/* ------------------------------------------------------------------------------- Copyright (C) 1999-2007 id Software, Inc. and contributors. For a list of contributors, see the accompanying CONTRIBUTORS file. This file is part of GtkRadiant. GtkRadiant is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. GtkRadiant is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GtkRadiant; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA ------------------------------------------------------------------------------- This code has been altered significantly from its original form, to support several games based on the Quake III Arena engine, in the form of "Q3Map2." ------------------------------------------------------------------------------- */ /* dependencies */ #include "q3map2.h" /* AnalyzeBSP() - ydnar analyzes a Quake engine BSP file */ typedef struct abspHeader_s { char ident[ 4 ]; int version; bspLump_t lumps[ 1 ]; /* unknown size */ } abspHeader_t; typedef struct abspLumpTest_s { int radix, minCount; char *name; } abspLumpTest_t; int AnalyzeBSP( int argc, char **argv ){ abspHeader_t *header; int size, i, version, offset, length, lumpInt, count; char ident[ 5 ]; void *lump; float lumpFloat; char lumpString[ 1024 ], source[ 1024 ]; qboolean lumpSwap = qfalse; abspLumpTest_t *lumpTest; static abspLumpTest_t lumpTests[] = { { sizeof( bspPlane_t ), 6, "IBSP LUMP_PLANES" }, { sizeof( bspBrush_t ), 1, "IBSP LUMP_BRUSHES" }, { 8, 6, "IBSP LUMP_BRUSHSIDES" }, { sizeof( bspBrushSide_t ), 6, "RBSP LUMP_BRUSHSIDES" }, { sizeof( bspModel_t ), 1, "IBSP LUMP_MODELS" }, { sizeof( bspNode_t ), 2, "IBSP LUMP_NODES" }, { sizeof( bspLeaf_t ), 1, "IBSP LUMP_LEAFS" }, { 104, 3, "IBSP LUMP_DRAWSURFS" }, { 44, 3, "IBSP LUMP_DRAWVERTS" }, { 4, 6, "IBSP LUMP_DRAWINDEXES" }, { 128 * 128 * 3, 1, "IBSP LUMP_LIGHTMAPS" }, { 256 * 256 * 3, 1, "IBSP LUMP_LIGHTMAPS (256 x 256)" }, { 512 * 512 * 3, 1, "IBSP LUMP_LIGHTMAPS (512 x 512)" }, { 0, 0, NULL } }; /* arg checking */ if ( argc < 1 ) { Sys_Printf( "Usage: q3map -analyze [-lumpswap] [-v] \n" ); return 0; } /* process arguments */ for ( i = 1; i < ( argc - 1 ); i++ ) { /* -format map|ase|... */ if ( !strcmp( argv[ i ], "-lumpswap" ) ) { Sys_Printf( "Swapped lump structs enabled\n" ); lumpSwap = qtrue; } } /* clean up map name */ strcpy( source, ExpandArg( argv[ i ] ) ); Sys_Printf( "Loading %s\n", source ); /* load the file */ size = LoadFile( source, (void**) &header ); if ( size == 0 || header == NULL ) { Sys_Printf( "Unable to load %s.\n", source ); return -1; } /* analyze ident/version */ memcpy( ident, header->ident, 4 ); ident[ 4 ] = '\0'; version = LittleLong( header->version ); Sys_Printf( "Identity: %s\n", ident ); Sys_Printf( "Version: %d\n", version ); Sys_Printf( "---------------------------------------\n" ); /* analyze each lump */ for ( i = 0; i < 100; i++ ) { /* call of duty swapped lump pairs */ if ( lumpSwap ) { offset = LittleLong( header->lumps[ i ].length ); length = LittleLong( header->lumps[ i ].offset ); } /* standard lump pairs */ else { offset = LittleLong( header->lumps[ i ].offset ); length = LittleLong( header->lumps[ i ].length ); } /* extract data */ lump = (byte*) header + offset; lumpInt = LittleLong( (int) *( (int*) lump ) ); lumpFloat = LittleFloat( (float) *( (float*) lump ) ); memcpy( lumpString, (char*) lump, ( (size_t)length < sizeof( lumpString ) ? (size_t)length : sizeof( lumpString ) - 1 ) ); lumpString[ sizeof( lumpString ) - 1 ] = '\0'; /* print basic lump info */ Sys_Printf( "Lump: %d\n", i ); Sys_Printf( "Offset: %d bytes\n", offset ); Sys_Printf( "Length: %d bytes\n", length ); /* only operate on valid lumps */ if ( length > 0 ) { /* print data in 4 formats */ Sys_Printf( "As hex: %08X\n", lumpInt ); Sys_Printf( "As int: %d\n", lumpInt ); Sys_Printf( "As float: %f\n", lumpFloat ); Sys_Printf( "As string: %s\n", lumpString ); /* guess lump type */ if ( lumpString[ 0 ] == '{' && lumpString[ 2 ] == '"' ) { Sys_Printf( "Type guess: IBSP LUMP_ENTITIES\n" ); } else if ( strstr( lumpString, "textures/" ) ) { Sys_Printf( "Type guess: IBSP LUMP_SHADERS\n" ); } else { /* guess based on size/count */ for ( lumpTest = lumpTests; lumpTest->radix > 0; lumpTest++ ) { if ( ( length % lumpTest->radix ) != 0 ) { continue; } count = length / lumpTest->radix; if ( count < lumpTest->minCount ) { continue; } Sys_Printf( "Type guess: %s (%d x %d)\n", lumpTest->name, count, lumpTest->radix ); } } } Sys_Printf( "---------------------------------------\n" ); /* end of file */ if ( offset + length >= size ) { break; } } /* last stats */ Sys_Printf( "Lump count: %d\n", i + 1 ); Sys_Printf( "File size: %d bytes\n", size ); /* return to caller */ return 0; } /* BSPInfo() emits statistics about the bsp file */ int BSPInfo( int count, char **fileNames ){ int i; char source[ 1024 ], ext[ 64 ]; int size; FILE *f; /* dummy check */ if ( count < 1 ) { Sys_Printf( "No files to dump info for.\n" ); return -1; } /* enable info mode */ infoMode = qtrue; /* walk file list */ for ( i = 0; i < count; i++ ) { Sys_Printf( "---------------------------------\n" ); /* mangle filename and get size */ strcpy( source, fileNames[ i ] ); ExtractFileExtension( source, ext ); if ( !Q_stricmp( ext, "map" ) ) { StripExtension( source ); } DefaultExtension( source, ".bsp" ); f = fopen( source, "rb" ); if ( f ) { size = Q_filelength( f ); fclose( f ); } else{ size = 0; } /* load the bsp file and print lump sizes */ Sys_Printf( "%s\n", source ); LoadBSPFile( source ); PrintBSPFileSizes(); /* print sizes */ Sys_Printf( "\n" ); Sys_Printf( " total %9d\n", size ); Sys_Printf( " %9d KB\n", size / 1024 ); Sys_Printf( " %9d MB\n", size / ( 1024 * 1024 ) ); Sys_Printf( "---------------------------------\n" ); } /* return count */ return i; } static void ExtrapolateTexcoords( const float *axyz, const float *ast, const float *bxyz, const float *bst, const float *cxyz, const float *cst, const float *axyz_new, float *ast_out, const float *bxyz_new, float *bst_out, const float *cxyz_new, float *cst_out ){ vec4_t scoeffs, tcoeffs; float md; m4x4_t solvematrix; vec3_t norm; vec3_t dab, dac; VectorSubtract( bxyz, axyz, dab ); VectorSubtract( cxyz, axyz, dac ); CrossProduct( dab, dac, norm ); // assume: // s = f(x, y, z) // s(v + norm) = s(v) when n ortho xyz // s(v) = DotProduct(v, scoeffs) + scoeffs[3] // solve: // scoeffs * (axyz, 1) == ast[0] // scoeffs * (bxyz, 1) == bst[0] // scoeffs * (cxyz, 1) == cst[0] // scoeffs * (norm, 0) == 0 // scoeffs * [axyz, 1 | bxyz, 1 | cxyz, 1 | norm, 