gzdoom/src/p_udmf.cpp

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/*
** p_udmf.cpp
**
** UDMF text map parser
**
**---------------------------------------------------------------------------
** Copyright 2008 Christoph Oelckers
** All rights reserved.
**
** Redistribution and use in source and binary forms, with or without
** modification, are permitted provided that the following conditions
** are met:
**
** 1. Redistributions of source code must retain the above copyright
** notice, this list of conditions and the following disclaimer.
** 2. Redistributions in binary form must reproduce the above copyright
** notice, this list of conditions and the following disclaimer in the
** documentation and/or other materials provided with the distribution.
** 3. The name of the author may not be used to endorse or promote products
** derived from this software without specific prior written permission.
**
** THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
** IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
** OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
** IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
** INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
** NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
** DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
** THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
** (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
** THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
**---------------------------------------------------------------------------
**
*/
#include "r_data.h"
#include "p_setup.h"
#include "sc_man.h"
#include "vectors.h"
#include "p_lnspec.h"
#include "templates.h"
#include "i_system.h"
#include "gi.h"
// These tables define whichline an
static char HexenLineSpecialOk[]={
1,1,1,1,1,1,1,1,1,0, // 0-9
1,1,1,1,0,0,0,0,0,0, // 10-19
1,1,1,1,1,1,1,1,1,1, // 20-29
1,1,1,0,0,1,1,0,0,0, // 30-39
1,1,1,1,1,1,1,0,0,0, // 40-49
0,0,0,0,0,0,0,0,0,0, // 50-59
1,1,1,1,1,1,1,1,1,1, // 60-69
1,1,1,1,1,1,0,0,0,0, // 70-79
1,1,1,1,0,0,0,0,0,0, // 80-89
1,1,1,1,1,1,1,0,0,0, // 90-99
1,1,1,1,0,0,0,0,0,1, // 100-109
1,1,1,1,1,1,1,0,0,0, // 110-119
1,0,0,0,0,0,0,0,0,1, // 120-129
1,1,1,1,1,1,1,1,1,0, // 130-139
1
// 140 is the highest valid special in Hexen.
};
static char HexenSectorSpecialOk[256]={
1,1,1,1,1,0,0,0,0,0,
0,0,0,0,0,0,0,0,0,0,
0,0,0,0,0,0,1,1,0,0,
0,0,0,0,0,0,0,0,0,0,
1,1,1,1,1,1,1,1,1,1,
1,1,0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,1,1,
1,1,1,1,1,1,1,1,1,1,
1,1,1,1,1,
};
enum
{
Dm=1,
Ht=2,
Hx=4,
St=8,
Zd=16,
Zdt=32,
// will be extended later. Unknown namespaces will always be treated like the base
// namespace for each game
};
void P_ProcessSideTextures(bool checktranmap, side_t *sd, sector_t *sec, mapsidedef_t *msd, int special, int tag, short *alpha);
void P_AdjustLine (line_t *ld);
void P_FinishLoadingLineDef(line_t *ld, int alpha);
void SpawnMapThing(int index, FMapThing *mt, int position);
extern bool ForceNodeBuild;
extern TArray<FMapThing> MapThingsConverted;
extern TArray<int> linemap;
