(*r_skyfaces));
for (i=0 ; i<6 ; i++)
{
r_skyplanes[i].normal[skybox_planes[i*2]] = 1;
r_skyplanes[i].dist = skybox_planes[i*2+1];
VectorCopy (box_vecs[i][0], r_skytexinfo[i].vecs[0]);
VectorCopy (box_vecs[i][1], r_skytexinfo[i].vecs[1]);
r_skyfaces[i].plane = &r_skyplanes[i];
r_skyfaces[i].numedges = 4;
r_skyfaces[i].flags = box_faces[i] | SURF_DRAWSKYBOX;
r_skyfaces[i].firstedge = wm->numsurfedges+i*4;
r_skyfaces[i].texinfo = &r_skytexinfo[i];
r_skyfaces[i].texturemins[0] = -128;
r_skyfaces[i].texturemins[1] = -128;
r_skyfaces[i].extents[0] = 256;
r_skyfaces[i].extents[1] = 256;
}
for (i=0 ; i<24 ; i++)
if (box_surfedges[i] > 0)
r_skysurfedges[i] = wm->numedges - 1 + box_surfedges[i];
else
r_skysurfedges[i] = -(wm->numedges - 1 + -box_surfedges[i]);
for(i=0 ; i<12 ; i++)
{
r_skyedges[i].v[0] = wm->numvertexes-1+box_edges[i*2+0];
r_skyedges[i].v[1] = wm->numvertexes-1+box_edges[i*2+1];
r_skyedges[i].cachededgeoffset = 0;
}
Hunk_Check();
}
void SWR_Skyboxname_Callback(struct cvar_s *var, char *oldvalue)
{
Q_strncpyz (skyname, var->string, sizeof(skyname));
SWR_LoadSkyBox();
}
/*
================
R_EmitSkyBox
================
*/
qboolean R_EmitSkyBox (void)
{
int i, j;
int oldkey;
if (insubmodel)
return false; // submodels should never have skies
if (r_skyframe == r_framecount)
return true; // already set this frame
if (!*skyname) //none set
return false;
r_skyframe = r_framecount;
// set the eight fake vertexes
for (i=0 ; i<8 ; i++)
for (j=0 ; j<3 ; j++)
r_skyverts[i].position[j] = r_origin[j] + box_verts[i][j]*128;
// set the six fake planes
for (i=0 ; i<6 ; i++)
if (skybox_planes[i*2+1] > 0)
r_skyplanes[i].dist = r_origin[skybox_planes[i*2]]+128;
else
r_skyplanes[i].dist = r_origin[skybox_planes[i*2]]-128;
// fix texture offseets
for (i=0 ; i<6 ; i++)
{
r_skytexinfo[i].vecs[0][3] = -DotProduct (r_origin, r_skytexinfo[i].vecs[0]);
r_skytexinfo[i].vecs[1][3] = -DotProduct (r_origin, r_skytexinfo[i].vecs[1]);
}
// emit the six faces
oldkey = r_currentkey;
r_currentkey = 0x7ffffff0;
for (i=0 ; i<6 ; i++)
{
R_RenderFace (r_skyfaces + i, 15);
}
r_currentkey = oldkey; // bsp sorting order
return true;
}
#if !id386
/*
================
R_EmitEdge
================
*/
void R_EmitEdge (mvertex_t *pv0, mvertex_t *pv1)
{
edge_t *edge, *pcheck;
int u_check;
float u, u_step;
vec3_t local, transformed;
float *world;
int v, v2, ceilv0;
float scale, lzi0, u0, v0;
int side;
if (r_lastvertvalid)
{
u0 = r_u1;
v0 = r_v1;
lzi0 = r_lzi1;
ceilv0 = r_ceilv1;
}
else
{
world = &pv0->position[0];
// transform and project
VectorSubtract (world, modelorg, local);
TransformVector (local, transformed);
if (transformed[2] < NEAR_CLIP)
transformed[2] = NEAR_CLIP;
lzi0 = 1.0 / transformed[2];
// FIXME: build x/yscale into transform?
scale = xscale * lzi0;
u0 = (xcenter + scale*transformed[0]);
if (u0 < r_refdef.fvrectx_adj)
u0 = r_refdef.fvrectx_adj;
if (u0 > r_refdef.fvrectright_adj)
u0 = r_refdef.fvrectright_adj;
scale = yscale * lzi0;
v0 = (ycenter - scale*transformed[1]);
if (v0 < r_refdef.fvrecty_adj)
v0 = r_refdef.fvrecty_adj;
if (v0 > r_refdef.fvrectbottom_adj)
v0 = r_refdef.fvrectbottom_adj;
ceilv0 = (int) ceil(v0);
}
world = &pv1->position[0];
// transform and project
VectorSubtract (world, modelorg, local);
TransformVector (local, transformed);
if (transformed[2] < NEAR_CLIP)
transformed[2] = NEAR_CLIP;
r_lzi1 = 1.0 / transformed[2];
scale = xscale * r_lzi1;
r_u1 = (xcenter + scale*transformed[0]);
if (r_u1 < r_refdef.fvrectx_adj)
r_u1 = r_refdef.fvrectx_adj;
if (r_u1 > r_refdef.fvrectright_adj)
r_u1 = r_refdef.fvrectright_adj;
scale = yscale * r_lzi1;
r_v1 = (ycenter - scale*transformed[1]);
if (r_v1 < r_refdef.fvrecty_adj)
r_v1 = r_refdef.fvrecty_adj;
if (r_v1 > r_refdef.fvrectbottom_adj)
r_v1 = r_refdef.fvrectbottom_adj;
if (r_lzi1 > lzi0)
lzi0 = r_lzi1;
if (lzi0 > r_nearzi) // for mipmap finding
r_nearzi = lzi0;
// for right edges, all we want is the effect on 1/z
if (r_nearzionly)
return;
r_emitted = 1;
r_ceilv1 = (int) ceil(r_v1);
// create the edge
if (ceilv0 == r_ceilv1)
{
// we cache unclipped horizontal edges as fully clipped
if (cacheoffset != 0x7FFFFFFF)
{
cacheoffset = FULLY_CLIPPED_CACHED |
(r_framecount & FRAMECOUNT_MASK);
}
return; // horizontal edge
}
side = ceilv0 > r_ceilv1;
edge = edge_p++;
edge->owner = r_pedge;
edge->nearzi = lzi0;
if (side == 0)
{
// trailing edge (go from p1 to p2)
v = ceilv0;
v2 = r_ceilv1 - 1;
edge->surfs[0] = surface_p - surfaces;
edge->surfs[1] = 0;
u_step = ((r_u1 - u0) / (r_v1 - v0));
u = u0 + ((float)v - v0) * u_step;
}
else
{
// leading edge (go from p2 to p1)
v2 = ceilv0 - 1;
v = r_ceilv1;
edge->surfs[0] = 0;
edge->surfs[1] = surface_p - surfaces;
u_step = ((u0 - r_u1) / (v0 - r_v1));
u = r_u1 + ((float)v - r_v1) * u_step;
}
edge->u_step = u_step*0x100000;
edge->u = u*0x100000 + 0xFFFFF;
// we need to do this to avoid stepping off the edges if a very nearly
// horizontal edge is less than epsilon above a scan, and numeric error causes
// it to incorrectly extend to the scan, and the extension of the line goes off
// the edge of the screen
// FIXME: is this actually needed?
