/** This file is part of Kig, a KDE program for Interactive Geometry... Copyright (C) 2002 Dominique Devriese This program 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. This program 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 this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA **/ #include "cabri-filter.h" #include "../kig/kig_document.h" #include "../kig/kig_part.h" #include "../misc/coordinate.h" #include "../objects/arc_type.h" #include "../objects/bogus_imp.h" #include "../objects/circle_type.h" #include "../objects/conic_types.h" #include "../objects/curve_imp.h" #include "../objects/line_imp.h" #include "../objects/line_type.h" #include "../objects/object_calcer.h" #include "../objects/object_drawer.h" #include "../objects/object_factory.h" #include "../objects/object_holder.h" #include "../objects/other_imp.h" #include "../objects/other_type.h" #include "../objects/point_type.h" #include "../objects/polygon_type.h" #include "../objects/transform_types.h" #include "../objects/vector_type.h" #include #include #include #include #include /** * a line: * "Nr": Type, Unknown, "CN:"NumberOfParents, "VN:"Unknown * Color, FillType, Thickness, "DS":Dots, "GT":SpecialAppearance, Visible, Fixed * ["Const": Parents] ["Val": Constants] * * Nr: Simple sequential numbering of the objects in a file. * Type: seen so far: Pt, Axes, Line, Cir * NumberOfParents: The number of parents that will be specified in * Parents * Color: * R -> red * O -> purple * Y -> yellow * P -> dark purple * V -> dark blue * Bl -> blue * lBl -> bright blue * G -> bright green * dG -> dark green * Br -> brown * dBr -> beige * lGr -> light grey * Gr -> grey * dGr -> dark grey * B -> black * FillType: * W -> not filled ( white ? ) * all values of the Color item are valid here too.. * Thickness: * t -> thin * tT -> medium * T -> Thick * Dots: * a specification for how a line should be drawn ( with many * dots, with short lines, it's a pretty generic format: the first * number signifies the number of sequential dots to draw first, and * the next is the sum of this first number with the number of * spaces to leave before starting a new segment. * SpecialAppearance: * a number indicating some way of specially drawing an object. This * can be modified using the "Modify Appearance" button in * Cabri. For example, for a segment, the number indicates the * amount of ticks to put on the segment, to indicate * correspondances between segments.. * Visible: * V means visible, I means invisible * Fixed: * St means fix this object ( if you move one of its parents, it * won't move ), nSt ( the default ) means don't fix this object. * Parents: * The numbers of the objects this object depends on * Constants: * Constants whose meaning depends on the type of object. E.g. for * a point, this means first x, then y component. */ struct CabriObject { uint id; TQCString type; uint numberOfParents; TQColor color; TQColor fillColor; int thick; int lineSegLength; int lineSegSplit; int specialAppearanceSwitch; bool visible; bool fixed; std::vector parents; std::vector data; }; KigFilterCabri::KigFilterCabri() { } KigFilterCabri::~KigFilterCabri() { } bool KigFilterCabri::supportMime( const TQString& mime ) { // ugly hack to avoid duplicate extension ( XFig and Cabri files // have the same .fig extension ). return ( mime == "image/x-xfig" ) || ( mime == "application/x-cabri" ); } static TQString readLine( TQFile& file ) { TQString ret; file.readLine( ret, 10000L ); if ( ret[ret.length() - 1] == '\n' ) ret.truncate( ret.length() - 1 ); if ( ret[ret.length() - 1] == '\r' ) ret.truncate( ret.length() - 1 ); return ret; } static TQColor translatecolor( const TQString& s ) { if ( s == "R" ) return TQt::red; if ( s == "O" ) return TQt::magenta; if ( s == "Y" ) return TQt::yellow; if ( s == "P" ) return TQt::darkMagenta; if ( s == "V" ) return TQt::darkBlue; if ( s == "Bl" ) return TQt::blue; if ( s == "lBl" ) return TQt::cyan; // TODO: bright blue if ( s == "G" ) return TQt::green; if ( s == "dG" ) return TQt::darkGreen; if ( s == "Br" ) return TQColor( 165, 42, 42 ); if ( s == "dBr" ) return TQColor( 128, 128, 0 ); if ( s == "lGr" ) return TQt::lightGray; if ( s == "Gr" ) return TQt::gray; if ( s == "dGr" ) return TQt::darkGray; if ( s == "B" ) return TQt::black; if ( s == "W" ) return TQt::white; kdDebug() << k_funcinfo << "unknown color: " << s << endl; return TQt::black; } bool KigFilterCabri::readObject( TQFile& f, CabriObject& myobj ) { // there are 4 lines per object in the file, so we read them all // four now. TQString line1, line2, line3, s; TQString file = f.name(); line1 = readLine( f ); line2 = readLine( f ); line3 = readLine( f ); // ignore line 4, it is empty.. s = readLine( f ); TQRegExp firstlinere( "^([^:]+): ([^,]+), ([^,]+), CN:([^,]*), VN:(.*)$" ); if ( ! firstlinere.exactMatch( line1 ) ) KIG_FILTER_PARSE_ERROR; bool ok; TQString tmp; tmp = firstlinere.cap( 1 ); myobj.id = tmp.toInt( &ok ); if ( !ok ) KIG_FILTER_PARSE_ERROR; tmp = firstlinere.cap( 2 ); myobj.type = tmp.latin1(); tmp = firstlinere.cap( 3 ); // i have no idea what this number means.. tmp = firstlinere.cap( 4 ); myobj.numberOfParents = tmp.toInt( &ok ); if ( ! ok ) KIG_FILTER_PARSE_ERROR; tmp = firstlinere.cap( 5 ); // i have no idea what this number means.. TQRegExp secondlinere( "^([^,]+), ([^,]+), ([^,]+), DS:([^ ]+) ([^,]+), GT:([^,]+), ([^,]+), (.*)$" ); if ( ! secondlinere.exactMatch( line2 ) ) KIG_FILTER_PARSE_ERROR; tmp = secondlinere.cap( 1 ); myobj.color = translatecolor( tmp ); // if ( ! color.isValid() ) KIG_FILTER_PARSE_ERROR; tmp = secondlinere.cap( 2 ); myobj.fillColor = translatecolor( tmp ); // if ( ! fillcolor.isValid() ) KIG_FILTER_PARSE_ERROR; tmp = secondlinere.cap( 3 ); myobj.thick = tmp == "t" ? 1 : tmp == "tT" ? 2 : 3; tmp = secondlinere.cap( 4 ); myobj.lineSegLength = tmp.toInt( &ok ); if ( ! ok ) KIG_FILTER_PARSE_ERROR; tmp = secondlinere.cap( 5 ); myobj.lineSegSplit = tmp.toInt( &ok ); if ( ! ok ) KIG_FILTER_PARSE_ERROR; tmp = secondlinere.cap( 6 ); myobj.specialAppearanceSwitch = tmp.toInt( &ok ); if ( ! ok ) KIG_FILTER_PARSE_ERROR; tmp = secondlinere.cap( 7 ); myobj.visible = tmp == "V"; tmp = secondlinere.cap( 8 ); myobj.fixed = tmp == "St"; TQRegExp thirdlinere( "^(Const: ([^,]*),? ?)?(Val: (.*))?$" ); if ( ! thirdlinere.exactMatch( line3 ) ) KIG_FILTER_PARSE_ERROR; tmp = thirdlinere.cap( 2 ); TQStringList parentsids = TQStringList::split( ' ', tmp ); for ( TQStringList::iterator i = parentsids.begin(); i != parentsids.end(); ++i ) { myobj.parents.push_back( ( *i ).toInt( &ok ) ); if ( ! ok ) KIG_FILTER_PARSE_ERROR; } if ( myobj.parents.size() != myobj.numberOfParents ) KIG_FILTER_PARSE_ERROR; tmp = thirdlinere.cap( 4 ); TQStringList valIds = TQStringList::split( ' ', tmp ); for ( TQStringList::iterator i = valIds.begin(); i != valIds.end(); ++i ) { myobj.data.push_back( ( *i ).toDouble( &ok ) ); if ( ! ok ) KIG_FILTER_PARSE_ERROR; } // kdDebug() // << k_funcinfo << endl // << "id = " << myobj.id << endl // << "type = " << myobj.type << endl // << "numberOfParents = " << myobj.numberOfParents << endl // << "color = " << myobj.color.name() << endl // << "fillcolor = " << myobj.fillColor.name() << endl // << "thick = " << myobj.thick << endl // << "lineseglength = " << myobj.lineSegLength << endl // << "linesegsplit = " << myobj.lineSegSplit << endl // << "specialAppearanceSwitch = " << myobj.specialAppearanceSwitch << endl // << "visible = " << visible << endl // << "fixed = " << myobj.fixed << endl // << "parents =" << endl; // for ( std::vector::iterator i = myobj.parents.begin(); i != myobj.parents.end(); ++i ) // kdDebug() << " " << *i << endl; // kdDebug() << "vals = " << endl; // for ( std::vector::iterator i = myobj.data.begin(); i != myobj.data.end(); ++i ) // kdDebug() << " " << *i << endl; return true; } KigDocument* KigFilterCabri::load( const TQString& file ) { TQFile f( file ); if ( ! f.open( IO_ReadOnly ) ) { fileNotFound( file ); return 0; } KigDocument* ret = new KigDocument(); TQString s = readLine( f ); TQString a = s.left( 21 ); TQString b = s.mid( 21 ); if( a != "FIGURE CabriII vers. " || ( b != "DOS 1.0" && b != "MS-Windows 1.0" ) ) { if ( s.left( 5 ) == "#FIG " ) { notSupported( file, i18n( "This is an XFig file, not a Cabri figure." ) ); return 0; } else KIG_FILTER_PARSE_ERROR; } // next we have: // line 2: empty line // line 3: window dimensions -> we don't need/use that... // line 4: empty line // line 5 through 8: center point // line 9 through 12: axes // so we skip 11 lines... for( int i = 0; i != 11; ++i) s = readLine( f ); // all Cabri files seem to at least have these center and axes... if ( f.atEnd() ) KIG_FILTER_PARSE_ERROR; std::vector holders; std::vector calcers; const ObjectFactory* fact = ObjectFactory::instance(); std::vector args; ObjectCalcer* oc = 0; while ( ! f.atEnd() ) { CabriObject obj; // we do one object each iteration.. if ( !readObject( f, obj ) ) return 0; // reading linestyle Qt::PenStyle ls = Qt::SolidLine; if ( ( obj.lineSegLength > 1 ) && ( obj.lineSegLength < 6 ) && ( obj.lineSegSplit > 1 ) && ( obj.lineSegSplit <= 10 ) ) ls = Qt::DotLine; else if ( ( obj.lineSegLength >= 6 ) && ( obj.lineSegSplit > 10 ) ) ls = Qt::DashLine; int ps = 0; args.clear(); for ( std::vector::iterator i = obj.parents.begin(); i != obj.parents.end(); ++i ) args.push_back( calcers[*i-3] ); // two fake objects at the start ( origin and axes.. ) if ( obj.id != calcers.size() + 3 ) KIG_FILTER_PARSE_ERROR; oc = 0; if ( obj.type == "Pt" ) { if ( ! args.empty() ) KIG_FILTER_PARSE_ERROR; if ( obj.data.size() != 2 ) KIG_FILTER_PARSE_ERROR; switch ( obj.specialAppearanceSwitch ) { case 0: { obj.thick -= 1; break; } case 2: { obj.thick += 1; break; } case 3: { obj.thick += 1; ps = 1; break; } case 4: { obj.thick += 2; ps = 4; break; } } // different sizes for points.. obj.thick *= 2; oc = fact->fixedPointCalcer( Coordinate( obj.data[0], obj.data[1] ) ); } else if ( obj.type == "Cir" ) { if ( args.size() == 1 ) { if ( obj.data.size() != 1 ) KIG_FILTER_PARSE_ERROR; ObjectConstCalcer* radc = new ObjectConstCalcer( new DoubleImp( obj.data[0] ) ); args.push_back( radc ); oc = new ObjectTypeCalcer( CircleBPRType::instance(), args ); } else if ( args.size() == 2 ) { if ( ! obj.data.empty() ) KIG_FILTER_PARSE_ERROR; oc = new ObjectTypeCalcer( CircleBCPType::instance(), args ); } else KIG_FILTER_PARSE_ERROR; } else if ( obj.type == "Line" || obj.type == "Ray" || obj.type == "Seg" || obj.type == "Vec" ) { if ( args.size() == 1 ) { if ( obj.data.size() != 2 ) KIG_FILTER_PARSE_ERROR; Coordinate vect( obj.data[0], obj.data[1] ); ObjectConstCalcer* vectorcalcer = new ObjectConstCalcer( new VectorImp( Coordinate( 0, 0 ), vect ) ); args.push_back( vectorcalcer ); ObjectTypeCalcer* secondpoint = new ObjectTypeCalcer( TranslatedType::instance(), args ); secondpoint->calc( *ret ); args[1] = secondpoint; } if ( args.size() != 2 ) KIG_FILTER_PARSE_ERROR; const ObjectType* t = 0; if ( obj.type == "Line" ) t = LineABType::instance(); else if ( obj.type == "Ray" ) t = RayABType::instance(); else if ( obj.type == "Seg" ) t = SegmentABType::instance(); else if ( obj.type == "Vec" ) t = VectorType::instance(); else assert( t ); oc = new ObjectTypeCalcer( t, args ); } else if ( obj.type == "Pt/" ) { // different sizes for points.. obj.thick *= 2; if ( args.size() != 1 || obj.data.size() != 2 ) KIG_FILTER_PARSE_ERROR; ObjectCalcer* parent = args[0]; if ( !parent->imp()->inherits( CurveImp::stype() ) ) KIG_FILTER_PARSE_ERROR; const CurveImp* curve = static_cast( parent->imp() ); Coordinate pt = Coordinate( obj.data[0], obj.data[1] ); double param = curve->getParam( pt, *ret ); args.push_back( new ObjectConstCalcer( new DoubleImp( param ) ) ); oc = new ObjectTypeCalcer( ConstrainedPointType::instance(), args ); } else if ( obj.type == "Perp" || obj.type == "Par" ) { if ( args.size() != 2 || obj.data.size() != 0 ) KIG_FILTER_PARSE_ERROR; const ObjectType* t = 0; if ( obj.type == "Perp" ) t = LinePerpendLPType::instance(); else if ( obj.type == "Par" ) t = LineParallelLPType::instance(); else assert( false ); oc = new ObjectTypeCalcer( t, args ); } else if ( obj.type == "Arc" ) { if ( args.size() != 3 || ! obj.data.empty() ) KIG_FILTER_PARSE_ERROR; oc = new ObjectTypeCalcer( ArcBTPType::instance(), args ); } else if ( obj.type == "Con" ) { if ( args.size() != 5 || !obj.data.empty() ) KIG_FILTER_PARSE_ERROR; oc = new ObjectTypeCalcer( ConicB5PType::instance(), args ); } else if ( obj.type == "Mid" ) { if ( args.size() == 2 ) { ObjectCalcer* c = new ObjectTypeCalcer( SegmentABType::instance(), args ); c->calc( *ret ); args.clear(); args.push_back( c ); } // midpoint -> this can be the midpoint of a segment, two // points, or a vector... if ( args.size() != 1 || !obj.data.empty() ) KIG_FILTER_PARSE_ERROR; ObjectCalcer* parent = args[0]; if ( parent->imp()->inherits( SegmentImp::stype() ) ) oc = fact->propertyObjectCalcer( parent, "mid-point" ) ; else if ( parent->imp()->inherits( VectorImp::stype() ) ) oc = fact->propertyObjectCalcer( parent, "vect-mid-point" ); else KIG_FILTER_PARSE_ERROR; } else if ( obj.type == "PBiss" ) { if ( args.size() == 2 ) { ObjectCalcer* c = new ObjectTypeCalcer( SegmentABType::instance(), args ); c->calc( *ret ); args.clear(); args.push_back( c ); } if ( args.size() != 1 || !obj.data.empty() ) KIG_FILTER_PARSE_ERROR; ObjectCalcer* parent = args[0]; ObjectCalcer* midpoint = 0; if ( parent->imp()->inherits( SegmentImp::stype() ) ) midpoint = fact->propertyObjectCalcer( parent, "mid-point" ) ; // else if ( parent->imp()->inherits( VectorImp::stype() ) ) // midpoint = fact->propertyObjectCalcer( parent, "vect-mid-point" ); else KIG_FILTER_PARSE_ERROR; midpoint->calc( *ret ); args.push_back( midpoint ); oc = new ObjectTypeCalcer( LinePerpendLPType::instance(), args ); } else if ( obj.type == "Pol" ) { if ( args.size() < 3 || !obj.data.empty() ) KIG_FILTER_PARSE_ERROR; oc = new ObjectTypeCalcer( PolygonBNPType::instance(), args ); } else if ( obj.type == "Locus" ) { if ( args.size() != 2 || !obj.data.empty() ) KIG_FILTER_PARSE_ERROR; oc = fact->locusCalcer( args[0], args[1] ); } else if ( obj.type == "Refl" ) { if ( args.size() != 2 || !obj.data.empty() ) KIG_FILTER_PARSE_ERROR; oc = new ObjectTypeCalcer( LineReflectionType::instance(), args ); } else if ( obj.type == "Sym" ) { if ( args.size() != 2 || !obj.data.empty() ) KIG_FILTER_PARSE_ERROR; oc = new ObjectTypeCalcer( PointReflectionType::instance(), args ); } else if ( obj.type == "Tran" ) { if ( args.size() != 2 || !obj.data.empty() ) KIG_FILTER_PARSE_ERROR; oc = new ObjectTypeCalcer( TranslatedType::instance(), args ); } else { notSupported( file, i18n( "This Cabri file contains a \"%1\" object, " "which Kig does not currently support." ).arg( TQString(obj.type) ) ); return 0; } if ( oc == 0 ) KIG_FILTER_PARSE_ERROR; oc->calc( *ret ); calcers.push_back( oc ); ObjectDrawer* d = new ObjectDrawer( obj.color, obj.thick, obj.visible, ls, ps ); ObjectHolder* oh = new ObjectHolder( oc, d ); holders.push_back( oh ); oc = 0; } ret->addObjects( holders ); ret->setGrid( false ); ret->setAxes( false ); return ret; } KigFilterCabri* KigFilterCabri::instance() { static KigFilterCabri t; return &t; }