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// Hyperbolic Rogue -- Arbitrary Tilings
// Copyright (C) 2011-2019 Zeno Rogue, see 'hyper.cpp' for details
/** \file arbitrile.cpp
* \ brief Arbitrary tilings
*
* Arbitrary tilings , defined in . tes files .
*/
# include "hyper.h"
namespace hr {
EX namespace arb {
# if HDR
struct shape {
int id ;
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int flags ;
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vector < hyperpoint > vertices ;
vector < ld > angles ;
vector < ld > edges ;
vector < tuple < int , int , int > > connections ;
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int size ( ) const { return isize ( vertices ) ; }
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void build_from_angles_edges ( ) ;
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vector < pair < int , int > > sublines ;
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} ;
struct arbi_tiling {
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int order ;
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bool have_line , have_ph ;
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vector < shape > shapes ;
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string name ;
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string comment ;
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geometryinfo1 & get_geometry ( ) ;
eGeometryClass get_class ( ) { return get_geometry ( ) . kind ; }
ld scale ( ) ;
} ;
# endif
EX arbi_tiling current ;
/** id of vertex in the arbitrary tiling */
EX short & id_of ( heptagon * h ) { return h - > zebraval ; }
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struct hr_polygon_error : hr_exception {
vector < transmatrix > v ;
eGeometryClass c ;
int id ;
hr_polygon_error ( const vector < transmatrix > & _v , int _id ) : v ( _v ) , c ( cgclass ) , id ( _id ) { }
~ hr_polygon_error ( ) noexcept ( true ) { }
} ;
void start_debugger ( hr_polygon_error & err ) {
stop_game ( ) ;
if ( err . c ! = cgclass ) {
if ( err . c = = gcEuclid ) set_geometry ( gEuclid ) ;
if ( err . c = = gcHyperbolic ) set_geometry ( gNormal ) ;
if ( err . c = = gcSphere ) set_geometry ( gSphere ) ;
}
if ( specialland ! = laCanvas ) {
canvas_default_wall = waInvisibleFloor ;
patterns : : whichCanvas = ' g ' ;
patterns : : canvasback = 0xFFFFFF ;
firstland = specialland = laCanvas ;
}
start_game ( ) ;
drawthemap ( ) ;
mapeditor : : drawing_tool = true ;
pushScreen ( mapeditor : : showDrawEditor ) ;
mapeditor : : initdraw ( cwt . at ) ;
int n = isize ( err . v ) ;
mapeditor : : dtcolor = 0xFF0000FF ;
mapeditor : : dtwidth = 0.02 ;
for ( int i = 0 ; i < n - 1 ; i + + )
mapeditor : : dt_add_line ( tC0 ( err . v [ i ] ) , tC0 ( err . v [ i + 1 ] ) , 0 ) ;
mapeditor : : dtcolor = 0xFFFFFFFF ;
for ( int i = 0 ; i < n ; i + + )
mapeditor : : dt_add_text ( tC0 ( err . v [ i ] ) , 0.5 , its ( i ) ) ;
}
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void shape : : build_from_angles_edges ( ) {
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transmatrix at = Id ;
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vertices . clear ( ) ;
int n = isize ( angles ) ;
hyperpoint ctr = Hypc ;
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vector < transmatrix > matrices ;
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for ( int i = 0 ; i < n ; i + + ) {
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matrices . push_back ( at ) ;
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println ( hlog , " at = " , at ) ;
vertices . push_back ( tC0 ( at ) ) ;
ctr + = tC0 ( at ) ;
at = at * xpush ( edges [ i ] ) * spin ( angles [ i ] ) ;
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}
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matrices . push_back ( at ) ;
if ( ! eqmatrix ( at , Id ) ) throw hr_polygon_error ( matrices , id ) ;
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if ( sqhypot_d ( 3 , ctr ) < 1e-2 ) {
// this may happen for some spherical tilings