#define CHECK_N(f) if (!(namespace_bits&(f))) break;
struct UDMFParser
{
FScanner sc;
FName namespc;
int namespace_bits;
bool isTranslated;
bool isExtended;
bool floordrop;
TArray<line_t> ParsedLines;
TArray<side_t> ParsedSides;
TArray<mapsidedef_t> ParsedSideTextures;
TArray<sector_t> ParsedSectors;
TArray<vertex_t> ParsedVertices;
FDynamicColormap *fogMap, *normMap;
UDMFParser()
{
linemap.Clear();
fogMap = normMap = NULL;
}
FName ParseKey()
{
sc.MustGetString();
FName key = sc.String;
sc.MustGetToken('=');
sc.Number = 0;
sc.Float = 0;
sc.MustGetAnyToken();
if (sc.TokenType == '+' || sc.TokenType == '-')
{
bool neg = (sc.TokenType == '-');
sc.MustGetAnyToken();
if (sc.TokenType != TK_IntConst && sc.TokenType != TK_FloatConst)
{
sc.ScriptMessage("Numeric constant expected");
}
if (neg)
{
sc.Number = -sc.Number;
sc.Float = -sc.Float;
}
}
return key;
}
int CheckInt(const char *key)
{
if (sc.TokenType != TK_IntConst)
{
sc.ScriptMessage("Integer value expected for key '%s'", key);
}
return sc.Number;
}
double CheckFloat(const char *key)
{
if (sc.TokenType != TK_IntConst && sc.TokenType != TK_FloatConst)
{
sc.ScriptMessage("Floatint point value expected for key '%s'", key);
}
return sc.Float;
}
fixed_t CheckFixed(const char *key)
{
return FLOAT2FIXED(CheckFloat(key));
}
bool CheckBool(const char *key)
{
if (sc.TokenType == TK_True) return true;
if (sc.TokenType == TK_False) return false;
sc.ScriptMessage("Boolean value expected for key '%s'", key);
return false;
}
const char *CheckString(const char *key)
{
if (sc.TokenType != TK_StringConst)
{
sc.ScriptMessage("String value expected for key '%s'", key);
}
return sc.String;
}
void Flag(DWORD &value, int mask, const char *key)
{
if (CheckBool(key)) value |= mask;
else value &= ~mask;
}
void ParseThing(FMapThing *th)
{
memset(th, 0, sizeof(*th));
sc.MustGetToken('{');
while (!sc.CheckToken('}'))
{
FName key = ParseKey();
switch(key)
{
case NAME_Id:
th->thingid = CheckInt(key);
break;
case NAME_X:
th->x = CheckFixed(key);
break;
case NAME_Y:
th->y = CheckFixed(key);
break;
case NAME_Height:
th->z = CheckFixed(key);
break;
case NAME_Angle:
th->angle = (short)CheckInt(key);
break;
case NAME_Type:
th->type = (short)CheckInt(key);
break;
case NAME_Special:
CHECK_N(Hx | Zd | Zdt)
th->special = CheckInt(key);
break;
case NAME_Arg0:
case NAME_Arg1:
case NAME_Arg2:
case NAME_Arg3:
case NAME_Arg4:
CHECK_N(Hx | Zd | Zdt)
th->args[int(key)-int(NAME_Arg0)] = CheckInt(key);
break;
case NAME_Skill1:
case NAME_Skill2:
case NAME_Skill3:
case NAME_Skill4:
case NAME_Skill5:
case NAME_Skill6:
case NAME_Skill7:
case NAME_Skill8:
case NAME_Skill9:
case NAME_Skill10:
case NAME_Skill11:
case NAME_Skill12:
case NAME_Skill13:
case NAME_Skill14:
case NAME_Skill15:
case NAME_Skill16:
if (CheckBool(key)) th->SkillFilter |= (1<<(int(key)-NAME_Skill1));
else th->SkillFilter &= ~(1<<(int(key)-NAME_Skill1));
break;
case NAME_Class1:
case NAME_Class2:
case NAME_Class3:
case NAME_Class4:
case NAME_Class5:
case NAME_Class6:
case NAME_Class7:
case NAME_Class8:
case NAME_Class9:
case NAME_Class10:
case NAME_Class11:
case NAME_Class12:
