ref: 8723be0d01ab4150ed6ca63649a6ec1ddcc06efb
dir: /r_alias.c/
/* 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_alias.c: routines for setting up to draw alias models #include "quakedef.h" #include "r_local.h" #include "d_local.h" // FIXME: shouldn't be needed (is needed for patch // right now, but that should move) #define LIGHT_MIN 5 // lowest light value we'll allow, to avoid the // need for inner-loop light clamping mtriangle_t *ptriangles; affinetridesc_t r_affinetridesc; void * acolormap; // FIXME: should go away trivertx_t *r_apverts; // TODO: these probably will go away with optimized rasterization mdl_t *pmdl; vec3_t r_plightvec; int r_ambientlight; float r_shadelight; aliashdr_t *paliashdr; finalvert_t *pfinalverts; auxvert_t *pauxverts; static float ziscale; static model_t *pmodel; static vec3_t alias_forward, alias_right, alias_up; static maliasskindesc_t *pskindesc; int r_amodels_drawn; int a_skinwidth; int r_anumverts; float aliastransform[3][4]; typedef struct { int index0; int index1; } aedge_t; static aedge_t aedges[12] = { {0, 1}, {1, 2}, {2, 3}, {3, 0}, {4, 5}, {5, 6}, {6, 7}, {7, 4}, {0, 5}, {1, 4}, {2, 7}, {3, 6} }; #define NUMVERTEXNORMALS 162 float r_avertexnormals[NUMVERTEXNORMALS][3] = { #include "anorms.h" }; void R_AliasTransformAndProjectFinalVerts (finalvert_t *fv, stvert_t *pstverts); void R_AliasSetUpTransform (int trivial_accept); void R_AliasTransformVector (vec3_t in, vec3_t out); void R_AliasTransformFinalVert (finalvert_t *fv, auxvert_t *av, trivertx_t *pverts, stvert_t *pstverts); void R_AliasProjectFinalVert (finalvert_t *fv, auxvert_t *av); /* ================ R_AliasCheckBBox ================ */ qboolean R_AliasCheckBBox (void) { int i, flags, frame, numv; aliashdr_t *pahdr; float zi, basepts[8][3], v0, v1, frac; finalvert_t *pv0, *pv1, viewpts[16]; auxvert_t *pa0, *pa1, viewaux[16]; maliasframedesc_t *pframedesc; qboolean zclipped, zfullyclipped; unsigned anyclip, allclip; int minz; // expand, rotate, and translate points into worldspace currententity->trivial_accept = 0; pmodel = currententity->model; pahdr = Mod_Extradata (pmodel); pmdl = (mdl_t *)((byte *)pahdr + pahdr->model); R_AliasSetUpTransform (0); // construct the base bounding box for this frame frame = currententity->frame; // TODO: don't repeat this check when drawing? if ((frame >= pmdl->numframes) || (frame < 0)) { Con_DPrintf ("No such frame %d %s\n", frame, pmodel->name); frame = 0; } pframedesc = &pahdr->frames[frame]; // x worldspace coordinates basepts[0][0] = basepts[1][0] = basepts[2][0] = basepts[3][0] = (float)pframedesc->bboxmin.v[0]; basepts[4][0] = basepts[5][0] = basepts[6][0] = basepts[7][0] = (float)pframedesc->bboxmax.v[0]; // y worldspace coordinates basepts[0][1] = basepts[3][1] = basepts[5][1] = basepts[6][1] = (float)pframedesc->bboxmin.v[1]; basepts[1][1] = basepts[2][1] = basepts[4][1] = basepts[7][1] = (float)pframedesc->bboxmax.v[1]; // z worldspace coordinates basepts[0][2] = basepts[1][2] = basepts[4][2] = basepts[5][2] = (float)pframedesc->bboxmin.v[2]; basepts[2][2] = basepts[3][2] = basepts[6][2] = basepts[7][2] = (float)pframedesc->bboxmax.v[2]; zclipped = false; zfullyclipped = true; minz = 9999; for (i=0; i<8 ; i++) { R_AliasTransformVector (&basepts[i][0], &viewaux[i].fv[0]); if (viewaux[i].fv[2] < ALIAS_Z_CLIP_PLANE) { // we must clip points that are closer than the near clip plane viewpts[i].flags = ALIAS_Z_CLIP; zclipped = true; } else { if (viewaux[i].fv[2] < minz) minz = viewaux[i].fv[2]; viewpts[i].flags = 0; zfullyclipped = false; } } if (zfullyclipped) { return false; // everything was near-z-clipped } numv = 8; if (zclipped) { // organize points by edges, use edges to get new points (possible trivial // reject) for (i=0 ; i<12 ; i++) { // edge endpoints pv0 = &viewpts[aedges[i].index0]; pv1 = &viewpts[aedges[i].index1]; pa0 = &viewaux[aedges[i].index0]; pa1 = &viewaux[aedges[i].index1]; // if one end is clipped and the other isn't, make a new point if (pv0->flags ^ pv1->flags) { frac = (ALIAS_Z_CLIP_PLANE - pa0->fv[2]) / (pa1->fv[2] - pa0->fv[2]); viewaux[numv].fv[0] = pa0->fv[0] + (pa1->fv[0] - pa0->fv[0]) * frac; viewaux[numv].fv[1] = pa0->fv[1] + (pa1->fv[1] - pa0->fv[1]) * frac; viewaux[numv].fv[2] = ALIAS_Z_CLIP_PLANE; viewpts[numv].flags = 0; numv++; } } } // project the vertices that remain after clipping anyclip = 0; allclip = ALIAS_XY_CLIP_MASK; // TODO: probably should do this loop in ASM, especially if we use floats for (i=0 ; i<numv ; i++) { // we don't need to bother with vertices that were z-clipped if (viewpts[i].flags & ALIAS_Z_CLIP) continue; zi = 1.0 / viewaux[i].fv[2]; // FIXME: do with chop mode in ASM, or convert to float v0 = (viewaux[i].fv[0] * xscale * zi) + xcenter; v1 = (viewaux[i].fv[1] * yscale * zi) + ycenter; flags = 0; if (v0 < r_refdef.fvrectx) flags |= ALIAS_LEFT_CLIP; if (v1 < r_refdef.fvrecty) flags |= ALIAS_TOP_CLIP; if (v0 > r_refdef.fvrectright) flags |= ALIAS_RIGHT_CLIP; if (v1 > r_refdef.fvrectbottom) flags |= ALIAS_BOTTOM_CLIP; anyclip |= flags; allclip &= flags; } if (allclip) return false; // trivial reject off one side currententity->trivial_accept = !anyclip & !zclipped; if (currententity->trivial_accept) { if (minz > (r_aliastransition + (pmdl->size * r_resfudge))) { currententity->trivial_accept |= 2; } } return true; } /* ================ R_AliasTransformVector ================ */ void R_AliasTransformVector (vec3_t in, vec3_t out) { out[0] = DotProduct(in, aliastransform[0]) + aliastransform[0][3]; out[1] = DotProduct(in, aliastransform[1]) + aliastransform[1][3]; out[2] = DotProduct(in, aliastransform[2]) + aliastransform[2][3]; } /* ================ R_AliasPreparePoints General clipped case ================ */ void R_AliasPreparePoints (void) { int i; stvert_t *pstverts; finalvert_t *fv; auxvert_t *av; mtriangle_t *ptri; finalvert_t *pfv[3]; pstverts = (stvert_t *)((byte *)paliashdr + paliashdr->stverts); r_anumverts = pmdl->numverts; fv = pfinalverts; av = pauxverts; for (i=0 ; i<r_anumverts ; i++, fv++, av++, r_apverts++, pstverts++) { R_AliasTransformFinalVert (fv, av, r_apverts, pstverts); if (av->fv[2] < ALIAS_Z_CLIP_PLANE) fv->flags |= ALIAS_Z_CLIP; else { R_AliasProjectFinalVert (fv, av); if (fv->v[0] < r_refdef.aliasvrect.x) fv->flags |= ALIAS_LEFT_CLIP; if (fv->v[1] < r_refdef.aliasvrect.y) fv->flags |= ALIAS_TOP_CLIP; if (fv->v[0] > r_refdef.aliasvrectright) fv->flags |= ALIAS_RIGHT_CLIP; if (fv->v[1] > r_refdef.aliasvrectbottom) fv->flags |= ALIAS_BOTTOM_CLIP; } } // // clip and draw all triangles // r_affinetridesc.numtriangles = 1; ptri = (mtriangle_t *)((byte *)paliashdr + paliashdr->triangles); for (i=0 ; i<pmdl->numtris ; i++, ptri++) { pfv[0] = &pfinalverts[ptri->vertindex[0]]; pfv[1] = &pfinalverts[ptri->vertindex[1]]; pfv[2] = &pfinalverts[ptri->vertindex[2]]; if ( pfv[0]->flags & pfv[1]->flags & pfv[2]->flags & (ALIAS_XY_CLIP_MASK | ALIAS_Z_CLIP) ) continue; // completely clipped if ( ! ( (pfv[0]->flags | pfv[1]->flags | pfv[2]->flags) & (ALIAS_XY_CLIP_MASK | ALIAS_Z_CLIP) ) ) { // totally unclipped r_affinetridesc.pfinalverts = pfinalverts; r_affinetridesc.ptriangles = ptri; D_PolysetDraw (); } else { // partially clipped R_AliasClipTriangle (ptri); } } } /* ================ R_AliasSetUpTransform ================ */ void R_AliasSetUpTransform (int trivial_accept) { int i; float rotationmatrix[3][4], t2matrix[3][4]; static float tmatrix[3][4]; static float viewmatrix[3][4]; vec3_t angles; // TODO: should really be stored with the entity instead of being reconstructed // TODO: should use a look-up table // TODO: could cache lazily, stored in the entity angles[ROLL] = currententity->angles[ROLL]; angles[PITCH] = -currententity->angles[PITCH]; angles[YAW] = currententity->angles[YAW]; AngleVectors (angles, alias_forward, alias_right, alias_up); tmatrix[0][0] = pmdl->scale[0]; tmatrix[1][1] = pmdl->scale[1]; tmatrix[2][2] = pmdl->scale[2]; tmatrix[0][3] = pmdl->scale_origin[0]; tmatrix[1][3] = pmdl->scale_origin[1]; tmatrix[2][3] = pmdl->scale_origin[2]; // TODO: can do this with simple matrix rearrangement for (i=0 ; i<3 ; i++) { t2matrix[i][0] = alias_forward[i]; t2matrix[i][1] = -alias_right[i]; t2matrix[i][2] = alias_up[i]; } t2matrix[0][3] = -modelorg[0]; t2matrix[1][3] = -modelorg[1]; t2matrix[2][3] = -modelorg[2]; // FIXME: can do more efficiently than full concatenation R_ConcatTransforms (t2matrix, tmatrix, rotationmatrix); // TODO: should be global, set when vright, etc., set VectorCopy (vright, viewmatrix[0]); VectorCopy (vup, viewmatrix[1]); VectorInverse (viewmatrix[1]); VectorCopy (vpn, viewmatrix[2]); // viewmatrix[0][3] = 0; // viewmatrix[1][3] = 0; // viewmatrix[2][3] = 0; R_ConcatTransforms (viewmatrix, rotationmatrix, aliastransform); // do the scaling up of x and y to screen coordinates as part of the transform // for the unclipped case (it would mess up clipping in the clipped case). // Also scale down z, so 1/z is scaled 31 bits for free, and scale down x and y // correspondingly so the projected x and y come out right // FIXME: make this work for clipped case too? if (trivial_accept) { for (i=0 ; i<4 ; i++) { aliastransform[0][i] *= aliasxscale * (1.0 / ((float)0x8000 * 0x10000)); aliastransform[1][i] *= aliasyscale * (1.0 / ((float)0x8000 * 0x10000)); aliastransform[2][i] *= 1.0 / ((float)0x8000 * 0x10000); } } } /* ================ R_AliasTransformFinalVert ================ */ void R_AliasTransformFinalVert (finalvert_t *fv, auxvert_t *av, trivertx_t *pverts, stvert_t *pstverts) { int temp; float lightcos, *plightnormal; av->fv[0] = DotProduct(pverts->v, aliastransform[0]) + aliastransform[0][3]; av->fv[1] = DotProduct(pverts->v, aliastransform[1]) + aliastransform[1][3]; av->fv[2] = DotProduct(pverts->v, aliastransform[2]) + aliastransform[2][3]; fv->v[2] = pstverts->s; fv->v[3] = pstverts->t; fv->flags = pstverts->onseam; // lighting plightnormal = r_avertexnormals[pverts->lightnormalindex]; lightcos = DotProduct (plightnormal, r_plightvec); temp = r_ambientlight; if (lightcos < 0) { temp += (int)(r_shadelight * lightcos); // clamp; because we limited the minimum ambient and shading light, we // don't have to clamp low light, just bright if (temp < 0) temp = 0; } fv->v[4] = temp; } #if !id386 /* ================ R_AliasTransformAndProjectFinalVerts ================ */ void R_AliasTransformAndProjectFinalVerts (finalvert_t *fv, stvert_t *pstverts) { int i, temp; float lightcos, *plightnormal, zi; trivertx_t *pverts; pverts = r_apverts; for (i=0 ; i<r_anumverts ; i++, fv++, pverts++, pstverts++) { // transform and project zi = 1.0 / (DotProduct(pverts->v, aliastransform[2]) + aliastransform[2][3]); // x, y, and z are scaled down by 1/2**31 in the transform, so 1/z is // scaled up by 1/2**31, and the scaling cancels out for x and y in the // projection fv->v[5] = zi; fv->v[0] = ((DotProduct(pverts->v, aliastransform[0]) + aliastransform[0][3]) * zi) + aliasxcenter; fv->v[1] = ((DotProduct(pverts->v, aliastransform[1]) + aliastransform[1][3]) * zi) + aliasycenter; fv->v[2] = pstverts->s; fv->v[3] = pstverts->t; fv->flags = pstverts->onseam; // lighting plightnormal = r_avertexnormals[pverts->lightnormalindex]; lightcos = DotProduct (plightnormal, r_plightvec); temp = r_ambientlight; if (lightcos < 0) { temp += (int)(r_shadelight * lightcos); // clamp; because we limited the minimum ambient and shading light, we // don't have to clamp low light, just bright if (temp < 0) temp = 0; } fv->v[4] = temp; } } #endif /* ================ R_AliasProjectFinalVert ================ */ void R_AliasProjectFinalVert (finalvert_t *fv, auxvert_t *av) { float zi; // project points zi = 1.0 / av->fv[2]; fv->v[5] = zi * ziscale; fv->v[0] = (av->fv[0] * aliasxscale * zi) + aliasxcenter; fv->v[1] = (av->fv[1] * aliasyscale * zi) + aliasycenter; } /* ================ R_AliasPrepareUnclippedPoints ================ */ void R_AliasPrepareUnclippedPoints (void) { stvert_t *pstverts; finalvert_t *fv; pstverts = (stvert_t *)((byte *)paliashdr + paliashdr->stverts); r_anumverts = pmdl->numverts; // FIXME: just use pfinalverts directly? fv = pfinalverts; R_AliasTransformAndProjectFinalVerts (fv, pstverts); if (r_affinetridesc.drawtype) D_PolysetDrawFinalVerts (fv, r_anumverts); r_affinetridesc.pfinalverts = pfinalverts; r_affinetridesc.ptriangles = (mtriangle_t *) ((byte *)paliashdr + paliashdr->triangles); r_affinetridesc.numtriangles = pmdl->numtris; D_PolysetDraw (); } /* =============== R_AliasSetupSkin =============== */ void R_AliasSetupSkin (void) { int skinnum; int i, numskins; maliasskingroup_t *paliasskingroup; float *pskinintervals, fullskininterval; float skintargettime, skintime; skinnum = currententity->skinnum; if ((skinnum >= pmdl->numskins) || (skinnum < 0)) { Con_DPrintf ("R_AliasSetupSkin: no such skin # %d\n", skinnum); skinnum = 0; } pskindesc = ((maliasskindesc_t *) ((byte *)paliashdr + paliashdr->skindesc)) + skinnum; a_skinwidth = pmdl->skinwidth; if (pskindesc->type == ALIAS_SKIN_GROUP) { paliasskingroup = (maliasskingroup_t *)((byte *)paliashdr + pskindesc->skin); pskinintervals = (float *) ((byte *)paliashdr + paliasskingroup->intervals); numskins = paliasskingroup->numskins; fullskininterval = pskinintervals[numskins-1]; skintime = cl.time + currententity->syncbase; // when loading in Mod_LoadAliasSkinGroup, we guaranteed all interval // values are positive, so we don't have to worry about division by 0 skintargettime = skintime - ((int)(skintime / fullskininterval)) * fullskininterval; for (i=0 ; i<(numskins-1) ; i++) { if (pskinintervals[i] > skintargettime) break; } pskindesc = &paliasskingroup->skindescs[i]; } r_affinetridesc.pskindesc = pskindesc; r_affinetridesc.pskin = (void *)((byte *)paliashdr + pskindesc->skin); r_affinetridesc.skinwidth = a_skinwidth; r_affinetridesc.seamfixupX16 = (a_skinwidth >> 1) << 16; r_affinetridesc.skinheight = pmdl->skinheight; } /* ================ R_AliasSetupLighting ================ */ void R_AliasSetupLighting (alight_t *plighting) { // guarantee that no vertex will ever be lit below LIGHT_MIN, so we don't have // to clamp off the bottom r_ambientlight = plighting->ambientlight; if (r_ambientlight < LIGHT_MIN) r_ambientlight = LIGHT_MIN; r_ambientlight = (255 - r_ambientlight) << VID_CBITS; if (r_ambientlight < LIGHT_MIN) r_ambientlight = LIGHT_MIN; r_shadelight = plighting->shadelight; if (r_shadelight < 0) r_shadelight = 0; r_shadelight *= VID_GRADES; // rotate the lighting vector into the model's frame of reference r_plightvec[0] = DotProduct (plighting->plightvec, alias_forward); r_plightvec[1] = -DotProduct (plighting->plightvec, alias_right); r_plightvec[2] = DotProduct (plighting->plightvec, alias_up); } /* ================= R_AliasSetupFrame set r_apverts ================= */ void R_AliasSetupFrame (void) { int frame; int i, numframes; maliasgroup_t *paliasgroup; float *pintervals, fullinterval, targettime, time; frame = currententity->frame; if ((frame >= pmdl->numframes) || (frame < 0)) { Con_DPrintf ("R_AliasSetupFrame: no such frame %d\n", frame); frame = 0; } if (paliashdr->frames[frame].type == ALIAS_SINGLE) { r_apverts = (trivertx_t *) ((byte *)paliashdr + paliashdr->frames[frame].frame); return; } paliasgroup = (maliasgroup_t *) ((byte *)paliashdr + paliashdr->frames[frame].frame); pintervals = (float *)((byte *)paliashdr + paliasgroup->intervals); numframes = paliasgroup->numframes; fullinterval = pintervals[numframes-1]; time = cl.time + currententity->syncbase; // // when loading in Mod_LoadAliasGroup, we guaranteed all interval values // are positive, so we don't have to worry about division by 0 // targettime = time - ((int)(time / fullinterval)) * fullinterval; for (i=0 ; i<(numframes-1) ; i++) { if (pintervals[i] > targettime) break; } r_apverts = (trivertx_t *) ((byte *)paliashdr + paliasgroup->frames[i].frame); } /* ================ R_AliasDrawModel ================ */ void R_AliasDrawModel (alight_t *plighting) { finalvert_t finalverts[MAXALIASVERTS + ((CACHE_SIZE - 1) / sizeof(finalvert_t)) + 1]; auxvert_t auxverts[MAXALIASVERTS]; r_amodels_drawn++; // cache align pfinalverts = (finalvert_t *) (((long)&finalverts[0] + CACHE_SIZE - 1) & ~(CACHE_SIZE - 1)); pauxverts = &auxverts[0]; paliashdr = (aliashdr_t *)Mod_Extradata (currententity->model); pmdl = (mdl_t *)((byte *)paliashdr + paliashdr->model); R_AliasSetupSkin (); R_AliasSetUpTransform (currententity->trivial_accept); R_AliasSetupLighting (plighting); R_AliasSetupFrame (); if (!currententity->colormap) Sys_Error ("R_AliasDrawModel: !currententity->colormap"); r_affinetridesc.drawtype = (currententity->trivial_accept == 3) && r_recursiveaffinetriangles; if (r_affinetridesc.drawtype) { D_PolysetUpdateTables (); // FIXME: precalc... } else { #if id386 D_Aff8Patch (currententity->colormap); #endif } acolormap = currententity->colormap; if (currententity != &cl.viewent) ziscale = (float)0x8000 * (float)0x10000; else ziscale = (float)0x8000 * (float)0x10000 * 3.0; if (currententity->trivial_accept) R_AliasPrepareUnclippedPoints (); else R_AliasPreparePoints (); }