if (edge->u < r_refdef.vrect_x_adj_shift20)
edge->u = r_refdef.vrect_x_adj_shift20;
if (edge->u > r_refdef.vrectright_adj_shift20)
edge->u = r_refdef.vrectright_adj_shift20;
//
// sort the edge in normally
//
u_check = edge->u;
if (edge->surfs[0])
u_check++; // sort trailers after leaders
if (!newedges[v] || newedges[v]->u >= u_check)
{
edge->next = newedges[v];
newedges[v] = edge;
}
else
{
pcheck = newedges[v];
while (pcheck->next && pcheck->next->u < u_check)
pcheck = pcheck->next;
edge->next = pcheck->next;
pcheck->next = edge;
}
edge->nextremove = removeedges[v2];
removeedges[v2] = edge;
}
/*
================
R_ClipEdge
================
*/
void R_ClipEdge (mvertex_t *pv0, mvertex_t *pv1, clipplane_t *clip)
{
float d0, d1, f;
mvertex_t clipvert;
if (clip)
{
do
{
d0 = DotProduct (pv0->position, clip->normal) - clip->dist;
d1 = DotProduct (pv1->position, clip->normal) - clip->dist;
if (d0 >= 0)
{
// point 0 is unclipped
if (d1 >= 0)
{
// both points are unclipped
continue;
}
// only point 1 is clipped
// we don't cache clipped edges
cacheoffset = 0x7FFFFFFF;
f = d0 / (d0 - d1);
clipvert.position[0] = pv0->position[0] +
f * (pv1->position[0] - pv0->position[0]);
clipvert.position[1] = pv0->position[1] +
f * (pv1->position[1] - pv0->position[1]);
clipvert.position[2] = pv0->position[2] +
f * (pv1->position[2] - pv0->position[2]);
if (clip->leftedge)
{
r_leftclipped = true;
r_leftexit = clipvert;
}
else if (clip->rightedge)
{
r_rightclipped = true;
r_rightexit = clipvert;
}
R_ClipEdge (pv0, &clipvert, clip->next);
return;
}
else
{
// point 0 is clipped
if (d1 < 0)
{
// both points are clipped
// we do cache fully clipped edges
if (!r_leftclipped)
cacheoffset = FULLY_CLIPPED_CACHED |
(r_framecount & FRAMECOUNT_MASK);
return;
}
// only point 0 is clipped
r_lastvertvalid = false;
// we don't cache partially clipped edges
cacheoffset = 0x7FFFFFFF;
f = d0 / (d0 - d1);
clipvert.position[0] = pv0->position[0] +
f * (pv1->position[0] - pv0->position[0]);
clipvert.position[1] = pv0->position[1] +
f * (pv1->position[1] - pv0->position[1]);
clipvert.position[2] = pv0->position[2] +
f * (pv1->position[2] - pv0->position[2]);
if (clip->leftedge)
{
r_leftclipped = true;
r_leftenter = clipvert;
}
else if (clip->rightedge)
{
r_rightclipped = true;
r_rightenter = clipvert;
}
R_ClipEdge (&clipvert, pv1, clip->next);
return;
}
} while ((clip = clip->next) != NULL);
}
// add the edge
R_EmitEdge (pv0, pv1);
}
#endif // !id386
/*
================
R_EmitCachedEdge
================
*/
void R_EmitCachedEdge (void)
{
edge_t *pedge_t;
pedge_t = (edge_t *)((unsigned long)r_edges + r_pedge->cachededgeoffset);
if (!pedge_t->surfs[0])
pedge_t->surfs[0] = surface_p - surfaces;
else
pedge_t->surfs[1] = surface_p - surfaces;
if (pedge_t->nearzi > r_nearzi) // for mipmap finding
r_nearzi = pedge_t->nearzi;
r_emitted = 1;
}
/*
================
R_RenderFace
================
*/
void R_RenderFace (msurface_t *fa, int clipflags)
{
extern float r_wateralphaval;
int i, lindex;
unsigned mask;
mplane_t *pplane;
float distinv;
vec3_t p_normal;
medge_t *pedges, tedge;
clipplane_t *pclip;
if (fa->texinfo->texture && (fa->texinfo->flags & (SURF_ALPHATEST|SURF_TRANS33|SURF_TRANS66)))
{
if (fa->nextalphasurface)
return;
fa->nextalphasurface = r_alpha_surfaces;
r_alpha_surfaces = fa;
return;
}
if (r_wateralphaval != 1.0 && fa->flags & SURF_DRAWTURB)
{
if (fa->nextalphasurface)
return;
fa->nextalphasurface = r_alpha_surfaces;
r_alpha_surfaces = fa;
return;
}
if ( fa->texinfo->flags & SURF_SKY)
{
if (R_EmitSkyBox ())
return;
}
// skip out if no more surfs
if ((surface_p) >= surf_max)
{
r_outofsurfaces++;
return;
}
// ditto if not enough edges left, or switch to auxedges if possible
if ((edge_p + fa->numedges + 4) >= edge_max)
{
r_outofedges += fa->numedges;
return;
}
c_faceclip++;
// set up clip planes
pclip = NULL;
for (i=3, mask = 0x08 ; i>=0 ; i--, mask >>= 1)
{
if (clipflags & mask)
{
view_clipplanes[i].next = pclip;
pclip = &view_clipplanes[i];
}
}
// push the edges through
r_emitted = 0;
r_nearzi = 0;
r_nearzionly = false;
makeleftedge = makerightedge = false;
pedges = currententity->model->edges;
r_lastvertvalid = false;
for (i=0 ; i<fa->numedges ; i++)
{
lindex = currententity->model->surfedges[fa->firstedge + i];
if (lindex > 0)
{
r_pedge = &pedges[lindex];
// if the edge is cached, we can just reuse the edge
if (!insubmodel)
{
if (r_pedge->cachededgeoffset & FULLY_CLIPPED_CACHED)
{
if ((r_pedge->cachededgeoffset & FRAMECOUNT_MASK) ==
r_framecount)
{
r_lastvertvalid = false;
continue;
}
}
else
{
if ((((unsigned long)edge_p - (unsigned long)r_edges) >
r_pedge->cachededgeoffset) &&
(((edge_t *)((unsigned long)r_edges +
r_pedge->cachededgeoffset))->owner == r_pedge))
{
R_EmitCachedEdge ();
r_lastvertvalid = false;
continue;
}
}
}
// assume it's cacheable
cacheoffset = (qbyte *)edge_p - (qbyte *)r_edges;
r_leftclipped = r_rightclipped = false;
R_ClipEdge (&r_pcurrentvertbase[r_pedge->v[0]],
&r_pcurrentvertbase[r_pedge->v[1]],
pclip);
r_pedge->cachededgeoffset = cacheoffset;
if (r_leftclipped)
makeleftedge = true;
if (r_rightclipped)
makerightedge = true;
r_lastvertvalid = true;
}
else
{
lindex = -lindex;
r_pedge = &pedges[lindex];
// if the edge is cached, we can just reuse the edge
if (!insubmodel)
{
if (r_pedge->cachededgeoffset & FULLY_CLIPPED_CACHED)
{
if ((r_pedge->cachededgeoffset & FRAMECOUNT_MASK) ==
r_framecount)
{
r_lastvertvalid = false;
continue;
}
}
else
{
// it's cached if the cached edge is valid and is owned
// by this medge_t
if ((((unsigned long)edge_p - (unsigned long)r_edges) >
r_pedge->cachededgeoffset) &&
(((edge_t *)((unsigned long)r_edges +
r_pedge->cachededgeoffset))->owner == r_pedge))
{
R_EmitCachedEdge ();
r_lastvertvalid = false;
continue;
}
}
}
// assume it's cacheable
cacheoffset = (qbyte *)edge_p - (qbyte *)r_edges;
r_leftclipped = r_rightclipped = false;
R_ClipEdge (&r_pcurrentvertbase[r_pedge->v[1]],
&r_pcurrentvertbase[r_pedge->v[0]],
pclip);
r_pedge->cachededgeoffset = cacheoffset;
if (r_leftclipped)
makeleftedge = true;
if (r_rightclipped)
makerightedge = true;
r_lastvertvalid = true;
}
}
// if there was a clip off the left edge, add that edge too
// FIXME: faster to do in screen space?
