/* =========================================================================== Copyright (C) 1999-2005 Id Software, Inc. This file is part of Quake III Arena source code. Quake III Arena source code 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. Quake III Arena source code 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 Foobar; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA =========================================================================== */ #include "qbsp.h" #include "../botlib/aasfile.h" #include "aas_create.h" #include "aas_store.h" #include "aas_gsubdiv.h" #include "aas_facemerging.h" #include "aas_areamerging.h" #include "aas_edgemelting.h" #include "aas_prunenodes.h" #include "aas_cfg.h" #include "../qcommon/surfaceflags.h" //#define AW_DEBUG //#define L_DEBUG #define AREAONFACESIDE(face, area) (face->frontarea != area) tmp_aas_t tmpaasworld; //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_InitTmpAAS(void) { //tmp faces tmpaasworld.numfaces = 0; tmpaasworld.facenum = 0; tmpaasworld.faces = NULL; //tmp convex areas tmpaasworld.numareas = 0; tmpaasworld.areanum = 0; tmpaasworld.areas = NULL; //tmp nodes tmpaasworld.numnodes = 0; tmpaasworld.nodes = NULL; // tmpaasworld.nodebuffer = NULL; } //end of the function AAS_InitTmpAAS //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_FreeTmpAAS(void) { tmp_face_t *f, *nextf; tmp_area_t *a, *nexta; tmp_nodebuf_t *nb, *nextnb; //free all the faces for (f = tmpaasworld.faces; f; f = nextf) { nextf = f->l_next; if (f->winding) FreeWinding(f->winding); FreeMemory(f); } //end if //free all tmp areas for (a = tmpaasworld.areas; a; a = nexta) { nexta = a->l_next; if (a->settings) FreeMemory(a->settings); FreeMemory(a); } //end for //free all the tmp nodes for (nb = tmpaasworld.nodebuffer; nb; nb = nextnb) { nextnb = nb->next; FreeMemory(nb); } //end for } //end of the function AAS_FreeTmpAAS //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== tmp_face_t *AAS_AllocTmpFace(void) { tmp_face_t *tmpface; tmpface = (tmp_face_t *) GetClearedMemory(sizeof(tmp_face_t)); tmpface->num = tmpaasworld.facenum++; tmpface->l_prev = NULL; tmpface->l_next = tmpaasworld.faces; if (tmpaasworld.faces) tmpaasworld.faces->l_prev = tmpface; tmpaasworld.faces = tmpface; tmpaasworld.numfaces++; return tmpface; } //end of the function AAS_AllocTmpFace //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_FreeTmpFace(tmp_face_t *tmpface) { if (tmpface->l_next) tmpface->l_next->l_prev = tmpface->l_prev; if (tmpface->l_prev) tmpface->l_prev->l_next = tmpface->l_next; else tmpaasworld.faces = tmpface->l_next; //free the winding if (tmpface->winding) FreeWinding(tmpface->winding); //free the face FreeMemory(tmpface); tmpaasworld.numfaces--; } //end of the function AAS_FreeTmpFace //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== tmp_area_t *AAS_AllocTmpArea(void) { tmp_area_t *tmparea; tmparea = (tmp_area_t *) GetClearedMemory(sizeof(tmp_area_t)); tmparea->areanum = tmpaasworld.areanum++; tmparea->l_prev = NULL; tmparea->l_next = tmpaasworld.areas; if (tmpaasworld.areas) tmpaasworld.areas->l_prev = tmparea; tmpaasworld.areas = tmparea; tmpaasworld.numareas++; return tmparea; } //end of the function AAS_AllocTmpArea //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_FreeTmpArea(tmp_area_t *tmparea) { if (tmparea->l_next) tmparea->l_next->l_prev = tmparea->l_prev; if (tmparea->l_prev) tmparea->l_prev->l_next = tmparea->l_next; else tmpaasworld.areas = tmparea->l_next; if (tmparea->settings) FreeMemory(tmparea->settings); FreeMemory(tmparea); tmpaasworld.numareas--; } //end of the function AAS_FreeTmpArea //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== tmp_node_t *AAS_AllocTmpNode(void) { tmp_nodebuf_t *nodebuf; if (!tmpaasworld.nodebuffer || tmpaasworld.nodebuffer->numnodes >= NODEBUF_SIZE) { nodebuf = (tmp_nodebuf_t *) GetClearedMemory(sizeof(tmp_nodebuf_t)); nodebuf->next = tmpaasworld.nodebuffer; nodebuf->numnodes = 0; tmpaasworld.nodebuffer = nodebuf; } //end if tmpaasworld.numnodes++; return &tmpaasworld.nodebuffer->nodes[tmpaasworld.nodebuffer->numnodes++]; } //end of the function AAS_AllocTmpNode //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_FreeTmpNode(tmp_node_t *tmpnode) { tmpaasworld.numnodes--; } //end of the function AAS_FreeTmpNode //=========================================================================== // returns true if the face is a gap from the given side // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== int AAS_GapFace(tmp_face_t *tmpface, int side) { vec3_t invgravity; //if the face is a solid or ground face it can't be a gap if (tmpface->faceflags & (FACE_GROUND | FACE_SOLID)) return 0; VectorCopy(cfg.phys_gravitydirection, invgravity); VectorInverse(invgravity); return (DotProduct(invgravity, mapplanes[tmpface->planenum ^ side].normal) > cfg.phys_maxsteepness); } //end of the function AAS_GapFace //=========================================================================== // returns true if the face is a ground face // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== int AAS_GroundFace(tmp_face_t *tmpface) { vec3_t invgravity; //must be a solid face if (!(tmpface->faceflags & FACE_SOLID)) return 0; VectorCopy(cfg.phys_gravitydirection, invgravity); VectorInverse(invgravity); return (DotProduct(invgravity, mapplanes[tmpface->planenum].normal) > cfg.phys_maxsteepness); } //end of the function AAS_GroundFace //=========================================================================== // adds the side of a face to an area // // side : 0 = front side // 1 = back side // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_AddFaceSideToArea(tmp_face_t *tmpface, int side, tmp_area_t *tmparea) { int tmpfaceside; if (side) { if (tmpface->backarea) Error("AAS_AddFaceSideToArea: already a back area\n"); } //end if else { if (tmpface->frontarea) Error("AAS_AddFaceSideToArea: already a front area\n"); } //end else if (side) tmpface->backarea = tmparea; else tmpface->frontarea = tmparea; if (tmparea->tmpfaces) { tmpfaceside = tmparea->tmpfaces->frontarea != tmparea; tmparea->tmpfaces->prev[tmpfaceside] = tmpface; } //end if tmpface->next[side] = tmparea->tmpfaces; tmpface->prev[side] = NULL; tmparea->tmpfaces = tmpface; } //end of the function AAS_AddFaceSideToArea //=========================================================================== // remove (a side of) a face from an area // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_RemoveFaceFromArea(tmp_face_t *tmpface, tmp_area_t *tmparea) { int side, prevside, nextside; if (tmpface->frontarea != tmparea && tmpface->backarea != tmparea) { Error("AAS_RemoveFaceFromArea: face not part of the area"); } //end if side = tmpface->frontarea != tmparea; if (tmpface->prev[side]) { prevside = tmpface->prev[side]->frontarea != tmparea; tmpface->prev[side]->next[prevside] = tmpface->next[side]; } //end if else { tmparea->tmpfaces = tmpface->next[side]; } //end else if (tmpface->next[side]) { nextside = tmpface->next[side]->frontarea != tmparea; tmpface->next[side]->prev[nextside] = tmpface->prev[side]; } //end if //remove the area number from the face depending on the side if (side) tmpface->backarea = NULL; else tmpface->frontarea = NULL; tmpface->prev[side] = NULL; tmpface->next[side] = NULL; } //end of the function AAS_RemoveFaceFromArea //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_CheckArea(tmp_area_t *tmparea) { int side; tmp_face_t *face; plane_t *plane; vec3_t wcenter, acenter = {0, 0, 0}; vec3_t normal; float n, dist; if (tmparea->invalid) Log_Print("AAS_CheckArea: invalid area\n"); for (n = 0, face = tmparea->tmpfaces; face; face = face->next[side]) { //side of the face the area is on side = face->frontarea != tmparea; WindingCenter(face->winding, wcenter); VectorAdd(acenter, wcenter, acenter); n++; } //end for n = 1 / n; VectorScale(acenter, n, acenter); for (face = tmparea->tmpfaces; face; face = face->next[side]) { //side of the face the area is on side = face->frontarea != tmparea; #ifdef L_DEBUG if (WindingError(face->winding)) { Log_Write("AAS_CheckArea: area %d face %d: %s\r\n", tmparea->areanum, face->num, WindingErrorString()); } //end if #endif L_DEBUG plane = &mapplanes[face->planenum ^ side]; if (DotProduct(plane->normal, acenter) - plane->dist < 0) { Log_Print("AAS_CheckArea: area %d face %d is flipped\n", tmparea->areanum, face->num); Log_Print("AAS_CheckArea: area %d center is %f %f %f\n", tmparea->areanum, acenter[0], acenter[1], acenter[2]); } //end if //check if the winding plane is the same as the face plane WindingPlane(face->winding, normal, &dist); plane = &mapplanes[face->planenum]; #ifdef L_DEBUG if (fabs(dist - plane->dist) > 0.4 || fabs(normal[0] - plane->normal[0]) > 0.0001 || fabs(normal[1] - plane->normal[1]) > 0.0001 || fabs(normal[2] - plane->normal[2]) > 0.0001) { Log_Write("AAS_CheckArea: area %d face %d winding plane unequal to face plane\r\n", tmparea->areanum, face->num); } //end if #endif L_DEBUG } //end for } //end of the function AAS_CheckArea //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_CheckFaceWindingPlane(tmp_face_t *face) { float dist, sign1, sign2; vec3_t normal; plane_t *plane; winding_t *w; //check if the winding plane is the same as the face plane WindingPlane(face->winding, normal, &dist); plane = &mapplanes[face->planenum]; // sign1 = DotProduct(plane->normal, normal); // if (fabs(dist - plane->dist) > 0.4 || fabs(normal[0] - plane->normal[0]) > 0.0001 || fabs(normal[1] - plane->normal[1]) > 0.0001 || fabs(normal[2] - plane->normal[2]) > 0.0001) { VectorInverse(normal); dist = -dist; if (fabs(dist - plane->dist) > 0.4 || fabs(normal[0] - plane->normal[0]) > 0.0001 || fabs(normal[1] - plane->normal[1]) > 0.0001 || fabs(normal[2] - plane->normal[2]) > 0.0001) { Log_Write("AAS_CheckFaceWindingPlane: face %d winding plane unequal to face plane\r\n", face->num); // sign2 = DotProduct(plane->normal, normal); if ((sign1 < 0 && sign2 > 0) || (sign1 > 0 && sign2 < 0)) { Log_Write("AAS_CheckFaceWindingPlane: face %d winding reversed\r\n", face->num); w = face->winding; face->winding = ReverseWinding(w); FreeWinding(w); } //end if } //end if else { Log_Write("AAS_CheckFaceWindingPlane: face %d winding reversed\r\n", face->num); w = face->winding; face->winding = ReverseWinding(w); FreeWinding(w); } //end else } //end if } //end of the function AAS_CheckFaceWindingPlane //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_CheckAreaWindingPlanes(void) { int side; tmp_area_t *tmparea; tmp_face_t *face; Log_Write("AAS_CheckAreaWindingPlanes:\r\n"); for (tmparea = tmpaasworld.areas; tmparea; tmparea = tmparea->l_next) { if (tmparea->invalid) continue; for (face = tmparea->tmpfaces; face; face = face->next[side]) { side = face->frontarea != tmparea; AAS_CheckFaceWindingPlane(face); } //end for } //end for } //end of the function AAS_CheckAreaWindingPlanes //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_FlipAreaFaces(tmp_area_t *tmparea) { int side; tmp_face_t *face; plane_t *plane; vec3_t wcenter, acenter = {0, 0, 0}; //winding_t *w; float n; for (n = 0, face = tmparea->tmpfaces; face; face = face->next[side]) { if (!face->frontarea) Error("face %d has no front area\n", face->num); //side of the face the area is on side = face->frontarea != tmparea; WindingCenter(face->winding, wcenter); VectorAdd(acenter, wcenter, acenter); n++; } //end for n = 1 / n; VectorScale(acenter, n, acenter); for (face = tmparea->tmpfaces; face; face = face->next[side]) { //side of the face the area is on side = face->frontarea != tmparea; plane = &mapplanes[face->planenum ^ side]; if (DotProduct(plane->normal, acenter) - plane->dist < 0) { Log_Print("area %d face %d flipped: front area %d, back area %d\n", tmparea->areanum, face->num, face->frontarea ? face->frontarea->areanum : 0, face->backarea ? face->backarea->areanum : 0); /* face->planenum = face->planenum ^ 1; w = face->winding; face->winding = ReverseWinding(w); FreeWinding(w); */ } //end if #ifdef L_DEBUG { float dist; vec3_t normal; //check if the winding plane is the same as the face plane WindingPlane(face->winding, normal, &dist); plane = &mapplanes[face->planenum]; if (fabs(dist - plane->dist) > 0.4 || fabs(normal[0] - plane->normal[0]) > 0.0001 || fabs(normal[1] - plane->normal[1]) > 0.0001 || fabs(normal[2] - plane->normal[2]) > 0.0001) { Log_Write("area %d face %d winding plane unequal to face plane\r\n", tmparea->areanum, face->num); } //end if } #endif } //end for } //end of the function AAS_FlipAreaFaces //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_RemoveAreaFaceColinearPoints(void) { int side; tmp_face_t *face; tmp_area_t *tmparea; //FIXME: loop over the faces instead of area->faces for (tmparea = tmpaasworld.areas; tmparea; tmparea = tmparea->l_next) { for (face = tmparea->tmpfaces; face; face = face->next[side]) { side = face->frontarea != tmparea; RemoveColinearPoints(face->winding); // RemoveEqualPoints(face->winding, 0.1); } //end for } //end for } //end of the function AAS_RemoveAreaFaceColinearPoints //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_RemoveTinyFaces(void) { int side, num; tmp_face_t *face, *nextface; tmp_area_t *tmparea; //FIXME: loop over the faces instead of area->faces Log_Write("AAS_RemoveTinyFaces\r\n"); num = 0; for (tmparea = tmpaasworld.areas; tmparea; tmparea = tmparea->l_next) { for (face = tmparea->tmpfaces; face; face = nextface) { side = face->frontarea != tmparea; nextface = face->next[side]; // if (WindingArea(face->winding) < 1) { if (face->frontarea) AAS_RemoveFaceFromArea(face, face->frontarea); if (face->backarea) AAS_RemoveFaceFromArea(face, face->backarea); AAS_FreeTmpFace(face); //Log_Write("area %d face %d is tiny\r\n", tmparea->areanum, face->num); num++; } //end if } //end for } //end for Log_Write("%d tiny faces removed\r\n", num); } //end of the function AAS_RemoveTinyFaces //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_CreateAreaSettings(void) { int i, flags, side, numgrounded, numladderareas, numliquidareas; tmp_face_t *face; tmp_area_t *tmparea; numgrounded = 0; numladderareas = 0; numliquidareas = 0; Log_Write("AAS_CreateAreaSettings\r\n"); i = 0; qprintf("%6d areas provided with settings", i); for (tmparea = tmpaasworld.areas; tmparea; tmparea = tmparea->l_next) { //if the area is invalid there no need to create settings for it if (tmparea->invalid) continue; tmparea->settings = (tmp_areasettings_t *) GetClearedMemory(sizeof(tmp_areasettings_t)); tmparea->settings->contents = tmparea->contents; tmparea->settings->modelnum = tmparea->modelnum; flags = 0; for (face = tmparea->tmpfaces; face; face = face->next[side]) { side = face->frontarea != tmparea; flags |= face->faceflags; } //end for tmparea->settings->areaflags = 0; if (flags & FACE_GROUND) { tmparea->settings->areaflags |= AREA_GROUNDED; numgrounded++; } //end if if (flags & FACE_LADDER) { tmparea->settings->areaflags |= AREA_LADDER; numladderareas++; } //end if if (tmparea->contents & (AREACONTENTS_WATER | AREACONTENTS_SLIME | AREACONTENTS_LAVA)) { tmparea->settings->areaflags |= AREA_LIQUID; numliquidareas++; } //end if //presence type of the area tmparea->settings->presencetype = tmparea->presencetype; // qprintf("\r%6d", ++i); } //end for qprintf("\n"); #ifdef AASINFO Log_Print("%6d grounded areas\n", numgrounded); Log_Print("%6d ladder areas\n", numladderareas); Log_Print("%6d liquid areas\n", numliquidareas); #endif //AASINFO } //end of the function AAS_CreateAreaSettings //=========================================================================== // create a tmp AAS area from a leaf node // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== tmp_node_t *AAS_CreateArea(node_t *node) { int pside; int areafaceflags; portal_t *p; tmp_face_t *tmpface; tmp_area_t *tmparea; tmp_node_t *tmpnode; vec3_t up = {0, 0, 1}; //create an area from this leaf tmparea = AAS_AllocTmpArea(); tmparea->tmpfaces = NULL; //clear the area face flags areafaceflags = 0; //make aas faces from the portals for (p = node->portals; p; p = p->next[pside]) { pside = (p->nodes[1] == node); //don't create faces from very small portals // if (WindingArea(p->winding) < 1) continue; //if there's already a face created for this portal if (p->tmpface) { //add the back side of the face to the area AAS_AddFaceSideToArea(p->tmpface, 1, tmparea); } //end if else { tmpface = AAS_AllocTmpFace(); //set the face pointer at the portal so we can see from //the portal there's a face created for it p->tmpface = tmpface; //FIXME: test this change //tmpface->planenum = (p->planenum & ~1) | pside; tmpface->planenum = p->planenum ^ pside; if (pside) tmpface->winding = ReverseWinding(p->winding); else tmpface->winding = CopyWinding(p->winding); #ifdef L_DEBUG // AAS_CheckFaceWindingPlane(tmpface); #endif //L_DEBUG //if there's solid at the other side of the portal if (p->nodes[!pside]->contents & (CONTENTS_SOLID | CONTENTS_PLAYERCLIP)) { tmpface->faceflags |= FACE_SOLID; } //end if //else there is no solid at the other side and if there //is a liquid at this side else if (node->contents & (CONTENTS_WATER|CONTENTS_SLIME|CONTENTS_LAVA)) { tmpface->faceflags |= FACE_LIQUID; //if there's no liquid at the other side if (!(p->nodes[!pside]->contents & (CONTENTS_WATER|CONTENTS_SLIME|CONTENTS_LAVA))) { tmpface->faceflags |= FACE_LIQUIDSURFACE; } //end if } //end else //if there's ladder contents at other side of the portal if ((p->nodes[pside]->contents & CONTENTS_LADDER) || (p->nodes[!pside]->contents & CONTENTS_LADDER)) { //NOTE: doesn't have to be solid at the other side because // when standing one can use a crouch area (which is not solid) // as a ladder // imagine a ladder one can walk underthrough, // under the ladder against the ladder is a crouch area // the (vertical) sides of this crouch area area also used as // ladder sides when standing (not crouched) tmpface->faceflags |= FACE_LADDER; } //end if //if it is possible to stand on the face if (AAS_GroundFace(tmpface)) { tmpface->faceflags |= FACE_GROUND; } //end if // areafaceflags |= tmpface->faceflags; //no aas face number yet (zero is a dummy in the aasworld faces) tmpface->aasfacenum = 0; //add the front side of the face to the area AAS_AddFaceSideToArea(tmpface, 0, tmparea); } //end else } //end for qprintf("\r%6d", tmparea->areanum); //presence type in the area tmparea->presencetype = ~node->expansionbboxes & cfg.allpresencetypes; // tmparea->contents = 0; if (node->contents & CONTENTS_CLUSTERPORTAL) tmparea->contents |= AREACONTENTS_CLUSTERPORTAL; if (node->contents & CONTENTS_MOVER) tmparea->contents |= AREACONTENTS_MOVER; if (node->contents & CONTENTS_TELEPORTER) tmparea->contents |= AREACONTENTS_TELEPORTER; if (node->contents & CONTENTS_JUMPPAD) tmparea->contents |= AREACONTENTS_JUMPPAD; if (node->contents & CONTENTS_DONOTENTER) tmparea->contents |= AREACONTENTS_DONOTENTER; if (node->contents & CONTENTS_WATER) tmparea->contents |= AREACONTENTS_WATER; if (node->contents & CONTENTS_LAVA) tmparea->contents |= AREACONTENTS_LAVA; if (node->contents & CONTENTS_SLIME) tmparea->contents |= AREACONTENTS_SLIME; if (node->contents & CONTENTS_NOTTEAM1) tmparea->contents |= AREACONTENTS_NOTTEAM1; if (node->contents & CONTENTS_NOTTEAM2) tmparea->contents |= AREACONTENTS_NOTTEAM2; //store the bsp model that's inside this node tmparea->modelnum = node->modelnum; //sorta check for flipped area faces (remove??) AAS_FlipAreaFaces(tmparea); //check if the area is ok (remove??) AAS_CheckArea(tmparea); // tmpnode = AAS_AllocTmpNode(); tmpnode->planenum = 0; tmpnode->children[0] = 0; tmpnode->children[1] = 0; tmpnode->tmparea = tmparea; // return tmpnode; } //end of the function AAS_CreateArea //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== tmp_node_t *AAS_CreateAreas_r(node_t *node) { tmp_node_t *tmpnode; //recurse down to leafs if (node->planenum != PLANENUM_LEAF) { //the first tmp node is a dummy tmpnode = AAS_AllocTmpNode(); tmpnode->planenum = node->planenum; tmpnode->children[0] = AAS_CreateAreas_r(node->children[0]); tmpnode->children[1] = AAS_CreateAreas_r(node->children[1]); return tmpnode; } //end if //areas won't be created for solid leafs if (node->contents & CONTENTS_SOLID) { //just return zero for a solid leaf (in tmp AAS NULL is a solid leaf) return NULL; } //end if return AAS_CreateArea(node); } //end of the function AAS_CreateAreas_r //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_CreateAreas(node_t *node) { Log_Write("AAS_CreateAreas\r\n"); qprintf("%6d areas created", 0); tmpaasworld.nodes = AAS_CreateAreas_r(node); qprintf("\n"); Log_Write("%6d areas created\r\n", tmpaasworld.numareas); } //end of the function AAS_CreateAreas //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_PrintNumGroundFaces(void) { tmp_face_t *tmpface; int numgroundfaces = 0; for (tmpface = tmpaasworld.faces; tmpface; tmpface = tmpface->l_next) { if (tmpface->faceflags & FACE_GROUND) { numgroundfaces++; } //end if } //end for qprintf("%6d ground faces\n", numgroundfaces); } //end of the function AAS_PrintNumGroundFaces //=========================================================================== // checks the number of shared faces between the given two areas // since areas are convex they should only have ONE shared face // however due to crappy face merging there are sometimes several // shared faces // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_CheckAreaSharedFaces(tmp_area_t *tmparea1, tmp_area_t *tmparea2) { int numsharedfaces, side; tmp_face_t *face1, *sharedface; if (tmparea1->invalid || tmparea2->invalid) return; sharedface = NULL; numsharedfaces = 0; for (face1 = tmparea1->tmpfaces; face1; face1 = face1->next[side]) { side = face1->frontarea != tmparea1; if (face1->backarea == tmparea2 || face1->frontarea == tmparea2) { sharedface = face1; numsharedfaces++; } //end if } //end if if (!sharedface) return; //the areas should only have one shared face if (numsharedfaces > 1) { Log_Write("---- tmp area %d and %d have %d shared faces\r\n", tmparea1->areanum, tmparea2->areanum, numsharedfaces); for (face1 = tmparea1->tmpfaces; face1; face1 = face1->next[side]) { side = face1->frontarea != tmparea1; if (face1->backarea == tmparea2 || face1->frontarea == tmparea2) { Log_Write("face %d, planenum = %d, face->frontarea = %d face->backarea = %d\r\n", face1->num, face1->planenum, face1->frontarea->areanum, face1->backarea->areanum); } //end if } //end if } //end if } //end of the function AAS_CheckAreaSharedFaces //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_CheckSharedFaces(void) { tmp_area_t *tmparea1, *tmparea2; for (tmparea1 = tmpaasworld.areas; tmparea1; tmparea1 = tmparea1->l_next) { for (tmparea2 = tmpaasworld.areas; tmparea2; tmparea2 = tmparea2->l_next) { if (tmparea1 == tmparea2) continue; AAS_CheckAreaSharedFaces(tmparea1, tmparea2); } //end for } //end for } //end of the function AAS_CheckSharedFaces //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_FlipFace(tmp_face_t *face) { tmp_area_t *frontarea, *backarea; winding_t *w; frontarea = face->frontarea; backarea = face->backarea; //must have an area at both sides before flipping is allowed if (!frontarea || !backarea) return; //flip the face winding w = face->winding; face->winding = ReverseWinding(w); FreeWinding(w); //flip the face plane face->planenum ^= 1; //flip the face areas AAS_RemoveFaceFromArea(face, frontarea); AAS_RemoveFaceFromArea(face, backarea); AAS_AddFaceSideToArea(face, 1, frontarea); AAS_AddFaceSideToArea(face, 0, backarea); } //end of the function AAS_FlipFace //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== /* void AAS_FlipAreaSharedFaces(tmp_area_t *tmparea1, tmp_area_t *tmparea2) { int numsharedfaces, side, area1facing, area2facing; tmp_face_t *face1, *sharedface; if (tmparea1->invalid || tmparea2->invalid) return; sharedface = NULL; numsharedfaces = 0; area1facing = 0; //number of shared faces facing towards area 1 area2facing = 0; //number of shared faces facing towards area 2 for (face1 = tmparea1->tmpfaces; face1; face1 = face1->next[side]) { side = face1->frontarea != tmparea1; if (face1->backarea == tmparea2 || face1->frontarea == tmparea2) { sharedface = face1; numsharedfaces++; if (face1->frontarea == tmparea1) area1facing++; else area2facing++; } //end if } //end if if (!sharedface) return; //if there's only one shared face if (numsharedfaces <= 1) return; //if all the shared faces are facing to the same area if (numsharedfaces == area1facing || numsharedfaces == area2facing) return; // do { for (face1 = tmparea1->tmpfaces; face1; face1 = face1->next[side]) { side = face1->frontarea != tmparea1; if (face1->backarea == tmparea2 || face1->frontarea == tmparea2) { if (face1->frontarea != tmparea1) { AAS_FlipFace(face1); break; } //end if } //end if } //end for } while(face1); } //end of the function AAS_FlipAreaSharedFaces //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_FlipSharedFaces(void) { int i; tmp_area_t *tmparea1, *tmparea2; i = 0; qprintf("%6d areas checked for shared face flipping", i); for (tmparea1 = tmpaasworld.areas; tmparea1; tmparea1 = tmparea1->l_next) { if (tmparea1->invalid) continue; for (tmparea2 = tmpaasworld.areas; tmparea2; tmparea2 = tmparea2->l_next) { if (tmparea2->invalid) continue; if (tmparea1 == tmparea2) continue; AAS_FlipAreaSharedFaces(tmparea1, tmparea2); } //end for qprintf("\r%6d", ++i); } //end for Log_Print("\r%6d areas checked for shared face flipping\n", i); } //end of the function AAS_FlipSharedFaces */ //=========================================================================== // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_FlipSharedFaces(void) { int i, side1, side2; tmp_area_t *tmparea1; tmp_face_t *face1, *face2; i = 0; qprintf("%6d areas checked for shared face flipping", i); for (tmparea1 = tmpaasworld.areas; tmparea1; tmparea1 = tmparea1->l_next) { if (tmparea1->invalid) continue; for (face1 = tmparea1->tmpfaces; face1; face1 = face1->next[side1]) { side1 = face1->frontarea != tmparea1; if (!face1->frontarea || !face1->backarea) continue; // for (face2 = face1->next[side1]; face2; face2 = face2->next[side2]) { side2 = face2->frontarea != tmparea1; if (!face2->frontarea || !face2->backarea) continue; // if (face1->frontarea == face2->backarea && face1->backarea == face2->frontarea) { AAS_FlipFace(face2); } //end if //recheck side side2 = face2->frontarea != tmparea1; } //end for } //end for qprintf("\r%6d", ++i); } //end for qprintf("\n"); Log_Write("%6d areas checked for shared face flipping\r\n", i); } //end of the function AAS_FlipSharedFaces //=========================================================================== // creates an .AAS file with the given name // a MAP should be loaded before calling this // // Parameter: - // Returns: - // Changes Globals: - //=========================================================================== void AAS_Create(char *aasfile) { entity_t *e; tree_t *tree; double start_time; //for a possible leak file strcpy(source, aasfile); StripExtension(source); //the time started start_time = I_FloatTime(); //set the default number of threads (depends on number of processors) ThreadSetDefault(); //set the global entity number to the world model entity_num = 0; //the world entity e = &entities[entity_num]; //process the whole world tree = ProcessWorldBrushes(e->firstbrush, e->firstbrush + e->numbrushes); //if the conversion is cancelled if (cancelconversion) { Tree_Free(tree); return; } //end if //display BSP tree creation time Log_Print("BSP tree created in %5.0f seconds\n", I_FloatTime() - start_time); //prune the bsp tree Tree_PruneNodes(tree->headnode); //if the conversion is cancelled if (cancelconversion) { Tree_Free(tree); return; } //end if //create the tree portals MakeTreePortals(tree); //if the conversion is cancelled if (cancelconversion) { Tree_Free(tree); return; } //end if //Marks all nodes that can be reached by entites if (FloodEntities(tree)) { //fill out nodes that can't be reached FillOutside(tree->headnode); } //end if else { LeakFile(tree); Error("**** leaked ****\n"); return; } //end else //create AAS from the BSP tree //========================================== //initialize tmp aas AAS_InitTmpAAS(); //create the convex areas from the leaves AAS_CreateAreas(tree->headnode); //free the BSP tree because it isn't used anymore if (freetree) Tree_Free(tree); //try to merge area faces AAS_MergeAreaFaces(); //do gravitational subdivision AAS_GravitationalSubdivision(); //merge faces if possible AAS_MergeAreaFaces(); AAS_RemoveAreaFaceColinearPoints(); //merge areas if possible AAS_MergeAreas(); //NOTE: prune nodes directly after area merging AAS_PruneNodes(); //flip shared faces so they are all facing to the same area AAS_FlipSharedFaces(); AAS_RemoveAreaFaceColinearPoints(); //merge faces if possible AAS_MergeAreaFaces(); //merge area faces in the same plane AAS_MergeAreaPlaneFaces(); //do ladder subdivision AAS_LadderSubdivision(); //FIXME: melting is buggy AAS_MeltAreaFaceWindings(); //remove tiny faces AAS_RemoveTinyFaces(); //create area settings AAS_CreateAreaSettings(); //check if the winding plane is equal to the face plane //AAS_CheckAreaWindingPlanes(); // //AAS_CheckSharedFaces(); //========================================== //if the conversion is cancelled if (cancelconversion) { Tree_Free(tree); AAS_FreeTmpAAS(); return; } //end if //store the created AAS stuff in the AAS file format and write the file AAS_StoreFile(aasfile); //free the temporary AAS memory AAS_FreeTmpAAS(); //display creation time Log_Print("\nAAS created in %5.0f seconds\n", I_FloatTime() - start_time); } //end of the function AAS_Create