case NAME_Class13:
case NAME_Class14:
case NAME_Class15:
case NAME_Class16:
CHECK_N(Hx | Zd | Zdt)
if (CheckBool(key)) th->ClassFilter |= (1<<(int(key)-NAME_Class1));
else th->SkillFilter &= ~(1<<(int(key)-NAME_Class1));
break;
case NAME_Ambush:
Flag(th->flags, MTF_AMBUSH, key);
break;
case NAME_Dormant:
CHECK_N(Hx | Zd | Zdt)
Flag(th->flags, MTF_DORMANT, key);
break;
case NAME_Single:
Flag(th->flags, MTF_SINGLE, key);
break;
case NAME_Coop:
Flag(th->flags, MTF_COOPERATIVE, key);
break;
case NAME_Dm:
Flag(th->flags, MTF_DEATHMATCH, key);
break;
case NAME_Translucent:
CHECK_N(St | Zd | Zdt)
Flag(th->flags, MTF_SHADOW, key);
break;
case NAME_Invisible:
CHECK_N(St | Zd | Zdt)
Flag(th->flags, MTF_ALTSHADOW, key);
break;
case NAME_Friend: // This maps to Strife's friendly flag
CHECK_N(Dm | Zd | Zdt)
Flag(th->flags, MTF_FRIENDLY, key);
break;
case NAME_Strifeally:
CHECK_N(St | Zd | Zdt)
Flag(th->flags, MTF_FRIENDLY, key);
break;
case NAME_Standing:
CHECK_N(St | Zd | Zdt)
Flag(th->flags, MTF_STANDSTILL, key);
break;
default:
break;
}
sc.MustGetToken(';');
}
// Thing specials are only valid in namespaces with Hexen-type specials
// and in ZDoomTranslated - which will use the translator on them.
if (namespc == NAME_ZDoomTranslated)
{
maplinedef_t mld;
line_t ld;
if (th->special != 0) // if special is 0, keep the args (e.g. for bridge things)
{
// The trigger type is ignored here.
mld.flags = 0;
mld.special = th->special;
mld.tag = th->args[0];
P_TranslateLineDef(&ld, &mld);
th->special = ld.special;
memcpy(th->args, ld.args, sizeof (ld.args));
}
}
else if (isTranslated)
{
th->special = 0;
memset(th->args, 0, sizeof (th->args));
}
}
void ParseLinedef(line_t *ld)
{
bool passuse = false;
bool strifetrans = false;
memset(ld, 0, sizeof(*ld));
ld->Alpha = FRACUNIT;
ld->id = -1;
ld->sidenum[0] = ld->sidenum[1] = NO_SIDE;
if (level.flags & LEVEL_CLIPMIDTEX) ld->flags |= ML_CLIP_MIDTEX;
if (level.flags & LEVEL_WRAPMIDTEX) ld->flags |= ML_WRAP_MIDTEX;
if (level.flags & LEVEL_CHECKSWITCHRANGE) ld->flags |= ML_CHECKSWITCHRANGE;
sc.MustGetToken('{');
while (!sc.CheckToken('}'))
{
FName key = ParseKey();
// This switch contains all keys of the UDMF base spec
switch(key)
{
case NAME_V1:
ld->v1 = (vertex_t*)(intptr_t)CheckInt(key); // must be relocated later
break;
case NAME_V2:
ld->v2 = (vertex_t*)(intptr_t)CheckInt(key); // must be relocated later
break;
case NAME_Special:
ld->special = CheckInt(key);
if (namespc == NAME_Hexen)
{
if (ld->special < 0 || ld->special > 140 || !HexenLineSpecialOk[ld->special])
ld->special = 0; // NULL all specials which don't exist in Hexen
}
break;
case NAME_Id:
ld->id = CheckInt(key);
break;
case NAME_Sidefront:
ld->sidenum[0] = CheckInt(key);
break;
case NAME_Sideback:
ld->sidenum[1] = CheckInt(key);
break;
case NAME_Arg0:
case NAME_Arg1:
case NAME_Arg2:
case NAME_Arg3:
case NAME_Arg4:
ld->args[int(key)-int(NAME_Arg0)] = CheckInt(key);
break;
case NAME_Blocking:
Flag(ld->flags, ML_BLOCKING, key);
break;
case NAME_Blockmonsters:
Flag(ld->flags, ML_BLOCKMONSTERS, key);
break;
case NAME_Twosided:
Flag(ld->flags, ML_TWOSIDED, key);
break;