// FIXME: share clipped edges?
if (makeleftedge)
{
r_pedge = &tedge;
r_lastvertvalid = false;
R_ClipEdge (&r_leftexit, &r_leftenter, pclip->next);
}
// if there was a clip off the right edge, get the right r_nearzi
if (makerightedge)
{
r_pedge = &tedge;
r_lastvertvalid = false;
r_nearzionly = true;
R_ClipEdge (&r_rightexit, &r_rightenter, view_clipplanes[1].next);
}
// if no edges made it out, return without posting the surface
if (!r_emitted)
return;
r_polycount++;
surface_p->data = (void *)fa;
surface_p->nearzi = r_nearzi;
surface_p->flags = fa->flags;
surface_p->insubmodel = insubmodel;
surface_p->spanstate = 0;
surface_p->entity = currententity;
surface_p->key = r_currentkey++;
surface_p->spans = NULL;
pplane = fa->plane;
// FIXME: cache this?
TransformVector (pplane->normal, p_normal);
// FIXME: cache this?
distinv = 1.0 / (pplane->dist - DotProduct (modelorg, pplane->normal));
surface_p->d_zistepu = p_normal[0] * xscaleinv * distinv;
surface_p->d_zistepv = -p_normal[1] * yscaleinv * distinv;
surface_p->d_ziorigin = p_normal[2] * distinv -
xcenter * surface_p->d_zistepu -
ycenter * surface_p->d_zistepv;
//JDC VectorCopy (r_worldmodelorg, surface_p->modelorg);
surface_p++;
}
/*
================
R_RenderBmodelFace
================
*/
void R_RenderBmodelFace (bedge_t *pedges, msurface_t *psurf)
{
int i;
unsigned mask;
mplane_t *pplane;
float distinv;
vec3_t p_normal;
medge_t tedge;
clipplane_t *pclip;
// skip out if no more surfs
if (surface_p >= surf_max)
{
r_outofsurfaces++;
return;
}
if (psurf->texinfo->flags & (SURF_TRANS33|SURF_TRANS66|SURF_ALPHATEST))
{
if (psurf->nextalphasurface)
return;
psurf->nextalphasurface = r_alpha_surfaces;
r_alpha_surfaces = psurf;
return;
}
// ditto if not enough edges left, or switch to auxedges if possible
if ((edge_p + psurf->numedges + 4) >= edge_max)
{
r_outofedges += psurf->numedges;
return;
}
c_faceclip++;
// this is a dummy to give the caching mechanism someplace to write to
r_pedge = &tedge;
// set up clip planes
pclip = NULL;
for (i=3, mask = 0x08 ; i>=0 ; i--, mask >>= 1)
{
if (r_clipflags & mask)
{
view_clipplanes[i].next = pclip;
pclip = &view_clipplanes[i];
}
}
// push the edges through
r_emitted = 0;
r_nearzi = 0;
r_nearzionly = false;
makeleftedge = makerightedge = false;
// FIXME: keep clipped bmodel edges in clockwise order so last vertex caching
// can be used?
r_lastvertvalid = false;
for ( ; pedges ; pedges = pedges->pnext)
{
r_leftclipped = r_rightclipped = false;
R_ClipEdge (pedges->v[0], pedges->v[1], pclip);
if (r_leftclipped)
makeleftedge = true;
if (r_rightclipped)
makerightedge = true;
}
// if there was a clip off the left edge, add that edge too
// FIXME: faster to do in screen space?
// FIXME: share clipped edges?
if (makeleftedge)
{
r_pedge = &tedge;
R_ClipEdge (&r_leftexit, &r_leftenter, pclip->next);
}
// if there was a clip off the right edge, get the right r_nearzi
if (makerightedge)
{
r_pedge = &tedge;
r_nearzionly = true;
R_ClipEdge (&r_rightexit, &r_rightenter, view_clipplanes[1].next);
}
// if no edges made it out, return without posting the surface
if (!r_emitted)
return;
r_polycount++;
surface_p->data = (void *)psurf;
surface_p->nearzi = r_nearzi;
surface_p->flags = psurf->flags;
surface_p->insubmodel = true;
surface_p->spanstate = 0;
surface_p->entity = currententity;
surface_p->key = r_currentbkey;
surface_p->spans = NULL;
pplane = psurf->plane;
// FIXME: cache this?
TransformVector (pplane->normal, p_normal);
// FIXME: cache this?
distinv = 1.0 / (pplane->dist - DotProduct (modelorg, pplane->normal));
surface_p->d_zistepu = p_normal[0] * xscaleinv * distinv;
surface_p->d_zistepv = -p_normal[1] * yscaleinv * distinv;
surface_p->d_ziorigin = p_normal[2] * distinv -
xcenter * surface_p->d_zistepu -
ycenter * surface_p->d_zistepv;
//JDC VectorCopy (r_worldmodelorg, surface_p->modelorg);
surface_p++;
}
/*
================
R_RenderPoly
================
*/
void R_RenderPoly (msurface_t *fa, int clipflags)
{
int i, lindex, lnumverts, s_axis, t_axis;
float dist, lastdist, lzi, scale, u, v, frac;
unsigned mask;
vec3_t local, transformed;
clipplane_t *pclip;
medge_t *pedges;
mplane_t *pplane;
mvertex_t verts[2][100]; //FIXME: do real number
polyvert_t pverts[100]; //FIXME: do real number, safely
int vertpage, newverts, newpage, lastvert;
qboolean visible;
// FIXME: clean this up and make it faster
// FIXME: guard against running out of vertices
s_axis = t_axis = 0; // keep compiler happy
// set up clip planes
pclip = NULL;
for (i=3, mask = 0x08 ; i>=0 ; i--, mask >>= 1)
{
if (clipflags & mask)
{
view_clipplanes[i].next = pclip;
pclip = &view_clipplanes[i];
}
}
// reconstruct the polygon
// FIXME: these should be precalculated and loaded off disk
pedges = currententity->model->edges;
lnumverts = fa->numedges;
vertpage = 0;
for (i=0 ; i<lnumverts ; i++)
{
lindex = currententity->model->surfedges[fa->firstedge + i];
if (lindex > 0)
{
r_pedge = &pedges[lindex];
verts[0][i] = r_pcurrentvertbase[r_pedge->v[0]];
}
else
{
r_pedge = &pedges[-lindex];
verts[0][i] = r_pcurrentvertbase[r_pedge->v[1]];
}
}
// clip the polygon, done if not visible
while (pclip)
{
lastvert = lnumverts - 1;
lastdist = DotProduct (verts[vertpage][lastvert].position,
pclip->normal) - pclip->dist;
visible = false;
newverts = 0;
newpage = vertpage ^ 1;
for (i=0 ; i<lnumverts ; i++)
{
dist = DotProduct (verts[vertpage][i].position, pclip->normal) -
pclip->dist;
if ((lastdist > 0) != (dist > 0))
{
frac = dist / (dist - lastdist);
verts[newpage][newverts].position[0] =
verts[vertpage][i].position[0] +
((verts[vertpage][lastvert].position[0] -
verts[vertpage][i].position[0]) * frac);
verts[newpage][newverts].position[1] =
verts[vertpage][i].position[1] +
((verts[vertpage][lastvert].position[1] -
verts[vertpage][i].position[1]) * frac);
verts[newpage][newverts].position[2] =
verts[vertpage][i].position[2] +
((verts[vertpage][lastvert].position[2] -
verts[vertpage][i].position[2]) * frac);
newverts++;
}
if (dist >= 0)
{
verts[newpage][newverts] = verts[vertpage][i];
newverts++;
visible = true;
}
lastvert = i;
lastdist = dist;
}
if (!visible || (newverts < 3))
return;
lnumverts = newverts;
vertpage ^= 1;
pclip = pclip->next;
}
// transform and project, remembering the z values at the vertices and
// r_nearzi, and extract the s and t coordinates at the vertices
pplane = fa->plane;
switch (pplane->type)
{
case PLANE_X:
case PLANE_ANYX:
s_axis = 1;
t_axis = 2;
break;
case PLANE_Y:
case PLANE_ANYY:
s_axis = 0;
t_axis = 2;
break;
case PLANE_Z:
case PLANE_ANYZ:
s_axis = 0;
t_axis = 1;
break;
}
r_nearzi = 0;
for (i=0 ; i<lnumverts ; i++)
{
// transform and project
VectorSubtract (verts[vertpage][i].position, modelorg, local);
TransformVector (local, transformed);
if (transformed[2] < NEAR_CLIP)
transformed[2] = NEAR_CLIP;
lzi = 1.0 / transformed[2];
if (lzi > r_nearzi) // for mipmap finding
r_nearzi = lzi;
// FIXME: build x/yscale into transform?
