/* ** Potential visible set (PVS) handling ** Copyright (c) 2016 Magnus Norddahl ** ** This software is provided 'as-is', without any express or implied ** warranty. In no event will the authors be held liable for any damages ** arising from the use of this software. ** ** Permission is granted to anyone to use this software for any purpose, ** including commercial applications, and to alter it and redistribute it ** freely, subject to the following restrictions: ** ** 1. The origin of this software must not be misrepresented; you must not ** claim that you wrote the original software. If you use this software ** in a product, an acknowledgment in the product documentation would be ** appreciated but is not required. ** 2. Altered source versions must be plainly marked as such, and must not be ** misrepresented as being the original software. ** 3. This notice may not be removed or altered from any source distribution. ** */ #include #include "templates.h" #include "doomdef.h" #include "sbar.h" #include "r_data/r_translate.h" #include "poly_cull.h" #include "polyrenderer/poly_renderer.h" void PolyCull::CullScene(const TriMatrix &worldToClip, const PolyClipPlane &portalClipPlane) { PvsSectors.clear(); PortalClipPlane = portalClipPlane; // Cull front to back FirstSkyHeight = true; MaxCeilingHeight = 0.0; MinFloorHeight = 0.0; if (level.nodes.Size() == 0) CullSubsector(&level.subsectors[0]); else CullNode(level.HeadNode()); } void PolyCull::CullNode(void *node) { while (!((size_t)node & 1)) // Keep going until found a subsector { node_t *bsp = (node_t *)node; // Decide which side the view point is on. int side = PointOnSide(PolyRenderer::Instance()->Viewpoint.Pos, bsp); // Recursively divide front space (toward the viewer). CullNode(bsp->children[side]); // Possibly divide back space (away from the viewer). side ^= 1; if (!CheckBBox(bsp->bbox[side])) return; node = bsp->children[side]; } subsector_t *sub = (subsector_t *)((uint8_t *)node - 1); CullSubsector(sub); } void PolyCull::CullSubsector(subsector_t *sub) { // Update sky heights for the scene if (!FirstSkyHeight) { MaxCeilingHeight = MAX(MaxCeilingHeight, sub->sector->ceilingplane.Zat0()); MinFloorHeight = MIN(MinFloorHeight, sub->sector->floorplane.Zat0()); } else { MaxCeilingHeight = sub->sector->ceilingplane.Zat0(); MinFloorHeight = sub->sector->floorplane.Zat0(); FirstSkyHeight = false; } // Mark that we need to render this PvsSectors.push_back(sub); // Update culling info for further bsp clipping for (uint32_t i = 0; i < sub->numlines; i++) { seg_t *line = &sub->firstline[i]; if ((line->sidedef == nullptr || !(line->sidedef->Flags & WALLF_POLYOBJ)) && line->backsector == nullptr) { // Skip lines not facing viewer DVector2 pt1 = line->v1->fPos() - PolyRenderer::Instance()->Viewpoint.Pos; DVector2 pt2 = line->v2->fPos() - PolyRenderer::Instance()->Viewpoint.Pos; if (pt1.Y * (pt1.X - pt2.X) + pt1.X * (pt2.Y - pt1.Y) >= 0) continue; angle_t angle1, angle2; if (GetAnglesForLine(line->v1->fX(), line->v1->fY(), line->v2->fX(), line->v2->fY(), angle1, angle2)) { MarkSegmentCulled(angle1, angle2); } } } } void PolyCull::ClearSolidSegments() { SolidSegments.clear(); } void PolyCull::InvertSegments() { TempInvertSolidSegments.swap(SolidSegments); ClearSolidSegments(); angle_t cur = 0; for (const auto &segment : TempInvertSolidSegments) { if (segment.Start != 0 || segment.End != ANGLE_MAX) MarkSegmentCulled(cur, segment.Start - 1); cur = segment.End + 1; } if (cur != 0) MarkSegmentCulled(cur, ANGLE_MAX); } bool PolyCull::IsSegmentCulled(angle_t startAngle, angle_t endAngle) const { if (startAngle > endAngle) { return IsSegmentCulled(startAngle, ANGLE_MAX) && IsSegmentCulled(0, endAngle); } for (const auto &segment : SolidSegments) { if (startAngle >= segment.Start && endAngle <= segment.End) return true; else if (endAngle < segment.Start) return false; } return false; } void PolyCull::MarkSegmentCulled(angle_t startAngle, angle_t endAngle) { if (startAngle > endAngle) { MarkSegmentCulled(startAngle, ANGLE_MAX); MarkSegmentCulled(0, endAngle); return; } int count = (int)SolidSegments.size(); int cur = 0; while (cur < count) { if (SolidSegments[cur].Start <= startAngle && SolidSegments[cur].End >= endAngle) // Already fully marked { return; } else if (SolidSegments[cur].End >= startAngle && SolidSegments[cur].Start <= endAngle) // Merge segments { // Find last segment int merge = cur; while (merge + 1 != count && SolidSegments[merge + 1].Start <= endAngle) merge++; // Apply new merged range SolidSegments[cur].Start = MIN(SolidSegments[cur].Start, startAngle); SolidSegments[cur].End = MAX(SolidSegments[merge].End, endAngle); // Remove additional segments we merged with if (merge > cur) SolidSegments.erase(SolidSegments.begin() + (cur + 1), SolidSegments.begin() + (merge + 1)); return; } else if (SolidSegments[cur].Start > startAngle) // Insert new segment { SolidSegments.insert(SolidSegments.begin() + cur, { startAngle, endAngle }); return; } cur++; } SolidSegments.push_back({ startAngle, endAngle }); #if 0 count = (int)SolidSegments.size(); for (int i = 1; i < count; i++) { if (SolidSegments[i - 1].Start >= SolidSegments[i].Start || SolidSegments[i - 1].End >= SolidSegments[i].Start || SolidSegments[i - 1].End + 1 == SolidSegments[i].Start || SolidSegments[i].Start > SolidSegments[i].End) { I_FatalError("MarkSegmentCulled is broken!"); } } #endif } int PolyCull::PointOnSide(const DVector2 &pos, const node_t *node) { return DMulScale32(FLOAT2FIXED(pos.Y) - node->y, node->dx, node->x - FLOAT2FIXED(pos.X), node->dy) > 0; } bool PolyCull::CheckBBox(float *bspcoord) { // Occlusion test using solid segments: static const uint8_t checkcoord[12][4] = { { 3,0,2,1 }, { 3,0,2,0 }, { 3,1,2,0 }, { 0 }, { 2,0,2,1 }, { 0,0,0,0 }, { 3,1,3,0 }, { 0 }, { 2,0,3,1 }, { 2,1,3,1 }, { 2,1,3,0 } }; // Find the corners of the box that define the edges from current viewpoint. const auto &viewpoint = PolyRenderer::Instance()->Viewpoint; int boxpos = (viewpoint.Pos.X <= bspcoord[BOXLEFT] ? 0 : viewpoint.Pos.X < bspcoord[BOXRIGHT] ? 1 : 2) + (viewpoint.Pos.Y >= bspcoord[BOXTOP] ? 0 : viewpoint.Pos.Y > bspcoord[BOXBOTTOM] ? 4 : 8); if (boxpos == 5) return true; const uint8_t *check = checkcoord[boxpos]; angle_t angle1 = PointToPseudoAngle(bspcoord[check[0]], bspcoord[check[1]]); angle_t angle2 = PointToPseudoAngle(bspcoord[check[2]], bspcoord[check[3]]); return !IsSegmentCulled(angle2, angle1); } bool PolyCull::GetAnglesForLine(double x1, double y1, double x2, double y2, angle_t &angle1, angle_t &angle2) const { #if 0 // Clip line to the portal clip plane float distance1 = Vec4f::dot(PortalClipPlane, Vec4f((float)x1, (float)y1, 0.0f, 1.0f)); float distance2 = Vec4f::dot(PortalClipPlane, Vec4f((float)x2, (float)y2, 0.0f, 1.0f)); if (distance1 < 0.0f && distance2 < 0.0f) { return false; } else if (distance1 < 0.0f || distance2 < 0.0f) { double t1 = 0.0f, t2 = 1.0f; if (distance1 < 0.0f) t1 = clamp(distance1 / (distance1 - distance2), 0.0f, 1.0f); else t2 = clamp(distance2 / (distance1 - distance2), 0.0f, 1.0f); double nx1 = x1 * (1.0 - t1) + x2 * t1; double ny1 = y1 * (1.0 - t1) + y2 * t1; double nx2 = x1 * (1.0 - t2) + x2 * t2; double ny2 = y1 * (1.0 - t2) + y2 * t2; x1 = nx1; x2 = nx2; y1 = ny1; y2 = ny2; } #endif angle2 = PointToPseudoAngle(x1, y1); angle1 = PointToPseudoAngle(x2, y2); return !IsSegmentCulled(angle1, angle2); } void PolyCull::MarkViewFrustum() { // Clips things outside the viewing frustum. auto &viewpoint = PolyRenderer::Instance()->Viewpoint; auto &viewwindow = PolyRenderer::Instance()->Viewwindow; double tilt = fabs(viewpoint.Angles.Pitch.Degrees); if (tilt > 46.0) // If the pitch is larger than this you can look all around return; double floatangle = 2.0 + (45.0 + ((tilt / 1.9)))*viewpoint.FieldOfView.Degrees*48.0 / AspectMultiplier(viewwindow.WidescreenRatio) / 90.0; angle_t a1 = DAngle(floatangle).BAMs(); if (a1 < ANGLE_180) { MarkSegmentCulled(AngleToPseudo(viewpoint.Angles.Yaw.BAMs() + a1), AngleToPseudo(viewpoint.Angles.Yaw.BAMs() - a1)); } } //----------------------------------------------------------------------------- // // ! Returns the pseudoangle between the line p1 to (infinity, p1.y) and the // line from p1 to p2. The pseudoangle has the property that the ordering of // points by true angle around p1 and ordering of points by pseudoangle are the // same. // // For clipping exact angles are not needed. Only the ordering matters. // This is about as fast as the fixed point R_PointToAngle2 but without // the precision issues associated with that function. // //----------------------------------------------------------------------------- angle_t PolyCull::PointToPseudoAngle(double x, double y) { const auto &viewpoint = PolyRenderer::Instance()->Viewpoint; double vecx = x - viewpoint.Pos.X; double vecy = y - viewpoint.Pos.Y; if (vecx == 0 && vecy == 0) { return 0; } else { double result = vecy / (fabs(vecx) + fabs(vecy)); if (vecx < 0) { result = 2. - result; } return xs_Fix<30>::ToFix(result); } } angle_t PolyCull::AngleToPseudo(angle_t ang) { double vecx = cos(ang * M_PI / ANGLE_180); double vecy = sin(ang * M_PI / ANGLE_180); double result = vecy / (fabs(vecx) + fabs(vecy)); if (vecx < 0) { result = 2.f - result; } return xs_Fix<30>::ToFix(result); }