case NAME_Dontpegtop:
Flag(ld->flags, ML_DONTPEGTOP, key);
break;
case NAME_Dontpegbottom:
Flag(ld->flags, ML_DONTPEGBOTTOM, key);
break;
case NAME_Secret:
Flag(ld->flags, ML_SECRET, key);
break;
case NAME_Blocksound:
Flag(ld->flags, ML_SOUNDBLOCK, key);
break;
case NAME_Dontdraw:
Flag(ld->flags, ML_DONTDRAW, key);
break;
case NAME_Mapped:
Flag(ld->flags, ML_MAPPED, key);
break;
case NAME_Jumpover:
CHECK_N(St | Zd | Zdt)
Flag(ld->flags, ML_RAILING, key);
break;
case NAME_Blockfloating:
CHECK_N(St | Zd | Zdt)
Flag(ld->flags, ML_BLOCK_FLOATERS, key);
break;
case NAME_Transparent:
CHECK_N(St | Zd | Zdt)
strifetrans = CheckBool(key);
break;
case NAME_Passuse:
CHECK_N(Dm | Zd | Zdt)
passuse = CheckBool(key);
break;
default:
break;
}
// This switch contains all keys of the UDMF base spec which only apply to Hexen format specials
if (!isTranslated) switch (key)
{
case NAME_Playercross:
Flag(ld->activation, SPAC_Cross, key);
break;
case NAME_Playeruse:
Flag(ld->activation, SPAC_Use, key);
break;
case NAME_Monstercross:
Flag(ld->activation, SPAC_MCross, key);
break;
case NAME_Impact:
Flag(ld->activation, SPAC_Impact, key);
break;
case NAME_Playerpush:
Flag(ld->activation, SPAC_Push, key);
break;
case NAME_Missilecross:
Flag(ld->activation, SPAC_PCross, key);
break;
case NAME_Monsteruse:
Flag(ld->activation, SPAC_MUse, key);
break;
case NAME_Monsterpush:
Flag(ld->activation, SPAC_MPush, key);
break;
case NAME_Repeatspecial:
Flag(ld->flags, ML_REPEAT_SPECIAL, key);
break;
default:
break;
}
// This switch contains all keys which are ZDoom specific
if (namespace_bits & (Zd|Zdt)) switch(key)
{
case NAME_Anycross:
Flag(ld->activation, SPAC_AnyCross, key);
break;
case NAME_Monsteractivate:
Flag(ld->flags, ML_MONSTERSCANACTIVATE, key);
break;
case NAME_Blockplayers:
Flag(ld->flags, ML_BLOCK_PLAYERS, key);
break;
case NAME_Blockeverything:
Flag(ld->flags, ML_BLOCKEVERYTHING, key);
break;
case NAME_Zoneboundary:
Flag(ld->flags, ML_ZONEBOUNDARY, key);
break;
case NAME_Clipmidtex:
Flag(ld->flags, ML_CLIP_MIDTEX, key);
break;
case NAME_Wrapmidtex:
Flag(ld->flags, ML_WRAP_MIDTEX, key);
break;
case NAME_Midtex3d:
Flag(ld->flags, ML_3DMIDTEX, key);
break;
case NAME_Checkswitchrange:
Flag(ld->flags, ML_CHECKSWITCHRANGE, key);
break;
case NAME_Firstsideonly:
Flag(ld->flags, ML_FIRSTSIDEONLY, key);
break;
default:
break;
}
sc.MustGetToken(';');
}
if (isTranslated)
{
int saved = ld->flags;
maplinedef_t mld;
memset(&mld, 0, sizeof(mld));
mld.special = ld->special;
mld.tag = ld->id;
P_TranslateLineDef(ld, &mld);
ld->flags = saved | (ld->flags&(ML_MONSTERSCANACTIVATE|ML_REPEAT_SPECIAL|ML_FIRSTSIDEONLY));
}
if (passuse && (ld->activation & SPAC_Use))
{
ld->activation = (ld->activation & ~SPAC_Use) | SPAC_UseThrough;
}
if (strifetrans && ld->Alpha == FRACUNIT)
{
ld->Alpha = FRACUNIT * 3/4;
}
}
void ParseSidedef(side_t *sd, mapsidedef_t *sdt)
{
fixed_t texofs[2]={0,0};
memset(sd, 0, sizeof(*sd));
strncpy(sdt->bottomtexture, "-", 8);
strncpy(sdt->toptexture, "-", 8);
strncpy(sdt->midtexture, "-", 8);
sc.MustGetToken('{');
while (!sc.CheckToken('}'))
{
FName key = ParseKey();