scale = xscale * lzi;
u = (xcenter + scale*transformed[0]);
if (u < r_refdef.fvrectx_adj)
u = r_refdef.fvrectx_adj;
if (u > r_refdef.fvrectright_adj)
u = r_refdef.fvrectright_adj;
scale = yscale * lzi;
v = (ycenter - scale*transformed[1]);
if (v < r_refdef.fvrecty_adj)
v = r_refdef.fvrecty_adj;
if (v > r_refdef.fvrectbottom_adj)
v = r_refdef.fvrectbottom_adj;
pverts[i].u = u;
pverts[i].v = v;
pverts[i].zi = lzi;
pverts[i].s = verts[vertpage][i].position[s_axis];
pverts[i].t = verts[vertpage][i].position[t_axis];
}
// build the polygon descriptor, including fa, r_nearzi, and u, v, s, t, and z
// for each vertex
r_polydesc.numverts = lnumverts;
r_polydesc.nearzi = r_nearzi;
r_polydesc.pcurrentface = fa;
r_polydesc.pverts = pverts;
// draw the polygon
D_DrawPoly ();
}
/*
================
R_ZDrawSubmodelPolys
================
*/
void R_ZDrawSubmodelPolys (model_t *pmodel)
{
int i, numsurfaces;
msurface_t *psurf;
float dot;
mplane_t *pplane;
psurf = &pmodel->surfaces[pmodel->firstmodelsurface];
numsurfaces = pmodel->nummodelsurfaces;
for (i=0 ; i<numsurfaces ; i++, psurf++)
{
// find which side of the node we are on
pplane = psurf->plane;
dot = DotProduct (modelorg, pplane->normal) - pplane->dist;
// draw the polygon
if (((psurf->flags & SURF_PLANEBACK) && (dot < -BACKFACE_EPSILON)) ||
(!(psurf->flags & SURF_PLANEBACK) && (dot > BACKFACE_EPSILON)))
{
// FIXME: use bounding-box-based frustum clipping info?
R_RenderPoly (psurf, 15);
}
}
}
//this code from Quake2
typedef struct
{
int nump;
emitpoint_t *pverts;
qbyte *pixels; // image
int pixel_width; // image width
int pixel_height; // image height
vec3_t vup, vright, vpn; // in worldspace, for plane eq
float dist;
float s_offset, t_offset;
float viewer_position[3];
void (*drawspanlet)( void );
int stipple_parity;
int alpha;
} q2polydesc_t;
q2polydesc_t r_q2polydesc;
static espan_t *s_polygon_spans;
static int clip_current;
static int s_minindex, s_maxindex;
vec5_t r_clip_verts[2][MAXWORKINGVERTS+2];
model_t *currentmodel;
#define AFFINE_SPANLET_SIZE 16
#define AFFINE_SPANLET_SIZE_BITS 4
typedef struct
{
qbyte *pbase, *pdest;
short *pz;
fixed16_t s, t;
fixed16_t sstep, tstep;
int izi, izistep, izistep_times_2;
int spancount;
unsigned u, v;
} spanletvars_t;
spanletvars_t s_spanletvars;
void R_DrawSpanletConstant( void )
{
do
{
if (*s_spanletvars.pz <= (s_spanletvars.izi >> 16))
{
*s_spanletvars.pdest = 15;//r_polyblendcolor;
}
s_spanletvars.izi += s_spanletvars.izistep;
s_spanletvars.pdest++;
s_spanletvars.pz++;
} while (--s_spanletvars.spancount > 0);
}
void R_16DrawSpanlet33Stipple( void )
{
unsigned btemp;
unsigned short *pdest = (unsigned short *)s_spanletvars.pdest;
short *pz = s_spanletvars.pz;
int izi = s_spanletvars.izi;
if ( r_q2polydesc.stipple_parity ^ ( s_spanletvars.v & 1 ) )
{
s_spanletvars.pdest += s_spanletvars.spancount;
s_spanletvars.pz += s_spanletvars.spancount;
if ( s_spanletvars.spancount == AFFINE_SPANLET_SIZE )
s_spanletvars.izi += s_spanletvars.izistep << AFFINE_SPANLET_SIZE_BITS;
else
s_spanletvars.izi += s_spanletvars.izistep * s_spanletvars.izistep;
if ( r_q2polydesc.stipple_parity ^ ( s_spanletvars.u & 1 ) )
{
izi += s_spanletvars.izistep;
s_spanletvars.s += s_spanletvars.sstep;
s_spanletvars.t += s_spanletvars.tstep;
pdest++;
pz++;
s_spanletvars.spancount--;
}
s_spanletvars.sstep *= 2;
s_spanletvars.tstep *= 2;
while ( s_spanletvars.spancount > 0 )
{
unsigned s = s_spanletvars.s >> 16;
unsigned t = s_spanletvars.t >> 16;
btemp = *( s_spanletvars.pbase + ( s ) + ( t * cachewidth ) );
if ( btemp != 255 )
{
if ( *pz <= ( izi >> 16 ) )
*pdest = btemp;
}
izi += s_spanletvars.izistep_times_2;
s_spanletvars.s += s_spanletvars.sstep;
s_spanletvars.t += s_spanletvars.tstep;
pdest += 2;
pz += 2;
s_spanletvars.spancount -= 2;
}
}
}
void R_8DrawSpanletAlphaTest( void ) //8 bit rendering only
{
unsigned btemp;
do
{
unsigned ts, tt;
ts = s_spanletvars.s >> 16;
tt = s_spanletvars.t >> 16;
btemp = *(s_spanletvars.pbase + (ts) + (tt) * cachewidth);
if ( btemp != 255 )
{
if (*s_spanletvars.pz <= (s_spanletvars.izi >> 16))
{
*s_spanletvars.pdest = btemp;
}
}
s_spanletvars.izi += s_spanletvars.izistep;
s_spanletvars.pdest++;
s_spanletvars.pz++;
s_spanletvars.s += s_spanletvars.sstep;
s_spanletvars.t += s_spanletvars.tstep;
} while (--s_spanletvars.spancount > 0);
}
void R_8DrawSpanletAlphaBlend( void ) //8 bit rendering only
{
unsigned btemp;
D_SetTransLevel(r_q2polydesc.alpha/255.0, BM_BLEND);
do
{
unsigned ts, tt;
ts = s_spanletvars.s >> 16;
tt = s_spanletvars.t >> 16;
btemp = *(s_spanletvars.pbase + (ts) + (tt) * cachewidth);
if ( btemp != 255 )
{
if (*s_spanletvars.pz <= (s_spanletvars.izi >> 16))
{
*s_spanletvars.pdest = Trans(*s_spanletvars.pdest, btemp);
}
}
s_spanletvars.izi += s_spanletvars.izistep;
s_spanletvars.pdest++;
s_spanletvars.pz++;
s_spanletvars.s += s_spanletvars.sstep;
s_spanletvars.t += s_spanletvars.tstep;
} while (--s_spanletvars.spancount > 0);
}
void R_8DrawSpanletTurbulentAlphaBlend( void )
{
extern int *r_turb_turb;
unsigned btemp;
D_SetTransLevel(r_q2polydesc.alpha/255.0, BM_BLEND);
do
{
unsigned ts, tt;
ts = ((s_spanletvars.s + r_turb_turb[(s_spanletvars.t>>16)&(CYCLE-1)])>>16)&63;
tt = ((s_spanletvars.t + r_turb_turb[(s_spanletvars.s>>16)&(CYCLE-1)])>>16)&63;
btemp = *(s_spanletvars.pbase + (ts) + (tt) * cachewidth);
if ( btemp != 255 )