// try to move towards the center
println ( hlog , " special case encountered " ) ;
for ( int i = 0 ; i < n ; i + + ) {
ctr + = at * xpush ( edges [ i ] ) * spin ( ( angles [ i ] + M_PI ) / 2 ) * xpush0 ( .01 ) ;
at = at * xpush ( edges [ i ] ) * spin ( angles [ i ] ) ;
}
println ( hlog , " ctr = " , ctr ) ;
}
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ctr = normalize ( ctr ) ;
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for ( auto & v : vertices ) v = gpushxto0 ( ctr ) * v ;
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}
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bool correct_index ( int index , int size ) { return index > = 0 & & index < size ; }
template < class T > bool correct_index ( int index , const T & v ) { return correct_index ( index , isize ( v ) ) ; }
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template < class T > void verify_index ( int index , const T & v , exp_parser & ep ) { if ( ! correct_index ( index , v ) ) throw hr_parse_exception ( " bad index: " + its ( index ) + " at " + ep . where ( ) ) ; }
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string unnamed = " unnamed " ;
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EX void load ( const string & fname ) {
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fhstream f ( fname , " rt " ) ;
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string s ;
while ( true ) {
int c = fgetc ( f . f ) ;
if ( c < 0 ) break ;
s + = c ;
}
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auto & c = current ;
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c . order + + ;
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c . shapes . clear ( ) ;
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c . name = unnamed ;
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c . comment = " " ;
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exp_parser ep ;
ep . s = s ;
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ld angleunit = 1 , distunit = 1 , angleofs = 0 ;
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auto addflag = [ & ] ( int f ) {
int ai ;
if ( ep . next ( ) = = ' ) ' ) ai = isize ( c . shapes ) - 1 ;
else ai = ep . iparse ( ) ;
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verify_index ( ai , c . shapes , ep ) ;
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c . shapes [ ai ] . flags | = f ;
ep . force_eat ( " ) " ) ;
} ;
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while ( true ) {
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ep . extra_params [ " distunit " ] = distunit ;
ep . extra_params [ " angleunit " ] = angleunit ;
ep . extra_params [ " angleofs " ] = angleofs ;
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ep . skip_white ( ) ;
if ( ep . next ( ) = = 0 ) break ;
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if ( ep . eat ( " # " ) ) {
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bool doubled = ep . eat ( " # " ) ;
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while ( ep . eat ( " " ) ) ;
string s = " " ;
while ( ep . next ( ) > = 32 ) s + = ep . next ( ) , ep . at + + ;
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if ( doubled ) {
if ( c . name = = unnamed ) c . name = s ;
else {
c . comment + = s ;
c . comment + = " \n " ;
}
}
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}
else if ( ep . eat ( " e2. " ) ) {
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ginf [ gArbitrary ] . g = giEuclid2 ;
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ginf [ gArbitrary ] . sides = 7 ;
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set_flag ( ginf [ gArbitrary ] . flags , qBOUNDED , false ) ;
}
else if ( ep . eat ( " h2. " ) ) {
ginf [ gArbitrary ] . g = giHyperb2 ;
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ginf [ gArbitrary ] . sides = 7 ;
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set_flag ( ginf [ gArbitrary ] . flags , qBOUNDED , false ) ;
}
else if ( ep . eat ( " s2. " ) ) {
