qzdoom-gpl/src/p_maputl.h

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#ifndef __P_MAPUTL_H
#define __P_MAPUTL_H
#include "r_defs.h"
#include "doomstat.h"
#include "m_bbox.h"
extern int validcount;
struct fdivline_t
{
fixed_t x;
fixed_t y;
fixed_t dx;
fixed_t dy;
};
struct divline_t
{
double x;
double y;
double dx;
double dy;
};
struct intercept_t
{
fixed_t frac; // along trace line
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_PointOnLineSide (fixed_t x, fixed_t y, const line_t *line)
{
extern int P_VanillaPointOnLineSide(fixed_t x, fixed_t y, const line_t* line);
return i_compatflags2 & COMPATF2_POINTONLINE
? P_VanillaPointOnLineSide(x, y, line)
: DMulScale32 (y-line->v1->y, line->dx, line->v1->x-x, line->dy) > 0;
}
inline int P_PointOnLineSidePrecise (fixed_t x, fixed_t y, const line_t *line)
{
return DMulScale32 (y-line->v1->y, line->dx, line->v1->x-x, line->dy) > 0;
}
inline int P_PointOnLineSidePrecise(double x, double y, const line_t *line)
{
return DMulScale32(FLOAT2FIXED(y) - line->v1->y, line->dx, line->v1->x - FLOAT2FIXED(x), line->dy) > 0;
}
inline int P_PointOnLineSidePrecise(const DVector2 &pt, const line_t *line)
{
return DMulScale32(FLOAT2FIXED(pt.Y) - line->v1->y, line->dx, line->v1->x - FLOAT2FIXED(pt.X), line->dy) > 0;
}
inline int P_PointOnLineSidePrecise(const DVector3 &pt, const line_t *line)
{
return DMulScale32(FLOAT2FIXED(pt.Y) - line->v1->y, line->dx, line->v1->x - FLOAT2FIXED(pt.X), line->dy) > 0;
}
//==========================================================================
//
// P_PointOnDivlineSide
//
// Same as P_PointOnLineSide except it uses divlines
// [RH] inlined, stripped down, and made more precise
//
//==========================================================================
inline int P_PointOnDivlineSide (fixed_t x, fixed_t y, const fdivline_t *line)
{
extern int P_VanillaPointOnDivlineSide(fixed_t x, fixed_t y, const fdivline_t* line);
return (i_compatflags2 & COMPATF2_POINTONLINE)
? P_VanillaPointOnDivlineSide(x, y, line)
: (DMulScale32 (y-line->y, line->dx, line->x-x, line->dy) > 0);
}
inline int P_PointOnDivlineSidePrecise (fixed_t x, fixed_t y, const fdivline_t *line)
{
return DMulScale32 (y-line->y, line->dx, line->x-x, line->dy) > 0;
}
inline int P_PointOnDivlineSidePrecise(double x, double y, const divline_t *line)
{
return (y - line->y) * line->dx + (line->x - x) * line->dy > 0;
}
//==========================================================================
//
// P_MakeDivline
//
//==========================================================================
inline void P_MakeDivline (const line_t *li, fdivline_t *dl)
{
dl->x = li->v1->x;
dl->y = li->v1->y;
dl->dx = li->dx;
dl->dy = li->dy;
}
struct FLineOpening
{
fixed_t top;
fixed_t bottom;
fixed_t range;
fixed_t lowfloor;
sector_t *bottomsec;
sector_t *topsec;
FTextureID ceilingpic;
FTextureID floorpic;
secplane_t frontfloorplane;
secplane_t backfloorplane;
int floorterrain;
bool touchmidtex;
bool abovemidtex;
};
void P_LineOpening (FLineOpening &open, AActor *thing, const line_t *linedef, fixed_t x, fixed_t y, fixed_t refx=FIXED_MIN, fixed_t refy=0, int flags=0);
inline void P_LineOpening(FLineOpening &open, AActor *thing, const line_t *linedef, fixedvec2 xy, fixed_t refx = FIXED_MIN, fixed_t refy = 0, int flags = 0)
{
P_LineOpening(open, thing, linedef, xy.x, xy.y, refx, refy, 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(DWORD num)
{
if (varused < MAX_STATIC) entry[varused++] = (WORD)num;
else data.Push((WORD)num);
}
unsigned Size()
{
return varused + data.Size();
}
DWORD operator[](unsigned index)
{
return index < MAX_STATIC ? entry[index] : data[index - MAX_STATIC];
}
bool inited;
int method;
private:
WORD entry[MAX_STATIC];
BYTE varused;
TArray<WORD> 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;
fixedvec3 checkpoint;
fixedvec2 offset;
sector_t *startsector;
sector_t *cursector;
short basegroup;
short portalflags;
short index;
bool continueup;
bool continuedown;
FBlockLinesIterator blockIterator;
FBoundingBox bbox;
bool GoUp(fixed_t x, fixed_t y);
bool GoDown(fixed_t x, fixed_t y);
void startIteratorForGroup(int group);
public:
struct CheckResult
{
line_t *line;
fixedvec3 position;
int portalflags;
};
FMultiBlockLinesIterator(FPortalGroupArray &check, AActor *origin, fixed_t checkradius = -1);
FMultiBlockLinesIterator(FPortalGroupArray &check, fixed_t checkx, fixed_t checky, fixed_t checkz, fixed_t checkh, fixed_t 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<HashEntry> 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;
fixedvec3 checkpoint;
short basegroup;
short portalflags;
short index;
FBlockThingsIterator blockIterator;
FBoundingBox bbox;
void startIteratorForGroup(int group);
public:
struct CheckResult
{
AActor *thing;
fixedvec3 position; // keep these both until the fixed version can be removed.
DVector3 Position;
int portalflags;
};
FMultiBlockThingsIterator(FPortalGroupArray &check, AActor *origin, fixed_t checkradius = -1, bool ignorerestricted = false);
FMultiBlockThingsIterator(FPortalGroupArray &check, fixed_t checkx, fixed_t checky, fixed_t checkz, fixed_t checkh, fixed_t checkradius, bool ignorerestricted, sector_t *newsec);
FMultiBlockThingsIterator(FPortalGroupArray &check, double checkx, double checky, double checkz, double checkh, double checkradius, bool ignorerestricted, sector_t *newsec)
: FMultiBlockThingsIterator(check, FLOAT2FIXED(checkx), FLOAT2FIXED(checky), FLOAT2FIXED(checkz), FLOAT2FIXED(checkh), FLOAT2FIXED(checkradius), ignorerestricted, newsec)
{
}
bool Next(CheckResult *item);
void Reset();
const FBoundingBox &Box() const
{
return bbox;
}
};
class FPathTraverse
{
protected:
static TArray<intercept_t> intercepts;
fdivline_t trace;
fixed_t 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(fixed_t x1, fixed_t y1, fixed_t x2, fixed_t y2, int flags, fixed_t startfrac = 0)
{
init(x1, y1, x2, y2, flags, startfrac);
}
void init(fixed_t x1, fixed_t y1, fixed_t x2, fixed_t y2, int flags, fixed_t startfrac = 0);
int PortalRelocate(intercept_t *in, int flags, fixedvec3 *optpos = NULL);
virtual ~FPathTraverse();
const fdivline_t &Trace() const { return trace; }
inline fixedvec2 InterceptPoint(const intercept_t *in)
{
return
{
trace.x + FixedMul(trace.dx, in->frac),
trace.y + FixedMul(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);
fixed_t P_AproxDistance (fixed_t dx, fixed_t dy);
fixed_t P_InterceptVector (const fdivline_t *v2, const fdivline_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