{
if (*s_spanletvars.pz <= (s_spanletvars.izi >> 16))
{
*s_spanletvars.pdest = Trans(*s_spanletvars.pdest, btemp);
}
}
s_spanletvars.izi += s_spanletvars.izistep;
s_spanletvars.pdest++;
s_spanletvars.pz++;
s_spanletvars.s += s_spanletvars.sstep;
s_spanletvars.t += s_spanletvars.tstep;
} while (--s_spanletvars.spancount > 0);
}
void R_16DrawSpanletAlphaTest( void ) //16 bit rendering only
{
unsigned btemp;
do
{
unsigned ts, tt;
ts = s_spanletvars.s >> 16;
tt = s_spanletvars.t >> 16;
btemp = *(s_spanletvars.pbase + (ts) + (tt) * cachewidth);
if ( btemp != 255 )
{
if (*s_spanletvars.pz <= (s_spanletvars.izi >> 16))
{
*s_spanletvars.pdest = btemp;
}
}
s_spanletvars.izi += s_spanletvars.izistep;
s_spanletvars.pdest++;
s_spanletvars.pz++;
s_spanletvars.s += s_spanletvars.sstep;
s_spanletvars.t += s_spanletvars.tstep;
} while (--s_spanletvars.spancount > 0);
}
void R_32DrawSpanletAlphaTest( void )
{
unsigned btemp;
do
{
unsigned ts, tt;
ts = s_spanletvars.s >> 16;
tt = s_spanletvars.t >> 16;
btemp = *((int *)s_spanletvars.pbase + (ts) + (tt) * cachewidth);
if ( btemp &0xff000000 )
{
if (*s_spanletvars.pz <= (s_spanletvars.izi >> 16))
{
*(int*)s_spanletvars.pdest = btemp;
}
}
s_spanletvars.izi += s_spanletvars.izistep;
s_spanletvars.pdest+=4;
s_spanletvars.pz++;
s_spanletvars.s += s_spanletvars.sstep;
s_spanletvars.t += s_spanletvars.tstep;
} while (--s_spanletvars.spancount > 0);
}
void R_32DrawSpanletBlended( void )
{
unsigned *btemp;
do
{
unsigned ts, tt;
ts = s_spanletvars.s >> 16;
tt = s_spanletvars.t >> 16;
btemp = ((unsigned int *)s_spanletvars.pbase + (ts) + (tt) * cachewidth);
if ( ((qbyte *)btemp)[3] )
{
if (*s_spanletvars.pz <= (s_spanletvars.izi >> 16))
{
((qbyte *)s_spanletvars.pdest)[0] = (((qbyte *)s_spanletvars.pdest)[0]*(255-r_q2polydesc.alpha) + ((qbyte *)btemp)[2]*r_q2polydesc.alpha)/255;
((qbyte *)s_spanletvars.pdest)[1] = (((qbyte *)s_spanletvars.pdest)[1]*(255-r_q2polydesc.alpha) + ((qbyte *)btemp)[1]*r_q2polydesc.alpha)/255;
((qbyte *)s_spanletvars.pdest)[2] = (((qbyte *)s_spanletvars.pdest)[2]*(255-r_q2polydesc.alpha) + ((qbyte *)btemp)[0]*r_q2polydesc.alpha)/255;
}
}
s_spanletvars.izi += s_spanletvars.izistep;
s_spanletvars.pdest+=4;
s_spanletvars.pz++;
s_spanletvars.s += s_spanletvars.sstep;
s_spanletvars.t += s_spanletvars.tstep;
} while (--s_spanletvars.spancount > 0);
}
void R_32DrawSpanletTurbulentBlended( void )
{
extern int *r_turb_turb;
unsigned *btemp;
int sturb, tturb;
do
{
sturb = ((s_spanletvars.s + r_turb_turb[(s_spanletvars.t>>16)&(CYCLE-1)])>>16)&63;
tturb = ((s_spanletvars.t + r_turb_turb[(s_spanletvars.s>>16)&(CYCLE-1)])>>16)&63;
btemp = ( (int *)s_spanletvars.pbase + ( sturb ) + ( tturb << 6 ) );
if ( *s_spanletvars.pz <= ( s_spanletvars.izi >> 16 ) )
{
((qbyte *)s_spanletvars.pdest)[0] = (((qbyte *)s_spanletvars.pdest)[0]*(255-r_q2polydesc.alpha) + ((qbyte *)btemp)[2]*r_q2polydesc.alpha)/255;
((qbyte *)s_spanletvars.pdest)[1] = (((qbyte *)s_spanletvars.pdest)[1]*(255-r_q2polydesc.alpha) + ((qbyte *)btemp)[1]*r_q2polydesc.alpha)/255;
((qbyte *)s_spanletvars.pdest)[2] = (((qbyte *)s_spanletvars.pdest)[2]*(255-r_q2polydesc.alpha) + ((qbyte *)btemp)[0]*r_q2polydesc.alpha)/255;
}
s_spanletvars.izi += s_spanletvars.izistep;
s_spanletvars.pdest+=4;
s_spanletvars.pz++;
s_spanletvars.s += s_spanletvars.sstep;
s_spanletvars.t += s_spanletvars.tstep;
} while ( --s_spanletvars.spancount > 0 );
}
/*
** R_DrawSpanlet66Stipple
*/
void R_16DrawSpanlet66Stipple( void )
{
unsigned btemp;
unsigned short *pdest = (unsigned short *)s_spanletvars.pdest;
short *pz = s_spanletvars.pz;
int izi = s_spanletvars.izi;
s_spanletvars.pdest += s_spanletvars.spancount<<1;
s_spanletvars.pz += s_spanletvars.spancount;
if ( s_spanletvars.spancount == AFFINE_SPANLET_SIZE )
s_spanletvars.izi += s_spanletvars.izistep << AFFINE_SPANLET_SIZE_BITS;
else
s_spanletvars.izi += s_spanletvars.izistep * s_spanletvars.izistep;
if ( r_q2polydesc.stipple_parity ^ ( s_spanletvars.v & 1 ) )
{
if ( r_q2polydesc.stipple_parity ^ ( s_spanletvars.u & 1 ) )
{
izi += s_spanletvars.izistep;
s_spanletvars.s += s_spanletvars.sstep;
s_spanletvars.t += s_spanletvars.tstep;
pdest++;
pz++;
s_spanletvars.spancount--;
}
s_spanletvars.sstep *= 2;
s_spanletvars.tstep *= 2;
while ( s_spanletvars.spancount > 0 )
{
unsigned s = s_spanletvars.s >> 16;
unsigned t = s_spanletvars.t >> 16;
btemp = vid.colormap16[*( s_spanletvars.pbase + ( s ) + ( t * cachewidth ) )];
if ( btemp != 255 )
{
if ( *pz <= ( izi >> 16 ) )
*pdest = btemp;
}
izi += s_spanletvars.izistep_times_2;
s_spanletvars.s += s_spanletvars.sstep;
s_spanletvars.t += s_spanletvars.tstep;
pdest += 2;
pz += 2;
s_spanletvars.spancount -= 2;
}
}
else
{
while ( s_spanletvars.spancount > 0 )
{
unsigned s = s_spanletvars.s >> 16;
unsigned t = s_spanletvars.t >> 16;
btemp = s+t;//vid.colormap16[*( s_spanletvars.pbase + ( s ) + ( t * cachewidth ) )];
if ( btemp != 255 )
{
if ( *pz <= ( izi >> 16 ) )
*pdest = btemp;
}
izi += s_spanletvars.izistep;
s_spanletvars.s += s_spanletvars.sstep;
s_spanletvars.t += s_spanletvars.tstep;
pdest++;
pz++;
s_spanletvars.spancount--;
}
}
}
/*
** R_PolygonDrawSpans
*/
// PGM - iswater was qboolean. changed to allow passing more flags
void R_PolygonDrawSpans(espan_t *pspan, int iswater )
{
extern int *r_turb_turb;
int count;
fixed16_t snext, tnext;