0] = [ast[0], bst[0], cst[0], 0] solvematrix[0] = axyz[0]; solvematrix[4] = axyz[1]; solvematrix[8] = axyz[2]; solvematrix[12] = 1; solvematrix[1] = bxyz[0]; solvematrix[5] = bxyz[1]; solvematrix[9] = bxyz[2]; solvematrix[13] = 1; solvematrix[2] = cxyz[0]; solvematrix[6] = cxyz[1]; solvematrix[10] = cxyz[2]; solvematrix[14] = 1; solvematrix[3] = norm[0]; solvematrix[7] = norm[1]; solvematrix[11] = norm[2]; solvematrix[15] = 0; md = m4_det( solvematrix ); if ( md * md < 1e-10 ) { Sys_Printf( "Cannot invert some matrix, some texcoords aren't extrapolated!" ); return; } m4x4_invert( solvematrix ); scoeffs[0] = ast[0]; scoeffs[1] = bst[0]; scoeffs[2] = cst[0]; scoeffs[3] = 0; m4x4_transform_vec4( solvematrix, scoeffs ); tcoeffs[0] = ast[1]; tcoeffs[1] = bst[1]; tcoeffs[2] = cst[1]; tcoeffs[3] = 0; m4x4_transform_vec4( solvematrix, tcoeffs ); ast_out[0] = scoeffs[0] * axyz_new[0] + scoeffs[1] * axyz_new[1] + scoeffs[2] * axyz_new[2] + scoeffs[3]; ast_out[1] = tcoeffs[0] * axyz_new[0] + tcoeffs[1] * axyz_new[1] + tcoeffs[2] * axyz_new[2] + tcoeffs[3]; bst_out[0] = scoeffs[0] * bxyz_new[0] + scoeffs[1] * bxyz_new[1] + scoeffs[2] * bxyz_new[2] + scoeffs[3]; bst_out[1] = tcoeffs[0] * bxyz_new[0] + tcoeffs[1] * bxyz_new[1] + tcoeffs[2] * bxyz_new[2] + tcoeffs[3]; cst_out[0] = scoeffs[0] * cxyz_new[0] + scoeffs[1] * cxyz_new[1] + scoeffs[2] * cxyz_new[2] + scoeffs[3]; cst_out[1] = tcoeffs[0] * cxyz_new[0] + tcoeffs[1] * cxyz_new[1] + tcoeffs[2] * cxyz_new[2] + tcoeffs[3]; } /* ScaleBSPMain() amaze and confuse your enemies with wierd scaled maps! */ int ScaleBSPMain( int argc, char **argv ){ int i, j; float f, a; vec3_t scale; vec3_t vec; char str[ 1024 ]; int uniform, axis; qboolean texscale; float *old_xyzst = NULL; float spawn_ref = 0; /* arg checking */ if ( argc < 3 ) { Sys_Printf( "Usage: q3map [-v] -scale [-tex] [-spawn_ref ] \n" ); return 0; } texscale = qfalse; for ( i = 1; i < argc - 2; ++i ) { if ( !strcmp( argv[i], "-tex" ) ) { texscale = qtrue; } else if ( !strcmp( argv[i], "-spawn_ref" ) ) { spawn_ref = atof( argv[i + 1] ); ++i; } else{ break; } } /* get scale */ // if(argc-2 >= i) // always true scale[2] = scale[1] = scale[0] = atof( argv[ argc - 2 ] ); if ( argc - 3 >= i ) { scale[1] = scale[0] = atof( argv[ argc - 3 ] ); } if ( argc - 4 >= i ) { scale[0] = atof( argv[ argc - 4 ] ); } uniform = ( ( scale[0] == scale[1] ) && ( scale[1] == scale[2] ) ); if ( scale[0] == 0.0f || scale[1] == 0.0f || scale[2] == 0.0f ) { Sys_Printf( "Usage: q3map [-v] -scale [-tex] [-spawn_ref ] \n" ); Sys_Printf( "Non-zero scale value required.\n" ); return 0; } /* do some path mangling */ strcpy( source, ExpandArg( argv[ argc - 1 ] ) ); StripExtension( source ); DefaultExtension( source, ".bsp" ); /* load the bsp */ Sys_Printf( "Loading %s\n", source ); LoadBSPFile( source ); ParseEntities(); /* note it */ Sys_Printf( "--- ScaleBSP ---\n" ); Sys_FPrintf( SYS_VRB, "%9d entities\n", numEntities ); /* scale entity keys */ for ( i = 0; i < numBSPEntities && i < numEntities; i++ ) { /* scale origin */ GetVectorForKey( &entities[ i ], "origin", vec ); if ( ( vec[ 0 ] || vec[ 1 ] || vec[ 2 ] ) ) { if ( !strncmp( ValueForKey( &entities[i], "classname" ), "info_player_", 12 ) ) { vec[2] += spawn_ref; } vec[0] *= scale[0]; vec[1] *= scale[1]; vec[2] *= scale[2]; if ( !strncmp( ValueForKey( &entities[i], "classname" ), "info_player_", 12 ) ) { vec[2] -= spawn_ref; } sprintf( str, "%f %f %f", vec[ 0 ], vec[ 1 ], vec[ 2 ] ); SetKeyValue( &entities[ i ], "origin", str ); } a = FloatForKey( &entities[ i ], "angle" ); if ( a == -1 || a == -2 ) { // z scale axis = 2; } else if ( fabs( sin( DEG2RAD( a ) ) ) < 0.707 ) { axis = 0; } else{ axis = 1; } /* scale door lip */ f = FloatForKey( &entities[ i ], "lip" ); if ( f ) { f *= scale[axis]; sprintf( str, "%f", f ); SetKeyValue( &entities[ i ], "lip", str ); } /* scale plat height */ f = FloatForKey( &entities[ i ], "height" ); if ( f ) { f *= scale[2]; sprintf( str, "%f", f ); SetKeyValue( &entities[ i ], "height", str ); } // TODO maybe allow a definition file for entities to specify which values are scaled how? } /* scale models */ for ( i = 0; i < numBSPModels; i++ ) { bspModels[ i ].mins[0] *= scale[0]; bspModels[ i ].mins[1] *= scale[1]; bspModels[ i ].mins[2] *= scale[2]; bspModels[ i ].maxs[0] *= scale[0]; bspModels[ i ].maxs[1] *= scale[1]; bspModels[ i ].maxs[2] *= scale[2]; } /* scale nodes */ for ( i = 0; i < numBSPNodes; i++ ) { bspNodes[ i ].mins[0] *= scale[0]; bspNodes[ i ].mins[1] *= scale[1]; bspNodes[ i ].mins[2] *= scale[2]; bspNodes[ i ].maxs[0] *= scale[0]; bspNodes[ i ].maxs[1] *= scale[1]; bspNodes[ i ].maxs[2] *= scale[2]; } /* scale leafs */ for ( i = 0; i < numBSPLeafs; i++ ) { bspLeafs[ i ].mins[0] *= scale[0]; bspLeafs[ i ].mins[1] *= scale[1]; bspLeafs[ i ].mins[2] *= scale[2]; bspLeafs[ i ].maxs[0] *= scale[0]; bspLeafs[ i ].maxs[1] *= scale[1]; bspLeafs[ i ].maxs[2] *= scale[2]; } if ( texscale ) { Sys_Printf( "Using texture unlocking (and probably breaking texture alignment a lot)\n" ); old_xyzst = safe_malloc( sizeof( *old_xyzst ) * numBSPDrawVerts * 5 ); for ( i = 0; i < numBSPDrawVerts; i++ ) { old_xyzst[5 * i + 0] = bspDrawVerts[i].xyz[0]; old_xyzst[5 * i + 1] = bspDrawVerts[i].xyz[1]; old_xyzst[5 * i + 2] = bspDrawVerts[i].xyz[2]; old_xyzst[5 * i + 3] = bspDrawVerts[i].st[0]; old_xyzst[5 * i + 4] = bspDrawVerts[i].st[1]; } } /* scale drawverts */ for ( i = 0; i < numBSPDrawVerts; i++ ) { bspDrawVerts[i].xyz[0] *= scale[0]; bspDrawVerts[i].xyz[1] *= scale[1]; bspDrawVerts[i].xyz[2] *= scale[2]; bspDrawVerts[i].normal[0] /= scale[0]; bspDrawVerts[i].normal[1] /= scale[1]; bspDrawVerts[i].normal[2] /= scale[2]; VectorNormalize( bspDrawVerts[i].normal, bspDrawVerts[i].normal ); } if ( texscale ) { for ( i = 0; i < numBSPDrawSurfaces; i++ ) { switch ( bspDrawSurfaces[i].surfaceType ) { case SURFACE_FACE: case SURFACE_META: if ( bspDrawSurfaces[i].numIndexes % 3 ) { Error( "Not a triangulation!" ); } for ( j = bspDrawSurfaces[i].firstIndex; j < bspDrawSurfaces[i].firstIndex + bspDrawSurfaces[i].numIndexes; j += 3 ) { int ia = bspDrawIndexes[j] + bspDrawSurfaces[i].firstVert, ib = bspDrawIndexes[j + 1] + bspDrawSurfaces[i].firstVert, ic = bspDrawIndexes[j + 2] + bspDrawSurfaces[i].firstVert; bspDrawVert_t *a = &bspDrawVerts[ia], *b = &bspDrawVerts[ib], *c = &bspDrawVerts[ic]; float *oa = &old_xyzst[ia * 5], *ob = &old_xyzst[ib * 5], *oc = &old_xyzst[ic * 5]; // extrapolate: // a->xyz -> oa // b->xyz -> ob // c->xyz -> oc