void Sys_Error(int entitynum, int brushnum, const char *text, ... )
{
char out_buffer[4096];
va_list argptr;
/* print */
va_start( argptr, text );
vsprintf( out_buffer, text, argptr );
va_end( argptr );
/* send */
xml_Select( out_buffer, entitynum, brushnum, qtrue );
}
void Sys_Warning(int entitynum, const char *text, ... )
{
char out_buffer[4096];
va_list argptr;
/* print */
va_start( argptr, text );
vsprintf( out_buffer, text, argptr );
va_end( argptr );
/* send */
xml_Select( out_buffer, entitynum, -1, qfalse );
}
void ParsePatch( qboolean onlyLights )
{
vec_t info[ 5 ];
int i, j, k;
parseMesh_t *pm;
char texture[ MAX_QPATH ];
char shader[ MAX_QPATH ];
mesh_t m;
bspDrawVert_t *verts;
epair_t *ep;
vec4_t delta, delta2, delta3;
qboolean degenerate;
float longestCurve;
int maxIterations;
MatchToken( "{" );
/* get texture */
GetToken( qtrue );
strcpy( texture, token );
Parse1DMatrix( 5, info );
m.width = info[0];
m.height = info[1];
m.verts = verts = safe_malloc( m.width * m.height * sizeof( m.verts[0] ) );
if( m.width < 0 || m.width > MAX_PATCH_SIZE || m.height < 0 || m.height > MAX_PATCH_SIZE )
Error( "ParsePatch: bad size" );
MatchToken( "(" );
for( j = 0; j < m.width ; j++ )
{
MatchToken( "(" );
for( i = 0; i < m.height ; i++ )
{
Parse1DMatrix( 5, verts[ i * m.width + j ].xyz );
/* ydnar: fix colors */
for( k = 0; k < MAX_LIGHTMAPS; k++ )
{
verts[ i * m.width + j ].color[ k ][ 0 ] = 255;
verts[ i * m.width + j ].color[ k ][ 1 ] = 255;
verts[ i * m.width + j ].color[ k ][ 2 ] = 255;
verts[ i * m.width + j ].color[ k ][ 3 ] = 255;
}
}
MatchToken( ")" );
}
MatchToken( ")" );
// if brush primitives format, we may have some epairs to ignore here
GetToken(qtrue);
if (g_bBrushPrimit!=BPRIMIT_OLDBRUSHES && strcmp(token,"}"))
{
ep = ParseEPair();
free(ep->key);
free(ep->value);
free(ep);
}
else
UnGetToken();
MatchToken( "}" );
MatchToken( "}" );
/* short circuit */
if( noCurveBrushes || onlyLights )
return;
/* ydnar: delete and warn about degenerate patches */
j = (m.width * m.height);
VectorClear( delta );
delta[ 3 ] = 0;
degenerate = qtrue;
/* find first valid vector */
for( i = 1; i < j && delta[ 3 ] == 0; i++ )
{
VectorSubtract( m.verts[ 0 ].xyz, m.verts[ i ].xyz, delta );
delta[ 3 ] = VectorNormalize( delta, delta );
}
/* secondary degenerate test */
if( delta[ 3 ] == 0 )
degenerate = qtrue;
else
{
/* if all vectors match this or are zero, then this is a degenerate patch */
for( i = 1; i < j && degenerate == qtrue; i++ )
{
VectorSubtract( m.verts[ 0 ].xyz, m.verts[ i ].xyz, delta2 );
delta2[ 3 ] = VectorNormalize( delta2, delta2 );
if( delta2[ 3 ] != 0 )
{
/* create inverse vector */
VectorCopy( delta2, delta3 );
delta3[ 3 ] = delta2[ 3 ];
VectorInverse( delta3 );
/* compare */
if( VectorCompare( delta, delta2 ) == qfalse && VectorCompare( delta, delta3 ) == qfalse )
degenerate = qfalse;
}
}
}
/* warn and select degenerate patch */
if( degenerate )
{
xml_Select( "degenerate patch", mapEnt->mapEntityNum, entitySourceBrushes, qfalse );
free( m.verts );
return;
}
/* find longest curve on the mesh */
longestCurve = 0.0f;
maxIterations = 0;
for( j = 0; j + 2 < m.width; j += 2 )
{
for( i = 0; i + 2 < m.height; i += 2 )
{
