// Emacs style mode select -*- C++ -*- //----------------------------------------------------------------------------- // // $Id:$ // // Copyright (C) 1993-1996 by id Software, Inc. // // This source is available for distribution and/or modification // only under the terms of the DOOM Source Code License as // published by id Software. All rights reserved. // // The source is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // FITNESS FOR A PARTICULAR PURPOSE. See the DOOM Source Code License // for more details. // // DESCRIPTION: // Refresh/rendering module, shared data struct definitions. // //----------------------------------------------------------------------------- #ifndef __R_DEFS_H__ #define __R_DEFS_H__ #include "doomdef.h" #include "templates.h" // Some more or less basic data types // we depend on. #include "m_fixed.h" // We rely on the thinker data struct // to handle sound origins in sectors. // SECTORS do store MObjs anyway. #include "actor.h" #include "dthinker.h" #include "farchive.h" #define MAXWIDTH 2560 #define MAXHEIGHT 1600 const WORD NO_INDEX = 0xffffu; const DWORD NO_SIDE = 0xffffffffu; // Silhouette, needed for clipping Segs (mainly) // and sprites representing things. enum { SIL_NONE, SIL_BOTTOM, SIL_TOP, SIL_BOTH }; extern size_t MaxDrawSegs; // // INTERNAL MAP TYPES // used by play and refresh // // // Your plain vanilla vertex. // Note: transformed values not buffered locally, // like some DOOM-alikes ("wt", "WebView") did. // struct vertex_t { fixed_t x, y; bool operator== (const vertex_t &other) { return x == other.x && y == other.y; } }; // Forward of LineDefs, for Sectors. struct line_t; class player_t; class FScanner; class FBitmap; struct FCopyInfo; class DInterpolation; enum { UDMF_Line, UDMF_Side, UDMF_Sector, UDMF_Thing }; struct FUDMFKey { enum { UDMF_Int, UDMF_Float, UDMF_String }; FName Key; int Type; int IntVal; double FloatVal; FString StringVal; FUDMFKey() { } FUDMFKey& operator =(int val) { Type = UDMF_Int; IntVal = val; FloatVal = val; StringVal = ""; return *this; } FUDMFKey& operator =(double val) { Type = UDMF_Float; IntVal = int(val); FloatVal = val; StringVal = ""; return *this; } FUDMFKey& operator =(const FString &val) { Type = UDMF_String; IntVal = strtol(val, NULL, 0); FloatVal = strtod(val, NULL); StringVal = val; return *this; } }; class FUDMFKeys : public TArray { public: void Sort(); FUDMFKey *Find(FName key); }; // // The SECTORS record, at runtime. // Stores things/mobjs. // class DSectorEffect; struct sector_t; struct line_t; struct FRemapTable; enum { SECSPAC_Enter = 1, // Trigger when player enters SECSPAC_Exit = 2, // Trigger when player exits SECSPAC_HitFloor = 4, // Trigger when player hits floor SECSPAC_HitCeiling = 8, // Trigger when player hits ceiling SECSPAC_Use = 16, // Trigger when player uses SECSPAC_UseWall = 32, // Trigger when player uses a wall SECSPAC_EyesDive = 64, // Trigger when player eyes go below fake floor SECSPAC_EyesSurface = 128, // Trigger when player eyes go above fake floor SECSPAC_EyesBelowC = 256, // Trigger when player eyes go below fake ceiling SECSPAC_EyesAboveC = 512, // Trigger when player eyes go above fake ceiling SECSPAC_HitFakeFloor= 1024, // Trigger when player hits fake floor }; class ASectorAction : public AActor { DECLARE_CLASS (ASectorAction, AActor) public: void Destroy (); void BeginPlay (); void Activate (AActor *source); void Deactivate (AActor *source); virtual bool TriggerAction (AActor *triggerer, int activationType); protected: bool CheckTrigger (AActor *triggerer) const; }; class ASkyViewpoint; struct secplane_t { // the plane is defined as a*x + b*y + c*z + d = 0 // ic is 1/c, for faster Z calculations fixed_t a, b, c, d, ic; // Returns the value of z at (x,y) fixed_t ZatPoint (fixed_t x, fixed_t y) const { return FixedMul (ic, -d - DMulScale16 (a, x, b, y)); } // Returns the value of z at (x,y) as a double double ZatPoint (double x, double y) const { return (d + a*x + b*y) * ic / (-65536.0 * 65536.0); } // Returns the value of z at vertex v fixed_t ZatPoint (const vertex_t *v) const { return FixedMul (ic, -d - DMulScale16 (a, v->x, b, v->y)); } // Returns the value of z at (x,y) if d is equal to dist fixed_t ZatPointDist (fixed_t x, fixed_t y, fixed_t dist) const { return FixedMul (ic, -dist - DMulScale16 (a, x, b, y)); } // Returns the value of z at vertex v if d is equal to dist fixed_t ZatPointDist (const vertex_t *v, fixed_t dist) { return FixedMul (ic, -dist - DMulScale16 (a, v->x, b, v->y)); } // Flips the plane's vertical orientiation, so that if it pointed up, // it will point down, and vice versa. void FlipVert () { a = -a; b = -b; c = -c; d = -d; ic = -ic; } // Returns true if 2 planes are the same bool operator== (const secplane_t &other) const { return a == other.a && b == other.b && c == other.c && d == other.d; } // Returns true if 2 planes are different bool operator!= (const secplane_t &other) const { return a != other.a || b != other.b || c != other.c || d != other.d; } // Moves a plane up/down by hdiff units void ChangeHeight (fixed_t hdiff) { d = d - FixedMul (hdiff, c); } // Moves a plane up/down by hdiff units fixed_t GetChangedHeight (fixed_t hdiff) { return d - FixedMul (hdiff, c); } // Returns how much this plane's height would change if d were set to oldd fixed_t HeightDiff (fixed_t oldd) const { return FixedMul (oldd - d, ic); } // Returns how much this plane's height would change if d were set to oldd fixed_t HeightDiff (fixed_t oldd, fixed_t newd) const { return FixedMul (oldd - newd, ic); } fixed_t PointToDist (fixed_t x, fixed_t y, fixed_t z) const { return -TMulScale16 (a, x, y, b, z, c); } fixed_t PointToDist (const vertex_t *v, fixed_t z) const { return -TMulScale16 (a, v->x, b, v->y, z, c); } }; inline FArchive &operator<< (FArchive &arc, secplane_t &plane) { arc << plane.a << plane.b << plane.c << plane.d; //if (plane.c != 0) { // plane.c should always be non-0. Otherwise, the plane // would be perfectly vertical. plane.ic = DivScale32 (1, plane.c); } return arc; } #include "p_3dfloors.h" // Ceiling/floor flags enum { PLANEF_ABSLIGHTING = 1, // floor/ceiling light is absolute, not relative PLANEF_BLOCKED = 2 // can not be moved anymore. }; // Internal sector flags enum { SECF_FAKEFLOORONLY = 2, // when used as heightsec in R_FakeFlat, only copies floor SECF_CLIPFAKEPLANES = 4, // as a heightsec, clip planes to target sector's planes SECF_NOFAKELIGHT = 8, // heightsec does not change lighting SECF_IGNOREHEIGHTSEC= 16, // heightsec is only for triggering sector actions SECF_UNDERWATER = 32, // sector is underwater SECF_FORCEDUNDERWATER= 64, // sector is forced to be underwater SECF_UNDERWATERMASK = 32+64, SECF_DRAWN = 128, // sector has been drawn at least once }; enum { SECF_SILENT = 1, // actors in sector make no noise SECF_NOFALLINGDAMAGE= 2, // No falling damage in this sector SECF_FLOORDROP = 4, // all actors standing on this floor will remain on it when it lowers very fast. SECF_NORESPAWN = 8, // players can not respawn in this sector }; enum { PL_SKYFLAT = 0x40000000 }; struct FDynamicColormap; struct FLightStack { secplane_t Plane; // Plane above this light (points up) sector_t *Master; // Sector to get light from (NULL for owner) BITFIELD bBottom:1; // Light is from the bottom of a block? BITFIELD