qzdoom/src/r_defs.h

// 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"

// 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"



#define MAXWIDTH 2048
#define MAXHEIGHT 1536

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_s
{
	fixed_t x, y;

	bool operator== (const vertex_s &other)
	{
		return x == other.x && y == other.y;
	}
};
typedef struct vertex_s vertex_t;

// Forward of LineDefs, for Sectors.
struct line_s;

class player_s;

//
// The SECTORS record, at runtime.
// Stores things/mobjs.
//
class DSectorEffect;
struct sector_t;

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_ACTOR (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 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);
	}

	// 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);
	}

	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;
}

// Ceiling/floor flags
enum
{
	SECF_ABSLIGHTING	= 1		// floor/ceiling light is absolute, not relative
};

// Misc sector flags
enum
{
	SECF_SILENT			= 1,	// actors in sector make no noise
	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
};

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_s *line, int type);
};

struct sector_t
{
	// Member functions
	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;

	// 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;
	fixed_t		floortexz, ceilingtexz;	// [RH] used for wall texture mapping

	// [RH] give floor and ceiling even more properties
	FDynamicColormap *ColorMap;	// [RH] Per-sector colormap

	// killough 3/7/98: floor and ceiling texture offsets
	fixed_t		  floor_xoffs,   floor_yoffs;
	fixed_t		ceiling_xoffs, ceiling_yoffs;

	// [RH] floor and ceiling texture scales
	fixed_t		  floor_xscale,   floor_yscale;
	fixed_t		ceiling_xscale, ceiling_yscale;

	// [RH] floor and ceiling texture rotation
	angle_t		floor_angle, ceiling_angle;

	fixed_t		base_ceiling_angle, base_ceiling_yoffs;
	fixed_t		base_floor_angle, base_floor_yoffs;

	BYTE		FloorLight, CeilingLight;
	BYTE		FloorFlags, CeilingFlags;
	short		floorpic, ceilingpic;
	BYTE		lightlevel;

	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[3];	// 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
	DSectorEffect *floordata;			// jff 2/22/98 make thinkers on
	DSectorEffect *ceilingdata;			// floors, ceilings, lighting,
	DSectorEffect *lightingdata;		// independent of one another

	// 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_s **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_s *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] Misc 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.
	ASectorAction *SecActTarget;

	// [RH] The sky box to render for this sector. NULL means use a
	// regular sky.
	ASkyViewpoint *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						oldspecial;			//jff 2/16/98 remembers if sector WAS secret (automap)
};

struct ReverbContainer;
struct zone_t
{
	ReverbContainer *Environment;
};


//
// The SideDef.
//

class ADecal;

enum
{
	WALLF_ABSLIGHTING	= 1,	// Light is absolute instead of relative
	WALLF_NOAUTODECALS	= 2,	// Do not attach impact decals to this wall
	WALLF_ADDTRANS		= 4,	// Use additive instead of normal translucency
	WALLF_AUTOCONTRAST	= 8,	// Automatically handle fake contrast in side_s::GetLightLevel
};

struct side_s
{
	fixed_t 	textureoffset;	// add this to the calculated texture column
	fixed_t 	rowoffset;		// add this to the calculated texture top
	sector_t*	sector;			// Sector the SideDef is facing.
	ADecal*		BoundActors;	// [RH] Decals bound to the wall
	short		toptexture, bottomtexture, midtexture;	// texture indices
	WORD		linenum;
	DWORD		LeftSide, RightSide;	// [RH] Group walls into loops
	WORD		TexelLength;
	SBYTE		Light;
	BYTE		Flags;

	int GetLightLevel (bool foggy, int baselight) const;
};
typedef struct side_s side_t;


//
// Move clipping aid for LineDefs.
//
enum slopetype_t
{
	ST_HORIZONTAL,
	ST_VERTICAL,
	ST_POSITIVE,
	ST_NEGATIVE
};

#define ML_ZONEBOUNDARY		0x00010000

struct line_s
{
	vertex_t	*v1, *v2;	// vertices, from v1 to v2
	fixed_t 	dx, dy;		// precalculated v2 - v1 for side checking
	DWORD		flags;
	byte		special;	// [RH] specials are only one byte (like Hexen)
	byte		alpha;		// <--- translucency (0-255/255=opaque)
	short		id;			// <--- same as tag or set with Line_SetIdentification
	short		args[5];	// <--- hexen-style arguments
							//		note that these are shorts in order to support
							//		the tag parameter from DOOM.
	int			firstid, nextid;
	DWORD		sidenum[2];	// sidenum[1] will be 0xffffffff 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

