// //--------------------------------------------------------------------------- // // Copyright(C) 2000-2016 Christoph Oelckers // All rights reserved. // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser 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 Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with this program. If not, see http://www.gnu.org/licenses/ // //-------------------------------------------------------------------------- // #include "texturemanager.h" #include "hw_dynlightdata.h" #include "hw_material.h" #include "hw_cvars.h" #include "hw_clock.h" //#include "hw_lighting.h" #include "hw_drawinfo.h" #include "hw_portal.h" #include "hw_lightbuffer.h" #include "hw_renderstate.h" #include "hw_skydome.h" #include "hw_drawstructs.h" #include "hw_vertexmap.h" #include "gamefuncs.h" #include "cmdlib.h" #include "v_video.h" #include "flatvertices.h" #include "glbackend/glbackend.h" DCoreActor* wall_to_sprite_actors[8]; // gets updated each frame. Todo: Encapsulate this better without having to permanently store actors in the wall object. //========================================================================== // // // //========================================================================== static walltype* IsOnWall(tspritetype* tspr, int height, DVector2& outpos) { double maxorthdist = 3; // maximum orthogonal distance to be considered an attached sprite. double maxdistsq = 3 * 3; walltype* best = nullptr; auto sect = tspr->sectp; for(auto& wal : wallsofsector(sect)) { // Intentionally include two sided walls. Even on them the sprite should be projected onto the wall for better results. auto d = wal.delta(); int walang = getangle(d.X, d.Y); int deltaang = abs((((walang - tspr->ang) & 2047) << 21) >> 21); const int maxangdelta = 1; // angle of the sprite must either be the wall's normal or the negative wall's normal to be aligned. if (deltaang >= 512 - maxangdelta && deltaang <= 512 + maxangdelta) { // orthogonal lines do not check the actual position so that certain off-sector sprites get handled properly. // In Wanton Destruction's airplane level there's such a sprite assigned to the wrong sector. if (d.X == 0) { double newdist = fabs(tspr->pos.X - wal.wall_int_pos().X); if (newdist < maxorthdist) { maxorthdist = newdist; best = &wal; } } else if (d.Y == 0) { double newdist = fabs(tspr->pos.Y - wal.wall_int_pos().Y); if (newdist < maxorthdist) { maxorthdist = newdist; best = &wal; } } else { double wdist = SquareDistToWall(tspr->pos.X, tspr->pos.Y, &wal, &outpos); if (wdist <= maxdistsq) { return &wal; } } } } return best; } //========================================================================== // // General purpose wall rendering function // everything goes through here // //========================================================================== void HWWall::RenderWall(HWDrawInfo *di, FRenderState &state, int textured) { assert(vertcount > 0); state.SetLightIndex(dynlightindex); state.Draw(DT_TriangleFan, vertindex, vertcount); vertexcount += vertcount; } //========================================================================== // // // //========================================================================== void HWWall::RenderFogBoundary(HWDrawInfo *di, FRenderState &state) { if (gl_fogmode)// && !di->isFullbrightScene()) { state.EnableDrawBufferAttachments(false); SetLightAndFog(di, state, fade, palette, shade, visibility, alpha); state.SetEffect(EFF_FOGBOUNDARY); state.AlphaFunc(Alpha_GEqual, 0.f); state.SetDepthBias(-1, -128); RenderWall(di, state, HWWall::RWF_BLANK); state.ClearDepthBias(); state.SetEffect(EFF_NONE); state.EnableDrawBufferAttachments(true); } } //========================================================================== // // // //========================================================================== void HWWall::RenderMirrorSurface(HWDrawInfo *di, FRenderState &state) { if (!TexMan.mirrorTexture.isValid()) return; state.SetDepthFunc(DF_LEqual); // we use texture coordinates and texture matrix to pass the normal stuff to the shader so that the default vertex buffer format can be used as is. state.EnableTextureMatrix(true); // Use sphere mapping for this state.SetEffect(EFF_SPHEREMAP); SetLightAndFog(di, state, fade, palette, min(shade, numshades), visibility, alpha); state.SetColor(PalEntry(25, globalr >> 1, globalg >> 1, globalb >> 1)); state.SetRenderStyle(STYLE_Add); state.AlphaFunc(Alpha_Greater, 0); auto tex = TexMan.GetGameTexture(TexMan.mirrorTexture, false); state.SetMaterial(tex, UF_None, 0, CLAMP_NONE, 0, -1); // do not upscale the mirror texture. RenderWall(di, state, HWWall::RWF_BLANK); state.EnableTextureMatrix(false); state.SetEffect(EFF_NONE); state.AlphaFunc(Alpha_GEqual, 0.5f); state.SetDepthFunc(DF_Less); state.SetRenderStyle(STYLE_Translucent); } //========================================================================== // // // //========================================================================== void HWWall::RenderTexturedWall(HWDrawInfo *di, FRenderState &state, int rflags) { SetLightAndFog(di, state, fade, palette, shade, visibility, alpha); state.SetMaterial(texture, UF_Texture, 0, (flags & (HWF_CLAMPX | HWF_CLAMPY)), TRANSLATION(Translation_Remap + curbasepal, palette), -1); if (Sprite == nullptr) { if (shade > numshades && (GlobalMapFog || (fade & 0xffffff))) { state.SetObjectColor(fade | 0xff000000); state.EnableTexture(false); } int h = (int)texture->GetDisplayHeight(); int h2 = 1 << sizeToBits(h); if (h2 < h) h2 *= 2; if (h != h2) { float xOffset = 1.f / texture->GetDisplayWidth(); state.SetNpotEmulation(float(h2) / h, xOffset); } RenderWall(di, state, rflags); } else if (!(rflags & RWF_TRANS)) { auto oldbias = state.GetDepthBias(); if (walldist) state.SetDepthBias(-1, -129); else state.ClearDepthBias(); RenderWall(di, state, rflags); state.SetDepthBias(oldbias); } else RenderWall(di, state, rflags); state.SetNpotEmulation(0.f, 0.f); state.SetObjectColor(0xffffffff); state.EnableTexture(true); /* none of these functions is in use. state.SetObjectColor2(0); state.SetAddColor(0); state.SetTextureMode(tmode); state.EnableGlow(false); state.EnableGradient(false); state.ApplyTextureManipulation(nullptr); */ } //========================================================================== // // // //========================================================================== void HWWall::RenderTranslucentWall(HWDrawInfo *di, FRenderState &state) { if (RenderStyle.BlendOp != STYLEOP_Add) { state.EnableBrightmap(false); } state.SetRenderStyle(RenderStyle); state.SetTextureMode(RenderStyle); if (texture && !checkTranslucentReplacement(texture->GetID(), palette)) state.AlphaFunc(Alpha_GEqual, texture->alphaThreshold); else state.AlphaFunc(Alpha_GEqual, 0.f); RenderTexturedWall(di, state, HWWall::RWF_TEXTURED); state.SetRenderStyle(STYLE_Translucent); state.EnableBrightmap(true); } //========================================================================== // // // //========================================================================== void HWWall::DrawWall(HWDrawInfo *di, FRenderState &state, bool translucent) { rendered_lines++; if (screen->BuffersArePersistent()) { /* if (di->Level->HasDynamicLights && !di->isFullbrightScene() && texture != nullptr) { SetupLights(di, lightdata); } */ MakeVertices(di, !!