ExpandLongestCurve( &longestCurve, verts[ i * m.width + j ].xyz, verts[ i * m.width + (j + 1) ].xyz, verts[ i * m.width + (j + 2) ].xyz ); /* row */
ExpandLongestCurve( &longestCurve, verts[ i * m.width + j ].xyz, verts[ (i + 1) * m.width + j ].xyz, verts[ (i + 2) * m.width + j ].xyz ); /* col */
ExpandMaxIterations( &maxIterations, patchSubdivisions, verts[ i * m.width + j ].xyz, verts[ i * m.width + (j + 1) ].xyz, verts[ i * m.width + (j + 2) ].xyz ); /* row */
ExpandMaxIterations( &maxIterations, patchSubdivisions, verts[ i * m.width + j ].xyz, verts[ (i + 1) * m.width + j ].xyz, verts[ (i + 2) * m.width + j ].xyz ); /* col */
}
}
/* allocate patch mesh */
pm = safe_malloc( sizeof( *pm ) );
memset( pm, 0, sizeof( *pm ) );
/* ydnar: add entity/brush numbering */
pm->entityNum = mapEnt->mapEntityNum;
pm->brushNum = entitySourceBrushes;
/* set shader */
sprintf( shader, "textures/%s", texture );
pm->shaderInfo = ShaderInfoForShader( shader );
/* set mesh */
pm->mesh = m;
/* set longest curve */
pm->longestCurve = longestCurve;
pm->maxIterations = maxIterations;
/* link to the entity */
pm->next = mapEnt->patches;
mapEnt->patches = pm;
}
qboolean FloodEntities( tree_t *tree )
{
int i, s;
vec3_t origin, offset, scale, angles;
qboolean r, inside, tripped, skybox;
node_t *headnode;
entity_t *e;
const char *value;
headnode = tree->headnode;
Sys_FPrintf( SYS_VRB,"--- FloodEntities ---\n" );
inside = qfalse;
tree->outside_node.occupied = 0;
tripped = qfalse;
c_floodedleafs = 0;
for( i = 1; i < numEntities; i++ )
{
/* get entity */
e = &entities[ i ];
/* get origin */
GetVectorForKey( e, "origin", origin );
if( VectorCompare( origin, vec3_origin ) )
continue;
/* handle skybox entities */
value = ValueForKey( e, "classname" );
if( !Q_stricmp( value, "_skybox" ) )
{
skybox = qtrue;
skyboxPresent = qtrue;
/* invert origin */
VectorScale( origin, -1.0f, offset );
/* get scale */
VectorSet( scale, 64.0f, 64.0f, 64.0f );
value = ValueForKey( e, "_scale" );
if( value[ 0 ] != '\0' )
{
s = sscanf( value, "%f %f %f", &scale[ 0 ], &scale[ 1 ], &scale[ 2 ] );
if( s == 1 )
{
scale[ 1 ] = scale[ 0 ];
scale[ 2 ] = scale[ 0 ];
}
}
/* get "angle" (yaw) or "angles" (pitch yaw roll) */
VectorClear( angles );
angles[ 2 ] = FloatForKey( e, "angle" );
value = ValueForKey( e, "angles" );
if( value[ 0 ] != '\0' )
sscanf( value, "%f %f %f", &angles[ 1 ], &angles[ 2 ], &angles[ 0 ] );
/* set transform matrix (thanks spog) */
m4x4_identity( skyboxTransform );
m4x4_pivoted_transform_by_vec3( skyboxTransform, offset, angles, eXYZ, scale, origin );
}
else
skybox = qfalse;
/* nudge off floor */
origin[ 2 ] += 1;
/* debugging code */
//% if( i == 1 )
//% origin[ 2 ] += 4096;
/* find leaf */
r = PlaceOccupant( headnode, origin, e, skybox );
if( r )
inside = qtrue;
if( (!r || tree->outside_node.occupied) && !tripped )
{
xml_Select( "Entity leaked", e->mapEntityNum, 0, qfalse );
tripped = qtrue;
}
}
Sys_FPrintf( SYS_VRB, "%9d flooded leafs\n", c_floodedleafs );
if( !inside )
Sys_FPrintf( SYS_VRB, "no entities in open -- no filling\n" );
else if( tree->outside_node.occupied )
Sys_FPrintf( SYS_VRB, "entity reached from outside -- no filling\n" );
return (qboolean) (inside && !tree->outside_node.occupied);
}