ExtrapolateTexcoords( &oa[0], &oa[3], &ob[0], &ob[3], &oc[0], &oc[3], a->xyz, a->st, b->xyz, b->st, c->xyz, c->st ); } break; } } } /* scale planes */ if ( uniform ) { for ( i = 0; i < numBSPPlanes; i++ ) { bspPlanes[ i ].dist *= scale[0]; } } else { for ( i = 0; i < numBSPPlanes; i++ ) { bspPlanes[ i ].normal[0] /= scale[0]; bspPlanes[ i ].normal[1] /= scale[1]; bspPlanes[ i ].normal[2] /= scale[2]; f = 1 / VectorLength( bspPlanes[i].normal ); VectorScale( bspPlanes[i].normal, f, bspPlanes[i].normal ); bspPlanes[ i ].dist *= f; } } /* scale gridsize */ GetVectorForKey( &entities[ 0 ], "gridsize", vec ); if ( ( vec[ 0 ] + vec[ 1 ] + vec[ 2 ] ) == 0.0f ) { VectorCopy( gridSize, vec ); } vec[0] *= scale[0]; vec[1] *= scale[1]; vec[2] *= scale[2]; sprintf( str, "%f %f %f", vec[ 0 ], vec[ 1 ], vec[ 2 ] ); SetKeyValue( &entities[ 0 ], "gridsize", str ); /* inject command line parameters */ InjectCommandLine( argv, 0, argc - 1 ); /* write the bsp */ UnparseEntities(); StripExtension( source ); DefaultExtension( source, "_s.bsp" ); Sys_Printf( "Writing %s\n", source ); WriteBSPFile( source ); /* return to sender */ return 0; } /* PseudoCompileBSP() a stripped down ProcessModels */ void PseudoCompileBSP( qboolean need_tree ){ int models; char modelValue[10]; entity_t *entity; face_t *faces; tree_t *tree; node_t *node; brush_t *brush; side_t *side; int i; SetDrawSurfacesBuffer(); mapDrawSurfs = safe_malloc( sizeof( mapDrawSurface_t ) * MAX_MAP_DRAW_SURFS ); memset( mapDrawSurfs, 0, sizeof( mapDrawSurface_t ) * MAX_MAP_DRAW_SURFS ); numMapDrawSurfs = 0; BeginBSPFile(); models = 1; for ( mapEntityNum = 0; mapEntityNum < numEntities; mapEntityNum++ ) { /* get entity */ entity = &entities[ mapEntityNum ]; if ( entity->brushes == NULL && entity->patches == NULL ) { continue; } if ( mapEntityNum != 0 ) { sprintf( modelValue, "*%d", models++ ); SetKeyValue( entity, "model", modelValue ); } /* process the model */ Sys_FPrintf( SYS_VRB, "############### model %i ###############\n", numBSPModels ); BeginModel(); entity->firstDrawSurf = numMapDrawSurfs; ClearMetaTriangles(); PatchMapDrawSurfs( entity ); if ( mapEntityNum == 0 && need_tree ) { faces = MakeStructuralBSPFaceList( entities[0].brushes ); tree = FaceBSP( faces ); node = tree->headnode; } else { node = AllocNode(); node->planenum = PLANENUM_LEAF; tree = AllocTree(); tree->headnode = node; } /* a minimized ClipSidesIntoTree */ for ( brush = entity->brushes; brush; brush = brush->next ) { /* walk the brush sides */ for ( i = 0; i < brush->numsides; i++ ) { /* get side */ side = &brush->sides[ i ]; if ( side->winding == NULL ) { continue; } /* shader? */ if ( side->shaderInfo == NULL ) { continue; } /* save this winding as a visible surface */ DrawSurfaceForSide( entity, brush, side, side->winding ); } } if ( meta ) { ClassifyEntitySurfaces( entity ); MakeEntityDecals( entity ); MakeEntityMetaTriangles( entity ); SmoothMetaTriangles(); MergeMetaTriangles(); } FilterDrawsurfsIntoTree( entity, tree ); FilterStructuralBrushesIntoTree( entity, tree ); FilterDetailBrushesIntoTree( entity, tree ); EmitBrushes( entity->brushes, &entity->firstBrush, &entity->numBrushes ); EndModel( entity, node ); } EndBSPFile( qfalse ); } /* ConvertBSPMain() main argument processing function for bsp conversion */ int ConvertBSPMain( int