//************************************************************************** //** //** PO_MAN.C : Heretic 2 : Raven Software, Corp. //** //** $RCSfile: po_man.c,v $ //** $Revision: 1.22 $ //** $Date: 95/09/28 18:20:56 $ //** $Author: cjr $ //** //************************************************************************** // HEADER FILES ------------------------------------------------------------ #include "doomdef.h" #include "p_local.h" #include "i_system.h" #include "w_wad.h" #include "m_swap.h" #include "m_bbox.h" #include "tables.h" #include "s_sndseq.h" #include "a_sharedglobal.h" #include "p_3dmidtex.h" #include "p_lnspec.h" #include "r_data/r_interpolate.h" #include "g_level.h" #include "po_man.h" #include "p_setup.h" #include "vectors.h" #include "farchive.h" #include "p_blockmap.h" #include "p_maputl.h" #include "r_utility.h" // MACROS ------------------------------------------------------------------ #define PO_MAXPOLYSEGS 64 // TYPES ------------------------------------------------------------------- inline vertex_t *side_t::V1() const { return this == linedef->sidedef[0]? linedef->v1 : linedef->v2; } inline vertex_t *side_t::V2() const { return this == linedef->sidedef[0]? linedef->v2 : linedef->v1; } FArchive &operator<< (FArchive &arc, FPolyObj *&poly) { return arc.SerializePointer (polyobjs, (BYTE **)&poly, sizeof(FPolyObj)); } FArchive &operator<< (FArchive &arc, const FPolyObj *&poly) { return arc.SerializePointer (polyobjs, (BYTE **)&poly, sizeof(FPolyObj)); } inline FArchive &operator<< (FArchive &arc, podoortype_t &type) { BYTE val = (BYTE)type; arc << val; type = (podoortype_t)val; return arc; } class DPolyAction : public DThinker { DECLARE_CLASS (DPolyAction, DThinker) HAS_OBJECT_POINTERS public: DPolyAction (int polyNum); void Serialize (FArchive &arc); void Destroy(); void Stop(); int GetSpeed() const { return m_Speed; } void StopInterpolation (); protected: DPolyAction (); int m_PolyObj; int m_Speed; int m_Dist; TObjPtr m_Interpolation; void SetInterpolation (); }; class DRotatePoly : public DPolyAction { DECLARE_CLASS (DRotatePoly, DPolyAction) public: DRotatePoly (int polyNum); void Tick (); private: DRotatePoly (); friend bool EV_RotatePoly (line_t *line, int polyNum, int speed, int byteAngle, int direction, bool overRide); }; class DMovePoly : public DPolyAction { DECLARE_CLASS (DMovePoly, DPolyAction) public: DMovePoly (int polyNum); void Serialize (FArchive &arc); void Tick (); protected: DMovePoly (); int m_Angle; fixed_t m_xSpeed; // for sliding walls fixed_t m_ySpeed; friend bool EV_MovePoly (line_t *line, int polyNum, int speed, angle_t angle, fixed_t dist, bool overRide); }; class DMovePolyTo : public DPolyAction { DECLARE_CLASS(DMovePolyTo, DPolyAction) public: DMovePolyTo(int polyNum); void Serialize(FArchive &arc); void Tick(); protected: DMovePolyTo(); fixed_t m_xSpeed; fixed_t m_ySpeed; fixed_t m_xTarget; fixed_t m_yTarget; friend bool EV_MovePolyTo(line_t *line, int polyNum, int speed, fixed_t x, fixed_t y, bool overRide); }; class DPolyDoor : public DMovePoly { DECLARE_CLASS (DPolyDoor, DMovePoly) public: DPolyDoor (int polyNum, podoortype_t type); void Serialize (FArchive &arc); void Tick (); protected: int m_Direction; int m_TotalDist; int m_Tics; int m_WaitTics; podoortype_t m_Type; bool m_Close; friend bool EV_OpenPolyDoor (line_t *line, int polyNum, int speed, angle_t angle, int delay, int distance, podoortype_t type); private: DPolyDoor (); }; class FPolyMirrorIterator { FPolyObj *CurPoly; int UsedPolys[100]; // tracks mirrored polyobjects we've seen int NumUsedPolys; public: FPolyMirrorIterator(FPolyObj *poly); FPolyObj *NextMirror(); }; // EXTERNAL FUNCTION PROTOTYPES -------------------------------------------- void PO_Init (void); // PRIVATE FUNCTION PROTOTYPES --------------------------------------------- static void UnLinkPolyobj (FPolyObj *po); static void LinkPolyobj (FPolyObj *po); static bool CheckMobjBlocking (side_t *seg, FPolyObj *po); static void InitBlockMap (void); static void IterFindPolySides (FPolyObj *po, side_t *side); static void SpawnPolyobj (int index, int tag, int type); static void TranslateToStartSpot (int tag, int originX, int originY); static void DoMovePolyobj (FPolyObj *po, int x, int y); static void InitSegLists (); static void KillSegLists (); static FPolyNode *NewPolyNode(); static void FreePolyNode(); static void ReleaseAllPolyNodes(); // EXTERNAL DATA DECLARATIONS ---------------------------------------------- extern seg_t *segs; // PUBLIC DATA DEFINITIONS ------------------------------------------------- polyblock_t **PolyBlockMap; FPolyObj *polyobjs; // list of all poly-objects on the level int po_NumPolyobjs; polyspawns_t *polyspawns; // [RH] Let P_SpawnMapThings() find our thingies for us // PRIVATE DATA DEFINITIONS ------------------------------------------------ static TArray KnownPolySides; static FPolyNode *FreePolyNodes; // CODE -------------------------------------------------------------------- //========================================================================== // // // //========================================================================== IMPLEMENT_POINTY_CLASS (DPolyAction) DECLARE_POINTER(m_Interpolation) END_POINTERS DPolyAction::DPolyAction () { } void DPolyAction::Serialize (FArchive &arc) { Super::Serialize (arc); arc << m_PolyObj << m_Speed << m_Dist << m_Interpolation; } DPolyAction::DPolyAction (int polyNum) { m_PolyObj = polyNum; m_Speed = 0; m_Dist = 0; SetInterpolation (); } void DPolyAction::Destroy() { FPolyObj *poly = PO_GetPolyobj (m_PolyObj); if (poly->specialdata == this) { poly->specialdata = NULL; } StopInterpolation(); Super::Destroy(); } void DPolyAction::Stop() { FPolyObj *poly = PO_GetPolyobj(m_PolyObj); SN_StopSequence(poly); Destroy(); } void DPolyAction::SetInterpolation () { FPolyObj *poly = PO_GetPolyobj (m_PolyObj); m_Interpolation = poly->SetInterpolation(); } void DPolyAction::StopInterpolation () { if (m_Interpolation != NULL) { m_Interpolation->DelRef(); m_Interpolation = NULL; } } //========================================================================== // // // //========================================================================== IMPLEMENT_CLASS (DRotatePoly) DRotatePoly::DRotatePoly () { } DRotatePoly::DRotatePoly (int polyNum) : Super (polyNum) { } //========================================================================== // // // //========================================================================== IMPLEMENT_CLASS (DMovePoly) DMovePoly::DMovePoly () { } void DMovePoly::Serialize (FArchive &arc) { Super::Serialize (arc); arc << m_Angle << m_xSpeed << m_ySpeed; } DMovePoly::DMovePoly (int polyNum) : Super (polyNum) { m_Angle = 0; m_xSpeed = 0; m_ySpeed = 0; } //========================================================================== // // // // //========================================================================== IMPLEMENT_CLASS(DMovePolyTo) DMovePolyTo::DMovePolyTo() { } void DMovePolyTo::Serialize(FArchive &arc) { Super::Serialize(arc); arc << m_xSpeed << m_ySpeed << m_xTarget << m_yTarget; } DMovePolyTo::DMovePolyTo(int polyNum) : Super(polyNum) { m_xSpeed = 0; m_ySpeed = 0; m_xTarget = 0; m_yTarget = 0; } //========================================================================== // // // //========================================================================== IMPLEMENT_CLASS (DPolyDoor) DPolyDoor::DPolyDoor () { } void DPolyDoor::Serialize (FArchive &arc) { Super::Serialize (arc); arc << m_Direction << m_TotalDist << m_Tics << m_WaitTics << m_Type << m_Close; } DPolyDoor::DPolyDoor (int polyNum, podoortype_t type) : Super (polyNum), m_Type (type) { m_Direction = 0; m_TotalDist = 0; m_Tics = 0; m_WaitTics = 0; m_Close = false; } // ===== Polyobj Event Code ===== //========================================================================== // // T_RotatePoly // //========================================================================== void DRotatePoly::Tick () { FPolyObj *poly = PO_GetPolyobj (m_PolyObj); if (poly == NULL) return; // Don't let non-perpetual polyobjs overshoot their targets. if (m_Dist != -1 && (unsigned int)m_Dist < (unsigned int)abs(m_Speed)) { m_Speed = m_Speed < 0 ? -m_Dist : m_Dist; } if (poly->RotatePolyobj (m_Speed)) { if (m_Dist == -1) { // perpetual polyobj return; } m_Dist -= abs(m_Speed); if (m_Dist == 0) { SN_StopSequence (poly); Destroy (); } } } //========================================================================== // // EV_RotatePoly // //========================================================================== bool EV_RotatePoly (line_t *line, int polyNum, int speed, int byteAngle, int direction, bool overRide) { DRotatePoly *pe = NULL; FPolyObj *poly; if ((poly = PO_GetPolyobj(polyNum)) == NULL) { Printf("EV_RotatePoly: Invalid polyobj num: %d\n", polyNum); return false; } FPolyMirrorIterator it(poly); while ((poly = it.NextMirror()) != NULL) { if (poly->specialdata != NULL && !overRide) { // poly is already in motion break; } pe = new DRotatePoly(poly->tag); poly->specialdata = pe; if (byteAngle != 0) { if (byteAngle == 255) { pe->m_Dist = ~0; } else { pe->m_Dist = byteAngle*(ANGLE_90/64); // Angle } } else { pe->m_Dist = ANGLE_MAX-1; } pe->m_Speed = speed*direction*(ANGLE_90/(64<<3)); SN_StartSequence (poly, poly->seqType, SEQ_DOOR, 0); direction = -direction; // Reverse the direction } return pe != NULL; // Return true if something started moving. } //========================================================================== // // T_MovePoly // //========================================================================== void DMovePoly::Tick () { FPolyObj *poly = PO_GetPolyobj (m_PolyObj); if (poly != NULL) { if (poly->MovePolyobj (m_xSpeed, m_ySpeed)) { int absSpeed = abs (m_Speed); m_Dist -= absSpeed; if (m_Dist <= 0) { SN_StopSequence (poly); Destroy (); } else if (m_Dist < absSpeed) { m_Speed = m_Dist * (m_Speed < 0 ? -1 : 1); m_xSpeed = FixedMul (m_Speed, finecosine[m_Angle]); m_ySpeed = FixedMul (m_Speed, finesine[m_Angle]); } } } } //========================================================================== // // EV_MovePoly // //========================================================================== bool EV_MovePoly (line_t *line, int polyNum, int speed, angle_t angle, fixed_t dist, bool overRide) { DMovePoly *pe = NULL; FPolyObj *poly; angle_t an = angle; if ((poly = PO_GetPolyobj(polyNum)) == NULL) { Printf("EV_MovePoly: Invalid polyobj num: %d\n", polyNum); return false; } FPolyMirrorIterator it(poly); while ((poly = it.NextMirror()) != NULL) { if (poly->specialdata != NULL && !overRide) { // poly is already in motion break; } pe = new DMovePoly(poly->tag); poly->specialdata = pe; pe->m_Dist = dist; // Distance pe->m_Speed = speed; pe->m_Angle = an >> ANGLETOFINESHIFT; pe->m_xSpeed = FixedMul (pe->m_Speed, finecosine[pe->m_Angle]); pe->m_ySpeed = FixedMul (pe->m_Speed, finesine[pe->m_Angle]); SN_StartSequence (poly, poly->seqType, SEQ_DOOR, 0); // Do not interpolate very fast moving polyobjects. The minimum tic count is // 3 instead of 2, because the moving crate effect in Massmouth 2, Hostitality // that this fixes isn't quite fast enough to move the crate back to its start // in just 1 tic. if (dist/speed <= 2) { pe->StopInterpolation (); } an = an + ANGLE_180; // Reverse the angle. } return pe != NULL; // Return true if something started moving. } //========================================================================== // // DMovePolyTo :: Tick // //========================================================================== void DMovePolyTo::Tick () { FPolyObj *poly = PO_GetPolyobj (m_PolyObj); if (poly != NULL) { if (poly->MovePolyobj (m_xSpeed, m_ySpeed)) { int absSpeed = abs (m_Speed); m_Dist -= absSpeed; if (m_Dist <= 0) { SN_StopSequence (poly); Destroy (); } else if (m_Dist < absSpeed) { m_Speed = m_Dist * (m_Speed < 0 ? -1 : 1); m_xSpeed = m_xTarget - poly->StartSpot.x; m_ySpeed = m_yTarget - poly->StartSpot.y; } } } } //========================================================================== // // EV_MovePolyTo // //========================================================================== bool EV_MovePolyTo(line_t *line, int polyNum, int speed, fixed_t targx, fixed_t targy, bool overRide) { DMovePolyTo *pe = NULL; FPolyObj *poly; DVector2 dist; double distlen; if ((poly = PO_GetPolyobj(polyNum)) == NULL) { Printf("EV_MovePolyTo: Invalid polyobj num: %d\n", polyNum); return false; } FPolyMirrorIterator it(poly); dist.X = targx - poly->StartSpot.x; dist.Y = targy - poly->StartSpot.y; distlen = dist.MakeUnit(); while ((poly = it.NextMirror()) != NULL) { if (poly->specialdata != NULL && !overRide) { // poly is already in motion break; } pe = new DMovePolyTo(poly->tag); poly->specialdata = pe; pe->m_Dist = xs_RoundToInt(distlen); pe->m_Speed = speed; pe->m_xSpeed = xs_RoundToInt(speed * dist.X); pe->m_ySpeed = xs_RoundToInt(speed * dist.Y); pe->m_xTarget = xs_RoundToInt(poly->StartSpot.x + distlen * dist.X); pe->m_yTarget = xs_RoundToInt(poly->StartSpot.y + distlen * dist.Y); if ((pe->m_Dist / pe->m_Speed) <= 2) { pe->StopInterpolation(); } dist = -dist; // reverse the direction } return pe != NULL; // Return true if something started moving. } //========================================================================== // // T_PolyDoor // //========================================================================== void DPolyDoor::Tick () { int absSpeed; FPolyObj *poly = PO_GetPolyobj (m_PolyObj); if (poly == NULL) return; if (m_Tics) { if (!