(flags & HWWall::HWF_TRANSLUCENT)); } state.SetNormal(glseg.Normal()); if (!translucent) { RenderTexturedWall(di, state, HWWall::RWF_TEXTURED); } else { switch (type) { case RENDERWALL_MIRRORSURFACE: RenderMirrorSurface(di, state); break; case RENDERWALL_FOGBOUNDARY: RenderFogBoundary(di, state); break; default: RenderTranslucentWall(di, state); break; } } } //========================================================================== // // Collect lights for shader // //========================================================================== #if 0 void HWWall::SetupLights(HWDrawInfo *di, FDynLightData &lightdata) { lightdata.Clear(); if (RenderStyle == STYLE_Add && !di->Level->lightadditivesurfaces) return; // no lights on additively blended surfaces. // check for wall types which cannot have dynamic lights on them (portal types never get here so they don't need to be checked.) switch (type) { case RENDERWALL_FOGBOUNDARY: case RENDERWALL_MIRRORSURFACE: case RENDERWALL_COLOR: return; } float vtx[]={glseg.x1,zbottom[0],glseg.y1, glseg.x1,ztop[0],glseg.y1, glseg.x2,ztop[1],glseg.y2, glseg.x2,zbottom[1],glseg.y2}; Plane p; auto normal = glseg.Normal(); p.Set(normal, -normal.X * glseg.x1 - normal.Z * glseg.y1); FLightNode *node; if (seg->sidedef == NULL) { node = NULL; } else if (!(seg->sidedef->Flags & WALLF_POLYOBJ)) { node = seg->sidedef->lighthead; } else if (sub) { // Polobject segs cannot be checked per sidedef so use the subsector instead. node = sub->section->lighthead; } else node = NULL; // Iterate through all dynamic lights which touch this wall and render them while (node) { if (node->lightsource->IsActive()) { iter_dlight++; DVector3 posrel = node->lightsource->PosRelative(seg->frontsector->PortalGroup); float x = posrel.X; float y = posrel.Y; float z = posrel.Z; float dist = fabsf(p.DistToPoint(x, z, y)); float radius = node->lightsource->GetRadius(); float scale = 1.0f / ((2.f * radius) - dist); FVector3 fn, pos; if (radius > 0.f && dist < radius) { FVector3 nearPt, up, right; pos = { x, z, y }; fn = p.Normal(); fn.GetRightUp(right, up); FVector3 tmpVec = fn * dist; nearPt = pos + tmpVec; FVector3 t1; int outcnt[4]={0,0,0,0}; texcoord tcs[4]; // do a quick check whether the light touches this polygon for(int i=0;i<4;i++) { t1 = FVector3(&vtx[i*3]); FVector3 nearToVert = t1 - nearPt; tcs[i].u = ((nearToVert | right) * scale) + 0.5f; tcs[i].v = ((nearToVert | up) * scale) + 0.5f; if (tcs[i].u<0) outcnt[0]++; if (tcs[i].u>1) outcnt[1]++; if (tcs[i].v<0) outcnt[2]++; if (tcs[i].v>1) outcnt[3]++; } if (outcnt[0]!=4 && outcnt[1]!=4 && outcnt[2]!=4 && outcnt[3]!=4) { draw_dlight += GetLight(lightdata, seg->frontsector->PortalGroup, p, node->lightsource, true); } } } node = node->nextLight; } dynlightindex = screen->mLights->UploadLights(lightdata); } #endif //========================================================================== // // // //========================================================================== void HWWall::PutWall(HWDrawInfo *di, bool translucent) { if (translucent || (texture && texture->GetTranslucency() && type == RENDERWALL_M2S)) { flags |= HWF_TRANSLUCENT; ViewDistance = (di->Viewpoint.Pos.XY() - DVector2((glseg.x1 + glseg.x2) * 0.5f, (glseg.y1 + glseg.y2) * 0.5f)).LengthSquared(); } if (texture->isHardwareCanvas()) { tcs[UPLFT].v = 1.f - tcs[UPLFT].v; tcs[LOLFT].v = 1.f - tcs[LOLFT].v; tcs[UPRGT].v = 1.f - tcs[UPRGT].v; tcs[LORGT].v = 1.f - tcs[LORGT].v; } if (!screen->BuffersArePersistent()) { /* if (di->Level->HasDynamicLights && !di->isFullbrightScene() && texture != nullptr) { SetupLights(di, lightdata); } */ MakeVertices(di, translucent); } di->AddWall(this); // make sure that following parts of the same linedef do not get this one's vertex and lighting info. vertcount = 0; dynlightindex = -1; flags &= ~(HWF_TRANSLUCENT|HWF_CLAMPX|HWF_CLAMPY); } //========================================================================== // // will be done later. // //========================================================================== void HWWall::PutPortal(HWDrawInfo *di, int ptype, int plane) { HWPortal * portal = nullptr; MakeVertices(di, false); switch (ptype) { #if 0 // portals don't go into the draw list. // Instead they are added to the portal manager case PORTALTYPE_HORIZON: horizon = portalState.UniqueHorizons.Get(horizon); portal = di->FindPortal(horizon); if (!portal) { portal = new HWHorizonPortal(&portalState, horizon, di->Viewpoint); di->Portals.Push(portal); } portal->AddLine(this); break; case PORTALTYPE_SKYBOX: portal = di->FindPortal(secportal); if (!portal) { // either a regular skybox or an Eternity-style horizon if (secportal->mType != PORTS_SKYVIEWPOINT) portal = new HWEEHorizonPortal(&portalState, secportal); else { portal = new HWSkyboxPortal(&portalState, secportal); di->Portals.Push(portal); } } portal->AddLine(this); break; #endif case PORTALTYPE_SECTORSTACK: portal = di->FindPortal(this->portal); if (!portal) { portal = new HWSectorStackPortal(&portalState, this->portal); di->Portals.Push(portal); } portal->AddLine(this); break; #if 0 case PORTALTYPE_PLANEMIRROR: if (portalState.PlaneMirrorMode * planemirror->fC() <= 0) { planemirror = portalState.UniquePlaneMirrors.Get(planemirror); portal = di->FindPortal(planemirror); if (!portal) { portal = new HWPlaneMirrorPortal(&portalState, planemirror); di->Portals.Push(portal); } portal->AddLine(this); } break; #endif case PORTALTYPE_MIRROR: // These are unique. No need to look existing ones up. portal = new HWMirrorPortal(&portalState, seg); di->Portals.Push(portal); portal->AddLine(this); if (gl_mirror_envmap) { // draw a reflective layer over the mirror di->AddMirrorSurface(this); } break; case PORTALTYPE_LINETOLINE: // These are also unique. portal = new HWLineToLinePortal(&portalState, seg, &wall[seg->portalnum]); di->Portals.Push(portal); portal->AddLine(this); break; case PORTALTYPE_LINETOSPRITE: // These are also unique. assert(seg->portalnum >= 0 && seg->portalnum < 8); portal = new HWLineToSpritePortal(&portalState, seg, wall_to_sprite_actors[seg->portalnum]); di->Portals.Push(portal); portal->AddLine(this); break; case PORTALTYPE_SKY: sky = portalState.UniqueSkies.Get(sky); portal = di->FindPortal(sky); if (!portal) { portal = new HWSkyPortal(screen->mSkyData, &portalState, sky); di->Portals.Push(portal); } portal->AddLine(this); break; } vertcount = 0; if (plane != -1 && portal) { portal->planesused |= (1<GetPlaneTexZ(sector_t::ceiling); zbottom[1] = zbottom[0] = fs->GetPlaneTexZ(sector_t::floor); auto vpz = di->Viewpoint.Pos.Z; if (vpz < fs->GetPlaneTexZ(sector_t::ceiling)) { if (vpz > fs->GetPlaneTexZ(sector_t::floor)) zbottom[1] = zbottom[0] = vpz; if (fs->GetTexture(sector_t::ceiling) == skyflatnum) { SkyPlane(di, fs, sector_t::ceiling, false); } else { horizon = &hi; PutPortal(di, PORTALTYPE_HORIZON, -1); } ztop[1] = ztop[0] = zbottom[0]; } if (vpz > fs->GetPlaneTexZ(sector_t::floor)) { zbottom[1] = zbottom[0] = fs->GetPlaneTexZ(sector_t::floor); if (fs->GetTexture(sector_t::floor) == skyflatnum) { SkyPlane(di, fs, sector_t::floor, false); } else { horizon = &hi; PutPortal(di, PORTALTYPE_HORIZON, -1); } } #endif return true; } //========================================================================== // // // //========================================================================== bool HWWall::SetWallCoordinates(walltype * seg, float topleft, float topright, float bottomleft, float bottomright) { // // // set up coordinates for the left side of the polygon // // check left side for intersections if (topleft >= bottomleft) { // normal case ztop[0] = topleft; zbottom[0] = bottomleft; } else { // ceiling below floor - clip to the visible part of the wall float dch = topright - topleft; float dfh = bottomright - bottomleft; float inter_x = (bottomleft - topleft) / (dch - dfh); float inter_y = topleft + inter_x * dch; glseg.x1 = glseg.x1 + inter_x * (glseg.x2 - glseg.x1); glseg.y1 = glseg.y1 + inter_x * (glseg.y2 - glseg.y1); glseg.fracleft = inter_x; zbottom[0] = ztop[0] = inter_y; } // // // set up coordinates for the right side of the polygon // // check left side for intersections if (topright >= bottomright) { // normal case ztop[1] = topright; zbottom[1] = bottomright; } else { // ceiling below floor - clip to