/* Routines for extracting usable data from the new BSP tree. Copyright (C) 2002-2006 Randy Heit 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., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include #include #include #include "zdbsp.h" #include "nodebuild.h" #include "templates.h" #if 0 #define D(x) x #define DD 1 #else #define D(x) do{}while(0) #undef DD #endif void FNodeBuilder::GetGLNodes (MapNodeEx *&outNodes, int &nodeCount, MapSegGLEx *&outSegs, int &segCount, MapSubsectorEx *&outSubs, int &subCount) { TArray segs (Segs.Size()*5/4); int i, j, k; nodeCount = Nodes.Size (); outNodes = new MapNodeEx[nodeCount]; for (i = 0; i < nodeCount; ++i) { const node_t *orgnode = &Nodes[i]; MapNodeEx *newnode = &outNodes[i]; newnode->x = orgnode->x; newnode->y = orgnode->y; newnode->dx = orgnode->dx; newnode->dy = orgnode->dy; for (j = 0; j < 2; ++j) { for (k = 0; k < 4; ++k) { newnode->bbox[j][k] = orgnode->bbox[j][k] >> FRACBITS; } newnode->children[j] = orgnode->intchildren[j]; } } subCount = Subsectors.Size(); outSubs = new MapSubsectorEx[subCount]; for (i = 0; i < subCount; ++i) { int numsegs = CloseSubsector (segs, i); outSubs[i].numlines = numsegs; outSubs[i].firstline = segs.Size() - numsegs; } segCount = segs.Size (); outSegs = new MapSegGLEx[segCount]; memcpy (outSegs, &segs[0], segCount*sizeof(MapSegGLEx)); for (i = 0; i < segCount; ++i) { if (outSegs[i].partner != DWORD_MAX) { outSegs[i].partner = Segs[outSegs[i].partner].storedseg; } } D(DumpNodes(outNodes, nodeCount)); } int FNodeBuilder::CloseSubsector (TArray &segs, int subsector) { FPrivSeg *seg, *prev; angle_t prevAngle; double accumx, accumy; fixed_t midx, midy; int i, j, first, max, count, firstVert; bool diffplanes; int firstplane; first = Subsectors[subsector].firstline; max = first + Subsectors[subsector].numlines; count = 0; accumx = accumy = 0.0; diffplanes = false; firstplane = Segs[SegList[first].SegNum].planenum; // Calculate the midpoint of the subsector and also check for degenerate subsectors. // A subsector is degenerate if it exists in only one dimension, which can be // detected when all the segs lie in the same plane. This can happen if you have // outward-facing lines in the void that don't point toward any sector. (Some of the // polyobjects in Hexen are constructed like this.) for (i = first; i < max; ++i) { seg = &Segs[SegList[i].SegNum]; accumx += double(Vertices[seg->v1].x) + double(Vertices[seg->v2].x); accumy += double(Vertices[seg->v1].y) + double(Vertices[seg->v2].y); if (firstplane != seg->planenum) { diffplanes = true; } } midx = fixed_t(accumx / (max - first) / 2); midy = fixed_t(accumy / (max - first) / 2); seg = &Segs[SegList[first].SegNum]; prevAngle = PointToAngle (Vertices[seg->v1].x - midx, Vertices[seg->v1].y - midy); seg->storedseg = PushGLSeg (segs, seg); count = 1; prev = seg; firstVert = seg->v1; #ifdef DD printf("--%d--\n", subsector); for (j = first; j < max; ++j) { seg = &Segs[SegList[j].SegNum]; angle_t ang = PointToAngle (Vertices[seg->v1].x - midx, Vertices[seg->v1].y - midy); printf ("%d%c %5d(%5d,%5d)->%5d(%5d,%5d) - %3.5f %d,%d [%08x,%08x]-[%08x,%08x]\n", j, seg->linedef == -1 ? '+' : ':', seg->v1, Vertices[seg->v1].x>>16, Vertices[seg->v1].y>>16, seg->v2, Vertices[seg->v2].x>>16, Vertices[seg->v2].y>>16, double(ang/2)*180/(1<<30), seg->planenum, seg->planefront, Vertices[seg->v1].x, Vertices[seg->v1].y, Vertices[seg->v2].x, Vertices[seg->v2].y); } #endif if (diffplanes) { // A well-behaved subsector. Output the segs sorted by the angle formed by connecting // the subsector's center to their first vertex. D(printf("Well behaved subsector\n")); for (i = first + 1; i < max; ++i) { angle_t bestdiff = ANGLE_MAX; FPrivSeg *bestseg = NULL; int bestj = -1; for (j = first; j < max; ++j) { seg = &Segs[SegList[j].SegNum]; angle_t ang = PointToAngle (Vertices[seg->v1].x - midx, Vertices[seg->v1].y - midy); angle_t diff = prevAngle - ang; if (seg->v1 == prev->v2) { bestdiff = diff; bestseg = seg; bestj = j; break; } if (diff < bestdiff && diff > 0) { bestdiff = diff; bestseg = seg; bestj = j; } } if (bestseg != NULL) { seg = bestseg; } if (prev->v2 != seg->v1) { // Add a new miniseg to connect the two segs PushConnectingGLSeg (subsector, segs, prev->v2, seg->v1); count++; } #ifdef DD printf ("+%d\n", bestj); #endif prevAngle -= bestdiff; seg->storedseg = PushGLSeg (segs, seg); count++; prev = seg; if (seg->v2 == firstVert) { prev = seg; break; } } #ifdef DD printf ("\n"); #endif } else { // A degenerate subsector. These are handled in three stages: // Stage 1. Proceed in the same direction as the start seg until we // hit the seg furthest from it. // Stage 2. Reverse direction and proceed until we hit the seg // furthest from the start seg. // Stage 3. Reverse direction again and insert segs until we get // to the start seg. // A dot product serves to determine distance from the start seg. D(printf("degenerate subsector\n")); // Stage 1. Go forward. count += OutputDegenerateSubsector (segs, subsector, true, 0, prev); // Stage 2. Go backward. count += OutputDegenerateSubsector (segs, subsector, false, DBL_MAX, prev); // Stage 3. Go forward again. count += OutputDegenerateSubsector (segs, subsector, true, -DBL_MAX, prev); } if (prev->v2 != firstVert) { PushConnectingGLSeg (subsector, segs, prev->v2, firstVert); count++; } #ifdef DD printf ("Output GL subsector %d:\n", subsector); for (i = segs.Size() - count; i < (int)segs.Size(); ++i) { printf (" Seg %5d%c(%5d,%5d)-(%5d,%5d) [%08x,%08x]-[%08x,%08x]\n", i, segs[i].linedef == NO_INDEX ? '+' : ' ', Vertices[segs[i].v1].x>>16, Vertices[segs[i].v1].y>>16, Vertices[segs[i].v2].x>>16, Vertices[segs[i].v2].y>>16, Vertices[segs[i].v1].x, Vertices[segs[i].v1].y, Vertices[segs[i].v2].x, Vertices[segs[i].v2].y); } #endif return count; } int FNodeBuilder::OutputDegenerateSubsector (TArray &segs, int subsector, bool bForward, double lastdot, FPrivSeg *&prev) { static const double bestinit[2] = { -DBL_MAX, DBL_MAX }; FPrivSeg *seg; int i, j, first, max, count; double dot, x1, y1, dx, dy, dx2, dy2; bool wantside; first = Subsectors[subsector].firstline; max = first + Subsectors[subsector].numlines; count = 0; seg = &Segs[SegList[first].SegNum]; x1 = Vertices[seg->v1].x; y1 = Vertices[seg->v1].y; dx = Vertices[seg->v2].x - x1; dy = Vertices[seg->v2].y - y1; wantside = seg->planefront ^ !bForward; for (i = first + 1; i < max; ++i) { double bestdot = bestinit[bForward]; FPrivSeg *bestseg = NULL; for (j = first + 1; j < max; ++j) { seg = &Segs[SegList[j].SegNum]; if (seg->planefront != wantside) { continue; } dx2 = Vertices[seg->v1].x - x1; dy2 = Vertices[seg->v1].y - y1; dot = dx*dx2 + dy*dy2; if (bForward) { if (dot < bestdot && dot > lastdot) { bestdot = dot; bestseg = seg; } } else { if (dot > bestdot && dot < lastdot) { bestdot = dot; bestseg = seg; } } } if (bestseg != NULL) { if (prev->v2 != bestseg->v1) { PushConnectingGLSeg (subsector, segs, prev->v2, bestseg->v1); count++; } seg->storedseg = PushGLSeg (segs, bestseg); count++; prev = bestseg; lastdot = bestdot; } } return count; } DWORD FNodeBuilder::PushGLSeg (TArray &segs, const FPrivSeg *seg) { MapSegGLEx newseg; newseg.v1 = seg->v1; newseg.v2 = seg->v2; newseg.linedef = seg->linedef; // Just checking the sidedef to determine the side is insufficient. // When a level is sidedef compressed both sides may well have the same sidedef. if (newseg.linedef != NO_INDEX) { IntLineDef *ld = &Level.Lines[newseg.linedef]; if (ld->sidenum[0] == ld->sidenum[1]) { // When both sidedefs are the same a quick check doesn't work so this // has to be done by comparing the distances of the seg's end point to // the line's start. WideVertex *lv1 = &Level.Vertices[ld->v1]; WideVertex *sv1 = &Level.Vertices[seg->v1]; WideVertex *sv2 = &Level.Vertices[seg->v2]; double dist1sq = double(sv1->x-lv1->x)*(sv1->x-lv1->x) + double(sv1->y-lv1->y)*(sv1->y-lv1->y); double dist2sq = double(sv2->x-lv1->x)*(sv2->x-lv1->x) + double(sv2->y-lv1->y)*(sv2->y-lv1->y); newseg.side = dist1sq < dist2sq ? 0 : 1; } else { newseg.side = ld->sidenum[1] == seg->sidedef ? 1 : 0; } } else { newseg.side = 0; } newseg.partner = seg->partner; return segs.Push (newseg); } void FNodeBuilder::PushConnectingGLSeg (int subsector, TArray &segs, int v1, int v2) { MapSegGLEx newseg; Warn ("Unclosed subsector %d, from (%d,%d) to (%d,%d)\n", subsector, Vertices[v1].x >> FRACBITS, Vertices[v1].y >> FRACBITS, Vertices[v2].x >> FRACBITS, Vertices[v2].y >> FRACBITS); newseg.v1 = v1; newseg.v2 = v2; newseg.linedef = NO_INDEX; newseg.side = 0; newseg.partner = DWORD_MAX; segs.Push (newseg); } void FNodeBuilder::GetVertices (WideVertex *&verts, int &count) { count = Vertices.Size (); verts = new WideVertex[count]; for (int i = 0; i < count; ++i) { verts[i].x = Vertices[i].x; verts[i].y = Vertices[i].y; verts[i].index = Vertices[i].index; } } void FNodeBuilder::GetNodes (MapNodeEx *&outNodes, int &nodeCount, MapSegEx *&outSegs, int &segCount, MapSubsectorEx *&outSubs, int &subCount) { short bbox[4]; TArray segs (Segs.Size()); // Walk the BSP and create a new BSP with only the information // suitable for a standard tree. At a minimum, this means removing // all minisegs. As an optional step, I also recompute all the // nodes' bounding boxes so that they only bound the real segs and // not the minisegs. nodeCount = Nodes.Size (); outNodes = new MapNodeEx[nodeCount]; subCount = Subsectors.Size (); outSubs = new MapSubsectorEx[subCount]; RemoveMinisegs (outNodes, segs, outSubs, Nodes.Size() - 1, bbox); segCount = segs.Size (); outSegs = new MapSegEx[segCount]; memcpy (outSegs, &segs[0], segCount*sizeof(MapSegEx)); D(DumpNodes(outNodes, nodeCount)); #ifdef DD for (int i = 0; i < segCount; ++i) { printf("Seg %d: v1(%d) -> v2(%d)\n", i, outSegs[i].v1, outSegs[i].v2); } #endif } int FNodeBuilder::RemoveMinisegs (MapNodeEx *nodes, TArray &segs, MapSubsectorEx *subs, int node, short bbox[4]) { if (node & NFX_SUBSECTOR) { int subnum = node == -1 ? 