--m_Tics) { SN_StartSequence (poly, poly->seqType, SEQ_DOOR, m_Close); } return; } switch (m_Type) { case PODOOR_SLIDE: if (m_Dist <= 0 || poly->MovePolyobj (m_xSpeed, m_ySpeed)) { absSpeed = abs (m_Speed); m_Dist -= absSpeed; if (m_Dist <= 0) { SN_StopSequence (poly); if (!m_Close) { m_Dist = m_TotalDist; m_Close = true; m_Tics = m_WaitTics; m_Direction = (ANGLE_MAX>>ANGLETOFINESHIFT) - m_Direction; m_xSpeed = -m_xSpeed; m_ySpeed = -m_ySpeed; } else { Destroy (); } } } else { if (poly->crush || !m_Close) { // continue moving if the poly is a crusher, or is opening return; } else { // open back up m_Dist = m_TotalDist - m_Dist; m_Direction = (ANGLE_MAX>>ANGLETOFINESHIFT)- m_Direction; m_xSpeed = -m_xSpeed; m_ySpeed = -m_ySpeed; m_Close = false; SN_StartSequence (poly, poly->seqType, SEQ_DOOR, 0); } } break; case PODOOR_SWING: if (m_Dist <= 0 || poly->RotatePolyobj (m_Speed)) { absSpeed = abs (m_Speed); m_Dist -= absSpeed; if (m_Dist <= 0) { SN_StopSequence (poly); if (!m_Close) { m_Dist = m_TotalDist; m_Close = true; m_Tics = m_WaitTics; m_Speed = -m_Speed; } else { Destroy (); } } } else { if(poly->crush || !m_Close) { // continue moving if the poly is a crusher, or is opening return; } else { // open back up and rewait m_Dist = m_TotalDist - m_Dist; m_Speed = -m_Speed; m_Close = false; SN_StartSequence (poly, poly->seqType, SEQ_DOOR, 0); } } break; default: break; } } //========================================================================== // // EV_OpenPolyDoor // //========================================================================== bool EV_OpenPolyDoor (line_t *line, int polyNum, int speed, angle_t angle, int delay, int distance, podoortype_t type) { DPolyDoor *pd = NULL; FPolyObj *poly; int swingdir = 1; // ADD: PODOOR_SWINGL, PODOOR_SWINGR if ((poly = PO_GetPolyobj(polyNum)) == NULL) { Printf("EV_OpenPolyDoor: Invalid polyobj num: %d\n", polyNum); return false; } FPolyMirrorIterator it(poly); while ((poly = it.NextMirror()) != NULL) { if (poly->specialdata != NULL) { // poly is already moving break; } pd = new DPolyDoor(poly->tag, type); poly->specialdata = pd; if (type == PODOOR_SLIDE) { pd->m_WaitTics = delay; pd->m_Speed = speed; pd->m_Dist = pd->m_TotalDist = distance; // Distance pd->m_Direction = angle >> ANGLETOFINESHIFT; pd->m_xSpeed = FixedMul (pd->m_Speed, finecosine[pd->m_Direction]); pd->m_ySpeed = FixedMul (pd->m_Speed, finesine[pd->m_Direction]); SN_StartSequence (poly, poly->seqType, SEQ_DOOR, 0); angle += ANGLE_180; // reverse the angle } else if (type == PODOOR_SWING) { pd->m_WaitTics = delay; pd->m_Direction = swingdir; pd->m_Speed = (speed*pd->m_Direction*(ANGLE_90/64))>>3; pd->m_Dist = pd->m_TotalDist = angle; SN_StartSequence (poly, poly->seqType, SEQ_DOOR, 0); swingdir = -swingdir; // reverse the direction } } return pd != NULL; // Return true if something started moving. } //========================================================================== // // EV_StopPoly // //========================================================================== bool EV_StopPoly(int polynum) { FPolyObj *poly; if (NULL != (poly = PO_GetPolyobj(polynum))) { if (poly->specialdata != NULL) { poly->specialdata->Stop(); } return true; } return false; } // ===== Higher Level Poly Interface code ===== //========================================================================== // // PO_GetPolyobj // //========================================================================== FPolyObj *PO_GetPolyobj (int polyNum) { int i; for (i = 0; i < po_NumPolyobjs; i++) { if (polyobjs[i].tag == polyNum) { return &polyobjs[i]; } } return NULL; } //========================================================================== // // // //========================================================================== FPolyObj::FPolyObj() { StartSpot.x = StartSpot.y = 0; angle = 0; tag = 0; memset(bbox, 0, sizeof(bbox)); validcount = 0; crush = 0; bHurtOnTouch = false; seqType = 0; size = 0; subsectorlinks = NULL; specialdata = NULL; interpolation = NULL; } //========================================================================== // // GetPolyobjMirror // //========================================================================== int FPolyObj::GetMirror() { return MirrorNum; } //========================================================================== // // ThrustMobj // //========================================================================== void FPolyObj::ThrustMobj (AActor *actor, side_t *side) { DAngle thrustAngle; DPolyAction *pe; int force; if (!