bFlooder:1; // Light floods lower lights until another flooder is reached? BITFIELD bOverlaps:1; // Plane overlaps the next one }; struct FExtraLight { short Tag; WORD NumLights; WORD NumUsedLights; FLightStack *Lights; // Lights arranged from top to bottom void InsertLight (const secplane_t &plane, line_t *line, int type); }; struct FLinkedSector { sector_t *Sector; int Type; }; // this substructure contains a few sector properties that are stored in dynamic arrays // These must not be copied by R_FakeFlat etc. or bad things will happen. struct extsector_t { // Boom sector transfer information struct fakefloor { TArray Sectors; } FakeFloor; // 3DMIDTEX information struct midtex { struct plane { TArray AttachedSectors; // all sectors containing 3dMidtex lines attached to this sector TArray AttachedLines; // all 3dMidtex lines attached to this sector } Floor, Ceiling; } Midtex; // Linked sector information struct linked { struct plane { TArray Sectors; } Floor, Ceiling; } Linked; // 3D floors struct xfloor { TDeletingArray ffloors; // 3D floors in this sector TArray lightlist; // 3D light list TArray attached; // 3D floors attached to this sector } XFloor; void Serialize(FArchive &arc); }; struct FTransform { // killough 3/7/98: floor and ceiling texture offsets fixed_t xoffs, yoffs; // [RH] floor and ceiling texture scales fixed_t xscale, yscale; // [RH] floor and ceiling texture rotation angle_t angle; // base values fixed_t base_angle, base_yoffs; }; struct sector_t { // Member functions bool IsLinked(sector_t *other, bool ceiling) const; fixed_t FindLowestFloorSurrounding (vertex_t **v) const; fixed_t FindHighestFloorSurrounding (vertex_t **v) const; fixed_t FindNextHighestFloor (vertex_t **v) const; fixed_t FindNextLowestFloor (vertex_t **v) const; fixed_t FindLowestCeilingSurrounding (vertex_t **v) const; // jff 2/04/98 fixed_t FindHighestCeilingSurrounding (vertex_t **v) const; // jff 2/04/98 fixed_t FindNextLowestCeiling (vertex_t **v) const; // jff 2/04/98 fixed_t FindNextHighestCeiling (vertex_t **v) const; // jff 2/04/98 fixed_t FindShortestTextureAround () const; // jff 2/04/98 fixed_t FindShortestUpperAround () const; // jff 2/04/98 sector_t *FindModelFloorSector (fixed_t floordestheight) const; // jff 2/04/98 sector_t *FindModelCeilingSector (fixed_t floordestheight) const; // jff 2/04/98 int FindMinSurroundingLight (int max) const; sector_t *NextSpecialSector (int type, sector_t *prev) const; // [RH] fixed_t FindLowestCeilingPoint (vertex_t **v) const; fixed_t FindHighestFloorPoint (vertex_t **v) const; void AdjustFloorClip () const; void SetColor(int r, int g, int b, int desat); void SetFade(int r, int g, int b); void ClosestPoint(fixed_t x, fixed_t y, fixed_t &ox, fixed_t &oy) const; DInterpolation *SetInterpolation(int position, bool attach); void StopInterpolation(int position); enum { floor, ceiling }; struct splane { FTransform xform; int Flags; int Light; FTextureID Texture; fixed_t TexZ; }; splane planes[2]; void SetXOffset(int pos, fixed_t o) { planes[pos].xform.xoffs = o; } void AddXOffset(int pos, fixed_t o) { planes[pos].xform.xoffs += o; } fixed_t GetXOffset(int pos) const { return planes[pos].xform.xoffs; } void SetYOffset(int pos, fixed_t o) { planes[pos].xform.yoffs = o; } void AddYOffset(int pos, fixed_t o) { planes[pos].xform.yoffs += o; } fixed_t GetYOffset(int pos, bool addbase = true) const { if (!addbase) { return planes[pos].xform.yoffs; } else { return planes[pos].xform.yoffs + planes[pos].xform.base_yoffs; } } void SetXScale(int pos, fixed_t o) { planes[pos].xform.xscale = o; } fixed_t GetXScale(int pos) const { return planes[pos].xform.xscale; } void