#ifndef __P_MAPUTL_H #define __P_MAPUTL_H #include #include "r_defs.h" #include "doomstat.h" #include "m_bbox.h" extern int validcount; struct FBlockNode; struct divline_t { double x; double y; double dx; double dy; }; struct intercept_t { double frac; bool isaline; bool done; union { AActor *thing; line_t *line; } d; }; //========================================================================== // // P_PointOnLineSide // // Returns 0 (front/on) or 1 (back) // [RH] inlined, stripped down, and made more precise // //========================================================================== inline int P_PointOnLineSidePrecise(double x, double y, const line_t *line) { return (y - line->v1->fY()) * line->Delta().X + (line->v1->fX() - x) * line->Delta().Y > EQUAL_EPSILON; } inline int P_PointOnLineSidePrecise(const DVector2 &pt, const line_t *line) { return (pt.Y - line->v1->fY()) * line->Delta().X + (line->v1->fX() - pt.X) * line->Delta().Y > EQUAL_EPSILON; } inline int P_PointOnLineSide (double x, double y, const line_t *line) { extern int P_VanillaPointOnLineSide(double x, double y, const line_t* line); return i_compatflags2 & COMPATF2_POINTONLINE ? P_VanillaPointOnLineSide(x, y, line) : P_PointOnLineSidePrecise(x, y, line); } inline int P_PointOnLineSide(const DVector2 & p, const line_t *line) { return P_PointOnLineSide(p.X, p.Y, line); } //========================================================================== // // P_PointOnDivlineSideCompat // // Same as P_PointOnLineSide except it uses divlines // [RH] inlined, stripped down, and made more precise // //========================================================================== inline int P_PointOnDivlineSide(double x, double y, const divline_t *line) { return (y - line->y) * line->dx + (line->x - x) * line->dy > EQUAL_EPSILON; } inline int P_PointOnDivlineSide(const DVector2 &pos, const divline_t *line) { return (pos.Y - line->y) * line->dx + (line->x - pos.X) * line->dy > EQUAL_EPSILON; } //========================================================================== // // P_MakeDivline // //========================================================================== inline void P_MakeDivline(const line_t *li, divline_t *dl) { dl->x = li->v1->fX(); dl->y = li->v1->fY(); dl->dx = li->Delta().X; dl->dy = li->Delta().Y; } struct FLineOpening { double top; double bottom; double range; double lowfloor; sector_t *bottomsec; sector_t *topsec; FTextureID ceilingpic; FTextureID floorpic; secplane_t frontfloorplane; secplane_t backfloorplane; int floorterrain; bool touchmidtex; bool abovemidtex; uint8_t lowfloorthroughportal; F3DFloor *topffloor; F3DFloor *bottomffloor; }; static const double LINEOPEN_MIN = -FLT_MAX; static const double LINEOPEN_MAX = FLT_MAX; void P_LineOpening(FLineOpening &open, AActor *thing, const line_t *linedef, const DVector2 &xy, const DVector2 *ref = NULL, int flags = 0); inline void P_LineOpening(FLineOpening &open, AActor *thing, const line_t *linedef, const DVector2 &xy, const DVector3 *ref, int flags = 0) { P_LineOpening(open, thing, linedef, xy, reinterpret_cast(ref), flags); } class FBoundingBox; struct polyblock_t; //============================================================================ // // This is a dynamic array which holds its first MAX_STATIC entries in normal // variables to avoid constant allocations which this would otherwise // require. // // When collecting touched portal groups the normal cases are either // no portals == one group or // two portals = two groups // // Anything with more can happen but far less infrequently, so this // organization helps avoiding the overhead from heap allocations // in the vast majority of situations. // //============================================================================ struct FPortalGroupArray { // Controls how groups are connected enum { PGA_NoSectorPortals,// only collect line portals PGA_CheckPosition, // only collects sector portals at the actual position PGA_Full3d, // Goes up and down sector portals at any linedef within the bounding box (this is a lot slower and should only be done if really needed.) }; enum { LOWER = 0x4000, UPPER = 0x8000, FLAT = 0xc000, }; enum { MAX_STATIC = 4 }; FPortalGroupArray(int collectionmethod = PGA_CheckPosition) { method = collectionmethod; varused = 0; inited = false; } void Clear() { data.Clear(); varused = 0; inited = false; } void Add(uint32_t num) { if (varused < MAX_STATIC) entry[varused++] = (uint16_t)num; else data.Push((uint16_t)num); } unsigned Size() { return varused + data.Size(); } uint32_t operator[](unsigned index) { return index < MAX_STATIC ? entry[index] : data[index - MAX_STATIC]; } bool inited; int method; private: uint16_t entry[MAX_STATIC]; uint8_t varused; TArray data; }; class FBlockLinesIterator { friend class FMultiBlockLinesIterator; int minx, maxx; int miny, maxy; int curx, cury; polyblock_t *polyLink; int polyIndex; int *list; void StartBlock(int x, int y); FBlockLinesIterator() {} void init(const FBoundingBox &box); public: FBlockLinesIterator(int minx, int miny, int maxx, int maxy, bool keepvalidcount = false); FBlockLinesIterator(const FBoundingBox &box); line_t *Next(); void Reset() { StartBlock(minx, miny); } }; class FMultiBlockLinesIterator { FPortalGroupArray &checklist; DVector3 checkpoint; DVector2 offset; sector_t *startsector; sector_t *cursector; short basegroup; short portalflags; short index; bool continueup; bool continuedown; FBlockLinesIterator blockIterator; FBoundingBox bbox; bool GoUp(double x, double y); bool GoDown(double x, double y); bool startIteratorForGroup(int group); public: struct CheckResult { line_t *line; DVector3 Position; int portalflags; }; FMultiBlockLinesIterator(FPortalGroupArray &check, AActor *origin, double checkradius = -1); FMultiBlockLinesIterator(FPortalGroupArray &check, double checkx, double checky, double checkz, double checkh, double checkradius, sector_t *newsec); bool Next(CheckResult *item); void Reset(); // for stopping group traversal through portals. Only the calling code can decide whether this is needed so this needs to be set from the outside. void StopUp() { continueup = false; } void StopDown() { continuedown = false; } const FBoundingBox &Box() const { return bbox; } }; class FBlockThingsIterator { int minx, maxx; int miny, maxy; int curx, cury; FBlockNode *block; int Buckets[32]; struct HashEntry { AActor *Actor; int Next; }; HashEntry FixedHash[10]; int NumFixedHash; TArray DynHash; HashEntry *GetHashEntry(int i) { return i < (int)countof(FixedHash) ? &FixedHash[i] : &DynHash[i - countof(FixedHash)]; } void StartBlock(int x, int y); void SwitchBlock(int x, int y); void ClearHash(); // The following is only for use in the path traverser // and therefore declared private. FBlockThingsIterator(); friend class FPathTraverse; friend class FMultiBlockThingsIterator; public: FBlockThingsIterator(int minx, int miny, int maxx, int maxy); FBlockThingsIterator(const FBoundingBox &box) { init(box); } void init(const FBoundingBox &box); AActor *Next(bool centeronly = false); void Reset() { StartBlock(minx, miny); } }; class FMultiBlockThingsIterator { FPortalGroupArray &checklist; DVector3 checkpoint; short basegroup; short portalflags; short index; FBlockThingsIterator blockIterator; FBoundingBox bbox; void startIteratorForGroup(int group); protected: FMultiBlockThingsIterator(FPortalGroupArray &check) : checklist(check) {} public: struct CheckResult { AActor *thing; DVector3 Position; int portalflags; }; FMultiBlockThingsIterator(FPortalGroupArray &check, AActor *origin, double checkradius = -1, bool ignorerestricted = false); FMultiBlockThingsIterator(FPortalGroupArray &check, double checkx, double checky, double checkz, double checkh, double checkradius, bool ignorerestricted, sector_t *newsec); bool Next(CheckResult *item); void Reset(); const FBoundingBox &Box() const { return bbox; } }; class FPathTraverse { protected: static TArray intercepts; divline_t trace; double Startfrac; unsigned int intercept_index; unsigned int intercept_count; unsigned int count; virtual void AddLineIntercepts(int bx, int by); virtual void AddThingIntercepts(int bx, int by, FBlockThingsIterator &it, bool compatible); FPathTraverse() {} public: intercept_t *Next(); FPathTraverse(double x1, double y1, double x2, double y2, int flags, double startfrac = 0) { init(x1, y1, x2, y2, flags, startfrac); } void init(double x1, double y1, double x2, double y2, int flags, double startfrac = 0); int PortalRelocate(intercept_t *in, int flags, DVector3 *optpos = NULL); void PortalRelocate(const DVector2 &disp, int flags, double hitfrac); virtual ~FPathTraverse(); const divline_t &Trace() const { return trace; } inline DVector2 InterceptPoint(const intercept_t *in) { return { trace.x + trace.dx * in->frac, trace.y + trace.dy * in->frac }; } }; //============================================================================ // // A traverser that uses the portal blockmap // This should be in portal.h but that'd create circular dependencies. // //============================================================================ class FLinePortalTraverse : public FPathTraverse { void AddLineIntercepts(int bx, int by); public: FLinePortalTraverse() { } }; // // P_MAPUTL // typedef bool(*traverser_t) (intercept_t *in); int P_AproxDistance (int dx, int dy); double P_InterceptVector(const divline_t *v2, const divline_t *v1); #define PT_ADDLINES 1 #define PT_ADDTHINGS 2 #define PT_COMPATIBLE 4 #define PT_DELTA 8 // x2,y2 is passed as a delta, not as an endpoint #endif