(actor->flags&MF_SHOOTABLE) && !actor->player) { return; } vertex_t *v1 = side->V1(); vertex_t *v2 = side->V2(); thrustAngle = (v2->fPos() - v1->fPos()).Angle() - 90.; pe = static_cast(specialdata); if (pe) { if (pe->IsKindOf (RUNTIME_CLASS (DRotatePoly))) { force = pe->GetSpeed() >> 8; } else { force = pe->GetSpeed() >> 3; } if (force < FRACUNIT) { force = FRACUNIT; } else if (force > 4*FRACUNIT) { force = 4*FRACUNIT; } } else { force = FRACUNIT; } DVector2 thrust = thrustAngle.ToVector(FIXED2FLOAT(force)); actor->Vel += thrust; if (crush) { DVector2 pos = actor->Vec2Offset(thrust.X, thrust.Y); if (bHurtOnTouch || !P_CheckMove (actor, pos)) { int newdam = P_DamageMobj (actor, NULL, NULL, crush, NAME_Crush); P_TraceBleed (newdam > 0 ? newdam : crush, actor); } } if (level.flags2 & LEVEL2_POLYGRIND) actor->Grind(false); // crush corpses that get caught in a polyobject's way } //========================================================================== // // UpdateSegBBox // //========================================================================== void FPolyObj::UpdateBBox () { for(unsigned i=0;iv1->fixX() < line->v2->fixX()) { line->bbox[BOXLEFT] = line->v1->fixX(); line->bbox[BOXRIGHT] = line->v2->fixX(); } else { line->bbox[BOXLEFT] = line->v2->fixX(); line->bbox[BOXRIGHT] = line->v1->fixX(); } if (line->v1->fixY() < line->v2->fixY()) { line->bbox[BOXBOTTOM] = line->v1->fixY(); line->bbox[BOXTOP] = line->v2->fixY(); } else { line->bbox[BOXBOTTOM] = line->v2->fixY(); line->bbox[BOXTOP] = line->v1->fixY(); } // Update the line's slopetype line->setDelta( line->v2->fixX() - line->v1->fixX(), line->v2->fixY() - line->v1->fixY()); } CalcCenter(); } void FPolyObj::CalcCenter() { SQWORD cx = 0, cy = 0; for(unsigned i=0;ifixX(); cy += Vertices[i]->fixY(); } CenterSpot.x = (fixed_t)(cx / Vertices.Size()); CenterSpot.y = (fixed_t)(cy / Vertices.Size()); } //========================================================================== // // PO_MovePolyobj // //========================================================================== bool FPolyObj::MovePolyobj (int x, int y, bool force) { FBoundingBox oldbounds = Bounds; UnLinkPolyobj (); DoMovePolyobj (x, y); if (!force) { bool blocked = false; for(unsigned i=0;i < Sidedefs.Size(); i++) { if (CheckMobjBlocking(Sidedefs[i])) { blocked = true; } } if (blocked) { DoMovePolyobj (-x, -y); LinkPolyobj(); return false; } } StartSpot.x += x; StartSpot.y += y; CenterSpot.x += x; CenterSpot.y += y; LinkPolyobj (); ClearSubsectorLinks(); RecalcActorFloorCeil(Bounds | oldbounds); return true; } //========================================================================== // // DoMovePolyobj // //========================================================================== void FPolyObj::DoMovePolyobj (int x, int y) { for(unsigned i=0;i < Vertices.Size(); i++) { Vertices[i]->set(Vertices[i]->fixX() + x, Vertices[i]->fixY() + y); PrevPts[i].x += x; PrevPts[i].y += y; } for (unsigned i = 0; i < Linedefs.Size(); i++) { Linedefs[i]->bbox[BOXTOP] += y; Linedefs[i]->bbox[BOXBOTTOM] += y; Linedefs[i]->bbox[BOXLEFT] += x; Linedefs[i]->bbox[BOXRIGHT] += x; } } //========================================================================== // // RotatePt // //========================================================================== static void RotatePt (DAngle an, fixed_t *x, fixed_t *y, fixed_t startSpotX, fixed_t startSpotY) { fixed_t tr_x = *x; fixed_t tr_y = *y; double s = an.Sin(); double c = an.Cos(); *x = (xs_CRoundToInt(tr_x * c - tr_y*s) & 0xfffffe00) + startSpotX; *y = (xs_CRoundToInt(tr_x * s + tr_y*c) & 0xfffffe00) + startSpotY; } //========================================================================== // // PO_RotatePolyobj // //========================================================================== bool FPolyObj::RotatePolyobj (angle_t angle, bool fromsave) { DAngle an; bool blocked; FBoundingBox oldbounds = Bounds; an = ANGLE2DBL(this->angle + angle); UnLinkPolyobj(); for(unsigned i=0;i < Vertices.Size(); i++) { PrevPts[i].x = Vertices[i]->fixX(); PrevPts[i].y = Vertices[i]->fixY(); FPolyVertex torot = OriginalPts[i]; RotatePt(an, &torot.x, &torot.y, StartSpot.x, StartSpot.y); Vertices[i]->set(torot.x, torot.y); } blocked = false; validcount++; UpdateBBox(); // If we are loading a savegame we do not really want to damage actors and be blocked by them. This can also cause crashes when trying to damage incompletely deserialized player pawns. if (!fromsave) { for (unsigned i = 0; i < Sidedefs.Size(); i++) { if (CheckMobjBlocking(Sidedefs[i])) { blocked = true; } } if (blocked) { for(unsigned i=0;i < Vertices.Size(); i++) { Vertices[i]->set(PrevPts[i].x, PrevPts[i].y); } UpdateBBox(); LinkPolyobj(); return false; } } this->angle += angle; LinkPolyobj(); ClearSubsectorLinks(); RecalcActorFloorCeil(Bounds | oldbounds); return true; } //========================================================================== // // UnLinkPolyobj // //========================================================================== void FPolyObj::UnLinkPolyobj () { polyblock_t *link; int i, j; int index; // remove the polyobj from each blockmap section for(j = bbox[BOXBOTTOM]; j <= bbox[BOXTOP]; j++) { index = j*bmapwidth; for(i = bbox[BOXLEFT]; i <= bbox[BOXRIGHT]; i++) { if(i >= 0 && i < bmapwidth && j >= 0 && j < bmapheight) { link = PolyBlockMap[index+i]; while(link != NULL && link->polyobj != this) { link = link->next; } if(link == NULL) { // polyobj not located in the link cell continue; } link->polyobj = NULL; } } } } //========================================================================== // // CheckMobjBlocking // //========================================================================== bool FPolyObj::CheckMobjBlocking (side_t *sd) { static TArray checker; FBlockNode *block; AActor *mobj; int i, j, k; int left, right, top, bottom; line_t *ld; bool blocked; bool performBlockingThrust; ld = sd->linedef; top = GetSafeBlockY(ld->bbox[BOXTOP]-bmaporgy); bottom = GetSafeBlockY(ld->bbox[BOXBOTTOM]-bmaporgy); left = GetSafeBlockX(ld->bbox[BOXLEFT]-bmaporgx); right = GetSafeBlockX(ld->bbox[BOXRIGHT]-bmaporgx); blocked = false; checker.Clear(); bottom = bottom < 0 ? 0 : bottom; bottom = bottom >= bmapheight ? bmapheight-1 : bottom; top = top < 0 ? 0 : top; top = top >= bmapheight ? bmapheight-1 : top; left = left < 0 ? 0 : left; left = left >= bmapwidth ? bmapwidth-1 : left; right = right < 0 ? 0 : right; right = right >= bmapwidth ? bmapwidth-1 : right; for (j = bottom*bmapwidth; j <= top*bmapwidth; j += bmapwidth) { for (i = left; i <= right; i++) { for (block = blocklinks[j+i]; block != NULL; block = block->NextActor) { mobj = block->Me; for (k = (int)checker.Size()-1; k >= 0; --k) { if (checker[k] == mobj) { break; } } if (k < 0) { checker.Push (mobj); if ((mobj->flags&MF_SOLID) && !(mobj->flags&MF_NOCLIP)) { FLineOpening open; open.top = LINEOPEN_MAX; open.bottom = LINEOPEN_MIN; // [TN] Check wether this actor gets blocked by the line. if (ld->backsector != NULL && !(ld->flags & (ML_BLOCKING|ML_BLOCKEVERYTHING)) && !(ld->flags & ML_BLOCK_PLAYERS && mobj->player) && !