switch(key)
{
case NAME_Offsetx:
texofs[0] = CheckInt(key) << FRACBITS;
break;
case NAME_Offsety:
texofs[1] = CheckInt(key) << FRACBITS;
break;
case NAME_Texturetop:
strncpy(sdt->toptexture, CheckString(key), 8);
break;
case NAME_Texturebottom:
strncpy(sdt->bottomtexture, CheckString(key), 8);
break;
case NAME_Texturemiddle:
strncpy(sdt->midtexture, CheckString(key), 8);
break;
case NAME_Sector:
sd->sector = (sector_t*)(intptr_t)CheckInt(key);
break;
default:
break;
}
sc.MustGetToken(';');
}
// initialization of these is delayed to allow separate offsets and add them with the global ones.
sd->AddTextureXOffset(side_t::top, texofs[0]);
sd->AddTextureXOffset(side_t::mid, texofs[0]);
sd->AddTextureXOffset(side_t::bottom, texofs[0]);
sd->AddTextureYOffset(side_t::top, texofs[1]);
sd->AddTextureYOffset(side_t::mid, texofs[1]);
sd->AddTextureYOffset(side_t::bottom, texofs[1]);
}
void ParseSector(sector_t *sec)
{
memset(sec, 0, sizeof(*sec));
sec->lightlevel = 160;
sec->floor_xscale = FRACUNIT; // [RH] floor and ceiling scaling
sec->floor_yscale = FRACUNIT;
sec->ceiling_xscale = FRACUNIT;
sec->ceiling_yscale = FRACUNIT;
sec->oldspecial = !!(sec->special&SECRET_MASK);
sec->thinglist = NULL;
sec->touching_thinglist = NULL; // phares 3/14/98
sec->seqType = (level.flags & LEVEL_SNDSEQTOTALCTRL)? 0:-1;
sec->nextsec = -1; //jff 2/26/98 add fields to support locking out
sec->prevsec = -1; // stair retriggering until build completes
sec->heightsec = NULL; // sector used to get floor and ceiling height
if (floordrop) sec->Flags = SECF_FLOORDROP;
// killough 3/7/98: end changes
sec->gravity = 1.f; // [RH] Default sector gravity of 1.0
sec->ZoneNumber = 0xFFFF;
// killough 8/28/98: initialize all sectors to normal friction
sec->friction = ORIG_FRICTION;
sec->movefactor = ORIG_FRICTION_FACTOR;
sc.MustGetToken('{');
while (!sc.CheckToken('}'))
{
FName key = ParseKey();
switch(key)
{
case NAME_Heightfloor:
sec->floortexz = CheckInt(key) << FRACBITS;
break;
case NAME_Heightceiling:
sec->ceilingtexz = CheckInt(key) << FRACBITS;
break;
case NAME_Texturefloor:
sec->floorpic = TexMan.GetTexture (CheckString(key), FTexture::TEX_Flat, FTextureManager::TEXMAN_Overridable);
break;
case NAME_Textureceiling:
sec->ceilingpic = TexMan.GetTexture (CheckString(key), FTexture::TEX_Flat, FTextureManager::TEXMAN_Overridable);
break;
case NAME_Lightlevel:
sec->lightlevel = (BYTE)clamp<int>(CheckInt(key), 0, 255);
break;
case NAME_Special:
sec->special = (short)CheckInt(key);
if (isTranslated) sec->special = P_TranslateSectorSpecial(sec->special);
else if (namespc == NAME_Hexen)
{
if (sec->special < 0 || sec->special > 255 || !HexenSectorSpecialOk[sec->special])
sec->special = 0; // NULL all unknown specials
}
break;
case NAME_Id:
sec->tag = (short)CheckInt(key);
break;
default:
break;
}
sc.MustGetToken(';');
}
sec->floorplane.d = -sec->floortexz;
sec->floorplane.c = FRACUNIT;
sec->floorplane.ic = FRACUNIT;
sec->ceilingplane.d = sec->ceilingtexz;
sec->ceilingplane.c = -FRACUNIT;
sec->ceilingplane.ic = -FRACUNIT;
// [RH] Sectors default to white light with the default fade.