argc, char **argv ){ int i; int ( *convertFunc )( char * ); game_t *convertGame; char ext[1024]; qboolean map_allowed, force_bsp, force_map; /* set default */ convertFunc = ConvertBSPToASE; convertGame = NULL; map_allowed = qfalse; force_bsp = qfalse; force_map = qfalse; /* arg checking */ if ( argc < 1 ) { Sys_Printf( "Usage: q3map -convert [-format ] [-shadersasbitmap|-lightmapsastexcoord|-deluxemapsastexcoord] [-readbsp|-readmap [-meta|-patchmeta]] [-v] \n" ); return 0; } /* process arguments */ for ( i = 1; i < ( argc - 1 ); i++ ) { /* -format map|ase|... */ if ( !strcmp( argv[ i ], "-format" ) ) { i++; if ( !Q_stricmp( argv[ i ], "ase" ) ) { convertFunc = ConvertBSPToASE; map_allowed = qfalse; } else if ( !Q_stricmp( argv[ i ], "obj" ) ) { convertFunc = ConvertBSPToOBJ; map_allowed = qfalse; } else if ( !Q_stricmp( argv[ i ], "map_bp" ) ) { convertFunc = ConvertBSPToMap_BP; map_allowed = qtrue; } else if ( !Q_stricmp( argv[ i ], "map" ) ) { convertFunc = ConvertBSPToMap; map_allowed = qtrue; } else { convertGame = GetGame( argv[ i ] ); map_allowed = qfalse; if ( convertGame == NULL ) { Sys_Printf( "Unknown conversion format \"%s\". Defaulting to ASE.\n", argv[ i ] ); } } } else if ( !strcmp( argv[ i ], "-ne" ) ) { normalEpsilon = atof( argv[ i + 1 ] ); i++; Sys_Printf( "Normal epsilon set to %f\n", normalEpsilon ); } else if ( !strcmp( argv[ i ], "-de" ) ) { distanceEpsilon = atof( argv[ i + 1 ] ); i++; Sys_Printf( "Distance epsilon set to %f\n", distanceEpsilon ); } else if ( !strcmp( argv[ i ], "-shaderasbitmap" ) || !strcmp( argv[ i ], "-shadersasbitmap" ) ) { shadersAsBitmap = qtrue; } else if ( !strcmp( argv[ i ], "-lightmapastexcoord" ) || !strcmp( argv[ i ], "-lightmapsastexcoord" ) ) { lightmapsAsTexcoord = qtrue; } else if ( !strcmp( argv[ i ], "-deluxemapastexcoord" ) || !strcmp( argv[ i ], "-deluxemapsastexcoord" ) ) { lightmapsAsTexcoord = qtrue; deluxemap = qtrue; } else if ( !strcmp( argv[ i ], "-readbsp" ) ) { force_bsp = qtrue; } else if ( !strcmp( argv[ i ], "-readmap" ) ) { force_map = qtrue; } else if ( !strcmp( argv[ i ], "-meta" ) ) { meta = qtrue; } else if ( !strcmp( argv[ i ], "-patchmeta" ) ) { meta = qtrue; patchMeta = qtrue; } } LoadShaderInfo(); /* clean up map name */ strcpy( source, ExpandArg( argv[i] ) ); ExtractFileExtension( source, ext ); if ( !map_allowed && !force_map ) { force_bsp = qtrue; } if ( force_map || ( !force_bsp && !Q_stricmp( ext, "map" ) && map_allowed ) ) { if ( !map_allowed ) { Sys_Printf( "WARNING: the requested conversion should not be done from .map files. Compile a .bsp first.\n" ); } StripExtension( source ); DefaultExtension( source, ".map" ); Sys_Printf( "Loading %s\n", source ); LoadMapFile( source, qfalse, convertGame == NULL ); PseudoCompileBSP( convertGame != NULL ); } else { StripExtension( source ); DefaultExtension( source, ".bsp" ); Sys_Printf( "Loading %s\n", source ); LoadBSPFile( source ); ParseEntities(); } /* bsp format convert? */ if ( convertGame != NULL ) { /* set global game */ game = convertGame; /* write bsp */ StripExtension( source ); DefaultExtension( source, "_c.bsp" ); Sys_Printf( "Writing %s\n", source ); WriteBSPFile( source ); /* return to sender */ return 0; } /* normal convert */ return convertFunc( source ); }