SetYScale(int pos, fixed_t o) { planes[pos].xform.yscale = o; } fixed_t GetYScale(int pos) const { return planes[pos].xform.yscale; } void SetAngle(int pos, angle_t o) { planes[pos].xform.angle = o; } angle_t GetAngle(int pos, bool addbase = true) const { if (!addbase) { return planes[pos].xform.angle; } else { return planes[pos].xform.angle + planes[pos].xform.base_angle; } } void SetBase(int pos, fixed_t y, angle_t o) { planes[pos].xform.base_yoffs = y; planes[pos].xform.base_angle = o; } int GetFlags(int pos) const { return planes[pos].Flags; } void ChangeFlags(int pos, int And, int Or) { planes[pos].Flags &= ~And; planes[pos].Flags |= Or; } int GetPlaneLight(int pos) const { return planes[pos].Light; } void SetPlaneLight(int pos, int level) { planes[pos].Light = level; } FTextureID GetTexture(int pos) const { return planes[pos].Texture; } void SetTexture(int pos, FTextureID tex, bool floorclip = true) { FTextureID old = planes[pos].Texture; planes[pos].Texture = tex; if (floorclip && pos == floor && tex != old) AdjustFloorClip(); } fixed_t GetPlaneTexZ(int pos) const { return planes[pos].TexZ; } void SetPlaneTexZ(int pos, fixed_t val) { planes[pos].TexZ = val; } void ChangePlaneTexZ(int pos, fixed_t val) { planes[pos].TexZ += val; } sector_t *GetHeightSec() const { return (MoreFlags & SECF_IGNOREHEIGHTSEC)? NULL : heightsec; } void ChangeLightLevel(int newval) { lightlevel = (BYTE)clamp(lightlevel + newval, 0, 255); } void SetLightLevel(int newval) { lightlevel = (BYTE)clamp(newval, 0, 255); } int GetLightLevel() const { return lightlevel; } bool PlaneMoving(int pos); // Member variables fixed_t CenterFloor () const { return floorplane.ZatPoint (soundorg[0], soundorg[1]); } fixed_t CenterCeiling () const { return ceilingplane.ZatPoint (soundorg[0], soundorg[1]); } // [RH] store floor and ceiling planes instead of heights secplane_t floorplane, ceilingplane; // [RH] give floor and ceiling even more properties FDynamicColormap *ColorMap; // [RH] Per-sector colormap BYTE lightlevel; TObjPtr SoundTarget; BYTE soundtraversed; // 0 = untraversed, 1,2 = sndlines -1 short special; short tag; int nexttag,firsttag; // killough 1/30/98: improves searches for tags. int sky; short seqType; // this sector's sound sequence fixed_t soundorg[2]; // origin for any sounds played by the sector int validcount; // if == validcount, already checked AActor* thinglist; // list of mobjs in sector // killough 8/28/98: friction is a sector property, not an mobj property. // these fields used to be in AActor, but presented performance problems // when processed as mobj properties. Fix is to make them sector properties. fixed_t friction, movefactor; // thinker_t for reversable actions TObjPtr floordata; // jff 2/22/98 make thinkers on TObjPtr ceilingdata; // floors, ceilings, lighting, TObjPtr lightingdata; // independent of one another enum { CeilingMove, FloorMove, CeilingScroll, FloorScroll }; TObjPtr interpolations[4]; // jff 2/26/98 lockout machinery for stairbuilding SBYTE stairlock; // -2 on first locked -1 after thinker done 0 normally SWORD prevsec; // -1 or number of sector for previous step SWORD nextsec; // -1 or number of next step sector short linecount; struct line_t **lines; // [linecount] size // killough 3/7/98: support flat heights drawn at another sector's heights sector_t *heightsec; // other sector, or NULL if no other sector DWORD bottommap, midmap, topmap; // killough 4/4/98: dynamic colormaps // [RH] these can also be blend values if // the alpha mask is non-zero // list of mobjs that are at least partially in the sector // thinglist is a subset of touching_thinglist struct msecnode_t *touching_thinglist; // phares 3/14/98 float gravity; // [RH] Sector gravity (1.0 is normal) short damage; // [RH] Damage to do while standing on floor short mod; // [RH] Means-of-death for applied damage WORD ZoneNumber; // [RH] Zone this sector belongs to WORD MoreFlags; // [RH] Internal sector flags DWORD Flags; // Sector flags // [RH] Action specials for sectors. Like Skull Tag, but more // flexible in a Bloody way. SecActTarget forms a list of actors // joined by their tracer fields. When a potential sector action // occurs, SecActTarget's TriggerAction method is called. TObjPtr SecActTarget; // [RH] The sky box to render for this sector. NULL means use a // regular sky. TObjPtr FloorSkyBox, CeilingSkyBox; // Planes that partition this sector into different light zones. FExtraLight *ExtraLights; vertex_t *Triangle[3]; // Three points that can define a plane short secretsector; //jff 2/16/98 remembers if sector WAS secret (automap) int sectornum; // for comparing sector copies extsector_t * e; // This stores data that requires construction/destruction. Such data must not be copied by R_FakeFlat. }; FArchive &operator<< (FArchive &arc, sector_t::splane &p); struct ReverbContainer; struct zone_t { ReverbContainer *Environment; }; // // The SideDef. // class DBaseDecal; enum { WALLF_ABSLIGHTING = 1, // Light is absolute instead of relative WALLF_NOAUTODECALS = 2, // Do not attach impact decals to this wall WALLF_NOFAKECONTRAST = 4, // Don't do fake contrast for this wall in side_t::GetLightLevel WALLF_SMOOTHLIGHTING = 8, // Similar to autocontrast but applies to all angles. WALLF_CLIP_MIDTEX = 16, // Like the line counterpart, but only for this side. WALLF_WRAP_MIDTEX = 32, // Like the line counterpart, but only for this side. }; struct side_t { enum ETexpart { top=0, mid=1, bottom=2 }; struct part { fixed_t xoffset; fixed_t yoffset; fixed_t xscale; fixed_t yscale; FTextureID texture; TObjPtr interpolation; //int Light; }; sector_t* sector; // Sector the SideDef is facing. DBaseDecal* AttachedDecals; // [RH] Decals bound to the wall part textures[3]; line_t *linedef; //DWORD linenum; DWORD LeftSide, RightSide; // [RH] Group walls into loops WORD TexelLength; SWORD Light; BYTE Flags; int Index; // needed to access custom UDMF fields which are stored in loading order. int GetLightLevel (bool foggy, int baselight) const; void SetLight(SWORD l) { Light = l; } FTextureID GetTexture(int which) const { return textures[which].texture; } void SetTexture(int which, FTextureID tex) { textures[which].texture = tex; } void SetTextureXOffset(int which, fixed_t offset) { textures[which].xoffset = offset; } void SetTextureXOffset(fixed_t offset) { textures[top].xoffset = textures[mid].xoffset = textures[bottom].xoffset = offset; } fixed_t GetTextureXOffset(int which) const { return textures[which].xoffset; } void AddTextureXOffset(int which, fixed_t delta) { textures[which].xoffset += delta; } void SetTextureYOffset(int which, fixed_t offset) { textures[which].yoffset = offset; } void SetTextureYOffset(fixed_t offset) { textures[top].yoffset = textures[mid].yoffset = textures[bottom].yoffset = offset; } fixed_t GetTextureYOffset(int which) const { return textures[which].yoffset; } void AddTextureYOffset(int which, fixed_t delta) { textures[which].yoffset += delta; } void SetTextureXScale(int which, fixed_t scale) { textures[which].xscale = scale <= 0? FRACUNIT : scale; } void SetTextureXScale(fixed_t scale) { textures[top].xscale = textures[mid].xscale = textures[bottom].xscale = scale <= 0? FRACUNIT : scale; } fixed_t GetTextureXScale(int which) const { return textures[which].xscale; } void MultiplyTextureXScale(int