float sdivz, tdivz, zi, z, du, dv, spancountminus1;
float sdivzspanletstepu, tdivzspanletstepu, zispanletstepu;
s_spanletvars.pbase = cacheblock;
//PGM
// if ( iswater & SURF_WARP)
r_turb_turb = sintable + ((int)(cl.time*SPEED)&(CYCLE-1));
// else if (iswater & SURF_FLOWING)
// r_turb_turb = blanktable;
//PGM
sdivzspanletstepu = d_sdivzstepu * AFFINE_SPANLET_SIZE;
tdivzspanletstepu = d_tdivzstepu * AFFINE_SPANLET_SIZE;
zispanletstepu = d_zistepu * AFFINE_SPANLET_SIZE;
// we count on FP exceptions being turned off to avoid range problems
s_spanletvars.izistep = (int)(d_zistepu * 0x8000 * 0x10000);
s_spanletvars.izistep_times_2 = s_spanletvars.izistep * 2;
s_spanletvars.pz = 0;
do
{
s_spanletvars.pdest = (qbyte *)d_viewbuffer + r_pixbytes*( d_scantable[pspan->v] /*r_screenwidth * pspan->v*/ + pspan->u);
s_spanletvars.pz = d_pzbuffer + (d_zwidth * pspan->v) + pspan->u;
s_spanletvars.u = pspan->u;
s_spanletvars.v = pspan->v;
count = pspan->count;
if (count <= 0)
goto NextSpan;
// calculate the initial s/z, t/z, 1/z, s, and t and clamp
du = (float)pspan->u;
dv = (float)pspan->v;
sdivz = d_sdivzorigin + dv*d_sdivzstepv + du*d_sdivzstepu;
tdivz = d_tdivzorigin + dv*d_tdivzstepv + du*d_tdivzstepu;
zi = d_ziorigin + dv*d_zistepv + du*d_zistepu;
z = (float)0x10000 / zi; // prescale to 16.16 fixed-point
// we count on FP exceptions being turned off to avoid range problems
s_spanletvars.izi = (int)(zi * 0x8000 * 0x10000);
s_spanletvars.s = (int)(sdivz * z) + sadjust;
s_spanletvars.t = (int)(tdivz * z) + tadjust;
if ( !iswater )
{
if (s_spanletvars.s > bbextents)
s_spanletvars.s = bbextents;
else if (s_spanletvars.s < 0)
s_spanletvars.s = 0;
if (s_spanletvars.t > bbextentt)
s_spanletvars.t = bbextentt;
else if (s_spanletvars.t < 0)
s_spanletvars.t = 0;
}
do
{
// calculate s and t at the far end of the span
if (count >= AFFINE_SPANLET_SIZE )
s_spanletvars.spancount = AFFINE_SPANLET_SIZE;
else
s_spanletvars.spancount = count;
count -= s_spanletvars.spancount;
if (count)
{
// calculate s/z, t/z, zi->fixed s and t at far end of span,
// calculate s and t steps across span by shifting
sdivz += sdivzspanletstepu;
tdivz += tdivzspanletstepu;
zi += zispanletstepu;
z = (float)0x10000 / zi; // prescale to 16.16 fixed-point
snext = (int)(sdivz * z) + sadjust;
tnext = (int)(tdivz * z) + tadjust;
if ( !iswater )
{
if (snext > bbextents)
snext = bbextents;
else if (snext < AFFINE_SPANLET_SIZE)
snext = AFFINE_SPANLET_SIZE; // prevent round-off error on <0 steps from
// from causing overstepping & running off the
// edge of the texture
if (tnext > bbextentt)
tnext = bbextentt;
else if (tnext < AFFINE_SPANLET_SIZE)
tnext = AFFINE_SPANLET_SIZE; // guard against round-off error on <0 steps
}
s_spanletvars.sstep = (snext - s_spanletvars.s) >> AFFINE_SPANLET_SIZE_BITS;
s_spanletvars.tstep = (tnext - s_spanletvars.t) >> AFFINE_SPANLET_SIZE_BITS;
}
else
{
// calculate s/z, t/z, zi->fixed s and t at last pixel in span (so
// can't step off polygon), clamp, calculate s and t steps across
// span by division, biasing steps low so we don't run off the
// texture
spancountminus1 = (float)(s_spanletvars.spancount - 1);
sdivz += d_sdivzstepu * spancountminus1;
tdivz += d_tdivzstepu * spancountminus1;
zi += d_zistepu * spancountminus1;
z = (float)0x10000 / zi; // prescale to 16.16 fixed-point
snext = (int)(sdivz * z) + sadjust;
tnext = (int)(tdivz * z) + tadjust;
if ( !iswater )
{
if (snext > bbextents)
snext = bbextents;
else if (snext < AFFINE_SPANLET_SIZE)
snext = AFFINE_SPANLET_SIZE; // prevent round-off error on <0 steps from
// from causing overstepping & running off the
// edge of the texture
if (tnext > bbextentt)
tnext = bbextentt;
else if (tnext < AFFINE_SPANLET_SIZE)
tnext = AFFINE_SPANLET_SIZE; // guard against round-off error on <0 steps
}
if (s_spanletvars.spancount > 1)
{
s_spanletvars.sstep = (snext - s_spanletvars.s) / (s_spanletvars.spancount - 1);
s_spanletvars.tstep = (tnext - s_spanletvars.t) / (s_spanletvars.spancount - 1);
}
}
if ( iswater )
{
s_spanletvars.s = s_spanletvars.s & ((CYCLE<<16)-1);
s_spanletvars.t = s_spanletvars.t & ((CYCLE<<16)-1);
}
r_q2polydesc.drawspanlet();
s_spanletvars.s = snext;
s_spanletvars.t = tnext;
} while (count > 0);
NextSpan:
pspan++;
} while (pspan->count != DS_SPAN_LIST_END);
}
/*
**
** R_PolygonScanLeftEdge
**
** Goes through the polygon and scans the left edge, filling in
** screen coordinate data for the spans
*/
void R_PolygonScanLeftEdge (void)
{
int i, v, itop, ibottom, lmaxindex;
emitpoint_t *pvert, *pnext;
espan_t *pspan;
float du, dv, vtop, vbottom, slope;
fixed16_t u, u_step;
pspan = s_polygon_spans;
i = s_minindex;
if (i == 0)
i = r_q2polydesc.nump;
lmaxindex = s_maxindex;
if (lmaxindex == 0)
lmaxindex = r_q2polydesc.nump;
vtop = ceil (r_q2polydesc.pverts[i].v);
do
{
pvert = &r_q2polydesc.pverts[i];
pnext = pvert - 1;
vbottom = ceil (pnext->v);
if (vtop < vbottom)
{
du = pnext->u - pvert->u;
dv = pnext->v - pvert->v;
slope = du / dv;
u_step = (int)(slope * 0x10000);
// adjust u to ceil the integer portion
u = (int)((pvert->u + (slope * (vtop - pvert->v))) * 0x10000) +
(0x10000 - 1);
itop = (int)vtop;
ibottom = (int)vbottom;
for (v=itop ; v<ibottom ; v++)
{
pspan->u = u >> 16;
pspan->v = v;
u += u_step;
pspan++;
}
}
vtop = vbottom;
i--;
if (i == 0)
i = r_q2polydesc.nump;
} while (i != lmaxindex);