};
typedef struct line_s line_t;

// 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.

typedef struct msecnode_s
{
	sector_t			*m_sector;	// a sector containing this object
	AActor				*m_thing;	// this object
	struct msecnode_s	*m_tprev;	// prev msecnode_t for this thing
	struct msecnode_s	*m_tnext;	// next msecnode_t for this thing
	struct msecnode_s	*m_sprev;	// prev msecnode_t for this sector
	struct msecnode_s	*m_snext;	// next msecnode_t for this sector
	BOOL visited;	// killough 4/4/98, 4/7/98: used in search algorithms
} msecnode_t;

//
// 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;
typedef struct subsector_s
{
	sector_t	*sector;
	DWORD		numlines;
	DWORD		firstline;
	FPolyObj	*poly;
	int			validcount;
	fixed_t		CenterX, CenterY;
} subsector_t;

//
// The LineSeg.
//
struct seg_s
{
	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_s*			PartnerSeg;

	BITFIELD		bPolySeg:1;
};
typedef struct seg_s seg_t;

// ===== Polyobj data =====
typedef struct FPolyObj
{
	int			numsegs;
	seg_t		**segs;
	fixed_t		startSpot[3];
	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
} polyobj_t;

//
// BSP node.
//
struct node_s
{
	// 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.
	};
};
typedef struct node_s node_t;


typedef struct polyblock_s
{
	polyobj_t *polyobj;
	struct polyblock_s *prev;
	struct polyblock_s *next;
} polyblock_t;



// posts are runs of non masked source pixels
struct post_s
{
	byte		topdelta;		// -1 is the last post in a column
	byte		length; 		// length data bytes follows
};
typedef struct post_s post_t;

// column_t is a list of 0 or more post_t, (byte)-1 terminated
typedef post_t	column_t;



//
// OTHER TYPES
//

typedef byte lighttable_t;	// This could be wider for >8 bit display.

// Patches.
// A patch holds one or more columns.
// Patches are used for sprites and all masked pictures, and we compose
// textures from the TEXTURE1/2 lists of patches.
struct patch_t
{ 
	SWORD			width;			// bounding box size 
	SWORD			height; 
	SWORD			leftoffset; 	// pixels to the left of origin 
	SWORD			topoffset;		// pixels below the origin 
	DWORD 			columnofs[8];	// only [width] used
	// the [0] is &columnofs[width] 
};

// Base texture class
class FTexture
{
public:
	FTexture ();
	virtual ~FTexture ();

	SWORD LeftOffset, TopOffset;

	BYTE WidthBits, HeightBits;
	BYTE ScaleX, ScaleY;

	char Name[9];
	BYTE UseType;	// This texture's primary purpose

	BYTE bNoDecals:1;		// Decals should not stick to texture
	BYTE bNoRemap0:1;		// Do not remap color 0 (used by front layer of parallax skies)
	BYTE bWorldPanning:1;	// Texture is panned in world units rather than texels
	BYTE bMasked:1;			// Texture (might) have holes
	BYTE bAlphaTexture:1;	// Texture is an alpha channel without color information
	BYTE bHasCanvas:1;		// Texture is based off FCanvasTexture
	BYTE bWarped:2;			// This is a warped texture. Used to avoid multiple warps on one texture

	WORD Rotations;

	enum // UseTypes
	{
		TEX_Any,
		TEX_Wall,
		TEX_Flat,
		TEX_Sprite,
		TEX_WallPatch,
		TEX_Build,
		TEX_SkinSprite,
		TEX_Decal,
		TEX_MiscPatch,
		TEX_FontChar,
		TEX_Override,	// For patches between TX_START/TX_END
		TEX_Null,
	};

	struct Span
	{
		WORD TopOffset;
		WORD Length;	// A length of 0 terminates this column
	};

	// Returns a single column of the texture
	virtual const BYTE *GetColumn (unsigned int column, const Span **spans_out) = 0;

	// Returns the whole texture, stored in column-major order
	virtual const BYTE *GetPixels () = 0;

	virtual void Unload () = 0;

	int GetWidth () { if (Width == 0xFFFF) { GetDimensions(); } return Width; }
	int GetHeight () { if (Width == 0xFFFF) { GetDimensions(); } return Height; }

	virtual void SetFrontSkyLayer();

	void CopyToBlock (BYTE *dest, int dwidth, int dheight, int x, int y, const BYTE *translation=NULL);