0 : node & ~NFX_SUBSECTOR; int numsegs = StripMinisegs (segs, subnum, bbox); subs[subnum].numlines = numsegs; subs[subnum].firstline = segs.Size() - numsegs; return NFX_SUBSECTOR | subnum; } else { const node_t *orgnode = &Nodes[node]; MapNodeEx *newnode = &nodes[node]; int child0 = RemoveMinisegs (nodes, segs, subs, orgnode->intchildren[0], newnode->bbox[0]); int child1 = RemoveMinisegs (nodes, segs, subs, orgnode->intchildren[1], newnode->bbox[1]); newnode->x = orgnode->x; newnode->y = orgnode->y; newnode->dx = orgnode->dx; newnode->dy = orgnode->dy; newnode->children[0] = child0; newnode->children[1] = child1; bbox[BOXTOP] = MAX(newnode->bbox[0][BOXTOP], newnode->bbox[1][BOXTOP]); bbox[BOXBOTTOM] = MIN(newnode->bbox[0][BOXBOTTOM], newnode->bbox[1][BOXBOTTOM]); bbox[BOXLEFT] = MIN(newnode->bbox[0][BOXLEFT], newnode->bbox[1][BOXLEFT]); bbox[BOXRIGHT] = MAX(newnode->bbox[0][BOXRIGHT], newnode->bbox[1][BOXRIGHT]); return node; } } int FNodeBuilder::StripMinisegs (TArray &segs, int subsector, short bbox[4]) { int count, i, max; // The bounding box is recomputed to only cover the real segs and not the // minisegs in the subsector. bbox[BOXTOP] = -32768; bbox[BOXBOTTOM] = 32767; bbox[BOXLEFT] = 32767; bbox[BOXRIGHT] = -32768; i = Subsectors[subsector].firstline; max = Subsectors[subsector].numlines + i; for (count = 0; i < max; ++i) { const FPrivSeg *org = &Segs[SegList[i].SegNum]; // Because of the ordering guaranteed by SortSegs(), all mini segs will // be at the end of the subsector, so once one is encountered, we can // stop right away. if (org->linedef == -1) { break; } else { MapSegEx newseg; AddSegToShortBBox (bbox, org); newseg.v1 = org->v1; newseg.v2 = org->v2; newseg.angle = org->angle >> 16; newseg.offset = org->offset >> FRACBITS; newseg.linedef = org->linedef; // Just checking the sidedef to determine the side is insufficient. // When a level is sidedef compressed both sides may well have the same sidedef. IntLineDef * ld = &Level.Lines[newseg.linedef]; if (ld->sidenum[0]==ld->sidenum[1]) { // When both sidedefs are the same a quick check doesn't work so this // has to be done by comparing the distances of the seg's end point to // the line's start. WideVertex * lv1 = &Level.Vertices[ld->v1]; WideVertex * sv1 = &Level.Vertices[org->v1]; WideVertex * sv2 = &Level.Vertices[org->v2]; double dist1sq = double(sv1->x-lv1->x)*(sv1->x-lv1->x) + double(sv1->y-lv1->y)*(sv1->y-lv1->y); double dist2sq = double(sv2->x-lv1->x)*(sv2->x-lv1->x) + double(sv2->y-lv1->y)*(sv2->y-lv1->y); newseg.side = dist1sqsidenum[1] == org->sidedef ? 1 : 0; } newseg.side = Level.Lines[org->linedef].sidenum[1] == org->sidedef ? 1 : 0; segs.Push (newseg); ++count; } } return count; } void FNodeBuilder::AddSegToShortBBox (short bbox[4], const FPrivSeg *seg) { const FPrivVert *v1 = &Vertices[seg->v1]; const FPrivVert *v2 = &Vertices[seg->v2]; short v1x = v1->x >> FRACBITS; short v1y = v1->y >> FRACBITS; short v2x = v2->x >> FRACBITS; short v2y = v2->y >> FRACBITS; if (v1x < bbox[BOXLEFT]) bbox[BOXLEFT] = v1x; if (v1x > bbox[BOXRIGHT]) bbox[BOXRIGHT] = v1x; if (v1y < bbox[BOXBOTTOM]) bbox[BOXBOTTOM] = v1y; if (v1y > bbox[BOXTOP]) bbox[BOXTOP] = v1y; if (v2x < bbox[BOXLEFT]) bbox[BOXLEFT] = v2x; if (v2x > bbox[BOXRIGHT]) bbox[BOXRIGHT] = v2x; if (v2y < bbox[BOXBOTTOM]) bbox[BOXBOTTOM] = v2y; if (v2y > bbox[BOXTOP]) bbox[BOXTOP] = v2y; } void FNodeBuilder::DumpNodes(MapNodeEx *outNodes, int nodeCount) { for (unsigned int i = 0; i < Nodes.Size(); ++i) { printf("Node %d: Splitter[%08x,%08x] [%08x,%08x]\n", i, outNodes[i].x, outNodes[i].y, outNodes[i].dx, outNodes[i].dy); for (int j = 1; j >= 0; --j) { if (outNodes[i].children[j] & NFX_SUBSECTOR) { printf(" subsector %d\n", outNodes[i].children[j] & ~NFX_SUBSECTOR); } else { printf(" node %d\n", outNodes[i].children[j]); } } } }