ginf [ gArbitrary ] . g = giSphere2 ;
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ginf [ gArbitrary ] . sides = 5 ;
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set_flag ( ginf [ gArbitrary ] . flags , qBOUNDED , false ) ;
}
else if ( ep . eat ( " angleunit( " ) ) angleunit = real ( ep . parsepar ( ) ) ;
else if ( ep . eat ( " angleofs( " ) ) angleofs = real ( ep . parsepar ( ) ) ;
else if ( ep . eat ( " distunit( " ) ) distunit = real ( ep . parsepar ( ) ) ;
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else if ( ep . eat ( " line( " ) ) {
addflag ( arcm : : sfLINE ) ;
c . have_line = true ;
}
else if ( ep . eat ( " grave( " ) ) {
addflag ( arcm : : sfPH ) ;
c . have_ph = true ;
}
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else if ( ep . eat ( " let( " ) ) {
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string tok = ep . next_token ( ) ;
ep . force_eat ( " = " ) ;
ep . extra_params [ tok ] = ep . parsepar ( ) ;
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if ( debugflags & DF_GEOM )
println ( hlog , " let " , tok , " = " , real ( ep . extra_params [ tok ] ) ) ;
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}
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else if ( ep . eat ( " unittile( " ) ) {
c . shapes . emplace_back ( ) ;
auto & cc = c . shapes . back ( ) ;
cc . id = isize ( c . shapes ) - 1 ;
cc . flags = 0 ;
while ( ep . next ( ) ! = ' ) ' ) {
ld angle = ep . rparse ( 0 ) ;
cc . edges . push_back ( distunit ) ;
cc . angles . push_back ( angle * angleunit + angleofs ) ;
if ( ep . eat ( " , " ) ) continue ;
else if ( ep . eat ( " ) " )) break ;
else throw hr_parse_exception ( " expecting , or ) " ) ;
}
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try {
cc . build_from_angles_edges ( ) ;
}
catch ( hr_parse_exception & ex ) {
throw hr_parse_exception ( ex . s + ep . where ( ) ) ;
}
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cc . connections . resize ( cc . size ( ) ) ;
for ( int i = 0 ; i < isize ( cc . connections ) ; i + + )
cc . connections [ i ] = make_tuple ( cc . id , i , false ) ;
}
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else if ( ep . eat ( " tile( " ) ) {
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c . shapes . emplace_back ( ) ;
auto & cc = c . shapes . back ( ) ;
cc . id = isize ( c . shapes ) - 1 ;
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cc . flags = 0 ;
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while ( ep . next ( ) ! = ' ) ' ) {
ld dist = ep . rparse ( 0 ) ;
ep . force_eat ( " , " ) ;
ld angle = ep . rparse ( 0 ) ;
cc . edges . push_back ( dist * distunit ) ;
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cc . angles . push_back ( angle * angleunit + angleofs ) ;
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if ( ep . eat ( " , " ) ) continue ;
else if ( ep . eat ( " ) " )) break ;
else throw hr_parse_exception ( " expecting , or ) " ) ;
}
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try {
cc . build_from_angles_edges ( ) ;
}
catch ( hr_parse_exception & ex ) {
throw hr_parse_exception ( ex . s + ep . where ( ) ) ;
}
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cc . connections . resize ( cc . size ( ) ) ;
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for ( int i = 0 ; i < isize ( cc . connections ) ; i + + )
cc . connections [ i ] = make_tuple ( cc . id , i , false ) ;
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}
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else if ( ep . eat ( " conway( \" " ) ) {
string s = " " ;
while ( true ) {
int m = 0 ;
if ( ep . eat ( " ( " ) ) m = 0 ;
else if ( ep . eat ( " [ " ) ) m = 1 ;
else if ( ep . eat ( " \" " ) ) break ;
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else throw hr_parse_exception ( " cannot parse Conway notation, " + ep . where ( ) ) ;
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int ai = 0 ;
int as = ep . iparse ( ) ;
while ( ep . eat ( " ' " ) ) ai + + ;
if ( ep . eat ( " @ " ) ) ai = ep . iparse ( ) ;