the visible part of the wall float dch = topright - topleft; float dfh = bottomright - bottomleft; float inter_x = (bottomleft - topleft) / (dch - dfh); float inter_y = topleft + inter_x * dch; glseg.x2 = glseg.x1 + inter_x * (glseg.x2 - glseg.x1); glseg.y2 = glseg.y1 + inter_x * (glseg.y2 - glseg.y1); glseg.fracright = inter_x; zbottom[1] = ztop[1] = inter_y; } return true; } //========================================================================== // // Do some tweaks with the texture coordinates to reduce visual glitches // //========================================================================== void HWWall::CheckTexturePosition() { float sub; if (texture->isHardwareCanvas()) return; // clamp texture coordinates to a reasonable range. // Extremely large values can cause visual problems if (tcs[UPLFT].v < tcs[LOLFT].v || tcs[UPRGT].v < tcs[LORGT].v) { if (tcs[UPLFT].v < tcs[UPRGT].v) { sub = float(xs_FloorToInt(tcs[UPLFT].v)); } else { sub = float(xs_FloorToInt(tcs[UPRGT].v)); } tcs[UPLFT].v -= sub; tcs[UPRGT].v -= sub; tcs[LOLFT].v -= sub; tcs[LORGT].v -= sub; } else { if (tcs[LOLFT].v < tcs[LORGT].v) { sub = float(xs_FloorToInt(tcs[LOLFT].v)); } else { sub = float(xs_FloorToInt(tcs[LORGT].v)); } tcs[UPLFT].v -= sub; tcs[UPRGT].v -= sub; tcs[LOLFT].v -= sub; tcs[LORGT].v -= sub; } if (tcs[UPLFT].u >= 0.f && tcs[UPRGT].u >= 0.f && tcs[LOLFT].u >= 0.f && tcs[LORGT].u >= 0.f && tcs[UPLFT].u <= 1.f && tcs[UPRGT].u <= 1.f && tcs[LOLFT].u <= 1.f && tcs[LORGT].u <= 1.f) { flags |= HWF_CLAMPX; } if (tcs[UPLFT].v >= 0.f && tcs[UPRGT].v >= 0.f && tcs[LOLFT].v >= 0.f && tcs[LORGT].v >= 0.f && tcs[UPLFT].v <= 1.f && tcs[UPRGT].v <= 1.f && tcs[LOLFT].v <= 1.f && tcs[LORGT].v <= 1.f) { flags |= HWF_CLAMPY; } } //========================================================================== // // Common part of wall drawers // //========================================================================== void HWWall::DoTexture(HWDrawInfo* di, walltype* wal, walltype* refwall, float refheight, float topleft, float topright, float bottomleft, float bottomright) { auto glsave = glseg; SetWallCoordinates(wal, topleft, topright, bottomleft, bottomright); bool xflipped = (wal->cstat & CSTAT_WALL_XFLIP); float leftdist = xflipped ? 1.f - glseg.fracleft : glseg.fracleft; float rightdist = xflipped ? 1.f - glseg.fracright : glseg.fracright; float tw = texture->GetDisplayWidth(); float th = texture->GetDisplayHeight(); int pow2size = 1 << sizeToBits(th); if (pow2size < th) pow2size *= 2; float ypanning = refwall->ypan_ ? pow2size * refwall->ypan_ / (256.0f * th) : 0; tcs[LOLFT].u = tcs[UPLFT].u = ((leftdist * 8.f * wal->xrepeat) + refwall->xpan_) / tw; tcs[LORGT].u = tcs[UPRGT].u = ((rightdist * 8.f * wal->xrepeat) + refwall->xpan_) / tw; auto setv = [=](float hl, float hr, float frac) -> float { float h = hl + (hr - hl) * frac; h = (-(float)(refheight + (h * 256)) / ((th * 2048.0f) / (float)(wal->yrepeat))) + ypanning; if (refwall->cstat & CSTAT_WALL_YFLIP) h = -h; return h; }; tcs[UPLFT].v = setv(topleft, topright, glseg.fracleft); tcs[LOLFT].v = setv(bottomleft, bottomright, glseg.fracleft); tcs[UPRGT].v = setv(topleft, topright, glseg.fracright); tcs[LORGT].v = setv(bottomleft, bottomright, glseg.fracright); if (th == pow2size) CheckTexturePosition(); // for NPOT textures this adjustment can break things. bool trans = type == RENDERWALL_M2S && maskWallHasTranslucency(wal); if (trans) { RenderStyle = GetRenderStyle(0, !!(wal->cstat & CSTAT_WALL_TRANS_FLIP)); alpha = GetAlphaFromBlend((wal->cstat & CSTAT_WALL_TRANS_FLIP) ? DAMETH_TRANS2 : DAMETH_TRANS1, 0); } PutWall(di, trans); flags = 0; glseg = glsave; } //========================================================================== // // Handle one sided walls // //========================================================================== void HWWall::DoOneSidedTexture(HWDrawInfo* di, walltype* wal, sectortype* frontsector, sectortype* backsector, float topleft, float topright, float bottomleft, float bottomright) { // get the alignment reference position. int refheight; if ((wal->cstat & CSTAT_WALL_1WAY) && backsector) { if ((!