/* Most of the logic for the node builder. 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 #include #ifndef _WIN32 #include #endif #include "zdbsp.h" #include "nodebuild.h" #include "templates.h" #define Printf printf #define STACK_ARGS #if 0 #define D(x) x #else #define D(x) do{}while(0) #endif FNodeBuilder::FNodeBuilder (FLevel &level, TArray &polyspots, TArray &anchors, const char *name, bool makeGLnodes) : Level(level), SegsStuffed(0), MapName(name) { VertexMap = new FVertexMap (*this, Level.MinX, Level.MinY, Level.MaxX, Level.MaxY); GLNodes = makeGLnodes; FindUsedVertices (Level.Vertices, Level.NumVertices); MakeSegsFromSides (); FindPolyContainers (polyspots, anchors); GroupSegPlanes (); BuildTree (); } FNodeBuilder::~FNodeBuilder() { if (VertexMap != 0) { delete VertexMap; } } void FNodeBuilder::BuildTree () { fixed_t bbox[4]; fprintf (stderr, " BSP: 0.0%%\r"); HackSeg = DWORD_MAX; HackMate = DWORD_MAX; CreateNode (0, Segs.Size(), bbox); CreateSubsectorsForReal (); fprintf (stderr, " BSP: 100.0%%\n"); } DWORD FNodeBuilder::CreateNode (DWORD set, unsigned int count, fixed_t bbox[4]) { node_t node; int skip, selstat; DWORD splitseg; // When building GL nodes, count may not be an exact count of the number of segs // in this set. That's okay, because we just use it to get a skip count, so an // estimate is fine. skip = int(count / MaxSegs); if ((selstat = SelectSplitter (set, node, splitseg, skip, true)) > 0 || (skip > 0 && (selstat = SelectSplitter (set, node, splitseg, 1, true)) > 0) || (selstat < 0 && (SelectSplitter (set, node, splitseg, skip, false) > 0 || (skip > 0 && SelectSplitter (set, node, splitseg, 1, false)))) || CheckSubsector (set, node, splitseg)) { // Create a normal node DWORD set1, set2; unsigned int count1, count2; SplitSegs (set, node, splitseg, set1, set2, count1, count2); D(PrintSet (1, set1)); D(Printf ("(%d,%d) delta (%d,%d) from seg %d\n", node.x>>16, node.y>>16, node.dx>>16, node.dy>>16, splitseg)); D(PrintSet (2, set2)); node.intchildren[0] = CreateNode (set1, count1, node.bbox[0]); node.intchildren[1] = CreateNode (set2, count2, node.bbox[1]); bbox[BOXTOP] = MAX (node.bbox[0][BOXTOP], node.bbox[1][BOXTOP]); bbox[BOXBOTTOM] = MIN (node.bbox[0][BOXBOTTOM], node.bbox[1][BOXBOTTOM]); bbox[BOXLEFT] = MIN (node.bbox[0][BOXLEFT], node.bbox[1][BOXLEFT]); bbox[BOXRIGHT] = MAX (node.bbox[0][BOXRIGHT], node.bbox[1][BOXRIGHT]); return (int)Nodes.Push (node); } else { return NFX_SUBSECTOR | CreateSubsector (set, bbox); } } DWORD FNodeBuilder::CreateSubsector (DWORD set, fixed_t bbox[4]) { int ssnum, count; bbox[BOXTOP] = bbox[BOXRIGHT] = INT_MIN; bbox[BOXBOTTOM] = bbox[BOXLEFT] = INT_MAX; D(Printf ("Subsector from set %d\n", set)); assert (set != DWORD_MAX); #if defined(_DEBUG)// || 1 // Check for segs with duplicate start/end vertices DWORD s1, s2; for (s1 = set; s1 != DWORD_MAX; s1 = Segs[s1].next) { for (s2 = Segs[s1].next; s2 != DWORD_MAX; s2 = Segs[s2].next) { if (Segs[s1].v1 == Segs[s2].v1) printf ("Segs %d%c and %d%c have duplicate start vertex %d (%d, %d)\n", s1, Segs[s1].linedef == -1 ? '*' : ' ', s2, Segs[s2].linedef == -1 ? '*' : ' ', Segs[s1].v1, Vertices[Segs[s1].v1].x >> 16, Vertices[Segs[s1].v1].y >> 16); if (Segs[s1].v2 == Segs[s2].v2) printf ("Segs %d%c and %d%c have duplicate end vertex %d (%d, %d)\n", s1, Segs[s1].linedef == -1 ? '*' : ' ', s2, Segs[s2].linedef == -1 ? '*' : ' ', Segs[s1].v2, Vertices[Segs[s1].v2].x >> 16, Vertices[Segs[s1].v2].y >> 16); } } #endif // We cannot actually create the subsector now because the node building // process might split a seg in this subsector (because all partner segs // must use the same pair of vertices), adding a new seg that hasn't been // created yet. After all the nodes are built, then we can create the // actual subsectors using the CreateSubsectorsForReal function below. ssnum = (int)SubsectorSets.Push (set); count = 0; while (set != DWORD_MAX) { AddSegToBBox (bbox, &Segs[set]); set = Segs[set].next; count++; } SegsStuffed += count; if ((SegsStuffed & ~63) != ((SegsStuffed - count) & ~63)) { int percent = (int)(SegsStuffed * 1000.0 / Segs.Size()); fprintf (stderr, " BSP: %3d.%d%%\r", percent/10, percent%10); } D(Printf ("bbox (%d,%d)-(%d,%d)\n", bbox[BOXLEFT]>>16, bbox[BOXBOTTOM]>>16, bbox[BOXRIGHT]>>16, bbox[BOXTOP]>>16)); return ssnum; } void FNodeBuilder::CreateSubsectorsForReal () { unsigned int i; for (i = 0; i < SubsectorSets.Size(); ++i) { subsector_t sub; DWORD set = SubsectorSets[i]; sub.firstline = (DWORD)SegList.Size(); while (set != DWORD_MAX) { USegPtr ptr; ptr.SegPtr = &Segs[set]; SegList.Push (ptr); set = ptr.SegPtr->next; } sub.numlines = (DWORD)(SegList.Size() - sub.firstline); // Sort segs by linedef for special effects qsort (&SegList[sub.firstline], sub.numlines, sizeof(USegPtr), SortSegs); // Convert seg pointers into indices D(printf ("Output subsector %d:\n", Subsectors.Size())); if (SegList[sub.firstline].SegPtr->linedef == -1) { printf (" Failure: Subsector %d is all minisegs!\n", Subsectors.Size()); } for (unsigned int i = sub.firstline; i < SegList.Size(); ++i) { D(printf (" Seg %5d%c%d(%5d,%5d)-%d(%5d,%5d) [%08x,%08x]-[%08x,%08x]\n", SegList[i].SegPtr - &Segs[0], SegList[i].SegPtr->linedef == -1 ? '+' : ' ', SegList[i].SegPtr->v1, Vertices[SegList[i].SegPtr->v1].x>>16, Vertices[SegList[i].SegPtr->v1].y>>16, SegList[i].SegPtr->v2, Vertices[SegList[i].SegPtr->v2].x>>16, Vertices[SegList[i].SegPtr->v2].y>>16, Vertices[SegList[i].SegPtr->v1].x, Vertices[SegList[i].SegPtr->v1].y, Vertices[SegList[i].SegPtr->v2].x, Vertices[SegList[i].SegPtr->v2].y)); SegList[i].SegNum = DWORD(SegList[i].SegPtr - &Segs[0]); } Subsectors.Push (sub); } } int STACK_ARGS FNodeBuilder::SortSegs (const void *a, const void *b) { const FPrivSeg *x = ((const USegPtr *)a)->SegPtr; const FPrivSeg *y = ((const USegPtr *)b)->SegPtr; // Segs are grouped into three categories in this order: // // 1. Segs with different front and back sectors (or no back at all). // 2. Segs with the same front and back sectors. // 3. Minisegs. // // Within the first two sets, segs are also sorted by linedef. // // Note that when GL subsectors are written, the segs will be reordered // so that they are in clockwise order, and extra minisegs will be added // as needed to close the subsector. But the first seg used will still be // the first seg chosen here. int xtype, ytype; if (x->linedef == -1) { xtype = 2; } else if (x->frontsector == x->backsector) { xtype = 1; } else { xtype = 0; } if (y->linedef == -1) { ytype = 2; } else if (y->frontsector == y->backsector) { ytype = 1; } else { ytype = 0; } if (xtype != ytype) { return xtype - ytype; } else if (xtype < 2) { return x->linedef - y->linedef; } else { return 0; } } // Given a set of segs, checks to make sure they all belong to a single // sector. If so, false is returned, and they become a subsector. If not, // a splitter is synthesized, and true is returned