int bi = 0 , bs = 0 ;
if ( ep . eat ( " ) " ) | | ep . eat ( " ] " ) ) bs = as , bi = ai ;
else {
bs = ep . iparse ( ) ;
while ( ep . eat ( " ' " ) ) bi + + ;
if ( ep . eat ( " @ " ) ) bi = ep . iparse ( ) ;
}
if ( ep . eat ( " ) " ) | | ep . eat ( " ] " ) ) { }
c . shapes [ ai ] . connections [ as ] = make_tuple ( bi , bs , m ) ;
c . shapes [ bi ] . connections [ bs ] = make_tuple ( ai , as , m ) ;
}
ep . force_eat ( " ) " ) ;
}
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else if ( ep . eat ( " c( " ) ) {
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int ai = ep . iparse ( ) ; verify_index ( ai , c . shapes , ep ) ; ep . force_eat ( " , " ) ;
int as = ep . iparse ( ) ; verify_index ( as , c . shapes [ ai ] , ep ) ; ep . force_eat ( " , " ) ;
int bi = ep . iparse ( ) ; verify_index ( bi , c . shapes , ep ) ; ep . force_eat ( " , " ) ;
int bs = ep . iparse ( ) ; verify_index ( bs , c . shapes [ bi ] , ep ) ; ep . force_eat ( " , " ) ;
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int m = ep . iparse ( ) ; ep . force_eat ( " ) " ) ;
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c . shapes [ ai ] . connections [ as ] = make_tuple ( bi , bs , m ) ;
c . shapes [ bi ] . connections [ bs ] = make_tuple ( ai , as , m ) ;
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}
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else if ( ep . eat ( " subline( " ) ) {
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int ai = ep . iparse ( ) ; verify_index ( ai , c . shapes , ep ) ; ep . force_eat ( " , " ) ;
int as = ep . iparse ( ) ; verify_index ( as , c . shapes [ ai ] , ep ) ; ep . force_eat ( " , " ) ;
int bs = ep . iparse ( ) ; verify_index ( bs , c . shapes [ ai ] , ep ) ; ep . force_eat ( " ) " ) ;
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c . shapes [ ai ] . sublines . emplace_back ( as , bs ) ;
}
else if ( ep . eat ( " sublines( " ) ) {
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ld d = ep . rparse ( ) * distunit ;
ld eps = 1e-4 ;
if ( ep . eat ( " , " ) ) eps = ep . rparse ( ) * distunit ;
ep . force_eat ( " ) " ) ;
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for ( auto & sh : c . shapes ) {
for ( int i = 0 ; i < isize ( sh . vertices ) ; i + + )
for ( int j = 0 ; j < isize ( sh . vertices ) ; j + + )
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if ( j ! = i + 1 & & i ! = j + 1 & & ! ( i = = 0 & & j = = isize ( sh . vertices ) - 1 ) & & ! ( j = = 0 & & i = = isize ( sh . vertices ) - 1 ) & & i ! = j ) {
ld dist = hdist ( sh . vertices [ i ] , sh . vertices [ j ] ) ;
if ( abs ( dist - d ) < eps ) {
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sh . sublines . emplace_back ( i , j ) ;
println ( hlog , " add subline " , i , " - " , j ) ;
}
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}
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}
}
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else throw hr_parse_exception ( " expecting command, " + ep . where ( ) ) ;
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}
}
geometryinfo1 & arbi_tiling : : get_geometry ( ) {
return ginf [ gEuclid ] . g ;
}
map < heptagon * , vector < pair < heptagon * , transmatrix > > > altmap ;
EX map < heptagon * , pair < heptagon * , transmatrix > > arbi_matrix ;
EX hrmap * current_altmap ;
heptagon * build_child ( heptspin p , pair < int , int > adj ) ;
struct hrmap_arbi : hrmap {
heptagon * origin ;
heptagon * getOrigin ( ) override { return origin ; }
hrmap_arbi ( ) {
dynamicval < hrmap * > curmap ( currentmap , this ) ;
origin = tailored_alloc < heptagon > ( current . shapes [ 0 ] . size ( ) ) ;
origin - > s = hsOrigin ;
origin - > emeraldval = 0 ;
origin - > zebraval = 0 ;
origin - > fiftyval = 0 ;
origin - > fieldval = 0 ;
origin - > rval0 = origin - > rval1 = 0 ;
origin - > cdata = NULL ;
origin - > alt = NULL ;
origin - > c7 = newCell ( origin - > type , origin ) ;
origin - > distance = 0 ;
heptagon * alt = NULL ;
if ( hyperbolic ) {
dynamicval < eGeometry > g ( geometry , gNormal ) ;