(wal->cstat & CSTAT_WALL_BOTTOM_SWAP) && (wal->cstat & CSTAT_WALL_1WAY)) || ((wal->cstat & CSTAT_WALL_BOTTOM_SWAP) && (wal->nextWall()->cstat & CSTAT_WALL_ALIGN_BOTTOM))) refheight = frontsector->ceilingz; else refheight = backsector->floorz; } else { refheight = (wal->cstat & CSTAT_WALL_ALIGN_BOTTOM) ? frontsector->floorz : frontsector->ceilingz; } type = RENDERWALL_M1S; DoTexture(di, wal, wal, refheight, topleft, topright, bottomleft, bottomright); } //========================================================================== // // // //========================================================================== void HWWall::DoUpperTexture(HWDrawInfo* di, walltype* wal, sectortype* frontsector, sectortype* backsector, float topleft, float topright, float bottomleft, float bottomright) { // get the alignment reference position. int refheight = (wal->cstat & CSTAT_WALL_ALIGN_BOTTOM) ? frontsector->ceilingz : backsector->ceilingz; type = RENDERWALL_TOP; DoTexture(di, wal, wal, refheight, topleft, topright, bottomleft, bottomright); } //========================================================================== // // // //========================================================================== void HWWall::DoLowerTexture(HWDrawInfo* di, walltype* wal, sectortype* frontsector, sectortype* backsector, float topleft, float topright, float bottomleft, float bottomright) { // get the alignment reference position. int refheight; auto refwall = (wal->cstat & CSTAT_WALL_BOTTOM_SWAP) ? wal->nextWall() : wal; refheight = (refwall->cstat & CSTAT_WALL_ALIGN_BOTTOM) ? frontsector->ceilingz : backsector->floorz; shade = refwall->shade; palette = refwall->pal; type = RENDERWALL_BOTTOM; DoTexture(di, wal, refwall, refheight, topleft, topright, bottomleft, bottomright); } //========================================================================== // // // //========================================================================== void HWWall::DoMidTexture(HWDrawInfo* di, walltype* wal, sectortype* front, sectortype* back, float fch1, float fch2, float ffh1, float ffh2, float bch1, float bch2, float bfh1, float bfh2) { float topleft,bottomleft,topright,bottomright; int refheight; const int swapit = (wal->cstat & CSTAT_WALL_ALIGN_BOTTOM); if (wal->cstat & CSTAT_WALL_1WAY) { // 1-sided wall refheight = swapit ? front->ceilingz : back->ceilingz; } else { // masked wall if (swapit) refheight = min(front->floorz, back->floorz); else refheight = max(front->ceilingz, back->ceilingz); } if ((bch1 - fch1) * (bch2 - fch2) >= 0) { topleft = min(bch1, fch1); topright = min(bch2, fch2); } else { // Front ceiling slope obstructs part of the wall topleft = bch1; topright = bch2; } if ((bfh1 - ffh1) * (bfh2 - ffh2) >= 0) { bottomleft = max(bfh1, ffh1); bottomright = max(bfh2, ffh2); } else { // Front floor slope obstructs part of the wall bottomleft = bfh1; bottomright = bfh2; } if (topleft<=bottomleft && topright<=bottomright) return; type = seg->cstat & CSTAT_WALL_1WAY ? RENDERWALL_M1S : RENDERWALL_M2S; // todo: transparency. DoTexture(di, wal, wal, refheight, topleft, topright, bottomleft, bottomright); RenderStyle = STYLE_Translucent; alpha = 1.f; } //========================================================================== // // // //========================================================================== void HWWall::Process(HWDrawInfo* di, walltype* wal, sectortype* frontsector, sectortype* backsector) { auto backwall = wal->twoSided()? wal->nextWall() : nullptr; auto p2wall = wal->point2Wall(); float fch1; float ffh1; float fch2; float ffh2; FVector2 v1(WallStartX(wal), WallStartY(wal)); FVector2 