to continue processing // down this branch of the tree. bool FNodeBuilder::CheckSubsector (DWORD set, node_t &node, DWORD &splitseg) { int sec; DWORD seg; sec = -1; seg = set; do { D(Printf (" - seg %d%c(%d,%d)-(%d,%d) line %d front %d back %d\n", seg, Segs[seg].linedef == -1 ? '+' : ' ', Vertices[Segs[seg].v1].x>>16, Vertices[Segs[seg].v1].y>>16, Vertices[Segs[seg].v2].x>>16, Vertices[Segs[seg].v2].y>>16, Segs[seg].linedef, Segs[seg].frontsector, Segs[seg].backsector)); if (Segs[seg].linedef != -1 && Segs[seg].frontsector != sec // Segs with the same front and back sectors are allowed to reside // in a subsector with segs from a different sector, because the // only effect they can have on the display is to place masked // mid textures in the scene. Since minisegs only mark subsector // boundaries, their sector information is unimportant. // // Update: Lines with the same front and back sectors *can* affect // the display if their subsector does not match their front sector. /*&& Segs[seg].frontsector != Segs[seg].backsector*/) { if (sec == -1) { sec = Segs[seg].frontsector; } else { break; } } seg = Segs[seg].next; } while (seg != DWORD_MAX); if (seg == DWORD_MAX) { // It's a valid non-GL subsector, and probably a valid GL subsector too. if (GLNodes) { return CheckSubsectorOverlappingSegs (set, node, splitseg); } return false; } D(Printf("Need to synthesize a splitter for set %d on seg %d\n", set, seg)); splitseg = DWORD_MAX; // This is a very simple and cheap "fix" for subsectors with segs // from multiple sectors, and it seems ZenNode does something // similar. It is the only technique I could find that makes the // "transparent water" in nb_bmtrk.wad work properly. return ShoveSegBehind (set, node, seg, DWORD_MAX); } // When creating GL nodes, we need to check for segs with the same start and // end vertices and split them into two subsectors. bool FNodeBuilder::CheckSubsectorOverlappingSegs (DWORD set, node_t &node, DWORD &splitseg) { int v1, v2; DWORD seg1, seg2; for (seg1 = set; seg1 != DWORD_MAX; seg1 = Segs[seg1].next) { if (Segs[seg1].linedef == -1) { // Do not check minisegs. continue; } v1 = Segs[seg1].v1; v2 = Segs[seg1].v2; for (seg2 = Segs[seg1].next; seg2 != DWORD_MAX; seg2 = Segs[seg2].next) { if (Segs[seg2].v1 == v1 && Segs[seg2].v2 == v2) { if (Segs[seg2].linedef == -1) { // Do not put minisegs into a new subsector. swap (seg1, seg2); } D(Printf("Need to synthesize a splitter for set %d on seg %d (ov)\n", set, seg2)); splitseg = DWORD_MAX; return ShoveSegBehind (set, node, seg2, seg1); } } } // It really is a good subsector. return false; } // The seg is marked to indicate that it should be forced to the // back of the splitter. Because these segs already form a convex // set, all the other segs will be in front of the splitter. Since // the splitter is formed from this seg, the back of the splitter // will have a one-dimensional subsector. SplitSegs() will add one // or two new minisegs to close it: If mate is DWORD_MAX, then a // new seg is created to replace this one on the front of the // splitter. Otherwise, mate takes its place. In either case, the // seg in front of the splitter is partnered with a new miniseg on // the back so that the back will have two segs. bool FNodeBuilder::ShoveSegBehind (DWORD set, node_t &node, DWORD seg, DWORD mate) { SetNodeFromSeg (node, &Segs[seg]); HackSeg = seg; HackMate = mate; if (!Segs[seg].planefront) { node.x += node.dx; node.y += node.dy; node.dx = -node.dx; node.dy = -node.dy; } return Heuristic (node, set, false) > 0; } // Splitters are chosen to coincide with segs in the given set. To reduce the // number of segs that need to be considered as splitters, segs are grouped into // according to the planes that they lie on. Because one seg on the plane is just // as good as any other seg on the plane at defining a split, only one seg from // each unique plane needs to be considered as a splitter. A result of 0 means // this set is a convex region. A result of -1 means that there were possible // splitters, but they all split segs we want to keep intact. int FNodeBuilder::SelectSplitter (DWORD set, node_t &node, DWORD &splitseg, int step, bool nosplit) { int stepleft; int bestvalue; DWORD bestseg; DWORD seg; bool nosplitters = false; bestvalue = 0; bestseg = DWORD_MAX; seg = set; stepleft = 0; memset (&PlaneChecked[0], 0, PlaneChecked.Size()); D(printf("Processing set %d\n", set)); while (seg != DWORD_MAX) { FPrivSeg *pseg = &Segs[seg]; if (--stepleft <= 0) { int l = pseg->planenum >> 3; int r = 1 << (pseg->planenum & 7); if (l < 0 || (PlaneChecked[l] & r) == 0) { if (l >= 0) { PlaneChecked[l] |= r; } stepleft = step; SetNodeFromSeg (node, pseg); int value = Heuristic (node, set, nosplit); D(Printf ("Seg %5d, ld %d (%5d,%5d)-(%5d,%5d) scores %d\n", seg, Segs[seg].linedef, node.x>>16, node.y>>16, (node.x+node.dx)>>16, (node.y+node.dy)>>16, value)); if (value > bestvalue) { bestvalue = value; bestseg = seg; } else if (value < 0) { nosplitters = true; } } else { pseg = pseg; } } seg = pseg->next; } if (bestseg == DWORD_MAX) { // No lines split any others into two sets, so this is a convex region. D(Printf ("set %d, step %d, nosplit %d has no good splitter (%d)\n", set, step, nosplit, nosplitters)); return nosplitters ? -1 : 0; } D(Printf ("split seg %u in set %u, score %d, step %d, nosplit %d\n", bestseg, set, bestvalue, step, nosplit)); splitseg = bestseg; SetNodeFromSeg (node, &Segs[bestseg]); return 1; } // Given a splitter (node), returns a score based on how "good" the resulting // split in a set of segs is. Higher scores are better. -1 means this splitter // splits something it shouldn't and will only be returned if honorNoSplit is // true. A score of 0 means that the splitter does not split any of the segs // in the set. int FNodeBuilder::Heuristic (node_t &node, DWORD set, bool honorNoSplit) { // Set the initial score above 0 so that near vertex anti-weighting is less likely to produce a negative score. int score = 1000000; int segsInSet = 0; int counts[2] = { 0, 0 }; int realSegs[2] = { 0, 0 }; int specialSegs[2] = { 0, 0 }; DWORD i = set; int sidev[2]; int side; bool splitter = false; unsigned int max, m2, p, q; double frac; Touched.Clear (); Colinear.Clear (); while (i != DWORD_MAX) { const FPrivSeg *test = &Segs[i]; if (HackSeg == i) { side = 1; } else { side = ClassifyLine (node, &Vertices[test->v1], &Vertices[test->v2], sidev); } switch (side) { case 0: // Seg is on only one side of the partition case 1: // If we don't split this line, but it abuts the splitter, also reject it. // The "right" thing to do in this case is to only reject it if there is // another nosplit seg from the same sector at this vertex. Note that a line // that lies exactly on top of the splitter is okay. if (test->loopnum && honorNoSplit && (sidev[0] == 0 || sidev[1] == 0)) { if ((sidev[0] | sidev[1]) != 0) { max = Touched.Size(); for (p = 0; p < max; ++p) { if (Touched[p] == test->loopnum) { break; } } if (p == max) { Touched.Push (test->loopnum); } } else { max = Colinear.Size(); for (p = 0; p < max; ++p) { if (Colinear[p] == test->loopnum) { break; } } if (p == max) { Colinear.Push (test->loopnum); } } } counts[side]++; if (test->linedef != -1) { realSegs[side]++; if (test->frontsector == test->backsector) { specialSegs[side]++; } // Add some weight to the score for unsplit lines score += SplitCost; } else { // Minisegs don't count quite as much for nosplitting score += SplitCost / 4; } break; default: // Seg is cut by the partition // If we are not allowed to split this seg, reject this splitter if (test->loopnum) { if (honorNoSplit) { D(Printf ("Splits seg %d\n", i)); return -1; } else { splitter = true; } } // Splitters that are too close to a vertex are bad. frac = InterceptVector (node, *test); if (frac < 0.001 || frac > 0.999) { FPrivVert *v1 = &Vertices[test->v1]; FPrivVert *v2 = &Vertices[test->v2]; double x = v1->x, y = v1->y; x += frac * (v2->x - x); y += frac * (v2->y - y); if (fabs(x - v1->x) < VERTEX_EPSILON+1 && fabs(y - v1->y) < VERTEX_EPSILON+1) { D(Printf("Splitter will produce same start vertex as seg %d\n", i)); return -1; } if (fabs(x - v2->x) < VERTEX_EPSILON+1 && fabs(y - v2->y) < VERTEX_EPSILON+1) { D(Printf("Splitter will produce same end vertex as seg %d\n", i)); return -1; } if (frac > 0.999) { frac = 1 - frac; } int penalty = int(1 / frac); score = MAX(score - penalty, 1); D(Printf ("Penalized splitter by %d for being near endpt of seg %d (%f).\n", penalty, i, frac)); } counts[0]++; counts[1]++; if (test->linedef != -1) { realSegs[0]++; realSegs[1]++; if (test->frontsector == test->backsector) { specialSegs[0]++; specialSegs[1]++; } } break; } segsInSet++; i = test->next; } // If this line is outside all the others, return a special score if (counts[0] == 0 || counts[1] == 0) { return 0; } // A splitter must have at least one real seg on each side. // Otherwise, a subsector could be left without any way to easily // determine which sector it lies inside. if (realSegs[0] == 0 || realSegs[1] == 0) { D(Printf ("Leaves a side with only mini segs\n")); return -1; } // Try to avoid splits that leave only "special" segs, so that the generated // subsectors have a better chance of choosing the correct sector. This situation // is not neccesarily bad, just undesirable. if (honorNoSplit && (specialSegs[0] == realSegs[0] || specialSegs[1] == realSegs[1])) { D(Printf ("Leaves a side with only special segs\n")); return -1; } // If this splitter intersects any vertices of segs that should not be split, // check if it is also colinear with another seg from the same sector. If it // is, the splitter is okay. If not, it should be rejected. Why? Assuming that // polyobject containers are convex (which they should be), a splitter that // is colinear with one of the sector's segs and crosses the vertex of another // seg of that sector must be crossing the container's corner and does not // actually split the container. max = Touched.Size (); m2 = Colinear.Size (); // If honorNoSplit is false, then both these lists will be empty. // If the splitter touches some vertices without being colinear to any, we // can skip further checks and reject this right away. if (m2 == 0 && max > 0) { return -1; } for (p = 0; p < max; ++p) { int look = Touched[p]; for (q = 0; q < m2; ++q) { if (look == Colinear[q]) { break; } } if (q == m2) { // Not a good one return -1; } } // Doom maps are primarily axis-aligned lines, so it's usually a good // idea to prefer axis-aligned splitters over diagonal ones. Doom originally // had special-casing for orthogonal lines, so they performed better. ZDoom // does not care about the line's direction, so this is merely a choice to // try and improve the final tree. if ((node.dx == 0) || (node.dy == 0)) { // If we have to split a seg we would prefer to keep unsplit, give // extra precedence to orthogonal lines so that the polyobjects // outside the entrance to MAP06 in Hexen MAP02 display properly. if (splitter) { score += segsInSet*8; } else { score += segsInSet/AAPreference; } } score += (counts[0] + counts[1]) - abs(counts[0] - counts[1]); return score; } void FNodeBuilder::SplitSegs (DWORD set, node_t &node, DWORD splitseg, DWORD &outset0, DWORD &outset1, unsigned int &count0, unsigned int &count1) { unsigned int _count0 = 0; unsigned int _count1 = 0; outset0 = DWORD_MAX; outset1 = DWORD_MAX; Events.DeleteAll (); SplitSharers.Clear (); while (set != DWORD_MAX) { bool hack; FPrivSeg *seg = &Segs[set]; int next = seg->next; int sidev[2], side; if (HackSeg == set) { HackSeg = DWORD_MAX; side = 1; sidev[0] = sidev[1] = 0; hack = true; } else { side = ClassifyLine (node, &Vertices[seg->v1], &Vertices[seg->v2], sidev); hack = false; } switch (side) { case 0: // seg is entirely in front seg->next = outset0; //Printf ("%u in front\n", set); outset0 = set; _count0++; break; case 1: // seg is entirely in back seg->next = outset1; //Printf ("%u in back\n", set); outset1 = set; _count1++; break; default: // seg needs to be split double frac; FPrivVert newvert; unsigned int vertnum; int seg2; //Printf ("%u is cut\n", set); if (seg->loopnum) { Printf (" Split seg %lu (%d,%d)-(%d,%d) of sector %d on line %d\n", (unsigned long)set, Vertices[seg->v1].x>>16, Vertices[seg->v1].y>>16, Vertices[seg->v2].x>>16, Vertices[seg->v2].y>>16, seg->frontsector, seg->linedef); } frac = InterceptVector (node, *seg); newvert.x = Vertices[seg->v1].x; newvert.y = Vertices[seg->v1].y; newvert.x += fixed_t(frac * double(Vertices[seg->v2].x - newvert.x)); newvert.y += fixed_t(frac * double(Vertices[seg->v2].y - newvert.y)); newvert.index = 0; vertnum = VertexMap->SelectVertexClose (newvert); if ((int)vertnum == seg->v1 || (int)vertnum == seg->v2) { Printf("SelectVertexClose selected endpoint of seg %u\n", (unsigned int)set); } seg2 = SplitSeg (set, vertnum, sidev[0]); Segs[seg2].next = outset0; outset0 = seg2; Segs[set].next = outset1; outset1 = set; _count0++; _count1++; // Also split the seg on the back side if (Segs[set].partner != DWORD_MAX) { int partner1 = Segs[set].partner; int partner2 = SplitSeg (partner1, vertnum, sidev[1]); // The newly created seg stays in the same set as the // back seg because it has not been considered for splitting // yet. If it had been, then the front seg would have already // been split, and we would not be in this default case. // Moreover, the back seg may not even be in the set being // split, so we must not move its pieces into the out sets. Segs[partner1].next = partner2; Segs[partner2].partner = seg2; Segs[seg2].partner = partner2; assert (Segs[partner2].v1 == Segs[seg2].v2); assert (Segs[partner2].v2 == Segs[seg2].v1); assert (Segs[partner1].v1 == Segs[set].v2); assert (Segs[partner1].v2 == Segs[set].v1); } if (GLNodes) { AddIntersection (node, vertnum); } break; } if (side >= 0 && GLNodes) { if (sidev[0] == 0) { double dist1 = AddIntersection (node, seg->v1); if (sidev[1] == 0) { double dist2 = AddIntersection (node, seg->v2); FSplitSharer share = { dist1, set, dist2 > dist1 }; SplitSharers.Push (share); } } else if (sidev[1] == 0) { AddIntersection (node, seg->v2); } } if (hack && GLNodes) { DWORD newback, newfront; newback = AddMiniseg (seg->v2, seg->v1, DWORD_MAX, set, splitseg); if (HackMate == DWORD_MAX) { newfront = AddMiniseg (Segs[set].v1, Segs[set].v2, newback, set, splitseg); Segs[newfront].next = outset0; outset0 = newfront; } else { newfront = HackMate; Segs[newfront].partner = newback; Segs[newback].partner = newfront; } Segs[newback].frontsector = Segs[newback].backsector = Segs[newfront].frontsector = Segs[newfront].backsector = Segs[set].frontsector; Segs[newback].next = outset1; outset1 = newback; } set = next; } FixSplitSharers (); if (GLNodes) { AddMinisegs (node, splitseg, outset0, outset1); } count0 = _count0; count1 = _count1; } void FNodeBuilder::SetNodeFromSeg (node_t &node, const FPrivSeg *pseg) const { if (pseg->planenum >= 0) { FSimpleLine *pline = &Planes[pseg->planenum]; node.x = pline->x; node.y = pline->y; node.dx = pline->dx; node.dy = pline->dy; } else { node.x = Vertices[pseg->v1].x; node.y = Vertices[pseg->v1].y; node.dx = Vertices[pseg->v2].x - node.x; node.dy = Vertices[pseg->v2].y - node.y; } } DWORD FNodeBuilder::SplitSeg (DWORD segnum, int splitvert, int v1InFront) { double dx, dy; FPrivSeg newseg; int newnum = (int)Segs.Size(); newseg = Segs[segnum]; dx = double(Vertices[splitvert].x - Vertices[newseg.v1].x); dy = double(Vertices[splitvert].y - Vertices[newseg.v1].y); if (v1InFront > 0) { newseg.offset += fixed_t (sqrt (dx*dx + dy*dy)); newseg.v1 = splitvert; Segs[segnum].v2 = splitvert; RemoveSegFromVert2 (segnum, newseg.v2); newseg.nextforvert = Vertices[splitvert].segs; Vertices[splitvert].segs = newnum; newseg.nextforvert2 = Vertices[newseg.v2].segs2; Vertices[newseg.v2].segs2 = newnum; Segs[segnum].nextforvert2 = Vertices[splitvert].segs2; Vertices[splitvert].segs2 = segnum; } else { Segs[segnum].offset += fixed_t (sqrt (dx*dx + dy*dy)); Segs[segnum].v1 = splitvert; newseg.v2 = splitvert; RemoveSegFromVert1 (segnum, newseg.v1); newseg.nextforvert = Vertices[newseg.v1].segs; Vertices[newseg.v1].segs = newnum; newseg.nextforvert2 = Vertices[splitvert].segs2; Vertices[splitvert].segs2 = newnum; Segs[segnum].nextforvert = Vertices[splitvert].segs; Vertices[splitvert].segs = segnum; } Segs.Push (newseg); D(Printf("Split seg %d to get seg %d\n", segnum, newnum)); return newnum; } void FNodeBuilder::RemoveSegFromVert1 (DWORD segnum, int vertnum) { FPrivVert *v = &Vertices[vertnum]; if (v->segs == segnum) { v->segs = Segs[segnum].nextforvert; } else { DWORD prev, curr; prev = 0; curr = v->segs; while (curr != DWORD_MAX && curr != segnum) { prev = curr; curr = Segs[curr].nextforvert; } if (curr == segnum) { Segs[prev].nextforvert = Segs[curr].nextforvert; } } } void FNodeBuilder::RemoveSegFromVert2 (DWORD segnum, int vertnum) { FPrivVert *v = &Vertices[vertnum]; if (v->segs2 == segnum) { v->segs2 = Segs[segnum].nextforvert2; } else { DWORD prev, curr; prev = 0; curr = v->segs2; while (curr != DWORD_MAX && curr != segnum) { prev = curr; curr = Segs[curr].nextforvert2; } if (curr == segnum) { Segs[prev].nextforvert2 = Segs[curr].nextforvert2; } } } double FNodeBuilder::InterceptVector (const node_t &splitter, const