	// Returns true if the next call to GetPixels() will return an image different from the
	// last call to GetPixels(). This should be considered valid only if a call to CheckModified()
	// is immediately followed by a call to GetPixels().
	virtual bool CheckModified ();

protected:
	WORD Width, Height, WidthMask;

	virtual void GetDimensions ();

	Span **CreateSpans (const BYTE *pixels) const;
	void FreeSpans (Span **spans) const;
	void CalcBitSize ();

	static void FlipSquareBlock (BYTE *block, int x, int y);
	static void FlipSquareBlockRemap (BYTE *block, int x, int y, const BYTE *remap);
	static void FlipNonSquareBlock (BYTE *blockto, const BYTE *blockfrom, int x, int y);
	static void FlipNonSquareBlockRemap (BYTE *blockto, const BYTE *blockfrom, int x, int y, const BYTE *remap);
};

// Texture manager
class FTextureManager
{
public:
	FTextureManager ();
	~FTextureManager ();

	// Get texture without translation
	FTexture *operator[] (int texnum)
	{
		if ((size_t)texnum >= Textures.Size()) return NULL;
		return Textures[texnum].Texture;
	}
	FTexture *operator[] (const char *texname)
	{
		int texnum = GetTexture (texname, FTexture::TEX_MiscPatch);
		return Textures[texnum].Texture;
	}

	// Get texture with translation
	FTexture *operator() (int texnum)
	{
		if ((size_t)texnum >= Textures.Size()) return NULL;
		return Textures[Translation[texnum]].Texture;
	}
	FTexture *operator() (const char *texname)
	{
		int texnum = GetTexture (texname, FTexture::TEX_MiscPatch);
		return Textures[Translation[texnum]].Texture;
	}

	void SetTranslation (int fromtexnum, int totexnum)
	{
		if ((size_t)fromtexnum < Translation.Size())
		{
			if ((size_t)totexnum >= Textures.Size())
			{
				totexnum = fromtexnum;
			}
			Translation[fromtexnum] = totexnum;
		}
	}

	enum
	{
		TEXMAN_TryAny = 1,
		TEXMAN_Overridable = 2,
	};

	int CheckForTexture (const char *name, int usetype, BITFIELD flags=TEXMAN_TryAny);
	int GetTexture (const char *name, int usetype, BITFIELD flags=0);

	void WriteTexture (FArchive &arc, int picnum);
	int ReadTexture (FArchive &arc);

	void AddTexturesLump (const void *lumpdata, int lumpsize, int patcheslump, int firstdup=0, bool texture1=false);
	void AddTexturesLumps (int lump1, int lump2, int patcheslump);
	void AddFlats ();
	void AddSprites ();
	void AddPatches (int lumpnum);
	void AddTiles (void *tileFile);
	void AddExtraTextures ();	// Adds patches in the ns_newtextures namespace

	int CreateTexture (int lumpnum, int usetype=FTexture::TEX_Any);	// Also calls AddTexture
	int AddTexture (FTexture *texture);
	int AddPatch (const char *patchname, int namespc=0);

	// Replaces one texture with another. The new texture will be assigned
	// the same name, slot, and use type as the texture it is replacing.
	// The old texture will no longer be managed. Set free true if you want
	// the old texture to be deleted or set it false if you want it to
	// be left alone in memory. You will still need to delete it at some
	// point, because the texture manager no longer knows about it.
	// This function can be used for such things as warping textures.
	void ReplaceTexture (int picnum, FTexture *newtexture, bool free);

	void UnloadAll ();

	int NumTextures () const { return (int)Textures.Size(); }

private:
	struct TextureHash
	{
		FTexture *Texture;
		WORD HashNext;
	};
	enum { HASH_END = 0xFFFF, HASH_SIZE = 1027 };
	TArray<TextureHash> Textures;
	TArray<WORD> Translation;
	WORD HashFirst[HASH_SIZE];
	int DefaultTexture;
};

extern FTextureManager TexMan;


// 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			idepth;			// 1/z
	fixed_t			texturemid;
	DWORD			AlphaColor;
	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;
	WORD			Translation;	// [RH] for color translation
	BYTE			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
{
	WORD 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
{
	char name[5];
	BYTE numframes;
	WORD spriteframes;
};

extern TArray<spriteframe_t> SpriteFrames;

//
// [RH] Internal "skin" definition.
//
class FPlayerSkin
{
public:
	char		name[17];	// 16 chars + NULL
	char		face[3];
	byte		gender;		// This skin's gender (not really used)
	byte		range0start;
	byte		range0end;
	byte		scale;
	byte		game;
	int			sprite;
	int			namespc;	// namespace for this skin
};

#endif