}
/*
** R_PolygonScanRightEdge
**
** Goes through the polygon and scans the right edge, filling in
** count values.
*/
void R_PolygonScanRightEdge (void)
{
int i, v, itop, ibottom;
emitpoint_t *pvert, *pnext;
espan_t *pspan;
float du, dv, vtop, vbottom, slope, uvert, unext, vvert, vnext;
fixed16_t u, u_step;
pspan = s_polygon_spans;
i = s_minindex;
vvert = r_q2polydesc.pverts[i].v;
if (vvert < r_refdef.fvrecty_adj)
vvert = r_refdef.fvrecty_adj;
if (vvert > r_refdef.fvrectbottom_adj)
vvert = r_refdef.fvrectbottom_adj;
vtop = ceil (vvert);
do
{
pvert = &r_q2polydesc.pverts[i];
pnext = pvert + 1;
vnext = pnext->v;
if (vnext < r_refdef.fvrecty_adj)
vnext = r_refdef.fvrecty_adj;
if (vnext > r_refdef.fvrectbottom_adj)
vnext = r_refdef.fvrectbottom_adj;
vbottom = ceil (vnext);
if (vtop < vbottom)
{
uvert = pvert->u;
if (uvert < r_refdef.fvrectx_adj)
uvert = r_refdef.fvrectx_adj;
if (uvert > r_refdef.fvrectright_adj)
uvert = r_refdef.fvrectright_adj;
unext = pnext->u;
if (unext < r_refdef.fvrectx_adj)
unext = r_refdef.fvrectx_adj;
if (unext > r_refdef.fvrectright_adj)
unext = r_refdef.fvrectright_adj;
du = unext - uvert;
dv = vnext - vvert;
slope = du / dv;
u_step = (int)(slope * 0x10000);
// adjust u to ceil the integer portion
u = (int)((uvert + (slope * (vtop - vvert))) * 0x10000) +
(0x10000 - 1);
itop = (int)vtop;
ibottom = (int)vbottom;
for (v=itop ; v<ibottom ; v++)
{
pspan->count = (u >> 16) - pspan->u;
u += u_step;
pspan++;
}
}
vtop = vbottom;
vvert = vnext;
i++;
if (i == r_q2polydesc.nump)
i = 0;
} while (i != s_maxindex);
pspan->count = DS_SPAN_LIST_END; // mark the end of the span list
}
/*
** R_ClipPolyFace
**
** Clips the winding at clip_verts[clip_current] and changes clip_current
** Throws out the back side
*/
int R_ClipPolyFace (int nump, clipplane_t *pclipplane)
{
int i, outcount;
float dists[MAXWORKINGVERTS+3];
float frac, clipdist, *pclipnormal;
float *in, *instep, *outstep, *vert2;
clipdist = pclipplane->dist;
pclipnormal = pclipplane->normal;
// calc dists
if (clip_current)
{
in = r_clip_verts[1][0];
outstep = r_clip_verts[0][0];
clip_current = 0;
}
else
{
in = r_clip_verts[0][0];
outstep = r_clip_verts[1][0];
clip_current = 1;
}
instep = in;
for (i=0 ; i<nump ; i++, instep += sizeof (vec5_t) / sizeof (float))
{
dists[i] = DotProduct (instep, pclipnormal) - clipdist;
}
// handle wraparound case
dists[nump] = dists[0];
memcpy (instep, in, sizeof (vec5_t));
// clip the winding
instep = in;
outcount = 0;
for (i=0 ; i<nump ; i++, instep += sizeof (vec5_t) / sizeof (float))
{
if (dists[i] >= 0)
{
memcpy (outstep, instep, sizeof (vec5_t));
outstep += sizeof (vec5_t) / sizeof (float);
outcount++;
}
if (dists[i] == 0 || dists[i+1] == 0)
continue;
if ( (dists[i] > 0) == (dists[i+1] > 0) )
continue;
// split it into a new vertex
frac = dists[i] / (dists[i] - dists[i+1]);
vert2 = instep + sizeof (vec5_t) / sizeof (float);
outstep[0] = instep[0] + frac*(vert2[0] - instep[0]);
outstep[1] = instep[1] + frac*(vert2[1] - instep[1]);
outstep[2] = instep[2] + frac*(vert2[2] - instep[2]);
outstep[3] = instep[3] + frac*(vert2[3] - instep[3]);
outstep[4] = instep[4] + frac*(vert2[4] - instep[4]);
outstep += sizeof (vec5_t) / sizeof (float);
outcount++;
}
return outcount;
}
void R_PolygonCalculateGradients (void)
{
vec3_t p_normal, p_saxis, p_taxis;
float distinv;
TransformVector (r_q2polydesc.vpn, p_normal);
TransformVector (r_q2polydesc.vright, p_saxis);
TransformVector (r_q2polydesc.vup, p_taxis);
distinv = 1.0 / (-(DotProduct (r_q2polydesc.viewer_position, r_q2polydesc.vpn)) + r_q2polydesc.dist );
d_sdivzstepu = p_saxis[0] * xscaleinv;
d_sdivzstepv = -p_saxis[1] * yscaleinv;
d_sdivzorigin = p_saxis[2] - xcenter * d_sdivzstepu - ycenter * d_sdivzstepv;
d_tdivzstepu = p_taxis[0] * xscaleinv;
d_tdivzstepv = -p_taxis[1] * yscaleinv;
d_tdivzorigin = p_taxis[2] - xcenter * d_tdivzstepu - ycenter * d_tdivzstepv;
d_zistepu = p_normal[0] * xscaleinv * distinv;
d_zistepv = -p_normal[1] * yscaleinv * distinv;
d_ziorigin = p_normal[2] * distinv - xcenter * d_zistepu - ycenter * d_zistepv;
sadjust = (fixed16_t) ( ( DotProduct( r_q2polydesc.viewer_position, r_q2polydesc.vright) + r_q2polydesc.s_offset ) * 0x10000 );
tadjust = (fixed16_t) ( ( DotProduct( r_q2polydesc.viewer_position, r_q2polydesc.vup ) + r_q2polydesc.t_offset ) * 0x10000 );
// -1 (-epsilon) so we never wander off the edge of the texture
bbextents = (r_q2polydesc.pixel_width << 16) - 1;
bbextentt = (r_q2polydesc.pixel_height << 16) - 1;
}
static void R_DrawPoly( int iswater )
{
int i, nump;
float ymin, ymax;
emitpoint_t *pverts;
espan_t spans[MAXHEIGHT+1];
s_polygon_spans = spans;
// find the top and bottom vertices, and make sure there's at least one scan to
// draw
ymin = 999999.9;
ymax = -999999.9;
pverts = r_q2polydesc.pverts;
for (i=0 ; i<r_q2polydesc.nump ; i++)
{
if (pverts->v < ymin)
{
ymin = pverts->v;
s_minindex = i;
}
if (pverts->v > ymax)
{
ymax = pverts->v;
s_maxindex = i;
}
pverts++;
}
ymin = ceil (ymin);
ymax = ceil (ymax);
if (ymin >= ymax)
return; // doesn't cross any scans at all
cachewidth = r_q2polydesc.pixel_width;