// If they are outside (have a sky ceiling), they use the outside fog.
if (level.outsidefog != 0xff000000 && (sec->ceilingpic == skyflatnum || (sec->special&0xff) == Sector_Outside))
{
if (fogMap == NULL)
fogMap = GetSpecialLights (PalEntry (255,255,255), level.outsidefog, 0);
sec->ColorMap = fogMap;
}
else
{
if (normMap == NULL)
normMap = GetSpecialLights (PalEntry (255,255,255), level.fadeto, NormalLight.Desaturate);
sec->ColorMap = normMap;
}
}
void ParseVertex(vertex_t *vt)
{
vt->x = vt->y = 0;
sc.MustGetStringName("{");
while (!sc.CheckString("}"))
{
sc.MustGetString();
FName key = sc.String;
sc.MustGetStringName("=");
sc.MustGetString();
FString value = sc.String;
sc.MustGetStringName(";");
switch(key)
{
case NAME_X:
vt->x = FLOAT2FIXED(strtod(value, NULL));
break;
case NAME_Y:
vt->y = FLOAT2FIXED(strtod(value, NULL));
break;
default:
break;
}
}
}
void ProcessLineDefs()
{
int sidecount = 0;
for(unsigned i = 0, skipped = 0; i < ParsedLines.Size();)
{
// Relocate the vertices
intptr_t v1i = intptr_t(ParsedLines[i].v1);
intptr_t v2i = intptr_t(ParsedLines[i].v2);
if (v1i >= numvertexes || v2i >= numvertexes || v1i < 0 || v2i < 0)
{
I_Error ("Line %d has invalid vertices: %zd and/or %zd.\nThe map only contains %d vertices.", i+skipped, v1i, v2i, numvertexes);
}
else if (v1i == v2i ||
(vertexes[v1i].x == vertexes[v2i].x && vertexes[v1i].y == vertexes[v2i].y))
{
Printf ("Removing 0-length line %d\n", i+skipped);
ParsedLines.Delete(i);
ForceNodeBuild = true;
skipped++;
}
else
{
ParsedLines[i].v1 = &vertexes[v1i];
ParsedLines[i].v2 = &vertexes[v2i];
if (ParsedLines[i].sidenum[0] != NO_SIDE)
sidecount++;
if (ParsedLines[i].sidenum[1] != NO_SIDE)
sidecount++;
linemap.Push(i+skipped);
i++;
}
}
numlines = ParsedLines.Size();
numsides = sidecount;
lines = new line_t[numlines];
sides = new side_t[numsides];
for(int line = 0, side = 0; line < numlines; line++)
{
short tempalpha[2] = {-1,-1};
lines[line] = ParsedLines[line];
for(int sd = 0; sd < 2; sd++)
{
if (lines[line].sidenum[sd] != NO_SIDE)
{
int mapside = lines[line].sidenum[sd];
sides[side] = ParsedSides[mapside];
sides[side].linenum = line;
sides[side].sector = &sectors[intptr_t(sides[side].sector)];
lines[line].sidenum[sd] = side;
P_ProcessSideTextures(!isExtended, &sides[side], sides[side].sector, &ParsedSideTextures[mapside],
lines[line].special, lines[line].args[0], &tempalpha[sd]);
side++;
}
}
P_AdjustLine(&lines[line]);
P_FinishLoadingLineDef(&lines[line], tempalpha[0]);
}
}
void ParseTextMap(MapData *map)
{
char *buffer = new char[map->Size(ML_TEXTMAP)];
isTranslated = true;
map->Read(ML_TEXTMAP, buffer);
sc.OpenMem(Wads.GetLumpFullName(map->lumpnum), buffer, map->Size(ML_TEXTMAP));