(ld->flags & ML_BLOCKMONSTERS && mobj->flags3 & MF3_ISMONSTER) && !((mobj->flags & MF_FLOAT) && (ld->flags & ML_BLOCK_FLOATERS)) && (!(ld->flags & ML_3DMIDTEX) || (!P_LineOpening_3dMidtex(mobj, ld, open) && (mobj->Top() < open.top) ) || (open.abovemidtex && mobj->Z() > mobj->floorz)) ) { // [BL] We can't just continue here since we must // determine if the line's backsector is going to // be blocked. performBlockingThrust = false; } else { performBlockingThrust = true; } FBoundingBox box(mobj->_f_X(), mobj->_f_Y(), mobj->_f_radius()); if (box.Right() <= ld->bbox[BOXLEFT] || box.Left() >= ld->bbox[BOXRIGHT] || box.Top() <= ld->bbox[BOXBOTTOM] || box.Bottom() >= ld->bbox[BOXTOP]) { continue; } if (box.BoxOnLineSide(ld) != -1) { continue; } // We have a two-sided linedef so we should only check one side // so that the thrust from both sides doesn't cancel each other out. // Best use the one facing the player and ignore the back side. if (ld->sidedef[1] != NULL) { int side = P_PointOnLineSidePrecise(mobj->Pos(), ld); if (ld->sidedef[side] != sd) { continue; } // [BL] See if we hit below the floor/ceiling of the poly. else if(!performBlockingThrust && ( mobj->Z() < ld->sidedef[!side]->sector->GetSecPlane(sector_t::floor).ZatPoint(mobj) || mobj->Top() > ld->sidedef[!side]->sector->GetSecPlane(sector_t::ceiling).ZatPoint(mobj) )) { performBlockingThrust = true; } } if(performBlockingThrust) { ThrustMobj (mobj, sd); blocked = true; } else continue; } } } } } return blocked; } //========================================================================== // // LinkPolyobj // //========================================================================== void FPolyObj::LinkPolyobj () { polyblock_t **link; polyblock_t *tempLink; // calculate the polyobj bbox Bounds.ClearBox(); for(unsigned i = 0; i < Sidedefs.Size(); i++) { vertex_t *vt; vt = Sidedefs[i]->linedef->v1; Bounds.AddToBox(vt->fixX(), vt->fixY()); vt = Sidedefs[i]->linedef->v2; Bounds.AddToBox(vt->fixX(), vt->fixY()); } bbox[BOXRIGHT] = GetSafeBlockX(Bounds.Right() - bmaporgx); bbox[BOXLEFT] = GetSafeBlockX(Bounds.Left() - bmaporgx); bbox[BOXTOP] = GetSafeBlockY(Bounds.Top() - bmaporgy); bbox[BOXBOTTOM] = GetSafeBlockY(Bounds.Bottom() - bmaporgy); // add the polyobj to each blockmap section for(int j = bbox[BOXBOTTOM]*bmapwidth; j <= bbox[BOXTOP]*bmapwidth; j += bmapwidth) { for(int i = bbox[BOXLEFT]; i <= bbox[BOXRIGHT]; i++) { if(i >= 0 && i < bmapwidth && j >= 0 && j < bmapheight*bmapwidth) { link = &PolyBlockMap[j+i]; if(!(*link)) { // Create a new link at the current block cell *link = new polyblock_t; (*link)->next = NULL; (*link)->prev = NULL; (*link)->polyobj = this; continue; } else { tempLink = *link; while(tempLink->next != NULL && tempLink->polyobj != NULL) { tempLink = tempLink->next; } } if(tempLink->polyobj == NULL) { tempLink->polyobj = this; continue; } else { tempLink->next = new polyblock_t; tempLink->next->next = NULL; tempLink->next->prev = tempLink; tempLink->next->polyobj = this; } } // else, don't link the polyobj, since it's off the map } } } //=========================================================================== // // FPolyObj :: RecalcActorFloorCeil // // For each actor within the bounding box, recalculate its floorz, ceilingz, // and related values. // //=========================================================================== void FPolyObj::RecalcActorFloorCeil(FBoundingBox bounds) const { FBlockThingsIterator it(bounds); AActor *actor; while ((actor = it.Next()) != NULL) { P_FindFloorCeiling(actor); } } //=========================================================================== // // PO_ClosestPoint // // Given a point (x,y), returns the point (ox,oy) on the polyobject's walls // that is nearest to (x,y). Also returns the seg this point came from. // //=========================================================================== void FPolyObj::ClosestPoint(fixed_t fx, fixed_t fy, fixed_t &ox, fixed_t &oy, side_t **side) const { unsigned int i; double x = fx, y = fy; double bestdist = HUGE_VAL; double bestx = 0, besty = 0; side_t *bestline = NULL; for (i = 0; i < Sidedefs.Size(); ++i) { vertex_t *v1 = Sidedefs[i]->V1(); vertex_t *v2 = Sidedefs[i]->V2(); double a = v2->fixX() - v1->fixX(); double b = v2->fixY() - v1->fixY(); double den = a*a + b*b; double ix, iy, dist; if (den == 0) { // Line is actually a point! ix = v1->fixX(); iy = v1->fixY(); } else { double num = (x - v1->fixX()) * a + (y - v1->fixY()) * b; double u = num / den; if (u <= 0) { ix = v1->fixX(); iy = v1->fixY(); } else if (u >= 1) { ix = v2->fixX(); iy = v2->fixY(); } else { ix = v1->fixX() + u * a; iy = v1->fixY() + u * b; } } a = (ix - x); b = (iy - y); dist = a*a + b*b; if (dist < bestdist) { bestdist = dist; bestx = ix; besty = iy; bestline = Sidedefs[i]; } } ox = fixed_t(bestx); oy = fixed_t(besty); if (side != NULL) { *side = bestline; } } //========================================================================== // // InitBlockMap // //========================================================================== static void InitBlockMap (void) { int i; PolyBlockMap = new polyblock_t *[bmapwidth*bmapheight]; memset (PolyBlockMap, 0, bmapwidth*bmapheight*sizeof(polyblock_t *)); for (i = 0; i < po_NumPolyobjs; i++) { polyobjs[i].LinkPolyobj(); } } //========================================================================== // // InitSideLists [RH] // // Group sides by vertex and collect side that are known to belong to a // polyobject so that they can be initialized fast. //========================================================================== static void InitSideLists () { for (int i = 0; i < numsides; ++i) { if (sides[i].linedef != NULL && (sides[i].linedef->special == Polyobj_StartLine || sides[i].linedef->special == Polyobj_ExplicitLine)) { KnownPolySides.Push (i); } } } //========================================================================== // // KillSideLists [RH] // //========================================================================== static void KillSideLists () { KnownPolySides.Clear (); KnownPolySides.ShrinkToFit (); } //========================================================================== // // AddPolyVert // // Helper function for IterFindPolySides() // //========================================================================== static