cacheblock = r_q2polydesc.pixels;
// copy the first vertex to the last vertex, so we don't have to deal with
// wrapping
nump = r_q2polydesc.nump;
pverts = r_q2polydesc.pverts;
pverts[nump] = pverts[0];
R_PolygonCalculateGradients ();
R_PolygonScanLeftEdge ();
R_PolygonScanRightEdge ();
R_PolygonDrawSpans( s_polygon_spans, iswater );
}
void R_ClipAndDrawPoly ( float alpha, int isturbulent, qboolean textured )
{
emitpoint_t outverts[MAXWORKINGVERTS+3], *pout;
float *pv;
int i, nump;
float scale;
vec3_t transformed, local;
if (r_pixbytes == 4)
{
if (alpha == 1 && !isturbulent)
r_q2polydesc.drawspanlet = R_32DrawSpanletAlphaTest;
else if (alpha <= 0)
return;
else
{
r_q2polydesc.alpha = alpha*255;
if (isturbulent)
r_q2polydesc.drawspanlet = R_32DrawSpanletTurbulentBlended;
else
r_q2polydesc.drawspanlet = R_32DrawSpanletBlended;
}
}
else if (r_pixbytes == 2)
{
if (alpha < 0.2)
return;
else if (alpha < 0.5)
r_q2polydesc.drawspanlet = R_16DrawSpanlet33Stipple;
else if (alpha < 0.9)
r_q2polydesc.drawspanlet = R_16DrawSpanlet66Stipple;
else
r_q2polydesc.drawspanlet = R_16DrawSpanletAlphaTest;
}
else
{
if (alpha >= TRANS_UPPER_CAP)
r_q2polydesc.drawspanlet = R_8DrawSpanletAlphaTest;
else if (alpha <= TRANS_LOWER_CAP)
return;
else if (isturbulent)
{
r_q2polydesc.alpha = alpha*255;
r_q2polydesc.drawspanlet = R_8DrawSpanletTurbulentAlphaBlend;
}
else
{
r_q2polydesc.alpha = alpha*255;
r_q2polydesc.drawspanlet = R_8DrawSpanletAlphaBlend;
}
}
// clip to the frustum in worldspace
nump = r_q2polydesc.nump;
clip_current = 0;
for (i=0 ; i<4 ; i++)
{
nump = R_ClipPolyFace (nump, &view_clipplanes[i]);
if (nump < 3)
return;
if (nump > MAXWORKINGVERTS)
Host_Error("R_ClipAndDrawPoly: too many points: %d", nump );
}
// transform vertices into viewspace and project
pv = &r_clip_verts[clip_current][0][0];
for (i=0 ; i<nump ; i++)
{
VectorSubtract (pv, r_origin, local);
TransformVector (local, transformed);
if (transformed[2] < NEAR_CLIP)
transformed[2] = NEAR_CLIP;
pout = &outverts[i];
pout->zi = 1.0 / transformed[2];
pout->s = pv[3];
pout->t = pv[4];
scale = xscale * pout->zi;
pout->u = (xcenter+0.5 + scale * transformed[0]);
scale = yscale * pout->zi;
pout->v = (ycenter - scale * transformed[1]);
pv += sizeof (vec5_t) / sizeof (pv);
}
// draw it
r_q2polydesc.nump = nump;
r_q2polydesc.pverts = outverts;
R_DrawPoly( isturbulent );
}
void R_BuildPolygonFromSurface(msurface_t *fa)
{
int i, lindex, lnumverts;
medge_t *pedges, *r_pedge;
int vertpage;
float *vec;
vec5_t *pverts;
float tmins[2] = { 0, 0 };
r_q2polydesc.nump = 0;
// reconstruct the polygon
pedges = currentmodel->edges;
lnumverts = fa->numedges;
vertpage = 0;
pverts = r_clip_verts[0];
for (i=0 ; i<lnumverts ; i++)
{
lindex = currentmodel->surfedges[fa->firstedge + i];
if (lindex > 0)
{
r_pedge = &pedges[lindex];
vec = currentmodel->vertexes[r_pedge->v[0]].position;
}
else
{
r_pedge = &pedges[-lindex];
vec = currentmodel->vertexes[r_pedge->v[1]].position;
}
VectorCopy (vec, pverts[i] );
}
VectorCopy( fa->texinfo->vecs[0], r_q2polydesc.vright );
VectorCopy( fa->texinfo->vecs[1], r_q2polydesc.vup );
VectorCopy( fa->plane->normal, r_q2polydesc.vpn );
VectorCopy( r_origin, r_q2polydesc.viewer_position );
if ( fa->flags & SURF_PLANEBACK )
{
VectorNegate( r_q2polydesc.vpn, r_q2polydesc.vpn );
}
// PGM 09/16/98
if ( fa->texinfo->flags & (SURF_WARP|SURF_FLOWING) || (fa->flags & SURF_DRAWTURB) )
{
r_q2polydesc.pixels = (qbyte *)fa->texinfo->texture + fa->texinfo->texture->offsets[0];
r_q2polydesc.pixel_width = fa->texinfo->texture->width;
r_q2polydesc.pixel_height = fa->texinfo->texture->height;
}
// PGM 09/16/98
else
{
surfcache_t *scache;
scache = D_CacheSurface( fa, 0 );
r_q2polydesc.pixels = scache->data;
r_q2polydesc.pixel_width = scache->width;
r_q2polydesc.pixel_height = scache->height;
tmins[0] = fa->texturemins[0];
tmins[1] = fa->texturemins[1];
}
r_q2polydesc.dist = DotProduct( r_q2polydesc.vpn, pverts[0] );
r_q2polydesc.s_offset = fa->texinfo->vecs[0][3] - tmins[0];
r_q2polydesc.t_offset = fa->texinfo->vecs[1][3] - tmins[1];
// scrolling texture addition
if (fa->texinfo->flags & SURF_FLOWING)
{
r_q2polydesc.s_offset += -128 * ( (cl.time*0.25) - (int)(cl.time*0.25) );
}
r_q2polydesc.nump = lnumverts;
}
void SWR_DrawAlphaSurfaces( void )
{
msurface_t *s = r_alpha_surfaces, *os;
currentmodel = r_worldentity.model;
modelorg[0] = -r_origin[0];
modelorg[1] = -r_origin[1];
modelorg[2] = -r_origin[2];
while ( s )
{
R_BuildPolygonFromSurface( s );
if (s->flags & SURF_DRAWTURB)
{
extern float r_wateralphaval;
R_ClipAndDrawPoly( r_wateralphaval, true, true );
}
else if (s->texinfo->flags & SURF_TRANS66)
{
R_ClipAndDrawPoly( 0.66f, (s->texinfo->flags & (SURF_WARP|SURF_FLOWING)), true );
}
else if (s->texinfo->flags & SURF_TRANS33)
{
R_ClipAndDrawPoly( 0.33f, (s->texinfo->flags & (SURF_WARP|SURF_FLOWING)), true );
}
else
R_ClipAndDrawPoly( 1.f, (s->texinfo->flags & (SURF_WARP|SURF_FLOWING)), true );
os = s;
s = s->nextalphasurface;
os->nextalphasurface=NULL;
}
r_alpha_surfaces = NULL;
}
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