which, fixed_t delta) { textures[which].xscale = FixedMul(textures[which].xscale, delta); } void SetTextureYScale(int which, fixed_t scale) { textures[which].yscale = scale <= 0? FRACUNIT : scale; } void SetTextureYScale(fixed_t scale) { textures[top].yscale = textures[mid].yscale = textures[bottom].yscale = scale <= 0? FRACUNIT : scale; } fixed_t GetTextureYScale(int which) const { return textures[which].yscale; } void MultiplyTextureYScale(int which, fixed_t delta) { textures[which].yscale = FixedMul(textures[which].yscale, delta); } DInterpolation *SetInterpolation(int position); void StopInterpolation(int position); }; FArchive &operator<< (FArchive &arc, side_t::part &p); // // Move clipping aid for LineDefs. // enum slopetype_t { ST_HORIZONTAL, ST_VERTICAL, ST_POSITIVE, ST_NEGATIVE }; struct line_t { vertex_t *v1, *v2; // vertices, from v1 to v2 fixed_t dx, dy; // precalculated v2 - v1 for side checking DWORD flags; DWORD activation; // activation type int special; fixed_t Alpha; // <--- translucency (0-255/255=opaque) int id; // <--- same as tag or set with Line_SetIdentification int args[5]; // <--- hexen-style arguments (expanded to ZDoom's full width) int firstid, nextid; side_t *sidedef[2]; //DWORD sidenum[2]; // sidenum[1] will be NO_SIDE if one sided fixed_t bbox[4]; // bounding box, for the extent of the LineDef. slopetype_t slopetype; // To aid move clipping. sector_t *frontsector, *backsector; int validcount; // if == validcount, already checked }; // phares 3/14/98 // // Sector list node showing all sectors an object appears in. // // There are two threads that flow through these nodes. The first thread // starts at touching_thinglist in a sector_t and flows through the m_snext // links to find all mobjs that are entirely or partially in the sector. // The second thread starts at touching_sectorlist in a AActor and flows // through the m_tnext links to find all sectors a thing touches. This is // useful when applying friction or push effects to sectors. These effects // can be done as thinkers that act upon all objects touching their sectors. // As an mobj moves through the world, these nodes are created and // destroyed, with the links changed appropriately. // // For the links, NULL means top or end of list. struct msecnode_t { sector_t *m_sector; // a sector containing this object AActor *m_thing; // this object struct msecnode_t *m_tprev; // prev msecnode_t for this thing struct msecnode_t *m_tnext; // next msecnode_t for this thing struct msecnode_t *m_sprev; // prev msecnode_t for this sector struct msecnode_t *m_snext; // next msecnode_t for this sector bool visited; // killough 4/4/98, 4/7/98: used in search algorithms }; // // A SubSector. // References a Sector. // Basically, this is a list of LineSegs indicating the visible walls that // define (all or some) sides of a convex BSP leaf. // struct FPolyObj; struct subsector_t { sector_t *sector; DWORD numlines; DWORD firstline; FPolyObj *poly; int validcount; fixed_t CenterX, CenterY; }; // // The LineSeg. // struct seg_t { vertex_t* v1; vertex_t* v2; side_t* sidedef; line_t* linedef; // Sector references. Could be retrieved from linedef, too. sector_t* frontsector; sector_t* backsector; // NULL for one-sided lines subsector_t* Subsector; seg_t* PartnerSeg; BITFIELD bPolySeg:1; }; // ===== Polyobj data ===== struct FPolyObj { int numsegs; seg_t **segs; int numlines; line_t **lines; int numvertices; vertex_t **vertices; fixed_t startSpot[2]; vertex_t *originalPts; // used as the base for the rotations vertex_t *prevPts; // use to restore the old point values angle_t angle; int tag; // reference tag assigned