v2(WallEndX(wal), WallEndY(wal)); PlanesAtPointf(frontsector, wal->pos.X, wal->pos.Y, &fch1, &ffh1); PlanesAtPointf(frontsector, p2wall->pos.X, p2wall->pos.Y, &fch2, &ffh2); #ifdef _DEBUG if (wallnum(wal) == 34) { int a = 0; } #endif this->seg = wal; this->frontsector = frontsector; this->backsector = backsector; Sprite = nullptr; vertindex = 0; vertcount = 0; glseg.x1 = v1.X; glseg.y1 = v1.Y; glseg.x2 = v2.X; glseg.y2 = v2.Y; glseg.fracleft = 0; glseg.fracright = 1; flags = 0; dynlightindex = -1; shade = wal->shade; palette = wal->pal; fade = lookups.getFade(wal->pal); visibility = sectorVisibility(frontsector); alpha = 1.0f; RenderStyle = STYLE_Translucent; texture = NULL; if (gl_seamless) { auto v = &vertices[vertexMap[wallnum(wal)]]; if (v->dirty) v->RecalcVertexHeights(); v = &vertices[vertexMap[wal->point2]]; if (v->dirty) v->RecalcVertexHeights(); } /* if (wal->linedef->special == Line_Horizon) { SkyNormal(di, frontsector, v1, v2); DoHorizon(di, wal, frontsector, v1, v2); return; } */ bool isportal = false;// wal->linedef->isVisualPortal() && wal->sidedef == wal->linedef->sidedef[0]; if (seg->portalflags) { int ptype = -1; if (seg->portalflags == PORTAL_WALL_MIRROR) ptype = PORTALTYPE_MIRROR; else if (seg->portalflags == PORTAL_WALL_VIEW) ptype = PORTALTYPE_LINETOLINE; else if (seg->portalflags == PORTAL_WALL_TO_SPRITE) ptype = PORTALTYPE_LINETOSPRITE; if (ptype != -1) { ztop[0] = fch1; ztop[1] = fch2; zbottom[0] = ffh1; zbottom[1] = ffh2; PutPortal(di, ptype, -1); return; } } if (!backsector || !backwall) { // sector's sky SkyNormal(di, frontsector, v1, v2, fch1, fch2, ffh1, ffh2); // normal texture int tilenum = ((wal->cstat & CSTAT_WALL_1WAY) && wal->nextwall != -1) ? wal->overpicnum : wal->picnum; gotpic.Set(tilenum); tileUpdatePicnum(&tilenum, wallnum(wal) + 16384, wal->cstat); texture = tileGetTexture(tilenum); if (texture && texture->isValid()) { DoOneSidedTexture(di, wal, frontsector, backsector, fch1, fch2, ffh1, ffh2); } } else // two sided { float bfh1; float bfh2; float bch1; float bch2; PlanesAtPointf(backsector, wal->pos.X, wal->pos.Y, &bch1, &bfh1); PlanesAtPointf(backsector, p2wall->pos.X, p2wall->pos.Y, &bch2, &bfh2); SkyTop(di, wal, frontsector, backsector, v1, v2, fch1, fch2); SkyBottom(di, wal, frontsector, backsector, v1, v2, ffh1, ffh2); // upper texture if (!(frontsector->ceilingstat & backsector->ceilingstat & CSTAT_SECTOR_SKY)) { float bch1a = bch1; float bch2a = bch2; if (ffh1 > bch1 || ffh2 > bch2) { // the back sector's floor obstructs part of this wall. Todo: Handle the portal case better. if ((ffh1 > bch1 && ffh2 > bch2) || frontsector->portalflags == PORTAL_SECTOR_FLOOR) { bch2a = ffh2; bch1a = ffh1; } } if (bch1a < fch1 || bch2a < fch2) { int tilenum = wal->picnum; gotpic.Set(tilenum); tileUpdatePicnum(&tilenum, wallnum(wal) + 16384, wal->cstat); texture = tileGetTexture(tilenum); if (texture && texture->isValid()) { DoUpperTexture(di, wal, frontsector, backsector, fch1, fch2, bch1a, bch2a); } } } if (wal->cstat & (CSTAT_WALL_MASKED | CSTAT_WALL_1WAY)) { int tilenum = wal->overpicnum; gotpic.Set(tilenum); tileUpdatePicnum(&tilenum, wallnum(wal) + 16384, wal->cstat); texture = tileGetTexture(tilenum); if (texture && texture->isValid()) { DoMidTexture(di, wal, frontsector, backsector, fch1, fch2, ffh1, ffh2, bch1, bch2, bfh1, bfh2); } } // lower texture if (!(frontsector->floorstat & backsector->floorstat & CSTAT_SECTOR_SKY)) { if (fch1 < bfh1 || fch2 < bfh2) { // the back sector's ceiling obstructs part of this wall. Todo: Handle the portal case better. if ((fch1 < bfh1 && fch2 < bfh2) || frontsector->portalflags == PORTAL_SECTOR_CEILING) { bfh1 = fch1; bfh2 = fch2; } } if (bfh1 > ffh1 || bfh2 > ffh2) { auto w = (wal->cstat & CSTAT_WALL_BOTTOM_SWAP) ? backwall : wal; int tilenum = w->picnum; gotpic.Set(tilenum); tileUpdatePicnum(&tilenum, wallnum(wal) + 16384, w->cstat); texture = tileGetTexture(tilenum); if (texture && texture->isValid()) { DoLowerTexture(di, wal, frontsector, backsector, bfh1, bfh2, ffh1, ffh2); } } } } } void HWWall::ProcessWallSprite(HWDrawInfo* di, tspritetype* spr, sectortype* sector) { auto tex = tileGetTexture(spr->picnum); if (!tex || !tex->isValid()) return; seg = nullptr; Sprite = spr; vec2_t pos[2]; int sprz = spr->pos.Z; GetWallSpritePosition(spr, spr->pos.vec2, pos, true); glseg.x1 = pos[0].X * (1 / 16.f); glseg.y1 = pos[0].Y * (1 / -16.f); glseg.x2 = pos[1].X * (1 / 16.f); glseg.y2 = pos[1].Y * (1 / -16.f); if (spr->cstat & CSTAT_SPRITE_ONE_SIDE) { if (PointOnLineSide(di->Viewpoint.Pos.X, di->Viewpoint.Pos.Y, glseg.x1, glseg.y1, glseg.x2 - glseg.x1, glseg.y2 - glseg.y1) <= 0) { return; } } vertindex = 0; vertcount = 0; type = RENDERWALL_M2S; frontsector = sector; backsector = sector; texture = tex; flags = HWF_CLAMPX|HWF_CLAMPY; dynlightindex = -1; shade = spr->shade; palette = spr->pal; fade = lookups.getFade(sector->floorpal); // fog is per sector. visibility = sectorVisibility(sector); SetSpriteTranslucency(Sprite, alpha, RenderStyle); int height, topofs; if (hw_hightile && TileFiles.tiledata[spr->picnum].hiofs.xsize) { height = TileFiles.tiledata[spr->picnum].hiofs.ysize; topofs = (TileFiles.tiledata[spr->picnum].hiofs.yoffs + spr->yoffset); } else { height = (int)tex->GetDisplayHeight(); topofs = ((int)tex->GetDisplayTopOffset() + spr->yoffset); } DVector2 vec{}; walldist = IsOnWall(spr, height, vec); if (walldist) { // project the sprite right onto the wall. auto v1 = NearestPointLine(pos[0].X, pos[0].Y, walldist); auto v2 = NearestPointLine(pos[1].X, pos[1].Y, walldist); glseg.x1 = v1.X * (1 / 16.f); glseg.y1 = v1.Y * (1 / -16.f); glseg.x2 = v2.X * (1 / 16.f); glseg.y2 = v2.Y * (1 / -16.f); } if (spr->cstat & CSTAT_SPRITE_YFLIP) topofs = -topofs; sprz -= ((topofs * spr->yrepeat) << 2); if (spr->cstat & CSTAT_SPRITE_YCENTER) { sprz += ((height * spr->yrepeat) << 1); if (height & 1) sprz += (spr->yrepeat << 1); // Odd yspans (taken from polymost as-is) } glseg.fracleft = 0; glseg.fracright = 1; tcs[LOLFT].u = tcs[UPLFT].u = (spr->cstat & CSTAT_SPRITE_XFLIP) ? 1.f : 0.f; tcs[LORGT].u = tcs[UPRGT].u = (spr->cstat & CSTAT_SPRITE_XFLIP) ? 0.f : 1.f; tcs[UPLFT].v = tcs[UPRGT].v = (spr->cstat & CSTAT_SPRITE_YFLIP) ? 1.f : 0.f; tcs[LOLFT].v = tcs[LORGT].v = (spr->cstat & CSTAT_SPRITE_YFLIP) ? 0.f : 1.f; zbottom[0] = zbottom[1] = (sprz) * (1 / -256.); ztop[0] = ztop[1] = (sprz - ((height * spr->yrepeat) << 2)) * (1 / -256.); if (zbottom[0] > ztop[0]) { // reorder coordinates to make the clipping code below behave. auto zz = zbottom[0]; zbottom[0] = zbottom[1] = ztop[0]; ztop[0] = ztop[1] = zz; tcs[UPLFT].v = tcs[UPRGT].v = 1.f - tcs[UPLFT].v; tcs[LOLFT].v = tcs[LORGT].v = 1.f - tcs[LOLFT].v; } // Clip sprites to ceilings/floors if (!(sector->ceilingstat & CSTAT_SECTOR_SKY)) { float polyh = (ztop[0] - zbottom[0]); float ceilingz = sector->ceilingz * (1 / -256.f); if (ceilingz < ztop[0] && ceilingz > zbottom[0]) { float newv = (ceilingz - zbottom[0]) / polyh; tcs[UPLFT].v = tcs[UPRGT].v = tcs[LOLFT].v + newv * (tcs[UPLFT].v - tcs[LOLFT].v); ztop[0] = ztop[1] = ceilingz; } } if (!(sector->floorstat & CSTAT_SECTOR_SKY)) { float polyh = (ztop[0] - zbottom[0]); float floorz = sector->floorz * (1 / -256.f); if (floorz < ztop[0] && floorz > zbottom[0]) { float newv = (floorz - zbottom[0]) / polyh; tcs[LOLFT].v = tcs[LORGT].v = tcs[LOLFT].v + newv * (tcs[UPLFT].v - tcs[LOLFT].v); zbottom[0] = zbottom[1] = floorz; } } // If the sprite is backward, flip it around so that we have guaranteed orientation when this is about to be sorted. if (PointOnLineSide(di->Viewpoint.Pos.XY(), DVector2(glseg.x1, glseg.y1), DVector2(glseg.x2, glseg.y2)) < 0) { std::swap(glseg.x1, glseg.x2); std::swap(glseg.y1, glseg.y2); // z is always the same on both sides. std::swap(tcs[LOLFT], tcs[LORGT]); std::swap(tcs[UPLFT], tcs[UPRGT]); } PutWall(di, spriteHasTranslucency(Sprite)); }