sc.SetCMode(true);
if (sc.CheckString("namespace"))
{
sc.MustGetStringName("=");
sc.MustGetString();
namespc = sc.String;
switch(namespc)
{
case NAME_ZDoom:
namespace_bits = Zd;
isTranslated = false;
break;
case NAME_ZDoomTranslated:
namespace_bits = Zdt;
break;
case NAME_Hexen:
namespace_bits = Hx;
isTranslated = false;
break;
case NAME_Doom:
namespace_bits = Dm;
P_LoadTranslator("xlat/doom_base.txt");
level.flags |= LEVEL_DUMMYSWITCHES;
floordrop = true;
break;
case NAME_Heretic:
namespace_bits = Ht;
P_LoadTranslator("xlat/heretic_base.txt");
level.flags |= LEVEL_DUMMYSWITCHES;
floordrop = true;
break;
case NAME_Strife:
namespace_bits = St;
P_LoadTranslator("xlat/strife_base.txt");
level.flags |= LEVEL_DUMMYSWITCHES|LEVEL_RAILINGHACK;
floordrop = true;
break;
default:
Printf("Unknown namespace %s. Using defaults for %s\n", sc.String, GameNames[gameinfo.gametype]);
switch (gameinfo.gametype)
{
case GAME_Doom:
namespace_bits = Dm;
P_LoadTranslator("xlat/doom_base.txt");
break;
case GAME_Heretic:
namespace_bits = Ht;
P_LoadTranslator("xlat/heretic_base.txt");
break;
case GAME_Strife:
namespace_bits = St;
P_LoadTranslator("xlat/strife_base.txt");
break;
case GAME_Hexen:
namespace_bits = Hx;
isTranslated = false;
break;
}
}
sc.MustGetStringName(";");
}
else
{
Printf("Map does not define a namespace.\n");
}
while (sc.GetString())
{
if (sc.Compare("thing"))
{
FMapThing th;
ParseThing(&th);
MapThingsConverted.Push(th);
}
else if (sc.Compare("linedef"))
{
line_t li;
ParseLinedef(&li);
ParsedLines.Push(li);
}
else if (sc.Compare("sidedef"))
{
side_t si;
mapsidedef_t st;
ParseSidedef(&si, &st);
ParsedSides.Push(si);
ParsedSideTextures.Push(st);
}
else if (sc.Compare("sector"))
{
sector_t sec;
ParseSector(&sec);
ParsedSectors.Push(sec);
}
else if (sc.Compare("vertex"))
{
vertex_t vt;
ParseVertex(&vt);
ParsedVertices.Push(vt);
}
}
// Create the real vertices
numvertexes = ParsedVertices.Size();
vertexes = new vertex_t[numvertexes];
memcpy(vertexes, &ParsedVertices[0], numvertexes * sizeof(*vertexes));
// Create the real sectors
numsectors = ParsedSectors.Size();
sectors = new sector_t[numsectors];
memcpy(sectors, &ParsedSectors[0], numsectors * sizeof(*sectors));
sectors[0].e = new extsector_t[numsectors];
for(int i = 0; i < numsectors; i++)
{
sectors[i].e = &sectors[0].e[i];
}
// Create the real linedefs and decompress the sidedefs
ProcessLineDefs();
}
};
void P_ParseTextMap(MapData *map)
{
UDMFParser parse;
parse.ParseTextMap(map);
}
void P_SpawnTextThings(int position)
{
for(unsigned i=0; i<MapThingsConverted.Size(); i++)
{
SpawnMapThing (i, &MapThingsConverted[i], position);
}
}