in HereticEd int bbox[4]; int validcount; int crush; // should the polyobj attempt to crush mobjs? bool bHurtOnTouch; // should the polyobj hurt anything it touches? int seqType; fixed_t size; // polyobj size (area of POLY_AREAUNIT == size of FRACUNIT) DThinker *specialdata; // pointer to a thinker, if the poly is moving TObjPtr interpolation; ~FPolyObj(); DInterpolation *SetInterpolation(); void StopInterpolation(); }; extern FPolyObj *polyobjs; // list of all poly-objects on the level inline FArchive &operator<< (FArchive &arc, FPolyObj *&poly) { return arc.SerializePointer (polyobjs, (BYTE **)&poly, sizeof(FPolyObj)); } inline FArchive &operator<< (FArchive &arc, const FPolyObj *&poly) { return arc.SerializePointer (polyobjs, (BYTE **)&poly, sizeof(FPolyObj)); } // // BSP node. // struct node_t { // Partition line. fixed_t x; fixed_t y; fixed_t dx; fixed_t dy; fixed_t bbox[2][4]; // Bounding box for each child. union { void *children[2]; // If bit 0 is set, it's a subsector. int intchildren[2]; // Used by nodebuilder. }; }; struct polyblock_t { FPolyObj *polyobj; struct polyblock_t *prev; struct polyblock_t *next; }; // posts are runs of non masked source pixels struct column_t { BYTE topdelta; // -1 is the last post in a column BYTE length; // length data bytes follows }; // // OTHER TYPES // typedef BYTE lighttable_t; // This could be wider for >8 bit display. // A vissprite_t is a thing // that will be drawn during a refresh. // I.e. a sprite object that is partly visible. struct vissprite_t { short x1, x2; fixed_t cx; // for line side calculation fixed_t gx, gy; // for fake floor clipping fixed_t gz, gzt; // global bottom / top for silhouette clipping fixed_t startfrac; // horizontal position of x1 fixed_t xscale, yscale; fixed_t xiscale; // negative if flipped fixed_t depth; fixed_t idepth; // 1/z fixed_t texturemid; DWORD FillColor; lighttable_t *colormap; sector_t *heightsec; // killough 3/27/98: height sector for underwater/fake ceiling sector_t *sector; // [RH] sector this sprite is in fixed_t alpha; fixed_t floorclip; FTexture *pic; short renderflags; DWORD Translation; // [RH] for color translation FRenderStyle RenderStyle; BYTE FakeFlatStat; // [RH] which side of fake/floor ceiling sprite is on BYTE bSplitSprite; // [RH] Sprite was split by a drawseg }; enum { FAKED_Center, FAKED_BelowFloor, FAKED_AboveCeiling }; // // Sprites are patches with a special naming convention so they can be // recognized by R_InitSprites. The base name is NNNNFx or NNNNFxFx, with // x indicating the rotation, x = 0, 1-7. The sprite and frame specified // by a thing_t is range checked at run time. // A sprite is a patch_t that is assumed to represent a three dimensional // object and may have multiple rotations pre drawn. Horizontal flipping // is used to save space, thus NNNNF2F5 defines a mirrored patch. // Some sprites will only have one picture used for all views: NNNNF0 // struct spriteframe_t { FTextureID Texture[16]; // texture to use for view angles 0-15 WORD Flip; // flip (1 = flip) to use for view angles 0-15. }; // // A sprite definition: // a number of animation frames. // struct spritedef_t { union { char name[5]; DWORD dwName; }; BYTE numframes; WORD spriteframes; }; extern TArray SpriteFrames; // // [RH] Internal "skin" definition. // class FPlayerSkin { public: char name[17]; // 16 chars + NULL char face[4]; // 3 chars ([MH] + NULL so can use as a C string) BYTE gender; // This skin's gender (not really used) BYTE range0start; BYTE range0end; bool othergame; // [GRB] fixed_t ScaleX; fixed_t ScaleY; int sprite; int crouchsprite; int namespc; // namespace for this skin }; #endif