FPrivSeg &seg) { double v2x = (double)Vertices[seg.v1].x; double v2y = (double)Vertices[seg.v1].y; double v2dx = (double)Vertices[seg.v2].x - v2x; double v2dy = (double)Vertices[seg.v2].y - v2y; double v1dx = (double)splitter.dx; double v1dy = (double)splitter.dy; double den = v1dy*v2dx - v1dx*v2dy; if (den == 0.0) return 0; // parallel double v1x = (double)splitter.x; double v1y = (double)splitter.y; double num = (v1x - v2x)*v1dy + (v2y - v1y)*v1dx; return num / den; } void FNodeBuilder::PrintSet (int l, DWORD set) { Printf ("set %d:\n", l); for (; set != DWORD_MAX; set = Segs[set].next) { Printf ("\t%5lu(%d)%c%d(%d,%d)-%d(%d,%d)\n", (unsigned long)set, Segs[set].frontsector, Segs[set].linedef == -1 ? '+' : ':', Segs[set].v1, Vertices[Segs[set].v1].x>>16, Vertices[Segs[set].v1].y>>16, Segs[set].v2, Vertices[Segs[set].v2].x>>16, Vertices[Segs[set].v2].y>>16); } Printf ("*\n"); } #ifdef BACKPATCH #ifdef _WIN32 #define WIN32_LEAN_AND_MEAN #include #else #include #include #endif #ifdef __GNUC__ extern "C" int ClassifyLineBackpatch (node_t &node, const FSimpleVert *v1, const FSimpleVert *v2, int sidev[2]) #else static int *CallerOffset; int ClassifyLineBackpatchC (node_t &node, const FSimpleVert *v1, const FSimpleVert *v2, int sidev[2]) #endif { // Select the routine based on SSELevel and patch the caller so that // they call that routine directly next time instead of going through here. int *calleroffset; int diff; int (*func)(node_t &, const FSimpleVert *, const FSimpleVert *, int[2]); DWORD oldprotect; #ifdef __GNUC__ calleroffset = (int *)__builtin_return_address(0); #else calleroffset = CallerOffset; #endif // printf ("Patching for SSE %d @ %p %d\n", SSELevel, calleroffset, *calleroffset); if (SSELevel == 2) { func = ClassifyLineSSE2; diff = (char *)ClassifyLineSSE2 - (char *)calleroffset; } else if (SSELevel == 1) { func = ClassifyLineSSE1; diff = (char *)ClassifyLineSSE1 - (char *)calleroffset; } else { func = ClassifyLine2; diff = (char *)ClassifyLine2 - (char *)calleroffset; } // Patch the caller. calleroffset--; #ifdef _WIN32 if (VirtualProtect (calleroffset, sizeof(void*), PAGE_EXECUTE_READWRITE, &oldprotect)) #else // must make this page-aligned for mprotect long pagesize = sysconf(_SC_PAGESIZE); char *callerpage = (char *)((intptr_t)calleroffset & ~(pagesize - 1)); size_t protectlen = (intptr_t)calleroffset + sizeof(void*) - (intptr_t)callerpage; int ptect; if (!(ptect = mprotect(callerpage, protectlen, PROT_READ|PROT_WRITE|PROT_EXEC))) #endif { *calleroffset = diff; #ifdef _WIN32 VirtualProtect (calleroffset, sizeof(void*), oldprotect, &oldprotect); #else mprotect(callerpage, protectlen, PROT_READ|PROT_EXEC); #endif } // And return by calling the real function. return func (node, v1, v2, sidev); } #ifndef __GNUC__ // The ClassifyLineBackpatch() function here is a stub that uses inline assembly and nakedness // to retrieve the return address of the stack before sending control to the real // ClassifyLineBackpatchC() function. Since BACKPATCH shouldn't be defined on 64-bit builds, // we're okay that VC++ can't do inline assembly on that target. extern "C" __declspec(noinline) __declspec(naked) int ClassifyLineBackpatch (node_t &node, const FSimpleVert *v1, const FSimpleVert *v2, int sidev[2]) { // We store the return address in a global, so as not to need to mess with the parameter list. __asm { mov eax, [esp] mov CallerOffset, eax jmp ClassifyLineBackpatchC } } #endif #endif