alt = tailored_alloc < heptagon > ( S7 ) ;
alt - > s = hsOrigin ;
alt - > emeraldval = 0 ;
alt - > zebraval = 0 ;
alt - > distance = 0 ;
alt - > c7 = NULL ;
alt - > alt = alt ;
alt - > cdata = NULL ;
current_altmap = newAltMap ( alt ) ;
}
transmatrix T = xpush ( .01241 ) * spin ( 1.4117 ) * xpush ( 0.1241 ) * Id ;
arbi_matrix [ origin ] = make_pair ( alt , T ) ;
altmap [ alt ] . emplace_back ( origin , T ) ;
cgi . base_distlimit = 0 ;
celllister cl ( origin - > c7 , 1000 , 200 , NULL ) ;
ginf [ geometry ] . distlimit [ 0 ] = cgi . base_distlimit = cl . dists . back ( ) ;
if ( sphere ) cgi . base_distlimit = SEE_ALL ;
}
~ hrmap_arbi ( ) {
/*
if ( hyperbolic ) for ( auto & p : arbi_matrix ) if ( p . second . first - > cdata ) {
delete p . second . first - > cdata ;
p . second . first - > cdata = NULL ;
}
*/
clearfrom ( origin ) ;
altmap . clear ( ) ;
arbi_matrix . clear ( ) ;
if ( current_altmap ) {
dynamicval < eGeometry > g ( geometry , gNormal ) ;
delete current_altmap ;
current_altmap = NULL ;
}
}
void verify ( ) override { }
transmatrix adj ( heptagon * h , int dl ) override {
auto & c = current ;
int t = id_of ( h ) ;
auto & sh = c . shapes [ t ] ;
int dr = gmod ( dl + 1 , sh . size ( ) ) ;
auto & co = sh . connections [ dl ] ;
int xt = get < 0 > ( co ) ;
int xdl = get < 1 > ( co ) ;
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int m = get < 2 > ( co ) ;
if ( h - > c . move ( dl ) ) xdl = h - > c . spin ( dl ) ;
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auto & xsh = c . shapes [ xt ] ;
int xdr = gmod ( xdl + 1 , xsh . size ( ) ) ;
hyperpoint vl = sh . vertices [ dl ] ;
hyperpoint vr = sh . vertices [ dr ] ;
hyperpoint vm = mid ( vl , vr ) ;
transmatrix rm = gpushxto0 ( vm ) ;
hyperpoint xvl = xsh . vertices [ xdl ] ;
hyperpoint xvr = xsh . vertices [ xdr ] ;
hyperpoint xvm = mid ( xvl , xvr ) ;
transmatrix xrm = gpushxto0 ( xvm ) ;
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transmatrix Res = rgpushxto0 ( vm ) * rspintox ( rm * vr ) ;
if ( m ) Res = Res * MirrorX ;
Res = Res * spintox ( xrm * xvl ) * xrm ;
if ( m ) swap ( vl , vr ) ;
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if ( hdist ( vl , Res * xvr ) + hdist ( vr , Res * xvl ) > .1 ) {
println ( hlog , " s1 = " , kz ( spintox ( rm * vr ) ) , " s2 = " , kz ( rspintox ( xrm * xvr ) ) ) ;
println ( hlog , tie ( t , dl ) , " = " , kz ( Res ) ) ;
println ( hlog , hdist ( vl , Res * xvr ) , " # " , hdist ( vr , Res * xvl ) ) ;
exit ( 3 ) ;
}
return Res ;
}
heptagon * create_step ( heptagon * h , int d ) override {
int t = id_of ( h ) ;
const auto & p = arbi_matrix [ h ] ;
heptagon * alt = p . first ;
auto & sh = current . shapes [ t ] ;
auto & co = sh . connections [ d ] ;
int xt = get < 0 > ( co ) ;
int e = get < 1 > ( co ) ;
int m = get < 2 > ( co ) ;
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auto & xsh = current . shapes [ xt ] ;
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transmatrix T = p . second * adj ( h , d ) ;
if ( hyperbolic ) {
dynamicval < eGeometry > g ( geometry , gNormal ) ;
dynamicval < hrmap * > cm ( currentmap , current_altmap ) ;
// transmatrix U = T;
current_altmap - > virtualRebase ( alt , T ) ;
// U = U * inverse(T);
}
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fixmatrix ( T ) ;
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if ( euclid ) {
/* hash the rough coordinates as heptagon* alt */
size_t s = size_t ( T [ 0 ] [ LDIM ] + .261 ) * 124101 + size_t ( T [ 1 ] [ LDIM ] + .261 ) * 82143 ;
alt = ( heptagon * ) s ;
}
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for ( auto & p2 : altmap [ alt ] ) if ( id_of ( p2 . first ) = = xt & & hdist ( tC0 ( p2 . second ) , tC0 ( T ) ) < 1e-2 ) {
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for ( int oth = 0 ; oth < p2 . first - > type ; oth + + ) {
ld err = hdist ( p2 . second * xsh . vertices [ oth ] , T * xsh . vertices [ e ] ) ;
if ( err < 1e-2 ) {
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static ld max_err = 0 ;