void AddPolyVert(TArray &vnum, DWORD vert) { for (unsigned int i = vnum.Size() - 1; i-- != 0; ) { if (vnum[i] == vert) { // Already in the set. No need to add it. return; } } vnum.Push(vert); } //========================================================================== // // IterFindPolySides // // Beginning with the first vertex of the starting side, for each vertex // in vnum, add all the sides that use it as a first vertex to the polyobj, // and add all their second vertices to vnum. This continues until there // are no new vertices in vnum. // //========================================================================== static void IterFindPolySides (FPolyObj *po, side_t *side) { static TArray vnum; unsigned int vnumat; assert(sidetemp != NULL); vnum.Clear(); vnum.Push(DWORD(side->V1() - vertexes)); vnumat = 0; while (vnum.Size() != vnumat) { DWORD sidenum = sidetemp[vnum[vnumat++]].b.first; while (sidenum != NO_SIDE) { po->Sidedefs.Push(&sides[sidenum]); AddPolyVert(vnum, DWORD(sides[sidenum].V2() - vertexes)); sidenum = sidetemp[sidenum].b.next; } } } //========================================================================== // // SpawnPolyobj // //========================================================================== static int STACK_ARGS posicmp(const void *a, const void *b) { return (*(const side_t **)a)->linedef->args[1] - (*(const side_t **)b)->linedef->args[1]; } static void SpawnPolyobj (int index, int tag, int type) { unsigned int ii; int i; FPolyObj *po = &polyobjs[index]; for (ii = 0; ii < KnownPolySides.Size(); ++ii) { i = KnownPolySides[ii]; if (i < 0) { continue; } side_t *sd = &sides[i]; if (sd->linedef->special == Polyobj_StartLine && sd->linedef->args[0] == tag) { if (po->Sidedefs.Size() > 0) { I_Error ("SpawnPolyobj: Polyobj %d already spawned.\n", tag); } sd->linedef->special = 0; sd->linedef->args[0] = 0; IterFindPolySides(&polyobjs[index], sd); po->MirrorNum = sd->linedef->args[1]; po->crush = (type != SMT_PolySpawn) ? 3 : 0; po->bHurtOnTouch = (type == SMT_PolySpawnHurt); po->tag = tag; po->seqType = sd->linedef->args[2]; if (po->seqType < 0 || po->seqType > 63) { po->seqType = 0; } break; } } if (po->Sidedefs.Size() == 0) { // didn't find a polyobj through PO_LINE_START TArray polySideList; unsigned int psIndexOld; psIndexOld = po->Sidedefs.Size(); for (ii = 0; ii < KnownPolySides.Size(); ++ii) { i = KnownPolySides[ii]; if (i >= 0 && sides[i].linedef->special == Polyobj_ExplicitLine && sides[i].linedef->args[0] == tag) { if (!sides[i].linedef->args[1]) { I_Error("SpawnPolyobj: Explicit line missing order number in poly %d, linedef %d.\n", tag, int(sides[i].linedef - lines)); } po->Sidedefs.Push (&sides[i]); } } qsort(&po->Sidedefs[0], po->Sidedefs.Size(), sizeof(po->Sidedefs[0]), posicmp); if (po->Sidedefs.Size() > 0) { po->crush = (type != SMT_PolySpawn) ? 3 : 0; po->bHurtOnTouch = (type == SMT_PolySpawnHurt); po->tag = tag; po->seqType = po->Sidedefs[0]->linedef->args[3]; po->MirrorNum = po->Sidedefs[0]->linedef->args[2]; } else I_Error ("SpawnPolyobj: Poly %d does not exist\n", tag); } validcount++; for(unsigned int i=0; iSidedefs.Size(); i++) { line_t *l = po->Sidedefs[i]->linedef; if (l->validcount != validcount) { l->validcount = validcount; po->Linedefs.Push(l); vertex_t *v = l->v1; int j; for(j = po->Vertices.Size() - 1; j >= 0; j--) { if (po->Vertices[j] == v) break; } if (j < 0) po->Vertices.Push(v); v = l->v2; for(j = po->Vertices.Size() - 1; j >= 0; j--) { if (po->Vertices[j] == v) break; } if (j < 0) po->Vertices.Push(v); } } po->Sidedefs.ShrinkToFit(); po->Linedefs.ShrinkToFit(); po->Vertices.ShrinkToFit(); } //========================================================================== // // TranslateToStartSpot // //========================================================================== static void TranslateToStartSpot (int tag, int originX, int originY) { FPolyObj *po; int deltaX; int deltaY; po = NULL; for (int i = 0; i < po_NumPolyobjs; i++) { if (polyobjs[i].tag == tag) { po = &polyobjs[i]; break; } } if (po == NULL) { // didn't match the tag with a polyobj tag I_Error("TranslateToStartSpot: Unable to match polyobj tag: %d\n", tag); } if (po->Sidedefs.Size() == 0) { I_Error ("TranslateToStartSpot: Anchor point located without a StartSpot point: %d\n", tag); } po->OriginalPts.Resize(po->Sidedefs.Size()); po->PrevPts.Resize(po->Sidedefs.Size()); deltaX = originX - po->StartSpot.x; deltaY = originY - po->StartSpot.y; for (unsigned i = 0; i < po->Sidedefs.Size(); i++) { po->Sidedefs[i]->Flags |= WALLF_POLYOBJ; } for (unsigned i = 0; i < po->Linedefs.Size(); i++) { po->Linedefs[i]->bbox[BOXTOP] -= deltaY; po->Linedefs[i]->bbox[BOXBOTTOM] -= deltaY; po->Linedefs[i]->bbox[BOXLEFT] -= deltaX; po->Linedefs[i]->bbox[BOXRIGHT] -= deltaX; } for (unsigned i = 0; i < po->Vertices.Size(); i++) { po->Vertices[i]->set(po->Vertices[i]->fixX() - deltaX, po->Vertices[i]->fixY() - deltaY); po->OriginalPts[i].x = po->Vertices[i]->fixX() - po->StartSpot.x; po->OriginalPts[i].y = po->Vertices[i]->fixY() - po->StartSpot.y; } po->CalcCenter(); // For compatibility purposes po->CenterSubsector = R_PointInSubsector(po->CenterSpot.x, po->CenterSpot.y); } //========================================================================== // // PO_Init // //========================================================================== void PO_Init (void) { // [RH] Hexen found the polyobject-related things by reloading the map's // THINGS lump here and scanning through it. I have P_SpawnMapThing() // record those things instead, so that in here we simply need to // look at the polyspawns list. polyspawns_t *polyspawn, **prev; int polyIndex; // [RH] Make this faster InitSideLists (); polyobjs = new FPolyObj[po_NumPolyobjs]; polyIndex = 0; // index polyobj number // Find the startSpot points, and spawn each polyobj for (polyspawn = polyspawns, prev = &polyspawns; polyspawn;) { // 9301 (3001) = no crush, 9302 (3002) = crushing, 9303 = hurting touch if (polyspawn->type >= SMT_PolySpawn && polyspawn->type <= SMT_PolySpawnHurt) { // Polyobj StartSpot Pt. polyobjs[polyIndex].StartSpot.x = FLOAT2FIXED(polyspawn->pos.X); polyobjs[polyIndex].StartSpot.y = FLOAT2FIXED(polyspawn->pos.Y); SpawnPolyobj(polyIndex, polyspawn->angle, polyspawn->type); polyIndex++; *prev = polyspawn->next; delete polyspawn; polyspawn = *prev; } else { prev = &polyspawn->next; polyspawn = polyspawn->next; } } for (polyspawn = polyspawns; polyspawn;) { polyspawns_t *next = polyspawn->next; if (polyspawn->type == SMT_PolyAnchor) { // Polyobj Anchor Pt. TranslateToStartSpot (polyspawn->angle, FLOAT2FIXED(polyspawn->pos.X), FLOAT2FIXED(polyspawn->pos.Y)); } delete polyspawn; polyspawn = next; } polyspawns = NULL; // check for a startspot without an anchor point for (polyIndex = 0; polyIndex < po_NumPolyobjs; polyIndex++) { if (polyobjs[polyIndex].OriginalPts.Size() == 0) { I_Error ("PO_Init: StartSpot located without an Anchor point: %d\n", polyobjs[polyIndex].tag); } } InitBlockMap(); // [RH] Don't need the seg lists anymore KillSideLists (); for(int i=0;idx; double fdy = (double)no->dy; no->len = (float)g_sqrt(fdx * fdx + fdy * fdy); } // mark all subsectors which have a seg belonging to a polyobj // These ones should not be rendered on the textured automap. for (int i = 0; i < numsubsectors; i++) { subsector_t *ss = &subsectors[i]; for(DWORD j=0;jnumlines; j++) { if (ss->firstline[j].sidedef != NULL && ss->firstline[j].sidedef->Flags & WALLF_POLYOBJ) { ss->flags |= SSECF_POLYORG; break; } } } } //========================================================================== // // PO_Busy // //========================================================================== bool PO_Busy (int polyobj) { FPolyObj *poly; poly = PO_GetPolyobj (polyobj); return (poly != NULL && poly->specialdata != NULL); } //========================================================================== // // // //========================================================================== void FPolyObj::ClearSubsectorLinks() { while (subsectorlinks != NULL) { assert(subsectorlinks->state == 1337); FPolyNode *next = subsectorlinks->snext; if (subsectorlinks->pnext != NULL) { assert(subsectorlinks->pnext->state == 1337); subsectorlinks->pnext->pprev = subsectorlinks->pprev; } if (subsectorlinks->pprev != NULL) { assert(subsectorlinks->pprev->state == 1337); subsectorlinks->pprev->pnext = subsectorlinks->pnext; } else { subsectorlinks->subsector->polys = subsectorlinks->pnext; } if (subsectorlinks->subsector->BSP != NULL) { subsectorlinks->subsector->BSP->bDirty = true; } subsectorlinks->state = -1; delete subsectorlinks; subsectorlinks = next; } subsectorlinks = NULL; } void FPolyObj::ClearAllSubsectorLinks() { for (int i = 0; i < po_NumPolyobjs; i++) { polyobjs[i].ClearSubsectorLinks(); } ReleaseAllPolyNodes(); } //========================================================================== // // GetIntersection // // adapted from P_InterceptVector // //========================================================================== static bool GetIntersection(FPolySeg *seg, node_t *bsp, FPolyVertex *v) { double frac; double num; double den; double v2x = (double)seg->v1.x; double v2y = (double)seg->v1.y; double v2dx = (double)(seg->v2.x - seg->v1.x); double v2dy = (double)(seg->v2.y - seg->v1.y); double v1x = (double)bsp->x; double v1y = (double)bsp->y; double v1dx = (double)bsp->dx; double v1dy = (double)bsp->dy; den = v1dy*v2dx - v1dx*v2dy; if (den == 0) return false; // parallel num = (v1x - v2x)*v1dy + (v2y - v1y)*v1dx; frac = num / den; if (frac < 0. || frac > 1.) return false; v->x = xs_RoundToInt(v2x + frac * v2dx); v->y = xs_RoundToInt(v2y + frac * v2dy); return true; } //========================================================================== // // PartitionDistance // // Determine the distance of a vertex to a node's partition line. // //========================================================================== static double PartitionDistance(FPolyVertex *vt, node_t *node) { return fabs(double(-node->dy) * (vt->x - node->x) + double(node->dx) * (vt->y - node->y)) / node->len; } //========================================================================== // // AddToBBox // //========================================================================== static void AddToBBox(fixed_t child[4], fixed_t parent[4]) { if (child[BOXTOP] > parent[BOXTOP]) { parent[BOXTOP] = child[BOXTOP]; } if (child[BOXBOTTOM] < parent[BOXBOTTOM]) { parent[BOXBOTTOM] = child[BOXBOTTOM]; } if (child[BOXLEFT] < parent[BOXLEFT]) { parent[BOXLEFT] = child[BOXLEFT]; } if (child[BOXRIGHT] > parent[BOXRIGHT]) { parent[BOXRIGHT] = child[BOXRIGHT]; } } //========================================================================== // // AddToBBox // //========================================================================== static void AddToBBox(FPolyVertex *v, fixed_t bbox[4]) { if (v->x < bbox[BOXLEFT]) { bbox[BOXLEFT] = v->x; } if (v->x > bbox[BOXRIGHT]) { bbox[BOXRIGHT] = v->x; } if (v->y < bbox[BOXBOTTOM]) { bbox[BOXBOTTOM] = v->y; } if (v->y > bbox[BOXTOP]) { bbox[BOXTOP] = v->y; } } //========================================================================== // // SplitPoly // //========================================================================== static void SplitPoly(FPolyNode *pnode, void *node, fixed_t bbox[4]) { static TArray lists[2]; static const double POLY_EPSILON = 0.3125; if (!((size_t)node & 1)) // Keep going until found a subsector { node_t *bsp = (node_t *)node; int centerside = R_PointOnSide(pnode->poly->CenterSpot.x, pnode->poly->CenterSpot.y, bsp); lists[0].Clear(); lists[1].Clear(); for(unsigned i=0;isegs.Size(); i++) { FPolySeg *seg = &pnode->segs[i]; // Parts of the following code were taken from Eternity and are // being used with permission. // get distance of vertices from partition line // If the distance is too small, we may decide to // change our idea of sidedness. double dist_v1 = PartitionDistance(&seg->v1, bsp); double dist_v2 = PartitionDistance(&seg->v2, bsp); // If the distances are less than epsilon, consider the points as being // on the same side as the polyobj origin. Why? People like to build // polyobject doors flush with their door tracks. This breaks using the // usual assumptions. // Addition to Eternity code: We must also check any seg with only one // vertex inside the epsilon threshold. If not, these lines will get split but // adjoining ones with both vertices inside the threshold won't thus messing up // the order in which they get drawn. if(dist_v1 <= POLY_EPSILON) { if (dist_v2 <= POLY_EPSILON) { lists[centerside].Push(*seg); } else { int side = R_PointOnSide(seg->v2.x, seg->v2.y, bsp); lists[side].Push(*seg); } } else if (dist_v2 <= POLY_EPSILON) { int side = R_PointOnSide(seg->v1.x, seg->v1.y, bsp); lists[side].Push(*seg); } else { int side1 = R_PointOnSide(seg->v1.x, seg->v1.y, bsp); int side2 = R_PointOnSide(seg->v2.x, seg->v2.y, bsp); if(side1 != side2) { // if the partition line crosses this seg, we must split it. FPolyVertex vert; if (GetIntersection(seg, bsp, &vert)) { lists[0].Push(*seg); lists[1].Push(*seg); lists[side1].Last().v2 = vert; lists[side2].Last().v1 = vert; } else { // should never happen lists[side1].Push(*seg); } } else { // both points on the same side. lists[side1].Push(*seg); } } } if (lists[1].Size() == 0) { SplitPoly(pnode, bsp->children[0], bsp->bbox[0]); AddToBBox(bsp->bbox[0], bbox); } else if (lists[0].Size() == 0) { SplitPoly(pnode, bsp->children[1], bsp->bbox[1]); AddToBBox(bsp->bbox[1], bbox); } else { // create the new node FPolyNode *newnode = NewPolyNode(); newnode->poly = pnode->poly; newnode->segs = lists[1]; // set segs for original node pnode->segs = lists[0]; // recurse back side SplitPoly(newnode, bsp->children[1], bsp->bbox[1]); // recurse front side SplitPoly(pnode, bsp->children[0], bsp->bbox[0]); AddToBBox(bsp->bbox[0], bbox); AddToBBox(bsp->bbox[1], bbox); } } else { // we reached a subsector so we can link the node with this subsector subsector_t *sub = (subsector_t *)((BYTE *)node - 1); // Link node to subsector pnode->pnext = sub->polys; if (pnode->pnext != NULL) { assert(pnode->pnext->state == 1337); pnode->pnext->pprev = pnode; } pnode->pprev = NULL; sub->polys = pnode; // link node to polyobject pnode->snext = pnode->poly->subsectorlinks; pnode->poly->subsectorlinks = pnode; pnode->subsector = sub; // calculate bounding box for this polynode assert(pnode->segs.Size() != 0); fixed_t subbbox[4] = { FIXED_MIN, FIXED_MAX, FIXED_MAX, FIXED_MIN }; for (unsigned i = 0; i < pnode->segs.Size(); ++i) { AddToBBox(&pnode->segs[i].v1, subbbox); AddToBBox(&pnode->segs[i].v2, subbbox); } // Potentially expand the parent node's bounding box to contain these bits of polyobject. AddToBBox(subbbox, bbox); } } //========================================================================== // // // //========================================================================== void FPolyObj::CreateSubsectorLinks() { FPolyNode *node = NewPolyNode(); // Even though we don't care about it, we need to initialize this // bounding box to something so that Valgrind won't complain about it // when SplitPoly modifies it. fixed_t dummybbox[4] = { 0 }; node->poly = this; node->segs.Resize(Sidedefs.Size()); for(unsigned i=0; isegs[i]; side_t *side = Sidedefs[i]; seg->v1 = side->V1(); seg->v2 = side->V2(); seg->wall = side; } if (!(i_compatflags & COMPATF_POLYOBJ)) { SplitPoly(node, nodes + numnodes - 1, dummybbox); } else { subsector_t *sub = CenterSubsector; // Link node to subsector node->pnext = sub->polys; if (node->pnext != NULL) { assert(node->pnext->state == 1337); node->pnext->pprev = node; } node->pprev = NULL; sub->polys = node; // link node to polyobject node->snext = node->poly->subsectorlinks; node->poly->subsectorlinks = node; node->subsector = sub; } } //========================================================================== // // // //========================================================================== void PO_LinkToSubsectors() { for (int i = 0; i < po_NumPolyobjs; i++) { if (polyobjs[i].subsectorlinks == NULL) { polyobjs[i].CreateSubsectorLinks(); } } } //========================================================================== // // NewPolyNode // //========================================================================== static FPolyNode *NewPolyNode() { FPolyNode *node; if (FreePolyNodes != NULL) { node = FreePolyNodes; FreePolyNodes = node->pnext; } else { node = new FPolyNode; } node->state = 1337; node->poly = NULL; node->pnext = NULL; node->pprev = NULL; node->subsector = NULL; node->snext = NULL; return node; } //========================================================================== // // FreePolyNode // //========================================================================== void FreePolyNode(FPolyNode *node) { node->segs.Clear(); node->pnext = FreePolyNodes; FreePolyNodes = node; } //========================================================================== // // ReleaseAllPolyNodes // //========================================================================== void ReleaseAllPolyNodes() { FPolyNode *node, *next; for (node = FreePolyNodes; node != NULL; node = next) { next = node->pnext; delete node; } } //========================================================================== // // FPolyMirrorIterator Constructor // // This class is used to avoid infinitely looping on cyclical chains of // mirrored polyobjects. // //========================================================================== FPolyMirrorIterator::FPolyMirrorIterator(FPolyObj *poly) { CurPoly = poly; if (poly != NULL) { UsedPolys[0] = poly->tag; NumUsedPolys = 1; } else { NumUsedPolys = 0; } } //========================================================================== // // FPolyMirrorIterator :: NextMirror // // Returns the polyobject that mirrors the current one, or NULL if there // is no mirroring polyobject, or there is a mirroring polyobject but it was // already returned. // //========================================================================== FPolyObj *FPolyMirrorIterator::NextMirror() { FPolyObj *poly = CurPoly, *nextpoly; if (poly == NULL) { return NULL; } // Do the work to decide which polyobject to return the next time this // function is called. int mirror = poly->GetMirror(), i; nextpoly = NULL; // Is there a mirror and we have room to remember it? if (mirror != 0 && NumUsedPolys != countof(UsedPolys)) { // Has this polyobject been returned already? for (i = 0; i < NumUsedPolys; ++i) { if (UsedPolys[i] == mirror) { break; // Yes, it has been returned. } } if (i == NumUsedPolys) { // No, it has not been returned. UsedPolys[NumUsedPolys++] = mirror; nextpoly = PO_GetPolyobj(mirror); if (nextpoly == NULL) { Printf("Invalid mirror polyobj num %d for polyobj num %d\n", mirror, UsedPolys[i - 1]); } } } CurPoly = nextpoly; return poly; }