if ( err > max_err ) {
println ( hlog , " err = " , err ) ;
max_err = err ;
}
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h - > c . connect ( d , p2 . first , oth % p2 . first - > type , m ) ;
return p2 . first ;
}
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}
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}
auto h1 = tailored_alloc < heptagon > ( current . shapes [ xt ] . size ( ) ) ;
h1 - > distance = h - > distance + 1 ;
h1 - > zebraval = xt ;
h1 - > c7 = newCell ( h1 - > type , h1 ) ;
h1 - > alt = nullptr ;
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h1 - > cdata = nullptr ;
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h1 - > emeraldval = h - > emeraldval ^ m ;
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h - > c . connect ( d , h1 , e , m ) ;
arbi_matrix [ h1 ] = make_pair ( alt , T ) ;
altmap [ alt ] . emplace_back ( h1 , T ) ;
return h1 ;
}
void draw ( ) override {
dq : : visited . clear ( ) ;
dq : : enqueue ( centerover - > master , cview ( ) ) ;
while ( ! dq : : drawqueue . empty ( ) ) {
auto & p = dq : : drawqueue . front ( ) ;
heptagon * h = get < 0 > ( p ) ;
transmatrix V = get < 1 > ( p ) ;
dynamicval < ld > b ( band_shift , get < 2 > ( p ) ) ;
dq : : drawqueue . pop ( ) ;
if ( do_draw ( h - > c7 , V ) ) drawcell ( h - > c7 , V ) ;
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else continue ;
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for ( int i = 0 ; i < h - > type ; i + + ) {
transmatrix V1 = V * adj ( h , i ) ;
bandfixer bf ( V1 ) ;
dq : : enqueue ( h - > move ( i ) , V1 ) ;
}
}
}
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transmatrix relative_matrix ( heptagon * h2 , heptagon * h1 , const hyperpoint & hint ) override {
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return relative_matrix_recursive ( h2 , h1 ) ;
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}
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transmatrix adj ( cell * c , int dir ) override { return adj ( c - > master , dir ) ; }
ld spin_angle ( cell * c , int d ) override { return SPIN_NOT_AVAILABLE ; }
} ;
EX hrmap * new_map ( ) { return new hrmap_arbi ; }
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void run ( string fname ) {
stop_game ( ) ;
eGeometry g = geometry ;
arbi_tiling t = current ;
auto v = variation ;
set_geometry ( gArbitrary ) ;
try {
load ( fname ) ;
ginf [ gArbitrary ] . tiling_name = current . name ;
}
catch ( hr_polygon_error & poly ) {
set_geometry ( g ) ;
set_variation ( v ) ;
current = t ;
start_debugger ( poly ) ;
addMessage ( " polygon error, debugger started " ) ;
}
catch ( hr_parse_exception & ex ) {
println ( hlog , " failed: " , ex . s ) ;
set_geometry ( g ) ;
current = t ;
start_game ( ) ;
addMessage ( " failed: " + ex . s ) ;
}
start_game ( ) ;
}
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# if CAP_COMMANDLINE
int readArgs ( ) {
using namespace arg ;
if ( 0 ) ;
else if ( argis ( " -arbi " ) ) {
PHASEFROM ( 2 ) ;
shift ( ) ;
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run ( args ( ) ) ;
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}
else return 1 ;
return 0 ;
}
auto hook = addHook ( hooks_args , 100 , readArgs ) ;
# endif
EX bool in ( ) { return geometry = = gArbitrary ; }
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EX string tes = " tessellations/sample/marjorie-rice.tes " ;
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EX bool linespattern ( cell * c ) {
return current . shapes [ id_of ( c - > master ) ] . flags & arcm : : sfLINE ;
}
EX bool pseudohept ( cell * c ) {
return current . shapes [ id_of ( c - > master ) ] . flags & arcm : : sfPH ;
}
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EX void choose ( ) {
dialog : : openFileDialog ( tes , XLAT ( " open a tiling " ) , " .tes " ,
[ ] ( ) {
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run ( tes ) ;
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return true ;
} ) ;
}
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EX }
}